Initial revision

git-svn-id: svn://localhost/trunk/ardour2@4 d708f5d6-7413-0410-9779-e7cbd77b26cf

69 files changed, 34422 insertions, 0 deletions

diff --git a/libs/sigc++2/.cvsignore b/libs/sigc++2/.cvsignore
new file mode 100644
index 0000000000..d505773e75
--- /dev/null
+++ b/libs/sigc++2/.cvsignore
@@ -0,0 +1,18 @@
+Makefile
+Makefile.in
+aclocal.m4
+autom4te.cache
+config.guess
+config.log
+config.status
+config.sub
+depcomp
+install-sh
+libsigc++-2.0.spec
+libtool
+ltmain.sh
+missing
+sigc++-2.0.pc
+stamp-h1
+configure
+sigc++config.h
diff --git a/libs/sigc++2/AUTHORS b/libs/sigc++2/AUTHORS
new file mode 100644
index 0000000000..000671ac0a
--- /dev/null
+++ b/libs/sigc++2/AUTHORS
@@ -0,0 +1,8 @@
+Martin Schulze <mschulze@cvs.gnome.org>
+Murray Cumming <murrayc@murrayc.com>
+Cedric Gustin <cedric.gustin@swing.be> (win32 support)
+Timothy M. Shead <tshead@k-3d.com> and James Lin <jameslin@vmware.com> (MSVC support)
+Damien Carbery <Damien.Carbery@Sun.COM> (Sun FORTE C++ support)
+Takashi Takekawa <takekawa@users.sourceforge.jp> (Intel C++ support)
+Andreas Rottmann <rottmann@users.sourceforge.net> (make system)
+Karl Einar Nelson <kenelson@ece.ucdavis.edu> (initial version 1.9.4)
diff --git a/libs/sigc++2/COPYING b/libs/sigc++2/COPYING
new file mode 100644
index 0000000000..c4792dd27a
--- /dev/null
+++ b/libs/sigc++2/COPYING
@@ -0,0 +1,515 @@
+
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diff --git a/libs/sigc++2/ChangeLog b/libs/sigc++2/ChangeLog
new file mode 100644
index 0000000000..8e02aef058
--- /dev/null
+++ b/libs/sigc++2/ChangeLog
@@ -0,0 +1,1249 @@
+2004-10-12  Martin Schulze  <mschulze@cvs.gnome.org>
+
+	* MSVC_Net2003/*/*.vcproj, MSVC_Net2003/blank.cpp: Fix project files
+	to compile out-of-the-box and add dummy file so that .cc files get
+	recognized as c++ code files (patch from Timothy M. Shead).
+
+2004-10-10  Martin Schulze <mschulze@cvs.gnome.org>
+
+	* sigc++/signal_base.{h,cc}, sigc++/functors/slot_base.{h,cc},
+	sigc++/functors/macros/slot.h.m4: If SIGC_NEW_DELETE_IN_LIBRARY_ONLY
+	is defined, implement signal_base::operator new/delete and
+	slot_rep::operator new/delete (suggested by Timothy M. Shead).
+	Remove old work-around from 2004-10-02 since it didn't work.
+
+2004-10-07  Martin Schulze <mschulze@cvs.gnome.org>
+
+	* configure.ac: Update for libtool 1.5a (with support for Intel C++).
+	* MSVC_Net2003/sigc++config.h: Remove bogus '#define'
+	(reported by Timothy M. Shead <tshead@k-3d.com>).
+
+2004-10-02  Martin Schulze <mschulze@cvs.gnome.org>
+
+	* configure.ac: Bump version number to 2.0.6.
+	* NEWS: Add ChangeLog summary for version 2.0.6.
+
+2004-10-02  Martin Schulze <mschulze@cvs.gnome.org>
+
+	* sigc++/functors/slot_base.{h,cc}, sigc++/functors/macros/slot.h.m4:
+	Rename (typed_)slot_rep::detach to (typed_)slot_rep::destroy.
+	Call the dtor of the functor stored in typed_slot_rep from destroy().
+	A cleaner solution would be to add an additional "virtual" function
+	that calls 'delete' or a real virtual dtor. However, this would be
+	less efficient and might break the ABI. (Fixes #152323.)
+
+2004-10-02  Martin Schulze <mschulze@cvs.gnome.org>
+
+	* sigc++config.h.in, MSVC_Net2003/sigc++config.h,
+	sigc++/signal_base.cc, sigc++/functors/slot_base.{h,cc},
+	sigc++/functors/macros/slot.h.m4: Define and use new macro
+	SIGC_NEW_DELETE_IN_LIBRARY_ONLY to ABI-compatibly move
+	all calls to new and delete into non-inline library code.
+
+2004-09-26  Martin Schulze <mschulze@cvs.gnome.org>
+
+	* sigc++/adaptors/lambda/macros/group.h.m4: Add a missing
+	template keyword in the definition of deduce_result_type::type
+	(hopefully fixes #152327).
+
+2004-09-26  Martin Schulze <mschulze@cvs.gnome.org>
+
+	* sigc++/macros/object_slot.h.m4: Use correct bound_mem_functor
+	variants for const (volatile) methods (fixes #148744).
+
+2004-09-01  Martin Schulze <mschulze@cvs.gnome.org>
+
+	* docs/index.html: Correct link to lambda module.
+
+2004-09-01  Martin Schulze <mschulze@cvs.gnome.org>
+
+	* README: Update compatibility section.
+
+2.0.5:
+
+2004-09-01  Martin Schulze <mschulze@cvs.gnome.org>
+
+	* MSVC_Net2003/Makefile.am: Add sigc++config.h to EXTRA_DIST.
+	* configure.ac: Bump version number to 2.0.5.
+	* NEWS: Add ChangeLog summary for version 2.0.5.
+
+2.0.4:
+
+2004-08-21  Martin Schulze <mschulze@cvs.gnome.org>
+
+	* tests/test_lambda.cc: Use sigc::var("\n") instead of sigc::ref("\n").
+	Comment out the affected lines, nevertheless.
+	Sun FORTE and Compaq C++ can handle neither sigc::ref("\n") nor
+	sigc::var("\n"). I see more chances fixing sigc::var("\n").
+	* sigc++/adaptors/lambda/macros/base.h.m4: Add a comment about a
+	possible work around for sigc::var("\n") compiler problems.
+	* tests/test_compatibility.cc: Remove a 'const' keyword that prevents
+	the test case from compiling with the Sun FORTE.
+	* tests/test_trackable.cc: Remove a 'virtual' keyword and an unused
+	variable to avoid compiler warnings.
+	* NEWS: Add ChangeLog summary for version 2.0.4.
+
+2004-08-03  Martin Schulze <mschulze@cvs.gnome.org>
+
+	* scripts/cxx.m4, sigc++config.h.in, configure.ac,
+	sigc++/adaptors/lambda/macros/operator.h.m4, tests/test_lambda.cc:
+	Rollback change from 2004-07-15: configure check
+	SIGC_OPERATOR_OVERLOAD_AMBIGUITY is not needed - the overload
+	ambiguity doesn't occur if the lambda operators take all arguments
+	as const reference.
+	* configure.ac: Bump version number to 2.0.4.
+
+2004-08-03  James Lin <slimjimmy@mail.com>
+
+	* Added SIGC_API qualifier to all externally-visible non-template 
+	classes/structs.
+	* Added #include <sigc++config.h> to the files that use SIGC_API.
+	* Added empty SIGC_API definition to sigc++config.h.in for non-MSVC
+	compilers.  I'm not sure if this is the right place to put this
+	(probably not).
+	* Added MSVC-specific sigc++config.h to the MSVC project directory.
+	(The comment in it probably should be edited.)
+	* Changed MSVC project settings to output a multi-threaded DLL, set 
+	the include paths to work (hopefully) out-of-the-box.  Disabled
+	precompiled headers, since they just complicate things and 
+	shouldn't be necessary for such a relatively project.
+
+2004-08-01  Martin Schulze <mschulze@cvs.gnome.org>
+
+	* sigc++/type_traits.h: Remove type_trait<>::instance()
+	(was unimplemented and unused; caused problems with the MSVC).
+
+2004-07-23  Martin Schulze <mschulze@cvs.gnome.org>
+
+	* Makefile.am: Fix typo concerning distribution of libsigc++-2.0.spec.
+	* AUTHORS: Mention our contributors for platforms Sun FORTE and Intel C++.
+
+2004-07-15  Martin Schulze <mschulze@cvs.gnome.org>
+
+	* *.h.m4: Don't call operator()() in sun_forte_workaround(); rather copy
+	operator()(). Calling operator()() makes a copy of the arguments causing
+	wrong results if an argument type is a reference. Hopefully fixes #147311.
+
+2004-07-15  Martin Schulze <mschulze@cvs.gnome.org>
+
+	* tests/test_lambda.cc: Break "std::cout << [expr] << a << std::endl;"
+	into "std::cout << [expr]; std::cout << a << std::endl;".
+	I hope this fixes #147313 where the right values for "[expr]" but wrong
+	values for "a" were written to std::cout for some compiler with optimizations
+	turned off.
+
+2004-07-15  Martin Schulze <mschulze@cvs.gnome.org>
+
+	* sigc++/adaptors/lambda/macros/operator.h.m4: Correct return type deduction
+	of lambda expressions in lambda_operator*::operator()(). Might be related to
+	bug #147313.
+	* sigc++/adaptors/lambda/macros/group.h.m4: Use m4 macro _P_().
+
+2004-07-15  Martin Schulze <mschulze@cvs.gnome.org>
+
+	* scripts/cxx.m4, sigc++config.h.in, configure.ac,
+	sigc++/adaptors/lambda/macros/operator.h.m4, tests/test_lambda.cc:
+	Add configure check SIGC_OPERATOR_OVERLOAD_AMBIGUITY for a SUN FORTE
+	compiler problem (bug #147391). Use it to decide whether the lambda
+	action operators may be overloaded (not doing so restricts the API slightly).
+	* sigc++/adaptors/lambda/macros/operator.h.m4: Add some doxygen comments
+	and remove attic code.
+	* sigc++/adaptors/lambda/macros/base.h.m4:
+	Add templates unwrap_lambda_type and unwrap_lambda_value() to support
+	the non-overloaded lambda action operators. Also add some doxygen comments
+	and remove attic code.
+	* sigc++/adaptors/lambda/macros/group.h.m4: Fix a bug that resulted in
+	gargabe values being passed on to the functor contained in the group adaptor
+	(partly fixes #147313).
+
+2004-07-11  Martin Schulze <mschulze@cvs.gnome.org>
+
+	* scripts/cxx.m4, sigc++config.h.in, configure.ac, *.h.m4:
+	Split SIGC_CXX_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+	into SIGC_CXX_GCC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+	and SIGC_CXX_MSVC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD.
+	Remove LIBSIGC_TEMPLATE_PREFIX. Add template keyword to
+	SIGC_WORKAROUND_OPERATOR_PARENTHESES depending on the configure checks.
+	Should fix the compiler problems with MSVC.
+
+2004-07-11  Martin Schulze <mschulze@cvs.gnome.org>
+
+	* examples/hello_world.cc: Use sigc::ptr_fun instead of std::ptr_fun.
+	(fixes bug #144846)
+
+2004-07-11  Eric Bourque <ericb@computer.org>
+
+	* libsigc++-2.0.spec.in: new file
+	* configure.ac : patched generate spec file
+	* .cvsignore: ignore generated file (Martin Schulze)
+	* Makefile.am: distribute spec file (Martin Schulze)
+
+2004-07-11  Murray Cumming  <murrayc@murrayc.com>
+
+	* sigc++/connection.cc: Added some comments.
+	* sigc++/trackable.cc: operator=(): Check for self-asignment, though I 
+	do not know of any actual bug that this fixes. Added some comments.
+	* sigc++/trackable.h Added some doxygen documentation.
+
+2004-07-09  Murray Cumming  <murrayc@murrayc.com>
+
+	* tests/: Added test_disconnect_during_emit.cc, to prove that this 
+	works.
+
+2004-07-08  Murray Cumming  <murrayc@murrayc.com>
+
+	* tests/test_retype_return.cc: foo::operator(int): return a 
+	value. The SUN Forte 5.5 compiler complains about this, as it should.
+
+2004-07-08  Murray Cumming  <murrayc@murrayc.com>
+
+	* sigc++/macros/signal.h.m4: class signal*: Rename the slot_list 
+	typedef to slot_list_type, because there is already a template class 
+	called slot_type. SUN Forte 5.5 seems to complain about this and I am 
+	not surprised. The old typdef is still there for backwards 
+	compatibility, except when building with SUN Forte.
+
+2004-07-07  Murray Cumming  <murrayc@murrayc.com>
+
+	* scripts/cxx.m4: SIGC_CXX_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD():
+	Don't define the SIGC_TEMPLATE_SPECIALIZATOIN_OPERATOR_OVERLOAD C 
+	macro at all if the test fails. This might fix the build on SUN Forte.
+	* sigc++/functors/macros/mem_fun.h.m4: Default constructor: Initialize 
+	the func_ptr_ member variable. I have no evidence that this solves any 
+	problems, but it worried me.
+	* sigc++/functors/slot_base.h: operator bool(): Correct documentation, 
+	to use @code instead of <code>
+	* sigc++/macros/signal.h.m4: Remove the documentation for the 
+	parameters named first and last, because they do not exist.
+
+2004-05-31  Martin Schulze  <mschulze@cvs.gnome.org>
+
+	* autogen.sh: Add '--force'-flag to the 'libtoolize'-command (bug #143425).
+
+2.0.3:
+
+2004-05-30  Martin Schulze  <mschulze@cvs.gnome.org>
+
+	* configure.ac: Bump version number to 2.0.3.
+	* NEWS: Add ChangeLog summary for version 2.0.3.
+	* sigc++/macros/signal.h.m4: Fix segfault on emission of unconnected signal.
+	* tests/test_signal.cc, tests/test_accumulated.cc: Emit unconnected signal.
+	* sigc++/macros/object_slot.h.m4: Suppress compiler warning at
+	dynamic_cast<>-test (tested by Christof Petig/Timothy M. Shead).
+
+2.0.2:
+
+2004-05-22  Martin Schulze  <mschulze@cvs.gnome.org>
+
+	* configure.ac: Bump version number to 2.0.2.
+	* NEWS: Add ChangeLog summary for version 2.0.2.
+
+2004-05-20  Martin Schulze  <mschulze@cvs.gnome.org>
+
+	* sigc++/macros/signal.h.m4: If a custom accumulator is specified
+	invoke it on signal emission even if the signal's slot list is empty.
+	(This used to be the case in libsigc++-1.2 as pointed out by Timothy.)
+
+2004-05-20  Martin Schulze  <mschulze@cvs.gnome.org>
+
+	* sigc++/macros/object_slot.h.m4: Suppress compiler warning at
+	dynamic_cast<>-test (suggested by Timothy M. Shead).
+
+2004-05-01  Martin Schulze  <mschulze@cvs.gnome.org>
+
+	* README: Updated for libsigc++-2.0.
+
+2.0.1:
+
+2004-04-27  Martin Schulze  <mschulze@cvs.gnome.org>
+
+	* configure.ac: Bump version number to 2.0.1.
+	* NEWS: Add ChangeLog summary for version 2.0.1.
+	* sigc++/adaptors/lambda/macros/base.h.m4: Fixed documentation.
+	* sigc++/adaptors/macros/bind.h.m4: Hide work-arounds from doxygen.
+	* scripts/cxx.m4, sigc++config.h.in, configure.ac,
+	sigc++/adaptors/macros/bind.h.m4: Removed configure	check. It
+	showed that the Apple gcc can also compile the sophisticated version
+	of the work-around.
+
+2004-04-26  Martin Schulze  <mschulze@cvs.gnome.org>
+
+	* sigc++/macros/object_slot.h.m4: Modified test for SigC::Object
+	inheritance so that it also works if SigC::Object is virtual base.
+	(Fixes bug 141094 reported by Jonathan Brandmeyer)
+
+2004-04-26  Martin Schulze  <mschulze@cvs.gnome.org>
+
+	* scripts/cxx.m4: Updated the configure check. It would probably
+	have succeeded on the Apple.
+
+2004-04-26  Martin Schulze  <mschulze@cvs.gnome.org>
+
+	* sigc++/adaptors/macros/bind.h.m4: Add work-arounds for
+	bind<-1>::deduce_result_type compilation error on Apple gcc 3.3.
+	* scripts/cxx.m4, sigc++config.h.in, configure.ac: Add configure
+	check for the compilation error above.
+	* sigc++/adaptors/lambda/macros/operator.h.m4: Replace _A with
+	_Aa. _A is a reserved keyword on Apple gcc 3.3 (Spundun Bhatt).
+	(fixes bug #10444 reported by Spundun Bhatt)
+
+2004-04-19  Martin Schulze  <mschulze@cvs.gnome.org>
+
+  * sigc++/signal_base.cc: Fixed serious bug in signal_base::impl():
+  Only reference a newly created object (initial reference).
+  (This fixes bug #140269 reported by Andris.)
+
+2004-04-19  Murray Cumming  <murrayc@murrayc.com>
+
+	* scripts/cxx.m4: Updated the operator() template check, because it
+	failed with gcc 3.4 (from cvs). Apparently the template keyword can
+	only be used from another template.
+
+2.0.0:
+
+2004-04-06  Martin Schulze  <mschulze@cvs.gnome.org>
+
+	* configure.ac: Bump version number to 2.0.0.
+	* NEWS: Add ChangeLog summary for version 2.0.0.
+	* TODO, AUTHORS: Bring up to date.
+	* sigc++-2.0.pc.in, Makefile.am: 1.9 -> 2.0
+	* Added more documentation.
+
+2004-04-10  Murray Cumming  <murrayc@murrayc.com>
+
+	* sigc++/connection.[h|cc]: Implement blocked() to avoid undefined 
+	symbol linker error.
+
+2004-04-08  Murray Cumming  <murrayc@murrayc.com>
+
+	* dist the scripts directory.
+
+1.9.16:
+
+2004-04-06  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* configure.ac: Bump version number to 1.9.16.
+	* NEWS: Add ChangeLog summary for version 1.9.16.
+
+2004-04-02  Murray Cumming  <murrayc@murrayc.com>
+
+	* sigc++/connection.cc: Make block() and unblock() always return a 
+	value, to fix compiler warnings. Patch from bug #138620 by
+	Alexander Nedotsukov.
+
+2004-04-02  Murray Cumming  <murrayc@murrayc.com>
+
+	* Fix the compile of examples/member_method.cc. Bug #131701 from 
+	Kirill Smelkov. I also made the examples build as part of the regular
+	build.
+
+2004-04-02  Murray Cumming  <murrayc@murrayc.com>
+
+	* sigc++config.h.m4: Remove every undef apart from the one we need, to
+	avoid clashes, because we #include this in a public header.
+
+2004-03-25  Murray Cumming  <murrayc@murrayc.com>
+
+	* scripts/cxx.m4, configure.in, sigc++config.h.in: Rename the 
+	template_keyword check to template_specialization, because the problem
+	is with or without the keyword.
+	* sigc++/adaptors/macros/adaptor_trait.h.m4: Define 
+	SIGC_WORKAROUND_OPERATOR_PARENTHESES, which calls either operator() or 
+	sun_forte_workaround() depending on the result of the compiler test.
+	* many .m4 files: Add sun_forte_workaround methods that call the 
+	operator() methods. Put them in #ifdefs so that only SUN Forte C++ 
+	sees them.
+
+2004-03-22  Murray Cumming  <murrayc@murrayc.com>
+
+	* Makefile.am, sigc++/Makfile.am: Fix the sigc++config.h.in disting,
+	to fix make distcheck.
+
+2004-03-21  Murray Cumming  <murrayc@murrayc.com>
+
+	* Rename config.h.in to sigc++config.h.in so that gtkmm does not 
+	include some other config.h at strange times - fixes a problem in
+	the gtkmm demos. This should really be in the sigc++ directory, but
+	that seems to add that as an include path, which causes the STL
+	headers to include sigc++/signal.h instead of some STL signal.h header.
+
+2004-03-20  Murray Cumming  <murrayc@murrayc.com>
+
+	* Makefile.am: Install the config.h platform-specific header.
+	* sigc++-2.0.pc.in: Report the include path for config.h
+
+2004-03-20  Murray Cumming  <murrayc@murrayc.com>
+
+	* Added config.h.in, using autoheader, from which config.h will be 
+	generated, so we can detect compiler features.
+	* configure.ac: Added AC_CONFIG_HEADER(config.h) to generate config.h
+	from config.h.in.
+	* scripts/cxx.m4: Added this directory and file, with a 
+	SIGC_CXX_TEMPLATE_KEYWORD_OPERATOR_OVERLOAD macro that defines 
+	the SIGC_TEMPLATE_KEYWORD_OPERATOR_OVERLOAD C macro.
+	* autogen.sh: Added -I scripts to the aclocal call, so that it finds
+	the m4 macro for configure.ac.
+	* sigc++/adapators/macros/adaptor_trait.h.m4: Include config.h and
+	use SIGC_TEMPLATE_KEYOWRD_OPERATOR_OVERLOAD.
+
+2004-03-18  Martin Schulze  <mschulze@cvs.gnome.org>
+
+  * tests/test_mem_fun.cc, tests/test_ptr_fun.cc: Don't test
+  making functors from overloaded methods with partial template
+  specialization. Not portable among different compilers (SUN FORTE).
+  * adaptors/macros/apdaptor_trait.h.m4: Only gcc seems to use the
+  notation A.template operator()<...>(...) => adapt preprocessor check
+  for #define LIBSIGC_TEMPLATE_PREFIX. TODO: replace with configure check.
+
+2004-03-13  Murray Cumming  <murrayc@murrayc.com>
+
+	* g++ 3.4 (pre-release) build fixes:
+	* sigc++/macros/signal.h.m4: slot_iterator_buf::operator*():
+	Use blocked() and empty() instead of non-existant blocked_and_empty().
+	* sigc++/functors/macros/mem_fun.h.m4: memfun_functor*::operator()(): 
+	Use this->func_ptr_ instead of just func_ptr_.
+	* sigc++/adaptors/macros/deduce_result_type.h.m4: Use 
+	T_functor::template deduce_result_type<> instead of just
+	T_functor::deduce_result_type<>.
+	* sigc++/adaptors/lambda/macros/base.h.m4, operator.h.m4, group.h.m4:: 
+	Use template keyword again. operator[](): Use this->value_ instead of 
+	just value_.
+	* sigc++/adaptors/lambda/macros/bind/m4: Use template keyword, and 
+	this-> again.
+	* sigc++/adaptors/macros/compose.h.m4, hide.h.m4, bind_return.h.m4, 
+	exception_catch.h.m4:
+	rettype.h.m4, rettype_return.h.m4: Use template keyword,and this-> again
+
+1.9.15:
+
+2004-02-27  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* configure.ac: Bump version number to 1.9.15.
+	* NEWS: Add ChangeLog summary for version 1.9.15.
+
+2004-02-27  Martin Schulze  <teebaum@cvs.gnome.org>
+
+  * sigc++/functors/macros/slot.h.m4: Make the unnumbered slot templates'
+  copy ctors use the copy ctors of the base class. Fixes bug #24698.
+  * tests/test_slot.cc: Test copy ctor (Bryan Forbes).
+
+2004-02-27  Martin Schulze  <teebaum@cvs.gnome.org>
+
+  * tests/type_functor_trait.cc: Bring it up-to-date (use sigc::ref).
+  Make it work with the SUN Forte.
+
+2004-02-24  Martin Schulze  <teebaum@cvs.gnome.org>
+
+  * sigc++/type_traits.h: Make is_base_and_derived<> work with the SUN Forte.
+
+2004-02-19  Martin Schulze  <teebaum@cvs.gnome.org>
+
+  * sigc++/type_traits.h: Make is_base_and_derived<> platform independant.
+  * sigc++/adaptors/lambda/macros/base.h.m4: Make lambda_core<> ctors
+  explicit. Remove an unused ctor from lambda_core<T_type, true>.
+
+2004-02-14  Martin Schulze  <teebaum@cvs.gnome.org>
+
+  * sigc++/functors/slot_base.h, sigc++/functors/macros/slot.h.m4:
+  Move some documentation to slot_base.h.
+  * sigc++/signal_base.h, sigc++/macros/signal.h.m4:
+  Move some documentation to signal_base.h.
+
+  API addition:
+  * sigc++/functors/macros/slot.h.m4: Add numbered slot# templates.
+  Make unnumbered slot templates inherit from slot#.
+
+  API change:
+  * sigc++/functors/macros/mem_fun.h.m4: Allow for methods of the object's
+  base types to be passed into sigc::mem_fun(). (Used to be the case in
+  libsigc++-1.2).
+
+2004-02-13  Murray Cumming  <murrayc@usa.net>
+
+	* sigc++/functors/slot_base.[h|cc], sigc++/trackable.[h|cc]: Create 
+	and use a typedef for the destroy_notify callback functions, to avoid
+	confusion function pointer declaration syntax in the API.
+
+2004-02-13  Murray Cumming  <murrayc@murrayc.com>
+
+	* Moved implementation to .cc files:
+	* sigc++/functors/: Added slot_base.[h|cc] which contains non-template
+	code that was previsouly in the generated functors/slot.h and 
+	non-generated slot.cc files. All non-inline implementation is now in 
+	the .cc file.
+	* sigc++/functors/macros/slot.m4: Removed the code that has been moved
+	to slot_base.[h|cc].
+	* sigc++/: Added signal_base.[h|cc] which contains non-template code 
+	that was previously in the generated signal.h and non-generated
+	signal.cc file. All non-inline implementation is now in the .cc file.
+	* sigc++/macros/signal.m4: Removed the code that ahs been moved to
+	signal.cc
+	* sigc++/connector.[h|cc]: method implementation moved to the .cc file.
+
+1.9.14:
+
+2004-02-13  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* configure.ac: Bump version number to 1.9.14.
+	* NEWS: Add ChangeLog summary for version 1.9.14.
+
+2004-02-09  Murray Cumming  <murrayc@usa.net>
+
+	* sigc++/functors/macros/slot.h.m4: slot_base: Added operator bool(), needed to
+	check for a slot that is created with the default constructor. This was
+	present in libsigc++ 1.2 also.
+
+2004-02-06  Murray Cumming  <murrayc@usa.net>
+
+	* Makefile.am: Build the docs directory, by adding it to SUBDIRS.
+	* docs/Doxyfile.in: Updated to be more glibmm-like.
+	* Added some @deprecated doxygen bits.
+	* sigc++/macros/signal.h.m4: Call base constructor from signal_base
+	constructor - this is an error-as-warning when building gtkmm.
+
+1.9.13:
+
+2003-11-30  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* configure.ac: Bump version number to 1.9.13.
+	* NEWS: Add ChangeLog summary for version 1.9.13.
+	* Makefile.am, MSVC_Net2003/Makefile.am, configure.ac:
+	Distribute MS .Net project files.
+	* sigc++/adaptors/macros/[bind,hide].h.m4: Correct and add
+	documentation. Make hide_functor ctor explicit.
+
+2003-11-11  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* sigc++/adaptors/macros/[bind,hide].h.m4: Change to zero-based
+	argument index in numbered bind() and hide() overload
+	(Agreement on the mailing list).
+	Support binding up to CALL_SIZE arguments with one bind adaptor.
+	(Requested by joey yandle and others).
+	Only support binding of multiple arguments in unnumberd overloads
+	to keep the API simple (Requested by Murray Cumming).
+	* tests/test_[bind,hide,functor_trait].cc, sigc++/bind.h:
+	Reflect API changes in compatibility module and test cases.
+
+2003-11-10  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* sigc++/adaptors/macros/[bind,hide].h.m4: Add unnumbered
+	bind() and hide() overloads to make specifying the argument
+	position optional (Proposed by Jeff Franks).
+	* tests/test_[bind,hide].cc: Test unnumbered bind() and hide().
+	* sigc++/adaptors/macros/adaptor_trait.h.m4:
+	Change "#ifdef MSVC" to "#ifdef _MSC_VER" (Roel Vanhout).
+
+2003-11-09  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* sigc++/functors/macros/slot.h.m4: Change functor type in
+	typed_slot_rep to adaptor_trait::adaptor_type<T_functor>
+	and use explicit function template instantiation in
+	internal::slot_call::call_it(). Avoids copying of arguments
+	in call_it() and enables binding of object instances
+	to class methods through bind() (Reported by Jeff Franks).
+	* tests/test_bind.cc: Test binding object instances to
+	class methods through bind().
+	* sigc++/adaptors/adaptors.h: Include retype[_result].h.
+	* sigc++/adaptors/macros/adaptor_trait.h.m4:
+	- Add documentation.
+	- Mark some c-tors as explicit.
+	- Remove ununsed operator T_functor&() from adaptor_functor.
+	* sigc++/adaptors/macros/deduce_result_type.h.m4:
+	Rewrite parts of the documentation.
+	* sigc++/adaptors/macros/bind.h.m4: Add documentation.
+	* sigc++/functors/macros/mem_fun.h.m4: Remove unnecessary
+	explicit markers. Minor fixes to documentation.
+	* sigc++/functors/macros/functor_trait.h.m4:
+	Minor fixes to documentation.
+
+1.9.12:
+
+2003-11-04  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* configure.ac: Bump version number to 1.9.12.
+	* NEWS: Add ChangeLog summary for version 1.9.12.
+
+2003-11-03  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* sigc++/macros/signal.h.m4: Document accumulators.
+	Move slot_iterator_buf into namespace internal. Since
+	accumulators have the iterator type as a template argument
+	there is no need to expose this very internal type.
+	* sigc++/functors/macros/*.m4: Regroup documentation.
+	Documentation of the core parts of the library should be
+	complete by now.
+
+2003-11-02  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* Improve documentation of the core parts of the library.
+	* tests/test_ptr_fun.cc: Test ptr_fun() with static
+	member functions.
+
+2003-11-02  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* Move all .m4 files into new subdirectories
+	sigc++/[...]/macros. Install the .m4 files on
+	"make install" (Reported by Ron Steinke).
+
+2003-11-01  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* sigc++/[class,method,object]_slot.h.m4: Include
+	sigc++/functors/mem_fun.h (Reported by Ron Steinke).
+
+2003-11-01  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* sigc++/adaptors/lambda/operator.h.m4: Add negation
+	operator I have completely overlooked until now.
+	* sigc++/tests/test_lambda.cc: Test negation operator.
+
+2003-11-01  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* sigc++/[class_slot,method_slot,object_slot,hide].h.m4,
+	sigc++/signal.h.m4, sigc++/functors/mem_fun.h.m4:
+	- Use a shorter notation for ..._mem_function variants.
+	- Change order of mem_funcotr<>'s template arguments to
+	match std::mem_fun_t and to be more consistent with adaptors.
+	- Use ::sigc::slot's implicit ctor in compatibility module.
+	* sigc++/adaptors/lambda/operator.h.m4: Change some
+	lambda action names to match action names in std.
+
+	API addition:
+	* sigc++/adaptors/retype.h.m4: New file adding
+	adaptor retype.
+	* sigc++/Makefile.am: Build and distribute new file.
+	* tests/test_retype.cc: New file testing adaptor retype.
+	* MSVC_Net2003/tests/test_retype/test_reytype.vcproj,
+	tests/Makefile.am: Build and distribute new test case.
+
+2003-11-01  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* MSVC_Net2003: New directory containing project
+	files for Visual Studio .Net 2003.
+	Credits to Roel Vanhout <roel@riks.nl>!
+
+2003-11-01  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* sigc++/retype.h.m4: Use LIBSIGC_TEMPLATE_PREFIX
+	in explicit function template instantiations.
+	* sigc++/type_traits.h: Add template specialization
+	for arrays (T_type[N]) to disable non-working member
+	type_trait<T_type[N]>::instance().
+	* sigc++/visit_each.h: Remove more disturbing
+	limit_derived_target<>::operator() overloads.
+	(Should have noticed earlier that they are unnecessary.)
+	* sigc++/adaptors/deduce_result_type.h.m4,
+	sigc++/adaptors/lambda/operator.h.m4,
+	sigc++/functors/functor_trait.h.m4,
+	tests/test_[bind,compose,exception_catch,hide,lambda].cc:
+	Completely removed support for typeof(). We don't need
+	it any more and it is completely non-standard!
+
+2003-10-30  Cedric Gustin <cedric.gustin@swing.be>
+ 
+ 	* configure.ac: Added test of win32 platform. Commented
+ 	out AM_DISABLE_SHARED (DLLs are shared libraries).
+ 	* sigc++/Makefile.am: added a few LDFLAGS for win32
+ 	DLLs.
+
+2003-10-30  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* sigc++/signal.h.m4: Add SigC::Signal#<>::slot().
+	* sigc++/slot.h.m4: Comment out make_slot() work-around.
+	* sigc++/adaptors/bind.h.m4: Remove unnecessary brackets
+	in template argument lists. They are confusing MSVC.
+	* sigc++/adaptors/*.h.m4, sigc++/adaptors/lambda/*.h.m4:
+	Use LIBSIGC_TEMPLATE_PREFIX in explicit function
+	template instantiations.
+	* sigc++/tests/test_*.cc:
+	- Include <string> where std::string is used.
+	- Use double instead of float.
+
+2003-10-27  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* sigc++/retype.h.m4: Cleanup.
+	* TODO: Bring it up to date.
+
+1.9.11:
+
+2003-10-26  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* configure.ac: Bump version number to 1.9.11.
+	* NEWS: Add ChangeLog summary for version 1.9.11.
+
+2003-10-26  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	Compatiblity module:
+	* sigc++/signal.h.m4: Move definition of compatiblity
+	classes SigC::SignalN to here.
+	* sigc++/connection.h:
+	- Add connection::connected().
+	- Add compatibility typedef SigC::Connection.
+	* sigc++/bind.h, sigc++/bind_return.h,
+	sigc++/class_slot.h.m4,	sigc++/hide.h.m4,
+	sigc++/method_slot.h.m4, sigc++/object.h,
+	sigc++/object_slot.h.m4, sigc++/retype.h.m4,
+	sigc++/retype_return.h sigc++/slot.h.m4,
+	sigc++/compatibility.h:
+	New files to complete compatibility module.
+	Split content of compatibility.h.m4 among the new files.
+	* sigc++/compatibility.h.m4: Removed.
+	* Makefile.am: Build and distribute new files.
+	* tests/test_compatibility.cc: Test new stuff.
+
+	Fixes:
+	* sigc++/functors/slot.h.m4: Fix copy constructor and
+	operator=() of slot template.
+	* sigc++/adaptors/bind.h.m4: Fix deduce_result_type
+	template specializations. bind<0>() probably compiles
+	with gcc-3.3, now.
+
+2003-10-26  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	Fixes:
+	* sigc++/functors/slot.{cc,h.m4}:
+	- Fix notification process: don't defer detaching of a
+	slot from all referred trackables during signal emission!
+	- Size optimization: replace virtual functions from
+	struct typed_slot_rep with function pointers in slot_rep
+	(reduces size of a typical typed_slot_rep instantiation
+	by 30% !!!).
+	* tests/test_slot.cc: Test sigc::slot more thoroughly.
+	* sigc++/functors/mem_fun.h.m4: Fix visit_each().
+	* sigc++/adaptos/bind_return.h.m4: Add support for
+	sigc::ref().
+	* tests/test_bind_return.cc: Use sigc::ref().
+	* sigc++/signal.h.m4: Avoid compiler warning about
+	uninitialized variable r_ in emit().
+	* sigc++/visit_each.h: Cleanup.
+
+	API additions:
+	* sigc++/adpators/lambda/operators.h.m4: Add
+	lambda actions sigc::{reinterpret,static,dynamic}_cast_
+	to support explicit parameter conversion.
+	* tests/test_lambda.cc: Test sigc::static_cast_.
+	* sigc++/adaptors/retype_return.h.m4: New file adding
+	adaptor retype_return (and hide_return).
+	* sigc++/Makefile.am: Build and distribute new file.
+	* tests/test_retype_return.cc: New file testing
+	adaptor retype_return (and hide_return).
+	* tests/Makefile.am: Build and distribute new test case.
+
+2003-10-25  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* sigc++/visit_each.h: Remove disturbing
+	limit_derived_target<>::operator() overloads.
+	* sigc++/adaptors/bind.h.m4: Add support for sigc::ref().
+	* tests/test_bind.cc: Test sigc::ref().
+	* sigc++/adaptors/lambda/{operator,group,base}.h.m4:
+	- Move support for sigc::ref() from lambda_core<> into
+	lambda operator and lambda group creator functions.
+	- Add missing visit_each() overload for lambda<> template.
+	* tests/test_lambda.cc: Test auto-disconnection.
+	TODO: Fix a strange bug that leads to "Bus error"
+	during auto-disconnection.
+
+1.9.10:
+
+2003-10-23  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* configure.ac: Bump version number to 1.9.10.
+	* NEWS: Add ChangeLog summary for version 1.9.10.
+
+2003-10-23  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* sigc++/functors/{functor_trait,slot}.h.m4:
+	Move definition of struct nil into functor_trait.h.
+
+2003-10-23  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* configure.ac: Disable typeof() compiler checks.
+	* sigc++/adaptors/bind.h.m4: Remove unnecessary
+	deduce_result_type<> template specializations.
+
+2003-10-20  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* sigc++/adaptors/compose.h.m4:
+	Correct order of typedefs for good. (Patch from Jeff Franks.)
+
+1.9.9:
+
+2003-10-20  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* sigc++/connection.h: Add constructor that takes
+	a sigc::slot_base& to support 3rd-party slot lists
+	like they are used in glibmm/gtkmm.
+	* sigc++/functors/slot.h.m4: Make sigc::slot::call_type public.
+	(Fixes compile problems reported by Jeff Franks.)
+	* sig++/type_traits.h: Don't use long long in
+	sigc::is_base_and_derived.
+	(Fixes compile problems reported by Jeff Franks.)
+	* sigc++/adaptors/{bind,compose,hide,exception_catch}.h.m4:
+	Correct order of typedefs. (Repoted by Jeff Franks.)
+	* configure.ac: Bump version number to 1.9.9.
+	* NEWS: Add ChangeLog summary for version 1.9.9.
+
+1.9.8:
+
+2003-10-19  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* sigc++/functors/slot.h.m4: Define doxygen group functors.
+	* configure.ac: Bump version number to 1.9.8.
+	* NEWS: Add ChangeLog summary for version 1.9.8.
+
+2003-10-19  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* NEWS: Add announces of versions 1.9.6 and 1.9.7.
+	* sigc++/compatibility.h.m4: New file. Defines namespace SigC.
+	namespace SigC should be API compatible to libsigc++-1.2.
+	* sigc++/Makefile.am: Build compatibility.h.
+	* tests/test_compatibility.cc, tests/Makefile.am:
+	Add test case for compatibility module.
+	* docs/index.html: Change group names.
+	* sigc++/sigc++.h: Include connection.h.
+	* sigc++/connection.{cc,h}:
+	- Rename dependency to destroy_notify_callback.
+	- Change parameter name in set_slot() from d to data.
+	- Fix operator=(): Add "return *this;"
+	- Get rid of namespace functor.
+	- Corrections in documentation.
+	* sigc++/signal.{cc,h.m4}:
+	- Add reference counter to signal_impl. Replaces "bool destroy_".
+	- Move signal_base, slot_iterator[_buf], slot_list out of
+	namespace internal. They are part of the public API.
+	- Add convenience function signal#::make_slot().
+	- Get rid of namespace functor.
+	- Corrections in documentation.
+	* sigc++/trackable.{cc,h}:
+	- Rename dependency to destroy_notify_callback.
+	- Rename trackable::clear() to trackable::notify_callbacks().
+	- Corrections in documentation.
+	* sigc++/type_traits.h: Add documentation.
+	* sigc++/visit_each.h:
+	- Get rid of namespace functor.
+	- Add documentation.
+	* sigc++/adaptors[/lambda]/*: Get rid of namespace functor.
+	* sigc++/functors/{functor_trait.h,ptr_fun.h.m4,mem_fun.h.m4}:
+	- Get rid of namespace functor.
+	- Corrections in documentation / add documentation.
+	* sigc++/functors/slot.{cc,h.m4}:
+	- Move slot_base out of namespace internal. It's public API.
+	- Get rid of one-letter-parameter-names.
+	- Get rid of namespace functor.
+	- Corrections in documentation.
+	* tests/*.cc: Get rid of "using namespace ...".
+
+2003-09-10  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* sigc++/adaptors/lambda/{base,operators}.h.m4:
+	Add subscript ([]) and assign (=) operator. I think there are now
+	enough operators available to make any future power user happy.
+	The only one missing is the comma operator and if we added it
+	the logical consequence would be to also add if(), switch(), do(),
+	etc. lambda expressions which are really out of place in libsigc++.
+	* sigc++/type_traits.h: Fix is_base_and_derived<> for const types.
+	* tests/test_lambda.cc: Test new operators.
+
+1.9.7:
+
+2003-09-05  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* configure.ac: Bump version number to 1.9.7.
+
+2003-09-03  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* sigc++/adaptors/lambda/operator.h.m4:
+	- Restructure so that the size of the generated source file stays
+	reasonable for 34 operators: There are only two lambda templates
+	lambda_operator and lambda_operator_unary. The action is an additional
+	template parameter. A small template lambda_action[_unary] is specialized
+	for all actions.
+	- Add most operators that boost::lambda supports. Missing operators are
+	"=", "[]", "," and support for pointer arithmetic. I don't know if it's
+	worth adding these. In libsigc++, the purpose of lambda operators is to
+	provide some extra functionality for the group adaptor.
+	* tests/test_lambda.cc:
+	Test pre-increment, address and dereference operator.
+
+2003-08-31  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* sigc++/reference_wrapper.h, sigc++/type_traits.h, sigc++/Makefile.am:
+	New file reference_wrapper.h provides ref() to specify that adaptors/lambdas
+	should take a reference to the object passed into ref() instead of a copy.
+	* tests/test_lambda.cc:
+	- Test group() with mem_fun().
+	- Use ref() where lambdas should store references to objects.
+	- Test var() and constant().
+	* sigc++/adaptors/lambda/base.h.m4:
+	- Support ref() in return type deduction.
+	- Add var() and constant() which create lambdas for usage with lambda operators.
+	* sigc++/adaptors/lambda/operator.h.m4:
+	- Fix return type deduction.
+	- Remove operator{+,-,*,...} overloads added on 2003-08-29. ref() is way cleaner.
+	* sigc++/adaptors/lambda/group.h.m4,
+	sigc++/adaptors/bind.h.m4, sigc++/adaptors/compose.h.m4,
+	sigc++/adaptors/exception_catch.h.m4, sigc++/adaptors/hide.h.m4:
+	Fix return type deduction.
+
+2003-08-29  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* tests/test_lambda.cc: Add more tests.
+	* sigc++/adaptors/lambda/select.h.m4, sigc++/adaptors/lambda/lambda.cc.m4:
+	Make _1, _2, ... constant.
+	* sigc++/adaptors/lambda/operator.h.m4:
+	Add operator{+,-,*,...} overloads to distinguish between const and non-const objects.
+	Store references to non-const objects rather than copies.
+	This allows expressions like e.g. std::cout << _1.
+	* sigc++/adaptors/lambda/base.h.m4, sigc++/adaptors/lambda/group.h.m4:
+	Remove void specializations. Functors returning void are tested and work fine.
+
+2003-08-27  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* tests/test_callof.cc, tests/test_deduce_result_type.cc:
+	Rename, correct and improve this test case.
+	* tests/Makefile.am: Build and run test_deduce_result_type
+	instead of test_callof.
+
+2003-08-27  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* Update TODO.
+
+2003-08-27  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* sigc++/adaptors/hide.h.m4: Remove usage of callof_ignore_arg<>.
+	* sigc++/callof.h.m4, sigc++/adaptors/deduce_result_type.h.m4,
+	sigc++/functors/functor_trait.h.m4:
+	Remove the first and move deduce_result_type templates from
+	functor_trait.h.m4 into new file deduce_result_type.h.m4.
+	* sigc++/Makefile.am, sigc++/sigc++.h, sigc++/adaptors/adaptor_trait.h.m4:
+	Build and include sigc++/adaptors/deduce_result_type.h instead of callof.h.
+	* sigc++/functors/slot.h.m4: Document struct nil.
+
+2003-08-24  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* sigc++/functors/functor_trait.h.m4: Simplify usage of convenience
+	macro SIGC_FUNCTORS_HAVE_RESULT_TYPE:
+	namespace sigc{ namespace functor{ SIGC_FUNCTORS_HAVE_RESULT_TYPE }}
+
+2003-08-24  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* sigc++/functors/functor_trait.h,m4, sigc++/adaptors[/lambda]/*.h.m4:
+	Merge adaptor return type deduction and typeof() into
+	sigc::functor::deduce_result_type. Use it for all adaptors.
+	* tests/test_compose.cc: Only test multi-type get-functor if
+	typeof() if supported.
+
+2003-08-24  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* sigc++/adaptors[/lambda]/*.h.m4:
+	- Remove unnecessary void specializations. In fact, only the one
+	for sigc::functor::exception_catch<> is needed and I don't really
+	understand why. For the lambda stuff the void specializatoins are
+	just commented out at the moment.
+	- Make typeof() optional. Surprisingly, I got the lambda stuff working
+	without typeof()! The test suite doesn't catch all cases yet, so maybe
+	some thing are still not working.
+	TODO: Implement configure check.
+	* tests/test_bind.cc, tests/test_compose.cc tests/test_exception_catch.cc,
+	tests/test_hide.cc, tests/test_lambda.cc:
+	Only test multiple functor return types if typeof() is supported.
+
+2003-08-06  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* sigc++/trackable.{cc,h}: Add function trackable::clear().
+
+2003-06-24  Andreas Rottmann  <rottmann@users.sourceforge.net>
+
+	* TODO: Minor tweaks.
+
+2003-06-23  Andreas Rottmann  <rottmann@users.sourceforge.net>
+
+	* docs/reference/Doxyfile.in: Use these variables.
+	* docs/reference/Makefile.am (html/index.html): Provide doxygen 
+	with SRCDIR and TOP_SRCDIR environment variables.
+	
+	* sigc++/functors/slot.h.m4: Make slot::call_type typedef public;
+	this fixes a g++ 3.3 error in signal.h.
+
+	* sigc++/signal.h.m4: Make the signal::accumulated class public;
+	this fixes a g++ 3.3 error in test_accumulated.cc.
+
+2003-06-15  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* sigc++/functor/slot.h.m4: Correct typing error in docs.
+	* sigc++/functor/ptr_fun.h.m4: Document the whole thing.
+
+2003-05-31  Murray Cumming  <murrayc@usa.net>
+
+	* Reference documentation: Rearranged the groups to make it all
+	a bit more like the libsigc++ 1.2 reference documentation.
+	Corrected some spelling and grammar too.
+	This needs a lot of work. The text is very hard to read and it's
+	generally not appropriate for a user of the code who doesn't
+	care about the internals. But it's not impossible - our examples
+	should show us what we need to say in the documentation.
+	We probably need some more groups for the extra stuff, like we do
+	in libsigc++ 1.2.
+
+2003-05-29  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* sigc++/signal.h.m4: Fix documentation.
+	* sigc++/connection.h, sigc++/functor/slot.h.m4:
+	Document the whole thing.
+
+2003-05-29  Martin Schulze  <teebaum@cvs.gnome.org>
+
+	* sigc++/signal.h.m4:
+	- Remove bogus operator() from unnumbered signal<> and
+	  signal<>::accumulated templates.
+	- Document the whole thing.
+
+	* docs/index.html: Fix some links.
+
+2003-04-06  Martin Schulze  <MHL.Schulze@t-online.de>
+
+	* TODO, configure.ac, Makefile.am, docs/*:
+	Add Doxygen framework.
+
+2003-04-06  Martin Schulze  <MHL.Schulze@t-online.de>
+
+	* sigc++/callof.h.m4, sigc++/adaptors/*, tests/test_callof.cc:
+	Move sigc::callof<> to sigc::functor::internal::callof<>.
+
+	* sigc++/functors/mem_fun.h.m4, tests/test_mem_fun.cc:
+	Add new types [bound_][const_]volatile_mem_functor, visit_each()
+	and mem_fun() overloads for volatile qualifier.
+	Add ctor overloads in bound_*mem_functor and mem_fun() overloads
+	that take reference instead of pointer.
+
+2003-03-26  Martin Schulze  <MHL.Schulze@t-online.de>
+
+	* Change "closure" to "slot" throughout sigc++2 (file names,
+	class names, member variables, documentation, etc.).
+
+2003-03-26  Martin Schulze  <MHL.Schulze@t-online.de>
+
+	* TODO: Rewrite to reflect recent changes as well as recent discussions.
+
+2003-03-24  Martin Schulze  <MHL.Schulze@t-online.de>
+
+	* sigc++/adaptors/bind_return.h.m4: Make the adaptor's data member
+	public so that visit_each() can access it.
+
+	* sigc++/adaptors/lambda/*.h.m4: More fixes. Add a note about
+	malfunctioning typeof() (probably compiler bug in gcc-3.2).
+
+	* tests/*.cc: Test references. Fix compose equivalent in test_lambda.
+
+2003-03-24  Martin Schulze  <MHL.Schulze@t-online.de>
+
+	* sigc++/Makefile.am, sigc++/functors/functor_trait.h[.m4],
+	sigc++/adaptors/adaptor_trait.h.m4: Move detection of function
+	and member method pointers' return types from adaptor_trait into
+	functor_trait. (We'll use functor_trait rather than adaptor_trait for
+	our lambda stuff.) functor_trait.h needs to be generated from .m4 now.
+
+	* sigc++/functors/functor_trait.h.m4: Add convenience macros:
+	- SIGC_FUNCTORS_HAVE_RESULT_TYPE indicates that the existance of
+	T_functor::result_type should be assumed for all unknown functors.
+	- SIGC_FUNCTOR_TRAIT(T_functor, T_result) explicitly specifies the
+	result type of a functor.
+	("typename functor_trait<T_functor>::result_type") is used to
+	determine the return type of our adaptors' operator()() overloads.
+
+	* sigc++/adaptors/[lambda/]*.h.m4: Various fixes in visit_each() and
+	operator()() overloads to make these operator()() overloads usable.
+	Most of them were just commented out before. Some adaptor types also
+	have void specializations, now.
+
+	* sigc++/adaptors/lambda/group.h.m4: Change syntax from
+	"[some_functor] % grp([args])" to "group([some_functor], [args])"
+	like we agreed on the ml some time ago.
+
+	* sigc++/tests/test_[all adaptors].cc: Test stuff that didn't work
+	before.
+
+2003-03-22  Murray Cumming  <murrayc@usa.net>
+
+	* Added pgk-config file, from a mystery person in bug #108857
+
+2003-03-22  Martin Schulze  <MHL.Schulze@t-online.de>
+
+	* tests/test_bind.cc: Test and show how to use functor_trait
+	for user defined or 3rd-party functors so that a
+	bind<0>([functor],[arg1])() call with no arguments can return a value.
+
+2003-03-20  Martin Schulze  <MHL.Schulze@t-online.de>
+
+	* sigc++/callof.h.m4: Add explanations. Comment in / create templates
+	callof_safe[#]. Unfortunately they don't work for functors with overloaded
+	operator() so we don't use it for now. At least everything is documented.
+
+	* sigc++/functors/functor_trait.h, sigc++/functors/*.h.m4: Add back
+	functor_base compiler hint. We're using it now in adaptor_functor<>.
+
+	* sigc++/adaptors/{adaptor_trait,bind}.h.m4: Make operator() overloads
+	with no arguments return the result of the functor invocation.
+	Fix multiple bind<0>().
+	* tests/test_bind.cc: Test the stuff that's working now.
+
+2003-03-16  Murray Cumming  <murrayc@usa.net>
+
+	* Added sigc++/sigc++.h, like in libsigc++ 1.2
+	* examples: Added member_method example, which uses a class method
+	and which demonstrates disconnection.
+
+1.9.6:
+
+2003-03-11  Andreas Rottmann  <rottmann@users.sourceforge.net>
+
+	* sigc++/Makefile.am: Use substitution references instead of
+	$(patsubst). Is shorter and fixes the strange-dirs-in-dist-tarball
+	bug.
+
+2003-03-09  Martin Schulze  <MHL.Schulze@t-online.de>
+
+	* sigc++/connection.h: Add block() capability.
+
+2003-03-09  Martin Schulze  <MHL.Schulze@t-online.de>
+
+	* sigc++/signal.{cc,h.m4}: Add flag signal_impl::destroy_
+	and function signal_impl::destroy(). Use them to defer
+	the destruction of the signal_impl object during signal
+	emission.
+
+	* tests/test_disconnect.cc: Add tests for the connection
+	class and for deleting signals during emission.
+
+2003-03-09  Martin Schulze  <MHL.Schulze@t-online.de>
+
+	* sigc++/connection.{cc,h}, sigc++/Makefile.am:
+	- New files that add a connection class. Objects of this
+	  class are constructed from closure list iterators and can
+	  be used to disconnect the refered closure. As opposed to
+	  iterators they stay valid beyond the lifetime of the closure.
+
+2003-03-09  Martin Schulze  <MHL.Schulze@t-online.de>
+
+	* sigc++/functors/closure.{cc,h.m4}, sigc++/signal.cc:
+	- Rename closure_{base,rep}::[set_]dependency_ -> [set_]parent_.
+	- Make closure_rep inherit trackable. This allows for
+	  connection objects that stay valid beyond the life time
+	  of the refered closure.
+	- Make some one-line-functions inline again.
+
+2003-03-08  Martin Schulze  <MHL.Schulze@t-online.de>
+
+	* sigc++/trackable.cc: BUGFIX in trackable_dep_list::clear()
+
+2003-03-08  Andreas Rottmann  <rottmann@users.sourceforge.net>
+
+	* sigc++/Makefile.am: Rewritten so we can build lambda cleanly.
+	* sigc++/Makefile.am_fragment: Removed.
+
+	* sigc++/functors/Makfile.am: Removed.
+	* sigc++/adaptors/Makefile.am: Removed.
+	* sigc++/adaptors/lambda/Makefile.am: Removed.
+	* configure.ac (AC_OUTPUT): Remove the above Makefiles.
+
+	* tests/Makefile.am: Re-included lambda test.
+	
+2003-03-07  Martin Schulze  <MHL.Schulze@t-online.de>
+
+	* sigc++/signal.{cc,h.m4}:
+	- signal_emit#<>: New templates replacing signal#<>::caller.
+	  The purpose of these templates is implementing the emit
+	  function and optimizing signal emission for the case that
+	  no accumulator is used via template specializations.
+	- default_accumulator<>: Removed. The default for T_accumulator
+	  in signal#<> now is nil. An example how to use accumulators
+	  is available in tests/test_accumulator.cc.
+	- signal_{base,impl}: Move the implementation of signal_base's
+	  interface to signal_impl. An object of this class is
+	  dynamically allocated when first connecting a closure to
+	  the signal. This drastically reduces the size of empty signals
+	  and allows for future addition of a reference counter to make
+	  it safe to delete a signal during emission.
+	- Directly work on closure_rep during signal emission. This
+	  seems to be quicker than using the closure templates.
+	- Document the classes. Restructure the header file a bit.
+
+	* sigc++/functors/closure.h.m4: Make closure_base::rep_ data
+	member public, so that signal emission can directly work on it.
+
+	* tests/test_size.cc: Add an entry for signal_impl.
+
+2003-03-07  Martin Schulze  <MHL.Schulze@t-online.de>
+
+	* sigc++/functors/closure.{cc,h.m4}:
+	- closure_base: BUGFIXES in ~closure_base() and operator=().
+	- Mark some functions with the inline keyword. This seems to
+          help gcc 3.2 to optimize signal emission and (dis)connection.
+	- Document the classes. Restructure the header file a bit.
+
+2003-03-07  Martin Schulze  <MHL.Schulze@t-online.de>
+
+	* sigc++/trackable.{cc,h}: Make trackable allocate a
+	trackable_dep_list object dynamically when adding the first
+	dependency. (This reduces the size of objects, that are not
+	refered by a closure by 4 bytes (50%) and increases the size
+	of objects that are refered by a closure by 4 bytes (50%)
+	on a 32 bit architecture => This reduces total memory use
+	when >50% of the trackables are not refered by a closure.)
+	Document the classes.
+
+2003-03-05  Martin Schulze  <MHL.Schulze@t-online.de>
+
+	* tests/Makefile.am, tests/test_size.cc, tests/test_accumulated.cc:
+	Add two test cases. test_size is showing the size of  public and
+	internal structures. (Which apart from empty signals are smaller
+	than the sizes of the equivalent libsigc++-1.2 structures.)
+	test_accumulated is a test for the template signal<>::accumulated<>
+	at the same time showing the use of accumulators in libsigc++2.
+
+	* Offtopic: My note about binary sizes from 2003-02-10 is wrong.
+	Stripped libsigc++2 test binaries are about 8-10k in size.
+
+2003-03-05  Martin Schulze  <MHL.Schulze@t-online.de>
+
+	* sigc++/visit_each.h: BUGFIX in template specialization
+	limit_derive_target<T_Target*,T_action>::with_type<false,T_type>:
+	Add non-const overloads for static void execute_() avoiding
+	compile time errors.
+
+2003-02-16  Martin Schulze  <MHL.Schulze@t-online.de>
+
+	* tests/Makefile.am, tests/test_disconnect.cc:
+	Add testcase with a mixed connection & disconnection sequence.
+
+2003-02-16  Martin Schulze  <MHL.Schulze@t-online.de>
+
+	* sigc++/signal.cc: Bugfix in signal_base::insert():
+	Set notification function in the newly created copy of
+	slot_ rather than in slot_ itself.
+
+2003-02-10  Martin Schulze  <MHL.Schulze@t-online.de>
+
+	* sigc++/signal.h.m4: Comment in typedefs for iterator types in
+	the signal#<> class template. Make signal#<>::connect() return an
+	iterator for convenience.
+	(Note that the first change increases the binary size of
+	tests/test_signal from 201k to 204k, the second change to 206k.)
+
+2003-01-23  Murray Cumming  <murrayc@usa.net>
+
+	* sigc++/adaptors/lambda is disable temporarily (not built and
+	not distributed) because it gets built before its parent
+	directory, but #includes generated sources in the parent directory.
+
+2003-01-22  Murray Cumming  <murrayc@usa.net>
+
+	* Added Andreas Rottman's example.
+
+2003-01-22  Murray Cumming  <murrayc@usa.net>
+
+	* Applied Andreas Rottman's make dist fixes.
+
+2003-01-14  Murray Cumming  <murrayc@usa.net>
+
+	* Added whitespace to make the code more readable.
+
diff --git a/libs/sigc++2/INSTALL b/libs/sigc++2/INSTALL
new file mode 100644
index 0000000000..a4b34144dc
--- /dev/null
+++ b/libs/sigc++2/INSTALL
@@ -0,0 +1,229 @@
+Copyright 1994, 1995, 1996, 1999, 2000, 2001, 2002 Free Software
+Foundation, Inc.
+
+   This file is free documentation; the Free Software Foundation gives
+unlimited permission to copy, distribute and modify it.
+
+Basic Installation
+==================
+
+   These are generic installation instructions.
+
+   The `configure' shell script attempts to guess correct values for
+various system-dependent variables used during compilation.  It uses
+those values to create a `Makefile' in each directory of the package.
+It may also create one or more `.h' files containing system-dependent
+definitions.  Finally, it creates a shell script `config.status' that
+you can run in the future to recreate the current configuration, and a
+file `config.log' containing compiler output (useful mainly for
+debugging `configure').
+
+   It can also use an optional file (typically called `config.cache'
+and enabled with `--cache-file=config.cache' or simply `-C') that saves
+the results of its tests to speed up reconfiguring.  (Caching is
+disabled by default to prevent problems with accidental use of stale
+cache files.)
+
+   If you need to do unusual things to compile the package, please try
+to figure out how `configure' could check whether to do them, and mail
+diffs or instructions to the address given in the `README' so they can
+be considered for the next release.  If you are using the cache, and at
+some point `config.cache' contains results you don't want to keep, you
+may remove or edit it.
+
+   The file `configure.ac' (or `configure.in') is used to create
+`configure' by a program called `autoconf'.  You only need
+`configure.ac' if you want to change it or regenerate `configure' using
+a newer version of `autoconf'.
+
+The simplest way to compile this package is:
+
+  1. `cd' to the directory containing the package's source code and type
+     `./configure' to configure the package for your system.  If you're
+     using `csh' on an old version of System V, you might need to type
+     `sh ./configure' instead to prevent `csh' from trying to execute
+     `configure' itself.
+
+     Running `configure' takes awhile.  While running, it prints some
+     messages telling which features it is checking for.
+
+  2. Type `make' to compile the package.
+
+  3. Optionally, type `make check' to run any self-tests that come with
+     the package.
+
+  4. Type `make install' to install the programs and any data files and
+     documentation.
+
+  5. You can remove the program binaries and object files from the
+     source code directory by typing `make clean'.  To also remove the
+     files that `configure' created (so you can compile the package for
+     a different kind of computer), type `make distclean'.  There is
+     also a `make maintainer-clean' target, but that is intended mainly
+     for the package's developers.  If you use it, you may have to get
+     all sorts of other programs in order to regenerate files that came
+     with the distribution.
+
+Compilers and Options
+=====================
+
+   Some systems require unusual options for compilation or linking that
+the `configure' script does not know about.  Run `./configure --help'
+for details on some of the pertinent environment variables.
+
+   You can give `configure' initial values for configuration parameters
+by setting variables in the command line or in the environment.  Here
+is an example:
+
+     ./configure CC=c89 CFLAGS=-O2 LIBS=-lposix
+
+   *Note Defining Variables::, for more details.
+
+Compiling For Multiple Architectures
+====================================
+
+   You can compile the package for more than one kind of computer at the
+same time, by placing the object files for each architecture in their
+own directory.  To do this, you must use a version of `make' that
+supports the `VPATH' variable, such as GNU `make'.  `cd' to the
+directory where you want the object files and executables to go and run
+the `configure' script.  `configure' automatically checks for the
+source code in the directory that `configure' is in and in `..'.
+
+   If you have to use a `make' that does not support the `VPATH'
+variable, you have to compile the package for one architecture at a
+time in the source code directory.  After you have installed the
+package for one architecture, use `make distclean' before reconfiguring
+for another architecture.
+
+Installation Names
+==================
+
+   By default, `make install' will install the package's files in
+`/usr/local/bin', `/usr/local/man', etc.  You can specify an
+installation prefix other than `/usr/local' by giving `configure' the
+option `--prefix=PATH'.
+
+   You can specify separate installation prefixes for
+architecture-specific files and architecture-independent files.  If you
+give `configure' the option `--exec-prefix=PATH', the package will use
+PATH as the prefix for installing programs and libraries.
+Documentation and other data files will still use the regular prefix.
+
+   In addition, if you use an unusual directory layout you can give
+options like `--bindir=PATH' to specify different values for particular
+kinds of files.  Run `configure --help' for a list of the directories
+you can set and what kinds of files go in them.
+
+   If the package supports it, you can cause programs to be installed
+with an extra prefix or suffix on their names by giving `configure' the
+option `--program-prefix=PREFIX' or `--program-suffix=SUFFIX'.
+
+Optional Features
+=================
+
+   Some packages pay attention to `--enable-FEATURE' options to
+`configure', where FEATURE indicates an optional part of the package.
+They may also pay attention to `--with-PACKAGE' options, where PACKAGE
+is something like `gnu-as' or `x' (for the X Window System).  The
+`README' should mention any `--enable-' and `--with-' options that the
+package recognizes.
+
+   For packages that use the X Window System, `configure' can usually
+find the X include and library files automatically, but if it doesn't,
+you can use the `configure' options `--x-includes=DIR' and
+`--x-libraries=DIR' to specify their locations.
+
+Specifying the System Type
+==========================
+
+   There may be some features `configure' cannot figure out
+automatically, but needs to determine by the type of machine the package
+will run on.  Usually, assuming the package is built to be run on the
+_same_ architectures, `configure' can figure that out, but if it prints
+a message saying it cannot guess the machine type, give it the
+`--build=TYPE' option.  TYPE can either be a short name for the system
+type, such as `sun4', or a canonical name which has the form:
+
+     CPU-COMPANY-SYSTEM
+
+where SYSTEM can have one of these forms:
+
+     OS KERNEL-OS
+
+   See the file `config.sub' for the possible values of each field.  If
+`config.sub' isn't included in this package, then this package doesn't
+need to know the machine type.
+
+   If you are _building_ compiler tools for cross-compiling, you should
+use the `--target=TYPE' option to select the type of system they will
+produce code for.
+
+   If you want to _use_ a cross compiler, that generates code for a
+platform different from the build platform, you should specify the
+"host" platform (i.e., that on which the generated programs will
+eventually be run) with `--host=TYPE'.
+
+Sharing Defaults
+================
+
+   If you want to set default values for `configure' scripts to share,
+you can create a site shell script called `config.site' that gives
+default values for variables like `CC', `cache_file', and `prefix'.
+`configure' looks for `PREFIX/share/config.site' if it exists, then
+`PREFIX/etc/config.site' if it exists.  Or, you can set the
+`CONFIG_SITE' environment variable to the location of the site script.
+A warning: not all `configure' scripts look for a site script.
+
+Defining Variables
+==================
+
+   Variables not defined in a site shell script can be set in the
+environment passed to `configure'.  However, some packages may run
+configure again during the build, and the customized values of these
+variables may be lost.  In order to avoid this problem, you should set
+them in the `configure' command line, using `VAR=value'.  For example:
+
+     ./configure CC=/usr/local2/bin/gcc
+
+will cause the specified gcc to be used as the C compiler (unless it is
+overridden in the site shell script).
+
+`configure' Invocation
+======================
+
+   `configure' recognizes the following options to control how it
+operates.
+
+`--help'
+`-h'
+     Print a summary of the options to `configure', and exit.
+
+`--version'
+`-V'
+     Print the version of Autoconf used to generate the `configure'
+     script, and exit.
+
+`--cache-file=FILE'
+     Enable the cache: use and save the results of the tests in FILE,
+     traditionally `config.cache'.  FILE defaults to `/dev/null' to
+     disable caching.
+
+`--config-cache'
+`-C'
+     Alias for `--cache-file=config.cache'.
+
+`--quiet'
+`--silent'
+`-q'
+     Do not print messages saying which checks are being made.  To
+     suppress all normal output, redirect it to `/dev/null' (any error
+     messages will still be shown).
+
+`--srcdir=DIR'
+     Look for the package's source code in directory DIR.  Usually
+     `configure' can determine that directory automatically.
+
+`configure' also accepts some other, not widely useful, options.  Run
+`configure --help' for more details.
+
diff --git a/libs/sigc++2/Makefile.am b/libs/sigc++2/Makefile.am
new file mode 100644
index 0000000000..03d67389c6
--- /dev/null
+++ b/libs/sigc++2/Makefile.am
@@ -0,0 +1,30 @@
+
+# it includes all the autostuff automatically, you just name the
+# other stuff here
+EXTRA_DIST = autogen.sh sigc++config.h.in libsigc++-2.0.spec.in
+# ACLOCAL_FLAGS = -I scripts
+
+SUBDIRS      = sigc++ 
+DIST_SUBDIRS = $(SUBDIRS) 
+
+sigc_configdir = $(libdir)/sigc++-2.0/include
+sigc_config_DATA = sigc++config.h
+
+pkgconfigdir = $(libdir)/pkgconfig
+pkgconfig_DATA = sigc++-2.0.pc
+
+all-local:
+	@echo "*** Everything completed ***"
+
+dist-hook:
+	@echo; echo; \
+	echo "**********************************************************"; \
+	echo "* IMPORTANT NOTICE:                                      *"; \
+	echo "*                                                        *"; \
+	echo "* Be sure you have done a complete build before running  *"; \
+	echo "* 'make dist' or 'make distcheck', because otherwise     *"; \
+	echo "* the tarball will _not_ contain the dependency rules    *"; \
+	echo "* generated by the compiler.                             *"; \
+	echo "**********************************************************"; \
+	echo; echo \
+	cp libsigc++-2.0.spec $(distdir)
diff --git a/libs/sigc++2/NEWS b/libs/sigc++2/NEWS
new file mode 100644
index 0000000000..83c29f5626
--- /dev/null
+++ b/libs/sigc++2/NEWS
@@ -0,0 +1,232 @@
+*** libsigc++ 2.0:
+
+libsigc++ implements a typesafe callback system for standard C++. It
+allows you to define signals and to connect those signals to any
+callback function, either global or a member function, regardless of
+whether it is static or virtual.
+
+libsigc++ is used by gtkmm to wrap the GTK+ signal system. It does not depend 
+on GTK or gtkmm.
+
+libsigc++ 2.0 uses modern C++ mechanisms to achieve a highly flexible,
+yet typesafe callback system. It supports all features of libsigc++ 1.2
+and improves upon it with a simpler and more powerful API.
+
+This version of libsigc++ needs GNU g++ 3.2 or higher to compile.
+
+
+*** ChangeLog summary:
+
+2.0.6:
+
+* Fixed a memory leak in sigc::slot.
+* Fixed compilation for gcc-3.4.
+* Fixed compilation for Intel C++ compiler (upgraded libtool).
+* Fixed project files for MSVC .Net (Timothy M. Shead).
+* Fixed segfaults when compiled with MSVC .Net 2003 (moved
+  all calls to new and delete into non-inline library code).
+* In the compatibility module use correct bound_mem_functor
+  variants for const (volatile) methods when creating a slot.
+* Minor documentation fix.
+* Resolved bugs: #152327 #148744 #152323 #151404 #153143
+
+2.0.5:
+
+* Distribute pregenerated configuration header for MSVC .Net.
+
+2.0.4:
+
+* Fixed warnings and compiler errors in the test cases.
+* Added a new test case (Murray Cumming).
+* Fixed 'hello_world' example.
+* Don't test optional features that fail with the Sun FORTE.
+* Fixes for the Sun FORTE to compile out-of-the-box
+  (Damien Carbery, Murray Cumming, Martin Schulze).
+* Fixes for MSVC to build a DLL out-of-the-box (James Lin).
+* Improved compiler specific configuration during 'configure'.
+* Added rmp description file libsigc++-2.0.spec (Eric Bourque).
+* Minor documentation improvements (Murray Cumming).
+* Resolved bugs: #147311 #147313 #147391 #144846 #145541
+
+2.0.3:
+
+* Fix segfault on emission of unconnected signal.
+* Test emission of unconnected signals in the test case.
+* Suppress compiler warning at dynamic_cast<>-test for good.
+  (Help from Christof Petig and Timothy M. Shead.)
+
+2.0.2:
+
+* Suppress compiler warning in compatibility module at
+  dynamic_cast<>-test (fix suggested by Timothy M. Shead).
+* If a custom accumulator is specified invoke it on signal
+  emission even if the signal's slot list is empty. (This used
+  to be the case in libsigc++-1.2 as pointed out by Timothy.)
+
+2.0.1:
+
+* Fixed serious bug in reference counting in sigc::signal_base::impl().
+* Fixed SigC::Object-derivation check in SigC::slot() compatibility module.
+* Fixed compilation on Apple gcc 3.3 (assisted by Spundun Bhatt).
+* Fixed configure check for gcc 3.4 (Murray Cumming).
+
+2.0.0:
+
+* Implemented sigc::connection::blocked() (Murray Cumming).
+* Added the scripts directory to the make dist target (Murray Cumming).
+* Added more documentation (Martin Schulze).
+
+1.9.16:
+
+* Fixed compiler warning in sigc::connection (Alexander Nedotsukov, Murray Cumming).
+* Fixed examples and made them part of the regular build (Murray Cumming).
+* Added header sigc++config.h for configure time checks (Murray Cumming).
+* Added configure time checks to determine the correct syntax
+  for explicit template method specializations (Murray Cumming).
+* Removed code using partial specializations of overloaded template methods
+  from test cases. SUN Forte doesn't support this feature (Martin Schulze).
+* Fixed compilation for gcc 3.4 (Murray Cumming).
+
+1.9.15:
+
+API additions:
+* Add numbered slot# templates.
+* Allow for methods of the object's base types to be passed into sigc::mem_fun().
+
+Other fixes and cleanups:
+* Make is_base_and_derived template compatible with the SUN Forte.
+* Non-template code moved from .m4 macro source to .h/.cc files (Murray Cumming).
+* Implementation moved to .cc files (Murray Cumming).
+* More fixes for the SUN Forte. Make some more ctors explicit.
+
+1.9.14:
+
+* Added sigc::slot_base::operator bool() (Murray Cumming).
+* Build docs directory by default (Murray Cumming).
+* Fixed minor doxygen issues (Murray Cumming).
+* Fixed compiler warning in signal.h (Murray Cumming).
+
+1.9.13:
+
+* Fixed passing references through sigc::slot (Reported by Jeff Franks).
+* Enabled binding of objects to method slots through sigc::bind().
+* Reworked sigc::bind() API: Made the template argument for the
+  parameter position zero-based and optional. Added overloads for
+  binding of up to 7 arguments at a time when no position is specified.
+* Reworked sigc::hide() API: Made the template argument for the
+  parameter position zero-based and optional.
+* Fixed compilation problems with MSVC .Net 2003 (Roel Vanhout).
+* Distribute MSVC .Net 2003 project files in the tarballs.
+* Improved and extended documentation.
+* Minor cleanups.
+
+1.9.12:
+
+* Added adaptor retype(). With this final API addition all adaptors
+  are in place that are available in libsigc++-1.2.
+* Added negation lambda operator. Use STL names for lambda actions.
+* Remove formerly disabled support for gcc extension typeof().
+* Added project files for MS Visual Studio .Net 2003. (Roel Vanhout)
+* Make libsigc++2 compile with .Net 2003. (Roel Vanhout, Martin Schulze)
+* Build shared version of libsigc++2 by default. (Cedric Gustin)
+* Add support for win32 platform. (Cedric Gustin)
+* Install .m4 files. (requested by Ron Steinke)
+* Cleaned up functors.
+* Restructured and completed documentation of the core library parts.
+
+1.9.11:
+
+API Additions and important bug fixes:
+* Compatibility module completed. libsigc++-1.2 filenames are preserved.
+* Fixed critical bug in auto-disconnection: don't defer detaching
+  of a slot from all referred trackables during signal emission.
+* Reduced size of slots significantly.
+* Fixed support for sigc::ref() in adaptors.
+* Fixed sigc::visit_each(): only hit targets that are passed by
+  reference; pass bound members in bound_member_functor by reference.
+* Add lambda actions sigc::{reinterpret,static,dynamic}_cast_
+  to support explicit parameter conversion.
+* Add adaptors sigc::retype_return<>() and sigc::hide_return().
+
+Minor fixes:
+* Fixed return type deduction for bind<0>.
+  libsigc++-1.9.11 should compile with gcc-3.3.
+* Fixed copy constructor and operator=() of slot template.
+* Fixed a compiler warning in signal_emit#<>::emit().
+* Improved test case.
+
+1.9.10:
+
+* Fix compiler issues with gcc-3.3.2 (patch from Jeff Franks).
+* Remove compiler check for the gcc extension typeof().
+* Simplify bind_functor templates.
+* Move definition of struct nil into functor_trait.h.
+
+1.9.9:
+
+* Add a constructor to sigc::connection that takes a slot_base&
+  to support user defined slot lists like they are used in gtkmm.
+* Fix compiler issues with gcc-3.3.2 (reported by Jeff Franks).
+
+1.9.8:
+
+* Add compatibility module that defines namespace SigC.
+  namespace SigC should be API compatible to libsigc++-1.2.
+  Currently only the core parts of the library are supported.
+  Adaptors are still to follow.
+* Fix connection::operator=(). Include connection.h in sigc++.h.
+* Get rid of namespace functor.
+* Rename dependency to destroy_notify_callback.
+* Rename trackable::clear() to trackable::notify_callbacks().
+* Move slot_base, signal_base, slot_iterator[_buf], slot_list
+  out of namespace internal. They are public API.
+* Add reference counter to signal_impl enabling signals
+  to share the underlying information.
+* Add convenience function signal#::make_slot().
+* Get rid of one-letter-parameter-names.
+* Get rid of "using namespace ..." in the test cases.
+* Add lambda operators subscript ([]) and assign (=).
+* Fix is_base_and_derived<> for const types.
+* New and updated documentation.
+* Add previous announces to file NEWS.
+
+1.9.7:
+
+* Added sigc++/sigc++.h. (Murray Cumming)
+* Added member_method example. (Murray Cumming)
+* Renamed closure to slot.
+* Fixed issues with gcc-3.3. (Adreas Rottmann)
+* Removed unnecessary void specializations.
+* Made adaptors' operator()() (overload with no arguments) return a value.
+* Made visit_each() support adaptors.
+* Overhauled return type deduction to make it work without typeof().
+* Added convinience macros SIGC_FUNCTORS_HAVE_RESULT_TYPE and 
+SIGC_FUNCTOR_TRAIT(T_functor, T_result) to make return type deduction system 
+support 3rd-party funtors.
+* Changed syntax of group adaptor from "[functor] % grp([lambdas])" to "group
+([functor], [lambdas])".
+* Made many fixes to lambda functionality.
+* Added var() and constant() lambda creators.
+* Added many lambda operators.
+* Added ref() which creates a reference wrapper to enable storage of 
+references in bind and group adaptors.
+* Expanded test suite.
+* Added documentation. (Corrections by Murray Cumming)
+
+1.9.6:
+
+* First public release of the unstable 2.0 generation.
+  libsigc++ 2.0 uses modern C++ mechanisms to achieve a highly
+  flexible, yet typesafe callback system. It supports all features of
+  libsigc++ 1.2 and improves upon it by:
+  - No need to specify the number of arguments in signal definitions.
+  - Connection of any compatible (=implicitly convertable) functor
+   to a signal.
+  - Implicit type conversions of parameters during signal emission.
+  - Lambda adaptor for complete restructuring of functor parameter
+   lists in one line (subject to changes).
+  - Signal has a fully featured stl style list interface.
+  - A convinient accumulator API (replacing the old marshaller API).
+  - Removal of unnecessary memory management functionality.
+  - Lightweight class "trackable" for use as base class of your
+   class hierarchy replaces class "Object".
diff --git a/libs/sigc++2/README b/libs/sigc++2/README
new file mode 100644
index 0000000000..f90f8f055a
--- /dev/null
+++ b/libs/sigc++2/README
@@ -0,0 +1,72 @@
+libsigc++ -- The Typesafe Callback Framework for C++
+
+
+General information:
+
+   libsigc++ implements a typesafe callback system for standard C++. It
+   allows you to define signals and to connect those signals to any
+   callback function, either global or a member function, regardless of
+   whether it is static or virtual.
+
+   libsigc++ is used by gtkmm to wrap the GTK+ signal system. It does not
+   depend on GTK or gtkmm.
+
+   Further information about the major release 2.0 is available on the
+   libsigc++ project home page: http://libsigc.sourceforge.net/
+
+
+License information:
+
+   Distribution of library and components is under the LGPL as listed in the
+   file COPYING. Examples and tests are Public Domain.
+
+
+Contact information:
+   Maintainer: mailto: mschulze@cvs.gnome.org
+   Maillist: mailto: libsigc-list@gnome.org
+   Homepage: http://libsigc.sourceforge.net
+   Online reference documentation: http://libsigc.sourceforge.net/libsigc2/docs/
+   Ftp: http://ftp.gnome.org/pub/GNOME/sources/libsigc++/2.0/
+   CVS:
+
+
+Overview of the distribution:
+
+   docs/                             documentation on the signal system
+      docs/reference/                reference documentation
+   
+   examples/                         examples of various signal functions
+   
+   sigc++/                           source for library
+      sigc++/macros/                 .m4 files used to auto-generate source files
+      sigc++/functors/               source for library (various functors)
+      sigc++/functors/macros/        .m4 files used to auto-generate source files
+      sigc++/adaptors/               source for library (various adaptors)
+      sigc++/adaptors/macros/        .m4 files used to auto-generate source files
+      sigc++/adpators/lambda/        source for library (lambda library)
+      sigc++/adpators/lambda/macros/ .m4 files used to auto-generate source files
+   
+   scripts/                          automake junk
+   
+   tests/                            programs testing and verifying proper behaviour
+   
+   MSVC_Net2003/                     project files for building the library with MSVC .NET 2003
+
+
+Compatibility:
+
+   Compatible compilers must supports the following recent c++ techniques:
+   * Partial template (function) specialization.
+   * Explicit template (member) function instantiation.
+   * Treat void return as normal return.
+
+   This release has only been tested with gcc-3.3. It should at least also compile with:
+   * gcc >= 3.2
+   * cygwin (gcc >= 3.2)
+   * mingw32
+   * Microsoft Visual Studio .Net 2003
+   * Sun Forte C++ compiler >= 5.5
+   * Compaq C++ compiler
+   * Intel compiler
+   Please report any troubles you encounter with these compilers!
+   You are also invited to try a compiler that is not listed above.
diff --git a/libs/sigc++2/SConscript b/libs/sigc++2/SConscript
new file mode 100644
index 0000000000..a9d5649e7b
--- /dev/null
+++ b/libs/sigc++2/SConscript
@@ -0,0 +1,13 @@
+import glob
+import os
+
+sigc2_files = glob.glob('sigc++/*.cc') + glob.glob('sigc++/functors/*.cc') + glob.glob('sigc++/adaptors/lambda/*.cc')
+
+Import('env')
+sigc2 = env.Copy()
+
+sigc2_configure_script = sigc2.Command ('configure', 'configure.ac', 'cd libs/sigc++2; ./autogen.sh; cd -', ENV=os.environ)
+sigc2_config_h = sigc2.Command('sigc++config.h', [sigc2_configure_script, 'sigc++config.h.in'], 'cd libs/sigc++2; ./configure; cd -', ENV=os.environ)
+
+libsigc2 = sigc2.StaticLibrary('sigc++2', sigc2_files)
+Default([sigc2_config_h, libsigc2])
diff --git a/libs/sigc++2/TODO b/libs/sigc++2/TODO
new file mode 100644
index 0000000000..7ea792aeb0
--- /dev/null
+++ b/libs/sigc++2/TODO
@@ -0,0 +1,66 @@
+Compatibility:
+
+- Fix compilation for SUN FORTE C++ 5.5.
+
+
+Configure checks and Makefile issues:
+
+- When you use a single Makefile.am for
+  several directories (in sigc++2, all under sigc++/ is ruled by a
+  single Makefile.am with the new build system), you have a problem when
+  you do a build where $(srcdir) != $(builddir), since in the build-tree
+  the necessary subdirectories are not created. So I have to find a
+  place where to create this directories, in case they do not exist. 
+  This is only an issue for clean CVS checkouts, however (Andy)
+
+
+sigc++-1.2 compatibility:
+
+- Verify completeness.
+
+
+documentation:
+
+- Improve documentation: Make groups (see index.html). Exclude stuff to make
+  the html output readable.
+
+- Add documentation for adaptors and accumulators.
+
+
+basic functionality:
+
+- I don't understand what is meant by "stl-pointer-like functions" (Martin):
+
+  slot should have the full set of stl pointer like functions. (Karl Nelson)
+
+
+lambda functionality (I don't understand this (Martin)):
+
+- Add support for _R to force references down into 
+  the stack frame of lambda.  Ie.
+
+  A a;
+  (_1+_2)(1,a);  // fail if no "operator int() const"
+
+- Call groups in lambda.  (Huh, that appears to be in group?)
+
+
+Old TODO's that should be almost finished (Martin):
+
+- Fine-tooth comb the code looking for missing operator =() function
+  and missing copy constructors.
+
+- Improve and expand the test suite.  There are a lot of combinations which
+  should be valid but haven't been tested which are likely to result in
+  wierd compiler errors if something wasn't done consistantly.  
+
+
+Old TODO's that should be finished (Martin):
+
+- Improve signal#, it currently is just barely functional.
+- Add iterator support and stl like functionality to signal.
+
+- Add blocking capablity to slot.
+
+- Deinline/move to .cc where possible to move functions into the
+  library to reduce resulting binary size.
diff --git a/libs/sigc++2/autogen.sh b/libs/sigc++2/autogen.sh
new file mode 100755
index 0000000000..c58ddd27a2
--- /dev/null
+++ b/libs/sigc++2/autogen.sh
@@ -0,0 +1,18 @@
+#! /bin/sh
+
+srcdir=`dirname $0`
+test -z "$srcdir" && srcdir=.
+
+echo "Adding libtools."
+libtoolize --automake --copy --force
+
+echo "Building macros."
+aclocal  -I "$srcdir/scripts" $ACLOCAL_FLAGS
+
+echo "Building makefiles."
+automake --add-missing --copy
+
+echo "Building configure."
+autoconf
+
+rm -f config.cache
diff --git a/libs/sigc++2/configure.ac b/libs/sigc++2/configure.ac
new file mode 100644
index 0000000000..14c0ee6a7f
--- /dev/null
+++ b/libs/sigc++2/configure.ac
@@ -0,0 +1,64 @@
+dnl Configure.in
+dnl
+dnl  Source for generating compiler independent libraries.
+dnl
+
+dnl INIT is required name a file which is unique to the package
+dnl just to prevent someone from copying the configure to the wrong package.
+AC_INIT(sigc++)
+
+dnl This version stuff is just for the packaging section of the tool.
+dnl   thus make format_package-0.0.1.tar.gz  
+FP_MAJOR_VERSION=2
+FP_MINOR_VERSION=0
+FP_MICRO_VERSION=6
+FP_VERSION=$FP_MAJOR_VERSION.$FP_MINOR_VERSION.$FP_MICRO_VERSION
+
+dnl For automake.
+VERSION=$FP_VERSION
+PACKAGE=libsigc++
+
+dnl Initialize automake stuff
+AM_INIT_AUTOMAKE($PACKAGE, $VERSION)
+
+dnl Specify a configuration file:
+AC_CONFIG_HEADER(sigc++config.h)
+
+dnl disable autoheader
+AUTOHEADER=':'
+
+dnl Maintainer support (autodependencies and packaging)
+AM_MAINTAINER_MODE
+
+dnl Using C compiler
+AC_PROG_CC
+AC_PROG_CPP
+
+dnl Using libtool
+AC_CONFIG_MACRO_DIR(scripts)
+LT_INIT
+dnl AM_PROG_LIBTOOL
+
+dnl Using C++ compiler
+AC_PROG_CXX
+AC_LANG_CPLUSPLUS
+
+SIGC_CXX_GCC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD()
+
+if test "X$config_error" = "Xyes" ; then
+  AC_ERROR(
+[One or more of the required compiler features is missing.
+If you believe this is in error, please consult the config.log file
+for further details.
+])
+fi
+ 
+
+# Generate output
+AC_OUTPUT([
+  Makefile
+  sigc++-2.0.pc
+
+  sigc++/Makefile
+  libsigc++-2.0.spec
+])
diff --git a/libs/sigc++2/libsigc++-2.0.spec.in b/libs/sigc++2/libsigc++-2.0.spec.in
new file mode 100644
index 0000000000..7dc756c6ce
--- /dev/null
+++ b/libs/sigc++2/libsigc++-2.0.spec.in
@@ -0,0 +1,91 @@
+Summary: The Typesafe Signal Framework for C++
+Name: @PACKAGE@
+Version: @VERSION@
+Release: 1
+License: LGPL
+Group: System Environment/Libraries
+Packager: Eric Bourque <ericb@computer.org>
+URL: http://libsigc.sourceforge.net/
+Source0: http://ftp.gnome.org/pub/GNOME/sources/libsigc++/2.0/%{name}-%{version}.tar.bz2
+BuildRoot: %{_tmppath}/%{name}-%{version}-%{release}-root
+
+%description
+
+This library implements a full callback system for use in widget
+libraries, abstract interfaces, and general programming. Originally
+part of the Gtk-- widget set, %name is now a seperate library to
+provide for more general use. It is the most complete library of its
+kind with the ablity to connect an abstract callback to a class
+method, function, or function object. It contains adaptor classes for
+connection of dissimilar callbacks and has an ease of use unmatched by
+other C++ callback libraries.
+
+Package GTK-- (gtkmm), which is a C++ binding to the GTK+ library,
+starting with version 1.1.2, uses %name.
+
+Due to C++ ABI changes, this will only work with the gcc version which
+the distribution was supplied with.  If you got your rpm from any
+previous version, please rebuild from spec!
+
+%package devel
+Summary: Development tools for the Typesafe Signal Framework for C++
+Group: Development/Libraries
+Requires: %name = %version
+
+%description devel
+The %name-devel package contains the static libraries and header files
+needed for development with %name.
+
+%package examples
+Summary: Examples and tests for the Typesafe Signal Framework for C++
+Group: Development/Libraries
+Requires: %name-devel = %version
+
+%description examples
+The %name-devel package contains source code of
+example and test programs for %name.
+
+
+%prep
+%setup -q
+
+%build
+./configure --prefix=/usr
+make
+
+%install
+rm -rf $RPM_BUILD_ROOT
+make DESTDIR=$RPM_BUILD_ROOT install
+mkdir -p -m 755 $RPM_BUILD_ROOT/%{_libdir}/sigc++-2.0
+cp -a examples tests $RPM_BUILD_ROOT/%{_libdir}/sigc++-2.0
+
+%post -p /sbin/ldconfig
+
+%postun -p /sbin/ldconfig
+
+%clean
+rm -rf $RPM_BUILD_ROOT
+
+
+%files
+%defattr(-,root,root,-)
+%{_libdir}/libsigc*.so*
+%doc /usr/share/doc/libsigc-2.0
+
+%files devel
+/usr/include/sigc++-2.0
+%{_libdir}/pkgconfig/*
+%{_libdir}/libsigc*.a
+%{_libdir}/libsigc*.la
+%dir %{_libdir}/sigc++-2.0
+%dir %{_libdir}/sigc++-2.0/include
+%{_libdir}/sigc++-2.0/include/sigc++config.h
+
+%files examples
+%{_libdir}/sigc++-2.0/examples
+%{_libdir}/sigc++-2.0/tests
+
+%changelog
+* Tue Jun 29 2004 Eric Bourque <ericb@computer.org> - 2.0-1
+- Initial build.
+
diff --git a/libs/sigc++2/scripts/cxx.m4 b/libs/sigc++2/scripts/cxx.m4
new file mode 100644
index 0000000000..8753b53827
--- /dev/null
+++ b/libs/sigc++2/scripts/cxx.m4
@@ -0,0 +1,94 @@
+dnl
+dnl SIGC_CXX_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD()
+dnl
+dnl
+AC_DEFUN([SIGC_CXX_GCC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD],[
+AC_MSG_CHECKING([if C++ compiler supports the use of a particular specialization when calling operator() template methods.])
+AC_TRY_COMPILE(
+[
+  #include <iostream>
+
+  class Thing
+  {
+    public:
+    Thing()
+    {}
+
+    template <class T>
+    void operator()(T a, T b)
+    {
+      T c = a + b;
+      std::cout << c << std::endl;
+    }
+  };
+
+  template<class T2>
+  class OtherThing
+  {
+  public:
+    void do_something()
+    {
+       Thing thing_;
+       thing_.template operator()<T2>(1, 2);
+       //This fails with or without the template keyword, on SUN Forte C++ 5.3, 5.4, and 5.5:
+    }
+  };
+],
+[
+  OtherThing<int> thing;
+  thing.do_something();
+],
+[
+  sigcm_cxx_gcc_template_specialization_operator_overload=yes
+  AC_DEFINE([SIGC_GCC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD],[1],[does the C++ compiler support the use of a particular specialization when calling operator() template methods.])
+  AC_MSG_RESULT([$sigcm_cxx_gcc_template_specialization_operator_overload])
+],[
+  sigcm_cxx_gcc_template_specialization_operator_overload=no
+  AC_MSG_RESULT([$sigcm_cxx_gcc_template_specialization_operator_overload])
+])
+])
+AC_DEFUN([SIGC_CXX_MSVC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD],[
+AC_MSG_CHECKING([if C++ compiler supports the use of a particular specialization when calling operator() template methods omitting the template keyword.])
+AC_TRY_COMPILE(
+[
+  #include <iostream>
+
+  class Thing
+  {
+    public:
+    Thing()
+    {}
+
+    template <class T>
+    void operator()(T a, T b)
+    {
+      T c = a + b;
+      std::cout << c << std::endl;
+    }
+  };
+
+  template<class T2>
+  class OtherThing
+  {
+  public:
+    void do_something()
+    {
+       Thing thing_;
+       thing_.operator()<T2>(1, 2);
+       //This fails with or without the template keyword, on SUN Forte C++ 5.3, 5.4, and 5.5:
+    }
+  };
+],
+[
+  OtherThing<int> thing;
+  thing.do_something();
+],
+[
+  sigcm_cxx_msvc_template_specialization_operator_overload=yes
+  AC_DEFINE([SIGC_MSVC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD],[1],[does the C++ compiler support the use of a particular specialization when calling operator() template methods omitting the template keyword.])
+  AC_MSG_RESULT([$sigcm_cxx_msvc_template_specialization_operator_overload])
+],[
+  sigcm_cxx_msvc_template_specialization_operator_overload=no
+  AC_MSG_RESULT([$sigcm_cxx_msvc_template_specialization_operator_overload])
+])
+])
diff --git a/libs/sigc++2/scripts/libtool.m4 b/libs/sigc++2/scripts/libtool.m4
new file mode 100644
index 0000000000..1ceda32823
--- /dev/null
+++ b/libs/sigc++2/scripts/libtool.m4
@@ -0,0 +1,5767 @@
+# libtool.m4 - Configure libtool for the host system. -*-Autoconf-*-
+
+m4_define([_LT_COPYING], [dnl
+# Copyright (C) 1996, 1997, 1998, 1999, 2000, 2001, 2003, 2004
+# Free Software Foundation, Inc.
+#
+# This file is part of GNU Libtool:
+# Originally by Gordon Matzigkeit <gord@gnu.ai.mit.edu>, 1996
+#
+# This program is free software; you can redistribute it and/or modify
+# it under the terms of the GNU General Public License as published by
+# the Free Software Foundation; either version 2 of the License, or
+# (at your option) any later version.
+#
+# This program is distributed in the hope that it will be useful, but
+# WITHOUT ANY WARRANTY; without even the implied warranty of
+# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
+# General Public License for more details.
+#
+# You should have received a copy of the GNU General Public License
+# along with this program; if not, write to the Free Software
+# Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
+#
+# As a special exception to the GNU General Public License, if you
+# distribute this file as part of a program that contains a
+# configuration script generated by Autoconf, you may include it under
+# the same distribution terms that you use for the rest of that program.
+])
+
+# serial 49 LT_INIT
+
+
+# LT_PREREQ(VERSION)
+# ------------------
+# Complain and exit if this libtool version is less that VERSION.
+m4_define([LT_PREREQ],
+[m4_if(m4_version_compare(m4_defn([LT_PACKAGE_VERSION]), [$1]), -1,
+       [m4_default([$3],
+		   [m4_fatal([Libtool version $1 or higher is required],
+		             63)])],
+       [$2])])
+
+
+# LT_INIT([OPTIONS])
+# --------------------------
+AC_DEFUN([LT_INIT],
+[AC_PREREQ([2.58])dnl We use AC_INCLUDES_DEFAULT
+dnl Autoconf doesn't catch unexpanded LT_ macros by default:
+m4_pattern_forbid([^_?LT_[A-Z_]+$])dnl
+m4_pattern_allow([^(_LT_EOF|LT_DLGLOBAL|LT_DLLAZY_OR_NOW)$])dnl
+dnl aclocal doesn't pull ltoptions.m4, ltsugar.m4, or ltversion.m4
+dnl unless we require an AC_DEFUNed macro:
+AC_REQUIRE([LTOPTIONS_VERSION])dnl
+AC_REQUIRE([LTSUGAR_VERSION])dnl
+AC_REQUIRE([LTVERSION_VERSION])dnl
+AC_REQUIRE([_LT_PROG_LTMAIN])dnl
+AC_BEFORE([$0], [LT_LANG])dnl
+
+# This can be used to rebuild libtool when needed
+LIBTOOL_DEPS="$ltmain"
+
+# Always use our own libtool.
+LIBTOOL='$(SHELL) $(top_builddir)/libtool'
+AC_SUBST(LIBTOOL)dnl
+
+# Set options
+_LT_SET_OPTIONS([$1])dnl
+
+_LT_SETUP
+
+# Only expand once:
+m4_define([LT_INIT])
+])# _LT_INIT
+
+# Old names:
+AU_DEFUN([AC_PROG_LIBTOOL],	    [LT_INIT])
+AU_DEFUN([AM_PROG_LIBTOOL],	    [LT_INIT])
+
+
+# _LT_SETUP
+# ---------
+m4_define([_LT_SETUP],
+[AC_REQUIRE([AC_CANONICAL_HOST])dnl
+AC_REQUIRE([AC_CANONICAL_BUILD])dnl
+_LT_DECL([], [host_alias], [0], [The host system])dnl
+_LT_DECL([], [host], [0])dnl
+dnl
+AC_REQUIRE([AC_PROG_CC])dnl
+AC_REQUIRE([AC_PROG_LD])dnl
+AC_REQUIRE([AC_PROG_LD_RELOAD_FLAG])dnl
+AC_REQUIRE([AC_PROG_NM])dnl
+dnl
+AC_REQUIRE([AC_PROG_LN_S])dnl
+test -z "$LN_S" && LN_S="ln -s"
+_LT_DECL([], [LN_S], [1], [Whether we need soft or hard links])dnl
+dnl
+AC_REQUIRE([AC_DEPLIBS_CHECK_METHOD])dnl
+AC_REQUIRE([AC_LIBTOOL_SYS_OLD_ARCHIVE])dnl
+AC_REQUIRE([AC_LIBTOOL_SYS_MAX_CMD_LEN])dnl
+AC_REQUIRE([AC_LIBTOOL_SYS_GLOBAL_SYMBOL_PIPE])dnl
+AC_REQUIRE([AC_OBJEXT])dnl
+_LT_DECL([objext], [ac_objext], [0], [Object file suffix (normally "o")])dnl
+AC_REQUIRE([AC_EXEEXT])dnl
+_LT_DECL([], [exeext], [0], [Executable file suffix (normally "")])dnl
+dnl
+
+_LT_CONFIG_LIBTOOL_INIT([
+# See if we are running on zsh, and set the options which allow our
+# commands through without removal of \ escapes INIT.
+if test -n "\${ZSH_VERSION+set}" ; then
+   setopt NO_GLOB_SUBST
+fi
+])
+if test -n "${ZSH_VERSION+set}" ; then
+   setopt NO_GLOB_SUBST
+fi
+
+AC_LIBTOOL_OBJDIR
+
+AC_REQUIRE([_LT_AC_SYS_COMPILER])dnl
+_LT_AC_PROG_ECHO_BACKSLASH
+
+case $host_os in
+aix3*)
+  # AIX sometimes has problems with the GCC collect2 program.  For some
+  # reason, if we set the COLLECT_NAMES environment variable, the problems
+  # vanish in a puff of smoke.
+  if test "X${COLLECT_NAMES+set}" != Xset; then
+    COLLECT_NAMES=
+    export COLLECT_NAMES
+  fi
+  ;;
+esac
+
+# Sed substitution that helps us do robust quoting.  It backslashifies
+# metacharacters that are still active within double-quoted strings.
+Xsed='sed -e s/^X//'
+[sed_quote_subst='s/\([\\"\\`$\\\\]\)/\\\1/g']
+
+# Same as above, but do not quote variable references.
+[double_quote_subst='s/\([\\"\\`\\\\]\)/\\\1/g']
+
+# Sed substitution to delay expansion of an escaped shell variable in a
+# double_quote_subst'ed string.
+delay_variable_subst='s/\\\\\\\\\\\$/\\\\\\$/g'
+
+# Sed substitution to delay expansion of an escaped single quote.
+delay_single_quote_subst='s/'\''/'\'\\\\\\\'\''/g'
+
+# Sed substitution to avoid accidental globbing in evaled expressions
+no_glob_subst='s/\*/\\\*/g'
+
+# Constants:
+rm="rm -f"
+
+# Global variables:
+default_ofile=libtool
+ofile="$default_ofile"
+can_build_shared=yes
+
+# All known linkers require a `.a' archive for static linking (except M$VC,
+# which needs '.lib').
+libext=a
+
+with_gnu_ld="$lt_cv_prog_gnu_ld"
+
+old_CC="$CC"
+old_CFLAGS="$CFLAGS"
+
+# Set sane defaults for various variables
+test -z "$CC" && CC=cc
+test -z "$LTCC" && LTCC=$CC
+test -z "$LD" && LD=ld
+test -z "$ac_objext" && ac_objext=o
+
+cc_basename=`$echo X"$compiler" | $Xsed -e 's%^.*/%%'`
+
+# Only perform the check for file, if the check method requires it
+test -z "$MAGIC_CMD" && MAGIC_CMD=file
+case $deplibs_check_method in
+file_magic*)
+  if test "$file_magic_cmd" = '$MAGIC_CMD'; then
+    AC_PATH_MAGIC
+  fi
+  ;;
+esac
+
+AC_ARG_ENABLE([libtool-lock],
+    [AC_HELP_STRING([--disable-libtool-lock],
+	[avoid locking (might break parallel builds)])])
+test "x$enable_libtool_lock" != xno && enable_libtool_lock=yes
+
+# Use C for the default configuration in the libtool script
+_LT_LANG_C_CONFIG
+_LT_LANG_DEFAULT_CONFIG
+_LT_CONFIG_COMMANDS
+])# _LT_SETUP
+
+
+# _LT_PROG_LTMAIN
+# ---------------
+# In libtool itself `ltmain.sh' is in the build tree, but everything else
+# ships it in the source tree, for completeness, if we find a copy in the
+# build tree use that before falling back to auxdir.
+#
+# Note that this code is called both from `configure', and `config.status'
+# now that we use AC_CONFIG_COMMANDS to generate libtool.  Notably,
+# `config.status' has no value for ac_aux_dir unless we are using Automake,
+# so we pass a copy along to make sure it has a sensible value anyway.
+AC_DEFUN([_LT_PROG_LTMAIN],
+[_LT_CONFIG_LIBTOOL_INIT([ac_aux_dir='$ac_aux_dir'])
+case $ac_aux_dir in
+  $srcdir)   ltmain=./ltmain.sh ;;
+  $srcdir/*) ltmain=`expr "$ac_aux_dir" : "$srcdir/\(.*\)"`/ltmain.sh ;;
+esac
+test -f "$ltmain" || ltmain="$ac_aux_dir/ltmain.sh"
+])# _LT_PROG_LTMAIN
+
+
+
+## ------------------------------------- ##
+## Accumulate code for creating libtool. ##
+## ------------------------------------- ##
+
+# So that we can recreate a full libtool script including additional
+# tags, we accumulate the chunks of code to send to AC_CONFIG_COMMANDS
+# in macros and then make a single call at the end using the `libtool'
+# label.
+
+# _LT_CONFIG_LIBTOOL_INIT([INIT-COMMANDS])
+# ----------------------------------------
+# Register INIT-COMMANDS to be passed to AC_CONFIG_COMMANDS later.
+m4_define([_LT_CONFIG_LIBTOOL_INIT],
+[m4_ifval([$1],
+          [m4_append([_LT_OUTPUT_LIBTOOL_INIT],
+                     [$1
+])])])
+
+# Initialize.
+m4_define([_LT_OUTPUT_LIBTOOL_INIT])
+
+# _LT_CONFIG_LIBTOOL([COMMANDS])
+# ------------------------------
+# Register COMMANDS to be passed to AC_CONFIG_COMMANDS later.
+m4_define([_LT_CONFIG_LIBTOOL],
+[m4_ifval([$1],
+          [m4_append([_LT_OUTPUT_LIBTOOL_COMMANDS],
+                     [$1
+])])])
+
+# Initialize.
+m4_define([_LT_OUTPUT_LIBTOOL_COMMANDS])
+
+
+# _LT_CONFIG_SAVE_COMMANDS([COMMANDS], [INIT_COMMANDS])
+# ---------------------------------------------------
+m4_define([_LT_CONFIG_SAVE_COMMANDS],
+[_LT_CONFIG_LIBTOOL([$1])
+_LT_CONFIG_LIBTOOL_INIT([$2])
+])
+
+
+# _LT_FORMAT_COMMENT([COMMENT])
+# -----------------------------
+# Add leading comment marks to the start of each line, and a trailing
+# full-stop to the whole comment if one is not present already.
+m4_define([_LT_FORMAT_COMMENT],
+[m4_ifval([$1], [
+m4_bpatsubst([$1], [^ *], [# ])]m4_bmatch([$1], [[!?.]$], [], [.])
+)])
+
+
+
+## ------------------------ ##
+## FIXME: Eliminate VARNAME ##
+## ------------------------ ##
+
+# _LT_DECL([CONFIGNAME], VARNAME, VALUE, [DESCRIPTION], [IS-TAGGED?])
+# -------------------------------------------------------------------
+# CONFIGNAME is the name given to the value in the libtool script.
+# VARNAME is the (base) name used in the configure script.
+# VALUE may be 0, 1 or 2 for a computed quote escaped value based on
+# VARNAME.  Any other value will be used directly.
+m4_define([_LT_DECL],
+[lt_if_append_uniq([lt_decl_varnames], [$2], [[, ]],
+    [lt_dict_add_subkey([lt_decl_dict], [$2], [libtool_name],
+	[m4_ifval([$1], [$1], [$2])])
+    lt_dict_add_subkey([lt_decl_dict], [$2], [value], [$3])
+    m4_ifval([$4],
+	[lt_dict_add_subkey([lt_decl_dict], [$2], [description], [$4])])
+    lt_dict_add_subkey([lt_decl_dict], [$2],
+	[tagged?], [m4_ifval([$5], [yes], [no])])])
+])
+
+
+# _LT_TAGDECL([CONFIGNAME], VARNAME, VALUE, [DESCRIPTION])
+# --------------------------------------------------------
+m4_define([_LT_TAGDECL], [_LT_DECL([$1], [$2], [$3], [$4], [yes])])
+
+
+# lt_decl_tag_varnames([SEPARATOR], [VARNAME1...])
+# -------------------------------------------------
+m4_define([lt_decl_tag_varnames],
+[_lt_decl_filter([tagged?], [yes], $@)])
+m4_define([_lt_decl_filter],
+[m4_case([$#],
+  [0], [m4_fatal([$0: too few arguments: $#])],
+  [1], [m4_fatal([$0: too few arguments: $#: $1])],
+  [2], [lt_dict_filter([lt_decl_dict], [$1], [$2], [], lt_decl_varnames)],
+  [3], [lt_dict_filter([lt_decl_dict], [$1], [$2], [$3], lt_decl_varnames)],
+  [lt_dict_filter([lt_decl_dict], $@)])[]dnl
+])
+
+
+# lt_decl_quote_varnames([SEPARATOR], [VARNAME1...])
+# ---------------------------------------------------
+m4_define([lt_decl_quote_varnames],
+[_lt_decl_filter([value], [1], $@)])
+
+# lt_decl_dquote_varnames([SEPARATOR], [VARNAME1...])
+# ----------------------------------------------------
+m4_define([lt_decl_dquote_varnames],
+[_lt_decl_filter([value], [2], $@)])
+
+
+# lt_decl_varnames_tagged([SEPARATOR], [VARNAME1...])
+# ----------------------------------------------------
+m4_define([lt_decl_varnames_tagged],
+[_$0(m4_quote(m4_default([$1], [[, ]])),
+     m4_quote(m4_if([$2], [],
+		     m4_quote(lt_decl_tag_varnames),
+		  m4_quote(m4_shift($@)))),
+     m4_split(m4_normalize(m4_quote(_LT_TAGS))))])
+m4_define([_lt_decl_varnames_tagged], [lt_combine([$1], [$2], [_], $3)])
+
+
+# lt_decl_all_varnames([SEPARATOR], [VARNAME1...])
+# ------------------------------------------------
+m4_define([lt_decl_all_varnames],
+[_$0(m4_quote(m4_default([$1], [[, ]])),
+     m4_if([$2], [],
+	   m4_quote(lt_decl_varnames),
+	m4_quote(m4_shift($@))))[]dnl
+])
+m4_define([_lt_decl_all_varnames],
+[lt_join($@, lt_decl_varnames_tagged([$1],
+			lt_decl_tag_varnames([[, ]], m4_shift($@))))dnl
+])
+
+
+# _LT_CONFIG_STATUS_DECLARE([VARNAME])
+# ------------------------------------
+# Quote a variable value, and forward it to `config.status' so that its
+# declaration there will have the same value as in `configure'.  VARNAME
+# must have a single quote delimited value for this to work.
+m4_define([_LT_CONFIG_STATUS_DECLARE],
+[$1='`$echo "X$][$1" | $Xsed -e "$delay_single_quote_subst"`'])
+
+
+# _LT_CONFIG_STATUS_DECLARATIONS
+# ------------------------------
+# We delimit libtool config variables with single quotes, so when
+# we write them to config.status, we have to be sure to quote all
+# embedded single quotes properly.  In configure, this macro expands
+# each variable declared with _LT_DECL (and _LT_TAGDECL) into:
+#
+#    <var>='`$echo "X$<var>" | $Xsed -e "$delay_single_quote_subst"`'
+m4_define([_LT_CONFIG_STATUS_DECLARATIONS],
+[m4_foreach([_lt_var], m4_quote(lt_decl_all_varnames),
+    [m4_n([_LT_CONFIG_STATUS_DECLARE(_lt_var)])])])
+
+
+# _LT_LIBTOOL_TAGS
+# ----------------
+# Output comment and list of tags supported by the script
+m4_define([_LT_LIBTOOL_TAGS],
+[_LT_FORMAT_COMMENT([The names of the tagged configurations supported by this script])dnl
+available_tags="[]_LT_TAGS[]"dnl
+])
+
+# _LT_LIBTOOL_DECLARE(VARNAME, [TAG])
+# -----------------------------------
+# Extract the dictionary values for VARNAME (optionally with TAG) and
+# expand to a commented shell variable setting:
+#
+#    # Some comment about what VAR is for.
+#    visible_name=$lt_internal_name
+m4_define([_LT_LIBTOOL_DECLARE],
+[_LT_FORMAT_COMMENT(m4_quote(lt_dict_fetch([lt_decl_dict], [$1],
+					   [description])))[]dnl
+m4_pushdef([_libtool_name],
+    m4_quote(lt_dict_fetch([lt_decl_dict], [$1], [libtool_name])))[]dnl
+m4_case(m4_quote(lt_dict_fetch([lt_decl_dict], [$1], [value])),
+    [0], [_libtool_name=[$]$1],
+    [1], [_libtool_name=$lt_[]$1],
+    [2], [_libtool_name=$lt_[]$1],
+    [_libtool_name=lt_dict_fetch([lt_decl_dict], [$1], [value])])[]dnl
+m4_ifval([$2], [_$2])[]m4_popdef([_libtool_name])[]dnl
+])
+
+# _LT_LIBTOOL_CONFIG_VARS
+# -----------------------
+# Produce commented declarations of non-tagged libtool config variables
+# suitable for insertion in the LIBTOOL CONFIG section of the `libtool'
+# script.  Tagged libtool config variables (even for the LIBTOOL CONFIG
+# section) are produced by _LT_LIBTOOL_TAG_VARS.
+m4_define([_LT_LIBTOOL_CONFIG_VARS],
+[m4_foreach([_lt_var],
+    m4_quote(_lt_decl_filter([tagged?], [no], [], lt_decl_varnames)),
+    [m4_n([_LT_LIBTOOL_DECLARE(_lt_var)])])])
+
+# _LT_LIBTOOL_TAG_VARS(TAG)
+# -------------------------
+m4_define([_LT_LIBTOOL_TAG_VARS],
+[m4_foreach([_lt_var], m4_quote(lt_decl_tag_varnames),
+    [m4_n([_LT_LIBTOOL_DECLARE(_lt_var, [$1])])])])
+
+
+# _LT_AC_TAGVAR(VARNAME, [TAGNAME])
+# ---------------------------------
+m4_define([_LT_AC_TAGVAR], [m4_ifval([$2], [$1_$2], [$1])])
+
+
+# _LT_CONFIG_COMMANDS
+# -------------------
+# Send accumulated output to $CONFIG_STATUS.  Thanks to the lists of
+# variables for single and double quote escaping we saved from calls
+# to _LT_DECL, we can put quote escaped variables declarations
+# into `config.status', and then the shell code to quote escape them in
+# for loops in `config.status'.  Finally, any additional code accumulated
+# from calls to _LT_CONFIG_LIBTOOL_INIT is expanded.
+m4_define([_LT_CONFIG_COMMANDS],
+[AC_CONFIG_COMMANDS([libtool], [_LT_OUTPUT_LIBTOOL_COMMANDS], [
+
+# The HP-UX ksh and POSIX shell print the target directory to stdout
+# if CDPATH is set.
+if test "X${CDPATH+set}" = Xset; then CDPATH=${ZSH_VERSION+.}:; export CDPATH; fi
+
+sed_quote_subst='$sed_quote_subst'
+double_quote_subst='$double_quote_subst'
+delay_variable_subst='$delay_variable_subst'
+_LT_CONFIG_STATUS_DECLARATIONS
+LTCC='$LTCC'
+compiler='$compiler_DEFAULT'
+
+# Quote evaled strings.
+for var in lt_decl_all_varnames([[ ]], lt_decl_quote_varnames); do
+    eval "lt_\$var=\\\\\\"\\\`\\\$echo \\"X\\\$\$var\\" | \\\$Xsed -e \\"\\\$sed_quote_subst\\"\\\`\\\\\\""
+done
+
+# Double-quote double-evaled strings.
+for var in lt_decl_all_varnames([[ ]], lt_decl_dquote_varnames); do
+    eval "lt_\$var=\\\\\\"\\\`\\\$echo \\"X\\\$\$var\\" | \\\$Xsed -e \\"\\\$double_quote_subst\\" -e \\"\\\$sed_quote_subst\\" -e \\"\\\$delay_variable_subst\\"\\\`\\\\\\""
+done
+
+# Fix-up fallback echo if it was mangled by the above quoting rules.
+case \$lt_echo in
+*'\\\[$]0 --fallback-echo"')dnl "
+  lt_echo=\`\$echo "X\$lt_echo" | \$Xsed -e 's/\\\\\\\\\\\\\\\[$]0 --fallback-echo"\[$]/\[$]0 --fallback-echo"/'\`
+  ;;
+esac
+
+_LT_OUTPUT_LIBTOOL_INIT
+])
+])#_LT_CONFIG_COMMANDS
+
+
+# _LT_CONFIG(TAG)
+# ----------------------------
+# If TAG is the built-in tag, create an initial libtool script with a
+# default configuration from the untagged config vars.  Otherwise add code
+# to config.status for appending the configuration named by TAG from the
+# matching tagged config vars.
+m4_define([_LT_CONFIG],
+[_LT_CONFIG_SAVE_COMMANDS([
+  m4_define([_LT_TAG], m4_if([$1], [], [C], [$1]))dnl
+  m4_if(_LT_TAG, [C], [
+    # See if we are running on zsh, and set the options which allow our
+    # commands through without removal of \ escapes.
+    if test -n "${ZSH_VERSION+set}" ; then
+      setopt NO_GLOB_SUBST
+    fi
+
+    cfgfile="${ofile}T"
+    trap "$rm \"$cfgfile\"; exit 1" 1 2 15
+    $rm -f "$cfgfile"
+
+    cat <<_LT_EOF >> "$cfgfile"
+#! $SHELL
+
+# `$echo "$ofile" | sed 's%^.*/%%'` - Provide generalized library-building support services.
+# Generated automatically by config.status (GNU $PACKAGE$TIMESTAMP) $VERSION
+# Libtool was configured on host `(hostname || uname -n) 2>/dev/null | sed 1q`:
+# NOTE: Changes made to this file will be lost: look at ltmain.sh.
+#
+_LT_COPYING
+
+_LT_LIBTOOL_TAGS
+
+# ### BEGIN LIBTOOL CONFIG
+_LT_LIBTOOL_CONFIG_VARS
+_LT_LIBTOOL_TAG_VARS
+# ### END LIBTOOL CONFIG
+
+# The HP-UX ksh and POSIX shell print the target directory to stdout
+# if CDPATH is set.
+if test "X\${CDPATH+set}" = Xset; then CDPATH=:; export CDPATH; fi
+
+_LT_EOF
+
+  case $host_os in
+  aix3*)
+    cat <<\_LT_EOF >> "$cfgfile"
+# AIX sometimes has problems with the GCC collect2 program.  For some
+# reason, if we set the COLLECT_NAMES environment variable, the problems
+# vanish in a puff of smoke.
+if test "X${COLLECT_NAMES+set}" != Xset; then
+  COLLECT_NAMES=
+  export COLLECT_NAMES
+fi
+_LT_EOF
+    ;;
+  esac
+
+  _LT_PROG_LTMAIN
+
+  # We use sed instead of cat because bash on DJGPP gets confused if
+  # if finds mixed CR/LF and LF-only lines.  Since sed operates in
+  # text mode, it properly converts lines to CR/LF.  This bash problem
+  # is reportedly fixed, but why not run on old versions too?
+  sed '$q' "$ltmain" >> "$cfgfile" || (rm -f "$cfgfile"; exit 1)
+
+  mv -f "$cfgfile" "$ofile" ||
+    (rm -f "$ofile" && cp "$cfgfile" "$ofile" && rm -f "$cfgfile")
+  chmod +x "$ofile"
+],
+[cat <<_LT_EOF >> "$ofile"
+
+dnl Unfortunately we have to use $1 here, since _LT_TAG is not expanded
+dnl in a comment (ie after a #).
+# ### BEGIN LIBTOOL TAG CONFIG: $1
+_LT_LIBTOOL_TAG_VARS(_LT_TAG)
+# ### END LIBTOOL TAG CONFIG: $1
+_LT_EOF
+])dnl /m4_if
+],
+[m4_if([$1], [], [
+    PACKAGE='$PACKAGE'
+    VERSION='$VERSION'
+    TIMESTAMP='$TIMESTAMP'
+    rm='$rm'
+    ofile='$ofile'], [])
+])dnl /_LT_CONFIG_SAVE_COMMANDS
+])# _LT_CONFIG
+
+
+# C support is built-in for now
+m4_define([_LT_LANG_C_enabled], [])
+m4_define([_LT_TAGS], [])
+
+# LT_LANG(LANG)
+# -------------
+# Enable libtool support for the given language if not already enabled.
+AC_DEFUN([LT_LANG],
+[m4_case([$1],
+  [C],			[_LT_LANG(C)],
+  [C++],		[_LT_LANG(CXX)],
+  [Java],		[_LT_LANG(GCJ)],
+  [Fortran 77],		[_LT_LANG(F77)],
+  [Windows Resource],	[_LT_LANG(RC)],
+  [m4_ifdef([_LT_LANG_]$1[_CONFIG],
+    [_LT_LANG($1)],
+    [m4_fatal([$0: unsupported language: "$1"])])])dnl
+])# LT_LANG
+
+# _LT_LANG(LANGNAME)
+# ------------------
+m4_define([_LT_LANG],
+[m4_ifdef([_LT_LANG_]$1[_enabled], [],
+  [m4_append([_LT_TAGS], [$1 ])dnl
+  m4_define([_LT_LANG_]$1[_enabled], [])dnl
+  _LT_LANG_$1_CONFIG($1)])dnl
+])# _LT_LANG
+
+# _LT_LANG_DEFAULT_CONFIG
+# -----------------------
+m4_define([_LT_LANG_DEFAULT_CONFIG],
+[AC_PROVIDE_IFELSE([AC_PROG_CXX],
+  [LT_LANG(CXX)],
+  [m4_define([AC_PROG_CXX], defn([AC_PROG_CXX])[LT_LANG(CXX)])])
+
+AC_PROVIDE_IFELSE([AC_PROG_F77],
+  [LT_LANG(F77)],
+  [m4_define([AC_PROG_F77], defn([AC_PROG_F77])[LT_LANG(F77)])])
+
+dnl The call to [A][M_PROG_GCJ] is quoted like that to stop aclocal
+dnl pulling things in needlessly.
+AC_PROVIDE_IFELSE([AC_PROG_GCJ],
+  [LT_LANG(GCJ)],
+  [AC_PROVIDE_IFELSE([A][M_PROG_GCJ],
+    [LT_LANG(GCJ)],
+    [AC_PROVIDE_IFELSE([LT_PROG_GCJ],
+      [LT_LANG(GCJ)],
+      [m4_ifdef([AC_PROG_GCJ],
+	[m4_define([AC_PROG_GCJ], defn([AC_PROG_GCJ])[LT_LANG(GCJ)])])
+       m4_ifdef([A][M_PROG_GCJ],
+	[m4_define([A][M_PROG_GCJ], defn([A][M_PROG_GCJ])[LT_LANG(GCJ)])])
+       m4_ifdef([LT_PROG_GCJ],
+	[m4_define([LT_PROG_GCJ], defn([LT_PROG_GCJ])[LT_LANG(GCJ)])])])])])
+
+AC_PROVIDE_IFELSE([LT_PROG_RC],
+  [LT_LANG(RC)],
+  [m4_define([LT_PROG_RC], defn([LT_PROG_RC])[LT_LANG(RC)])])
+])# _LT_LANG_DEFAULT_CONFIG
+
+# Obsolete macros
+AU_DEFUN([AC_LIBTOOL_CXX], [LT_LANG(C++)])
+AU_DEFUN([AC_LIBTOOL_F77], [LT_LANG(Fortran 77)])
+AU_DEFUN([AC_LIBTOOL_GCJ], [LT_LANG(Java])])
+
+
+# _LT_AC_SYS_COMPILER
+# -------------------
+AC_DEFUN([_LT_AC_SYS_COMPILER],
+[AC_REQUIRE([AC_PROG_CC])dnl
+
+_LT_DECL([LTCC], [CC], [1], [A C compiler])
+_LT_TAGDECL([CC], [compiler], [1], [A language specific compiler])dnl
+_LT_TAGDECL([with_gcc], [GCC], [0], [Is the compiler the GNU C compiler?])
+
+# If no C compiler was specified, use CC.
+LTCC=${LTCC-"$CC"}
+
+# Allow CC to be a program name with arguments.
+compiler=$CC
+])# _LT_AC_SYS_COMPILER
+
+
+# _LT_AC_SYS_LIBPATH_AIX
+# ----------------------
+# Links a minimal program and checks the executable
+# for the system default hardcoded library path. In most cases,
+# this is /usr/lib:/lib, but when the MPI compilers are used
+# the location of the communication and MPI libs are included too.
+# If we don't find anything, use the default library path according
+# to the aix ld manual.
+m4_define([_LT_AC_SYS_LIBPATH_AIX],
+[AC_LINK_IFELSE(AC_LANG_PROGRAM,[
+aix_libpath=`dump -H conftest$ac_exeext 2>/dev/null | $SED -n -e '/Import File Strings/,/^$/ { /^0/ { s/^0  *\(.*\)$/\1/; p; }
+}'`
+# Check for a 64-bit object if we didn't find anything.
+if test -z "$aix_libpath"; then aix_libpath=`dump -HX64 conftest$ac_exeext 2>/dev/null | $SED -n -e '/Import File Strings/,/^$/ { /^0/ { s/^0  *\(.*\)$/\1/; p; }
+}'`; fi],[])
+if test -z "$aix_libpath"; then aix_libpath="/usr/lib:/lib"; fi
+])# _LT_AC_SYS_LIBPATH_AIX
+
+
+# _LT_AC_SHELL_INIT(ARG)
+# ----------------------
+m4_define([_LT_AC_SHELL_INIT],
+[ifdef([AC_DIVERSION_NOTICE],
+	     [AC_DIVERT_PUSH(AC_DIVERSION_NOTICE)],
+	 [AC_DIVERT_PUSH(NOTICE)])
+$1
+AC_DIVERT_POP
+])# _LT_AC_SHELL_INIT
+
+
+# _LT_AC_PROG_ECHO_BACKSLASH
+# --------------------------
+# Add some code to the start of the generated configure script which
+# will find an echo command which doesn't interpret backslashes.
+m4_define([_LT_AC_PROG_ECHO_BACKSLASH],
+[_LT_AC_SHELL_INIT([
+# Check that we are running under the correct shell.
+SHELL=${CONFIG_SHELL-/bin/sh}
+
+case X$ECHO in
+X*--fallback-echo)
+  # Remove one level of quotation (which was required for Make).
+  ECHO=`echo "$ECHO" | sed 's,\\\\\[$]\\[$]0,'[$]0','`
+  ;;
+esac
+
+echo=${ECHO-echo}
+if test "X[$]1" = X--no-reexec; then
+  # Discard the --no-reexec flag, and continue.
+  shift
+elif test "X[$]1" = X--fallback-echo; then
+  # Avoid inline document here, it may be left over
+  :
+elif test "X`($echo '\t') 2>/dev/null`" = 'X\t' ; then
+  # Yippee, $echo works!
+  :
+else
+  # Restart under the correct shell.
+  exec $SHELL "[$]0" --no-reexec ${1+"[$]@"}
+fi
+
+if test "X[$]1" = X--fallback-echo; then
+  # used as fallback echo
+  shift
+  cat <<_LT_EOF
+[$]*
+_LT_EOF
+  exit 0
+fi
+
+# The HP-UX ksh and POSIX shell print the target directory to stdout
+# if CDPATH is set.
+if test "X${CDPATH+set}" = Xset; then CDPATH=:; export CDPATH; fi
+
+if test -z "$ECHO"; then
+if test "X${echo_test_string+set}" != Xset; then
+# find a string as large as possible, as long as the shell can cope with it
+  for cmd in 'sed 50q "[$]0"' 'sed 20q "[$]0"' 'sed 10q "[$]0"' 'sed 2q "[$]0"' 'echo test'; do
+    # expected sizes: less than 2Kb, 1Kb, 512 bytes, 16 bytes, ...
+    if (echo_test_string="`eval $cmd`") 2>/dev/null &&
+       echo_test_string="`eval $cmd`" &&
+       (test "X$echo_test_string" = "X$echo_test_string") 2>/dev/null
+    then
+      break
+    fi
+  done
+fi
+
+if test "X`($echo '\t') 2>/dev/null`" = 'X\t' &&
+   echo_testing_string=`($echo "$echo_test_string") 2>/dev/null` &&
+   test "X$echo_testing_string" = "X$echo_test_string"; then
+  :
+else
+  # The Solaris, AIX, and Digital Unix default echo programs unquote
+  # backslashes.  This makes it impossible to quote backslashes using
+  #   echo "$something" | sed 's/\\/\\\\/g'
+  #
+  # So, first we look for a working echo in the user's PATH.
+
+  lt_save_ifs="$IFS"; IFS=$PATH_SEPARATOR
+  for dir in $PATH /usr/ucb; do
+    IFS="$lt_save_ifs"
+    if (test -f $dir/echo || test -f $dir/echo$ac_exeext) &&
+       test "X`($dir/echo '\t') 2>/dev/null`" = 'X\t' &&
+       echo_testing_string=`($dir/echo "$echo_test_string") 2>/dev/null` &&
+       test "X$echo_testing_string" = "X$echo_test_string"; then
+      echo="$dir/echo"
+      break
+    fi
+  done
+  IFS="$lt_save_ifs"
+
+  if test "X$echo" = Xecho; then
+    # We didn't find a better echo, so look for alternatives.
+    if test "X`(print -r '\t') 2>/dev/null`" = 'X\t' &&
+       echo_testing_string=`(print -r "$echo_test_string") 2>/dev/null` &&
+       test "X$echo_testing_string" = "X$echo_test_string"; then
+      # This shell has a builtin print -r that does the trick.
+      echo='print -r'
+    elif (test -f /bin/ksh || test -f /bin/ksh$ac_exeext) &&
+	 test "X$CONFIG_SHELL" != X/bin/ksh; then
+      # If we have ksh, try running configure again with it.
+      ORIGINAL_CONFIG_SHELL=${CONFIG_SHELL-/bin/sh}
+      export ORIGINAL_CONFIG_SHELL
+      CONFIG_SHELL=/bin/ksh
+      export CONFIG_SHELL
+      exec $CONFIG_SHELL "[$]0" --no-reexec ${1+"[$]@"}
+    else
+      # Try using printf.
+      echo='printf %s\n'
+      if test "X`($echo '\t') 2>/dev/null`" = 'X\t' &&
+	 echo_testing_string=`($echo "$echo_test_string") 2>/dev/null` &&
+	 test "X$echo_testing_string" = "X$echo_test_string"; then
+	# Cool, printf works
+	:
+      elif echo_testing_string=`($ORIGINAL_CONFIG_SHELL "[$]0" --fallback-echo '\t') 2>/dev/null` &&
+	   test "X$echo_testing_string" = 'X\t' &&
+	   echo_testing_string=`($ORIGINAL_CONFIG_SHELL "[$]0" --fallback-echo "$echo_test_string") 2>/dev/null` &&
+	   test "X$echo_testing_string" = "X$echo_test_string"; then
+	CONFIG_SHELL=$ORIGINAL_CONFIG_SHELL
+	export CONFIG_SHELL
+	SHELL="$CONFIG_SHELL"
+	export SHELL
+	echo="$CONFIG_SHELL [$]0 --fallback-echo"
+      elif echo_testing_string=`($CONFIG_SHELL "[$]0" --fallback-echo '\t') 2>/dev/null` &&
+	   test "X$echo_testing_string" = 'X\t' &&
+	   echo_testing_string=`($CONFIG_SHELL "[$]0" --fallback-echo "$echo_test_string") 2>/dev/null` &&
+	   test "X$echo_testing_string" = "X$echo_test_string"; then
+	echo="$CONFIG_SHELL [$]0 --fallback-echo"
+      else
+	# maybe with a smaller string...
+	prev=:
+
+	for cmd in 'echo test' 'sed 2q "[$]0"' 'sed 10q "[$]0"' 'sed 20q "[$]0"' 'sed 50q "[$]0"'; do
+	  if (test "X$echo_test_string" = "X`eval $cmd`") 2>/dev/null
+	  then
+	    break
+	  fi
+	  prev="$cmd"
+	done
+
+	if test "$prev" != 'sed 50q "[$]0"'; then
+	  echo_test_string=`eval $prev`
+	  export echo_test_string
+	  exec ${ORIGINAL_CONFIG_SHELL-${CONFIG_SHELL-/bin/sh}} "[$]0" ${1+"[$]@"}
+	else
+	  # Oops.  We lost completely, so just stick with echo.
+	  echo=echo
+	fi
+      fi
+    fi
+  fi
+fi
+fi
+
+# Copy echo and quote the copy suitably for passing to libtool from
+# the Makefile, instead of quoting the original, which is used later.
+ECHO=$echo
+if test "X$ECHO" = "X$CONFIG_SHELL [$]0 --fallback-echo"; then
+   ECHO="$CONFIG_SHELL \\\$\[$]0 --fallback-echo"
+fi
+
+AC_SUBST(ECHO)
+])
+_LT_DECL([], [SHELL], [1], [Shell to use when invoking shell scripts])
+_LT_DECL([], [echo], [1],
+    [An echo program that does not interpret backslashes])
+])# _LT_AC_PROG_ECHO_BACKSLASH
+
+
+# _LT_AC_LOCK
+# -----------
+AC_DEFUN([_LT_AC_LOCK],
+[AC_REQUIRE([AC_OBJEXT])dnl
+AC_ARG_ENABLE([libtool-lock],
+    [AC_HELP_STRING([--disable-libtool-lock],
+	[avoid locking (might break parallel builds)])])
+test "x$enable_libtool_lock" != xno && enable_libtool_lock=yes
+
+# Some flags need to be propagated to the compiler or linker for good
+# libtool support.
+case $host in
+ia64-*-hpux*)
+  # Find out which ABI we are using.
+  echo 'int i;' > conftest.$ac_ext
+  if AC_TRY_EVAL(ac_compile); then
+    case `/usr/bin/file conftest.$ac_objext` in
+    *ELF-32*)
+      HPUX_IA64_MODE="32"
+      ;;
+    *ELF-64*)
+      HPUX_IA64_MODE="64"
+      ;;
+    esac
+  fi
+  rm -rf conftest*
+  ;;
+*-*-irix6*)
+  # Find out which ABI we are using.
+  echo '[#]line __oline__ "configure"' > conftest.$ac_ext
+  if AC_TRY_EVAL(ac_compile); then
+   if test "$lt_cv_prog_gnu_ld" = yes; then
+    case `/usr/bin/file conftest.$ac_objext` in
+    *32-bit*)
+      LD="${LD-ld} -melf32bsmip"
+      ;;
+    *N32*)
+      LD="${LD-ld} -melf32bmipn32"
+      ;;
+    *64-bit*)
+      LD="${LD-ld} -melf64bmip"
+      ;;
+    esac
+   else
+    case `/usr/bin/file conftest.$ac_objext` in
+    *32-bit*)
+      LD="${LD-ld} -32"
+      ;;
+    *N32*)
+      LD="${LD-ld} -n32"
+      ;;
+    *64-bit*)
+      LD="${LD-ld} -64"
+      ;;
+    esac
+   fi
+  fi
+  rm -rf conftest*
+  ;;
+
+x86_64-*linux*|ppc*-*linux*|powerpc*-*linux*|s390*-*linux*|sparc*-*linux*)
+  # Find out which ABI we are using.
+  echo 'int i;' > conftest.$ac_ext
+  if AC_TRY_EVAL(ac_compile); then
+    case "`/usr/bin/file conftest.o`" in
+    *32-bit*)
+      case $host in
+        x86_64-*linux*)
+          LD="${LD-ld} -m elf_i386"
+          ;;
+        ppc64-*linux*|powerpc64-*linux*)
+          LD="${LD-ld} -m elf32ppclinux"
+          ;;
+        s390x-*linux*)
+          LD="${LD-ld} -m elf_s390"
+          ;;
+        sparc64-*linux*)
+          LD="${LD-ld} -m elf32_sparc"
+          ;;
+      esac
+      ;;
+    *64-bit*)
+      case $host in
+        x86_64-*linux*)
+          LD="${LD-ld} -m elf_x86_64"
+          ;;
+        ppc*-*linux*|powerpc*-*linux*)
+          LD="${LD-ld} -m elf64ppc"
+          ;;
+        s390*-*linux*)
+          LD="${LD-ld} -m elf64_s390"
+          ;;
+        sparc*-*linux*)
+          LD="${LD-ld} -m elf64_sparc"
+          ;;
+      esac
+      ;;
+    esac
+  fi
+  rm -rf conftest*
+  ;;
+
+*-*-sco3.2v5*)
+  # On SCO OpenServer 5, we need -belf to get full-featured binaries.
+  SAVE_CFLAGS="$CFLAGS"
+  CFLAGS="$CFLAGS -belf"
+  AC_CACHE_CHECK([whether the C compiler needs -belf], lt_cv_cc_needs_belf,
+    [AC_LANG_PUSH(C)
+     AC_TRY_LINK([],[],[lt_cv_cc_needs_belf=yes],[lt_cv_cc_needs_belf=no])
+     AC_LANG_POP])
+  if test x"$lt_cv_cc_needs_belf" != x"yes"; then
+    # this is probably gcc 2.8.0, egcs 1.0 or newer; no need for -belf
+    CFLAGS="$SAVE_CFLAGS"
+  fi
+  ;;
+esac
+
+need_locks="$enable_libtool_lock"
+])# _LT_AC_LOCK
+
+
+# AC_LIBTOOL_SYS_OLD_ARCHIVE
+# --------------------------
+AC_DEFUN([AC_LIBTOOL_SYS_OLD_ARCHIVE],
+[AC_CHECK_TOOL(AR, ar, false)
+test -z "$AR" && AR=ar
+test -z "$AR_FLAGS" && AR_FLAGS=cru
+_LT_DECL([], [AR], [1], [The archiver])
+_LT_DECL([], [AR_FLAGS], [1])
+
+AC_CHECK_TOOL(STRIP, strip, :)
+test -z "$STRIP" && STRIP=:
+_LT_DECL([], [STRIP], [1], [A symbol stripping program])
+
+AC_CHECK_TOOL(RANLIB, ranlib, :)
+test -z "$RANLIB" && RANLIB=:
+_LT_DECL([], [RANLIB], [1],
+    [Commands used to install an old-style archive])
+
+# Determine commands to create old-style static archives.
+old_archive_cmds='$AR $AR_FLAGS $oldlib$oldobjs$old_deplibs'
+old_postinstall_cmds='chmod 644 $oldlib'
+old_postuninstall_cmds=
+
+if test -n "$RANLIB"; then
+  case $host_os in
+  openbsd*)
+    old_postinstall_cmds="\$RANLIB -t \$oldlib~$old_postinstall_cmds"
+    ;;
+  *)
+    old_postinstall_cmds="\$RANLIB \$oldlib~$old_postinstall_cmds"
+    ;;
+  esac
+  old_archive_cmds="$old_archive_cmds~\$RANLIB \$oldlib"
+fi
+_LT_DECL([], [old_postinstall_cmds], [2])
+_LT_DECL([], [old_postuninstall_cmds], [2])
+_LT_TAGDECL([], [old_archive_cmds], [2],
+    [Commands used to build an old-style archive])
+])# AC_LIBTOOL_SYS_OLD_ARCHIVE
+
+
+# AC_LIBTOOL_COMPILER_OPTION(MESSAGE, VARIABLE-NAME, FLAGS,
+#		[OUTPUT-FILE], [ACTION-SUCCESS], [ACTION-FAILURE])
+# ----------------------------------------------------------------
+# Check whether the given compiler option works
+AC_DEFUN([AC_LIBTOOL_COMPILER_OPTION],
+[AC_REQUIRE([AC_OBJEXT])dnl
+AC_REQUIRE([LT_AC_PROG_SED])dnl
+AC_CACHE_CHECK([$1], [$2],
+  [$2=no
+  m4_if([$4], , [ac_outfile=conftest.$ac_objext], [ac_outfile=$4])
+   printf "$lt_simple_compile_test_code" > conftest.$ac_ext
+   lt_compiler_flag="$3"
+   # Insert the option either (1) after the last *FLAGS variable, or
+   # (2) before a word containing "conftest.", or (3) at the end.
+   # Note that $ac_compile itself does not contain backslashes and begins
+   # with a dollar sign (not a hyphen), so the echo should work correctly.
+   # The option is referenced via a variable to avoid confusing sed.
+   lt_compile=`echo "$ac_compile" | $SED \
+   -e 's:.*FLAGS}? :&$lt_compiler_flag :; t' \
+   -e 's: [[^ ]]*conftest\.: $lt_compiler_flag&:; t' \
+   -e 's:$: $lt_compiler_flag:'`
+   (eval echo "\"\$as_me:__oline__: $lt_compile\"" >&AS_MESSAGE_LOG_FD)
+   (eval "$lt_compile" 2>conftest.err)
+   ac_status=$?
+   cat conftest.err >&AS_MESSAGE_LOG_FD
+   echo "$as_me:__oline__: \$? = $ac_status" >&AS_MESSAGE_LOG_FD
+   if (exit $ac_status) && test -s "$ac_outfile"; then
+     # The compiler can only warn and ignore the option if not recognized
+     # So say no if there are warnings
+     if test ! -s conftest.err; then
+       $2=yes
+     fi
+   fi
+   $rm conftest*
+])
+
+if test x"[$]$2" = xyes; then
+    m4_if([$5], , :, [$5])
+else
+    m4_if([$6], , :, [$6])
+fi
+])# AC_LIBTOOL_COMPILER_OPTION
+
+
+# AC_LIBTOOL_LINKER_OPTION(MESSAGE, VARIABLE-NAME, FLAGS,
+#                          [ACTION-SUCCESS], [ACTION-FAILURE])
+# ------------------------------------------------------------
+# Check whether the given compiler option works
+m4_define([AC_LIBTOOL_LINKER_OPTION],
+[AC_CACHE_CHECK([$1], [$2],
+  [$2=no
+   save_LDFLAGS="$LDFLAGS"
+   LDFLAGS="$LDFLAGS $3"
+   printf "$lt_simple_link_test_code" > conftest.$ac_ext
+   if (eval $ac_link 2>conftest.err) && test -s conftest$ac_exeext; then
+     # The compiler can only warn and ignore the option if not recognized
+     # So say no if there are warnings
+     if test -s conftest.err; then
+       # Append any errors to the config.log.
+       cat conftest.err 1>&AS_MESSAGE_LOG_FD
+     else
+       $2=yes
+     fi
+   fi
+   $rm conftest*
+   LDFLAGS="$save_LDFLAGS"
+])
+
+if test x"[$]$2" = xyes; then
+    m4_if([$4], , :, [$4])
+else
+    m4_if([$5], , :, [$5])
+fi
+])# AC_LIBTOOL_LINKER_OPTION
+
+
+# AC_LIBTOOL_SYS_MAX_CMD_LEN
+# --------------------------
+AC_DEFUN([AC_LIBTOOL_SYS_MAX_CMD_LEN],
+[AC_REQUIRE([AC_CANONICAL_HOST])dnl
+# find the maximum length of command line arguments
+AC_MSG_CHECKING([the maximum length of command line arguments])
+AC_CACHE_VAL([lt_cv_sys_max_cmd_len], [dnl
+  i=0
+  teststring="ABCD"
+
+  case $build_os in
+  msdosdjgpp*)
+    # On DJGPP, this test can blow up pretty badly due to problems in libc
+    # (any single argument exceeding 2000 bytes causes a buffer overrun
+    # during glob expansion).  Even if it were fixed, the result of this
+    # check would be larger than it should be.
+    lt_cv_sys_max_cmd_len=12288;    # 12K is about right
+    ;;
+
+  gnu*)
+    # Under GNU Hurd, this test is not required because there is
+    # no limit to the length of command line arguments.
+    # Libtool will interpret -1 as no limit whatsoever
+    lt_cv_sys_max_cmd_len=-1;
+    ;;
+
+  cygwin* | mingw*)
+    # On Win9x/ME, this test blows up -- it succeeds, but takes
+    # about 5 minutes as the teststring grows exponentially.
+    # Worse, since 9x/ME are not pre-emptively multitasking,
+    # you end up with a "frozen" computer, even though with patience
+    # the test eventually succeeds (with a max line length of 256k).
+    # Instead, let's just punt: use the minimum linelength reported by
+    # all of the supported platforms: 8192 (on NT/2K/XP).
+    lt_cv_sys_max_cmd_len=8192;
+    ;;
+
+  amigaos*)
+    # On AmigaOS with pdksh, this test takes hours, literally.
+    # So we just punt and use a minimum line length of 8192.
+    lt_cv_sys_max_cmd_len=8192;
+    ;;
+
+ *)
+    # Make teststring a little bigger before we do anything with it.
+    # a 1K string should be a reasonable start.
+    for i in 1 2 3 4 5 6 7 8 ; do
+      teststring=$teststring$teststring
+    done
+    # If test is not a shell built-in, we'll probably end up computing a
+    # maximum length that is only half of the actual maximum length, but
+    # we can't tell.
+    while (test "X"`$CONFIG_SHELL [$]0 --fallback-echo "X$teststring$teststring" 2>/dev/null` \
+	       = "XX$teststring$teststring") >/dev/null 2>&1 &&
+	    test $i != 17 # 1/2 MB should be enough
+    do
+      i=`expr $i + 1`
+      teststring=$teststring$teststring
+    done
+    # Only check the string length outside the loop.
+    lt_cv_sys_max_cmd_len=`expr "X$teststring" : ".*" 2>&1`
+    teststring=
+    # Add a significant safety factor because C++ compilers can tack on massive
+    # amounts of additional arguments before passing them to the linker.
+    # It appears as though 1/2 is a usable value.
+    lt_cv_sys_max_cmd_len=`expr $lt_cv_sys_max_cmd_len \/ 2`
+    ;;
+  esac
+])
+if test -n $lt_cv_sys_max_cmd_len ; then
+  AC_MSG_RESULT($lt_cv_sys_max_cmd_len)
+else
+  AC_MSG_RESULT(none)
+fi
+_LT_DECL([max_cmd_len], [lt_cv_sys_max_cmd_len], [0],
+    [What is the maximum length of a command?])
+])# AC_LIBTOOL_SYS_MAX_CMD_LEN
+
+
+# _LT_AC_CHECK_DLFCN
+# --------------------
+AC_DEFUN([_LT_AC_CHECK_DLFCN],
+[AC_CHECK_HEADERS([dlfcn.h], [], [], [AC_INCLUDES_DEFAULT])dnl
+])# _LT_AC_CHECK_DLFCN
+
+
+# _LT_AC_TRY_DLOPEN_SELF (ACTION-IF-TRUE, ACTION-IF-TRUE-W-USCORE,
+#                           ACTION-IF-FALSE, ACTION-IF-CROSS-COMPILING)
+# ------------------------------------------------------------------
+AC_DEFUN([_LT_AC_TRY_DLOPEN_SELF],
+[AC_REQUIRE([_LT_AC_CHECK_DLFCN])dnl
+if test "$cross_compiling" = yes; then :
+  [$4]
+else
+  lt_dlunknown=0; lt_dlno_uscore=1; lt_dlneed_uscore=2
+  lt_status=$lt_dlunknown
+  cat > conftest.$ac_ext <<_LT_EOF
+[#line __oline__ "configure"
+#include "confdefs.h"
+
+#if HAVE_DLFCN_H
+#include <dlfcn.h>
+#endif
+
+#include <stdio.h>
+
+#ifdef RTLD_GLOBAL
+#  define LT_DLGLOBAL		RTLD_GLOBAL
+#else
+#  ifdef DL_GLOBAL
+#    define LT_DLGLOBAL		DL_GLOBAL
+#  else
+#    define LT_DLGLOBAL		0
+#  endif
+#endif
+
+/* We may have to define LT_DLLAZY_OR_NOW in the command line if we
+   find out it does not work in some platform. */
+#ifndef LT_DLLAZY_OR_NOW
+#  ifdef RTLD_LAZY
+#    define LT_DLLAZY_OR_NOW		RTLD_LAZY
+#  else
+#    ifdef DL_LAZY
+#      define LT_DLLAZY_OR_NOW		DL_LAZY
+#    else
+#      ifdef RTLD_NOW
+#        define LT_DLLAZY_OR_NOW	RTLD_NOW
+#      else
+#        ifdef DL_NOW
+#          define LT_DLLAZY_OR_NOW	DL_NOW
+#        else
+#          define LT_DLLAZY_OR_NOW	0
+#        endif
+#      endif
+#    endif
+#  endif
+#endif
+
+#ifdef __cplusplus
+extern "C" void exit (int);
+#endif
+
+void fnord() { int i=42;}
+int main ()
+{
+  void *self = dlopen (0, LT_DLGLOBAL|LT_DLLAZY_OR_NOW);
+  int status = $lt_dlunknown;
+
+  if (self)
+    {
+      if (dlsym (self,"fnord"))       status = $lt_dlno_uscore;
+      else if (dlsym( self,"_fnord")) status = $lt_dlneed_uscore;
+      /* dlclose (self); */
+    }
+
+    exit (status);
+}]
+_LT_EOF
+  if AC_TRY_EVAL(ac_link) && test -s conftest${ac_exeext} 2>/dev/null; then
+    (./conftest; exit; ) 2>/dev/null
+    lt_status=$?
+    case x$lt_status in
+      x$lt_dlno_uscore) $1 ;;
+      x$lt_dlneed_uscore) $2 ;;
+      x$lt_unknown|x*) $3 ;;
+    esac
+  else :
+    # compilation failed
+    $3
+  fi
+fi
+rm -fr conftest*
+])# _LT_AC_TRY_DLOPEN_SELF
+
+
+# AC_LIBTOOL_DLOPEN_SELF
+# -------------------
+AC_DEFUN([AC_LIBTOOL_DLOPEN_SELF],
+[AC_REQUIRE([_LT_AC_CHECK_DLFCN])dnl
+if test "x$enable_dlopen" != xyes; then
+  enable_dlopen=unknown
+  enable_dlopen_self=unknown
+  enable_dlopen_self_static=unknown
+else
+  lt_cv_dlopen=no
+  lt_cv_dlopen_libs=
+
+  case $host_os in
+  beos*)
+    lt_cv_dlopen="load_add_on"
+    lt_cv_dlopen_libs=
+    lt_cv_dlopen_self=yes
+    ;;
+
+  mingw* | pw32*)
+    lt_cv_dlopen="LoadLibrary"
+    lt_cv_dlopen_libs=
+   ;;
+
+  cygwin*)
+    lt_cv_dlopen="dlopen"
+    lt_cv_dlopen_libs=
+   ;;
+
+  darwin*)
+  # if libdl is installed we need to link against it
+    AC_CHECK_LIB([dl], [dlopen],
+		[lt_cv_dlopen="dlopen" lt_cv_dlopen_libs="-ldl"],[
+    lt_cv_dlopen="dyld"
+    lt_cv_dlopen_libs=
+    lt_cv_dlopen_self=yes
+    ])
+   ;;
+
+  *)
+    AC_CHECK_FUNC([shl_load],
+	  [lt_cv_dlopen="shl_load"],
+      [AC_CHECK_LIB([dld], [shl_load],
+	    [lt_cv_dlopen="shl_load" lt_cv_dlopen_libs="-dld"],
+	[AC_CHECK_FUNC([dlopen],
+	      [lt_cv_dlopen="dlopen"],
+	  [AC_CHECK_LIB([dl], [dlopen],
+		[lt_cv_dlopen="dlopen" lt_cv_dlopen_libs="-ldl"],
+	    [AC_CHECK_LIB([svld], [dlopen],
+		  [lt_cv_dlopen="dlopen" lt_cv_dlopen_libs="-lsvld"],
+	      [AC_CHECK_LIB([dld], [dld_link],
+		    [lt_cv_dlopen="dld_link" lt_cv_dlopen_libs="-dld"])
+	      ])
+	    ])
+	  ])
+	])
+      ])
+    ;;
+  esac
+
+  if test "x$lt_cv_dlopen" != xno; then
+    enable_dlopen=yes
+  else
+    enable_dlopen=no
+  fi
+
+  case $lt_cv_dlopen in
+  dlopen)
+    save_CPPFLAGS="$CPPFLAGS"
+    test "x$ac_cv_header_dlfcn_h" = xyes && CPPFLAGS="$CPPFLAGS -DHAVE_DLFCN_H"
+
+    save_LDFLAGS="$LDFLAGS"
+    eval LDFLAGS=\"\$LDFLAGS $export_dynamic_flag_spec\"
+
+    save_LIBS="$LIBS"
+    LIBS="$lt_cv_dlopen_libs $LIBS"
+
+    AC_CACHE_CHECK([whether a program can dlopen itself],
+	  lt_cv_dlopen_self, [dnl
+	  _LT_AC_TRY_DLOPEN_SELF(
+	    lt_cv_dlopen_self=yes, lt_cv_dlopen_self=yes,
+	    lt_cv_dlopen_self=no, lt_cv_dlopen_self=cross)
+    ])
+
+    if test "x$lt_cv_dlopen_self" = xyes; then
+      LDFLAGS="$LDFLAGS $link_static_flag"
+      AC_CACHE_CHECK([whether a statically linked program can dlopen itself],
+    	  lt_cv_dlopen_self_static, [dnl
+	  _LT_AC_TRY_DLOPEN_SELF(
+	    lt_cv_dlopen_self_static=yes, lt_cv_dlopen_self_static=yes,
+	    lt_cv_dlopen_self_static=no,  lt_cv_dlopen_self_static=cross)
+      ])
+    fi
+
+    CPPFLAGS="$save_CPPFLAGS"
+    LDFLAGS="$save_LDFLAGS"
+    LIBS="$save_LIBS"
+    ;;
+  esac
+
+  case $lt_cv_dlopen_self in
+  yes|no) enable_dlopen_self=$lt_cv_dlopen_self ;;
+  *) enable_dlopen_self=unknown ;;
+  esac
+
+  case $lt_cv_dlopen_self_static in
+  yes|no) enable_dlopen_self_static=$lt_cv_dlopen_self_static ;;
+  *) enable_dlopen_self_static=unknown ;;
+  esac
+fi
+_LT_DECL([dlopen_support], [enable_dlopen], [0],
+	 [Whether dlopen is supported])
+_LT_DECL([dlopen_self], [enable_dlopen_self], [0],
+	 [Whether dlopen of programs is supported])
+_LT_DECL([dlopen_self_static], [enable_dlopen_self_static], [0],
+	 [Whether dlopen of statically linked programs is supported])
+])# AC_LIBTOOL_DLOPEN_SELF
+
+
+# AC_LIBTOOL_PROG_CC_C_O([TAGNAME])
+# ---------------------------------
+# Check to see if options -c and -o are simultaneously supported by compiler
+AC_DEFUN([AC_LIBTOOL_PROG_CC_C_O],
+[AC_REQUIRE([_LT_AC_SYS_COMPILER])dnl
+AC_REQUIRE([AC_OBJEXT])dnl
+AC_CACHE_CHECK([if $compiler supports -c -o file.$ac_objext],
+  [_LT_AC_TAGVAR(lt_cv_prog_compiler_c_o, $1)],
+  [_LT_AC_TAGVAR(lt_cv_prog_compiler_c_o, $1)=no
+   $rm -r conftest 2>/dev/null
+   mkdir conftest
+   cd conftest
+   mkdir out
+   printf "$lt_simple_compile_test_code" > conftest.$ac_ext
+
+   lt_compiler_flag="-o out/conftest2.$ac_objext"
+   # Insert the option either (1) after the last *FLAGS variable, or
+   # (2) before a word containing "conftest.", or (3) at the end.
+   # Note that $ac_compile itself does not contain backslashes and begins
+   # with a dollar sign (not a hyphen), so the echo should work correctly.
+   lt_compile=`echo "$ac_compile" | $SED \
+   -e 's:.*FLAGS}? :&$lt_compiler_flag :; t' \
+   -e 's: [[^ ]]*conftest\.: $lt_compiler_flag&:; t' \
+   -e 's:$: $lt_compiler_flag:'`
+   (eval echo "\"\$as_me:__oline__: $lt_compile\"" >&AS_MESSAGE_LOG_FD)
+   (eval "$lt_compile" 2>out/conftest.err)
+   ac_status=$?
+   cat out/conftest.err >&AS_MESSAGE_LOG_FD
+   echo "$as_me:__oline__: \$? = $ac_status" >&AS_MESSAGE_LOG_FD
+   if (exit $ac_status) && test -s out/conftest2.$ac_objext
+   then
+     # The compiler can only warn and ignore the option if not recognized
+     # So say no if there are warnings
+     if test ! -s out/conftest.err; then
+       _LT_AC_TAGVAR(lt_cv_prog_compiler_c_o, $1)=yes
+     fi
+   fi
+   chmod u+w .
+   $rm conftest*
+   # SGI C++ compiler will create directory out/ii_files/ for
+   # template instantiation
+   test -d out/ii_files && $rm out/ii_files/* && rmdir out/ii_files
+   $rm out/* && rmdir out
+   cd ..
+   rmdir conftest
+   $rm conftest*
+])
+_LT_DECL([compiler_c_o], [lt_cv_prog_compiler_c_o], [1],
+	[Does compiler simultaneously support -c and -o options?])
+])# AC_LIBTOOL_PROG_CC_C_O
+
+
+# AC_LIBTOOL_SYS_HARD_LINK_LOCKS([TAGNAME])
+# -----------------------------------------
+# Check to see if we can do hard links to lock some files if needed
+AC_DEFUN([AC_LIBTOOL_SYS_HARD_LINK_LOCKS],
+[AC_REQUIRE([AC_LIBTOOL_PROG_CC_C_O])dnl
+AC_REQUIRE([_LT_AC_LOCK])dnl
+
+hard_links="nottested"
+if test "$_LT_AC_TAGVAR(lt_cv_prog_compiler_c_o, $1)" = no && test "$need_locks" != no; then
+  # do not overwrite the value of need_locks provided by the user
+  AC_MSG_CHECKING([if we can lock with hard links])
+  hard_links=yes
+  $rm conftest*
+  ln conftest.a conftest.b 2>/dev/null && hard_links=no
+  touch conftest.a
+  ln conftest.a conftest.b 2>&5 || hard_links=no
+  ln conftest.a conftest.b 2>/dev/null && hard_links=no
+  AC_MSG_RESULT([$hard_links])
+  if test "$hard_links" = no; then
+    AC_MSG_WARN([`$CC' does not support `-c -o', so `make -j' may be unsafe])
+    need_locks=warn
+  fi
+else
+  need_locks=no
+fi
+_LT_DECL([], [need_locks], [1], [Must we lock files when doing compilation?])
+])# AC_LIBTOOL_SYS_HARD_LINK_LOCKS
+
+
+# AC_LIBTOOL_OBJDIR
+# -----------------
+AC_DEFUN([AC_LIBTOOL_OBJDIR],
+[AC_CACHE_CHECK([for objdir], [lt_cv_objdir],
+[rm -f .libs 2>/dev/null
+mkdir .libs 2>/dev/null
+if test -d .libs; then
+  lt_cv_objdir=.libs
+else
+  # MS-DOS does not allow filenames that begin with a dot.
+  lt_cv_objdir=_libs
+fi
+rmdir .libs 2>/dev/null])
+objdir=$lt_cv_objdir
+_LT_DECL([], [objdir], [0],
+         [The name of the directory that contains temporary libtool files])dnl
+])# AC_LIBTOOL_OBJDIR
+
+
+# AC_LIBTOOL_PROG_LD_HARDCODE_LIBPATH([TAGNAME])
+# ----------------------------------------------
+# Check hardcoding attributes.
+AC_DEFUN([AC_LIBTOOL_PROG_LD_HARDCODE_LIBPATH],
+[AC_MSG_CHECKING([how to hardcode library paths into programs])
+_LT_AC_TAGVAR(hardcode_action, $1)=
+if test -n "$_LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)" ||
+   test -n "$_LT_AC_TAGVAR(runpath_var $1)" ||
+   test "X$_LT_AC_TAGVAR(hardcode_automatic, $1)"="Xyes" ; then
+
+  # We can hardcode non-existant directories.
+  if test "$_LT_AC_TAGVAR(hardcode_direct, $1)" != no &&
+     # If the only mechanism to avoid hardcoding is shlibpath_var, we
+     # have to relink, otherwise we might link with an installed library
+     # when we should be linking with a yet-to-be-installed one
+     ## test "$_LT_AC_TAGVAR(hardcode_shlibpath_var, $1)" != no &&
+     test "$_LT_AC_TAGVAR(hardcode_minus_L, $1)" != no; then
+    # Linking always hardcodes the temporary library directory.
+    _LT_AC_TAGVAR(hardcode_action, $1)=relink
+  else
+    # We can link without hardcoding, and we can hardcode nonexisting dirs.
+    _LT_AC_TAGVAR(hardcode_action, $1)=immediate
+  fi
+else
+  # We cannot hardcode anything, or else we can only hardcode existing
+  # directories.
+  _LT_AC_TAGVAR(hardcode_action, $1)=unsupported
+fi
+AC_MSG_RESULT([$_LT_AC_TAGVAR(hardcode_action, $1)])
+
+if test "$_LT_AC_TAGVAR(hardcode_action, $1)" = relink ||
+   test "$_LT_AC_TAGVAR(inherit_rpath, $1)" = yes; then
+  # Fast installation is not supported
+  enable_fast_install=no
+elif test "$shlibpath_overrides_runpath" = yes ||
+     test "$enable_shared" = no; then
+  # Fast installation is not necessary
+  enable_fast_install=needless
+fi
+_LT_TAGDECL([], [hardcode_action], [0],
+    [How to hardcode a shared library path into an executable])
+])# AC_LIBTOOL_PROG_LD_HARDCODE_LIBPATH
+
+
+# AC_LIBTOOL_SYS_LIB_STRIP
+# ------------------------
+AC_DEFUN([AC_LIBTOOL_SYS_LIB_STRIP],
+[AC_REQUIRE([LT_AC_PROG_EGREP])
+striplib=
+old_striplib=
+AC_MSG_CHECKING([whether stripping libraries is possible])
+if test -n "$STRIP" && $STRIP -V 2>&1 | $GREP "GNU strip" >/dev/null; then
+  test -z "$old_striplib" && old_striplib="$STRIP --strip-debug"
+  test -z "$striplib" && striplib="$STRIP --strip-unneeded"
+  AC_MSG_RESULT([yes])
+else
+# FIXME - insert some real tests, host_os isn't really good enough
+  case $host_os in
+   darwin*)
+       if test -n "$STRIP" ; then
+         striplib="$STRIP -x"
+         AC_MSG_RESULT([yes])
+       else
+  AC_MSG_RESULT([no])
+fi
+       ;;
+   *)
+  AC_MSG_RESULT([no])
+    ;;
+  esac
+fi
+_LT_DECL([], [old_striplib], [1], [Commands to strip libraries])
+_LT_DECL([], [striplib], [1])
+])# AC_LIBTOOL_SYS_LIB_STRIP
+
+
+# AC_LIBTOOL_SYS_DYNAMIC_LINKER
+# -----------------------------
+# PORTME Fill in your ld.so characteristics
+AC_DEFUN([AC_LIBTOOL_SYS_DYNAMIC_LINKER],
+[AC_REQUIRE([LT_AC_PROG_EGREP])
+AC_MSG_CHECKING([dynamic linker characteristics])
+library_names_spec=
+libname_spec='lib$name'
+soname_spec=
+shrext_cmds=".so"
+postinstall_cmds=
+postuninstall_cmds=
+finish_cmds=
+finish_eval=
+shlibpath_var=
+shlibpath_overrides_runpath=unknown
+version_type=none
+dynamic_linker="$host_os ld.so"
+sys_lib_dlsearch_path_spec="/lib /usr/lib"
+if test "$GCC" = yes; then
+  sys_lib_search_path_spec=`$CC -print-search-dirs | $GREP "^libraries:" | $SED -e "s/^libraries://" -e "s,=/,/,g"`
+  if echo "$sys_lib_search_path_spec" | $GREP ';' >/dev/null ; then
+    # if the path contains ";" then we assume it to be the separator
+    # otherwise default to the standard path separator (i.e. ":") - it is
+    # assumed that no part of a normal pathname contains ";" but that should
+    # okay in the real world where ";" in dirpaths is itself problematic.
+    sys_lib_search_path_spec=`echo "$sys_lib_search_path_spec" | $SED -e 's/;/ /g'`
+  else
+    sys_lib_search_path_spec=`echo "$sys_lib_search_path_spec" | $SED  -e "s/$PATH_SEPARATOR/ /g"`
+  fi
+else
+  sys_lib_search_path_spec="/lib /usr/lib /usr/local/lib"
+fi
+need_lib_prefix=unknown
+hardcode_into_libs=no
+
+# when you set need_version to no, make sure it does not cause -set_version
+# flags to be left without arguments
+need_version=unknown
+
+case $host_os in
+aix3*)
+  version_type=linux
+  library_names_spec='${libname}${release}${shared_ext}$versuffix $libname.a'
+  shlibpath_var=LIBPATH
+
+  # AIX 3 has no versioning support, so we append a major version to the name.
+  soname_spec='${libname}${release}${shared_ext}$major'
+  ;;
+
+aix4* | aix5*)
+  version_type=linux
+  need_lib_prefix=no
+  need_version=no
+  hardcode_into_libs=yes
+  if test "$host_cpu" = ia64; then
+    # AIX 5 supports IA64
+    library_names_spec='${libname}${release}${shared_ext}$major ${libname}${release}${shared_ext}$versuffix $libname${shared_ext}'
+    shlibpath_var=LD_LIBRARY_PATH
+  else
+    # With GCC up to 2.95.x, collect2 would create an import file
+    # for dependence libraries.  The import file would start with
+    # the line `#! .'.  This would cause the generated library to
+    # depend on `.', always an invalid library.  This was fixed in
+    # development snapshots of GCC prior to 3.0.
+    case $host_os in
+      aix4 | aix4.[[01]] | aix4.[[01]].*)
+      if { echo '#if __GNUC__ > 2 || (__GNUC__ == 2 && __GNUC_MINOR__ >= 97)'
+	   echo ' yes '
+	   echo '#endif'; } | ${CC} -E - | $GREP yes > /dev/null; then
+	:
+      else
+	can_build_shared=no
+      fi
+      ;;
+    esac
+    # AIX (on Power*) has no versioning support, so currently we can not hardcode correct
+    # soname into executable. Probably we can add versioning support to
+    # collect2, so additional links can be useful in future.
+    if test "$aix_use_runtimelinking" = yes; then
+      # If using run time linking (on AIX 4.2 or later) use lib<name>.so
+      # instead of lib<name>.a to let people know that these are not
+      # typical AIX shared libraries.
+      library_names_spec='${libname}${release}${shared_ext}$versuffix ${libname}${release}${shared_ext}$major $libname${shared_ext}'
+    else
+      # We preserve .a as extension for shared libraries through AIX4.2
+      # and later when we are not doing run time linking.
+      library_names_spec='${libname}${release}.a $libname.a'
+      soname_spec='${libname}${release}${shared_ext}$major'
+    fi
+    shlibpath_var=LIBPATH
+  fi
+  ;;
+
+amigaos*)
+  if test "$host_cpu" = m68k; then
+    library_names_spec='$libname.ixlibrary $libname.a'
+    # Create ${libname}_ixlibrary.a entries in /sys/libs.
+    finish_eval='for lib in `ls $libdir/*.ixlibrary 2>/dev/null`; do libname=`$echo "X$lib" | $Xsed -e '\''s%^.*/\([[^/]]*\)\.ixlibrary$%\1%'\''`; test $rm /sys/libs/${libname}_ixlibrary.a; $show "cd /sys/libs && $LN_S $lib ${libname}_ixlibrary.a"; cd /sys/libs && $LN_S $lib ${libname}_ixlibrary.a || exit 1; done'
+  else
+    dynamic_linker=no
+  fi
+  ;;
+
+beos*)
+  library_names_spec='${libname}${shared_ext}'
+  dynamic_linker="$host_os ld.so"
+  shlibpath_var=LIBRARY_PATH
+  ;;
+
+bsdi4*)
+  version_type=linux
+  need_version=no
+  library_names_spec='${libname}${release}${shared_ext}$versuffix ${libname}${release}${shared_ext}$major $libname${shared_ext}'
+  soname_spec='${libname}${release}${shared_ext}$major'
+  finish_cmds='PATH="\$PATH:/sbin" ldconfig $libdir'
+  shlibpath_var=LD_LIBRARY_PATH
+  sys_lib_search_path_spec="/shlib /usr/lib /usr/X11/lib /usr/contrib/lib /lib /usr/local/lib"
+  sys_lib_dlsearch_path_spec="/shlib /usr/lib /usr/local/lib"
+  # the default ld.so.conf also contains /usr/contrib/lib and
+  # /usr/X11R6/lib (/usr/X11 is a link to /usr/X11R6), but let us allow
+  # libtool to hard-code these into programs
+  ;;
+
+cygwin* | mingw* | pw32*)
+  version_type=windows
+  shrext_cmds=".dll"
+  need_version=no
+  need_lib_prefix=no
+
+  case $GCC,$host_os in
+  yes,cygwin* | yes,mingw* | yes,pw32*)
+    library_names_spec='$libname.dll.a'
+    # DLL is installed to $(libdir)/../bin by postinstall_cmds
+    postinstall_cmds='base_file=`basename \${file}`~
+      dlpath=`$SHELL 2>&1 -c '\''. $dir/'\''\${base_file}'\''i;echo \$dlname'\''`~
+      dldir=$destdir/`dirname \$dlpath`~
+      test -d \$dldir || mkdir -p \$dldir~
+      $install_prog $dir/$dlname \$dldir/$dlname'
+    postuninstall_cmds='dldll=`$SHELL 2>&1 -c '\''. $file; echo \$dlname'\''`~
+      dlpath=$dir/\$dldll~
+       $rm \$dlpath'
+    shlibpath_overrides_runpath=yes
+
+    case $host_os in
+    cygwin*)
+      # Cygwin DLLs use 'cyg' prefix rather than 'lib'
+      soname_spec='`echo ${libname} | sed -e 's/^lib/cyg/'``echo ${release} | $SED -e 's/[[.]]/-/g'`${versuffix}${shared_ext}'
+      sys_lib_search_path_spec="/usr/lib /lib/w32api /lib /usr/local/lib"
+      ;;
+    mingw*)
+      # MinGW DLLs use traditional 'lib' prefix
+      soname_spec='${libname}`echo ${release} | $SED -e 's/[[.]]/-/g'`${versuffix}${shared_ext}'
+      sys_lib_search_path_spec=`$CC -print-search-dirs | $GREP "^libraries:" | $SED -e "s/^libraries://" -e "s,=/,/,g"`
+      if echo "$sys_lib_search_path_spec" | [$GREP ';[c-zC-Z]:/' >/dev/null]; then
+        # It is most probably a Windows format PATH printed by
+        # mingw gcc, but we are running on Cygwin. Gcc prints its search
+        # path with ; separators, and with drive letters. We can handle the
+        # drive letters (cygwin fileutils understands them), so leave them,
+        # especially as we might pass files found there to a mingw objdump,
+        # which wouldn't understand a cygwinified path. Ahh.
+        sys_lib_search_path_spec=`echo "$sys_lib_search_path_spec" | $SED -e 's/;/ /g'`
+      else
+        sys_lib_search_path_spec=`echo "$sys_lib_search_path_spec" | $SED  -e "s/$PATH_SEPARATOR/ /g"`
+      fi
+      ;;
+    pw32*)
+      # pw32 DLLs use 'pw' prefix rather than 'lib'
+      library_names_spec='`echo ${libname} | sed -e 's/^lib/pw/'``echo ${release} | $SED -e 's/[.]/-/g'`${versuffix}${shared_ext}'
+      ;;
+    esac
+    ;;
+
+  *)
+    library_names_spec='${libname}`echo ${release} | $SED -e 's/[[.]]/-/g'`${versuffix}${shared_ext} $libname.lib'
+    ;;
+  esac
+  dynamic_linker='Win32 ld.exe'
+  # FIXME: first we should search . and the directory the executable is in
+  shlibpath_var=PATH
+  ;;
+
+darwin* | rhapsody*)
+  dynamic_linker="$host_os dyld"
+  version_type=darwin
+  need_lib_prefix=no
+  need_version=no
+  library_names_spec='${libname}${release}${versuffix}$shared_ext ${libname}${release}${major}$shared_ext ${libname}$shared_ext'
+  soname_spec='${libname}${release}${major}$shared_ext'
+  shlibpath_overrides_runpath=yes
+  shlibpath_var=DYLD_LIBRARY_PATH
+  shrext_cmds='$(test .$module = .yes && echo .so || echo .dylib)'
+  # Apple's gcc prints 'gcc -print-search-dirs' doesn't operate the same.
+  if test "$GCC" = yes; then
+    sys_lib_search_path_spec=`$CC -print-search-dirs | tr "\n" "$PATH_SEPARATOR" | sed -e 's/libraries:/@libraries:/' | tr "@" "\n" | $GREP "^libraries:" | sed -e "s/^libraries://" -e "s,=/,/,g" -e "s,$PATH_SEPARATOR, ,g" -e "s,.*,& /lib /usr/lib /usr/local/lib,g"`
+  else
+    sys_lib_search_path_spec='/lib /usr/lib /usr/local/lib'
+  fi
+  sys_lib_dlsearch_path_spec='/usr/local/lib /lib /usr/lib'
+  ;;
+
+dgux*)
+  version_type=linux
+  need_lib_prefix=no
+  need_version=no
+  library_names_spec='${libname}${release}${shared_ext}$versuffix ${libname}${release}${shared_ext}$major $libname$shared_ext'
+  soname_spec='${libname}${release}${shared_ext}$major'
+  shlibpath_var=LD_LIBRARY_PATH
+  ;;
+
+freebsd1*)
+  dynamic_linker=no
+  ;;
+
+kfreebsd*-gnu)
+  version_type=linux
+  need_lib_prefix=no
+  need_version=no
+  library_names_spec='${libname}${release}${shared_ext}$versuffix ${libname}${release}${shared_ext}$major ${libname}${shared_ext}'
+  soname_spec='${libname}${release}${shared_ext}$major'
+  shlibpath_var=LD_LIBRARY_PATH
+  shlibpath_overrides_runpath=no
+  hardcode_into_libs=yes
+  dynamic_linker='GNU ld.so'
+  ;;
+
+freebsd*)
+  objformat=`test -x /usr/bin/objformat && /usr/bin/objformat || echo aout`
+  version_type=freebsd-$objformat
+  case $version_type in
+    freebsd-elf*)
+      library_names_spec='${libname}${release}${shared_ext}$versuffix ${libname}${release}${shared_ext} $libname${shared_ext}'
+      need_version=no
+      need_lib_prefix=no
+      ;;
+    freebsd-*)
+      library_names_spec='${libname}${release}${shared_ext}$versuffix $libname${shared_ext}$versuffix'
+      need_version=yes
+      ;;
+  esac
+  shlibpath_var=LD_LIBRARY_PATH
+  case $host_os in
+  freebsd2*)
+    shlibpath_overrides_runpath=yes
+    ;;
+  freebsd3.[01]* | freebsdelf3.[01]*)
+    shlibpath_overrides_runpath=yes
+    hardcode_into_libs=yes
+    ;;
+  *) # from 3.2 on
+    shlibpath_overrides_runpath=no
+    hardcode_into_libs=yes
+    ;;
+  esac
+  ;;
+
+gnu*)
+  version_type=linux
+  need_lib_prefix=no
+  need_version=no
+  library_names_spec='${libname}${release}${shared_ext}$versuffix ${libname}${release}${shared_ext}${major} ${libname}${shared_ext}'
+  soname_spec='${libname}${release}${shared_ext}$major'
+  shlibpath_var=LD_LIBRARY_PATH
+  hardcode_into_libs=yes
+  ;;
+
+hpux9* | hpux10* | hpux11*)
+  # Give a soname corresponding to the major version so that dld.sl refuses to
+  # link against other versions.
+  version_type=sunos
+  need_lib_prefix=no
+  need_version=no
+  case "$host_cpu" in
+  ia64*)
+    shrext_cmds='.so'
+    hardcode_into_libs=yes
+    dynamic_linker="$host_os dld.so"
+    shlibpath_var=LD_LIBRARY_PATH
+    shlibpath_overrides_runpath=yes # Unless +noenvvar is specified.
+    library_names_spec='${libname}${release}${shared_ext}$versuffix ${libname}${release}${shared_ext}$major $libname${shared_ext}'
+    soname_spec='${libname}${release}${shared_ext}$major'
+    if test "X$HPUX_IA64_MODE" = X32; then
+      sys_lib_search_path_spec="/usr/lib/hpux32 /usr/local/lib/hpux32 /usr/local/lib"
+    else
+      sys_lib_search_path_spec="/usr/lib/hpux64 /usr/local/lib/hpux64"
+    fi
+    sys_lib_dlsearch_path_spec=$sys_lib_search_path_spec
+    ;;
+   hppa*64*)
+     shrext_cmds='.sl'
+     hardcode_into_libs=yes
+     dynamic_linker="$host_os dld.sl"
+     shlibpath_var=LD_LIBRARY_PATH # How should we handle SHLIB_PATH
+     shlibpath_overrides_runpath=yes # Unless +noenvvar is specified.
+     library_names_spec='${libname}${release}${shared_ext}$versuffix ${libname}${release}${shared_ext}$major $libname${shared_ext}'
+     soname_spec='${libname}${release}${shared_ext}$major'
+     sys_lib_search_path_spec="/usr/lib/pa20_64 /usr/ccs/lib/pa20_64"
+     sys_lib_dlsearch_path_spec=$sys_lib_search_path_spec
+     ;;
+   *)
+    shrext_cmds='.sl'
+    dynamic_linker="$host_os dld.sl"
+    shlibpath_var=SHLIB_PATH
+    shlibpath_overrides_runpath=no # +s is required to enable SHLIB_PATH
+    library_names_spec='${libname}${release}${shared_ext}$versuffix ${libname}${release}${shared_ext}$major $libname${shared_ext}'
+    soname_spec='${libname}${release}${shared_ext}$major'
+    ;;
+  esac
+  # HP-UX runs *really* slowly unless shared libraries are mode 555.
+  postinstall_cmds='chmod 555 $lib'
+  ;;
+
+irix5* | irix6* | nonstopux*)
+  case $host_os in
+    nonstopux*) version_type=nonstopux ;;
+    *)
+	if test "$lt_cv_prog_gnu_ld" = yes; then
+		version_type=linux
+	else
+		version_type=irix
+	fi ;;
+  esac
+  need_lib_prefix=no
+  need_version=no
+  soname_spec='${libname}${release}${shared_ext}$major'
+  library_names_spec='${libname}${release}${shared_ext}$versuffix ${libname}${release}${shared_ext}$major ${libname}${release}${shared_ext} $libname${shared_ext}'
+  case $host_os in
+  irix5* | nonstopux*)
+    libsuff= shlibsuff=
+    ;;
+  *)
+    case $LD in # libtool.m4 will add one of these switches to LD
+    *-32|*"-32 "|*-melf32bsmip|*"-melf32bsmip ")
+      libsuff= shlibsuff= libmagic=32-bit;;
+    *-n32|*"-n32 "|*-melf32bmipn32|*"-melf32bmipn32 ")
+      libsuff=32 shlibsuff=N32 libmagic=N32;;
+    *-64|*"-64 "|*-melf64bmip|*"-melf64bmip ")
+      libsuff=64 shlibsuff=64 libmagic=64-bit;;
+    *) libsuff= shlibsuff= libmagic=never-match;;
+    esac
+    ;;
+  esac
+  shlibpath_var=LD_LIBRARY${shlibsuff}_PATH
+  shlibpath_overrides_runpath=no
+  sys_lib_search_path_spec="/usr/lib${libsuff} /lib${libsuff} /usr/local/lib${libsuff}"
+  sys_lib_dlsearch_path_spec="/usr/lib${libsuff} /lib${libsuff}"
+  hardcode_into_libs=yes
+  ;;
+
+# No shared lib support for Linux oldld, aout, or coff.
+linux*oldld* | linux*aout* | linux*coff*)
+  dynamic_linker=no
+  ;;
+
+# This must be Linux ELF.
+linux*)
+  version_type=linux
+  need_lib_prefix=no
+  need_version=no
+  library_names_spec='${libname}${release}${shared_ext}$versuffix ${libname}${release}${shared_ext}$major $libname${shared_ext}'
+  soname_spec='${libname}${release}${shared_ext}$major'
+  finish_cmds='PATH="\$PATH:/sbin" ldconfig -n $libdir'
+  shlibpath_var=LD_LIBRARY_PATH
+  shlibpath_overrides_runpath=no
+  # This implies no fast_install, which is unacceptable.
+  # Some rework will be needed to allow for fast_install
+  # before this can be enabled.
+  hardcode_into_libs=yes
+
+  # Append ld.so.conf contents to the search path
+  if test -f /etc/ld.so.conf; then
+    lt_ld_extra=`$SED -e 's/[:,\t]/ /g;s/=[^=]*$//;s/=[^= ]* / /g' /etc/ld.so.conf | tr '\n' ' '`
+    sys_lib_dlsearch_path_spec="/lib /usr/lib $lt_ld_extra"
+  fi
+
+  # We used to test for /lib/ld.so.1 and disable shared libraries on
+  # powerpc, because MkLinux only supported shared libraries with the
+  # GNU dynamic linker.  Since this was broken with cross compilers,
+  # most powerpc-linux boxes support dynamic linking these days and
+  # people can always --disable-shared, the test was removed, and we
+  # assume the GNU/Linux dynamic linker is in use.
+  dynamic_linker='GNU/Linux ld.so'
+  ;;
+
+knetbsd*-gnu)
+  version_type=linux
+  need_lib_prefix=no
+  need_version=no
+  library_names_spec='${libname}${release}${shared_ext}$versuffix ${libname}${release}${shared_ext}$major ${libname}${shared_ext}'
+  soname_spec='${libname}${release}${shared_ext}$major'
+  shlibpath_var=LD_LIBRARY_PATH
+  shlibpath_overrides_runpath=no
+  hardcode_into_libs=yes
+  dynamic_linker='GNU ld.so'
+  ;;
+
+netbsd*)
+  version_type=sunos
+  need_lib_prefix=no
+  need_version=no
+  if echo __ELF__ | $CC -E - | $GREP __ELF__ >/dev/null; then
+    library_names_spec='${libname}${release}${shared_ext}$versuffix ${libname}${shared_ext}$versuffix'
+    finish_cmds='PATH="\$PATH:/sbin" ldconfig -m $libdir'
+    dynamic_linker='NetBSD (a.out) ld.so'
+  else
+    library_names_spec='${libname}${release}${shared_ext}$versuffix ${libname}${release}${shared_ext}$major ${libname}${shared_ext}'
+    soname_spec='${libname}${release}${shared_ext}$major'
+    dynamic_linker='NetBSD ld.elf_so'
+  fi
+  shlibpath_var=LD_LIBRARY_PATH
+  shlibpath_overrides_runpath=yes
+  hardcode_into_libs=yes
+  ;;
+
+newsos6)
+  version_type=linux
+  library_names_spec='${libname}${release}${shared_ext}$versuffix ${libname}${release}${shared_ext}$major $libname${shared_ext}'
+  shlibpath_var=LD_LIBRARY_PATH
+  shlibpath_overrides_runpath=yes
+  ;;
+
+nto-qnx*)
+  version_type=linux
+  need_lib_prefix=no
+  need_version=no
+  library_names_spec='${libname}${release}${shared_ext}$versuffix ${libname}${release}${shared_ext}$major $libname${shared_ext}'
+  soname_spec='${libname}${release}${shared_ext}$major'
+  shlibpath_var=LD_LIBRARY_PATH
+  shlibpath_overrides_runpath=yes
+  ;;
+
+openbsd*)
+  version_type=sunos
+  need_lib_prefix=no
+  need_version=yes
+  library_names_spec='${libname}${release}${shared_ext}$versuffix ${libname}${shared_ext}$versuffix'
+  finish_cmds='PATH="\$PATH:/sbin" ldconfig -m $libdir'
+  shlibpath_var=LD_LIBRARY_PATH
+  if test -z "`echo __ELF__ | $CC -E - | $GREP __ELF__`" || test "$host_os-$host_cpu" = "openbsd2.8-powerpc"; then
+    case $host_os in
+      openbsd2.[[89]] | openbsd2.[[89]].*)
+	shlibpath_overrides_runpath=no
+	;;
+      *)
+	shlibpath_overrides_runpath=yes
+	;;
+      esac
+  else
+    shlibpath_overrides_runpath=yes
+  fi
+  ;;
+
+os2*)
+  libname_spec='$name'
+  shrext_cmds=".dll"
+  need_lib_prefix=no
+  library_names_spec='$libname${shared_ext} $libname.a'
+  dynamic_linker='OS/2 ld.exe'
+  shlibpath_var=LIBPATH
+  ;;
+
+osf3* | osf4* | osf5*)
+  version_type=osf
+  need_lib_prefix=no
+  need_version=no
+  soname_spec='${libname}${release}${shared_ext}$major'
+  library_names_spec='${libname}${release}${shared_ext}$versuffix ${libname}${release}${shared_ext}$major $libname${shared_ext}'
+  shlibpath_var=LD_LIBRARY_PATH
+  sys_lib_search_path_spec="/usr/shlib /usr/ccs/lib /usr/lib/cmplrs/cc /usr/lib /usr/local/lib /var/shlib"
+  sys_lib_dlsearch_path_spec="$sys_lib_search_path_spec"
+  ;;
+
+sco3.2v5*)
+  version_type=osf
+  soname_spec='${libname}${release}${shared_ext}$major'
+  library_names_spec='${libname}${release}${shared_ext}$versuffix ${libname}${release}${shared_ext}$major $libname${shared_ext}'
+  shlibpath_var=LD_LIBRARY_PATH
+  ;;
+
+solaris*)
+  version_type=linux
+  need_lib_prefix=no
+  need_version=no
+  library_names_spec='${libname}${release}${shared_ext}$versuffix ${libname}${release}${shared_ext}$major $libname${shared_ext}'
+  soname_spec='${libname}${release}${shared_ext}$major'
+  shlibpath_var=LD_LIBRARY_PATH
+  shlibpath_overrides_runpath=yes
+  hardcode_into_libs=yes
+  # ldd complains unless libraries are executable
+  postinstall_cmds='chmod +x $lib'
+  ;;
+
+sunos4*)
+  version_type=sunos
+  library_names_spec='${libname}${release}${shared_ext}$versuffix ${libname}${shared_ext}$versuffix'
+  finish_cmds='PATH="\$PATH:/usr/etc" ldconfig $libdir'
+  shlibpath_var=LD_LIBRARY_PATH
+  shlibpath_overrides_runpath=yes
+  if test "$with_gnu_ld" = yes; then
+    need_lib_prefix=no
+  fi
+  need_version=yes
+  ;;
+
+sysv4 | sysv4.2uw2* | sysv4.3* | sysv5*)
+  version_type=linux
+  library_names_spec='${libname}${release}${shared_ext}$versuffix ${libname}${release}${shared_ext}$major $libname${shared_ext}'
+  soname_spec='${libname}${release}${shared_ext}$major'
+  shlibpath_var=LD_LIBRARY_PATH
+  case $host_vendor in
+    sni)
+      shlibpath_overrides_runpath=no
+      need_lib_prefix=no
+      runpath_var=LD_RUN_PATH
+      ;;
+    siemens)
+      need_lib_prefix=no
+      ;;
+    motorola)
+      need_lib_prefix=no
+      need_version=no
+      shlibpath_overrides_runpath=no
+      sys_lib_search_path_spec='/lib /usr/lib /usr/ccs/lib'
+      ;;
+  esac
+  ;;
+
+sysv4*MP*)
+  if test -d /usr/nec ;then
+    version_type=linux
+    library_names_spec='$libname${shared_ext}.$versuffix $libname${shared_ext}.$major $libname${shared_ext}'
+    soname_spec='$libname${shared_ext}.$major'
+    shlibpath_var=LD_LIBRARY_PATH
+  fi
+  ;;
+
+uts4*)
+  version_type=linux
+  library_names_spec='${libname}${release}${shared_ext}$versuffix ${libname}${release}${shared_ext}$major $libname${shared_ext}'
+  soname_spec='${libname}${release}${shared_ext}$major'
+  shlibpath_var=LD_LIBRARY_PATH
+  ;;
+
+*)
+  dynamic_linker=no
+  ;;
+esac
+AC_MSG_RESULT([$dynamic_linker])
+test "$dynamic_linker" = no && can_build_shared=no
+_LT_DECL([], [need_lib_prefix], [0],
+    [Do we need the "lib" prefix for modules?])
+_LT_DECL([], [need_version], [0], [Do we need a version for libraries?])
+_LT_DECL([], [version_type], [0], [Library versioning type])
+_LT_DECL([], [runpath_var], [0],  [Shared library runtime path variable])
+_LT_DECL([], [shlibpath_var], [0],[Shared library path variable])
+_LT_DECL([], [shlibpath_overrides_runpath], [0],
+    [Is shibpath searched before the hard-coded library search path?])
+_LT_DECL([], [libname_spec], [1], [Format of library name prefix])
+_LT_DECL([], [library_names_spec], [1],
+    [List of archive names.  First name is the real one, the rest are links.
+    The last name is the one that the linker finds with -lNAME])
+_LT_DECL([], [soname_spec], [1],
+    [The coded name of the library, if different from the real name])
+_LT_DECL([], [postinstall_cmds], [2],
+    [Command to use after installation of a shared archive])
+_LT_DECL([], [postuninstall_cmds], [2],
+    [Command to use after uninstallation of a shared archive])
+_LT_DECL([], [finish_cmds], [2],
+    [Commands used to finish a libtool library installation in a directory])
+_LT_DECL([], [finish_eval], [1],
+    [As "finish_cmds", except a single script fragment to be evaled but
+    not shown])
+_LT_DECL([], [hardcode_into_libs], [0],
+    [Whether we should hardcode library paths into libraries])
+_LT_DECL([], [sys_lib_search_path_spec], [2],
+    [Compile-time system search path for libraries])
+_LT_DECL([], [sys_lib_dlsearch_path_spec], [2],
+    [Run-time system search path for libraries])
+])# AC_LIBTOOL_SYS_DYNAMIC_LINKER
+
+
+# AC_PATH_TOOL_PREFIX
+# -------------------
+# find a file program which can recognise shared library
+AC_DEFUN([AC_PATH_TOOL_PREFIX],
+[AC_REQUIRE([LT_AC_PROG_EGREP])dnl
+AC_MSG_CHECKING([for $1])
+AC_CACHE_VAL(lt_cv_path_MAGIC_CMD,
+[case $MAGIC_CMD in
+[[\\/*] |  ?:[\\/]*])
+  lt_cv_path_MAGIC_CMD="$MAGIC_CMD" # Let the user override the test with a path.
+  ;;
+*)
+  lt_save_MAGIC_CMD="$MAGIC_CMD"
+  lt_save_ifs="$IFS"; IFS=$PATH_SEPARATOR
+dnl $ac_dummy forces splitting on constant user-supplied paths.
+dnl POSIX.2 word splitting is done only on the output of word expansions,
+dnl not every word.  This closes a longstanding sh security hole.
+  ac_dummy="m4_if([$2], , $PATH, [$2])"
+  for ac_dir in $ac_dummy; do
+    IFS="$lt_save_ifs"
+    test -z "$ac_dir" && ac_dir=.
+    if test -f $ac_dir/$1; then
+      lt_cv_path_MAGIC_CMD="$ac_dir/$1"
+      if test -n "$file_magic_test_file"; then
+	case $deplibs_check_method in
+	"file_magic "*)
+	  file_magic_regex="`expr \"$deplibs_check_method\" : \"file_magic \(.*\)\"`"
+	  MAGIC_CMD="$lt_cv_path_MAGIC_CMD"
+	  if eval $file_magic_cmd \$file_magic_test_file 2> /dev/null |
+	    $EGREP "$file_magic_regex" > /dev/null; then
+	    :
+	  else
+	    cat <<_LT_EOF 1>&2
+
+*** Warning: the command libtool uses to detect shared libraries,
+*** $file_magic_cmd, produces output that libtool cannot recognize.
+*** The result is that libtool may fail to recognize shared libraries
+*** as such.  This will affect the creation of libtool libraries that
+*** depend on shared libraries, but programs linked with such libtool
+*** libraries will work regardless of this problem.  Nevertheless, you
+*** may want to report the problem to your system manager and/or to
+*** bug-libtool@gnu.org
+
+_LT_EOF
+	  fi ;;
+	esac
+      fi
+      break
+    fi
+  done
+  IFS="$lt_save_ifs"
+  MAGIC_CMD="$lt_save_MAGIC_CMD"
+  ;;
+esac])
+MAGIC_CMD="$lt_cv_path_MAGIC_CMD"
+if test -n "$MAGIC_CMD"; then
+  AC_MSG_RESULT($MAGIC_CMD)
+else
+  AC_MSG_RESULT(no)
+fi
+_LT_DECL([], [MAGIC_CMD], [0],
+	 [Used to examine libraries when file_magic_cmd begins "file"])dnl
+])# AC_PATH_TOOL_PREFIX
+
+
+# AC_PATH_MAGIC
+# -------------
+# find a file program which can recognise a shared library
+AC_DEFUN([AC_PATH_MAGIC],
+[AC_PATH_TOOL_PREFIX(${ac_tool_prefix}file, /usr/bin$PATH_SEPARATOR$PATH)
+if test -z "$lt_cv_path_MAGIC_CMD"; then
+  if test -n "$ac_tool_prefix"; then
+    AC_PATH_TOOL_PREFIX(file, /usr/bin$PATH_SEPARATOR$PATH)
+  else
+    MAGIC_CMD=:
+  fi
+fi
+])# AC_PATH_MAGIC
+
+
+# AC_PROG_LD
+# ----------
+# find the pathname to the GNU or non-GNU linker
+AC_DEFUN([AC_PROG_LD],
+[AC_ARG_WITH([gnu-ld],
+    [AC_HELP_STRING([--with-gnu-ld],
+	[assume the C compiler uses GNU ld @<:@default=no@:>@])],
+    [test "$withval" = no || with_gnu_ld=yes],
+    [with_gnu_ld=no])
+AC_REQUIRE([LT_AC_PROG_SED])dnl
+AC_REQUIRE([LT_AC_PROG_EGREP])dnl
+AC_REQUIRE([AC_PROG_CC])dnl
+AC_REQUIRE([AC_CANONICAL_HOST])dnl
+AC_REQUIRE([AC_CANONICAL_BUILD])dnl
+
+ac_prog=ld
+if test "$GCC" = yes; then
+  # Check if gcc -print-prog-name=ld gives a path.
+  AC_MSG_CHECKING([for ld used by $CC])
+  case $host in
+  *-*-mingw*)
+    # gcc leaves a trailing carriage return which upsets mingw
+    ac_prog=`($CC -print-prog-name=ld) 2>&5 | tr -d '\015'` ;;
+  *)
+    ac_prog=`($CC -print-prog-name=ld) 2>&5` ;;
+  esac
+  case $ac_prog in
+    # Accept absolute paths.
+    [[\\/]]* | ?:[[\\/]]*)
+      re_direlt='/[[^/]][[^/]]*/\.\./'
+      # Canonicalize the pathname of ld
+      ac_prog=`echo $ac_prog| $SED 's%\\\\%/%g'`
+      while echo $ac_prog | $GREP "$re_direlt" > /dev/null 2>&1; do
+	ac_prog=`echo $ac_prog| $SED "s%$re_direlt%/%"`
+      done
+      test -z "$LD" && LD="$ac_prog"
+      ;;
+  "")
+    # If it fails, then pretend we aren't using GCC.
+    ac_prog=ld
+    ;;
+  *)
+    # If it is relative, then search for the first ld in PATH.
+    with_gnu_ld=unknown
+    ;;
+  esac
+elif test "$with_gnu_ld" = yes; then
+  AC_MSG_CHECKING([for GNU ld])
+else
+  AC_MSG_CHECKING([for non-GNU ld])
+fi
+AC_CACHE_VAL(lt_cv_path_LD,
+[if test -z "$LD"; then
+  lt_save_ifs="$IFS"; IFS=$PATH_SEPARATOR
+  for ac_dir in $PATH; do
+    IFS="$lt_save_ifs"
+    test -z "$ac_dir" && ac_dir=.
+    if test -f "$ac_dir/$ac_prog" || test -f "$ac_dir/$ac_prog$ac_exeext"; then
+      lt_cv_path_LD="$ac_dir/$ac_prog"
+      # Check to see if the program is GNU ld.  I'd rather use --version,
+      # but apparently some GNU ld's only accept -v.
+      # Break only if it was the GNU/non-GNU ld that we prefer.
+      case `"$lt_cv_path_LD" -v 2>&1 </dev/null` in
+      *GNU* | *'with BFD'*)
+	test "$with_gnu_ld" != no && break
+	;;
+      *)
+	test "$with_gnu_ld" != yes && break
+	;;
+      esac
+    fi
+  done
+  IFS="$lt_save_ifs"
+else
+  lt_cv_path_LD="$LD" # Let the user override the test with a path.
+fi])
+LD="$lt_cv_path_LD"
+if test -n "$LD"; then
+  AC_MSG_RESULT($LD)
+else
+  AC_MSG_RESULT(no)
+fi
+test -z "$LD" && AC_MSG_ERROR([no acceptable ld found in \$PATH])
+AC_PROG_LD_GNU
+AC_SUBST([LD])
+
+_LT_TAGDECL([], [LD], [1], [The linker used to build libraries])
+])# AC_PROG_LD
+
+# Old name:
+AU_DEFUN([AM_PROG_LD], [AC_PROG_LD])
+
+
+# AC_PROG_LD_GNU
+# --------------
+AC_DEFUN([AC_PROG_LD_GNU],
+[AC_CACHE_CHECK([if the linker ($LD) is GNU ld], lt_cv_prog_gnu_ld,
+[# I'd rather use --version here, but apparently some GNU ld's only accept -v.
+case `$LD -v 2>&1 </dev/null` in
+*GNU* | *'with BFD'*)
+  lt_cv_prog_gnu_ld=yes
+  ;;
+*)
+  lt_cv_prog_gnu_ld=no
+  ;;
+esac])
+with_gnu_ld=$lt_cv_prog_gnu_ld
+])# AC_PROG_LD_GNU
+
+
+# AC_PROG_LD_RELOAD_FLAG
+# ----------------------
+# find reload flag for linker
+#   -- PORTME Some linkers may need a different reload flag.
+AC_DEFUN([AC_PROG_LD_RELOAD_FLAG],
+[AC_CACHE_CHECK([for $LD option to reload object files],
+  lt_cv_ld_reload_flag,
+  [lt_cv_ld_reload_flag='-r'])
+reload_flag=$lt_cv_ld_reload_flag
+case $reload_flag in
+"" | " "*) ;;
+*) reload_flag=" $reload_flag" ;;
+esac
+reload_cmds='$LD$reload_flag -o $output$reload_objs'
+case $host_os in
+  darwin*)
+    if test "$GCC" = yes; then
+      reload_cmds='$CC -nostdlib ${wl}-r -o $output$reload_objs'
+    else
+      reload_cmds='$LD$reload_flag -o $output$reload_objs'   
+    fi
+    ;;
+esac
+_LT_DECL([], [reload_flag], [1], [How to create reloadable object files])dnl
+_LT_DECL([], [reload_cmds], [2])dnl
+])# AC_PROG_LD_RELOAD_FLAG
+
+
+# AC_DEPLIBS_CHECK_METHOD
+# -----------------------
+# how to check for library dependencies
+#  -- PORTME fill in with the dynamic library characteristics
+AC_DEFUN([AC_DEPLIBS_CHECK_METHOD],
+[AC_REQUIRE([LT_AC_PROG_EGREP])
+AC_CACHE_CHECK([how to recognise dependent libraries],
+lt_cv_deplibs_check_method,
+[lt_cv_file_magic_cmd='$MAGIC_CMD'
+lt_cv_file_magic_test_file=
+lt_cv_deplibs_check_method='unknown'
+# Need to set the preceding variable on all platforms that support
+# interlibrary dependencies.
+# 'none' -- dependencies not supported.
+# `unknown' -- same as none, but documents that we really don't know.
+# 'pass_all' -- all dependencies passed with no checks.
+# 'test_compile' -- check by making test program.
+# 'file_magic [[regex]]' -- check by looking for files in library path
+# which responds to the $file_magic_cmd with a given extended regex.
+# If you have `file' or equivalent on your system and you're not sure
+# whether `pass_all' will *always* work, you probably want this one.
+
+case $host_os in
+aix4* | aix5*)
+  lt_cv_deplibs_check_method=pass_all
+  ;;
+
+beos*)
+  lt_cv_deplibs_check_method=pass_all
+  ;;
+
+bsdi4*)
+  lt_cv_deplibs_check_method='file_magic ELF [[0-9]][[0-9]]*-bit [[ML]]SB (shared object|dynamic lib)'
+  lt_cv_file_magic_cmd='/usr/bin/file -L'
+  lt_cv_file_magic_test_file=/shlib/libc.so
+  ;;
+
+cygwin*)
+  # func_win32_libid is a shell function defined in ltmain.sh
+  lt_cv_deplibs_check_method='file_magic ^x86 archive import|^x86 DLL'
+  lt_cv_file_magic_cmd='func_win32_libid'
+  ;;
+
+  # Base MSYS/MinGW do not provide the 'file' command needed by
+  # func_win32_libid shell function, so use a weaker test based on 'objdump'.
+mingw* | pw32*)
+  lt_cv_deplibs_check_method='file_magic file format pei*-i386(.*architecture: i386)?'
+  lt_cv_file_magic_cmd='$OBJDUMP -f'
+  ;;
+
+darwin* | rhapsody*)
+  lt_cv_deplibs_check_method=pass_all
+  ;;
+
+freebsd* | kfreebsd*-gnu)
+  if echo __ELF__ | $CC -E - | $GREP __ELF__ > /dev/null; then
+    case $host_cpu in
+    i*86 )
+      # Not sure whether the presence of OpenBSD here was a mistake.
+      # Let's accept both of them until this is cleared up.
+      lt_cv_deplibs_check_method='file_magic (FreeBSD|OpenBSD)/i[[3-9]]86 (compact )?demand paged shared library'
+      lt_cv_file_magic_cmd=/usr/bin/file
+      lt_cv_file_magic_test_file=`echo /usr/lib/libc.so.*`
+      ;;
+    esac
+  else
+    lt_cv_deplibs_check_method=pass_all
+  fi
+  ;;
+
+gnu*)
+  lt_cv_deplibs_check_method=pass_all
+  ;;
+
+hpux10.20* | hpux11*)
+  lt_cv_file_magic_cmd=/usr/bin/file
+  case "$host_cpu" in
+  ia64*)
+    lt_cv_deplibs_check_method='file_magic (s[[0-9]][[0-9]][[0-9]]|ELF-[[0-9]][[0-9]]) shared object file - IA64'
+    lt_cv_file_magic_test_file=/usr/lib/hpux32/libc.so
+    ;;
+  hppa*64*)
+    [lt_cv_deplibs_check_method='file_magic (s[0-9][0-9][0-9]|ELF-[0-9][0-9]) shared object file - PA-RISC [0-9].[0-9]']
+    lt_cv_file_magic_test_file=/usr/lib/pa20_64/libc.sl
+    ;;
+  *)
+    lt_cv_deplibs_check_method='file_magic (s[[0-9]][[0-9]][[0-9]]|PA-RISC[[0-9]].[[0-9]]) shared library'
+    lt_cv_file_magic_test_file=/usr/lib/libc.sl
+    ;;
+  esac
+  ;;
+
+irix5* | irix6* | nonstopux*)
+  case $LD in
+  *-32|*"-32 ") libmagic=32-bit;;
+  *-n32|*"-n32 ") libmagic=N32;;
+  *-64|*"-64 ") libmagic=64-bit;;
+  *) libmagic=never-match;;
+  esac
+  lt_cv_deplibs_check_method=pass_all
+  ;;
+
+# This must be Linux ELF.
+linux*)
+  case $host_cpu in
+  alpha*|hppa*|i*86|ia64*|m68*|mips*|powerpc*|sparc*|s390*|sh*)
+    lt_cv_deplibs_check_method=pass_all ;;
+  *)
+    # glibc up to 2.1.1 does not perform some relocations on ARM
+    # this will be overridden with pass_all, but let us keep it just in case
+    lt_cv_deplibs_check_method='file_magic ELF [[0-9]][[0-9]]*-bit [[LM]]SB (shared object|dynamic lib )' ;;
+  esac
+  lt_cv_file_magic_test_file=`echo /lib/libc.so* /lib/libc-*.so`
+  lt_cv_deplibs_check_method=pass_all
+  ;;
+
+netbsd* | knetbsd*-gnu)
+  if echo __ELF__ | $CC -E - | $GREP __ELF__ > /dev/null; then
+    lt_cv_deplibs_check_method='match_pattern /lib[[^/]]+(\.so\.[[0-9]]+\.[[0-9]]+|_pic\.a)$'
+  else
+    lt_cv_deplibs_check_method='match_pattern /lib[[^/]]+(\.so|_pic\.a)$'
+  fi
+  ;;
+
+newos6*)
+  lt_cv_deplibs_check_method='file_magic ELF [[0-9]][[0-9]]*-bit [[ML]]SB (executable|dynamic lib)'
+  lt_cv_file_magic_cmd=/usr/bin/file
+  lt_cv_file_magic_test_file=/usr/lib/libnls.so
+  ;;
+
+nto-qnx*)
+  lt_cv_deplibs_check_method=unknown
+  ;;
+
+openbsd*)
+  lt_cv_file_magic_cmd=/usr/bin/file
+  lt_cv_file_magic_test_file=`echo /usr/lib/libc.so.*`
+  if test -z "`echo __ELF__ | $CC -E - | $GREP __ELF__`" || test "$host_os-$host_cpu" = "openbsd2.8-powerpc"; then
+    lt_cv_deplibs_check_method='file_magic ELF [[0-9]][[0-9]]*-bit [[LM]]SB shared object'
+  else
+    lt_cv_deplibs_check_method='file_magic OpenBSD.* shared library'
+  fi
+  ;;
+
+osf3* | osf4* | osf5*)
+  lt_cv_deplibs_check_method=pass_all
+  ;;
+
+sco3.2v5*)
+  lt_cv_deplibs_check_method=pass_all
+  ;;
+
+solaris*)
+  lt_cv_deplibs_check_method=pass_all
+  ;;
+
+sysv4 | sysv4.2uw2* | sysv4.3* | sysv5*)
+  case $host_vendor in
+  motorola)
+    lt_cv_deplibs_check_method='file_magic ELF [[0-9]][[0-9]]*-bit [[ML]]SB (shared object|dynamic lib) M[[0-9]][[0-9]]* Version [[0-9]]'
+    lt_cv_file_magic_test_file=`echo /usr/lib/libc.so*`
+    ;;
+  ncr)
+    lt_cv_deplibs_check_method=pass_all
+    ;;
+  sequent)
+    lt_cv_file_magic_cmd='/bin/file'
+    lt_cv_deplibs_check_method='file_magic ELF [[0-9]][[0-9]]*-bit [[LM]]SB (shared object|dynamic lib )'
+    ;;
+  sni)
+    lt_cv_file_magic_cmd='/bin/file'
+    lt_cv_deplibs_check_method="file_magic ELF [[0-9]][[0-9]]*-bit [[LM]]SB dynamic lib"
+    lt_cv_file_magic_test_file=/lib/libc.so
+    ;;
+  siemens)
+    lt_cv_deplibs_check_method=pass_all
+    ;;
+  esac
+  ;;
+
+sysv5OpenUNIX8* | sysv5UnixWare7* | sysv5uw[[78]]* | unixware7* | sysv4*uw2*)
+  lt_cv_deplibs_check_method=pass_all
+  ;;
+esac
+])
+file_magic_cmd=$lt_cv_file_magic_cmd
+deplibs_check_method=$lt_cv_deplibs_check_method
+test -z "$deplibs_check_method" && deplibs_check_method=unknown
+
+_LT_DECL([], [deplibs_check_method], [1],
+    [Method to check whether dependent libraries are shared objects])
+_LT_DECL([], [file_magic_cmd], [1],
+    [Command to use when deplibs_check_method == "file_magic"])
+])# AC_DEPLIBS_CHECK_METHOD
+
+
+# AC_PROG_NM
+# ----------
+# find the pathname to a BSD-compatible name lister
+AC_DEFUN([AC_PROG_NM],
+[AC_CACHE_CHECK([for BSD-compatible nm], lt_cv_path_NM,
+[if test -n "$NM"; then
+  # Let the user override the test.
+  lt_cv_path_NM="$NM"
+else
+  lt_save_ifs="$IFS"; IFS=$PATH_SEPARATOR
+  for ac_dir in $PATH /usr/ccs/bin /usr/ucb /bin; do
+    IFS="$lt_save_ifs"
+    test -z "$ac_dir" && ac_dir=.
+    tmp_nm="$ac_dir/${ac_tool_prefix}nm"
+    if test -f "$tmp_nm" || test -f "$tmp_nm$ac_exeext" ; then
+      # Check to see if the nm accepts a BSD-compat flag.
+      # Adding the `sed 1q' prevents false positives on HP-UX, which says:
+      #   nm: unknown option "B" ignored
+      # Tru64's nm complains that /dev/null is an invalid object file
+      case `"$tmp_nm" -B /dev/null 2>&1 | sed '1q'` in
+      */dev/null* | *'Invalid file or object type'*)
+	lt_cv_path_NM="$tmp_nm -B"
+	break
+        ;;
+      *)
+	case `"$tmp_nm" -p /dev/null 2>&1 | sed '1q'` in
+	*/dev/null*)
+	  lt_cv_path_NM="$tmp_nm -p"
+	  break
+	  ;;
+	*)
+	  lt_cv_path_NM=${lt_cv_path_NM="$tmp_nm"} # keep the first match, but
+	  continue # so that we can try to find one that supports BSD flags
+	  ;;
+	esac
+      esac
+    fi
+  done
+  IFS="$lt_save_ifs"
+  test -z "$lt_cv_path_NM" && lt_cv_path_NM=nm
+fi])
+NM="$lt_cv_path_NM"
+test -z "$NM" && NM=nm
+AC_SUBST([NM])
+_LT_DECL([], [NM], [1], [A BSD-compatible nm program])dnl
+])# AC_PROG_NM
+
+# Old name:
+AU_DEFUN([AM_PROG_NM], [AC_PROG_NM])
+
+
+# AC_CHECK_LIBM
+# -------------
+# check for math library
+AC_DEFUN([AC_CHECK_LIBM],
+[AC_REQUIRE([AC_CANONICAL_HOST])dnl
+LIBM=
+case $host in
+*-*-beos* | *-*-cygwin* | *-*-pw32* | *-*-darwin*)
+  # These system don't have libm, or don't need it
+  ;;
+*-ncr-sysv4.3*)
+  AC_CHECK_LIB(mw, _mwvalidcheckl, LIBM="-lmw")
+  AC_CHECK_LIB(m, cos, LIBM="$LIBM -lm")
+  ;;
+*)
+  AC_CHECK_LIB(m, cos, LIBM="-lm")
+  ;;
+esac
+])# AC_CHECK_LIBM
+
+
+# AC_LIBLTDL_CONVENIENCE([DIRECTORY])
+# -----------------------------------
+# sets LIBLTDL to the link flags for the libltdl convenience library and
+# LTDLINCL to the include flags for the libltdl header and adds
+# --enable-ltdl-convenience to the configure arguments.  Note that LIBLTDL
+# and LTDLINCL are not AC_SUBSTed, nor is AC_CONFIG_SUBDIRS called.  If
+# DIRECTORY is not provided, it is assumed to be `libltdl'.  LIBLTDL will
+# be prefixed with '${top_builddir}/' and LTDLINCL will be prefixed with
+# '${top_srcdir}/' (note the single quotes!).  If your package is not
+# flat and you're not using automake, define top_builddir and
+# top_srcdir appropriately in the Makefiles.
+AC_DEFUN([AC_LIBLTDL_CONVENIENCE],
+[case $enable_ltdl_convenience in
+  no) AC_MSG_ERROR([this package needs a convenience libltdl]) ;;
+  "") enable_ltdl_convenience=yes
+      ac_configure_args="$ac_configure_args --enable-ltdl-convenience" ;;
+  esac
+  LIBLTDL='${top_builddir}/'m4_if($#, 1,[$1], ['libltdl'])/libltdlc.la
+  LTDLINCL='-I${top_srcdir}/'m4_if($#, 1, [$1], ['libltdl'])
+  # For backwards non-gettext consistent compatibility...
+  INCLTDL="$LTDLINCL"
+])# AC_LIBLTDL_CONVENIENCE
+
+
+# AC_LIBLTDL_INSTALLABLE([DIRECTORY])
+# -----------------------------------
+# sets LIBLTDL to the link flags for the libltdl installable library and
+# LTDLINCL to the include flags for the libltdl header and adds
+# --enable-ltdl-install to the configure arguments.  Note that LIBLTDL
+# and LTDLINCL are not AC_SUBSTed, nor is AC_CONFIG_SUBDIRS called.  If
+# DIRECTORY is not provided and an installed libltdl is not found, it is
+# assumed to be `libltdl'.  LIBLTDL will be prefixed with '${top_builddir}/'
+# and LTDLINCL will be prefixed with '${top_srcdir}/' (note the single
+# quotes!).  If your package is not flat and you're not using automake,
+# define top_builddir and top_srcdir appropriately in the Makefiles.
+# In the future, this macro may have to be called after AC_PROG_LIBTOOL.
+AC_DEFUN([AC_LIBLTDL_INSTALLABLE],
+[AC_CHECK_LIB(ltdl, lt_dlinit,
+  [test x"$enable_ltdl_install" != xyes && enable_ltdl_install=no],
+  [if test x"$enable_ltdl_install" = xno; then
+     AC_MSG_WARN([libltdl not installed, but installation disabled])
+   else
+     enable_ltdl_install=yes
+   fi
+  ])
+  if test x"$enable_ltdl_install" = x"yes"; then
+    ac_configure_args="$ac_configure_args --enable-ltdl-install"
+    LIBLTDL='${top_builddir}/'m4_if($#, 1, [$1], ['libltdl'])/libltdl.la
+    LTDLINCL='-I${top_srcdir}/'m4_if($#, 1, [$1], ['libltdl'])
+  else
+    ac_configure_args="$ac_configure_args --enable-ltdl-install=no"
+    LIBLTDL="-lltdl"
+    LTDLINCL=
+  fi
+  # For backwards non-gettext consistent compatibility...
+  INCLTDL="$LTDLINCL"
+])# AC_LIBLTDL_INSTALLABLE
+
+
+# AC_LIBTOOL_PROG_COMPILER_NO_RTTI([TAGNAME])
+# -------------------------------------------
+AC_DEFUN([AC_LIBTOOL_PROG_COMPILER_NO_RTTI],
+[AC_REQUIRE([_LT_AC_SYS_COMPILER])dnl
+
+_LT_AC_TAGVAR(lt_prog_compiler_no_builtin_flag, $1)=
+
+if test "$GCC" = yes; then
+  _LT_AC_TAGVAR(lt_prog_compiler_no_builtin_flag, $1)=' -fno-builtin'
+
+  AC_LIBTOOL_COMPILER_OPTION([if $compiler supports -fno-rtti -fno-exceptions],
+    lt_cv_prog_compiler_rtti_exceptions,
+    [-fno-rtti -fno-exceptions], [],
+    [_LT_AC_TAGVAR(lt_prog_compiler_no_builtin_flag, $1)="$_LT_AC_TAGVAR(lt_prog_compiler_no_builtin_flag, $1) -fno-rtti -fno-exceptions"])
+fi
+_LT_TAGDECL([no_builtin_flag], [lt_prog_compiler_no_builtin_flag], [1],
+	[Compiler flag to turn off builtin functions])
+])# AC_LIBTOOL_PROG_COMPILER_NO_RTTI
+
+
+# AC_LIBTOOL_SYS_GLOBAL_SYMBOL_PIPE
+# ---------------------------------
+AC_DEFUN([AC_LIBTOOL_SYS_GLOBAL_SYMBOL_PIPE],
+[AC_REQUIRE([AC_CANONICAL_HOST])dnl
+AC_REQUIRE([LT_AC_PROG_EGREP])dnl
+AC_REQUIRE([AC_PROG_CC])dnl
+AC_REQUIRE([AC_PROG_LD])dnl
+AC_REQUIRE([AC_PROG_NM])dnl
+AC_REQUIRE([AC_OBJEXT])dnl
+# Check for command to grab the raw symbol name followed by C symbol from nm.
+AC_MSG_CHECKING([command to parse $NM output from $compiler object])
+AC_CACHE_VAL([lt_cv_sys_global_symbol_pipe],
+[
+# These are sane defaults that work on at least a few old systems.
+# [They come from Ultrix.  What could be older than Ultrix?!! ;)]
+
+# Character class describing NM global symbol codes.
+symcode='[[BCDEGRST]]'
+
+# Regexp to match symbols that can be accessed directly from C.
+sympat='\([[_A-Za-z]][[_A-Za-z0-9]]*\)'
+
+# Transform the above into a raw symbol and a C symbol.
+symxfrm='\1 \2\3 \3'
+
+# Transform an extracted symbol line into a proper C declaration
+lt_cv_sys_global_symbol_to_cdecl="sed -n -e 's/^. .* \(.*\)$/extern int \1;/p'"
+
+# Transform an extracted symbol line into symbol name and symbol address
+lt_cv_sys_global_symbol_to_c_name_address="sed -n -e 's/^: \([[^ ]]*\) $/  {\\\"\1\\\", (lt_ptr) 0},/p' -e 's/^$symcode \([[^ ]]*\) \([[^ ]]*\)$/  {\"\2\", (lt_ptr) \&\2},/p'"
+
+# Define system-specific variables.
+case $host_os in
+aix*)
+  symcode='[[BCDT]]'
+  ;;
+cygwin* | mingw* | pw32*)
+  symcode='[[ABCDGISTW]]'
+  ;;
+hpux*) # Its linker distinguishes data from code symbols
+  if test "$host_cpu" = ia64; then
+    symcode='[[ABCDEGRST]]'
+  fi
+  lt_cv_sys_global_symbol_to_cdecl="sed -n -e 's/^T .* \(.*\)$/extern int \1();/p' -e 's/^$symcode* .* \(.*\)$/extern char \1;/p'"
+  lt_cv_sys_global_symbol_to_c_name_address="sed -n -e 's/^: \([[^ ]]*\) $/  {\\\"\1\\\", (lt_ptr) 0},/p' -e 's/^$symcode* \([[^ ]]*\) \([[^ ]]*\)$/  {\"\2\", (lt_ptr) \&\2},/p'"
+  ;;
+irix* | nonstopux*)
+  symcode='[[BCDEGRST]]'
+  ;;
+osf*)
+  symcode='[[BCDEGQRST]]'
+  ;;
+solaris* | sysv5*)
+  symcode='[[BDRT]]'
+  ;;
+sysv4)
+  symcode='[[DFNSTU]]'
+  ;;
+esac
+
+# Handle CRLF in mingw tool chain
+opt_cr=
+case $build_os in
+mingw*)
+  opt_cr=`echo 'x\{0,1\}' | tr x '\015'` # option cr in regexp
+  ;;
+esac
+
+# If we're using GNU nm, then use its standard symbol codes.
+case `$NM -V 2>&1` in
+*GNU* | *'with BFD'*)
+  symcode='[[ABCDGIRSTW]]' ;;
+esac
+
+# Try without a prefix undercore, then with it.
+for ac_symprfx in "" "_"; do
+
+  # Write the raw and C identifiers.
+  lt_cv_sys_global_symbol_pipe="sed -n -e 's/^.*[[ 	]]\($symcode$symcode*\)[[ 	]][[ 	]]*\($ac_symprfx\)$sympat$opt_cr$/$symxfrm/p'"
+
+  # Check to see that the pipe works correctly.
+  pipe_works=no
+
+  rm -f conftest*
+  cat > conftest.$ac_ext <<_LT_EOF
+#ifdef __cplusplus
+extern "C" {
+#endif
+char nm_test_var;
+void nm_test_func(){}
+#ifdef __cplusplus
+}
+#endif
+int main(){nm_test_var='a';nm_test_func();return(0);}
+_LT_EOF
+
+  if AC_TRY_EVAL(ac_compile); then
+    # Now try to grab the symbols.
+    nlist=conftest.nm
+    if AC_TRY_EVAL(NM conftest.$ac_objext \| $lt_cv_sys_global_symbol_pipe \> $nlist) && test -s "$nlist"; then
+      # Try sorting and uniquifying the output.
+      if sort "$nlist" | uniq > "$nlist"T; then
+	mv -f "$nlist"T "$nlist"
+      else
+	rm -f "$nlist"T
+      fi
+
+      # Make sure that we snagged all the symbols we need.
+      if $GREP ' nm_test_var$' "$nlist" >/dev/null; then
+	if $GREP ' nm_test_func$' "$nlist" >/dev/null; then
+	  cat <<_LT_EOF > conftest.$ac_ext
+#ifdef __cplusplus
+extern "C" {
+#endif
+
+_LT_EOF
+	  # Now generate the symbol file.
+	  eval "$lt_cv_sys_global_symbol_to_cdecl"' < "$nlist" | $GREP -v main >> conftest.$ac_ext'
+
+	  cat <<_LT_EOF >> conftest.$ac_ext
+#if defined (__STDC__) && __STDC__
+# define lt_ptr_t void *
+#else
+# define lt_ptr_t char *
+# define const
+#endif
+
+/* The mapping between symbol names and symbols. */
+const struct {
+  const char *name;
+  lt_ptr_t address;
+}
+lt_preloaded_symbols[[]] =
+{
+_LT_EOF
+	  $SED "s/^$symcode$symcode* \(.*\) \(.*\)$/  {\"\2\", (lt_ptr_t) \&\2},/" < "$nlist" | $GREP -v main >> conftest.$ac_ext
+	  cat <<\_LT_EOF >> conftest.$ac_ext
+  {0, (lt_ptr_t) 0}
+};
+
+#ifdef __cplusplus
+}
+#endif
+_LT_EOF
+	  # Now try linking the two files.
+	  mv conftest.$ac_objext conftstm.$ac_objext
+	  lt_save_LIBS="$LIBS"
+	  lt_save_CFLAGS="$CFLAGS"
+	  LIBS="conftstm.$ac_objext"
+	  CFLAGS="$CFLAGS$_LT_AC_TAGVAR(lt_prog_compiler_no_builtin_flag, $1)"
+	  if AC_TRY_EVAL(ac_link) && test -s conftest${ac_exeext}; then
+	    pipe_works=yes
+	  fi
+	  LIBS="$lt_save_LIBS"
+	  CFLAGS="$lt_save_CFLAGS"
+	else
+	  echo "cannot find nm_test_func in $nlist" >&AS_MESSAGE_LOG_FD
+	fi
+      else
+	echo "cannot find nm_test_var in $nlist" >&AS_MESSAGE_LOG_FD
+      fi
+    else
+      echo "cannot run $lt_cv_sys_global_symbol_pipe" >&AS_MESSAGE_LOG_FD
+    fi
+  else
+    echo "$progname: failed program was:" >&AS_MESSAGE_LOG_FD
+    cat conftest.$ac_ext >&5
+  fi
+  rm -f conftest* conftst*
+
+  # Do not use the global_symbol_pipe unless it works.
+  if test "$pipe_works" = yes; then
+    break
+  else
+    lt_cv_sys_global_symbol_pipe=
+  fi
+done
+])
+if test -z "$lt_cv_sys_global_symbol_pipe"; then
+  lt_cv_sys_global_symbol_to_cdecl=
+fi
+if test -z "$lt_cv_sys_global_symbol_pipe$lt_cv_sys_global_symbol_to_cdecl"; then
+  AC_MSG_RESULT(failed)
+else
+  AC_MSG_RESULT(ok)
+fi
+
+_LT_DECL([global_symbol_pipe], [lt_cv_sys_global_symbol_pipe], [1],
+    [Take the output of nm and produce a listing of raw symbols and C names])
+_LT_DECL([global_symbol_to_cdecl], [lt_cv_sys_global_symbol_to_cdecl], [1],
+    [Transform the output of nm in a proper C declaration])
+_LT_DECL([global_symbol_to_c_name_address],
+    [lt_cv_sys_global_symbol_to_c_name_address], [1],
+    [Transform the output of nm in a C name address pair])
+]) # AC_LIBTOOL_SYS_GLOBAL_SYMBOL_PIPE
+
+
+# AC_LIBTOOL_PROG_COMPILER_PIC([TAGNAME])
+# ---------------------------------------
+AC_DEFUN([AC_LIBTOOL_PROG_COMPILER_PIC],
+[_LT_AC_TAGVAR(lt_prog_compiler_wl, $1)=
+_LT_AC_TAGVAR(lt_prog_compiler_pic, $1)=
+_LT_AC_TAGVAR(lt_prog_compiler_static, $1)=
+
+AC_MSG_CHECKING([for $compiler option to produce PIC])
+m4_if([$1], [CXX], [
+  # C++ specific cases for pic, static, wl, etc.
+  if test "$GXX" = yes; then
+    _LT_AC_TAGVAR(lt_prog_compiler_wl, $1)='-Wl,'
+    _LT_AC_TAGVAR(lt_prog_compiler_static, $1)='-static'
+
+    case $host_os in
+    aix*)
+      # All AIX code is PIC.
+      if test "$host_cpu" = ia64; then
+	# AIX 5 now supports IA64 processor
+	_LT_AC_TAGVAR(lt_prog_compiler_static, $1)='-Bstatic'
+      fi
+      ;;
+    amigaos*)
+      if test "$host_cpu" = m68k; then
+        # FIXME: we need at least 68020 code to build shared libraries, but
+        # adding the `-m68020' flag to GCC prevents building anything better,
+        # like `-m68040'.
+        _LT_AC_TAGVAR(lt_prog_compiler_pic, $1)='-m68020 -resident32 -malways-restore-a4'
+      fi
+      ;;
+    beos* | cygwin* | irix5* | irix6* | nonstopux* | osf3* | osf4* | osf5*)
+      # PIC is the default for these OSes.
+      ;;
+    mingw* | os2* | pw32*)
+      # This hack is so that the source file can tell whether it is being
+      # built for inclusion in a dll (and should export symbols for example).
+      _LT_AC_TAGVAR(lt_prog_compiler_pic, $1)='-DDLL_EXPORT'
+      ;;
+    darwin* | rhapsody*)
+      # PIC is the default on this platform
+      # Common symbols not allowed in MH_DYLIB files
+      _LT_AC_TAGVAR(lt_prog_compiler_pic, $1)='-fno-common'
+      ;;
+    *djgpp*)
+      # DJGPP does not support shared libraries at all
+      _LT_AC_TAGVAR(lt_prog_compiler_pic, $1)=
+      ;;
+    sysv4*MP*)
+      if test -d /usr/nec; then
+	_LT_AC_TAGVAR(lt_prog_compiler_pic, $1)=-Kconform_pic
+      fi
+      ;;
+    hpux*)
+      # PIC is the default for IA64 HP-UX and 64-bit HP-UX, but
+      # not for PA HP-UX.
+      case "$host_cpu" in
+      hppa*64*|ia64*)
+	;;
+      *)
+	_LT_AC_TAGVAR(lt_prog_compiler_pic, $1)='-fPIC'
+	;;
+      esac
+      ;;
+    *)
+      _LT_AC_TAGVAR(lt_prog_compiler_pic, $1)='-fPIC'
+      ;;
+    esac
+  else
+    case $host_os in
+      aix4* | aix5*)
+	# All AIX code is PIC.
+	if test "$host_cpu" = ia64; then
+	  # AIX 5 now supports IA64 processor
+	  _LT_AC_TAGVAR(lt_prog_compiler_static, $1)='-Bstatic'
+	else
+	  _LT_AC_TAGVAR(lt_prog_compiler_static, $1)='-bnso -bI:/lib/syscalls.exp'
+	fi
+	;;
+      chorus*)
+	case $cc_basename in
+	cxch68)
+	  # Green Hills C++ Compiler
+	  # _LT_AC_TAGVAR(lt_prog_compiler_static, $1)="--no_auto_instantiation -u __main -u __premain -u _abort -r $COOL_DIR/lib/libOrb.a $MVME_DIR/lib/CC/libC.a $MVME_DIR/lib/classix/libcx.s.a"
+	  ;;
+	esac
+	;;
+       darwin*)
+         # PIC is the default on this platform
+         # Common symbols not allowed in MH_DYLIB files
+         case "$cc_basename" in
+           xlc*)
+           _LT_AC_TAGVAR(lt_prog_compiler_pic, $1)='-qnocommon'
+           _LT_AC_TAGVAR(lt_prog_compiler_wl, $1)='-Wl,'
+           ;;
+         esac
+       ;;
+      dgux*)
+	case $cc_basename in
+	  ec++)
+	    _LT_AC_TAGVAR(lt_prog_compiler_pic, $1)='-KPIC'
+	    ;;
+	  ghcx)
+	    # Green Hills C++ Compiler
+	    _LT_AC_TAGVAR(lt_prog_compiler_pic, $1)='-pic'
+	    ;;
+	  *)
+	    ;;
+	esac
+	;;
+      freebsd* | kfreebsd*-gnu)
+	# FreeBSD uses GNU C++
+	;;
+      hpux9* | hpux10* | hpux11*)
+	case $cc_basename in
+	  CC)
+	    _LT_AC_TAGVAR(lt_prog_compiler_wl, $1)='-Wl,'
+	    _LT_AC_TAGVAR(lt_prog_compiler_static, $1)="${ac_cv_prog_cc_wl}-a ${ac_cv_prog_cc_wl}archive"
+	    if test "$host_cpu" != ia64; then
+	      _LT_AC_TAGVAR(lt_prog_compiler_pic, $1)='+Z'
+	    fi
+	    ;;
+	  aCC)
+	    _LT_AC_TAGVAR(lt_prog_compiler_wl, $1)='-Wl,'
+	    _LT_AC_TAGVAR(lt_prog_compiler_static, $1)="${ac_cv_prog_cc_wl}-a ${ac_cv_prog_cc_wl}archive"
+	    case "$host_cpu" in
+	    hppa*64*|ia64*)
+	      # +Z the default
+	      ;;
+	    *)
+	      _LT_AC_TAGVAR(lt_prog_compiler_pic, $1)='+Z'
+	      ;;
+	    esac
+	    ;;
+	  *)
+	    ;;
+	esac
+	;;
+      irix5* | irix6* | nonstopux*)
+	case $cc_basename in
+	  CC)
+	    _LT_AC_TAGVAR(lt_prog_compiler_wl, $1)='-Wl,'
+	    _LT_AC_TAGVAR(lt_prog_compiler_static, $1)='-non_shared'
+	    # CC pic flag -KPIC is the default.
+	    ;;
+	  *)
+	    ;;
+	esac
+	;;
+      linux*)
+	case $cc_basename in
+	  KCC)
+	    # KAI C++ Compiler
+	    _LT_AC_TAGVAR(lt_prog_compiler_wl, $1)='--backend -Wl,'
+	    _LT_AC_TAGVAR(lt_prog_compiler_pic, $1)='-fPIC'
+	    ;;
+	  icpc)
+	    # Intel C++
+	    _LT_AC_TAGVAR(lt_prog_compiler_wl, $1)='-Wl,'
+	    _LT_AC_TAGVAR(lt_prog_compiler_pic, $1)='-KPIC'
+	    _LT_AC_TAGVAR(lt_prog_compiler_static, $1)='-static'
+	    ;;
+	  cxx)
+	    # Compaq C++
+	    # Make sure the PIC flag is empty.  It appears that all Alpha
+	    # Linux and Compaq Tru64 Unix objects are PIC.
+	    _LT_AC_TAGVAR(lt_prog_compiler_pic, $1)=
+	    _LT_AC_TAGVAR(lt_prog_compiler_static, $1)='-non_shared'
+	    ;;
+	  *)
+	    ;;
+	esac
+	;;
+      lynxos*)
+	;;
+      m88k*)
+	;;
+      mvs*)
+	case $cc_basename in
+	  cxx)
+	    _LT_AC_TAGVAR(lt_prog_compiler_pic, $1)='-W c,exportall'
+	    ;;
+	  *)
+	    ;;
+	esac
+	;;
+      netbsd*)
+	;;
+      osf3* | osf4* | osf5*)
+	case $cc_basename in
+	  KCC)
+	    _LT_AC_TAGVAR(lt_prog_compiler_wl, $1)='--backend -Wl,'
+	    ;;
+	  RCC)
+	    # Rational C++ 2.4.1
+	    _LT_AC_TAGVAR(lt_prog_compiler_pic, $1)='-pic'
+	    ;;
+	  cxx)
+	    # Digital/Compaq C++
+	    _LT_AC_TAGVAR(lt_prog_compiler_wl, $1)='-Wl,'
+	    # Make sure the PIC flag is empty.  It appears that all Alpha
+	    # Linux and Compaq Tru64 Unix objects are PIC.
+	    _LT_AC_TAGVAR(lt_prog_compiler_pic, $1)=
+	    _LT_AC_TAGVAR(lt_prog_compiler_static, $1)='-non_shared'
+	    ;;
+	  *)
+	    ;;
+	esac
+	;;
+      psos*)
+	;;
+      sco*)
+	case $cc_basename in
+	  CC)
+	    _LT_AC_TAGVAR(lt_prog_compiler_pic, $1)='-fPIC'
+	    ;;
+	  *)
+	    ;;
+	esac
+	;;
+      solaris*)
+	case $cc_basename in
+	  CC)
+	    # Sun C++ 4.2, 5.x and Centerline C++
+	    _LT_AC_TAGVAR(lt_prog_compiler_pic, $1)='-KPIC'
+	    _LT_AC_TAGVAR(lt_prog_compiler_static, $1)='-Bstatic'
+	    _LT_AC_TAGVAR(lt_prog_compiler_wl, $1)='-Qoption ld '
+	    ;;
+	  gcx)
+	    # Green Hills C++ Compiler
+	    _LT_AC_TAGVAR(lt_prog_compiler_pic, $1)='-PIC'
+	    ;;
+	  *)
+	    ;;
+	esac
+	;;
+      sunos4*)
+	case $cc_basename in
+	  CC)
+	    # Sun C++ 4.x
+	    _LT_AC_TAGVAR(lt_prog_compiler_pic, $1)='-pic'
+	    _LT_AC_TAGVAR(lt_prog_compiler_static, $1)='-Bstatic'
+	    ;;
+	  lcc)
+	    # Lucid
+	    _LT_AC_TAGVAR(lt_prog_compiler_pic, $1)='-pic'
+	    ;;
+	  *)
+	    ;;
+	esac
+	;;
+      tandem*)
+	case $cc_basename in
+	  NCC)
+	    # NonStop-UX NCC 3.20
+	    _LT_AC_TAGVAR(lt_prog_compiler_pic, $1)='-KPIC'
+	    ;;
+	  *)
+	    ;;
+	esac
+	;;
+      unixware*)
+	;;
+      vxworks*)
+	;;
+      *)
+	_LT_AC_TAGVAR(lt_prog_compiler_can_build_shared, $1)=no
+	;;
+    esac
+  fi
+],
+[
+  if test "$GCC" = yes; then
+    _LT_AC_TAGVAR(lt_prog_compiler_wl, $1)='-Wl,'
+    _LT_AC_TAGVAR(lt_prog_compiler_static, $1)='-static'
+
+    case $host_os in
+      aix*)
+      # All AIX code is PIC.
+      if test "$host_cpu" = ia64; then
+	# AIX 5 now supports IA64 processor
+	_LT_AC_TAGVAR(lt_prog_compiler_static, $1)='-Bstatic'
+      fi
+      ;;
+
+    amigaos*)
+      if test "$host_cpu" = m68k; then
+        # FIXME: we need at least 68020 code to build shared libraries, but
+        # adding the `-m68020' flag to GCC prevents building anything better,
+        # like `-m68040'.
+        _LT_AC_TAGVAR(lt_prog_compiler_pic, $1)='-m68020 -resident32 -malways-restore-a4'
+      fi
+      ;;
+
+    beos* | cygwin* | irix5* | irix6* | nonstopux* | osf3* | osf4* | osf5*)
+      # PIC is the default for these OSes.
+      ;;
+
+    mingw* | pw32* | os2*)
+      # This hack is so that the source file can tell whether it is being
+      # built for inclusion in a dll (and should export symbols for example).
+      _LT_AC_TAGVAR(lt_prog_compiler_pic, $1)='-DDLL_EXPORT'
+      ;;
+
+    darwin* | rhapsody*)
+      # PIC is the default on this platform
+      # Common symbols not allowed in MH_DYLIB files
+      _LT_AC_TAGVAR(lt_prog_compiler_pic, $1)='-fno-common'
+      ;;
+
+    msdosdjgpp*)
+      # Just because we use GCC doesn't mean we suddenly get shared libraries
+      # on systems that don't support them.
+      _LT_AC_TAGVAR(lt_prog_compiler_can_build_shared, $1)=no
+      enable_shared=no
+      ;;
+
+    sysv4*MP*)
+      if test -d /usr/nec; then
+	_LT_AC_TAGVAR(lt_prog_compiler_pic, $1)=-Kconform_pic
+      fi
+      ;;
+
+    hpux*)
+      # PIC is the default for IA64 HP-UX and 64-bit HP-UX, but
+      # not for PA HP-UX.
+      case "$host_cpu" in
+      hppa*64*|ia64*)
+	# +Z the default
+	;;
+      *)
+	_LT_AC_TAGVAR(lt_prog_compiler_pic, $1)='-fPIC'
+	;;
+      esac
+      ;;
+
+    *)
+      _LT_AC_TAGVAR(lt_prog_compiler_pic, $1)='-fPIC'
+      ;;
+    esac
+  else
+    # PORTME Check for flag to pass linker flags through the system compiler.
+    case $host_os in
+    aix*)
+      _LT_AC_TAGVAR(lt_prog_compiler_wl, $1)='-Wl,'
+      if test "$host_cpu" = ia64; then
+	# AIX 5 now supports IA64 processor
+	_LT_AC_TAGVAR(lt_prog_compiler_static, $1)='-Bstatic'
+      else
+	_LT_AC_TAGVAR(lt_prog_compiler_static, $1)='-bnso -bI:/lib/syscalls.exp'
+      fi
+      ;;
+      darwin*)
+        # PIC is the default on this platform
+        # Common symbols not allowed in MH_DYLIB files
+       case "$cc_basename" in
+         xlc*)
+         _LT_AC_TAGVAR(lt_prog_compiler_pic, $1)='-qnocommon'
+         _LT_AC_TAGVAR(lt_prog_compiler_wl, $1)='-Wl,'
+         ;;
+       esac
+       ;;
+
+    mingw* | pw32* | os2*)
+      # This hack is so that the source file can tell whether it is being
+      # built for inclusion in a dll (and should export symbols for example).
+      _LT_AC_TAGVAR(lt_prog_compiler_pic, $1)='-DDLL_EXPORT'
+      ;;
+
+    hpux9* | hpux10* | hpux11*)
+      _LT_AC_TAGVAR(lt_prog_compiler_wl, $1)='-Wl,'
+      # PIC is the default for IA64 HP-UX and 64-bit HP-UX, but
+      # not for PA HP-UX.
+      case "$host_cpu" in
+      hppa*64*|ia64*)
+	# +Z the default
+	;;
+      *)
+	_LT_AC_TAGVAR(lt_prog_compiler_pic, $1)='+Z'
+	;;
+      esac
+      # Is there a better lt_prog_compiler_static that works with the bundled CC?
+      _LT_AC_TAGVAR(lt_prog_compiler_static, $1)='${wl}-a ${wl}archive'
+      ;;
+
+    irix5* | irix6* | nonstopux*)
+      _LT_AC_TAGVAR(lt_prog_compiler_wl, $1)='-Wl,'
+      # PIC (with -KPIC) is the default.
+      _LT_AC_TAGVAR(lt_prog_compiler_static, $1)='-non_shared'
+      ;;
+
+    newsos6)
+      _LT_AC_TAGVAR(lt_prog_compiler_pic, $1)='-KPIC'
+      _LT_AC_TAGVAR(lt_prog_compiler_static, $1)='-Bstatic'
+      ;;
+
+    linux*)
+      case $CC in
+      icc* | ecc*)
+	_LT_AC_TAGVAR(lt_prog_compiler_wl, $1)='-Wl,'
+	_LT_AC_TAGVAR(lt_prog_compiler_pic, $1)='-KPIC'
+	_LT_AC_TAGVAR(lt_prog_compiler_static, $1)='-static'
+        ;;
+      ccc*)
+        _LT_AC_TAGVAR(lt_prog_compiler_wl, $1)='-Wl,'
+        # All Alpha code is PIC.
+        _LT_AC_TAGVAR(lt_prog_compiler_static, $1)='-non_shared'
+        ;;
+      esac
+      ;;
+
+    osf3* | osf4* | osf5*)
+      _LT_AC_TAGVAR(lt_prog_compiler_wl, $1)='-Wl,'
+      # All OSF/1 code is PIC.
+      _LT_AC_TAGVAR(lt_prog_compiler_static, $1)='-non_shared'
+      ;;
+
+    sco3.2v5*)
+      _LT_AC_TAGVAR(lt_prog_compiler_pic, $1)='-Kpic'
+      _LT_AC_TAGVAR(lt_prog_compiler_static, $1)='-dn'
+      ;;
+
+    solaris*)
+      _LT_AC_TAGVAR(lt_prog_compiler_wl, $1)='-Wl,'
+      _LT_AC_TAGVAR(lt_prog_compiler_pic, $1)='-KPIC'
+      _LT_AC_TAGVAR(lt_prog_compiler_static, $1)='-Bstatic'
+      ;;
+
+    sunos4*)
+      _LT_AC_TAGVAR(lt_prog_compiler_wl, $1)='-Qoption ld '
+      _LT_AC_TAGVAR(lt_prog_compiler_pic, $1)='-PIC'
+      _LT_AC_TAGVAR(lt_prog_compiler_static, $1)='-Bstatic'
+      ;;
+
+    sysv4 | sysv4.2uw2* | sysv4.3* | sysv5*)
+      _LT_AC_TAGVAR(lt_prog_compiler_wl, $1)='-Wl,'
+      _LT_AC_TAGVAR(lt_prog_compiler_pic, $1)='-KPIC'
+      _LT_AC_TAGVAR(lt_prog_compiler_static, $1)='-Bstatic'
+      ;;
+
+    sysv4*MP*)
+      if test -d /usr/nec ;then
+	_LT_AC_TAGVAR(lt_prog_compiler_pic, $1)='-Kconform_pic'
+	_LT_AC_TAGVAR(lt_prog_compiler_static, $1)='-Bstatic'
+      fi
+      ;;
+
+    uts4*)
+      _LT_AC_TAGVAR(lt_prog_compiler_pic, $1)='-pic'
+      _LT_AC_TAGVAR(lt_prog_compiler_static, $1)='-Bstatic'
+      ;;
+
+    *)
+      _LT_AC_TAGVAR(lt_prog_compiler_can_build_shared, $1)=no
+      ;;
+    esac
+  fi
+])
+case "$host_os" in
+  # For platforms which do not support PIC, -DPIC is meaningless:
+  *djgpp*)
+    _LT_AC_TAGVAR(lt_prog_compiler_pic, $1)=
+    ;;
+  *)
+    _LT_AC_TAGVAR(lt_prog_compiler_pic, $1)="$_LT_AC_TAGVAR(lt_prog_compiler_pic, $1)@&t@m4_if([$1],[],[ -DPIC],[m4_if([$1],[CXX],[ -DPIC],[])])"
+    ;;
+esac
+AC_MSG_RESULT([$_LT_AC_TAGVAR(lt_prog_compiler_pic, $1)])
+_LT_TAGDECL([wl], [lt_prog_compiler_wl], [1],
+	[How to pass a linker flag through the compiler])
+
+#
+# Check to make sure the PIC flag actually works.
+#
+if test -n "$_LT_AC_TAGVAR(lt_prog_compiler_pic, $1)"; then
+  AC_LIBTOOL_COMPILER_OPTION([if $compiler PIC flag $_LT_AC_TAGVAR(lt_prog_compiler_pic, $1) works],
+    [_LT_AC_TAGVAR(lt_prog_compiler_pic_works, $1)],
+    [$_LT_AC_TAGVAR(lt_prog_compiler_pic, $1)@&t@m4_if([$1],[],[ -DPIC],[m4_if([$1],[CXX],[ -DPIC],[])])], [],
+    [case $_LT_AC_TAGVAR(lt_prog_compiler_pic, $1) in
+     "" | " "*) ;;
+     *) _LT_AC_TAGVAR(lt_prog_compiler_pic, $1)=" $_LT_AC_TAGVAR(lt_prog_compiler_pic, $1)" ;;
+     esac],
+    [_LT_AC_TAGVAR(lt_prog_compiler_pic, $1)=
+     _LT_AC_TAGVAR(lt_prog_compiler_can_build_shared, $1)=no])
+fi
+_LT_TAGDECL([pic_flag], [lt_prog_compiler_pic], [1],
+	[Additional compiler flags for building library objects])
+
+#
+# Check to make sure the static flag actually works.
+#
+AC_LIBTOOL_LINKER_OPTION([if $compiler static flag $_LT_AC_TAGVAR(lt_prog_compiler_static, $1) works],
+  _LT_AC_TAGVAR(lt_prog_compiler_static_works, $1),
+  $_LT_AC_TAGVAR(lt_prog_compiler_static, $1),
+  [],
+  [_LT_AC_TAGVAR(lt_prog_compiler_static, $1)=])
+_LT_TAGDECL([link_static_flag], [lt_prog_compiler_static], [1],
+	[Compiler flag to prevent dynamic linking])
+])# AC_LIBTOOL_PROG_COMPILER_PIC
+
+
+# AC_LIBTOOL_PROG_LD_SHLIBS([TAGNAME])
+# ------------------------------------
+# See if the linker supports building shared libraries.
+AC_DEFUN([AC_LIBTOOL_PROG_LD_SHLIBS],
+[AC_REQUIRE([LT_AC_PROG_EGREP])dnl
+AC_REQUIRE([AC_PROG_LD])dnl
+AC_REQUIRE([AC_PROG_NM])dnl
+AC_REQUIRE([AC_LIBTOOL_SYS_GLOBAL_SYMBOL_PIPE])dnl
+AC_MSG_CHECKING([whether the $compiler linker ($LD) supports shared libraries])
+m4_if([$1], [CXX], [
+  _LT_AC_TAGVAR(export_symbols_cmds, $1)='$NM $libobjs $convenience | $global_symbol_pipe | $SED '\''s/.* //'\'' | sort | uniq > $export_symbols'
+  case $host_os in
+  aix4* | aix5*)
+    # If we're using GNU nm, then we don't want the "-C" option.
+    # -C means demangle to AIX nm, but means don't demangle with GNU nm
+    if $NM -V 2>&1 | $GREP 'GNU' > /dev/null; then
+      _LT_AC_TAGVAR(export_symbols_cmds, $1)='$NM -Bpg $libobjs $convenience | awk '\''{ if (((\[$]2 == "T") || (\[$]2 == "D") || (\[$]2 == "B")) && ([substr](\[$]3,1,1) != ".")) { print \[$]3 } }'\'' | sort -u > $export_symbols'
+    else
+      _LT_AC_TAGVAR(export_symbols_cmds, $1)='$NM -BCpg $libobjs $convenience | awk '\''{ if (((\[$]2 == "T") || (\[$]2 == "D") || (\[$]2 == "B")) && ([substr](\[$]3,1,1) != ".")) { print \[$]3 } }'\'' | sort -u > $export_symbols'
+    fi
+    ;;
+  pw32*)
+    _LT_AC_TAGVAR(export_symbols_cmds, $1)="$ltdll_cmds"
+  ;;
+  cygwin* | mingw*)
+    _LT_AC_TAGVAR(export_symbols_cmds, $1)='$NM $libobjs $convenience | $global_symbol_pipe | $SED -e '\''/^[[BCDGS]] /s/.* \([[^ ]]*\)/\1 DATA/;/^.* __nm__/s/^.* __nm__\([[^ ]]*\) [[^ ]]*/\1 DATA/;/^I /d;/^[[AITW]] /s/.* //'\'' | sort | uniq > $export_symbols'
+  ;;
+  *)
+    _LT_AC_TAGVAR(export_symbols_cmds, $1)='$NM $libobjs $convenience | $global_symbol_pipe | $SED '\''s/.* //'\'' | sort | uniq > $export_symbols'
+  ;;
+  esac
+], [
+  runpath_var=
+  _LT_AC_TAGVAR(allow_undefined_flag, $1)=
+  _LT_AC_TAGVAR(always_export_symbols, $1)=no
+  _LT_AC_TAGVAR(archive_cmds, $1)=
+  _LT_AC_TAGVAR(archive_expsym_cmds, $1)=
+  _LT_AC_TAGVAR(enable_shared_with_static_runtimes, $1)=no
+  _LT_AC_TAGVAR(export_dynamic_flag_spec, $1)=
+  _LT_AC_TAGVAR(export_symbols_cmds, $1)='$NM $libobjs $convenience | $global_symbol_pipe | $SED '\''s/.* //'\'' | sort | uniq > $export_symbols'
+  _LT_AC_TAGVAR(hardcode_automatic, $1)=no
+  _LT_AC_TAGVAR(hardcode_direct, $1)=no
+  _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)=
+  _LT_AC_TAGVAR(hardcode_libdir_flag_spec_ld, $1)=
+  _LT_AC_TAGVAR(hardcode_libdir_separator, $1)=
+  _LT_AC_TAGVAR(hardcode_minus_L, $1)=no
+  _LT_AC_TAGVAR(hardcode_shlibpath_var, $1)=unsupported
+  _LT_AC_TAGVAR(inherit_rpath, $1)=no
+  _LT_AC_TAGVAR(link_all_deplibs, $1)=unknown
+  _LT_AC_TAGVAR(module_cmds, $1)=
+  _LT_AC_TAGVAR(module_expsym_cmds, $1)=
+  _LT_AC_TAGVAR(old_archive_from_new_cmds, $1)=
+  _LT_AC_TAGVAR(old_archive_from_expsyms_cmds, $1)=
+  _LT_AC_TAGVAR(thread_safe_flag_spec, $1)=
+  _LT_AC_TAGVAR(whole_archive_flag_spec, $1)=
+  # include_expsyms should be a list of space-separated symbols to be *always*
+  # included in the symbol list
+  _LT_AC_TAGVAR(include_expsyms, $1)=
+  # exclude_expsyms can be an extended regexp of symbols to exclude
+  # it will be wrapped by ` (' and `)$', so one must not match beginning or
+  # end of line.  Example: `a|bc|.*d.*' will exclude the symbols `a' and `bc',
+  # as well as any symbol that contains `d'.
+  _LT_AC_TAGVAR(exclude_expsyms, $1)="_GLOBAL_OFFSET_TABLE_"
+  # Although _GLOBAL_OFFSET_TABLE_ is a valid symbol C name, most a.out
+  # platforms (ab)use it in PIC code, but their linkers get confused if
+  # the symbol is explicitly referenced.  Since portable code cannot
+  # rely on this symbol name, it's probably fine to never include it in
+  # preloaded symbol tables.
+  extract_expsyms_cmds=
+
+  case $host_os in
+  cygwin* | mingw* | pw32*)
+    # FIXME: the MSVC++ port hasn't been tested in a loooong time
+    # When not using gcc, we currently assume that we are using
+    # Microsoft Visual C++.
+    if test "$GCC" != yes; then
+      with_gnu_ld=no
+    fi
+    ;;
+  openbsd*)
+    with_gnu_ld=no
+    ;;
+  esac
+
+  _LT_AC_TAGVAR(ld_shlibs, $1)=yes
+  if test "$with_gnu_ld" = yes; then
+    # If archive_cmds runs LD, not CC, wlarc should be empty
+    wlarc='${wl}'
+
+    # See if GNU ld supports shared libraries.
+    case $host_os in
+    aix3* | aix4* | aix5*)
+      # On AIX/PPC, the GNU linker is very broken
+      if test "$host_cpu" != ia64; then
+	_LT_AC_TAGVAR(ld_shlibs, $1)=no
+	cat <<_LT_EOF 1>&2
+
+*** Warning: the GNU linker, at least up to release 2.9.1, is reported
+*** to be unable to reliably create shared libraries on AIX.
+*** Therefore, libtool is disabling shared libraries support.  If you
+*** really care for shared libraries, you may want to modify your PATH
+*** so that a non-GNU linker is found, and then restart.
+
+_LT_EOF
+      fi
+      ;;
+
+    amigaos*)
+      if test "$host_cpu" = m68k; then
+        _LT_AC_TAGVAR(archive_cmds, $1)='$rm $output_objdir/a2ixlibrary.data~$echo "#define NAME $libname" > $output_objdir/a2ixlibrary.data~$echo "#define LIBRARY_ID 1" >> $output_objdir/a2ixlibrary.data~$echo "#define VERSION $major" >> $output_objdir/a2ixlibrary.data~$echo "#define REVISION $revision" >> $output_objdir/a2ixlibrary.data~$AR $AR_FLAGS $lib $libobjs~$RANLIB $lib~(cd $output_objdir && a2ixlibrary -32)'
+        _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='-L$libdir'
+        _LT_AC_TAGVAR(hardcode_minus_L, $1)=yes
+      fi
+
+      # Samuel A. Falvo II <kc5tja@dolphin.openprojects.net> reports
+      # that the semantics of dynamic libraries on AmigaOS, at least up
+      # to version 4, is to share data among multiple programs linked
+      # with the same dynamic library.  Since this doesn't match the
+      # behavior of shared libraries on other platforms, we can't use
+      # them.
+      _LT_AC_TAGVAR(ld_shlibs, $1)=no
+      ;;
+
+    beos*)
+      if $LD --help 2>&1 | $GREP ': supported targets:.* elf' > /dev/null; then
+	_LT_AC_TAGVAR(allow_undefined_flag, $1)=unsupported
+	# Joseph Beckenbach <jrb3@best.com> says some releases of gcc
+	# support --undefined.  This deserves some investigation.  FIXME
+	_LT_AC_TAGVAR(archive_cmds, $1)='$CC -nostart $libobjs $deplibs $compiler_flags ${wl}-soname $wl$soname -o $lib'
+      else
+	_LT_AC_TAGVAR(ld_shlibs, $1)=no
+      fi
+      ;;
+
+    cygwin* | mingw* | pw32*)
+      # _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1) is actually meaningless,
+      # as there is no search path for DLLs.
+      _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='-L$libdir'
+      _LT_AC_TAGVAR(allow_undefined_flag, $1)=unsupported
+      _LT_AC_TAGVAR(always_export_symbols, $1)=no
+      _LT_AC_TAGVAR(enable_shared_with_static_runtimes, $1)=yes
+      _LT_AC_TAGVAR(export_symbols_cmds, $1)='$NM $libobjs $convenience | $global_symbol_pipe | $SED -e '\''/^[[BCDGS]] /s/.* \([[^ ]]*\)/\1 DATA/'\'' | $SED -e '\''/^[[AITW]] /s/.* //'\'' | sort | uniq > $export_symbols'
+
+      if $LD --help 2>&1 | $GREP 'auto-import' > /dev/null; then
+        _LT_AC_TAGVAR(archive_cmds, $1)='$CC -shared $libobjs $deplibs $compiler_flags -o $output_objdir/$soname ${wl}--image-base=0x10000000 ${wl}--out-implib,$lib'
+	# If the export-symbols file already is a .def file (1st line
+	# is EXPORTS), use it as is; otherwise, prepend...
+	_LT_AC_TAGVAR(archive_expsym_cmds, $1)='if test "x`$SED 1q $export_symbols`" = xEXPORTS; then
+	  cp $export_symbols $output_objdir/$soname.def;
+	else
+	  echo EXPORTS > $output_objdir/$soname.def;
+	  cat $export_symbols >> $output_objdir/$soname.def;
+	fi~
+	$CC -shared $output_objdir/$soname.def $libobjs $deplibs $compiler_flags -o $output_objdir/$soname ${wl}--image-base=0x10000000  ${wl}--out-implib,$lib'
+      else
+	ld_shlibs=no
+      fi
+      ;;
+
+    netbsd*)
+      if echo __ELF__ | $CC -E - | $GREP __ELF__ >/dev/null; then
+	_LT_AC_TAGVAR(archive_cmds, $1)='$LD -Bshareable $libobjs $deplibs $linker_flags -o $lib'
+	wlarc=
+      else
+	_LT_AC_TAGVAR(archive_cmds, $1)='$CC -shared $libobjs $deplibs $compiler_flags ${wl}-soname $wl$soname -o $lib'
+	_LT_AC_TAGVAR(archive_expsym_cmds, $1)='$CC -shared $libobjs $deplibs $compiler_flags ${wl}-soname $wl$soname ${wl}-retain-symbols-file $wl$export_symbols -o $lib'
+      fi
+      ;;
+
+    solaris* | sysv5*)
+      if $LD -v 2>&1 | $GREP 'BFD 2\.8' > /dev/null; then
+	_LT_AC_TAGVAR(ld_shlibs, $1)=no
+	cat <<_LT_EOF 1>&2
+
+*** Warning: The releases 2.8.* of the GNU linker cannot reliably
+*** create shared libraries on Solaris systems.  Therefore, libtool
+*** is disabling shared libraries support.  We urge you to upgrade GNU
+*** binutils to release 2.9.1 or newer.  Another option is to modify
+*** your PATH or compiler configuration so that the native linker is
+*** used, and then restart.
+
+_LT_EOF
+      elif $LD --help 2>&1 | $GREP ': supported targets:.* elf' > /dev/null; then
+	_LT_AC_TAGVAR(archive_cmds, $1)='$CC -shared $libobjs $deplibs $compiler_flags ${wl}-soname $wl$soname -o $lib'
+	_LT_AC_TAGVAR(archive_expsym_cmds, $1)='$CC -shared $libobjs $deplibs $compiler_flags ${wl}-soname $wl$soname ${wl}-retain-symbols-file $wl$export_symbols -o $lib'
+      else
+	_LT_AC_TAGVAR(ld_shlibs, $1)=no
+      fi
+      ;;
+
+    sunos4*)
+      _LT_AC_TAGVAR(archive_cmds, $1)='$LD -assert pure-text -Bshareable -o $lib $libobjs $deplibs $linker_flags'
+      wlarc=
+      _LT_AC_TAGVAR(hardcode_direct, $1)=yes
+      _LT_AC_TAGVAR(hardcode_shlibpath_var, $1)=no
+      ;;
+
+  linux*)
+    if $LD --help 2>&1 | $EGREP ': supported targets:.* elf' > /dev/null; then
+      _LT_AC_TAGVAR(archive_cmds, $1)='$CC -shared $libobjs $deplibs $compiler_flags ${wl}-soname $wl$soname -o $lib'
+      case `$LD -v 2>&1` in
+        *\ [01].* | *\ 2.[[0-9]].* | *\ 2.10.*) ;; # catch versions < 2.11
+        *\ 2.11.93.0.2\ *) supports_anon_versioning=yes ;; # RH7.3 ...
+        *\ 2.11.92.0.12\ *) supports_anon_versioning=yes ;; # Mandrake 8.2 ...
+        *\ 2.11.*) ;; # other 2.11 versions
+        *) supports_anon_versioning=yes ;;
+      esac
+      if test "x$supports_anon_versioning" = xyes; then
+        _LT_AC_TAGVAR(archive_expsym_cmds, $1)='$echo "{ global:" > $output_objdir/$libname.ver~cat $export_symbols | sed -e "s/\(.*\)/\1;/" >> $output_objdir/$libname.ver~$echo "local: *; };" >> $output_objdir/$libname.ver~$CC -shared $libobjs $deplibs $compiler_flags ${wl}-soname $wl$soname ${wl}-version-script ${wl}$output_objdir/$libname.ver -o $lib'
+      else
+        _LT_AC_TAGVAR(archive_expsym_cmds, $1)=$_LT_AC_TAGVAR(archive_cmds, $1)
+      fi
+    else
+      _LT_AC_TAGVAR(ld_shlibs, $1)=no
+    fi
+    ;;
+
+    *)
+      if $LD --help 2>&1 | $GREP ': supported targets:.* elf' > /dev/null; then
+	_LT_AC_TAGVAR(archive_cmds, $1)='$CC -shared $libobjs $deplibs $compiler_flags ${wl}-soname $wl$soname -o $lib'
+	_LT_AC_TAGVAR(archive_expsym_cmds, $1)='$CC -shared $libobjs $deplibs $compiler_flags ${wl}-soname $wl$soname ${wl}-retain-symbols-file $wl$export_symbols -o $lib'
+      else
+	_LT_AC_TAGVAR(ld_shlibs, $1)=no
+      fi
+      ;;
+    esac
+
+    if test "$_LT_AC_TAGVAR(ld_shlibs, $1)" = yes; then
+      runpath_var=LD_RUN_PATH
+      _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='${wl}--rpath ${wl}$libdir'
+      _LT_AC_TAGVAR(export_dynamic_flag_spec, $1)='${wl}--export-dynamic'
+      # ancient GNU ld didn't support --whole-archive et. al.
+      if $LD --help 2>&1 | $GREP 'no-whole-archive' > /dev/null; then
+ 	_LT_AC_TAGVAR(whole_archive_flag_spec, $1)="$wlarc"'--whole-archive$convenience '"$wlarc"'--no-whole-archive'
+      else
+  	_LT_AC_TAGVAR(whole_archive_flag_spec, $1)=
+      fi
+    fi
+  else
+    # PORTME fill in a description of your system's linker (not GNU ld)
+    case $host_os in
+    aix3*)
+      _LT_AC_TAGVAR(allow_undefined_flag, $1)=unsupported
+      _LT_AC_TAGVAR(always_export_symbols, $1)=yes
+      _LT_AC_TAGVAR(archive_expsym_cmds, $1)='$LD -o $output_objdir/$soname $libobjs $deplibs $linker_flags -bE:$export_symbols -T512 -H512 -bM:SRE~$AR $AR_FLAGS $lib $output_objdir/$soname'
+      # Note: this linker hardcodes the directories in LIBPATH if there
+      # are no directories specified by -L.
+      _LT_AC_TAGVAR(hardcode_minus_L, $1)=yes
+      if test "$GCC" = yes && test -z "$link_static_flag"; then
+	# Neither direct hardcoding nor static linking is supported with a
+	# broken collect2.
+	_LT_AC_TAGVAR(hardcode_direct, $1)=unsupported
+      fi
+      ;;
+
+    aix4* | aix5*)
+      if test "$host_cpu" = ia64; then
+	# On IA64, the linker does run time linking by default, so we don't
+	# have to do anything special.
+	aix_use_runtimelinking=no
+	exp_sym_flag='-Bexport'
+	no_entry_flag=""
+      else
+	# If we're using GNU nm, then we don't want the "-C" option.
+	# -C means demangle to AIX nm, but means don't demangle with GNU nm
+	if $NM -V 2>&1 | $GREP 'GNU' > /dev/null; then
+	  _LT_AC_TAGVAR(export_symbols_cmds, $1)='$NM -Bpg $libobjs $convenience | awk '\''{ if (((\[$]2 == "T") || (\[$]2 == "D") || (\[$]2 == "B")) && ([substr](\[$]3,1,1) != ".")) { print \[$]3 } }'\'' | sort -u > $export_symbols'
+	else
+	  _LT_AC_TAGVAR(export_symbols_cmds, $1)='$NM -BCpg $libobjs $convenience | awk '\''{ if (((\[$]2 == "T") || (\[$]2 == "D") || (\[$]2 == "B")) && ([substr](\[$]3,1,1) != ".")) { print \[$]3 } }'\'' | sort -u > $export_symbols'
+	fi
+	aix_use_runtimelinking=no
+
+	# Test if we are trying to use run time linking or normal
+	# AIX style linking. If -brtl is somewhere in LDFLAGS, we
+	# need to do runtime linking.
+	case $host_os in aix4.[[23]]|aix4.[[23]].*|aix5*)
+	  for ld_flag in $LDFLAGS; do
+  	  if (test $ld_flag = "-brtl" || test $ld_flag = "-Wl,-brtl"); then
+  	    aix_use_runtimelinking=yes
+  	    break
+  	  fi
+	  done
+	esac
+
+	exp_sym_flag='-bexport'
+	no_entry_flag='-bnoentry'
+      fi
+
+      # When large executables or shared objects are built, AIX ld can
+      # have problems creating the table of contents.  If linking a library
+      # or program results in "error TOC overflow" add -mminimal-toc to
+      # CXXFLAGS/CFLAGS for g++/gcc.  In the cases where that is not
+      # enough to fix the problem, add -Wl,-bbigtoc to LDFLAGS.
+
+      _LT_AC_TAGVAR(archive_cmds, $1)=''
+      _LT_AC_TAGVAR(hardcode_direct, $1)=yes
+      _LT_AC_TAGVAR(hardcode_libdir_separator, $1)=':'
+      _LT_AC_TAGVAR(link_all_deplibs, $1)=yes
+
+      if test "$GCC" = yes; then
+	case $host_os in aix4.[012]|aix4.[012].*)
+	# We only want to do this on AIX 4.2 and lower, the check
+	# below for broken collect2 doesn't work under 4.3+
+	  collect2name=`${CC} -print-prog-name=collect2`
+	  if test -f "$collect2name" &&
+  	   strings "$collect2name" | $GREP resolve_lib_name >/dev/null
+	  then
+  	  # We have reworked collect2
+  	  _LT_AC_TAGVAR(hardcode_direct, $1)=yes
+	  else
+  	  # We have old collect2
+  	  _LT_AC_TAGVAR(hardcode_direct, $1)=unsupported
+  	  # It fails to find uninstalled libraries when the uninstalled
+  	  # path is not listed in the libpath.  Setting hardcode_minus_L
+  	  # to unsupported forces relinking
+  	  _LT_AC_TAGVAR(hardcode_minus_L, $1)=yes
+  	  _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='-L$libdir'
+  	  _LT_AC_TAGVAR(hardcode_libdir_separator, $1)=
+	  fi
+	esac
+	shared_flag='-shared'
+      else
+	# not using gcc
+	if test "$host_cpu" = ia64; then
+  	# VisualAge C++, Version 5.5 for AIX 5L for IA-64, Beta 3 Release
+  	# chokes on -Wl,-G. The following line is correct:
+	  shared_flag='-G'
+	else
+  	if test "$aix_use_runtimelinking" = yes; then
+	    shared_flag='${wl}-G'
+	  else
+	    shared_flag='${wl}-bM:SRE'
+  	fi
+	fi
+      fi
+
+      # It seems that -bexpall does not export symbols beginning with
+      # underscore (_), so it is better to generate a list of symbols to export.
+      _LT_AC_TAGVAR(always_export_symbols, $1)=yes
+      if test "$aix_use_runtimelinking" = yes; then
+	# Warning - without using the other runtime loading flags (-brtl),
+	# -berok will link without error, but may produce a broken library.
+	_LT_AC_TAGVAR(allow_undefined_flag, $1)='-berok'
+        # Determine the default libpath from the value encoded in an
+        # empty executable.
+       _LT_AC_SYS_LIBPATH_AIX
+       _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='${wl}-blibpath:$libdir:'"$aix_libpath"
+	_LT_AC_TAGVAR(archive_expsym_cmds, $1)="\$CC"' -o $output_objdir/$soname $libobjs $deplibs $compiler_flags `if test "x${allow_undefined_flag}" != "x"; then echo "${wl}${allow_undefined_flag}"; else :; fi` '"\${wl}$no_entry_flag \${wl}$exp_sym_flag:\$export_symbols $shared_flag"
+      else
+	if test "$host_cpu" = ia64; then
+	  _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='${wl}-R $libdir:/usr/lib:/lib'
+	  _LT_AC_TAGVAR(allow_undefined_flag, $1)="-z nodefs"
+	  _LT_AC_TAGVAR(archive_expsym_cmds, $1)="\$CC $shared_flag"' -o $output_objdir/$soname $libobjs $deplibs $compiler_flags ${wl}${allow_undefined_flag} '"\${wl}$no_entry_flag \${wl}$exp_sym_flag:\$export_symbols"
+	else
+	 # Determine the default libpath from the value encoded in an
+	 # empty executable.
+	 _LT_AC_SYS_LIBPATH_AIX
+	 _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='${wl}-blibpath:$libdir:'"$aix_libpath"
+	  # Warning - without using the other run time loading flags,
+	  # -berok will link without error, but may produce a broken library.
+	  _LT_AC_TAGVAR(no_undefined_flag, $1)=' ${wl}-bernotok'
+	  _LT_AC_TAGVAR(allow_undefined_flag, $1)=' ${wl}-berok'
+	  # -bexpall does not export symbols beginning with underscore (_)
+	  _LT_AC_TAGVAR(always_export_symbols, $1)=yes
+	  # Exported symbols can be pulled into shared objects from archives
+	  _LT_AC_TAGVAR(whole_archive_flag_spec, $1)=' '
+	  _LT_AC_TAGVAR(archive_cmds_need_lc, $1)=yes
+	  # This is similar to how AIX traditionally builds it's shared libraries.
+	  _LT_AC_TAGVAR(archive_expsym_cmds, $1)="\$CC $shared_flag"' -o $output_objdir/$soname $libobjs $deplibs $compiler_flags ${wl}-bE:$export_symbols ${wl}-bnoentry${allow_undefined_flag}~$AR $AR_FLAGS $output_objdir/$libname$release.a $output_objdir/$soname'
+	fi
+      fi
+      ;;
+
+    amigaos*)
+      if test "$host_cpu" = m68k; then
+        _LT_AC_TAGVAR(archive_cmds, $1)='$rm $output_objdir/a2ixlibrary.data~$echo "#define NAME $libname" > $output_objdir/a2ixlibrary.data~$echo "#define LIBRARY_ID 1" >> $output_objdir/a2ixlibrary.data~$echo "#define VERSION $major" >> $output_objdir/a2ixlibrary.data~$echo "#define REVISION $revision" >> $output_objdir/a2ixlibrary.data~$AR $AR_FLAGS $lib $libobjs~$RANLIB $lib~(cd $output_objdir && a2ixlibrary -32)'
+        _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='-L$libdir'
+        _LT_AC_TAGVAR(hardcode_minus_L, $1)=yes
+      fi
+      # see comment about different semantics on the GNU ld section
+      _LT_AC_TAGVAR(ld_shlibs, $1)=no
+      ;;
+
+    bsdi4*)
+      _LT_AC_TAGVAR(export_dynamic_flag_spec, $1)=-rdynamic
+      ;;
+
+    cygwin* | mingw* | pw32*)
+      # When not using gcc, we currently assume that we are using
+      # Microsoft Visual C++.
+      # hardcode_libdir_flag_spec is actually meaningless, as there is
+      # no search path for DLLs.
+      _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)=' '
+      _LT_AC_TAGVAR(allow_undefined_flag, $1)=unsupported
+      # Tell ltmain to make .lib files, not .a files.
+      libext=lib
+      # Tell ltmain to make .dll files, not .so files.
+      shrext_cmds=".dll"
+      # FIXME: Setting linknames here is a bad hack.
+      _LT_AC_TAGVAR(archive_cmds, $1)='$CC -o $lib $libobjs $compiler_flags `echo "$deplibs" | $SED -e '\''s/ -lc$//'\''` -link -dll~linknames='
+      # The linker will automatically build a .lib file if we build a DLL.
+      _LT_AC_TAGVAR(old_archive_from_new_cmds, $1)='true'
+      # FIXME: Should let the user specify the lib program.
+      _LT_AC_TAGVAR(old_archive_cmds, $1)='lib /OUT:$oldlib$oldobjs$old_deplibs'
+      fix_srcfile_path='`cygpath -w "$srcfile"`'
+      _LT_AC_TAGVAR(enable_shared_with_static_runtimes, $1)=yes
+      ;;
+
+    darwin* | rhapsody*)
+      case "$host_os" in
+        rhapsody* | darwin1.[[012]])
+         _LT_AC_TAGVAR(allow_undefined_flag, $1)='${wl}-undefined ${wl}suppress'
+         ;;
+       *) # Darwin 1.3 on
+         if test -z ${MACOSX_DEPLOYMENT_TARGET} ; then
+           _LT_AC_TAGVAR(allow_undefined_flag, $1)='${wl}-flat_namespace ${wl}-undefined ${Wl}suppress'
+         else
+           case ${MACOSX_DEPLOYMENT_TARGET} in
+             10.[[012]])
+               _LT_AC_TAGVAR(allow_undefined_flag, $1)='${wl}-flat_namespace ${wl}-undefined ${wl}suppress'
+               ;;
+             10.*)
+               _LT_AC_TAGVAR(allow_undefined_flag, $1)='${wl}-undefined ${wl}dynamic_lookup'
+               ;;
+           esac
+         fi
+         ;;
+      esac
+      _LT_AC_TAGVAR(archive_cmds_need_lc, $1)=no
+      _LT_AC_TAGVAR(hardcode_direct, $1)=no
+      _LT_AC_TAGVAR(hardcode_automatic, $1)=yes
+      _LT_AC_TAGVAR(hardcode_shlibpath_var, $1)=unsupported
+      _LT_AC_TAGVAR(whole_archive_flag_spec, $1)='-all_load $convenience'
+      _LT_AC_TAGVAR(link_all_deplibs, $1)=yes
+    if test "$GCC" = yes ; then
+    	output_verbose_link_cmd='echo'
+        _LT_AC_TAGVAR(archive_cmds, $1)='$CC -dynamiclib $allow_undefined_flag -o $lib $libobjs $deplibs $compiler_flags -install_name $rpath/$soname $verstring'
+      _LT_AC_TAGVAR(module_cmds, $1)='$CC $allow_undefined_flag -o $lib -bundle $libobjs $deplibs$compiler_flags'
+      # Don't fix this by using the ld -exported_symbols_list flag, it doesn't exist in older darwin ld's
+      _LT_AC_TAGVAR(archive_expsym_cmds, $1)='sed -e "s,#.*,," -e "s,^[    ]*,," -e "s,^\(..*\),_&," < $export_symbols > $output_objdir/${libname}-symbols.expsym~$CC -dynamiclib $allow_undefined_flag -o $lib $libobjs $deplibs $compiler_flags -install_name $rpath/$soname $verstring~nmedit -s $output_objdir/${libname}-symbols.expsym ${lib}'
+      _LT_AC_TAGVAR(module_expsym_cmds, $1)='sed -e "s,#.*,," -e "s,^[    ]*,," -e "s,^\(..*\),_&," < $export_symbols > $output_objdir/${libname}-symbols.expsym~$CC $allow_undefined_flag  -o $lib -bundle $libobjs $deplibs$compiler_flags~nmedit -s $output_objdir/${libname}-symbols.expsym ${lib}'
+    else
+      case "$cc_basename" in
+        xlc*)
+         output_verbose_link_cmd='echo'
+          _LT_AC_TAGVAR(archive_cmds, $1)='$CC -qmkshrobj $allow_undefined_flag -o $lib $libobjs $deplibs $compiler_flags ${wl}-install_name ${wl}`echo $rpath/$soname` $verstring'
+          _LT_AC_TAGVAR(module_cmds, $1)='$CC $allow_undefined_flag -o $lib -bundle $libobjs $deplibs$compiler_flags'
+          # Don't fix this by using the ld -exported_symbols_list flag, it doesn't exist in older darwin ld's
+          _LT_AC_TAGVAR(archive_expsym_cmds, $1)='sed -e "s,#.*,," -e "s,^[    ]*,," -e "s,^\(..*\),_&," < $export_symbols > $output_objdir/${libname}-symbols.expsym~$CC -qmkshrobj $allow_undefined_flag -o $lib $libobjs $deplibs $compiler_flags ${wl}-install_name ${wl}$rpath/$soname $verstring~nmedit -s $output_objdir/${libname}-symbols.expsym ${lib}'
+          _LT_AC_TAGVAR(module_expsym_cmds, $1)='sed -e "s,#.*,," -e "s,^[    ]*,," -e "s,^\(..*\),_&," < $export_symbols > $output_objdir/${libname}-symbols.expsym~$CC $allow_undefined_flag  -o $lib -bundle $libobjs $deplibs$compiler_flags~nmedit -s $output_objdir/${libname}-symbols.expsym ${lib}'
+          ;;
+       *)
+         _LT_AC_TAGVAR(ld_shlibs, $1)=no
+          ;;
+      esac     
+    fi
+      ;;
+    dgux*)
+      _LT_AC_TAGVAR(archive_cmds, $1)='$LD -G -h $soname -o $lib $libobjs $deplibs $linker_flags'
+      _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='-L$libdir'
+      _LT_AC_TAGVAR(hardcode_shlibpath_var, $1)=no
+      ;;
+
+    freebsd1*)
+      _LT_AC_TAGVAR(ld_shlibs, $1)=no
+      ;;
+
+    # FreeBSD 2.2.[012] allows us to include c++rt0.o to get C++ constructor
+    # support.  Future versions do this automatically, but an explicit c++rt0.o
+    # does not break anything, and helps significantly (at the cost of a little
+    # extra space).
+    freebsd2.2*)
+      _LT_AC_TAGVAR(archive_cmds, $1)='$LD -Bshareable -o $lib $libobjs $deplibs $linker_flags /usr/lib/c++rt0.o'
+      _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='-R$libdir'
+      _LT_AC_TAGVAR(hardcode_direct, $1)=yes
+      _LT_AC_TAGVAR(hardcode_shlibpath_var, $1)=no
+      ;;
+
+    # Unfortunately, older versions of FreeBSD 2 do not have this feature.
+    freebsd2*)
+      _LT_AC_TAGVAR(archive_cmds, $1)='$LD -Bshareable -o $lib $libobjs $deplibs $linker_flags'
+      _LT_AC_TAGVAR(hardcode_direct, $1)=yes
+      _LT_AC_TAGVAR(hardcode_minus_L, $1)=yes
+      _LT_AC_TAGVAR(hardcode_shlibpath_var, $1)=no
+      ;;
+
+    # FreeBSD 3 and greater uses gcc -shared to do shared libraries.
+    freebsd* | kfreebsd*-gnu)
+      _LT_AC_TAGVAR(archive_cmds, $1)='$CC -shared -o $lib $libobjs $deplibs $compiler_flags'
+      _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='-R$libdir'
+      _LT_AC_TAGVAR(hardcode_direct, $1)=yes
+      _LT_AC_TAGVAR(hardcode_shlibpath_var, $1)=no
+      ;;
+
+    hpux9*)
+      if test "$GCC" = yes; then
+	_LT_AC_TAGVAR(archive_cmds, $1)='$rm $output_objdir/$soname~$CC -shared -fPIC ${wl}+b ${wl}$install_libdir -o $output_objdir/$soname $libobjs $deplibs $compiler_flags~test $output_objdir/$soname = $lib || mv $output_objdir/$soname $lib'
+      else
+	_LT_AC_TAGVAR(archive_cmds, $1)='$rm $output_objdir/$soname~$LD -b +b $install_libdir -o $output_objdir/$soname $libobjs $deplibs $linker_flags~test $output_objdir/$soname = $lib || mv $output_objdir/$soname $lib'
+      fi
+      _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='${wl}+b ${wl}$libdir'
+      _LT_AC_TAGVAR(hardcode_libdir_separator, $1)=:
+      _LT_AC_TAGVAR(hardcode_direct, $1)=yes
+
+      # hardcode_minus_L: Not really in the search PATH,
+      # but as the default location of the library.
+      _LT_AC_TAGVAR(hardcode_minus_L, $1)=yes
+      _LT_AC_TAGVAR(export_dynamic_flag_spec, $1)='${wl}-E'
+      ;;
+
+    hpux10* | hpux11*)
+      if test "$GCC" = yes -a "$with_gnu_ld" = no; then
+	case "$host_cpu" in
+	hppa*64*|ia64*)
+	  _LT_AC_TAGVAR(archive_cmds, $1)='$CC -shared ${wl}+h ${wl}$soname -o $lib $libobjs $deplibs $compiler_flags'
+	  ;;
+	*)
+	  _LT_AC_TAGVAR(archive_cmds, $1)='$CC -shared -fPIC ${wl}+h ${wl}$soname ${wl}+b ${wl}$install_libdir -o $lib $libobjs $deplibs $compiler_flags'
+	  ;;
+	esac
+      else
+	case "$host_cpu" in
+	hppa*64*|ia64*)
+	  _LT_AC_TAGVAR(archive_cmds, $1)='$LD -b +h $soname -o $lib $libobjs $deplibs $linker_flags'
+	  ;;
+	*)
+	  _LT_AC_TAGVAR(archive_cmds, $1)='$LD -b +h $soname +b $install_libdir -o $lib $libobjs $deplibs $linker_flags'
+	  ;;
+	esac
+      fi
+      if test "$with_gnu_ld" = no; then
+	case "$host_cpu" in
+	hppa*64*)
+	  _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='${wl}+b ${wl}$libdir'
+	  _LT_AC_TAGVAR(hardcode_libdir_flag_spec_ld, $1)='+b $libdir'
+	  _LT_AC_TAGVAR(hardcode_libdir_separator, $1)=:
+	  _LT_AC_TAGVAR(hardcode_direct, $1)=no
+	  _LT_AC_TAGVAR(hardcode_shlibpath_var, $1)=no
+	  ;;
+	ia64*)
+	  _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='-L$libdir'
+	  _LT_AC_TAGVAR(hardcode_direct, $1)=no
+	  _LT_AC_TAGVAR(hardcode_shlibpath_var, $1)=no
+
+	  # hardcode_minus_L: Not really in the search PATH,
+	  # but as the default location of the library.
+	  _LT_AC_TAGVAR(hardcode_minus_L, $1)=yes
+	  ;;
+	*)
+	  _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='${wl}+b ${wl}$libdir'
+	  _LT_AC_TAGVAR(hardcode_libdir_separator, $1)=:
+	  _LT_AC_TAGVAR(hardcode_direct, $1)=yes
+	  _LT_AC_TAGVAR(export_dynamic_flag_spec, $1)='${wl}-E'
+
+	  # hardcode_minus_L: Not really in the search PATH,
+	  # but as the default location of the library.
+	  _LT_AC_TAGVAR(hardcode_minus_L, $1)=yes
+	  ;;
+	esac
+      fi
+      ;;
+
+    irix5* | irix6* | nonstopux*)
+      if test "$GCC" = yes; then
+	_LT_AC_TAGVAR(archive_cmds, $1)='$CC -shared $libobjs $deplibs $compiler_flags ${wl}-soname ${wl}$soname `test -n "$verstring" && echo ${wl}-set_version ${wl}$verstring` ${wl}-update_registry ${wl}${output_objdir}/so_locations -o $lib'
+	_LT_AC_TAGVAR(archive_expsym_cmds, $1)='$CC -shared $libobjs $deplibs $compiler_flags ${wl}-soname ${wl}$soname `test -n "$verstring" && echo ${wl}-set_version ${wl}$verstring` ${wl}-update_registry ${wl}${output_objdir}/so_locations ${wl}-exports_file ${wl}$export_symbols -o $lib'
+      else
+	_LT_AC_TAGVAR(archive_cmds, $1)='$LD -shared $libobjs $deplibs $linker_flags -soname $soname `test -n "$verstring" && echo -set_version $verstring` -update_registry ${output_objdir}/so_locations -o $lib'
+	_LT_AC_TAGVAR(archive_expsym_cmds, $1)='$LD -shared $libobjs $deplibs $linker_flags -soname $soname `test -n "$verstring" && echo -set_version $verstring` -update_registry ${output_objdir}/so_locations -exports_file $export_symbols -o $lib'
+	_LT_AC_TAGVAR(hardcode_libdir_flag_spec_ld, $1)='-rpath $libdir'
+      fi
+      _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='${wl}-rpath ${wl}$libdir'
+      _LT_AC_TAGVAR(hardcode_libdir_separator, $1)=:
+      _LT_AC_TAGVAR(inherit_rpath, $1)=yes
+      _LT_AC_TAGVAR(link_all_deplibs, $1)=yes
+      ;;
+
+    netbsd*)
+      if echo __ELF__ | $CC -E - | $GREP __ELF__ >/dev/null; then
+	_LT_AC_TAGVAR(archive_cmds, $1)='$LD -Bshareable -o $lib $libobjs $deplibs $linker_flags'  # a.out
+      else
+	_LT_AC_TAGVAR(archive_cmds, $1)='$LD -shared -o $lib $libobjs $deplibs $linker_flags'      # ELF
+      fi
+      _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='-R$libdir'
+      _LT_AC_TAGVAR(hardcode_direct, $1)=yes
+      _LT_AC_TAGVAR(hardcode_shlibpath_var, $1)=no
+      ;;
+
+    newsos6)
+      _LT_AC_TAGVAR(archive_cmds, $1)='$LD -G -h $soname -o $lib $libobjs $deplibs $linker_flags'
+      _LT_AC_TAGVAR(hardcode_direct, $1)=yes
+      _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='${wl}-rpath ${wl}$libdir'
+      _LT_AC_TAGVAR(hardcode_libdir_separator, $1)=:
+      _LT_AC_TAGVAR(hardcode_shlibpath_var, $1)=no
+      ;;
+
+    openbsd*)
+      _LT_AC_TAGVAR(hardcode_direct, $1)=yes
+      _LT_AC_TAGVAR(hardcode_shlibpath_var, $1)=no
+      if test -z "`echo __ELF__ | $CC -E - | $GREP __ELF__`" || test "$host_os-$host_cpu" = "openbsd2.8-powerpc"; then
+	_LT_AC_TAGVAR(archive_cmds, $1)='$CC -shared $pic_flag -o $lib $libobjs $deplibs $compiler_flags'
+	_LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='${wl}-rpath,$libdir'
+	_LT_AC_TAGVAR(export_dynamic_flag_spec, $1)='${wl}-E'
+      else
+       case $host_os in
+	 openbsd[[01]].* | openbsd2.[[0-7]] | openbsd2.[[0-7]].*)
+	   _LT_AC_TAGVAR(archive_cmds, $1)='$LD -Bshareable -o $lib $libobjs $deplibs $linker_flags'
+	   _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='-R$libdir'
+	   ;;
+	 *)
+	   _LT_AC_TAGVAR(archive_cmds, $1)='$CC -shared $pic_flag -o $lib $libobjs $deplibs $compiler_flags'
+	   _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='${wl}-rpath,$libdir'
+	   ;;
+       esac
+      fi
+      ;;
+
+    os2*)
+      _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='-L$libdir'
+      _LT_AC_TAGVAR(hardcode_minus_L, $1)=yes
+      _LT_AC_TAGVAR(allow_undefined_flag, $1)=unsupported
+      _LT_AC_TAGVAR(archive_cmds, $1)='$echo "LIBRARY $libname INITINSTANCE" > $output_objdir/$libname.def~$echo "DESCRIPTION \"$libname\"" >> $output_objdir/$libname.def~$echo DATA >> $output_objdir/$libname.def~$echo " SINGLE NONSHARED" >> $output_objdir/$libname.def~$echo EXPORTS >> $output_objdir/$libname.def~emxexp $libobjs >> $output_objdir/$libname.def~$CC -Zdll -Zcrtdll -o $lib $libobjs $deplibs $compiler_flags $output_objdir/$libname.def'
+      _LT_AC_TAGVAR(old_archive_from_new_cmds, $1)='emximp -o $output_objdir/$libname.a $output_objdir/$libname.def'
+      ;;
+
+    osf3*)
+      if test "$GCC" = yes; then
+	_LT_AC_TAGVAR(allow_undefined_flag, $1)=' ${wl}-expect_unresolved ${wl}\*'
+	_LT_AC_TAGVAR(archive_cmds, $1)='$CC -shared${allow_undefined_flag} $libobjs $deplibs $compiler_flags ${wl}-soname ${wl}$soname `test -n "$verstring" && echo ${wl}-set_version ${wl}$verstring` ${wl}-update_registry ${wl}${output_objdir}/so_locations -o $lib'
+      else
+	_LT_AC_TAGVAR(allow_undefined_flag, $1)=' -expect_unresolved \*'
+	_LT_AC_TAGVAR(archive_cmds, $1)='$LD -shared${allow_undefined_flag} $libobjs $deplibs $linker_flags -soname $soname `test -n "$verstring" && echo -set_version $verstring` -update_registry ${output_objdir}/so_locations -o $lib'
+      fi
+      _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='${wl}-rpath ${wl}$libdir'
+      _LT_AC_TAGVAR(hardcode_libdir_separator, $1)=:
+      ;;
+
+    osf4* | osf5*)	# as osf3* with the addition of -msym flag
+      if test "$GCC" = yes; then
+	_LT_AC_TAGVAR(allow_undefined_flag, $1)=' ${wl}-expect_unresolved ${wl}\*'
+	_LT_AC_TAGVAR(archive_cmds, $1)='$CC -shared${allow_undefined_flag} $libobjs $deplibs $compiler_flags ${wl}-msym ${wl}-soname ${wl}$soname `test -n "$verstring" && echo ${wl}-set_version ${wl}$verstring` ${wl}-update_registry ${wl}${output_objdir}/so_locations -o $lib'
+	_LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='${wl}-rpath ${wl}$libdir'
+      else
+	_LT_AC_TAGVAR(allow_undefined_flag, $1)=' -expect_unresolved \*'
+	_LT_AC_TAGVAR(archive_cmds, $1)='$LD -shared${allow_undefined_flag} $libobjs $deplibs $linker_flags -msym -soname $soname `test -n "$verstring" && echo -set_version $verstring` -update_registry ${output_objdir}/so_locations -o $lib'
+	_LT_AC_TAGVAR(archive_expsym_cmds, $1)='for i in `cat $export_symbols`; do printf "%s %s\\n" -exported_symbol "\$i" >> $lib.exp; done; echo "-hidden">> $lib.exp~
+	$LD -shared${allow_undefined_flag} -input $lib.exp $linker_flags $libobjs $deplibs -soname $soname `test -n "$verstring" && echo -set_version $verstring` -update_registry ${objdir}/so_locations -o $lib~$rm $lib.exp'
+
+	# Both c and cxx compiler support -rpath directly
+	_LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='-rpath $libdir'
+      fi
+      _LT_AC_TAGVAR(hardcode_libdir_separator, $1)=:
+      ;;
+
+    sco3.2v5*)
+      _LT_AC_TAGVAR(archive_cmds, $1)='$LD -G -h $soname -o $lib $libobjs $deplibs $linker_flags'
+      _LT_AC_TAGVAR(hardcode_shlibpath_var, $1)=no
+      _LT_AC_TAGVAR(export_dynamic_flag_spec, $1)='${wl}-Bexport'
+      runpath_var=LD_RUN_PATH
+      hardcode_runpath_var=yes
+      ;;
+
+    solaris*)
+      _LT_AC_TAGVAR(no_undefined_flag, $1)=' -z text'
+      if test "$GCC" = yes; then
+	_LT_AC_TAGVAR(archive_cmds, $1)='$CC -shared ${wl}-h ${wl}$soname -o $lib $libobjs $deplibs $compiler_flags'
+	_LT_AC_TAGVAR(archive_expsym_cmds, $1)='$echo "{ global:" > $lib.exp~cat $export_symbols | $SED -e "s/\(.*\)/\1;/" >> $lib.exp~$echo "local: *; };" >> $lib.exp~
+	  $CC -shared ${wl}-M ${wl}$lib.exp ${wl}-h ${wl}$soname -o $lib $libobjs $deplibs $compiler_flags~$rm $lib.exp'
+      else
+	_LT_AC_TAGVAR(archive_cmds, $1)='$LD -G${allow_undefined_flag} -h $soname -o $lib $libobjs $deplibs $linker_flags'
+	_LT_AC_TAGVAR(archive_expsym_cmds, $1)='$echo "{ global:" > $lib.exp~cat $export_symbols | $SED -e "s/\(.*\)/\1;/" >> $lib.exp~$echo "local: *; };" >> $lib.exp~
+  	$LD -G${allow_undefined_flag} -M $lib.exp -h $soname -o $lib $libobjs $deplibs $linker_flags~$rm $lib.exp'
+      fi
+      _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='-R$libdir'
+      _LT_AC_TAGVAR(hardcode_shlibpath_var, $1)=no
+      case $host_os in
+      solaris2.[[0-5]] | solaris2.[[0-5]].*) ;;
+      *) # Supported since Solaris 2.6 (maybe 2.5.1?)
+	_LT_AC_TAGVAR(whole_archive_flag_spec, $1)='-z allextract$convenience -z defaultextract' ;;
+      esac
+      _LT_AC_TAGVAR(link_all_deplibs, $1)=yes
+      ;;
+
+    sunos4*)
+      if test "x$host_vendor" = xsequent; then
+	# Use $CC to link under sequent, because it throws in some extra .o
+	# files that make .init and .fini sections work.
+	_LT_AC_TAGVAR(archive_cmds, $1)='$CC -G ${wl}-h $soname -o $lib $libobjs $deplibs $compiler_flags'
+      else
+	_LT_AC_TAGVAR(archive_cmds, $1)='$LD -assert pure-text -Bstatic -o $lib $libobjs $deplibs $linker_flags'
+      fi
+      _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='-L$libdir'
+      _LT_AC_TAGVAR(hardcode_direct, $1)=yes
+      _LT_AC_TAGVAR(hardcode_minus_L, $1)=yes
+      _LT_AC_TAGVAR(hardcode_shlibpath_var, $1)=no
+      ;;
+
+    sysv4)
+      case $host_vendor in
+	sni)
+	  _LT_AC_TAGVAR(archive_cmds, $1)='$LD -G -h $soname -o $lib $libobjs $deplibs $linker_flags'
+	  _LT_AC_TAGVAR(hardcode_direct, $1)=yes # is this really true???
+	;;
+	siemens)
+	  ## LD is ld it makes a PLAMLIB
+	  ## CC just makes a GrossModule.
+	  _LT_AC_TAGVAR(archive_cmds, $1)='$LD -G -o $lib $libobjs $deplibs $linker_flags'
+	  _LT_AC_TAGVAR(reload_cmds, $1)='$CC -r -o $output$reload_objs'
+	  _LT_AC_TAGVAR(hardcode_direct, $1)=no
+        ;;
+	motorola)
+	  _LT_AC_TAGVAR(archive_cmds, $1)='$LD -G -h $soname -o $lib $libobjs $deplibs $linker_flags'
+	  _LT_AC_TAGVAR(hardcode_direct, $1)=no #Motorola manual says yes, but my tests say they lie
+	;;
+      esac
+      runpath_var='LD_RUN_PATH'
+      _LT_AC_TAGVAR(hardcode_shlibpath_var, $1)=no
+      ;;
+
+    sysv4.3*)
+      _LT_AC_TAGVAR(archive_cmds, $1)='$LD -G -h $soname -o $lib $libobjs $deplibs $linker_flags'
+      _LT_AC_TAGVAR(hardcode_shlibpath_var, $1)=no
+      _LT_AC_TAGVAR(export_dynamic_flag_spec, $1)='-Bexport'
+      ;;
+
+    sysv4*MP*)
+      if test -d /usr/nec; then
+	_LT_AC_TAGVAR(archive_cmds, $1)='$LD -G -h $soname -o $lib $libobjs $deplibs $linker_flags'
+	_LT_AC_TAGVAR(hardcode_shlibpath_var, $1)=no
+	runpath_var=LD_RUN_PATH
+	hardcode_runpath_var=yes
+	_LT_AC_TAGVAR(ld_shlibs, $1)=yes
+      fi
+      ;;
+
+    sysv4.2uw2*)
+      _LT_AC_TAGVAR(archive_cmds, $1)='$LD -G -o $lib $libobjs $deplibs $linker_flags'
+      _LT_AC_TAGVAR(hardcode_direct, $1)=yes
+      _LT_AC_TAGVAR(hardcode_minus_L, $1)=no
+      _LT_AC_TAGVAR(hardcode_shlibpath_var, $1)=no
+      hardcode_runpath_var=yes
+      runpath_var=LD_RUN_PATH
+      ;;
+
+   sysv5OpenUNIX8* | sysv5UnixWare7* |  sysv5uw[[78]]* | unixware7*)
+      _LT_AC_TAGVAR(no_undefined_flag, $1)='${wl}-z ${wl}text'
+      if test "$GCC" = yes; then
+	_LT_AC_TAGVAR(archive_cmds, $1)='$CC -shared ${wl}-h ${wl}$soname -o $lib $libobjs $deplibs $compiler_flags'
+      else
+	_LT_AC_TAGVAR(archive_cmds, $1)='$CC -G ${wl}-h ${wl}$soname -o $lib $libobjs $deplibs $compiler_flags'
+      fi
+      runpath_var='LD_RUN_PATH'
+      _LT_AC_TAGVAR(hardcode_shlibpath_var, $1)=no
+      ;;
+
+    sysv5*)
+      _LT_AC_TAGVAR(no_undefined_flag, $1)=' -z text'
+      # $CC -shared without GNU ld will not create a library from C++
+      # object files and a static libstdc++, better avoid it by now
+      _LT_AC_TAGVAR(archive_cmds, $1)='$LD -G${allow_undefined_flag} -h $soname -o $lib $libobjs $deplibs $linker_flags'
+      _LT_AC_TAGVAR(archive_expsym_cmds, $1)='$echo "{ global:" > $lib.exp~cat $export_symbols | $SED -e "s/\(.*\)/\1;/" >> $lib.exp~$echo "local: *; };" >> $lib.exp~
+  		$LD -G${allow_undefined_flag} -M $lib.exp -h $soname -o $lib $libobjs $deplibs $linker_flags~$rm $lib.exp'
+      _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)=
+      _LT_AC_TAGVAR(hardcode_shlibpath_var, $1)=no
+      runpath_var='LD_RUN_PATH'
+      ;;
+
+    uts4*)
+      _LT_AC_TAGVAR(archive_cmds, $1)='$LD -G -h $soname -o $lib $libobjs $deplibs $linker_flags'
+      _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='-L$libdir'
+      _LT_AC_TAGVAR(hardcode_shlibpath_var, $1)=no
+      ;;
+
+    *)
+      _LT_AC_TAGVAR(ld_shlibs, $1)=no
+      ;;
+    esac
+
+    if test x$host_vendor = xsni; then
+      case $host in
+      sysv4 | sysv4.2uw2* | sysv4.3* | sysv5*)
+	export_dynamic_flag_spec='${wl}-Blargedynsym'
+	;;
+      esac
+    fi
+  fi
+])
+AC_MSG_RESULT([$_LT_AC_TAGVAR(ld_shlibs, $1)])
+test "$_LT_AC_TAGVAR(ld_shlibs, $1)" = no && can_build_shared=no
+
+_LT_DECL([], [libext], [0], [Old archive suffix (normally "a")])dnl
+_LT_DECL([], [shrext_cmds], [1], [Shared library suffix (normally ".so")])dnl
+_LT_DECL([], [extract_expsyms_cmds], [2],
+    [The commands to extract the exported symbol list from a shared archive])
+
+variables_saved_for_relink="PATH $shlibpath_var $runpath_var"
+if test "$GCC" = yes; then
+  variables_saved_for_relink="$variables_saved_for_relink GCC_EXEC_PREFIX COMPILER_PATH LIBRARY_PATH"
+fi
+_LT_DECL([], [variables_saved_for_relink], [1],
+    [Variables whose values should be saved in libtool wrapper scripts and
+    restored at link time])
+
+#
+# Do we need to explicitly link libc?
+#
+case "x$_LT_AC_TAGVAR(archive_cmds_need_lc, $1)" in
+x|xyes)
+  # Assume -lc should be added
+  _LT_AC_TAGVAR(archive_cmds_need_lc, $1)=yes
+
+  if test "$enable_shared" = yes && test "$GCC" = yes; then
+    case $_LT_AC_TAGVAR(archive_cmds, $1) in
+    *'~'*)
+      # FIXME: we may have to deal with multi-command sequences.
+      ;;
+    '$CC '*)
+      # Test whether the compiler implicitly links with -lc since on some
+      # systems, -lgcc has to come before -lc. If gcc already passes -lc
+      # to ld, don't add -lc before -lgcc.
+      AC_MSG_CHECKING([whether -lc should be explicitly linked in])
+      $rm conftest*
+      printf "$lt_simple_compile_test_code" > conftest.$ac_ext
+
+      if AC_TRY_EVAL(ac_compile) 2>conftest.err; then
+        soname=conftest
+        lib=conftest
+        libobjs=conftest.$ac_objext
+        deplibs=
+        wl=$_LT_AC_TAGVAR(lt_prog_compiler_wl, $1)
+        compiler_flags=-v
+        linker_flags=-v
+        verstring=
+        output_objdir=.
+        libname=conftest
+        lt_save_allow_undefined_flag=$_LT_AC_TAGVAR(allow_undefined_flag, $1)
+        _LT_AC_TAGVAR(allow_undefined_flag, $1)=
+        if AC_TRY_EVAL(_LT_AC_TAGVAR(archive_cmds, $1) 2\>\&1 \| $GREP \" -lc \" \>/dev/null 2\>\&1)
+        then
+	  _LT_AC_TAGVAR(archive_cmds_need_lc, $1)=no
+        else
+	  _LT_AC_TAGVAR(archive_cmds_need_lc, $1)=yes
+        fi
+        _LT_AC_TAGVAR(allow_undefined_flag, $1)=$lt_save_allow_undefined_flag
+      else
+        cat conftest.err 1>&5
+      fi
+      $rm conftest*
+      AC_MSG_RESULT([$_LT_AC_TAGVAR(archive_cmds_need_lc, $1)])
+      ;;
+    esac
+  fi
+  ;;
+esac
+
+_LT_TAGDECL([build_libtool_need_lc], [archive_cmds_need_lc], [0],
+    [Whether or not to add -lc for building shared libraries])
+_LT_TAGDECL([allow_libtool_libs_with_static_runtimes],
+    [enable_shared_with_static_runtimes], [0],
+    [Whether or not to disallow shared libs when runtime libs are static])
+_LT_TAGDECL([], [export_dynamic_flag_spec], [1],
+    [Compiler flag to allow reflexive dlopens])
+_LT_TAGDECL([], [whole_archive_flag_spec], [1],
+    [Compiler flag to generate shared objects directly from archives])
+_LT_TAGDECL([], [old_archive_from_new_cmds], [2],
+    [Create an old-style archive from a shared archive])
+_LT_TAGDECL([], [old_archive_from_expsyms_cmds], [2],
+    [Create a temporary old-style archive to link instead of a shared archive])
+_LT_TAGDECL([], [archive_cmds], [2], [Commands used to build a shared archive])
+_LT_TAGDECL([], [archive_expsym_cmds], [2])
+_LT_TAGDECL([], [module_cmds], [2],
+    [Commands used to build a loadable module if different from building
+    a shared archive.])
+_LT_TAGDECL([], [module_expsym_cmds], [2])
+_LT_TAGDECL([], [allow_undefined_flag], [1],
+    [Flag that allows shared libraries with undefined symbols to be built])
+_LT_TAGDECL([], [no_undefined_flag], [1],
+    [Flag that enforces no undefined symbols])
+_LT_TAGDECL([], [hardcode_libdir_flag_spec], [1],
+    [Flag to hardcode $libdir into a binary during linking.
+    This must work even if $libdir does not exist])
+_LT_TAGDECL([], [hardcode_libdir_flag_spec_ld], [1],
+    [If ld is used when linking, flag to hardcode $libdir into a binary
+    during linking.  This must work even if $libdir does not exist])
+_LT_TAGDECL([], [hardcode_libdir_separator], [1],
+    [Whether we need a single "-rpath" flag with a separated argument])
+_LT_TAGDECL([], [hardcode_direct], [0],
+    [Set to "yes" if using DIR/libNAME${shared_ext} during linking hardcodes
+    DIR into the resulting binary])
+_LT_TAGDECL([], [hardcode_minus_L], [0],
+    [Set to "yes" if using the -LDIR flag during linking hardcodes DIR
+    into the resulting binary])
+_LT_TAGDECL([], [hardcode_shlibpath_var], [0],
+    [Set to "yes" if using SHLIBPATH_VAR=DIR during linking hardcodes DIR
+    into the resulting binary])
+_LT_TAGDECL([], [hardcode_automatic], [0],
+    [Set to "yes" if building a shared library automatically hardcodes DIR
+    into the library and all subsequent libraries and executables linked
+    against it])
+_LT_TAGDECL([], [inherit_rpath], [0],
+    [Set to yes if linker adds runtime paths of dependent libraries
+    to runtime path list])
+_LT_TAGDECL([], [link_all_deplibs], [0],
+    [Whether libtool must link a program against all its dependency libraries])
+_LT_TAGDECL([], [fix_srcfile_path], [1],
+    [Fix the shell variable $srcfile for the compiler])
+_LT_TAGDECL([], [always_export_symbols], [0],
+    [Set to "yes" if exported symbols are required])
+_LT_TAGDECL([], [export_symbols_cmds], [2],
+    [The commands to list exported symbols])
+_LT_TAGDECL([], [exclude_expsyms], [1],
+    [Symbols that should not be listed in the preloaded symbols])
+_LT_TAGDECL([], [include_expsyms], [1],
+    [Symbols that must always be exported])
+dnl FIXME: Not yet implemented
+dnl _LT_TAGDECL([], [thread_safe_flag_spec], [1],
+dnl    [Compiler flag to generate thread safe objects])
+])# AC_LIBTOOL_PROG_LD_SHLIBS
+
+
+# _LT_LANG_C_CONFIG([TAG])
+# ------------------------
+# Ensure that the configuration variables for a C compiler are suitably
+# defined.  These variables are subsequently used by _LT_CONFIG to write
+# the compiler configuration to `libtool'.
+m4_define([_LT_LANG_C_CONFIG],
+[AC_REQUIRE([LT_AC_PROG_EGREP])
+lt_save_CC="$CC"
+AC_LANG_PUSH(C)
+
+# Source file extension for C test sources.
+ac_ext=c
+
+# Object file extension for compiled C test sources.
+objext=o
+_LT_AC_TAGVAR(objext, $1)=$objext
+
+# Code to be used in simple compile tests
+lt_simple_compile_test_code="int some_variable = 0;\n"
+
+# Code to be used in simple link tests
+lt_simple_link_test_code='int main(){return(0);}\n'
+
+_LT_AC_SYS_COMPILER
+# Save the default compiler, since it gets overwritten when the other
+# tags are being tested, and _LT_AC_TAGVAR(compiler, []) is a NOP.
+compiler_DEFAULT=$CC
+
+#
+# Check for any special shared library compilation flags.
+#
+_LT_AC_TAGVAR(lt_prog_cc_shlib, $1)=
+if test "$GCC" = no; then
+  case $host_os in
+  sco3.2v5*)
+    _LT_AC_TAGVAR(lt_prog_cc_shlib, $1)='-belf'
+    ;;
+  esac
+fi
+if test -n "$_LT_AC_TAGVAR(lt_prog_cc_shlib, $1)"; then
+  AC_MSG_WARN([`$CC' requires `$_LT_AC_TAGVAR(lt_prog_cc_shlib, $1)' to build shared libraries])
+  if echo "$old_CC $old_CFLAGS " | $GREP "[[ 	]]$_LT_AC_TAGVAR(lt_prog_cc_shlib, $1)[[ 	]]" >/dev/null; then :
+  else
+    AC_MSG_WARN([add `$_LT_AC_TAGVAR(lt_prog_cc_shlib, $1)' to the CC or CFLAGS env variable and reconfigure])
+    _LT_AC_TAGVAR(lt_cv_prog_cc_can_build_shared, $1)=no
+  fi
+fi
+
+
+## CAVEAT EMPTOR:
+## There is no encapsulation within the following macros, do not change
+## the running order or otherwise move them around unless you know exactly
+## what you are doing...
+if test -n "$compiler"; then
+  AC_LIBTOOL_PROG_COMPILER_NO_RTTI($1)
+  AC_LIBTOOL_PROG_COMPILER_PIC($1)
+  AC_LIBTOOL_PROG_CC_C_O($1)
+  AC_LIBTOOL_SYS_HARD_LINK_LOCKS($1)
+  AC_LIBTOOL_PROG_LD_SHLIBS($1)
+  AC_LIBTOOL_SYS_DYNAMIC_LINKER($1)
+  AC_LIBTOOL_PROG_LD_HARDCODE_LIBPATH($1)
+  AC_LIBTOOL_SYS_LIB_STRIP
+  AC_LIBTOOL_DLOPEN_SELF($1)
+
+  # Report which library types will actually be built
+  AC_MSG_CHECKING([if libtool supports shared libraries])
+  AC_MSG_RESULT([$can_build_shared])
+
+  AC_MSG_CHECKING([whether to build shared libraries])
+  test "$can_build_shared" = "no" && enable_shared=no
+
+  # On AIX, shared libraries and static libraries use the same namespace, and
+  # are all built from PIC.
+  case "$host_os" in
+  aix3*)
+    test "$enable_shared" = yes && enable_static=no
+    if test -n "$RANLIB"; then
+      archive_cmds="$archive_cmds~\$RANLIB \$lib"
+      postinstall_cmds='$RANLIB $lib'
+    fi
+    ;;
+
+  aix4* | aix5*)
+    if test "$host_cpu" != ia64 && test "$aix_use_runtimelinking" = no ; then
+      test "$enable_shared" = yes && enable_static=no
+    fi
+    ;;
+  esac
+  AC_MSG_RESULT([$enable_shared])
+
+  AC_MSG_CHECKING([whether to build static libraries])
+  # Make sure either enable_shared or enable_static is yes.
+  test "$enable_shared" = yes || enable_static=yes
+  AC_MSG_RESULT([$enable_static])
+
+  _LT_CONFIG($1)
+fi
+AC_LANG_POP
+CC="$lt_save_CC"
+])# _LT_LANG_C_CONFIG
+
+
+# _LT_LANG_CXX_CONFIG([TAG])
+# --------------------------
+# Ensure that the configuration variables for a C++ compiler are suitably
+# defined.  These variables are subsequently used by _LT_CONFIG to write
+# the compiler configuration to `libtool'.
+m4_define([_LT_LANG_CXX_CONFIG],
+[AC_LANG_PUSH(C++)
+AC_REQUIRE([LT_AC_PROG_EGREP])
+AC_REQUIRE([AC_PROG_CXX])
+AC_REQUIRE([AC_PROG_CXXCPP])
+
+_LT_AC_TAGVAR(archive_cmds_need_lc, $1)=no
+_LT_AC_TAGVAR(allow_undefined_flag, $1)=
+_LT_AC_TAGVAR(always_export_symbols, $1)=no
+_LT_AC_TAGVAR(archive_expsym_cmds, $1)=
+_LT_AC_TAGVAR(export_dynamic_flag_spec, $1)=
+_LT_AC_TAGVAR(hardcode_direct, $1)=no
+_LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)=
+_LT_AC_TAGVAR(hardcode_libdir_flag_spec_ld, $1)=
+_LT_AC_TAGVAR(hardcode_libdir_separator, $1)=
+_LT_AC_TAGVAR(hardcode_minus_L, $1)=no
+_LT_AC_TAGVAR(hardcode_automatic, $1)=no
+_LT_AC_TAGVAR(inherit_rpath, $1)=no
+_LT_AC_TAGVAR(module_cmds, $1)=
+_LT_AC_TAGVAR(module_expsym_cmds, $1)=
+_LT_AC_TAGVAR(link_all_deplibs, $1)=unknown
+_LT_AC_TAGVAR(old_archive_cmds, $1)=$old_archive_cmds
+_LT_AC_TAGVAR(no_undefined_flag, $1)=
+_LT_AC_TAGVAR(whole_archive_flag_spec, $1)=
+_LT_AC_TAGVAR(enable_shared_with_static_runtimes, $1)=no
+
+# Source file extension for C++ test sources.
+ac_ext=cc
+
+# Object file extension for compiled C++ test sources.
+objext=o
+_LT_AC_TAGVAR(objext, $1)=$objext
+
+# Code to be used in simple compile tests
+lt_simple_compile_test_code="int some_variable = 0;\n"
+
+# Code to be used in simple link tests
+lt_simple_link_test_code='int main(int, char *[]) { return(0); }\n'
+
+# ltmain only uses $CC for tagged configurations so make sure $CC is set.
+_LT_AC_SYS_COMPILER
+
+# Allow CC to be a program name with arguments.
+lt_save_CC=$CC
+lt_save_LD=$LD
+lt_save_GCC=$GCC
+GCC=$GXX
+lt_save_with_gnu_ld=$with_gnu_ld
+lt_save_path_LD=$lt_cv_path_LD
+if test -n "${lt_cv_prog_gnu_ldcxx+set}"; then
+  lt_cv_prog_gnu_ld=$lt_cv_prog_gnu_ldcxx
+else
+  unset lt_cv_prog_gnu_ld
+fi
+if test -n "${lt_cv_path_LDCXX+set}"; then
+  lt_cv_path_LD=$lt_cv_path_LDCXX
+else
+  unset lt_cv_path_LD
+fi
+test -z "${LDCXX+set}" || LD=$LDCXX
+CC=${CXX-"c++"}
+compiler=$CC
+_LT_AC_TAGVAR(compiler, $1)=$CC
+cc_basename=`$echo X"$compiler" | $Xsed -e 's%^.*/%%'`
+
+if test -n "$compiler"; then
+  # We don't want -fno-exception when compiling C++ code, so set the
+  # no_builtin_flag separately
+  if test "$GXX" = yes; then
+    _LT_AC_TAGVAR(lt_prog_compiler_no_builtin_flag, $1)=' -fno-builtin'
+  else
+    _LT_AC_TAGVAR(lt_prog_compiler_no_builtin_flag, $1)=
+  fi
+
+  if test "$GXX" = yes; then
+    # Set up default GNU C++ configuration
+
+    AC_PROG_LD
+
+    # Check if GNU C++ uses GNU ld as the underlying linker, since the
+    # archiving commands below assume that GNU ld is being used.
+    if test "$with_gnu_ld" = yes; then
+      _LT_AC_TAGVAR(archive_cmds, $1)='$CC -shared -nostdlib $predep_objects $libobjs $deplibs $postdep_objects $compiler_flags ${wl}-soname $wl$soname -o $lib'
+      _LT_AC_TAGVAR(archive_expsym_cmds, $1)='$CC -shared -nostdlib $predep_objects $libobjs $deplibs $postdep_objects $compiler_flags ${wl}-soname $wl$soname ${wl}-retain-symbols-file $wl$export_symbols -o $lib'
+
+      _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='${wl}--rpath ${wl}$libdir'
+      _LT_AC_TAGVAR(export_dynamic_flag_spec, $1)='${wl}--export-dynamic'
+
+      # If archive_cmds runs LD, not CC, wlarc should be empty
+      # XXX I think wlarc can be eliminated in ltcf-cxx, but I need to
+      #     investigate it a little bit more. (MM)
+      wlarc='${wl}'
+
+      # ancient GNU ld didn't support --whole-archive et. al.
+      if eval "`$CC -print-prog-name=ld` --help 2>&1" |
+  	$GREP 'no-whole-archive' > /dev/null; then
+        _LT_AC_TAGVAR(whole_archive_flag_spec, $1)="$wlarc"'--whole-archive$convenience '"$wlarc"'--no-whole-archive'
+      else
+        _LT_AC_TAGVAR(whole_archive_flag_spec, $1)=
+      fi
+    else
+      with_gnu_ld=no
+      wlarc=
+
+      # A generic and very simple default shared library creation
+      # command for GNU C++ for the case where it uses the native
+      # linker, instead of GNU ld.  If possible, this setting should
+      # overridden to take advantage of the native linker features on
+      # the platform it is being used on.
+      _LT_AC_TAGVAR(archive_cmds, $1)='$CC -shared -nostdlib $predep_objects $libobjs $deplibs $postdep_objects $compiler_flags -o $lib'
+    fi
+
+    # Commands to make compiler produce verbose output that lists
+    # what "hidden" libraries, object files and flags are used when
+    # linking a shared library.
+    output_verbose_link_cmd='$CC -shared $CFLAGS -v conftest.$objext 2>&1 | $GREP "\-L"'
+
+  else
+    GXX=no
+    with_gnu_ld=no
+    wlarc=
+  fi
+
+  # PORTME: fill in a description of your system's C++ link characteristics
+  AC_MSG_CHECKING([whether the $compiler linker ($LD) supports shared libraries])
+  _LT_AC_TAGVAR(ld_shlibs, $1)=yes
+  case $host_os in
+    aix3*)
+      # FIXME: insert proper C++ library support
+      _LT_AC_TAGVAR(ld_shlibs, $1)=no
+      ;;
+    aix4* | aix5*)
+      if test "$host_cpu" = ia64; then
+        # On IA64, the linker does run time linking by default, so we don't
+        # have to do anything special.
+        aix_use_runtimelinking=no
+        exp_sym_flag='-Bexport'
+        no_entry_flag=""
+      else
+        aix_use_runtimelinking=no
+
+        # Test if we are trying to use run time linking or normal
+        # AIX style linking. If -brtl is somewhere in LDFLAGS, we
+        # need to do runtime linking.
+        case $host_os in aix4.[[23]]|aix4.[[23]].*|aix5*)
+  	for ld_flag in $LDFLAGS; do
+  	  case $ld_flag in
+  	  *-brtl*)
+  	    aix_use_runtimelinking=yes
+  	    break
+  	    ;;
+  	  esac
+  	done
+        esac
+
+        exp_sym_flag='-bexport'
+        no_entry_flag='-bnoentry'
+      fi
+
+      # When large executables or shared objects are built, AIX ld can
+      # have problems creating the table of contents.  If linking a library
+      # or program results in "error TOC overflow" add -mminimal-toc to
+      # CXXFLAGS/CFLAGS for g++/gcc.  In the cases where that is not
+      # enough to fix the problem, add -Wl,-bbigtoc to LDFLAGS.
+
+      _LT_AC_TAGVAR(archive_cmds, $1)=''
+      _LT_AC_TAGVAR(hardcode_direct, $1)=yes
+      _LT_AC_TAGVAR(hardcode_libdir_separator, $1)=':'
+      _LT_AC_TAGVAR(link_all_deplibs, $1)=yes
+
+      if test "$GXX" = yes; then
+        case $host_os in aix4.[012]|aix4.[012].*)
+        # We only want to do this on AIX 4.2 and lower, the check
+        # below for broken collect2 doesn't work under 4.3+
+  	collect2name=`${CC} -print-prog-name=collect2`
+  	if test -f "$collect2name" &&
+  	   strings "$collect2name" | $GREP resolve_lib_name >/dev/null
+  	then
+  	  # We have reworked collect2
+  	  _LT_AC_TAGVAR(hardcode_direct, $1)=yes
+  	else
+  	  # We have old collect2
+  	  _LT_AC_TAGVAR(hardcode_direct, $1)=unsupported
+  	  # It fails to find uninstalled libraries when the uninstalled
+  	  # path is not listed in the libpath.  Setting hardcode_minus_L
+  	  # to unsupported forces relinking
+  	  _LT_AC_TAGVAR(hardcode_minus_L, $1)=yes
+  	  _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='-L$libdir'
+  	  _LT_AC_TAGVAR(hardcode_libdir_separator, $1)=
+  	fi
+        esac
+        shared_flag='-shared'
+      else
+        # not using gcc
+        if test "$host_cpu" = ia64; then
+  	# VisualAge C++, Version 5.5 for AIX 5L for IA-64, Beta 3 Release
+  	# chokes on -Wl,-G. The following line is correct:
+  	shared_flag='-G'
+        else
+  	if test "$aix_use_runtimelinking" = yes; then
+  	  shared_flag='${wl}-G'
+  	else
+  	  shared_flag='${wl}-bM:SRE'
+  	fi
+        fi
+      fi
+
+      # It seems that -bexpall does not export symbols beginning with
+      # underscore (_), so it is better to generate a list of symbols to export.
+      _LT_AC_TAGVAR(always_export_symbols, $1)=yes
+      if test "$aix_use_runtimelinking" = yes; then
+        # Warning - without using the other runtime loading flags (-brtl),
+        # -berok will link without error, but may produce a broken library.
+        _LT_AC_TAGVAR(allow_undefined_flag, $1)='-berok'
+        # Determine the default libpath from the value encoded in an empty
+        # executable.
+        _LT_AC_SYS_LIBPATH_AIX
+        _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='${wl}-blibpath:$libdir:'"$aix_libpath"
+
+        _LT_AC_TAGVAR(archive_expsym_cmds, $1)="\$CC"' -o $output_objdir/$soname $libobjs $deplibs $compiler_flags `if test "x${allow_undefined_flag}" != "x"; then echo "${wl}${allow_undefined_flag}"; else :; fi` '"\${wl}$no_entry_flag \${wl}$exp_sym_flag:\$export_symbols $shared_flag"
+       else
+        if test "$host_cpu" = ia64; then
+  	_LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='${wl}-R $libdir:/usr/lib:/lib'
+  	_LT_AC_TAGVAR(allow_undefined_flag, $1)="-z nodefs"
+  	_LT_AC_TAGVAR(archive_expsym_cmds, $1)="\$CC $shared_flag"' -o $output_objdir/$soname $libobjs $deplibs $compiler_flags ${wl}${allow_undefined_flag} '"\${wl}$no_entry_flag \${wl}$exp_sym_flag:\$export_symbols"
+        else
+  	# Determine the default libpath from the value encoded in an
+  	# empty executable.
+  	_LT_AC_SYS_LIBPATH_AIX
+  	_LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='${wl}-blibpath:$libdir:'"$aix_libpath"
+  	# Warning - without using the other run time loading flags,
+  	# -berok will link without error, but may produce a broken library.
+  	_LT_AC_TAGVAR(no_undefined_flag, $1)=' ${wl}-bernotok'
+  	_LT_AC_TAGVAR(allow_undefined_flag, $1)=' ${wl}-berok'
+  	# -bexpall does not export symbols beginning with underscore (_)
+  	_LT_AC_TAGVAR(always_export_symbols, $1)=yes
+  	# Exported symbols can be pulled into shared objects from archives
+  	_LT_AC_TAGVAR(whole_archive_flag_spec, $1)=' '
+  	_LT_AC_TAGVAR(archive_cmds_need_lc, $1)=yes
+  	# This is similar to how AIX traditionally builds it's shared libraries.
+  	_LT_AC_TAGVAR(archive_expsym_cmds, $1)="\$CC $shared_flag"' -o $output_objdir/$soname $libobjs $deplibs $compiler_flags ${wl}-bE:$export_symbols ${wl}-bnoentry${allow_undefined_flag}~$AR $AR_FLAGS $output_objdir/$libname$release.a $output_objdir/$soname'
+        fi
+      fi
+      ;;
+    chorus*)
+      case $cc_basename in
+        *)
+  	# FIXME: insert proper C++ library support
+  	_LT_AC_TAGVAR(ld_shlibs, $1)=no
+  	;;
+      esac
+      ;;
+
+    cygwin* | mingw* | pw32*)
+      # _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1) is actually meaningless,
+      # as there is no search path for DLLs.
+      _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='-L$libdir'
+      _LT_AC_TAGVAR(allow_undefined_flag, $1)=unsupported
+      _LT_AC_TAGVAR(always_export_symbols, $1)=no
+      _LT_AC_TAGVAR(enable_shared_with_static_runtimes, $1)=yes
+
+      if $LD --help 2>&1 | $GREP 'auto-import' > /dev/null; then
+        _LT_AC_TAGVAR(archive_cmds, $1)='$CC -shared -nostdlib $predep_objects $libobjs $deplibs $postdep_objects $compiler_flags -o $output_objdir/$soname ${wl}--image-base=0x10000000 ${wl}--out-implib,$lib'
+        # If the export-symbols file already is a .def file (1st line
+        # is EXPORTS), use it as is; otherwise, prepend...
+        _LT_AC_TAGVAR(archive_expsym_cmds, $1)='if test "x`$SED 1q $export_symbols`" = xEXPORTS; then
+  	cp $export_symbols $output_objdir/$soname.def;
+        else
+  	echo EXPORTS > $output_objdir/$soname.def;
+  	cat $export_symbols >> $output_objdir/$soname.def;
+        fi~
+        $CC -shared -nostdlib $output_objdir/$soname.def $predep_objects $libobjs $deplibs $postdep_objects $compiler_flags -o $output_objdir/$soname ${wl}--image-base=0x10000000 ${wl}--out-implib,$lib'
+      else
+        _LT_AC_TAGVAR(ld_shlibs, $1)=no
+      fi
+    ;;
+      darwin* | rhapsody*)
+        case "$host_os" in
+        rhapsody* | darwin1.[[012]])
+         _LT_AC_TAGVAR(allow_undefined_flag, $1)='${wl}-undefined ${wl}suppress'
+         ;;
+       *) # Darwin 1.3 on
+         if test -z ${MACOSX_DEPLOYMENT_TARGET} ; then
+           _LT_AC_TAGVAR(allow_undefined_flag, $1)='${wl}-flat_namespace ${wl}-undefined ${Wl}suppress'
+         else
+           case ${MACOSX_DEPLOYMENT_TARGET} in
+             10.[[012]])
+               _LT_AC_TAGVAR(allow_undefined_flag, $1)='${wl}-flat_namespace ${wl}-undefined ${wl}suppress'
+               ;;
+             10.*)
+               _LT_AC_TAGVAR(allow_undefined_flag, $1)='${wl}-undefined ${wl}dynamic_lookup'
+               ;;
+           esac
+         fi
+         ;;
+        esac
+      _LT_AC_TAGVAR(archive_cmds_need_lc, $1)=no
+      _LT_AC_TAGVAR(hardcode_direct, $1)=no
+      _LT_AC_TAGVAR(hardcode_automatic, $1)=yes
+      _LT_AC_TAGVAR(hardcode_shlibpath_var, $1)=unsupported
+      _LT_AC_TAGVAR(whole_archive_flag_spec, $1)='-all_load $convenience'
+      _LT_AC_TAGVAR(link_all_deplibs, $1)=yes
+
+    if test "$GXX" = yes ; then
+      lt_int_apple_cc_single_mod=no
+      output_verbose_link_cmd='echo'
+      if $CC -dumpspecs 2>&1 | $GREP 'single_module' >/dev/null ; then
+       lt_int_apple_cc_single_mod=yes
+      fi
+      if test "X$lt_int_apple_cc_single_mod" = Xyes ; then
+       _LT_AC_TAGVAR(archive_cmds, $1)='$CC -dynamiclib -single_module $allow_undefined_flag -o $lib $libobjs $deplibs $compiler_flags -install_name $rpath/$soname $verstring'
+      else
+          _LT_AC_TAGVAR(archive_cmds, $1)='$CC -r -keep_private_externs -nostdlib -o ${lib}-master.o $libobjs~$CC -dynamiclib $allow_undefined_flag -o $lib ${lib}-master.o $deplibs $compiler_flags -install_name $rpath/$soname $verstring'
+        fi
+        _LT_AC_TAGVAR(module_cmds, $1)='$CC $allow_undefined_flag -o $lib -bundle $libobjs $deplibs$compiler_flags'
+        # Don't fix this by using the ld -exported_symbols_list flag, it doesn't exist in older darwin ld's
+          if test "X$lt_int_apple_cc_single_mod" = Xyes ; then
+            _LT_AC_TAGVAR(archive_expsym_cmds, $1)='sed -e "s,#.*,," -e "s,^[    ]*,," -e "s,^\(..*\),_&," < $export_symbols > $output_objdir/${libname}-symbols.expsym~$CC -dynamiclib -single_module $allow_undefined_flag -o $lib $libobjs $deplibs $compiler_flags -install_name $rpath/$soname $verstring~nmedit -s $output_objdir/${libname}-symbols.expsym ${lib}'
+          else
+            _LT_AC_TAGVAR(archive_expsym_cmds, $1)='sed -e "s,#.*,," -e "s,^[    ]*,," -e "s,^\(..*\),_&," < $export_symbols > $output_objdir/${libname}-symbols.expsym~$CC -r -keep_private_externs -nostdlib -o ${lib}-master.o $libobjs~$CC -dynamiclib $allow_undefined_flag -o $lib ${lib}-master.o $deplibs $compiler_flags -install_name $rpath/$soname $verstring~nmedit -s $output_objdir/${libname}-symbols.expsym ${lib}'
+          fi
+            _LT_AC_TAGVAR(module_expsym_cmds, $1)='sed -e "s,#.*,," -e "s,^[    ]*,," -e "s,^\(..*\),_&," < $export_symbols > $output_objdir/${libname}-symbols.expsym~$CC $allow_undefined_flag  -o $lib -bundle $libobjs $deplibs$compiler_flags~nmedit -s $output_objdir/${libname}-symbols.expsym ${lib}'
+      else
+      case "$cc_basename" in
+        xlc*)
+         output_verbose_link_cmd='echo'
+          _LT_AC_TAGVAR(archive_cmds, $1)='$CC -qmkshrobj ${wl}-single_module $allow_undefined_flag -o $lib $libobjs $deplibs $compiler_flags ${wl}-install_name ${wl}`echo $rpath/$soname` $verstring'
+          _LT_AC_TAGVAR(module_cmds, $1)='$CC $allow_undefined_flag -o $lib -bundle $libobjs $deplibs$compiler_flags'
+          # Don't fix this by using the ld -exported_symbols_list flag, it doesn't exist in older darwin ld's
+          _LT_AC_TAGVAR(archive_expsym_cmds, $1)='sed -e "s,#.*,," -e "s,^[    ]*,," -e "s,^\(..*\),_&," < $export_symbols > $output_objdir/${libname}-symbols.expsym~$CC -qmkshrobj ${wl}-single_module $allow_undefined_flag -o $lib $libobjs $deplibs $compiler_flags ${wl}-install_name ${wl}$rpath/$soname $verstring~nmedit -s $output_objdir/${libname}-symbols.expsym ${lib}'
+          _LT_AC_TAGVAR(module_expsym_cmds, $1)='sed -e "s,#.*,," -e "s,^[    ]*,," -e "s,^\(..*\),_&," < $export_symbols > $output_objdir/${libname}-symbols.expsym~$CC $allow_undefined_flag  -o $lib -bundle $libobjs $deplibs$compiler_flags~nmedit -s $output_objdir/${libname}-symbols.expsym ${lib}'
+          ;;
+       *)
+         _LT_AC_TAGVAR(ld_shlibs, $1)=no
+          ;;
+      esac
+      fi
+        ;;
+
+    dgux*)
+      case $cc_basename in
+        ec++)
+  	# FIXME: insert proper C++ library support
+  	_LT_AC_TAGVAR(ld_shlibs, $1)=no
+  	;;
+        ghcx)
+  	# Green Hills C++ Compiler
+  	# FIXME: insert proper C++ library support
+  	_LT_AC_TAGVAR(ld_shlibs, $1)=no
+  	;;
+        *)
+  	# FIXME: insert proper C++ library support
+  	_LT_AC_TAGVAR(ld_shlibs, $1)=no
+  	;;
+      esac
+      ;;
+    freebsd[12]*)
+      # C++ shared libraries reported to be fairly broken before switch to ELF
+      _LT_AC_TAGVAR(ld_shlibs, $1)=no
+      ;;
+    freebsd-elf*)
+      _LT_AC_TAGVAR(archive_cmds_need_lc, $1)=no
+      ;;
+    freebsd* | kfreebsd*-gnu)
+      # FreeBSD 3 and later use GNU C++ and GNU ld with standard ELF
+      # conventions
+      _LT_AC_TAGVAR(ld_shlibs, $1)=yes
+      ;;
+    gnu*)
+      ;;
+    hpux9*)
+      _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='${wl}+b ${wl}$libdir'
+      _LT_AC_TAGVAR(hardcode_libdir_separator, $1)=:
+      _LT_AC_TAGVAR(export_dynamic_flag_spec, $1)='${wl}-E'
+      _LT_AC_TAGVAR(hardcode_direct, $1)=yes
+      _LT_AC_TAGVAR(hardcode_minus_L, $1)=yes # Not in the search PATH,
+  				# but as the default
+  				# location of the library.
+
+      case $cc_basename in
+      CC)
+        # FIXME: insert proper C++ library support
+        _LT_AC_TAGVAR(ld_shlibs, $1)=no
+        ;;
+      aCC)
+        _LT_AC_TAGVAR(archive_cmds, $1)='$rm $output_objdir/$soname~$CC -b ${wl}+b ${wl}$install_libdir -o $output_objdir/$soname $predep_objects $libobjs $deplibs $postdep_objects $compiler_flags~test $output_objdir/$soname = $lib || mv $output_objdir/$soname $lib'
+        # Commands to make compiler produce verbose output that lists
+        # what "hidden" libraries, object files and flags are used when
+        # linking a shared library.
+        #
+        # There doesn't appear to be a way to prevent this compiler from
+        # explicitly linking system object files so we need to strip them
+        # from the output so that they don't get included in the library
+        # dependencies.
+        output_verbose_link_cmd='templist=`($CC -b $CFLAGS -v conftest.$objext 2>&1) | $EGREP "\-L"`; list=""; for z in $templist; do case $z in conftest.$objext) list="$list $z";; *.$objext);; *) list="$list $z";;esac; done; echo $list'
+        ;;
+      *)
+        if test "$GXX" = yes; then
+          _LT_AC_TAGVAR(archive_cmds, $1)='$rm $output_objdir/$soname~$CC -shared -nostdlib -fPIC ${wl}+b ${wl}$install_libdir -o $output_objdir/$soname $predep_objects $libobjs $deplibs $postdep_objects $compiler_flags~test $output_objdir/$soname = $lib || mv $output_objdir/$soname $lib'
+        else
+          # FIXME: insert proper C++ library support
+          _LT_AC_TAGVAR(ld_shlibs, $1)=no
+        fi
+        ;;
+      esac
+      ;;
+    hpux10*|hpux11*)
+      if test $with_gnu_ld = no; then
+        case "$host_cpu" in
+        hppa*64*)
+  	_LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='${wl}+b ${wl}$libdir'
+  	_LT_AC_TAGVAR(hardcode_libdir_flag_spec_ld, $1)='+b $libdir'
+  	_LT_AC_TAGVAR(hardcode_libdir_separator, $1)=:
+          ;;
+        ia64*)
+  	_LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='-L$libdir'
+          ;;
+        *)
+  	_LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='${wl}+b ${wl}$libdir'
+  	_LT_AC_TAGVAR(hardcode_libdir_separator, $1)=:
+  	_LT_AC_TAGVAR(export_dynamic_flag_spec, $1)='${wl}-E'
+          ;;
+        esac
+      fi
+      case "$host_cpu" in
+      hppa*64*)
+        _LT_AC_TAGVAR(hardcode_direct, $1)=no
+        _LT_AC_TAGVAR(hardcode_shlibpath_var, $1)=no
+        ;;
+      ia64*)
+        _LT_AC_TAGVAR(hardcode_direct, $1)=no
+        _LT_AC_TAGVAR(hardcode_shlibpath_var, $1)=no
+        _LT_AC_TAGVAR(hardcode_minus_L, $1)=yes # Not in the search PATH,
+  					      # but as the default
+  					      # location of the library.
+        ;;
+      *)
+        _LT_AC_TAGVAR(hardcode_direct, $1)=yes
+        _LT_AC_TAGVAR(hardcode_minus_L, $1)=yes # Not in the search PATH,
+  					      # but as the default
+  					      # location of the library.
+        ;;
+      esac
+
+      case $cc_basename in
+        CC)
+  	# FIXME: insert proper C++ library support
+  	_LT_AC_TAGVAR(ld_shlibs, $1)=no
+  	;;
+        aCC)
+  	case "$host_cpu" in
+  	hppa*64*|ia64*)
+  	  _LT_AC_TAGVAR(archive_cmds, $1)='$LD -b +h $soname -o $lib $linker_flags $libobjs $deplibs'
+  	  ;;
+  	*)
+  	  _LT_AC_TAGVAR(archive_cmds, $1)='$CC -b ${wl}+h ${wl}$soname ${wl}+b ${wl}$install_libdir -o $lib $predep_objects $libobjs $deplibs $postdep_objects $compiler_flags'
+  	  ;;
+  	esac
+  	# Commands to make compiler produce verbose output that lists
+  	# what "hidden" libraries, object files and flags are used when
+  	# linking a shared library.
+  	#
+  	# There doesn't appear to be a way to prevent this compiler from
+  	# explicitly linking system object files so we need to strip them
+  	# from the output so that they don't get included in the library
+  	# dependencies.
+  	output_verbose_link_cmd='templist=`($CC -b $CFLAGS -v conftest.$objext 2>&1) | $GREP "\-L"`; list=""; for z in $templist; do case $z in conftest.$objext) list="$list $z";; *.$objext);; *) list="$list $z";;esac; done; echo $list'
+  	;;
+        *)
+  	if test "$GXX" = yes; then
+  	  if test $with_gnu_ld = no; then
+  	    case "$host_cpu" in
+  	    ia64*|hppa*64*)
+  	      _LT_AC_TAGVAR(archive_cmds, $1)='$LD -b +h $soname -o $lib $linker_flags $libobjs $deplibs'
+  	      ;;
+  	    *)
+  	      _LT_AC_TAGVAR(archive_cmds, $1)='$CC -shared -nostdlib -fPIC ${wl}+h ${wl}$soname ${wl}+b ${wl}$install_libdir -o $lib $predep_objects $libobjs $deplibs $postdep_objects $compiler_flags'
+  	      ;;
+  	    esac
+  	  fi
+  	else
+  	  # FIXME: insert proper C++ library support
+  	  _LT_AC_TAGVAR(ld_shlibs, $1)=no
+  	fi
+  	;;
+      esac
+      ;;
+    irix5* | irix6*)
+      case $cc_basename in
+        CC)
+  	# SGI C++
+  	_LT_AC_TAGVAR(archive_cmds, $1)='$CC -shared -all -multigot $predep_objects $libobjs $deplibs $postdep_objects $compiler_flags -soname $soname `test -n "$verstring" && echo -set_version $verstring` -update_registry ${objdir}/so_locations -o $lib'
+
+  	# Archives containing C++ object files must be created using
+  	# "CC -ar", where "CC" is the IRIX C++ compiler.  This is
+  	# necessary to make sure instantiated templates are included
+  	# in the archive.
+  	_LT_AC_TAGVAR(old_archive_cmds, $1)='$CC -ar -WR,-u -o $oldlib $oldobjs'
+  	;;
+        *)
+  	if test "$GXX" = yes; then
+  	  if test "$with_gnu_ld" = no; then
+  	    _LT_AC_TAGVAR(archive_cmds, $1)='$CC -shared -nostdlib $predep_objects $libobjs $deplibs $postdep_objects $compiler_flags ${wl}-soname ${wl}$soname `test -n "$verstring" && echo ${wl}-set_version ${wl}$verstring` ${wl}-update_registry ${wl}${objdir}/so_locations -o $lib'
+  	  else
+  	    _LT_AC_TAGVAR(archive_cmds, $1)='$CC -shared -nostdlib $predep_objects $libobjs $deplibs $postdep_objects $compiler_flags ${wl}-soname ${wl}$soname `test -n "$verstring" && echo ${wl}-set_version ${wl}$verstring` -o $lib'
+  	  fi
+  	fi
+  	_LT_AC_TAGVAR(link_all_deplibs, $1)=yes
+  	;;
+      esac
+      _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='${wl}-rpath ${wl}$libdir'
+      _LT_AC_TAGVAR(hardcode_libdir_separator, $1)=:
+      _LT_AC_TAGVAR(inherit_rpath, $1)=yes
+      ;;
+    linux*)
+      case $cc_basename in
+        KCC)
+  	# Kuck and Associates, Inc. (KAI) C++ Compiler
+
+  	# KCC will only create a shared library if the output file
+  	# ends with ".so" (or ".sl" for HP-UX), so rename the library
+  	# to its proper name (with version) after linking.
+  	_LT_AC_TAGVAR(archive_cmds, $1)='tempext=`echo $shared_ext | $SED -e '\''s/\([[^()0-9A-Za-z{}]]\)/\\\\\1/g'\''`; templib=`echo $lib | $SED -e "s/\${tempext}\..*/.so/"`; $CC $predep_objects $libobjs $deplibs $postdep_objects $compiler_flags --soname $soname -o \$templib; mv \$templib $lib'
+  	_LT_AC_TAGVAR(archive_expsym_cmds, $1)='tempext=`echo $shared_ext | $SED -e '\''s/\([[^()0-9A-Za-z{}]]\)/\\\\\1/g'\''`; templib=`echo $lib | $SED -e "s/\${tempext}\..*/.so/"`; $CC $predep_objects $libobjs $deplibs $postdep_objects $compiler_flags --soname $soname -o \$templib ${wl}-retain-symbols-file,$export_symbols; mv \$templib $lib'
+  	# Commands to make compiler produce verbose output that lists
+  	# what "hidden" libraries, object files and flags are used when
+  	# linking a shared library.
+  	#
+  	# There doesn't appear to be a way to prevent this compiler from
+  	# explicitly linking system object files so we need to strip them
+  	# from the output so that they don't get included in the library
+  	# dependencies.
+  	output_verbose_link_cmd='templist=`$CC $CFLAGS -v conftest.$objext -o libconftest$shared_ext 2>&1 | $GREP "ld"`; rm -f libconftest$shared_ext; list=""; for z in $templist; do case $z in conftest.$objext) list="$list $z";; *.$objext);; *) list="$list $z";;esac; done; echo $list'
+
+  	_LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='${wl}--rpath,$libdir'
+  	_LT_AC_TAGVAR(export_dynamic_flag_spec, $1)='${wl}--export-dynamic'
+
+  	# Archives containing C++ object files must be created using
+  	# "CC -Bstatic", where "CC" is the KAI C++ compiler.
+  	_LT_AC_TAGVAR(old_archive_cmds, $1)='$CC -Bstatic -o $oldlib $oldobjs'
+  	;;
+        icpc)
+  	# Intel C++
+  	with_gnu_ld=yes
+  	_LT_AC_TAGVAR(archive_cmds_need_lc, $1)=no
+  	_LT_AC_TAGVAR(archive_cmds, $1)='$CC -shared $predep_objects $libobjs $deplibs $postdep_objects $compiler_flags ${wl}-soname $wl$soname -o $lib'
+  	_LT_AC_TAGVAR(archive_expsym_cmds, $1)='$CC -shared $predep_objects $libobjs $deplibs $postdep_objects $compiler_flags ${wl}-soname $wl$soname ${wl}-retain-symbols-file $wl$export_symbols -o $lib'
+  	_LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='${wl}-rpath,$libdir'
+  	_LT_AC_TAGVAR(export_dynamic_flag_spec, $1)='${wl}--export-dynamic'
+  	_LT_AC_TAGVAR(whole_archive_flag_spec, $1)='${wl}--whole-archive$convenience ${wl}--no-whole-archive'
+  	;;
+        cxx)
+  	# Compaq C++
+  	_LT_AC_TAGVAR(archive_cmds, $1)='$CC -shared $predep_objects $libobjs $deplibs $postdep_objects $compiler_flags ${wl}-soname $wl$soname -o $lib'
+  	_LT_AC_TAGVAR(archive_expsym_cmds, $1)='$CC -shared $predep_objects $libobjs $deplibs $postdep_objects $compiler_flags ${wl}-soname $wl$soname  -o $lib ${wl}-retain-symbols-file $wl$export_symbols'
+
+  	runpath_var=LD_RUN_PATH
+  	_LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='-rpath $libdir'
+  	_LT_AC_TAGVAR(hardcode_libdir_separator, $1)=:
+
+  	# Commands to make compiler produce verbose output that lists
+  	# what "hidden" libraries, object files and flags are used when
+  	# linking a shared library.
+  	#
+  	# There doesn't appear to be a way to prevent this compiler from
+  	# explicitly linking system object files so we need to strip them
+  	# from the output so that they don't get included in the library
+  	# dependencies.
+  	output_verbose_link_cmd='templist=`$CC -shared $CFLAGS -v conftest.$objext 2>&1 | $GREP "ld"`; templist=`echo $templist | $SED "s/\(^.*ld.*\)\( .*ld .*$\)/\1/"`; list=""; for z in $templist; do case $z in conftest.$objext) list="$list $z";; *.$objext);; *) list="$list $z";;esac; done; echo $list'
+  	;;
+      esac
+      ;;
+    lynxos*)
+      # FIXME: insert proper C++ library support
+      _LT_AC_TAGVAR(ld_shlibs, $1)=no
+      ;;
+    m88k*)
+      # FIXME: insert proper C++ library support
+      _LT_AC_TAGVAR(ld_shlibs, $1)=no
+      ;;
+    mvs*)
+      case $cc_basename in
+        cxx)
+  	# FIXME: insert proper C++ library support
+  	_LT_AC_TAGVAR(ld_shlibs, $1)=no
+  	;;
+        *)
+  	# FIXME: insert proper C++ library support
+  	_LT_AC_TAGVAR(ld_shlibs, $1)=no
+  	;;
+      esac
+      ;;
+    netbsd*)
+      if echo __ELF__ | $CC -E - | $GREP __ELF__ >/dev/null; then
+        _LT_AC_TAGVAR(archive_cmds, $1)='$LD -Bshareable  -o $lib $predep_objects $libobjs $deplibs $postdep_objects $linker_flags'
+        wlarc=
+        _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='-R$libdir'
+        _LT_AC_TAGVAR(hardcode_direct, $1)=yes
+        _LT_AC_TAGVAR(hardcode_shlibpath_var, $1)=no
+      fi
+      # Workaround some broken pre-1.5 toolchains
+      output_verbose_link_cmd='$CC -shared $CFLAGS -v conftest.$objext 2>&1 | $GREP conftest.$objext | $SED -e "s:-lgcc -lc -lgcc::"'
+      ;;
+    osf3*)
+      case $cc_basename in
+        KCC)
+  	# Kuck and Associates, Inc. (KAI) C++ Compiler
+
+  	# KCC will only create a shared library if the output file
+  	# ends with ".so" (or ".sl" for HP-UX), so rename the library
+  	# to its proper name (with version) after linking.
+  	_LT_AC_TAGVAR(archive_cmds, $1)='tempext=`echo $shared_ext | $SED -e '\''s/\([[^()0-9A-Za-z{}]]\)/\\\\\1/g'\''`; templib=`echo $lib | $SED -e "s/\${tempext}\..*/.so/"`; $CC $predep_objects $libobjs $deplibs $postdep_objects $compiler_flags --soname $soname -o \$templib; mv \$templib $lib'
+
+  	_LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='${wl}-rpath,$libdir'
+  	_LT_AC_TAGVAR(hardcode_libdir_separator, $1)=:
+
+  	# Archives containing C++ object files must be created using
+  	# "CC -Bstatic", where "CC" is the KAI C++ compiler.
+  	_LT_AC_TAGVAR(old_archive_cmds, $1)='$CC -Bstatic -o $oldlib $oldobjs'
+
+  	;;
+        RCC)
+  	# Rational C++ 2.4.1
+  	# FIXME: insert proper C++ library support
+  	_LT_AC_TAGVAR(ld_shlibs, $1)=no
+  	;;
+        cxx)
+  	_LT_AC_TAGVAR(allow_undefined_flag, $1)=' ${wl}-expect_unresolved ${wl}\*'
+  	_LT_AC_TAGVAR(archive_cmds, $1)='$CC -shared${allow_undefined_flag} $predep_objects $libobjs $deplibs $postdep_objects $compiler_flags ${wl}-soname $soname `test -n "$verstring" && echo ${wl}-set_version $verstring` -update_registry ${objdir}/so_locations -o $lib'
+
+  	_LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='${wl}-rpath ${wl}$libdir'
+  	_LT_AC_TAGVAR(hardcode_libdir_separator, $1)=:
+
+  	# Commands to make compiler produce verbose output that lists
+  	# what "hidden" libraries, object files and flags are used when
+  	# linking a shared library.
+  	#
+  	# There doesn't appear to be a way to prevent this compiler from
+  	# explicitly linking system object files so we need to strip them
+  	# from the output so that they don't get included in the library
+  	# dependencies.
+  	output_verbose_link_cmd='templist=`$CC -shared $CFLAGS -v conftest.$objext 2>&1 | $GREP "ld" | $GREP -v "ld:"`; templist=`echo $templist | $SED "s/\(^.*ld.*\)\( .*ld.*$\)/\1/"`; list=""; for z in $templist; do case $z in conftest.$objext) list="$list $z";; *.$objext);; *) list="$list $z";;esac; done; echo $list'
+  	;;
+        *)
+  	if test "$GXX" = yes && test "$with_gnu_ld" = no; then
+  	  _LT_AC_TAGVAR(allow_undefined_flag, $1)=' ${wl}-expect_unresolved ${wl}\*'
+  	  _LT_AC_TAGVAR(archive_cmds, $1)='$CC -shared -nostdlib ${allow_undefined_flag} $predep_objects $libobjs $deplibs $postdep_objects $compiler_flags ${wl}-soname ${wl}$soname `test -n "$verstring" && echo ${wl}-set_version ${wl}$verstring` ${wl}-update_registry ${wl}${objdir}/so_locations -o $lib'
+
+  	  _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='${wl}-rpath ${wl}$libdir'
+  	  _LT_AC_TAGVAR(hardcode_libdir_separator, $1)=:
+
+  	  # Commands to make compiler produce verbose output that lists
+  	  # what "hidden" libraries, object files and flags are used when
+  	  # linking a shared library.
+  	  output_verbose_link_cmd='$CC -shared $CFLAGS -v conftest.$objext 2>&1 | $GREP "\-L"'
+
+  	else
+  	  # FIXME: insert proper C++ library support
+  	  _LT_AC_TAGVAR(ld_shlibs, $1)=no
+  	fi
+  	;;
+      esac
+      ;;
+    osf4* | osf5*)
+      case $cc_basename in
+        KCC)
+  	# Kuck and Associates, Inc. (KAI) C++ Compiler
+
+  	# KCC will only create a shared library if the output file
+  	# ends with ".so" (or ".sl" for HP-UX), so rename the library
+  	# to its proper name (with version) after linking.
+  	_LT_AC_TAGVAR(archive_cmds, $1)='tempext=`echo $shared_ext | $SED -e '\''s/\([[^()0-9A-Za-z{}]]\)/\\\\\1/g'\''`; templib=`echo $lib | $SED -e "s/\${tempext}\..*/.so/"`; $CC $predep_objects $libobjs $deplibs $postdep_objects $compiler_flags --soname $soname -o \$templib; mv \$templib $lib'
+
+  	_LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='${wl}-rpath,$libdir'
+  	_LT_AC_TAGVAR(hardcode_libdir_separator, $1)=:
+
+  	# Archives containing C++ object files must be created using
+  	# the KAI C++ compiler.
+  	_LT_AC_TAGVAR(old_archive_cmds, $1)='$CC -o $oldlib $oldobjs'
+  	;;
+        RCC)
+  	# Rational C++ 2.4.1
+  	# FIXME: insert proper C++ library support
+  	_LT_AC_TAGVAR(ld_shlibs, $1)=no
+  	;;
+        cxx)
+  	_LT_AC_TAGVAR(allow_undefined_flag, $1)=' -expect_unresolved \*'
+  	_LT_AC_TAGVAR(archive_cmds, $1)='$CC -shared${allow_undefined_flag} $predep_objects $libobjs $deplibs $postdep_objects $compiler_flags -msym -soname $soname `test -n "$verstring" && echo -set_version $verstring` -update_registry ${objdir}/so_locations -o $lib'
+  	_LT_AC_TAGVAR(archive_expsym_cmds, $1)='for i in `cat $export_symbols`; do printf "%s %s\\n" -exported_symbol "\$i" >> $lib.exp; done~
+  	  echo "-hidden">> $lib.exp~
+  	  $CC -shared$allow_undefined_flag $predep_objects $libobjs $deplibs $postdep_objects $compiler_flags -msym -soname $soname -Wl,-input -Wl,$lib.exp  `test -n "$verstring" && echo -set_version	$verstring` -update_registry $objdir/so_locations -o $lib~
+  	  $rm $lib.exp'
+
+  	_LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='-rpath $libdir'
+  	_LT_AC_TAGVAR(hardcode_libdir_separator, $1)=:
+
+  	# Commands to make compiler produce verbose output that lists
+  	# what "hidden" libraries, object files and flags are used when
+  	# linking a shared library.
+  	#
+  	# There doesn't appear to be a way to prevent this compiler from
+  	# explicitly linking system object files so we need to strip them
+  	# from the output so that they don't get included in the library
+  	# dependencies.
+  	output_verbose_link_cmd='templist=`$CC -shared $CFLAGS -v conftest.$objext 2>&1 | $GREP "ld" | $GREP -v "ld:"`; templist=`echo $templist | $SED "s/\(^.*ld.*\)\( .*ld.*$\)/\1/"`; list=""; for z in $templist; do case $z in conftest.$objext) list="$list $z";; *.$objext);; *) list="$list $z";;esac; done; echo $list'
+  	;;
+        *)
+  	if test "$GXX" = yes && test "$with_gnu_ld" = no; then
+  	  _LT_AC_TAGVAR(allow_undefined_flag, $1)=' ${wl}-expect_unresolved ${wl}\*'
+  	 _LT_AC_TAGVAR(archive_cmds, $1)='$CC -shared -nostdlib ${allow_undefined_flag} $predep_objects $libobjs $deplibs $postdep_objects $compiler_flags ${wl}-msym ${wl}-soname ${wl}$soname `test -n "$verstring" && echo ${wl}-set_version ${wl}$verstring` ${wl}-update_registry ${wl}${objdir}/so_locations -o $lib'
+
+  	  _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='${wl}-rpath ${wl}$libdir'
+  	  _LT_AC_TAGVAR(hardcode_libdir_separator, $1)=:
+
+  	  # Commands to make compiler produce verbose output that lists
+  	  # what "hidden" libraries, object files and flags are used when
+  	  # linking a shared library.
+  	  output_verbose_link_cmd='$CC -shared $CFLAGS -v conftest.$objext 2>&1 | $GREP "\-L"'
+
+  	else
+  	  # FIXME: insert proper C++ library support
+  	  _LT_AC_TAGVAR(ld_shlibs, $1)=no
+  	fi
+  	;;
+      esac
+      ;;
+    psos*)
+      # FIXME: insert proper C++ library support
+      _LT_AC_TAGVAR(ld_shlibs, $1)=no
+      ;;
+    sco*)
+      _LT_AC_TAGVAR(archive_cmds_need_lc, $1)=no
+      case $cc_basename in
+        CC)
+  	# FIXME: insert proper C++ library support
+  	_LT_AC_TAGVAR(ld_shlibs, $1)=no
+  	;;
+        *)
+  	# FIXME: insert proper C++ library support
+  	_LT_AC_TAGVAR(ld_shlibs, $1)=no
+  	;;
+      esac
+      ;;
+    sunos4*)
+      case $cc_basename in
+        CC)
+  	# Sun C++ 4.x
+  	# FIXME: insert proper C++ library support
+  	_LT_AC_TAGVAR(ld_shlibs, $1)=no
+  	;;
+        lcc)
+  	# Lucid
+  	# FIXME: insert proper C++ library support
+  	_LT_AC_TAGVAR(ld_shlibs, $1)=no
+  	;;
+        *)
+  	# FIXME: insert proper C++ library support
+  	_LT_AC_TAGVAR(ld_shlibs, $1)=no
+  	;;
+      esac
+      ;;
+    solaris*)
+      case $cc_basename in
+        CC)
+  	# Sun C++ 4.2, 5.x and Centerline C++
+  	_LT_AC_TAGVAR(no_undefined_flag, $1)=' -zdefs'
+  	_LT_AC_TAGVAR(archive_cmds, $1)='$CC -G${allow_undefined_flag} -nolib -h$soname -o $lib $predep_objects $libobjs $deplibs $postdep_objects $compiler_flags'
+  	_LT_AC_TAGVAR(archive_expsym_cmds, $1)='$echo "{ global:" > $lib.exp~cat $export_symbols | $SED -e "s/\(.*\)/\1;/" >> $lib.exp~$echo "local: *; };" >> $lib.exp~
+  	$CC -G${allow_undefined_flag} -nolib ${wl}-M ${wl}$lib.exp -h$soname -o $lib $predep_objects $libobjs $deplibs $postdep_objects $compiler_flags~$rm $lib.exp'
+
+  	_LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='-R$libdir'
+  	_LT_AC_TAGVAR(hardcode_shlibpath_var, $1)=no
+  	case $host_os in
+  	  solaris2.[0-5] | solaris2.[0-5].*) ;;
+  	  *)
+  	    # The C++ compiler is used as linker so we must use $wl
+  	    # flag to pass the commands to the underlying system
+  	    # linker. We must also pass each convience library through
+  	    # to the system linker between allextract/defaultextract.
+  	    # The C++ compiler will combine linker options so we
+  	    # cannot just pass the convience library names through
+  	    # without $wl.
+  	    # Supported since Solaris 2.6 (maybe 2.5.1?)
+  	    _LT_AC_TAGVAR(whole_archive_flag_spec, $1)='${wl}-z ${wl}allextract`for conv in $convenience\"\"; do test -n \"$conv\" && new_convenience=\"$new_convenience,$conv\"; done; $echo \"$new_convenience\"` ${wl}-z ${wl}defaultextract'
+  	    ;;
+  	esac
+  	_LT_AC_TAGVAR(link_all_deplibs, $1)=yes
+
+  	# Commands to make compiler produce verbose output that lists
+  	# what "hidden" libraries, object files and flags are used when
+  	# linking a shared library.
+  	#
+  	# There doesn't appear to be a way to prevent this compiler from
+  	# explicitly linking system object files so we need to strip them
+  	# from the output so that they don't get included in the library
+  	# dependencies.
+  	output_verbose_link_cmd='templist=`$CC -G $CFLAGS -v conftest.$objext 2>&1 | $GREP "\-[[LR]]"`; list=""; for z in $templist; do case $z in conftest.$objext) list="$list $z";; *.$objext);; *) list="$list $z";;esac; done; echo $list'
+
+  	# Archives containing C++ object files must be created using
+  	# "CC -xar", where "CC" is the Sun C++ compiler.  This is
+  	# necessary to make sure instantiated templates are included
+  	# in the archive.
+  	_LT_AC_TAGVAR(old_archive_cmds, $1)='$CC -xar -o $oldlib $oldobjs'
+  	;;
+        gcx)
+  	# Green Hills C++ Compiler
+  	_LT_AC_TAGVAR(archive_cmds, $1)='$CC -shared $predep_objects $libobjs $deplibs $postdep_objects $compiler_flags ${wl}-h $wl$soname -o $lib'
+
+  	# The C++ compiler must be used to create the archive.
+  	_LT_AC_TAGVAR(old_archive_cmds, $1)='$CC $LDFLAGS -archive -o $oldlib $oldobjs'
+  	;;
+        *)
+  	# GNU C++ compiler with Solaris linker
+  	if test "$GXX" = yes && test "$with_gnu_ld" = no; then
+  	  _LT_AC_TAGVAR(no_undefined_flag, $1)=' ${wl}-z ${wl}defs'
+  	  if $CC --version | $GREP -v '^2\.7' > /dev/null; then
+  	    _LT_AC_TAGVAR(archive_cmds, $1)='$CC -shared -nostdlib $LDFLAGS $predep_objects $libobjs $deplibs $postdep_objects $compiler_flags ${wl}-h $wl$soname -o $lib'
+  	    _LT_AC_TAGVAR(archive_expsym_cmds, $1)='$echo "{ global:" > $lib.exp~cat $export_symbols | $SED -e "s/\(.*\)/\1;/" >> $lib.exp~$echo "local: *; };" >> $lib.exp~
+  		$CC -shared -nostdlib ${wl}-M $wl$lib.exp -o $lib $predep_objects $libobjs $deplibs $postdep_objects $compiler_flags~$rm $lib.exp'
+
+  	    # Commands to make compiler produce verbose output that lists
+  	    # what "hidden" libraries, object files and flags are used when
+  	    # linking a shared library.
+  	    output_verbose_link_cmd="$CC -shared $CFLAGS -v conftest.$objext 2>&1 | $GREP \"\-L\""
+  	  else
+  	    # g++ 2.7 appears to require `-G' NOT `-shared' on this
+  	    # platform.
+  	    _LT_AC_TAGVAR(archive_cmds, $1)='$CC -G -nostdlib $LDFLAGS $predep_objects $libobjs $deplibs $postdep_objects $compiler_flags ${wl}-h $wl$soname -o $lib'
+  	    _LT_AC_TAGVAR(archive_expsym_cmds, $1)='$echo "{ global:" > $lib.exp~cat $export_symbols | $SED -e "s/\(.*\)/\1;/" >> $lib.exp~$echo "local: *; };" >> $lib.exp~
+  		$CC -G -nostdlib ${wl}-M $wl$lib.exp -o $lib $predep_objects $libobjs $deplibs $postdep_objects $compiler_flags~$rm $lib.exp'
+
+  	    # Commands to make compiler produce verbose output that lists
+  	    # what "hidden" libraries, object files and flags are used when
+  	    # linking a shared library.
+  	    output_verbose_link_cmd="$CC -G $CFLAGS -v conftest.$objext 2>&1 | $GREP \"\-L\""
+  	  fi
+
+  	  _LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)='${wl}-R $wl$libdir'
+  	fi
+  	;;
+      esac
+      ;;
+    sysv5OpenUNIX8* | sysv5UnixWare7* | sysv5uw[[78]]* | unixware7*)
+      _LT_AC_TAGVAR(archive_cmds_need_lc, $1)=no
+      ;;
+    tandem*)
+      case $cc_basename in
+        NCC)
+  	# NonStop-UX NCC 3.20
+  	# FIXME: insert proper C++ library support
+  	_LT_AC_TAGVAR(ld_shlibs, $1)=no
+  	;;
+        *)
+  	# FIXME: insert proper C++ library support
+  	_LT_AC_TAGVAR(ld_shlibs, $1)=no
+  	;;
+      esac
+      ;;
+    vxworks*)
+      # FIXME: insert proper C++ library support
+      _LT_AC_TAGVAR(ld_shlibs, $1)=no
+      ;;
+    *)
+      # FIXME: insert proper C++ library support
+      _LT_AC_TAGVAR(ld_shlibs, $1)=no
+      ;;
+  esac
+  AC_MSG_RESULT([$_LT_AC_TAGVAR(ld_shlibs, $1)])
+  test "$_LT_AC_TAGVAR(ld_shlibs, $1)" = no && can_build_shared=no
+
+  _LT_AC_TAGVAR(GCC, $1)="$GXX"
+  _LT_AC_TAGVAR(LD, $1)="$LD"
+
+  ## CAVEAT EMPTOR:
+  ## There is no encapsulation within the following macros, do not change
+  ## the running order or otherwise move them around unless you know exactly
+  ## what you are doing...
+  AC_LIBTOOL_POSTDEP_PREDEP($1)
+  AC_LIBTOOL_PROG_COMPILER_PIC($1)
+  AC_LIBTOOL_PROG_CC_C_O($1)
+  AC_LIBTOOL_SYS_HARD_LINK_LOCKS($1)
+  AC_LIBTOOL_PROG_LD_SHLIBS($1)
+  AC_LIBTOOL_SYS_DYNAMIC_LINKER($1)
+  AC_LIBTOOL_PROG_LD_HARDCODE_LIBPATH($1)
+  AC_LIBTOOL_SYS_LIB_STRIP
+  AC_LIBTOOL_DLOPEN_SELF($1)
+
+  _LT_CONFIG($1)
+fi
+
+AC_LANG_POP
+CC=$lt_save_CC
+LDCXX=$LD
+LD=$lt_save_LD
+GCC=$lt_save_GCC
+with_gnu_ldcxx=$with_gnu_ld
+with_gnu_ld=$lt_save_with_gnu_ld
+lt_cv_path_LDCXX=$lt_cv_path_LD
+lt_cv_path_LD=$lt_save_path_LD
+lt_cv_prog_gnu_ldcxx=$lt_cv_prog_gnu_ld
+lt_cv_prog_gnu_ld=$lt_save_with_gnu_ld
+])# _LT_LANG_CXX_CONFIG
+
+
+# AC_LIBTOOL_POSTDEP_PREDEP([TAGNAME])
+# ------------------------------------
+# Figure out "hidden" library dependencies from verbose
+# compiler output when linking a shared library.
+# Parse the compiler output and extract the necessary
+# objects, libraries and library flags.
+AC_DEFUN([AC_LIBTOOL_POSTDEP_PREDEP],[
+# Dependencies to place before and after the object being linked:
+_LT_AC_TAGVAR(predep_objects, $1)=
+_LT_AC_TAGVAR(postdep_objects, $1)=
+_LT_AC_TAGVAR(predeps, $1)=
+_LT_AC_TAGVAR(postdeps, $1)=
+_LT_AC_TAGVAR(compiler_lib_search_path, $1)=
+
+dnl we can't use the lt_simple_compile_test_code here,
+dnl because it contains code intended for an executable,
+dnl not a library.  It's possible we should let each
+dnl tag define a new lt_????_link_test_code variable,
+dnl but it's only used here...
+m4_if([$1], [], [cat > conftest.$ac_ext <<_LT_EOF
+int a;
+void foo (void) { a = 0; }
+_LT_EOF
+], [$1], [CXX], [cat > conftest.$ac_ext <<_LT_EOF
+class Foo
+{
+public:
+  Foo (void) { a = 0; }
+private:
+  int a;
+};
+_LT_EOF
+], [$1], [F77], [cat > conftest.$ac_ext <<_LT_EOF
+      subroutine foo
+      implicit none
+      integer*4 a
+      a=0
+      return
+      end
+_LT_EOF
+], [$1], [GCJ], [cat > conftest.$ac_ext <<_LT_EOF
+public class foo {
+  private int a;
+  public void bar (void) {
+    a = 0;
+  }
+};
+_LT_EOF
+])
+dnl Parse the compiler output and extract the necessary
+dnl objects, libraries and library flags.
+if AC_TRY_EVAL(ac_compile); then
+  # Parse the compiler output and extract the necessary
+  # objects, libraries and library flags.
+
+  # Sentinel used to keep track of whether or not we are before
+  # the conftest object file.
+  pre_test_object_deps_done=no
+
+  # The `*' in the case matches for architectures that use `case' in
+  # $output_verbose_cmd can trigger glob expansion during the loop
+  # eval without this substitution.
+  output_verbose_link_cmd="`$echo \"X$output_verbose_link_cmd\" | $Xsed -e \"$no_glob_subst\"`"
+
+  for p in `eval $output_verbose_link_cmd`; do
+    case $p in
+
+    -L* | -R* | -l*)
+       # Some compilers place space between "-{L,R}" and the path.
+       # Remove the space.
+       if test $p = "-L" ||
+          test $p = "-R"; then
+	 prev=$p
+	 continue
+       else
+	 prev=
+       fi
+
+       if test "$pre_test_object_deps_done" = no; then
+	 case $p in
+	 -L* | -R*)
+	   # Internal compiler library paths should come after those
+	   # provided the user.  The postdeps already come after the
+	   # user supplied libs so there is no need to process them.
+	   if test -z "$_LT_AC_TAGVAR(compiler_lib_search_path, $1)"; then
+	     _LT_AC_TAGVAR(compiler_lib_search_path, $1)="${prev}${p}"
+	   else
+	     _LT_AC_TAGVAR(compiler_lib_search_path, $1)="${_LT_AC_TAGVAR(compiler_lib_search_path, $1)} ${prev}${p}"
+	   fi
+	   ;;
+	 # The "-l" case would never come before the object being
+	 # linked, so don't bother handling this case.
+	 esac
+       else
+	 if test -z "$_LT_AC_TAGVAR(postdeps, $1)"; then
+	   _LT_AC_TAGVAR(postdeps, $1)="${prev}${p}"
+	 else
+	   _LT_AC_TAGVAR(postdeps, $1)="${_LT_AC_TAGVAR(postdeps, $1)} ${prev}${p}"
+	 fi
+       fi
+       ;;
+
+    *.$objext)
+       # This assumes that the test object file only shows up
+       # once in the compiler output.
+       if test "$p" = "conftest.$objext"; then
+	 pre_test_object_deps_done=yes
+	 continue
+       fi
+
+       if test "$pre_test_object_deps_done" = no; then
+	 if test -z "$_LT_AC_TAGVAR(predep_objects, $1)"; then
+	   _LT_AC_TAGVAR(predep_objects, $1)="$p"
+	 else
+	   _LT_AC_TAGVAR(predep_objects, $1)="$_LT_AC_TAGVAR(predep_objects, $1) $p"
+	 fi
+       else
+	 if test -z "$_LT_AC_TAGVAR(postdep_objects, $1)"; then
+	   _LT_AC_TAGVAR(postdep_objects, $1)="$p"
+	 else
+	   _LT_AC_TAGVAR(postdep_objects, $1)="$_LT_AC_TAGVAR(postdep_objects, $1) $p"
+	 fi
+       fi
+       ;;
+
+    *) ;; # Ignore the rest.
+
+    esac
+  done
+
+  # Clean up.
+  rm -f a.out a.exe
+else
+  echo "libtool.m4: error: problem compiling $1 test program"
+fi
+
+$rm -f confest.$objext
+
+case " $_LT_AC_TAGVAR(postdeps, $1) " in
+*" -lc "*) _LT_AC_TAGVAR(archive_cmds_need_lc, $1)=no ;;
+esac
+_LT_TAGDECL([], [predep_objects], [1],
+    [Dependencies to place before and after  the objects being linked to
+    create a shared library])
+_LT_TAGDECL([], [postdep_objects], [1])
+_LT_TAGDECL([], [predeps], [1])
+_LT_TAGDECL([], [postdeps], [1])
+_LT_TAGDECL([], [compiler_lib_search_path], [1],
+    [The library search path used internally by the compiler when linking
+    a shared library])
+])# AC_LIBTOOL_POSTDEP_PREDEP
+
+# _LT_LANG_F77_CONFIG([TAG])
+# --------------------------
+# Ensure that the configuration variables for a Fortran 77 compiler are
+# suitably defined.  These variables are subsequently used by _LT_CONFIG
+# to write the compiler configuration to `libtool'.
+m4_define([_LT_LANG_F77_CONFIG],
+[AC_REQUIRE([AC_PROG_F77])
+AC_LANG_PUSH(Fortran 77)
+
+_LT_AC_TAGVAR(archive_cmds_need_lc, $1)=no
+_LT_AC_TAGVAR(allow_undefined_flag, $1)=
+_LT_AC_TAGVAR(always_export_symbols, $1)=no
+_LT_AC_TAGVAR(archive_expsym_cmds, $1)=
+_LT_AC_TAGVAR(export_dynamic_flag_spec, $1)=
+_LT_AC_TAGVAR(hardcode_direct, $1)=no
+_LT_AC_TAGVAR(hardcode_libdir_flag_spec, $1)=
+_LT_AC_TAGVAR(hardcode_libdir_flag_spec_ld, $1)=
+_LT_AC_TAGVAR(hardcode_libdir_separator, $1)=
+_LT_AC_TAGVAR(hardcode_minus_L, $1)=no
+_LT_AC_TAGVAR(hardcode_automatic, $1)=no
+_LT_AC_TAGVAR(inherit_rpath, $1)=no
+_LT_AC_TAGVAR(module_cmds, $1)=
+_LT_AC_TAGVAR(module_expsym_cmds, $1)=
+_LT_AC_TAGVAR(link_all_deplibs, $1)=unknown
+_LT_AC_TAGVAR(old_archive_cmds, $1)=$old_archive_cmds
+_LT_AC_TAGVAR(no_undefined_flag, $1)=
+_LT_AC_TAGVAR(whole_archive_flag_spec, $1)=
+_LT_AC_TAGVAR(enable_shared_with_static_runtimes, $1)=no
+
+# Source file extension for f77 test sources.
+ac_ext=f
+
+# Object file extension for compiled f77 test sources.
+objext=o
+_LT_AC_TAGVAR(objext, $1)=$objext
+
+# Code to be used in simple compile tests
+lt_simple_compile_test_code="      subroutine t\n      return\n      end\n"
+
+# Code to be used in simple link tests
+lt_simple_link_test_code="      program t\n      end\n"
+
+# ltmain only uses $CC for tagged configurations so make sure $CC is set.
+_LT_AC_SYS_COMPILER
+
+# Allow CC to be a program name with arguments.
+lt_save_CC="$CC"
+CC=${F77-"f77"}
+compiler=$CC
+_LT_AC_TAGVAR(compiler, $1)=$CC
+cc_basename=`$echo X"$compiler" | $Xsed -e 's%^.*/%%'`
+
+if test -n "$compiler"; then
+  AC_MSG_CHECKING([if libtool supports shared libraries])
+  AC_MSG_RESULT([$can_build_shared])
+
+  AC_MSG_CHECKING([whether to build shared libraries])
+  test "$can_build_shared" = "no" && enable_shared=no
+
+  # On AIX, shared libraries and static libraries use the same namespace, and
+  # are all built from PIC.
+  case "$host_os" in
+  aix3*)
+    test "$enable_shared" = yes && enable_static=no
+    if test -n "$RANLIB"; then
+      archive_cmds="$archive_cmds~\$RANLIB \$lib"
+      postinstall_cmds='$RANLIB $lib'
+    fi
+    ;;
+  aix4* | aix5*)
+    test "$enable_shared" = yes && enable_static=no
+    ;;
+  esac
+  AC_MSG_RESULT([$enable_shared])
+
+  AC_MSG_CHECKING([whether to build static libraries])
+  # Make sure either enable_shared or enable_static is yes.
+  test "$enable_shared" = yes || enable_static=yes
+  AC_MSG_RESULT([$enable_static])
+
+  test "$_LT_AC_TAGVAR(ld_shlibs, $1)" = no && can_build_shared=no
+
+  _LT_AC_TAGVAR(GCC, $1)="$G77"
+  _LT_AC_TAGVAR(LD, $1)="$LD"
+
+  ## CAVEAT EMPTOR:
+  ## There is no encapsulation within the following macros, do not change
+  ## the running order or otherwise move them around unless you know exactly
+  ## what you are doing...
+  AC_LIBTOOL_PROG_COMPILER_PIC($1)
+  AC_LIBTOOL_PROG_CC_C_O($1)
+  AC_LIBTOOL_SYS_HARD_LINK_LOCKS($1)
+  AC_LIBTOOL_PROG_LD_SHLIBS($1)
+  AC_LIBTOOL_SYS_DYNAMIC_LINKER($1)
+  AC_LIBTOOL_PROG_LD_HARDCODE_LIBPATH($1)
+  AC_LIBTOOL_SYS_LIB_STRIP
+
+  _LT_CONFIG($1)
+fi
+
+AC_LANG_POP
+CC="$lt_save_CC"
+])# _LT_LANG_F77_CONFIG
+
+
+# _LT_LANG_GCJ_CONFIG([TAG])
+# --------------------------
+# Ensure that the configuration variables for the GNU Java Compiler compiler
+# are suitably defined.  These variables are subsequently used by _LT_CONFIG
+# to write the compiler configuration to `libtool'.
+m4_define([_LT_LANG_GCJ_CONFIG],
+[AC_REQUIRE([LT_PROG_GCJ])
+AC_LANG_SAVE
+
+# Source file extension for Java test sources.
+ac_ext=java
+
+# Object file extension for compiled Java test sources.
+objext=o
+_LT_AC_TAGVAR(objext, $1)=$objext
+
+# Code to be used in simple compile tests
+lt_simple_compile_test_code="class foo {}\n"
+
+# Code to be used in simple link tests
+lt_simple_link_test_code='public class conftest { public static void main(String[] argv) {}; }\n'
+
+# ltmain only uses $CC for tagged configurations so make sure $CC is set.
+_LT_AC_SYS_COMPILER
+
+# Allow CC to be a program name with arguments.
+lt_save_CC="$CC"
+CC=${GCJ-"gcj"}
+compiler=$CC
+_LT_AC_TAGVAR(compiler, $1)=$CC
+
+# GCJ did not exist at the time GCC didn't implicitly link libc in.
+_LT_AC_TAGVAR(archive_cmds_need_lc, $1)=no
+
+## CAVEAT EMPTOR:
+## There is no encapsulation within the following macros, do not change
+## the running order or otherwise move them around unless you know exactly
+## what you are doing...
+if test -n "$compiler"; then
+  AC_LIBTOOL_PROG_COMPILER_NO_RTTI($1)
+  AC_LIBTOOL_PROG_COMPILER_PIC($1)
+  AC_LIBTOOL_PROG_CC_C_O($1)
+  AC_LIBTOOL_SYS_HARD_LINK_LOCKS($1)
+  AC_LIBTOOL_PROG_LD_SHLIBS($1)
+  AC_LIBTOOL_SYS_DYNAMIC_LINKER($1)
+  AC_LIBTOOL_PROG_LD_HARDCODE_LIBPATH($1)
+  AC_LIBTOOL_SYS_LIB_STRIP
+  AC_LIBTOOL_DLOPEN_SELF($1)
+
+  _LT_CONFIG($1)
+fi
+
+AC_LANG_RESTORE
+CC="$lt_save_CC"
+])# _LT_LANG_GCJ_CONFIG
+
+
+# _LT_LANG_RC_CONFIG([TAG])
+# --------------------------
+# Ensure that the configuration variables for the Windows resource compiler
+# are suitably defined.  These variables are subsequently used by _LT_CONFIG
+# to write the compiler configuration to `libtool'.
+m4_define([_LT_LANG_RC_CONFIG],
+[AC_REQUIRE([LT_PROG_RC])
+AC_LANG_SAVE
+
+# Source file extension for RC test sources.
+ac_ext=rc
+
+# Object file extension for compiled RC test sources.
+objext=o
+_LT_AC_TAGVAR(objext, $1)=$objext
+
+# Code to be used in simple compile tests
+lt_simple_compile_test_code='sample MENU { MENUITEM "&Soup", 100, CHECKED }\n'
+
+# Code to be used in simple link tests
+lt_simple_link_test_code="$lt_simple_compile_test_code"
+
+# ltmain only uses $CC for tagged configurations so make sure $CC is set.
+_LT_AC_SYS_COMPILER
+
+# Allow CC to be a program name with arguments.
+lt_save_CC="$CC"
+CC=${RC-"windres"}
+compiler=$CC
+_LT_AC_TAGVAR(compiler, $1)=$CC
+_LT_AC_TAGVAR(lt_cv_prog_compiler_c_o, $1)=yes
+
+if test -n "$compiler"; then
+  :
+  _LT_CONFIG($1)
+fi
+
+AC_LANG_RESTORE
+CC="$lt_save_CC"
+])# _LT_LANG_RC_CONFIG
+
+
+AC_DEFUN([LT_PROG_GCJ],
+[m4_ifdef([AC_PROG_GCJ], [AC_PROG_GCJ],
+  [m4_ifdef([A][M_PROG_GCJ], [A][M_PROG_GCJ],
+    [AC_CHECK_TOOL(GCJ, gcj,)
+      test "x${GCJFLAGS+set}" = xset || GCJFLAGS="-g -O2"
+      AC_SUBST(GCJFLAGS)])])dnl
+])
+AU_DEFUN([LT_AC_PROG_GCJ], [LT_PROG_GCJ])
+
+AC_DEFUN([LT_PROG_RC],
+[AC_CHECK_TOOL(RC, windres,)
+])
+AU_DEFUN([LT_AC_PROG_RC], [LT_PROG_RC])
+
+
+# LT_AC_PROG_EGREP
+# ----------------
+# If we don't have a new enough Autoconf to choose the best grep
+# available, choose the one first in the user's PATH.
+AC_DEFUN([LT_AC_PROG_EGREP],
+[AC_REQUIRE([AC_PROG_EGREP])
+test -z "$GREP" && GREP=grep
+_LT_DECL([], [GREP], [1], [A grep program that handles long line])
+_LT_DECL([], [EGREP], [1], [An ERE matcher])
+])
+
+
+# LT_AC_PROG_SED
+# --------------
+# Check for a fully-functional sed program, that truncates
+# as few characters as possible.  Prefer GNU sed if found.
+AC_DEFUN([LT_AC_PROG_SED],
+[AC_PROG_SED
+test -z "$SED" && SED=sed
+_LT_DECL([], [SED], [1], [A sed program that does not truncate output])
+_LT_DECL([], [Xsed], ["\$SED -e s/^X//"],
+    [Sed that helps us avoid accidentally triggering echo(1) options like -n])
+])# LT_AC_PROG_SED
+
+m4_ifndef([AC_PROG_SED], [
+############################################################
+# NOTE: This macro has been submitted for inclusion into   #
+#  GNU Autoconf as AC_PROG_SED.  When it is available in   #
+#  a released version of Autoconf we should remove this    #
+#  macro and use it instead.                               #
+############################################################
+
+m4_define([AC_PROG_SED],
+[AC_MSG_CHECKING([for a sed that does not truncate output])
+AC_CACHE_VAL(lt_cv_path_SED,
+[# Loop through the user's path and test for sed and gsed.
+# Then use that list of sed's as ones to test for truncation.
+as_save_IFS=$IFS; IFS=$PATH_SEPARATOR
+for as_dir in $PATH
+do
+  IFS=$as_save_IFS
+  test -z "$as_dir" && as_dir=.
+  for lt_ac_prog in sed gsed; do
+    for ac_exec_ext in '' $ac_executable_extensions; do
+      if $as_executable_p "$as_dir/$lt_ac_prog$ac_exec_ext"; then
+        lt_ac_sed_list="$lt_ac_sed_list $as_dir/$lt_ac_prog$ac_exec_ext"
+      fi
+    done
+  done
+done
+lt_ac_max=0
+lt_ac_count=0
+# Add /usr/xpg4/bin/sed as it is typically found on Solaris
+# along with /bin/sed that truncates output.
+for lt_ac_sed in $lt_ac_sed_list /usr/xpg4/bin/sed; do
+  test ! -f $lt_ac_sed && break
+  cat /dev/null > conftest.in
+  lt_ac_count=0
+  echo $ECHO_N "0123456789$ECHO_C" >conftest.in
+  # Check for GNU sed and select it if it is found.
+  if "$lt_ac_sed" --version 2>&1 < /dev/null | grep 'GNU' > /dev/null; then
+    lt_cv_path_SED=$lt_ac_sed
+    break
+  fi
+  while true; do
+    cat conftest.in conftest.in >conftest.tmp
+    mv conftest.tmp conftest.in
+    cp conftest.in conftest.nl
+    echo >>conftest.nl
+    $lt_ac_sed -e 's/a$//' < conftest.nl >conftest.out || break
+    cmp -s conftest.out conftest.nl || break
+    # 10000 chars as input seems more than enough
+    test $lt_ac_count -gt 10 && break
+    lt_ac_count=`expr $lt_ac_count + 1`
+    if test $lt_ac_count -gt $lt_ac_max; then
+      lt_ac_max=$lt_ac_count
+      lt_cv_path_SED=$lt_ac_sed
+    fi
+  done
+done
+SED=$lt_cv_path_SED
+AC_SUBST([SED])
+])
+AC_MSG_RESULT([$SED])
+])#AC_PROG_SED
+])#m4_ifndef
diff --git a/libs/sigc++2/scripts/ltoptions.m4 b/libs/sigc++2/scripts/ltoptions.m4
new file mode 100644
index 0000000000..ea3089d330
--- /dev/null
+++ b/libs/sigc++2/scripts/ltoptions.m4
@@ -0,0 +1,358 @@
+# Helper functions for option handling.                    -*- Autoconf -*-
+# Written by Gary V. Vaughan <gary@gnu.org>
+
+# Copyright (C) 2004  Free Software Foundation, Inc.
+
+# This program is free software; you can redistribute it and/or modify
+# it under the terms of the GNU General Public License as published by
+# the Free Software Foundation; either version 2, or (at your option)
+# any later version.
+#
+# This program is distributed in the hope that it will be useful,
+# but WITHOUT ANY WARRANTY; without even the implied warranty of
+# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
+# GNU General Public License for more details.
+#
+# You should have received a copy of the GNU General Public License
+# along with this program; if not, write to the Free Software
+# Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA
+# 02111-1307, USA.
+
+# serial 1
+
+# This is to help aclocal find these macros, as it can't see m4_define.
+AC_DEFUN([LTOPTIONS_VERSION], [m4_if([1])])
+
+
+# _LT_MANGLE_OPTION(NAME)
+# -----------------------
+m4_define([_LT_MANGLE_OPTION],
+[[_LT_OPTION_]m4_bpatsubst($1, [[^a-zA-Z0-9_]], [_])])
+
+
+# _LT_SET_OPTION(NAME)
+# ------------------------------
+# Set option NAME.  Other NAMEs are saved as a flag.
+m4_define([_LT_SET_OPTION], [m4_define(_LT_MANGLE_OPTION([$1]))])
+
+
+# _LT_IF_OPTION(OPTION, IF-SET, [IF-NOT-SET])
+# -------------------------------------------
+# Execute IF-SET if OPTION is set, IF-NOT-SET otherwise.
+m4_define([_LT_IF_OPTION],
+[m4_ifdef(_LT_MANGLE_OPTION([$1]), [$2], [$3])])
+
+
+# _LT_UNLESS_OPTIONS(OPTIONS, IF-NOT-SET)
+# ---------------------------------------
+# Execute IF-NOT-SET if all OPTIONS are not set.
+m4_define([_LT_UNLESS_OPTIONS],
+[AC_FOREACH([_LT_Option], [$1],
+	    [m4_ifdef(_LT_MANGLE_OPTION(_LT_Option),
+		      [m4_define([$0_found])])])[]dnl
+m4_ifdef([$0_found], [m4_undefine([$0_found])], [$2
+])[]dnl
+])
+
+
+# _LT_SET_OPTIONS(OPTIONS)
+# ------------------------
+# OPTIONS is a space-separated list of Automake options.
+# If any OPTION has a handler macro declared with LT_OPTION_DEFINE,
+# despatch to that macro; otherwise complain about the unknown option
+# and exit.
+m4_define([_LT_SET_OPTIONS],
+[AC_FOREACH([_LT_Option], [$1],
+    [_LT_SET_OPTION(_LT_Option)
+    m4_ifdef(_LT_MANGLE_DEFUN(_LT_Option),
+		_LT_MANGLE_DEFUN(_LT_Option),
+	[m4_fatal([Unknown option `]_LT_Option[' to LT][_INIT_LIBTOOL])])
+    ])dnl
+dnl
+dnl Simply set some default values (i.e off) if boolean options were not
+dnl specified:
+_LT_UNLESS_OPTIONS([dlopen], enable_dlopen=no)
+_LT_UNLESS_OPTIONS([win32-dll], enable_win32_dll=no)
+dnl
+dnl If no reference was made to various pairs of opposing options, then
+dnl we run the default mode handler for the pair.  For example, if neither
+dnl `shared' nor `disable-shared' was passed, we enable building of shared
+dnl archives by default:
+_LT_UNLESS_OPTIONS([shared disable-shared], [_LT_ENABLE_SHARED])
+_LT_UNLESS_OPTIONS([static disable-static], [_LT_ENABLE_STATIC])
+_LT_UNLESS_OPTIONS([pic-only no-pic], [_LT_WITH_PIC])
+_LT_UNLESS_OPTIONS([fast-install disable-fast-install],
+		   [_LT_ENABLE_FAST_INSTALL])
+])# _LT_SET_OPTIONS
+
+
+## ----------------------------------------- ##
+## Macros to handle LT_INIT_LIBTOOL options. ##
+## ----------------------------------------- ##
+
+m4_define([_LT_MANGLE_DEFUN],
+[[_LT_OPTION_DEFUN_]m4_bpatsubst(m4_toupper([$1]), [[^A-Z0-9_]], [_])])
+
+
+# LT_OPTION_DEFINE(NAME, CODE)
+# ----------------------------
+m4_define([LT_OPTION_DEFINE],
+[m4_define(_LT_MANGLE_DEFUN([$1]), [$2])[]dnl
+])# LT_OPTION_DEFINE
+
+
+# dlopen
+# ------
+LT_OPTION_DEFINE([dlopen], [enable_dlopen=yes])
+
+AU_DEFUN([AC_LIBTOOL_DLOPEN],
+[_LT_SET_OPTION([dlopen])
+AC_DIAGNOSE([obsolete],
+[$0: Remove this warning and the call to _LT_SET_OPTION when you
+put the `dlopen' option into LT_LIBTOOL_INIT's first parameter.])
+])
+
+
+# win32-dll
+# ---------
+# Declare package support for building win32 dll's.
+LT_OPTION_DEFINE([win32-dll],
+[enable_win32_dll=yes
+
+case $host in
+*-*-cygwin* | *-*-mingw* | *-*-pw32*)
+  AC_CHECK_TOOL(AS, as, false)
+  AC_CHECK_TOOL(DLLTOOL, dlltool, false)
+  AC_CHECK_TOOL(OBJDUMP, objdump, false)
+  ;;
+esac
+
+test -z "$AS" && AS=as
+_LT_DECL([], [AS],      [0], [Assembler program])dnl
+
+test -z "$DLLTOOL" && DLLTOOL=dlltool
+_LT_DECL([], [DLLTOOL], [0], [DLL creation program])dnl
+
+test -z "$OBJDUMP" && OBJDUMP=objdump
+_LT_DECL([], [OBJDUMP], [0], [Object dumper program])dnl
+])# win32-dll
+
+AU_DEFUN([AC_LIBTOOL_WIN32_DLL],
+[_LT_SET_OPTION([win32-dll])
+AC_DIAGNOSE([obsolete],
+[$0: Remove this warning and the call to _LT_SET_OPTION when you
+put the `win32-dll' option into LT_LIBTOOL_INIT's first parameter.])
+])
+
+
+# _LT_ENABLE_SHARED([DEFAULT])
+# ----------------------------
+# implement the --enable-shared flag, and supports the `shared' and
+# `disable-shared' LT_INIT_LIBTOOL options.
+# DEFAULT is either `yes' or `no'.  If omitted, it defaults to `yes'.
+m4_define([_LT_ENABLE_SHARED],
+[m4_define([_LT_ENABLE_SHARED_DEFAULT], [m4_if($1, no, no, yes)])dnl
+AC_ARG_ENABLE([shared],
+    [AC_HELP_STRING([--enable-shared@<:@=PKGS@:>@],
+	[build shared libraries @<:@default=]_LT_ENABLE_SHARED_DEFAULT[@:>@])],
+    [p=${PACKAGE-default}
+    case $enableval in
+    yes) enable_shared=yes ;;
+    no) enable_shared=no ;;
+    *)
+      enable_shared=no
+      # Look at the argument we got.  We use all the common list separators.
+      lt_save_ifs="$IFS"; IFS="${IFS}$PATH_SEPARATOR,"
+      for pkg in $enableval; do
+	IFS="$lt_save_ifs"
+	if test "X$pkg" = "X$p"; then
+	  enable_shared=yes
+	fi
+      done
+      IFS="$lt_save_ifs"
+      ;;
+    esac],
+    [enable_shared=]_LT_ENABLE_SHARED_DEFAULT)
+
+    _LT_DECL([build_libtool_libs], [enable_shared], [0],
+	[Whether or not to build shared libraries])
+])# _LT_ENABLE_SHARED
+
+LT_OPTION_DEFINE([shared], [_LT_ENABLE_SHARED([yes])])
+LT_OPTION_DEFINE([disable-shared], [_LT_ENABLE_SHARED([no])])
+
+# Old names:
+AU_DEFUN([AC_ENABLE_SHARED],
+[_LT_SET_OPTION([shared])
+AC_DIAGNOSE([obsolete],
+[$0: Remove this warning and the call to _LT_SET_OPTION when you
+put the `shared' option into LT_LIBTOOL_INIT's first parameter.])
+])
+
+AU_DEFUN([AM_ENABLE_SHARED],
+[_LT_SET_OPTION([shared])
+AC_DIAGNOSE([obsolete],
+[$0: Remove this warning and the call to _LT_SET_OPTION when you
+put the `shared' option into LT_LIBTOOL_INIT's first parameter.])
+])
+
+AU_DEFUN([AC_DISABLE_SHARED],
+[_LT_SET_OPTION([disable-shared])
+AC_DIAGNOSE([obsolete],
+[$0: Remove this warning and the call to _LT_SET_OPTION when you put
+the `disable-shared' option into LT_LIBTOOL_INIT's first parameter.])
+])
+
+AU_DEFUN([AM_DISABLE_SHARED],
+[_LT_SET_OPTION([disable-shared])
+AC_DIAGNOSE([obsolete],
+[$0: Remove this warning and the call to _LT_SET_OPTION when you put
+the `disable-shared' option into LT_LIBTOOL_INIT's first parameter.])
+])
+
+
+# _LT_ENABLE_STATIC([DEFAULT])
+# ----------------------------
+# implement the --enable-static flag, and support the `static' and
+# `disable-static' LT_INIT_LIBTOOL options.
+# DEFAULT is either `yes' or `no'.  If omitted, it defaults to `yes'.
+m4_define([_LT_ENABLE_STATIC],
+[m4_define([_LT_ENABLE_STATIC_DEFAULT], [m4_if($1, no, no, yes)])dnl
+AC_ARG_ENABLE([static],
+    [AC_HELP_STRING([--enable-static@<:@=PKGS@:>@],
+	[build static libraries @<:@default=]_LT_ENABLE_STATIC_DEFAULT[@:>@])],
+    [p=${PACKAGE-default}
+    case $enableval in
+    yes) enable_static=yes ;;
+    no) enable_static=no ;;
+    *)
+     enable_static=no
+      # Look at the argument we got.  We use all the common list separators.
+      lt_save_ifs="$IFS"; IFS="${IFS}$PATH_SEPARATOR,"
+      for pkg in $enableval; do
+	IFS="$lt_save_ifs"
+	if test "X$pkg" = "X$p"; then
+	  enable_static=yes
+	fi
+      done
+      IFS="$lt_save_ifs"
+      ;;
+    esac],
+    [enable_static=]_LT_ENABLE_STATIC_DEFAULT)
+
+    _LT_DECL([build_old_libs], [enable_static], [0],
+	[Whether or not to build static libraries])
+])# _LT_ENABLE_STATIC
+
+LT_OPTION_DEFINE([static], [_LT_ENABLE_STATIC([yes])])
+LT_OPTION_DEFINE([disable-static], [_LT_ENABLE_STATIC([no])])
+
+# Old names:
+AU_DEFUN([AC_ENABLE_STATIC],
+[_LT_SET_OPTION([static])
+AC_DIAGNOSE([obsolete],
+[$0: Remove this warning and the call to _LT_SET_OPTION when you
+put the `static' option into LT_LIBTOOL_INIT's first parameter.])
+])
+
+AU_DEFUN([AM_ENABLE_STATIC],
+[_LT_SET_OPTION([static])
+AC_DIAGNOSE([obsolete],
+[$0: Remove this warning and the call to _LT_SET_OPTION when you
+put the `static' option into LT_LIBTOOL_INIT's first parameter.])
+])
+
+AU_DEFUN([AC_DISABLE_STATIC],
+[_LT_SET_OPTION([disable-static])
+AC_DIAGNOSE([obsolete],
+[$0: Remove this warning and the call to _LT_SET_OPTION when you put
+the `disable-static' option into LT_LIBTOOL_INIT's first parameter.])
+])
+
+AU_DEFUN([AM_DISABLE_STATIC],
+[_LT_SET_OPTION([disable-static])
+AC_DIAGNOSE([obsolete],
+[$0: Remove this warning and the call to _LT_SET_OPTION when you put
+the `disable-static' option into LT_LIBTOOL_INIT's first parameter.])
+])
+
+
+# _LT_ENABLE_FAST_INSTALL([DEFAULT])
+# ----------------------------------
+# implement the --enable-fast-install flag, and support the `fast-install'
+# and `disable-fast-install' LT_INIT_LIBTOOL options.
+# DEFAULT is either `yes' or `no'.  If omitted, it defaults to `yes'.
+m4_define([_LT_ENABLE_FAST_INSTALL],
+[m4_define([_LT_ENABLE_FAST_INSTALL_DEFAULT], [m4_if($1, no, no, yes)])dnl
+AC_ARG_ENABLE([fast-install],
+    [AC_HELP_STRING([--enable-fast-install@<:@=PKGS@:>@],
+    [optimize for fast installation @<:@default=]_LT_ENABLE_FAST_INSTALL_DEFAULT[@:>@])],
+    [p=${PACKAGE-default}
+    case $enableval in
+    yes) enable_fast_install=yes ;;
+    no) enable_fast_install=no ;;
+    *)
+      enable_fast_install=no
+      # Look at the argument we got.  We use all the common list separators.
+      lt_save_ifs="$IFS"; IFS="${IFS}$PATH_SEPARATOR,"
+      for pkg in $enableval; do
+	IFS="$lt_save_ifs"
+	if test "X$pkg" = "X$p"; then
+	  enable_fast_install=yes
+	fi
+      done
+      IFS="$lt_save_ifs"
+      ;;
+    esac],
+    [enable_fast_install=]_LT_ENABLE_FAST_INSTALL_DEFAULT)
+
+_LT_DECL([fast_install], [enable_fast_install], [0],
+	 [Whether or not to optimize for fast installation])dnl
+])# _LT_ENABLE_FAST_INSTALL
+
+LT_OPTION_DEFINE([fast-install], [_LT_ENABLE_FAST_INSTALL([yes])])
+LT_OPTION_DEFINE([disable-fast-install], [_LT_ENABLE_FAST_INSTALL([no])])
+
+# Old names:
+AU_DEFUN([AC_ENABLE_FAST_INSTALL],
+[_LT_SET_OPTION([fast-install])
+AC_DIAGNOSE([obsolete],
+[$0: Remove this warning and the call to _LT_SET_OPTION when you put
+the `fast-install' option into LT_LIBTOOL_INIT's first parameter.])
+])
+
+AU_DEFUN([AC_DISABLE_FAST_INSTALL],
+[_LT_SET_OPTION([disable-fast-install])
+AC_DIAGNOSE([obsolete],
+[$0: Remove this warning and the call to _LT_SET_OPTION when you put
+the `disable-fast-install' option into LT_LIBTOOL_INIT's first parameter.])
+])
+
+
+# _LT_WITH_PIC([MODE])
+# --------------------
+# implement the --with-pic flag, and support the `pic-only' and `no-pic'
+# LT_INIT_LIBTOOL options.
+# MODE is either `yes' or `no'.  If omitted, it defaults to `both'.
+m4_define([_LT_WITH_PIC],
+[AC_ARG_WITH([pic],
+    [AC_HELP_STRING([--with-pic],
+	[try to use only PIC/non-PIC objects @<:@default=use both@:>@])],
+    [pic_mode="$withval"],
+    [pic_mode=default])
+
+test -z "$pic_mode" && pic_mode=m4_if($#, 1, $1, default)
+
+_LT_DECL([], [pic_mode], [0], [What type of objects to build])dnl
+])# _LT_WITH_PIC
+
+LT_OPTION_DEFINE([pic-only], [_LT_WITH_PIC([yes])])
+LT_OPTION_DEFINE([no-pic], [_LT_WITH_PIC([no])])
+
+# Old name:
+AU_DEFUN([AC_LIBTOOL_PIC_MODE],
+[_LT_SET_OPTION([pic-only])
+AC_DIAGNOSE([obsolete],
+[$0: Remove this warning and the call to _LT_SET_OPTION when you
+put the `pic-only' option into LT_LIBTOOL_INIT's first parameter.])
+])
diff --git a/libs/sigc++2/scripts/ltsugar.m4 b/libs/sigc++2/scripts/ltsugar.m4
new file mode 100644
index 0000000000..c0f31aa63d
--- /dev/null
+++ b/libs/sigc++2/scripts/ltsugar.m4
@@ -0,0 +1,115 @@
+# ltsugar.m4 -- libtool m4 base layer.                         -*-Autoconf-*-
+#
+# Copyright (C) 2004 Free Software Foundation, Inc.
+# Written by Gary V. Vaughan.
+#
+# This program is free software; you can redistribute it and/or modify
+# it under the terms of the GNU General Public License as published by
+# the Free Software Foundation; either version 2 of the License, or
+# (at your option) any later version.
+#
+# This program is distributed in the hope that it will be useful, but
+# WITHOUT ANY WARRANTY; without even the implied warranty of
+# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
+# General Public License for more details.
+#
+# You should have received a copy of the GNU General Public License
+# along with this program; if not, write to the Free Software
+# Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
+#
+# As a special exception to the GNU General Public License, if you
+# distribute this file as part of a program that contains a
+# configuration script generated by Autoconf, you may include it under
+# the same distribution terms that you use for the rest of that program.
+
+# serial 1
+
+# This is to help aclocal find these macros, as it can't see m4_define.
+AC_DEFUN([LTSUGAR_VERSION], [m4_if([0.1])])
+
+
+# lt_join(SEP, ARG1, [ARG2...])
+# -----------------------------
+# Produce ARG1SEPARG2...SEPARGn, omitting [] arguments and their
+# associated separator.
+m4_define([lt_join],
+[m4_case([$#],
+	 [0], [m4_fatal([$0: too few arguments: $#])],
+	 [1], [],
+	 [2], [[$2]],
+	 [m4_ifval([$2],
+		   [m4_ifval([$3],
+			     [[$2][$1][]$0([$1], m4_shiftn(2, $@))],
+		       [m4_if([$#], [3],
+			      [$2],
+			   [$0([$1], [$2], m4_shiftn(3, $@))])])],
+	      [$0([$1], m4_shiftn(2, $@))])])[]dnl
+])
+
+
+# lt_combine(SEP, PREFIX-LIST, INFIX, SUFFIX1, [SUFFIX2...])
+# ----------------------------------------------------------
+# Produce a SEP delimited list of all paired combinations of elements of
+# PREFIX-LIST with SUFFIX1 through SUFFIXn.  Each element of the list
+# has the form PREFIXmINFIXSUFFIXn.
+m4_define([lt_combine],
+[m4_if([$2], [[]], [],
+       [lt_join(m4_quote(m4_default([$1], [, ])),
+		_$0([$1], m4_car($2)[$3], m4_shiftn(3, $@)),
+		$0([$1], m4_cdr($2), m4_shiftn(2, $@)))])])
+m4_define([_lt_combine],
+[m4_if([$3], [], [],
+       [lt_join(m4_quote(m4_default([$1], [, ])),
+		[$2$3],
+		$0([$1], [$2], m4_shiftn(3, $@)))])[]dnl
+])
+
+
+# lt_if_append_uniq(MACRO-NAME, VARNAME, [SEPARATOR], [UNIQ], [NOT-UNIQ])
+# -----------------------------------------------------------------------
+# Iff MACRO-NAME does not yet contain VARNAME, then append it (delimited
+# by SEPARATOR if supplied) and expand UNIQ, else NOT-UNIQ.
+m4_define([lt_if_append_uniq],
+[m4_ifdef([$1],
+	[m4_bmatch($3[]m4_defn([$1])$3, $3[]m4_re_escape([$2])$3,
+		[$5],
+	    [m4_append([$1], [$2], [$3])$4])],
+    [m4_append([$1], [$2], [$3])$4])])
+
+
+# lt_dict_add(DICT, KEY, VALUE)
+# -----------------------------
+m4_define([lt_dict_add],
+[m4_define([$1($2)], [$4])])
+
+
+# lt_dict_add_subkey(DICT, KEY, SUBKEY, VALUE)
+# --------------------------------------------
+m4_define([lt_dict_add_subkey],
+[m4_define([$1($2:$3)], [$4])])
+
+
+# lt_dict_fetch(DICT, KEY, [SUBKEY])
+# ----------------------------------
+m4_define([lt_dict_fetch],
+[m4_ifval([$3],
+	m4_ifdef([$1($2:$3)], [m4_defn([$1($2:$3)])]),
+    m4_ifdef([$1($2)], [m4_defn([$1($2)])]))])
+
+
+# lt_if_dict_fetch(DICT, KEY, [SUBKEY], VALUE, IF-TRUE, [IF-FALSE])
+# -----------------------------------------------------------------
+m4_define([lt_if_dict_fetch],
+[m4_if(lt_dict_fetch([$1], [$2], [$3]), [$4],
+	[$5],
+    [$6])])
+
+
+# lt_dict_filter(DICT, [SUBKEY], VALUE, [SEPARATOR], KEY, [...])
+# ------------------------------------------------------------
+m4_define([lt_dict_filter],
+[m4_if([$5], [], [],
+  [lt_join(m4_quote(m4_default([$4], [[, ]])),
+	   m4_quote(lt_if_dict_fetch([$1], [$5], [$2], [$3], [$5])),
+	   m4_quote($0([$1], [$2], [$3], [$4], m4_shiftn(5, $@))))])dnl
+])
diff --git a/libs/sigc++2/scripts/ltversion.m4 b/libs/sigc++2/scripts/ltversion.m4
new file mode 100644
index 0000000000..8b8db37ad4
--- /dev/null
+++ b/libs/sigc++2/scripts/ltversion.m4
@@ -0,0 +1,15 @@
+# ltversion.m4 -- version numbers			-*- Autoconf -*-
+# Generated from ltversion.in; do not edit by hand.
+
+# serial 1467
+# This file is part of GNU Libtool
+
+m4_define([LT_PACKAGE_VERSION], [])
+m4_define([LT_PACKAGE_REVISION], [1.1467])
+
+AC_DEFUN([LTVERSION_VERSION],
+[macro_version=''
+macro_revision='1.1467'
+_LT_DECL(, macro_version, 0, [Which release of libtool.m4 was used?])
+_LT_DECL(, macro_revision, 0)
+])
diff --git a/libs/sigc++2/sigc++-2.0.pc.in b/libs/sigc++2/sigc++-2.0.pc.in
new file mode 100644
index 0000000000..7c55753531
--- /dev/null
+++ b/libs/sigc++2/sigc++-2.0.pc.in
@@ -0,0 +1,10 @@
+prefix=@prefix@
+exec_prefix=@exec_prefix@
+libdir=@libdir@
+includedir=@includedir@
+
+Name: libsigc++ 2
+Description: Typesafe signal and callback system for C++
+Version: @VERSION@
+Libs: -L${libdir} -lsigc-2.0
+Cflags: -I${includedir}/sigc++-2.0 -I${libdir}/sigc++-2.0/include
diff --git a/libs/sigc++2/sigc++/.cvsignore b/libs/sigc++2/sigc++/.cvsignore
new file mode 100644
index 0000000000..051d1bd50b
--- /dev/null
+++ b/libs/sigc++2/sigc++/.cvsignore
@@ -0,0 +1,3 @@
+Makefile
+Makefile.in
+.deps
diff --git a/libs/sigc++2/sigc++/Makefile.am b/libs/sigc++2/sigc++/Makefile.am
new file mode 100644
index 0000000000..45fe09d0c1
--- /dev/null
+++ b/libs/sigc++2/sigc++/Makefile.am
@@ -0,0 +1,96 @@
+# Base (./)
+base_m4 = template.macros.m4 signal.h.m4 slot.h.m4 method_slot.h.m4 \
+	  object_slot.h.m4 class_slot.h.m4 hide.h.m4 retype.h.m4
+base_built_cc =
+base_built_h = signal.h slot.h method_slot.h \
+	       object_slot.h class_slot.h hide.h retype.h
+
+signal.cc : signal.h signal_base.h functors/slot.h functors/slot_base.h functors/mem_fun.h functors/functor_trait.h
+
+# Functors (functors/)
+functors_m4 = functor_trait.h.m4 slot.h.m4 ptr_fun.h.m4 mem_fun.h.m4
+functors_built_cc = 
+functors_built_h = functor_trait.h slot.h ptr_fun.h mem_fun.h
+
+functors/slot.cc : functors/slot.h functors/slot_base.h functors/functor_trait.h
+
+# Adaptors (adaptors/)
+adaptors_m4 = deduce_result_type.h.m4 adaptor_trait.h.m4 bind.h.m4 bind_return.h.m4 \
+	      retype_return.h.m4 hide.h.m4 retype.h.m4 compose.h.m4 exception_catch.h.m4
+adaptors_built_cc =
+adaptors_built_h = deduce_result_type.h adaptor_trait.h bind.h bind_return.h \
+                   retype_return.h hide.h retype.h compose.h exception_catch.h
+
+# Lambda (adaptors/lambda)
+lambda_m4 = base.h.m4 select.h.m4 operator.h.m4 group.h.m4 lambda.cc.m4
+lambda_built_cc = lambda.cc
+lambda_built_h = base.h select.h operator.h group.h
+
+adaptors/lambda/lambda.cc : adaptors/lambda/select.h adaptors/lambda/base.h \
+                   adaptors/adaptor_trait.h adaptors/deduce_result_type.h \
+                   functors/ptr_fun.h functors/mem_fun.h functors/functor_trait.h
+
+# Subdirectories needed also in the build dir
+build_subdirs = functors adaptors adaptors/lambda
+
+# Combine all the above parts with right directories prefixed
+sigc_m4 = $(base_m4:%=macros/%) \
+	  $(functors_m4:%=functors/macros/%) \
+          $(adaptors_m4:%=adaptors/macros/%) \
+          $(lambda_m4:%=adaptors/lambda/macros/%)
+sigc_built_cc = $(base_built_cc) \
+	  $(functors_built_cc:%=functors/%) \
+          $(adaptors_built_cc:%=adaptors/%) \
+          $(lambda_built_cc:%=adaptors/lambda/%)
+sigc_built_h = $(base_built_h) \
+	  $(functors_built_h:%=functors/%) \
+          $(adaptors_built_h:%=adaptors/%) \
+          $(lambda_built_h:%=adaptors/lambda/%)
+
+EXTRA_DIST = $(sigc_m4) $(sigc_built_h) $(sigc_built_cc)
+
+# install the headers
+library_includedir = $(includedir)/sigc++-2.0/sigc++
+nobase_library_include_HEADERS = $(sigc_m4) $(sigc_built_h) \
+  sigc++.h connection.h trackable.h reference_wrapper.h type_traits.h visit_each.h \
+  object.h retype_return.h bind.h bind_return.h compatibility.h signal_base.h \
+  functors/functors.h \
+  functors/slot_base.h \
+  adaptors/adaptors.h \
+  adaptors/lambda/lambda.h
+
+# build the library
+lib_LTLIBRARIES = libsigc-2.0.la
+libsigc_2_0_la_SOURCES = signal.cc signal_base.cc trackable.cc connection.cc \
+                         functors/slot.cc functors/slot_base.cc \
+			 adaptors/lambda/lambda.cc
+libsigc_2_0_la_LDFLAGS  = 
+BUILT_SOURCES = $(sigc_built_h) $(sigc_built_cc)
+
+CLEANFILES = build-subdirs-stamp
+
+# Remove the generated sources during maintainer-clean:
+MAINTAINERCLEANFILES = $(built_sources)
+
+M4_DIR = $(top_srcdir)/sigc++/macros
+
+# Rules to generate .h and .cc from .h.m4 and .cc.m4:
+%.h: macros/%.h.m4 $(M4_DIR)/template.macros.m4
+	        $(M4) $(M4_INCLUDES) $(DEFINES) -I $(M4_DIR) -I macros $<  > $@
+
+%.cc: macros/%.cc.m4 $(M4_DIR)/template.macros.m4
+	        $(M4) $(M4_INCLUDES) $(DEFINES) -I $(M4_DIR) -I macros $<  > $@
+
+# This would be a necessary target for VPATH builds from a clean CVS checkout,
+# but I'm not sure where to invoke it... [rotty]
+build-subdirs-stamp:
+	for dir in $(build_subdirs); do \
+	  test -d $$dir || mkdir $$dir; \
+	done
+	touch build-subdirs-stamp
+
+# Remove current directory from DEFAULT_INCLUDES because signal.h has
+# the same name as a standard header:
+DEFAULT_INCLUDES =
+AM_CPPFLAGS = -I$(top_srcdir) -I$(top_builddir)
+
diff --git a/libs/sigc++2/sigc++/adaptors/adaptor_trait.h b/libs/sigc++2/sigc++/adaptors/adaptor_trait.h
new file mode 100644
index 0000000000..8b618d7450
--- /dev/null
+++ b/libs/sigc++2/sigc++/adaptors/adaptor_trait.h
@@ -0,0 +1,362 @@
+// -*- c++ -*-
+/* Do not edit! -- generated file */
+#ifndef _SIGC_ADAPTORS_MACROS_ADAPTOR_TRAITHM4_
+#define _SIGC_ADAPTORS_MACROS_ADAPTOR_TRAITHM4_
+#include <sigc++config.h> //To get SIGC_TEMPLATE_KEYWORD_OPERATOR_OVERLOAD
+#include <sigc++/visit_each.h>
+#include <sigc++/functors/functor_trait.h>
+#include <sigc++/functors/ptr_fun.h>
+#include <sigc++/functors/mem_fun.h>
+#include <sigc++/adaptors/deduce_result_type.h>
+
+namespace sigc {
+
+// Call either operator()<>() or sun_forte_workaround<>(),
+// depending on the compiler:
+#ifdef SIGC_GCC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  #define SIGC_WORKAROUND_OPERATOR_PARENTHESES template operator()
+  #define SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+#else
+  #ifdef SIGC_MSVC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+    #define SIGC_WORKAROUND_OPERATOR_PARENTHESES operator()
+    #define SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  #else
+    #define SIGC_WORKAROUND_OPERATOR_PARENTHESES sun_forte_workaround
+  #endif
+#endif
+
+
+template <class T_functor> struct adapts;
+
+/** @defgroup adaptors Adaptors
+ * Adaptors are functors that alter the signature of a functor's
+ * operator()().
+ *
+ * The adaptor types libsigc++ provides
+ * are created with bind(), bind_return(), hide(), hide_return(),
+ * retype_return(), retype(), compose(), exception_catch() and group().
+ *
+ * You can easily derive your own adaptor type from sigc::adapts.
+ */
+
+/** Converts an arbitrary functor into an adaptor type.
+ * All adaptor tyes in libsigc++ are unnumbered and have
+ * a <tt>template operator()</tt> member of every argument count
+ * they support. These functions in turn invoke a stored adaptor's
+ * <tt>template operator()</tt> processing the arguments and return
+ * value in a characteristic manner. Explicit function template
+ * instantiation is used to pass type hints thus saving copy costs.
+ *
+ * adaptor_functor is a glue between adaptors and arbitrary functors
+ * that just passes on the arguments. You won't use this type directly.
+ *
+ * The template argument @e T_functor determines the type of stored
+ * functor.
+ *
+ * @ingroup adaptors
+ */
+template <class T_functor>
+struct adaptor_functor : public adaptor_base
+{
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef typename sigc::deduce_result_type<T_functor, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type type; };
+  typedef typename functor_trait<T_functor>::result_type result_type;
+
+  /** Invokes the wrapped functor passing on the arguments.
+   * @return The return value of the functor invocation.
+   */
+  result_type
+  operator()() const;
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  result_type sun_forte_workaround() const
+    { return operator(); }
+  #endif
+  
+  /** Invokes the wrapped functor passing on the arguments.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  operator()(T_arg1 _A_arg1) const
+    { return functor_(_A_arg1); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  sun_forte_workaround(T_arg1 _A_arg1) const
+    { //Just calling operator() tries to copy the argument:
+      return functor_(_A_arg1);
+    }
+  #endif
+  
+  /** Invokes the wrapped functor passing on the arguments.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2) const
+    { return functor_(_A_arg1,_A_arg2); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2) const
+    { //Just calling operator() tries to copy the argument:
+      return functor_(_A_arg1,_A_arg2);
+    }
+  #endif
+  
+  /** Invokes the wrapped functor passing on the arguments.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3) const
+    { return functor_(_A_arg1,_A_arg2,_A_arg3); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3) const
+    { //Just calling operator() tries to copy the argument:
+      return functor_(_A_arg1,_A_arg2,_A_arg3);
+    }
+  #endif
+  
+  /** Invokes the wrapped functor passing on the arguments.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4) const
+    { return functor_(_A_arg1,_A_arg2,_A_arg3,_A_arg4); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4) const
+    { //Just calling operator() tries to copy the argument:
+      return functor_(_A_arg1,_A_arg2,_A_arg3,_A_arg4);
+    }
+  #endif
+  
+  /** Invokes the wrapped functor passing on the arguments.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @param _A_arg5 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5) const
+    { return functor_(_A_arg1,_A_arg2,_A_arg3,_A_arg4,_A_arg5); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5) const
+    { //Just calling operator() tries to copy the argument:
+      return functor_(_A_arg1,_A_arg2,_A_arg3,_A_arg4,_A_arg5);
+    }
+  #endif
+  
+  /** Invokes the wrapped functor passing on the arguments.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @param _A_arg5 Argument to be passed on to the functor.
+   * @param _A_arg6 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5,T_arg6 _A_arg6) const
+    { return functor_(_A_arg1,_A_arg2,_A_arg3,_A_arg4,_A_arg5,_A_arg6); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5,T_arg6 _A_arg6) const
+    { //Just calling operator() tries to copy the argument:
+      return functor_(_A_arg1,_A_arg2,_A_arg3,_A_arg4,_A_arg5,_A_arg6);
+    }
+  #endif
+  
+  /** Invokes the wrapped functor passing on the arguments.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @param _A_arg5 Argument to be passed on to the functor.
+   * @param _A_arg6 Argument to be passed on to the functor.
+   * @param _A_arg7 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5,T_arg6 _A_arg6,T_arg7 _A_arg7) const
+    { return functor_(_A_arg1,_A_arg2,_A_arg3,_A_arg4,_A_arg5,_A_arg6,_A_arg7); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5,T_arg6 _A_arg6,T_arg7 _A_arg7) const
+    { //Just calling operator() tries to copy the argument:
+      return functor_(_A_arg1,_A_arg2,_A_arg3,_A_arg4,_A_arg5,_A_arg6,_A_arg7);
+    }
+  #endif
+  
+  /// Constructs an invalid functor.
+  adaptor_functor()
+    {}
+
+  /** Constructs an adaptor_functor object that wraps the passed functor.
+   * @param _A_functor Functor to invoke from operator()().
+   */
+  explicit adaptor_functor(const T_functor& _A_functor)
+    : functor_(_A_functor)
+    {}
+
+  /** Constructs an adaptor_functor object that wraps the passed (member)
+   * function pointer.
+   * @param _A_type Pointer to function or class method to invoke from operator()().
+   */
+  template <class T_type>
+  explicit adaptor_functor(const T_type& _A_type)
+    : functor_(_A_type)
+    {}
+
+  /// Functor that is invoked from operator()().
+  mutable T_functor functor_;
+};
+
+template <class T_functor>
+typename adaptor_functor<T_functor>::result_type
+adaptor_functor<T_functor>::operator()() const
+  { return functor_(); }
+
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::adaptor_functor performs a functor
+ * on the functor stored in the sigc::adaptor_functor object.
+ *
+ * @ingroup adaptors
+ */
+template <class T_action, class T_functor>
+void visit_each(const T_action& _A_action,
+                const adaptor_functor<T_functor>& _A_target)
+{
+  visit_each(_A_action, _A_target.functor_);
+}
+
+
+/** Trait that specifies what is the adaptor version of a functor type.
+ * Template specializations for sigc::adaptor_base derived functors,
+ * for function pointers and for class methods are provided.
+ *
+ * The template argument @e T_functor is the functor type to convert.
+ * @e I_isadaptor indicates whether @e T_functor inherits from sigc::adaptor_base.
+ *
+ * @ingroup adaptors
+ */
+template <class T_functor, bool I_isadaptor = is_base_and_derived<adaptor_base, T_functor>::value> struct adaptor_trait;
+
+/** Trait that specifies what is the adaptor version of a functor type.
+ * This template specialization is used for types that inherit from adaptor_base.
+ * adaptor_type is equal to @p T_functor in this case.
+ */
+template <class T_functor> 
+struct adaptor_trait<T_functor, true>
+{
+  typedef typename T_functor::result_type result_type;
+  typedef T_functor functor_type;
+  typedef T_functor adaptor_type;
+};
+
+/** Trait that specifies what is the adaptor version of a functor type.
+ * This template specialization is used for arbitrary functors,
+ * for function pointers and for class methods are provided.
+ * The latter are converted into @p pointer_functor or @p mem_functor types.
+ * adaptor_type is equal to @p adaptor_functor<functor_type>.
+ */
+template <class T_functor>
+struct adaptor_trait<T_functor, false>
+{
+  typedef typename functor_trait<T_functor>::result_type result_type;
+  typedef typename functor_trait<T_functor>::functor_type functor_type;
+  typedef adaptor_functor<functor_type> adaptor_type;
+};
+
+
+/** Base type for adaptors.
+ * adapts wraps adaptors, functors, function pointers and class methods.
+ * It contains a single member functor which is always a sigc::adaptor_base.
+ * The typedef adaptor_type defines the exact type that is used
+ * to store the adaptor, functor, function pointer or class method passed
+ * into the constructor. It differs from @e T_functor unless @e T_functor
+ * inherits from sigc::adaptor_base.
+ *
+ * @par Example of a simple adaptor:
+ *   @code
+ *   template <T_functor>
+ *   struct my_adpator : public sigc::adapts<T_functor>
+ *   {
+ *     template <class T_arg1=void, class T_arg2=void>
+ *     struct deduce_result_type
+ *     { typedef typename sigc::deduce_result_type<T_functor, T_arg1, T_arg2>::type type; };
+ *     typedef typename sigc::functor_trait<T_functor>::result_type result_type;
+ *
+ *     result_type
+ *     operator()() const;
+ *
+ *     template <class T_arg1>
+ *     typename deduce_result_type<T_arg1>::type
+ *     operator()(T_arg1 _A_arg1) const;
+ *
+ *     template <class T_arg1, class T_arg2>
+ *     typename deduce_result_type<T_arg1, T_arg2>::type
+ *     operator()(T_arg1 _A_arg1, class T_arg2) const;
+ *
+ *     explicit adaptor_functor(const T_functor& _A_functor) // Constructs a my_functor object that wraps the passed functor.
+ *       : sigc::adapts<T_functor>(_A_functor) {}
+ *
+ *     mutable T_functor functor_; // Functor that is invoked from operator()().
+ *   };
+ *   @endcode
+ *
+ * @ingroup adaptors
+ */
+template <class T_functor>
+struct adapts : public adaptor_base
+{
+  typedef typename adaptor_trait<T_functor>::result_type  result_type;
+  typedef typename adaptor_trait<T_functor>::adaptor_type adaptor_type;
+
+  /** Constructs an adaptor that wraps the passed functor.
+   * @param _A_functor Functor to invoke from operator()().
+   */
+  explicit adapts(const T_functor& _A_functor)
+    : functor_(_A_functor)
+    {}
+
+  /// Adaptor that is invoked from operator()().
+  mutable adaptor_type functor_;
+};
+
+} /* namespace sigc */
+#endif /* _SIGC_ADAPTORS_MACROS_ADAPTOR_TRAITHM4_ */
diff --git a/libs/sigc++2/sigc++/adaptors/adaptors.h b/libs/sigc++2/sigc++/adaptors/adaptors.h
new file mode 100644
index 0000000000..950063b122
--- /dev/null
+++ b/libs/sigc++2/sigc++/adaptors/adaptors.h
@@ -0,0 +1,32 @@
+// -*- c++ -*-
+/*
+ * Copyright 2002, The libsigc++ Development Team
+ *
+ *  This library is free software; you can redistribute it and/or
+ *  modify it under the terms of the GNU Lesser General Public
+ *  License as published by the Free Software Foundation; either
+ *  version 2.1 of the License, or (at your option) any later version.
+ *
+ *  This library is distributed in the hope that it will be useful,
+ *  but WITHOUT ANY WARRANTY; without even the implied warranty of
+ *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
+ *  Lesser General Public License for more details.
+ *
+ *  You should have received a copy of the GNU Lesser General Public
+ *  License along with this library; if not, write to the Free Software
+ *  Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
+ *
+ */
+#ifndef _SIGC_ADAPTOR_HPP_
+#define _SIGC_ADAPTOR_HPP_
+
+#include <sigc++/adaptors/bind.h>
+#include <sigc++/adaptors/bind_return.h>
+#include <sigc++/adaptors/hide.h>
+#include <sigc++/adaptors/retype_return.h>
+#include <sigc++/adaptors/retype.h>
+#include <sigc++/adaptors/compose.h>
+#include <sigc++/adaptors/exception_catch.h>
+#include <sigc++/adaptors/lambda/lambda.h>
+
+#endif /* _SIGC_ADAPTOR_HPP_ */
diff --git a/libs/sigc++2/sigc++/adaptors/bind.h b/libs/sigc++2/sigc++/adaptors/bind.h
new file mode 100644
index 0000000000..81edaf7934
--- /dev/null
+++ b/libs/sigc++2/sigc++/adaptors/bind.h
@@ -0,0 +1,2262 @@
+// -*- c++ -*-
+/* Do not edit! -- generated file */
+#ifndef _SIGC_ADAPTORS_MACROS_BINDHM4_
+#define _SIGC_ADAPTORS_MACROS_BINDHM4_
+#include <sigc++/adaptors/adaptor_trait.h>
+
+namespace sigc { 
+
+#ifndef DOXYGEN_SHOULD_SKIP_THIS
+
+namespace internal {
+
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+struct count_void
+  { static const int value=0; };
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+struct count_void<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,void>
+  { static const int value=1; };
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+struct count_void<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,void,void>
+  { static const int value=2; };
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+struct count_void<T_arg1,T_arg2,T_arg3,T_arg4,void,void,void>
+  { static const int value=3; };
+template <class T_arg1,class T_arg2,class T_arg3>
+struct count_void<T_arg1,T_arg2,T_arg3,void,void,void,void>
+  { static const int value=4; };
+template <class T_arg1,class T_arg2>
+struct count_void<T_arg1,T_arg2,void,void,void,void,void>
+  { static const int value=5; };
+template <class T_arg1>
+struct count_void<T_arg1,void,void,void,void,void,void>
+  { static const int value=6; };
+template <>
+struct count_void<void,void,void,void,void,void,void>
+  { static const int value=7; };
+
+} /* namespace internal */
+
+#endif /*DOXYGEN_SHOULD_SKIP_THIS*/
+
+
+/** @defgroup bind bind(), bind_return()
+ * sigc::bind() alters an arbitrary functor by fixing arguments to certain values.
+ * Up to 7 arguments can be bound at a time.
+ * For single argument binding overloads of sigc::bind() are provided that let you
+ * specify the zero-based position of the argument to fix with the first template parameter.
+ * (A value of @p -1 fixes the last argument so sigc::bind<-1>() gives the same result as sigc::bind().)
+ * The types of the arguments can optionally be specified if not deduced.
+ *
+ * @par Examples:
+ *   @code
+ *   void foo(int, int, int);
+ *   // single argument binding ...
+ *   sigc::bind(&foo,1)(2,3);     //fixes the last (third) argument and calls foo(2,3,1)
+ *   sigc::bind<-1>(&foo,1)(2,3); //same as bind(&foo,1)(2,3) (calls foo(2,3,1))
+ *   sigc::bind<0>(&foo,1)(2,3);  //fixes the first argument and calls foo(1,2,3)
+ *   sigc::bind<1>(&foo,1)(2,3);  //fixes the second argument and calls foo(2,1,3)
+ *   sigc::bind<2>(&foo,1)(2,3);  //fixes the third argument and calls foo(2,3,1)
+ *   // multi argument binding ...
+ *   sigc::bind(&foo,1,2)(3);     //fixes the last two arguments and calls foo(3,1,2)
+ *   sigc::bind(&foo,1,2,3)();    //fixes all three arguments and calls foo(1,2,3)
+ *   @endcode
+ *
+ * The functor sigc::bind() returns can be passed into
+ * sigc::signal::connect() directly.
+ *
+ * @par Example:
+ *   @code
+ *   sigc::signal<void> some_signal;
+ *   void foo(int);
+ *   some_signal.connect(sigc::bind(&foo,1));
+ *   @endcode
+ *
+ * sigc::bind_return() alters an arbitrary functor by
+ * fixing its return value to a certain value.
+ *
+ * @par Example:
+ *   @code
+ *   void foo();
+ *   std::cout << sigc::bind_return(&foo, 5)(); // calls foo() and returns 5
+ *   @endcode
+ *
+ * You can bind references to functors by passing the objects through
+ * the sigc::ref() helper function.
+ *
+ * @par Example:
+ *   @code
+ *   int some_int;
+ *   sigc::signal<void> some_signal;
+ *   void foo(int&);
+ *   some_signal.connect(sigc::bind(&foo,sigc::ref(some_int)));
+ *   @endcode
+ *
+ * If you bind an object of a sigc::trackable derived type to a functor
+ * by reference, a slot assigned to the bind adaptor is cleared automatically
+ * when the object goes out of scope.
+ *
+ * @par Example:
+ *   @code
+ *   struct bar : public sigc::trackable {} some_bar;
+ *   sigc::signal<void> some_signal;
+ *   void foo(bar&);
+ *   some_signal.connect(sigc::bind(&foo,sigc::ref(some_bar)));
+ *     // disconnected automatically if some_bar goes out of scope
+ *   @endcode
+ *
+ * For a more powerful version of this functionality see the lambda
+ * library adaptor sigc::group() which can bind, hide and reorder
+ * arguments arbitrarily.  Although sigc::group() is more flexible,
+ * sigc::bind() provides a means of binding parameters when then total
+ * number of parameters called is variable.
+ *
+ * @ingroup adaptors
+ */
+
+/** Adaptor that binds an argument to the wrapped functor.
+ * Use the convenience function sigc::bind() to create an instance of sigc::bind_functor.
+ *
+ * The following template arguments are used:
+ * - @e I_location Zero-based position of the argument to fix (@p -1 for the last argument).
+
+ * - @e T_type1 Type of the 1st bound argument.
+ * - @e T_type2 Type of the 2st bound argument.
+ * - @e T_type3 Type of the 3st bound argument.
+ * - @e T_type4 Type of the 4st bound argument.
+ * - @e T_type5 Type of the 5st bound argument.
+ * - @e T_type6 Type of the 6st bound argument.
+ * - @e T_type7 Type of the 7st bound argument.
+ * - @e T_functor Type of the functor to wrap.
+ *
+ * @ingroup bind
+ */
+template <int I_location, class T_functor, class T_type1=nil,class T_type2=nil,class T_type3=nil,class T_type4=nil,class T_type5=nil,class T_type6=nil,class T_type7=nil>
+struct bind_functor;
+
+/** Adaptor that binds an argument to the wrapped functor.
+ * This template specialization fixes the 1th argument of the wrapped functor.
+ *
+ * @ingroup bind
+ */
+template <class T_functor, class T_bound>
+struct bind_functor<0, T_functor, T_bound> : public adapts<T_functor>
+{
+  typedef typename adapts<T_functor>::adaptor_type adaptor_type;
+
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_bound>::pass, typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass>::type type; };
+  typedef typename adaptor_type::result_type  result_type;
+
+  /** Invokes the wrapped functor passing on the bound argument only.
+   * @return The return value of the functor invocation.
+   */
+  result_type
+  operator()();
+
+  /** Invokes the wrapped functor passing on the arguments.
+   * bound_ is passed as the 1th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  operator()(T_arg1 _A_arg1)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_bound>::pass, typename type_trait<T_arg1>::pass>
+        (bound_, _A_arg1);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  sun_forte_workaround(T_arg1 _A_arg1)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_bound>::pass, typename type_trait<T_arg1>::pass>
+        (bound_, _A_arg1);
+    }
+  #endif
+    
+  /** Invokes the wrapped functor passing on the arguments.
+   * bound_ is passed as the 1th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_bound>::pass, typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass>
+        (bound_, _A_arg1, _A_arg2);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_bound>::pass, typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass>
+        (bound_, _A_arg1, _A_arg2);
+    }
+  #endif
+    
+  /** Invokes the wrapped functor passing on the arguments.
+   * bound_ is passed as the 1th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_bound>::pass, typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass>
+        (bound_, _A_arg1, _A_arg2, _A_arg3);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_bound>::pass, typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass>
+        (bound_, _A_arg1, _A_arg2, _A_arg3);
+    }
+  #endif
+    
+  /** Invokes the wrapped functor passing on the arguments.
+   * bound_ is passed as the 1th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_bound>::pass, typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass>
+        (bound_, _A_arg1, _A_arg2, _A_arg3, _A_arg4);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_bound>::pass, typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass>
+        (bound_, _A_arg1, _A_arg2, _A_arg3, _A_arg4);
+    }
+  #endif
+    
+  /** Invokes the wrapped functor passing on the arguments.
+   * bound_ is passed as the 1th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @param _A_arg5 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_bound>::pass, typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass>
+        (bound_, _A_arg1, _A_arg2, _A_arg3, _A_arg4, _A_arg5);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_bound>::pass, typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass>
+        (bound_, _A_arg1, _A_arg2, _A_arg3, _A_arg4, _A_arg5);
+    }
+  #endif
+    
+  /** Invokes the wrapped functor passing on the arguments.
+   * bound_ is passed as the 1th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @param _A_arg5 Argument to be passed on to the functor.
+   * @param _A_arg6 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5,T_arg6 _A_arg6)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_bound>::pass, typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass>
+        (bound_, _A_arg1, _A_arg2, _A_arg3, _A_arg4, _A_arg5, _A_arg6);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5,T_arg6 _A_arg6)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_bound>::pass, typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass>
+        (bound_, _A_arg1, _A_arg2, _A_arg3, _A_arg4, _A_arg5, _A_arg6);
+    }
+  #endif
+    
+  /** Constructs a bind_functor object that binds an argument to the passed functor.
+   * @param _A_functor Functor to invoke from operator()().
+   * @param _A_bound Argument to bind to the functor.
+   */
+  bind_functor(typename type_trait<T_functor>::take _A_func, typename type_trait<T_bound>::take _A_bound)
+    : adapts<T_functor>(_A_func), bound_(_A_bound)
+    {}
+
+  /// The argument bound to the functor.
+  T_bound bound_;
+};
+
+template <class T_functor, class T_bound>
+typename bind_functor<0, T_functor, T_bound>::result_type
+bind_functor<0, T_functor, T_bound>::operator()()
+  { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_bound>::pass> (bound_); }
+
+/** Adaptor that binds an argument to the wrapped functor.
+ * This template specialization fixes the 2th argument of the wrapped functor.
+ *
+ * @ingroup bind
+ */
+template <class T_functor, class T_bound>
+struct bind_functor<1, T_functor, T_bound> : public adapts<T_functor>
+{
+  typedef typename adapts<T_functor>::adaptor_type adaptor_type;
+
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_arg1>::pass, typename type_trait<T_bound>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass>::type type; };
+  typedef typename adaptor_type::result_type  result_type;
+
+  /** Invokes the wrapped functor passing on the bound argument only.
+   * @return The return value of the functor invocation.
+   */
+  result_type
+  operator()();
+
+  /** Invokes the wrapped functor passing on the arguments.
+   * bound_ is passed as the 2th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  operator()(T_arg1 _A_arg1)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_bound>::pass>
+        (_A_arg1, bound_);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  sun_forte_workaround(T_arg1 _A_arg1)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_bound>::pass>
+        (_A_arg1, bound_);
+    }
+  #endif
+    
+  /** Invokes the wrapped functor passing on the arguments.
+   * bound_ is passed as the 2th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_bound>::pass, typename type_trait<T_arg2>::pass>
+        (_A_arg1, bound_, _A_arg2);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_bound>::pass, typename type_trait<T_arg2>::pass>
+        (_A_arg1, bound_, _A_arg2);
+    }
+  #endif
+    
+  /** Invokes the wrapped functor passing on the arguments.
+   * bound_ is passed as the 2th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_bound>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass>
+        (_A_arg1, bound_, _A_arg2, _A_arg3);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_bound>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass>
+        (_A_arg1, bound_, _A_arg2, _A_arg3);
+    }
+  #endif
+    
+  /** Invokes the wrapped functor passing on the arguments.
+   * bound_ is passed as the 2th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_bound>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass>
+        (_A_arg1, bound_, _A_arg2, _A_arg3, _A_arg4);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_bound>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass>
+        (_A_arg1, bound_, _A_arg2, _A_arg3, _A_arg4);
+    }
+  #endif
+    
+  /** Invokes the wrapped functor passing on the arguments.
+   * bound_ is passed as the 2th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @param _A_arg5 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_bound>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass>
+        (_A_arg1, bound_, _A_arg2, _A_arg3, _A_arg4, _A_arg5);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_bound>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass>
+        (_A_arg1, bound_, _A_arg2, _A_arg3, _A_arg4, _A_arg5);
+    }
+  #endif
+    
+  /** Invokes the wrapped functor passing on the arguments.
+   * bound_ is passed as the 2th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @param _A_arg5 Argument to be passed on to the functor.
+   * @param _A_arg6 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5,T_arg6 _A_arg6)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_bound>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass>
+        (_A_arg1, bound_, _A_arg2, _A_arg3, _A_arg4, _A_arg5, _A_arg6);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5,T_arg6 _A_arg6)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_bound>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass>
+        (_A_arg1, bound_, _A_arg2, _A_arg3, _A_arg4, _A_arg5, _A_arg6);
+    }
+  #endif
+    
+  /** Constructs a bind_functor object that binds an argument to the passed functor.
+   * @param _A_functor Functor to invoke from operator()().
+   * @param _A_bound Argument to bind to the functor.
+   */
+  bind_functor(typename type_trait<T_functor>::take _A_func, typename type_trait<T_bound>::take _A_bound)
+    : adapts<T_functor>(_A_func), bound_(_A_bound)
+    {}
+
+  /// The argument bound to the functor.
+  T_bound bound_;
+};
+
+template <class T_functor, class T_bound>
+typename bind_functor<1, T_functor, T_bound>::result_type
+bind_functor<1, T_functor, T_bound>::operator()()
+  { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_bound>::pass> (bound_); }
+
+/** Adaptor that binds an argument to the wrapped functor.
+ * This template specialization fixes the 3th argument of the wrapped functor.
+ *
+ * @ingroup bind
+ */
+template <class T_functor, class T_bound>
+struct bind_functor<2, T_functor, T_bound> : public adapts<T_functor>
+{
+  typedef typename adapts<T_functor>::adaptor_type adaptor_type;
+
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass, typename type_trait<T_bound>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass>::type type; };
+  typedef typename adaptor_type::result_type  result_type;
+
+  /** Invokes the wrapped functor passing on the bound argument only.
+   * @return The return value of the functor invocation.
+   */
+  result_type
+  operator()();
+
+  /** Invokes the wrapped functor passing on the arguments.
+   * bound_ is passed as the 3th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass, typename type_trait<T_bound>::pass>
+        (_A_arg1,_A_arg2, bound_);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass, typename type_trait<T_bound>::pass>
+        (_A_arg1,_A_arg2, bound_);
+    }
+  #endif
+    
+  /** Invokes the wrapped functor passing on the arguments.
+   * bound_ is passed as the 3th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass, typename type_trait<T_bound>::pass, typename type_trait<T_arg3>::pass>
+        (_A_arg1,_A_arg2, bound_, _A_arg3);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass, typename type_trait<T_bound>::pass, typename type_trait<T_arg3>::pass>
+        (_A_arg1,_A_arg2, bound_, _A_arg3);
+    }
+  #endif
+    
+  /** Invokes the wrapped functor passing on the arguments.
+   * bound_ is passed as the 3th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass, typename type_trait<T_bound>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass>
+        (_A_arg1,_A_arg2, bound_, _A_arg3, _A_arg4);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass, typename type_trait<T_bound>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass>
+        (_A_arg1,_A_arg2, bound_, _A_arg3, _A_arg4);
+    }
+  #endif
+    
+  /** Invokes the wrapped functor passing on the arguments.
+   * bound_ is passed as the 3th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @param _A_arg5 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass, typename type_trait<T_bound>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass>
+        (_A_arg1,_A_arg2, bound_, _A_arg3, _A_arg4, _A_arg5);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass, typename type_trait<T_bound>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass>
+        (_A_arg1,_A_arg2, bound_, _A_arg3, _A_arg4, _A_arg5);
+    }
+  #endif
+    
+  /** Invokes the wrapped functor passing on the arguments.
+   * bound_ is passed as the 3th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @param _A_arg5 Argument to be passed on to the functor.
+   * @param _A_arg6 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5,T_arg6 _A_arg6)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass, typename type_trait<T_bound>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass>
+        (_A_arg1,_A_arg2, bound_, _A_arg3, _A_arg4, _A_arg5, _A_arg6);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5,T_arg6 _A_arg6)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass, typename type_trait<T_bound>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass>
+        (_A_arg1,_A_arg2, bound_, _A_arg3, _A_arg4, _A_arg5, _A_arg6);
+    }
+  #endif
+    
+  /** Constructs a bind_functor object that binds an argument to the passed functor.
+   * @param _A_functor Functor to invoke from operator()().
+   * @param _A_bound Argument to bind to the functor.
+   */
+  bind_functor(typename type_trait<T_functor>::take _A_func, typename type_trait<T_bound>::take _A_bound)
+    : adapts<T_functor>(_A_func), bound_(_A_bound)
+    {}
+
+  /// The argument bound to the functor.
+  T_bound bound_;
+};
+
+template <class T_functor, class T_bound>
+typename bind_functor<2, T_functor, T_bound>::result_type
+bind_functor<2, T_functor, T_bound>::operator()()
+  { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_bound>::pass> (bound_); }
+
+/** Adaptor that binds an argument to the wrapped functor.
+ * This template specialization fixes the 4th argument of the wrapped functor.
+ *
+ * @ingroup bind
+ */
+template <class T_functor, class T_bound>
+struct bind_functor<3, T_functor, T_bound> : public adapts<T_functor>
+{
+  typedef typename adapts<T_functor>::adaptor_type adaptor_type;
+
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass, typename type_trait<T_bound>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass>::type type; };
+  typedef typename adaptor_type::result_type  result_type;
+
+  /** Invokes the wrapped functor passing on the bound argument only.
+   * @return The return value of the functor invocation.
+   */
+  result_type
+  operator()();
+
+  /** Invokes the wrapped functor passing on the arguments.
+   * bound_ is passed as the 4th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass, typename type_trait<T_bound>::pass>
+        (_A_arg1,_A_arg2,_A_arg3, bound_);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass, typename type_trait<T_bound>::pass>
+        (_A_arg1,_A_arg2,_A_arg3, bound_);
+    }
+  #endif
+    
+  /** Invokes the wrapped functor passing on the arguments.
+   * bound_ is passed as the 4th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass, typename type_trait<T_bound>::pass, typename type_trait<T_arg4>::pass>
+        (_A_arg1,_A_arg2,_A_arg3, bound_, _A_arg4);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass, typename type_trait<T_bound>::pass, typename type_trait<T_arg4>::pass>
+        (_A_arg1,_A_arg2,_A_arg3, bound_, _A_arg4);
+    }
+  #endif
+    
+  /** Invokes the wrapped functor passing on the arguments.
+   * bound_ is passed as the 4th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @param _A_arg5 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass, typename type_trait<T_bound>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass>
+        (_A_arg1,_A_arg2,_A_arg3, bound_, _A_arg4, _A_arg5);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass, typename type_trait<T_bound>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass>
+        (_A_arg1,_A_arg2,_A_arg3, bound_, _A_arg4, _A_arg5);
+    }
+  #endif
+    
+  /** Invokes the wrapped functor passing on the arguments.
+   * bound_ is passed as the 4th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @param _A_arg5 Argument to be passed on to the functor.
+   * @param _A_arg6 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5,T_arg6 _A_arg6)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass, typename type_trait<T_bound>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass>
+        (_A_arg1,_A_arg2,_A_arg3, bound_, _A_arg4, _A_arg5, _A_arg6);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5,T_arg6 _A_arg6)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass, typename type_trait<T_bound>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass>
+        (_A_arg1,_A_arg2,_A_arg3, bound_, _A_arg4, _A_arg5, _A_arg6);
+    }
+  #endif
+    
+  /** Constructs a bind_functor object that binds an argument to the passed functor.
+   * @param _A_functor Functor to invoke from operator()().
+   * @param _A_bound Argument to bind to the functor.
+   */
+  bind_functor(typename type_trait<T_functor>::take _A_func, typename type_trait<T_bound>::take _A_bound)
+    : adapts<T_functor>(_A_func), bound_(_A_bound)
+    {}
+
+  /// The argument bound to the functor.
+  T_bound bound_;
+};
+
+template <class T_functor, class T_bound>
+typename bind_functor<3, T_functor, T_bound>::result_type
+bind_functor<3, T_functor, T_bound>::operator()()
+  { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_bound>::pass> (bound_); }
+
+/** Adaptor that binds an argument to the wrapped functor.
+ * This template specialization fixes the 5th argument of the wrapped functor.
+ *
+ * @ingroup bind
+ */
+template <class T_functor, class T_bound>
+struct bind_functor<4, T_functor, T_bound> : public adapts<T_functor>
+{
+  typedef typename adapts<T_functor>::adaptor_type adaptor_type;
+
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass, typename type_trait<T_bound>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass>::type type; };
+  typedef typename adaptor_type::result_type  result_type;
+
+  /** Invokes the wrapped functor passing on the bound argument only.
+   * @return The return value of the functor invocation.
+   */
+  result_type
+  operator()();
+
+  /** Invokes the wrapped functor passing on the arguments.
+   * bound_ is passed as the 5th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass, typename type_trait<T_bound>::pass>
+        (_A_arg1,_A_arg2,_A_arg3,_A_arg4, bound_);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass, typename type_trait<T_bound>::pass>
+        (_A_arg1,_A_arg2,_A_arg3,_A_arg4, bound_);
+    }
+  #endif
+    
+  /** Invokes the wrapped functor passing on the arguments.
+   * bound_ is passed as the 5th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @param _A_arg5 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass, typename type_trait<T_bound>::pass, typename type_trait<T_arg5>::pass>
+        (_A_arg1,_A_arg2,_A_arg3,_A_arg4, bound_, _A_arg5);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass, typename type_trait<T_bound>::pass, typename type_trait<T_arg5>::pass>
+        (_A_arg1,_A_arg2,_A_arg3,_A_arg4, bound_, _A_arg5);
+    }
+  #endif
+    
+  /** Invokes the wrapped functor passing on the arguments.
+   * bound_ is passed as the 5th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @param _A_arg5 Argument to be passed on to the functor.
+   * @param _A_arg6 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5,T_arg6 _A_arg6)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass, typename type_trait<T_bound>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass>
+        (_A_arg1,_A_arg2,_A_arg3,_A_arg4, bound_, _A_arg5, _A_arg6);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5,T_arg6 _A_arg6)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass, typename type_trait<T_bound>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass>
+        (_A_arg1,_A_arg2,_A_arg3,_A_arg4, bound_, _A_arg5, _A_arg6);
+    }
+  #endif
+    
+  /** Constructs a bind_functor object that binds an argument to the passed functor.
+   * @param _A_functor Functor to invoke from operator()().
+   * @param _A_bound Argument to bind to the functor.
+   */
+  bind_functor(typename type_trait<T_functor>::take _A_func, typename type_trait<T_bound>::take _A_bound)
+    : adapts<T_functor>(_A_func), bound_(_A_bound)
+    {}
+
+  /// The argument bound to the functor.
+  T_bound bound_;
+};
+
+template <class T_functor, class T_bound>
+typename bind_functor<4, T_functor, T_bound>::result_type
+bind_functor<4, T_functor, T_bound>::operator()()
+  { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_bound>::pass> (bound_); }
+
+/** Adaptor that binds an argument to the wrapped functor.
+ * This template specialization fixes the 6th argument of the wrapped functor.
+ *
+ * @ingroup bind
+ */
+template <class T_functor, class T_bound>
+struct bind_functor<5, T_functor, T_bound> : public adapts<T_functor>
+{
+  typedef typename adapts<T_functor>::adaptor_type adaptor_type;
+
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass, typename type_trait<T_bound>::pass, typename type_trait<T_arg6>::pass>::type type; };
+  typedef typename adaptor_type::result_type  result_type;
+
+  /** Invokes the wrapped functor passing on the bound argument only.
+   * @return The return value of the functor invocation.
+   */
+  result_type
+  operator()();
+
+  /** Invokes the wrapped functor passing on the arguments.
+   * bound_ is passed as the 6th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @param _A_arg5 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass, typename type_trait<T_bound>::pass>
+        (_A_arg1,_A_arg2,_A_arg3,_A_arg4,_A_arg5, bound_);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass, typename type_trait<T_bound>::pass>
+        (_A_arg1,_A_arg2,_A_arg3,_A_arg4,_A_arg5, bound_);
+    }
+  #endif
+    
+  /** Invokes the wrapped functor passing on the arguments.
+   * bound_ is passed as the 6th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @param _A_arg5 Argument to be passed on to the functor.
+   * @param _A_arg6 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5,T_arg6 _A_arg6)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass, typename type_trait<T_bound>::pass, typename type_trait<T_arg6>::pass>
+        (_A_arg1,_A_arg2,_A_arg3,_A_arg4,_A_arg5, bound_, _A_arg6);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5,T_arg6 _A_arg6)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass, typename type_trait<T_bound>::pass, typename type_trait<T_arg6>::pass>
+        (_A_arg1,_A_arg2,_A_arg3,_A_arg4,_A_arg5, bound_, _A_arg6);
+    }
+  #endif
+    
+  /** Constructs a bind_functor object that binds an argument to the passed functor.
+   * @param _A_functor Functor to invoke from operator()().
+   * @param _A_bound Argument to bind to the functor.
+   */
+  bind_functor(typename type_trait<T_functor>::take _A_func, typename type_trait<T_bound>::take _A_bound)
+    : adapts<T_functor>(_A_func), bound_(_A_bound)
+    {}
+
+  /// The argument bound to the functor.
+  T_bound bound_;
+};
+
+template <class T_functor, class T_bound>
+typename bind_functor<5, T_functor, T_bound>::result_type
+bind_functor<5, T_functor, T_bound>::operator()()
+  { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_bound>::pass> (bound_); }
+
+/** Adaptor that binds an argument to the wrapped functor.
+ * This template specialization fixes the 7th argument of the wrapped functor.
+ *
+ * @ingroup bind
+ */
+template <class T_functor, class T_bound>
+struct bind_functor<6, T_functor, T_bound> : public adapts<T_functor>
+{
+  typedef typename adapts<T_functor>::adaptor_type adaptor_type;
+
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass, typename type_trait<T_bound>::pass>::type type; };
+  typedef typename adaptor_type::result_type  result_type;
+
+  /** Invokes the wrapped functor passing on the bound argument only.
+   * @return The return value of the functor invocation.
+   */
+  result_type
+  operator()();
+
+  /** Invokes the wrapped functor passing on the arguments.
+   * bound_ is passed as the 7th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @param _A_arg5 Argument to be passed on to the functor.
+   * @param _A_arg6 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5,T_arg6 _A_arg6)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass, typename type_trait<T_bound>::pass>
+        (_A_arg1,_A_arg2,_A_arg3,_A_arg4,_A_arg5,_A_arg6, bound_);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5,T_arg6 _A_arg6)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass, typename type_trait<T_bound>::pass>
+        (_A_arg1,_A_arg2,_A_arg3,_A_arg4,_A_arg5,_A_arg6, bound_);
+    }
+  #endif
+    
+  /** Constructs a bind_functor object that binds an argument to the passed functor.
+   * @param _A_functor Functor to invoke from operator()().
+   * @param _A_bound Argument to bind to the functor.
+   */
+  bind_functor(typename type_trait<T_functor>::take _A_func, typename type_trait<T_bound>::take _A_bound)
+    : adapts<T_functor>(_A_func), bound_(_A_bound)
+    {}
+
+  /// The argument bound to the functor.
+  T_bound bound_;
+};
+
+template <class T_functor, class T_bound>
+typename bind_functor<6, T_functor, T_bound>::result_type
+bind_functor<6, T_functor, T_bound>::operator()()
+  { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_bound>::pass> (bound_); }
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bind_functor performs a functor on the
+ * functor and on the object instances stored in the sigc::bind_functor object.
+ *
+ * @ingroup bind
+ */
+template <class T_action, int T_loc, class T_functor, class T_bound>
+void visit_each(const T_action& _A_action,
+                const bind_functor<T_loc, T_functor, T_bound>& _A_target)
+{
+  visit_each(_A_action, _A_target.functor_);
+  visit_each(_A_action, _A_target.bound_);
+}
+
+/** Adaptor that binds 1 argument(s) to the wrapped functor.
+ * This template specialization fixes the last 1 argument(s) of the wrapped functor.
+ *
+ * @ingroup bind
+ */
+template <class T_functor, class T_type1>
+struct bind_functor<-1, T_functor, T_type1> : public adapts<T_functor>
+{
+  typedef typename adapts<T_functor>::adaptor_type adaptor_type;
+
+#ifndef DOXYGEN_SHOULD_SKIP_THIS
+  template <int count, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  struct deduce_result_type_internal
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass, typename type_trait<T_type1>::pass>::type type; };
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  struct deduce_result_type_internal<2, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass, typename type_trait<T_type1>::pass>::type type; };
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  struct deduce_result_type_internal<3, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass, typename type_trait<T_type1>::pass>::type type; };
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  struct deduce_result_type_internal<4, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass, typename type_trait<T_type1>::pass>::type type; };
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  struct deduce_result_type_internal<5, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass, typename type_trait<T_type1>::pass>::type type; };
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  struct deduce_result_type_internal<6, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_arg1>::pass, typename type_trait<T_type1>::pass>::type type; };
+#endif /*DOXYGEN_SHOULD_SKIP_THIS*/
+
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type {
+    typedef typename deduce_result_type_internal<internal::count_void<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::value,
+                                                 T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type type;
+  };
+  typedef typename adaptor_type::result_type  result_type;
+
+  /** Invokes the wrapped functor passing on the bound argument only.
+   * @return The return value of the functor invocation.
+   */
+  result_type
+  operator()();
+
+  /** Invokes the wrapped functor passing on the arguments.
+   * The last 1 argument(s) are fixed.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  operator()(T_arg1 _A_arg1)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_type1>::pass>
+        (_A_arg1, bound1_);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  sun_forte_workaround(T_arg1 _A_arg1)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_type1>::pass>
+        (_A_arg1, bound1_);
+    }
+  #endif
+    
+  /** Invokes the wrapped functor passing on the arguments.
+   * The last 1 argument(s) are fixed.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass, typename type_trait<T_type1>::pass>
+        (_A_arg1,_A_arg2, bound1_);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass, typename type_trait<T_type1>::pass>
+        (_A_arg1,_A_arg2, bound1_);
+    }
+  #endif
+    
+  /** Invokes the wrapped functor passing on the arguments.
+   * The last 1 argument(s) are fixed.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass, typename type_trait<T_type1>::pass>
+        (_A_arg1,_A_arg2,_A_arg3, bound1_);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass, typename type_trait<T_type1>::pass>
+        (_A_arg1,_A_arg2,_A_arg3, bound1_);
+    }
+  #endif
+    
+  /** Invokes the wrapped functor passing on the arguments.
+   * The last 1 argument(s) are fixed.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass, typename type_trait<T_type1>::pass>
+        (_A_arg1,_A_arg2,_A_arg3,_A_arg4, bound1_);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass, typename type_trait<T_type1>::pass>
+        (_A_arg1,_A_arg2,_A_arg3,_A_arg4, bound1_);
+    }
+  #endif
+    
+  /** Invokes the wrapped functor passing on the arguments.
+   * The last 1 argument(s) are fixed.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @param _A_arg5 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass, typename type_trait<T_type1>::pass>
+        (_A_arg1,_A_arg2,_A_arg3,_A_arg4,_A_arg5, bound1_);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass, typename type_trait<T_type1>::pass>
+        (_A_arg1,_A_arg2,_A_arg3,_A_arg4,_A_arg5, bound1_);
+    }
+  #endif
+    
+  /** Invokes the wrapped functor passing on the arguments.
+   * The last 1 argument(s) are fixed.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @param _A_arg5 Argument to be passed on to the functor.
+   * @param _A_arg6 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5,T_arg6 _A_arg6)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass, typename type_trait<T_type1>::pass>
+        (_A_arg1,_A_arg2,_A_arg3,_A_arg4,_A_arg5,_A_arg6, bound1_);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5,T_arg6 _A_arg6)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass, typename type_trait<T_type1>::pass>
+        (_A_arg1,_A_arg2,_A_arg3,_A_arg4,_A_arg5,_A_arg6, bound1_);
+    }
+  #endif
+    
+  /** Constructs a bind_functor object that binds an argument to the passed functor.
+   * @param _A_functor Functor to invoke from operator()().
+   * @param _A_bound Argument to bind to the functor.
+   */
+  bind_functor(typename type_trait<T_functor>::take _A_func, typename type_trait<T_type1>::take _A_bound1)
+    : adapts<T_functor>(_A_func), bound1_(_A_bound1)
+    {}
+
+  /// The argument bound to the functor.
+  T_type1 bound1_;
+};
+
+template <class T_functor, class T_type1>
+typename bind_functor<-1, T_functor, T_type1>::result_type
+bind_functor<-1, T_functor, T_type1>::operator()()
+  { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_type1>::pass> (bound1_); }
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bind_functor performs a functor on the
+ * functor and on the object instances stored in the sigc::bind_functor object.
+ *
+ * @ingroup bind
+ */
+template <class T_action, class T_functor, class T_type1>
+void visit_each(const T_action& _A_action,
+                const bind_functor<-1, T_functor, T_type1>& _A_target)
+{
+  visit_each(_A_action, _A_target.functor_);
+  visit_each(_A_action, _A_target.bound1_);
+}
+
+/** Adaptor that binds 2 argument(s) to the wrapped functor.
+ * This template specialization fixes the last 2 argument(s) of the wrapped functor.
+ *
+ * @ingroup bind
+ */
+template <class T_functor, class T_type1,class T_type2>
+struct bind_functor<-1, T_functor, T_type1,T_type2> : public adapts<T_functor>
+{
+  typedef typename adapts<T_functor>::adaptor_type adaptor_type;
+
+#ifndef DOXYGEN_SHOULD_SKIP_THIS
+  template <int count, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  struct deduce_result_type_internal
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass>::type type; };
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  struct deduce_result_type_internal<3, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass>::type type; };
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  struct deduce_result_type_internal<4, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass>::type type; };
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  struct deduce_result_type_internal<5, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass>::type type; };
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  struct deduce_result_type_internal<6, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_arg1>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass>::type type; };
+#endif /*DOXYGEN_SHOULD_SKIP_THIS*/
+
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type {
+    typedef typename deduce_result_type_internal<internal::count_void<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::value,
+                                                 T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type type;
+  };
+  typedef typename adaptor_type::result_type  result_type;
+
+  /** Invokes the wrapped functor passing on the bound argument only.
+   * @return The return value of the functor invocation.
+   */
+  result_type
+  operator()();
+
+  /** Invokes the wrapped functor passing on the arguments.
+   * The last 2 argument(s) are fixed.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  operator()(T_arg1 _A_arg1)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass>
+        (_A_arg1, bound1_,bound2_);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  sun_forte_workaround(T_arg1 _A_arg1)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass>
+        (_A_arg1, bound1_,bound2_);
+    }
+  #endif
+    
+  /** Invokes the wrapped functor passing on the arguments.
+   * The last 2 argument(s) are fixed.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass>
+        (_A_arg1,_A_arg2, bound1_,bound2_);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass>
+        (_A_arg1,_A_arg2, bound1_,bound2_);
+    }
+  #endif
+    
+  /** Invokes the wrapped functor passing on the arguments.
+   * The last 2 argument(s) are fixed.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass>
+        (_A_arg1,_A_arg2,_A_arg3, bound1_,bound2_);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass>
+        (_A_arg1,_A_arg2,_A_arg3, bound1_,bound2_);
+    }
+  #endif
+    
+  /** Invokes the wrapped functor passing on the arguments.
+   * The last 2 argument(s) are fixed.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass>
+        (_A_arg1,_A_arg2,_A_arg3,_A_arg4, bound1_,bound2_);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass>
+        (_A_arg1,_A_arg2,_A_arg3,_A_arg4, bound1_,bound2_);
+    }
+  #endif
+    
+  /** Invokes the wrapped functor passing on the arguments.
+   * The last 2 argument(s) are fixed.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @param _A_arg5 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass>
+        (_A_arg1,_A_arg2,_A_arg3,_A_arg4,_A_arg5, bound1_,bound2_);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4,T_arg5 _A_arg5)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass>
+        (_A_arg1,_A_arg2,_A_arg3,_A_arg4,_A_arg5, bound1_,bound2_);
+    }
+  #endif
+    
+  /** Constructs a bind_functor object that binds an argument to the passed functor.
+   * @param _A_functor Functor to invoke from operator()().
+   * @param _A_bound Argument to bind to the functor.
+   */
+  bind_functor(typename type_trait<T_functor>::take _A_func, typename type_trait<T_type1>::take _A_bound1,typename type_trait<T_type2>::take _A_bound2)
+    : adapts<T_functor>(_A_func), bound1_(_A_bound1),bound2_(_A_bound2)
+    {}
+
+  /// The argument bound to the functor.
+  T_type1 bound1_;
+  T_type2 bound2_;
+};
+
+template <class T_functor, class T_type1,class T_type2>
+typename bind_functor<-1, T_functor, T_type1,T_type2>::result_type
+bind_functor<-1, T_functor, T_type1,T_type2>::operator()()
+  { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass> (bound1_,bound2_); }
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bind_functor performs a functor on the
+ * functor and on the object instances stored in the sigc::bind_functor object.
+ *
+ * @ingroup bind
+ */
+template <class T_action, class T_functor, class T_type1,class T_type2>
+void visit_each(const T_action& _A_action,
+                const bind_functor<-1, T_functor, T_type1,T_type2>& _A_target)
+{
+  visit_each(_A_action, _A_target.functor_);
+  visit_each(_A_action, _A_target.bound1_);
+  visit_each(_A_action, _A_target.bound2_);
+}
+
+/** Adaptor that binds 3 argument(s) to the wrapped functor.
+ * This template specialization fixes the last 3 argument(s) of the wrapped functor.
+ *
+ * @ingroup bind
+ */
+template <class T_functor, class T_type1,class T_type2,class T_type3>
+struct bind_functor<-1, T_functor, T_type1,T_type2,T_type3> : public adapts<T_functor>
+{
+  typedef typename adapts<T_functor>::adaptor_type adaptor_type;
+
+#ifndef DOXYGEN_SHOULD_SKIP_THIS
+  template <int count, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  struct deduce_result_type_internal
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass,typename type_trait<T_type3>::pass>::type type; };
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  struct deduce_result_type_internal<4, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass,typename type_trait<T_type3>::pass>::type type; };
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  struct deduce_result_type_internal<5, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass,typename type_trait<T_type3>::pass>::type type; };
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  struct deduce_result_type_internal<6, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_arg1>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass,typename type_trait<T_type3>::pass>::type type; };
+#endif /*DOXYGEN_SHOULD_SKIP_THIS*/
+
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type {
+    typedef typename deduce_result_type_internal<internal::count_void<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::value,
+                                                 T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type type;
+  };
+  typedef typename adaptor_type::result_type  result_type;
+
+  /** Invokes the wrapped functor passing on the bound argument only.
+   * @return The return value of the functor invocation.
+   */
+  result_type
+  operator()();
+
+  /** Invokes the wrapped functor passing on the arguments.
+   * The last 3 argument(s) are fixed.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  operator()(T_arg1 _A_arg1)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass,typename type_trait<T_type3>::pass>
+        (_A_arg1, bound1_,bound2_,bound3_);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  sun_forte_workaround(T_arg1 _A_arg1)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass,typename type_trait<T_type3>::pass>
+        (_A_arg1, bound1_,bound2_,bound3_);
+    }
+  #endif
+    
+  /** Invokes the wrapped functor passing on the arguments.
+   * The last 3 argument(s) are fixed.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass,typename type_trait<T_type3>::pass>
+        (_A_arg1,_A_arg2, bound1_,bound2_,bound3_);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass,typename type_trait<T_type3>::pass>
+        (_A_arg1,_A_arg2, bound1_,bound2_,bound3_);
+    }
+  #endif
+    
+  /** Invokes the wrapped functor passing on the arguments.
+   * The last 3 argument(s) are fixed.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass,typename type_trait<T_type3>::pass>
+        (_A_arg1,_A_arg2,_A_arg3, bound1_,bound2_,bound3_);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass,typename type_trait<T_type3>::pass>
+        (_A_arg1,_A_arg2,_A_arg3, bound1_,bound2_,bound3_);
+    }
+  #endif
+    
+  /** Invokes the wrapped functor passing on the arguments.
+   * The last 3 argument(s) are fixed.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass,typename type_trait<T_type3>::pass>
+        (_A_arg1,_A_arg2,_A_arg3,_A_arg4, bound1_,bound2_,bound3_);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3,T_arg4 _A_arg4)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass,typename type_trait<T_type3>::pass>
+        (_A_arg1,_A_arg2,_A_arg3,_A_arg4, bound1_,bound2_,bound3_);
+    }
+  #endif
+    
+  /** Constructs a bind_functor object that binds an argument to the passed functor.
+   * @param _A_functor Functor to invoke from operator()().
+   * @param _A_bound Argument to bind to the functor.
+   */
+  bind_functor(typename type_trait<T_functor>::take _A_func, typename type_trait<T_type1>::take _A_bound1,typename type_trait<T_type2>::take _A_bound2,typename type_trait<T_type3>::take _A_bound3)
+    : adapts<T_functor>(_A_func), bound1_(_A_bound1),bound2_(_A_bound2),bound3_(_A_bound3)
+    {}
+
+  /// The argument bound to the functor.
+  T_type1 bound1_;
+  T_type2 bound2_;
+  T_type3 bound3_;
+};
+
+template <class T_functor, class T_type1,class T_type2,class T_type3>
+typename bind_functor<-1, T_functor, T_type1,T_type2,T_type3>::result_type
+bind_functor<-1, T_functor, T_type1,T_type2,T_type3>::operator()()
+  { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass,typename type_trait<T_type3>::pass> (bound1_,bound2_,bound3_); }
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bind_functor performs a functor on the
+ * functor and on the object instances stored in the sigc::bind_functor object.
+ *
+ * @ingroup bind
+ */
+template <class T_action, class T_functor, class T_type1,class T_type2,class T_type3>
+void visit_each(const T_action& _A_action,
+                const bind_functor<-1, T_functor, T_type1,T_type2,T_type3>& _A_target)
+{
+  visit_each(_A_action, _A_target.functor_);
+  visit_each(_A_action, _A_target.bound1_);
+  visit_each(_A_action, _A_target.bound2_);
+  visit_each(_A_action, _A_target.bound3_);
+}
+
+/** Adaptor that binds 4 argument(s) to the wrapped functor.
+ * This template specialization fixes the last 4 argument(s) of the wrapped functor.
+ *
+ * @ingroup bind
+ */
+template <class T_functor, class T_type1,class T_type2,class T_type3,class T_type4>
+struct bind_functor<-1, T_functor, T_type1,T_type2,T_type3,T_type4> : public adapts<T_functor>
+{
+  typedef typename adapts<T_functor>::adaptor_type adaptor_type;
+
+#ifndef DOXYGEN_SHOULD_SKIP_THIS
+  template <int count, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  struct deduce_result_type_internal
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass,typename type_trait<T_type3>::pass,typename type_trait<T_type4>::pass>::type type; };
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  struct deduce_result_type_internal<5, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass,typename type_trait<T_type3>::pass,typename type_trait<T_type4>::pass>::type type; };
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  struct deduce_result_type_internal<6, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_arg1>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass,typename type_trait<T_type3>::pass,typename type_trait<T_type4>::pass>::type type; };
+#endif /*DOXYGEN_SHOULD_SKIP_THIS*/
+
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type {
+    typedef typename deduce_result_type_internal<internal::count_void<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::value,
+                                                 T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type type;
+  };
+  typedef typename adaptor_type::result_type  result_type;
+
+  /** Invokes the wrapped functor passing on the bound argument only.
+   * @return The return value of the functor invocation.
+   */
+  result_type
+  operator()();
+
+  /** Invokes the wrapped functor passing on the arguments.
+   * The last 4 argument(s) are fixed.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  operator()(T_arg1 _A_arg1)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass,typename type_trait<T_type3>::pass,typename type_trait<T_type4>::pass>
+        (_A_arg1, bound1_,bound2_,bound3_,bound4_);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  sun_forte_workaround(T_arg1 _A_arg1)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass,typename type_trait<T_type3>::pass,typename type_trait<T_type4>::pass>
+        (_A_arg1, bound1_,bound2_,bound3_,bound4_);
+    }
+  #endif
+    
+  /** Invokes the wrapped functor passing on the arguments.
+   * The last 4 argument(s) are fixed.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass,typename type_trait<T_type3>::pass,typename type_trait<T_type4>::pass>
+        (_A_arg1,_A_arg2, bound1_,bound2_,bound3_,bound4_);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass,typename type_trait<T_type3>::pass,typename type_trait<T_type4>::pass>
+        (_A_arg1,_A_arg2, bound1_,bound2_,bound3_,bound4_);
+    }
+  #endif
+    
+  /** Invokes the wrapped functor passing on the arguments.
+   * The last 4 argument(s) are fixed.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass,typename type_trait<T_type3>::pass,typename type_trait<T_type4>::pass>
+        (_A_arg1,_A_arg2,_A_arg3, bound1_,bound2_,bound3_,bound4_);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2,T_arg3 _A_arg3)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass,typename type_trait<T_type3>::pass,typename type_trait<T_type4>::pass>
+        (_A_arg1,_A_arg2,_A_arg3, bound1_,bound2_,bound3_,bound4_);
+    }
+  #endif
+    
+  /** Constructs a bind_functor object that binds an argument to the passed functor.
+   * @param _A_functor Functor to invoke from operator()().
+   * @param _A_bound Argument to bind to the functor.
+   */
+  bind_functor(typename type_trait<T_functor>::take _A_func, typename type_trait<T_type1>::take _A_bound1,typename type_trait<T_type2>::take _A_bound2,typename type_trait<T_type3>::take _A_bound3,typename type_trait<T_type4>::take _A_bound4)
+    : adapts<T_functor>(_A_func), bound1_(_A_bound1),bound2_(_A_bound2),bound3_(_A_bound3),bound4_(_A_bound4)
+    {}
+
+  /// The argument bound to the functor.
+  T_type1 bound1_;
+  T_type2 bound2_;
+  T_type3 bound3_;
+  T_type4 bound4_;
+};
+
+template <class T_functor, class T_type1,class T_type2,class T_type3,class T_type4>
+typename bind_functor<-1, T_functor, T_type1,T_type2,T_type3,T_type4>::result_type
+bind_functor<-1, T_functor, T_type1,T_type2,T_type3,T_type4>::operator()()
+  { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass,typename type_trait<T_type3>::pass,typename type_trait<T_type4>::pass> (bound1_,bound2_,bound3_,bound4_); }
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bind_functor performs a functor on the
+ * functor and on the object instances stored in the sigc::bind_functor object.
+ *
+ * @ingroup bind
+ */
+template <class T_action, class T_functor, class T_type1,class T_type2,class T_type3,class T_type4>
+void visit_each(const T_action& _A_action,
+                const bind_functor<-1, T_functor, T_type1,T_type2,T_type3,T_type4>& _A_target)
+{
+  visit_each(_A_action, _A_target.functor_);
+  visit_each(_A_action, _A_target.bound1_);
+  visit_each(_A_action, _A_target.bound2_);
+  visit_each(_A_action, _A_target.bound3_);
+  visit_each(_A_action, _A_target.bound4_);
+}
+
+/** Adaptor that binds 5 argument(s) to the wrapped functor.
+ * This template specialization fixes the last 5 argument(s) of the wrapped functor.
+ *
+ * @ingroup bind
+ */
+template <class T_functor, class T_type1,class T_type2,class T_type3,class T_type4,class T_type5>
+struct bind_functor<-1, T_functor, T_type1,T_type2,T_type3,T_type4,T_type5> : public adapts<T_functor>
+{
+  typedef typename adapts<T_functor>::adaptor_type adaptor_type;
+
+#ifndef DOXYGEN_SHOULD_SKIP_THIS
+  template <int count, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  struct deduce_result_type_internal
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass,typename type_trait<T_type3>::pass,typename type_trait<T_type4>::pass,typename type_trait<T_type5>::pass>::type type; };
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  struct deduce_result_type_internal<6, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_arg1>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass,typename type_trait<T_type3>::pass,typename type_trait<T_type4>::pass,typename type_trait<T_type5>::pass>::type type; };
+#endif /*DOXYGEN_SHOULD_SKIP_THIS*/
+
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type {
+    typedef typename deduce_result_type_internal<internal::count_void<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::value,
+                                                 T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type type;
+  };
+  typedef typename adaptor_type::result_type  result_type;
+
+  /** Invokes the wrapped functor passing on the bound argument only.
+   * @return The return value of the functor invocation.
+   */
+  result_type
+  operator()();
+
+  /** Invokes the wrapped functor passing on the arguments.
+   * The last 5 argument(s) are fixed.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  operator()(T_arg1 _A_arg1)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass,typename type_trait<T_type3>::pass,typename type_trait<T_type4>::pass,typename type_trait<T_type5>::pass>
+        (_A_arg1, bound1_,bound2_,bound3_,bound4_,bound5_);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  sun_forte_workaround(T_arg1 _A_arg1)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass,typename type_trait<T_type3>::pass,typename type_trait<T_type4>::pass,typename type_trait<T_type5>::pass>
+        (_A_arg1, bound1_,bound2_,bound3_,bound4_,bound5_);
+    }
+  #endif
+    
+  /** Invokes the wrapped functor passing on the arguments.
+   * The last 5 argument(s) are fixed.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  operator()(T_arg1 _A_arg1,T_arg2 _A_arg2)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass,typename type_trait<T_type3>::pass,typename type_trait<T_type4>::pass,typename type_trait<T_type5>::pass>
+        (_A_arg1,_A_arg2, bound1_,bound2_,bound3_,bound4_,bound5_);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  sun_forte_workaround(T_arg1 _A_arg1,T_arg2 _A_arg2)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass,typename type_trait<T_type3>::pass,typename type_trait<T_type4>::pass,typename type_trait<T_type5>::pass>
+        (_A_arg1,_A_arg2, bound1_,bound2_,bound3_,bound4_,bound5_);
+    }
+  #endif
+    
+  /** Constructs a bind_functor object that binds an argument to the passed functor.
+   * @param _A_functor Functor to invoke from operator()().
+   * @param _A_bound Argument to bind to the functor.
+   */
+  bind_functor(typename type_trait<T_functor>::take _A_func, typename type_trait<T_type1>::take _A_bound1,typename type_trait<T_type2>::take _A_bound2,typename type_trait<T_type3>::take _A_bound3,typename type_trait<T_type4>::take _A_bound4,typename type_trait<T_type5>::take _A_bound5)
+    : adapts<T_functor>(_A_func), bound1_(_A_bound1),bound2_(_A_bound2),bound3_(_A_bound3),bound4_(_A_bound4),bound5_(_A_bound5)
+    {}
+
+  /// The argument bound to the functor.
+  T_type1 bound1_;
+  T_type2 bound2_;
+  T_type3 bound3_;
+  T_type4 bound4_;
+  T_type5 bound5_;
+};
+
+template <class T_functor, class T_type1,class T_type2,class T_type3,class T_type4,class T_type5>
+typename bind_functor<-1, T_functor, T_type1,T_type2,T_type3,T_type4,T_type5>::result_type
+bind_functor<-1, T_functor, T_type1,T_type2,T_type3,T_type4,T_type5>::operator()()
+  { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass,typename type_trait<T_type3>::pass,typename type_trait<T_type4>::pass,typename type_trait<T_type5>::pass> (bound1_,bound2_,bound3_,bound4_,bound5_); }
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bind_functor performs a functor on the
+ * functor and on the object instances stored in the sigc::bind_functor object.
+ *
+ * @ingroup bind
+ */
+template <class T_action, class T_functor, class T_type1,class T_type2,class T_type3,class T_type4,class T_type5>
+void visit_each(const T_action& _A_action,
+                const bind_functor<-1, T_functor, T_type1,T_type2,T_type3,T_type4,T_type5>& _A_target)
+{
+  visit_each(_A_action, _A_target.functor_);
+  visit_each(_A_action, _A_target.bound1_);
+  visit_each(_A_action, _A_target.bound2_);
+  visit_each(_A_action, _A_target.bound3_);
+  visit_each(_A_action, _A_target.bound4_);
+  visit_each(_A_action, _A_target.bound5_);
+}
+
+/** Adaptor that binds 6 argument(s) to the wrapped functor.
+ * This template specialization fixes the last 6 argument(s) of the wrapped functor.
+ *
+ * @ingroup bind
+ */
+template <class T_functor, class T_type1,class T_type2,class T_type3,class T_type4,class T_type5,class T_type6>
+struct bind_functor<-1, T_functor, T_type1,T_type2,T_type3,T_type4,T_type5,T_type6> : public adapts<T_functor>
+{
+  typedef typename adapts<T_functor>::adaptor_type adaptor_type;
+
+#ifndef DOXYGEN_SHOULD_SKIP_THIS
+  template <int count, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  struct deduce_result_type_internal
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_arg1>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass,typename type_trait<T_type3>::pass,typename type_trait<T_type4>::pass,typename type_trait<T_type5>::pass,typename type_trait<T_type6>::pass>::type type; };
+#endif /*DOXYGEN_SHOULD_SKIP_THIS*/
+
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type {
+    typedef typename deduce_result_type_internal<internal::count_void<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::value,
+                                                 T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type type;
+  };
+  typedef typename adaptor_type::result_type  result_type;
+
+  /** Invokes the wrapped functor passing on the bound argument only.
+   * @return The return value of the functor invocation.
+   */
+  result_type
+  operator()();
+
+  /** Invokes the wrapped functor passing on the arguments.
+   * The last 6 argument(s) are fixed.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  operator()(T_arg1 _A_arg1)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass,typename type_trait<T_type3>::pass,typename type_trait<T_type4>::pass,typename type_trait<T_type5>::pass,typename type_trait<T_type6>::pass>
+        (_A_arg1, bound1_,bound2_,bound3_,bound4_,bound5_,bound6_);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  sun_forte_workaround(T_arg1 _A_arg1)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass,typename type_trait<T_type3>::pass,typename type_trait<T_type4>::pass,typename type_trait<T_type5>::pass,typename type_trait<T_type6>::pass>
+        (_A_arg1, bound1_,bound2_,bound3_,bound4_,bound5_,bound6_);
+    }
+  #endif
+    
+  /** Constructs a bind_functor object that binds an argument to the passed functor.
+   * @param _A_functor Functor to invoke from operator()().
+   * @param _A_bound Argument to bind to the functor.
+   */
+  bind_functor(typename type_trait<T_functor>::take _A_func, typename type_trait<T_type1>::take _A_bound1,typename type_trait<T_type2>::take _A_bound2,typename type_trait<T_type3>::take _A_bound3,typename type_trait<T_type4>::take _A_bound4,typename type_trait<T_type5>::take _A_bound5,typename type_trait<T_type6>::take _A_bound6)
+    : adapts<T_functor>(_A_func), bound1_(_A_bound1),bound2_(_A_bound2),bound3_(_A_bound3),bound4_(_A_bound4),bound5_(_A_bound5),bound6_(_A_bound6)
+    {}
+
+  /// The argument bound to the functor.
+  T_type1 bound1_;
+  T_type2 bound2_;
+  T_type3 bound3_;
+  T_type4 bound4_;
+  T_type5 bound5_;
+  T_type6 bound6_;
+};
+
+template <class T_functor, class T_type1,class T_type2,class T_type3,class T_type4,class T_type5,class T_type6>
+typename bind_functor<-1, T_functor, T_type1,T_type2,T_type3,T_type4,T_type5,T_type6>::result_type
+bind_functor<-1, T_functor, T_type1,T_type2,T_type3,T_type4,T_type5,T_type6>::operator()()
+  { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass,typename type_trait<T_type3>::pass,typename type_trait<T_type4>::pass,typename type_trait<T_type5>::pass,typename type_trait<T_type6>::pass> (bound1_,bound2_,bound3_,bound4_,bound5_,bound6_); }
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bind_functor performs a functor on the
+ * functor and on the object instances stored in the sigc::bind_functor object.
+ *
+ * @ingroup bind
+ */
+template <class T_action, class T_functor, class T_type1,class T_type2,class T_type3,class T_type4,class T_type5,class T_type6>
+void visit_each(const T_action& _A_action,
+                const bind_functor<-1, T_functor, T_type1,T_type2,T_type3,T_type4,T_type5,T_type6>& _A_target)
+{
+  visit_each(_A_action, _A_target.functor_);
+  visit_each(_A_action, _A_target.bound1_);
+  visit_each(_A_action, _A_target.bound2_);
+  visit_each(_A_action, _A_target.bound3_);
+  visit_each(_A_action, _A_target.bound4_);
+  visit_each(_A_action, _A_target.bound5_);
+  visit_each(_A_action, _A_target.bound6_);
+}
+
+/** Adaptor that binds 7 argument(s) to the wrapped functor.
+ * This template specialization fixes the last 7 argument(s) of the wrapped functor.
+ *
+ * @ingroup bind
+ */
+template <class T_functor, class T_type1,class T_type2,class T_type3,class T_type4,class T_type5,class T_type6,class T_type7>
+struct bind_functor<-1, T_functor, T_type1,T_type2,T_type3,T_type4,T_type5,T_type6,T_type7> : public adapts<T_functor>
+{
+  typedef typename adapts<T_functor>::adaptor_type adaptor_type;
+
+#ifndef DOXYGEN_SHOULD_SKIP_THIS
+  template <int count, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  struct deduce_result_type_internal
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass,typename type_trait<T_type3>::pass,typename type_trait<T_type4>::pass,typename type_trait<T_type5>::pass,typename type_trait<T_type6>::pass,typename type_trait<T_type7>::pass>::type type; };
+#endif /*DOXYGEN_SHOULD_SKIP_THIS*/
+
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type {
+    typedef typename deduce_result_type_internal<internal::count_void<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::value,
+                                                 T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type type;
+  };
+  typedef typename adaptor_type::result_type  result_type;
+
+  /** Invokes the wrapped functor passing on the bound argument only.
+   * @return The return value of the functor invocation.
+   */
+  result_type
+  operator()();
+
+  /** Constructs a bind_functor object that binds an argument to the passed functor.
+   * @param _A_functor Functor to invoke from operator()().
+   * @param _A_bound Argument to bind to the functor.
+   */
+  bind_functor(typename type_trait<T_functor>::take _A_func, typename type_trait<T_type1>::take _A_bound1,typename type_trait<T_type2>::take _A_bound2,typename type_trait<T_type3>::take _A_bound3,typename type_trait<T_type4>::take _A_bound4,typename type_trait<T_type5>::take _A_bound5,typename type_trait<T_type6>::take _A_bound6,typename type_trait<T_type7>::take _A_bound7)
+    : adapts<T_functor>(_A_func), bound1_(_A_bound1),bound2_(_A_bound2),bound3_(_A_bound3),bound4_(_A_bound4),bound5_(_A_bound5),bound6_(_A_bound6),bound7_(_A_bound7)
+    {}
+
+  /// The argument bound to the functor.
+  T_type1 bound1_;
+  T_type2 bound2_;
+  T_type3 bound3_;
+  T_type4 bound4_;
+  T_type5 bound5_;
+  T_type6 bound6_;
+  T_type7 bound7_;
+};
+
+template <class T_functor, class T_type1,class T_type2,class T_type3,class T_type4,class T_type5,class T_type6,class T_type7>
+typename bind_functor<-1, T_functor, T_type1,T_type2,T_type3,T_type4,T_type5,T_type6,T_type7>::result_type
+bind_functor<-1, T_functor, T_type1,T_type2,T_type3,T_type4,T_type5,T_type6,T_type7>::operator()()
+  { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_type1>::pass,typename type_trait<T_type2>::pass,typename type_trait<T_type3>::pass,typename type_trait<T_type4>::pass,typename type_trait<T_type5>::pass,typename type_trait<T_type6>::pass,typename type_trait<T_type7>::pass> (bound1_,bound2_,bound3_,bound4_,bound5_,bound6_,bound7_); }
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bind_functor performs a functor on the
+ * functor and on the object instances stored in the sigc::bind_functor object.
+ *
+ * @ingroup bind
+ */
+template <class T_action, class T_functor, class T_type1,class T_type2,class T_type3,class T_type4,class T_type5,class T_type6,class T_type7>
+void visit_each(const T_action& _A_action,
+                const bind_functor<-1, T_functor, T_type1,T_type2,T_type3,T_type4,T_type5,T_type6,T_type7>& _A_target)
+{
+  visit_each(_A_action, _A_target.functor_);
+  visit_each(_A_action, _A_target.bound1_);
+  visit_each(_A_action, _A_target.bound2_);
+  visit_each(_A_action, _A_target.bound3_);
+  visit_each(_A_action, _A_target.bound4_);
+  visit_each(_A_action, _A_target.bound5_);
+  visit_each(_A_action, _A_target.bound6_);
+  visit_each(_A_action, _A_target.bound7_);
+}
+
+
+/** Creates an adaptor of type sigc::bind_functor which binds the passed argument to the passed functor.
+ * The optional template argument @e I_location specifies the zero-based
+ * position of the argument to be fixed (@p -1 stands for the last argument).
+ *
+ * @param _A_func Functor that should be wrapped.
+ * @param _A_b1 Argument to bind to @e _A_func.
+ * @return Adaptor that executes @e _A_func with the bound argument on invokation.
+ *
+ * @ingroup bind
+ */
+template <int I_location, class T_bound1, class T_functor>
+inline bind_functor<I_location, T_functor, typename unwrap_reference<T_bound1>::type>
+bind(const T_functor& _A_func, T_bound1 _A_b1)
+{ 
+  return bind_functor<I_location, T_functor, typename unwrap_reference<T_bound1>::type>
+           (_A_func, _A_b1);
+}
+
+/** Creates an adaptor of type sigc::bind_functor which fixes the last 1 argument(s) of the passed functor.
+ * This function overload fixes the last 1 argument(s) of @e _A_func.
+ *
+ * @param _A_func Functor that should be wrapped.
+ * @param _A_b1 Argument to bind to @e _A_func.
+ * @return Adaptor that executes _A_func with the bound argument on invokation.
+ *
+ * @ingroup bind
+ */
+template <class T_type1, class T_functor>
+inline bind_functor<-1, T_functor,
+                    typename unwrap_reference<T_type1>::type>
+bind(const T_functor& _A_func, T_type1 _A_b1)
+{ return bind_functor<-1, T_functor,
+                    typename unwrap_reference<T_type1>::type>
+                    (_A_func, _A_b1);
+}
+
+/** Creates an adaptor of type sigc::bind_functor which fixes the last 2 argument(s) of the passed functor.
+ * This function overload fixes the last 2 argument(s) of @e _A_func.
+ *
+ * @param _A_func Functor that should be wrapped.
+ * @param _A_b1 Argument to bind to @e _A_func.
+ * @param _A_b2 Argument to bind to @e _A_func.
+ * @return Adaptor that executes _A_func with the bound argument on invokation.
+ *
+ * @ingroup bind
+ */
+template <class T_type1,class T_type2, class T_functor>
+inline bind_functor<-1, T_functor,
+                    typename unwrap_reference<T_type1>::type,
+                    typename unwrap_reference<T_type2>::type>
+bind(const T_functor& _A_func, T_type1 _A_b1,T_type2 _A_b2)
+{ return bind_functor<-1, T_functor,
+                    typename unwrap_reference<T_type1>::type,
+                    typename unwrap_reference<T_type2>::type>
+                    (_A_func, _A_b1,_A_b2);
+}
+
+/** Creates an adaptor of type sigc::bind_functor which fixes the last 3 argument(s) of the passed functor.
+ * This function overload fixes the last 3 argument(s) of @e _A_func.
+ *
+ * @param _A_func Functor that should be wrapped.
+ * @param _A_b1 Argument to bind to @e _A_func.
+ * @param _A_b2 Argument to bind to @e _A_func.
+ * @param _A_b3 Argument to bind to @e _A_func.
+ * @return Adaptor that executes _A_func with the bound argument on invokation.
+ *
+ * @ingroup bind
+ */
+template <class T_type1,class T_type2,class T_type3, class T_functor>
+inline bind_functor<-1, T_functor,
+                    typename unwrap_reference<T_type1>::type,
+                    typename unwrap_reference<T_type2>::type,
+                    typename unwrap_reference<T_type3>::type>
+bind(const T_functor& _A_func, T_type1 _A_b1,T_type2 _A_b2,T_type3 _A_b3)
+{ return bind_functor<-1, T_functor,
+                    typename unwrap_reference<T_type1>::type,
+                    typename unwrap_reference<T_type2>::type,
+                    typename unwrap_reference<T_type3>::type>
+                    (_A_func, _A_b1,_A_b2,_A_b3);
+}
+
+/** Creates an adaptor of type sigc::bind_functor which fixes the last 4 argument(s) of the passed functor.
+ * This function overload fixes the last 4 argument(s) of @e _A_func.
+ *
+ * @param _A_func Functor that should be wrapped.
+ * @param _A_b1 Argument to bind to @e _A_func.
+ * @param _A_b2 Argument to bind to @e _A_func.
+ * @param _A_b3 Argument to bind to @e _A_func.
+ * @param _A_b4 Argument to bind to @e _A_func.
+ * @return Adaptor that executes _A_func with the bound argument on invokation.
+ *
+ * @ingroup bind
+ */
+template <class T_type1,class T_type2,class T_type3,class T_type4, class T_functor>
+inline bind_functor<-1, T_functor,
+                    typename unwrap_reference<T_type1>::type,
+                    typename unwrap_reference<T_type2>::type,
+                    typename unwrap_reference<T_type3>::type,
+                    typename unwrap_reference<T_type4>::type>
+bind(const T_functor& _A_func, T_type1 _A_b1,T_type2 _A_b2,T_type3 _A_b3,T_type4 _A_b4)
+{ return bind_functor<-1, T_functor,
+                    typename unwrap_reference<T_type1>::type,
+                    typename unwrap_reference<T_type2>::type,
+                    typename unwrap_reference<T_type3>::type,
+                    typename unwrap_reference<T_type4>::type>
+                    (_A_func, _A_b1,_A_b2,_A_b3,_A_b4);
+}
+
+/** Creates an adaptor of type sigc::bind_functor which fixes the last 5 argument(s) of the passed functor.
+ * This function overload fixes the last 5 argument(s) of @e _A_func.
+ *
+ * @param _A_func Functor that should be wrapped.
+ * @param _A_b1 Argument to bind to @e _A_func.
+ * @param _A_b2 Argument to bind to @e _A_func.
+ * @param _A_b3 Argument to bind to @e _A_func.
+ * @param _A_b4 Argument to bind to @e _A_func.
+ * @param _A_b5 Argument to bind to @e _A_func.
+ * @return Adaptor that executes _A_func with the bound argument on invokation.
+ *
+ * @ingroup bind
+ */
+template <class T_type1,class T_type2,class T_type3,class T_type4,class T_type5, class T_functor>
+inline bind_functor<-1, T_functor,
+                    typename unwrap_reference<T_type1>::type,
+                    typename unwrap_reference<T_type2>::type,
+                    typename unwrap_reference<T_type3>::type,
+                    typename unwrap_reference<T_type4>::type,
+                    typename unwrap_reference<T_type5>::type>
+bind(const T_functor& _A_func, T_type1 _A_b1,T_type2 _A_b2,T_type3 _A_b3,T_type4 _A_b4,T_type5 _A_b5)
+{ return bind_functor<-1, T_functor,
+                    typename unwrap_reference<T_type1>::type,
+                    typename unwrap_reference<T_type2>::type,
+                    typename unwrap_reference<T_type3>::type,
+                    typename unwrap_reference<T_type4>::type,
+                    typename unwrap_reference<T_type5>::type>
+                    (_A_func, _A_b1,_A_b2,_A_b3,_A_b4,_A_b5);
+}
+
+/** Creates an adaptor of type sigc::bind_functor which fixes the last 6 argument(s) of the passed functor.
+ * This function overload fixes the last 6 argument(s) of @e _A_func.
+ *
+ * @param _A_func Functor that should be wrapped.
+ * @param _A_b1 Argument to bind to @e _A_func.
+ * @param _A_b2 Argument to bind to @e _A_func.
+ * @param _A_b3 Argument to bind to @e _A_func.
+ * @param _A_b4 Argument to bind to @e _A_func.
+ * @param _A_b5 Argument to bind to @e _A_func.
+ * @param _A_b6 Argument to bind to @e _A_func.
+ * @return Adaptor that executes _A_func with the bound argument on invokation.
+ *
+ * @ingroup bind
+ */
+template <class T_type1,class T_type2,class T_type3,class T_type4,class T_type5,class T_type6, class T_functor>
+inline bind_functor<-1, T_functor,
+                    typename unwrap_reference<T_type1>::type,
+                    typename unwrap_reference<T_type2>::type,
+                    typename unwrap_reference<T_type3>::type,
+                    typename unwrap_reference<T_type4>::type,
+                    typename unwrap_reference<T_type5>::type,
+                    typename unwrap_reference<T_type6>::type>
+bind(const T_functor& _A_func, T_type1 _A_b1,T_type2 _A_b2,T_type3 _A_b3,T_type4 _A_b4,T_type5 _A_b5,T_type6 _A_b6)
+{ return bind_functor<-1, T_functor,
+                    typename unwrap_reference<T_type1>::type,
+                    typename unwrap_reference<T_type2>::type,
+                    typename unwrap_reference<T_type3>::type,
+                    typename unwrap_reference<T_type4>::type,
+                    typename unwrap_reference<T_type5>::type,
+                    typename unwrap_reference<T_type6>::type>
+                    (_A_func, _A_b1,_A_b2,_A_b3,_A_b4,_A_b5,_A_b6);
+}
+
+/** Creates an adaptor of type sigc::bind_functor which fixes the last 7 argument(s) of the passed functor.
+ * This function overload fixes the last 7 argument(s) of @e _A_func.
+ *
+ * @param _A_func Functor that should be wrapped.
+ * @param _A_b1 Argument to bind to @e _A_func.
+ * @param _A_b2 Argument to bind to @e _A_func.
+ * @param _A_b3 Argument to bind to @e _A_func.
+ * @param _A_b4 Argument to bind to @e _A_func.
+ * @param _A_b5 Argument to bind to @e _A_func.
+ * @param _A_b6 Argument to bind to @e _A_func.
+ * @param _A_b7 Argument to bind to @e _A_func.
+ * @return Adaptor that executes _A_func with the bound argument on invokation.
+ *
+ * @ingroup bind
+ */
+template <class T_type1,class T_type2,class T_type3,class T_type4,class T_type5,class T_type6,class T_type7, class T_functor>
+inline bind_functor<-1, T_functor,
+                    typename unwrap_reference<T_type1>::type,
+                    typename unwrap_reference<T_type2>::type,
+                    typename unwrap_reference<T_type3>::type,
+                    typename unwrap_reference<T_type4>::type,
+                    typename unwrap_reference<T_type5>::type,
+                    typename unwrap_reference<T_type6>::type,
+                    typename unwrap_reference<T_type7>::type>
+bind(const T_functor& _A_func, T_type1 _A_b1,T_type2 _A_b2,T_type3 _A_b3,T_type4 _A_b4,T_type5 _A_b5,T_type6 _A_b6,T_type7 _A_b7)
+{ return bind_functor<-1, T_functor,
+                    typename unwrap_reference<T_type1>::type,
+                    typename unwrap_reference<T_type2>::type,
+                    typename unwrap_reference<T_type3>::type,
+                    typename unwrap_reference<T_type4>::type,
+                    typename unwrap_reference<T_type5>::type,
+                    typename unwrap_reference<T_type6>::type,
+                    typename unwrap_reference<T_type7>::type>
+                    (_A_func, _A_b1,_A_b2,_A_b3,_A_b4,_A_b5,_A_b6,_A_b7);
+}
+
+
+} /* namespace sigc */
+#endif /* _SIGC_ADAPTORS_MACROS_BINDHM4_ */
diff --git a/libs/sigc++2/sigc++/adaptors/bind_return.h b/libs/sigc++2/sigc++/adaptors/bind_return.h
new file mode 100644
index 0000000000..40e3524090
--- /dev/null
+++ b/libs/sigc++2/sigc++/adaptors/bind_return.h
@@ -0,0 +1,204 @@
+// -*- c++ -*-
+/* Do not edit! -- generated file */
+#ifndef _SIGC_ADAPTORS_MACROS_BIND_RETURNHM4_
+#define _SIGC_ADAPTORS_MACROS_BIND_RETURNHM4_
+#include <sigc++/adaptors/adaptor_trait.h>
+
+namespace sigc {
+
+/** Adaptor that fixes the return value of the wrapped functor.
+ * Use the convenience function sigc::bind_return() to create an instance of sigc::bind_return_functor.
+ *
+ * The following template arguments are used:
+ * - @e T_return Type of the fixed return value.
+ * - @e T_functor Type of the functor to wrap.
+ *
+ * @ingroup bind
+ */
+template <class T_return, class T_functor>
+struct bind_return_functor : public adapts<T_functor>
+{
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef T_return type; };
+  typedef T_return result_type;
+
+  /** Invokes the wrapped functor dropping its return value.
+   * @return The fixed return value.
+   */
+  T_return operator()();
+
+  /** Invokes the wrapped functor passing on the arguments.,
+   * @param _A_arg%1 Argument to be passed on to the functor.)
+   * @return The fixed return value.
+   */
+  template <class T_arg1>
+  inline T_return operator()(T_arg1 _A_a1)
+    { this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass>
+        (_A_a1); return ret_value_;
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1>
+  inline T_return sun_forte_workaround(T_arg1 _A_a1)
+    { this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass>
+        (_A_a1); return ret_value_;
+    }
+  #endif
+
+  /** Invokes the wrapped functor passing on the arguments.,
+   * @param _A_arg%1 Argument to be passed on to the functor.)
+   * @return The fixed return value.
+   */
+  template <class T_arg1,class T_arg2>
+  inline T_return operator()(T_arg1 _A_a1,T_arg2 _A_a2)
+    { this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>
+        (_A_a1,_A_a2); return ret_value_;
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2>
+  inline T_return sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2)
+    { this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>
+        (_A_a1,_A_a2); return ret_value_;
+    }
+  #endif
+
+  /** Invokes the wrapped functor passing on the arguments.,
+   * @param _A_arg%1 Argument to be passed on to the functor.)
+   * @return The fixed return value.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3>
+  inline T_return operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3)
+    { this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>
+        (_A_a1,_A_a2,_A_a3); return ret_value_;
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3>
+  inline T_return sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3)
+    { this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>
+        (_A_a1,_A_a2,_A_a3); return ret_value_;
+    }
+  #endif
+
+  /** Invokes the wrapped functor passing on the arguments.,
+   * @param _A_arg%1 Argument to be passed on to the functor.)
+   * @return The fixed return value.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  inline T_return operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4)
+    { this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>
+        (_A_a1,_A_a2,_A_a3,_A_a4); return ret_value_;
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  inline T_return sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4)
+    { this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>
+        (_A_a1,_A_a2,_A_a3,_A_a4); return ret_value_;
+    }
+  #endif
+
+  /** Invokes the wrapped functor passing on the arguments.,
+   * @param _A_arg%1 Argument to be passed on to the functor.)
+   * @return The fixed return value.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  inline T_return operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5)
+    { this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>
+        (_A_a1,_A_a2,_A_a3,_A_a4,_A_a5); return ret_value_;
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  inline T_return sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5)
+    { this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>
+        (_A_a1,_A_a2,_A_a3,_A_a4,_A_a5); return ret_value_;
+    }
+  #endif
+
+  /** Invokes the wrapped functor passing on the arguments.,
+   * @param _A_arg%1 Argument to be passed on to the functor.)
+   * @return The fixed return value.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  inline T_return operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6)
+    { this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>
+        (_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6); return ret_value_;
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  inline T_return sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6)
+    { this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>
+        (_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6); return ret_value_;
+    }
+  #endif
+
+  /** Invokes the wrapped functor passing on the arguments.,
+   * @param _A_arg%1 Argument to be passed on to the functor.)
+   * @return The fixed return value.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  inline T_return operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6,T_arg7 _A_a7)
+    { this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>
+        (_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6,_A_a7); return ret_value_;
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  inline T_return sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6,T_arg7 _A_a7)
+    { this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>
+        (_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6,_A_a7); return ret_value_;
+    }
+  #endif
+
+
+  /** Constructs a bind_return_functor object that fixes the return value to @p _A_ret_value.
+   * @param _A_functor Functor to invoke from operator()().
+   * @param _A_ret_value Value to return from operator()().
+   */
+  bind_return_functor(typename type_trait<T_functor>::take _A_functor, typename type_trait<T_return>::take _A_ret_value)
+    : adapts<T_functor>(_A_functor), ret_value_(_A_ret_value)
+    {}
+
+  /// The fixed return value.
+  T_return ret_value_; // public, so that visit_each() can access it
+};
+
+template <class T_return, class T_functor>
+T_return bind_return_functor<T_return, T_functor>::operator()()
+  { this->functor_(); return ret_value_; }
+
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bind_return_functor performs a functor on the
+ * functor and on the object instance stored in the sigc::bind_return_functor object.
+ *
+ * @ingroup bind
+ */
+template <class T_action, class T_return, class T_functor>
+void visit_each(const T_action& _A_action,
+                const bind_return_functor<T_return, T_functor>& _A_target)
+{
+  visit_each(_A_action, _A_target.ret_value_);
+  visit_each(_A_action, _A_target.functor_);
+}
+
+
+/** Creates an adaptor of type sigc::bind_return_functor which fixes the return value of the passed functor to the passed argument.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @param _A_ret_value Argument to fix the return value of @e _A_functor to.
+ * @return Adaptor that executes @e _A_functor on invokation and returns @e _A_ret_value.
+ *
+ * @ingroup bind
+ */
+template <class T_return, class T_functor>
+inline bind_return_functor<typename unwrap_reference<T_return>::type, T_functor>
+bind_return(const T_functor& _A_functor, T_return _A_ret_value)
+{ return bind_return_functor<typename unwrap_reference<T_return>::type, T_functor>(_A_functor, _A_ret_value); }
+
+} /* namespace sigc */
+#endif /* _SIGC_ADAPTORS_MACROS_BIND_RETURNHM4_ */
diff --git a/libs/sigc++2/sigc++/adaptors/compose.h b/libs/sigc++2/sigc++/adaptors/compose.h
new file mode 100644
index 0000000000..0f098ff2df
--- /dev/null
+++ b/libs/sigc++2/sigc++/adaptors/compose.h
@@ -0,0 +1,294 @@
+// -*- c++ -*-
+/* Do not edit! -- generated file */
+
+#ifndef _SIGC_ADAPTORS_MACROS_COMPOSEHM4_
+#define _SIGC_ADAPTORS_MACROS_COMPOSEHM4_
+#include <sigc++/adaptors/adaptor_trait.h>
+
+namespace sigc {
+
+/** @defgroup compose compose()
+ * sigc::compose() combines two or three arbitrary functors.
+ * On invokation parameters are passed on to one or two getter functor(s).
+ * The return value(s) are then passed on to the setter function.
+ *
+ * @par Examples:
+ *   @code
+ *   float square_root(float a)  { return sqrtf(a); }
+ *   float sum(float a, float b) { return a+b; }
+ *   std::cout << sigc::compose(&square_root, &sum)(9, 16); // calls square_root(sum(3,6))
+ *   std::cout << sigc::compose(&sum, &square_root, &square_root)(9); // calls sum(square_root(9), square_root(9))
+ *   @endcode
+ *
+ * The functor sigc::compose() returns can be passed into
+ * sigc::signal::connect() directly.
+ *
+ * @par Example:
+ *   @code
+ *   sigc::signal<float,float,float> some_signal;
+ *   some_signal.connect(sigc::compose(&square_root, &sum));
+ *   @endcode
+ *
+ * For a more powerful version of this functionality see the lambda
+ * library adaptor sigc::group() which can bind, hide and reorder
+ * arguments arbitrarily.  Although sigc::group() is more flexible,
+ * sigc::bind() provides a means of binding parameters when then total
+ * number of parameters called is variable.
+ *
+ * @ingroup adaptors
+ */
+
+/** Adaptor that combines two functors.
+ * Use the convenience function sigc::compose() to create an instance of sigc::compose1_functor.
+ *
+ * The following template arguments are used:
+ * - @e T_setter Type of the setter functor to wrap.
+ * - @e T_getter Type of the getter functor to wrap.
+ *
+ * @ingroup compose
+ */
+template <class T_setter, class T_getter>
+struct compose1_functor : public adapts<T_setter>
+{
+  typedef typename adapts<T_setter>::adaptor_type adaptor_type;
+
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef typename adaptor_type::template deduce_result_type<
+        typename sigc::deduce_result_type<T_getter, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+          >::type type; };
+  typedef typename adaptor_type::result_type  result_type;
+
+  result_type
+  operator()();
+
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  operator()(T_arg1 _A_a1)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename sigc::deduce_result_type<T_getter, T_arg1>::type>
+        (get_(_A_a1));
+    }
+
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename sigc::deduce_result_type<T_getter, T_arg1,T_arg2>::type>
+        (get_(_A_a1,_A_a2));
+    }
+
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename sigc::deduce_result_type<T_getter, T_arg1,T_arg2,T_arg3>::type>
+        (get_(_A_a1,_A_a2,_A_a3));
+    }
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename sigc::deduce_result_type<T_getter, T_arg1,T_arg2,T_arg3,T_arg4>::type>
+        (get_(_A_a1,_A_a2,_A_a3,_A_a4));
+    }
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename sigc::deduce_result_type<T_getter, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type>
+        (get_(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5));
+    }
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename sigc::deduce_result_type<T_getter, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type>
+        (get_(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6));
+    }
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6,T_arg7 _A_a7)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename sigc::deduce_result_type<T_getter, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type>
+        (get_(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6,_A_a7));
+    }
+
+
+  /** Constructs a compose1_functor object that combines the passed functors.
+   * @param _A_setter Functor that receives the return values of the invokation of @e _A_getter1 and @e _A_getter2.
+   * @param _A_getter1 Functor to invoke from operator()().
+   * @param _A_getter2 Functor to invoke from operator()().
+   */
+  compose1_functor(const T_setter& _A_setter, const T_getter& _A_getter)
+    : adapts<T_setter>(_A_setter), get_(_A_getter)
+    {}
+
+  T_getter get_; // public, so that visit_each() can access it
+};
+
+template <class T_setter, class T_getter>
+typename compose1_functor<T_setter, T_getter>::result_type
+compose1_functor<T_setter, T_getter>::operator()()
+  { return this->functor_(get_()); }
+
+/** Adaptor that combines three functors.
+ * Use the convenience function sigc::compose() to create an instance of sigc::compose2_functor.
+ *
+ * The following template arguments are used:
+ * - @e T_setter Type of the setter functor to wrap.
+ * - @e T_getter1 Type of the first getter functor to wrap.
+ * - @e T_getter2 Type of the second getter functor to wrap.
+ *
+ * @ingroup compose
+ */
+template <class T_setter, class T_getter1, class T_getter2>
+struct compose2_functor : public adapts<T_setter>
+{
+  typedef typename adapts<T_setter>::adaptor_type adaptor_type;
+
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef typename adaptor_type::template deduce_result_type<
+        typename sigc::deduce_result_type<T_getter1, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type,
+        typename sigc::deduce_result_type<T_getter2, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+          >::type result_type; };
+  typedef typename adaptor_type::result_type  result_type;
+
+  result_type
+  operator()();
+
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  operator()(T_arg1 _A_a1)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename sigc::deduce_result_type<T_getter1, T_arg1>::type,
+                                                         typename sigc::deduce_result_type<T_getter2, T_arg1>::type>
+        (get1_(_A_a1), get2_(_A_a1));
+    }
+
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename sigc::deduce_result_type<T_getter1, T_arg1,T_arg2>::type,
+                                                         typename sigc::deduce_result_type<T_getter2, T_arg1,T_arg2>::type>
+        (get1_(_A_a1,_A_a2), get2_(_A_a1,_A_a2));
+    }
+
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename sigc::deduce_result_type<T_getter1, T_arg1,T_arg2,T_arg3>::type,
+                                                         typename sigc::deduce_result_type<T_getter2, T_arg1,T_arg2,T_arg3>::type>
+        (get1_(_A_a1,_A_a2,_A_a3), get2_(_A_a1,_A_a2,_A_a3));
+    }
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename sigc::deduce_result_type<T_getter1, T_arg1,T_arg2,T_arg3,T_arg4>::type,
+                                                         typename sigc::deduce_result_type<T_getter2, T_arg1,T_arg2,T_arg3,T_arg4>::type>
+        (get1_(_A_a1,_A_a2,_A_a3,_A_a4), get2_(_A_a1,_A_a2,_A_a3,_A_a4));
+    }
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename sigc::deduce_result_type<T_getter1, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type,
+                                                         typename sigc::deduce_result_type<T_getter2, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type>
+        (get1_(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5), get2_(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5));
+    }
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename sigc::deduce_result_type<T_getter1, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type,
+                                                         typename sigc::deduce_result_type<T_getter2, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type>
+        (get1_(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6), get2_(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6));
+    }
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6,T_arg7 _A_a7)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename sigc::deduce_result_type<T_getter1, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type,
+                                                         typename sigc::deduce_result_type<T_getter2, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type>
+        (get1_(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6,_A_a7), get2_(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6,_A_a7));
+    }
+
+
+  /** Constructs a compose2_functor object that combines the passed functors.
+   * @param _A_setter Functor that receives the return values of the invokation of @e _A_getter1 and @e _A_getter2.
+   * @param _A_getter1 Functor to invoke from operator()().
+   * @param _A_getter2 Functor to invoke from operator()().
+   */
+  compose2_functor(const T_setter& _A_setter,
+                   const T_getter1& _A_getter1,
+                   const T_getter2& _A_getter2)
+    : adapts<T_setter>(_A_setter), get1_(_A_getter1), get2_(_A_getter2)
+    {}
+
+  T_getter1 get1_; // public, so that visit_each() can access it
+  T_getter2 get2_; // public, so that visit_each() can access it
+};
+
+template <class T_setter, class T_getter1, class T_getter2>
+typename compose2_functor<T_setter, T_getter1, T_getter2>::result_type
+compose2_functor<T_setter, T_getter1, T_getter2>::operator()()
+  { return this->functor_(get1_(), get2_()); }
+
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::compose1_functor performs a functor on the
+ * functors stored in the sigc::compose1_functor object.
+ *
+ * @ingroup compose
+ */
+template <class T_action, class T_setter, class T_getter>
+void visit_each(const T_action& _A_action,
+                const compose1_functor<T_setter, T_getter>& _A_target)
+{
+  visit_each(_A_action, _A_target.functor_);
+  visit_each(_A_action, _A_target.get_);
+}
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::compose2_functor performs a functor on the
+ * functors stored in the sigc::compose2_functor object.
+ *
+ * @ingroup compose
+ */
+template <class T_action, class T_setter, class T_getter1, class T_getter2>
+void visit_each(const T_action& _A_action,
+                const compose2_functor<T_setter, T_getter1, T_getter2>& _A_target)
+{
+  visit_each(_A_action, _A_target.functor_);
+  visit_each(_A_action, _A_target.get1_);
+  visit_each(_A_action, _A_target.get2_);
+}
+
+
+/** Creates an adaptor of type sigc::compose1_functor which combines two functors.
+ *
+ * @param _A_setter Functor that receives the return value of the invokation of @e _A_getter.
+ * @param _A_getter Functor to invoke from operator()().
+ * @return Adaptor that executes @e _A_setter with the value returned from invokation of @e _A_getter.
+ *
+ * @ingroup compose
+ */
+template <class T_setter, class T_getter>
+inline compose1_functor<T_setter, T_getter>
+compose(const T_setter& _A_setter, const T_getter& _A_getter)
+  { return compose1_functor<T_setter, T_getter>(_A_setter, _A_getter); }
+
+/** Creates an adaptor of type sigc::compose2_functor which combines three functors.
+ *
+ * @param _A_setter Functor that receives the return values of the invokation of @e _A_getter1 and @e _A_getter2.
+ * @param _A_getter1 Functor to invoke from operator()().
+ * @param _A_getter2 Functor to invoke from operator()().
+ * @return Adaptor that executes @e _A_setter with the values return from invokation of @e _A_getter1 and @e _A_getter2.
+ *
+ * @ingroup compose
+ */
+template <class T_setter, class T_getter1, class T_getter2>
+inline compose2_functor<T_setter, T_getter1, T_getter2>
+compose(const T_setter& _A_setter, const T_getter1& _A_getter1, const T_getter2& _A_getter2)
+  { return compose2_functor<T_setter, T_getter1, T_getter2>(_A_setter, _A_getter1, _A_getter2); }
+
+} /* namespace sigc */
+#endif /* _SIGC_ADAPTORS_MACROS_COMPOSEHM4_ */
diff --git a/libs/sigc++2/sigc++/adaptors/deduce_result_type.h b/libs/sigc++2/sigc++/adaptors/deduce_result_type.h
new file mode 100644
index 0000000000..397bb50ff7
--- /dev/null
+++ b/libs/sigc++2/sigc++/adaptors/deduce_result_type.h
@@ -0,0 +1,121 @@
+// -*- c++ -*-
+/* Do not edit! -- generated file */
+/*
+*/
+#ifndef _SIGC_ADAPTORS_MACROS_DEDUCE_RESULT_TYPEHM4_
+#define _SIGC_ADAPTORS_MACROS_DEDUCE_RESULT_TYPEHM4_
+#include <sigc++/functors/functor_trait.h>
+
+
+namespace sigc {
+
+/** A hint to the compiler.
+ * Functors which have all methods based on templates
+ * should publicly inherit from this hint and define 
+ * a nested template class @p deduce_result_type that
+ * can be used to deduce the methods' return types.
+ *
+ * adaptor_base inherits from the functor_base hint so
+ * derived types should also have a result_type defined.
+ *
+ * Adaptors don't inherit from this type directly. They use
+ * use sigc::adapts as a base type instead. sigc::adaptors
+ * wraps arbitrary functor types as well as function pointers
+ * and class methods.
+ *
+ * @ingroup adaptors
+ */
+struct adaptor_base : public functor_base {};
+
+
+/** Deduce the return type of a functor.
+ * <tt>typename deduce_result_type<functor_type, list of arg_types>::type</tt>
+ * deduces a functor's result type if @p functor_type inherits from
+ * sigc::functor_base and defines @p result_type or if @p functor_type
+ * is actually a (member) function type. Multi-type functors are not
+ * supported.
+ *
+ * sigc++ adaptors use
+ * <tt>typename deduce_result_type<functor_type, list of arg_types>::type</tt>
+ * to determine the return type of their <tt>templated operator()</tt> overloads.
+ *
+ * Adaptors in turn define a nested template class @p deduce_result_type
+ * that is used by template specializations of the global deduce_result_type
+ * template to correctly deduce the return types of the adaptor's suitable
+ * <tt>template operator()</tt> overload.
+ *
+ * @ingroup adaptors
+ */
+template <class T_functor,
+          class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void,
+          bool I_derives_adaptor_base=is_base_and_derived<adaptor_base,T_functor>::value>
+struct deduce_result_type
+  { typedef typename functor_trait<T_functor>::result_type type; };
+
+/** Deduce the return type of a functor.
+ * This is the template specialization of the sigc::deduce_result_type template
+ * for 0 arguments.
+ */
+template <class T_functor>
+struct deduce_result_type<T_functor, void,void,void,void,void,void,void, true>
+  { typedef typename T_functor::template deduce_result_type<>::type type; };
+
+/** Deduce the return type of a functor.
+ * This is the template specialization of the sigc::deduce_result_type template
+ * for 1 arguments.
+ */
+template <class T_functor, class T_arg1>
+struct deduce_result_type<T_functor, T_arg1, void,void,void,void,void,void, true>
+  { typedef typename T_functor::template deduce_result_type<T_arg1>::type type; };
+
+/** Deduce the return type of a functor.
+ * This is the template specialization of the sigc::deduce_result_type template
+ * for 2 arguments.
+ */
+template <class T_functor, class T_arg1,class T_arg2>
+struct deduce_result_type<T_functor, T_arg1,T_arg2, void,void,void,void,void, true>
+  { typedef typename T_functor::template deduce_result_type<T_arg1,T_arg2>::type type; };
+
+/** Deduce the return type of a functor.
+ * This is the template specialization of the sigc::deduce_result_type template
+ * for 3 arguments.
+ */
+template <class T_functor, class T_arg1,class T_arg2,class T_arg3>
+struct deduce_result_type<T_functor, T_arg1,T_arg2,T_arg3, void,void,void,void, true>
+  { typedef typename T_functor::template deduce_result_type<T_arg1,T_arg2,T_arg3>::type type; };
+
+/** Deduce the return type of a functor.
+ * This is the template specialization of the sigc::deduce_result_type template
+ * for 4 arguments.
+ */
+template <class T_functor, class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+struct deduce_result_type<T_functor, T_arg1,T_arg2,T_arg3,T_arg4, void,void,void, true>
+  { typedef typename T_functor::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type type; };
+
+/** Deduce the return type of a functor.
+ * This is the template specialization of the sigc::deduce_result_type template
+ * for 5 arguments.
+ */
+template <class T_functor, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+struct deduce_result_type<T_functor, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5, void,void, true>
+  { typedef typename T_functor::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type type; };
+
+/** Deduce the return type of a functor.
+ * This is the template specialization of the sigc::deduce_result_type template
+ * for 6 arguments.
+ */
+template <class T_functor, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+struct deduce_result_type<T_functor, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6, void, true>
+  { typedef typename T_functor::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type type; };
+
+/** Deduce the return type of a functor.
+ * This is the template specialization of the sigc::deduce_result_type template
+ * for 7 arguments.
+ */
+template <class T_functor, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+struct deduce_result_type<T_functor, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7, true>
+  { typedef typename T_functor::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type type; };
+
+
+} /* namespace sigc */
+#endif /* _SIGC_ADAPTORS_MACROS_DEDUCE_RESULT_TYPEHM4_ */
diff --git a/libs/sigc++2/sigc++/adaptors/exception_catch.h b/libs/sigc++2/sigc++/adaptors/exception_catch.h
new file mode 100644
index 0000000000..cd7c41e67d
--- /dev/null
+++ b/libs/sigc++2/sigc++/adaptors/exception_catch.h
@@ -0,0 +1,319 @@
+// -*- c++ -*-
+/* Do not edit! -- generated file */
+#ifndef _SIGC_ADAPTORS_MACROS_EXCEPTION_CATCHHM4_
+#define _SIGC_ADAPTORS_MACROS_EXCEPTION_CATCHHM4_
+#include <sigc++/adaptors/adaptor_trait.h>
+
+namespace sigc {
+
+/*
+   functor adaptor:  exception_catch(functor, catcher)
+
+   usage:
+
+
+   Future directions:
+     The catcher should be told what type of return it needs to
+   return for multiple type functors,  to do this the user
+   will need to derive from catcher_base.
+*/
+/** @defgroup exception_catch exception_catch()
+ * sigc::exception_catch() catches an exception thrown from within 
+ * the wrapped functor and directs it to a catcher functor.
+ * This catcher can then rethrow the exception and catch it with the proper type.
+ *
+ * Note that the catcher is expected to return the same type
+ * as the wrapped functor so that normal flow can continue.
+ *
+ * Catchers can be cascaded to catch multiple types because uncaught
+ * rethrown exceptions proceed to the next catcher adaptor.
+ *
+ * @par Examples:
+ *   @code
+ *   struct my_catch
+ *   {
+ *     int operator()()
+ *     {
+ *       try { throw; }
+ *       catch (std::range_error e) // catch what types we know
+ *         { std::cerr << "caught " << e.what() << std::endl; }
+ *       return 1;
+ *     }
+ *   }
+ *   int foo(); // throws std::range_error
+ *   sigc::exception_catch(&foo, my_catch())();
+ *   @endcode
+ *
+ * The functor sigc::execption_catch() returns can be passed into
+ * sigc::signal::connect() directly.
+ *
+ * @par Example:
+ *   @code
+ *   sigc::signal<int> some_signal;
+ *   some_signal.connect(sigc::exception_catch(&foo, my_catch));
+ *   @endcode
+ *
+ * @ingroup adaptors
+ */
+
+template <class T_functor, class T_catcher, class T_return = typename adapts<T_functor>::result_type>
+struct exception_catch_functor : public adapts<T_functor>
+{
+  typedef typename adapts<T_functor>::adaptor_type adaptor_type;
+
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>::type type; };
+  typedef T_return result_type;
+
+  result_type
+  operator()();
+
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  operator()(T_arg1 _A_a1)
+    { 
+      try
+        {
+          return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass>
+            (_A_a1);
+        } 
+      catch (...)
+        { return catcher_(); }
+    }
+
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2)
+    { 
+      try
+        {
+          return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>
+            (_A_a1,_A_a2);
+        } 
+      catch (...)
+        { return catcher_(); }
+    }
+
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3)
+    { 
+      try
+        {
+          return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>
+            (_A_a1,_A_a2,_A_a3);
+        } 
+      catch (...)
+        { return catcher_(); }
+    }
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4)
+    { 
+      try
+        {
+          return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>
+            (_A_a1,_A_a2,_A_a3,_A_a4);
+        } 
+      catch (...)
+        { return catcher_(); }
+    }
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5)
+    { 
+      try
+        {
+          return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>
+            (_A_a1,_A_a2,_A_a3,_A_a4,_A_a5);
+        } 
+      catch (...)
+        { return catcher_(); }
+    }
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6)
+    { 
+      try
+        {
+          return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>
+            (_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6);
+        } 
+      catch (...)
+        { return catcher_(); }
+    }
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6,T_arg7 _A_a7)
+    { 
+      try
+        {
+          return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>
+            (_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6,_A_a7);
+        } 
+      catch (...)
+        { return catcher_(); }
+    }
+
+  exception_catch_functor(const T_functor& _A_func,
+                          const T_catcher& _A_catcher)
+    : adapts<T_functor>(_A_func), catcher_(_A_catcher)
+    {}
+
+  protected: 
+    T_catcher catcher_; 
+};
+
+template <class T_functor, class T_catcher, class T_return>
+typename exception_catch_functor<T_functor, T_catcher, T_return>::result_type
+exception_catch_functor<T_functor, T_catcher, T_return>::operator()()
+  { 
+    try
+      { return this->functor_(); }
+    catch (...)
+      { return catcher_(); }
+  }
+
+// void specialization
+template <class T_functor, class T_catcher>
+struct exception_catch_functor<T_functor, T_catcher, void> : public adapts<T_functor>
+{
+  typedef void result_type;
+  typedef typename adapts<T_functor>::adaptor_type adaptor_type;
+
+  void
+  operator()();
+
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  operator()(T_arg1 _A_a1)
+    { 
+      try
+        {
+          return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass>
+            (_A_a1);
+        } 
+      catch (...)
+        { return catcher_(); }
+    }
+
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2)
+    { 
+      try
+        {
+          return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>
+            (_A_a1,_A_a2);
+        } 
+      catch (...)
+        { return catcher_(); }
+    }
+
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3)
+    { 
+      try
+        {
+          return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>
+            (_A_a1,_A_a2,_A_a3);
+        } 
+      catch (...)
+        { return catcher_(); }
+    }
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4)
+    { 
+      try
+        {
+          return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>
+            (_A_a1,_A_a2,_A_a3,_A_a4);
+        } 
+      catch (...)
+        { return catcher_(); }
+    }
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5)
+    { 
+      try
+        {
+          return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>
+            (_A_a1,_A_a2,_A_a3,_A_a4,_A_a5);
+        } 
+      catch (...)
+        { return catcher_(); }
+    }
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6)
+    { 
+      try
+        {
+          return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>
+            (_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6);
+        } 
+      catch (...)
+        { return catcher_(); }
+    }
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6,T_arg7 _A_a7)
+    { 
+      try
+        {
+          return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>
+            (_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6,_A_a7);
+        } 
+      catch (...)
+        { return catcher_(); }
+    }
+
+  exception_catch_functor() {}
+  exception_catch_functor(const T_functor& _A_func,
+                          const T_catcher& _A_catcher)
+    : adapts<T_functor>(_A_func), catcher_(_A_catcher)
+    {}
+  ~exception_catch_functor() {}
+
+  protected: 
+    T_catcher catcher_; 
+};
+
+template <class T_functor, class T_catcher>
+void exception_catch_functor<T_functor, T_catcher, void>::operator()()
+  { 
+    try
+      { this->functor_(); } // I don't understand why void return doesn't work here (Martin)
+    catch (...)
+      { this->catcher_(); }
+  }
+
+
+template <class T_action, class T_functor, class T_catcher, class T_return>
+void visit_each(const T_action& _A_action,
+                const exception_catch_functor<T_functor, T_catcher, T_return>& _A_target)
+{
+  visit_each(_A_action, _A_target.functor_);
+  visit_each(_A_action, _A_target.catcher_);
+}
+
+
+template <class T_functor, class T_catcher>
+inline exception_catch_functor<T_functor, T_catcher>
+exception_catch(const T_functor& _A_func, const T_catcher& _A_catcher)
+  { return exception_catch_functor<T_functor, T_catcher>(_A_func, _A_catcher); }
+
+} /* namespace sigc */
+#endif /* _SIGC_ADAPTORS_MACROS_EXCEPTION_CATCHHM4_ */
diff --git a/libs/sigc++2/sigc++/adaptors/hide.h b/libs/sigc++2/sigc++/adaptors/hide.h
new file mode 100644
index 0000000000..1b820fea6b
--- /dev/null
+++ b/libs/sigc++2/sigc++/adaptors/hide.h
@@ -0,0 +1,1063 @@
+// -*- c++ -*-
+/* Do not edit! -- generated file */
+#ifndef _SIGC_ADAPTORS_MACROS_HIDEHM4_
+#define _SIGC_ADAPTORS_MACROS_HIDEHM4_
+#include <sigc++/adaptors/adaptor_trait.h>
+
+namespace sigc { 
+
+/** @defgroup hide hide(), hide_return()
+ * sigc::hide() alters an arbitrary functor in that it adds a parameter
+ * whose value is ignored on invocation of the returned functor.
+ * Thus you can discard one or more of the arguments of a signal.
+ *
+ * You may optionally specify the zero-based position of the parameter
+ * to ignore as a template argument. The default is to ignore the last
+ * parameter.
+ * (A value of @p -1 adds a parameter at the end so sigc::hide<-1>() gives the same result as sigc::hide().)
+ *
+ * The type of the parameter can optionally be specified if not deduced.
+ *
+ * @par Examples:
+ *   @code
+ *   void foo(int, int);
+ *   // single argument hiding ...
+ *   sigc::hide(&foo)(1,2,3);     // adds a dummy parameter at the back and calls foo(1,2)
+ *   sigc::hide<-1>(&foo)(1,2,3); // same as sigc::hide(&foo)(1,2,3) (calls foo(1,2))
+ *   sigc::hide<0>(&foo)(1,2,3);  // adds a dummy parameter at the beginning and calls foo(2,3)
+ *   sigc::hide<1>(&foo)(1,2,3);  // adds a dummy parameter in the middle and calls foo(1,3)
+ *   sigc::hide<2>(&foo)(1,2,3);  // adds a dummy parameter at the back and calls foo(1,2)
+ *   // multiple argument hiding ...
+ *   sigc::hide(sigc::hide(&foo))(1,2,3,4); // adds two dummy parameters at the back and calls foo(1,2)
+ *   @endcode
+ *
+ * The functor sigc::hide() returns can be passed into
+ * sigc::signal::connect() directly.
+ *
+ * @par Example:
+ *   @code
+ *   sigc::signal<void,int> some_signal;
+ *   void foo();
+ *   some_signal.connect(sigc::hide(&foo));
+ *   @endcode
+ *
+ * sigc::hide_return() alters an arbitrary functor by
+ * dropping its return value, thus converting it to a void functor.
+ *
+ * For a more powerful version of this functionality see the lambda
+ * library adaptor sigc::group() which can bind, hide and reorder
+ * arguments arbitrarily.  Although sigc::group() is more flexible,
+ * sigc::hide() provides a means of hiding parameters when then total
+ * number of parameters called is variable.
+ *
+ * @ingroup adaptors
+ */
+
+/** Adaptor that adds a dummy parameter to the wrapped functor.
+ * Use the convenience function sigc::hide() to create an instance of sigc::hide_functor.
+ *
+ * The following template arguments are used:
+ * - @e I_location Zero-based position of the dummy parameter (@p -1 for the last parameter).
+ * - @e T_type Type of the dummy parameter.
+ * - @e T_functor Type of the functor to wrap.
+ *
+ * @ingroup hide
+ */
+template <int I_location, class T_functor>
+struct hide_functor;
+
+/** Adaptor that adds a dummy parameter to the wrapped functor.
+ * This template specialization ignores the value of the last parameter in operator()().
+ *
+ * @ingroup hide
+ */
+template <class T_functor>
+struct hide_functor <-1, T_functor> : public adapts<T_functor>
+{
+  typedef typename adapts<T_functor>::adaptor_type adaptor_type;
+
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>::type type; };
+  typedef typename adaptor_type::result_type  result_type;
+
+  /** Invokes the wrapped functor ignoring the only argument.
+   * @param _A_arg%1 Argument to be ignored.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  operator()(T_arg1 _A_a1)
+    { return this->functor_(); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  sun_forte_workaround(T_arg1 _A_a1)
+    { return this->functor_(); }
+  #endif
+
+  /** Invokes the wrapped functor ignoring the last argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be ignored.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass>
+        (_A_a1); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass>
+        (_A_a1); }
+  #endif
+
+  /** Invokes the wrapped functor ignoring the last argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be ignored.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass>
+        (_A_a1, _A_a2); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass>
+        (_A_a1, _A_a2); }
+  #endif
+
+  /** Invokes the wrapped functor ignoring the last argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be ignored.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass>
+        (_A_a1, _A_a2, _A_a3); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass>
+        (_A_a1, _A_a2, _A_a3); }
+  #endif
+
+  /** Invokes the wrapped functor ignoring the last argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @param _A_arg5 Argument to be ignored.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass>
+        (_A_a1, _A_a2, _A_a3, _A_a4); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass>
+        (_A_a1, _A_a2, _A_a3, _A_a4); }
+  #endif
+
+  /** Invokes the wrapped functor ignoring the last argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @param _A_arg5 Argument to be passed on to the functor.
+   * @param _A_arg6 Argument to be ignored.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass>
+        (_A_a1, _A_a2, _A_a3, _A_a4, _A_a5); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass>
+        (_A_a1, _A_a2, _A_a3, _A_a4, _A_a5); }
+  #endif
+
+  /** Invokes the wrapped functor ignoring the last argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @param _A_arg5 Argument to be passed on to the functor.
+   * @param _A_arg6 Argument to be passed on to the functor.
+   * @param _A_arg7 Argument to be ignored.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6,T_arg7 _A_a7)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass>
+        (_A_a1, _A_a2, _A_a3, _A_a4, _A_a5, _A_a6); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6,T_arg7 _A_a7)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass>
+        (_A_a1, _A_a2, _A_a3, _A_a4, _A_a5, _A_a6); }
+  #endif
+
+
+  /** Constructs a hide_functor object that adds a dummy parameter to the passed functor.
+   * @param _A_functor Functor to invoke from operator()().
+   */
+  explicit hide_functor(const T_functor& _A_func)
+    : adapts<T_functor>(_A_func)
+    {}
+};
+
+/** Adaptor that adds a dummy parameter to the wrapped functor.
+ * This template specialization ignores the value of the 0th parameter in operator()().
+ *
+ * @ingroup hide
+ */
+template <class T_functor>
+struct hide_functor <0, T_functor> : public adapts<T_functor>
+{
+  typedef typename adapts<T_functor>::adaptor_type adaptor_type;
+
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass, typename type_trait<T_arg7>::pass>::type type; };
+  typedef typename adaptor_type::result_type  result_type;
+
+  /** Invokes the wrapped functor ignoring the only argument.
+   * @param _A_arg%1 Argument to be ignored.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  operator()(T_arg1 _A_a1)
+    { return this->functor_(); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  sun_forte_workaround(T_arg1 _A_a1)
+    { return this->functor_(); }
+  #endif
+
+  /** Invokes the wrapped functor ignoring the 1th argument.
+   * @param _A_arg1 Argument to be ignored.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg2>::pass>
+        (_A_a2); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg2>::pass>
+        (_A_a2); }
+  #endif
+    
+  /** Invokes the wrapped functor ignoring the 1th argument.
+   * @param _A_arg1 Argument to be ignored.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass>
+        (_A_a2, _A_a3); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass>
+        (_A_a2, _A_a3); }
+  #endif
+    
+  /** Invokes the wrapped functor ignoring the 1th argument.
+   * @param _A_arg1 Argument to be ignored.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass>
+        (_A_a2, _A_a3, _A_a4); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass>
+        (_A_a2, _A_a3, _A_a4); }
+  #endif
+    
+  /** Invokes the wrapped functor ignoring the 1th argument.
+   * @param _A_arg1 Argument to be ignored.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @param _A_arg5 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass>
+        (_A_a2, _A_a3, _A_a4, _A_a5); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass>
+        (_A_a2, _A_a3, _A_a4, _A_a5); }
+  #endif
+    
+  /** Invokes the wrapped functor ignoring the 1th argument.
+   * @param _A_arg1 Argument to be ignored.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @param _A_arg5 Argument to be passed on to the functor.
+   * @param _A_arg6 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass>
+        (_A_a2, _A_a3, _A_a4, _A_a5, _A_a6); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass>
+        (_A_a2, _A_a3, _A_a4, _A_a5, _A_a6); }
+  #endif
+    
+  /** Invokes the wrapped functor ignoring the 1th argument.
+   * @param _A_arg1 Argument to be ignored.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @param _A_arg5 Argument to be passed on to the functor.
+   * @param _A_arg6 Argument to be passed on to the functor.
+   * @param _A_arg7 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6,T_arg7 _A_a7)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass, typename type_trait<T_arg7>::pass>
+        (_A_a2, _A_a3, _A_a4, _A_a5, _A_a6, _A_a7); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6,T_arg7 _A_a7)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass, typename type_trait<T_arg7>::pass>
+        (_A_a2, _A_a3, _A_a4, _A_a5, _A_a6, _A_a7); }
+  #endif
+    
+
+  /** Constructs a hide_functor object that adds a dummy parameter to the passed functor.
+   * @param _A_functor Functor to invoke from operator()().
+   */
+  explicit hide_functor(const T_functor& _A_func)
+    : adapts<T_functor>(_A_func)
+    {}
+};
+
+/** Adaptor that adds a dummy parameter to the wrapped functor.
+ * This template specialization ignores the value of the 1th parameter in operator()().
+ *
+ * @ingroup hide
+ */
+template <class T_functor>
+struct hide_functor <1, T_functor> : public adapts<T_functor>
+{
+  typedef typename adapts<T_functor>::adaptor_type adaptor_type;
+
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_arg1>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass, typename type_trait<T_arg7>::pass>::type type; };
+  typedef typename adaptor_type::result_type  result_type;
+
+  /** Invokes the wrapped functor ignoring the 2th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be ignored.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass>
+        (_A_a1); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass>
+        (_A_a1); }
+  #endif
+    
+  /** Invokes the wrapped functor ignoring the 2th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be ignored.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg3>::pass>
+        (_A_a1, _A_a3); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg3>::pass>
+        (_A_a1, _A_a3); }
+  #endif
+    
+  /** Invokes the wrapped functor ignoring the 2th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be ignored.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass>
+        (_A_a1, _A_a3, _A_a4); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass>
+        (_A_a1, _A_a3, _A_a4); }
+  #endif
+    
+  /** Invokes the wrapped functor ignoring the 2th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be ignored.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @param _A_arg5 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass>
+        (_A_a1, _A_a3, _A_a4, _A_a5); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass>
+        (_A_a1, _A_a3, _A_a4, _A_a5); }
+  #endif
+    
+  /** Invokes the wrapped functor ignoring the 2th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be ignored.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @param _A_arg5 Argument to be passed on to the functor.
+   * @param _A_arg6 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass>
+        (_A_a1, _A_a3, _A_a4, _A_a5, _A_a6); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass>
+        (_A_a1, _A_a3, _A_a4, _A_a5, _A_a6); }
+  #endif
+    
+  /** Invokes the wrapped functor ignoring the 2th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be ignored.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @param _A_arg5 Argument to be passed on to the functor.
+   * @param _A_arg6 Argument to be passed on to the functor.
+   * @param _A_arg7 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6,T_arg7 _A_a7)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass, typename type_trait<T_arg7>::pass>
+        (_A_a1, _A_a3, _A_a4, _A_a5, _A_a6, _A_a7); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6,T_arg7 _A_a7)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass, typename type_trait<T_arg7>::pass>
+        (_A_a1, _A_a3, _A_a4, _A_a5, _A_a6, _A_a7); }
+  #endif
+    
+
+  /** Constructs a hide_functor object that adds a dummy parameter to the passed functor.
+   * @param _A_functor Functor to invoke from operator()().
+   */
+  explicit hide_functor(const T_functor& _A_func)
+    : adapts<T_functor>(_A_func)
+    {}
+};
+
+/** Adaptor that adds a dummy parameter to the wrapped functor.
+ * This template specialization ignores the value of the 2th parameter in operator()().
+ *
+ * @ingroup hide
+ */
+template <class T_functor>
+struct hide_functor <2, T_functor> : public adapts<T_functor>
+{
+  typedef typename adapts<T_functor>::adaptor_type adaptor_type;
+
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass, typename type_trait<T_arg7>::pass>::type type; };
+  typedef typename adaptor_type::result_type  result_type;
+
+  /** Invokes the wrapped functor ignoring the 3th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be ignored.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass>
+        (_A_a1, _A_a2); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass>
+        (_A_a1, _A_a2); }
+  #endif
+    
+  /** Invokes the wrapped functor ignoring the 3th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be ignored.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg4>::pass>
+        (_A_a1, _A_a2, _A_a4); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg4>::pass>
+        (_A_a1, _A_a2, _A_a4); }
+  #endif
+    
+  /** Invokes the wrapped functor ignoring the 3th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be ignored.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @param _A_arg5 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass>
+        (_A_a1, _A_a2, _A_a4, _A_a5); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass>
+        (_A_a1, _A_a2, _A_a4, _A_a5); }
+  #endif
+    
+  /** Invokes the wrapped functor ignoring the 3th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be ignored.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @param _A_arg5 Argument to be passed on to the functor.
+   * @param _A_arg6 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass>
+        (_A_a1, _A_a2, _A_a4, _A_a5, _A_a6); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass>
+        (_A_a1, _A_a2, _A_a4, _A_a5, _A_a6); }
+  #endif
+    
+  /** Invokes the wrapped functor ignoring the 3th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be ignored.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @param _A_arg5 Argument to be passed on to the functor.
+   * @param _A_arg6 Argument to be passed on to the functor.
+   * @param _A_arg7 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6,T_arg7 _A_a7)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass, typename type_trait<T_arg7>::pass>
+        (_A_a1, _A_a2, _A_a4, _A_a5, _A_a6, _A_a7); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6,T_arg7 _A_a7)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass, typename type_trait<T_arg7>::pass>
+        (_A_a1, _A_a2, _A_a4, _A_a5, _A_a6, _A_a7); }
+  #endif
+    
+
+  /** Constructs a hide_functor object that adds a dummy parameter to the passed functor.
+   * @param _A_functor Functor to invoke from operator()().
+   */
+  explicit hide_functor(const T_functor& _A_func)
+    : adapts<T_functor>(_A_func)
+    {}
+};
+
+/** Adaptor that adds a dummy parameter to the wrapped functor.
+ * This template specialization ignores the value of the 3th parameter in operator()().
+ *
+ * @ingroup hide
+ */
+template <class T_functor>
+struct hide_functor <3, T_functor> : public adapts<T_functor>
+{
+  typedef typename adapts<T_functor>::adaptor_type adaptor_type;
+
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass, typename type_trait<T_arg7>::pass>::type type; };
+  typedef typename adaptor_type::result_type  result_type;
+
+  /** Invokes the wrapped functor ignoring the 4th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be ignored.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass>
+        (_A_a1, _A_a2, _A_a3); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass>
+        (_A_a1, _A_a2, _A_a3); }
+  #endif
+    
+  /** Invokes the wrapped functor ignoring the 4th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be ignored.
+   * @param _A_arg5 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg5>::pass>
+        (_A_a1, _A_a2, _A_a3, _A_a5); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg5>::pass>
+        (_A_a1, _A_a2, _A_a3, _A_a5); }
+  #endif
+    
+  /** Invokes the wrapped functor ignoring the 4th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be ignored.
+   * @param _A_arg5 Argument to be passed on to the functor.
+   * @param _A_arg6 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass>
+        (_A_a1, _A_a2, _A_a3, _A_a5, _A_a6); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass>
+        (_A_a1, _A_a2, _A_a3, _A_a5, _A_a6); }
+  #endif
+    
+  /** Invokes the wrapped functor ignoring the 4th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be ignored.
+   * @param _A_arg5 Argument to be passed on to the functor.
+   * @param _A_arg6 Argument to be passed on to the functor.
+   * @param _A_arg7 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6,T_arg7 _A_a7)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass, typename type_trait<T_arg7>::pass>
+        (_A_a1, _A_a2, _A_a3, _A_a5, _A_a6, _A_a7); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6,T_arg7 _A_a7)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass, typename type_trait<T_arg7>::pass>
+        (_A_a1, _A_a2, _A_a3, _A_a5, _A_a6, _A_a7); }
+  #endif
+    
+
+  /** Constructs a hide_functor object that adds a dummy parameter to the passed functor.
+   * @param _A_functor Functor to invoke from operator()().
+   */
+  explicit hide_functor(const T_functor& _A_func)
+    : adapts<T_functor>(_A_func)
+    {}
+};
+
+/** Adaptor that adds a dummy parameter to the wrapped functor.
+ * This template specialization ignores the value of the 4th parameter in operator()().
+ *
+ * @ingroup hide
+ */
+template <class T_functor>
+struct hide_functor <4, T_functor> : public adapts<T_functor>
+{
+  typedef typename adapts<T_functor>::adaptor_type adaptor_type;
+
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass, typename type_trait<T_arg6>::pass, typename type_trait<T_arg7>::pass>::type type; };
+  typedef typename adaptor_type::result_type  result_type;
+
+  /** Invokes the wrapped functor ignoring the 5th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @param _A_arg5 Argument to be ignored.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass>
+        (_A_a1, _A_a2, _A_a3, _A_a4); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass>
+        (_A_a1, _A_a2, _A_a3, _A_a4); }
+  #endif
+    
+  /** Invokes the wrapped functor ignoring the 5th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @param _A_arg5 Argument to be ignored.
+   * @param _A_arg6 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg6>::pass>
+        (_A_a1, _A_a2, _A_a3, _A_a4, _A_a6); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg6>::pass>
+        (_A_a1, _A_a2, _A_a3, _A_a4, _A_a6); }
+  #endif
+    
+  /** Invokes the wrapped functor ignoring the 5th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @param _A_arg5 Argument to be ignored.
+   * @param _A_arg6 Argument to be passed on to the functor.
+   * @param _A_arg7 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6,T_arg7 _A_a7)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg6>::pass, typename type_trait<T_arg7>::pass>
+        (_A_a1, _A_a2, _A_a3, _A_a4, _A_a6, _A_a7); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6,T_arg7 _A_a7)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg6>::pass, typename type_trait<T_arg7>::pass>
+        (_A_a1, _A_a2, _A_a3, _A_a4, _A_a6, _A_a7); }
+  #endif
+    
+
+  /** Constructs a hide_functor object that adds a dummy parameter to the passed functor.
+   * @param _A_functor Functor to invoke from operator()().
+   */
+  explicit hide_functor(const T_functor& _A_func)
+    : adapts<T_functor>(_A_func)
+    {}
+};
+
+/** Adaptor that adds a dummy parameter to the wrapped functor.
+ * This template specialization ignores the value of the 5th parameter in operator()().
+ *
+ * @ingroup hide
+ */
+template <class T_functor>
+struct hide_functor <5, T_functor> : public adapts<T_functor>
+{
+  typedef typename adapts<T_functor>::adaptor_type adaptor_type;
+
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass, typename type_trait<T_arg7>::pass>::type type; };
+  typedef typename adaptor_type::result_type  result_type;
+
+  /** Invokes the wrapped functor ignoring the 6th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @param _A_arg5 Argument to be passed on to the functor.
+   * @param _A_arg6 Argument to be ignored.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass>
+        (_A_a1, _A_a2, _A_a3, _A_a4, _A_a5); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass>
+        (_A_a1, _A_a2, _A_a3, _A_a4, _A_a5); }
+  #endif
+    
+  /** Invokes the wrapped functor ignoring the 6th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @param _A_arg5 Argument to be passed on to the functor.
+   * @param _A_arg6 Argument to be ignored.
+   * @param _A_arg7 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6,T_arg7 _A_a7)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg7>::pass>
+        (_A_a1, _A_a2, _A_a3, _A_a4, _A_a5, _A_a7); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6,T_arg7 _A_a7)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg7>::pass>
+        (_A_a1, _A_a2, _A_a3, _A_a4, _A_a5, _A_a7); }
+  #endif
+    
+
+  /** Constructs a hide_functor object that adds a dummy parameter to the passed functor.
+   * @param _A_functor Functor to invoke from operator()().
+   */
+  explicit hide_functor(const T_functor& _A_func)
+    : adapts<T_functor>(_A_func)
+    {}
+};
+
+/** Adaptor that adds a dummy parameter to the wrapped functor.
+ * This template specialization ignores the value of the 6th parameter in operator()().
+ *
+ * @ingroup hide
+ */
+template <class T_functor>
+struct hide_functor <6, T_functor> : public adapts<T_functor>
+{
+  typedef typename adapts<T_functor>::adaptor_type adaptor_type;
+
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>::type type; };
+  typedef typename adaptor_type::result_type  result_type;
+
+  /** Invokes the wrapped functor ignoring the 7th argument.
+   * @param _A_arg1 Argument to be passed on to the functor.
+   * @param _A_arg2 Argument to be passed on to the functor.
+   * @param _A_arg3 Argument to be passed on to the functor.
+   * @param _A_arg4 Argument to be passed on to the functor.
+   * @param _A_arg5 Argument to be passed on to the functor.
+   * @param _A_arg6 Argument to be passed on to the functor.
+   * @param _A_arg7 Argument to be ignored.
+   * @return The return value of the functor invocation.
+   */
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6,T_arg7 _A_a7)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass>
+        (_A_a1, _A_a2, _A_a3, _A_a4, _A_a5, _A_a6); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6,T_arg7 _A_a7)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass, typename type_trait<T_arg2>::pass, typename type_trait<T_arg3>::pass, typename type_trait<T_arg4>::pass, typename type_trait<T_arg5>::pass, typename type_trait<T_arg6>::pass>
+        (_A_a1, _A_a2, _A_a3, _A_a4, _A_a5, _A_a6); }
+  #endif
+    
+
+  /** Constructs a hide_functor object that adds a dummy parameter to the passed functor.
+   * @param _A_functor Functor to invoke from operator()().
+   */
+  explicit hide_functor(const T_functor& _A_func)
+    : adapts<T_functor>(_A_func)
+    {}
+};
+
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::hide_functor performs a functor on the
+ * functor stored in the sigc::hide_functor object.
+ *
+ * @ingroup hide
+ */
+template <class T_action, int I_location, class T_functor>
+void visit_each(const T_action& _A_action,
+                const hide_functor<I_location, T_functor>& _A_target)
+{
+  visit_each(_A_action, _A_target.functor_);
+}
+
+
+/** Creates an adaptor of type sigc::hide_functor which adds a dummy parameter to the passed functor.
+ * The optional template argument @e I_location specifies the zero-based
+ * position of the dummy parameter in the returned functor (@p -1 stands for the last parameter).
+ *
+ * @param _A_func Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_func ignoring the value of the dummy parameter.
+ *
+ * @ingroup hide
+ */
+template <int I_location, class T_functor>
+inline hide_functor<I_location, T_functor>
+hide(const T_functor& _A_func)
+  { return hide_functor<I_location, T_functor>(_A_func); }
+
+/** Creates an adaptor of type sigc::hide_functor which adds a dummy parameter to the passed functor.
+ * This overload adds a dummy parameter at the back of the functor's parameter list.
+ *
+ * @param _A_func Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_func ignoring the value of the last parameter.
+ *
+ * @ingroup hide
+ */
+template <class T_functor>
+inline hide_functor<-1, T_functor>
+hide(const T_functor& _A_func)
+  { return hide_functor<-1, T_functor> (_A_func); }
+
+} /* namespace sigc */
+#endif /* _SIGC_ADAPTORS_MACROS_HIDEHM4_ */
diff --git a/libs/sigc++2/sigc++/adaptors/lambda/base.h b/libs/sigc++2/sigc++/adaptors/lambda/base.h
new file mode 100644
index 0000000000..6a2c402c89
--- /dev/null
+++ b/libs/sigc++2/sigc++/adaptors/lambda/base.h
@@ -0,0 +1,392 @@
+// -*- c++ -*-
+/* Do not edit! -- generated file */
+#ifndef _SIGC_LAMBDA_BASE_HPP_
+#define _SIGC_LAMBDA_BASE_HPP_
+#include <sigc++/adaptors/adaptor_trait.h>
+
+namespace sigc {
+
+/** @defgroup lambdas Lambdas
+ * libsigc++ ships with basic lambda functionality and the sigc::group adaptor that uses lambdas to transform a functor's parameter list.
+ *
+ * The lambda selectors sigc::_1, sigc::_2, ..., sigc::_9 are used to select the
+ * first, second, ..., nineth argument from a list.
+ *
+ * @par Examples:
+ *   @code
+ *   std::cout << sigc::_1(10,20,30); // returns 10
+ *   std::cout << sigc::_2(10,20,30); // returns 20
+ *   ...
+ *   @endcode
+ *
+ * Operators are defined so that lambda selectors can be used e.g. as placeholders in
+ * arithmetic expressions.
+ *
+ * @par Examples:
+ *   @code
+ *   std::cout << (sigc::_1 + 5)(3); // returns (3 + 5)
+ *   std::cout << (sigc::_1 * sigc::_2)(7,10); // returns (7 * 10)
+ *   @endcode
+ */
+
+/** A hint to the compiler.
+ * All lambda types publically inherit from this hint.
+ *
+ * @ingroup lambdas
+ */
+struct lambda_base : public adaptor_base {};
+
+// Forward declaration of lambda.
+template <class T_type> struct lambda;
+
+
+namespace internal {
+
+/** Abstracts lambda functionality.
+ * Objects of this type store a value that may be of type lambda itself.
+ * In this case, operator()() executes the lambda (a lambda is always a functor at the same time).
+ * Otherwise, operator()() simply returns the stored value.
+ */
+template <class T_type, bool I_islambda = is_base_and_derived<lambda_base, T_type>::value> struct lambda_core;
+
+/// Abstracts lambda functionality (template specialization for lambda values).
+template <class T_type>
+struct lambda_core<T_type, true> : public lambda_base
+{
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef typename T_type::template deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>::type type; };
+  typedef typename T_type::result_type result_type;
+  typedef T_type lambda_type;
+
+  result_type
+  operator()() const;
+
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  operator ()(T_arg1 _A_1) const 
+    { return value_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass>
+             (_A_1); 
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  sun_forte_workaround(T_arg1 _A_1) const
+    { return value_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass>
+             (_A_1); 
+    }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  operator ()(T_arg1 _A_1,T_arg2 _A_2) const 
+    { return value_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>
+             (_A_1,_A_2); 
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2) const
+    { return value_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>
+             (_A_1,_A_2); 
+    }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3) const 
+    { return value_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>
+             (_A_1,_A_2,_A_3); 
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3) const
+    { return value_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>
+             (_A_1,_A_2,_A_3); 
+    }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4) const 
+    { return value_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>
+             (_A_1,_A_2,_A_3,_A_4); 
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4) const
+    { return value_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>
+             (_A_1,_A_2,_A_3,_A_4); 
+    }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5) const 
+    { return value_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>
+             (_A_1,_A_2,_A_3,_A_4,_A_5); 
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5) const
+    { return value_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>
+             (_A_1,_A_2,_A_3,_A_4,_A_5); 
+    }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6) const 
+    { return value_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>
+             (_A_1,_A_2,_A_3,_A_4,_A_5,_A_6); 
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6) const
+    { return value_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>
+             (_A_1,_A_2,_A_3,_A_4,_A_5,_A_6); 
+    }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6,T_arg7 _A_7) const 
+    { return value_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>
+             (_A_1,_A_2,_A_3,_A_4,_A_5,_A_6,_A_7); 
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6,T_arg7 _A_7) const
+    { return value_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>
+             (_A_1,_A_2,_A_3,_A_4,_A_5,_A_6,_A_7); 
+    }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  lambda_core() {}
+
+  explicit lambda_core(const T_type& v)
+    : value_(v) {}
+
+  T_type value_;
+};
+
+template <class T_type>
+typename lambda_core<T_type, true>::result_type
+lambda_core<T_type, true>::operator()() const
+  { return value_(); }
+
+
+/// Abstracts lambda functionality (template specialization for other value types).
+template <class T_type>
+struct lambda_core<T_type, false> : public lambda_base
+{
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef T_type type; };
+  typedef T_type result_type; // all operator() overloads return T_type.
+  typedef lambda<T_type> lambda_type;
+
+  result_type operator()() const;
+
+  template <class T_arg1>
+  result_type operator ()(T_arg1 _A_1) const 
+    { return value_; }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1>
+  result_type sun_forte_workaround(T_arg1 _A_1) const
+    { return value_; }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  template <class T_arg1,class T_arg2>
+  result_type operator ()(T_arg1 _A_1,T_arg2 _A_2) const 
+    { return value_; }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2>
+  result_type sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2) const
+    { return value_; }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  template <class T_arg1,class T_arg2,class T_arg3>
+  result_type operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3) const 
+    { return value_; }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3>
+  result_type sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3) const
+    { return value_; }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  result_type operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4) const 
+    { return value_; }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  result_type sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4) const
+    { return value_; }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  result_type operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5) const 
+    { return value_; }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  result_type sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5) const
+    { return value_; }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  result_type operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6) const 
+    { return value_; }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  result_type sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6) const
+    { return value_; }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  result_type operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6,T_arg7 _A_7) const 
+    { return value_; }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  result_type sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6,T_arg7 _A_7) const
+    { return value_; }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  explicit lambda_core(typename type_trait<T_type>::take v)
+    : value_(v) {}
+
+  T_type value_;
+};
+
+template <class T_type>
+typename lambda_core<T_type, false>::result_type lambda_core<T_type, false>::operator()() const
+  { return value_; }
+
+} /* namespace internal */
+
+
+template <class T_action, class T_functor, bool I_islambda>
+void visit_each(const T_action& _A_action,
+                const internal::lambda_core<T_functor, I_islambda>& _A_target)
+{
+  visit_each(_A_action, _A_target.value_);
+}
+
+
+// forward declarations for lambda operators other<subscript> and other<assign>
+template <class T_type>
+struct other;
+struct subscript;
+struct assign;
+
+template <class T_action, class T_type1, class T_type2>
+struct lambda_operator;
+
+template <class T_type>
+struct unwrap_lambda_type;
+
+
+/** Lambda type.
+ * Objects of this type store a value that may be of type lambda itself.
+ * In this case, operator()() executes the lambda (a lambda is always a functor at the same time).
+ * Otherwise, operator()() simply returns the stored value.
+ * The assign and subscript operators are defined to return a lambda operator.
+ *
+ * @ingroup lambdas
+ */
+template <class T_type>
+struct lambda : public internal::lambda_core<T_type>
+{
+  typedef lambda<T_type> self;
+
+  lambda()
+    {}
+
+  lambda(typename type_trait<T_type>::take v)
+    : internal::lambda_core<T_type>(v) 
+    {}
+
+  // operators for other<subscript>
+  template <class T_arg>
+  lambda<lambda_operator<other<subscript>, self, typename unwrap_lambda_type<T_arg>::type> >
+  operator [] (const T_arg& a) const
+    { typedef lambda_operator<other<subscript>, self, typename unwrap_lambda_type<T_arg>::type> lambda_operator_type;
+      return lambda<lambda_operator_type>(lambda_operator_type(this->value_, unwrap_lambda_value(a))); }
+
+  // operators for other<assign>
+  template <class T_arg>
+  lambda<lambda_operator<other<assign>, self, typename unwrap_lambda_type<T_arg>::type> >
+  operator = (const T_arg& a) const
+    { typedef lambda_operator<other<assign>, self, typename unwrap_lambda_type<T_arg>::type> lambda_operator_type;
+      return lambda<lambda_operator_type>(lambda_operator_type(this->value_, unwrap_lambda_value(a))); }
+};
+
+
+template <class T_action, class T_type>
+void visit_each(const T_action& _A_action,
+                const lambda<T_type>& _A_target)
+{
+  visit_each(_A_action, _A_target.value_);
+}
+
+
+/// Converts a reference into a lambda object.
+template <class T_type>
+lambda<T_type&> var(T_type& v)
+{ return lambda<T_type&>(v); }
+
+/// Converts a constant reference into a lambda object.
+template <class T_type>
+lambda<const T_type&> var(const T_type& v)
+{ return lambda<const T_type&>(v); }
+
+
+/** Deduces the type of the object stored in an object of the passed lambda type.
+ * If the type passed as template argument is no lambda type,
+ * type is defined to unwrap_reference<T_type>::type.
+ */
+template <class T_type>
+struct unwrap_lambda_type
+{ typedef typename unwrap_reference<T_type>::type type; };
+
+template <class T_type>
+struct unwrap_lambda_type<lambda<T_type> >
+{ typedef T_type type; };
+
+
+/** Gets the object stored inside a lambda object.
+ * Returns the object passed as argument if it is not of type lambda.
+ */
+template <class T_type>
+T_type& unwrap_lambda_value(T_type& a)
+{ return a; }
+
+template <class T_type>
+const T_type& unwrap_lambda_value(const T_type& a)
+{ return a; }
+
+template <class T_type>
+const T_type& unwrap_lambda_value(const lambda<T_type>& a)
+{ return a.value_; }
+
+} /* namespace sigc */
+
+#endif /* _SIGC_LAMBDA_BASE_HPP_ */
diff --git a/libs/sigc++2/sigc++/adaptors/lambda/group.h b/libs/sigc++2/sigc++/adaptors/lambda/group.h
new file mode 100644
index 0000000000..7b7525dc41
--- /dev/null
+++ b/libs/sigc++2/sigc++/adaptors/lambda/group.h
@@ -0,0 +1,734 @@
+// -*- c++ -*-
+/* Do not edit! -- generated file */
+#ifndef _SIGC_ADAPTORS_LAMBDA_MACROS_GROUPHM4_
+#define _SIGC_ADAPTORS_LAMBDA_MACROS_GROUPHM4_
+#include <sigc++/adaptors/lambda/base.h>
+
+/** @defgroup group_ group()
+ * sigc::group() alters an arbitrary functor by rebuilding its arguments from one or more lambda expressions.
+ * For each parameter that should be passed to the wrapped functor one lambda expression
+ * has to be passed into group(). Lambda selectors can be used as placeholders for the
+ * arguments passed into the new functor. Arguments that don't have a placeholder in one
+ * of the lambda expressions are dropped.
+ *
+ * @par Examples:
+ *   @code
+ *   void foo(int, int);
+ *   int bar(int);
+ *   // argument binding ...
+ *   sigc::group(&foo,10,sigc::_1)(20); //fixes the first argument and calls foo(10,20)
+ *   sigc::group(&foo,sigc::_1,30)(40); //fixes the second argument and calls foo(40,30)
+ *   // argument reordering ...
+ *   sigc::group(&foo,sigc::_2,sigc::_1)(1,2); //calls foo(2,1)
+ *   // argument hiding ...
+ *   sigc::group(&foo,sigc::_1,sigc::_2)(1,2,3); //calls foo(1,2)
+ *   // functor composition ...
+ *   sigc::group(&foo,sigc::_1,sigc::group(&bar,sigc::_2))(1,2); //calls foo(1,bar(2))
+ *   // algebraic expressions ...
+ *   sigc::group(&foo,sigc::_1*sigc::_2,sigc::_1/sigc::_2)(6,3); //calls foo(6*3,6/3)
+ *   @endcode
+ *
+ * The functor sigc::group() returns can be passed into
+ * sigc::signal::connect() directly.
+ *
+ * @par Example:
+ *   @code
+ *   sigc::signal<void,int,int> some_signal;
+ *   void foo(int);
+ *   some_signal.connect(sigc::group(&foo,sigc::_2));
+ *   @endcode
+ *
+ * Like in sigc::bind() you can bind references to functors by passing the objects
+ * through the sigc::ref() helper function.
+ *
+ * @par Example:
+ *   @code
+ *   int some_int;
+ *   sigc::signal<void> some_signal;
+ *   void foo(int&);
+ *   some_signal.connect(sigc::group(&foo,sigc::ref(some_int)));
+ *   @endcode
+ *
+ * If you bind an object of a sigc::trackable derived type to a functor
+ * by reference, a slot assigned to the group adaptor is cleared automatically
+ * when the object goes out of scope.
+ *
+ * @par Example:
+ *   @code
+ *   struct bar : public sigc::trackable {} some_bar;
+ *   sigc::signal<void> some_signal;
+ *   void foo(bar&);
+ *   some_signal.connect(sigc::group(&foo,sigc::ref(some_bar)));
+ *     // disconnected automatically if some_bar goes out of scope
+ *   @endcode
+ *
+ * @ingroup adaptors, lambdas
+ */
+
+namespace sigc {
+
+template <class T_functor, class T_type1>
+struct lambda_group1 : public lambda_base
+{
+  typedef typename functor_trait<T_functor>::result_type result_type;
+  typedef typename lambda<T_type1>::lambda_type   value1_type;
+  typedef typename adaptor_trait<T_functor>::adaptor_type functor_type;
+
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef typename functor_type::template deduce_result_type<
+          typename value1_type::template deduce_result_type<
+            typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>::type
+        >::type type; };
+
+  result_type
+  operator ()() const;
+
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  operator() (T_arg1 _A_1) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass>(_A_1)); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  sun_forte_workaround (T_arg1 _A_1) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass>(_A_1)); }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  operator() (T_arg1 _A_1,T_arg2 _A_2) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1,T_arg2>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>(_A_1,_A_2)); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  sun_forte_workaround (T_arg1 _A_1,T_arg2 _A_2) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1,T_arg2>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>(_A_1,_A_2)); }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  operator() (T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1,T_arg2,T_arg3>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>(_A_1,_A_2,_A_3)); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  sun_forte_workaround (T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1,T_arg2,T_arg3>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>(_A_1,_A_2,_A_3)); }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  operator() (T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>(_A_1,_A_2,_A_3,_A_4)); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  sun_forte_workaround (T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>(_A_1,_A_2,_A_3,_A_4)); }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  operator() (T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>(_A_1,_A_2,_A_3,_A_4,_A_5)); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  sun_forte_workaround (T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>(_A_1,_A_2,_A_3,_A_4,_A_5)); }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  operator() (T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>(_A_1,_A_2,_A_3,_A_4,_A_5,_A_6)); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  sun_forte_workaround (T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>(_A_1,_A_2,_A_3,_A_4,_A_5,_A_6)); }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  operator() (T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6,T_arg7 _A_7) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>(_A_1,_A_2,_A_3,_A_4,_A_5,_A_6,_A_7)); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  sun_forte_workaround (T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6,T_arg7 _A_7) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>(_A_1,_A_2,_A_3,_A_4,_A_5,_A_6,_A_7)); }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  lambda_group1(typename type_trait<T_functor>::take _A_func, typename type_trait<T_type1>::take _A_1)
+    : value1_(_A_1), func_(_A_func) {}
+
+  value1_type value1_;
+  mutable functor_type func_;
+};
+
+template <class T_functor, class T_type1>
+typename lambda_group1<T_functor, T_type1>::result_type
+lambda_group1<T_functor, T_type1>::operator ()() const
+  { return func_(value1_()); }
+
+
+template <class T_action, class T_functor, class T_type1>
+void visit_each(const T_action& _A_action,
+                const lambda_group1<T_functor, T_type1>& _A_target)
+{
+  visit_each(_A_action, _A_target.value1_);
+  visit_each(_A_action, _A_target.func_);
+}
+
+
+template <class T_functor, class T_type1,class T_type2>
+struct lambda_group2 : public lambda_base
+{
+  typedef typename functor_trait<T_functor>::result_type result_type;
+  typedef typename lambda<T_type1>::lambda_type   value1_type;
+  typedef typename lambda<T_type2>::lambda_type   value2_type;
+  typedef typename adaptor_trait<T_functor>::adaptor_type functor_type;
+
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef typename functor_type::template deduce_result_type<
+          typename value1_type::template deduce_result_type<
+            typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>::type,
+          typename value2_type::template deduce_result_type<
+            typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>::type
+        >::type type; };
+
+  result_type
+  operator ()() const;
+
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  operator() (T_arg1 _A_1) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1>::type,
+          typename value2_type::template deduce_result_type<T_arg1>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass>(_A_1),
+        this->value2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass>(_A_1)); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  sun_forte_workaround (T_arg1 _A_1) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1>::type,
+          typename value2_type::template deduce_result_type<T_arg1>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass>(_A_1),
+        this->value2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass>(_A_1)); }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  operator() (T_arg1 _A_1,T_arg2 _A_2) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1,T_arg2>::type,
+          typename value2_type::template deduce_result_type<T_arg1,T_arg2>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>(_A_1,_A_2),
+        this->value2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>(_A_1,_A_2)); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  sun_forte_workaround (T_arg1 _A_1,T_arg2 _A_2) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1,T_arg2>::type,
+          typename value2_type::template deduce_result_type<T_arg1,T_arg2>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>(_A_1,_A_2),
+        this->value2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>(_A_1,_A_2)); }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  operator() (T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1,T_arg2,T_arg3>::type,
+          typename value2_type::template deduce_result_type<T_arg1,T_arg2,T_arg3>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>(_A_1,_A_2,_A_3),
+        this->value2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>(_A_1,_A_2,_A_3)); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  sun_forte_workaround (T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1,T_arg2,T_arg3>::type,
+          typename value2_type::template deduce_result_type<T_arg1,T_arg2,T_arg3>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>(_A_1,_A_2,_A_3),
+        this->value2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>(_A_1,_A_2,_A_3)); }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  operator() (T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type,
+          typename value2_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>(_A_1,_A_2,_A_3,_A_4),
+        this->value2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>(_A_1,_A_2,_A_3,_A_4)); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  sun_forte_workaround (T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type,
+          typename value2_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>(_A_1,_A_2,_A_3,_A_4),
+        this->value2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>(_A_1,_A_2,_A_3,_A_4)); }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  operator() (T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type,
+          typename value2_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>(_A_1,_A_2,_A_3,_A_4,_A_5),
+        this->value2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>(_A_1,_A_2,_A_3,_A_4,_A_5)); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  sun_forte_workaround (T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type,
+          typename value2_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>(_A_1,_A_2,_A_3,_A_4,_A_5),
+        this->value2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>(_A_1,_A_2,_A_3,_A_4,_A_5)); }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  operator() (T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type,
+          typename value2_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>(_A_1,_A_2,_A_3,_A_4,_A_5,_A_6),
+        this->value2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>(_A_1,_A_2,_A_3,_A_4,_A_5,_A_6)); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  sun_forte_workaround (T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type,
+          typename value2_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>(_A_1,_A_2,_A_3,_A_4,_A_5,_A_6),
+        this->value2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>(_A_1,_A_2,_A_3,_A_4,_A_5,_A_6)); }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  operator() (T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6,T_arg7 _A_7) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type,
+          typename value2_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>(_A_1,_A_2,_A_3,_A_4,_A_5,_A_6,_A_7),
+        this->value2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>(_A_1,_A_2,_A_3,_A_4,_A_5,_A_6,_A_7)); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  sun_forte_workaround (T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6,T_arg7 _A_7) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type,
+          typename value2_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>(_A_1,_A_2,_A_3,_A_4,_A_5,_A_6,_A_7),
+        this->value2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>(_A_1,_A_2,_A_3,_A_4,_A_5,_A_6,_A_7)); }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  lambda_group2(typename type_trait<T_functor>::take _A_func, typename type_trait<T_type1>::take _A_1,typename type_trait<T_type2>::take _A_2)
+    : value1_(_A_1),value2_(_A_2), func_(_A_func) {}
+
+  value1_type value1_;
+  value2_type value2_;
+  mutable functor_type func_;
+};
+
+template <class T_functor, class T_type1,class T_type2>
+typename lambda_group2<T_functor, T_type1,T_type2>::result_type
+lambda_group2<T_functor, T_type1,T_type2>::operator ()() const
+  { return func_(value1_(),value2_()); }
+
+
+template <class T_action, class T_functor, class T_type1,class T_type2>
+void visit_each(const T_action& _A_action,
+                const lambda_group2<T_functor, T_type1,T_type2>& _A_target)
+{
+  visit_each(_A_action, _A_target.value1_);
+  visit_each(_A_action, _A_target.value2_);
+  visit_each(_A_action, _A_target.func_);
+}
+
+
+template <class T_functor, class T_type1,class T_type2,class T_type3>
+struct lambda_group3 : public lambda_base
+{
+  typedef typename functor_trait<T_functor>::result_type result_type;
+  typedef typename lambda<T_type1>::lambda_type   value1_type;
+  typedef typename lambda<T_type2>::lambda_type   value2_type;
+  typedef typename lambda<T_type3>::lambda_type   value3_type;
+  typedef typename adaptor_trait<T_functor>::adaptor_type functor_type;
+
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef typename functor_type::template deduce_result_type<
+          typename value1_type::template deduce_result_type<
+            typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>::type,
+          typename value2_type::template deduce_result_type<
+            typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>::type,
+          typename value3_type::template deduce_result_type<
+            typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>::type
+        >::type type; };
+
+  result_type
+  operator ()() const;
+
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  operator() (T_arg1 _A_1) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1>::type,
+          typename value2_type::template deduce_result_type<T_arg1>::type,
+          typename value3_type::template deduce_result_type<T_arg1>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass>(_A_1),
+        this->value2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass>(_A_1),
+        this->value3_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass>(_A_1)); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  sun_forte_workaround (T_arg1 _A_1) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1>::type,
+          typename value2_type::template deduce_result_type<T_arg1>::type,
+          typename value3_type::template deduce_result_type<T_arg1>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass>(_A_1),
+        this->value2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass>(_A_1),
+        this->value3_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass>(_A_1)); }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  operator() (T_arg1 _A_1,T_arg2 _A_2) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1,T_arg2>::type,
+          typename value2_type::template deduce_result_type<T_arg1,T_arg2>::type,
+          typename value3_type::template deduce_result_type<T_arg1,T_arg2>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>(_A_1,_A_2),
+        this->value2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>(_A_1,_A_2),
+        this->value3_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>(_A_1,_A_2)); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  sun_forte_workaround (T_arg1 _A_1,T_arg2 _A_2) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1,T_arg2>::type,
+          typename value2_type::template deduce_result_type<T_arg1,T_arg2>::type,
+          typename value3_type::template deduce_result_type<T_arg1,T_arg2>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>(_A_1,_A_2),
+        this->value2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>(_A_1,_A_2),
+        this->value3_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>(_A_1,_A_2)); }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  operator() (T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1,T_arg2,T_arg3>::type,
+          typename value2_type::template deduce_result_type<T_arg1,T_arg2,T_arg3>::type,
+          typename value3_type::template deduce_result_type<T_arg1,T_arg2,T_arg3>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>(_A_1,_A_2,_A_3),
+        this->value2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>(_A_1,_A_2,_A_3),
+        this->value3_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>(_A_1,_A_2,_A_3)); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  sun_forte_workaround (T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1,T_arg2,T_arg3>::type,
+          typename value2_type::template deduce_result_type<T_arg1,T_arg2,T_arg3>::type,
+          typename value3_type::template deduce_result_type<T_arg1,T_arg2,T_arg3>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>(_A_1,_A_2,_A_3),
+        this->value2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>(_A_1,_A_2,_A_3),
+        this->value3_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>(_A_1,_A_2,_A_3)); }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  operator() (T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type,
+          typename value2_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type,
+          typename value3_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>(_A_1,_A_2,_A_3,_A_4),
+        this->value2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>(_A_1,_A_2,_A_3,_A_4),
+        this->value3_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>(_A_1,_A_2,_A_3,_A_4)); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  sun_forte_workaround (T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type,
+          typename value2_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type,
+          typename value3_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>(_A_1,_A_2,_A_3,_A_4),
+        this->value2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>(_A_1,_A_2,_A_3,_A_4),
+        this->value3_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>(_A_1,_A_2,_A_3,_A_4)); }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  operator() (T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type,
+          typename value2_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type,
+          typename value3_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>(_A_1,_A_2,_A_3,_A_4,_A_5),
+        this->value2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>(_A_1,_A_2,_A_3,_A_4,_A_5),
+        this->value3_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>(_A_1,_A_2,_A_3,_A_4,_A_5)); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  sun_forte_workaround (T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type,
+          typename value2_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type,
+          typename value3_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>(_A_1,_A_2,_A_3,_A_4,_A_5),
+        this->value2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>(_A_1,_A_2,_A_3,_A_4,_A_5),
+        this->value3_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>(_A_1,_A_2,_A_3,_A_4,_A_5)); }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  operator() (T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type,
+          typename value2_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type,
+          typename value3_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>(_A_1,_A_2,_A_3,_A_4,_A_5,_A_6),
+        this->value2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>(_A_1,_A_2,_A_3,_A_4,_A_5,_A_6),
+        this->value3_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>(_A_1,_A_2,_A_3,_A_4,_A_5,_A_6)); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  sun_forte_workaround (T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type,
+          typename value2_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type,
+          typename value3_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>(_A_1,_A_2,_A_3,_A_4,_A_5,_A_6),
+        this->value2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>(_A_1,_A_2,_A_3,_A_4,_A_5,_A_6),
+        this->value3_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>(_A_1,_A_2,_A_3,_A_4,_A_5,_A_6)); }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  operator() (T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6,T_arg7 _A_7) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type,
+          typename value2_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type,
+          typename value3_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>(_A_1,_A_2,_A_3,_A_4,_A_5,_A_6,_A_7),
+        this->value2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>(_A_1,_A_2,_A_3,_A_4,_A_5,_A_6,_A_7),
+        this->value3_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>(_A_1,_A_2,_A_3,_A_4,_A_5,_A_6,_A_7)); }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  sun_forte_workaround (T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6,T_arg7 _A_7) const
+    { return this->func_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename value1_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type,
+          typename value2_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type,
+          typename value3_type::template deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type>(
+        this->value1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>(_A_1,_A_2,_A_3,_A_4,_A_5,_A_6,_A_7),
+        this->value2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>(_A_1,_A_2,_A_3,_A_4,_A_5,_A_6,_A_7),
+        this->value3_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<
+          typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>(_A_1,_A_2,_A_3,_A_4,_A_5,_A_6,_A_7)); }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  lambda_group3(typename type_trait<T_functor>::take _A_func, typename type_trait<T_type1>::take _A_1,typename type_trait<T_type2>::take _A_2,typename type_trait<T_type3>::take _A_3)
+    : value1_(_A_1),value2_(_A_2),value3_(_A_3), func_(_A_func) {}
+
+  value1_type value1_;
+  value2_type value2_;
+  value3_type value3_;
+  mutable functor_type func_;
+};
+
+template <class T_functor, class T_type1,class T_type2,class T_type3>
+typename lambda_group3<T_functor, T_type1,T_type2,T_type3>::result_type
+lambda_group3<T_functor, T_type1,T_type2,T_type3>::operator ()() const
+  { return func_(value1_(),value2_(),value3_()); }
+
+
+template <class T_action, class T_functor, class T_type1,class T_type2,class T_type3>
+void visit_each(const T_action& _A_action,
+                const lambda_group3<T_functor, T_type1,T_type2,T_type3>& _A_target)
+{
+  visit_each(_A_action, _A_target.value1_);
+  visit_each(_A_action, _A_target.value2_);
+  visit_each(_A_action, _A_target.value3_);
+  visit_each(_A_action, _A_target.func_);
+}
+
+
+
+template <class T_functor, class T_type1>
+lambda<lambda_group1<T_functor, typename unwrap_reference<T_type1>::type> >
+group(const T_functor& _A_func, T_type1 _A_1)
+{
+  typedef lambda_group1<T_functor, typename unwrap_reference<T_type1>::type> T_lambda;
+  return lambda<T_lambda>(T_lambda(_A_func, _A_1));
+}
+
+template <class T_functor, class T_type1,class T_type2>
+lambda<lambda_group2<T_functor, typename unwrap_reference<T_type1>::type,typename unwrap_reference<T_type2>::type> >
+group(const T_functor& _A_func, T_type1 _A_1,T_type2 _A_2)
+{
+  typedef lambda_group2<T_functor, typename unwrap_reference<T_type1>::type,typename unwrap_reference<T_type2>::type> T_lambda;
+  return lambda<T_lambda>(T_lambda(_A_func, _A_1,_A_2));
+}
+
+template <class T_functor, class T_type1,class T_type2,class T_type3>
+lambda<lambda_group3<T_functor, typename unwrap_reference<T_type1>::type,typename unwrap_reference<T_type2>::type,typename unwrap_reference<T_type3>::type> >
+group(const T_functor& _A_func, T_type1 _A_1,T_type2 _A_2,T_type3 _A_3)
+{
+  typedef lambda_group3<T_functor, typename unwrap_reference<T_type1>::type,typename unwrap_reference<T_type2>::type,typename unwrap_reference<T_type3>::type> T_lambda;
+  return lambda<T_lambda>(T_lambda(_A_func, _A_1,_A_2,_A_3));
+}
+
+
+
+} /* namespace sigc */
+#endif /* _SIGC_ADAPTORS_LAMBDA_MACROS_GROUPHM4_ */
diff --git a/libs/sigc++2/sigc++/adaptors/lambda/lambda.cc b/libs/sigc++2/sigc++/adaptors/lambda/lambda.cc
new file mode 100644
index 0000000000..78fd516df2
--- /dev/null
+++ b/libs/sigc++2/sigc++/adaptors/lambda/lambda.cc
@@ -0,0 +1,15 @@
+// -*- c++ -*-
+/* Do not edit! -- generated file */
+#include <sigc++/adaptors/lambda/select.h>
+
+namespace sigc {
+
+const lambda<internal::lambda_select1> _1;
+const lambda<internal::lambda_select2> _2;
+const lambda<internal::lambda_select3> _3;
+const lambda<internal::lambda_select4> _4;
+const lambda<internal::lambda_select5> _5;
+const lambda<internal::lambda_select6> _6;
+const lambda<internal::lambda_select7> _7;
+
+} /* namespace sigc */
diff --git a/libs/sigc++2/sigc++/adaptors/lambda/lambda.h b/libs/sigc++2/sigc++/adaptors/lambda/lambda.h
new file mode 100644
index 0000000000..487522ad10
--- /dev/null
+++ b/libs/sigc++2/sigc++/adaptors/lambda/lambda.h
@@ -0,0 +1,28 @@
+// -*- c++ -*-
+/*
+ * Copyright 2002, The libsigc++ Development Team
+ *
+ *  This library is free software; you can redistribute it and/or
+ *  modify it under the terms of the GNU Lesser General Public
+ *  License as published by the Free Software Foundation; either
+ *  version 2.1 of the License, or (at your option) any later version.
+ *
+ *  This library is distributed in the hope that it will be useful,
+ *  but WITHOUT ANY WARRANTY; without even the implied warranty of
+ *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
+ *  Lesser General Public License for more details.
+ *
+ *  You should have received a copy of the GNU Lesser General Public
+ *  License along with this library; if not, write to the Free Software
+ *  Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
+ *
+ */
+#ifndef _SIGC_LAMBDA_HPP_
+#define _SIGC_LAMBDA_HPP_
+
+#include <sigc++/adaptors/lambda/base.h>
+#include <sigc++/adaptors/lambda/select.h>
+#include <sigc++/adaptors/lambda/operator.h>
+#include <sigc++/adaptors/lambda/group.h>
+
+#endif /* _SIGC_LAMBDA_HPP_ */
diff --git a/libs/sigc++2/sigc++/adaptors/lambda/operator.h b/libs/sigc++2/sigc++/adaptors/lambda/operator.h
new file mode 100644
index 0000000000..5d9e00bcde
--- /dev/null
+++ b/libs/sigc++2/sigc++/adaptors/lambda/operator.h
@@ -0,0 +1,1697 @@
+// -*- c++ -*-
+/* Do not edit! -- generated file */
+#ifndef _SIGC_LAMBDA_OPERATOR_HPP_
+#define _SIGC_LAMBDA_OPERATOR_HPP_
+#include <sigc++/adaptors/lambda/base.h>
+
+namespace sigc {
+
+/** Deduces the base type of a reference or a pointer.
+ * @ingroup internal
+ */
+template <class T_type>
+struct dereference_trait
+  { typedef void type; };
+
+template <class T_type>
+struct dereference_trait<T_type*>
+  { typedef T_type type; };
+
+template <class T_type>
+struct dereference_trait<const T_type*>
+  { typedef const T_type type; };
+
+template <class T_type>
+struct dereference_trait<T_type*&>
+  { typedef T_type type; };
+
+template <class T_type>
+struct dereference_trait<const T_type*&>
+  { typedef const T_type type; };
+
+template <class T_type>
+struct dereference_trait<T_type* const&>
+  { typedef T_type type; };
+
+template <class T_type>
+struct dereference_trait<const T_type* const&>
+  { typedef const T_type type; };
+
+template <class T_type>
+struct arithmetic {};
+
+template <class T_type>
+struct bitwise {};
+
+template <class T_type>
+struct logical {};
+
+template <class T_type>
+struct relational {};
+
+template <class T_type>
+struct arithmetic_assign {};
+
+template <class T_type>
+struct bitwise_assign {};
+
+template <class T_type>
+struct other {};
+
+template <class T_type>
+struct unary_arithmetic {};
+
+template <class T_type>
+struct unary_bitwise {};
+
+template <class T_type>
+struct unary_logical {};
+
+template <class T_type>
+struct unary_other {};
+
+template <class T_type>
+struct cast_ {};
+
+struct plus {};
+struct minus {};
+struct multiplies {};
+struct divides {};
+struct modulus {};
+struct leftshift {};
+struct rightshift {};
+struct and_ {};
+struct or_ {};
+struct xor_ {};
+struct less {};
+struct greater {};
+struct less_equal {};
+struct greater_equal {};
+struct equal_to {};
+struct not_equal_to {};
+struct subscript {};
+struct assign {};
+struct pre_increment {};
+struct pre_decrement {};
+struct negate {};
+struct not_ {};
+struct address {};
+struct dereference {};
+struct reinterpret_ {};
+struct static_ {};
+struct dynamic_ {};
+
+template <class T_action, class T_test1, class T_test2>
+struct lambda_action_deduce_result_type
+  { typedef typename type_trait<T_test1>::type type; }; // TODO: e.g. T_test1=int, T_test2=double yields int but it should yield double !
+
+template <class T_action, class T_test1, class T_test2>
+struct lambda_action_deduce_result_type<logical<T_action>, T_test1, T_test2>
+  { typedef bool type; };
+
+template <class T_action, class T_test1, class T_test2>
+struct lambda_action_deduce_result_type<relational<T_action>, T_test1, T_test2>
+  { typedef bool type; };
+
+template <class T_action, class T_test1, class T_test2>
+struct lambda_action_deduce_result_type<arithmetic_assign<T_action>, T_test1, T_test2>
+  { typedef T_test1 type; };
+
+template <class T_action, class T_test1, class T_test2>
+struct lambda_action_deduce_result_type<bitwise_assign<T_action>, T_test1, T_test2>
+  { typedef T_test1 type; };
+
+template <class T_test1, class T_test2>
+struct lambda_action_deduce_result_type<other<subscript>, T_test1, T_test2>
+  { typedef typename type_trait<typename dereference_trait<T_test1>::type>::pass type; };
+
+template <class T_action, class T_test>
+struct lambda_action_unary_deduce_result_type
+  { typedef typename type_trait<T_test>::type type; };
+
+template <class T_action, class T_type, class T_test>
+struct lambda_action_convert_deduce_result_type
+  { typedef typename type_trait<T_type>::type type; };
+
+template <class T_action, class T_test>
+struct lambda_action_unary_deduce_result_type<unary_logical<T_action>, T_test>
+  { typedef bool type; };
+
+template <class T_test>
+struct lambda_action_unary_deduce_result_type<unary_other<address>, T_test>
+  { typedef typename type_trait<T_test>::pointer type; };
+
+template <class T_test>
+struct lambda_action_unary_deduce_result_type<unary_other<dereference>, T_test>
+  { typedef typename type_trait<typename dereference_trait<T_test>::type>::pass type; };
+
+
+
+template <class T_action>
+struct lambda_action {};
+
+template <class T_action>
+struct lambda_action_unary {};
+
+template <class T_action, class T_type>
+struct lambda_action_convert {};
+
+template <>
+struct lambda_action<arithmetic<plus> >
+{
+  template <class T_arg1, class T_arg2>
+  static typename lambda_action_deduce_result_type<arithmetic<plus>, T_arg1, T_arg2>::type
+  do_action(T_arg1 _A_1, T_arg2 _A_2)
+    { return _A_1 + _A_2; }
+};
+
+template <>
+struct lambda_action<arithmetic<minus> >
+{
+  template <class T_arg1, class T_arg2>
+  static typename lambda_action_deduce_result_type<arithmetic<minus>, T_arg1, T_arg2>::type
+  do_action(T_arg1 _A_1, T_arg2 _A_2)
+    { return _A_1 - _A_2; }
+};
+
+template <>
+struct lambda_action<arithmetic<multiplies> >
+{
+  template <class T_arg1, class T_arg2>
+  static typename lambda_action_deduce_result_type<arithmetic<multiplies>, T_arg1, T_arg2>::type
+  do_action(T_arg1 _A_1, T_arg2 _A_2)
+    { return _A_1 * _A_2; }
+};
+
+template <>
+struct lambda_action<arithmetic<divides> >
+{
+  template <class T_arg1, class T_arg2>
+  static typename lambda_action_deduce_result_type<arithmetic<divides>, T_arg1, T_arg2>::type
+  do_action(T_arg1 _A_1, T_arg2 _A_2)
+    { return _A_1 / _A_2; }
+};
+
+template <>
+struct lambda_action<arithmetic<modulus> >
+{
+  template <class T_arg1, class T_arg2>
+  static typename lambda_action_deduce_result_type<arithmetic<modulus>, T_arg1, T_arg2>::type
+  do_action(T_arg1 _A_1, T_arg2 _A_2)
+    { return _A_1 % _A_2; }
+};
+
+template <>
+struct lambda_action<bitwise<leftshift> >
+{
+  template <class T_arg1, class T_arg2>
+  static typename lambda_action_deduce_result_type<bitwise<leftshift>, T_arg1, T_arg2>::type
+  do_action(T_arg1 _A_1, T_arg2 _A_2)
+    { return _A_1 << _A_2; }
+};
+
+template <>
+struct lambda_action<bitwise<rightshift> >
+{
+  template <class T_arg1, class T_arg2>
+  static typename lambda_action_deduce_result_type<bitwise<rightshift>, T_arg1, T_arg2>::type
+  do_action(T_arg1 _A_1, T_arg2 _A_2)
+    { return _A_1 >> _A_2; }
+};
+
+template <>
+struct lambda_action<bitwise<and_> >
+{
+  template <class T_arg1, class T_arg2>
+  static typename lambda_action_deduce_result_type<bitwise<and_>, T_arg1, T_arg2>::type
+  do_action(T_arg1 _A_1, T_arg2 _A_2)
+    { return _A_1 & _A_2; }
+};
+
+template <>
+struct lambda_action<bitwise<or_> >
+{
+  template <class T_arg1, class T_arg2>
+  static typename lambda_action_deduce_result_type<bitwise<or_>, T_arg1, T_arg2>::type
+  do_action(T_arg1 _A_1, T_arg2 _A_2)
+    { return _A_1 | _A_2; }
+};
+
+template <>
+struct lambda_action<bitwise<xor_> >
+{
+  template <class T_arg1, class T_arg2>
+  static typename lambda_action_deduce_result_type<bitwise<xor_>, T_arg1, T_arg2>::type
+  do_action(T_arg1 _A_1, T_arg2 _A_2)
+    { return _A_1 ^ _A_2; }
+};
+
+template <>
+struct lambda_action<logical<and_> >
+{
+  template <class T_arg1, class T_arg2>
+  static typename lambda_action_deduce_result_type<logical<and_>, T_arg1, T_arg2>::type
+  do_action(T_arg1 _A_1, T_arg2 _A_2)
+    { return _A_1 && _A_2; }
+};
+
+template <>
+struct lambda_action<logical<or_> >
+{
+  template <class T_arg1, class T_arg2>
+  static typename lambda_action_deduce_result_type<logical<or_>, T_arg1, T_arg2>::type
+  do_action(T_arg1 _A_1, T_arg2 _A_2)
+    { return _A_1 || _A_2; }
+};
+
+template <>
+struct lambda_action<relational<less> >
+{
+  template <class T_arg1, class T_arg2>
+  static typename lambda_action_deduce_result_type<relational<less>, T_arg1, T_arg2>::type
+  do_action(T_arg1 _A_1, T_arg2 _A_2)
+    { return _A_1 < _A_2; }
+};
+
+template <>
+struct lambda_action<relational<greater> >
+{
+  template <class T_arg1, class T_arg2>
+  static typename lambda_action_deduce_result_type<relational<greater>, T_arg1, T_arg2>::type
+  do_action(T_arg1 _A_1, T_arg2 _A_2)
+    { return _A_1 > _A_2; }
+};
+
+template <>
+struct lambda_action<relational<less_equal> >
+{
+  template <class T_arg1, class T_arg2>
+  static typename lambda_action_deduce_result_type<relational<less_equal>, T_arg1, T_arg2>::type
+  do_action(T_arg1 _A_1, T_arg2 _A_2)
+    { return _A_1 <= _A_2; }
+};
+
+template <>
+struct lambda_action<relational<greater_equal> >
+{
+  template <class T_arg1, class T_arg2>
+  static typename lambda_action_deduce_result_type<relational<greater_equal>, T_arg1, T_arg2>::type
+  do_action(T_arg1 _A_1, T_arg2 _A_2)
+    { return _A_1 >= _A_2; }
+};
+
+template <>
+struct lambda_action<relational<equal_to> >
+{
+  template <class T_arg1, class T_arg2>
+  static typename lambda_action_deduce_result_type<relational<equal_to>, T_arg1, T_arg2>::type
+  do_action(T_arg1 _A_1, T_arg2 _A_2)
+    { return _A_1 == _A_2; }
+};
+
+template <>
+struct lambda_action<relational<not_equal_to> >
+{
+  template <class T_arg1, class T_arg2>
+  static typename lambda_action_deduce_result_type<relational<not_equal_to>, T_arg1, T_arg2>::type
+  do_action(T_arg1 _A_1, T_arg2 _A_2)
+    { return _A_1 != _A_2; }
+};
+
+template <>
+struct lambda_action<arithmetic_assign<plus> >
+{
+  template <class T_arg1, class T_arg2>
+  static typename lambda_action_deduce_result_type<arithmetic_assign<plus>, T_arg1, T_arg2>::type
+  do_action(T_arg1 _A_1, T_arg2 _A_2)
+    { return _A_1 += _A_2; }
+};
+
+template <>
+struct lambda_action<arithmetic_assign<minus> >
+{
+  template <class T_arg1, class T_arg2>
+  static typename lambda_action_deduce_result_type<arithmetic_assign<minus>, T_arg1, T_arg2>::type
+  do_action(T_arg1 _A_1, T_arg2 _A_2)
+    { return _A_1 -= _A_2; }
+};
+
+template <>
+struct lambda_action<arithmetic_assign<multiplies> >
+{
+  template <class T_arg1, class T_arg2>
+  static typename lambda_action_deduce_result_type<arithmetic_assign<multiplies>, T_arg1, T_arg2>::type
+  do_action(T_arg1 _A_1, T_arg2 _A_2)
+    { return _A_1 *= _A_2; }
+};
+
+template <>
+struct lambda_action<arithmetic_assign<divides> >
+{
+  template <class T_arg1, class T_arg2>
+  static typename lambda_action_deduce_result_type<arithmetic_assign<divides>, T_arg1, T_arg2>::type
+  do_action(T_arg1 _A_1, T_arg2 _A_2)
+    { return _A_1 /= _A_2; }
+};
+
+template <>
+struct lambda_action<arithmetic_assign<modulus> >
+{
+  template <class T_arg1, class T_arg2>
+  static typename lambda_action_deduce_result_type<arithmetic_assign<modulus>, T_arg1, T_arg2>::type
+  do_action(T_arg1 _A_1, T_arg2 _A_2)
+    { return _A_1 %= _A_2; }
+};
+
+template <>
+struct lambda_action<bitwise_assign<leftshift> >
+{
+  template <class T_arg1, class T_arg2>
+  static typename lambda_action_deduce_result_type<bitwise_assign<leftshift>, T_arg1, T_arg2>::type
+  do_action(T_arg1 _A_1, T_arg2 _A_2)
+    { return _A_1 <<= _A_2; }
+};
+
+template <>
+struct lambda_action<bitwise_assign<rightshift> >
+{
+  template <class T_arg1, class T_arg2>
+  static typename lambda_action_deduce_result_type<bitwise_assign<rightshift>, T_arg1, T_arg2>::type
+  do_action(T_arg1 _A_1, T_arg2 _A_2)
+    { return _A_1 >>= _A_2; }
+};
+
+template <>
+struct lambda_action<bitwise_assign<and_> >
+{
+  template <class T_arg1, class T_arg2>
+  static typename lambda_action_deduce_result_type<bitwise_assign<and_>, T_arg1, T_arg2>::type
+  do_action(T_arg1 _A_1, T_arg2 _A_2)
+    { return _A_1 &= _A_2; }
+};
+
+template <>
+struct lambda_action<bitwise_assign<or_> >
+{
+  template <class T_arg1, class T_arg2>
+  static typename lambda_action_deduce_result_type<bitwise_assign<or_>, T_arg1, T_arg2>::type
+  do_action(T_arg1 _A_1, T_arg2 _A_2)
+    { return _A_1 |= _A_2; }
+};
+
+template <>
+struct lambda_action<bitwise_assign<xor_> >
+{
+  template <class T_arg1, class T_arg2>
+  static typename lambda_action_deduce_result_type<bitwise_assign<xor_>, T_arg1, T_arg2>::type
+  do_action(T_arg1 _A_1, T_arg2 _A_2)
+    { return _A_1 ^= _A_2; }
+};
+
+template <>
+struct lambda_action<other<subscript> >
+{
+  template <class T_arg1, class T_arg2>
+  static typename lambda_action_deduce_result_type<other<subscript>, T_arg1, T_arg2>::type
+  do_action(T_arg1 _A_1, T_arg2 _A_2)
+    { return _A_1[_A_2]; }
+};
+
+template <>
+struct lambda_action<other<assign> >
+{
+  template <class T_arg1, class T_arg2>
+  static typename lambda_action_deduce_result_type<other<assign>, T_arg1, T_arg2>::type
+  do_action(T_arg1 _A_1, T_arg2 _A_2)
+    { return _A_1 = _A_2; }
+};
+
+template <>
+struct lambda_action_unary<unary_arithmetic<pre_increment> >
+{
+  template <class T_arg>
+  static typename lambda_action_unary_deduce_result_type<unary_arithmetic<pre_increment>, T_arg>::type
+  do_action(T_arg _Aa)
+    { return ++_Aa; }
+};
+
+template <>
+struct lambda_action_unary<unary_arithmetic<pre_decrement> >
+{
+  template <class T_arg>
+  static typename lambda_action_unary_deduce_result_type<unary_arithmetic<pre_decrement>, T_arg>::type
+  do_action(T_arg _Aa)
+    { return --_Aa; }
+};
+
+template <>
+struct lambda_action_unary<unary_arithmetic<negate> >
+{
+  template <class T_arg>
+  static typename lambda_action_unary_deduce_result_type<unary_arithmetic<negate>, T_arg>::type
+  do_action(T_arg _Aa)
+    { return -_Aa; }
+};
+
+template <>
+struct lambda_action_unary<unary_bitwise<not_> >
+{
+  template <class T_arg>
+  static typename lambda_action_unary_deduce_result_type<unary_bitwise<not_>, T_arg>::type
+  do_action(T_arg _Aa)
+    { return ~_Aa; }
+};
+
+template <>
+struct lambda_action_unary<unary_logical<not_> >
+{
+  template <class T_arg>
+  static typename lambda_action_unary_deduce_result_type<unary_logical<not_>, T_arg>::type
+  do_action(T_arg _Aa)
+    { return !_Aa; }
+};
+
+template <>
+struct lambda_action_unary<unary_other<address> >
+{
+  template <class T_arg>
+  static typename lambda_action_unary_deduce_result_type<unary_other<address>, T_arg>::type
+  do_action(T_arg _Aa)
+    { return &_Aa; }
+};
+
+template <>
+struct lambda_action_unary<unary_other<dereference> >
+{
+  template <class T_arg>
+  static typename lambda_action_unary_deduce_result_type<unary_other<dereference>, T_arg>::type
+  do_action(T_arg _Aa)
+    { return *_Aa; }
+};
+
+template <class T_type>
+struct lambda_action_convert<cast_<reinterpret_>, T_type>
+{
+  template <class T_arg>
+  static typename lambda_action_convert_deduce_result_type<cast_<reinterpret_>, T_type, T_arg>::type
+  do_action(T_arg _Aa)
+    { return reinterpret_cast<T_type>(_Aa); }
+};
+
+template <class T_type>
+struct lambda_action_convert<cast_<static_>, T_type>
+{
+  template <class T_arg>
+  static typename lambda_action_convert_deduce_result_type<cast_<static_>, T_type, T_arg>::type
+  do_action(T_arg _Aa)
+    { return static_cast<T_type>(_Aa); }
+};
+
+template <class T_type>
+struct lambda_action_convert<cast_<dynamic_>, T_type>
+{
+  template <class T_arg>
+  static typename lambda_action_convert_deduce_result_type<cast_<dynamic_>, T_type, T_arg>::type
+  do_action(T_arg _Aa)
+    { return dynamic_cast<T_type>(_Aa); }
+};
+
+
+
+template <class T_action, class T_type1, class T_type2>
+struct lambda_operator : public lambda_base
+{
+  typedef typename lambda<T_type1>::lambda_type arg1_type;
+  typedef typename lambda<T_type2>::lambda_type arg2_type;
+
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef typename arg1_type::template deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>::type left_type;
+      typedef typename arg2_type::template deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>::type right_type;
+      typedef typename lambda_action_deduce_result_type<T_action, left_type, right_type>::type type;
+    };
+  typedef typename lambda_action_deduce_result_type<
+      T_action,
+      typename arg1_type::result_type,
+      typename arg2_type::result_type
+    >::type result_type;
+
+  result_type
+  operator ()() const;
+
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  operator ()(T_arg1 _A_1) const
+    {
+      return lambda_action<T_action>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass>::left_type,
+            typename deduce_result_type<typename type_trait<T_arg1>::pass>::right_type>
+        (arg1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass>
+            (_A_1),
+         arg2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass>
+            (_A_1));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  sun_forte_workaround(T_arg1 _A_1) const
+    {
+      return lambda_action<T_action>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass>::left_type,
+            typename deduce_result_type<typename type_trait<T_arg1>::pass>::right_type>
+        (arg1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass>
+            (_A_1),
+         arg2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass>
+            (_A_1));
+    }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  operator ()(T_arg1 _A_1,T_arg2 _A_2) const
+    {
+      return lambda_action<T_action>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>::left_type,
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>::right_type>
+        (arg1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>
+            (_A_1,_A_2),
+         arg2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>
+            (_A_1,_A_2));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2) const
+    {
+      return lambda_action<T_action>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>::left_type,
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>::right_type>
+        (arg1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>
+            (_A_1,_A_2),
+         arg2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>
+            (_A_1,_A_2));
+    }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3) const
+    {
+      return lambda_action<T_action>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>::left_type,
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>::right_type>
+        (arg1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>
+            (_A_1,_A_2,_A_3),
+         arg2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>
+            (_A_1,_A_2,_A_3));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3) const
+    {
+      return lambda_action<T_action>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>::left_type,
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>::right_type>
+        (arg1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>
+            (_A_1,_A_2,_A_3),
+         arg2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>
+            (_A_1,_A_2,_A_3));
+    }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4) const
+    {
+      return lambda_action<T_action>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>::left_type,
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>::right_type>
+        (arg1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>
+            (_A_1,_A_2,_A_3,_A_4),
+         arg2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>
+            (_A_1,_A_2,_A_3,_A_4));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4) const
+    {
+      return lambda_action<T_action>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>::left_type,
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>::right_type>
+        (arg1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>
+            (_A_1,_A_2,_A_3,_A_4),
+         arg2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>
+            (_A_1,_A_2,_A_3,_A_4));
+    }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5) const
+    {
+      return lambda_action<T_action>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>::left_type,
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>::right_type>
+        (arg1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>
+            (_A_1,_A_2,_A_3,_A_4,_A_5),
+         arg2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>
+            (_A_1,_A_2,_A_3,_A_4,_A_5));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5) const
+    {
+      return lambda_action<T_action>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>::left_type,
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>::right_type>
+        (arg1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>
+            (_A_1,_A_2,_A_3,_A_4,_A_5),
+         arg2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>
+            (_A_1,_A_2,_A_3,_A_4,_A_5));
+    }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6) const
+    {
+      return lambda_action<T_action>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>::left_type,
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>::right_type>
+        (arg1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>
+            (_A_1,_A_2,_A_3,_A_4,_A_5,_A_6),
+         arg2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>
+            (_A_1,_A_2,_A_3,_A_4,_A_5,_A_6));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6) const
+    {
+      return lambda_action<T_action>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>::left_type,
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>::right_type>
+        (arg1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>
+            (_A_1,_A_2,_A_3,_A_4,_A_5,_A_6),
+         arg2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>
+            (_A_1,_A_2,_A_3,_A_4,_A_5,_A_6));
+    }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6,T_arg7 _A_7) const
+    {
+      return lambda_action<T_action>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>::left_type,
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>::right_type>
+        (arg1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>
+            (_A_1,_A_2,_A_3,_A_4,_A_5,_A_6,_A_7),
+         arg2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>
+            (_A_1,_A_2,_A_3,_A_4,_A_5,_A_6,_A_7));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6,T_arg7 _A_7) const
+    {
+      return lambda_action<T_action>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>::left_type,
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>::right_type>
+        (arg1_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>
+            (_A_1,_A_2,_A_3,_A_4,_A_5,_A_6,_A_7),
+         arg2_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>
+            (_A_1,_A_2,_A_3,_A_4,_A_5,_A_6,_A_7));
+    }
+  #endif //SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+  lambda_operator(typename type_trait<T_type1>::take a1, typename type_trait<T_type2>::take a2 )
+    : arg1_(a1), arg2_(a2) {}
+
+  arg1_type arg1_;
+  arg2_type arg2_;
+};
+
+template <class T_action, class T_type1, class T_type2>
+typename lambda_operator<T_action, T_type1, T_type2>::result_type
+lambda_operator<T_action, T_type1, T_type2>::operator ()() const
+  { return lambda_action<T_action>::template do_action<
+      typename arg1_type::result_type,
+      typename arg2_type::result_type>
+      (arg1_(), arg2_()); }
+
+template <class T_action, class T_lambda_action, class T_arg1, class T_arg2>
+void visit_each(const T_action& _A_action,
+                const lambda_operator<T_lambda_action, T_arg1, T_arg2>& _A_target)
+{
+  visit_each(_A_action, _A_target.arg1_);
+  visit_each(_A_action, _A_target.arg2_);
+}
+
+
+template <class T_action, class T_type>
+struct lambda_operator_unary : public lambda_base
+{
+  typedef typename lambda<T_type>::lambda_type arg_type;
+
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef typename arg_type::template deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>::type operand_type;
+      typedef typename lambda_action_unary_deduce_result_type<T_action, operand_type>::type type;
+    };
+  typedef typename lambda_action_unary_deduce_result_type<
+      T_action,
+      typename arg_type::result_type
+    >::type result_type;
+
+  result_type
+  operator ()() const;
+
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  operator ()(T_arg1 _A_1) const
+    {
+      return lambda_action_unary<T_action>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass>::operand_type>
+        (arg_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass>
+            (_A_1));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  sun_forte_workaround(T_arg1 _A_1) const
+    {
+      return lambda_action_unary<T_action>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass>::operand_type>
+        (arg_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass>
+            (_A_1));
+    }
+  #endif
+
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  operator ()(T_arg1 _A_1,T_arg2 _A_2) const
+    {
+      return lambda_action_unary<T_action>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>::operand_type>
+        (arg_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>
+            (_A_1,_A_2));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2) const
+    {
+      return lambda_action_unary<T_action>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>::operand_type>
+        (arg_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>
+            (_A_1,_A_2));
+    }
+  #endif
+
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3) const
+    {
+      return lambda_action_unary<T_action>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>::operand_type>
+        (arg_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>
+            (_A_1,_A_2,_A_3));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3) const
+    {
+      return lambda_action_unary<T_action>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>::operand_type>
+        (arg_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>
+            (_A_1,_A_2,_A_3));
+    }
+  #endif
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4) const
+    {
+      return lambda_action_unary<T_action>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>::operand_type>
+        (arg_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>
+            (_A_1,_A_2,_A_3,_A_4));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4) const
+    {
+      return lambda_action_unary<T_action>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>::operand_type>
+        (arg_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>
+            (_A_1,_A_2,_A_3,_A_4));
+    }
+  #endif
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5) const
+    {
+      return lambda_action_unary<T_action>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>::operand_type>
+        (arg_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>
+            (_A_1,_A_2,_A_3,_A_4,_A_5));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5) const
+    {
+      return lambda_action_unary<T_action>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>::operand_type>
+        (arg_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>
+            (_A_1,_A_2,_A_3,_A_4,_A_5));
+    }
+  #endif
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6) const
+    {
+      return lambda_action_unary<T_action>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>::operand_type>
+        (arg_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>
+            (_A_1,_A_2,_A_3,_A_4,_A_5,_A_6));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6) const
+    {
+      return lambda_action_unary<T_action>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>::operand_type>
+        (arg_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>
+            (_A_1,_A_2,_A_3,_A_4,_A_5,_A_6));
+    }
+  #endif
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6,T_arg7 _A_7) const
+    {
+      return lambda_action_unary<T_action>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>::operand_type>
+        (arg_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>
+            (_A_1,_A_2,_A_3,_A_4,_A_5,_A_6,_A_7));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6,T_arg7 _A_7) const
+    {
+      return lambda_action_unary<T_action>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>::operand_type>
+        (arg_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>
+            (_A_1,_A_2,_A_3,_A_4,_A_5,_A_6,_A_7));
+    }
+  #endif
+
+  lambda_operator_unary(typename type_trait<T_type>::take a)
+    : arg_(a) {}
+
+  arg_type arg_;
+};
+
+template <class T_action, class T_type>
+typename lambda_operator_unary<T_action, T_type>::result_type
+lambda_operator_unary<T_action, T_type>::operator ()() const
+  { return lambda_action_unary<T_action>::template do_action<
+      typename arg_type::result_type>
+      (arg_()); }
+
+template <class T_action, class T_lambda_action, class T_arg>
+void visit_each(const T_action& _A_action,
+                const lambda_operator_unary<T_lambda_action, T_arg>& _A_target)
+{
+  visit_each(_A_action, _A_target.arg_);
+}
+
+
+template <class T_action, class T_type, class T_arg>
+struct lambda_operator_convert : public lambda_base
+{
+  typedef typename lambda<T_arg>::lambda_type arg_type;
+
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef typename arg_type::template deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>::type operand_type;
+      typedef typename lambda_action_convert_deduce_result_type<T_action, T_type, operand_type>::type type;
+    };
+  typedef typename lambda_action_convert_deduce_result_type<
+      T_action, T_type,
+      typename arg_type::result_type
+    >::type result_type;
+
+  result_type
+  operator ()() const;
+
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  operator ()(T_arg1 _A_1) const
+    {
+      return lambda_action_convert<T_action, T_type>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass>::operand_type>
+        (arg_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass>
+            (_A_1));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  sun_forte_workaround(T_arg1 _A_1) const
+    {
+      return lambda_action_convert<T_action, T_type>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass>::operand_type>
+        (arg_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass>
+            (_A_1));
+    }
+  #endif
+
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  operator ()(T_arg1 _A_1,T_arg2 _A_2) const
+    {
+      return lambda_action_convert<T_action, T_type>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>::operand_type>
+        (arg_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>
+            (_A_1,_A_2));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2) const
+    {
+      return lambda_action_convert<T_action, T_type>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>::operand_type>
+        (arg_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>
+            (_A_1,_A_2));
+    }
+  #endif
+
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3) const
+    {
+      return lambda_action_convert<T_action, T_type>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>::operand_type>
+        (arg_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>
+            (_A_1,_A_2,_A_3));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3) const
+    {
+      return lambda_action_convert<T_action, T_type>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>::operand_type>
+        (arg_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>
+            (_A_1,_A_2,_A_3));
+    }
+  #endif
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4) const
+    {
+      return lambda_action_convert<T_action, T_type>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>::operand_type>
+        (arg_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>
+            (_A_1,_A_2,_A_3,_A_4));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4) const
+    {
+      return lambda_action_convert<T_action, T_type>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>::operand_type>
+        (arg_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>
+            (_A_1,_A_2,_A_3,_A_4));
+    }
+  #endif
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5) const
+    {
+      return lambda_action_convert<T_action, T_type>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>::operand_type>
+        (arg_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>
+            (_A_1,_A_2,_A_3,_A_4,_A_5));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5) const
+    {
+      return lambda_action_convert<T_action, T_type>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>::operand_type>
+        (arg_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>
+            (_A_1,_A_2,_A_3,_A_4,_A_5));
+    }
+  #endif
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6) const
+    {
+      return lambda_action_convert<T_action, T_type>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>::operand_type>
+        (arg_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>
+            (_A_1,_A_2,_A_3,_A_4,_A_5,_A_6));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6) const
+    {
+      return lambda_action_convert<T_action, T_type>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>::operand_type>
+        (arg_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>
+            (_A_1,_A_2,_A_3,_A_4,_A_5,_A_6));
+    }
+  #endif
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6,T_arg7 _A_7) const
+    {
+      return lambda_action_convert<T_action, T_type>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>::operand_type>
+        (arg_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>
+            (_A_1,_A_2,_A_3,_A_4,_A_5,_A_6,_A_7));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6,T_arg7 _A_7) const
+    {
+      return lambda_action_convert<T_action, T_type>::template do_action<
+            typename deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>::operand_type>
+        (arg_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>
+            (_A_1,_A_2,_A_3,_A_4,_A_5,_A_6,_A_7));
+    }
+  #endif
+
+  lambda_operator_convert(typename type_trait<T_arg>::take a)
+    : arg_(a) {}
+
+  arg_type arg_;
+};
+
+template <class T_action, class T_type, class T_arg>
+typename lambda_operator_convert<T_action, T_type, T_arg>::result_type
+lambda_operator_convert<T_action, T_type, T_arg>::operator ()() const
+  { return lambda_action_convert<T_action, T_type>::template do_action<
+      typename arg_type::result_type>
+      (arg_()); }
+
+template <class T_action, class T_lambda_action, class T_type, class T_arg>
+void visit_each(const T_action& _A_action,
+                const lambda_operator_convert<T_lambda_action, T_type, T_arg>& _A_target)
+{
+  visit_each(_A_action, _A_target.arg_);
+}
+
+
+// Operators for lambda action arithmetic<plus>. At least one of the arguments needs to be of type lamdba, hence the overloads.
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<arithmetic<plus>, T_arg1, T_arg2> >
+operator + (const lambda<T_arg1>& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<arithmetic<plus>, T_arg1, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2.value_)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<arithmetic<plus>, T_arg1, typename unwrap_reference<T_arg2>::type> >
+operator + (const lambda<T_arg1>& a1, const T_arg2& a2)
+{ typedef lambda_operator<arithmetic<plus>, T_arg1, typename unwrap_reference<T_arg2>::type> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<arithmetic<plus>, typename unwrap_reference<T_arg1>::type, T_arg2> >
+operator + (const T_arg1& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<arithmetic<plus>, typename unwrap_reference<T_arg1>::type, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1,a2.value_)); }
+
+// Operators for lambda action arithmetic<minus>. At least one of the arguments needs to be of type lamdba, hence the overloads.
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<arithmetic<minus>, T_arg1, T_arg2> >
+operator - (const lambda<T_arg1>& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<arithmetic<minus>, T_arg1, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2.value_)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<arithmetic<minus>, T_arg1, typename unwrap_reference<T_arg2>::type> >
+operator - (const lambda<T_arg1>& a1, const T_arg2& a2)
+{ typedef lambda_operator<arithmetic<minus>, T_arg1, typename unwrap_reference<T_arg2>::type> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<arithmetic<minus>, typename unwrap_reference<T_arg1>::type, T_arg2> >
+operator - (const T_arg1& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<arithmetic<minus>, typename unwrap_reference<T_arg1>::type, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1,a2.value_)); }
+
+// Operators for lambda action arithmetic<multiplies>. At least one of the arguments needs to be of type lamdba, hence the overloads.
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<arithmetic<multiplies>, T_arg1, T_arg2> >
+operator * (const lambda<T_arg1>& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<arithmetic<multiplies>, T_arg1, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2.value_)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<arithmetic<multiplies>, T_arg1, typename unwrap_reference<T_arg2>::type> >
+operator * (const lambda<T_arg1>& a1, const T_arg2& a2)
+{ typedef lambda_operator<arithmetic<multiplies>, T_arg1, typename unwrap_reference<T_arg2>::type> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<arithmetic<multiplies>, typename unwrap_reference<T_arg1>::type, T_arg2> >
+operator * (const T_arg1& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<arithmetic<multiplies>, typename unwrap_reference<T_arg1>::type, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1,a2.value_)); }
+
+// Operators for lambda action arithmetic<divides>. At least one of the arguments needs to be of type lamdba, hence the overloads.
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<arithmetic<divides>, T_arg1, T_arg2> >
+operator / (const lambda<T_arg1>& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<arithmetic<divides>, T_arg1, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2.value_)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<arithmetic<divides>, T_arg1, typename unwrap_reference<T_arg2>::type> >
+operator / (const lambda<T_arg1>& a1, const T_arg2& a2)
+{ typedef lambda_operator<arithmetic<divides>, T_arg1, typename unwrap_reference<T_arg2>::type> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<arithmetic<divides>, typename unwrap_reference<T_arg1>::type, T_arg2> >
+operator / (const T_arg1& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<arithmetic<divides>, typename unwrap_reference<T_arg1>::type, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1,a2.value_)); }
+
+// Operators for lambda action arithmetic<modulus>. At least one of the arguments needs to be of type lamdba, hence the overloads.
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<arithmetic<modulus>, T_arg1, T_arg2> >
+operator % (const lambda<T_arg1>& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<arithmetic<modulus>, T_arg1, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2.value_)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<arithmetic<modulus>, T_arg1, typename unwrap_reference<T_arg2>::type> >
+operator % (const lambda<T_arg1>& a1, const T_arg2& a2)
+{ typedef lambda_operator<arithmetic<modulus>, T_arg1, typename unwrap_reference<T_arg2>::type> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<arithmetic<modulus>, typename unwrap_reference<T_arg1>::type, T_arg2> >
+operator % (const T_arg1& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<arithmetic<modulus>, typename unwrap_reference<T_arg1>::type, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1,a2.value_)); }
+
+// Operators for lambda action bitwise<leftshift>. At least one of the arguments needs to be of type lamdba, hence the overloads.
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<bitwise<leftshift>, T_arg1, T_arg2> >
+operator << (const lambda<T_arg1>& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<bitwise<leftshift>, T_arg1, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2.value_)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<bitwise<leftshift>, T_arg1, typename unwrap_reference<T_arg2>::type> >
+operator << (const lambda<T_arg1>& a1, const T_arg2& a2)
+{ typedef lambda_operator<bitwise<leftshift>, T_arg1, typename unwrap_reference<T_arg2>::type> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<bitwise<leftshift>, typename unwrap_reference<T_arg1>::type, T_arg2> >
+operator << (const T_arg1& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<bitwise<leftshift>, typename unwrap_reference<T_arg1>::type, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1,a2.value_)); }
+
+// Operators for lambda action bitwise<rightshift>. At least one of the arguments needs to be of type lamdba, hence the overloads.
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<bitwise<rightshift>, T_arg1, T_arg2> >
+operator >> (const lambda<T_arg1>& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<bitwise<rightshift>, T_arg1, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2.value_)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<bitwise<rightshift>, T_arg1, typename unwrap_reference<T_arg2>::type> >
+operator >> (const lambda<T_arg1>& a1, const T_arg2& a2)
+{ typedef lambda_operator<bitwise<rightshift>, T_arg1, typename unwrap_reference<T_arg2>::type> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<bitwise<rightshift>, typename unwrap_reference<T_arg1>::type, T_arg2> >
+operator >> (const T_arg1& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<bitwise<rightshift>, typename unwrap_reference<T_arg1>::type, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1,a2.value_)); }
+
+// Operators for lambda action bitwise<and_>. At least one of the arguments needs to be of type lamdba, hence the overloads.
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<bitwise<and_>, T_arg1, T_arg2> >
+operator & (const lambda<T_arg1>& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<bitwise<and_>, T_arg1, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2.value_)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<bitwise<and_>, T_arg1, typename unwrap_reference<T_arg2>::type> >
+operator & (const lambda<T_arg1>& a1, const T_arg2& a2)
+{ typedef lambda_operator<bitwise<and_>, T_arg1, typename unwrap_reference<T_arg2>::type> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<bitwise<and_>, typename unwrap_reference<T_arg1>::type, T_arg2> >
+operator & (const T_arg1& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<bitwise<and_>, typename unwrap_reference<T_arg1>::type, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1,a2.value_)); }
+
+// Operators for lambda action bitwise<or_>. At least one of the arguments needs to be of type lamdba, hence the overloads.
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<bitwise<or_>, T_arg1, T_arg2> >
+operator | (const lambda<T_arg1>& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<bitwise<or_>, T_arg1, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2.value_)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<bitwise<or_>, T_arg1, typename unwrap_reference<T_arg2>::type> >
+operator | (const lambda<T_arg1>& a1, const T_arg2& a2)
+{ typedef lambda_operator<bitwise<or_>, T_arg1, typename unwrap_reference<T_arg2>::type> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<bitwise<or_>, typename unwrap_reference<T_arg1>::type, T_arg2> >
+operator | (const T_arg1& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<bitwise<or_>, typename unwrap_reference<T_arg1>::type, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1,a2.value_)); }
+
+// Operators for lambda action bitwise<xor_>. At least one of the arguments needs to be of type lamdba, hence the overloads.
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<bitwise<xor_>, T_arg1, T_arg2> >
+operator ^ (const lambda<T_arg1>& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<bitwise<xor_>, T_arg1, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2.value_)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<bitwise<xor_>, T_arg1, typename unwrap_reference<T_arg2>::type> >
+operator ^ (const lambda<T_arg1>& a1, const T_arg2& a2)
+{ typedef lambda_operator<bitwise<xor_>, T_arg1, typename unwrap_reference<T_arg2>::type> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<bitwise<xor_>, typename unwrap_reference<T_arg1>::type, T_arg2> >
+operator ^ (const T_arg1& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<bitwise<xor_>, typename unwrap_reference<T_arg1>::type, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1,a2.value_)); }
+
+// Operators for lambda action logical<and_>. At least one of the arguments needs to be of type lamdba, hence the overloads.
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<logical<and_>, T_arg1, T_arg2> >
+operator && (const lambda<T_arg1>& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<logical<and_>, T_arg1, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2.value_)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<logical<and_>, T_arg1, typename unwrap_reference<T_arg2>::type> >
+operator && (const lambda<T_arg1>& a1, const T_arg2& a2)
+{ typedef lambda_operator<logical<and_>, T_arg1, typename unwrap_reference<T_arg2>::type> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<logical<and_>, typename unwrap_reference<T_arg1>::type, T_arg2> >
+operator && (const T_arg1& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<logical<and_>, typename unwrap_reference<T_arg1>::type, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1,a2.value_)); }
+
+// Operators for lambda action logical<or_>. At least one of the arguments needs to be of type lamdba, hence the overloads.
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<logical<or_>, T_arg1, T_arg2> >
+operator || (const lambda<T_arg1>& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<logical<or_>, T_arg1, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2.value_)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<logical<or_>, T_arg1, typename unwrap_reference<T_arg2>::type> >
+operator || (const lambda<T_arg1>& a1, const T_arg2& a2)
+{ typedef lambda_operator<logical<or_>, T_arg1, typename unwrap_reference<T_arg2>::type> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<logical<or_>, typename unwrap_reference<T_arg1>::type, T_arg2> >
+operator || (const T_arg1& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<logical<or_>, typename unwrap_reference<T_arg1>::type, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1,a2.value_)); }
+
+// Operators for lambda action relational<less>. At least one of the arguments needs to be of type lamdba, hence the overloads.
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<relational<less>, T_arg1, T_arg2> >
+operator < (const lambda<T_arg1>& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<relational<less>, T_arg1, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2.value_)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<relational<less>, T_arg1, typename unwrap_reference<T_arg2>::type> >
+operator < (const lambda<T_arg1>& a1, const T_arg2& a2)
+{ typedef lambda_operator<relational<less>, T_arg1, typename unwrap_reference<T_arg2>::type> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<relational<less>, typename unwrap_reference<T_arg1>::type, T_arg2> >
+operator < (const T_arg1& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<relational<less>, typename unwrap_reference<T_arg1>::type, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1,a2.value_)); }
+
+// Operators for lambda action relational<greater>. At least one of the arguments needs to be of type lamdba, hence the overloads.
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<relational<greater>, T_arg1, T_arg2> >
+operator > (const lambda<T_arg1>& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<relational<greater>, T_arg1, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2.value_)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<relational<greater>, T_arg1, typename unwrap_reference<T_arg2>::type> >
+operator > (const lambda<T_arg1>& a1, const T_arg2& a2)
+{ typedef lambda_operator<relational<greater>, T_arg1, typename unwrap_reference<T_arg2>::type> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<relational<greater>, typename unwrap_reference<T_arg1>::type, T_arg2> >
+operator > (const T_arg1& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<relational<greater>, typename unwrap_reference<T_arg1>::type, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1,a2.value_)); }
+
+// Operators for lambda action relational<less_equal>. At least one of the arguments needs to be of type lamdba, hence the overloads.
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<relational<less_equal>, T_arg1, T_arg2> >
+operator <= (const lambda<T_arg1>& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<relational<less_equal>, T_arg1, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2.value_)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<relational<less_equal>, T_arg1, typename unwrap_reference<T_arg2>::type> >
+operator <= (const lambda<T_arg1>& a1, const T_arg2& a2)
+{ typedef lambda_operator<relational<less_equal>, T_arg1, typename unwrap_reference<T_arg2>::type> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<relational<less_equal>, typename unwrap_reference<T_arg1>::type, T_arg2> >
+operator <= (const T_arg1& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<relational<less_equal>, typename unwrap_reference<T_arg1>::type, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1,a2.value_)); }
+
+// Operators for lambda action relational<greater_equal>. At least one of the arguments needs to be of type lamdba, hence the overloads.
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<relational<greater_equal>, T_arg1, T_arg2> >
+operator >= (const lambda<T_arg1>& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<relational<greater_equal>, T_arg1, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2.value_)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<relational<greater_equal>, T_arg1, typename unwrap_reference<T_arg2>::type> >
+operator >= (const lambda<T_arg1>& a1, const T_arg2& a2)
+{ typedef lambda_operator<relational<greater_equal>, T_arg1, typename unwrap_reference<T_arg2>::type> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<relational<greater_equal>, typename unwrap_reference<T_arg1>::type, T_arg2> >
+operator >= (const T_arg1& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<relational<greater_equal>, typename unwrap_reference<T_arg1>::type, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1,a2.value_)); }
+
+// Operators for lambda action relational<equal_to>. At least one of the arguments needs to be of type lamdba, hence the overloads.
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<relational<equal_to>, T_arg1, T_arg2> >
+operator == (const lambda<T_arg1>& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<relational<equal_to>, T_arg1, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2.value_)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<relational<equal_to>, T_arg1, typename unwrap_reference<T_arg2>::type> >
+operator == (const lambda<T_arg1>& a1, const T_arg2& a2)
+{ typedef lambda_operator<relational<equal_to>, T_arg1, typename unwrap_reference<T_arg2>::type> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<relational<equal_to>, typename unwrap_reference<T_arg1>::type, T_arg2> >
+operator == (const T_arg1& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<relational<equal_to>, typename unwrap_reference<T_arg1>::type, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1,a2.value_)); }
+
+// Operators for lambda action relational<not_equal_to>. At least one of the arguments needs to be of type lamdba, hence the overloads.
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<relational<not_equal_to>, T_arg1, T_arg2> >
+operator != (const lambda<T_arg1>& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<relational<not_equal_to>, T_arg1, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2.value_)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<relational<not_equal_to>, T_arg1, typename unwrap_reference<T_arg2>::type> >
+operator != (const lambda<T_arg1>& a1, const T_arg2& a2)
+{ typedef lambda_operator<relational<not_equal_to>, T_arg1, typename unwrap_reference<T_arg2>::type> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<relational<not_equal_to>, typename unwrap_reference<T_arg1>::type, T_arg2> >
+operator != (const T_arg1& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<relational<not_equal_to>, typename unwrap_reference<T_arg1>::type, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1,a2.value_)); }
+
+// Operators for lambda action arithmetic_assign<plus>. At least one of the arguments needs to be of type lamdba, hence the overloads.
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<arithmetic_assign<plus>, T_arg1, T_arg2> >
+operator += (const lambda<T_arg1>& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<arithmetic_assign<plus>, T_arg1, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2.value_)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<arithmetic_assign<plus>, T_arg1, typename unwrap_reference<T_arg2>::type> >
+operator += (const lambda<T_arg1>& a1, const T_arg2& a2)
+{ typedef lambda_operator<arithmetic_assign<plus>, T_arg1, typename unwrap_reference<T_arg2>::type> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<arithmetic_assign<plus>, typename unwrap_reference<T_arg1>::type, T_arg2> >
+operator += (const T_arg1& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<arithmetic_assign<plus>, typename unwrap_reference<T_arg1>::type, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1,a2.value_)); }
+
+// Operators for lambda action arithmetic_assign<minus>. At least one of the arguments needs to be of type lamdba, hence the overloads.
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<arithmetic_assign<minus>, T_arg1, T_arg2> >
+operator -= (const lambda<T_arg1>& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<arithmetic_assign<minus>, T_arg1, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2.value_)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<arithmetic_assign<minus>, T_arg1, typename unwrap_reference<T_arg2>::type> >
+operator -= (const lambda<T_arg1>& a1, const T_arg2& a2)
+{ typedef lambda_operator<arithmetic_assign<minus>, T_arg1, typename unwrap_reference<T_arg2>::type> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<arithmetic_assign<minus>, typename unwrap_reference<T_arg1>::type, T_arg2> >
+operator -= (const T_arg1& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<arithmetic_assign<minus>, typename unwrap_reference<T_arg1>::type, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1,a2.value_)); }
+
+// Operators for lambda action arithmetic_assign<multiplies>. At least one of the arguments needs to be of type lamdba, hence the overloads.
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<arithmetic_assign<multiplies>, T_arg1, T_arg2> >
+operator *= (const lambda<T_arg1>& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<arithmetic_assign<multiplies>, T_arg1, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2.value_)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<arithmetic_assign<multiplies>, T_arg1, typename unwrap_reference<T_arg2>::type> >
+operator *= (const lambda<T_arg1>& a1, const T_arg2& a2)
+{ typedef lambda_operator<arithmetic_assign<multiplies>, T_arg1, typename unwrap_reference<T_arg2>::type> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<arithmetic_assign<multiplies>, typename unwrap_reference<T_arg1>::type, T_arg2> >
+operator *= (const T_arg1& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<arithmetic_assign<multiplies>, typename unwrap_reference<T_arg1>::type, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1,a2.value_)); }
+
+// Operators for lambda action arithmetic_assign<divides>. At least one of the arguments needs to be of type lamdba, hence the overloads.
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<arithmetic_assign<divides>, T_arg1, T_arg2> >
+operator /= (const lambda<T_arg1>& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<arithmetic_assign<divides>, T_arg1, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2.value_)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<arithmetic_assign<divides>, T_arg1, typename unwrap_reference<T_arg2>::type> >
+operator /= (const lambda<T_arg1>& a1, const T_arg2& a2)
+{ typedef lambda_operator<arithmetic_assign<divides>, T_arg1, typename unwrap_reference<T_arg2>::type> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<arithmetic_assign<divides>, typename unwrap_reference<T_arg1>::type, T_arg2> >
+operator /= (const T_arg1& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<arithmetic_assign<divides>, typename unwrap_reference<T_arg1>::type, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1,a2.value_)); }
+
+// Operators for lambda action arithmetic_assign<modulus>. At least one of the arguments needs to be of type lamdba, hence the overloads.
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<arithmetic_assign<modulus>, T_arg1, T_arg2> >
+operator %= (const lambda<T_arg1>& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<arithmetic_assign<modulus>, T_arg1, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2.value_)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<arithmetic_assign<modulus>, T_arg1, typename unwrap_reference<T_arg2>::type> >
+operator %= (const lambda<T_arg1>& a1, const T_arg2& a2)
+{ typedef lambda_operator<arithmetic_assign<modulus>, T_arg1, typename unwrap_reference<T_arg2>::type> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<arithmetic_assign<modulus>, typename unwrap_reference<T_arg1>::type, T_arg2> >
+operator %= (const T_arg1& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<arithmetic_assign<modulus>, typename unwrap_reference<T_arg1>::type, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1,a2.value_)); }
+
+// Operators for lambda action bitwise_assign<leftshift>. At least one of the arguments needs to be of type lamdba, hence the overloads.
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<bitwise_assign<leftshift>, T_arg1, T_arg2> >
+operator <<= (const lambda<T_arg1>& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<bitwise_assign<leftshift>, T_arg1, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2.value_)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<bitwise_assign<leftshift>, T_arg1, typename unwrap_reference<T_arg2>::type> >
+operator <<= (const lambda<T_arg1>& a1, const T_arg2& a2)
+{ typedef lambda_operator<bitwise_assign<leftshift>, T_arg1, typename unwrap_reference<T_arg2>::type> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<bitwise_assign<leftshift>, typename unwrap_reference<T_arg1>::type, T_arg2> >
+operator <<= (const T_arg1& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<bitwise_assign<leftshift>, typename unwrap_reference<T_arg1>::type, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1,a2.value_)); }
+
+// Operators for lambda action bitwise_assign<rightshift>. At least one of the arguments needs to be of type lamdba, hence the overloads.
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<bitwise_assign<rightshift>, T_arg1, T_arg2> >
+operator >>= (const lambda<T_arg1>& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<bitwise_assign<rightshift>, T_arg1, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2.value_)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<bitwise_assign<rightshift>, T_arg1, typename unwrap_reference<T_arg2>::type> >
+operator >>= (const lambda<T_arg1>& a1, const T_arg2& a2)
+{ typedef lambda_operator<bitwise_assign<rightshift>, T_arg1, typename unwrap_reference<T_arg2>::type> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<bitwise_assign<rightshift>, typename unwrap_reference<T_arg1>::type, T_arg2> >
+operator >>= (const T_arg1& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<bitwise_assign<rightshift>, typename unwrap_reference<T_arg1>::type, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1,a2.value_)); }
+
+// Operators for lambda action bitwise_assign<and_>. At least one of the arguments needs to be of type lamdba, hence the overloads.
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<bitwise_assign<and_>, T_arg1, T_arg2> >
+operator &= (const lambda<T_arg1>& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<bitwise_assign<and_>, T_arg1, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2.value_)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<bitwise_assign<and_>, T_arg1, typename unwrap_reference<T_arg2>::type> >
+operator &= (const lambda<T_arg1>& a1, const T_arg2& a2)
+{ typedef lambda_operator<bitwise_assign<and_>, T_arg1, typename unwrap_reference<T_arg2>::type> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<bitwise_assign<and_>, typename unwrap_reference<T_arg1>::type, T_arg2> >
+operator &= (const T_arg1& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<bitwise_assign<and_>, typename unwrap_reference<T_arg1>::type, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1,a2.value_)); }
+
+// Operators for lambda action bitwise_assign<or_>. At least one of the arguments needs to be of type lamdba, hence the overloads.
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<bitwise_assign<or_>, T_arg1, T_arg2> >
+operator |= (const lambda<T_arg1>& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<bitwise_assign<or_>, T_arg1, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2.value_)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<bitwise_assign<or_>, T_arg1, typename unwrap_reference<T_arg2>::type> >
+operator |= (const lambda<T_arg1>& a1, const T_arg2& a2)
+{ typedef lambda_operator<bitwise_assign<or_>, T_arg1, typename unwrap_reference<T_arg2>::type> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<bitwise_assign<or_>, typename unwrap_reference<T_arg1>::type, T_arg2> >
+operator |= (const T_arg1& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<bitwise_assign<or_>, typename unwrap_reference<T_arg1>::type, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1,a2.value_)); }
+
+// Operators for lambda action bitwise_assign<xor_>. At least one of the arguments needs to be of type lamdba, hence the overloads.
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<bitwise_assign<xor_>, T_arg1, T_arg2> >
+operator ^= (const lambda<T_arg1>& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<bitwise_assign<xor_>, T_arg1, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2.value_)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<bitwise_assign<xor_>, T_arg1, typename unwrap_reference<T_arg2>::type> >
+operator ^= (const lambda<T_arg1>& a1, const T_arg2& a2)
+{ typedef lambda_operator<bitwise_assign<xor_>, T_arg1, typename unwrap_reference<T_arg2>::type> operator_type;
+  return lambda<operator_type>(operator_type(a1.value_,a2)); }
+template <class T_arg1, class T_arg2>
+lambda<lambda_operator<bitwise_assign<xor_>, typename unwrap_reference<T_arg1>::type, T_arg2> >
+operator ^= (const T_arg1& a1, const lambda<T_arg2>& a2)
+{ typedef lambda_operator<bitwise_assign<xor_>, typename unwrap_reference<T_arg1>::type, T_arg2> operator_type;
+  return lambda<operator_type>(operator_type(a1,a2.value_)); }
+
+// Operator for lambda action unary_arithmetic<pre_increment>.
+template <class T_arg>
+lambda<lambda_operator_unary<unary_arithmetic<pre_increment>, T_arg> >
+operator ++ (const lambda<T_arg>& a)
+{ typedef lambda_operator_unary<unary_arithmetic<pre_increment>, T_arg> operator_type;
+  return lambda<operator_type>(operator_type(a.value_)); }
+
+// Operator for lambda action unary_arithmetic<pre_decrement>.
+template <class T_arg>
+lambda<lambda_operator_unary<unary_arithmetic<pre_decrement>, T_arg> >
+operator -- (const lambda<T_arg>& a)
+{ typedef lambda_operator_unary<unary_arithmetic<pre_decrement>, T_arg> operator_type;
+  return lambda<operator_type>(operator_type(a.value_)); }
+
+// Operator for lambda action unary_arithmetic<negate>.
+template <class T_arg>
+lambda<lambda_operator_unary<unary_arithmetic<negate>, T_arg> >
+operator - (const lambda<T_arg>& a)
+{ typedef lambda_operator_unary<unary_arithmetic<negate>, T_arg> operator_type;
+  return lambda<operator_type>(operator_type(a.value_)); }
+
+// Operator for lambda action unary_bitwise<not_>.
+template <class T_arg>
+lambda<lambda_operator_unary<unary_bitwise<not_>, T_arg> >
+operator ~ (const lambda<T_arg>& a)
+{ typedef lambda_operator_unary<unary_bitwise<not_>, T_arg> operator_type;
+  return lambda<operator_type>(operator_type(a.value_)); }
+
+// Operator for lambda action unary_logical<not_>.
+template <class T_arg>
+lambda<lambda_operator_unary<unary_logical<not_>, T_arg> >
+operator ! (const lambda<T_arg>& a)
+{ typedef lambda_operator_unary<unary_logical<not_>, T_arg> operator_type;
+  return lambda<operator_type>(operator_type(a.value_)); }
+
+// Operator for lambda action unary_other<address>.
+template <class T_arg>
+lambda<lambda_operator_unary<unary_other<address>, T_arg> >
+operator & (const lambda<T_arg>& a)
+{ typedef lambda_operator_unary<unary_other<address>, T_arg> operator_type;
+  return lambda<operator_type>(operator_type(a.value_)); }
+
+// Operator for lambda action unary_other<dereference>.
+template <class T_arg>
+lambda<lambda_operator_unary<unary_other<dereference>, T_arg> >
+operator * (const lambda<T_arg>& a)
+{ typedef lambda_operator_unary<unary_other<dereference>, T_arg> operator_type;
+  return lambda<operator_type>(operator_type(a.value_)); }
+
+// Creators for lambda action cast_<reinterpret_>.
+template <class T_type, class T_arg>
+lambda<lambda_operator_convert<cast_<reinterpret_>, T_type, typename unwrap_lambda_type<T_arg>::type> >
+reinterpret_cast_(const T_arg& a)
+{ typedef lambda_operator_convert<cast_<reinterpret_>, T_type, typename unwrap_lambda_type<T_arg>::type> operator_type;
+  return lambda<operator_type>(operator_type(unwrap_lambda_value(a))); }
+
+// Creators for lambda action cast_<static_>.
+template <class T_type, class T_arg>
+lambda<lambda_operator_convert<cast_<static_>, T_type, typename unwrap_lambda_type<T_arg>::type> >
+static_cast_(const T_arg& a)
+{ typedef lambda_operator_convert<cast_<static_>, T_type, typename unwrap_lambda_type<T_arg>::type> operator_type;
+  return lambda<operator_type>(operator_type(unwrap_lambda_value(a))); }
+
+// Creators for lambda action cast_<dynamic_>.
+template <class T_type, class T_arg>
+lambda<lambda_operator_convert<cast_<dynamic_>, T_type, typename unwrap_lambda_type<T_arg>::type> >
+dynamic_cast_(const T_arg& a)
+{ typedef lambda_operator_convert<cast_<dynamic_>, T_type, typename unwrap_lambda_type<T_arg>::type> operator_type;
+  return lambda<operator_type>(operator_type(unwrap_lambda_value(a))); }
+
+
+} /* namespace sigc */
+
+#endif /* _SIGC_LAMBDA_OPERATOR_HPP_ */
diff --git a/libs/sigc++2/sigc++/adaptors/lambda/select.h b/libs/sigc++2/sigc++/adaptors/lambda/select.h
new file mode 100644
index 0000000000..7cbf3eccfb
--- /dev/null
+++ b/libs/sigc++2/sigc++/adaptors/lambda/select.h
@@ -0,0 +1,346 @@
+// -*- c++ -*-
+/* Do not edit! -- generated file */
+#ifndef _SIGC_LAMBDA_SELECT_HPP_
+#define _SIGC_LAMBDA_SELECT_HPP_
+#include <sigc++/adaptors/lambda/base.h>
+
+namespace sigc {
+
+namespace internal {
+struct lambda_select1 : public lambda_base
+{
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef T_arg1 type; };
+  typedef void result_type; // no operator ()() overload
+
+  void operator ()() const; // not implemented
+  template <class T_arg1>
+  T_arg1 operator ()(T_arg1 _A_1) const { return _A_1; }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1>
+  //Does not work: T_arg1 sun_forte_workaround(T_arg1 _A_1) const { return operator()( _A_1 ); }
+  T_arg1 sun_forte_workaround(T_arg1 _A_1) const { return _A_1; }
+  #endif
+  
+  template <class T_arg1,class T_arg2>
+  T_arg1 operator ()(T_arg1 _A_1,T_arg2 _A_2) const { return _A_1; }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2>
+  //Does not work: T_arg1 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2) const { return operator()( _A_1,_A_2 ); }
+  T_arg1 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2) const { return _A_1; }
+  #endif
+  
+  template <class T_arg1,class T_arg2,class T_arg3>
+  T_arg1 operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3) const { return _A_1; }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3>
+  //Does not work: T_arg1 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3) const { return operator()( _A_1,_A_2,_A_3 ); }
+  T_arg1 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3) const { return _A_1; }
+  #endif
+  
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  T_arg1 operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4) const { return _A_1; }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  //Does not work: T_arg1 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4) const { return operator()( _A_1,_A_2,_A_3,_A_4 ); }
+  T_arg1 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4) const { return _A_1; }
+  #endif
+  
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  T_arg1 operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5) const { return _A_1; }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  //Does not work: T_arg1 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5) const { return operator()( _A_1,_A_2,_A_3,_A_4,_A_5 ); }
+  T_arg1 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5) const { return _A_1; }
+  #endif
+  
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  T_arg1 operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6) const { return _A_1; }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  //Does not work: T_arg1 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6) const { return operator()( _A_1,_A_2,_A_3,_A_4,_A_5,_A_6 ); }
+  T_arg1 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6) const { return _A_1; }
+  #endif
+  
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  T_arg1 operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6,T_arg7 _A_7) const { return _A_1; }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  //Does not work: T_arg1 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6,T_arg7 _A_7) const { return operator()( _A_1,_A_2,_A_3,_A_4,_A_5,_A_6,_A_7 ); }
+  T_arg1 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6,T_arg7 _A_7) const { return _A_1; }
+  #endif
+  
+};
+
+struct lambda_select2 : public lambda_base
+{
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef T_arg2 type; };
+  typedef void result_type; // no operator ()() overload
+
+  void operator ()() const; // not implemented
+  template <class T_arg1,class T_arg2>
+  T_arg2 operator ()(T_arg1 _A_1,T_arg2 _A_2) const { return _A_2; }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2>
+  //Does not work: T_arg2 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2) const { return operator()( _A_1,_A_2 ); }
+  T_arg2 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2) const { return _A_2; }
+  #endif
+  
+  template <class T_arg1,class T_arg2,class T_arg3>
+  T_arg2 operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3) const { return _A_2; }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3>
+  //Does not work: T_arg2 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3) const { return operator()( _A_1,_A_2,_A_3 ); }
+  T_arg2 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3) const { return _A_2; }
+  #endif
+  
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  T_arg2 operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4) const { return _A_2; }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  //Does not work: T_arg2 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4) const { return operator()( _A_1,_A_2,_A_3,_A_4 ); }
+  T_arg2 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4) const { return _A_2; }
+  #endif
+  
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  T_arg2 operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5) const { return _A_2; }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  //Does not work: T_arg2 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5) const { return operator()( _A_1,_A_2,_A_3,_A_4,_A_5 ); }
+  T_arg2 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5) const { return _A_2; }
+  #endif
+  
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  T_arg2 operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6) const { return _A_2; }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  //Does not work: T_arg2 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6) const { return operator()( _A_1,_A_2,_A_3,_A_4,_A_5,_A_6 ); }
+  T_arg2 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6) const { return _A_2; }
+  #endif
+  
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  T_arg2 operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6,T_arg7 _A_7) const { return _A_2; }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  //Does not work: T_arg2 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6,T_arg7 _A_7) const { return operator()( _A_1,_A_2,_A_3,_A_4,_A_5,_A_6,_A_7 ); }
+  T_arg2 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6,T_arg7 _A_7) const { return _A_2; }
+  #endif
+  
+};
+
+struct lambda_select3 : public lambda_base
+{
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef T_arg3 type; };
+  typedef void result_type; // no operator ()() overload
+
+  void operator ()() const; // not implemented
+  template <class T_arg1,class T_arg2,class T_arg3>
+  T_arg3 operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3) const { return _A_3; }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3>
+  //Does not work: T_arg3 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3) const { return operator()( _A_1,_A_2,_A_3 ); }
+  T_arg3 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3) const { return _A_3; }
+  #endif
+  
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  T_arg3 operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4) const { return _A_3; }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  //Does not work: T_arg3 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4) const { return operator()( _A_1,_A_2,_A_3,_A_4 ); }
+  T_arg3 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4) const { return _A_3; }
+  #endif
+  
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  T_arg3 operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5) const { return _A_3; }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  //Does not work: T_arg3 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5) const { return operator()( _A_1,_A_2,_A_3,_A_4,_A_5 ); }
+  T_arg3 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5) const { return _A_3; }
+  #endif
+  
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  T_arg3 operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6) const { return _A_3; }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  //Does not work: T_arg3 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6) const { return operator()( _A_1,_A_2,_A_3,_A_4,_A_5,_A_6 ); }
+  T_arg3 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6) const { return _A_3; }
+  #endif
+  
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  T_arg3 operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6,T_arg7 _A_7) const { return _A_3; }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  //Does not work: T_arg3 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6,T_arg7 _A_7) const { return operator()( _A_1,_A_2,_A_3,_A_4,_A_5,_A_6,_A_7 ); }
+  T_arg3 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6,T_arg7 _A_7) const { return _A_3; }
+  #endif
+  
+};
+
+struct lambda_select4 : public lambda_base
+{
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef T_arg4 type; };
+  typedef void result_type; // no operator ()() overload
+
+  void operator ()() const; // not implemented
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  T_arg4 operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4) const { return _A_4; }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  //Does not work: T_arg4 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4) const { return operator()( _A_1,_A_2,_A_3,_A_4 ); }
+  T_arg4 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4) const { return _A_4; }
+  #endif
+  
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  T_arg4 operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5) const { return _A_4; }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  //Does not work: T_arg4 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5) const { return operator()( _A_1,_A_2,_A_3,_A_4,_A_5 ); }
+  T_arg4 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5) const { return _A_4; }
+  #endif
+  
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  T_arg4 operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6) const { return _A_4; }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  //Does not work: T_arg4 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6) const { return operator()( _A_1,_A_2,_A_3,_A_4,_A_5,_A_6 ); }
+  T_arg4 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6) const { return _A_4; }
+  #endif
+  
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  T_arg4 operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6,T_arg7 _A_7) const { return _A_4; }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  //Does not work: T_arg4 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6,T_arg7 _A_7) const { return operator()( _A_1,_A_2,_A_3,_A_4,_A_5,_A_6,_A_7 ); }
+  T_arg4 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6,T_arg7 _A_7) const { return _A_4; }
+  #endif
+  
+};
+
+struct lambda_select5 : public lambda_base
+{
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef T_arg5 type; };
+  typedef void result_type; // no operator ()() overload
+
+  void operator ()() const; // not implemented
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  T_arg5 operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5) const { return _A_5; }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  //Does not work: T_arg5 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5) const { return operator()( _A_1,_A_2,_A_3,_A_4,_A_5 ); }
+  T_arg5 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5) const { return _A_5; }
+  #endif
+  
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  T_arg5 operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6) const { return _A_5; }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  //Does not work: T_arg5 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6) const { return operator()( _A_1,_A_2,_A_3,_A_4,_A_5,_A_6 ); }
+  T_arg5 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6) const { return _A_5; }
+  #endif
+  
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  T_arg5 operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6,T_arg7 _A_7) const { return _A_5; }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  //Does not work: T_arg5 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6,T_arg7 _A_7) const { return operator()( _A_1,_A_2,_A_3,_A_4,_A_5,_A_6,_A_7 ); }
+  T_arg5 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6,T_arg7 _A_7) const { return _A_5; }
+  #endif
+  
+};
+
+struct lambda_select6 : public lambda_base
+{
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef T_arg6 type; };
+  typedef void result_type; // no operator ()() overload
+
+  void operator ()() const; // not implemented
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  T_arg6 operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6) const { return _A_6; }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  //Does not work: T_arg6 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6) const { return operator()( _A_1,_A_2,_A_3,_A_4,_A_5,_A_6 ); }
+  T_arg6 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6) const { return _A_6; }
+  #endif
+  
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  T_arg6 operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6,T_arg7 _A_7) const { return _A_6; }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  //Does not work: T_arg6 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6,T_arg7 _A_7) const { return operator()( _A_1,_A_2,_A_3,_A_4,_A_5,_A_6,_A_7 ); }
+  T_arg6 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6,T_arg7 _A_7) const { return _A_6; }
+  #endif
+  
+};
+
+struct lambda_select7 : public lambda_base
+{
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef T_arg7 type; };
+  typedef void result_type; // no operator ()() overload
+
+  void operator ()() const; // not implemented
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  T_arg7 operator ()(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6,T_arg7 _A_7) const { return _A_7; }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  //Does not work: T_arg7 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6,T_arg7 _A_7) const { return operator()( _A_1,_A_2,_A_3,_A_4,_A_5,_A_6,_A_7 ); }
+  T_arg7 sun_forte_workaround(T_arg1 _A_1,T_arg2 _A_2,T_arg3 _A_3,T_arg4 _A_4,T_arg5 _A_5,T_arg6 _A_6,T_arg7 _A_7) const { return _A_7; }
+  #endif
+  
+};
+
+
+} /* namespace internal */
+
+extern SIGC_API const lambda<internal::lambda_select1> _1;
+extern SIGC_API const lambda<internal::lambda_select2> _2;
+extern SIGC_API const lambda<internal::lambda_select3> _3;
+extern SIGC_API const lambda<internal::lambda_select4> _4;
+extern SIGC_API const lambda<internal::lambda_select5> _5;
+extern SIGC_API const lambda<internal::lambda_select6> _6;
+extern SIGC_API const lambda<internal::lambda_select7> _7;
+
+
+} /* namespace sigc */
+
+#endif /* _SIGC_LAMBDA_SELECT_HPP_ */
diff --git a/libs/sigc++2/sigc++/adaptors/retype.h b/libs/sigc++2/sigc++/adaptors/retype.h
new file mode 100644
index 0000000000..502959d3cd
--- /dev/null
+++ b/libs/sigc++2/sigc++/adaptors/retype.h
@@ -0,0 +1,1247 @@
+// -*- c++ -*-
+/* Do not edit! -- generated file */
+#ifndef _SIGC_ADAPTORS_MACROS_RETYPEHM4_
+#define _SIGC_ADAPTORS_MACROS_RETYPEHM4_
+#include <sigc++/adaptors/adaptor_trait.h>
+#include <sigc++/functors/ptr_fun.h>
+#include <sigc++/functors/mem_fun.h>
+#include <sigc++/functors/slot.h>
+
+namespace sigc {
+
+/** @defgroup retype retype(), retype_return()
+ * sigc::retype() alters a sigc::pointer_functor, a sigc::mem_functor or a sigc::slot
+ * in that it makes C-style casts to the functor's parameter types
+ * of all parameters passed through operator()().
+ *
+ * Use this adaptor for inline conversion between numeric or other simple types.
+ * @par Example:
+ *   @code
+ *   void foo(int);
+ *   sigc::retype(sigc::ptr_fun(&foo))(5.7F); // calls foo(5)
+ *   @endcode
+ *
+ * The functor sigc::retype() returns can be passed into
+ * sigc::signal::connect() directly.
+ *
+ * @par Example:
+ *   @code
+ *   sigc::signal<void,float> some_signal;
+ *   void foo(int);
+ *   some_signal.connect(sigc::retype(sigc::ptr_fun(&foo)));
+ *   @endcode
+ *
+ * This adaptor builds an exception in that it only works on sig::pointer_functor,
+ * sigc::mem_functor and sigc::slot because it needs sophisticated information about
+ * the parameter types that cannot be deduced from arbitrary functor types.
+ *
+ * sigc::retype_return() alters the return type of an arbitrary functor.
+ * Like in sigc::retype() a C-style cast is preformed. Usage sigc::retype_return() is
+ * not restricted to libsigc++ functor types but you need to
+ * specify the new return type as a template parameter.
+ *
+ * @par Example:
+ *   @code
+ *   float foo();
+ *   std::cout << sigc::retype_return<int>(&foo)(); // converts foo's return value to an integer
+ *   @endcode
+ *
+ * @ingroup adaptors
+ */
+
+/** Adaptor that performs C-style casts on the parameters passed on to the functor.
+ * Use the convenience function sigc::retype() to create an instance of retype_functor.
+ *
+ * The following template arguments are used:
+ * - @e T_functor Type of the functor to wrap.
+ * - @e T_type1 Type of @e T_functor's 1th argument.
+ * - @e T_type2 Type of @e T_functor's 2th argument.
+ * - @e T_type3 Type of @e T_functor's 3th argument.
+ * - @e T_type4 Type of @e T_functor's 4th argument.
+ * - @e T_type5 Type of @e T_functor's 5th argument.
+ * - @e T_type6 Type of @e T_functor's 6th argument.
+ * - @e T_type7 Type of @e T_functor's 7th argument.
+ *
+ * @ingroup retype
+ */
+template <class T_functor, class T_type1=nil,class T_type2=nil,class T_type3=nil,class T_type4=nil,class T_type5=nil,class T_type6=nil,class T_type7=nil>
+struct retype_functor
+  : public adapts<T_functor>
+{
+  typedef typename adapts<T_functor>::adaptor_type adaptor_type;
+
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef typename adaptor_type::template deduce_result_type<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>::type type; };
+  typedef typename adapts<T_functor>::result_type result_type;
+
+  result_type operator()();
+    
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  operator()(T_arg1 _A_a1)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_type1>::take>
+        ((T_type1)_A_a1);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1>
+  typename deduce_result_type<T_arg1>::type
+  sun_forte_workaround(T_arg1 _A_a1)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_type1>::take>
+        ((T_type1)_A_a1);
+    }
+  #endif
+
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_type1>::take,typename type_trait<T_type2>::take>
+        ((T_type1)_A_a1,(T_type2)_A_a2);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2>
+  typename deduce_result_type<T_arg1,T_arg2>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_type1>::take,typename type_trait<T_type2>::take>
+        ((T_type1)_A_a1,(T_type2)_A_a2);
+    }
+  #endif
+
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_type1>::take,typename type_trait<T_type2>::take,typename type_trait<T_type3>::take>
+        ((T_type1)_A_a1,(T_type2)_A_a2,(T_type3)_A_a3);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_type1>::take,typename type_trait<T_type2>::take,typename type_trait<T_type3>::take>
+        ((T_type1)_A_a1,(T_type2)_A_a2,(T_type3)_A_a3);
+    }
+  #endif
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_type1>::take,typename type_trait<T_type2>::take,typename type_trait<T_type3>::take,typename type_trait<T_type4>::take>
+        ((T_type1)_A_a1,(T_type2)_A_a2,(T_type3)_A_a3,(T_type4)_A_a4);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_type1>::take,typename type_trait<T_type2>::take,typename type_trait<T_type3>::take,typename type_trait<T_type4>::take>
+        ((T_type1)_A_a1,(T_type2)_A_a2,(T_type3)_A_a3,(T_type4)_A_a4);
+    }
+  #endif
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_type1>::take,typename type_trait<T_type2>::take,typename type_trait<T_type3>::take,typename type_trait<T_type4>::take,typename type_trait<T_type5>::take>
+        ((T_type1)_A_a1,(T_type2)_A_a2,(T_type3)_A_a3,(T_type4)_A_a4,(T_type5)_A_a5);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_type1>::take,typename type_trait<T_type2>::take,typename type_trait<T_type3>::take,typename type_trait<T_type4>::take,typename type_trait<T_type5>::take>
+        ((T_type1)_A_a1,(T_type2)_A_a2,(T_type3)_A_a3,(T_type4)_A_a4,(T_type5)_A_a5);
+    }
+  #endif
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_type1>::take,typename type_trait<T_type2>::take,typename type_trait<T_type3>::take,typename type_trait<T_type4>::take,typename type_trait<T_type5>::take,typename type_trait<T_type6>::take>
+        ((T_type1)_A_a1,(T_type2)_A_a2,(T_type3)_A_a3,(T_type4)_A_a4,(T_type5)_A_a5,(T_type6)_A_a6);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_type1>::take,typename type_trait<T_type2>::take,typename type_trait<T_type3>::take,typename type_trait<T_type4>::take,typename type_trait<T_type5>::take,typename type_trait<T_type6>::take>
+        ((T_type1)_A_a1,(T_type2)_A_a2,(T_type3)_A_a3,(T_type4)_A_a4,(T_type5)_A_a5,(T_type6)_A_a6);
+    }
+  #endif
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6,T_arg7 _A_a7)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_type1>::take,typename type_trait<T_type2>::take,typename type_trait<T_type3>::take,typename type_trait<T_type4>::take,typename type_trait<T_type5>::take,typename type_trait<T_type6>::take,typename type_trait<T_type7>::take>
+        ((T_type1)_A_a1,(T_type2)_A_a2,(T_type3)_A_a3,(T_type4)_A_a4,(T_type5)_A_a5,(T_type6)_A_a6,(T_type7)_A_a7);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  typename deduce_result_type<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::type
+  sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6,T_arg7 _A_a7)
+    { return this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_type1>::take,typename type_trait<T_type2>::take,typename type_trait<T_type3>::take,typename type_trait<T_type4>::take,typename type_trait<T_type5>::take,typename type_trait<T_type6>::take,typename type_trait<T_type7>::take>
+        ((T_type1)_A_a1,(T_type2)_A_a2,(T_type3)_A_a3,(T_type4)_A_a4,(T_type5)_A_a5,(T_type6)_A_a6,(T_type7)_A_a7);
+    }
+  #endif
+
+
+  /** Constructs a retype_functor object that performs C-style casts on the parameters passed on to the functor.
+   * @param _A_functor Functor to invoke from operator()().
+   */
+  explicit retype_functor(typename type_trait<T_functor>::take _A_functor)
+    : adapts<T_functor>(_A_functor)
+    {}
+};
+
+template <class T_functor, class T_type1,class T_type2,class T_type3,class T_type4,class T_type5,class T_type6,class T_type7>
+typename retype_functor<T_functor, T_type1,T_type2,T_type3,T_type4,T_type5,T_type6,T_type7>::result_type
+retype_functor<T_functor, T_type1,T_type2,T_type3,T_type4,T_type5,T_type6,T_type7>::operator()()
+  { return this->functor_(); }
+
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::retype_functor performs a functor on the
+ * functor stored in the sigc::retype_functor object.
+ *
+ * @ingroup retype
+ */
+template <class T_action, class T_functor, class T_type1,class T_type2,class T_type3,class T_type4,class T_type5,class T_type6,class T_type7>
+void visit_each(const T_action& _A_action,
+                const retype_functor<T_functor, T_type1,T_type2,T_type3,T_type4,T_type5,T_type6,T_type7>& _A_target)
+{
+  visit_each(_A_action, _A_target.functor_);
+}
+
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::slot.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+inline retype_functor<slot<T_return, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6, T_arg7>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7 >
+retype(const slot<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>& _A_functor)
+{ return retype_functor<slot<T_return, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6, T_arg7>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7 >
+    (_A_functor); }
+
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::pointer_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return>
+inline retype_functor<pointer_functor0<T_return> >
+retype(const pointer_functor0<T_return>& _A_functor)
+{ return retype_functor<pointer_functor0<T_return> >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::pointer_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_arg1, class T_return>
+inline retype_functor<pointer_functor1<T_arg1, T_return>, T_arg1 >
+retype(const pointer_functor1<T_arg1, T_return>& _A_functor)
+{ return retype_functor<pointer_functor1<T_arg1, T_return>, T_arg1 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::pointer_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_arg1,class T_arg2, class T_return>
+inline retype_functor<pointer_functor2<T_arg1, T_arg2, T_return>, T_arg1,T_arg2 >
+retype(const pointer_functor2<T_arg1,T_arg2, T_return>& _A_functor)
+{ return retype_functor<pointer_functor2<T_arg1, T_arg2, T_return>, T_arg1,T_arg2 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::pointer_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_arg1,class T_arg2,class T_arg3, class T_return>
+inline retype_functor<pointer_functor3<T_arg1, T_arg2, T_arg3, T_return>, T_arg1,T_arg2,T_arg3 >
+retype(const pointer_functor3<T_arg1,T_arg2,T_arg3, T_return>& _A_functor)
+{ return retype_functor<pointer_functor3<T_arg1, T_arg2, T_arg3, T_return>, T_arg1,T_arg2,T_arg3 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::pointer_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_return>
+inline retype_functor<pointer_functor4<T_arg1, T_arg2, T_arg3, T_arg4, T_return>, T_arg1,T_arg2,T_arg3,T_arg4 >
+retype(const pointer_functor4<T_arg1,T_arg2,T_arg3,T_arg4, T_return>& _A_functor)
+{ return retype_functor<pointer_functor4<T_arg1, T_arg2, T_arg3, T_arg4, T_return>, T_arg1,T_arg2,T_arg3,T_arg4 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::pointer_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_return>
+inline retype_functor<pointer_functor5<T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_return>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5 >
+retype(const pointer_functor5<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5, T_return>& _A_functor)
+{ return retype_functor<pointer_functor5<T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_return>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::pointer_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_return>
+inline retype_functor<pointer_functor6<T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6, T_return>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6 >
+retype(const pointer_functor6<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6, T_return>& _A_functor)
+{ return retype_functor<pointer_functor6<T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6, T_return>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::pointer_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_return>
+inline retype_functor<pointer_functor7<T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6, T_arg7, T_return>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7 >
+retype(const pointer_functor7<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7, T_return>& _A_functor)
+{ return retype_functor<pointer_functor7<T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6, T_arg7, T_return>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7 >
+    (_A_functor); }
+
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj>
+inline retype_functor<mem_functor0<T_return, T_obj> >
+retype(const mem_functor0<T_return, T_obj>& _A_functor)
+{ return retype_functor<mem_functor0<T_return, T_obj> >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1>
+inline retype_functor<mem_functor1<T_return, T_obj, T_arg1>, T_arg1 >
+retype(const mem_functor1<T_return, T_obj, T_arg1>& _A_functor)
+{ return retype_functor<mem_functor1<T_return, T_obj, T_arg1>, T_arg1 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2>
+inline retype_functor<mem_functor2<T_return, T_obj, T_arg1, T_arg2>, T_arg1,T_arg2 >
+retype(const mem_functor2<T_return, T_obj, T_arg1,T_arg2>& _A_functor)
+{ return retype_functor<mem_functor2<T_return, T_obj, T_arg1, T_arg2>, T_arg1,T_arg2 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3>
+inline retype_functor<mem_functor3<T_return, T_obj, T_arg1, T_arg2, T_arg3>, T_arg1,T_arg2,T_arg3 >
+retype(const mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>& _A_functor)
+{ return retype_functor<mem_functor3<T_return, T_obj, T_arg1, T_arg2, T_arg3>, T_arg1,T_arg2,T_arg3 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+inline retype_functor<mem_functor4<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4>, T_arg1,T_arg2,T_arg3,T_arg4 >
+retype(const mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>& _A_functor)
+{ return retype_functor<mem_functor4<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4>, T_arg1,T_arg2,T_arg3,T_arg4 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+inline retype_functor<mem_functor5<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5 >
+retype(const mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>& _A_functor)
+{ return retype_functor<mem_functor5<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+inline retype_functor<mem_functor6<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6 >
+retype(const mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>& _A_functor)
+{ return retype_functor<mem_functor6<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+inline retype_functor<mem_functor7<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6, T_arg7>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7 >
+retype(const mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>& _A_functor)
+{ return retype_functor<mem_functor7<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6, T_arg7>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::const_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj>
+inline retype_functor<const_mem_functor0<T_return, T_obj> >
+retype(const const_mem_functor0<T_return, T_obj>& _A_functor)
+{ return retype_functor<const_mem_functor0<T_return, T_obj> >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::const_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1>
+inline retype_functor<const_mem_functor1<T_return, T_obj, T_arg1>, T_arg1 >
+retype(const const_mem_functor1<T_return, T_obj, T_arg1>& _A_functor)
+{ return retype_functor<const_mem_functor1<T_return, T_obj, T_arg1>, T_arg1 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::const_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2>
+inline retype_functor<const_mem_functor2<T_return, T_obj, T_arg1, T_arg2>, T_arg1,T_arg2 >
+retype(const const_mem_functor2<T_return, T_obj, T_arg1,T_arg2>& _A_functor)
+{ return retype_functor<const_mem_functor2<T_return, T_obj, T_arg1, T_arg2>, T_arg1,T_arg2 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::const_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3>
+inline retype_functor<const_mem_functor3<T_return, T_obj, T_arg1, T_arg2, T_arg3>, T_arg1,T_arg2,T_arg3 >
+retype(const const_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>& _A_functor)
+{ return retype_functor<const_mem_functor3<T_return, T_obj, T_arg1, T_arg2, T_arg3>, T_arg1,T_arg2,T_arg3 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::const_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+inline retype_functor<const_mem_functor4<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4>, T_arg1,T_arg2,T_arg3,T_arg4 >
+retype(const const_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>& _A_functor)
+{ return retype_functor<const_mem_functor4<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4>, T_arg1,T_arg2,T_arg3,T_arg4 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::const_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+inline retype_functor<const_mem_functor5<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5 >
+retype(const const_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>& _A_functor)
+{ return retype_functor<const_mem_functor5<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::const_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+inline retype_functor<const_mem_functor6<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6 >
+retype(const const_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>& _A_functor)
+{ return retype_functor<const_mem_functor6<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::const_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+inline retype_functor<const_mem_functor7<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6, T_arg7>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7 >
+retype(const const_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>& _A_functor)
+{ return retype_functor<const_mem_functor7<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6, T_arg7>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::volatile_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj>
+inline retype_functor<volatile_mem_functor0<T_return, T_obj> >
+retype(const volatile_mem_functor0<T_return, T_obj>& _A_functor)
+{ return retype_functor<volatile_mem_functor0<T_return, T_obj> >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::volatile_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1>
+inline retype_functor<volatile_mem_functor1<T_return, T_obj, T_arg1>, T_arg1 >
+retype(const volatile_mem_functor1<T_return, T_obj, T_arg1>& _A_functor)
+{ return retype_functor<volatile_mem_functor1<T_return, T_obj, T_arg1>, T_arg1 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::volatile_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2>
+inline retype_functor<volatile_mem_functor2<T_return, T_obj, T_arg1, T_arg2>, T_arg1,T_arg2 >
+retype(const volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2>& _A_functor)
+{ return retype_functor<volatile_mem_functor2<T_return, T_obj, T_arg1, T_arg2>, T_arg1,T_arg2 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::volatile_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3>
+inline retype_functor<volatile_mem_functor3<T_return, T_obj, T_arg1, T_arg2, T_arg3>, T_arg1,T_arg2,T_arg3 >
+retype(const volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>& _A_functor)
+{ return retype_functor<volatile_mem_functor3<T_return, T_obj, T_arg1, T_arg2, T_arg3>, T_arg1,T_arg2,T_arg3 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::volatile_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+inline retype_functor<volatile_mem_functor4<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4>, T_arg1,T_arg2,T_arg3,T_arg4 >
+retype(const volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>& _A_functor)
+{ return retype_functor<volatile_mem_functor4<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4>, T_arg1,T_arg2,T_arg3,T_arg4 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::volatile_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+inline retype_functor<volatile_mem_functor5<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5 >
+retype(const volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>& _A_functor)
+{ return retype_functor<volatile_mem_functor5<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::volatile_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+inline retype_functor<volatile_mem_functor6<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6 >
+retype(const volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>& _A_functor)
+{ return retype_functor<volatile_mem_functor6<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::volatile_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+inline retype_functor<volatile_mem_functor7<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6, T_arg7>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7 >
+retype(const volatile_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>& _A_functor)
+{ return retype_functor<volatile_mem_functor7<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6, T_arg7>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::const_volatile_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj>
+inline retype_functor<const_volatile_mem_functor0<T_return, T_obj> >
+retype(const const_volatile_mem_functor0<T_return, T_obj>& _A_functor)
+{ return retype_functor<const_volatile_mem_functor0<T_return, T_obj> >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::const_volatile_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1>
+inline retype_functor<const_volatile_mem_functor1<T_return, T_obj, T_arg1>, T_arg1 >
+retype(const const_volatile_mem_functor1<T_return, T_obj, T_arg1>& _A_functor)
+{ return retype_functor<const_volatile_mem_functor1<T_return, T_obj, T_arg1>, T_arg1 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::const_volatile_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2>
+inline retype_functor<const_volatile_mem_functor2<T_return, T_obj, T_arg1, T_arg2>, T_arg1,T_arg2 >
+retype(const const_volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2>& _A_functor)
+{ return retype_functor<const_volatile_mem_functor2<T_return, T_obj, T_arg1, T_arg2>, T_arg1,T_arg2 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::const_volatile_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3>
+inline retype_functor<const_volatile_mem_functor3<T_return, T_obj, T_arg1, T_arg2, T_arg3>, T_arg1,T_arg2,T_arg3 >
+retype(const const_volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>& _A_functor)
+{ return retype_functor<const_volatile_mem_functor3<T_return, T_obj, T_arg1, T_arg2, T_arg3>, T_arg1,T_arg2,T_arg3 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::const_volatile_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+inline retype_functor<const_volatile_mem_functor4<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4>, T_arg1,T_arg2,T_arg3,T_arg4 >
+retype(const const_volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>& _A_functor)
+{ return retype_functor<const_volatile_mem_functor4<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4>, T_arg1,T_arg2,T_arg3,T_arg4 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::const_volatile_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+inline retype_functor<const_volatile_mem_functor5<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5 >
+retype(const const_volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>& _A_functor)
+{ return retype_functor<const_volatile_mem_functor5<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::const_volatile_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+inline retype_functor<const_volatile_mem_functor6<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6 >
+retype(const const_volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>& _A_functor)
+{ return retype_functor<const_volatile_mem_functor6<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::const_volatile_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+inline retype_functor<const_volatile_mem_functor7<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6, T_arg7>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7 >
+retype(const const_volatile_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>& _A_functor)
+{ return retype_functor<const_volatile_mem_functor7<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6, T_arg7>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::bound_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj>
+inline retype_functor<bound_mem_functor0<T_return, T_obj> >
+retype(const bound_mem_functor0<T_return, T_obj>& _A_functor)
+{ return retype_functor<bound_mem_functor0<T_return, T_obj> >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::bound_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1>
+inline retype_functor<bound_mem_functor1<T_return, T_obj, T_arg1>, T_arg1 >
+retype(const bound_mem_functor1<T_return, T_obj, T_arg1>& _A_functor)
+{ return retype_functor<bound_mem_functor1<T_return, T_obj, T_arg1>, T_arg1 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::bound_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2>
+inline retype_functor<bound_mem_functor2<T_return, T_obj, T_arg1, T_arg2>, T_arg1,T_arg2 >
+retype(const bound_mem_functor2<T_return, T_obj, T_arg1,T_arg2>& _A_functor)
+{ return retype_functor<bound_mem_functor2<T_return, T_obj, T_arg1, T_arg2>, T_arg1,T_arg2 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::bound_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3>
+inline retype_functor<bound_mem_functor3<T_return, T_obj, T_arg1, T_arg2, T_arg3>, T_arg1,T_arg2,T_arg3 >
+retype(const bound_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>& _A_functor)
+{ return retype_functor<bound_mem_functor3<T_return, T_obj, T_arg1, T_arg2, T_arg3>, T_arg1,T_arg2,T_arg3 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::bound_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+inline retype_functor<bound_mem_functor4<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4>, T_arg1,T_arg2,T_arg3,T_arg4 >
+retype(const bound_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>& _A_functor)
+{ return retype_functor<bound_mem_functor4<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4>, T_arg1,T_arg2,T_arg3,T_arg4 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::bound_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+inline retype_functor<bound_mem_functor5<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5 >
+retype(const bound_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>& _A_functor)
+{ return retype_functor<bound_mem_functor5<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::bound_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+inline retype_functor<bound_mem_functor6<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6 >
+retype(const bound_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>& _A_functor)
+{ return retype_functor<bound_mem_functor6<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::bound_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+inline retype_functor<bound_mem_functor7<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6, T_arg7>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7 >
+retype(const bound_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>& _A_functor)
+{ return retype_functor<bound_mem_functor7<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6, T_arg7>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::bound_const_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj>
+inline retype_functor<bound_const_mem_functor0<T_return, T_obj> >
+retype(const bound_const_mem_functor0<T_return, T_obj>& _A_functor)
+{ return retype_functor<bound_const_mem_functor0<T_return, T_obj> >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::bound_const_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1>
+inline retype_functor<bound_const_mem_functor1<T_return, T_obj, T_arg1>, T_arg1 >
+retype(const bound_const_mem_functor1<T_return, T_obj, T_arg1>& _A_functor)
+{ return retype_functor<bound_const_mem_functor1<T_return, T_obj, T_arg1>, T_arg1 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::bound_const_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2>
+inline retype_functor<bound_const_mem_functor2<T_return, T_obj, T_arg1, T_arg2>, T_arg1,T_arg2 >
+retype(const bound_const_mem_functor2<T_return, T_obj, T_arg1,T_arg2>& _A_functor)
+{ return retype_functor<bound_const_mem_functor2<T_return, T_obj, T_arg1, T_arg2>, T_arg1,T_arg2 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::bound_const_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3>
+inline retype_functor<bound_const_mem_functor3<T_return, T_obj, T_arg1, T_arg2, T_arg3>, T_arg1,T_arg2,T_arg3 >
+retype(const bound_const_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>& _A_functor)
+{ return retype_functor<bound_const_mem_functor3<T_return, T_obj, T_arg1, T_arg2, T_arg3>, T_arg1,T_arg2,T_arg3 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::bound_const_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+inline retype_functor<bound_const_mem_functor4<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4>, T_arg1,T_arg2,T_arg3,T_arg4 >
+retype(const bound_const_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>& _A_functor)
+{ return retype_functor<bound_const_mem_functor4<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4>, T_arg1,T_arg2,T_arg3,T_arg4 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::bound_const_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+inline retype_functor<bound_const_mem_functor5<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5 >
+retype(const bound_const_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>& _A_functor)
+{ return retype_functor<bound_const_mem_functor5<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::bound_const_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+inline retype_functor<bound_const_mem_functor6<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6 >
+retype(const bound_const_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>& _A_functor)
+{ return retype_functor<bound_const_mem_functor6<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::bound_const_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+inline retype_functor<bound_const_mem_functor7<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6, T_arg7>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7 >
+retype(const bound_const_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>& _A_functor)
+{ return retype_functor<bound_const_mem_functor7<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6, T_arg7>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::bound_volatile_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj>
+inline retype_functor<bound_volatile_mem_functor0<T_return, T_obj> >
+retype(const bound_volatile_mem_functor0<T_return, T_obj>& _A_functor)
+{ return retype_functor<bound_volatile_mem_functor0<T_return, T_obj> >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::bound_volatile_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1>
+inline retype_functor<bound_volatile_mem_functor1<T_return, T_obj, T_arg1>, T_arg1 >
+retype(const bound_volatile_mem_functor1<T_return, T_obj, T_arg1>& _A_functor)
+{ return retype_functor<bound_volatile_mem_functor1<T_return, T_obj, T_arg1>, T_arg1 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::bound_volatile_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2>
+inline retype_functor<bound_volatile_mem_functor2<T_return, T_obj, T_arg1, T_arg2>, T_arg1,T_arg2 >
+retype(const bound_volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2>& _A_functor)
+{ return retype_functor<bound_volatile_mem_functor2<T_return, T_obj, T_arg1, T_arg2>, T_arg1,T_arg2 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::bound_volatile_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3>
+inline retype_functor<bound_volatile_mem_functor3<T_return, T_obj, T_arg1, T_arg2, T_arg3>, T_arg1,T_arg2,T_arg3 >
+retype(const bound_volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>& _A_functor)
+{ return retype_functor<bound_volatile_mem_functor3<T_return, T_obj, T_arg1, T_arg2, T_arg3>, T_arg1,T_arg2,T_arg3 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::bound_volatile_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+inline retype_functor<bound_volatile_mem_functor4<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4>, T_arg1,T_arg2,T_arg3,T_arg4 >
+retype(const bound_volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>& _A_functor)
+{ return retype_functor<bound_volatile_mem_functor4<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4>, T_arg1,T_arg2,T_arg3,T_arg4 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::bound_volatile_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+inline retype_functor<bound_volatile_mem_functor5<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5 >
+retype(const bound_volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>& _A_functor)
+{ return retype_functor<bound_volatile_mem_functor5<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::bound_volatile_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+inline retype_functor<bound_volatile_mem_functor6<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6 >
+retype(const bound_volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>& _A_functor)
+{ return retype_functor<bound_volatile_mem_functor6<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::bound_volatile_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+inline retype_functor<bound_volatile_mem_functor7<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6, T_arg7>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7 >
+retype(const bound_volatile_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>& _A_functor)
+{ return retype_functor<bound_volatile_mem_functor7<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6, T_arg7>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::bound_const_volatile_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj>
+inline retype_functor<bound_const_volatile_mem_functor0<T_return, T_obj> >
+retype(const bound_const_volatile_mem_functor0<T_return, T_obj>& _A_functor)
+{ return retype_functor<bound_const_volatile_mem_functor0<T_return, T_obj> >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::bound_const_volatile_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1>
+inline retype_functor<bound_const_volatile_mem_functor1<T_return, T_obj, T_arg1>, T_arg1 >
+retype(const bound_const_volatile_mem_functor1<T_return, T_obj, T_arg1>& _A_functor)
+{ return retype_functor<bound_const_volatile_mem_functor1<T_return, T_obj, T_arg1>, T_arg1 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::bound_const_volatile_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2>
+inline retype_functor<bound_const_volatile_mem_functor2<T_return, T_obj, T_arg1, T_arg2>, T_arg1,T_arg2 >
+retype(const bound_const_volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2>& _A_functor)
+{ return retype_functor<bound_const_volatile_mem_functor2<T_return, T_obj, T_arg1, T_arg2>, T_arg1,T_arg2 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::bound_const_volatile_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3>
+inline retype_functor<bound_const_volatile_mem_functor3<T_return, T_obj, T_arg1, T_arg2, T_arg3>, T_arg1,T_arg2,T_arg3 >
+retype(const bound_const_volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>& _A_functor)
+{ return retype_functor<bound_const_volatile_mem_functor3<T_return, T_obj, T_arg1, T_arg2, T_arg3>, T_arg1,T_arg2,T_arg3 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::bound_const_volatile_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+inline retype_functor<bound_const_volatile_mem_functor4<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4>, T_arg1,T_arg2,T_arg3,T_arg4 >
+retype(const bound_const_volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>& _A_functor)
+{ return retype_functor<bound_const_volatile_mem_functor4<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4>, T_arg1,T_arg2,T_arg3,T_arg4 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::bound_const_volatile_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+inline retype_functor<bound_const_volatile_mem_functor5<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5 >
+retype(const bound_const_volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>& _A_functor)
+{ return retype_functor<bound_const_volatile_mem_functor5<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::bound_const_volatile_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+inline retype_functor<bound_const_volatile_mem_functor6<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6 >
+retype(const bound_const_volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>& _A_functor)
+{ return retype_functor<bound_const_volatile_mem_functor6<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6 >
+    (_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_functor which performs C-style casts on the parameters passed on to the functor.
+ * This function template specialization works on sigc::bound_const_volatile_mem_functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing C-style casts on the paramters passed on.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+inline retype_functor<bound_const_volatile_mem_functor7<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6, T_arg7>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7 >
+retype(const bound_const_volatile_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>& _A_functor)
+{ return retype_functor<bound_const_volatile_mem_functor7<T_return, T_obj, T_arg1, T_arg2, T_arg3, T_arg4, T_arg5, T_arg6, T_arg7>, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7 >
+    (_A_functor); }
+
+
+} /* namespace sigc */
+#endif /* _SIGC_ADAPTORS_MACROS_RETYPEHM4_ */
diff --git a/libs/sigc++2/sigc++/adaptors/retype_return.h b/libs/sigc++2/sigc++/adaptors/retype_return.h
new file mode 100644
index 0000000000..ea413a0b30
--- /dev/null
+++ b/libs/sigc++2/sigc++/adaptors/retype_return.h
@@ -0,0 +1,308 @@
+// -*- c++ -*-
+/* Do not edit! -- generated file */
+#ifndef _SIGC_ADAPTORS_MACROS_RETYPE_RETURNHM4_
+#define _SIGC_ADAPTORS_MACROS_RETYPE_RETURNHM4_
+#include <sigc++/adaptors/adaptor_trait.h>
+
+namespace sigc {
+
+/** Adaptor that perform a C-style cast on the return value of a functor.
+ * Use the convenience function sigc::retype_return() to create an instance of retype_return_functor.
+ *
+ * The following template arguments are used:
+ * - @e T_return Target type of the C-style cast.
+ * - @e T_functor Type of the functor to wrap.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_functor>
+struct retype_return_functor : public adapts<T_functor>
+{
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef T_return type; };
+  typedef T_return result_type;
+
+  T_return operator()();
+
+  template <class T_arg1>
+  inline T_return operator()(T_arg1 _A_a1)
+    { return T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass>
+        (_A_a1));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1>
+  inline T_return sun_forte_workaround(T_arg1 _A_a1)
+    { return T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass>
+        (_A_a1));
+    }
+  #endif
+    
+  template <class T_arg1,class T_arg2>
+  inline T_return operator()(T_arg1 _A_a1,T_arg2 _A_a2)
+    { return T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>
+        (_A_a1,_A_a2));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2>
+  inline T_return sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2)
+    { return T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>
+        (_A_a1,_A_a2));
+    }
+  #endif
+    
+  template <class T_arg1,class T_arg2,class T_arg3>
+  inline T_return operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3)
+    { return T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>
+        (_A_a1,_A_a2,_A_a3));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3>
+  inline T_return sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3)
+    { return T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>
+        (_A_a1,_A_a2,_A_a3));
+    }
+  #endif
+    
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  inline T_return operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4)
+    { return T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>
+        (_A_a1,_A_a2,_A_a3,_A_a4));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  inline T_return sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4)
+    { return T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>
+        (_A_a1,_A_a2,_A_a3,_A_a4));
+    }
+  #endif
+    
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  inline T_return operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5)
+    { return T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>
+        (_A_a1,_A_a2,_A_a3,_A_a4,_A_a5));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  inline T_return sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5)
+    { return T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>
+        (_A_a1,_A_a2,_A_a3,_A_a4,_A_a5));
+    }
+  #endif
+    
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  inline T_return operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6)
+    { return T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>
+        (_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  inline T_return sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6)
+    { return T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>
+        (_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6));
+    }
+  #endif
+    
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  inline T_return operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6,T_arg7 _A_a7)
+    { return T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>
+        (_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6,_A_a7));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  inline T_return sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6,T_arg7 _A_a7)
+    { return T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>
+        (_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6,_A_a7));
+    }
+  #endif
+    
+  retype_return_functor() {}
+
+  /** Constructs a retype_return_functor object that perform a C-style cast on the return value of the passed functor.
+   * @param _A_functor Functor to invoke from operator()().
+   */
+  explicit retype_return_functor(typename type_trait<T_functor>::take _A_functor)
+    : adapts<T_functor>(_A_functor)
+    {}
+};
+
+template <class T_return, class T_functor>
+T_return retype_return_functor<T_return, T_functor>::operator()()
+  { return T_return(this->functor_()); }
+
+
+/** Adaptor that perform a C-style cast on the return value of a functor.
+ * This template specialization is for a void return. It drops the return value of the functor it invokes.
+ * Use the convenience function sigc::hide_return() to create an instance of sigc::retype_return_functor<void>.
+ *
+ * @ingroup retype
+ */
+/* The void specialization needed because of explicit cast to T_return.
+ */
+template <class T_functor>
+struct retype_return_functor<void, T_functor> : public adapts<T_functor>
+{
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef void type; };
+  typedef void result_type;
+
+  void operator()();
+
+  template <class T_arg1>
+  inline void operator()(T_arg1 _A_a1)
+    { this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass>
+        (_A_a1);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1>
+  inline void sun_forte_workaround(T_arg1 _A_a1)
+    { this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass>
+        (_A_a1);
+    }
+  #endif
+
+  template <class T_arg1,class T_arg2>
+  inline void operator()(T_arg1 _A_a1,T_arg2 _A_a2)
+    { this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>
+        (_A_a1,_A_a2);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2>
+  inline void sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2)
+    { this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass>
+        (_A_a1,_A_a2);
+    }
+  #endif
+
+  template <class T_arg1,class T_arg2,class T_arg3>
+  inline void operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3)
+    { this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>
+        (_A_a1,_A_a2,_A_a3);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3>
+  inline void sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3)
+    { this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass>
+        (_A_a1,_A_a2,_A_a3);
+    }
+  #endif
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  inline void operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4)
+    { this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>
+        (_A_a1,_A_a2,_A_a3,_A_a4);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  inline void sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4)
+    { this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass>
+        (_A_a1,_A_a2,_A_a3,_A_a4);
+    }
+  #endif
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  inline void operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5)
+    { this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>
+        (_A_a1,_A_a2,_A_a3,_A_a4,_A_a5);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  inline void sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5)
+    { this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass>
+        (_A_a1,_A_a2,_A_a3,_A_a4,_A_a5);
+    }
+  #endif
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  inline void operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6)
+    { this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>
+        (_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  inline void sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6)
+    { this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass>
+        (_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6);
+    }
+  #endif
+
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  inline void operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6,T_arg7 _A_a7)
+    { this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>
+        (_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6,_A_a7);
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  inline void sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6,T_arg7 _A_a7)
+    { this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::pass,typename type_trait<T_arg2>::pass,typename type_trait<T_arg3>::pass,typename type_trait<T_arg4>::pass,typename type_trait<T_arg5>::pass,typename type_trait<T_arg6>::pass,typename type_trait<T_arg7>::pass>
+        (_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6,_A_a7);
+    }
+  #endif
+
+  retype_return_functor() {}
+  retype_return_functor(typename type_trait<T_functor>::take _A_functor)
+    : adapts<T_functor>(_A_functor)
+    {}
+};
+
+template <class T_functor>
+void retype_return_functor<void, T_functor>::operator()()
+  { this->functor_(); }
+
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::retype_return_functor performs a functor on the
+ * functor stored in the sigc::retype_return_functor object.
+ *
+ * @ingroup retype
+ */
+template <class T_action, class T_return, class T_functor>
+void visit_each(const T_action& _A_action,
+                const retype_return_functor<T_return, T_functor>& _A_target)
+{
+  visit_each(_A_action, _A_target.functor_);
+}
+
+
+/** Creates an adaptor of type sigc::retype_return_functor which performs a C-style cast on the return value of the passed functor.
+ * The template argument @e T_return specifies the target type of the cast.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor performing a C-style casts on the return value.
+ *
+ * @ingroup retype
+ */
+template <class T_return, class T_functor>
+inline retype_return_functor<T_return, T_functor>
+retype_return(const T_functor& _A_functor)
+  { return retype_return_functor<T_return, T_functor>(_A_functor); }
+
+/** Creates an adaptor of type sigc::retype_return_functor which drops the return value of the passed functor.
+ *
+ * @param _A_functor Functor that should be wrapped.
+ * @return Adaptor that executes @e _A_functor dropping its return value.
+ *
+ * @ingroup hide
+ */
+template <class T_functor>
+inline retype_return_functor<void, T_functor>
+hide_return(const T_functor& _A_functor)
+  { return retype_return_functor<void, T_functor>(_A_functor); }
+
+} /* namespace sigc */
+#endif /* _SIGC_ADAPTORS_MACROS_RETYPE_RETURNHM4_ */
diff --git a/libs/sigc++2/sigc++/bind.h b/libs/sigc++2/sigc++/bind.h
new file mode 100644
index 0000000000..bebf08b58b
--- /dev/null
+++ b/libs/sigc++2/sigc++/bind.h
@@ -0,0 +1,65 @@
+/*
+ * Copyright 2002, The libsigc++ Development Team
+ *
+ *  This library is free software; you can redistribute it and/or
+ *  modify it under the terms of the GNU Lesser General Public
+ *  License as published by the Free Software Foundation; either
+ *  version 2.1 of the License, or (at your option) any later version.
+ *
+ *  This library is distributed in the hope that it will be useful,
+ *  but WITHOUT ANY WARRANTY; without even the implied warranty of
+ *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
+ *  Lesser General Public License for more details.
+ *
+ *  You should have received a copy of the GNU Lesser General Public
+ *  License along with this library; if not, write to the Free Software
+ *  Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
+ *
+ */
+#ifndef _SIGC_BIND_HPP_
+#define _SIGC_BIND_HPP_
+
+#include <sigc++/adaptors/bind.h>
+
+#ifndef LIBSIGC_DISABLE_DEPRECATED
+
+namespace SigC {
+
+template <class T_bound1, class T_functor>
+inline ::sigc::bind_functor<-1, T_functor,
+                            typename ::sigc::unwrap_reference<T_bound1>::type>
+bind(const T_functor& _A_functor, T_bound1 _A_b1)
+{ return ::sigc::bind_functor<-1, T_functor,
+                              typename ::sigc::unwrap_reference<T_bound1>::type>
+                              (_A_functor, _A_b1);
+}
+
+template <class T_bound1, class T_bound2, class T_functor>
+inline ::sigc::bind_functor<-1, T_functor,
+                            typename ::sigc::unwrap_reference<T_bound1>::type,
+                            typename ::sigc::unwrap_reference<T_bound2>::type>
+bind(const T_functor& _A_functor, T_bound1 _A_b1, T_bound2 _A_b2)
+{ return ::sigc::bind_functor<-1, T_functor,
+                              typename ::sigc::unwrap_reference<T_bound1>::type,
+                              typename ::sigc::unwrap_reference<T_bound2>::type>
+                              (_A_functor, _A_b1, _A_b2); 
+}
+
+template <class T_bound1, class T_bound2, class T_bound3, class T_functor>
+inline ::sigc::bind_functor<-1, T_functor,
+                            typename ::sigc::unwrap_reference<T_bound1>::type,
+                            typename ::sigc::unwrap_reference<T_bound2>::type,
+                            typename ::sigc::unwrap_reference<T_bound3>::type>
+bind(const T_functor& _A_functor, T_bound1 _A_b1, T_bound2 _A_b2,T_bound3 _A_b3)
+{ return ::sigc::bind_functor<-1, T_functor,
+                              typename ::sigc::unwrap_reference<T_bound1>::type,
+                              typename ::sigc::unwrap_reference<T_bound2>::type,
+                              typename ::sigc::unwrap_reference<T_bound3>::type>
+                              (_A_functor, _A_b1, _A_b2, _A_b3);
+}
+
+}
+
+#endif /* LIBSIGC_DISABLE_DEPRECATED */
+
+#endif /* _SIGC_BIND_HPP_ */
diff --git a/libs/sigc++2/sigc++/bind_return.h b/libs/sigc++2/sigc++/bind_return.h
new file mode 100644
index 0000000000..a0796cf2c3
--- /dev/null
+++ b/libs/sigc++2/sigc++/bind_return.h
@@ -0,0 +1,34 @@
+/*
+ * Copyright 2002, The libsigc++ Development Team
+ *
+ *  This library is free software; you can redistribute it and/or
+ *  modify it under the terms of the GNU Lesser General Public
+ *  License as published by the Free Software Foundation; either
+ *  version 2.1 of the License, or (at your option) any later version.
+ *
+ *  This library is distributed in the hope that it will be useful,
+ *  but WITHOUT ANY WARRANTY; without even the implied warranty of
+ *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
+ *  Lesser General Public License for more details.
+ *
+ *  You should have received a copy of the GNU Lesser General Public
+ *  License along with this library; if not, write to the Free Software
+ *  Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
+ *
+ */
+#ifndef _SIGC_BIND_RETURN_HPP_
+#define _SIGC_BIND_RETURN_HPP_
+
+#include <sigc++/adaptors/bind_return.h>
+
+#ifndef LIBSIGC_DISABLE_DEPRECATED
+
+namespace SigC {
+
+using ::sigc::bind_return;
+
+}
+
+#endif /* LIBSIGC_DISABLE_DEPRECATED */
+
+#endif /* _SIGC_BIND_RETURN_HPP_ */
diff --git a/libs/sigc++2/sigc++/class_slot.h b/libs/sigc++2/sigc++/class_slot.h
new file mode 100644
index 0000000000..df644bfd04
--- /dev/null
+++ b/libs/sigc++2/sigc++/class_slot.h
@@ -0,0 +1,568 @@
+// -*- c++ -*-
+/* Do not edit! -- generated file */
+
+
+#ifndef _SIGC_MACROS_CLASS_SLOTHM4_
+#define _SIGC_MACROS_CLASS_SLOTHM4_
+
+#include <sigc++/slot.h>
+#include <sigc++/functors/mem_fun.h>
+
+#ifndef LIBSIGC_DISABLE_DEPRECATED
+
+namespace SigC {
+
+// slot_class()
+/** Creates a functor of type SigC::Slot0 that encapsulates a  method and an object instance.
+ *
+ * This function is part of the compatibility module and therefore deprecated.
+ * Use sigc::mem_fun() instead.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_obj>
+inline Slot0<T_return>
+slot_class( T_obj& _A_obj, T_return (T_obj::*_A_func)() )
+{ return ::sigc::bound_mem_functor0<T_return, T_obj>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot1 that encapsulates a  method and an object instance.
+ *
+ * This function is part of the compatibility module and therefore deprecated.
+ * Use sigc::mem_fun() instead.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1, class T_obj>
+inline Slot1<T_return, T_arg1>
+slot_class( T_obj& _A_obj, T_return (T_obj::*_A_func)(T_arg1) )
+{ return ::sigc::bound_mem_functor1<T_return, T_obj, T_arg1>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot2 that encapsulates a  method and an object instance.
+ *
+ * This function is part of the compatibility module and therefore deprecated.
+ * Use sigc::mem_fun() instead.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2, class T_obj>
+inline Slot2<T_return, T_arg1,T_arg2>
+slot_class( T_obj& _A_obj, T_return (T_obj::*_A_func)(T_arg1,T_arg2) )
+{ return ::sigc::bound_mem_functor2<T_return, T_obj, T_arg1,T_arg2>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot3 that encapsulates a  method and an object instance.
+ *
+ * This function is part of the compatibility module and therefore deprecated.
+ * Use sigc::mem_fun() instead.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3, class T_obj>
+inline Slot3<T_return, T_arg1,T_arg2,T_arg3>
+slot_class( T_obj& _A_obj, T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3) )
+{ return ::sigc::bound_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot4 that encapsulates a  method and an object instance.
+ *
+ * This function is part of the compatibility module and therefore deprecated.
+ * Use sigc::mem_fun() instead.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_obj>
+inline Slot4<T_return, T_arg1,T_arg2,T_arg3,T_arg4>
+slot_class( T_obj& _A_obj, T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4) )
+{ return ::sigc::bound_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot5 that encapsulates a  method and an object instance.
+ *
+ * This function is part of the compatibility module and therefore deprecated.
+ * Use sigc::mem_fun() instead.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_obj>
+inline Slot5<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+slot_class( T_obj& _A_obj, T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) )
+{ return ::sigc::bound_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot6 that encapsulates a  method and an object instance.
+ *
+ * This function is part of the compatibility module and therefore deprecated.
+ * Use sigc::mem_fun() instead.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_obj>
+inline Slot6<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+slot_class( T_obj& _A_obj, T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) )
+{ return ::sigc::bound_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot7 that encapsulates a  method and an object instance.
+ *
+ * This function is part of the compatibility module and therefore deprecated.
+ * Use sigc::mem_fun() instead.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_obj>
+inline Slot7<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+slot_class( T_obj& _A_obj, T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7) )
+{ return ::sigc::bound_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>(_A_obj, _A_func); }
+
+
+/** Creates a functor of type SigC::Slot0 that encapsulates a const method and an object instance.
+ *
+ * This function is part of the compatibility module and therefore deprecated.
+ * Use sigc::mem_fun() instead.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_obj>
+inline Slot0<T_return>
+slot_class(const T_obj& _A_obj, T_return (T_obj::*_A_func)() const)
+{ return ::sigc::bound_const_mem_functor0<T_return, T_obj>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot1 that encapsulates a const method and an object instance.
+ *
+ * This function is part of the compatibility module and therefore deprecated.
+ * Use sigc::mem_fun() instead.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1, class T_obj>
+inline Slot1<T_return, T_arg1>
+slot_class(const T_obj& _A_obj, T_return (T_obj::*_A_func)(T_arg1) const)
+{ return ::sigc::bound_const_mem_functor1<T_return, T_obj, T_arg1>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot2 that encapsulates a const method and an object instance.
+ *
+ * This function is part of the compatibility module and therefore deprecated.
+ * Use sigc::mem_fun() instead.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2, class T_obj>
+inline Slot2<T_return, T_arg1,T_arg2>
+slot_class(const T_obj& _A_obj, T_return (T_obj::*_A_func)(T_arg1,T_arg2) const)
+{ return ::sigc::bound_const_mem_functor2<T_return, T_obj, T_arg1,T_arg2>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot3 that encapsulates a const method and an object instance.
+ *
+ * This function is part of the compatibility module and therefore deprecated.
+ * Use sigc::mem_fun() instead.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3, class T_obj>
+inline Slot3<T_return, T_arg1,T_arg2,T_arg3>
+slot_class(const T_obj& _A_obj, T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3) const)
+{ return ::sigc::bound_const_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot4 that encapsulates a const method and an object instance.
+ *
+ * This function is part of the compatibility module and therefore deprecated.
+ * Use sigc::mem_fun() instead.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_obj>
+inline Slot4<T_return, T_arg1,T_arg2,T_arg3,T_arg4>
+slot_class(const T_obj& _A_obj, T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4) const)
+{ return ::sigc::bound_const_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot5 that encapsulates a const method and an object instance.
+ *
+ * This function is part of the compatibility module and therefore deprecated.
+ * Use sigc::mem_fun() instead.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_obj>
+inline Slot5<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+slot_class(const T_obj& _A_obj, T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) const)
+{ return ::sigc::bound_const_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot6 that encapsulates a const method and an object instance.
+ *
+ * This function is part of the compatibility module and therefore deprecated.
+ * Use sigc::mem_fun() instead.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_obj>
+inline Slot6<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+slot_class(const T_obj& _A_obj, T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) const)
+{ return ::sigc::bound_const_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot7 that encapsulates a const method and an object instance.
+ *
+ * This function is part of the compatibility module and therefore deprecated.
+ * Use sigc::mem_fun() instead.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_obj>
+inline Slot7<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+slot_class(const T_obj& _A_obj, T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7) const)
+{ return ::sigc::bound_const_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>(_A_obj, _A_func); }
+
+
+/** Creates a functor of type SigC::Slot0 that encapsulates a volatile method and an object instance.
+ *
+ * This function is part of the compatibility module and therefore deprecated.
+ * Use sigc::mem_fun() instead.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_obj>
+inline Slot0<T_return>
+slot_class( T_obj& _A_obj, T_return (T_obj::*_A_func)() volatile)
+{ return ::sigc::bound_volatile_mem_functor0<T_return, T_obj>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot1 that encapsulates a volatile method and an object instance.
+ *
+ * This function is part of the compatibility module and therefore deprecated.
+ * Use sigc::mem_fun() instead.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1, class T_obj>
+inline Slot1<T_return, T_arg1>
+slot_class( T_obj& _A_obj, T_return (T_obj::*_A_func)(T_arg1) volatile)
+{ return ::sigc::bound_volatile_mem_functor1<T_return, T_obj, T_arg1>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot2 that encapsulates a volatile method and an object instance.
+ *
+ * This function is part of the compatibility module and therefore deprecated.
+ * Use sigc::mem_fun() instead.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2, class T_obj>
+inline Slot2<T_return, T_arg1,T_arg2>
+slot_class( T_obj& _A_obj, T_return (T_obj::*_A_func)(T_arg1,T_arg2) volatile)
+{ return ::sigc::bound_volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot3 that encapsulates a volatile method and an object instance.
+ *
+ * This function is part of the compatibility module and therefore deprecated.
+ * Use sigc::mem_fun() instead.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3, class T_obj>
+inline Slot3<T_return, T_arg1,T_arg2,T_arg3>
+slot_class( T_obj& _A_obj, T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3) volatile)
+{ return ::sigc::bound_volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot4 that encapsulates a volatile method and an object instance.
+ *
+ * This function is part of the compatibility module and therefore deprecated.
+ * Use sigc::mem_fun() instead.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_obj>
+inline Slot4<T_return, T_arg1,T_arg2,T_arg3,T_arg4>
+slot_class( T_obj& _A_obj, T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4) volatile)
+{ return ::sigc::bound_volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot5 that encapsulates a volatile method and an object instance.
+ *
+ * This function is part of the compatibility module and therefore deprecated.
+ * Use sigc::mem_fun() instead.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_obj>
+inline Slot5<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+slot_class( T_obj& _A_obj, T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) volatile)
+{ return ::sigc::bound_volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot6 that encapsulates a volatile method and an object instance.
+ *
+ * This function is part of the compatibility module and therefore deprecated.
+ * Use sigc::mem_fun() instead.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_obj>
+inline Slot6<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+slot_class( T_obj& _A_obj, T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) volatile)
+{ return ::sigc::bound_volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot7 that encapsulates a volatile method and an object instance.
+ *
+ * This function is part of the compatibility module and therefore deprecated.
+ * Use sigc::mem_fun() instead.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_obj>
+inline Slot7<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+slot_class( T_obj& _A_obj, T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7) volatile)
+{ return ::sigc::bound_volatile_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>(_A_obj, _A_func); }
+
+
+/** Creates a functor of type SigC::Slot0 that encapsulates a const volatile method and an object instance.
+ *
+ * This function is part of the compatibility module and therefore deprecated.
+ * Use sigc::mem_fun() instead.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_obj>
+inline Slot0<T_return>
+slot_class(const T_obj& _A_obj, T_return (T_obj::*_A_func)() const volatile)
+{ return ::sigc::bound_const_volatile_mem_functor0<T_return, T_obj>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot1 that encapsulates a const volatile method and an object instance.
+ *
+ * This function is part of the compatibility module and therefore deprecated.
+ * Use sigc::mem_fun() instead.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1, class T_obj>
+inline Slot1<T_return, T_arg1>
+slot_class(const T_obj& _A_obj, T_return (T_obj::*_A_func)(T_arg1) const volatile)
+{ return ::sigc::bound_const_volatile_mem_functor1<T_return, T_obj, T_arg1>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot2 that encapsulates a const volatile method and an object instance.
+ *
+ * This function is part of the compatibility module and therefore deprecated.
+ * Use sigc::mem_fun() instead.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2, class T_obj>
+inline Slot2<T_return, T_arg1,T_arg2>
+slot_class(const T_obj& _A_obj, T_return (T_obj::*_A_func)(T_arg1,T_arg2) const volatile)
+{ return ::sigc::bound_const_volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot3 that encapsulates a const volatile method and an object instance.
+ *
+ * This function is part of the compatibility module and therefore deprecated.
+ * Use sigc::mem_fun() instead.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3, class T_obj>
+inline Slot3<T_return, T_arg1,T_arg2,T_arg3>
+slot_class(const T_obj& _A_obj, T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3) const volatile)
+{ return ::sigc::bound_const_volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot4 that encapsulates a const volatile method and an object instance.
+ *
+ * This function is part of the compatibility module and therefore deprecated.
+ * Use sigc::mem_fun() instead.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_obj>
+inline Slot4<T_return, T_arg1,T_arg2,T_arg3,T_arg4>
+slot_class(const T_obj& _A_obj, T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4) const volatile)
+{ return ::sigc::bound_const_volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot5 that encapsulates a const volatile method and an object instance.
+ *
+ * This function is part of the compatibility module and therefore deprecated.
+ * Use sigc::mem_fun() instead.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_obj>
+inline Slot5<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+slot_class(const T_obj& _A_obj, T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) const volatile)
+{ return ::sigc::bound_const_volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot6 that encapsulates a const volatile method and an object instance.
+ *
+ * This function is part of the compatibility module and therefore deprecated.
+ * Use sigc::mem_fun() instead.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_obj>
+inline Slot6<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+slot_class(const T_obj& _A_obj, T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) const volatile)
+{ return ::sigc::bound_const_volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot7 that encapsulates a const volatile method and an object instance.
+ *
+ * This function is part of the compatibility module and therefore deprecated.
+ * Use sigc::mem_fun() instead.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_obj>
+inline Slot7<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+slot_class(const T_obj& _A_obj, T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7) const volatile)
+{ return ::sigc::bound_const_volatile_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>(_A_obj, _A_func); }
+
+
+
+}
+
+#endif
+#endif /* _SIGC_MACROS_CLASS_SLOTHM4_ */
diff --git a/libs/sigc++2/sigc++/compatibility.h b/libs/sigc++2/sigc++/compatibility.h
new file mode 100644
index 0000000000..3c5006c0f0
--- /dev/null
+++ b/libs/sigc++2/sigc++/compatibility.h
@@ -0,0 +1,42 @@
+/*
+ * Copyright 2002, The libsigc++ Development Team
+ *
+ *  This library is free software; you can redistribute it and/or
+ *  modify it under the terms of the GNU Lesser General Public
+ *  License as published by the Free Software Foundation; either
+ *  version 2.1 of the License, or (at your option) any later version.
+ *
+ *  This library is distributed in the hope that it will be useful,
+ *  but WITHOUT ANY WARRANTY; without even the implied warranty of
+ *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
+ *  Lesser General Public License for more details.
+ *
+ *  You should have received a copy of the GNU Lesser General Public
+ *  License along with this library; if not, write to the Free Software
+ *  Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
+ *
+ */
+#ifndef _SIGC_COMPATIBILITY_HPP_
+#define _SIGC_COMPATIBILITY_HPP_
+
+#include <sigc++/signal.h>
+#include <sigc++/connection.h>
+#include <sigc++/object_slot.h>
+
+#ifndef LIBSIGC_DISABLE_DEPRECATED
+
+namespace SigC {
+
+/** @defgroup compat Compatibility module
+ * This set of types and functions provides an API that is compatible to
+ * libsigc++-1.2. Some internal structures of libsigc++-1.2 are not available.
+ *
+ * All types and functions that are defined in namespace SigC are deprecated.
+ * Use the new libsigc++2 API that is defined in namespace sigc.
+ */
+
+}
+
+#endif /* LIBSIGC_DISABLE_DEPRECATED */
+
+#endif /* _SIGC_COMPATIBILITY_HPP_ */
diff --git a/libs/sigc++2/sigc++/connection.cc b/libs/sigc++2/sigc++/connection.cc
new file mode 100644
index 0000000000..8f4363482f
--- /dev/null
+++ b/libs/sigc++2/sigc++/connection.cc
@@ -0,0 +1,111 @@
+// -*- c++ -*-
+/*
+ * Copyright 2002, The libsigc++ Development Team
+ *
+ *  This library is free software; you can redistribute it and/or
+ *  modify it under the terms of the GNU Lesser General Public
+ *  License as published by the Free Software Foundation; either
+ *  version 2.1 of the License, or (at your option) any later version.
+ *
+ *  This library is distributed in the hope that it will be useful,
+ *  but WITHOUT ANY WARRANTY; without even the implied warranty of
+ *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
+ *  Lesser General Public License for more details.
+ *
+ *  You should have received a copy of the GNU Lesser General Public
+ *  License along with this library; if not, write to the Free Software
+ *  Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
+ *
+ */
+
+#include <sigc++/connection.h>
+using namespace std;
+
+namespace sigc {
+
+connection::connection()
+: slot_(0)
+{}
+
+connection::connection(const connection& c)
+: slot_(c.slot_)
+{
+  //Let the connection forget about the signal handler when the handler object dies:
+  if (slot_)
+    slot_->add_destroy_notify_callback(this, &notify);
+}
+
+connection::connection(slot_base& sl)
+: slot_(&sl)
+{
+  //Let the connection forget about the signal handler when the handler object dies:
+  slot_->add_destroy_notify_callback(this, &notify);
+}
+
+connection& connection::operator=(const connection& c)
+{
+  set_slot(c.slot_);
+  return *this;
+}
+
+connection::~connection()
+{
+  if (slot_)
+    slot_->remove_destroy_notify_callback(this);
+}
+
+bool connection::empty() const
+{
+  return (!slot_ || slot_->empty());
+}
+
+bool connection::connected() const
+{
+  return !empty();
+}
+
+bool connection::blocked() const
+{
+  return (slot_ ? slot_->blocked() : false);
+}
+
+bool connection::block(bool should_block)
+{
+  return (slot_ ? slot_->block(should_block) : false);
+}
+
+bool connection::unblock()
+{
+  return (slot_ ? slot_->unblock() : false);
+}
+
+void connection::disconnect()
+{
+  if (slot_)
+    slot_->disconnect(); // This notifies slot_'s parent.
+} 
+
+connection::operator bool()
+{
+  return !empty();
+}
+    
+void connection::set_slot(slot_base* sl)
+{
+  if (slot_)
+    slot_->remove_destroy_notify_callback(this);
+
+  slot_ = sl;
+
+  if (slot_)
+    slot_->add_destroy_notify_callback(this, &notify);
+}
+
+void* connection::notify(void* data)
+{
+  connection* self = (connection*)data;
+  self->slot_ = 0;
+  return 0;
+}
+
+} /* namespace sigc */
diff --git a/libs/sigc++2/sigc++/connection.h b/libs/sigc++2/sigc++/connection.h
new file mode 100644
index 0000000000..170db55618
--- /dev/null
+++ b/libs/sigc++2/sigc++/connection.h
@@ -0,0 +1,154 @@
+/*
+ * Copyright 2002, The libsigc++ Development Team
+ *
+ *  This library is free software; you can redistribute it and/or
+ *  modify it under the terms of the GNU Lesser General Public
+ *  License as published by the Free Software Foundation; either
+ *  version 2.1 of the License, or (at your option) any later version.
+ *
+ *  This library is distributed in the hope that it will be useful,
+ *  but WITHOUT ANY WARRANTY; without even the implied warranty of
+ *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
+ *  Lesser General Public License for more details.
+ *
+ *  You should have received a copy of the GNU Lesser General Public
+ *  License along with this library; if not, write to the Free Software
+ *  Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
+ *
+ */
+#ifndef _SIGC_CONNECTION_HPP_
+#define _SIGC_CONNECTION_HPP_
+#include <sigc++config.h>
+#include <sigc++/signal.h>
+
+namespace sigc {
+
+/** Convinience class for safe disconnection.
+ * Iterators must not be used beyond the lifetime of the list
+ * they work on. A connection object can be created from a
+ * slot list iterator and may safely be used to disconnect
+ * the referred slot at any time (disconnect()). If the slot
+ * has already been destroyed, disconnect() does nothing. empty() or
+ * operator bool() can be used to test whether the connection is
+ * still active. The connection can be blocked (block(), unblock()).
+ *
+ * This is possible because the connection object gets notified
+ * when the referred slot dies (notify()).
+ *
+ * @ingroup signal
+ */
+struct SIGC_API connection
+{
+  /** Constructs an empty connection object. */
+  connection();
+
+  /** Constructs a connection object copying an existing one.
+   * @param c The connection object to make a copy from.
+   */
+  connection(const connection& c);
+
+  /** Constructs a connection object from a slot list iterator.
+   * @param it The slot list iterator to take the slot from.
+   */
+  template <typename T_slot>
+  connection(const slot_iterator<T_slot>& it) : slot_(&(*it))
+    { if (slot_) slot_->add_destroy_notify_callback(this, &notify); }
+
+  /** Constructs a connection object from a slot object.
+   * This is only useful if you create your own slot list.
+   * @param sl The slot to operate on.
+   */
+  explicit connection(slot_base& sl);
+
+  /** Overrides this connection object copying another one.
+   * @param c The connection object to make a copy from.
+   */
+  connection& operator=(const connection& c);
+
+  /** Overrides this connection object with another slot list iterator.
+   * @param it The new slot list iterator to take the slot from.
+   */
+  template <typename T_slot>
+  connection& operator=(const slot_iterator<T_slot>& it)
+    { set_slot(&(*it)); return *this; }
+
+  ~connection();
+
+  /** Returns whether the connection is still active.
+   * @return @p false if the connection is still active.
+   */
+  bool empty() const;
+
+  /** Returns whether the connection is still active.
+   * @return @p true if the connection is still active.
+   */
+  bool connected() const;
+
+  /** Returns whether the connection is blocked.
+   * @return @p true if the connection is blocked.
+   */
+  bool blocked() const;
+
+  /** Sets or unsets the blocking state of this connection.
+   * See slot_base::block() for details.
+   * @param should_block Indicates whether the blocking state should be set or unset.
+   * @return @p true if the connection has been in blocking state before.
+   */
+  bool block(bool should_block = true);
+
+  /** Unsets the blocking state of this connection.
+   * @return @p true if the connection has been in blocking state before.
+   */
+  bool unblock();
+
+  /// Disconnects the referred slot.
+  void disconnect();
+
+  /** Returns whether the connection is still active.
+   * @return @p true if the connection is still active.
+   */
+  operator bool();
+
+  /** Callback that is executed when the referred slot is destroyed.
+   * @param d The connection object notified (@p this).
+   */
+  static void* notify(void* data);
+
+private:
+  void set_slot(slot_base* sl);
+
+  /* Referred slot. Set to zero from notify().
+   * A value of zero indicates an "empty" connection.
+   */
+  slot_base* slot_;
+};
+
+} /* namespace sigc */
+
+
+#ifndef LIBSIGC_DISABLE_DEPRECATED
+
+namespace SigC {
+
+/** Convinience class for safe disconnection.
+ * Iterators must not be used beyond the lifetime of the list
+ * they work on. A connection object can be created from a
+ * slot list iterator and may safely be used to disconnect
+ * the referred slot at any time (disconnect()). If the slot
+ * has already been destroyed, disconnect() does nothing. empty() or
+ * operator bool() can be used to test whether the connection is
+ * still active. The connection can be blocked (block(), unblock()).
+ *
+ * This is possible because the connection object gets notified
+ * when the referred slot dies (notify()).
+ *
+ * @deprecated Use sigc::connection instead.
+ * @ingroup compat
+ */
+typedef ::sigc::connection Connection;
+
+}
+
+#endif /* LIBSIGC_DISABLE_DEPRECATED */
+
+#endif /* _SIGC_TRACKABLE_HPP_ */
diff --git a/libs/sigc++2/sigc++/functors/functor_trait.h b/libs/sigc++2/sigc++/functors/functor_trait.h
new file mode 100644
index 0000000000..656d010414
--- /dev/null
+++ b/libs/sigc++2/sigc++/functors/functor_trait.h
@@ -0,0 +1,307 @@
+// -*- c++ -*-
+/* Do not edit! -- generated file */
+/*
+  Trait functor_trait<functor>:
+
+  This trait allows the user to specific what is the return type
+  of any type. It has been overloaded to detect the return type and
+  the functor version of function pointers and class methods as well.
+
+  To populate the return type of user defined and third party functors
+  use the macro SIGC_FUNCTOR_TRAIT(T_functor,T_return) in
+  namespace sigc. Multi-type functors are only partly supported.
+  Try specifying the return type of the functor's operator()() overload.
+
+  Alternatively, you can derive your functors from functor_base and
+  place "typedef T_return result_type;" in the class definition.
+
+  Use SIGC_FUNCTORS_HAVE_RESULT_TYPE if you want sigc++ to assume that
+  result_type is defined in all user defined or 3rd-party functors
+  (except those you specify a return type explicitly with SIGC_FUNCTOR_TRAIT()).
+
+*/
+#ifndef _SIGC_FUNCTORS_MACROS_FUNCTOR_TRAITHM4_
+#define _SIGC_FUNCTORS_MACROS_FUNCTOR_TRAITHM4_
+#include <sigc++/type_traits.h>
+
+
+namespace sigc {
+
+/** nil struct type.
+ * The nil struct type is used as default template argument in the
+ * unnumbered sigc::signal and sigc::slot templates.
+ *
+ * @ingroup signal
+ * @ingroup slot
+ */
+struct nil;
+
+
+/** @defgroup functors Functors
+ * Functors are copyable types that define operator()().
+ *
+ * Types that define operator()() overloads with different return types are referred to
+ * as multi-type functors. Multi-type functors are only partly supported in libsigc++.
+ *
+ * Closures are functors that store all information needed to invoke a callback from operator()().
+ *
+ * Adaptors are functors that alter the signature of a functor's operator()().
+ *
+ * libsigc++ defines numerous functors, closures and adaptors.
+ * Since libsigc++ is a callback libaray, most functors are also closures.
+ * The documentation doesn't distinguish between functors and closures.
+ *
+ * The basic functor types libsigc++ provides are created with ptr_fun() and mem_fun()
+ * and can be converted into slots implicitly.
+ * The set of adaptors that ships with libsigc++ is documented in the equally named module. 
+ */
+
+/** A hint to the compiler.
+ * All functors which define @p result_type should publically inherit from this hint.
+ *
+ * @ingroup functors
+ */
+struct functor_base {};
+
+
+template <class T_functor, bool I_derives_functor_base=is_base_and_derived<functor_base,T_functor>::value>
+struct functor_trait
+{
+  typedef void result_type;
+  typedef T_functor functor_type;
+};
+
+template <class T_functor>
+struct functor_trait<T_functor,true>
+{
+  typedef typename T_functor::result_type result_type;
+  typedef T_functor functor_type;
+};
+
+/** If you want to mix functors from a different library with libsigc++ and
+ * these functors define @p result_type simply use this macro inside namespace sigc like so:
+ * @code
+ * namespace sigc { SIGC_FUNCTORS_HAVE_RESULT_TYPE }
+ * @endcode
+ *
+ * @ingroup functors
+ */
+#define SIGC_FUNCTORS_HAVE_RESULT_TYPE                 \
+template <class T_functor>                             \
+struct functor_trait<T_functor,false>                  \
+{                                                      \
+  typedef typename T_functor::result_type result_type; \
+  typedef T_functor functor_type;                      \
+};
+
+/** If you want to mix functors from a different library with libsigc++ and
+ * these functors don't define @p result_type use this macro inside namespace sigc
+ * to expose the return type of the functors like so:
+ * @code
+ * namespace sigc {
+ *   SIGC_FUNCTOR_TRAIT(first_functor_type, return_type_of_first_functor_type)
+ *   SIGC_FUNCTOR_TRAIT(second_functor_type, return_type_of_second_functor_type)
+ *   ...
+ * }
+ * @endcode
+ *
+ * @ingroup functors
+ */
+#define SIGC_FUNCTOR_TRAIT(T_functor,T_return) \
+template <>                                    \
+struct functor_trait<T_functor,false>          \
+{                                              \
+  typedef T_return result_type;                \
+  typedef T_functor functor_type;              \
+};
+
+// detect the return type and the functor version of non-functor types.
+template <class T_return> class pointer_functor0;
+template <class T_return>
+struct functor_trait<T_return (*)(), false>
+{
+  typedef T_return result_type;
+  typedef pointer_functor0<T_return> functor_type;
+};
+
+template <class T_arg1, class T_return> class pointer_functor1;
+template <class T_arg1, class T_return>
+struct functor_trait<T_return (*)(T_arg1), false>
+{
+  typedef T_return result_type;
+  typedef pointer_functor1<T_arg1, T_return> functor_type;
+};
+
+template <class T_arg1,class T_arg2, class T_return> class pointer_functor2;
+template <class T_arg1,class T_arg2, class T_return>
+struct functor_trait<T_return (*)(T_arg1,T_arg2), false>
+{
+  typedef T_return result_type;
+  typedef pointer_functor2<T_arg1,T_arg2, T_return> functor_type;
+};
+
+template <class T_arg1,class T_arg2,class T_arg3, class T_return> class pointer_functor3;
+template <class T_arg1,class T_arg2,class T_arg3, class T_return>
+struct functor_trait<T_return (*)(T_arg1,T_arg2,T_arg3), false>
+{
+  typedef T_return result_type;
+  typedef pointer_functor3<T_arg1,T_arg2,T_arg3, T_return> functor_type;
+};
+
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_return> class pointer_functor4;
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_return>
+struct functor_trait<T_return (*)(T_arg1,T_arg2,T_arg3,T_arg4), false>
+{
+  typedef T_return result_type;
+  typedef pointer_functor4<T_arg1,T_arg2,T_arg3,T_arg4, T_return> functor_type;
+};
+
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_return> class pointer_functor5;
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_return>
+struct functor_trait<T_return (*)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5), false>
+{
+  typedef T_return result_type;
+  typedef pointer_functor5<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5, T_return> functor_type;
+};
+
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_return> class pointer_functor6;
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_return>
+struct functor_trait<T_return (*)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6), false>
+{
+  typedef T_return result_type;
+  typedef pointer_functor6<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6, T_return> functor_type;
+};
+
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_return> class pointer_functor7;
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_return>
+struct functor_trait<T_return (*)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7), false>
+{
+  typedef T_return result_type;
+  typedef pointer_functor7<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7, T_return> functor_type;
+};
+
+
+template <class T_return, class T_obj> class mem_functor0;
+template <class T_return, class T_obj> class const_mem_functor0;
+template <class T_return, class T_obj>
+struct functor_trait<T_return (T_obj::*)(), false>
+{
+  typedef T_return result_type;
+  typedef mem_functor0<T_return, T_obj> functor_type;
+};
+template <class T_return, class T_obj>
+struct functor_trait<T_return (T_obj::*)() const, false>
+{
+  typedef T_return result_type;
+  typedef const_mem_functor0<T_return, T_obj> functor_type;
+};
+
+template <class T_arg1, class T_return, class T_obj> class mem_functor1;
+template <class T_arg1, class T_return, class T_obj> class const_mem_functor1;
+template <class T_arg1, class T_return, class T_obj>
+struct functor_trait<T_return (T_obj::*)(T_arg1), false>
+{
+  typedef T_return result_type;
+  typedef mem_functor1<T_arg1, T_return, T_obj> functor_type;
+};
+template <class T_arg1, class T_return, class T_obj>
+struct functor_trait<T_return (T_obj::*)(T_arg1) const, false>
+{
+  typedef T_return result_type;
+  typedef const_mem_functor1<T_arg1, T_return, T_obj> functor_type;
+};
+
+template <class T_arg1,class T_arg2, class T_return, class T_obj> class mem_functor2;
+template <class T_arg1,class T_arg2, class T_return, class T_obj> class const_mem_functor2;
+template <class T_arg1,class T_arg2, class T_return, class T_obj>
+struct functor_trait<T_return (T_obj::*)(T_arg1,T_arg2), false>
+{
+  typedef T_return result_type;
+  typedef mem_functor2<T_arg1,T_arg2, T_return, T_obj> functor_type;
+};
+template <class T_arg1,class T_arg2, class T_return, class T_obj>
+struct functor_trait<T_return (T_obj::*)(T_arg1,T_arg2) const, false>
+{
+  typedef T_return result_type;
+  typedef const_mem_functor2<T_arg1,T_arg2, T_return, T_obj> functor_type;
+};
+
+template <class T_arg1,class T_arg2,class T_arg3, class T_return, class T_obj> class mem_functor3;
+template <class T_arg1,class T_arg2,class T_arg3, class T_return, class T_obj> class const_mem_functor3;
+template <class T_arg1,class T_arg2,class T_arg3, class T_return, class T_obj>
+struct functor_trait<T_return (T_obj::*)(T_arg1,T_arg2,T_arg3), false>
+{
+  typedef T_return result_type;
+  typedef mem_functor3<T_arg1,T_arg2,T_arg3, T_return, T_obj> functor_type;
+};
+template <class T_arg1,class T_arg2,class T_arg3, class T_return, class T_obj>
+struct functor_trait<T_return (T_obj::*)(T_arg1,T_arg2,T_arg3) const, false>
+{
+  typedef T_return result_type;
+  typedef const_mem_functor3<T_arg1,T_arg2,T_arg3, T_return, T_obj> functor_type;
+};
+
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_return, class T_obj> class mem_functor4;
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_return, class T_obj> class const_mem_functor4;
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_return, class T_obj>
+struct functor_trait<T_return (T_obj::*)(T_arg1,T_arg2,T_arg3,T_arg4), false>
+{
+  typedef T_return result_type;
+  typedef mem_functor4<T_arg1,T_arg2,T_arg3,T_arg4, T_return, T_obj> functor_type;
+};
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_return, class T_obj>
+struct functor_trait<T_return (T_obj::*)(T_arg1,T_arg2,T_arg3,T_arg4) const, false>
+{
+  typedef T_return result_type;
+  typedef const_mem_functor4<T_arg1,T_arg2,T_arg3,T_arg4, T_return, T_obj> functor_type;
+};
+
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_return, class T_obj> class mem_functor5;
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_return, class T_obj> class const_mem_functor5;
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_return, class T_obj>
+struct functor_trait<T_return (T_obj::*)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5), false>
+{
+  typedef T_return result_type;
+  typedef mem_functor5<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5, T_return, T_obj> functor_type;
+};
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_return, class T_obj>
+struct functor_trait<T_return (T_obj::*)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) const, false>
+{
+  typedef T_return result_type;
+  typedef const_mem_functor5<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5, T_return, T_obj> functor_type;
+};
+
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_return, class T_obj> class mem_functor6;
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_return, class T_obj> class const_mem_functor6;
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_return, class T_obj>
+struct functor_trait<T_return (T_obj::*)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6), false>
+{
+  typedef T_return result_type;
+  typedef mem_functor6<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6, T_return, T_obj> functor_type;
+};
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_return, class T_obj>
+struct functor_trait<T_return (T_obj::*)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) const, false>
+{
+  typedef T_return result_type;
+  typedef const_mem_functor6<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6, T_return, T_obj> functor_type;
+};
+
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_return, class T_obj> class mem_functor7;
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_return, class T_obj> class const_mem_functor7;
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_return, class T_obj>
+struct functor_trait<T_return (T_obj::*)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7), false>
+{
+  typedef T_return result_type;
+  typedef mem_functor7<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7, T_return, T_obj> functor_type;
+};
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_return, class T_obj>
+struct functor_trait<T_return (T_obj::*)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7) const, false>
+{
+  typedef T_return result_type;
+  typedef const_mem_functor7<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7, T_return, T_obj> functor_type;
+};
+
+
+
+} /* namespace sigc */
+#endif /* _SIGC_FUNCTORS_MACROS_FUNCTOR_TRAITHM4_ */
diff --git a/libs/sigc++2/sigc++/functors/functors.h b/libs/sigc++2/sigc++/functors/functors.h
new file mode 100644
index 0000000000..3a9619c21d
--- /dev/null
+++ b/libs/sigc++2/sigc++/functors/functors.h
@@ -0,0 +1,27 @@
+// -*- c++ -*-
+/*
+ * Copyright 2002, The libsigc++ Development Team
+ *
+ *  This library is free software; you can redistribute it and/or
+ *  modify it under the terms of the GNU Lesser General Public
+ *  License as published by the Free Software Foundation; either
+ *  version 2.1 of the License, or (at your option) any later version.
+ *
+ *  This library is distributed in the hope that it will be useful,
+ *  but WITHOUT ANY WARRANTY; without even the implied warranty of
+ *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
+ *  Lesser General Public License for more details.
+ *
+ *  You should have received a copy of the GNU Lesser General Public
+ *  License along with this library; if not, write to the Free Software
+ *  Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
+ *
+ */
+#ifndef _SIGC_FUNCTOR_HPP_
+#define _SIGC_FUNCTOR_HPP_
+
+#include <sigc++/functors/slot.h>
+#include <sigc++/functors/ptr_fun.h>
+#include <sigc++/functors/mem_fun.h>
+
+#endif /* _SIGC_FUNCTOR_HPP_ */
diff --git a/libs/sigc++2/sigc++/functors/mem_fun.h b/libs/sigc++2/sigc++/functors/mem_fun.h
new file mode 100644
index 0000000000..2bd7cde67f
--- /dev/null
+++ b/libs/sigc++2/sigc++/functors/mem_fun.h
@@ -0,0 +1,5976 @@
+// -*- c++ -*-
+/* Do not edit! -- generated file */
+
+
+// implementation notes:  
+//  - we do not use bind here, because it would introduce
+//    an extra copy and complicate the header include order if bind is
+//    to have automatic conversion for member pointers.
+#ifndef _SIGC_FUNCTORS_MACROS_MEM_FUNHM4_
+#define _SIGC_FUNCTORS_MACROS_MEM_FUNHM4_
+#include <sigc++/type_traits.h>
+#include <sigc++/functors/functor_trait.h>
+
+namespace sigc {
+
+/** @defgroup mem_fun mem_fun()
+ * mem_fun() is used to convert a pointer to a method to a functor.
+ *
+ * Optionally a reference or pointer to an object can be bound to the functor.
+ * Note that only if the object type inherits from sigc::trackable
+ * the slot is cleared automatically when the object goes out of scope!
+ *
+ * If the member function pointer is to an overloaded type, you must specify
+ * the types using template arguments starting with the first argument.
+ * It is not necessary to supply the return type.
+ *
+ * @par Example:
+ *   @code
+ *   struct foo : public sigc::trackable
+ *   {
+ *     void bar(int) {}
+ *   };
+ *   foo my_foo;
+ *   sigc::slot<void, int> sl = sigc::mem_fun(my_foo, &foo::bar);
+ *   @endcode
+ *
+ * For const methods mem_fun() takes a const reference or pointer to an object.
+ *
+ * @par Example:
+ *   @code
+ *   struct foo : public sigc::trackable
+ *   {
+ *     void bar(int) const {}
+ *   };
+ *   const foo my_foo;
+ *   sigc::slot<void, int> sl = sigc::mem_fun(my_foo, &foo::bar);
+ *   @endcode
+ *
+ * Use mem_fun#() if there is an abiguity as to the number of arguments.
+ *
+ * @par Example:
+ *   @code
+ *   struct foo : public sigc::trackable
+ *   {
+ *     void bar(int) {}
+ *     void bar(float) {}
+ *     void bar(int, int) {}
+ *   };
+ *   foo my_foo;
+ *   sigc::slot<void, int> sl = sigc::mem_fun1<int>(my_foo, &foo::bar);
+ *   @endcode
+ *
+ * @ingroup functors
+ */
+
+/** mem_functor0 wraps  methods with 0 argument(s).
+ * Use the convenience function mem_fun() to create an instance of mem_functor0.
+ *
+ * The following template arguments are used:
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj>
+class mem_functor0 : public functor_base
+{
+public:
+  typedef T_return (T_obj::*function_type)() ;
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  mem_functor0() : func_ptr_(0) {}
+
+  /** Constructs a mem_functor0 object that wraps the passed method.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  explicit mem_functor0(function_type _A_func) : func_ptr_(_A_func) {}
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Pointer to instance the method should operate on.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(T_obj* _A_obj) const
+    { return (_A_obj->*(this->func_ptr_))(); }
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Reference to instance the method should operate on.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(T_obj& _A_obj) const
+    { return (_A_obj.*func_ptr_)(); }
+
+protected:
+  function_type func_ptr_;
+};
+
+/** mem_functor1 wraps  methods with 1 argument(s).
+ * Use the convenience function mem_fun() to create an instance of mem_functor1.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1>
+class mem_functor1 : public functor_base
+{
+public:
+  typedef T_return (T_obj::*function_type)(T_arg1) ;
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  mem_functor1() : func_ptr_(0) {}
+
+  /** Constructs a mem_functor1 object that wraps the passed method.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  explicit mem_functor1(function_type _A_func) : func_ptr_(_A_func) {}
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Pointer to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(T_obj* _A_obj, typename type_trait<T_arg1>::take _A_a1) const
+    { return (_A_obj->*(this->func_ptr_))(_A_a1); }
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Reference to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(T_obj& _A_obj, typename type_trait<T_arg1>::take _A_a1) const
+    { return (_A_obj.*func_ptr_)(_A_a1); }
+
+protected:
+  function_type func_ptr_;
+};
+
+/** mem_functor2 wraps  methods with 2 argument(s).
+ * Use the convenience function mem_fun() to create an instance of mem_functor2.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2>
+class mem_functor2 : public functor_base
+{
+public:
+  typedef T_return (T_obj::*function_type)(T_arg1,T_arg2) ;
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  mem_functor2() : func_ptr_(0) {}
+
+  /** Constructs a mem_functor2 object that wraps the passed method.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  explicit mem_functor2(function_type _A_func) : func_ptr_(_A_func) {}
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Pointer to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(T_obj* _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2) const
+    { return (_A_obj->*(this->func_ptr_))(_A_a1,_A_a2); }
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Reference to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(T_obj& _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2) const
+    { return (_A_obj.*func_ptr_)(_A_a1,_A_a2); }
+
+protected:
+  function_type func_ptr_;
+};
+
+/** mem_functor3 wraps  methods with 3 argument(s).
+ * Use the convenience function mem_fun() to create an instance of mem_functor3.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3>
+class mem_functor3 : public functor_base
+{
+public:
+  typedef T_return (T_obj::*function_type)(T_arg1,T_arg2,T_arg3) ;
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  mem_functor3() : func_ptr_(0) {}
+
+  /** Constructs a mem_functor3 object that wraps the passed method.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  explicit mem_functor3(function_type _A_func) : func_ptr_(_A_func) {}
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Pointer to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(T_obj* _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3) const
+    { return (_A_obj->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3); }
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Reference to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(T_obj& _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3) const
+    { return (_A_obj.*func_ptr_)(_A_a1,_A_a2,_A_a3); }
+
+protected:
+  function_type func_ptr_;
+};
+
+/** mem_functor4 wraps  methods with 4 argument(s).
+ * Use the convenience function mem_fun() to create an instance of mem_functor4.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+class mem_functor4 : public functor_base
+{
+public:
+  typedef T_return (T_obj::*function_type)(T_arg1,T_arg2,T_arg3,T_arg4) ;
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  mem_functor4() : func_ptr_(0) {}
+
+  /** Constructs a mem_functor4 object that wraps the passed method.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  explicit mem_functor4(function_type _A_func) : func_ptr_(_A_func) {}
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Pointer to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(T_obj* _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4) const
+    { return (_A_obj->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3,_A_a4); }
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Reference to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(T_obj& _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4) const
+    { return (_A_obj.*func_ptr_)(_A_a1,_A_a2,_A_a3,_A_a4); }
+
+protected:
+  function_type func_ptr_;
+};
+
+/** mem_functor5 wraps  methods with 5 argument(s).
+ * Use the convenience function mem_fun() to create an instance of mem_functor5.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_arg5 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+class mem_functor5 : public functor_base
+{
+public:
+  typedef T_return (T_obj::*function_type)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) ;
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  mem_functor5() : func_ptr_(0) {}
+
+  /** Constructs a mem_functor5 object that wraps the passed method.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  explicit mem_functor5(function_type _A_func) : func_ptr_(_A_func) {}
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Pointer to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @param _A_a5 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(T_obj* _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5) const
+    { return (_A_obj->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5); }
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Reference to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @param _A_a5 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(T_obj& _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5) const
+    { return (_A_obj.*func_ptr_)(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5); }
+
+protected:
+  function_type func_ptr_;
+};
+
+/** mem_functor6 wraps  methods with 6 argument(s).
+ * Use the convenience function mem_fun() to create an instance of mem_functor6.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_arg5 Argument type used in the definition of operator()().
+ * - @e T_arg6 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+class mem_functor6 : public functor_base
+{
+public:
+  typedef T_return (T_obj::*function_type)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) ;
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  mem_functor6() : func_ptr_(0) {}
+
+  /** Constructs a mem_functor6 object that wraps the passed method.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  explicit mem_functor6(function_type _A_func) : func_ptr_(_A_func) {}
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Pointer to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @param _A_a5 Argument to be passed on to the method.
+   * @param _A_a6 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(T_obj* _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6) const
+    { return (_A_obj->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6); }
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Reference to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @param _A_a5 Argument to be passed on to the method.
+   * @param _A_a6 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(T_obj& _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6) const
+    { return (_A_obj.*func_ptr_)(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6); }
+
+protected:
+  function_type func_ptr_;
+};
+
+/** mem_functor7 wraps  methods with 7 argument(s).
+ * Use the convenience function mem_fun() to create an instance of mem_functor7.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_arg5 Argument type used in the definition of operator()().
+ * - @e T_arg6 Argument type used in the definition of operator()().
+ * - @e T_arg7 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+class mem_functor7 : public functor_base
+{
+public:
+  typedef T_return (T_obj::*function_type)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7) ;
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  mem_functor7() : func_ptr_(0) {}
+
+  /** Constructs a mem_functor7 object that wraps the passed method.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  explicit mem_functor7(function_type _A_func) : func_ptr_(_A_func) {}
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Pointer to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @param _A_a5 Argument to be passed on to the method.
+   * @param _A_a6 Argument to be passed on to the method.
+   * @param _A_a7 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(T_obj* _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6,typename type_trait<T_arg7>::take _A_a7) const
+    { return (_A_obj->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6,_A_a7); }
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Reference to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @param _A_a5 Argument to be passed on to the method.
+   * @param _A_a6 Argument to be passed on to the method.
+   * @param _A_a7 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(T_obj& _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6,typename type_trait<T_arg7>::take _A_a7) const
+    { return (_A_obj.*func_ptr_)(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6,_A_a7); }
+
+protected:
+  function_type func_ptr_;
+};
+
+/** const_mem_functor0 wraps const methods with 0 argument(s).
+ * Use the convenience function mem_fun() to create an instance of const_mem_functor0.
+ *
+ * The following template arguments are used:
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj>
+class const_mem_functor0 : public functor_base
+{
+public:
+  typedef T_return (T_obj::*function_type)() const;
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  const_mem_functor0() : func_ptr_(0) {}
+
+  /** Constructs a const_mem_functor0 object that wraps the passed method.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  explicit const_mem_functor0(function_type _A_func) : func_ptr_(_A_func) {}
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Pointer to instance the method should operate on.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(const T_obj* _A_obj) const
+    { return (_A_obj->*(this->func_ptr_))(); }
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Reference to instance the method should operate on.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(const T_obj& _A_obj) const
+    { return (_A_obj.*func_ptr_)(); }
+
+protected:
+  function_type func_ptr_;
+};
+
+/** const_mem_functor1 wraps const methods with 1 argument(s).
+ * Use the convenience function mem_fun() to create an instance of const_mem_functor1.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1>
+class const_mem_functor1 : public functor_base
+{
+public:
+  typedef T_return (T_obj::*function_type)(T_arg1) const;
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  const_mem_functor1() : func_ptr_(0) {}
+
+  /** Constructs a const_mem_functor1 object that wraps the passed method.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  explicit const_mem_functor1(function_type _A_func) : func_ptr_(_A_func) {}
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Pointer to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(const T_obj* _A_obj, typename type_trait<T_arg1>::take _A_a1) const
+    { return (_A_obj->*(this->func_ptr_))(_A_a1); }
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Reference to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(const T_obj& _A_obj, typename type_trait<T_arg1>::take _A_a1) const
+    { return (_A_obj.*func_ptr_)(_A_a1); }
+
+protected:
+  function_type func_ptr_;
+};
+
+/** const_mem_functor2 wraps const methods with 2 argument(s).
+ * Use the convenience function mem_fun() to create an instance of const_mem_functor2.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2>
+class const_mem_functor2 : public functor_base
+{
+public:
+  typedef T_return (T_obj::*function_type)(T_arg1,T_arg2) const;
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  const_mem_functor2() : func_ptr_(0) {}
+
+  /** Constructs a const_mem_functor2 object that wraps the passed method.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  explicit const_mem_functor2(function_type _A_func) : func_ptr_(_A_func) {}
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Pointer to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(const T_obj* _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2) const
+    { return (_A_obj->*(this->func_ptr_))(_A_a1,_A_a2); }
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Reference to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(const T_obj& _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2) const
+    { return (_A_obj.*func_ptr_)(_A_a1,_A_a2); }
+
+protected:
+  function_type func_ptr_;
+};
+
+/** const_mem_functor3 wraps const methods with 3 argument(s).
+ * Use the convenience function mem_fun() to create an instance of const_mem_functor3.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3>
+class const_mem_functor3 : public functor_base
+{
+public:
+  typedef T_return (T_obj::*function_type)(T_arg1,T_arg2,T_arg3) const;
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  const_mem_functor3() : func_ptr_(0) {}
+
+  /** Constructs a const_mem_functor3 object that wraps the passed method.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  explicit const_mem_functor3(function_type _A_func) : func_ptr_(_A_func) {}
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Pointer to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(const T_obj* _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3) const
+    { return (_A_obj->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3); }
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Reference to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(const T_obj& _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3) const
+    { return (_A_obj.*func_ptr_)(_A_a1,_A_a2,_A_a3); }
+
+protected:
+  function_type func_ptr_;
+};
+
+/** const_mem_functor4 wraps const methods with 4 argument(s).
+ * Use the convenience function mem_fun() to create an instance of const_mem_functor4.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+class const_mem_functor4 : public functor_base
+{
+public:
+  typedef T_return (T_obj::*function_type)(T_arg1,T_arg2,T_arg3,T_arg4) const;
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  const_mem_functor4() : func_ptr_(0) {}
+
+  /** Constructs a const_mem_functor4 object that wraps the passed method.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  explicit const_mem_functor4(function_type _A_func) : func_ptr_(_A_func) {}
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Pointer to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(const T_obj* _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4) const
+    { return (_A_obj->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3,_A_a4); }
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Reference to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(const T_obj& _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4) const
+    { return (_A_obj.*func_ptr_)(_A_a1,_A_a2,_A_a3,_A_a4); }
+
+protected:
+  function_type func_ptr_;
+};
+
+/** const_mem_functor5 wraps const methods with 5 argument(s).
+ * Use the convenience function mem_fun() to create an instance of const_mem_functor5.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_arg5 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+class const_mem_functor5 : public functor_base
+{
+public:
+  typedef T_return (T_obj::*function_type)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) const;
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  const_mem_functor5() : func_ptr_(0) {}
+
+  /** Constructs a const_mem_functor5 object that wraps the passed method.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  explicit const_mem_functor5(function_type _A_func) : func_ptr_(_A_func) {}
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Pointer to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @param _A_a5 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(const T_obj* _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5) const
+    { return (_A_obj->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5); }
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Reference to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @param _A_a5 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(const T_obj& _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5) const
+    { return (_A_obj.*func_ptr_)(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5); }
+
+protected:
+  function_type func_ptr_;
+};
+
+/** const_mem_functor6 wraps const methods with 6 argument(s).
+ * Use the convenience function mem_fun() to create an instance of const_mem_functor6.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_arg5 Argument type used in the definition of operator()().
+ * - @e T_arg6 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+class const_mem_functor6 : public functor_base
+{
+public:
+  typedef T_return (T_obj::*function_type)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) const;
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  const_mem_functor6() : func_ptr_(0) {}
+
+  /** Constructs a const_mem_functor6 object that wraps the passed method.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  explicit const_mem_functor6(function_type _A_func) : func_ptr_(_A_func) {}
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Pointer to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @param _A_a5 Argument to be passed on to the method.
+   * @param _A_a6 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(const T_obj* _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6) const
+    { return (_A_obj->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6); }
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Reference to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @param _A_a5 Argument to be passed on to the method.
+   * @param _A_a6 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(const T_obj& _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6) const
+    { return (_A_obj.*func_ptr_)(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6); }
+
+protected:
+  function_type func_ptr_;
+};
+
+/** const_mem_functor7 wraps const methods with 7 argument(s).
+ * Use the convenience function mem_fun() to create an instance of const_mem_functor7.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_arg5 Argument type used in the definition of operator()().
+ * - @e T_arg6 Argument type used in the definition of operator()().
+ * - @e T_arg7 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+class const_mem_functor7 : public functor_base
+{
+public:
+  typedef T_return (T_obj::*function_type)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7) const;
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  const_mem_functor7() : func_ptr_(0) {}
+
+  /** Constructs a const_mem_functor7 object that wraps the passed method.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  explicit const_mem_functor7(function_type _A_func) : func_ptr_(_A_func) {}
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Pointer to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @param _A_a5 Argument to be passed on to the method.
+   * @param _A_a6 Argument to be passed on to the method.
+   * @param _A_a7 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(const T_obj* _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6,typename type_trait<T_arg7>::take _A_a7) const
+    { return (_A_obj->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6,_A_a7); }
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Reference to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @param _A_a5 Argument to be passed on to the method.
+   * @param _A_a6 Argument to be passed on to the method.
+   * @param _A_a7 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(const T_obj& _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6,typename type_trait<T_arg7>::take _A_a7) const
+    { return (_A_obj.*func_ptr_)(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6,_A_a7); }
+
+protected:
+  function_type func_ptr_;
+};
+
+/** volatile_mem_functor0 wraps volatile methods with 0 argument(s).
+ * Use the convenience function mem_fun() to create an instance of volatile_mem_functor0.
+ *
+ * The following template arguments are used:
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj>
+class volatile_mem_functor0 : public functor_base
+{
+public:
+  typedef T_return (T_obj::*function_type)() volatile;
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  volatile_mem_functor0() : func_ptr_(0) {}
+
+  /** Constructs a volatile_mem_functor0 object that wraps the passed method.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  explicit volatile_mem_functor0(function_type _A_func) : func_ptr_(_A_func) {}
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Pointer to instance the method should operate on.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(T_obj* _A_obj) const
+    { return (_A_obj->*(this->func_ptr_))(); }
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Reference to instance the method should operate on.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(T_obj& _A_obj) const
+    { return (_A_obj.*func_ptr_)(); }
+
+protected:
+  function_type func_ptr_;
+};
+
+/** volatile_mem_functor1 wraps volatile methods with 1 argument(s).
+ * Use the convenience function mem_fun() to create an instance of volatile_mem_functor1.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1>
+class volatile_mem_functor1 : public functor_base
+{
+public:
+  typedef T_return (T_obj::*function_type)(T_arg1) volatile;
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  volatile_mem_functor1() : func_ptr_(0) {}
+
+  /** Constructs a volatile_mem_functor1 object that wraps the passed method.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  explicit volatile_mem_functor1(function_type _A_func) : func_ptr_(_A_func) {}
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Pointer to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(T_obj* _A_obj, typename type_trait<T_arg1>::take _A_a1) const
+    { return (_A_obj->*(this->func_ptr_))(_A_a1); }
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Reference to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(T_obj& _A_obj, typename type_trait<T_arg1>::take _A_a1) const
+    { return (_A_obj.*func_ptr_)(_A_a1); }
+
+protected:
+  function_type func_ptr_;
+};
+
+/** volatile_mem_functor2 wraps volatile methods with 2 argument(s).
+ * Use the convenience function mem_fun() to create an instance of volatile_mem_functor2.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2>
+class volatile_mem_functor2 : public functor_base
+{
+public:
+  typedef T_return (T_obj::*function_type)(T_arg1,T_arg2) volatile;
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  volatile_mem_functor2() : func_ptr_(0) {}
+
+  /** Constructs a volatile_mem_functor2 object that wraps the passed method.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  explicit volatile_mem_functor2(function_type _A_func) : func_ptr_(_A_func) {}
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Pointer to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(T_obj* _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2) const
+    { return (_A_obj->*(this->func_ptr_))(_A_a1,_A_a2); }
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Reference to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(T_obj& _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2) const
+    { return (_A_obj.*func_ptr_)(_A_a1,_A_a2); }
+
+protected:
+  function_type func_ptr_;
+};
+
+/** volatile_mem_functor3 wraps volatile methods with 3 argument(s).
+ * Use the convenience function mem_fun() to create an instance of volatile_mem_functor3.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3>
+class volatile_mem_functor3 : public functor_base
+{
+public:
+  typedef T_return (T_obj::*function_type)(T_arg1,T_arg2,T_arg3) volatile;
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  volatile_mem_functor3() : func_ptr_(0) {}
+
+  /** Constructs a volatile_mem_functor3 object that wraps the passed method.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  explicit volatile_mem_functor3(function_type _A_func) : func_ptr_(_A_func) {}
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Pointer to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(T_obj* _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3) const
+    { return (_A_obj->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3); }
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Reference to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(T_obj& _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3) const
+    { return (_A_obj.*func_ptr_)(_A_a1,_A_a2,_A_a3); }
+
+protected:
+  function_type func_ptr_;
+};
+
+/** volatile_mem_functor4 wraps volatile methods with 4 argument(s).
+ * Use the convenience function mem_fun() to create an instance of volatile_mem_functor4.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+class volatile_mem_functor4 : public functor_base
+{
+public:
+  typedef T_return (T_obj::*function_type)(T_arg1,T_arg2,T_arg3,T_arg4) volatile;
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  volatile_mem_functor4() : func_ptr_(0) {}
+
+  /** Constructs a volatile_mem_functor4 object that wraps the passed method.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  explicit volatile_mem_functor4(function_type _A_func) : func_ptr_(_A_func) {}
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Pointer to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(T_obj* _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4) const
+    { return (_A_obj->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3,_A_a4); }
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Reference to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(T_obj& _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4) const
+    { return (_A_obj.*func_ptr_)(_A_a1,_A_a2,_A_a3,_A_a4); }
+
+protected:
+  function_type func_ptr_;
+};
+
+/** volatile_mem_functor5 wraps volatile methods with 5 argument(s).
+ * Use the convenience function mem_fun() to create an instance of volatile_mem_functor5.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_arg5 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+class volatile_mem_functor5 : public functor_base
+{
+public:
+  typedef T_return (T_obj::*function_type)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) volatile;
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  volatile_mem_functor5() : func_ptr_(0) {}
+
+  /** Constructs a volatile_mem_functor5 object that wraps the passed method.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  explicit volatile_mem_functor5(function_type _A_func) : func_ptr_(_A_func) {}
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Pointer to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @param _A_a5 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(T_obj* _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5) const
+    { return (_A_obj->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5); }
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Reference to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @param _A_a5 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(T_obj& _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5) const
+    { return (_A_obj.*func_ptr_)(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5); }
+
+protected:
+  function_type func_ptr_;
+};
+
+/** volatile_mem_functor6 wraps volatile methods with 6 argument(s).
+ * Use the convenience function mem_fun() to create an instance of volatile_mem_functor6.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_arg5 Argument type used in the definition of operator()().
+ * - @e T_arg6 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+class volatile_mem_functor6 : public functor_base
+{
+public:
+  typedef T_return (T_obj::*function_type)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) volatile;
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  volatile_mem_functor6() : func_ptr_(0) {}
+
+  /** Constructs a volatile_mem_functor6 object that wraps the passed method.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  explicit volatile_mem_functor6(function_type _A_func) : func_ptr_(_A_func) {}
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Pointer to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @param _A_a5 Argument to be passed on to the method.
+   * @param _A_a6 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(T_obj* _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6) const
+    { return (_A_obj->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6); }
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Reference to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @param _A_a5 Argument to be passed on to the method.
+   * @param _A_a6 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(T_obj& _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6) const
+    { return (_A_obj.*func_ptr_)(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6); }
+
+protected:
+  function_type func_ptr_;
+};
+
+/** volatile_mem_functor7 wraps volatile methods with 7 argument(s).
+ * Use the convenience function mem_fun() to create an instance of volatile_mem_functor7.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_arg5 Argument type used in the definition of operator()().
+ * - @e T_arg6 Argument type used in the definition of operator()().
+ * - @e T_arg7 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+class volatile_mem_functor7 : public functor_base
+{
+public:
+  typedef T_return (T_obj::*function_type)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7) volatile;
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  volatile_mem_functor7() : func_ptr_(0) {}
+
+  /** Constructs a volatile_mem_functor7 object that wraps the passed method.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  explicit volatile_mem_functor7(function_type _A_func) : func_ptr_(_A_func) {}
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Pointer to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @param _A_a5 Argument to be passed on to the method.
+   * @param _A_a6 Argument to be passed on to the method.
+   * @param _A_a7 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(T_obj* _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6,typename type_trait<T_arg7>::take _A_a7) const
+    { return (_A_obj->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6,_A_a7); }
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Reference to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @param _A_a5 Argument to be passed on to the method.
+   * @param _A_a6 Argument to be passed on to the method.
+   * @param _A_a7 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(T_obj& _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6,typename type_trait<T_arg7>::take _A_a7) const
+    { return (_A_obj.*func_ptr_)(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6,_A_a7); }
+
+protected:
+  function_type func_ptr_;
+};
+
+/** const_volatile_mem_functor0 wraps const volatile methods with 0 argument(s).
+ * Use the convenience function mem_fun() to create an instance of const_volatile_mem_functor0.
+ *
+ * The following template arguments are used:
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj>
+class const_volatile_mem_functor0 : public functor_base
+{
+public:
+  typedef T_return (T_obj::*function_type)() const volatile;
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  const_volatile_mem_functor0() : func_ptr_(0) {}
+
+  /** Constructs a const_volatile_mem_functor0 object that wraps the passed method.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  explicit const_volatile_mem_functor0(function_type _A_func) : func_ptr_(_A_func) {}
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Pointer to instance the method should operate on.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(const T_obj* _A_obj) const
+    { return (_A_obj->*(this->func_ptr_))(); }
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Reference to instance the method should operate on.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(const T_obj& _A_obj) const
+    { return (_A_obj.*func_ptr_)(); }
+
+protected:
+  function_type func_ptr_;
+};
+
+/** const_volatile_mem_functor1 wraps const volatile methods with 1 argument(s).
+ * Use the convenience function mem_fun() to create an instance of const_volatile_mem_functor1.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1>
+class const_volatile_mem_functor1 : public functor_base
+{
+public:
+  typedef T_return (T_obj::*function_type)(T_arg1) const volatile;
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  const_volatile_mem_functor1() : func_ptr_(0) {}
+
+  /** Constructs a const_volatile_mem_functor1 object that wraps the passed method.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  explicit const_volatile_mem_functor1(function_type _A_func) : func_ptr_(_A_func) {}
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Pointer to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(const T_obj* _A_obj, typename type_trait<T_arg1>::take _A_a1) const
+    { return (_A_obj->*(this->func_ptr_))(_A_a1); }
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Reference to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(const T_obj& _A_obj, typename type_trait<T_arg1>::take _A_a1) const
+    { return (_A_obj.*func_ptr_)(_A_a1); }
+
+protected:
+  function_type func_ptr_;
+};
+
+/** const_volatile_mem_functor2 wraps const volatile methods with 2 argument(s).
+ * Use the convenience function mem_fun() to create an instance of const_volatile_mem_functor2.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2>
+class const_volatile_mem_functor2 : public functor_base
+{
+public:
+  typedef T_return (T_obj::*function_type)(T_arg1,T_arg2) const volatile;
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  const_volatile_mem_functor2() : func_ptr_(0) {}
+
+  /** Constructs a const_volatile_mem_functor2 object that wraps the passed method.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  explicit const_volatile_mem_functor2(function_type _A_func) : func_ptr_(_A_func) {}
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Pointer to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(const T_obj* _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2) const
+    { return (_A_obj->*(this->func_ptr_))(_A_a1,_A_a2); }
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Reference to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(const T_obj& _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2) const
+    { return (_A_obj.*func_ptr_)(_A_a1,_A_a2); }
+
+protected:
+  function_type func_ptr_;
+};
+
+/** const_volatile_mem_functor3 wraps const volatile methods with 3 argument(s).
+ * Use the convenience function mem_fun() to create an instance of const_volatile_mem_functor3.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3>
+class const_volatile_mem_functor3 : public functor_base
+{
+public:
+  typedef T_return (T_obj::*function_type)(T_arg1,T_arg2,T_arg3) const volatile;
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  const_volatile_mem_functor3() : func_ptr_(0) {}
+
+  /** Constructs a const_volatile_mem_functor3 object that wraps the passed method.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  explicit const_volatile_mem_functor3(function_type _A_func) : func_ptr_(_A_func) {}
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Pointer to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(const T_obj* _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3) const
+    { return (_A_obj->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3); }
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Reference to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(const T_obj& _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3) const
+    { return (_A_obj.*func_ptr_)(_A_a1,_A_a2,_A_a3); }
+
+protected:
+  function_type func_ptr_;
+};
+
+/** const_volatile_mem_functor4 wraps const volatile methods with 4 argument(s).
+ * Use the convenience function mem_fun() to create an instance of const_volatile_mem_functor4.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+class const_volatile_mem_functor4 : public functor_base
+{
+public:
+  typedef T_return (T_obj::*function_type)(T_arg1,T_arg2,T_arg3,T_arg4) const volatile;
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  const_volatile_mem_functor4() : func_ptr_(0) {}
+
+  /** Constructs a const_volatile_mem_functor4 object that wraps the passed method.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  explicit const_volatile_mem_functor4(function_type _A_func) : func_ptr_(_A_func) {}
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Pointer to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(const T_obj* _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4) const
+    { return (_A_obj->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3,_A_a4); }
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Reference to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(const T_obj& _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4) const
+    { return (_A_obj.*func_ptr_)(_A_a1,_A_a2,_A_a3,_A_a4); }
+
+protected:
+  function_type func_ptr_;
+};
+
+/** const_volatile_mem_functor5 wraps const volatile methods with 5 argument(s).
+ * Use the convenience function mem_fun() to create an instance of const_volatile_mem_functor5.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_arg5 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+class const_volatile_mem_functor5 : public functor_base
+{
+public:
+  typedef T_return (T_obj::*function_type)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) const volatile;
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  const_volatile_mem_functor5() : func_ptr_(0) {}
+
+  /** Constructs a const_volatile_mem_functor5 object that wraps the passed method.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  explicit const_volatile_mem_functor5(function_type _A_func) : func_ptr_(_A_func) {}
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Pointer to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @param _A_a5 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(const T_obj* _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5) const
+    { return (_A_obj->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5); }
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Reference to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @param _A_a5 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(const T_obj& _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5) const
+    { return (_A_obj.*func_ptr_)(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5); }
+
+protected:
+  function_type func_ptr_;
+};
+
+/** const_volatile_mem_functor6 wraps const volatile methods with 6 argument(s).
+ * Use the convenience function mem_fun() to create an instance of const_volatile_mem_functor6.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_arg5 Argument type used in the definition of operator()().
+ * - @e T_arg6 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+class const_volatile_mem_functor6 : public functor_base
+{
+public:
+  typedef T_return (T_obj::*function_type)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) const volatile;
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  const_volatile_mem_functor6() : func_ptr_(0) {}
+
+  /** Constructs a const_volatile_mem_functor6 object that wraps the passed method.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  explicit const_volatile_mem_functor6(function_type _A_func) : func_ptr_(_A_func) {}
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Pointer to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @param _A_a5 Argument to be passed on to the method.
+   * @param _A_a6 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(const T_obj* _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6) const
+    { return (_A_obj->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6); }
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Reference to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @param _A_a5 Argument to be passed on to the method.
+   * @param _A_a6 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(const T_obj& _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6) const
+    { return (_A_obj.*func_ptr_)(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6); }
+
+protected:
+  function_type func_ptr_;
+};
+
+/** const_volatile_mem_functor7 wraps const volatile methods with 7 argument(s).
+ * Use the convenience function mem_fun() to create an instance of const_volatile_mem_functor7.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_arg5 Argument type used in the definition of operator()().
+ * - @e T_arg6 Argument type used in the definition of operator()().
+ * - @e T_arg7 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+class const_volatile_mem_functor7 : public functor_base
+{
+public:
+  typedef T_return (T_obj::*function_type)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7) const volatile;
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  const_volatile_mem_functor7() : func_ptr_(0) {}
+
+  /** Constructs a const_volatile_mem_functor7 object that wraps the passed method.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  explicit const_volatile_mem_functor7(function_type _A_func) : func_ptr_(_A_func) {}
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Pointer to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @param _A_a5 Argument to be passed on to the method.
+   * @param _A_a6 Argument to be passed on to the method.
+   * @param _A_a7 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(const T_obj* _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6,typename type_trait<T_arg7>::take _A_a7) const
+    { return (_A_obj->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6,_A_a7); }
+
+  /** Execute the wrapped method operating on the passed instance.
+   * @param _A_obj Reference to instance the method should operate on.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @param _A_a5 Argument to be passed on to the method.
+   * @param _A_a6 Argument to be passed on to the method.
+   * @param _A_a7 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(const T_obj& _A_obj, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6,typename type_trait<T_arg7>::take _A_a7) const
+    { return (_A_obj.*func_ptr_)(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6,_A_a7); }
+
+protected:
+  function_type func_ptr_;
+};
+
+/** bound_mem_functor0 encapsulates a  method with 0 arguments and an object instance.
+ * Use the convenience function mem_fun() to create an instance of bound_mem_functor0.
+ *
+ * The following template arguments are used:
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj>
+class bound_mem_functor0
+  : public mem_functor0<T_return, T_obj>
+{
+  typedef mem_functor0<T_return, T_obj> base_type_;
+public:
+  typedef typename base_type_::function_type function_type;
+
+  /** Constructs a bound_mem_functor0 object that wraps the passed method.
+   * @param _A_obj Pointer to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_mem_functor0( T_obj* _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(_A_obj) {}
+
+  /** Constructs a bound_mem_functor0 object that wraps the passed method.
+   * @param _A_obj Reference to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_mem_functor0( T_obj& _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(&_A_obj) {}
+
+  /** Execute the wrapped method operating on the stored instance.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()() const
+    { return (obj_ptr_->*(this->func_ptr_))(); }
+
+//protected:
+  /// Pointer to stored object instance.
+   T_obj *obj_ptr_;
+};
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bound_mem_functor performs a functor
+ * on the object instance stored in the sigc::bound_mem_functor object.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_action, class T_return, class T_obj>
+void visit_each(const T_action& _A_action,
+                const bound_mem_functor0<T_return, T_obj>& _A_target)
+{
+  visit_each(_A_action, *_A_target.obj_ptr_);
+}
+
+/** bound_mem_functor1 encapsulates a  method with 1 arguments and an object instance.
+ * Use the convenience function mem_fun() to create an instance of bound_mem_functor1.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1>
+class bound_mem_functor1
+  : public mem_functor1<T_return, T_obj, T_arg1>
+{
+  typedef mem_functor1<T_return, T_obj, T_arg1> base_type_;
+public:
+  typedef typename base_type_::function_type function_type;
+
+  /** Constructs a bound_mem_functor1 object that wraps the passed method.
+   * @param _A_obj Pointer to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_mem_functor1( T_obj* _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(_A_obj) {}
+
+  /** Constructs a bound_mem_functor1 object that wraps the passed method.
+   * @param _A_obj Reference to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_mem_functor1( T_obj& _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(&_A_obj) {}
+
+  /** Execute the wrapped method operating on the stored instance.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(typename type_trait<T_arg1>::take _A_a1) const
+    { return (obj_ptr_->*(this->func_ptr_))(_A_a1); }
+
+//protected:
+  /// Pointer to stored object instance.
+   T_obj *obj_ptr_;
+};
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bound_mem_functor performs a functor
+ * on the object instance stored in the sigc::bound_mem_functor object.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_action, class T_return, class T_obj, class T_arg1>
+void visit_each(const T_action& _A_action,
+                const bound_mem_functor1<T_return, T_obj, T_arg1>& _A_target)
+{
+  visit_each(_A_action, *_A_target.obj_ptr_);
+}
+
+/** bound_mem_functor2 encapsulates a  method with 2 arguments and an object instance.
+ * Use the convenience function mem_fun() to create an instance of bound_mem_functor2.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2>
+class bound_mem_functor2
+  : public mem_functor2<T_return, T_obj, T_arg1,T_arg2>
+{
+  typedef mem_functor2<T_return, T_obj, T_arg1,T_arg2> base_type_;
+public:
+  typedef typename base_type_::function_type function_type;
+
+  /** Constructs a bound_mem_functor2 object that wraps the passed method.
+   * @param _A_obj Pointer to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_mem_functor2( T_obj* _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(_A_obj) {}
+
+  /** Constructs a bound_mem_functor2 object that wraps the passed method.
+   * @param _A_obj Reference to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_mem_functor2( T_obj& _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(&_A_obj) {}
+
+  /** Execute the wrapped method operating on the stored instance.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2) const
+    { return (obj_ptr_->*(this->func_ptr_))(_A_a1,_A_a2); }
+
+//protected:
+  /// Pointer to stored object instance.
+   T_obj *obj_ptr_;
+};
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bound_mem_functor performs a functor
+ * on the object instance stored in the sigc::bound_mem_functor object.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_action, class T_return, class T_obj, class T_arg1,class T_arg2>
+void visit_each(const T_action& _A_action,
+                const bound_mem_functor2<T_return, T_obj, T_arg1,T_arg2>& _A_target)
+{
+  visit_each(_A_action, *_A_target.obj_ptr_);
+}
+
+/** bound_mem_functor3 encapsulates a  method with 3 arguments and an object instance.
+ * Use the convenience function mem_fun() to create an instance of bound_mem_functor3.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3>
+class bound_mem_functor3
+  : public mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>
+{
+  typedef mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3> base_type_;
+public:
+  typedef typename base_type_::function_type function_type;
+
+  /** Constructs a bound_mem_functor3 object that wraps the passed method.
+   * @param _A_obj Pointer to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_mem_functor3( T_obj* _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(_A_obj) {}
+
+  /** Constructs a bound_mem_functor3 object that wraps the passed method.
+   * @param _A_obj Reference to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_mem_functor3( T_obj& _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(&_A_obj) {}
+
+  /** Execute the wrapped method operating on the stored instance.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3) const
+    { return (obj_ptr_->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3); }
+
+//protected:
+  /// Pointer to stored object instance.
+   T_obj *obj_ptr_;
+};
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bound_mem_functor performs a functor
+ * on the object instance stored in the sigc::bound_mem_functor object.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_action, class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3>
+void visit_each(const T_action& _A_action,
+                const bound_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>& _A_target)
+{
+  visit_each(_A_action, *_A_target.obj_ptr_);
+}
+
+/** bound_mem_functor4 encapsulates a  method with 4 arguments and an object instance.
+ * Use the convenience function mem_fun() to create an instance of bound_mem_functor4.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+class bound_mem_functor4
+  : public mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>
+{
+  typedef mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4> base_type_;
+public:
+  typedef typename base_type_::function_type function_type;
+
+  /** Constructs a bound_mem_functor4 object that wraps the passed method.
+   * @param _A_obj Pointer to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_mem_functor4( T_obj* _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(_A_obj) {}
+
+  /** Constructs a bound_mem_functor4 object that wraps the passed method.
+   * @param _A_obj Reference to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_mem_functor4( T_obj& _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(&_A_obj) {}
+
+  /** Execute the wrapped method operating on the stored instance.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4) const
+    { return (obj_ptr_->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3,_A_a4); }
+
+//protected:
+  /// Pointer to stored object instance.
+   T_obj *obj_ptr_;
+};
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bound_mem_functor performs a functor
+ * on the object instance stored in the sigc::bound_mem_functor object.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_action, class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+void visit_each(const T_action& _A_action,
+                const bound_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>& _A_target)
+{
+  visit_each(_A_action, *_A_target.obj_ptr_);
+}
+
+/** bound_mem_functor5 encapsulates a  method with 5 arguments and an object instance.
+ * Use the convenience function mem_fun() to create an instance of bound_mem_functor5.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_arg5 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+class bound_mem_functor5
+  : public mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+{
+  typedef mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5> base_type_;
+public:
+  typedef typename base_type_::function_type function_type;
+
+  /** Constructs a bound_mem_functor5 object that wraps the passed method.
+   * @param _A_obj Pointer to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_mem_functor5( T_obj* _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(_A_obj) {}
+
+  /** Constructs a bound_mem_functor5 object that wraps the passed method.
+   * @param _A_obj Reference to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_mem_functor5( T_obj& _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(&_A_obj) {}
+
+  /** Execute the wrapped method operating on the stored instance.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @param _A_a5 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5) const
+    { return (obj_ptr_->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5); }
+
+//protected:
+  /// Pointer to stored object instance.
+   T_obj *obj_ptr_;
+};
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bound_mem_functor performs a functor
+ * on the object instance stored in the sigc::bound_mem_functor object.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_action, class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+void visit_each(const T_action& _A_action,
+                const bound_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>& _A_target)
+{
+  visit_each(_A_action, *_A_target.obj_ptr_);
+}
+
+/** bound_mem_functor6 encapsulates a  method with 6 arguments and an object instance.
+ * Use the convenience function mem_fun() to create an instance of bound_mem_functor6.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_arg5 Argument type used in the definition of operator()().
+ * - @e T_arg6 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+class bound_mem_functor6
+  : public mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+{
+  typedef mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6> base_type_;
+public:
+  typedef typename base_type_::function_type function_type;
+
+  /** Constructs a bound_mem_functor6 object that wraps the passed method.
+   * @param _A_obj Pointer to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_mem_functor6( T_obj* _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(_A_obj) {}
+
+  /** Constructs a bound_mem_functor6 object that wraps the passed method.
+   * @param _A_obj Reference to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_mem_functor6( T_obj& _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(&_A_obj) {}
+
+  /** Execute the wrapped method operating on the stored instance.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @param _A_a5 Argument to be passed on to the method.
+   * @param _A_a6 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6) const
+    { return (obj_ptr_->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6); }
+
+//protected:
+  /// Pointer to stored object instance.
+   T_obj *obj_ptr_;
+};
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bound_mem_functor performs a functor
+ * on the object instance stored in the sigc::bound_mem_functor object.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_action, class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+void visit_each(const T_action& _A_action,
+                const bound_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>& _A_target)
+{
+  visit_each(_A_action, *_A_target.obj_ptr_);
+}
+
+/** bound_mem_functor7 encapsulates a  method with 7 arguments and an object instance.
+ * Use the convenience function mem_fun() to create an instance of bound_mem_functor7.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_arg5 Argument type used in the definition of operator()().
+ * - @e T_arg6 Argument type used in the definition of operator()().
+ * - @e T_arg7 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+class bound_mem_functor7
+  : public mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+{
+  typedef mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7> base_type_;
+public:
+  typedef typename base_type_::function_type function_type;
+
+  /** Constructs a bound_mem_functor7 object that wraps the passed method.
+   * @param _A_obj Pointer to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_mem_functor7( T_obj* _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(_A_obj) {}
+
+  /** Constructs a bound_mem_functor7 object that wraps the passed method.
+   * @param _A_obj Reference to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_mem_functor7( T_obj& _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(&_A_obj) {}
+
+  /** Execute the wrapped method operating on the stored instance.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @param _A_a5 Argument to be passed on to the method.
+   * @param _A_a6 Argument to be passed on to the method.
+   * @param _A_a7 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6,typename type_trait<T_arg7>::take _A_a7) const
+    { return (obj_ptr_->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6,_A_a7); }
+
+//protected:
+  /// Pointer to stored object instance.
+   T_obj *obj_ptr_;
+};
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bound_mem_functor performs a functor
+ * on the object instance stored in the sigc::bound_mem_functor object.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_action, class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+void visit_each(const T_action& _A_action,
+                const bound_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>& _A_target)
+{
+  visit_each(_A_action, *_A_target.obj_ptr_);
+}
+
+/** bound_const_mem_functor0 encapsulates a const method with 0 arguments and an object instance.
+ * Use the convenience function mem_fun() to create an instance of bound_const_mem_functor0.
+ *
+ * The following template arguments are used:
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj>
+class bound_const_mem_functor0
+  : public const_mem_functor0<T_return, T_obj>
+{
+  typedef const_mem_functor0<T_return, T_obj> base_type_;
+public:
+  typedef typename base_type_::function_type function_type;
+
+  /** Constructs a bound_const_mem_functor0 object that wraps the passed method.
+   * @param _A_obj Pointer to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_const_mem_functor0(const T_obj* _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(_A_obj) {}
+
+  /** Constructs a bound_const_mem_functor0 object that wraps the passed method.
+   * @param _A_obj Reference to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_const_mem_functor0(const T_obj& _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(&_A_obj) {}
+
+  /** Execute the wrapped method operating on the stored instance.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()() const
+    { return (obj_ptr_->*(this->func_ptr_))(); }
+
+//protected:
+  /// Pointer to stored object instance.
+  const T_obj *obj_ptr_;
+};
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bound_const_mem_functor performs a functor
+ * on the object instance stored in the sigc::bound_const_mem_functor object.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_action, class T_return, class T_obj>
+void visit_each(const T_action& _A_action,
+                const bound_const_mem_functor0<T_return, T_obj>& _A_target)
+{
+  visit_each(_A_action, *_A_target.obj_ptr_);
+}
+
+/** bound_const_mem_functor1 encapsulates a const method with 1 arguments and an object instance.
+ * Use the convenience function mem_fun() to create an instance of bound_const_mem_functor1.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1>
+class bound_const_mem_functor1
+  : public const_mem_functor1<T_return, T_obj, T_arg1>
+{
+  typedef const_mem_functor1<T_return, T_obj, T_arg1> base_type_;
+public:
+  typedef typename base_type_::function_type function_type;
+
+  /** Constructs a bound_const_mem_functor1 object that wraps the passed method.
+   * @param _A_obj Pointer to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_const_mem_functor1(const T_obj* _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(_A_obj) {}
+
+  /** Constructs a bound_const_mem_functor1 object that wraps the passed method.
+   * @param _A_obj Reference to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_const_mem_functor1(const T_obj& _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(&_A_obj) {}
+
+  /** Execute the wrapped method operating on the stored instance.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(typename type_trait<T_arg1>::take _A_a1) const
+    { return (obj_ptr_->*(this->func_ptr_))(_A_a1); }
+
+//protected:
+  /// Pointer to stored object instance.
+  const T_obj *obj_ptr_;
+};
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bound_const_mem_functor performs a functor
+ * on the object instance stored in the sigc::bound_const_mem_functor object.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_action, class T_return, class T_obj, class T_arg1>
+void visit_each(const T_action& _A_action,
+                const bound_const_mem_functor1<T_return, T_obj, T_arg1>& _A_target)
+{
+  visit_each(_A_action, *_A_target.obj_ptr_);
+}
+
+/** bound_const_mem_functor2 encapsulates a const method with 2 arguments and an object instance.
+ * Use the convenience function mem_fun() to create an instance of bound_const_mem_functor2.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2>
+class bound_const_mem_functor2
+  : public const_mem_functor2<T_return, T_obj, T_arg1,T_arg2>
+{
+  typedef const_mem_functor2<T_return, T_obj, T_arg1,T_arg2> base_type_;
+public:
+  typedef typename base_type_::function_type function_type;
+
+  /** Constructs a bound_const_mem_functor2 object that wraps the passed method.
+   * @param _A_obj Pointer to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_const_mem_functor2(const T_obj* _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(_A_obj) {}
+
+  /** Constructs a bound_const_mem_functor2 object that wraps the passed method.
+   * @param _A_obj Reference to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_const_mem_functor2(const T_obj& _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(&_A_obj) {}
+
+  /** Execute the wrapped method operating on the stored instance.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2) const
+    { return (obj_ptr_->*(this->func_ptr_))(_A_a1,_A_a2); }
+
+//protected:
+  /// Pointer to stored object instance.
+  const T_obj *obj_ptr_;
+};
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bound_const_mem_functor performs a functor
+ * on the object instance stored in the sigc::bound_const_mem_functor object.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_action, class T_return, class T_obj, class T_arg1,class T_arg2>
+void visit_each(const T_action& _A_action,
+                const bound_const_mem_functor2<T_return, T_obj, T_arg1,T_arg2>& _A_target)
+{
+  visit_each(_A_action, *_A_target.obj_ptr_);
+}
+
+/** bound_const_mem_functor3 encapsulates a const method with 3 arguments and an object instance.
+ * Use the convenience function mem_fun() to create an instance of bound_const_mem_functor3.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3>
+class bound_const_mem_functor3
+  : public const_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>
+{
+  typedef const_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3> base_type_;
+public:
+  typedef typename base_type_::function_type function_type;
+
+  /** Constructs a bound_const_mem_functor3 object that wraps the passed method.
+   * @param _A_obj Pointer to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_const_mem_functor3(const T_obj* _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(_A_obj) {}
+
+  /** Constructs a bound_const_mem_functor3 object that wraps the passed method.
+   * @param _A_obj Reference to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_const_mem_functor3(const T_obj& _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(&_A_obj) {}
+
+  /** Execute the wrapped method operating on the stored instance.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3) const
+    { return (obj_ptr_->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3); }
+
+//protected:
+  /// Pointer to stored object instance.
+  const T_obj *obj_ptr_;
+};
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bound_const_mem_functor performs a functor
+ * on the object instance stored in the sigc::bound_const_mem_functor object.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_action, class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3>
+void visit_each(const T_action& _A_action,
+                const bound_const_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>& _A_target)
+{
+  visit_each(_A_action, *_A_target.obj_ptr_);
+}
+
+/** bound_const_mem_functor4 encapsulates a const method with 4 arguments and an object instance.
+ * Use the convenience function mem_fun() to create an instance of bound_const_mem_functor4.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+class bound_const_mem_functor4
+  : public const_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>
+{
+  typedef const_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4> base_type_;
+public:
+  typedef typename base_type_::function_type function_type;
+
+  /** Constructs a bound_const_mem_functor4 object that wraps the passed method.
+   * @param _A_obj Pointer to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_const_mem_functor4(const T_obj* _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(_A_obj) {}
+
+  /** Constructs a bound_const_mem_functor4 object that wraps the passed method.
+   * @param _A_obj Reference to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_const_mem_functor4(const T_obj& _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(&_A_obj) {}
+
+  /** Execute the wrapped method operating on the stored instance.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4) const
+    { return (obj_ptr_->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3,_A_a4); }
+
+//protected:
+  /// Pointer to stored object instance.
+  const T_obj *obj_ptr_;
+};
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bound_const_mem_functor performs a functor
+ * on the object instance stored in the sigc::bound_const_mem_functor object.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_action, class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+void visit_each(const T_action& _A_action,
+                const bound_const_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>& _A_target)
+{
+  visit_each(_A_action, *_A_target.obj_ptr_);
+}
+
+/** bound_const_mem_functor5 encapsulates a const method with 5 arguments and an object instance.
+ * Use the convenience function mem_fun() to create an instance of bound_const_mem_functor5.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_arg5 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+class bound_const_mem_functor5
+  : public const_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+{
+  typedef const_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5> base_type_;
+public:
+  typedef typename base_type_::function_type function_type;
+
+  /** Constructs a bound_const_mem_functor5 object that wraps the passed method.
+   * @param _A_obj Pointer to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_const_mem_functor5(const T_obj* _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(_A_obj) {}
+
+  /** Constructs a bound_const_mem_functor5 object that wraps the passed method.
+   * @param _A_obj Reference to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_const_mem_functor5(const T_obj& _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(&_A_obj) {}
+
+  /** Execute the wrapped method operating on the stored instance.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @param _A_a5 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5) const
+    { return (obj_ptr_->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5); }
+
+//protected:
+  /// Pointer to stored object instance.
+  const T_obj *obj_ptr_;
+};
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bound_const_mem_functor performs a functor
+ * on the object instance stored in the sigc::bound_const_mem_functor object.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_action, class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+void visit_each(const T_action& _A_action,
+                const bound_const_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>& _A_target)
+{
+  visit_each(_A_action, *_A_target.obj_ptr_);
+}
+
+/** bound_const_mem_functor6 encapsulates a const method with 6 arguments and an object instance.
+ * Use the convenience function mem_fun() to create an instance of bound_const_mem_functor6.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_arg5 Argument type used in the definition of operator()().
+ * - @e T_arg6 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+class bound_const_mem_functor6
+  : public const_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+{
+  typedef const_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6> base_type_;
+public:
+  typedef typename base_type_::function_type function_type;
+
+  /** Constructs a bound_const_mem_functor6 object that wraps the passed method.
+   * @param _A_obj Pointer to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_const_mem_functor6(const T_obj* _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(_A_obj) {}
+
+  /** Constructs a bound_const_mem_functor6 object that wraps the passed method.
+   * @param _A_obj Reference to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_const_mem_functor6(const T_obj& _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(&_A_obj) {}
+
+  /** Execute the wrapped method operating on the stored instance.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @param _A_a5 Argument to be passed on to the method.
+   * @param _A_a6 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6) const
+    { return (obj_ptr_->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6); }
+
+//protected:
+  /// Pointer to stored object instance.
+  const T_obj *obj_ptr_;
+};
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bound_const_mem_functor performs a functor
+ * on the object instance stored in the sigc::bound_const_mem_functor object.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_action, class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+void visit_each(const T_action& _A_action,
+                const bound_const_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>& _A_target)
+{
+  visit_each(_A_action, *_A_target.obj_ptr_);
+}
+
+/** bound_const_mem_functor7 encapsulates a const method with 7 arguments and an object instance.
+ * Use the convenience function mem_fun() to create an instance of bound_const_mem_functor7.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_arg5 Argument type used in the definition of operator()().
+ * - @e T_arg6 Argument type used in the definition of operator()().
+ * - @e T_arg7 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+class bound_const_mem_functor7
+  : public const_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+{
+  typedef const_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7> base_type_;
+public:
+  typedef typename base_type_::function_type function_type;
+
+  /** Constructs a bound_const_mem_functor7 object that wraps the passed method.
+   * @param _A_obj Pointer to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_const_mem_functor7(const T_obj* _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(_A_obj) {}
+
+  /** Constructs a bound_const_mem_functor7 object that wraps the passed method.
+   * @param _A_obj Reference to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_const_mem_functor7(const T_obj& _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(&_A_obj) {}
+
+  /** Execute the wrapped method operating on the stored instance.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @param _A_a5 Argument to be passed on to the method.
+   * @param _A_a6 Argument to be passed on to the method.
+   * @param _A_a7 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6,typename type_trait<T_arg7>::take _A_a7) const
+    { return (obj_ptr_->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6,_A_a7); }
+
+//protected:
+  /// Pointer to stored object instance.
+  const T_obj *obj_ptr_;
+};
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bound_const_mem_functor performs a functor
+ * on the object instance stored in the sigc::bound_const_mem_functor object.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_action, class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+void visit_each(const T_action& _A_action,
+                const bound_const_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>& _A_target)
+{
+  visit_each(_A_action, *_A_target.obj_ptr_);
+}
+
+/** bound_volatile_mem_functor0 encapsulates a volatile method with 0 arguments and an object instance.
+ * Use the convenience function mem_fun() to create an instance of bound_volatile_mem_functor0.
+ *
+ * The following template arguments are used:
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj>
+class bound_volatile_mem_functor0
+  : public volatile_mem_functor0<T_return, T_obj>
+{
+  typedef volatile_mem_functor0<T_return, T_obj> base_type_;
+public:
+  typedef typename base_type_::function_type function_type;
+
+  /** Constructs a bound_volatile_mem_functor0 object that wraps the passed method.
+   * @param _A_obj Pointer to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_volatile_mem_functor0( T_obj* _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(_A_obj) {}
+
+  /** Constructs a bound_volatile_mem_functor0 object that wraps the passed method.
+   * @param _A_obj Reference to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_volatile_mem_functor0( T_obj& _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(&_A_obj) {}
+
+  /** Execute the wrapped method operating on the stored instance.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()() const
+    { return (obj_ptr_->*(this->func_ptr_))(); }
+
+//protected:
+  /// Pointer to stored object instance.
+   T_obj *obj_ptr_;
+};
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bound_volatile_mem_functor performs a functor
+ * on the object instance stored in the sigc::bound_volatile_mem_functor object.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_action, class T_return, class T_obj>
+void visit_each(const T_action& _A_action,
+                const bound_volatile_mem_functor0<T_return, T_obj>& _A_target)
+{
+  visit_each(_A_action, *_A_target.obj_ptr_);
+}
+
+/** bound_volatile_mem_functor1 encapsulates a volatile method with 1 arguments and an object instance.
+ * Use the convenience function mem_fun() to create an instance of bound_volatile_mem_functor1.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1>
+class bound_volatile_mem_functor1
+  : public volatile_mem_functor1<T_return, T_obj, T_arg1>
+{
+  typedef volatile_mem_functor1<T_return, T_obj, T_arg1> base_type_;
+public:
+  typedef typename base_type_::function_type function_type;
+
+  /** Constructs a bound_volatile_mem_functor1 object that wraps the passed method.
+   * @param _A_obj Pointer to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_volatile_mem_functor1( T_obj* _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(_A_obj) {}
+
+  /** Constructs a bound_volatile_mem_functor1 object that wraps the passed method.
+   * @param _A_obj Reference to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_volatile_mem_functor1( T_obj& _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(&_A_obj) {}
+
+  /** Execute the wrapped method operating on the stored instance.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(typename type_trait<T_arg1>::take _A_a1) const
+    { return (obj_ptr_->*(this->func_ptr_))(_A_a1); }
+
+//protected:
+  /// Pointer to stored object instance.
+   T_obj *obj_ptr_;
+};
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bound_volatile_mem_functor performs a functor
+ * on the object instance stored in the sigc::bound_volatile_mem_functor object.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_action, class T_return, class T_obj, class T_arg1>
+void visit_each(const T_action& _A_action,
+                const bound_volatile_mem_functor1<T_return, T_obj, T_arg1>& _A_target)
+{
+  visit_each(_A_action, *_A_target.obj_ptr_);
+}
+
+/** bound_volatile_mem_functor2 encapsulates a volatile method with 2 arguments and an object instance.
+ * Use the convenience function mem_fun() to create an instance of bound_volatile_mem_functor2.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2>
+class bound_volatile_mem_functor2
+  : public volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2>
+{
+  typedef volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2> base_type_;
+public:
+  typedef typename base_type_::function_type function_type;
+
+  /** Constructs a bound_volatile_mem_functor2 object that wraps the passed method.
+   * @param _A_obj Pointer to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_volatile_mem_functor2( T_obj* _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(_A_obj) {}
+
+  /** Constructs a bound_volatile_mem_functor2 object that wraps the passed method.
+   * @param _A_obj Reference to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_volatile_mem_functor2( T_obj& _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(&_A_obj) {}
+
+  /** Execute the wrapped method operating on the stored instance.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2) const
+    { return (obj_ptr_->*(this->func_ptr_))(_A_a1,_A_a2); }
+
+//protected:
+  /// Pointer to stored object instance.
+   T_obj *obj_ptr_;
+};
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bound_volatile_mem_functor performs a functor
+ * on the object instance stored in the sigc::bound_volatile_mem_functor object.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_action, class T_return, class T_obj, class T_arg1,class T_arg2>
+void visit_each(const T_action& _A_action,
+                const bound_volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2>& _A_target)
+{
+  visit_each(_A_action, *_A_target.obj_ptr_);
+}
+
+/** bound_volatile_mem_functor3 encapsulates a volatile method with 3 arguments and an object instance.
+ * Use the convenience function mem_fun() to create an instance of bound_volatile_mem_functor3.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3>
+class bound_volatile_mem_functor3
+  : public volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>
+{
+  typedef volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3> base_type_;
+public:
+  typedef typename base_type_::function_type function_type;
+
+  /** Constructs a bound_volatile_mem_functor3 object that wraps the passed method.
+   * @param _A_obj Pointer to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_volatile_mem_functor3( T_obj* _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(_A_obj) {}
+
+  /** Constructs a bound_volatile_mem_functor3 object that wraps the passed method.
+   * @param _A_obj Reference to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_volatile_mem_functor3( T_obj& _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(&_A_obj) {}
+
+  /** Execute the wrapped method operating on the stored instance.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3) const
+    { return (obj_ptr_->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3); }
+
+//protected:
+  /// Pointer to stored object instance.
+   T_obj *obj_ptr_;
+};
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bound_volatile_mem_functor performs a functor
+ * on the object instance stored in the sigc::bound_volatile_mem_functor object.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_action, class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3>
+void visit_each(const T_action& _A_action,
+                const bound_volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>& _A_target)
+{
+  visit_each(_A_action, *_A_target.obj_ptr_);
+}
+
+/** bound_volatile_mem_functor4 encapsulates a volatile method with 4 arguments and an object instance.
+ * Use the convenience function mem_fun() to create an instance of bound_volatile_mem_functor4.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+class bound_volatile_mem_functor4
+  : public volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>
+{
+  typedef volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4> base_type_;
+public:
+  typedef typename base_type_::function_type function_type;
+
+  /** Constructs a bound_volatile_mem_functor4 object that wraps the passed method.
+   * @param _A_obj Pointer to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_volatile_mem_functor4( T_obj* _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(_A_obj) {}
+
+  /** Constructs a bound_volatile_mem_functor4 object that wraps the passed method.
+   * @param _A_obj Reference to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_volatile_mem_functor4( T_obj& _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(&_A_obj) {}
+
+  /** Execute the wrapped method operating on the stored instance.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4) const
+    { return (obj_ptr_->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3,_A_a4); }
+
+//protected:
+  /// Pointer to stored object instance.
+   T_obj *obj_ptr_;
+};
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bound_volatile_mem_functor performs a functor
+ * on the object instance stored in the sigc::bound_volatile_mem_functor object.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_action, class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+void visit_each(const T_action& _A_action,
+                const bound_volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>& _A_target)
+{
+  visit_each(_A_action, *_A_target.obj_ptr_);
+}
+
+/** bound_volatile_mem_functor5 encapsulates a volatile method with 5 arguments and an object instance.
+ * Use the convenience function mem_fun() to create an instance of bound_volatile_mem_functor5.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_arg5 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+class bound_volatile_mem_functor5
+  : public volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+{
+  typedef volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5> base_type_;
+public:
+  typedef typename base_type_::function_type function_type;
+
+  /** Constructs a bound_volatile_mem_functor5 object that wraps the passed method.
+   * @param _A_obj Pointer to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_volatile_mem_functor5( T_obj* _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(_A_obj) {}
+
+  /** Constructs a bound_volatile_mem_functor5 object that wraps the passed method.
+   * @param _A_obj Reference to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_volatile_mem_functor5( T_obj& _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(&_A_obj) {}
+
+  /** Execute the wrapped method operating on the stored instance.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @param _A_a5 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5) const
+    { return (obj_ptr_->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5); }
+
+//protected:
+  /// Pointer to stored object instance.
+   T_obj *obj_ptr_;
+};
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bound_volatile_mem_functor performs a functor
+ * on the object instance stored in the sigc::bound_volatile_mem_functor object.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_action, class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+void visit_each(const T_action& _A_action,
+                const bound_volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>& _A_target)
+{
+  visit_each(_A_action, *_A_target.obj_ptr_);
+}
+
+/** bound_volatile_mem_functor6 encapsulates a volatile method with 6 arguments and an object instance.
+ * Use the convenience function mem_fun() to create an instance of bound_volatile_mem_functor6.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_arg5 Argument type used in the definition of operator()().
+ * - @e T_arg6 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+class bound_volatile_mem_functor6
+  : public volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+{
+  typedef volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6> base_type_;
+public:
+  typedef typename base_type_::function_type function_type;
+
+  /** Constructs a bound_volatile_mem_functor6 object that wraps the passed method.
+   * @param _A_obj Pointer to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_volatile_mem_functor6( T_obj* _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(_A_obj) {}
+
+  /** Constructs a bound_volatile_mem_functor6 object that wraps the passed method.
+   * @param _A_obj Reference to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_volatile_mem_functor6( T_obj& _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(&_A_obj) {}
+
+  /** Execute the wrapped method operating on the stored instance.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @param _A_a5 Argument to be passed on to the method.
+   * @param _A_a6 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6) const
+    { return (obj_ptr_->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6); }
+
+//protected:
+  /// Pointer to stored object instance.
+   T_obj *obj_ptr_;
+};
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bound_volatile_mem_functor performs a functor
+ * on the object instance stored in the sigc::bound_volatile_mem_functor object.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_action, class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+void visit_each(const T_action& _A_action,
+                const bound_volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>& _A_target)
+{
+  visit_each(_A_action, *_A_target.obj_ptr_);
+}
+
+/** bound_volatile_mem_functor7 encapsulates a volatile method with 7 arguments and an object instance.
+ * Use the convenience function mem_fun() to create an instance of bound_volatile_mem_functor7.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_arg5 Argument type used in the definition of operator()().
+ * - @e T_arg6 Argument type used in the definition of operator()().
+ * - @e T_arg7 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+class bound_volatile_mem_functor7
+  : public volatile_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+{
+  typedef volatile_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7> base_type_;
+public:
+  typedef typename base_type_::function_type function_type;
+
+  /** Constructs a bound_volatile_mem_functor7 object that wraps the passed method.
+   * @param _A_obj Pointer to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_volatile_mem_functor7( T_obj* _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(_A_obj) {}
+
+  /** Constructs a bound_volatile_mem_functor7 object that wraps the passed method.
+   * @param _A_obj Reference to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_volatile_mem_functor7( T_obj& _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(&_A_obj) {}
+
+  /** Execute the wrapped method operating on the stored instance.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @param _A_a5 Argument to be passed on to the method.
+   * @param _A_a6 Argument to be passed on to the method.
+   * @param _A_a7 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6,typename type_trait<T_arg7>::take _A_a7) const
+    { return (obj_ptr_->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6,_A_a7); }
+
+//protected:
+  /// Pointer to stored object instance.
+   T_obj *obj_ptr_;
+};
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bound_volatile_mem_functor performs a functor
+ * on the object instance stored in the sigc::bound_volatile_mem_functor object.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_action, class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+void visit_each(const T_action& _A_action,
+                const bound_volatile_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>& _A_target)
+{
+  visit_each(_A_action, *_A_target.obj_ptr_);
+}
+
+/** bound_const_volatile_mem_functor0 encapsulates a const volatile method with 0 arguments and an object instance.
+ * Use the convenience function mem_fun() to create an instance of bound_const_volatile_mem_functor0.
+ *
+ * The following template arguments are used:
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj>
+class bound_const_volatile_mem_functor0
+  : public const_volatile_mem_functor0<T_return, T_obj>
+{
+  typedef const_volatile_mem_functor0<T_return, T_obj> base_type_;
+public:
+  typedef typename base_type_::function_type function_type;
+
+  /** Constructs a bound_const_volatile_mem_functor0 object that wraps the passed method.
+   * @param _A_obj Pointer to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_const_volatile_mem_functor0(const T_obj* _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(_A_obj) {}
+
+  /** Constructs a bound_const_volatile_mem_functor0 object that wraps the passed method.
+   * @param _A_obj Reference to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_const_volatile_mem_functor0(const T_obj& _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(&_A_obj) {}
+
+  /** Execute the wrapped method operating on the stored instance.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()() const
+    { return (obj_ptr_->*(this->func_ptr_))(); }
+
+//protected:
+  /// Pointer to stored object instance.
+  const T_obj *obj_ptr_;
+};
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bound_const_volatile_mem_functor performs a functor
+ * on the object instance stored in the sigc::bound_const_volatile_mem_functor object.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_action, class T_return, class T_obj>
+void visit_each(const T_action& _A_action,
+                const bound_const_volatile_mem_functor0<T_return, T_obj>& _A_target)
+{
+  visit_each(_A_action, *_A_target.obj_ptr_);
+}
+
+/** bound_const_volatile_mem_functor1 encapsulates a const volatile method with 1 arguments and an object instance.
+ * Use the convenience function mem_fun() to create an instance of bound_const_volatile_mem_functor1.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1>
+class bound_const_volatile_mem_functor1
+  : public const_volatile_mem_functor1<T_return, T_obj, T_arg1>
+{
+  typedef const_volatile_mem_functor1<T_return, T_obj, T_arg1> base_type_;
+public:
+  typedef typename base_type_::function_type function_type;
+
+  /** Constructs a bound_const_volatile_mem_functor1 object that wraps the passed method.
+   * @param _A_obj Pointer to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_const_volatile_mem_functor1(const T_obj* _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(_A_obj) {}
+
+  /** Constructs a bound_const_volatile_mem_functor1 object that wraps the passed method.
+   * @param _A_obj Reference to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_const_volatile_mem_functor1(const T_obj& _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(&_A_obj) {}
+
+  /** Execute the wrapped method operating on the stored instance.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(typename type_trait<T_arg1>::take _A_a1) const
+    { return (obj_ptr_->*(this->func_ptr_))(_A_a1); }
+
+//protected:
+  /// Pointer to stored object instance.
+  const T_obj *obj_ptr_;
+};
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bound_const_volatile_mem_functor performs a functor
+ * on the object instance stored in the sigc::bound_const_volatile_mem_functor object.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_action, class T_return, class T_obj, class T_arg1>
+void visit_each(const T_action& _A_action,
+                const bound_const_volatile_mem_functor1<T_return, T_obj, T_arg1>& _A_target)
+{
+  visit_each(_A_action, *_A_target.obj_ptr_);
+}
+
+/** bound_const_volatile_mem_functor2 encapsulates a const volatile method with 2 arguments and an object instance.
+ * Use the convenience function mem_fun() to create an instance of bound_const_volatile_mem_functor2.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2>
+class bound_const_volatile_mem_functor2
+  : public const_volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2>
+{
+  typedef const_volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2> base_type_;
+public:
+  typedef typename base_type_::function_type function_type;
+
+  /** Constructs a bound_const_volatile_mem_functor2 object that wraps the passed method.
+   * @param _A_obj Pointer to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_const_volatile_mem_functor2(const T_obj* _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(_A_obj) {}
+
+  /** Constructs a bound_const_volatile_mem_functor2 object that wraps the passed method.
+   * @param _A_obj Reference to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_const_volatile_mem_functor2(const T_obj& _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(&_A_obj) {}
+
+  /** Execute the wrapped method operating on the stored instance.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2) const
+    { return (obj_ptr_->*(this->func_ptr_))(_A_a1,_A_a2); }
+
+//protected:
+  /// Pointer to stored object instance.
+  const T_obj *obj_ptr_;
+};
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bound_const_volatile_mem_functor performs a functor
+ * on the object instance stored in the sigc::bound_const_volatile_mem_functor object.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_action, class T_return, class T_obj, class T_arg1,class T_arg2>
+void visit_each(const T_action& _A_action,
+                const bound_const_volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2>& _A_target)
+{
+  visit_each(_A_action, *_A_target.obj_ptr_);
+}
+
+/** bound_const_volatile_mem_functor3 encapsulates a const volatile method with 3 arguments and an object instance.
+ * Use the convenience function mem_fun() to create an instance of bound_const_volatile_mem_functor3.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3>
+class bound_const_volatile_mem_functor3
+  : public const_volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>
+{
+  typedef const_volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3> base_type_;
+public:
+  typedef typename base_type_::function_type function_type;
+
+  /** Constructs a bound_const_volatile_mem_functor3 object that wraps the passed method.
+   * @param _A_obj Pointer to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_const_volatile_mem_functor3(const T_obj* _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(_A_obj) {}
+
+  /** Constructs a bound_const_volatile_mem_functor3 object that wraps the passed method.
+   * @param _A_obj Reference to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_const_volatile_mem_functor3(const T_obj& _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(&_A_obj) {}
+
+  /** Execute the wrapped method operating on the stored instance.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3) const
+    { return (obj_ptr_->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3); }
+
+//protected:
+  /// Pointer to stored object instance.
+  const T_obj *obj_ptr_;
+};
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bound_const_volatile_mem_functor performs a functor
+ * on the object instance stored in the sigc::bound_const_volatile_mem_functor object.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_action, class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3>
+void visit_each(const T_action& _A_action,
+                const bound_const_volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>& _A_target)
+{
+  visit_each(_A_action, *_A_target.obj_ptr_);
+}
+
+/** bound_const_volatile_mem_functor4 encapsulates a const volatile method with 4 arguments and an object instance.
+ * Use the convenience function mem_fun() to create an instance of bound_const_volatile_mem_functor4.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+class bound_const_volatile_mem_functor4
+  : public const_volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>
+{
+  typedef const_volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4> base_type_;
+public:
+  typedef typename base_type_::function_type function_type;
+
+  /** Constructs a bound_const_volatile_mem_functor4 object that wraps the passed method.
+   * @param _A_obj Pointer to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_const_volatile_mem_functor4(const T_obj* _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(_A_obj) {}
+
+  /** Constructs a bound_const_volatile_mem_functor4 object that wraps the passed method.
+   * @param _A_obj Reference to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_const_volatile_mem_functor4(const T_obj& _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(&_A_obj) {}
+
+  /** Execute the wrapped method operating on the stored instance.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4) const
+    { return (obj_ptr_->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3,_A_a4); }
+
+//protected:
+  /// Pointer to stored object instance.
+  const T_obj *obj_ptr_;
+};
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bound_const_volatile_mem_functor performs a functor
+ * on the object instance stored in the sigc::bound_const_volatile_mem_functor object.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_action, class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+void visit_each(const T_action& _A_action,
+                const bound_const_volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>& _A_target)
+{
+  visit_each(_A_action, *_A_target.obj_ptr_);
+}
+
+/** bound_const_volatile_mem_functor5 encapsulates a const volatile method with 5 arguments and an object instance.
+ * Use the convenience function mem_fun() to create an instance of bound_const_volatile_mem_functor5.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_arg5 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+class bound_const_volatile_mem_functor5
+  : public const_volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+{
+  typedef const_volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5> base_type_;
+public:
+  typedef typename base_type_::function_type function_type;
+
+  /** Constructs a bound_const_volatile_mem_functor5 object that wraps the passed method.
+   * @param _A_obj Pointer to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_const_volatile_mem_functor5(const T_obj* _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(_A_obj) {}
+
+  /** Constructs a bound_const_volatile_mem_functor5 object that wraps the passed method.
+   * @param _A_obj Reference to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_const_volatile_mem_functor5(const T_obj& _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(&_A_obj) {}
+
+  /** Execute the wrapped method operating on the stored instance.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @param _A_a5 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5) const
+    { return (obj_ptr_->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5); }
+
+//protected:
+  /// Pointer to stored object instance.
+  const T_obj *obj_ptr_;
+};
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bound_const_volatile_mem_functor performs a functor
+ * on the object instance stored in the sigc::bound_const_volatile_mem_functor object.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_action, class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+void visit_each(const T_action& _A_action,
+                const bound_const_volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>& _A_target)
+{
+  visit_each(_A_action, *_A_target.obj_ptr_);
+}
+
+/** bound_const_volatile_mem_functor6 encapsulates a const volatile method with 6 arguments and an object instance.
+ * Use the convenience function mem_fun() to create an instance of bound_const_volatile_mem_functor6.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_arg5 Argument type used in the definition of operator()().
+ * - @e T_arg6 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+class bound_const_volatile_mem_functor6
+  : public const_volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+{
+  typedef const_volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6> base_type_;
+public:
+  typedef typename base_type_::function_type function_type;
+
+  /** Constructs a bound_const_volatile_mem_functor6 object that wraps the passed method.
+   * @param _A_obj Pointer to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_const_volatile_mem_functor6(const T_obj* _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(_A_obj) {}
+
+  /** Constructs a bound_const_volatile_mem_functor6 object that wraps the passed method.
+   * @param _A_obj Reference to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_const_volatile_mem_functor6(const T_obj& _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(&_A_obj) {}
+
+  /** Execute the wrapped method operating on the stored instance.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @param _A_a5 Argument to be passed on to the method.
+   * @param _A_a6 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6) const
+    { return (obj_ptr_->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6); }
+
+//protected:
+  /// Pointer to stored object instance.
+  const T_obj *obj_ptr_;
+};
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bound_const_volatile_mem_functor performs a functor
+ * on the object instance stored in the sigc::bound_const_volatile_mem_functor object.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_action, class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+void visit_each(const T_action& _A_action,
+                const bound_const_volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>& _A_target)
+{
+  visit_each(_A_action, *_A_target.obj_ptr_);
+}
+
+/** bound_const_volatile_mem_functor7 encapsulates a const volatile method with 7 arguments and an object instance.
+ * Use the convenience function mem_fun() to create an instance of bound_const_volatile_mem_functor7.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_arg5 Argument type used in the definition of operator()().
+ * - @e T_arg6 Argument type used in the definition of operator()().
+ * - @e T_arg7 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ * - @e T_obj The object type.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+class bound_const_volatile_mem_functor7
+  : public const_volatile_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+{
+  typedef const_volatile_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7> base_type_;
+public:
+  typedef typename base_type_::function_type function_type;
+
+  /** Constructs a bound_const_volatile_mem_functor7 object that wraps the passed method.
+   * @param _A_obj Pointer to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_const_volatile_mem_functor7(const T_obj* _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(_A_obj) {}
+
+  /** Constructs a bound_const_volatile_mem_functor7 object that wraps the passed method.
+   * @param _A_obj Reference to instance the method will operate on.
+   * @param _A_func Pointer to method will be invoked from operator()().
+   */
+  bound_const_volatile_mem_functor7(const T_obj& _A_obj, function_type _A_func)
+    : base_type_(_A_func), obj_ptr_(&_A_obj) {}
+
+  /** Execute the wrapped method operating on the stored instance.
+   * @param _A_a1 Argument to be passed on to the method.
+   * @param _A_a2 Argument to be passed on to the method.
+   * @param _A_a3 Argument to be passed on to the method.
+   * @param _A_a4 Argument to be passed on to the method.
+   * @param _A_a5 Argument to be passed on to the method.
+   * @param _A_a6 Argument to be passed on to the method.
+   * @param _A_a7 Argument to be passed on to the method.
+   * @return The return value of the method invocation.
+   */
+  T_return operator()(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6,typename type_trait<T_arg7>::take _A_a7) const
+    { return (obj_ptr_->*(this->func_ptr_))(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6,_A_a7); }
+
+//protected:
+  /// Pointer to stored object instance.
+  const T_obj *obj_ptr_;
+};
+
+/** Performs a functor on each of the targets of a functor.
+ * The function overload for sigc::bound_const_volatile_mem_functor performs a functor
+ * on the object instance stored in the sigc::bound_const_volatile_mem_functor object.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_action, class T_return, class T_obj, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+void visit_each(const T_action& _A_action,
+                const bound_const_volatile_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>& _A_target)
+{
+  visit_each(_A_action, *_A_target.obj_ptr_);
+}
+
+
+// numbered
+/** Creates a functor of type sigc::mem_functor0 which wraps a  method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj>
+inline mem_functor0<T_return, T_obj>
+mem_fun0(T_return (T_obj::*_A_func)() )
+{ return mem_functor0<T_return, T_obj>(_A_func); }
+
+/** Creates a functor of type sigc::mem_functor1 which wraps a  method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1, class T_return, class T_obj>
+inline mem_functor1<T_return, T_obj, T_arg1>
+mem_fun1(T_return (T_obj::*_A_func)(T_arg1) )
+{ return mem_functor1<T_return, T_obj, T_arg1>(_A_func); }
+
+/** Creates a functor of type sigc::mem_functor2 which wraps a  method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2, class T_return, class T_obj>
+inline mem_functor2<T_return, T_obj, T_arg1,T_arg2>
+mem_fun2(T_return (T_obj::*_A_func)(T_arg1,T_arg2) )
+{ return mem_functor2<T_return, T_obj, T_arg1,T_arg2>(_A_func); }
+
+/** Creates a functor of type sigc::mem_functor3 which wraps a  method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3, class T_return, class T_obj>
+inline mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>
+mem_fun3(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3) )
+{ return mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>(_A_func); }
+
+/** Creates a functor of type sigc::mem_functor4 which wraps a  method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_return, class T_obj>
+inline mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>
+mem_fun4(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4) )
+{ return mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>(_A_func); }
+
+/** Creates a functor of type sigc::mem_functor5 which wraps a  method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_return, class T_obj>
+inline mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+mem_fun5(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) )
+{ return mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_func); }
+
+/** Creates a functor of type sigc::mem_functor6 which wraps a  method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_return, class T_obj>
+inline mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+mem_fun6(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) )
+{ return mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_func); }
+
+/** Creates a functor of type sigc::mem_functor7 which wraps a  method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_return, class T_obj>
+inline mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+mem_fun7(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7) )
+{ return mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>(_A_func); }
+
+/** Creates a functor of type sigc::const_mem_functor0 which wraps a const method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj>
+inline const_mem_functor0<T_return, T_obj>
+mem_fun0(T_return (T_obj::*_A_func)() const)
+{ return const_mem_functor0<T_return, T_obj>(_A_func); }
+
+/** Creates a functor of type sigc::const_mem_functor1 which wraps a const method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1, class T_return, class T_obj>
+inline const_mem_functor1<T_return, T_obj, T_arg1>
+mem_fun1(T_return (T_obj::*_A_func)(T_arg1) const)
+{ return const_mem_functor1<T_return, T_obj, T_arg1>(_A_func); }
+
+/** Creates a functor of type sigc::const_mem_functor2 which wraps a const method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2, class T_return, class T_obj>
+inline const_mem_functor2<T_return, T_obj, T_arg1,T_arg2>
+mem_fun2(T_return (T_obj::*_A_func)(T_arg1,T_arg2) const)
+{ return const_mem_functor2<T_return, T_obj, T_arg1,T_arg2>(_A_func); }
+
+/** Creates a functor of type sigc::const_mem_functor3 which wraps a const method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3, class T_return, class T_obj>
+inline const_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>
+mem_fun3(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3) const)
+{ return const_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>(_A_func); }
+
+/** Creates a functor of type sigc::const_mem_functor4 which wraps a const method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_return, class T_obj>
+inline const_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>
+mem_fun4(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4) const)
+{ return const_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>(_A_func); }
+
+/** Creates a functor of type sigc::const_mem_functor5 which wraps a const method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_return, class T_obj>
+inline const_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+mem_fun5(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) const)
+{ return const_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_func); }
+
+/** Creates a functor of type sigc::const_mem_functor6 which wraps a const method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_return, class T_obj>
+inline const_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+mem_fun6(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) const)
+{ return const_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_func); }
+
+/** Creates a functor of type sigc::const_mem_functor7 which wraps a const method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_return, class T_obj>
+inline const_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+mem_fun7(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7) const)
+{ return const_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>(_A_func); }
+
+/** Creates a functor of type sigc::volatile_mem_functor0 which wraps a volatile method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj>
+inline volatile_mem_functor0<T_return, T_obj>
+mem_fun0(T_return (T_obj::*_A_func)() volatile)
+{ return volatile_mem_functor0<T_return, T_obj>(_A_func); }
+
+/** Creates a functor of type sigc::volatile_mem_functor1 which wraps a volatile method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1, class T_return, class T_obj>
+inline volatile_mem_functor1<T_return, T_obj, T_arg1>
+mem_fun1(T_return (T_obj::*_A_func)(T_arg1) volatile)
+{ return volatile_mem_functor1<T_return, T_obj, T_arg1>(_A_func); }
+
+/** Creates a functor of type sigc::volatile_mem_functor2 which wraps a volatile method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2, class T_return, class T_obj>
+inline volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2>
+mem_fun2(T_return (T_obj::*_A_func)(T_arg1,T_arg2) volatile)
+{ return volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2>(_A_func); }
+
+/** Creates a functor of type sigc::volatile_mem_functor3 which wraps a volatile method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3, class T_return, class T_obj>
+inline volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>
+mem_fun3(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3) volatile)
+{ return volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>(_A_func); }
+
+/** Creates a functor of type sigc::volatile_mem_functor4 which wraps a volatile method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_return, class T_obj>
+inline volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>
+mem_fun4(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4) volatile)
+{ return volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>(_A_func); }
+
+/** Creates a functor of type sigc::volatile_mem_functor5 which wraps a volatile method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_return, class T_obj>
+inline volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+mem_fun5(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) volatile)
+{ return volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_func); }
+
+/** Creates a functor of type sigc::volatile_mem_functor6 which wraps a volatile method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_return, class T_obj>
+inline volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+mem_fun6(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) volatile)
+{ return volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_func); }
+
+/** Creates a functor of type sigc::volatile_mem_functor7 which wraps a volatile method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_return, class T_obj>
+inline volatile_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+mem_fun7(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7) volatile)
+{ return volatile_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>(_A_func); }
+
+/** Creates a functor of type sigc::const_volatile_mem_functor0 which wraps a const volatile method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj>
+inline const_volatile_mem_functor0<T_return, T_obj>
+mem_fun0(T_return (T_obj::*_A_func)() const volatile)
+{ return const_volatile_mem_functor0<T_return, T_obj>(_A_func); }
+
+/** Creates a functor of type sigc::const_volatile_mem_functor1 which wraps a const volatile method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1, class T_return, class T_obj>
+inline const_volatile_mem_functor1<T_return, T_obj, T_arg1>
+mem_fun1(T_return (T_obj::*_A_func)(T_arg1) const volatile)
+{ return const_volatile_mem_functor1<T_return, T_obj, T_arg1>(_A_func); }
+
+/** Creates a functor of type sigc::const_volatile_mem_functor2 which wraps a const volatile method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2, class T_return, class T_obj>
+inline const_volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2>
+mem_fun2(T_return (T_obj::*_A_func)(T_arg1,T_arg2) const volatile)
+{ return const_volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2>(_A_func); }
+
+/** Creates a functor of type sigc::const_volatile_mem_functor3 which wraps a const volatile method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3, class T_return, class T_obj>
+inline const_volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>
+mem_fun3(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3) const volatile)
+{ return const_volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>(_A_func); }
+
+/** Creates a functor of type sigc::const_volatile_mem_functor4 which wraps a const volatile method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_return, class T_obj>
+inline const_volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>
+mem_fun4(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4) const volatile)
+{ return const_volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>(_A_func); }
+
+/** Creates a functor of type sigc::const_volatile_mem_functor5 which wraps a const volatile method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_return, class T_obj>
+inline const_volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+mem_fun5(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) const volatile)
+{ return const_volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_func); }
+
+/** Creates a functor of type sigc::const_volatile_mem_functor6 which wraps a const volatile method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_return, class T_obj>
+inline const_volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+mem_fun6(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) const volatile)
+{ return const_volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_func); }
+
+/** Creates a functor of type sigc::const_volatile_mem_functor7 which wraps a const volatile method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_return, class T_obj>
+inline const_volatile_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+mem_fun7(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7) const volatile)
+{ return const_volatile_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>(_A_func); }
+
+/** Creates a functor of type sigc::bound_mem_functor0 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_obj2>
+inline bound_mem_functor0<T_return, T_obj>
+mem_fun0(/**/ T_obj* _A_obj, T_return (T_obj2::*_A_func)() )
+{ return bound_mem_functor0<T_return, T_obj>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_mem_functor0 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_obj2>
+inline bound_mem_functor0<T_return, T_obj>
+mem_fun0(/**/ T_obj& _A_obj, T_return (T_obj2::*_A_func)() )
+{ return bound_mem_functor0<T_return, T_obj>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_mem_functor1 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1, class T_return, class T_obj, class T_obj2>
+inline bound_mem_functor1<T_return, T_obj, T_arg1>
+mem_fun1(/**/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1) )
+{ return bound_mem_functor1<T_return, T_obj, T_arg1>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_mem_functor1 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1, class T_return, class T_obj, class T_obj2>
+inline bound_mem_functor1<T_return, T_obj, T_arg1>
+mem_fun1(/**/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1) )
+{ return bound_mem_functor1<T_return, T_obj, T_arg1>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_mem_functor2 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2, class T_return, class T_obj, class T_obj2>
+inline bound_mem_functor2<T_return, T_obj, T_arg1,T_arg2>
+mem_fun2(/**/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2) )
+{ return bound_mem_functor2<T_return, T_obj, T_arg1,T_arg2>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_mem_functor2 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2, class T_return, class T_obj, class T_obj2>
+inline bound_mem_functor2<T_return, T_obj, T_arg1,T_arg2>
+mem_fun2(/**/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2) )
+{ return bound_mem_functor2<T_return, T_obj, T_arg1,T_arg2>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_mem_functor3 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3, class T_return, class T_obj, class T_obj2>
+inline bound_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>
+mem_fun3(/**/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3) )
+{ return bound_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_mem_functor3 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3, class T_return, class T_obj, class T_obj2>
+inline bound_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>
+mem_fun3(/**/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3) )
+{ return bound_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_mem_functor4 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_return, class T_obj, class T_obj2>
+inline bound_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>
+mem_fun4(/**/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4) )
+{ return bound_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_mem_functor4 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_return, class T_obj, class T_obj2>
+inline bound_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>
+mem_fun4(/**/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4) )
+{ return bound_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_mem_functor5 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_return, class T_obj, class T_obj2>
+inline bound_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+mem_fun5(/**/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) )
+{ return bound_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_mem_functor5 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_return, class T_obj, class T_obj2>
+inline bound_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+mem_fun5(/**/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) )
+{ return bound_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_mem_functor6 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_return, class T_obj, class T_obj2>
+inline bound_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+mem_fun6(/**/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) )
+{ return bound_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_mem_functor6 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_return, class T_obj, class T_obj2>
+inline bound_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+mem_fun6(/**/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) )
+{ return bound_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_mem_functor7 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_return, class T_obj, class T_obj2>
+inline bound_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+mem_fun7(/**/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7) )
+{ return bound_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_mem_functor7 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_return, class T_obj, class T_obj2>
+inline bound_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+mem_fun7(/**/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7) )
+{ return bound_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_mem_functor0 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_obj2>
+inline bound_const_mem_functor0<T_return, T_obj>
+mem_fun0(/*const*/ T_obj* _A_obj, T_return (T_obj2::*_A_func)() const)
+{ return bound_const_mem_functor0<T_return, T_obj>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_mem_functor0 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_obj2>
+inline bound_const_mem_functor0<T_return, T_obj>
+mem_fun0(/*const*/ T_obj& _A_obj, T_return (T_obj2::*_A_func)() const)
+{ return bound_const_mem_functor0<T_return, T_obj>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_mem_functor1 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1, class T_return, class T_obj, class T_obj2>
+inline bound_const_mem_functor1<T_return, T_obj, T_arg1>
+mem_fun1(/*const*/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1) const)
+{ return bound_const_mem_functor1<T_return, T_obj, T_arg1>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_mem_functor1 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1, class T_return, class T_obj, class T_obj2>
+inline bound_const_mem_functor1<T_return, T_obj, T_arg1>
+mem_fun1(/*const*/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1) const)
+{ return bound_const_mem_functor1<T_return, T_obj, T_arg1>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_mem_functor2 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2, class T_return, class T_obj, class T_obj2>
+inline bound_const_mem_functor2<T_return, T_obj, T_arg1,T_arg2>
+mem_fun2(/*const*/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2) const)
+{ return bound_const_mem_functor2<T_return, T_obj, T_arg1,T_arg2>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_mem_functor2 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2, class T_return, class T_obj, class T_obj2>
+inline bound_const_mem_functor2<T_return, T_obj, T_arg1,T_arg2>
+mem_fun2(/*const*/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2) const)
+{ return bound_const_mem_functor2<T_return, T_obj, T_arg1,T_arg2>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_mem_functor3 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3, class T_return, class T_obj, class T_obj2>
+inline bound_const_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>
+mem_fun3(/*const*/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3) const)
+{ return bound_const_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_mem_functor3 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3, class T_return, class T_obj, class T_obj2>
+inline bound_const_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>
+mem_fun3(/*const*/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3) const)
+{ return bound_const_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_mem_functor4 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_return, class T_obj, class T_obj2>
+inline bound_const_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>
+mem_fun4(/*const*/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4) const)
+{ return bound_const_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_mem_functor4 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_return, class T_obj, class T_obj2>
+inline bound_const_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>
+mem_fun4(/*const*/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4) const)
+{ return bound_const_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_mem_functor5 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_return, class T_obj, class T_obj2>
+inline bound_const_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+mem_fun5(/*const*/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) const)
+{ return bound_const_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_mem_functor5 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_return, class T_obj, class T_obj2>
+inline bound_const_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+mem_fun5(/*const*/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) const)
+{ return bound_const_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_mem_functor6 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_return, class T_obj, class T_obj2>
+inline bound_const_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+mem_fun6(/*const*/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) const)
+{ return bound_const_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_mem_functor6 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_return, class T_obj, class T_obj2>
+inline bound_const_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+mem_fun6(/*const*/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) const)
+{ return bound_const_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_mem_functor7 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_return, class T_obj, class T_obj2>
+inline bound_const_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+mem_fun7(/*const*/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7) const)
+{ return bound_const_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_mem_functor7 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_return, class T_obj, class T_obj2>
+inline bound_const_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+mem_fun7(/*const*/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7) const)
+{ return bound_const_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_volatile_mem_functor0 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_obj2>
+inline bound_volatile_mem_functor0<T_return, T_obj>
+mem_fun0(/**/ T_obj* _A_obj, T_return (T_obj2::*_A_func)() volatile)
+{ return bound_volatile_mem_functor0<T_return, T_obj>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_volatile_mem_functor0 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_obj2>
+inline bound_volatile_mem_functor0<T_return, T_obj>
+mem_fun0(/**/ T_obj& _A_obj, T_return (T_obj2::*_A_func)() volatile)
+{ return bound_volatile_mem_functor0<T_return, T_obj>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_volatile_mem_functor1 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1, class T_return, class T_obj, class T_obj2>
+inline bound_volatile_mem_functor1<T_return, T_obj, T_arg1>
+mem_fun1(/**/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1) volatile)
+{ return bound_volatile_mem_functor1<T_return, T_obj, T_arg1>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_volatile_mem_functor1 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1, class T_return, class T_obj, class T_obj2>
+inline bound_volatile_mem_functor1<T_return, T_obj, T_arg1>
+mem_fun1(/**/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1) volatile)
+{ return bound_volatile_mem_functor1<T_return, T_obj, T_arg1>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_volatile_mem_functor2 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2, class T_return, class T_obj, class T_obj2>
+inline bound_volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2>
+mem_fun2(/**/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2) volatile)
+{ return bound_volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_volatile_mem_functor2 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2, class T_return, class T_obj, class T_obj2>
+inline bound_volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2>
+mem_fun2(/**/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2) volatile)
+{ return bound_volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_volatile_mem_functor3 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3, class T_return, class T_obj, class T_obj2>
+inline bound_volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>
+mem_fun3(/**/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3) volatile)
+{ return bound_volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_volatile_mem_functor3 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3, class T_return, class T_obj, class T_obj2>
+inline bound_volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>
+mem_fun3(/**/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3) volatile)
+{ return bound_volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_volatile_mem_functor4 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_return, class T_obj, class T_obj2>
+inline bound_volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>
+mem_fun4(/**/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4) volatile)
+{ return bound_volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_volatile_mem_functor4 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_return, class T_obj, class T_obj2>
+inline bound_volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>
+mem_fun4(/**/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4) volatile)
+{ return bound_volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_volatile_mem_functor5 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_return, class T_obj, class T_obj2>
+inline bound_volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+mem_fun5(/**/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) volatile)
+{ return bound_volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_volatile_mem_functor5 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_return, class T_obj, class T_obj2>
+inline bound_volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+mem_fun5(/**/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) volatile)
+{ return bound_volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_volatile_mem_functor6 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_return, class T_obj, class T_obj2>
+inline bound_volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+mem_fun6(/**/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) volatile)
+{ return bound_volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_volatile_mem_functor6 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_return, class T_obj, class T_obj2>
+inline bound_volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+mem_fun6(/**/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) volatile)
+{ return bound_volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_volatile_mem_functor7 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_return, class T_obj, class T_obj2>
+inline bound_volatile_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+mem_fun7(/**/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7) volatile)
+{ return bound_volatile_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_volatile_mem_functor7 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_return, class T_obj, class T_obj2>
+inline bound_volatile_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+mem_fun7(/**/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7) volatile)
+{ return bound_volatile_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_volatile_mem_functor0 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_obj2>
+inline bound_const_volatile_mem_functor0<T_return, T_obj>
+mem_fun0(/*const*/ T_obj* _A_obj, T_return (T_obj2::*_A_func)() const volatile)
+{ return bound_const_volatile_mem_functor0<T_return, T_obj>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_volatile_mem_functor0 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_obj2>
+inline bound_const_volatile_mem_functor0<T_return, T_obj>
+mem_fun0(/*const*/ T_obj& _A_obj, T_return (T_obj2::*_A_func)() const volatile)
+{ return bound_const_volatile_mem_functor0<T_return, T_obj>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_volatile_mem_functor1 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1, class T_return, class T_obj, class T_obj2>
+inline bound_const_volatile_mem_functor1<T_return, T_obj, T_arg1>
+mem_fun1(/*const*/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1) const volatile)
+{ return bound_const_volatile_mem_functor1<T_return, T_obj, T_arg1>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_volatile_mem_functor1 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1, class T_return, class T_obj, class T_obj2>
+inline bound_const_volatile_mem_functor1<T_return, T_obj, T_arg1>
+mem_fun1(/*const*/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1) const volatile)
+{ return bound_const_volatile_mem_functor1<T_return, T_obj, T_arg1>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_volatile_mem_functor2 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2, class T_return, class T_obj, class T_obj2>
+inline bound_const_volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2>
+mem_fun2(/*const*/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2) const volatile)
+{ return bound_const_volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_volatile_mem_functor2 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2, class T_return, class T_obj, class T_obj2>
+inline bound_const_volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2>
+mem_fun2(/*const*/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2) const volatile)
+{ return bound_const_volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_volatile_mem_functor3 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3, class T_return, class T_obj, class T_obj2>
+inline bound_const_volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>
+mem_fun3(/*const*/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3) const volatile)
+{ return bound_const_volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_volatile_mem_functor3 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3, class T_return, class T_obj, class T_obj2>
+inline bound_const_volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>
+mem_fun3(/*const*/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3) const volatile)
+{ return bound_const_volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_volatile_mem_functor4 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_return, class T_obj, class T_obj2>
+inline bound_const_volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>
+mem_fun4(/*const*/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4) const volatile)
+{ return bound_const_volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_volatile_mem_functor4 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_return, class T_obj, class T_obj2>
+inline bound_const_volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>
+mem_fun4(/*const*/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4) const volatile)
+{ return bound_const_volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_volatile_mem_functor5 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_return, class T_obj, class T_obj2>
+inline bound_const_volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+mem_fun5(/*const*/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) const volatile)
+{ return bound_const_volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_volatile_mem_functor5 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_return, class T_obj, class T_obj2>
+inline bound_const_volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+mem_fun5(/*const*/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) const volatile)
+{ return bound_const_volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_volatile_mem_functor6 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_return, class T_obj, class T_obj2>
+inline bound_const_volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+mem_fun6(/*const*/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) const volatile)
+{ return bound_const_volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_volatile_mem_functor6 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_return, class T_obj, class T_obj2>
+inline bound_const_volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+mem_fun6(/*const*/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) const volatile)
+{ return bound_const_volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_volatile_mem_functor7 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_return, class T_obj, class T_obj2>
+inline bound_const_volatile_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+mem_fun7(/*const*/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7) const volatile)
+{ return bound_const_volatile_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_volatile_mem_functor7 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_return, class T_obj, class T_obj2>
+inline bound_const_volatile_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+mem_fun7(/*const*/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7) const volatile)
+{ return bound_const_volatile_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>(_A_obj, _A_func); }
+
+
+// unnumbered
+/** Creates a functor of type sigc::mem_functor0 which wraps a  method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj>
+inline mem_functor0<T_return, T_obj>
+mem_fun(T_return (T_obj::*_A_func)() )
+{ return mem_functor0<T_return, T_obj>(_A_func); }
+
+/** Creates a functor of type sigc::mem_functor1 which wraps a  method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1, class T_return, class T_obj>
+inline mem_functor1<T_return, T_obj, T_arg1>
+mem_fun(T_return (T_obj::*_A_func)(T_arg1) )
+{ return mem_functor1<T_return, T_obj, T_arg1>(_A_func); }
+
+/** Creates a functor of type sigc::mem_functor2 which wraps a  method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2, class T_return, class T_obj>
+inline mem_functor2<T_return, T_obj, T_arg1,T_arg2>
+mem_fun(T_return (T_obj::*_A_func)(T_arg1,T_arg2) )
+{ return mem_functor2<T_return, T_obj, T_arg1,T_arg2>(_A_func); }
+
+/** Creates a functor of type sigc::mem_functor3 which wraps a  method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3, class T_return, class T_obj>
+inline mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>
+mem_fun(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3) )
+{ return mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>(_A_func); }
+
+/** Creates a functor of type sigc::mem_functor4 which wraps a  method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_return, class T_obj>
+inline mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>
+mem_fun(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4) )
+{ return mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>(_A_func); }
+
+/** Creates a functor of type sigc::mem_functor5 which wraps a  method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_return, class T_obj>
+inline mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+mem_fun(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) )
+{ return mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_func); }
+
+/** Creates a functor of type sigc::mem_functor6 which wraps a  method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_return, class T_obj>
+inline mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+mem_fun(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) )
+{ return mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_func); }
+
+/** Creates a functor of type sigc::mem_functor7 which wraps a  method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_return, class T_obj>
+inline mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+mem_fun(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7) )
+{ return mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>(_A_func); }
+
+/** Creates a functor of type sigc::const_mem_functor0 which wraps a const method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj>
+inline const_mem_functor0<T_return, T_obj>
+mem_fun(T_return (T_obj::*_A_func)() const)
+{ return const_mem_functor0<T_return, T_obj>(_A_func); }
+
+/** Creates a functor of type sigc::const_mem_functor1 which wraps a const method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1, class T_return, class T_obj>
+inline const_mem_functor1<T_return, T_obj, T_arg1>
+mem_fun(T_return (T_obj::*_A_func)(T_arg1) const)
+{ return const_mem_functor1<T_return, T_obj, T_arg1>(_A_func); }
+
+/** Creates a functor of type sigc::const_mem_functor2 which wraps a const method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2, class T_return, class T_obj>
+inline const_mem_functor2<T_return, T_obj, T_arg1,T_arg2>
+mem_fun(T_return (T_obj::*_A_func)(T_arg1,T_arg2) const)
+{ return const_mem_functor2<T_return, T_obj, T_arg1,T_arg2>(_A_func); }
+
+/** Creates a functor of type sigc::const_mem_functor3 which wraps a const method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3, class T_return, class T_obj>
+inline const_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>
+mem_fun(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3) const)
+{ return const_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>(_A_func); }
+
+/** Creates a functor of type sigc::const_mem_functor4 which wraps a const method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_return, class T_obj>
+inline const_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>
+mem_fun(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4) const)
+{ return const_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>(_A_func); }
+
+/** Creates a functor of type sigc::const_mem_functor5 which wraps a const method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_return, class T_obj>
+inline const_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+mem_fun(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) const)
+{ return const_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_func); }
+
+/** Creates a functor of type sigc::const_mem_functor6 which wraps a const method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_return, class T_obj>
+inline const_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+mem_fun(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) const)
+{ return const_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_func); }
+
+/** Creates a functor of type sigc::const_mem_functor7 which wraps a const method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_return, class T_obj>
+inline const_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+mem_fun(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7) const)
+{ return const_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>(_A_func); }
+
+/** Creates a functor of type sigc::volatile_mem_functor0 which wraps a volatile method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj>
+inline volatile_mem_functor0<T_return, T_obj>
+mem_fun(T_return (T_obj::*_A_func)() volatile)
+{ return volatile_mem_functor0<T_return, T_obj>(_A_func); }
+
+/** Creates a functor of type sigc::volatile_mem_functor1 which wraps a volatile method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1, class T_return, class T_obj>
+inline volatile_mem_functor1<T_return, T_obj, T_arg1>
+mem_fun(T_return (T_obj::*_A_func)(T_arg1) volatile)
+{ return volatile_mem_functor1<T_return, T_obj, T_arg1>(_A_func); }
+
+/** Creates a functor of type sigc::volatile_mem_functor2 which wraps a volatile method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2, class T_return, class T_obj>
+inline volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2>
+mem_fun(T_return (T_obj::*_A_func)(T_arg1,T_arg2) volatile)
+{ return volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2>(_A_func); }
+
+/** Creates a functor of type sigc::volatile_mem_functor3 which wraps a volatile method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3, class T_return, class T_obj>
+inline volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>
+mem_fun(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3) volatile)
+{ return volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>(_A_func); }
+
+/** Creates a functor of type sigc::volatile_mem_functor4 which wraps a volatile method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_return, class T_obj>
+inline volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>
+mem_fun(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4) volatile)
+{ return volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>(_A_func); }
+
+/** Creates a functor of type sigc::volatile_mem_functor5 which wraps a volatile method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_return, class T_obj>
+inline volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+mem_fun(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) volatile)
+{ return volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_func); }
+
+/** Creates a functor of type sigc::volatile_mem_functor6 which wraps a volatile method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_return, class T_obj>
+inline volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+mem_fun(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) volatile)
+{ return volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_func); }
+
+/** Creates a functor of type sigc::volatile_mem_functor7 which wraps a volatile method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_return, class T_obj>
+inline volatile_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+mem_fun(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7) volatile)
+{ return volatile_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>(_A_func); }
+
+/** Creates a functor of type sigc::const_volatile_mem_functor0 which wraps a const volatile method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj>
+inline const_volatile_mem_functor0<T_return, T_obj>
+mem_fun(T_return (T_obj::*_A_func)() const volatile)
+{ return const_volatile_mem_functor0<T_return, T_obj>(_A_func); }
+
+/** Creates a functor of type sigc::const_volatile_mem_functor1 which wraps a const volatile method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1, class T_return, class T_obj>
+inline const_volatile_mem_functor1<T_return, T_obj, T_arg1>
+mem_fun(T_return (T_obj::*_A_func)(T_arg1) const volatile)
+{ return const_volatile_mem_functor1<T_return, T_obj, T_arg1>(_A_func); }
+
+/** Creates a functor of type sigc::const_volatile_mem_functor2 which wraps a const volatile method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2, class T_return, class T_obj>
+inline const_volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2>
+mem_fun(T_return (T_obj::*_A_func)(T_arg1,T_arg2) const volatile)
+{ return const_volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2>(_A_func); }
+
+/** Creates a functor of type sigc::const_volatile_mem_functor3 which wraps a const volatile method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3, class T_return, class T_obj>
+inline const_volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>
+mem_fun(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3) const volatile)
+{ return const_volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>(_A_func); }
+
+/** Creates a functor of type sigc::const_volatile_mem_functor4 which wraps a const volatile method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_return, class T_obj>
+inline const_volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>
+mem_fun(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4) const volatile)
+{ return const_volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>(_A_func); }
+
+/** Creates a functor of type sigc::const_volatile_mem_functor5 which wraps a const volatile method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_return, class T_obj>
+inline const_volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+mem_fun(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) const volatile)
+{ return const_volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_func); }
+
+/** Creates a functor of type sigc::const_volatile_mem_functor6 which wraps a const volatile method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_return, class T_obj>
+inline const_volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+mem_fun(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) const volatile)
+{ return const_volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_func); }
+
+/** Creates a functor of type sigc::const_volatile_mem_functor7 which wraps a const volatile method.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_return, class T_obj>
+inline const_volatile_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+mem_fun(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7) const volatile)
+{ return const_volatile_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>(_A_func); }
+
+/** Creates a functor of type sigc::bound_mem_functor0 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_obj2>
+inline bound_mem_functor0<T_return, T_obj>
+mem_fun(/**/ T_obj* _A_obj, T_return (T_obj2::*_A_func)() )
+{ return bound_mem_functor0<T_return, T_obj>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_mem_functor0 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_obj2>
+inline bound_mem_functor0<T_return, T_obj>
+mem_fun(/**/ T_obj& _A_obj, T_return (T_obj2::*_A_func)() )
+{ return bound_mem_functor0<T_return, T_obj>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_mem_functor1 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1, class T_return, class T_obj, class T_obj2>
+inline bound_mem_functor1<T_return, T_obj, T_arg1>
+mem_fun(/**/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1) )
+{ return bound_mem_functor1<T_return, T_obj, T_arg1>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_mem_functor1 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1, class T_return, class T_obj, class T_obj2>
+inline bound_mem_functor1<T_return, T_obj, T_arg1>
+mem_fun(/**/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1) )
+{ return bound_mem_functor1<T_return, T_obj, T_arg1>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_mem_functor2 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2, class T_return, class T_obj, class T_obj2>
+inline bound_mem_functor2<T_return, T_obj, T_arg1,T_arg2>
+mem_fun(/**/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2) )
+{ return bound_mem_functor2<T_return, T_obj, T_arg1,T_arg2>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_mem_functor2 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2, class T_return, class T_obj, class T_obj2>
+inline bound_mem_functor2<T_return, T_obj, T_arg1,T_arg2>
+mem_fun(/**/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2) )
+{ return bound_mem_functor2<T_return, T_obj, T_arg1,T_arg2>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_mem_functor3 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3, class T_return, class T_obj, class T_obj2>
+inline bound_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>
+mem_fun(/**/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3) )
+{ return bound_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_mem_functor3 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3, class T_return, class T_obj, class T_obj2>
+inline bound_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>
+mem_fun(/**/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3) )
+{ return bound_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_mem_functor4 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_return, class T_obj, class T_obj2>
+inline bound_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>
+mem_fun(/**/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4) )
+{ return bound_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_mem_functor4 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_return, class T_obj, class T_obj2>
+inline bound_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>
+mem_fun(/**/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4) )
+{ return bound_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_mem_functor5 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_return, class T_obj, class T_obj2>
+inline bound_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+mem_fun(/**/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) )
+{ return bound_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_mem_functor5 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_return, class T_obj, class T_obj2>
+inline bound_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+mem_fun(/**/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) )
+{ return bound_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_mem_functor6 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_return, class T_obj, class T_obj2>
+inline bound_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+mem_fun(/**/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) )
+{ return bound_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_mem_functor6 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_return, class T_obj, class T_obj2>
+inline bound_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+mem_fun(/**/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) )
+{ return bound_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_mem_functor7 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_return, class T_obj, class T_obj2>
+inline bound_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+mem_fun(/**/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7) )
+{ return bound_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_mem_functor7 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_return, class T_obj, class T_obj2>
+inline bound_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+mem_fun(/**/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7) )
+{ return bound_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_mem_functor0 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_obj2>
+inline bound_const_mem_functor0<T_return, T_obj>
+mem_fun(/*const*/ T_obj* _A_obj, T_return (T_obj2::*_A_func)() const)
+{ return bound_const_mem_functor0<T_return, T_obj>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_mem_functor0 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_obj2>
+inline bound_const_mem_functor0<T_return, T_obj>
+mem_fun(/*const*/ T_obj& _A_obj, T_return (T_obj2::*_A_func)() const)
+{ return bound_const_mem_functor0<T_return, T_obj>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_mem_functor1 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1, class T_return, class T_obj, class T_obj2>
+inline bound_const_mem_functor1<T_return, T_obj, T_arg1>
+mem_fun(/*const*/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1) const)
+{ return bound_const_mem_functor1<T_return, T_obj, T_arg1>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_mem_functor1 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1, class T_return, class T_obj, class T_obj2>
+inline bound_const_mem_functor1<T_return, T_obj, T_arg1>
+mem_fun(/*const*/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1) const)
+{ return bound_const_mem_functor1<T_return, T_obj, T_arg1>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_mem_functor2 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2, class T_return, class T_obj, class T_obj2>
+inline bound_const_mem_functor2<T_return, T_obj, T_arg1,T_arg2>
+mem_fun(/*const*/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2) const)
+{ return bound_const_mem_functor2<T_return, T_obj, T_arg1,T_arg2>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_mem_functor2 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2, class T_return, class T_obj, class T_obj2>
+inline bound_const_mem_functor2<T_return, T_obj, T_arg1,T_arg2>
+mem_fun(/*const*/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2) const)
+{ return bound_const_mem_functor2<T_return, T_obj, T_arg1,T_arg2>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_mem_functor3 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3, class T_return, class T_obj, class T_obj2>
+inline bound_const_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>
+mem_fun(/*const*/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3) const)
+{ return bound_const_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_mem_functor3 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3, class T_return, class T_obj, class T_obj2>
+inline bound_const_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>
+mem_fun(/*const*/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3) const)
+{ return bound_const_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_mem_functor4 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_return, class T_obj, class T_obj2>
+inline bound_const_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>
+mem_fun(/*const*/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4) const)
+{ return bound_const_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_mem_functor4 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_return, class T_obj, class T_obj2>
+inline bound_const_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>
+mem_fun(/*const*/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4) const)
+{ return bound_const_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_mem_functor5 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_return, class T_obj, class T_obj2>
+inline bound_const_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+mem_fun(/*const*/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) const)
+{ return bound_const_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_mem_functor5 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_return, class T_obj, class T_obj2>
+inline bound_const_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+mem_fun(/*const*/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) const)
+{ return bound_const_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_mem_functor6 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_return, class T_obj, class T_obj2>
+inline bound_const_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+mem_fun(/*const*/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) const)
+{ return bound_const_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_mem_functor6 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_return, class T_obj, class T_obj2>
+inline bound_const_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+mem_fun(/*const*/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) const)
+{ return bound_const_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_mem_functor7 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_return, class T_obj, class T_obj2>
+inline bound_const_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+mem_fun(/*const*/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7) const)
+{ return bound_const_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_mem_functor7 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_return, class T_obj, class T_obj2>
+inline bound_const_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+mem_fun(/*const*/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7) const)
+{ return bound_const_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_volatile_mem_functor0 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_obj2>
+inline bound_volatile_mem_functor0<T_return, T_obj>
+mem_fun(/**/ T_obj* _A_obj, T_return (T_obj2::*_A_func)() volatile)
+{ return bound_volatile_mem_functor0<T_return, T_obj>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_volatile_mem_functor0 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_obj2>
+inline bound_volatile_mem_functor0<T_return, T_obj>
+mem_fun(/**/ T_obj& _A_obj, T_return (T_obj2::*_A_func)() volatile)
+{ return bound_volatile_mem_functor0<T_return, T_obj>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_volatile_mem_functor1 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1, class T_return, class T_obj, class T_obj2>
+inline bound_volatile_mem_functor1<T_return, T_obj, T_arg1>
+mem_fun(/**/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1) volatile)
+{ return bound_volatile_mem_functor1<T_return, T_obj, T_arg1>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_volatile_mem_functor1 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1, class T_return, class T_obj, class T_obj2>
+inline bound_volatile_mem_functor1<T_return, T_obj, T_arg1>
+mem_fun(/**/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1) volatile)
+{ return bound_volatile_mem_functor1<T_return, T_obj, T_arg1>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_volatile_mem_functor2 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2, class T_return, class T_obj, class T_obj2>
+inline bound_volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2>
+mem_fun(/**/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2) volatile)
+{ return bound_volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_volatile_mem_functor2 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2, class T_return, class T_obj, class T_obj2>
+inline bound_volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2>
+mem_fun(/**/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2) volatile)
+{ return bound_volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_volatile_mem_functor3 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3, class T_return, class T_obj, class T_obj2>
+inline bound_volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>
+mem_fun(/**/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3) volatile)
+{ return bound_volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_volatile_mem_functor3 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3, class T_return, class T_obj, class T_obj2>
+inline bound_volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>
+mem_fun(/**/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3) volatile)
+{ return bound_volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_volatile_mem_functor4 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_return, class T_obj, class T_obj2>
+inline bound_volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>
+mem_fun(/**/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4) volatile)
+{ return bound_volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_volatile_mem_functor4 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_return, class T_obj, class T_obj2>
+inline bound_volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>
+mem_fun(/**/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4) volatile)
+{ return bound_volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_volatile_mem_functor5 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_return, class T_obj, class T_obj2>
+inline bound_volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+mem_fun(/**/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) volatile)
+{ return bound_volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_volatile_mem_functor5 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_return, class T_obj, class T_obj2>
+inline bound_volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+mem_fun(/**/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) volatile)
+{ return bound_volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_volatile_mem_functor6 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_return, class T_obj, class T_obj2>
+inline bound_volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+mem_fun(/**/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) volatile)
+{ return bound_volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_volatile_mem_functor6 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_return, class T_obj, class T_obj2>
+inline bound_volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+mem_fun(/**/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) volatile)
+{ return bound_volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_volatile_mem_functor7 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_return, class T_obj, class T_obj2>
+inline bound_volatile_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+mem_fun(/**/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7) volatile)
+{ return bound_volatile_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_volatile_mem_functor7 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_return, class T_obj, class T_obj2>
+inline bound_volatile_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+mem_fun(/**/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7) volatile)
+{ return bound_volatile_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_volatile_mem_functor0 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_obj2>
+inline bound_const_volatile_mem_functor0<T_return, T_obj>
+mem_fun(/*const*/ T_obj* _A_obj, T_return (T_obj2::*_A_func)() const volatile)
+{ return bound_const_volatile_mem_functor0<T_return, T_obj>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_volatile_mem_functor0 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_return, class T_obj, class T_obj2>
+inline bound_const_volatile_mem_functor0<T_return, T_obj>
+mem_fun(/*const*/ T_obj& _A_obj, T_return (T_obj2::*_A_func)() const volatile)
+{ return bound_const_volatile_mem_functor0<T_return, T_obj>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_volatile_mem_functor1 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1, class T_return, class T_obj, class T_obj2>
+inline bound_const_volatile_mem_functor1<T_return, T_obj, T_arg1>
+mem_fun(/*const*/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1) const volatile)
+{ return bound_const_volatile_mem_functor1<T_return, T_obj, T_arg1>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_volatile_mem_functor1 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1, class T_return, class T_obj, class T_obj2>
+inline bound_const_volatile_mem_functor1<T_return, T_obj, T_arg1>
+mem_fun(/*const*/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1) const volatile)
+{ return bound_const_volatile_mem_functor1<T_return, T_obj, T_arg1>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_volatile_mem_functor2 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2, class T_return, class T_obj, class T_obj2>
+inline bound_const_volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2>
+mem_fun(/*const*/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2) const volatile)
+{ return bound_const_volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_volatile_mem_functor2 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2, class T_return, class T_obj, class T_obj2>
+inline bound_const_volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2>
+mem_fun(/*const*/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2) const volatile)
+{ return bound_const_volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_volatile_mem_functor3 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3, class T_return, class T_obj, class T_obj2>
+inline bound_const_volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>
+mem_fun(/*const*/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3) const volatile)
+{ return bound_const_volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_volatile_mem_functor3 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3, class T_return, class T_obj, class T_obj2>
+inline bound_const_volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>
+mem_fun(/*const*/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3) const volatile)
+{ return bound_const_volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_volatile_mem_functor4 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_return, class T_obj, class T_obj2>
+inline bound_const_volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>
+mem_fun(/*const*/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4) const volatile)
+{ return bound_const_volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_volatile_mem_functor4 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_return, class T_obj, class T_obj2>
+inline bound_const_volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>
+mem_fun(/*const*/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4) const volatile)
+{ return bound_const_volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_volatile_mem_functor5 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_return, class T_obj, class T_obj2>
+inline bound_const_volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+mem_fun(/*const*/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) const volatile)
+{ return bound_const_volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_volatile_mem_functor5 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_return, class T_obj, class T_obj2>
+inline bound_const_volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+mem_fun(/*const*/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) const volatile)
+{ return bound_const_volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_volatile_mem_functor6 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_return, class T_obj, class T_obj2>
+inline bound_const_volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+mem_fun(/*const*/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) const volatile)
+{ return bound_const_volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_volatile_mem_functor6 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_return, class T_obj, class T_obj2>
+inline bound_const_volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+mem_fun(/*const*/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) const volatile)
+{ return bound_const_volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_volatile_mem_functor7 which encapsulates a method and an object instance.
+ * @param _A_obj Pointer to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_return, class T_obj, class T_obj2>
+inline bound_const_volatile_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+mem_fun(/*const*/ T_obj* _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7) const volatile)
+{ return bound_const_volatile_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>(_A_obj, _A_func); }
+
+/** Creates a functor of type sigc::bound_const_volatile_mem_functor7 which encapsulates a method and an object instance.
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup mem_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_return, class T_obj, class T_obj2>
+inline bound_const_volatile_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+mem_fun(/*const*/ T_obj& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7) const volatile)
+{ return bound_const_volatile_mem_functor7<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>(_A_obj, _A_func); }
+
+
+} /* namespace sigc */
+#endif /* _SIGC_FUNCTORS_MACROS_MEM_FUNHM4_ */
diff --git a/libs/sigc++2/sigc++/functors/ptr_fun.h b/libs/sigc++2/sigc++/functors/ptr_fun.h
new file mode 100644
index 0000000000..5ab6b5ab96
--- /dev/null
+++ b/libs/sigc++2/sigc++/functors/ptr_fun.h
@@ -0,0 +1,542 @@
+// -*- c++ -*-
+/* Do not edit! -- generated file */
+
+#ifndef _SIGC_FUNCTORS_MACROS_PTR_FUNHM4_
+#define _SIGC_FUNCTORS_MACROS_PTR_FUNHM4_
+#include <sigc++/type_traits.h>
+#include <sigc++/functors/functor_trait.h>
+
+namespace sigc {
+
+/** @defgroup ptr_fun ptr_fun()
+ * ptr_fun() is used to convert a pointer to a function to a functor.
+ * If the function pointer is to an overloaded type, you must specify
+ * the types using template arguments starting with the first argument.
+ * It is not necessary to supply the return type.
+ *
+ * @par Example:
+ *   @code
+ *   void foo(int) {}
+ *   sigc::slot<void, int> sl = sigc::ptr_fun(&foo);
+ *   @endcode
+ *
+ * Use ptr_fun#() if there is an abiguity as to the number of arguments.
+ *
+ * @par Example:
+ *   @code
+ *   void foo(int) {}  // choose this one
+ *   void foo(float) {}
+ *   void foo(int, int) {}
+ *   sigc::slot<void, long> sl = sigc::ptr_fun1<int>(&foo);
+ *   @endcode
+ *
+ * ptr_fun() can also be used to convert a pointer to a static member
+ * function to a functor, like so:
+ *
+ * @par Example:
+ *   @code
+ *   struct foo
+ *   {
+ *     static void bar(int) {}
+ *   };
+ *   sigc::slot<void, int> sl = sigc::ptr_fun(&foo::bar);
+ *   @endcode
+ *
+ * @ingroup functors
+ */
+
+/** pointer_functor0 wraps existing non-member functions with 0 argument(s).
+ * Use the convenience function ptr_fun() to create an instance of pointer_functor0.
+ *
+ * The following template arguments are used:
+ * - @e T_return The return type of operator()().
+ *
+ * @ingroup ptr_fun
+ */
+template <class T_return>
+class pointer_functor0 : public functor_base
+{
+  typedef T_return (*function_type)();
+protected: 
+  function_type func_ptr_;
+public:
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  pointer_functor0() {}
+
+  /** Constructs a pointer_functor0 object that wraps an existing function.
+   * @param _A_func Pointer to function that will be invoked from operator()().
+   */
+  explicit pointer_functor0(function_type _A_func): func_ptr_(_A_func) {}
+
+  /** Execute the wrapped function.
+   * @return The return value of the function invocation.
+   */
+  T_return operator()() const 
+    { return func_ptr_(); }
+};
+
+/** pointer_functor1 wraps existing non-member functions with 1 argument(s).
+ * Use the convenience function ptr_fun() to create an instance of pointer_functor1.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ *
+ * @ingroup ptr_fun
+ */
+template <class T_arg1, class T_return>
+class pointer_functor1 : public functor_base
+{
+  typedef T_return (*function_type)(T_arg1);
+protected: 
+  function_type func_ptr_;
+public:
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  pointer_functor1() {}
+
+  /** Constructs a pointer_functor1 object that wraps an existing function.
+   * @param _A_func Pointer to function that will be invoked from operator()().
+   */
+  explicit pointer_functor1(function_type _A_func): func_ptr_(_A_func) {}
+
+  /** Execute the wrapped function.
+   * @param _A_a1 Argument to be passed on to the function.
+   * @return The return value of the function invocation.
+   */
+  T_return operator()(typename type_trait<T_arg1>::take _A_a1) const 
+    { return func_ptr_(_A_a1); }
+};
+
+/** pointer_functor2 wraps existing non-member functions with 2 argument(s).
+ * Use the convenience function ptr_fun() to create an instance of pointer_functor2.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ *
+ * @ingroup ptr_fun
+ */
+template <class T_arg1,class T_arg2, class T_return>
+class pointer_functor2 : public functor_base
+{
+  typedef T_return (*function_type)(T_arg1,T_arg2);
+protected: 
+  function_type func_ptr_;
+public:
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  pointer_functor2() {}
+
+  /** Constructs a pointer_functor2 object that wraps an existing function.
+   * @param _A_func Pointer to function that will be invoked from operator()().
+   */
+  explicit pointer_functor2(function_type _A_func): func_ptr_(_A_func) {}
+
+  /** Execute the wrapped function.
+   * @param _A_a1 Argument to be passed on to the function.
+   * @param _A_a2 Argument to be passed on to the function.
+   * @return The return value of the function invocation.
+   */
+  T_return operator()(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2) const 
+    { return func_ptr_(_A_a1,_A_a2); }
+};
+
+/** pointer_functor3 wraps existing non-member functions with 3 argument(s).
+ * Use the convenience function ptr_fun() to create an instance of pointer_functor3.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ *
+ * @ingroup ptr_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3, class T_return>
+class pointer_functor3 : public functor_base
+{
+  typedef T_return (*function_type)(T_arg1,T_arg2,T_arg3);
+protected: 
+  function_type func_ptr_;
+public:
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  pointer_functor3() {}
+
+  /** Constructs a pointer_functor3 object that wraps an existing function.
+   * @param _A_func Pointer to function that will be invoked from operator()().
+   */
+  explicit pointer_functor3(function_type _A_func): func_ptr_(_A_func) {}
+
+  /** Execute the wrapped function.
+   * @param _A_a1 Argument to be passed on to the function.
+   * @param _A_a2 Argument to be passed on to the function.
+   * @param _A_a3 Argument to be passed on to the function.
+   * @return The return value of the function invocation.
+   */
+  T_return operator()(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3) const 
+    { return func_ptr_(_A_a1,_A_a2,_A_a3); }
+};
+
+/** pointer_functor4 wraps existing non-member functions with 4 argument(s).
+ * Use the convenience function ptr_fun() to create an instance of pointer_functor4.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ *
+ * @ingroup ptr_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_return>
+class pointer_functor4 : public functor_base
+{
+  typedef T_return (*function_type)(T_arg1,T_arg2,T_arg3,T_arg4);
+protected: 
+  function_type func_ptr_;
+public:
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  pointer_functor4() {}
+
+  /** Constructs a pointer_functor4 object that wraps an existing function.
+   * @param _A_func Pointer to function that will be invoked from operator()().
+   */
+  explicit pointer_functor4(function_type _A_func): func_ptr_(_A_func) {}
+
+  /** Execute the wrapped function.
+   * @param _A_a1 Argument to be passed on to the function.
+   * @param _A_a2 Argument to be passed on to the function.
+   * @param _A_a3 Argument to be passed on to the function.
+   * @param _A_a4 Argument to be passed on to the function.
+   * @return The return value of the function invocation.
+   */
+  T_return operator()(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4) const 
+    { return func_ptr_(_A_a1,_A_a2,_A_a3,_A_a4); }
+};
+
+/** pointer_functor5 wraps existing non-member functions with 5 argument(s).
+ * Use the convenience function ptr_fun() to create an instance of pointer_functor5.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_arg5 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ *
+ * @ingroup ptr_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_return>
+class pointer_functor5 : public functor_base
+{
+  typedef T_return (*function_type)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5);
+protected: 
+  function_type func_ptr_;
+public:
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  pointer_functor5() {}
+
+  /** Constructs a pointer_functor5 object that wraps an existing function.
+   * @param _A_func Pointer to function that will be invoked from operator()().
+   */
+  explicit pointer_functor5(function_type _A_func): func_ptr_(_A_func) {}
+
+  /** Execute the wrapped function.
+   * @param _A_a1 Argument to be passed on to the function.
+   * @param _A_a2 Argument to be passed on to the function.
+   * @param _A_a3 Argument to be passed on to the function.
+   * @param _A_a4 Argument to be passed on to the function.
+   * @param _A_a5 Argument to be passed on to the function.
+   * @return The return value of the function invocation.
+   */
+  T_return operator()(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5) const 
+    { return func_ptr_(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5); }
+};
+
+/** pointer_functor6 wraps existing non-member functions with 6 argument(s).
+ * Use the convenience function ptr_fun() to create an instance of pointer_functor6.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_arg5 Argument type used in the definition of operator()().
+ * - @e T_arg6 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ *
+ * @ingroup ptr_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_return>
+class pointer_functor6 : public functor_base
+{
+  typedef T_return (*function_type)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6);
+protected: 
+  function_type func_ptr_;
+public:
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  pointer_functor6() {}
+
+  /** Constructs a pointer_functor6 object that wraps an existing function.
+   * @param _A_func Pointer to function that will be invoked from operator()().
+   */
+  explicit pointer_functor6(function_type _A_func): func_ptr_(_A_func) {}
+
+  /** Execute the wrapped function.
+   * @param _A_a1 Argument to be passed on to the function.
+   * @param _A_a2 Argument to be passed on to the function.
+   * @param _A_a3 Argument to be passed on to the function.
+   * @param _A_a4 Argument to be passed on to the function.
+   * @param _A_a5 Argument to be passed on to the function.
+   * @param _A_a6 Argument to be passed on to the function.
+   * @return The return value of the function invocation.
+   */
+  T_return operator()(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6) const 
+    { return func_ptr_(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6); }
+};
+
+/** pointer_functor7 wraps existing non-member functions with 7 argument(s).
+ * Use the convenience function ptr_fun() to create an instance of pointer_functor7.
+ *
+ * The following template arguments are used:
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_arg5 Argument type used in the definition of operator()().
+ * - @e T_arg6 Argument type used in the definition of operator()().
+ * - @e T_arg7 Argument type used in the definition of operator()().
+ * - @e T_return The return type of operator()().
+ *
+ * @ingroup ptr_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_return>
+class pointer_functor7 : public functor_base
+{
+  typedef T_return (*function_type)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7);
+protected: 
+  function_type func_ptr_;
+public:
+  typedef T_return result_type;
+
+  /// Constructs an invalid functor.
+  pointer_functor7() {}
+
+  /** Constructs a pointer_functor7 object that wraps an existing function.
+   * @param _A_func Pointer to function that will be invoked from operator()().
+   */
+  explicit pointer_functor7(function_type _A_func): func_ptr_(_A_func) {}
+
+  /** Execute the wrapped function.
+   * @param _A_a1 Argument to be passed on to the function.
+   * @param _A_a2 Argument to be passed on to the function.
+   * @param _A_a3 Argument to be passed on to the function.
+   * @param _A_a4 Argument to be passed on to the function.
+   * @param _A_a5 Argument to be passed on to the function.
+   * @param _A_a6 Argument to be passed on to the function.
+   * @param _A_a7 Argument to be passed on to the function.
+   * @return The return value of the function invocation.
+   */
+  T_return operator()(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6,typename type_trait<T_arg7>::take _A_a7) const 
+    { return func_ptr_(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6,_A_a7); }
+};
+
+
+// numbered ptr_fun
+/** Creates a functor of type sigc::pointer_functor0 which wraps an existing non-member function.
+ * @param _A_func Pointer to function that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup ptr_fun
+ */
+template <class T_return>
+inline pointer_functor0<T_return> 
+ptr_fun0(T_return (*_A_func)())
+{ return pointer_functor0<T_return>(_A_func); }
+
+/** Creates a functor of type sigc::pointer_functor1 which wraps an existing non-member function.
+ * @param _A_func Pointer to function that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup ptr_fun
+ */
+template <class T_arg1, class T_return>
+inline pointer_functor1<T_arg1, T_return> 
+ptr_fun1(T_return (*_A_func)(T_arg1))
+{ return pointer_functor1<T_arg1, T_return>(_A_func); }
+
+/** Creates a functor of type sigc::pointer_functor2 which wraps an existing non-member function.
+ * @param _A_func Pointer to function that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup ptr_fun
+ */
+template <class T_arg1,class T_arg2, class T_return>
+inline pointer_functor2<T_arg1,T_arg2, T_return> 
+ptr_fun2(T_return (*_A_func)(T_arg1,T_arg2))
+{ return pointer_functor2<T_arg1,T_arg2, T_return>(_A_func); }
+
+/** Creates a functor of type sigc::pointer_functor3 which wraps an existing non-member function.
+ * @param _A_func Pointer to function that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup ptr_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3, class T_return>
+inline pointer_functor3<T_arg1,T_arg2,T_arg3, T_return> 
+ptr_fun3(T_return (*_A_func)(T_arg1,T_arg2,T_arg3))
+{ return pointer_functor3<T_arg1,T_arg2,T_arg3, T_return>(_A_func); }
+
+/** Creates a functor of type sigc::pointer_functor4 which wraps an existing non-member function.
+ * @param _A_func Pointer to function that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup ptr_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_return>
+inline pointer_functor4<T_arg1,T_arg2,T_arg3,T_arg4, T_return> 
+ptr_fun4(T_return (*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4))
+{ return pointer_functor4<T_arg1,T_arg2,T_arg3,T_arg4, T_return>(_A_func); }
+
+/** Creates a functor of type sigc::pointer_functor5 which wraps an existing non-member function.
+ * @param _A_func Pointer to function that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup ptr_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_return>
+inline pointer_functor5<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5, T_return> 
+ptr_fun5(T_return (*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5))
+{ return pointer_functor5<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5, T_return>(_A_func); }
+
+/** Creates a functor of type sigc::pointer_functor6 which wraps an existing non-member function.
+ * @param _A_func Pointer to function that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup ptr_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_return>
+inline pointer_functor6<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6, T_return> 
+ptr_fun6(T_return (*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6))
+{ return pointer_functor6<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6, T_return>(_A_func); }
+
+/** Creates a functor of type sigc::pointer_functor7 which wraps an existing non-member function.
+ * @param _A_func Pointer to function that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup ptr_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_return>
+inline pointer_functor7<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7, T_return> 
+ptr_fun7(T_return (*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7))
+{ return pointer_functor7<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7, T_return>(_A_func); }
+
+
+// unnumbered ptr_fun
+/** Creates a functor of type sigc::pointer_functor0 which wraps an existing non-member function.
+ * @param _A_func Pointer to function that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup ptr_fun
+ */
+template <class T_return>
+inline pointer_functor0<T_return> 
+ptr_fun(T_return (*_A_func)())
+{ return pointer_functor0<T_return>(_A_func); }
+
+/** Creates a functor of type sigc::pointer_functor1 which wraps an existing non-member function.
+ * @param _A_func Pointer to function that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup ptr_fun
+ */
+template <class T_arg1, class T_return>
+inline pointer_functor1<T_arg1, T_return> 
+ptr_fun(T_return (*_A_func)(T_arg1))
+{ return pointer_functor1<T_arg1, T_return>(_A_func); }
+
+/** Creates a functor of type sigc::pointer_functor2 which wraps an existing non-member function.
+ * @param _A_func Pointer to function that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup ptr_fun
+ */
+template <class T_arg1,class T_arg2, class T_return>
+inline pointer_functor2<T_arg1,T_arg2, T_return> 
+ptr_fun(T_return (*_A_func)(T_arg1,T_arg2))
+{ return pointer_functor2<T_arg1,T_arg2, T_return>(_A_func); }
+
+/** Creates a functor of type sigc::pointer_functor3 which wraps an existing non-member function.
+ * @param _A_func Pointer to function that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup ptr_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3, class T_return>
+inline pointer_functor3<T_arg1,T_arg2,T_arg3, T_return> 
+ptr_fun(T_return (*_A_func)(T_arg1,T_arg2,T_arg3))
+{ return pointer_functor3<T_arg1,T_arg2,T_arg3, T_return>(_A_func); }
+
+/** Creates a functor of type sigc::pointer_functor4 which wraps an existing non-member function.
+ * @param _A_func Pointer to function that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup ptr_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_return>
+inline pointer_functor4<T_arg1,T_arg2,T_arg3,T_arg4, T_return> 
+ptr_fun(T_return (*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4))
+{ return pointer_functor4<T_arg1,T_arg2,T_arg3,T_arg4, T_return>(_A_func); }
+
+/** Creates a functor of type sigc::pointer_functor5 which wraps an existing non-member function.
+ * @param _A_func Pointer to function that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup ptr_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_return>
+inline pointer_functor5<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5, T_return> 
+ptr_fun(T_return (*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5))
+{ return pointer_functor5<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5, T_return>(_A_func); }
+
+/** Creates a functor of type sigc::pointer_functor6 which wraps an existing non-member function.
+ * @param _A_func Pointer to function that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup ptr_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_return>
+inline pointer_functor6<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6, T_return> 
+ptr_fun(T_return (*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6))
+{ return pointer_functor6<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6, T_return>(_A_func); }
+
+/** Creates a functor of type sigc::pointer_functor7 which wraps an existing non-member function.
+ * @param _A_func Pointer to function that should be wrapped.
+ * @return Functor that executes @e _A_func on invokation.
+ *
+ * @ingroup ptr_fun
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_return>
+inline pointer_functor7<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7, T_return> 
+ptr_fun(T_return (*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7))
+{ return pointer_functor7<T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7, T_return>(_A_func); }
+
+
+} /* namespace sigc */
+#endif /* _SIGC_FUNCTORS_MACROS_PTR_FUNHM4_ */
diff --git a/libs/sigc++2/sigc++/functors/slot.cc b/libs/sigc++2/sigc++/functors/slot.cc
new file mode 100644
index 0000000000..5b9c92e201
--- /dev/null
+++ b/libs/sigc++2/sigc++/functors/slot.cc
@@ -0,0 +1,25 @@
+// -*- c++ -*-
+/*
+ * Copyright 2002, The libsigc++ Development Team
+ *
+ *  This library is free software; you can redistribute it and/or
+ *  modify it under the terms of the GNU Lesser General Public
+ *  License as published by the Free Software Foundation; either
+ *  version 2.1 of the License, or (at your option) any later version.
+ *
+ *  This library is distributed in the hope that it will be useful,
+ *  but WITHOUT ANY WARRANTY; without even the implied warranty of
+ *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
+ *  Lesser General Public License for more details.
+ *
+ *  You should have received a copy of the GNU Lesser General Public
+ *  License along with this library; if not, write to the Free Software
+ *  Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
+ *
+ */
+#include <sigc++/functors/slot.h>
+
+namespace sigc {
+
+
+} /* namespace sigc */
diff --git a/libs/sigc++2/sigc++/functors/slot.h b/libs/sigc++2/sigc++/functors/slot.h
new file mode 100644
index 0000000000..51294fe4d8
--- /dev/null
+++ b/libs/sigc++2/sigc++/functors/slot.h
@@ -0,0 +1,1263 @@
+// -*- c++ -*-
+/* Do not edit! -- generated file */
+#ifndef _SIGC_FUNCTORS_MACROS_SLOTHM4_
+#define _SIGC_FUNCTORS_MACROS_SLOTHM4_
+#include <sigc++/trackable.h>
+#include <sigc++/visit_each.h>
+#include <sigc++/adaptors/adaptor_trait.h>
+#include <sigc++/functors/slot_base.h>
+
+namespace sigc {
+
+namespace internal {
+
+/** A typed slot_rep.
+ * A typed slot_rep holds a functor that can be invoked from
+ * slot::operator()(). visit_each() is used to visit the functor's
+ * targets that inherit trackable recursively and register the
+ * notification callback. Consequently the slot_rep object will be
+ * notified when some referred object is destroyed or overwritten.
+ */
+template <class T_functor>
+struct typed_slot_rep : public slot_rep
+{
+  typedef typed_slot_rep<T_functor> self;
+
+  /* Use an adaptor type so that arguments can be passed as const references
+   * through explicit template instantiation from slot_call#::call_it() */
+  typedef typename adaptor_trait<T_functor>::adaptor_type adaptor_type;
+
+  /** The functor contained by this slot_rep object. */
+  adaptor_type functor_;
+
+  /** Constructs an invalid typed slot_rep object.
+   * The notification callback is registered using visit_each().
+   * @param functor The functor contained by the new slot_rep object.
+   */
+  inline typed_slot_rep(const T_functor& functor)
+    : slot_rep(0, &destroy, &dup), functor_(functor)
+    { visit_each_type<trackable*>(slot_do_bind(this), functor_); }
+
+  inline typed_slot_rep(const typed_slot_rep& cl)
+    : slot_rep(cl.call_, &destroy, &dup), functor_(cl.functor_)
+    { visit_each_type<trackable*>(slot_do_bind(this), functor_); }
+
+  inline ~typed_slot_rep()
+    {
+      call_ = 0;
+      destroy_ = 0;
+      visit_each_type<trackable*>(slot_do_unbind(this), functor_);
+    }
+
+  /** Detaches the stored functor from the other referred trackables and destroys it.
+   * This does not destroy the base slot_rep object.
+   */
+  static void* destroy(void* data)
+    {
+      self* self_ = static_cast<self*>((slot_rep*)data);
+      self_->call_ = 0;
+      self_->destroy_ = 0;
+      visit_each_type<trackable*>(slot_do_unbind(self_), self_->functor_);
+      self_->functor_.~adaptor_type();
+      /* don't call disconnect() here: destroy() is either called
+       * a) from the parent itself (in which case disconnect() leads to a segfault) or
+       * b) from a parentless slot (in which case disconnect() does nothing)
+       */
+      return 0;
+    }
+
+  /** Makes a deep copy of the slot_rep object.
+   * Deep copy means that the notification callback of the new
+   * slot_rep object is registered in the referred trackables.
+   * @return A deep copy of the slot_rep object.
+   */
+  static void* dup(void* data)
+    {
+      slot_rep* rep_ = (slot_rep*)data;
+      return static_cast<slot_rep*>(new self(*static_cast<self*>(rep_)));
+    }
+};
+
+
+/** Abstracts functor execution.
+ * call_it() invokes a functor of type @e T_functor with a list of
+ * parameters whose types are given by the template arguments.
+ * address() forms a function pointer from call_it().
+ *
+ * The following template arguments are used:
+ * - @e T_functor The functor type.
+ * - @e T_return The return type of call_it().
+ *
+ */
+template<class T_functor, class T_return>
+struct slot_call0
+{
+  /** Invokes a functor of type @p T_functor.
+   * @param rep slot_rep object that holds a functor of type @p T_functor.
+   * @return The return values of the functor invocation.
+   */
+  static T_return call_it(slot_rep* rep)
+    {
+      typedef typed_slot_rep<T_functor> typed_slot;
+      typed_slot *typed_rep = static_cast<typed_slot*>(rep);
+      return (typed_rep->functor_)();
+    }
+
+  /** Forms a function pointer from call_it().
+   * @return A function pointer formed from call_it().
+   */
+  static hook address() 
+    { return reinterpret_cast<hook>(&call_it); }
+};
+
+/** Abstracts functor execution.
+ * call_it() invokes a functor of type @e T_functor with a list of
+ * parameters whose types are given by the template arguments.
+ * address() forms a function pointer from call_it().
+ *
+ * The following template arguments are used:
+ * - @e T_functor The functor type.
+ * - @e T_return The return type of call_it().
+ * - @e T_arg1 Argument type used in the definition of call_it().
+ *
+ */
+template<class T_functor, class T_return, class T_arg1>
+struct slot_call1
+{
+  /** Invokes a functor of type @p T_functor.
+   * @param rep slot_rep object that holds a functor of type @p T_functor.
+   * @param _A_a1 Argument to be passed on to the functor.
+   * @return The return values of the functor invocation.
+   */
+  static T_return call_it(slot_rep* rep, typename type_trait<T_arg1>::take a_1)
+    {
+      typedef typed_slot_rep<T_functor> typed_slot;
+      typed_slot *typed_rep = static_cast<typed_slot*>(rep);
+      return (typed_rep->functor_).SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::take>
+               (a_1);
+    }
+
+  /** Forms a function pointer from call_it().
+   * @return A function pointer formed from call_it().
+   */
+  static hook address() 
+    { return reinterpret_cast<hook>(&call_it); }
+};
+
+/** Abstracts functor execution.
+ * call_it() invokes a functor of type @e T_functor with a list of
+ * parameters whose types are given by the template arguments.
+ * address() forms a function pointer from call_it().
+ *
+ * The following template arguments are used:
+ * - @e T_functor The functor type.
+ * - @e T_return The return type of call_it().
+ * - @e T_arg1 Argument type used in the definition of call_it().
+ * - @e T_arg2 Argument type used in the definition of call_it().
+ *
+ */
+template<class T_functor, class T_return, class T_arg1,class T_arg2>
+struct slot_call2
+{
+  /** Invokes a functor of type @p T_functor.
+   * @param rep slot_rep object that holds a functor of type @p T_functor.
+   * @param _A_a1 Argument to be passed on to the functor.
+   * @param _A_a2 Argument to be passed on to the functor.
+   * @return The return values of the functor invocation.
+   */
+  static T_return call_it(slot_rep* rep, typename type_trait<T_arg1>::take a_1,typename type_trait<T_arg2>::take a_2)
+    {
+      typedef typed_slot_rep<T_functor> typed_slot;
+      typed_slot *typed_rep = static_cast<typed_slot*>(rep);
+      return (typed_rep->functor_).SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::take,typename type_trait<T_arg2>::take>
+               (a_1,a_2);
+    }
+
+  /** Forms a function pointer from call_it().
+   * @return A function pointer formed from call_it().
+   */
+  static hook address() 
+    { return reinterpret_cast<hook>(&call_it); }
+};
+
+/** Abstracts functor execution.
+ * call_it() invokes a functor of type @e T_functor with a list of
+ * parameters whose types are given by the template arguments.
+ * address() forms a function pointer from call_it().
+ *
+ * The following template arguments are used:
+ * - @e T_functor The functor type.
+ * - @e T_return The return type of call_it().
+ * - @e T_arg1 Argument type used in the definition of call_it().
+ * - @e T_arg2 Argument type used in the definition of call_it().
+ * - @e T_arg3 Argument type used in the definition of call_it().
+ *
+ */
+template<class T_functor, class T_return, class T_arg1,class T_arg2,class T_arg3>
+struct slot_call3
+{
+  /** Invokes a functor of type @p T_functor.
+   * @param rep slot_rep object that holds a functor of type @p T_functor.
+   * @param _A_a1 Argument to be passed on to the functor.
+   * @param _A_a2 Argument to be passed on to the functor.
+   * @param _A_a3 Argument to be passed on to the functor.
+   * @return The return values of the functor invocation.
+   */
+  static T_return call_it(slot_rep* rep, typename type_trait<T_arg1>::take a_1,typename type_trait<T_arg2>::take a_2,typename type_trait<T_arg3>::take a_3)
+    {
+      typedef typed_slot_rep<T_functor> typed_slot;
+      typed_slot *typed_rep = static_cast<typed_slot*>(rep);
+      return (typed_rep->functor_).SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::take,typename type_trait<T_arg2>::take,typename type_trait<T_arg3>::take>
+               (a_1,a_2,a_3);
+    }
+
+  /** Forms a function pointer from call_it().
+   * @return A function pointer formed from call_it().
+   */
+  static hook address() 
+    { return reinterpret_cast<hook>(&call_it); }
+};
+
+/** Abstracts functor execution.
+ * call_it() invokes a functor of type @e T_functor with a list of
+ * parameters whose types are given by the template arguments.
+ * address() forms a function pointer from call_it().
+ *
+ * The following template arguments are used:
+ * - @e T_functor The functor type.
+ * - @e T_return The return type of call_it().
+ * - @e T_arg1 Argument type used in the definition of call_it().
+ * - @e T_arg2 Argument type used in the definition of call_it().
+ * - @e T_arg3 Argument type used in the definition of call_it().
+ * - @e T_arg4 Argument type used in the definition of call_it().
+ *
+ */
+template<class T_functor, class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+struct slot_call4
+{
+  /** Invokes a functor of type @p T_functor.
+   * @param rep slot_rep object that holds a functor of type @p T_functor.
+   * @param _A_a1 Argument to be passed on to the functor.
+   * @param _A_a2 Argument to be passed on to the functor.
+   * @param _A_a3 Argument to be passed on to the functor.
+   * @param _A_a4 Argument to be passed on to the functor.
+   * @return The return values of the functor invocation.
+   */
+  static T_return call_it(slot_rep* rep, typename type_trait<T_arg1>::take a_1,typename type_trait<T_arg2>::take a_2,typename type_trait<T_arg3>::take a_3,typename type_trait<T_arg4>::take a_4)
+    {
+      typedef typed_slot_rep<T_functor> typed_slot;
+      typed_slot *typed_rep = static_cast<typed_slot*>(rep);
+      return (typed_rep->functor_).SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::take,typename type_trait<T_arg2>::take,typename type_trait<T_arg3>::take,typename type_trait<T_arg4>::take>
+               (a_1,a_2,a_3,a_4);
+    }
+
+  /** Forms a function pointer from call_it().
+   * @return A function pointer formed from call_it().
+   */
+  static hook address() 
+    { return reinterpret_cast<hook>(&call_it); }
+};
+
+/** Abstracts functor execution.
+ * call_it() invokes a functor of type @e T_functor with a list of
+ * parameters whose types are given by the template arguments.
+ * address() forms a function pointer from call_it().
+ *
+ * The following template arguments are used:
+ * - @e T_functor The functor type.
+ * - @e T_return The return type of call_it().
+ * - @e T_arg1 Argument type used in the definition of call_it().
+ * - @e T_arg2 Argument type used in the definition of call_it().
+ * - @e T_arg3 Argument type used in the definition of call_it().
+ * - @e T_arg4 Argument type used in the definition of call_it().
+ * - @e T_arg5 Argument type used in the definition of call_it().
+ *
+ */
+template<class T_functor, class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+struct slot_call5
+{
+  /** Invokes a functor of type @p T_functor.
+   * @param rep slot_rep object that holds a functor of type @p T_functor.
+   * @param _A_a1 Argument to be passed on to the functor.
+   * @param _A_a2 Argument to be passed on to the functor.
+   * @param _A_a3 Argument to be passed on to the functor.
+   * @param _A_a4 Argument to be passed on to the functor.
+   * @param _A_a5 Argument to be passed on to the functor.
+   * @return The return values of the functor invocation.
+   */
+  static T_return call_it(slot_rep* rep, typename type_trait<T_arg1>::take a_1,typename type_trait<T_arg2>::take a_2,typename type_trait<T_arg3>::take a_3,typename type_trait<T_arg4>::take a_4,typename type_trait<T_arg5>::take a_5)
+    {
+      typedef typed_slot_rep<T_functor> typed_slot;
+      typed_slot *typed_rep = static_cast<typed_slot*>(rep);
+      return (typed_rep->functor_).SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::take,typename type_trait<T_arg2>::take,typename type_trait<T_arg3>::take,typename type_trait<T_arg4>::take,typename type_trait<T_arg5>::take>
+               (a_1,a_2,a_3,a_4,a_5);
+    }
+
+  /** Forms a function pointer from call_it().
+   * @return A function pointer formed from call_it().
+   */
+  static hook address() 
+    { return reinterpret_cast<hook>(&call_it); }
+};
+
+/** Abstracts functor execution.
+ * call_it() invokes a functor of type @e T_functor with a list of
+ * parameters whose types are given by the template arguments.
+ * address() forms a function pointer from call_it().
+ *
+ * The following template arguments are used:
+ * - @e T_functor The functor type.
+ * - @e T_return The return type of call_it().
+ * - @e T_arg1 Argument type used in the definition of call_it().
+ * - @e T_arg2 Argument type used in the definition of call_it().
+ * - @e T_arg3 Argument type used in the definition of call_it().
+ * - @e T_arg4 Argument type used in the definition of call_it().
+ * - @e T_arg5 Argument type used in the definition of call_it().
+ * - @e T_arg6 Argument type used in the definition of call_it().
+ *
+ */
+template<class T_functor, class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+struct slot_call6
+{
+  /** Invokes a functor of type @p T_functor.
+   * @param rep slot_rep object that holds a functor of type @p T_functor.
+   * @param _A_a1 Argument to be passed on to the functor.
+   * @param _A_a2 Argument to be passed on to the functor.
+   * @param _A_a3 Argument to be passed on to the functor.
+   * @param _A_a4 Argument to be passed on to the functor.
+   * @param _A_a5 Argument to be passed on to the functor.
+   * @param _A_a6 Argument to be passed on to the functor.
+   * @return The return values of the functor invocation.
+   */
+  static T_return call_it(slot_rep* rep, typename type_trait<T_arg1>::take a_1,typename type_trait<T_arg2>::take a_2,typename type_trait<T_arg3>::take a_3,typename type_trait<T_arg4>::take a_4,typename type_trait<T_arg5>::take a_5,typename type_trait<T_arg6>::take a_6)
+    {
+      typedef typed_slot_rep<T_functor> typed_slot;
+      typed_slot *typed_rep = static_cast<typed_slot*>(rep);
+      return (typed_rep->functor_).SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::take,typename type_trait<T_arg2>::take,typename type_trait<T_arg3>::take,typename type_trait<T_arg4>::take,typename type_trait<T_arg5>::take,typename type_trait<T_arg6>::take>
+               (a_1,a_2,a_3,a_4,a_5,a_6);
+    }
+
+  /** Forms a function pointer from call_it().
+   * @return A function pointer formed from call_it().
+   */
+  static hook address() 
+    { return reinterpret_cast<hook>(&call_it); }
+};
+
+/** Abstracts functor execution.
+ * call_it() invokes a functor of type @e T_functor with a list of
+ * parameters whose types are given by the template arguments.
+ * address() forms a function pointer from call_it().
+ *
+ * The following template arguments are used:
+ * - @e T_functor The functor type.
+ * - @e T_return The return type of call_it().
+ * - @e T_arg1 Argument type used in the definition of call_it().
+ * - @e T_arg2 Argument type used in the definition of call_it().
+ * - @e T_arg3 Argument type used in the definition of call_it().
+ * - @e T_arg4 Argument type used in the definition of call_it().
+ * - @e T_arg5 Argument type used in the definition of call_it().
+ * - @e T_arg6 Argument type used in the definition of call_it().
+ * - @e T_arg7 Argument type used in the definition of call_it().
+ *
+ */
+template<class T_functor, class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+struct slot_call7
+{
+  /** Invokes a functor of type @p T_functor.
+   * @param rep slot_rep object that holds a functor of type @p T_functor.
+   * @param _A_a1 Argument to be passed on to the functor.
+   * @param _A_a2 Argument to be passed on to the functor.
+   * @param _A_a3 Argument to be passed on to the functor.
+   * @param _A_a4 Argument to be passed on to the functor.
+   * @param _A_a5 Argument to be passed on to the functor.
+   * @param _A_a6 Argument to be passed on to the functor.
+   * @param _A_a7 Argument to be passed on to the functor.
+   * @return The return values of the functor invocation.
+   */
+  static T_return call_it(slot_rep* rep, typename type_trait<T_arg1>::take a_1,typename type_trait<T_arg2>::take a_2,typename type_trait<T_arg3>::take a_3,typename type_trait<T_arg4>::take a_4,typename type_trait<T_arg5>::take a_5,typename type_trait<T_arg6>::take a_6,typename type_trait<T_arg7>::take a_7)
+    {
+      typedef typed_slot_rep<T_functor> typed_slot;
+      typed_slot *typed_rep = static_cast<typed_slot*>(rep);
+      return (typed_rep->functor_).SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename type_trait<T_arg1>::take,typename type_trait<T_arg2>::take,typename type_trait<T_arg3>::take,typename type_trait<T_arg4>::take,typename type_trait<T_arg5>::take,typename type_trait<T_arg6>::take,typename type_trait<T_arg7>::take>
+               (a_1,a_2,a_3,a_4,a_5,a_6,a_7);
+    }
+
+  /** Forms a function pointer from call_it().
+   * @return A function pointer formed from call_it().
+   */
+  static hook address() 
+    { return reinterpret_cast<hook>(&call_it); }
+};
+
+} /* namespace internal */
+
+
+/** Converts an arbitrary functor to a unified type which is opaque.
+ * sigc::slot itself is a functor or to be more precise a closure. It contains
+ * a single, arbitrary functor (or closure) that is executed in operator()().
+ *
+ * The template arguments determine the function signature of operator()():
+ * - @e T_return The return type of operator()().
+ *
+ * To use simply assign the slot to the desired functor. If the functor
+ * is not compatible with the parameter list defined with the template
+ * arguments compiler errors are triggered. When called the slot
+ * will invoke the functor with minimal copies.
+ * block() and unblock() can be used to block the functor's invocation
+ * from operator()() temporarily.
+ *
+ * You should use the more convenient unnumbered sigc::slot template.
+ *
+ * @ingroup slot
+ */
+/* TODO: Where put the following bit of information? I can't make any
+ *       sense of the "because", by the way!
+ *
+ * Because slot is opaque, visit_each() will not visit its internal members.
+ */
+template <class T_return>
+class slot0
+  : public slot_base
+{
+public:
+  typedef T_return result_type;
+
+
+#ifndef DOXYGEN_SHOULD_SKIP_THIS
+private:
+  typedef internal::slot_rep rep_type;
+public:
+  typedef T_return (*call_type)(rep_type*);
+#endif
+
+  /** Invoke the contained functor unless slot is in blocking state.
+   * @return The return value of the functor invocation.
+   */
+  inline T_return operator()() const
+    {
+      if (!empty() && !blocked())
+        return (reinterpret_cast<call_type>(rep_->call_))(rep_);
+      return T_return();
+    }
+
+  inline slot0() {}
+
+  /** Constructs a slot from an arbitrary functor.
+   * @param _A_func The desirer functor the new slot should be assigned to.
+   */
+  template <class T_functor>
+  slot0(const T_functor& _A_func)
+    : slot_base(new internal::typed_slot_rep<T_functor>(_A_func))
+    { rep_->call_ = internal::slot_call0<T_functor, T_return>::address(); }
+
+  slot0(const slot0& src)
+    : slot_base(src) {}
+
+  /** Overrides this slot making a copy from another slot.
+   * @param src The slot from which to make a copy.
+   * @return @p this.
+   */
+  slot0& operator=(const slot0& src)
+    { slot_base::operator=(src); return *this; }
+};
+
+/** Converts an arbitrary functor to a unified type which is opaque.
+ * sigc::slot itself is a functor or to be more precise a closure. It contains
+ * a single, arbitrary functor (or closure) that is executed in operator()().
+ *
+ * The template arguments determine the function signature of operator()():
+ * - @e T_return The return type of operator()().
+ * - @e T_arg1 Argument type used in the definition of operator()(). The default @p nil means no argument.
+ *
+ * To use simply assign the slot to the desired functor. If the functor
+ * is not compatible with the parameter list defined with the template
+ * arguments compiler errors are triggered. When called the slot
+ * will invoke the functor with minimal copies.
+ * block() and unblock() can be used to block the functor's invocation
+ * from operator()() temporarily.
+ *
+ * You should use the more convenient unnumbered sigc::slot template.
+ *
+ * @ingroup slot
+ */
+/* TODO: Where put the following bit of information? I can't make any
+ *       sense of the "because", by the way!
+ *
+ * Because slot is opaque, visit_each() will not visit its internal members.
+ */
+template <class T_return, class T_arg1>
+class slot1
+  : public slot_base
+{
+public:
+  typedef T_return result_type;
+  typedef typename type_trait<T_arg1>::take arg1_type_;
+
+
+#ifndef DOXYGEN_SHOULD_SKIP_THIS
+private:
+  typedef internal::slot_rep rep_type;
+public:
+  typedef T_return (*call_type)(rep_type*, arg1_type_);
+#endif
+
+  /** Invoke the contained functor unless slot is in blocking state.
+   * @param _A_a1 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  inline T_return operator()(arg1_type_ _A_a1) const
+    {
+      if (!empty() && !blocked())
+        return (reinterpret_cast<call_type>(rep_->call_))(rep_, _A_a1);
+      return T_return();
+    }
+
+  inline slot1() {}
+
+  /** Constructs a slot from an arbitrary functor.
+   * @param _A_func The desirer functor the new slot should be assigned to.
+   */
+  template <class T_functor>
+  slot1(const T_functor& _A_func)
+    : slot_base(new internal::typed_slot_rep<T_functor>(_A_func))
+    { rep_->call_ = internal::slot_call1<T_functor, T_return, T_arg1>::address(); }
+
+  slot1(const slot1& src)
+    : slot_base(src) {}
+
+  /** Overrides this slot making a copy from another slot.
+   * @param src The slot from which to make a copy.
+   * @return @p this.
+   */
+  slot1& operator=(const slot1& src)
+    { slot_base::operator=(src); return *this; }
+};
+
+/** Converts an arbitrary functor to a unified type which is opaque.
+ * sigc::slot itself is a functor or to be more precise a closure. It contains
+ * a single, arbitrary functor (or closure) that is executed in operator()().
+ *
+ * The template arguments determine the function signature of operator()():
+ * - @e T_return The return type of operator()().
+ * - @e T_arg1 Argument type used in the definition of operator()(). The default @p nil means no argument.
+ * - @e T_arg2 Argument type used in the definition of operator()(). The default @p nil means no argument.
+ *
+ * To use simply assign the slot to the desired functor. If the functor
+ * is not compatible with the parameter list defined with the template
+ * arguments compiler errors are triggered. When called the slot
+ * will invoke the functor with minimal copies.
+ * block() and unblock() can be used to block the functor's invocation
+ * from operator()() temporarily.
+ *
+ * You should use the more convenient unnumbered sigc::slot template.
+ *
+ * @ingroup slot
+ */
+/* TODO: Where put the following bit of information? I can't make any
+ *       sense of the "because", by the way!
+ *
+ * Because slot is opaque, visit_each() will not visit its internal members.
+ */
+template <class T_return, class T_arg1,class T_arg2>
+class slot2
+  : public slot_base
+{
+public:
+  typedef T_return result_type;
+  typedef typename type_trait<T_arg1>::take arg1_type_;
+  typedef typename type_trait<T_arg2>::take arg2_type_;
+
+
+#ifndef DOXYGEN_SHOULD_SKIP_THIS
+private:
+  typedef internal::slot_rep rep_type;
+public:
+  typedef T_return (*call_type)(rep_type*, arg1_type_,arg2_type_);
+#endif
+
+  /** Invoke the contained functor unless slot is in blocking state.
+   * @param _A_a1 Argument to be passed on to the functor.
+   * @param _A_a2 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  inline T_return operator()(arg1_type_ _A_a1,arg2_type_ _A_a2) const
+    {
+      if (!empty() && !blocked())
+        return (reinterpret_cast<call_type>(rep_->call_))(rep_, _A_a1,_A_a2);
+      return T_return();
+    }
+
+  inline slot2() {}
+
+  /** Constructs a slot from an arbitrary functor.
+   * @param _A_func The desirer functor the new slot should be assigned to.
+   */
+  template <class T_functor>
+  slot2(const T_functor& _A_func)
+    : slot_base(new internal::typed_slot_rep<T_functor>(_A_func))
+    { rep_->call_ = internal::slot_call2<T_functor, T_return, T_arg1,T_arg2>::address(); }
+
+  slot2(const slot2& src)
+    : slot_base(src) {}
+
+  /** Overrides this slot making a copy from another slot.
+   * @param src The slot from which to make a copy.
+   * @return @p this.
+   */
+  slot2& operator=(const slot2& src)
+    { slot_base::operator=(src); return *this; }
+};
+
+/** Converts an arbitrary functor to a unified type which is opaque.
+ * sigc::slot itself is a functor or to be more precise a closure. It contains
+ * a single, arbitrary functor (or closure) that is executed in operator()().
+ *
+ * The template arguments determine the function signature of operator()():
+ * - @e T_return The return type of operator()().
+ * - @e T_arg1 Argument type used in the definition of operator()(). The default @p nil means no argument.
+ * - @e T_arg2 Argument type used in the definition of operator()(). The default @p nil means no argument.
+ * - @e T_arg3 Argument type used in the definition of operator()(). The default @p nil means no argument.
+ *
+ * To use simply assign the slot to the desired functor. If the functor
+ * is not compatible with the parameter list defined with the template
+ * arguments compiler errors are triggered. When called the slot
+ * will invoke the functor with minimal copies.
+ * block() and unblock() can be used to block the functor's invocation
+ * from operator()() temporarily.
+ *
+ * You should use the more convenient unnumbered sigc::slot template.
+ *
+ * @ingroup slot
+ */
+/* TODO: Where put the following bit of information? I can't make any
+ *       sense of the "because", by the way!
+ *
+ * Because slot is opaque, visit_each() will not visit its internal members.
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3>
+class slot3
+  : public slot_base
+{
+public:
+  typedef T_return result_type;
+  typedef typename type_trait<T_arg1>::take arg1_type_;
+  typedef typename type_trait<T_arg2>::take arg2_type_;
+  typedef typename type_trait<T_arg3>::take arg3_type_;
+
+
+#ifndef DOXYGEN_SHOULD_SKIP_THIS
+private:
+  typedef internal::slot_rep rep_type;
+public:
+  typedef T_return (*call_type)(rep_type*, arg1_type_,arg2_type_,arg3_type_);
+#endif
+
+  /** Invoke the contained functor unless slot is in blocking state.
+   * @param _A_a1 Argument to be passed on to the functor.
+   * @param _A_a2 Argument to be passed on to the functor.
+   * @param _A_a3 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  inline T_return operator()(arg1_type_ _A_a1,arg2_type_ _A_a2,arg3_type_ _A_a3) const
+    {
+      if (!empty() && !blocked())
+        return (reinterpret_cast<call_type>(rep_->call_))(rep_, _A_a1,_A_a2,_A_a3);
+      return T_return();
+    }
+
+  inline slot3() {}
+
+  /** Constructs a slot from an arbitrary functor.
+   * @param _A_func The desirer functor the new slot should be assigned to.
+   */
+  template <class T_functor>
+  slot3(const T_functor& _A_func)
+    : slot_base(new internal::typed_slot_rep<T_functor>(_A_func))
+    { rep_->call_ = internal::slot_call3<T_functor, T_return, T_arg1,T_arg2,T_arg3>::address(); }
+
+  slot3(const slot3& src)
+    : slot_base(src) {}
+
+  /** Overrides this slot making a copy from another slot.
+   * @param src The slot from which to make a copy.
+   * @return @p this.
+   */
+  slot3& operator=(const slot3& src)
+    { slot_base::operator=(src); return *this; }
+};
+
+/** Converts an arbitrary functor to a unified type which is opaque.
+ * sigc::slot itself is a functor or to be more precise a closure. It contains
+ * a single, arbitrary functor (or closure) that is executed in operator()().
+ *
+ * The template arguments determine the function signature of operator()():
+ * - @e T_return The return type of operator()().
+ * - @e T_arg1 Argument type used in the definition of operator()(). The default @p nil means no argument.
+ * - @e T_arg2 Argument type used in the definition of operator()(). The default @p nil means no argument.
+ * - @e T_arg3 Argument type used in the definition of operator()(). The default @p nil means no argument.
+ * - @e T_arg4 Argument type used in the definition of operator()(). The default @p nil means no argument.
+ *
+ * To use simply assign the slot to the desired functor. If the functor
+ * is not compatible with the parameter list defined with the template
+ * arguments compiler errors are triggered. When called the slot
+ * will invoke the functor with minimal copies.
+ * block() and unblock() can be used to block the functor's invocation
+ * from operator()() temporarily.
+ *
+ * You should use the more convenient unnumbered sigc::slot template.
+ *
+ * @ingroup slot
+ */
+/* TODO: Where put the following bit of information? I can't make any
+ *       sense of the "because", by the way!
+ *
+ * Because slot is opaque, visit_each() will not visit its internal members.
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+class slot4
+  : public slot_base
+{
+public:
+  typedef T_return result_type;
+  typedef typename type_trait<T_arg1>::take arg1_type_;
+  typedef typename type_trait<T_arg2>::take arg2_type_;
+  typedef typename type_trait<T_arg3>::take arg3_type_;
+  typedef typename type_trait<T_arg4>::take arg4_type_;
+
+
+#ifndef DOXYGEN_SHOULD_SKIP_THIS
+private:
+  typedef internal::slot_rep rep_type;
+public:
+  typedef T_return (*call_type)(rep_type*, arg1_type_,arg2_type_,arg3_type_,arg4_type_);
+#endif
+
+  /** Invoke the contained functor unless slot is in blocking state.
+   * @param _A_a1 Argument to be passed on to the functor.
+   * @param _A_a2 Argument to be passed on to the functor.
+   * @param _A_a3 Argument to be passed on to the functor.
+   * @param _A_a4 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  inline T_return operator()(arg1_type_ _A_a1,arg2_type_ _A_a2,arg3_type_ _A_a3,arg4_type_ _A_a4) const
+    {
+      if (!empty() && !blocked())
+        return (reinterpret_cast<call_type>(rep_->call_))(rep_, _A_a1,_A_a2,_A_a3,_A_a4);
+      return T_return();
+    }
+
+  inline slot4() {}
+
+  /** Constructs a slot from an arbitrary functor.
+   * @param _A_func The desirer functor the new slot should be assigned to.
+   */
+  template <class T_functor>
+  slot4(const T_functor& _A_func)
+    : slot_base(new internal::typed_slot_rep<T_functor>(_A_func))
+    { rep_->call_ = internal::slot_call4<T_functor, T_return, T_arg1,T_arg2,T_arg3,T_arg4>::address(); }
+
+  slot4(const slot4& src)
+    : slot_base(src) {}
+
+  /** Overrides this slot making a copy from another slot.
+   * @param src The slot from which to make a copy.
+   * @return @p this.
+   */
+  slot4& operator=(const slot4& src)
+    { slot_base::operator=(src); return *this; }
+};
+
+/** Converts an arbitrary functor to a unified type which is opaque.
+ * sigc::slot itself is a functor or to be more precise a closure. It contains
+ * a single, arbitrary functor (or closure) that is executed in operator()().
+ *
+ * The template arguments determine the function signature of operator()():
+ * - @e T_return The return type of operator()().
+ * - @e T_arg1 Argument type used in the definition of operator()(). The default @p nil means no argument.
+ * - @e T_arg2 Argument type used in the definition of operator()(). The default @p nil means no argument.
+ * - @e T_arg3 Argument type used in the definition of operator()(). The default @p nil means no argument.
+ * - @e T_arg4 Argument type used in the definition of operator()(). The default @p nil means no argument.
+ * - @e T_arg5 Argument type used in the definition of operator()(). The default @p nil means no argument.
+ *
+ * To use simply assign the slot to the desired functor. If the functor
+ * is not compatible with the parameter list defined with the template
+ * arguments compiler errors are triggered. When called the slot
+ * will invoke the functor with minimal copies.
+ * block() and unblock() can be used to block the functor's invocation
+ * from operator()() temporarily.
+ *
+ * You should use the more convenient unnumbered sigc::slot template.
+ *
+ * @ingroup slot
+ */
+/* TODO: Where put the following bit of information? I can't make any
+ *       sense of the "because", by the way!
+ *
+ * Because slot is opaque, visit_each() will not visit its internal members.
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+class slot5
+  : public slot_base
+{
+public:
+  typedef T_return result_type;
+  typedef typename type_trait<T_arg1>::take arg1_type_;
+  typedef typename type_trait<T_arg2>::take arg2_type_;
+  typedef typename type_trait<T_arg3>::take arg3_type_;
+  typedef typename type_trait<T_arg4>::take arg4_type_;
+  typedef typename type_trait<T_arg5>::take arg5_type_;
+
+
+#ifndef DOXYGEN_SHOULD_SKIP_THIS
+private:
+  typedef internal::slot_rep rep_type;
+public:
+  typedef T_return (*call_type)(rep_type*, arg1_type_,arg2_type_,arg3_type_,arg4_type_,arg5_type_);
+#endif
+
+  /** Invoke the contained functor unless slot is in blocking state.
+   * @param _A_a1 Argument to be passed on to the functor.
+   * @param _A_a2 Argument to be passed on to the functor.
+   * @param _A_a3 Argument to be passed on to the functor.
+   * @param _A_a4 Argument to be passed on to the functor.
+   * @param _A_a5 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  inline T_return operator()(arg1_type_ _A_a1,arg2_type_ _A_a2,arg3_type_ _A_a3,arg4_type_ _A_a4,arg5_type_ _A_a5) const
+    {
+      if (!empty() && !blocked())
+        return (reinterpret_cast<call_type>(rep_->call_))(rep_, _A_a1,_A_a2,_A_a3,_A_a4,_A_a5);
+      return T_return();
+    }
+
+  inline slot5() {}
+
+  /** Constructs a slot from an arbitrary functor.
+   * @param _A_func The desirer functor the new slot should be assigned to.
+   */
+  template <class T_functor>
+  slot5(const T_functor& _A_func)
+    : slot_base(new internal::typed_slot_rep<T_functor>(_A_func))
+    { rep_->call_ = internal::slot_call5<T_functor, T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>::address(); }
+
+  slot5(const slot5& src)
+    : slot_base(src) {}
+
+  /** Overrides this slot making a copy from another slot.
+   * @param src The slot from which to make a copy.
+   * @return @p this.
+   */
+  slot5& operator=(const slot5& src)
+    { slot_base::operator=(src); return *this; }
+};
+
+/** Converts an arbitrary functor to a unified type which is opaque.
+ * sigc::slot itself is a functor or to be more precise a closure. It contains
+ * a single, arbitrary functor (or closure) that is executed in operator()().
+ *
+ * The template arguments determine the function signature of operator()():
+ * - @e T_return The return type of operator()().
+ * - @e T_arg1 Argument type used in the definition of operator()(). The default @p nil means no argument.
+ * - @e T_arg2 Argument type used in the definition of operator()(). The default @p nil means no argument.
+ * - @e T_arg3 Argument type used in the definition of operator()(). The default @p nil means no argument.
+ * - @e T_arg4 Argument type used in the definition of operator()(). The default @p nil means no argument.
+ * - @e T_arg5 Argument type used in the definition of operator()(). The default @p nil means no argument.
+ * - @e T_arg6 Argument type used in the definition of operator()(). The default @p nil means no argument.
+ *
+ * To use simply assign the slot to the desired functor. If the functor
+ * is not compatible with the parameter list defined with the template
+ * arguments compiler errors are triggered. When called the slot
+ * will invoke the functor with minimal copies.
+ * block() and unblock() can be used to block the functor's invocation
+ * from operator()() temporarily.
+ *
+ * You should use the more convenient unnumbered sigc::slot template.
+ *
+ * @ingroup slot
+ */
+/* TODO: Where put the following bit of information? I can't make any
+ *       sense of the "because", by the way!
+ *
+ * Because slot is opaque, visit_each() will not visit its internal members.
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+class slot6
+  : public slot_base
+{
+public:
+  typedef T_return result_type;
+  typedef typename type_trait<T_arg1>::take arg1_type_;
+  typedef typename type_trait<T_arg2>::take arg2_type_;
+  typedef typename type_trait<T_arg3>::take arg3_type_;
+  typedef typename type_trait<T_arg4>::take arg4_type_;
+  typedef typename type_trait<T_arg5>::take arg5_type_;
+  typedef typename type_trait<T_arg6>::take arg6_type_;
+
+
+#ifndef DOXYGEN_SHOULD_SKIP_THIS
+private:
+  typedef internal::slot_rep rep_type;
+public:
+  typedef T_return (*call_type)(rep_type*, arg1_type_,arg2_type_,arg3_type_,arg4_type_,arg5_type_,arg6_type_);
+#endif
+
+  /** Invoke the contained functor unless slot is in blocking state.
+   * @param _A_a1 Argument to be passed on to the functor.
+   * @param _A_a2 Argument to be passed on to the functor.
+   * @param _A_a3 Argument to be passed on to the functor.
+   * @param _A_a4 Argument to be passed on to the functor.
+   * @param _A_a5 Argument to be passed on to the functor.
+   * @param _A_a6 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  inline T_return operator()(arg1_type_ _A_a1,arg2_type_ _A_a2,arg3_type_ _A_a3,arg4_type_ _A_a4,arg5_type_ _A_a5,arg6_type_ _A_a6) const
+    {
+      if (!empty() && !blocked())
+        return (reinterpret_cast<call_type>(rep_->call_))(rep_, _A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6);
+      return T_return();
+    }
+
+  inline slot6() {}
+
+  /** Constructs a slot from an arbitrary functor.
+   * @param _A_func The desirer functor the new slot should be assigned to.
+   */
+  template <class T_functor>
+  slot6(const T_functor& _A_func)
+    : slot_base(new internal::typed_slot_rep<T_functor>(_A_func))
+    { rep_->call_ = internal::slot_call6<T_functor, T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>::address(); }
+
+  slot6(const slot6& src)
+    : slot_base(src) {}
+
+  /** Overrides this slot making a copy from another slot.
+   * @param src The slot from which to make a copy.
+   * @return @p this.
+   */
+  slot6& operator=(const slot6& src)
+    { slot_base::operator=(src); return *this; }
+};
+
+/** Converts an arbitrary functor to a unified type which is opaque.
+ * sigc::slot itself is a functor or to be more precise a closure. It contains
+ * a single, arbitrary functor (or closure) that is executed in operator()().
+ *
+ * The template arguments determine the function signature of operator()():
+ * - @e T_return The return type of operator()().
+ * - @e T_arg1 Argument type used in the definition of operator()(). The default @p nil means no argument.
+ * - @e T_arg2 Argument type used in the definition of operator()(). The default @p nil means no argument.
+ * - @e T_arg3 Argument type used in the definition of operator()(). The default @p nil means no argument.
+ * - @e T_arg4 Argument type used in the definition of operator()(). The default @p nil means no argument.
+ * - @e T_arg5 Argument type used in the definition of operator()(). The default @p nil means no argument.
+ * - @e T_arg6 Argument type used in the definition of operator()(). The default @p nil means no argument.
+ * - @e T_arg7 Argument type used in the definition of operator()(). The default @p nil means no argument.
+ *
+ * To use simply assign the slot to the desired functor. If the functor
+ * is not compatible with the parameter list defined with the template
+ * arguments compiler errors are triggered. When called the slot
+ * will invoke the functor with minimal copies.
+ * block() and unblock() can be used to block the functor's invocation
+ * from operator()() temporarily.
+ *
+ * You should use the more convenient unnumbered sigc::slot template.
+ *
+ * @ingroup slot
+ */
+/* TODO: Where put the following bit of information? I can't make any
+ *       sense of the "because", by the way!
+ *
+ * Because slot is opaque, visit_each() will not visit its internal members.
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+class slot7
+  : public slot_base
+{
+public:
+  typedef T_return result_type;
+  typedef typename type_trait<T_arg1>::take arg1_type_;
+  typedef typename type_trait<T_arg2>::take arg2_type_;
+  typedef typename type_trait<T_arg3>::take arg3_type_;
+  typedef typename type_trait<T_arg4>::take arg4_type_;
+  typedef typename type_trait<T_arg5>::take arg5_type_;
+  typedef typename type_trait<T_arg6>::take arg6_type_;
+  typedef typename type_trait<T_arg7>::take arg7_type_;
+
+
+#ifndef DOXYGEN_SHOULD_SKIP_THIS
+private:
+  typedef internal::slot_rep rep_type;
+public:
+  typedef T_return (*call_type)(rep_type*, arg1_type_,arg2_type_,arg3_type_,arg4_type_,arg5_type_,arg6_type_,arg7_type_);
+#endif
+
+  /** Invoke the contained functor unless slot is in blocking state.
+   * @param _A_a1 Argument to be passed on to the functor.
+   * @param _A_a2 Argument to be passed on to the functor.
+   * @param _A_a3 Argument to be passed on to the functor.
+   * @param _A_a4 Argument to be passed on to the functor.
+   * @param _A_a5 Argument to be passed on to the functor.
+   * @param _A_a6 Argument to be passed on to the functor.
+   * @param _A_a7 Argument to be passed on to the functor.
+   * @return The return value of the functor invocation.
+   */
+  inline T_return operator()(arg1_type_ _A_a1,arg2_type_ _A_a2,arg3_type_ _A_a3,arg4_type_ _A_a4,arg5_type_ _A_a5,arg6_type_ _A_a6,arg7_type_ _A_a7) const
+    {
+      if (!empty() && !blocked())
+        return (reinterpret_cast<call_type>(rep_->call_))(rep_, _A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6,_A_a7);
+      return T_return();
+    }
+
+  inline slot7() {}
+
+  /** Constructs a slot from an arbitrary functor.
+   * @param _A_func The desirer functor the new slot should be assigned to.
+   */
+  template <class T_functor>
+  slot7(const T_functor& _A_func)
+    : slot_base(new internal::typed_slot_rep<T_functor>(_A_func))
+    { rep_->call_ = internal::slot_call7<T_functor, T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>::address(); }
+
+  slot7(const slot7& src)
+    : slot_base(src) {}
+
+  /** Overrides this slot making a copy from another slot.
+   * @param src The slot from which to make a copy.
+   * @return @p this.
+   */
+  slot7& operator=(const slot7& src)
+    { slot_base::operator=(src); return *this; }
+};
+
+
+/** Convenience wrapper for the numbered sigc::slot# templates.
+ * Slots convert arbitrary functors to unified types which are opaque.
+ * sigc::slot itself is a functor or to be more precise a closure. It contains
+ * a single, arbitrary functor (or closure) that is executed in operator()().
+ *
+ * The template arguments determine the function signature of operator()():
+ * - @e T_return The return type of operator()().
+ * - @e T_arg1 Argument type used in the definition of operator()(). The default @p nil means no argument.
+ * - @e T_arg2 Argument type used in the definition of operator()(). The default @p nil means no argument.
+ * - @e T_arg3 Argument type used in the definition of operator()(). The default @p nil means no argument.
+ * - @e T_arg4 Argument type used in the definition of operator()(). The default @p nil means no argument.
+ * - @e T_arg5 Argument type used in the definition of operator()(). The default @p nil means no argument.
+ * - @e T_arg6 Argument type used in the definition of operator()(). The default @p nil means no argument.
+ * - @e T_arg7 Argument type used in the definition of operator()(). The default @p nil means no argument.
+ *
+ * To use simply assign the slot to the desired functor. If the functor
+ * is not compatible with the parameter list defined with the template
+ * arguments compiler errors are triggered. When called the slot
+ * will invoke the functor with minimal copies.
+ * block() and unblock() can be used to block the functor's invocation
+ * from operator()() temporarily.
+ *
+ * @par Example:
+ *   @code
+ *   void foo(int) {}
+ *   sigc::slot<void, long> s = sigc::ptr_fun(&foo);
+ *   s(19);
+ *   @endcode
+ *
+ * @ingroup slot
+ */
+template <class T_return, class T_arg1 = nil,class T_arg2 = nil,class T_arg3 = nil,class T_arg4 = nil,class T_arg5 = nil,class T_arg6 = nil,class T_arg7 = nil>
+class slot 
+  : public slot7<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+{
+public:
+  typedef slot7<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7> parent_type;
+
+  inline slot() {}
+
+  /** Constructs a slot from an arbitrary functor.
+   * @param _A_func The desirer functor the new slot should be assigned to.
+   */
+  template <class T_functor>
+  slot(const T_functor& _A_func)
+    : parent_type(_A_func) {}
+
+  slot(const slot& src)
+    : parent_type((const parent_type&)src) {}
+};
+
+
+/** Convenience wrapper for the numbered sigc::slot0 template.
+ * See the base class for useful methods.
+ * This is the template specialization of the unnumbered sigc::slot
+ * template for 0 argument(s).
+ */
+template <class T_return>
+class slot <T_return>
+  : public slot0<T_return>
+{
+public:
+  typedef slot0<T_return> parent_type;
+
+  inline slot() {}
+
+  /** Constructs a slot from an arbitrary functor.
+   * @param _A_func The desirer functor the new slot should be assigned to.
+   */
+  template <class T_functor>
+  slot(const T_functor& _A_func)
+    : parent_type(_A_func) {}
+
+  slot(const slot& src)
+    : parent_type((const parent_type&)src) {}
+};
+
+/** Convenience wrapper for the numbered sigc::slot1 template.
+ * See the base class for useful methods.
+ * This is the template specialization of the unnumbered sigc::slot
+ * template for 1 argument(s).
+ */
+template <class T_return, class T_arg1>
+class slot <T_return, T_arg1>
+  : public slot1<T_return, T_arg1>
+{
+public:
+  typedef slot1<T_return, T_arg1> parent_type;
+
+  inline slot() {}
+
+  /** Constructs a slot from an arbitrary functor.
+   * @param _A_func The desirer functor the new slot should be assigned to.
+   */
+  template <class T_functor>
+  slot(const T_functor& _A_func)
+    : parent_type(_A_func) {}
+
+  slot(const slot& src)
+    : parent_type((const parent_type&)src) {}
+};
+
+/** Convenience wrapper for the numbered sigc::slot2 template.
+ * See the base class for useful methods.
+ * This is the template specialization of the unnumbered sigc::slot
+ * template for 2 argument(s).
+ */
+template <class T_return, class T_arg1,class T_arg2>
+class slot <T_return, T_arg1,T_arg2>
+  : public slot2<T_return, T_arg1,T_arg2>
+{
+public:
+  typedef slot2<T_return, T_arg1,T_arg2> parent_type;
+
+  inline slot() {}
+
+  /** Constructs a slot from an arbitrary functor.
+   * @param _A_func The desirer functor the new slot should be assigned to.
+   */
+  template <class T_functor>
+  slot(const T_functor& _A_func)
+    : parent_type(_A_func) {}
+
+  slot(const slot& src)
+    : parent_type((const parent_type&)src) {}
+};
+
+/** Convenience wrapper for the numbered sigc::slot3 template.
+ * See the base class for useful methods.
+ * This is the template specialization of the unnumbered sigc::slot
+ * template for 3 argument(s).
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3>
+class slot <T_return, T_arg1,T_arg2,T_arg3>
+  : public slot3<T_return, T_arg1,T_arg2,T_arg3>
+{
+public:
+  typedef slot3<T_return, T_arg1,T_arg2,T_arg3> parent_type;
+
+  inline slot() {}
+
+  /** Constructs a slot from an arbitrary functor.
+   * @param _A_func The desirer functor the new slot should be assigned to.
+   */
+  template <class T_functor>
+  slot(const T_functor& _A_func)
+    : parent_type(_A_func) {}
+
+  slot(const slot& src)
+    : parent_type((const parent_type&)src) {}
+};
+
+/** Convenience wrapper for the numbered sigc::slot4 template.
+ * See the base class for useful methods.
+ * This is the template specialization of the unnumbered sigc::slot
+ * template for 4 argument(s).
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+class slot <T_return, T_arg1,T_arg2,T_arg3,T_arg4>
+  : public slot4<T_return, T_arg1,T_arg2,T_arg3,T_arg4>
+{
+public:
+  typedef slot4<T_return, T_arg1,T_arg2,T_arg3,T_arg4> parent_type;
+
+  inline slot() {}
+
+  /** Constructs a slot from an arbitrary functor.
+   * @param _A_func The desirer functor the new slot should be assigned to.
+   */
+  template <class T_functor>
+  slot(const T_functor& _A_func)
+    : parent_type(_A_func) {}
+
+  slot(const slot& src)
+    : parent_type((const parent_type&)src) {}
+};
+
+/** Convenience wrapper for the numbered sigc::slot5 template.
+ * See the base class for useful methods.
+ * This is the template specialization of the unnumbered sigc::slot
+ * template for 5 argument(s).
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+class slot <T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+  : public slot5<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+{
+public:
+  typedef slot5<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5> parent_type;
+
+  inline slot() {}
+
+  /** Constructs a slot from an arbitrary functor.
+   * @param _A_func The desirer functor the new slot should be assigned to.
+   */
+  template <class T_functor>
+  slot(const T_functor& _A_func)
+    : parent_type(_A_func) {}
+
+  slot(const slot& src)
+    : parent_type((const parent_type&)src) {}
+};
+
+/** Convenience wrapper for the numbered sigc::slot6 template.
+ * See the base class for useful methods.
+ * This is the template specialization of the unnumbered sigc::slot
+ * template for 6 argument(s).
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+class slot <T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+  : public slot6<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+{
+public:
+  typedef slot6<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6> parent_type;
+
+  inline slot() {}
+
+  /** Constructs a slot from an arbitrary functor.
+   * @param _A_func The desirer functor the new slot should be assigned to.
+   */
+  template <class T_functor>
+  slot(const T_functor& _A_func)
+    : parent_type(_A_func) {}
+
+  slot(const slot& src)
+    : parent_type((const parent_type&)src) {}
+};
+
+
+
+} /* namespace sigc */
+#endif /* _SIGC_FUNCTORS_MACROS_SLOTHM4_ */
diff --git a/libs/sigc++2/sigc++/functors/slot_base.cc b/libs/sigc++2/sigc++/functors/slot_base.cc
new file mode 100644
index 0000000000..bc0f173f22
--- /dev/null
+++ b/libs/sigc++2/sigc++/functors/slot_base.cc
@@ -0,0 +1,165 @@
+// -*- c++ -*-
+/*
+ * Copyright 2003, The libsigc++ Development Team
+ *
+ *  This library is free software; you can redistribute it and/or
+ *  modify it under the terms of the GNU Lesser General Public
+ *  License as published by the Free Software Foundation; either
+ *  version 2.1 of the License, or (at your option) any later version.
+ *
+ *  This library is distributed in the hope that it will be useful,
+ *  but WITHOUT ANY WARRANTY; without even the implied warranty of
+ *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
+ *  Lesser General Public License for more details.
+ *
+ *  You should have received a copy of the GNU Lesser General Public
+ *  License along with this library; if not, write to the Free Software
+ *  Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
+ *
+ */
+
+#include <sigc++/functors/slot_base.h>
+
+namespace sigc
+{
+
+namespace internal {
+
+// only MSVC needs this to guarantee that all new/delete are executed from the DLL module
+#ifdef SIGC_NEW_DELETE_IN_LIBRARY_ONLY
+void* slot_rep::operator new(size_t size_)
+{
+  return malloc(size_);
+}
+
+void slot_rep::operator delete(void* p)
+{
+  free(p);
+}
+#endif
+
+void slot_rep::disconnect()
+{
+  if (parent_)
+  {
+    call_ = 0;          // Invalidate the slot.
+                        // _Must_ be done here because parent_ might defer the actual
+                        // destruction of the slot_rep and try to invoke it before that point.
+    void* data_ = parent_;
+    parent_ = 0;        // Just a precaution.
+    (cleanup_)(data_);  // Notify the parent (might lead to destruction of this!).
+  }
+}
+
+//static
+void* slot_rep::notify(void* data)
+{
+  slot_rep* self_ = (slot_rep*)data;
+  self_->call_ = 0; // Invalidate the slot.
+  self_->destroy(); // Detach the stored functor from the other referred trackables and destroy it.
+  self_->disconnect(); // Disconnect the slot (might lead to deletion of self_!).
+  return 0;
+}
+
+} // namespace internal
+  
+slot_base::slot_base()
+: rep_(0),
+  blocked_(false)
+{}
+
+slot_base::slot_base(rep_type* rep)
+: rep_(rep),
+  blocked_(false)
+{}
+
+slot_base::slot_base(const slot_base& src)
+: rep_(0),
+  blocked_(src.blocked_)
+{
+  if (src.rep_)
+    rep_ = src.rep_->dup();
+}
+
+slot_base::~slot_base()
+{
+  if (rep_)
+    delete rep_;
+}
+
+slot_base::operator bool() const
+{
+  return rep_ != 0;
+}
+
+slot_base& slot_base::operator=(const slot_base& src)
+{
+  if (src.rep_ == rep_) return *this;
+
+  if (src.empty())
+  {
+    disconnect();
+    return *this;
+  }
+
+  internal::slot_rep* new_rep_ = src.rep_->dup();
+
+  if (rep_)               // Silently exchange the slot_rep.
+  {
+    new_rep_->set_parent(rep_->parent_, rep_->cleanup_);
+    delete rep_;
+  }
+
+  rep_ = new_rep_;
+
+  return *this;
+}
+
+void slot_base::set_parent(void* parent, void* (*cleanup)(void*)) const
+{
+  if (rep_)
+    rep_->set_parent(parent, cleanup);
+}
+
+void slot_base::add_destroy_notify_callback(void* data, func_destroy_notify func) const
+{
+  if (rep_)
+    rep_->add_destroy_notify_callback(data, func);
+}
+
+void slot_base::remove_destroy_notify_callback(void* data) const
+{
+  if (rep_)
+    rep_->remove_destroy_notify_callback(data);
+}
+
+bool slot_base::block(bool should_block)
+{
+  bool old = blocked_;
+  blocked_ = should_block;
+  return old;
+}
+
+bool slot_base::unblock()
+{
+  return block(false);
+}
+
+void slot_base::disconnect()
+{
+  if (rep_)
+    rep_->disconnect();
+}
+
+
+/*bool slot_base::empty() const // having this function not inline is killing performance !!!
+{
+  if (rep_ && !rep_->call_)
+    {
+      delete rep_;        // This is not strictly necessary here. I'm convinced that it is
+      rep_ = 0;           // safe to wait for the destructor to delete the slot_rep. Martin.
+    }
+  return (rep_ == 0);
+}*/
+
+} //namespace sigc
diff --git a/libs/sigc++2/sigc++/functors/slot_base.h b/libs/sigc++2/sigc++/functors/slot_base.h
new file mode 100644
index 0000000000..bb2ed343f3
--- /dev/null
+++ b/libs/sigc++2/sigc++/functors/slot_base.h
@@ -0,0 +1,319 @@
+/*
+ * Copyright 2003, The libsigc++ Development Team
+ *
+ *  This library is free software; you can redistribute it and/or
+ *  modify it under the terms of the GNU Lesser General Public
+ *  License as published by the Free Software Foundation; either
+ *  version 2.1 of the License, or (at your option) any later version.
+ *
+ *  This library is distributed in the hope that it will be useful,
+ *  but WITHOUT ANY WARRANTY; without even the implied warranty of
+ *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
+ *  Lesser General Public License for more details.
+ *
+ *  You should have received a copy of the GNU Lesser General Public
+ *  License along with this library; if not, write to the Free Software
+ *  Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
+ *
+ */
+#ifndef _SIGC_SLOT_BASE_HPP_
+#define _SIGC_SLOT_BASE_HPP_
+
+#include <sigc++config.h>
+#include <sigc++/trackable.h>
+#include <sigc++/functors/functor_trait.h>
+
+namespace sigc
+{
+
+namespace internal {
+
+typedef void* (*hook)(void*);
+
+/** Internal representation of a slot.
+ * Derivations of this class can be considered as a link
+ * between a slot and the functor that the slot should
+ * execute in operator(). This link is needed because in
+ * libsigc++2 the slot doesn't necessarily have exactly the
+ * same function signature as the functor thus allowing for
+ * implicit conversions.
+ * The base class slot_rep serves the purpose to
+ * - form a common pointer type (slot_rep*),
+ * - offer the possibility to create duplicates (dup()),
+ * - offer a notification callback (notify()),
+ * - implement some of slot_base's interface that depends
+ *   on the notification callback, i.e.
+ *   -# the possibility to set a single parent with a callback
+ *      (set_parent()) that is executed from notify(),
+ *   -# a generic function pointer, call_, that is simply
+ *      set to zero in notify() to invalidate the slot.
+ * slot_rep inherits trackable so that connection objects can
+ * refer to the slot and are notified when the slot is destroyed.
+ */
+struct SIGC_API slot_rep : public trackable
+{
+  /* NB: Instead of slot_rep we could inherit slot_base from trackable.
+   * However, a simple benchmark seems to indicate that this slows
+   * down dereferencing of slot list iterators. Martin. */
+
+  /// Callback that invokes the contained functor.
+  /* This can't be a virtual function since number of arguments
+   * must be flexible. We use function pointers to slot_call::call_it()
+   * instead. call_ is set to zero to indicate that the slot is invalid.
+   */
+  hook call_;
+
+  /// Callback that detaches the slot_rep object from referred trackables and destroys it.
+  /* This could be a replaced by a virtual dtor. However since this struct is
+   * crucual for the efficiency of the whole library we want to avoid this.
+   */
+  hook destroy_;
+
+  /** Callback that makes a deep copy of the slot_rep object.
+   * @return A deep copy of the slot_rep object.
+   */
+  hook dup_;
+
+  /** Callback of parent_. */
+  hook cleanup_;
+
+  /** Parent object whose callback cleanup_ is executed on notification. */
+  void* parent_;
+
+  inline slot_rep(hook call__, hook destroy__, hook dup__)
+    : call_(call__), destroy_(destroy__), dup_(dup__), cleanup_(0), parent_(0) {}
+
+  inline ~slot_rep()
+    { destroy(); }
+
+  // only MSVC needs this to guarantee that all new/delete are executed from the DLL module
+#ifdef SIGC_NEW_DELETE_IN_LIBRARY_ONLY
+  void* operator new(size_t size_);
+  void operator delete(void* p);
+#endif
+
+  /** Destroys the slot_rep object (but doesn't delete it).
+   */
+  inline void destroy()
+    { if (destroy_) (*destroy_)(this); }
+
+  /** Makes a deep copy of the slot_rep object.
+   * @return A deep copy of the slot_rep object.
+   */
+  inline slot_rep* dup() const
+    { return (slot_rep*)(*dup_)(const_cast<slot_rep*>(this)); }
+
+  /** Set the parent with a callback.
+   * slots have one parent exclusively.
+   * @param parent The new parent.
+   * @param cleanup The callback to execute from notify().
+   */
+  inline void set_parent(void* parent, hook cleanup)
+    {
+      parent_ = parent;
+      cleanup_ = cleanup;
+    }
+
+  /// Invalidates the slot and executes the parent's cleanup callback.
+  void disconnect();
+
+  /** Callback that invalidates the slot.
+   * This callback is registered in every object of a trackable
+   * inherited type that is referred by this slot_rep object.
+   * It is executed when the slot becomes invalid because of some
+   * referred object dying.
+   * @param data The slot_rep object that is becoming invalid (@p this).
+   */
+  static void* notify(void* data);
+};
+
+/** Functor used to add a dependency to a trackable.
+ * Consequently slot_rep::notify() gets executed when the
+ * trackable is destroyed or overwritten.
+ */
+struct SIGC_API slot_do_bind
+{
+  /** The slot_rep object trackables should notify on destruction. */
+  slot_rep* rep_;
+
+  /** Construct a slot_do_bind functor.
+   * @param rep The slot_rep object trackables should notify on destruction.
+   */
+  inline slot_do_bind(slot_rep* rep) : rep_(rep) {}
+
+  /** Adds a dependency to @p t.
+   * @param t The trackable object to add a callback to.
+   */
+  inline void operator()(const trackable* t) const
+    { t->add_destroy_notify_callback(rep_, &slot_rep::notify); }
+};
+
+/// Functor used to remove a dependency from a trackable.
+struct SIGC_API slot_do_unbind
+{
+  /** The slot_rep object trackables don't need to notify on destruction any more. */
+  slot_rep* rep_;
+
+  /** Construct a slot_do_unbind functor.
+   * @param rep The slot_rep object trackables don't need to notify on destruction any more.
+   */
+  inline slot_do_unbind(slot_rep* rep) : rep_(rep) {}
+
+  /** Removes a dependency from @p t.
+   * @param t The trackable object to remove the callback from.
+   */
+  inline void operator()(const trackable* t) const
+    { t->remove_destroy_notify_callback(rep_); }
+};
+
+} //namespace internal
+
+
+/** @defgroup slot Slots
+ * Slots are type-safe representations of callback methods and functions.
+ * A Slot can be constructed from any function, regardless of whether it is a global function,
+ * a member method, static, or virtual.
+ *
+ * Use the sigc::mem_fun() and sigc::ptr_fun() template functions to get a sigc::slot, like so:
+ *
+ * @code
+ * sigc::slot<void, int> sl = sigc::mem_fun(someobj,& SomeClass::somemethod);
+ * @endcode
+ *
+ * or
+ *
+ * @code
+ * sigc::slot<void, int> sl = sigc::ptr_fun(&somefunction);
+ * @endcode
+ *
+ * or
+ *
+ * @code
+ * m_Button.signal_clicked().connect( sigc::mem_fun(*this, &MyWindow::on_button_clicked) );
+ * @endcode
+ *
+ * The compiler will complain if SomeClass::somemethod, etc. have the wrong signature.
+ *
+ * You can also pass slots as method parameters where you might normally pass a function pointer.
+ *
+ * @ingroup functors
+ */
+
+/** Base type for slots.
+ * slot_base integrates most of the interface of the derived
+ * sigc::slot templates. slots
+ * can be connected to signals, be disconnected at some later point
+ * (disconnect()) and temporarily be blocked (block(), unblock()).
+ * The validity of a slot can be tested with empty().
+ *
+ * The internal representation of a sigc::internal::slot_rep derived
+ * type is built from slot_base's derivations. set_parent() is used to
+ * register a notification callback that is executed when the slot gets
+ * invalid. add_destroy_notify_callback() is used by connection objects
+ * to add a notification callback that is executed on destruction.
+ *
+ * @ingroup slot
+ */
+class SIGC_API slot_base : public functor_base
+{
+  typedef internal::slot_rep rep_type;
+
+public:
+  /// Constructs an empty slot.
+  slot_base();
+
+  /** Constructs a slot from an existing slot_rep object.
+   * @param rep The slot_rep object this slot should contain.
+   */
+  explicit slot_base(rep_type* rep);
+
+  /** Constructs a slot, copying an existing one.
+   * @param src The existing slot to copy.
+   */
+  slot_base(const slot_base& src);
+
+  ~slot_base();
+
+  /** Tests whether a slot is null, because the default constructor was used.
+   * Test a slot for null like so:
+   * @code
+   * if(slot)
+   *  do_something()
+   * @endcode
+   */
+  operator bool() const;
+
+  /** Sets the parent of this slot.
+   * This function is used by signals to register a notification callback.
+   * This notification callback is executed when the slot becomes invalid
+   * because of some referred object dying.
+   * @param parent The new parent.
+   * @param cleanup The notification callback.
+   */
+  void set_parent(void* parent, void* (*cleanup)(void*)) const;
+
+  typedef trackable::func_destroy_notify func_destroy_notify;
+  /** Add a callback that is executed (notified) when the slot is detroyed.
+   * This function is used internally by connection objects.
+   * @param data Passed into func upon notification.
+   * @param func Callback executed upon destruction of the object.
+   */
+  void add_destroy_notify_callback(void* data, func_destroy_notify func) const;
+
+  /** Remove a callback previously installed with add_destroy_notify_callback().
+   * The callback is not executed.
+   * @param data Parameter passed into previous call to add_destroy_notify_callback().
+   */
+  void remove_destroy_notify_callback(void* data) const;
+
+  /** Returns whether the slot is invalid.
+   * @return @p true if the slot is invalid (empty).
+   */
+  inline bool empty() const
+    { return (!rep_ || !rep_->call_); }
+
+  /** Returns whether the slot is blocked.
+   * @return @p true if the slot is blocked.
+   */
+  inline bool blocked() const
+    { return blocked_; }
+    
+  /** Sets the blocking state.
+   * If @e should_block is @p true then the blocking state is set.
+   * Subsequent calls to slot::operator()() don't invoke the functor
+   * contained by this slot until unblock() or block() with
+   * @e should_block = @p false is called.
+   * @param should_block Indicates whether the blocking state should be set or unset.
+   * @return @p true if the slot was in blocking state before.
+   */
+  bool block(bool should_block = true);
+
+  /** Unsets the blocking state.
+   * @return @p true if the slot was in blocking state before.
+   */
+  bool unblock();
+
+  /** Disconnects the slot.
+   * Invalidates the slot and notifies the parent.
+   */
+  void disconnect();
+
+protected:
+  /** Overrides this slot making a copy from another slot.
+   * @param src The slot from which to make a copy.
+   * @return @p this.
+   */
+  slot_base& operator=(const slot_base& src);
+
+public: // public to avoid template friend declarations
+  /** Typed slot_rep object that contains a functor. */
+  mutable rep_type *rep_;
+
+  /** Indicates whether the slot is blocked. */
+  bool blocked_;
+};
+
+} //namespace sigc
+
+#endif //_SIGC_SLOT_BASE_HPP_
+
diff --git a/libs/sigc++2/sigc++/hide.h b/libs/sigc++2/sigc++/hide.h
new file mode 100644
index 0000000000..c4852b7b42
--- /dev/null
+++ b/libs/sigc++2/sigc++/hide.h
@@ -0,0 +1,105 @@
+// -*- c++ -*-
+/* Do not edit! -- generated file */
+
+#ifndef _SIGC_MACROS_HIDEHM4_
+#define _SIGC_MACROS_HIDEHM4_
+
+#include <sigc++/slot.h>
+#include <sigc++/adaptors/hide.h>
+
+
+#ifndef LIBSIGC_DISABLE_DEPRECATED
+
+namespace SigC {
+
+template <class T_hidden1, class T_return>
+inline SigC::Slot1<T_return, T_hidden1>
+hide(const SigC::Slot0<T_return>& _A_slot)
+{ return ::sigc::hide_functor<0, SigC::Slot0<T_return> >
+      (_A_slot); }
+
+template <class T_hidden1, class T_return, class T_arg1>
+inline SigC::Slot2<T_return, T_arg1, T_hidden1>
+hide(const SigC::Slot1<T_return, T_arg1>& _A_slot)
+{ return ::sigc::hide_functor<0, SigC::Slot1<T_return, T_arg1> >
+      (_A_slot); }
+
+template <class T_hidden1, class T_return, class T_arg1,class T_arg2>
+inline SigC::Slot3<T_return, T_arg1,T_arg2, T_hidden1>
+hide(const SigC::Slot2<T_return, T_arg1,T_arg2>& _A_slot)
+{ return ::sigc::hide_functor<0, SigC::Slot2<T_return, T_arg1,T_arg2> >
+      (_A_slot); }
+
+template <class T_hidden1, class T_return, class T_arg1,class T_arg2,class T_arg3>
+inline SigC::Slot4<T_return, T_arg1,T_arg2,T_arg3, T_hidden1>
+hide(const SigC::Slot3<T_return, T_arg1,T_arg2,T_arg3>& _A_slot)
+{ return ::sigc::hide_functor<0, SigC::Slot3<T_return, T_arg1,T_arg2,T_arg3> >
+      (_A_slot); }
+
+template <class T_hidden1, class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+inline SigC::Slot5<T_return, T_arg1,T_arg2,T_arg3,T_arg4, T_hidden1>
+hide(const SigC::Slot4<T_return, T_arg1,T_arg2,T_arg3,T_arg4>& _A_slot)
+{ return ::sigc::hide_functor<0, SigC::Slot4<T_return, T_arg1,T_arg2,T_arg3,T_arg4> >
+      (_A_slot); }
+
+template <class T_hidden1, class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+inline SigC::Slot6<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5, T_hidden1>
+hide(const SigC::Slot5<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>& _A_slot)
+{ return ::sigc::hide_functor<0, SigC::Slot5<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5> >
+      (_A_slot); }
+
+template <class T_hidden1, class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+inline SigC::Slot7<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6, T_hidden1>
+hide(const SigC::Slot6<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>& _A_slot)
+{ return ::sigc::hide_functor<0, SigC::Slot6<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6> >
+      (_A_slot); }
+
+
+template <class T_hidden1,class T_hidden2, class T_return>
+inline SigC::Slot2<T_return, T_hidden1,T_hidden2>
+hide(const SigC::Slot0<T_return>& _A_slot)
+{ return ::sigc::hide<0>(
+    ::sigc::hide_functor<0, SigC::Slot0<T_return> >
+      (_A_slot)); }
+
+template <class T_hidden1,class T_hidden2, class T_return, class T_arg1>
+inline SigC::Slot3<T_return, T_arg1, T_hidden1,T_hidden2>
+hide(const SigC::Slot1<T_return, T_arg1>& _A_slot)
+{ return ::sigc::hide<0>(
+    ::sigc::hide_functor<0, SigC::Slot1<T_return, T_arg1> >
+      (_A_slot)); }
+
+template <class T_hidden1,class T_hidden2, class T_return, class T_arg1,class T_arg2>
+inline SigC::Slot4<T_return, T_arg1,T_arg2, T_hidden1,T_hidden2>
+hide(const SigC::Slot2<T_return, T_arg1,T_arg2>& _A_slot)
+{ return ::sigc::hide<0>(
+    ::sigc::hide_functor<0, SigC::Slot2<T_return, T_arg1,T_arg2> >
+      (_A_slot)); }
+
+template <class T_hidden1,class T_hidden2, class T_return, class T_arg1,class T_arg2,class T_arg3>
+inline SigC::Slot5<T_return, T_arg1,T_arg2,T_arg3, T_hidden1,T_hidden2>
+hide(const SigC::Slot3<T_return, T_arg1,T_arg2,T_arg3>& _A_slot)
+{ return ::sigc::hide<0>(
+    ::sigc::hide_functor<0, SigC::Slot3<T_return, T_arg1,T_arg2,T_arg3> >
+      (_A_slot)); }
+
+template <class T_hidden1,class T_hidden2, class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+inline SigC::Slot6<T_return, T_arg1,T_arg2,T_arg3,T_arg4, T_hidden1,T_hidden2>
+hide(const SigC::Slot4<T_return, T_arg1,T_arg2,T_arg3,T_arg4>& _A_slot)
+{ return ::sigc::hide<0>(
+    ::sigc::hide_functor<0, SigC::Slot4<T_return, T_arg1,T_arg2,T_arg3,T_arg4> >
+      (_A_slot)); }
+
+template <class T_hidden1,class T_hidden2, class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+inline SigC::Slot7<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5, T_hidden1,T_hidden2>
+hide(const SigC::Slot5<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>& _A_slot)
+{ return ::sigc::hide<0>(
+    ::sigc::hide_functor<0, SigC::Slot5<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5> >
+      (_A_slot)); }
+
+
+
+} /* namespace SigC */
+
+#endif /* LIBSIGC_DISABLE_DEPRECATED */
+#endif /* _SIGC_MACROS_HIDEHM4_ */
diff --git a/libs/sigc++2/sigc++/method_slot.h b/libs/sigc++2/sigc++/method_slot.h
new file mode 100644
index 0000000000..d92781633b
--- /dev/null
+++ b/libs/sigc++2/sigc++/method_slot.h
@@ -0,0 +1,387 @@
+// -*- c++ -*-
+/* Do not edit! -- generated file */
+
+
+#ifndef _SIGC_MACROS_METHOD_SLOTHM4_
+#define _SIGC_MACROS_METHOD_SLOTHM4_
+
+#include <sigc++/slot.h>
+#include <sigc++/functors/mem_fun.h>
+
+#ifndef LIBSIGC_DISABLE_DEPRECATED
+
+namespace SigC {
+
+/** Creates a functor of type Sigc::Slot1 that wraps a  method.
+ *
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_obj>
+inline Slot1<T_return, T_obj&>
+slot(T_return (T_obj::*_A_func)() )
+{ return ::sigc::mem_functor0<T_return, T_obj>(_A_func); }
+
+/** Creates a functor of type Sigc::Slot2 that wraps a  method.
+ *
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1, class T_obj>
+inline Slot2<T_return, T_obj&, T_arg1>
+slot(T_return (T_obj::*_A_func)(T_arg1) )
+{ return ::sigc::mem_functor1<T_return, T_obj, T_arg1>(_A_func); }
+
+/** Creates a functor of type Sigc::Slot3 that wraps a  method.
+ *
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2, class T_obj>
+inline Slot3<T_return, T_obj&, T_arg1,T_arg2>
+slot(T_return (T_obj::*_A_func)(T_arg1,T_arg2) )
+{ return ::sigc::mem_functor2<T_return, T_obj, T_arg1,T_arg2>(_A_func); }
+
+/** Creates a functor of type Sigc::Slot4 that wraps a  method.
+ *
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3, class T_obj>
+inline Slot4<T_return, T_obj&, T_arg1,T_arg2,T_arg3>
+slot(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3) )
+{ return ::sigc::mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>(_A_func); }
+
+/** Creates a functor of type Sigc::Slot5 that wraps a  method.
+ *
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_obj>
+inline Slot5<T_return, T_obj&, T_arg1,T_arg2,T_arg3,T_arg4>
+slot(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4) )
+{ return ::sigc::mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>(_A_func); }
+
+/** Creates a functor of type Sigc::Slot6 that wraps a  method.
+ *
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_obj>
+inline Slot6<T_return, T_obj&, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+slot(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) )
+{ return ::sigc::mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_func); }
+
+/** Creates a functor of type Sigc::Slot7 that wraps a  method.
+ *
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_obj>
+inline Slot7<T_return, T_obj&, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+slot(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) )
+{ return ::sigc::mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_func); }
+
+
+/** Creates a functor of type Sigc::Slot1 that wraps a const method.
+ *
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_obj>
+inline Slot1<T_return, T_obj&>
+slot(T_return (T_obj::*_A_func)() const)
+{ return ::sigc::const_mem_functor0<T_return, T_obj>(_A_func); }
+
+/** Creates a functor of type Sigc::Slot2 that wraps a const method.
+ *
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1, class T_obj>
+inline Slot2<T_return, T_obj&, T_arg1>
+slot(T_return (T_obj::*_A_func)(T_arg1) const)
+{ return ::sigc::const_mem_functor1<T_return, T_obj, T_arg1>(_A_func); }
+
+/** Creates a functor of type Sigc::Slot3 that wraps a const method.
+ *
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2, class T_obj>
+inline Slot3<T_return, T_obj&, T_arg1,T_arg2>
+slot(T_return (T_obj::*_A_func)(T_arg1,T_arg2) const)
+{ return ::sigc::const_mem_functor2<T_return, T_obj, T_arg1,T_arg2>(_A_func); }
+
+/** Creates a functor of type Sigc::Slot4 that wraps a const method.
+ *
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3, class T_obj>
+inline Slot4<T_return, T_obj&, T_arg1,T_arg2,T_arg3>
+slot(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3) const)
+{ return ::sigc::const_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>(_A_func); }
+
+/** Creates a functor of type Sigc::Slot5 that wraps a const method.
+ *
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_obj>
+inline Slot5<T_return, T_obj&, T_arg1,T_arg2,T_arg3,T_arg4>
+slot(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4) const)
+{ return ::sigc::const_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>(_A_func); }
+
+/** Creates a functor of type Sigc::Slot6 that wraps a const method.
+ *
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_obj>
+inline Slot6<T_return, T_obj&, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+slot(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) const)
+{ return ::sigc::const_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_func); }
+
+/** Creates a functor of type Sigc::Slot7 that wraps a const method.
+ *
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_obj>
+inline Slot7<T_return, T_obj&, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+slot(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) const)
+{ return ::sigc::const_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_func); }
+
+
+/** Creates a functor of type Sigc::Slot1 that wraps a volatile method.
+ *
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_obj>
+inline Slot1<T_return, T_obj&>
+slot(T_return (T_obj::*_A_func)() volatile)
+{ return ::sigc::volatile_mem_functor0<T_return, T_obj>(_A_func); }
+
+/** Creates a functor of type Sigc::Slot2 that wraps a volatile method.
+ *
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1, class T_obj>
+inline Slot2<T_return, T_obj&, T_arg1>
+slot(T_return (T_obj::*_A_func)(T_arg1) volatile)
+{ return ::sigc::volatile_mem_functor1<T_return, T_obj, T_arg1>(_A_func); }
+
+/** Creates a functor of type Sigc::Slot3 that wraps a volatile method.
+ *
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2, class T_obj>
+inline Slot3<T_return, T_obj&, T_arg1,T_arg2>
+slot(T_return (T_obj::*_A_func)(T_arg1,T_arg2) volatile)
+{ return ::sigc::volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2>(_A_func); }
+
+/** Creates a functor of type Sigc::Slot4 that wraps a volatile method.
+ *
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3, class T_obj>
+inline Slot4<T_return, T_obj&, T_arg1,T_arg2,T_arg3>
+slot(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3) volatile)
+{ return ::sigc::volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>(_A_func); }
+
+/** Creates a functor of type Sigc::Slot5 that wraps a volatile method.
+ *
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_obj>
+inline Slot5<T_return, T_obj&, T_arg1,T_arg2,T_arg3,T_arg4>
+slot(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4) volatile)
+{ return ::sigc::volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>(_A_func); }
+
+/** Creates a functor of type Sigc::Slot6 that wraps a volatile method.
+ *
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_obj>
+inline Slot6<T_return, T_obj&, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+slot(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) volatile)
+{ return ::sigc::volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_func); }
+
+/** Creates a functor of type Sigc::Slot7 that wraps a volatile method.
+ *
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_obj>
+inline Slot7<T_return, T_obj&, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+slot(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) volatile)
+{ return ::sigc::volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_func); }
+
+
+/** Creates a functor of type Sigc::Slot1 that wraps a const volatile method.
+ *
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_obj>
+inline Slot1<T_return, T_obj&>
+slot(T_return (T_obj::*_A_func)() const volatile)
+{ return ::sigc::const_volatile_mem_functor0<T_return, T_obj>(_A_func); }
+
+/** Creates a functor of type Sigc::Slot2 that wraps a const volatile method.
+ *
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1, class T_obj>
+inline Slot2<T_return, T_obj&, T_arg1>
+slot(T_return (T_obj::*_A_func)(T_arg1) const volatile)
+{ return ::sigc::const_volatile_mem_functor1<T_return, T_obj, T_arg1>(_A_func); }
+
+/** Creates a functor of type Sigc::Slot3 that wraps a const volatile method.
+ *
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2, class T_obj>
+inline Slot3<T_return, T_obj&, T_arg1,T_arg2>
+slot(T_return (T_obj::*_A_func)(T_arg1,T_arg2) const volatile)
+{ return ::sigc::const_volatile_mem_functor2<T_return, T_obj, T_arg1,T_arg2>(_A_func); }
+
+/** Creates a functor of type Sigc::Slot4 that wraps a const volatile method.
+ *
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3, class T_obj>
+inline Slot4<T_return, T_obj&, T_arg1,T_arg2,T_arg3>
+slot(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3) const volatile)
+{ return ::sigc::const_volatile_mem_functor3<T_return, T_obj, T_arg1,T_arg2,T_arg3>(_A_func); }
+
+/** Creates a functor of type Sigc::Slot5 that wraps a const volatile method.
+ *
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_obj>
+inline Slot5<T_return, T_obj&, T_arg1,T_arg2,T_arg3,T_arg4>
+slot(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4) const volatile)
+{ return ::sigc::const_volatile_mem_functor4<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4>(_A_func); }
+
+/** Creates a functor of type Sigc::Slot6 that wraps a const volatile method.
+ *
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_obj>
+inline Slot6<T_return, T_obj&, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+slot(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) const volatile)
+{ return ::sigc::const_volatile_mem_functor5<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_func); }
+
+/** Creates a functor of type Sigc::Slot7 that wraps a const volatile method.
+ *
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_obj>
+inline Slot7<T_return, T_obj&, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+slot(T_return (T_obj::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) const volatile)
+{ return ::sigc::const_volatile_mem_functor6<T_return, T_obj, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_func); }
+
+
+
+}
+
+#endif
+#endif /* _SIGC_MACROS_METHOD_SLOTHM4_ */
diff --git a/libs/sigc++2/sigc++/object.h b/libs/sigc++2/sigc++/object.h
new file mode 100644
index 0000000000..0ddefa02b2
--- /dev/null
+++ b/libs/sigc++2/sigc++/object.h
@@ -0,0 +1,35 @@
+/*
+ * Copyright 2002, The libsigc++ Development Team
+ *
+ *  This library is free software; you can redistribute it and/or
+ *  modify it under the terms of the GNU Lesser General Public
+ *  License as published by the Free Software Foundation; either
+ *  version 2.1 of the License, or (at your option) any later version.
+ *
+ *  This library is distributed in the hope that it will be useful,
+ *  but WITHOUT ANY WARRANTY; without even the implied warranty of
+ *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
+ *  Lesser General Public License for more details.
+ *
+ *  You should have received a copy of the GNU Lesser General Public
+ *  License along with this library; if not, write to the Free Software
+ *  Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
+ *
+ */
+#ifndef _SIGC_OBJECT_HPP_
+#define _SIGC_OBJECT_HPP_
+
+#include <sigc++/trackable.h>
+
+#ifndef LIBSIGC_DISABLE_DEPRECATED
+
+namespace SigC {
+
+// Object
+typedef ::sigc::trackable Object;
+
+}
+
+#endif /* LIBSIGC_DISABLE_DEPRECATED */
+
+#endif /* _SIGC_OBJECT_HPP_ */
diff --git a/libs/sigc++2/sigc++/object_slot.h b/libs/sigc++2/sigc++/object_slot.h
new file mode 100644
index 0000000000..e9d031ed50
--- /dev/null
+++ b/libs/sigc++2/sigc++/object_slot.h
@@ -0,0 +1,536 @@
+// -*- c++ -*-
+/* Do not edit! -- generated file */
+
+
+#ifndef _SIGC_MACROS_OBJECT_SLOTHM4_
+#define _SIGC_MACROS_OBJECT_SLOTHM4_
+
+#include <sigc++/slot.h>
+#include <sigc++/object.h>
+#include <sigc++/functors/mem_fun.h>
+
+#ifndef LIBSIGC_DISABLE_DEPRECATED
+
+namespace SigC {
+
+/** Creates a functor of type SigC::Slot0 that encapsulates a  method and an object instance.
+ * @e _A_obj must be of a type that inherits from SigC::Object.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_obj1, class T_obj2>
+inline Slot0<T_return>
+slot( T_obj1& _A_obj, T_return (T_obj2::*_A_func)() )
+{ (void)dynamic_cast< Object&>(_A_obj); // trigger compiler error if T_obj1 does not derive from SigC::Object
+  return ::sigc::bound_mem_functor0<T_return, T_obj2>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot1 that encapsulates a  method and an object instance.
+ * @e _A_obj must be of a type that inherits from SigC::Object.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1, class T_obj1, class T_obj2>
+inline Slot1<T_return, T_arg1>
+slot( T_obj1& _A_obj, T_return (T_obj2::*_A_func)(T_arg1) )
+{ (void)dynamic_cast< Object&>(_A_obj); // trigger compiler error if T_obj1 does not derive from SigC::Object
+  return ::sigc::bound_mem_functor1<T_return, T_obj2, T_arg1>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot2 that encapsulates a  method and an object instance.
+ * @e _A_obj must be of a type that inherits from SigC::Object.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2, class T_obj1, class T_obj2>
+inline Slot2<T_return, T_arg1,T_arg2>
+slot( T_obj1& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2) )
+{ (void)dynamic_cast< Object&>(_A_obj); // trigger compiler error if T_obj1 does not derive from SigC::Object
+  return ::sigc::bound_mem_functor2<T_return, T_obj2, T_arg1,T_arg2>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot3 that encapsulates a  method and an object instance.
+ * @e _A_obj must be of a type that inherits from SigC::Object.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3, class T_obj1, class T_obj2>
+inline Slot3<T_return, T_arg1,T_arg2,T_arg3>
+slot( T_obj1& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3) )
+{ (void)dynamic_cast< Object&>(_A_obj); // trigger compiler error if T_obj1 does not derive from SigC::Object
+  return ::sigc::bound_mem_functor3<T_return, T_obj2, T_arg1,T_arg2,T_arg3>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot4 that encapsulates a  method and an object instance.
+ * @e _A_obj must be of a type that inherits from SigC::Object.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_obj1, class T_obj2>
+inline Slot4<T_return, T_arg1,T_arg2,T_arg3,T_arg4>
+slot( T_obj1& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4) )
+{ (void)dynamic_cast< Object&>(_A_obj); // trigger compiler error if T_obj1 does not derive from SigC::Object
+  return ::sigc::bound_mem_functor4<T_return, T_obj2, T_arg1,T_arg2,T_arg3,T_arg4>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot5 that encapsulates a  method and an object instance.
+ * @e _A_obj must be of a type that inherits from SigC::Object.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_obj1, class T_obj2>
+inline Slot5<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+slot( T_obj1& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) )
+{ (void)dynamic_cast< Object&>(_A_obj); // trigger compiler error if T_obj1 does not derive from SigC::Object
+  return ::sigc::bound_mem_functor5<T_return, T_obj2, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot6 that encapsulates a  method and an object instance.
+ * @e _A_obj must be of a type that inherits from SigC::Object.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_obj1, class T_obj2>
+inline Slot6<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+slot( T_obj1& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) )
+{ (void)dynamic_cast< Object&>(_A_obj); // trigger compiler error if T_obj1 does not derive from SigC::Object
+  return ::sigc::bound_mem_functor6<T_return, T_obj2, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot7 that encapsulates a  method and an object instance.
+ * @e _A_obj must be of a type that inherits from SigC::Object.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_obj1, class T_obj2>
+inline Slot7<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+slot( T_obj1& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7) )
+{ (void)dynamic_cast< Object&>(_A_obj); // trigger compiler error if T_obj1 does not derive from SigC::Object
+  return ::sigc::bound_mem_functor7<T_return, T_obj2, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>(_A_obj, _A_func); }
+
+
+/** Creates a functor of type SigC::Slot0 that encapsulates a const method and an object instance.
+ * @e _A_obj must be of a type that inherits from SigC::Object.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_obj1, class T_obj2>
+inline Slot0<T_return>
+slot(const T_obj1& _A_obj, T_return (T_obj2::*_A_func)() const)
+{ (void)dynamic_cast<const Object&>(_A_obj); // trigger compiler error if T_obj1 does not derive from SigC::Object
+  return ::sigc::bound_const_mem_functor0<T_return, T_obj2>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot1 that encapsulates a const method and an object instance.
+ * @e _A_obj must be of a type that inherits from SigC::Object.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1, class T_obj1, class T_obj2>
+inline Slot1<T_return, T_arg1>
+slot(const T_obj1& _A_obj, T_return (T_obj2::*_A_func)(T_arg1) const)
+{ (void)dynamic_cast<const Object&>(_A_obj); // trigger compiler error if T_obj1 does not derive from SigC::Object
+  return ::sigc::bound_const_mem_functor1<T_return, T_obj2, T_arg1>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot2 that encapsulates a const method and an object instance.
+ * @e _A_obj must be of a type that inherits from SigC::Object.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2, class T_obj1, class T_obj2>
+inline Slot2<T_return, T_arg1,T_arg2>
+slot(const T_obj1& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2) const)
+{ (void)dynamic_cast<const Object&>(_A_obj); // trigger compiler error if T_obj1 does not derive from SigC::Object
+  return ::sigc::bound_const_mem_functor2<T_return, T_obj2, T_arg1,T_arg2>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot3 that encapsulates a const method and an object instance.
+ * @e _A_obj must be of a type that inherits from SigC::Object.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3, class T_obj1, class T_obj2>
+inline Slot3<T_return, T_arg1,T_arg2,T_arg3>
+slot(const T_obj1& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3) const)
+{ (void)dynamic_cast<const Object&>(_A_obj); // trigger compiler error if T_obj1 does not derive from SigC::Object
+  return ::sigc::bound_const_mem_functor3<T_return, T_obj2, T_arg1,T_arg2,T_arg3>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot4 that encapsulates a const method and an object instance.
+ * @e _A_obj must be of a type that inherits from SigC::Object.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_obj1, class T_obj2>
+inline Slot4<T_return, T_arg1,T_arg2,T_arg3,T_arg4>
+slot(const T_obj1& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4) const)
+{ (void)dynamic_cast<const Object&>(_A_obj); // trigger compiler error if T_obj1 does not derive from SigC::Object
+  return ::sigc::bound_const_mem_functor4<T_return, T_obj2, T_arg1,T_arg2,T_arg3,T_arg4>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot5 that encapsulates a const method and an object instance.
+ * @e _A_obj must be of a type that inherits from SigC::Object.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_obj1, class T_obj2>
+inline Slot5<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+slot(const T_obj1& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) const)
+{ (void)dynamic_cast<const Object&>(_A_obj); // trigger compiler error if T_obj1 does not derive from SigC::Object
+  return ::sigc::bound_const_mem_functor5<T_return, T_obj2, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot6 that encapsulates a const method and an object instance.
+ * @e _A_obj must be of a type that inherits from SigC::Object.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_obj1, class T_obj2>
+inline Slot6<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+slot(const T_obj1& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) const)
+{ (void)dynamic_cast<const Object&>(_A_obj); // trigger compiler error if T_obj1 does not derive from SigC::Object
+  return ::sigc::bound_const_mem_functor6<T_return, T_obj2, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot7 that encapsulates a const method and an object instance.
+ * @e _A_obj must be of a type that inherits from SigC::Object.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_obj1, class T_obj2>
+inline Slot7<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+slot(const T_obj1& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7) const)
+{ (void)dynamic_cast<const Object&>(_A_obj); // trigger compiler error if T_obj1 does not derive from SigC::Object
+  return ::sigc::bound_const_mem_functor7<T_return, T_obj2, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>(_A_obj, _A_func); }
+
+
+/** Creates a functor of type SigC::Slot0 that encapsulates a volatile method and an object instance.
+ * @e _A_obj must be of a type that inherits from SigC::Object.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_obj1, class T_obj2>
+inline Slot0<T_return>
+slot( T_obj1& _A_obj, T_return (T_obj2::*_A_func)() volatile)
+{ (void)dynamic_cast< Object&>(_A_obj); // trigger compiler error if T_obj1 does not derive from SigC::Object
+  return ::sigc::bound_volatile_mem_functor0<T_return, T_obj2>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot1 that encapsulates a volatile method and an object instance.
+ * @e _A_obj must be of a type that inherits from SigC::Object.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1, class T_obj1, class T_obj2>
+inline Slot1<T_return, T_arg1>
+slot( T_obj1& _A_obj, T_return (T_obj2::*_A_func)(T_arg1) volatile)
+{ (void)dynamic_cast< Object&>(_A_obj); // trigger compiler error if T_obj1 does not derive from SigC::Object
+  return ::sigc::bound_volatile_mem_functor1<T_return, T_obj2, T_arg1>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot2 that encapsulates a volatile method and an object instance.
+ * @e _A_obj must be of a type that inherits from SigC::Object.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2, class T_obj1, class T_obj2>
+inline Slot2<T_return, T_arg1,T_arg2>
+slot( T_obj1& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2) volatile)
+{ (void)dynamic_cast< Object&>(_A_obj); // trigger compiler error if T_obj1 does not derive from SigC::Object
+  return ::sigc::bound_volatile_mem_functor2<T_return, T_obj2, T_arg1,T_arg2>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot3 that encapsulates a volatile method and an object instance.
+ * @e _A_obj must be of a type that inherits from SigC::Object.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3, class T_obj1, class T_obj2>
+inline Slot3<T_return, T_arg1,T_arg2,T_arg3>
+slot( T_obj1& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3) volatile)
+{ (void)dynamic_cast< Object&>(_A_obj); // trigger compiler error if T_obj1 does not derive from SigC::Object
+  return ::sigc::bound_volatile_mem_functor3<T_return, T_obj2, T_arg1,T_arg2,T_arg3>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot4 that encapsulates a volatile method and an object instance.
+ * @e _A_obj must be of a type that inherits from SigC::Object.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_obj1, class T_obj2>
+inline Slot4<T_return, T_arg1,T_arg2,T_arg3,T_arg4>
+slot( T_obj1& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4) volatile)
+{ (void)dynamic_cast< Object&>(_A_obj); // trigger compiler error if T_obj1 does not derive from SigC::Object
+  return ::sigc::bound_volatile_mem_functor4<T_return, T_obj2, T_arg1,T_arg2,T_arg3,T_arg4>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot5 that encapsulates a volatile method and an object instance.
+ * @e _A_obj must be of a type that inherits from SigC::Object.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_obj1, class T_obj2>
+inline Slot5<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+slot( T_obj1& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) volatile)
+{ (void)dynamic_cast< Object&>(_A_obj); // trigger compiler error if T_obj1 does not derive from SigC::Object
+  return ::sigc::bound_volatile_mem_functor5<T_return, T_obj2, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot6 that encapsulates a volatile method and an object instance.
+ * @e _A_obj must be of a type that inherits from SigC::Object.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_obj1, class T_obj2>
+inline Slot6<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+slot( T_obj1& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) volatile)
+{ (void)dynamic_cast< Object&>(_A_obj); // trigger compiler error if T_obj1 does not derive from SigC::Object
+  return ::sigc::bound_volatile_mem_functor6<T_return, T_obj2, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot7 that encapsulates a volatile method and an object instance.
+ * @e _A_obj must be of a type that inherits from SigC::Object.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_obj1, class T_obj2>
+inline Slot7<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+slot( T_obj1& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7) volatile)
+{ (void)dynamic_cast< Object&>(_A_obj); // trigger compiler error if T_obj1 does not derive from SigC::Object
+  return ::sigc::bound_volatile_mem_functor7<T_return, T_obj2, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>(_A_obj, _A_func); }
+
+
+/** Creates a functor of type SigC::Slot0 that encapsulates a const volatile method and an object instance.
+ * @e _A_obj must be of a type that inherits from SigC::Object.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_obj1, class T_obj2>
+inline Slot0<T_return>
+slot(const T_obj1& _A_obj, T_return (T_obj2::*_A_func)() const volatile)
+{ (void)dynamic_cast<const Object&>(_A_obj); // trigger compiler error if T_obj1 does not derive from SigC::Object
+  return ::sigc::bound_const_volatile_mem_functor0<T_return, T_obj2>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot1 that encapsulates a const volatile method and an object instance.
+ * @e _A_obj must be of a type that inherits from SigC::Object.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1, class T_obj1, class T_obj2>
+inline Slot1<T_return, T_arg1>
+slot(const T_obj1& _A_obj, T_return (T_obj2::*_A_func)(T_arg1) const volatile)
+{ (void)dynamic_cast<const Object&>(_A_obj); // trigger compiler error if T_obj1 does not derive from SigC::Object
+  return ::sigc::bound_const_volatile_mem_functor1<T_return, T_obj2, T_arg1>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot2 that encapsulates a const volatile method and an object instance.
+ * @e _A_obj must be of a type that inherits from SigC::Object.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2, class T_obj1, class T_obj2>
+inline Slot2<T_return, T_arg1,T_arg2>
+slot(const T_obj1& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2) const volatile)
+{ (void)dynamic_cast<const Object&>(_A_obj); // trigger compiler error if T_obj1 does not derive from SigC::Object
+  return ::sigc::bound_const_volatile_mem_functor2<T_return, T_obj2, T_arg1,T_arg2>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot3 that encapsulates a const volatile method and an object instance.
+ * @e _A_obj must be of a type that inherits from SigC::Object.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3, class T_obj1, class T_obj2>
+inline Slot3<T_return, T_arg1,T_arg2,T_arg3>
+slot(const T_obj1& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3) const volatile)
+{ (void)dynamic_cast<const Object&>(_A_obj); // trigger compiler error if T_obj1 does not derive from SigC::Object
+  return ::sigc::bound_const_volatile_mem_functor3<T_return, T_obj2, T_arg1,T_arg2,T_arg3>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot4 that encapsulates a const volatile method and an object instance.
+ * @e _A_obj must be of a type that inherits from SigC::Object.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_obj1, class T_obj2>
+inline Slot4<T_return, T_arg1,T_arg2,T_arg3,T_arg4>
+slot(const T_obj1& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4) const volatile)
+{ (void)dynamic_cast<const Object&>(_A_obj); // trigger compiler error if T_obj1 does not derive from SigC::Object
+  return ::sigc::bound_const_volatile_mem_functor4<T_return, T_obj2, T_arg1,T_arg2,T_arg3,T_arg4>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot5 that encapsulates a const volatile method and an object instance.
+ * @e _A_obj must be of a type that inherits from SigC::Object.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_obj1, class T_obj2>
+inline Slot5<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+slot(const T_obj1& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5) const volatile)
+{ (void)dynamic_cast<const Object&>(_A_obj); // trigger compiler error if T_obj1 does not derive from SigC::Object
+  return ::sigc::bound_const_volatile_mem_functor5<T_return, T_obj2, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot6 that encapsulates a const volatile method and an object instance.
+ * @e _A_obj must be of a type that inherits from SigC::Object.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_obj1, class T_obj2>
+inline Slot6<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+slot(const T_obj1& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6) const volatile)
+{ (void)dynamic_cast<const Object&>(_A_obj); // trigger compiler error if T_obj1 does not derive from SigC::Object
+  return ::sigc::bound_const_volatile_mem_functor6<T_return, T_obj2, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_obj, _A_func); }
+
+/** Creates a functor of type SigC::Slot7 that encapsulates a const volatile method and an object instance.
+ * @e _A_obj must be of a type that inherits from SigC::Object.
+ *
+ * @param _A_obj Reference to object instance the functor should operate on.
+ * @param _A_func Pointer to method that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::mem_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_obj1, class T_obj2>
+inline Slot7<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+slot(const T_obj1& _A_obj, T_return (T_obj2::*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7) const volatile)
+{ (void)dynamic_cast<const Object&>(_A_obj); // trigger compiler error if T_obj1 does not derive from SigC::Object
+  return ::sigc::bound_const_volatile_mem_functor7<T_return, T_obj2, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>(_A_obj, _A_func); }
+
+
+
+}
+
+#endif
+#endif /* _SIGC_MACROS_OBJECT_SLOTHM4_ */
diff --git a/libs/sigc++2/sigc++/reference_wrapper.h b/libs/sigc++2/sigc++/reference_wrapper.h
new file mode 100644
index 0000000000..436e02f9bb
--- /dev/null
+++ b/libs/sigc++2/sigc++/reference_wrapper.h
@@ -0,0 +1,118 @@
+/*
+ * Copyright 2002, The libsigc++ Development Team
+ *
+ *  This library is free software; you can redistribute it and/or
+ *  modify it under the terms of the GNU Lesser General Public
+ *  License as published by the Free Software Foundation; either
+ *  version 2.1 of the License, or (at your option) any later version.
+ *
+ *  This library is distributed in the hope that it will be useful,
+ *  but WITHOUT ANY WARRANTY; without even the implied warranty of
+ *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
+ *  Lesser General Public License for more details.
+ *
+ *  You should have received a copy of the GNU Lesser General Public
+ *  License along with this library; if not, write to the Free Software
+ *  Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
+ *
+ */
+#ifndef _SIGC_REFERENCE_WRAPPER_H_
+#define _SIGC_REFERENCE_WRAPPER_H_
+
+namespace sigc {
+
+/** Reference wrapper.
+ * Use sigc::ref() to create a reference wrapper.
+ */
+template <class T_type>
+struct reference_wrapper
+{
+  explicit reference_wrapper(T_type& v)
+    : value_(v)  {}
+
+  operator T_type& () const
+    { return value_; }
+
+  T_type& value_;
+};
+
+/** Const reference wrapper.
+ * Use sigc::ref() to create a const reference wrapper.
+ */
+template <class T_type>
+struct const_reference_wrapper
+{
+  explicit const_reference_wrapper(const T_type& v)
+    : value_(v)  {}
+
+  operator const T_type& () const
+    { return value_; }
+
+  const T_type& value_;
+};
+
+/** Creates a reference wrapper.
+ * Passing an object throught sigc::ref() makes libsigc++ adaptors
+ * like, e.g., sigc::bind store references to the object instead of copies.
+ * If the object type inherits from sigc::trackable this will ensure
+ * automatic invalidation of the adaptors when the object is deleted
+ * or overwritten.
+ *
+ * @param v Reference to store.
+ * @return A reference wrapper.
+ */
+template <class T_type>
+reference_wrapper<T_type> ref(T_type& v)
+{ return reference_wrapper<T_type>(v); }
+
+/** Creates a const reference wrapper.
+ * Passing an object throught sigc::ref() makes libsigc++ adaptors
+ * like, e.g., sigc::bind store references to the object instead of copies.
+ * If the object type inherits from sigc::trackable this will ensure
+ * automatic invalidation of the adaptors when the object is deleted
+ * or overwritten.
+ *
+ * @param v Reference to store.
+ * @return A reference wrapper.
+ */
+template <class T_type>
+const_reference_wrapper<T_type> ref(const T_type& v)
+{ return const_reference_wrapper<T_type>(v); }
+
+template <class T_type>
+struct unwrap_reference
+{
+  typedef T_type type;
+};
+
+template <class T_type>
+struct unwrap_reference<reference_wrapper<T_type> >
+{
+  typedef T_type& type;
+};
+
+template <class T_type>
+struct unwrap_reference<const_reference_wrapper<T_type> >
+{
+  typedef const T_type& type;
+};
+
+template <class T_type>
+T_type& unwrap(T_type& v)
+{ return v; }
+
+template <class T_type>
+const T_type& unwrap(const T_type& v)
+{ return v; }
+
+template <class T_type>
+T_type& unwrap(const reference_wrapper<T_type>& v)
+{ return v; }
+
+template <class T_type>
+const T_type& unwrap(const const_reference_wrapper<T_type>& v)
+{ return v; }
+
+} /* namespace sigc */
+
+#endif /* _SIGC_REFERENCE_WRAPPER_H_ */
diff --git a/libs/sigc++2/sigc++/retype.h b/libs/sigc++2/sigc++/retype.h
new file mode 100644
index 0000000000..5df6622f84
--- /dev/null
+++ b/libs/sigc++2/sigc++/retype.h
@@ -0,0 +1,321 @@
+// -*- c++ -*-
+/* Do not edit! -- generated file */
+#ifndef _SIGC_MACROS_RETYPEHM4_
+#define _SIGC_MACROS_RETYPEHM4_
+#include <sigc++/adaptors/adaptor_trait.h>
+#include <sigc++/slot.h>
+
+#ifndef LIBSIGC_DISABLE_DEPRECATED
+
+namespace SigC {
+
+template <class T_functor, class T_return, class T_type1=::sigc::nil,class T_type2=::sigc::nil,class T_type3=::sigc::nil,class T_type4=::sigc::nil,class T_type5=::sigc::nil,class T_type6=::sigc::nil,class T_type7=::sigc::nil>
+struct retype_slot_functor
+  : public ::sigc::adapts<T_functor>
+{
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef T_return type; };
+  typedef T_return result_type;
+
+  T_return operator()();
+
+  template <class T_arg1>
+  inline T_return operator()(T_arg1 _A_a1)
+    { return T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename ::sigc::type_trait<T_type1>::take>
+        ((T_type1)_A_a1));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1>
+  inline T_return sun_forte_workaround(T_arg1 _A_a1)
+    { return T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename ::sigc::type_trait<T_type1>::take>
+        ((T_type1)_A_a1));
+    }
+  #endif
+  
+  template <class T_arg1,class T_arg2>
+  inline T_return operator()(T_arg1 _A_a1,T_arg2 _A_a2)
+    { return T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename ::sigc::type_trait<T_type1>::take,typename ::sigc::type_trait<T_type2>::take>
+        ((T_type1)_A_a1,(T_type2)_A_a2));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2>
+  inline T_return sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2)
+    { return T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename ::sigc::type_trait<T_type1>::take,typename ::sigc::type_trait<T_type2>::take>
+        ((T_type1)_A_a1,(T_type2)_A_a2));
+    }
+  #endif
+  
+  template <class T_arg1,class T_arg2,class T_arg3>
+  inline T_return operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3)
+    { return T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename ::sigc::type_trait<T_type1>::take,typename ::sigc::type_trait<T_type2>::take,typename ::sigc::type_trait<T_type3>::take>
+        ((T_type1)_A_a1,(T_type2)_A_a2,(T_type3)_A_a3));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3>
+  inline T_return sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3)
+    { return T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename ::sigc::type_trait<T_type1>::take,typename ::sigc::type_trait<T_type2>::take,typename ::sigc::type_trait<T_type3>::take>
+        ((T_type1)_A_a1,(T_type2)_A_a2,(T_type3)_A_a3));
+    }
+  #endif
+  
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  inline T_return operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4)
+    { return T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename ::sigc::type_trait<T_type1>::take,typename ::sigc::type_trait<T_type2>::take,typename ::sigc::type_trait<T_type3>::take,typename ::sigc::type_trait<T_type4>::take>
+        ((T_type1)_A_a1,(T_type2)_A_a2,(T_type3)_A_a3,(T_type4)_A_a4));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  inline T_return sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4)
+    { return T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename ::sigc::type_trait<T_type1>::take,typename ::sigc::type_trait<T_type2>::take,typename ::sigc::type_trait<T_type3>::take,typename ::sigc::type_trait<T_type4>::take>
+        ((T_type1)_A_a1,(T_type2)_A_a2,(T_type3)_A_a3,(T_type4)_A_a4));
+    }
+  #endif
+  
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  inline T_return operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5)
+    { return T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename ::sigc::type_trait<T_type1>::take,typename ::sigc::type_trait<T_type2>::take,typename ::sigc::type_trait<T_type3>::take,typename ::sigc::type_trait<T_type4>::take,typename ::sigc::type_trait<T_type5>::take>
+        ((T_type1)_A_a1,(T_type2)_A_a2,(T_type3)_A_a3,(T_type4)_A_a4,(T_type5)_A_a5));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  inline T_return sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5)
+    { return T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename ::sigc::type_trait<T_type1>::take,typename ::sigc::type_trait<T_type2>::take,typename ::sigc::type_trait<T_type3>::take,typename ::sigc::type_trait<T_type4>::take,typename ::sigc::type_trait<T_type5>::take>
+        ((T_type1)_A_a1,(T_type2)_A_a2,(T_type3)_A_a3,(T_type4)_A_a4,(T_type5)_A_a5));
+    }
+  #endif
+  
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  inline T_return operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6)
+    { return T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename ::sigc::type_trait<T_type1>::take,typename ::sigc::type_trait<T_type2>::take,typename ::sigc::type_trait<T_type3>::take,typename ::sigc::type_trait<T_type4>::take,typename ::sigc::type_trait<T_type5>::take,typename ::sigc::type_trait<T_type6>::take>
+        ((T_type1)_A_a1,(T_type2)_A_a2,(T_type3)_A_a3,(T_type4)_A_a4,(T_type5)_A_a5,(T_type6)_A_a6));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  inline T_return sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6)
+    { return T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename ::sigc::type_trait<T_type1>::take,typename ::sigc::type_trait<T_type2>::take,typename ::sigc::type_trait<T_type3>::take,typename ::sigc::type_trait<T_type4>::take,typename ::sigc::type_trait<T_type5>::take,typename ::sigc::type_trait<T_type6>::take>
+        ((T_type1)_A_a1,(T_type2)_A_a2,(T_type3)_A_a3,(T_type4)_A_a4,(T_type5)_A_a5,(T_type6)_A_a6));
+    }
+  #endif
+  
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  inline T_return operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6,T_arg7 _A_a7)
+    { return T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename ::sigc::type_trait<T_type1>::take,typename ::sigc::type_trait<T_type2>::take,typename ::sigc::type_trait<T_type3>::take,typename ::sigc::type_trait<T_type4>::take,typename ::sigc::type_trait<T_type5>::take,typename ::sigc::type_trait<T_type6>::take,typename ::sigc::type_trait<T_type7>::take>
+        ((T_type1)_A_a1,(T_type2)_A_a2,(T_type3)_A_a3,(T_type4)_A_a4,(T_type5)_A_a5,(T_type6)_A_a6,(T_type7)_A_a7));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  inline T_return sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6,T_arg7 _A_a7)
+    { return T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename ::sigc::type_trait<T_type1>::take,typename ::sigc::type_trait<T_type2>::take,typename ::sigc::type_trait<T_type3>::take,typename ::sigc::type_trait<T_type4>::take,typename ::sigc::type_trait<T_type5>::take,typename ::sigc::type_trait<T_type6>::take,typename ::sigc::type_trait<T_type7>::take>
+        ((T_type1)_A_a1,(T_type2)_A_a2,(T_type3)_A_a3,(T_type4)_A_a4,(T_type5)_A_a5,(T_type6)_A_a6,(T_type7)_A_a7));
+    }
+  #endif
+  
+
+  retype_slot_functor(typename ::sigc::type_trait<T_functor>::take _A_functor)
+    : ::sigc::adapts<T_functor>(_A_functor)
+    {}
+};
+
+template <class T_functor, class T_return, class T_type1,class T_type2,class T_type3,class T_type4,class T_type5,class T_type6,class T_type7>
+T_return retype_slot_functor<T_functor, T_return, T_type1,T_type2,T_type3,T_type4,T_type5,T_type6,T_type7>::operator()()
+  { return T_return(this->functor_()); }
+
+
+// void specialization needed because of explicit cast to T_return
+template <class T_functor, class T_type1,class T_type2,class T_type3,class T_type4,class T_type5,class T_type6,class T_type7>
+struct retype_slot_functor<T_functor, void, T_type1,T_type2,T_type3,T_type4,T_type5,T_type6,T_type7>
+  : public ::sigc::adapts<T_functor>
+{
+  template <class T_arg1=void,class T_arg2=void,class T_arg3=void,class T_arg4=void,class T_arg5=void,class T_arg6=void,class T_arg7=void>
+  struct deduce_result_type
+    { typedef void type; };
+  typedef void result_type;
+
+  void operator()();
+
+  template <class T_arg1>
+  inline void operator()(T_arg1 _A_a1)
+    { T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename ::sigc::type_trait<T_type1>::take>
+        ((T_type1)_A_a1));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1>
+  inline void sun_forte_workaround(T_arg1 _A_a1)
+    { T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename ::sigc::type_trait<T_type1>::take>
+        ((T_type1)_A_a1));
+    }
+  #endif
+    
+  template <class T_arg1,class T_arg2>
+  inline void operator()(T_arg1 _A_a1,T_arg2 _A_a2)
+    { T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename ::sigc::type_trait<T_type1>::take,typename ::sigc::type_trait<T_type2>::take>
+        ((T_type1)_A_a1,(T_type2)_A_a2));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2>
+  inline void sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2)
+    { T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename ::sigc::type_trait<T_type1>::take,typename ::sigc::type_trait<T_type2>::take>
+        ((T_type1)_A_a1,(T_type2)_A_a2));
+    }
+  #endif
+    
+  template <class T_arg1,class T_arg2,class T_arg3>
+  inline void operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3)
+    { T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename ::sigc::type_trait<T_type1>::take,typename ::sigc::type_trait<T_type2>::take,typename ::sigc::type_trait<T_type3>::take>
+        ((T_type1)_A_a1,(T_type2)_A_a2,(T_type3)_A_a3));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3>
+  inline void sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3)
+    { T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename ::sigc::type_trait<T_type1>::take,typename ::sigc::type_trait<T_type2>::take,typename ::sigc::type_trait<T_type3>::take>
+        ((T_type1)_A_a1,(T_type2)_A_a2,(T_type3)_A_a3));
+    }
+  #endif
+    
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  inline void operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4)
+    { T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename ::sigc::type_trait<T_type1>::take,typename ::sigc::type_trait<T_type2>::take,typename ::sigc::type_trait<T_type3>::take,typename ::sigc::type_trait<T_type4>::take>
+        ((T_type1)_A_a1,(T_type2)_A_a2,(T_type3)_A_a3,(T_type4)_A_a4));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+  inline void sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4)
+    { T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename ::sigc::type_trait<T_type1>::take,typename ::sigc::type_trait<T_type2>::take,typename ::sigc::type_trait<T_type3>::take,typename ::sigc::type_trait<T_type4>::take>
+        ((T_type1)_A_a1,(T_type2)_A_a2,(T_type3)_A_a3,(T_type4)_A_a4));
+    }
+  #endif
+    
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  inline void operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5)
+    { T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename ::sigc::type_trait<T_type1>::take,typename ::sigc::type_trait<T_type2>::take,typename ::sigc::type_trait<T_type3>::take,typename ::sigc::type_trait<T_type4>::take,typename ::sigc::type_trait<T_type5>::take>
+        ((T_type1)_A_a1,(T_type2)_A_a2,(T_type3)_A_a3,(T_type4)_A_a4,(T_type5)_A_a5));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+  inline void sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5)
+    { T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename ::sigc::type_trait<T_type1>::take,typename ::sigc::type_trait<T_type2>::take,typename ::sigc::type_trait<T_type3>::take,typename ::sigc::type_trait<T_type4>::take,typename ::sigc::type_trait<T_type5>::take>
+        ((T_type1)_A_a1,(T_type2)_A_a2,(T_type3)_A_a3,(T_type4)_A_a4,(T_type5)_A_a5));
+    }
+  #endif
+    
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  inline void operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6)
+    { T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename ::sigc::type_trait<T_type1>::take,typename ::sigc::type_trait<T_type2>::take,typename ::sigc::type_trait<T_type3>::take,typename ::sigc::type_trait<T_type4>::take,typename ::sigc::type_trait<T_type5>::take,typename ::sigc::type_trait<T_type6>::take>
+        ((T_type1)_A_a1,(T_type2)_A_a2,(T_type3)_A_a3,(T_type4)_A_a4,(T_type5)_A_a5,(T_type6)_A_a6));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+  inline void sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6)
+    { T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename ::sigc::type_trait<T_type1>::take,typename ::sigc::type_trait<T_type2>::take,typename ::sigc::type_trait<T_type3>::take,typename ::sigc::type_trait<T_type4>::take,typename ::sigc::type_trait<T_type5>::take,typename ::sigc::type_trait<T_type6>::take>
+        ((T_type1)_A_a1,(T_type2)_A_a2,(T_type3)_A_a3,(T_type4)_A_a4,(T_type5)_A_a5,(T_type6)_A_a6));
+    }
+  #endif
+    
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  inline void operator()(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6,T_arg7 _A_a7)
+    { T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename ::sigc::type_trait<T_type1>::take,typename ::sigc::type_trait<T_type2>::take,typename ::sigc::type_trait<T_type3>::take,typename ::sigc::type_trait<T_type4>::take,typename ::sigc::type_trait<T_type5>::take,typename ::sigc::type_trait<T_type6>::take,typename ::sigc::type_trait<T_type7>::take>
+        ((T_type1)_A_a1,(T_type2)_A_a2,(T_type3)_A_a3,(T_type4)_A_a4,(T_type5)_A_a5,(T_type6)_A_a6,(T_type7)_A_a7));
+    }
+
+  #ifndef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+  inline void sun_forte_workaround(T_arg1 _A_a1,T_arg2 _A_a2,T_arg3 _A_a3,T_arg4 _A_a4,T_arg5 _A_a5,T_arg6 _A_a6,T_arg7 _A_a7)
+    { T_return(this->functor_.SIGC_WORKAROUND_OPERATOR_PARENTHESES<typename ::sigc::type_trait<T_type1>::take,typename ::sigc::type_trait<T_type2>::take,typename ::sigc::type_trait<T_type3>::take,typename ::sigc::type_trait<T_type4>::take,typename ::sigc::type_trait<T_type5>::take,typename ::sigc::type_trait<T_type6>::take,typename ::sigc::type_trait<T_type7>::take>
+        ((T_type1)_A_a1,(T_type2)_A_a2,(T_type3)_A_a3,(T_type4)_A_a4,(T_type5)_A_a5,(T_type6)_A_a6,(T_type7)_A_a7));
+    }
+  #endif
+    
+
+  retype_slot_functor(typename ::sigc::type_trait<T_functor>::take _A_functor)
+    : ::sigc::adapts<T_functor>(_A_functor)
+    {}
+};
+
+template <class T_functor, class T_type1,class T_type2,class T_type3,class T_type4,class T_type5,class T_type6,class T_type7>
+void retype_slot_functor<T_functor, void, T_type1,T_type2,T_type3,T_type4,T_type5,T_type6,T_type7>::operator()()
+  { this->functor_(); }
+
+
+template <class T_action, class T_functor, class T_return, class T_type1,class T_type2,class T_type3,class T_type4,class T_type5,class T_type6,class T_type7>
+void visit_each(const T_action& _A_action,
+                const retype_slot_functor<T_functor, T_return, T_type1,T_type2,T_type3,T_type4,T_type5,T_type6,T_type7>& _A_target)
+{
+  visit_each(_A_action, _A_target.functor_);
+}
+
+
+template <class T_return, class T_ret>
+inline Slot0<T_return>
+retype(const Slot0<T_ret>& _A_slot)
+{ return Slot0<T_return>
+    (retype_slot_functor<Slot0<T_ret>, T_return>
+      (_A_slot)); }
+
+template <class T_return, class T_arg1, class T_ret, class T_type1>
+inline Slot1<T_return, T_arg1>
+retype(const Slot1<T_ret, T_type1>& _A_slot)
+{ return Slot1<T_return, T_arg1>
+    (retype_slot_functor<Slot1<T_ret, T_type1>, T_return, T_type1>
+      (_A_slot)); }
+
+template <class T_return, class T_arg1,class T_arg2, class T_ret, class T_type1,class T_type2>
+inline Slot2<T_return, T_arg1,T_arg2>
+retype(const Slot2<T_ret, T_type1,T_type2>& _A_slot)
+{ return Slot2<T_return, T_arg1,T_arg2>
+    (retype_slot_functor<Slot2<T_ret, T_type1, T_type2>, T_return, T_type1,T_type2>
+      (_A_slot)); }
+
+template <class T_return, class T_arg1,class T_arg2,class T_arg3, class T_ret, class T_type1,class T_type2,class T_type3>
+inline Slot3<T_return, T_arg1,T_arg2,T_arg3>
+retype(const Slot3<T_ret, T_type1,T_type2,T_type3>& _A_slot)
+{ return Slot3<T_return, T_arg1,T_arg2,T_arg3>
+    (retype_slot_functor<Slot3<T_ret, T_type1, T_type2, T_type3>, T_return, T_type1,T_type2,T_type3>
+      (_A_slot)); }
+
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_ret, class T_type1,class T_type2,class T_type3,class T_type4>
+inline Slot4<T_return, T_arg1,T_arg2,T_arg3,T_arg4>
+retype(const Slot4<T_ret, T_type1,T_type2,T_type3,T_type4>& _A_slot)
+{ return Slot4<T_return, T_arg1,T_arg2,T_arg3,T_arg4>
+    (retype_slot_functor<Slot4<T_ret, T_type1, T_type2, T_type3, T_type4>, T_return, T_type1,T_type2,T_type3,T_type4>
+      (_A_slot)); }
+
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_ret, class T_type1,class T_type2,class T_type3,class T_type4,class T_type5>
+inline Slot5<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+retype(const Slot5<T_ret, T_type1,T_type2,T_type3,T_type4,T_type5>& _A_slot)
+{ return Slot5<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+    (retype_slot_functor<Slot5<T_ret, T_type1, T_type2, T_type3, T_type4, T_type5>, T_return, T_type1,T_type2,T_type3,T_type4,T_type5>
+      (_A_slot)); }
+
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_ret, class T_type1,class T_type2,class T_type3,class T_type4,class T_type5,class T_type6>
+inline Slot6<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+retype(const Slot6<T_ret, T_type1,T_type2,T_type3,T_type4,T_type5,T_type6>& _A_slot)
+{ return Slot6<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+    (retype_slot_functor<Slot6<T_ret, T_type1, T_type2, T_type3, T_type4, T_type5, T_type6>, T_return, T_type1,T_type2,T_type3,T_type4,T_type5,T_type6>
+      (_A_slot)); }
+
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_ret, class T_type1,class T_type2,class T_type3,class T_type4,class T_type5,class T_type6,class T_type7>
+inline Slot7<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+retype(const Slot7<T_ret, T_type1,T_type2,T_type3,T_type4,T_type5,T_type6,T_type7>& _A_slot)
+{ return Slot7<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+    (retype_slot_functor<Slot7<T_ret, T_type1, T_type2, T_type3, T_type4, T_type5, T_type6, T_type7>, T_return, T_type1,T_type2,T_type3,T_type4,T_type5,T_type6,T_type7>
+      (_A_slot)); }
+
+
+} /* namespace SigC */
+
+#endif /* LIBSIGC_DISABLE_DEPRECATED */
+#endif /* _SIGC_MACROS_RETYPEHM4_ */
diff --git a/libs/sigc++2/sigc++/retype_return.h b/libs/sigc++2/sigc++/retype_return.h
new file mode 100644
index 0000000000..cc6c153394
--- /dev/null
+++ b/libs/sigc++2/sigc++/retype_return.h
@@ -0,0 +1,35 @@
+/*
+ * Copyright 2002, The libsigc++ Development Team
+ *
+ *  This library is free software; you can redistribute it and/or
+ *  modify it under the terms of the GNU Lesser General Public
+ *  License as published by the Free Software Foundation; either
+ *  version 2.1 of the License, or (at your option) any later version.
+ *
+ *  This library is distributed in the hope that it will be useful,
+ *  but WITHOUT ANY WARRANTY; without even the implied warranty of
+ *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
+ *  Lesser General Public License for more details.
+ *
+ *  You should have received a copy of the GNU Lesser General Public
+ *  License along with this library; if not, write to the Free Software
+ *  Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
+ *
+ */
+#ifndef _SIGC_RETYPE_RETURN_HPP_
+#define _SIGC_RETYPE_RETURN_HPP_
+
+#include <sigc++/adaptors/retype_return.h>
+
+#ifndef LIBSIGC_DISABLE_DEPRECATED
+
+namespace SigC {
+
+using ::sigc::retype_return;
+using ::sigc::hide_return;
+
+}
+
+#endif /* LIBSIGC_DISABLE_DEPRECATED */
+
+#endif /* _SIGC_RETYPE_RETURN_HPP_ */
diff --git a/libs/sigc++2/sigc++/sigc++.h b/libs/sigc++2/sigc++/sigc++.h
new file mode 100644
index 0000000000..90a9e6dd17
--- /dev/null
+++ b/libs/sigc++2/sigc++/sigc++.h
@@ -0,0 +1,30 @@
+/*
+ * Copyright 2003, The libsigc++ Development Team
+ *
+ *  This library is free software; you can redistribute it and/or
+ *  modify it under the terms of the GNU Lesser General Public
+ *  License as published by the Free Software Foundation; either
+ *  version 2.1 of the License, or (at your option) any later version.
+ *
+ *  This library is distributed in the hope that it will be useful,
+ *  but WITHOUT ANY WARRANTY; without even the implied warranty of
+ *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
+ *  Lesser General Public License for more details.
+ *
+ *  You should have received a copy of the GNU Lesser General Public
+ *  License along with this library; if not, write to the Free Software
+ *  Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
+ *
+ */
+
+#ifndef SIGCXX_SIGCXX_H
+#define SIGCXX_SIGCXX_H
+
+#include <sigc++/signal.h>
+#include <sigc++/connection.h>
+#include <sigc++/trackable.h>
+#include <sigc++/adaptors/adaptors.h>
+#include <sigc++/functors/functors.h>
+
+#endif /* SIGCXX_SIGCXX_H */
+
diff --git a/libs/sigc++2/sigc++/signal.cc b/libs/sigc++2/sigc++/signal.cc
new file mode 100644
index 0000000000..993eee4aca
--- /dev/null
+++ b/libs/sigc++2/sigc++/signal.cc
@@ -0,0 +1,25 @@
+// -*- c++ -*-
+/*
+ * Copyright 2002, The libsigc++ Development Team
+ *
+ *  This library is free software; you can redistribute it and/or
+ *  modify it under the terms of the GNU Lesser General Public
+ *  License as published by the Free Software Foundation; either
+ *  version 2.1 of the License, or (at your option) any later version.
+ *
+ *  This library is distributed in the hope that it will be useful,
+ *  but WITHOUT ANY WARRANTY; without even the implied warranty of
+ *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
+ *  Lesser General Public License for more details.
+ *
+ *  You should have received a copy of the GNU Lesser General Public
+ *  License along with this library; if not, write to the Free Software
+ *  Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
+ *
+ */
+#include <sigc++/signal.h>
+
+namespace sigc {
+
+
+} /* sigc */
diff --git a/libs/sigc++2/sigc++/signal.h b/libs/sigc++2/sigc++/signal.h
new file mode 100644
index 0000000000..a89112cf9e
--- /dev/null
+++ b/libs/sigc++2/sigc++/signal.h
@@ -0,0 +1,3188 @@
+// -*- c++ -*-
+/* Do not edit! -- generated file */
+
+#ifndef _SIGC_SIGNAL_H_
+#define _SIGC_SIGNAL_H_
+
+#include <list>
+#include <sigc++/signal_base.h>
+#include <sigc++/type_traits.h>
+#include <sigc++/trackable.h>
+#include <sigc++/functors/slot.h>
+#include <sigc++/functors/mem_fun.h>
+
+// TODO: This should have its own test.
+// I have just used this because there is a correlation between these two problems.
+#ifdef SIGC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+  //Compilers, such as SUN Forte C++, that do not allow this also often
+  //do not allow a typedef to have the same name as a class in the typedef's definition.
+  #define SIGC_TYPEDEF_REDEFINE_ALLOWED 1
+#endif
+
+namespace sigc {
+
+/** STL-style iterator for slot_list.
+ *
+ * @ingroup signal
+ */
+template <typename T_slot>
+struct slot_iterator
+{
+  typedef size_t                          size_type;
+  typedef ptrdiff_t                       difference_type;
+  typedef std::bidirectional_iterator_tag iterator_category;
+
+  typedef T_slot  slot_type;
+
+  typedef T_slot  value_type;
+  typedef T_slot* pointer;
+  typedef T_slot& reference;
+
+  typedef typename internal::signal_impl::iterator_type iterator_type;
+
+  slot_iterator()
+    {}
+
+  explicit slot_iterator(const iterator_type& i)
+    : i_(i) {}
+
+  reference operator*() const
+    { return static_cast<reference>(*i_); }
+
+  pointer operator->() const
+    { return &(operator*()); }
+
+  slot_iterator& operator++()
+    {
+      ++i_;
+      return *this;
+    }
+
+  slot_iterator operator++(int)
+    { 
+      slot_iterator __tmp(*this);
+      ++i_;
+      return __tmp;
+    }
+
+  slot_iterator& operator--()
+    {
+      --i_;
+      return *this;
+    }
+
+  slot_iterator& operator--(int)
+    {
+      slot_iterator __tmp(*this);
+      --i_;
+      return __tmp;
+    }
+
+  bool operator == (const slot_iterator& other) const
+    { return i_ == other.i_; }
+
+  bool operator != (const slot_iterator& other) const
+    { return i_ != other.i_; }
+
+  iterator_type i_;
+};
+
+/** STL-style const iterator for slot_list.
+ *
+ * @ingroup signal
+ */
+template <typename T_slot>
+struct slot_const_iterator
+{
+  typedef size_t                          size_type;
+  typedef ptrdiff_t                       difference_type;
+  typedef std::bidirectional_iterator_tag iterator_category;
+
+  typedef T_slot        slot_type;
+
+  typedef T_slot        value_type;
+  typedef const T_slot* pointer;
+  typedef const T_slot& reference;
+
+  typedef typename internal::signal_impl::const_iterator_type iterator_type;
+
+  slot_const_iterator()
+    {}
+
+  explicit slot_const_iterator(const iterator_type& i)
+    : i_(i) {}
+
+  reference operator*() const
+    { return static_cast<reference>(*i_); }
+
+  pointer operator->() const
+    { return &(operator*()); }
+
+  slot_const_iterator& operator++()
+    {
+      ++i_;
+      return *this;
+    }
+
+  slot_const_iterator operator++(int)
+    { 
+      slot_const_iterator __tmp(*this);
+      ++i_;
+      return __tmp;
+    }
+
+  slot_const_iterator& operator--()
+    {
+      --i_;
+      return *this;
+    }
+
+  slot_const_iterator& operator--(int)
+    {
+      slot_const_iterator __tmp(*this);
+      --i_;
+      return __tmp;
+    }
+
+  bool operator == (const slot_const_iterator& other) const
+    { return i_ == other.i_; }
+
+  bool operator != (const slot_const_iterator& other) const
+    { return i_ != other.i_; }
+
+  iterator_type i_;
+};
+
+/** STL-style list interface for sigc::signal#.
+ * slot_list can be used to iterate over the list of slots that
+ * is managed by a signal. Slots can be added or removed from
+ * the list while existing iterators stay valid. A slot_list
+ * object can be retrieved from the signal's slots() function.
+ *
+ * @ingroup signal
+ */
+template <class T_slot>
+struct slot_list
+{
+  typedef T_slot slot_type;
+
+  typedef slot_type&       reference;
+  typedef const slot_type& const_reference;
+
+  typedef slot_iterator<slot_type>              iterator;
+  typedef slot_const_iterator<slot_type>        const_iterator;
+  typedef std::reverse_iterator<iterator>       reverse_iterator;
+  typedef std::reverse_iterator<const_iterator> const_reverse_iterator;
+
+  slot_list()
+    : list_(0) {}
+
+  explicit slot_list(internal::signal_impl* __list)
+    : list_(__list) {}
+
+  iterator begin()
+    { return iterator(list_->slots_.begin()); }
+
+  const_iterator begin() const
+    { return const_iterator(list_->slots_.begin()); }
+
+  iterator end()
+    { return iterator(list_->slots_.end()); }
+
+  const_iterator end() const
+    { return const_iterator(list_->slots_.end()); }
+
+  reverse_iterator rbegin() 
+    { return reverse_iterator(end()); }
+
+  const_reverse_iterator rbegin() const 
+    { return const_reverse_iterator(end()); }
+
+  reverse_iterator rend()
+    { return reverse_iterator(begin()); }
+
+  const_reverse_iterator rend() const
+    { return const_reverse_iterator(begin()); }
+
+  reference front()
+    { return *begin(); }
+
+  const_reference front() const
+    { return *begin(); }
+
+  reference back()
+    { return *(--end()); }
+
+  const_reference back() const
+    { return *(--end()); }
+
+  iterator insert(iterator i, const slot_type& slot_)
+    { return iterator(list_->insert(i.i_, static_cast<const slot_base&>(slot_))); }
+
+  void push_front(const slot_type& c)
+    { insert(begin(), c); }
+
+  void push_back(const slot_type& c)
+    { insert(end(), c); }
+
+  iterator erase(iterator i)
+    { return iterator(list_->erase(i.i_)); }
+
+  iterator erase(iterator first_, iterator last_)
+    {
+      while (first_ != last_)
+        first_ = erase(first_);
+      return last_;
+    }
+
+  void pop_front()
+    { erase(begin()); }
+
+  void pop_back()
+    { 
+      iterator tmp_ = end();
+      erase(--tmp_);
+    }
+
+protected:
+  internal::signal_impl* list_;
+};
+
+
+namespace internal {
+
+/** Special iterator over sigc::internal::signal_impl's slot list that holds extra data.
+ * This iterators is for use in accumulators. operator*() executes
+ * the slot. The return value is buffered, so that in an expression
+ * like @code a = (*i) * (*i); @endcode the slot is executed only once.
+ */
+template <class T_emitter, class T_result = typename T_emitter::result_type>
+struct slot_iterator_buf
+{
+  typedef size_t                           size_type;
+  typedef ptrdiff_t                        difference_type;
+  typedef std::bidirectional_iterator_tag  iterator_category;
+
+  typedef T_emitter                        emitter_type;
+  typedef T_result                         result_type;
+  typedef typename T_emitter::slot_type    slot_type;
+
+  typedef signal_impl::const_iterator_type iterator_type;
+
+  slot_iterator_buf()
+    : c_(0), invoked_(false) {}
+
+  slot_iterator_buf(const iterator_type& i, const emitter_type* c)
+    : i_(i), c_(c), invoked_(false) {}
+
+  result_type operator*() const
+    {
+      if (!i_->empty() && !i_->blocked() && !invoked_)
+        {
+          r_ = (*c_)(static_cast<const slot_type&>(*i_));
+          invoked_ = true;
+        }
+      return r_;
+    }
+
+  slot_iterator_buf& operator++()
+    {
+      ++i_;
+      invoked_ = false;
+      return *this;
+    }
+
+  slot_iterator_buf operator++(int)
+    { 
+      slot_iterator_buf __tmp(*this);
+      ++i_;
+      invoked_ = false;
+      return __tmp;
+    }
+
+  slot_iterator_buf& operator--()
+    {
+      --i_;
+      invoked_ = false;
+      return *this;
+    }
+
+  slot_iterator_buf& operator--(int)
+    {
+      slot_iterator_buf __tmp(*this);
+      --i_;
+      invoked_ = false;
+      return __tmp;
+    }
+
+  bool operator == (const slot_iterator_buf& other) const
+    { return (!c_ || (i_ == other.i_)); } /* If '!c_' the iterators are empty.
+                                           * Unfortunately, empty stl iterators are not equal.
+                                           * We are forcing equality so that 'first==last'
+                                           * in the accumulator's emit function yields true. */
+
+  bool operator != (const slot_iterator_buf& other) const
+    { return (c_ && (i_ != other.i_)); }
+
+private:
+  iterator_type i_;
+  const emitter_type* c_;
+  mutable result_type r_;
+  mutable bool invoked_;
+};
+
+/** Template specialization of slot_iterator_buf for void return signals.
+ */
+template <class T_emitter>
+struct slot_iterator_buf<T_emitter, void>
+{
+  typedef size_t                           size_type;
+  typedef ptrdiff_t                        difference_type;
+  typedef std::bidirectional_iterator_tag  iterator_category;
+
+  typedef T_emitter                        emitter_type;
+  typedef void                             result_type;
+  typedef typename T_emitter::slot_type    slot_type;
+
+  typedef signal_impl::const_iterator_type iterator_type;
+
+  slot_iterator_buf()
+    : c_(0), invoked_(false) {}
+
+  slot_iterator_buf(const iterator_type& i, const emitter_type* c)
+    : i_(i), c_(c), invoked_(false) {}
+
+  void operator*() const
+    {
+      if (!i_->empty() && !i_->blocked() && !invoked_)
+        {
+          (*c_)(static_cast<const slot_type&>(*i_));
+          invoked_ = true;
+        }
+    }
+
+  slot_iterator_buf& operator++()
+    {
+      ++i_;
+      invoked_ = false;
+      return *this;
+    }
+
+  slot_iterator_buf operator++(int)
+    { 
+      slot_iterator_buf __tmp(*this);
+      ++i_;
+      invoked_ = false;
+      return __tmp;
+    }
+
+  slot_iterator_buf& operator--()
+    {
+      --i_;
+      invoked_ = false;
+      return *this;
+    }
+
+  slot_iterator_buf& operator--(int)
+    {
+      slot_iterator_buf __tmp(*this);
+      --i_;
+      invoked_ = false;
+      return __tmp;
+    }
+
+  bool operator == (const slot_iterator_buf& other) const
+    { return i_ == other.i_; }
+
+  bool operator != (const slot_iterator_buf& other) const
+    { return i_ != other.i_; }
+
+private:
+  iterator_type i_;
+  const emitter_type* c_;
+  mutable bool invoked_;
+};
+
+/** Abstracts signal emission.
+ * This template implements the emit() function of signal0.
+ * Template specializations are available to optimize signal
+ * emission when no accumulator is used, i.e. the template
+ * argument @e T_accumulator is @p nil.
+ */
+template <class T_return, class T_accumulator>
+struct signal_emit0
+{
+  typedef signal_emit0<T_return, T_accumulator> self_type;
+  typedef typename T_accumulator::result_type result_type;
+  typedef slot<T_return> slot_type;
+  typedef internal::slot_iterator_buf<self_type> slot_iterator_buf_type;
+  typedef signal_impl::const_iterator_type iterator_type;
+
+  signal_emit0()  {}
+
+  /** Invokes a slot.
+   * @param _A_slot Some slot to invoke.
+   * @return The slot's return value.
+   */
+  T_return operator()(const slot_type& _A_slot) const
+    { return (reinterpret_cast<typename slot_type::call_type>(_A_slot.rep_->call_))(_A_slot.rep_); }
+
+  /** Executes a list of slots using an accumulator of type @e T_accumulator.
+
+   * @return The accumulated return values of the slot invocations as processed by the accumulator.
+   */
+  static result_type emit(signal_impl* impl)
+    {
+      T_accumulator accumulator;
+
+      if (!impl)
+        return accumulator(slot_iterator_buf_type(), slot_iterator_buf_type());
+
+      signal_exec exec(impl);
+
+      self_type self ;
+      return accumulator(slot_iterator_buf_type(impl->slots_.begin(), &self),
+                         slot_iterator_buf_type(impl->slots_.end(), &self));
+    }
+  
+};
+
+/** Abstracts signal emission.
+ * This template specialization implements an optimized emit()
+ * function for the case that no accumulator is used.
+ */
+template <class T_return>
+struct signal_emit0<T_return, nil>
+{
+  typedef signal_emit0<T_return, nil > self_type;
+  typedef T_return result_type;
+  typedef slot<T_return> slot_type;
+  typedef signal_impl::const_iterator_type iterator_type;
+  typedef typename slot_type::call_type call_type;
+
+  /** Executes a list of slots using an accumulator of type @e T_accumulator.
+   * The return value of the last slot invoked is returned.
+   * @param first An iterator pointing to the first slot in the list.
+   * @param last An iterator pointing to the last slot in the list.
+   * @return The return value of the last slot invoked.
+   */
+  static result_type emit(signal_impl* impl)
+    {
+      if (!impl || impl->slots_.empty()) return T_return();
+      iterator_type it = impl->slots_.begin();
+      for (; it != impl->slots_.end(); ++it)
+        if (!it->empty() && !it->blocked()) break;
+      if (it == impl->slots_.end()) return T_return(); // note that 'T_return r_();' doesn't work => define 'r_' after this line and initialize as follows:
+
+      signal_exec exec(impl);
+
+      T_return r_ = (reinterpret_cast<call_type>(it->rep_->call_))(it->rep_);
+      for (++it; it != impl->slots_.end(); ++it)
+        {
+          if (it->empty() || it->blocked())
+            continue;
+          r_ = (reinterpret_cast<call_type>(it->rep_->call_))(it->rep_);
+        }
+      return r_;
+    }
+};
+
+/** Abstracts signal emission.
+ * This template specialization implements an optimized emit()
+ * function for the case that no accumulator is used and the
+ * return type is @p void.
+ */
+template <>
+struct signal_emit0<void, nil>
+{
+  typedef signal_emit0<void, nil> self_type;
+  typedef void result_type;
+  typedef slot<void> slot_type;
+  typedef signal_impl::const_iterator_type iterator_type;
+  typedef void (*call_type)(slot_rep*);
+
+  /** Executes a list of slots using an accumulator of type @e T_accumulator.
+   * @param first An iterator pointing to the first slot in the list.
+   * @param last An iterator pointing to the last slot in the list.
+   */
+  static result_type emit(signal_impl* impl)
+    {
+      if (!impl || impl->slots_.empty()) return;
+      signal_exec exec(impl);
+
+      for (iterator_type it = impl->slots_.begin(); it != impl->slots_.end(); ++it)
+        {
+          if (it->empty() || it->blocked())
+            continue;
+          (reinterpret_cast<call_type>(it->rep_->call_))(it->rep_);
+        }
+    }
+};
+
+/** Abstracts signal emission.
+ * This template implements the emit() function of signal1.
+ * Template specializations are available to optimize signal
+ * emission when no accumulator is used, i.e. the template
+ * argument @e T_accumulator is @p nil.
+ */
+template <class T_return, class T_arg1, class T_accumulator>
+struct signal_emit1
+{
+  typedef signal_emit1<T_return, T_arg1, T_accumulator> self_type;
+  typedef typename T_accumulator::result_type result_type;
+  typedef slot<T_return, T_arg1> slot_type;
+  typedef internal::slot_iterator_buf<self_type> slot_iterator_buf_type;
+  typedef signal_impl::const_iterator_type iterator_type;
+
+  /** Instantiates the class.
+   * The parameters are stored in member variables. operator()() passes
+   * the values on to some slot.
+   */
+  signal_emit1(typename type_trait<T_arg1>::take _A_a1) 
+    : _A_a1_(_A_a1) {}
+
+
+  /** Invokes a slot using the buffered parameter values.
+   * @param _A_slot Some slot to invoke.
+   * @return The slot's return value.
+   */
+  T_return operator()(const slot_type& _A_slot) const
+    { return (reinterpret_cast<typename slot_type::call_type>(_A_slot.rep_->call_))(_A_slot.rep_, _A_a1_); }
+
+  /** Executes a list of slots using an accumulator of type @e T_accumulator.
+   * The arguments are buffered in a temporary instance of signal_emit1.
+
+   * @param _A_a1 Argument to be passed on to the slots.
+   * @return The accumulated return values of the slot invocations as processed by the accumulator.
+   */
+  static result_type emit(signal_impl* impl, typename type_trait<T_arg1>::take _A_a1)
+    {
+      T_accumulator accumulator;
+
+      if (!impl)
+        return accumulator(slot_iterator_buf_type(), slot_iterator_buf_type());
+
+      signal_exec exec(impl);
+
+      self_type self (_A_a1);
+      return accumulator(slot_iterator_buf_type(impl->slots_.begin(), &self),
+                         slot_iterator_buf_type(impl->slots_.end(), &self));
+    }
+  
+  typename type_trait<T_arg1>::take _A_a1_;
+};
+
+/** Abstracts signal emission.
+ * This template specialization implements an optimized emit()
+ * function for the case that no accumulator is used.
+ */
+template <class T_return, class T_arg1>
+struct signal_emit1<T_return, T_arg1, nil>
+{
+  typedef signal_emit1<T_return, T_arg1, nil > self_type;
+  typedef T_return result_type;
+  typedef slot<T_return, T_arg1> slot_type;
+  typedef signal_impl::const_iterator_type iterator_type;
+  typedef typename slot_type::call_type call_type;
+
+  /** Executes a list of slots using an accumulator of type @e T_accumulator.
+   * The arguments are passed directly on to the slots.
+   * The return value of the last slot invoked is returned.
+   * @param first An iterator pointing to the first slot in the list.
+   * @param last An iterator pointing to the last slot in the list.
+   * @param _A_a1 Argument to be passed on to the slots.
+   * @return The return value of the last slot invoked.
+   */
+  static result_type emit(signal_impl* impl, typename type_trait<T_arg1>::take _A_a1)
+    {
+      if (!impl || impl->slots_.empty()) return T_return();
+      iterator_type it = impl->slots_.begin();
+      for (; it != impl->slots_.end(); ++it)
+        if (!it->empty() && !it->blocked()) break;
+      if (it == impl->slots_.end()) return T_return(); // note that 'T_return r_();' doesn't work => define 'r_' after this line and initialize as follows:
+
+      signal_exec exec(impl);
+
+      T_return r_ = (reinterpret_cast<call_type>(it->rep_->call_))(it->rep_, _A_a1);
+      for (++it; it != impl->slots_.end(); ++it)
+        {
+          if (it->empty() || it->blocked())
+            continue;
+          r_ = (reinterpret_cast<call_type>(it->rep_->call_))(it->rep_, _A_a1);
+        }
+      return r_;
+    }
+};
+
+/** Abstracts signal emission.
+ * This template specialization implements an optimized emit()
+ * function for the case that no accumulator is used and the
+ * return type is @p void.
+ */
+template <class T_arg1>
+struct signal_emit1<void, T_arg1, nil>
+{
+  typedef signal_emit1<void, T_arg1, nil> self_type;
+  typedef void result_type;
+  typedef slot<void, T_arg1> slot_type;
+  typedef signal_impl::const_iterator_type iterator_type;
+  typedef typename slot_type::call_type call_type;
+
+  /** Executes a list of slots using an accumulator of type @e T_accumulator.
+   * The arguments are passed directly on to the slots.
+   * @param first An iterator pointing to the first slot in the list.
+   * @param last An iterator pointing to the last slot in the list.
+   * @param _A_a1 Argument to be passed on to the slots.
+   */
+  static result_type emit(signal_impl* impl, typename type_trait<T_arg1>::take _A_a1)
+    {
+      if (!impl || impl->slots_.empty()) return;
+      signal_exec exec(impl);
+
+      for (iterator_type it = impl->slots_.begin(); it != impl->slots_.end(); ++it)
+        {
+          if (it->empty() || it->blocked())
+            continue;
+          (reinterpret_cast<call_type>(it->rep_->call_))(it->rep_, _A_a1);
+        }
+    }
+};
+
+/** Abstracts signal emission.
+ * This template implements the emit() function of signal2.
+ * Template specializations are available to optimize signal
+ * emission when no accumulator is used, i.e. the template
+ * argument @e T_accumulator is @p nil.
+ */
+template <class T_return, class T_arg1,class T_arg2, class T_accumulator>
+struct signal_emit2
+{
+  typedef signal_emit2<T_return, T_arg1,T_arg2, T_accumulator> self_type;
+  typedef typename T_accumulator::result_type result_type;
+  typedef slot<T_return, T_arg1,T_arg2> slot_type;
+  typedef internal::slot_iterator_buf<self_type> slot_iterator_buf_type;
+  typedef signal_impl::const_iterator_type iterator_type;
+
+  /** Instantiates the class.
+   * The parameters are stored in member variables. operator()() passes
+   * the values on to some slot.
+   */
+  signal_emit2(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2) 
+    : _A_a1_(_A_a1),_A_a2_(_A_a2) {}
+
+
+  /** Invokes a slot using the buffered parameter values.
+   * @param _A_slot Some slot to invoke.
+   * @return The slot's return value.
+   */
+  T_return operator()(const slot_type& _A_slot) const
+    { return (reinterpret_cast<typename slot_type::call_type>(_A_slot.rep_->call_))(_A_slot.rep_, _A_a1_,_A_a2_); }
+
+  /** Executes a list of slots using an accumulator of type @e T_accumulator.
+   * The arguments are buffered in a temporary instance of signal_emit2.
+
+   * @param _A_a1 Argument to be passed on to the slots.
+   * @param _A_a2 Argument to be passed on to the slots.
+   * @return The accumulated return values of the slot invocations as processed by the accumulator.
+   */
+  static result_type emit(signal_impl* impl, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2)
+    {
+      T_accumulator accumulator;
+
+      if (!impl)
+        return accumulator(slot_iterator_buf_type(), slot_iterator_buf_type());
+
+      signal_exec exec(impl);
+
+      self_type self (_A_a1,_A_a2);
+      return accumulator(slot_iterator_buf_type(impl->slots_.begin(), &self),
+                         slot_iterator_buf_type(impl->slots_.end(), &self));
+    }
+  
+  typename type_trait<T_arg1>::take _A_a1_;
+  typename type_trait<T_arg2>::take _A_a2_;
+};
+
+/** Abstracts signal emission.
+ * This template specialization implements an optimized emit()
+ * function for the case that no accumulator is used.
+ */
+template <class T_return, class T_arg1,class T_arg2>
+struct signal_emit2<T_return, T_arg1,T_arg2, nil>
+{
+  typedef signal_emit2<T_return, T_arg1,T_arg2, nil > self_type;
+  typedef T_return result_type;
+  typedef slot<T_return, T_arg1,T_arg2> slot_type;
+  typedef signal_impl::const_iterator_type iterator_type;
+  typedef typename slot_type::call_type call_type;
+
+  /** Executes a list of slots using an accumulator of type @e T_accumulator.
+   * The arguments are passed directly on to the slots.
+   * The return value of the last slot invoked is returned.
+   * @param first An iterator pointing to the first slot in the list.
+   * @param last An iterator pointing to the last slot in the list.
+   * @param _A_a1 Argument to be passed on to the slots.
+   * @param _A_a2 Argument to be passed on to the slots.
+   * @return The return value of the last slot invoked.
+   */
+  static result_type emit(signal_impl* impl, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2)
+    {
+      if (!impl || impl->slots_.empty()) return T_return();
+      iterator_type it = impl->slots_.begin();
+      for (; it != impl->slots_.end(); ++it)
+        if (!it->empty() && !it->blocked()) break;
+      if (it == impl->slots_.end()) return T_return(); // note that 'T_return r_();' doesn't work => define 'r_' after this line and initialize as follows:
+
+      signal_exec exec(impl);
+
+      T_return r_ = (reinterpret_cast<call_type>(it->rep_->call_))(it->rep_, _A_a1,_A_a2);
+      for (++it; it != impl->slots_.end(); ++it)
+        {
+          if (it->empty() || it->blocked())
+            continue;
+          r_ = (reinterpret_cast<call_type>(it->rep_->call_))(it->rep_, _A_a1,_A_a2);
+        }
+      return r_;
+    }
+};
+
+/** Abstracts signal emission.
+ * This template specialization implements an optimized emit()
+ * function for the case that no accumulator is used and the
+ * return type is @p void.
+ */
+template <class T_arg1,class T_arg2>
+struct signal_emit2<void, T_arg1,T_arg2, nil>
+{
+  typedef signal_emit2<void, T_arg1,T_arg2, nil> self_type;
+  typedef void result_type;
+  typedef slot<void, T_arg1,T_arg2> slot_type;
+  typedef signal_impl::const_iterator_type iterator_type;
+  typedef typename slot_type::call_type call_type;
+
+  /** Executes a list of slots using an accumulator of type @e T_accumulator.
+   * The arguments are passed directly on to the slots.
+   * @param first An iterator pointing to the first slot in the list.
+   * @param last An iterator pointing to the last slot in the list.
+   * @param _A_a1 Argument to be passed on to the slots.
+   * @param _A_a2 Argument to be passed on to the slots.
+   */
+  static result_type emit(signal_impl* impl, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2)
+    {
+      if (!impl || impl->slots_.empty()) return;
+      signal_exec exec(impl);
+
+      for (iterator_type it = impl->slots_.begin(); it != impl->slots_.end(); ++it)
+        {
+          if (it->empty() || it->blocked())
+            continue;
+          (reinterpret_cast<call_type>(it->rep_->call_))(it->rep_, _A_a1,_A_a2);
+        }
+    }
+};
+
+/** Abstracts signal emission.
+ * This template implements the emit() function of signal3.
+ * Template specializations are available to optimize signal
+ * emission when no accumulator is used, i.e. the template
+ * argument @e T_accumulator is @p nil.
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3, class T_accumulator>
+struct signal_emit3
+{
+  typedef signal_emit3<T_return, T_arg1,T_arg2,T_arg3, T_accumulator> self_type;
+  typedef typename T_accumulator::result_type result_type;
+  typedef slot<T_return, T_arg1,T_arg2,T_arg3> slot_type;
+  typedef internal::slot_iterator_buf<self_type> slot_iterator_buf_type;
+  typedef signal_impl::const_iterator_type iterator_type;
+
+  /** Instantiates the class.
+   * The parameters are stored in member variables. operator()() passes
+   * the values on to some slot.
+   */
+  signal_emit3(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3) 
+    : _A_a1_(_A_a1),_A_a2_(_A_a2),_A_a3_(_A_a3) {}
+
+
+  /** Invokes a slot using the buffered parameter values.
+   * @param _A_slot Some slot to invoke.
+   * @return The slot's return value.
+   */
+  T_return operator()(const slot_type& _A_slot) const
+    { return (reinterpret_cast<typename slot_type::call_type>(_A_slot.rep_->call_))(_A_slot.rep_, _A_a1_,_A_a2_,_A_a3_); }
+
+  /** Executes a list of slots using an accumulator of type @e T_accumulator.
+   * The arguments are buffered in a temporary instance of signal_emit3.
+
+   * @param _A_a1 Argument to be passed on to the slots.
+   * @param _A_a2 Argument to be passed on to the slots.
+   * @param _A_a3 Argument to be passed on to the slots.
+   * @return The accumulated return values of the slot invocations as processed by the accumulator.
+   */
+  static result_type emit(signal_impl* impl, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3)
+    {
+      T_accumulator accumulator;
+
+      if (!impl)
+        return accumulator(slot_iterator_buf_type(), slot_iterator_buf_type());
+
+      signal_exec exec(impl);
+
+      self_type self (_A_a1,_A_a2,_A_a3);
+      return accumulator(slot_iterator_buf_type(impl->slots_.begin(), &self),
+                         slot_iterator_buf_type(impl->slots_.end(), &self));
+    }
+  
+  typename type_trait<T_arg1>::take _A_a1_;
+  typename type_trait<T_arg2>::take _A_a2_;
+  typename type_trait<T_arg3>::take _A_a3_;
+};
+
+/** Abstracts signal emission.
+ * This template specialization implements an optimized emit()
+ * function for the case that no accumulator is used.
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3>
+struct signal_emit3<T_return, T_arg1,T_arg2,T_arg3, nil>
+{
+  typedef signal_emit3<T_return, T_arg1,T_arg2,T_arg3, nil > self_type;
+  typedef T_return result_type;
+  typedef slot<T_return, T_arg1,T_arg2,T_arg3> slot_type;
+  typedef signal_impl::const_iterator_type iterator_type;
+  typedef typename slot_type::call_type call_type;
+
+  /** Executes a list of slots using an accumulator of type @e T_accumulator.
+   * The arguments are passed directly on to the slots.
+   * The return value of the last slot invoked is returned.
+   * @param first An iterator pointing to the first slot in the list.
+   * @param last An iterator pointing to the last slot in the list.
+   * @param _A_a1 Argument to be passed on to the slots.
+   * @param _A_a2 Argument to be passed on to the slots.
+   * @param _A_a3 Argument to be passed on to the slots.
+   * @return The return value of the last slot invoked.
+   */
+  static result_type emit(signal_impl* impl, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3)
+    {
+      if (!impl || impl->slots_.empty()) return T_return();
+      iterator_type it = impl->slots_.begin();
+      for (; it != impl->slots_.end(); ++it)
+        if (!it->empty() && !it->blocked()) break;
+      if (it == impl->slots_.end()) return T_return(); // note that 'T_return r_();' doesn't work => define 'r_' after this line and initialize as follows:
+
+      signal_exec exec(impl);
+
+      T_return r_ = (reinterpret_cast<call_type>(it->rep_->call_))(it->rep_, _A_a1,_A_a2,_A_a3);
+      for (++it; it != impl->slots_.end(); ++it)
+        {
+          if (it->empty() || it->blocked())
+            continue;
+          r_ = (reinterpret_cast<call_type>(it->rep_->call_))(it->rep_, _A_a1,_A_a2,_A_a3);
+        }
+      return r_;
+    }
+};
+
+/** Abstracts signal emission.
+ * This template specialization implements an optimized emit()
+ * function for the case that no accumulator is used and the
+ * return type is @p void.
+ */
+template <class T_arg1,class T_arg2,class T_arg3>
+struct signal_emit3<void, T_arg1,T_arg2,T_arg3, nil>
+{
+  typedef signal_emit3<void, T_arg1,T_arg2,T_arg3, nil> self_type;
+  typedef void result_type;
+  typedef slot<void, T_arg1,T_arg2,T_arg3> slot_type;
+  typedef signal_impl::const_iterator_type iterator_type;
+  typedef typename slot_type::call_type call_type;
+
+  /** Executes a list of slots using an accumulator of type @e T_accumulator.
+   * The arguments are passed directly on to the slots.
+   * @param first An iterator pointing to the first slot in the list.
+   * @param last An iterator pointing to the last slot in the list.
+   * @param _A_a1 Argument to be passed on to the slots.
+   * @param _A_a2 Argument to be passed on to the slots.
+   * @param _A_a3 Argument to be passed on to the slots.
+   */
+  static result_type emit(signal_impl* impl, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3)
+    {
+      if (!impl || impl->slots_.empty()) return;
+      signal_exec exec(impl);
+
+      for (iterator_type it = impl->slots_.begin(); it != impl->slots_.end(); ++it)
+        {
+          if (it->empty() || it->blocked())
+            continue;
+          (reinterpret_cast<call_type>(it->rep_->call_))(it->rep_, _A_a1,_A_a2,_A_a3);
+        }
+    }
+};
+
+/** Abstracts signal emission.
+ * This template implements the emit() function of signal4.
+ * Template specializations are available to optimize signal
+ * emission when no accumulator is used, i.e. the template
+ * argument @e T_accumulator is @p nil.
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_accumulator>
+struct signal_emit4
+{
+  typedef signal_emit4<T_return, T_arg1,T_arg2,T_arg3,T_arg4, T_accumulator> self_type;
+  typedef typename T_accumulator::result_type result_type;
+  typedef slot<T_return, T_arg1,T_arg2,T_arg3,T_arg4> slot_type;
+  typedef internal::slot_iterator_buf<self_type> slot_iterator_buf_type;
+  typedef signal_impl::const_iterator_type iterator_type;
+
+  /** Instantiates the class.
+   * The parameters are stored in member variables. operator()() passes
+   * the values on to some slot.
+   */
+  signal_emit4(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4) 
+    : _A_a1_(_A_a1),_A_a2_(_A_a2),_A_a3_(_A_a3),_A_a4_(_A_a4) {}
+
+
+  /** Invokes a slot using the buffered parameter values.
+   * @param _A_slot Some slot to invoke.
+   * @return The slot's return value.
+   */
+  T_return operator()(const slot_type& _A_slot) const
+    { return (reinterpret_cast<typename slot_type::call_type>(_A_slot.rep_->call_))(_A_slot.rep_, _A_a1_,_A_a2_,_A_a3_,_A_a4_); }
+
+  /** Executes a list of slots using an accumulator of type @e T_accumulator.
+   * The arguments are buffered in a temporary instance of signal_emit4.
+
+   * @param _A_a1 Argument to be passed on to the slots.
+   * @param _A_a2 Argument to be passed on to the slots.
+   * @param _A_a3 Argument to be passed on to the slots.
+   * @param _A_a4 Argument to be passed on to the slots.
+   * @return The accumulated return values of the slot invocations as processed by the accumulator.
+   */
+  static result_type emit(signal_impl* impl, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4)
+    {
+      T_accumulator accumulator;
+
+      if (!impl)
+        return accumulator(slot_iterator_buf_type(), slot_iterator_buf_type());
+
+      signal_exec exec(impl);
+
+      self_type self (_A_a1,_A_a2,_A_a3,_A_a4);
+      return accumulator(slot_iterator_buf_type(impl->slots_.begin(), &self),
+                         slot_iterator_buf_type(impl->slots_.end(), &self));
+    }
+  
+  typename type_trait<T_arg1>::take _A_a1_;
+  typename type_trait<T_arg2>::take _A_a2_;
+  typename type_trait<T_arg3>::take _A_a3_;
+  typename type_trait<T_arg4>::take _A_a4_;
+};
+
+/** Abstracts signal emission.
+ * This template specialization implements an optimized emit()
+ * function for the case that no accumulator is used.
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+struct signal_emit4<T_return, T_arg1,T_arg2,T_arg3,T_arg4, nil>
+{
+  typedef signal_emit4<T_return, T_arg1,T_arg2,T_arg3,T_arg4, nil > self_type;
+  typedef T_return result_type;
+  typedef slot<T_return, T_arg1,T_arg2,T_arg3,T_arg4> slot_type;
+  typedef signal_impl::const_iterator_type iterator_type;
+  typedef typename slot_type::call_type call_type;
+
+  /** Executes a list of slots using an accumulator of type @e T_accumulator.
+   * The arguments are passed directly on to the slots.
+   * The return value of the last slot invoked is returned.
+   * @param first An iterator pointing to the first slot in the list.
+   * @param last An iterator pointing to the last slot in the list.
+   * @param _A_a1 Argument to be passed on to the slots.
+   * @param _A_a2 Argument to be passed on to the slots.
+   * @param _A_a3 Argument to be passed on to the slots.
+   * @param _A_a4 Argument to be passed on to the slots.
+   * @return The return value of the last slot invoked.
+   */
+  static result_type emit(signal_impl* impl, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4)
+    {
+      if (!impl || impl->slots_.empty()) return T_return();
+      iterator_type it = impl->slots_.begin();
+      for (; it != impl->slots_.end(); ++it)
+        if (!it->empty() && !it->blocked()) break;
+      if (it == impl->slots_.end()) return T_return(); // note that 'T_return r_();' doesn't work => define 'r_' after this line and initialize as follows:
+
+      signal_exec exec(impl);
+
+      T_return r_ = (reinterpret_cast<call_type>(it->rep_->call_))(it->rep_, _A_a1,_A_a2,_A_a3,_A_a4);
+      for (++it; it != impl->slots_.end(); ++it)
+        {
+          if (it->empty() || it->blocked())
+            continue;
+          r_ = (reinterpret_cast<call_type>(it->rep_->call_))(it->rep_, _A_a1,_A_a2,_A_a3,_A_a4);
+        }
+      return r_;
+    }
+};
+
+/** Abstracts signal emission.
+ * This template specialization implements an optimized emit()
+ * function for the case that no accumulator is used and the
+ * return type is @p void.
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+struct signal_emit4<void, T_arg1,T_arg2,T_arg3,T_arg4, nil>
+{
+  typedef signal_emit4<void, T_arg1,T_arg2,T_arg3,T_arg4, nil> self_type;
+  typedef void result_type;
+  typedef slot<void, T_arg1,T_arg2,T_arg3,T_arg4> slot_type;
+  typedef signal_impl::const_iterator_type iterator_type;
+  typedef typename slot_type::call_type call_type;
+
+  /** Executes a list of slots using an accumulator of type @e T_accumulator.
+   * The arguments are passed directly on to the slots.
+   * @param first An iterator pointing to the first slot in the list.
+   * @param last An iterator pointing to the last slot in the list.
+   * @param _A_a1 Argument to be passed on to the slots.
+   * @param _A_a2 Argument to be passed on to the slots.
+   * @param _A_a3 Argument to be passed on to the slots.
+   * @param _A_a4 Argument to be passed on to the slots.
+   */
+  static result_type emit(signal_impl* impl, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4)
+    {
+      if (!impl || impl->slots_.empty()) return;
+      signal_exec exec(impl);
+
+      for (iterator_type it = impl->slots_.begin(); it != impl->slots_.end(); ++it)
+        {
+          if (it->empty() || it->blocked())
+            continue;
+          (reinterpret_cast<call_type>(it->rep_->call_))(it->rep_, _A_a1,_A_a2,_A_a3,_A_a4);
+        }
+    }
+};
+
+/** Abstracts signal emission.
+ * This template implements the emit() function of signal5.
+ * Template specializations are available to optimize signal
+ * emission when no accumulator is used, i.e. the template
+ * argument @e T_accumulator is @p nil.
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_accumulator>
+struct signal_emit5
+{
+  typedef signal_emit5<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5, T_accumulator> self_type;
+  typedef typename T_accumulator::result_type result_type;
+  typedef slot<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5> slot_type;
+  typedef internal::slot_iterator_buf<self_type> slot_iterator_buf_type;
+  typedef signal_impl::const_iterator_type iterator_type;
+
+  /** Instantiates the class.
+   * The parameters are stored in member variables. operator()() passes
+   * the values on to some slot.
+   */
+  signal_emit5(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5) 
+    : _A_a1_(_A_a1),_A_a2_(_A_a2),_A_a3_(_A_a3),_A_a4_(_A_a4),_A_a5_(_A_a5) {}
+
+
+  /** Invokes a slot using the buffered parameter values.
+   * @param _A_slot Some slot to invoke.
+   * @return The slot's return value.
+   */
+  T_return operator()(const slot_type& _A_slot) const
+    { return (reinterpret_cast<typename slot_type::call_type>(_A_slot.rep_->call_))(_A_slot.rep_, _A_a1_,_A_a2_,_A_a3_,_A_a4_,_A_a5_); }
+
+  /** Executes a list of slots using an accumulator of type @e T_accumulator.
+   * The arguments are buffered in a temporary instance of signal_emit5.
+
+   * @param _A_a1 Argument to be passed on to the slots.
+   * @param _A_a2 Argument to be passed on to the slots.
+   * @param _A_a3 Argument to be passed on to the slots.
+   * @param _A_a4 Argument to be passed on to the slots.
+   * @param _A_a5 Argument to be passed on to the slots.
+   * @return The accumulated return values of the slot invocations as processed by the accumulator.
+   */
+  static result_type emit(signal_impl* impl, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5)
+    {
+      T_accumulator accumulator;
+
+      if (!impl)
+        return accumulator(slot_iterator_buf_type(), slot_iterator_buf_type());
+
+      signal_exec exec(impl);
+
+      self_type self (_A_a1,_A_a2,_A_a3,_A_a4,_A_a5);
+      return accumulator(slot_iterator_buf_type(impl->slots_.begin(), &self),
+                         slot_iterator_buf_type(impl->slots_.end(), &self));
+    }
+  
+  typename type_trait<T_arg1>::take _A_a1_;
+  typename type_trait<T_arg2>::take _A_a2_;
+  typename type_trait<T_arg3>::take _A_a3_;
+  typename type_trait<T_arg4>::take _A_a4_;
+  typename type_trait<T_arg5>::take _A_a5_;
+};
+
+/** Abstracts signal emission.
+ * This template specialization implements an optimized emit()
+ * function for the case that no accumulator is used.
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+struct signal_emit5<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5, nil>
+{
+  typedef signal_emit5<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5, nil > self_type;
+  typedef T_return result_type;
+  typedef slot<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5> slot_type;
+  typedef signal_impl::const_iterator_type iterator_type;
+  typedef typename slot_type::call_type call_type;
+
+  /** Executes a list of slots using an accumulator of type @e T_accumulator.
+   * The arguments are passed directly on to the slots.
+   * The return value of the last slot invoked is returned.
+   * @param first An iterator pointing to the first slot in the list.
+   * @param last An iterator pointing to the last slot in the list.
+   * @param _A_a1 Argument to be passed on to the slots.
+   * @param _A_a2 Argument to be passed on to the slots.
+   * @param _A_a3 Argument to be passed on to the slots.
+   * @param _A_a4 Argument to be passed on to the slots.
+   * @param _A_a5 Argument to be passed on to the slots.
+   * @return The return value of the last slot invoked.
+   */
+  static result_type emit(signal_impl* impl, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5)
+    {
+      if (!impl || impl->slots_.empty()) return T_return();
+      iterator_type it = impl->slots_.begin();
+      for (; it != impl->slots_.end(); ++it)
+        if (!it->empty() && !it->blocked()) break;
+      if (it == impl->slots_.end()) return T_return(); // note that 'T_return r_();' doesn't work => define 'r_' after this line and initialize as follows:
+
+      signal_exec exec(impl);
+
+      T_return r_ = (reinterpret_cast<call_type>(it->rep_->call_))(it->rep_, _A_a1,_A_a2,_A_a3,_A_a4,_A_a5);
+      for (++it; it != impl->slots_.end(); ++it)
+        {
+          if (it->empty() || it->blocked())
+            continue;
+          r_ = (reinterpret_cast<call_type>(it->rep_->call_))(it->rep_, _A_a1,_A_a2,_A_a3,_A_a4,_A_a5);
+        }
+      return r_;
+    }
+};
+
+/** Abstracts signal emission.
+ * This template specialization implements an optimized emit()
+ * function for the case that no accumulator is used and the
+ * return type is @p void.
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+struct signal_emit5<void, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5, nil>
+{
+  typedef signal_emit5<void, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5, nil> self_type;
+  typedef void result_type;
+  typedef slot<void, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5> slot_type;
+  typedef signal_impl::const_iterator_type iterator_type;
+  typedef typename slot_type::call_type call_type;
+
+  /** Executes a list of slots using an accumulator of type @e T_accumulator.
+   * The arguments are passed directly on to the slots.
+   * @param first An iterator pointing to the first slot in the list.
+   * @param last An iterator pointing to the last slot in the list.
+   * @param _A_a1 Argument to be passed on to the slots.
+   * @param _A_a2 Argument to be passed on to the slots.
+   * @param _A_a3 Argument to be passed on to the slots.
+   * @param _A_a4 Argument to be passed on to the slots.
+   * @param _A_a5 Argument to be passed on to the slots.
+   */
+  static result_type emit(signal_impl* impl, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5)
+    {
+      if (!impl || impl->slots_.empty()) return;
+      signal_exec exec(impl);
+
+      for (iterator_type it = impl->slots_.begin(); it != impl->slots_.end(); ++it)
+        {
+          if (it->empty() || it->blocked())
+            continue;
+          (reinterpret_cast<call_type>(it->rep_->call_))(it->rep_, _A_a1,_A_a2,_A_a3,_A_a4,_A_a5);
+        }
+    }
+};
+
+/** Abstracts signal emission.
+ * This template implements the emit() function of signal6.
+ * Template specializations are available to optimize signal
+ * emission when no accumulator is used, i.e. the template
+ * argument @e T_accumulator is @p nil.
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_accumulator>
+struct signal_emit6
+{
+  typedef signal_emit6<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6, T_accumulator> self_type;
+  typedef typename T_accumulator::result_type result_type;
+  typedef slot<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6> slot_type;
+  typedef internal::slot_iterator_buf<self_type> slot_iterator_buf_type;
+  typedef signal_impl::const_iterator_type iterator_type;
+
+  /** Instantiates the class.
+   * The parameters are stored in member variables. operator()() passes
+   * the values on to some slot.
+   */
+  signal_emit6(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6) 
+    : _A_a1_(_A_a1),_A_a2_(_A_a2),_A_a3_(_A_a3),_A_a4_(_A_a4),_A_a5_(_A_a5),_A_a6_(_A_a6) {}
+
+
+  /** Invokes a slot using the buffered parameter values.
+   * @param _A_slot Some slot to invoke.
+   * @return The slot's return value.
+   */
+  T_return operator()(const slot_type& _A_slot) const
+    { return (reinterpret_cast<typename slot_type::call_type>(_A_slot.rep_->call_))(_A_slot.rep_, _A_a1_,_A_a2_,_A_a3_,_A_a4_,_A_a5_,_A_a6_); }
+
+  /** Executes a list of slots using an accumulator of type @e T_accumulator.
+   * The arguments are buffered in a temporary instance of signal_emit6.
+
+   * @param _A_a1 Argument to be passed on to the slots.
+   * @param _A_a2 Argument to be passed on to the slots.
+   * @param _A_a3 Argument to be passed on to the slots.
+   * @param _A_a4 Argument to be passed on to the slots.
+   * @param _A_a5 Argument to be passed on to the slots.
+   * @param _A_a6 Argument to be passed on to the slots.
+   * @return The accumulated return values of the slot invocations as processed by the accumulator.
+   */
+  static result_type emit(signal_impl* impl, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6)
+    {
+      T_accumulator accumulator;
+
+      if (!impl)
+        return accumulator(slot_iterator_buf_type(), slot_iterator_buf_type());
+
+      signal_exec exec(impl);
+
+      self_type self (_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6);
+      return accumulator(slot_iterator_buf_type(impl->slots_.begin(), &self),
+                         slot_iterator_buf_type(impl->slots_.end(), &self));
+    }
+  
+  typename type_trait<T_arg1>::take _A_a1_;
+  typename type_trait<T_arg2>::take _A_a2_;
+  typename type_trait<T_arg3>::take _A_a3_;
+  typename type_trait<T_arg4>::take _A_a4_;
+  typename type_trait<T_arg5>::take _A_a5_;
+  typename type_trait<T_arg6>::take _A_a6_;
+};
+
+/** Abstracts signal emission.
+ * This template specialization implements an optimized emit()
+ * function for the case that no accumulator is used.
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+struct signal_emit6<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6, nil>
+{
+  typedef signal_emit6<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6, nil > self_type;
+  typedef T_return result_type;
+  typedef slot<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6> slot_type;
+  typedef signal_impl::const_iterator_type iterator_type;
+  typedef typename slot_type::call_type call_type;
+
+  /** Executes a list of slots using an accumulator of type @e T_accumulator.
+   * The arguments are passed directly on to the slots.
+   * The return value of the last slot invoked is returned.
+   * @param first An iterator pointing to the first slot in the list.
+   * @param last An iterator pointing to the last slot in the list.
+   * @param _A_a1 Argument to be passed on to the slots.
+   * @param _A_a2 Argument to be passed on to the slots.
+   * @param _A_a3 Argument to be passed on to the slots.
+   * @param _A_a4 Argument to be passed on to the slots.
+   * @param _A_a5 Argument to be passed on to the slots.
+   * @param _A_a6 Argument to be passed on to the slots.
+   * @return The return value of the last slot invoked.
+   */
+  static result_type emit(signal_impl* impl, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6)
+    {
+      if (!impl || impl->slots_.empty()) return T_return();
+      iterator_type it = impl->slots_.begin();
+      for (; it != impl->slots_.end(); ++it)
+        if (!it->empty() && !it->blocked()) break;
+      if (it == impl->slots_.end()) return T_return(); // note that 'T_return r_();' doesn't work => define 'r_' after this line and initialize as follows:
+
+      signal_exec exec(impl);
+
+      T_return r_ = (reinterpret_cast<call_type>(it->rep_->call_))(it->rep_, _A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6);
+      for (++it; it != impl->slots_.end(); ++it)
+        {
+          if (it->empty() || it->blocked())
+            continue;
+          r_ = (reinterpret_cast<call_type>(it->rep_->call_))(it->rep_, _A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6);
+        }
+      return r_;
+    }
+};
+
+/** Abstracts signal emission.
+ * This template specialization implements an optimized emit()
+ * function for the case that no accumulator is used and the
+ * return type is @p void.
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+struct signal_emit6<void, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6, nil>
+{
+  typedef signal_emit6<void, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6, nil> self_type;
+  typedef void result_type;
+  typedef slot<void, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6> slot_type;
+  typedef signal_impl::const_iterator_type iterator_type;
+  typedef typename slot_type::call_type call_type;
+
+  /** Executes a list of slots using an accumulator of type @e T_accumulator.
+   * The arguments are passed directly on to the slots.
+   * @param first An iterator pointing to the first slot in the list.
+   * @param last An iterator pointing to the last slot in the list.
+   * @param _A_a1 Argument to be passed on to the slots.
+   * @param _A_a2 Argument to be passed on to the slots.
+   * @param _A_a3 Argument to be passed on to the slots.
+   * @param _A_a4 Argument to be passed on to the slots.
+   * @param _A_a5 Argument to be passed on to the slots.
+   * @param _A_a6 Argument to be passed on to the slots.
+   */
+  static result_type emit(signal_impl* impl, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6)
+    {
+      if (!impl || impl->slots_.empty()) return;
+      signal_exec exec(impl);
+
+      for (iterator_type it = impl->slots_.begin(); it != impl->slots_.end(); ++it)
+        {
+          if (it->empty() || it->blocked())
+            continue;
+          (reinterpret_cast<call_type>(it->rep_->call_))(it->rep_, _A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6);
+        }
+    }
+};
+
+/** Abstracts signal emission.
+ * This template implements the emit() function of signal7.
+ * Template specializations are available to optimize signal
+ * emission when no accumulator is used, i.e. the template
+ * argument @e T_accumulator is @p nil.
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_accumulator>
+struct signal_emit7
+{
+  typedef signal_emit7<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7, T_accumulator> self_type;
+  typedef typename T_accumulator::result_type result_type;
+  typedef slot<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7> slot_type;
+  typedef internal::slot_iterator_buf<self_type> slot_iterator_buf_type;
+  typedef signal_impl::const_iterator_type iterator_type;
+
+  /** Instantiates the class.
+   * The parameters are stored in member variables. operator()() passes
+   * the values on to some slot.
+   */
+  signal_emit7(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6,typename type_trait<T_arg7>::take _A_a7) 
+    : _A_a1_(_A_a1),_A_a2_(_A_a2),_A_a3_(_A_a3),_A_a4_(_A_a4),_A_a5_(_A_a5),_A_a6_(_A_a6),_A_a7_(_A_a7) {}
+
+
+  /** Invokes a slot using the buffered parameter values.
+   * @param _A_slot Some slot to invoke.
+   * @return The slot's return value.
+   */
+  T_return operator()(const slot_type& _A_slot) const
+    { return (reinterpret_cast<typename slot_type::call_type>(_A_slot.rep_->call_))(_A_slot.rep_, _A_a1_,_A_a2_,_A_a3_,_A_a4_,_A_a5_,_A_a6_,_A_a7_); }
+
+  /** Executes a list of slots using an accumulator of type @e T_accumulator.
+   * The arguments are buffered in a temporary instance of signal_emit7.
+
+   * @param _A_a1 Argument to be passed on to the slots.
+   * @param _A_a2 Argument to be passed on to the slots.
+   * @param _A_a3 Argument to be passed on to the slots.
+   * @param _A_a4 Argument to be passed on to the slots.
+   * @param _A_a5 Argument to be passed on to the slots.
+   * @param _A_a6 Argument to be passed on to the slots.
+   * @param _A_a7 Argument to be passed on to the slots.
+   * @return The accumulated return values of the slot invocations as processed by the accumulator.
+   */
+  static result_type emit(signal_impl* impl, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6,typename type_trait<T_arg7>::take _A_a7)
+    {
+      T_accumulator accumulator;
+
+      if (!impl)
+        return accumulator(slot_iterator_buf_type(), slot_iterator_buf_type());
+
+      signal_exec exec(impl);
+
+      self_type self (_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6,_A_a7);
+      return accumulator(slot_iterator_buf_type(impl->slots_.begin(), &self),
+                         slot_iterator_buf_type(impl->slots_.end(), &self));
+    }
+  
+  typename type_trait<T_arg1>::take _A_a1_;
+  typename type_trait<T_arg2>::take _A_a2_;
+  typename type_trait<T_arg3>::take _A_a3_;
+  typename type_trait<T_arg4>::take _A_a4_;
+  typename type_trait<T_arg5>::take _A_a5_;
+  typename type_trait<T_arg6>::take _A_a6_;
+  typename type_trait<T_arg7>::take _A_a7_;
+};
+
+/** Abstracts signal emission.
+ * This template specialization implements an optimized emit()
+ * function for the case that no accumulator is used.
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+struct signal_emit7<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7, nil>
+{
+  typedef signal_emit7<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7, nil > self_type;
+  typedef T_return result_type;
+  typedef slot<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7> slot_type;
+  typedef signal_impl::const_iterator_type iterator_type;
+  typedef typename slot_type::call_type call_type;
+
+  /** Executes a list of slots using an accumulator of type @e T_accumulator.
+   * The arguments are passed directly on to the slots.
+   * The return value of the last slot invoked is returned.
+   * @param first An iterator pointing to the first slot in the list.
+   * @param last An iterator pointing to the last slot in the list.
+   * @param _A_a1 Argument to be passed on to the slots.
+   * @param _A_a2 Argument to be passed on to the slots.
+   * @param _A_a3 Argument to be passed on to the slots.
+   * @param _A_a4 Argument to be passed on to the slots.
+   * @param _A_a5 Argument to be passed on to the slots.
+   * @param _A_a6 Argument to be passed on to the slots.
+   * @param _A_a7 Argument to be passed on to the slots.
+   * @return The return value of the last slot invoked.
+   */
+  static result_type emit(signal_impl* impl, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6,typename type_trait<T_arg7>::take _A_a7)
+    {
+      if (!impl || impl->slots_.empty()) return T_return();
+      iterator_type it = impl->slots_.begin();
+      for (; it != impl->slots_.end(); ++it)
+        if (!it->empty() && !it->blocked()) break;
+      if (it == impl->slots_.end()) return T_return(); // note that 'T_return r_();' doesn't work => define 'r_' after this line and initialize as follows:
+
+      signal_exec exec(impl);
+
+      T_return r_ = (reinterpret_cast<call_type>(it->rep_->call_))(it->rep_, _A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6,_A_a7);
+      for (++it; it != impl->slots_.end(); ++it)
+        {
+          if (it->empty() || it->blocked())
+            continue;
+          r_ = (reinterpret_cast<call_type>(it->rep_->call_))(it->rep_, _A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6,_A_a7);
+        }
+      return r_;
+    }
+};
+
+/** Abstracts signal emission.
+ * This template specialization implements an optimized emit()
+ * function for the case that no accumulator is used and the
+ * return type is @p void.
+ */
+template <class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+struct signal_emit7<void, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7, nil>
+{
+  typedef signal_emit7<void, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7, nil> self_type;
+  typedef void result_type;
+  typedef slot<void, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7> slot_type;
+  typedef signal_impl::const_iterator_type iterator_type;
+  typedef typename slot_type::call_type call_type;
+
+  /** Executes a list of slots using an accumulator of type @e T_accumulator.
+   * The arguments are passed directly on to the slots.
+   * @param first An iterator pointing to the first slot in the list.
+   * @param last An iterator pointing to the last slot in the list.
+   * @param _A_a1 Argument to be passed on to the slots.
+   * @param _A_a2 Argument to be passed on to the slots.
+   * @param _A_a3 Argument to be passed on to the slots.
+   * @param _A_a4 Argument to be passed on to the slots.
+   * @param _A_a5 Argument to be passed on to the slots.
+   * @param _A_a6 Argument to be passed on to the slots.
+   * @param _A_a7 Argument to be passed on to the slots.
+   */
+  static result_type emit(signal_impl* impl, typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6,typename type_trait<T_arg7>::take _A_a7)
+    {
+      if (!impl || impl->slots_.empty()) return;
+      signal_exec exec(impl);
+
+      for (iterator_type it = impl->slots_.begin(); it != impl->slots_.end(); ++it)
+        {
+          if (it->empty() || it->blocked())
+            continue;
+          (reinterpret_cast<call_type>(it->rep_->call_))(it->rep_, _A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6,_A_a7);
+        }
+    }
+};
+
+
+} /* namespace internal */
+
+/** Signal declaration.
+ * signal0 can be used to connect() slots that are invoked
+ * during subsequent calls to emit(). Any functor or slot
+ * can be passed into connect(). It is converted into a slot
+ * implicitely.
+ *
+ * If you want to connect one signal to another, use make_slot()
+ * to retrieve a functor that emits the signal when invoked.
+ *
+ * Be careful if you directly pass one signal into the connect()
+ * method of another: a shallow copy of the signal is made and
+ * the signal's slots are not disconnected until both the signal
+ * and its clone are destroyed which is probably not what you want!
+ *
+ * An STL-style list interface for the signal's list of slots
+ * can be retrieved with slots(). This interface supports
+ * iteration, insertion and removal of slots.
+ *
+ * The following template arguments are used:
+ * - @e T_return The desired return type for the emit() function (may be overridden by the accumulator).
+ * - @e T_accumulator The accumulator type used for emission. The default @p nil means that no accumulator should be used, i.e. signal emission returns the return value of the last slot invoked.
+ *
+ * You should use the more convenient unnumbered sigc::signal template.
+ *
+ * @ingroup signal
+ */
+template <class T_return, class T_accumulator=nil>
+class signal0
+  : public signal_base
+{
+public:
+  typedef internal::signal_emit0<T_return, T_accumulator> emitter_type;
+  typedef typename emitter_type::result_type         result_type;
+  typedef slot<T_return>    slot_type;
+  typedef slot_list<slot_type>                       slot_list_type;
+  typedef typename slot_list_type::iterator               iterator;
+  typedef typename slot_list_type::const_iterator         const_iterator;
+  typedef typename slot_list_type::reverse_iterator       reverse_iterator;
+  typedef typename slot_list_type::const_reverse_iterator const_reverse_iterator;
+
+#ifdef SIGC_TYPEDEF_REDEFINE_ALLOWED
+  /** This typedef is only for backwards-compatibility.
+   * It is not available when using the SUN Forte compiler.
+   * @deprecated slot_list_type;
+   */
+  typedef slot_list_type slot_list;
+#endif
+
+  /** Add a slot to the list of slots.
+   * Any functor or slot may be passed into connect().
+   * It will be converted into a slot implicitely.
+   * The returned iterator may be stored for disconnection
+   * of the slot at some later point. It stays valid until
+   * the slot is removed from the list of slots. The iterator
+   * can also be implicitely converted into a sigc::connection object
+   * that may be used safely beyond the life time of the slot.
+   * @param slot_ The slot to add to the list of slots.
+   * @return An iterator pointing to the new slot in the list.
+   */
+  iterator connect(const slot_type& slot_)
+    { return iterator(signal_base::connect(static_cast<const slot_base&>(slot_))); }
+
+  /** Triggers the emission of the signal.
+   * During signal emission all slots that have been connected
+   * to the signal are invoked unless they are manually set into
+   * a blocking state. The parameters are passed on to the slots.
+   * If @e T_accumulated is not @p nil, an accumulator of this type
+   * is used to process the return values of the slot invocations.
+   * Otherwise, the return value of the last slot invoked is returned.
+   * @return The accumulated return values of the slot invocations.
+   */
+  result_type emit() const
+    { return emitter_type::emit(impl_); }
+
+  /** Triggers the emission of the signal (see emit()). */
+  result_type operator()() const
+    { return emit(); }
+
+  /** Creates a functor that calls emit() on this signal.
+   * @code
+   * sigc::mem_fun(mysignal, &sigc::signal0::emit)
+   * @endcode
+   * yields the same result.
+   * @return A functor that calls emit() on this signal.
+   */
+  bound_const_mem_functor0<result_type, signal0> make_slot() const
+    { return bound_const_mem_functor0<result_type, signal0>(this, &signal0::emit); }
+
+  /** Creates an STL-style interface for the signal's list of slots.
+   * This interface supports iteration, insertion and removal of slots.
+   * @return An STL-style interface for the signal's list of slots.
+   */
+  slot_list_type slots()
+    { return slot_list_type(impl()); }
+
+  /** Creates an STL-style interface for the signal's list of slots.
+   * This interface supports iteration, insertion and removal of slots.
+   * @return An STL-style interface for the signal's list of slots.
+   */
+  const slot_list_type slots() const
+    { return slot_list_type(const_cast<signal0*>(this)->impl()); }
+
+  signal0() {}
+
+  signal0(const signal0& src)
+    : signal_base(src) {}
+};
+
+/** Signal declaration.
+ * signal1 can be used to connect() slots that are invoked
+ * during subsequent calls to emit(). Any functor or slot
+ * can be passed into connect(). It is converted into a slot
+ * implicitely.
+ *
+ * If you want to connect one signal to another, use make_slot()
+ * to retrieve a functor that emits the signal when invoked.
+ *
+ * Be careful if you directly pass one signal into the connect()
+ * method of another: a shallow copy of the signal is made and
+ * the signal's slots are not disconnected until both the signal
+ * and its clone are destroyed which is probably not what you want!
+ *
+ * An STL-style list interface for the signal's list of slots
+ * can be retrieved with slots(). This interface supports
+ * iteration, insertion and removal of slots.
+ *
+ * The following template arguments are used:
+ * - @e T_return The desired return type for the emit() function (may be overridden by the accumulator).
+ * - @e T_arg1 Argument type used in the definition of emit().
+ * - @e T_accumulator The accumulator type used for emission. The default @p nil means that no accumulator should be used, i.e. signal emission returns the return value of the last slot invoked.
+ *
+ * You should use the more convenient unnumbered sigc::signal template.
+ *
+ * @ingroup signal
+ */
+template <class T_return, class T_arg1, class T_accumulator=nil>
+class signal1
+  : public signal_base
+{
+public:
+  typedef internal::signal_emit1<T_return, T_arg1, T_accumulator> emitter_type;
+  typedef typename emitter_type::result_type         result_type;
+  typedef slot<T_return, T_arg1>    slot_type;
+  typedef slot_list<slot_type>                       slot_list_type;
+  typedef typename slot_list_type::iterator               iterator;
+  typedef typename slot_list_type::const_iterator         const_iterator;
+  typedef typename slot_list_type::reverse_iterator       reverse_iterator;
+  typedef typename slot_list_type::const_reverse_iterator const_reverse_iterator;
+
+#ifdef SIGC_TYPEDEF_REDEFINE_ALLOWED
+  /** This typedef is only for backwards-compatibility.
+   * It is not available when using the SUN Forte compiler.
+   * @deprecated slot_list_type;
+   */
+  typedef slot_list_type slot_list;
+#endif
+
+  /** Add a slot to the list of slots.
+   * Any functor or slot may be passed into connect().
+   * It will be converted into a slot implicitely.
+   * The returned iterator may be stored for disconnection
+   * of the slot at some later point. It stays valid until
+   * the slot is removed from the list of slots. The iterator
+   * can also be implicitely converted into a sigc::connection object
+   * that may be used safely beyond the life time of the slot.
+   * @param slot_ The slot to add to the list of slots.
+   * @return An iterator pointing to the new slot in the list.
+   */
+  iterator connect(const slot_type& slot_)
+    { return iterator(signal_base::connect(static_cast<const slot_base&>(slot_))); }
+
+  /** Triggers the emission of the signal.
+   * During signal emission all slots that have been connected
+   * to the signal are invoked unless they are manually set into
+   * a blocking state. The parameters are passed on to the slots.
+   * If @e T_accumulated is not @p nil, an accumulator of this type
+   * is used to process the return values of the slot invocations.
+   * Otherwise, the return value of the last slot invoked is returned.
+   * @param _A_a1 Argument to be passed on to the slots.
+   * @return The accumulated return values of the slot invocations.
+   */
+  result_type emit(typename type_trait<T_arg1>::take _A_a1) const
+    { return emitter_type::emit(impl_, _A_a1); }
+
+  /** Triggers the emission of the signal (see emit()). */
+  result_type operator()(typename type_trait<T_arg1>::take _A_a1) const
+    { return emit(_A_a1); }
+
+  /** Creates a functor that calls emit() on this signal.
+   * @code
+   * sigc::mem_fun(mysignal, &sigc::signal1::emit)
+   * @endcode
+   * yields the same result.
+   * @return A functor that calls emit() on this signal.
+   */
+  bound_const_mem_functor1<result_type, signal1, typename type_trait<T_arg1>::take> make_slot() const
+    { return bound_const_mem_functor1<result_type, signal1, typename type_trait<T_arg1>::take>(this, &signal1::emit); }
+
+  /** Creates an STL-style interface for the signal's list of slots.
+   * This interface supports iteration, insertion and removal of slots.
+   * @return An STL-style interface for the signal's list of slots.
+   */
+  slot_list_type slots()
+    { return slot_list_type(impl()); }
+
+  /** Creates an STL-style interface for the signal's list of slots.
+   * This interface supports iteration, insertion and removal of slots.
+   * @return An STL-style interface for the signal's list of slots.
+   */
+  const slot_list_type slots() const
+    { return slot_list_type(const_cast<signal1*>(this)->impl()); }
+
+  signal1() {}
+
+  signal1(const signal1& src)
+    : signal_base(src) {}
+};
+
+/** Signal declaration.
+ * signal2 can be used to connect() slots that are invoked
+ * during subsequent calls to emit(). Any functor or slot
+ * can be passed into connect(). It is converted into a slot
+ * implicitely.
+ *
+ * If you want to connect one signal to another, use make_slot()
+ * to retrieve a functor that emits the signal when invoked.
+ *
+ * Be careful if you directly pass one signal into the connect()
+ * method of another: a shallow copy of the signal is made and
+ * the signal's slots are not disconnected until both the signal
+ * and its clone are destroyed which is probably not what you want!
+ *
+ * An STL-style list interface for the signal's list of slots
+ * can be retrieved with slots(). This interface supports
+ * iteration, insertion and removal of slots.
+ *
+ * The following template arguments are used:
+ * - @e T_return The desired return type for the emit() function (may be overridden by the accumulator).
+ * - @e T_arg1 Argument type used in the definition of emit().
+ * - @e T_arg2 Argument type used in the definition of emit().
+ * - @e T_accumulator The accumulator type used for emission. The default @p nil means that no accumulator should be used, i.e. signal emission returns the return value of the last slot invoked.
+ *
+ * You should use the more convenient unnumbered sigc::signal template.
+ *
+ * @ingroup signal
+ */
+template <class T_return, class T_arg1,class T_arg2, class T_accumulator=nil>
+class signal2
+  : public signal_base
+{
+public:
+  typedef internal::signal_emit2<T_return, T_arg1,T_arg2, T_accumulator> emitter_type;
+  typedef typename emitter_type::result_type         result_type;
+  typedef slot<T_return, T_arg1,T_arg2>    slot_type;
+  typedef slot_list<slot_type>                       slot_list_type;
+  typedef typename slot_list_type::iterator               iterator;
+  typedef typename slot_list_type::const_iterator         const_iterator;
+  typedef typename slot_list_type::reverse_iterator       reverse_iterator;
+  typedef typename slot_list_type::const_reverse_iterator const_reverse_iterator;
+
+#ifdef SIGC_TYPEDEF_REDEFINE_ALLOWED
+  /** This typedef is only for backwards-compatibility.
+   * It is not available when using the SUN Forte compiler.
+   * @deprecated slot_list_type;
+   */
+  typedef slot_list_type slot_list;
+#endif
+
+  /** Add a slot to the list of slots.
+   * Any functor or slot may be passed into connect().
+   * It will be converted into a slot implicitely.
+   * The returned iterator may be stored for disconnection
+   * of the slot at some later point. It stays valid until
+   * the slot is removed from the list of slots. The iterator
+   * can also be implicitely converted into a sigc::connection object
+   * that may be used safely beyond the life time of the slot.
+   * @param slot_ The slot to add to the list of slots.
+   * @return An iterator pointing to the new slot in the list.
+   */
+  iterator connect(const slot_type& slot_)
+    { return iterator(signal_base::connect(static_cast<const slot_base&>(slot_))); }
+
+  /** Triggers the emission of the signal.
+   * During signal emission all slots that have been connected
+   * to the signal are invoked unless they are manually set into
+   * a blocking state. The parameters are passed on to the slots.
+   * If @e T_accumulated is not @p nil, an accumulator of this type
+   * is used to process the return values of the slot invocations.
+   * Otherwise, the return value of the last slot invoked is returned.
+   * @param _A_a1 Argument to be passed on to the slots.
+   * @param _A_a2 Argument to be passed on to the slots.
+   * @return The accumulated return values of the slot invocations.
+   */
+  result_type emit(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2) const
+    { return emitter_type::emit(impl_, _A_a1,_A_a2); }
+
+  /** Triggers the emission of the signal (see emit()). */
+  result_type operator()(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2) const
+    { return emit(_A_a1,_A_a2); }
+
+  /** Creates a functor that calls emit() on this signal.
+   * @code
+   * sigc::mem_fun(mysignal, &sigc::signal2::emit)
+   * @endcode
+   * yields the same result.
+   * @return A functor that calls emit() on this signal.
+   */
+  bound_const_mem_functor2<result_type, signal2, typename type_trait<T_arg1>::take,typename type_trait<T_arg2>::take> make_slot() const
+    { return bound_const_mem_functor2<result_type, signal2, typename type_trait<T_arg1>::take,typename type_trait<T_arg2>::take>(this, &signal2::emit); }
+
+  /** Creates an STL-style interface for the signal's list of slots.
+   * This interface supports iteration, insertion and removal of slots.
+   * @return An STL-style interface for the signal's list of slots.
+   */
+  slot_list_type slots()
+    { return slot_list_type(impl()); }
+
+  /** Creates an STL-style interface for the signal's list of slots.
+   * This interface supports iteration, insertion and removal of slots.
+   * @return An STL-style interface for the signal's list of slots.
+   */
+  const slot_list_type slots() const
+    { return slot_list_type(const_cast<signal2*>(this)->impl()); }
+
+  signal2() {}
+
+  signal2(const signal2& src)
+    : signal_base(src) {}
+};
+
+/** Signal declaration.
+ * signal3 can be used to connect() slots that are invoked
+ * during subsequent calls to emit(). Any functor or slot
+ * can be passed into connect(). It is converted into a slot
+ * implicitely.
+ *
+ * If you want to connect one signal to another, use make_slot()
+ * to retrieve a functor that emits the signal when invoked.
+ *
+ * Be careful if you directly pass one signal into the connect()
+ * method of another: a shallow copy of the signal is made and
+ * the signal's slots are not disconnected until both the signal
+ * and its clone are destroyed which is probably not what you want!
+ *
+ * An STL-style list interface for the signal's list of slots
+ * can be retrieved with slots(). This interface supports
+ * iteration, insertion and removal of slots.
+ *
+ * The following template arguments are used:
+ * - @e T_return The desired return type for the emit() function (may be overridden by the accumulator).
+ * - @e T_arg1 Argument type used in the definition of emit().
+ * - @e T_arg2 Argument type used in the definition of emit().
+ * - @e T_arg3 Argument type used in the definition of emit().
+ * - @e T_accumulator The accumulator type used for emission. The default @p nil means that no accumulator should be used, i.e. signal emission returns the return value of the last slot invoked.
+ *
+ * You should use the more convenient unnumbered sigc::signal template.
+ *
+ * @ingroup signal
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3, class T_accumulator=nil>
+class signal3
+  : public signal_base
+{
+public:
+  typedef internal::signal_emit3<T_return, T_arg1,T_arg2,T_arg3, T_accumulator> emitter_type;
+  typedef typename emitter_type::result_type         result_type;
+  typedef slot<T_return, T_arg1,T_arg2,T_arg3>    slot_type;
+  typedef slot_list<slot_type>                       slot_list_type;
+  typedef typename slot_list_type::iterator               iterator;
+  typedef typename slot_list_type::const_iterator         const_iterator;
+  typedef typename slot_list_type::reverse_iterator       reverse_iterator;
+  typedef typename slot_list_type::const_reverse_iterator const_reverse_iterator;
+
+#ifdef SIGC_TYPEDEF_REDEFINE_ALLOWED
+  /** This typedef is only for backwards-compatibility.
+   * It is not available when using the SUN Forte compiler.
+   * @deprecated slot_list_type;
+   */
+  typedef slot_list_type slot_list;
+#endif
+
+  /** Add a slot to the list of slots.
+   * Any functor or slot may be passed into connect().
+   * It will be converted into a slot implicitely.
+   * The returned iterator may be stored for disconnection
+   * of the slot at some later point. It stays valid until
+   * the slot is removed from the list of slots. The iterator
+   * can also be implicitely converted into a sigc::connection object
+   * that may be used safely beyond the life time of the slot.
+   * @param slot_ The slot to add to the list of slots.
+   * @return An iterator pointing to the new slot in the list.
+   */
+  iterator connect(const slot_type& slot_)
+    { return iterator(signal_base::connect(static_cast<const slot_base&>(slot_))); }
+
+  /** Triggers the emission of the signal.
+   * During signal emission all slots that have been connected
+   * to the signal are invoked unless they are manually set into
+   * a blocking state. The parameters are passed on to the slots.
+   * If @e T_accumulated is not @p nil, an accumulator of this type
+   * is used to process the return values of the slot invocations.
+   * Otherwise, the return value of the last slot invoked is returned.
+   * @param _A_a1 Argument to be passed on to the slots.
+   * @param _A_a2 Argument to be passed on to the slots.
+   * @param _A_a3 Argument to be passed on to the slots.
+   * @return The accumulated return values of the slot invocations.
+   */
+  result_type emit(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3) const
+    { return emitter_type::emit(impl_, _A_a1,_A_a2,_A_a3); }
+
+  /** Triggers the emission of the signal (see emit()). */
+  result_type operator()(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3) const
+    { return emit(_A_a1,_A_a2,_A_a3); }
+
+  /** Creates a functor that calls emit() on this signal.
+   * @code
+   * sigc::mem_fun(mysignal, &sigc::signal3::emit)
+   * @endcode
+   * yields the same result.
+   * @return A functor that calls emit() on this signal.
+   */
+  bound_const_mem_functor3<result_type, signal3, typename type_trait<T_arg1>::take,typename type_trait<T_arg2>::take,typename type_trait<T_arg3>::take> make_slot() const
+    { return bound_const_mem_functor3<result_type, signal3, typename type_trait<T_arg1>::take,typename type_trait<T_arg2>::take,typename type_trait<T_arg3>::take>(this, &signal3::emit); }
+
+  /** Creates an STL-style interface for the signal's list of slots.
+   * This interface supports iteration, insertion and removal of slots.
+   * @return An STL-style interface for the signal's list of slots.
+   */
+  slot_list_type slots()
+    { return slot_list_type(impl()); }
+
+  /** Creates an STL-style interface for the signal's list of slots.
+   * This interface supports iteration, insertion and removal of slots.
+   * @return An STL-style interface for the signal's list of slots.
+   */
+  const slot_list_type slots() const
+    { return slot_list_type(const_cast<signal3*>(this)->impl()); }
+
+  signal3() {}
+
+  signal3(const signal3& src)
+    : signal_base(src) {}
+};
+
+/** Signal declaration.
+ * signal4 can be used to connect() slots that are invoked
+ * during subsequent calls to emit(). Any functor or slot
+ * can be passed into connect(). It is converted into a slot
+ * implicitely.
+ *
+ * If you want to connect one signal to another, use make_slot()
+ * to retrieve a functor that emits the signal when invoked.
+ *
+ * Be careful if you directly pass one signal into the connect()
+ * method of another: a shallow copy of the signal is made and
+ * the signal's slots are not disconnected until both the signal
+ * and its clone are destroyed which is probably not what you want!
+ *
+ * An STL-style list interface for the signal's list of slots
+ * can be retrieved with slots(). This interface supports
+ * iteration, insertion and removal of slots.
+ *
+ * The following template arguments are used:
+ * - @e T_return The desired return type for the emit() function (may be overridden by the accumulator).
+ * - @e T_arg1 Argument type used in the definition of emit().
+ * - @e T_arg2 Argument type used in the definition of emit().
+ * - @e T_arg3 Argument type used in the definition of emit().
+ * - @e T_arg4 Argument type used in the definition of emit().
+ * - @e T_accumulator The accumulator type used for emission. The default @p nil means that no accumulator should be used, i.e. signal emission returns the return value of the last slot invoked.
+ *
+ * You should use the more convenient unnumbered sigc::signal template.
+ *
+ * @ingroup signal
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_accumulator=nil>
+class signal4
+  : public signal_base
+{
+public:
+  typedef internal::signal_emit4<T_return, T_arg1,T_arg2,T_arg3,T_arg4, T_accumulator> emitter_type;
+  typedef typename emitter_type::result_type         result_type;
+  typedef slot<T_return, T_arg1,T_arg2,T_arg3,T_arg4>    slot_type;
+  typedef slot_list<slot_type>                       slot_list_type;
+  typedef typename slot_list_type::iterator               iterator;
+  typedef typename slot_list_type::const_iterator         const_iterator;
+  typedef typename slot_list_type::reverse_iterator       reverse_iterator;
+  typedef typename slot_list_type::const_reverse_iterator const_reverse_iterator;
+
+#ifdef SIGC_TYPEDEF_REDEFINE_ALLOWED
+  /** This typedef is only for backwards-compatibility.
+   * It is not available when using the SUN Forte compiler.
+   * @deprecated slot_list_type;
+   */
+  typedef slot_list_type slot_list;
+#endif
+
+  /** Add a slot to the list of slots.
+   * Any functor or slot may be passed into connect().
+   * It will be converted into a slot implicitely.
+   * The returned iterator may be stored for disconnection
+   * of the slot at some later point. It stays valid until
+   * the slot is removed from the list of slots. The iterator
+   * can also be implicitely converted into a sigc::connection object
+   * that may be used safely beyond the life time of the slot.
+   * @param slot_ The slot to add to the list of slots.
+   * @return An iterator pointing to the new slot in the list.
+   */
+  iterator connect(const slot_type& slot_)
+    { return iterator(signal_base::connect(static_cast<const slot_base&>(slot_))); }
+
+  /** Triggers the emission of the signal.
+   * During signal emission all slots that have been connected
+   * to the signal are invoked unless they are manually set into
+   * a blocking state. The parameters are passed on to the slots.
+   * If @e T_accumulated is not @p nil, an accumulator of this type
+   * is used to process the return values of the slot invocations.
+   * Otherwise, the return value of the last slot invoked is returned.
+   * @param _A_a1 Argument to be passed on to the slots.
+   * @param _A_a2 Argument to be passed on to the slots.
+   * @param _A_a3 Argument to be passed on to the slots.
+   * @param _A_a4 Argument to be passed on to the slots.
+   * @return The accumulated return values of the slot invocations.
+   */
+  result_type emit(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4) const
+    { return emitter_type::emit(impl_, _A_a1,_A_a2,_A_a3,_A_a4); }
+
+  /** Triggers the emission of the signal (see emit()). */
+  result_type operator()(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4) const
+    { return emit(_A_a1,_A_a2,_A_a3,_A_a4); }
+
+  /** Creates a functor that calls emit() on this signal.
+   * @code
+   * sigc::mem_fun(mysignal, &sigc::signal4::emit)
+   * @endcode
+   * yields the same result.
+   * @return A functor that calls emit() on this signal.
+   */
+  bound_const_mem_functor4<result_type, signal4, typename type_trait<T_arg1>::take,typename type_trait<T_arg2>::take,typename type_trait<T_arg3>::take,typename type_trait<T_arg4>::take> make_slot() const
+    { return bound_const_mem_functor4<result_type, signal4, typename type_trait<T_arg1>::take,typename type_trait<T_arg2>::take,typename type_trait<T_arg3>::take,typename type_trait<T_arg4>::take>(this, &signal4::emit); }
+
+  /** Creates an STL-style interface for the signal's list of slots.
+   * This interface supports iteration, insertion and removal of slots.
+   * @return An STL-style interface for the signal's list of slots.
+   */
+  slot_list_type slots()
+    { return slot_list_type(impl()); }
+
+  /** Creates an STL-style interface for the signal's list of slots.
+   * This interface supports iteration, insertion and removal of slots.
+   * @return An STL-style interface for the signal's list of slots.
+   */
+  const slot_list_type slots() const
+    { return slot_list_type(const_cast<signal4*>(this)->impl()); }
+
+  signal4() {}
+
+  signal4(const signal4& src)
+    : signal_base(src) {}
+};
+
+/** Signal declaration.
+ * signal5 can be used to connect() slots that are invoked
+ * during subsequent calls to emit(). Any functor or slot
+ * can be passed into connect(). It is converted into a slot
+ * implicitely.
+ *
+ * If you want to connect one signal to another, use make_slot()
+ * to retrieve a functor that emits the signal when invoked.
+ *
+ * Be careful if you directly pass one signal into the connect()
+ * method of another: a shallow copy of the signal is made and
+ * the signal's slots are not disconnected until both the signal
+ * and its clone are destroyed which is probably not what you want!
+ *
+ * An STL-style list interface for the signal's list of slots
+ * can be retrieved with slots(). This interface supports
+ * iteration, insertion and removal of slots.
+ *
+ * The following template arguments are used:
+ * - @e T_return The desired return type for the emit() function (may be overridden by the accumulator).
+ * - @e T_arg1 Argument type used in the definition of emit().
+ * - @e T_arg2 Argument type used in the definition of emit().
+ * - @e T_arg3 Argument type used in the definition of emit().
+ * - @e T_arg4 Argument type used in the definition of emit().
+ * - @e T_arg5 Argument type used in the definition of emit().
+ * - @e T_accumulator The accumulator type used for emission. The default @p nil means that no accumulator should be used, i.e. signal emission returns the return value of the last slot invoked.
+ *
+ * You should use the more convenient unnumbered sigc::signal template.
+ *
+ * @ingroup signal
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_accumulator=nil>
+class signal5
+  : public signal_base
+{
+public:
+  typedef internal::signal_emit5<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5, T_accumulator> emitter_type;
+  typedef typename emitter_type::result_type         result_type;
+  typedef slot<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>    slot_type;
+  typedef slot_list<slot_type>                       slot_list_type;
+  typedef typename slot_list_type::iterator               iterator;
+  typedef typename slot_list_type::const_iterator         const_iterator;
+  typedef typename slot_list_type::reverse_iterator       reverse_iterator;
+  typedef typename slot_list_type::const_reverse_iterator const_reverse_iterator;
+
+#ifdef SIGC_TYPEDEF_REDEFINE_ALLOWED
+  /** This typedef is only for backwards-compatibility.
+   * It is not available when using the SUN Forte compiler.
+   * @deprecated slot_list_type;
+   */
+  typedef slot_list_type slot_list;
+#endif
+
+  /** Add a slot to the list of slots.
+   * Any functor or slot may be passed into connect().
+   * It will be converted into a slot implicitely.
+   * The returned iterator may be stored for disconnection
+   * of the slot at some later point. It stays valid until
+   * the slot is removed from the list of slots. The iterator
+   * can also be implicitely converted into a sigc::connection object
+   * that may be used safely beyond the life time of the slot.
+   * @param slot_ The slot to add to the list of slots.
+   * @return An iterator pointing to the new slot in the list.
+   */
+  iterator connect(const slot_type& slot_)
+    { return iterator(signal_base::connect(static_cast<const slot_base&>(slot_))); }
+
+  /** Triggers the emission of the signal.
+   * During signal emission all slots that have been connected
+   * to the signal are invoked unless they are manually set into
+   * a blocking state. The parameters are passed on to the slots.
+   * If @e T_accumulated is not @p nil, an accumulator of this type
+   * is used to process the return values of the slot invocations.
+   * Otherwise, the return value of the last slot invoked is returned.
+   * @param _A_a1 Argument to be passed on to the slots.
+   * @param _A_a2 Argument to be passed on to the slots.
+   * @param _A_a3 Argument to be passed on to the slots.
+   * @param _A_a4 Argument to be passed on to the slots.
+   * @param _A_a5 Argument to be passed on to the slots.
+   * @return The accumulated return values of the slot invocations.
+   */
+  result_type emit(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5) const
+    { return emitter_type::emit(impl_, _A_a1,_A_a2,_A_a3,_A_a4,_A_a5); }
+
+  /** Triggers the emission of the signal (see emit()). */
+  result_type operator()(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5) const
+    { return emit(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5); }
+
+  /** Creates a functor that calls emit() on this signal.
+   * @code
+   * sigc::mem_fun(mysignal, &sigc::signal5::emit)
+   * @endcode
+   * yields the same result.
+   * @return A functor that calls emit() on this signal.
+   */
+  bound_const_mem_functor5<result_type, signal5, typename type_trait<T_arg1>::take,typename type_trait<T_arg2>::take,typename type_trait<T_arg3>::take,typename type_trait<T_arg4>::take,typename type_trait<T_arg5>::take> make_slot() const
+    { return bound_const_mem_functor5<result_type, signal5, typename type_trait<T_arg1>::take,typename type_trait<T_arg2>::take,typename type_trait<T_arg3>::take,typename type_trait<T_arg4>::take,typename type_trait<T_arg5>::take>(this, &signal5::emit); }
+
+  /** Creates an STL-style interface for the signal's list of slots.
+   * This interface supports iteration, insertion and removal of slots.
+   * @return An STL-style interface for the signal's list of slots.
+   */
+  slot_list_type slots()
+    { return slot_list_type(impl()); }
+
+  /** Creates an STL-style interface for the signal's list of slots.
+   * This interface supports iteration, insertion and removal of slots.
+   * @return An STL-style interface for the signal's list of slots.
+   */
+  const slot_list_type slots() const
+    { return slot_list_type(const_cast<signal5*>(this)->impl()); }
+
+  signal5() {}
+
+  signal5(const signal5& src)
+    : signal_base(src) {}
+};
+
+/** Signal declaration.
+ * signal6 can be used to connect() slots that are invoked
+ * during subsequent calls to emit(). Any functor or slot
+ * can be passed into connect(). It is converted into a slot
+ * implicitely.
+ *
+ * If you want to connect one signal to another, use make_slot()
+ * to retrieve a functor that emits the signal when invoked.
+ *
+ * Be careful if you directly pass one signal into the connect()
+ * method of another: a shallow copy of the signal is made and
+ * the signal's slots are not disconnected until both the signal
+ * and its clone are destroyed which is probably not what you want!
+ *
+ * An STL-style list interface for the signal's list of slots
+ * can be retrieved with slots(). This interface supports
+ * iteration, insertion and removal of slots.
+ *
+ * The following template arguments are used:
+ * - @e T_return The desired return type for the emit() function (may be overridden by the accumulator).
+ * - @e T_arg1 Argument type used in the definition of emit().
+ * - @e T_arg2 Argument type used in the definition of emit().
+ * - @e T_arg3 Argument type used in the definition of emit().
+ * - @e T_arg4 Argument type used in the definition of emit().
+ * - @e T_arg5 Argument type used in the definition of emit().
+ * - @e T_arg6 Argument type used in the definition of emit().
+ * - @e T_accumulator The accumulator type used for emission. The default @p nil means that no accumulator should be used, i.e. signal emission returns the return value of the last slot invoked.
+ *
+ * You should use the more convenient unnumbered sigc::signal template.
+ *
+ * @ingroup signal
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_accumulator=nil>
+class signal6
+  : public signal_base
+{
+public:
+  typedef internal::signal_emit6<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6, T_accumulator> emitter_type;
+  typedef typename emitter_type::result_type         result_type;
+  typedef slot<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>    slot_type;
+  typedef slot_list<slot_type>                       slot_list_type;
+  typedef typename slot_list_type::iterator               iterator;
+  typedef typename slot_list_type::const_iterator         const_iterator;
+  typedef typename slot_list_type::reverse_iterator       reverse_iterator;
+  typedef typename slot_list_type::const_reverse_iterator const_reverse_iterator;
+
+#ifdef SIGC_TYPEDEF_REDEFINE_ALLOWED
+  /** This typedef is only for backwards-compatibility.
+   * It is not available when using the SUN Forte compiler.
+   * @deprecated slot_list_type;
+   */
+  typedef slot_list_type slot_list;
+#endif
+
+  /** Add a slot to the list of slots.
+   * Any functor or slot may be passed into connect().
+   * It will be converted into a slot implicitely.
+   * The returned iterator may be stored for disconnection
+   * of the slot at some later point. It stays valid until
+   * the slot is removed from the list of slots. The iterator
+   * can also be implicitely converted into a sigc::connection object
+   * that may be used safely beyond the life time of the slot.
+   * @param slot_ The slot to add to the list of slots.
+   * @return An iterator pointing to the new slot in the list.
+   */
+  iterator connect(const slot_type& slot_)
+    { return iterator(signal_base::connect(static_cast<const slot_base&>(slot_))); }
+
+  /** Triggers the emission of the signal.
+   * During signal emission all slots that have been connected
+   * to the signal are invoked unless they are manually set into
+   * a blocking state. The parameters are passed on to the slots.
+   * If @e T_accumulated is not @p nil, an accumulator of this type
+   * is used to process the return values of the slot invocations.
+   * Otherwise, the return value of the last slot invoked is returned.
+   * @param _A_a1 Argument to be passed on to the slots.
+   * @param _A_a2 Argument to be passed on to the slots.
+   * @param _A_a3 Argument to be passed on to the slots.
+   * @param _A_a4 Argument to be passed on to the slots.
+   * @param _A_a5 Argument to be passed on to the slots.
+   * @param _A_a6 Argument to be passed on to the slots.
+   * @return The accumulated return values of the slot invocations.
+   */
+  result_type emit(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6) const
+    { return emitter_type::emit(impl_, _A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6); }
+
+  /** Triggers the emission of the signal (see emit()). */
+  result_type operator()(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6) const
+    { return emit(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6); }
+
+  /** Creates a functor that calls emit() on this signal.
+   * @code
+   * sigc::mem_fun(mysignal, &sigc::signal6::emit)
+   * @endcode
+   * yields the same result.
+   * @return A functor that calls emit() on this signal.
+   */
+  bound_const_mem_functor6<result_type, signal6, typename type_trait<T_arg1>::take,typename type_trait<T_arg2>::take,typename type_trait<T_arg3>::take,typename type_trait<T_arg4>::take,typename type_trait<T_arg5>::take,typename type_trait<T_arg6>::take> make_slot() const
+    { return bound_const_mem_functor6<result_type, signal6, typename type_trait<T_arg1>::take,typename type_trait<T_arg2>::take,typename type_trait<T_arg3>::take,typename type_trait<T_arg4>::take,typename type_trait<T_arg5>::take,typename type_trait<T_arg6>::take>(this, &signal6::emit); }
+
+  /** Creates an STL-style interface for the signal's list of slots.
+   * This interface supports iteration, insertion and removal of slots.
+   * @return An STL-style interface for the signal's list of slots.
+   */
+  slot_list_type slots()
+    { return slot_list_type(impl()); }
+
+  /** Creates an STL-style interface for the signal's list of slots.
+   * This interface supports iteration, insertion and removal of slots.
+   * @return An STL-style interface for the signal's list of slots.
+   */
+  const slot_list_type slots() const
+    { return slot_list_type(const_cast<signal6*>(this)->impl()); }
+
+  signal6() {}
+
+  signal6(const signal6& src)
+    : signal_base(src) {}
+};
+
+/** Signal declaration.
+ * signal7 can be used to connect() slots that are invoked
+ * during subsequent calls to emit(). Any functor or slot
+ * can be passed into connect(). It is converted into a slot
+ * implicitely.
+ *
+ * If you want to connect one signal to another, use make_slot()
+ * to retrieve a functor that emits the signal when invoked.
+ *
+ * Be careful if you directly pass one signal into the connect()
+ * method of another: a shallow copy of the signal is made and
+ * the signal's slots are not disconnected until both the signal
+ * and its clone are destroyed which is probably not what you want!
+ *
+ * An STL-style list interface for the signal's list of slots
+ * can be retrieved with slots(). This interface supports
+ * iteration, insertion and removal of slots.
+ *
+ * The following template arguments are used:
+ * - @e T_return The desired return type for the emit() function (may be overridden by the accumulator).
+ * - @e T_arg1 Argument type used in the definition of emit().
+ * - @e T_arg2 Argument type used in the definition of emit().
+ * - @e T_arg3 Argument type used in the definition of emit().
+ * - @e T_arg4 Argument type used in the definition of emit().
+ * - @e T_arg5 Argument type used in the definition of emit().
+ * - @e T_arg6 Argument type used in the definition of emit().
+ * - @e T_arg7 Argument type used in the definition of emit().
+ * - @e T_accumulator The accumulator type used for emission. The default @p nil means that no accumulator should be used, i.e. signal emission returns the return value of the last slot invoked.
+ *
+ * You should use the more convenient unnumbered sigc::signal template.
+ *
+ * @ingroup signal
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_accumulator=nil>
+class signal7
+  : public signal_base
+{
+public:
+  typedef internal::signal_emit7<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7, T_accumulator> emitter_type;
+  typedef typename emitter_type::result_type         result_type;
+  typedef slot<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>    slot_type;
+  typedef slot_list<slot_type>                       slot_list_type;
+  typedef typename slot_list_type::iterator               iterator;
+  typedef typename slot_list_type::const_iterator         const_iterator;
+  typedef typename slot_list_type::reverse_iterator       reverse_iterator;
+  typedef typename slot_list_type::const_reverse_iterator const_reverse_iterator;
+
+#ifdef SIGC_TYPEDEF_REDEFINE_ALLOWED
+  /** This typedef is only for backwards-compatibility.
+   * It is not available when using the SUN Forte compiler.
+   * @deprecated slot_list_type;
+   */
+  typedef slot_list_type slot_list;
+#endif
+
+  /** Add a slot to the list of slots.
+   * Any functor or slot may be passed into connect().
+   * It will be converted into a slot implicitely.
+   * The returned iterator may be stored for disconnection
+   * of the slot at some later point. It stays valid until
+   * the slot is removed from the list of slots. The iterator
+   * can also be implicitely converted into a sigc::connection object
+   * that may be used safely beyond the life time of the slot.
+   * @param slot_ The slot to add to the list of slots.
+   * @return An iterator pointing to the new slot in the list.
+   */
+  iterator connect(const slot_type& slot_)
+    { return iterator(signal_base::connect(static_cast<const slot_base&>(slot_))); }
+
+  /** Triggers the emission of the signal.
+   * During signal emission all slots that have been connected
+   * to the signal are invoked unless they are manually set into
+   * a blocking state. The parameters are passed on to the slots.
+   * If @e T_accumulated is not @p nil, an accumulator of this type
+   * is used to process the return values of the slot invocations.
+   * Otherwise, the return value of the last slot invoked is returned.
+   * @param _A_a1 Argument to be passed on to the slots.
+   * @param _A_a2 Argument to be passed on to the slots.
+   * @param _A_a3 Argument to be passed on to the slots.
+   * @param _A_a4 Argument to be passed on to the slots.
+   * @param _A_a5 Argument to be passed on to the slots.
+   * @param _A_a6 Argument to be passed on to the slots.
+   * @param _A_a7 Argument to be passed on to the slots.
+   * @return The accumulated return values of the slot invocations.
+   */
+  result_type emit(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6,typename type_trait<T_arg7>::take _A_a7) const
+    { return emitter_type::emit(impl_, _A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6,_A_a7); }
+
+  /** Triggers the emission of the signal (see emit()). */
+  result_type operator()(typename type_trait<T_arg1>::take _A_a1,typename type_trait<T_arg2>::take _A_a2,typename type_trait<T_arg3>::take _A_a3,typename type_trait<T_arg4>::take _A_a4,typename type_trait<T_arg5>::take _A_a5,typename type_trait<T_arg6>::take _A_a6,typename type_trait<T_arg7>::take _A_a7) const
+    { return emit(_A_a1,_A_a2,_A_a3,_A_a4,_A_a5,_A_a6,_A_a7); }
+
+  /** Creates a functor that calls emit() on this signal.
+   * @code
+   * sigc::mem_fun(mysignal, &sigc::signal7::emit)
+   * @endcode
+   * yields the same result.
+   * @return A functor that calls emit() on this signal.
+   */
+  bound_const_mem_functor7<result_type, signal7, typename type_trait<T_arg1>::take,typename type_trait<T_arg2>::take,typename type_trait<T_arg3>::take,typename type_trait<T_arg4>::take,typename type_trait<T_arg5>::take,typename type_trait<T_arg6>::take,typename type_trait<T_arg7>::take> make_slot() const
+    { return bound_const_mem_functor7<result_type, signal7, typename type_trait<T_arg1>::take,typename type_trait<T_arg2>::take,typename type_trait<T_arg3>::take,typename type_trait<T_arg4>::take,typename type_trait<T_arg5>::take,typename type_trait<T_arg6>::take,typename type_trait<T_arg7>::take>(this, &signal7::emit); }
+
+  /** Creates an STL-style interface for the signal's list of slots.
+   * This interface supports iteration, insertion and removal of slots.
+   * @return An STL-style interface for the signal's list of slots.
+   */
+  slot_list_type slots()
+    { return slot_list_type(impl()); }
+
+  /** Creates an STL-style interface for the signal's list of slots.
+   * This interface supports iteration, insertion and removal of slots.
+   * @return An STL-style interface for the signal's list of slots.
+   */
+  const slot_list_type slots() const
+    { return slot_list_type(const_cast<signal7*>(this)->impl()); }
+
+  signal7() {}
+
+  signal7(const signal7& src)
+    : signal_base(src) {}
+};
+
+
+
+/** Convenience wrapper for the numbered sigc::signal# templates.
+ * signal can be used to connect() slots that are invoked
+ * during subsequent calls to emit(). Any functor or slot
+ * can be passed into connect(). It is converted into a slot
+ * implicitly.
+ *
+ * If you want to connect one signal to another, use make_slot()
+ * to retrieve a functor that emits the signal when invoked.
+ *
+ * Be careful if you directly pass one signal into the connect()
+ * method of another: a shallow copy of the signal is made and
+ * the signal's slots are not disconnected until both the signal
+ * and its clone are destroyed which is probably not what you want!
+ *
+ * An STL-style list interface for the signal's list of slots
+ * can be retrieved with slots(). This interface supports
+ * iteration, insertion and removal of slots.
+ *
+ * The template arguments determine the function signature of
+ * the emit() function:
+ * - @e T_return The desired return type of the emit() function.
+ * - @e T_arg1 Argument type used in the definition of emit(). The default @p nil means no argument.
+ * - @e T_arg2 Argument type used in the definition of emit(). The default @p nil means no argument.
+ * - @e T_arg3 Argument type used in the definition of emit(). The default @p nil means no argument.
+ * - @e T_arg4 Argument type used in the definition of emit(). The default @p nil means no argument.
+ * - @e T_arg5 Argument type used in the definition of emit(). The default @p nil means no argument.
+ * - @e T_arg6 Argument type used in the definition of emit(). The default @p nil means no argument.
+ * - @e T_arg7 Argument type used in the definition of emit(). The default @p nil means no argument.
+ *
+ * To specify an accumulator type the nested class signal::accumulated can be used.
+ *
+ * @par Example:
+ *   @code
+ *   void foo(int) {}
+ *   sigc::signal<void, long> sig;
+ *   sig.connect(sigc::ptr_fun(&foo));
+ *   sig.emit(19);
+ *   @endcode
+ *
+ * @ingroup signal
+ */
+template <class T_return, class T_arg1 = nil,class T_arg2 = nil,class T_arg3 = nil,class T_arg4 = nil,class T_arg5 = nil,class T_arg6 = nil,class T_arg7 = nil>
+class signal 
+  : public signal7<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7, nil>
+{
+public:
+  /** Convenience wrapper for the numbered sigc::signal# templates.
+   * Like sigc::signal but the additional template parameter @e T_accumulator
+   * defines the accumulator type that should be used.
+   *
+   * An accumulator is a functor that uses a pair of special iterators
+   * to step through a list of slots and calculate a return value
+   * from the results of the slot invokations. The iterators' operator*()
+   * executes the slot. The return value is buffered, so that in an expression
+   * like @code a = (*i) * (*i); @endcode the slot is executed only once.
+   * The accumulator must define its return value as @p result_type.
+   * 
+   * @par Example 1:
+   *   This accumulator calculates the arithmetic mean value:
+   *   @code
+   *   struct arithmetic_mean_accumulator
+   *   {
+   *     typedef double result_type;
+   *     template<typename T_iterator>
+   *     result_type operator()(T_iterator first, T_iterator last) const
+   *     {
+   *       result_type value_ = 0;
+   *       int n_ = 0;
+   *       for (; first != last; ++first, ++n_)
+   *         value_ += *first;
+   *       return value_ / n_;
+   *     }
+   *   };
+   *   @endcode
+   *
+   * @par Example 2:
+   *   This accumulator stops signal emission when a slot returns zero:
+   *   @code
+   *   struct interruptable_accumulator
+   *   {
+   *     typedef bool result_type;
+   *     template<typename T_iterator>
+   *     result_type operator()(T_iterator first, T_iterator last) const
+   *     {
+   *       for (; first != last; ++first, ++n_)
+   *         if (!*first) return false;
+   *       return true;
+   *     }
+   *   };
+   *   @endcode
+   *
+   * @ingroup signal
+   */
+  template <class T_accumulator>
+  class accumulated
+    : public signal7<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7, T_accumulator>
+  {
+  public:
+    accumulated() {}
+    accumulated(const accumulated& src)
+      : signal7<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7, T_accumulator>(src) {}
+  };
+
+  signal() {}
+  signal(const signal& src)
+    : signal7<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7, nil>(src) {}
+};
+
+
+/** Convenience wrapper for the numbered sigc::signal0 template.
+ * See the base class for useful methods.
+ * This is the template specialization of the unnumbered sigc::signal
+ * template for 0 argument(s).
+ */
+template <class T_return>
+class signal <T_return>
+  : public signal0<T_return, nil>
+{
+public:
+
+  /** Convenience wrapper for the numbered sigc::signal0 template.
+   * Like sigc::signal but the additional template parameter @e T_accumulator
+   * defines the accumulator type that should be used.
+   */
+  template <class T_accumulator>
+  class accumulated
+    : public signal0<T_return, T_accumulator>
+  {
+  public:
+    accumulated() {}
+    accumulated(const accumulated& src)
+      : signal0<T_return, T_accumulator>(src) {}
+  };
+
+  signal() {}
+  signal(const signal& src)
+    : signal0<T_return, nil>(src) {}
+};
+
+/** Convenience wrapper for the numbered sigc::signal1 template.
+ * See the base class for useful methods.
+ * This is the template specialization of the unnumbered sigc::signal
+ * template for 1 argument(s).
+ */
+template <class T_return, class T_arg1>
+class signal <T_return, T_arg1>
+  : public signal1<T_return, T_arg1, nil>
+{
+public:
+
+  /** Convenience wrapper for the numbered sigc::signal1 template.
+   * Like sigc::signal but the additional template parameter @e T_accumulator
+   * defines the accumulator type that should be used.
+   */
+  template <class T_accumulator>
+  class accumulated
+    : public signal1<T_return, T_arg1, T_accumulator>
+  {
+  public:
+    accumulated() {}
+    accumulated(const accumulated& src)
+      : signal1<T_return, T_arg1, T_accumulator>(src) {}
+  };
+
+  signal() {}
+  signal(const signal& src)
+    : signal1<T_return, T_arg1, nil>(src) {}
+};
+
+/** Convenience wrapper for the numbered sigc::signal2 template.
+ * See the base class for useful methods.
+ * This is the template specialization of the unnumbered sigc::signal
+ * template for 2 argument(s).
+ */
+template <class T_return, class T_arg1,class T_arg2>
+class signal <T_return, T_arg1,T_arg2>
+  : public signal2<T_return, T_arg1,T_arg2, nil>
+{
+public:
+
+  /** Convenience wrapper for the numbered sigc::signal2 template.
+   * Like sigc::signal but the additional template parameter @e T_accumulator
+   * defines the accumulator type that should be used.
+   */
+  template <class T_accumulator>
+  class accumulated
+    : public signal2<T_return, T_arg1,T_arg2, T_accumulator>
+  {
+  public:
+    accumulated() {}
+    accumulated(const accumulated& src)
+      : signal2<T_return, T_arg1,T_arg2, T_accumulator>(src) {}
+  };
+
+  signal() {}
+  signal(const signal& src)
+    : signal2<T_return, T_arg1,T_arg2, nil>(src) {}
+};
+
+/** Convenience wrapper for the numbered sigc::signal3 template.
+ * See the base class for useful methods.
+ * This is the template specialization of the unnumbered sigc::signal
+ * template for 3 argument(s).
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3>
+class signal <T_return, T_arg1,T_arg2,T_arg3>
+  : public signal3<T_return, T_arg1,T_arg2,T_arg3, nil>
+{
+public:
+
+  /** Convenience wrapper for the numbered sigc::signal3 template.
+   * Like sigc::signal but the additional template parameter @e T_accumulator
+   * defines the accumulator type that should be used.
+   */
+  template <class T_accumulator>
+  class accumulated
+    : public signal3<T_return, T_arg1,T_arg2,T_arg3, T_accumulator>
+  {
+  public:
+    accumulated() {}
+    accumulated(const accumulated& src)
+      : signal3<T_return, T_arg1,T_arg2,T_arg3, T_accumulator>(src) {}
+  };
+
+  signal() {}
+  signal(const signal& src)
+    : signal3<T_return, T_arg1,T_arg2,T_arg3, nil>(src) {}
+};
+
+/** Convenience wrapper for the numbered sigc::signal4 template.
+ * See the base class for useful methods.
+ * This is the template specialization of the unnumbered sigc::signal
+ * template for 4 argument(s).
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+class signal <T_return, T_arg1,T_arg2,T_arg3,T_arg4>
+  : public signal4<T_return, T_arg1,T_arg2,T_arg3,T_arg4, nil>
+{
+public:
+
+  /** Convenience wrapper for the numbered sigc::signal4 template.
+   * Like sigc::signal but the additional template parameter @e T_accumulator
+   * defines the accumulator type that should be used.
+   */
+  template <class T_accumulator>
+  class accumulated
+    : public signal4<T_return, T_arg1,T_arg2,T_arg3,T_arg4, T_accumulator>
+  {
+  public:
+    accumulated() {}
+    accumulated(const accumulated& src)
+      : signal4<T_return, T_arg1,T_arg2,T_arg3,T_arg4, T_accumulator>(src) {}
+  };
+
+  signal() {}
+  signal(const signal& src)
+    : signal4<T_return, T_arg1,T_arg2,T_arg3,T_arg4, nil>(src) {}
+};
+
+/** Convenience wrapper for the numbered sigc::signal5 template.
+ * See the base class for useful methods.
+ * This is the template specialization of the unnumbered sigc::signal
+ * template for 5 argument(s).
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+class signal <T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+  : public signal5<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5, nil>
+{
+public:
+
+  /** Convenience wrapper for the numbered sigc::signal5 template.
+   * Like sigc::signal but the additional template parameter @e T_accumulator
+   * defines the accumulator type that should be used.
+   */
+  template <class T_accumulator>
+  class accumulated
+    : public signal5<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5, T_accumulator>
+  {
+  public:
+    accumulated() {}
+    accumulated(const accumulated& src)
+      : signal5<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5, T_accumulator>(src) {}
+  };
+
+  signal() {}
+  signal(const signal& src)
+    : signal5<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5, nil>(src) {}
+};
+
+/** Convenience wrapper for the numbered sigc::signal6 template.
+ * See the base class for useful methods.
+ * This is the template specialization of the unnumbered sigc::signal
+ * template for 6 argument(s).
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+class signal <T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+  : public signal6<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6, nil>
+{
+public:
+
+  /** Convenience wrapper for the numbered sigc::signal6 template.
+   * Like sigc::signal but the additional template parameter @e T_accumulator
+   * defines the accumulator type that should be used.
+   */
+  template <class T_accumulator>
+  class accumulated
+    : public signal6<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6, T_accumulator>
+  {
+  public:
+    accumulated() {}
+    accumulated(const accumulated& src)
+      : signal6<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6, T_accumulator>(src) {}
+  };
+
+  signal() {}
+  signal(const signal& src)
+    : signal6<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6, nil>(src) {}
+};
+
+
+
+} /* namespace sigc */
+
+
+#ifndef LIBSIGC_DISABLE_DEPRECATED
+
+namespace SigC {
+
+// SignalN
+/** Signal declaration.
+ * Signal0 can be used to connect() slots that are invoked
+ * during subsequent calls to emit(). Any functor or slot
+ * can be passed into connect(). It is converted into a slot
+ * implicitely.
+ *
+ * If you want to connect one signal to another, use slot()
+ * to retrieve a functor that emits the signal when invoked.
+ *
+ * Be careful if you directly pass one signal into the connect()
+ * method of another: a shallow copy of the signal is made and
+ * the signal's slots are not disconnected until both the signal
+ * and its clone are destroyed which is probably not what you want!
+ *
+ * An STL-style list interface for the signal's list of slots
+ * can be retrieved with slots(). This interface supports
+ * iteration, insertion and removal of slots.
+ *
+ * The following template arguments are used:
+ * - @e T_return The desired return type for the emit() function (may be overridden by the accumulator).
+ * - @e T_accumulator The accumulator type used for emission. The default @p nil means that no accumulator should be used. Signal emission returns the return value of the last slot invoked.
+ *
+ * @deprecated Use the unnumbered template sigc::signal instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_accumulator=::sigc::nil>
+class Signal0
+  : public ::sigc::signal0<T_return, T_accumulator>
+{
+public:
+  typedef ::sigc::signal0<T_return, T_accumulator> parent_type;
+  typedef typename parent_type::result_type result_type;
+  typedef typename parent_type::slot_type slot_type;
+
+  Signal0() {}
+  Signal0(const Signal0& src)
+    : ::sigc::signal0<T_return, T_accumulator>(src) {}
+
+  /** Creates a functor that calls emit() on this signal.
+   * @code
+   * sigc::mem_fun(mysignal, &sigc::signal0::emit)
+   * @endcode
+   * yields the same result.
+   * @return A functor that calls emit() on this signal.
+   */
+  slot_type slot() const
+    { return ::sigc::bound_const_mem_functor0<result_type, parent_type>(this, &parent_type::emit); }
+};
+
+/** Signal declaration.
+ * Signal1 can be used to connect() slots that are invoked
+ * during subsequent calls to emit(). Any functor or slot
+ * can be passed into connect(). It is converted into a slot
+ * implicitely.
+ *
+ * If you want to connect one signal to another, use slot()
+ * to retrieve a functor that emits the signal when invoked.
+ *
+ * Be careful if you directly pass one signal into the connect()
+ * method of another: a shallow copy of the signal is made and
+ * the signal's slots are not disconnected until both the signal
+ * and its clone are destroyed which is probably not what you want!
+ *
+ * An STL-style list interface for the signal's list of slots
+ * can be retrieved with slots(). This interface supports
+ * iteration, insertion and removal of slots.
+ *
+ * The following template arguments are used:
+ * - @e T_return The desired return type for the emit() function (may be overridden by the accumulator).
+ * - @e T_arg1 Argument type used in the definition of emit().
+ * - @e T_accumulator The accumulator type used for emission. The default @p nil means that no accumulator should be used. Signal emission returns the return value of the last slot invoked.
+ *
+ * @deprecated Use the unnumbered template sigc::signal instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1, class T_accumulator=::sigc::nil>
+class Signal1
+  : public ::sigc::signal1<T_return, T_arg1, T_accumulator>
+{
+public:
+  typedef ::sigc::signal1<T_return, T_arg1, T_accumulator> parent_type;
+  typedef typename parent_type::result_type result_type;
+  typedef typename parent_type::slot_type slot_type;
+
+  Signal1() {}
+  Signal1(const Signal1& src)
+    : ::sigc::signal1<T_return, T_arg1, T_accumulator>(src) {}
+
+  /** Creates a functor that calls emit() on this signal.
+   * @code
+   * sigc::mem_fun(mysignal, &sigc::signal1::emit)
+   * @endcode
+   * yields the same result.
+   * @return A functor that calls emit() on this signal.
+   */
+  slot_type slot() const
+    { return ::sigc::bound_const_mem_functor1<result_type, parent_type, typename ::sigc::type_trait<T_arg1>::take>(this, &parent_type::emit); }
+};
+
+/** Signal declaration.
+ * Signal2 can be used to connect() slots that are invoked
+ * during subsequent calls to emit(). Any functor or slot
+ * can be passed into connect(). It is converted into a slot
+ * implicitely.
+ *
+ * If you want to connect one signal to another, use slot()
+ * to retrieve a functor that emits the signal when invoked.
+ *
+ * Be careful if you directly pass one signal into the connect()
+ * method of another: a shallow copy of the signal is made and
+ * the signal's slots are not disconnected until both the signal
+ * and its clone are destroyed which is probably not what you want!
+ *
+ * An STL-style list interface for the signal's list of slots
+ * can be retrieved with slots(). This interface supports
+ * iteration, insertion and removal of slots.
+ *
+ * The following template arguments are used:
+ * - @e T_return The desired return type for the emit() function (may be overridden by the accumulator).
+ * - @e T_arg1 Argument type used in the definition of emit().
+ * - @e T_arg2 Argument type used in the definition of emit().
+ * - @e T_accumulator The accumulator type used for emission. The default @p nil means that no accumulator should be used. Signal emission returns the return value of the last slot invoked.
+ *
+ * @deprecated Use the unnumbered template sigc::signal instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2, class T_accumulator=::sigc::nil>
+class Signal2
+  : public ::sigc::signal2<T_return, T_arg1,T_arg2, T_accumulator>
+{
+public:
+  typedef ::sigc::signal2<T_return, T_arg1,T_arg2, T_accumulator> parent_type;
+  typedef typename parent_type::result_type result_type;
+  typedef typename parent_type::slot_type slot_type;
+
+  Signal2() {}
+  Signal2(const Signal2& src)
+    : ::sigc::signal2<T_return, T_arg1,T_arg2, T_accumulator>(src) {}
+
+  /** Creates a functor that calls emit() on this signal.
+   * @code
+   * sigc::mem_fun(mysignal, &sigc::signal2::emit)
+   * @endcode
+   * yields the same result.
+   * @return A functor that calls emit() on this signal.
+   */
+  slot_type slot() const
+    { return ::sigc::bound_const_mem_functor2<result_type, parent_type, typename ::sigc::type_trait<T_arg1>::take,typename ::sigc::type_trait<T_arg2>::take>(this, &parent_type::emit); }
+};
+
+/** Signal declaration.
+ * Signal3 can be used to connect() slots that are invoked
+ * during subsequent calls to emit(). Any functor or slot
+ * can be passed into connect(). It is converted into a slot
+ * implicitely.
+ *
+ * If you want to connect one signal to another, use slot()
+ * to retrieve a functor that emits the signal when invoked.
+ *
+ * Be careful if you directly pass one signal into the connect()
+ * method of another: a shallow copy of the signal is made and
+ * the signal's slots are not disconnected until both the signal
+ * and its clone are destroyed which is probably not what you want!
+ *
+ * An STL-style list interface for the signal's list of slots
+ * can be retrieved with slots(). This interface supports
+ * iteration, insertion and removal of slots.
+ *
+ * The following template arguments are used:
+ * - @e T_return The desired return type for the emit() function (may be overridden by the accumulator).
+ * - @e T_arg1 Argument type used in the definition of emit().
+ * - @e T_arg2 Argument type used in the definition of emit().
+ * - @e T_arg3 Argument type used in the definition of emit().
+ * - @e T_accumulator The accumulator type used for emission. The default @p nil means that no accumulator should be used. Signal emission returns the return value of the last slot invoked.
+ *
+ * @deprecated Use the unnumbered template sigc::signal instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3, class T_accumulator=::sigc::nil>
+class Signal3
+  : public ::sigc::signal3<T_return, T_arg1,T_arg2,T_arg3, T_accumulator>
+{
+public:
+  typedef ::sigc::signal3<T_return, T_arg1,T_arg2,T_arg3, T_accumulator> parent_type;
+  typedef typename parent_type::result_type result_type;
+  typedef typename parent_type::slot_type slot_type;
+
+  Signal3() {}
+  Signal3(const Signal3& src)
+    : ::sigc::signal3<T_return, T_arg1,T_arg2,T_arg3, T_accumulator>(src) {}
+
+  /** Creates a functor that calls emit() on this signal.
+   * @code
+   * sigc::mem_fun(mysignal, &sigc::signal3::emit)
+   * @endcode
+   * yields the same result.
+   * @return A functor that calls emit() on this signal.
+   */
+  slot_type slot() const
+    { return ::sigc::bound_const_mem_functor3<result_type, parent_type, typename ::sigc::type_trait<T_arg1>::take,typename ::sigc::type_trait<T_arg2>::take,typename ::sigc::type_trait<T_arg3>::take>(this, &parent_type::emit); }
+};
+
+/** Signal declaration.
+ * Signal4 can be used to connect() slots that are invoked
+ * during subsequent calls to emit(). Any functor or slot
+ * can be passed into connect(). It is converted into a slot
+ * implicitely.
+ *
+ * If you want to connect one signal to another, use slot()
+ * to retrieve a functor that emits the signal when invoked.
+ *
+ * Be careful if you directly pass one signal into the connect()
+ * method of another: a shallow copy of the signal is made and
+ * the signal's slots are not disconnected until both the signal
+ * and its clone are destroyed which is probably not what you want!
+ *
+ * An STL-style list interface for the signal's list of slots
+ * can be retrieved with slots(). This interface supports
+ * iteration, insertion and removal of slots.
+ *
+ * The following template arguments are used:
+ * - @e T_return The desired return type for the emit() function (may be overridden by the accumulator).
+ * - @e T_arg1 Argument type used in the definition of emit().
+ * - @e T_arg2 Argument type used in the definition of emit().
+ * - @e T_arg3 Argument type used in the definition of emit().
+ * - @e T_arg4 Argument type used in the definition of emit().
+ * - @e T_accumulator The accumulator type used for emission. The default @p nil means that no accumulator should be used. Signal emission returns the return value of the last slot invoked.
+ *
+ * @deprecated Use the unnumbered template sigc::signal instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4, class T_accumulator=::sigc::nil>
+class Signal4
+  : public ::sigc::signal4<T_return, T_arg1,T_arg2,T_arg3,T_arg4, T_accumulator>
+{
+public:
+  typedef ::sigc::signal4<T_return, T_arg1,T_arg2,T_arg3,T_arg4, T_accumulator> parent_type;
+  typedef typename parent_type::result_type result_type;
+  typedef typename parent_type::slot_type slot_type;
+
+  Signal4() {}
+  Signal4(const Signal4& src)
+    : ::sigc::signal4<T_return, T_arg1,T_arg2,T_arg3,T_arg4, T_accumulator>(src) {}
+
+  /** Creates a functor that calls emit() on this signal.
+   * @code
+   * sigc::mem_fun(mysignal, &sigc::signal4::emit)
+   * @endcode
+   * yields the same result.
+   * @return A functor that calls emit() on this signal.
+   */
+  slot_type slot() const
+    { return ::sigc::bound_const_mem_functor4<result_type, parent_type, typename ::sigc::type_trait<T_arg1>::take,typename ::sigc::type_trait<T_arg2>::take,typename ::sigc::type_trait<T_arg3>::take,typename ::sigc::type_trait<T_arg4>::take>(this, &parent_type::emit); }
+};
+
+/** Signal declaration.
+ * Signal5 can be used to connect() slots that are invoked
+ * during subsequent calls to emit(). Any functor or slot
+ * can be passed into connect(). It is converted into a slot
+ * implicitely.
+ *
+ * If you want to connect one signal to another, use slot()
+ * to retrieve a functor that emits the signal when invoked.
+ *
+ * Be careful if you directly pass one signal into the connect()
+ * method of another: a shallow copy of the signal is made and
+ * the signal's slots are not disconnected until both the signal
+ * and its clone are destroyed which is probably not what you want!
+ *
+ * An STL-style list interface for the signal's list of slots
+ * can be retrieved with slots(). This interface supports
+ * iteration, insertion and removal of slots.
+ *
+ * The following template arguments are used:
+ * - @e T_return The desired return type for the emit() function (may be overridden by the accumulator).
+ * - @e T_arg1 Argument type used in the definition of emit().
+ * - @e T_arg2 Argument type used in the definition of emit().
+ * - @e T_arg3 Argument type used in the definition of emit().
+ * - @e T_arg4 Argument type used in the definition of emit().
+ * - @e T_arg5 Argument type used in the definition of emit().
+ * - @e T_accumulator The accumulator type used for emission. The default @p nil means that no accumulator should be used. Signal emission returns the return value of the last slot invoked.
+ *
+ * @deprecated Use the unnumbered template sigc::signal instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5, class T_accumulator=::sigc::nil>
+class Signal5
+  : public ::sigc::signal5<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5, T_accumulator>
+{
+public:
+  typedef ::sigc::signal5<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5, T_accumulator> parent_type;
+  typedef typename parent_type::result_type result_type;
+  typedef typename parent_type::slot_type slot_type;
+
+  Signal5() {}
+  Signal5(const Signal5& src)
+    : ::sigc::signal5<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5, T_accumulator>(src) {}
+
+  /** Creates a functor that calls emit() on this signal.
+   * @code
+   * sigc::mem_fun(mysignal, &sigc::signal5::emit)
+   * @endcode
+   * yields the same result.
+   * @return A functor that calls emit() on this signal.
+   */
+  slot_type slot() const
+    { return ::sigc::bound_const_mem_functor5<result_type, parent_type, typename ::sigc::type_trait<T_arg1>::take,typename ::sigc::type_trait<T_arg2>::take,typename ::sigc::type_trait<T_arg3>::take,typename ::sigc::type_trait<T_arg4>::take,typename ::sigc::type_trait<T_arg5>::take>(this, &parent_type::emit); }
+};
+
+/** Signal declaration.
+ * Signal6 can be used to connect() slots that are invoked
+ * during subsequent calls to emit(). Any functor or slot
+ * can be passed into connect(). It is converted into a slot
+ * implicitely.
+ *
+ * If you want to connect one signal to another, use slot()
+ * to retrieve a functor that emits the signal when invoked.
+ *
+ * Be careful if you directly pass one signal into the connect()
+ * method of another: a shallow copy of the signal is made and
+ * the signal's slots are not disconnected until both the signal
+ * and its clone are destroyed which is probably not what you want!
+ *
+ * An STL-style list interface for the signal's list of slots
+ * can be retrieved with slots(). This interface supports
+ * iteration, insertion and removal of slots.
+ *
+ * The following template arguments are used:
+ * - @e T_return The desired return type for the emit() function (may be overridden by the accumulator).
+ * - @e T_arg1 Argument type used in the definition of emit().
+ * - @e T_arg2 Argument type used in the definition of emit().
+ * - @e T_arg3 Argument type used in the definition of emit().
+ * - @e T_arg4 Argument type used in the definition of emit().
+ * - @e T_arg5 Argument type used in the definition of emit().
+ * - @e T_arg6 Argument type used in the definition of emit().
+ * - @e T_accumulator The accumulator type used for emission. The default @p nil means that no accumulator should be used. Signal emission returns the return value of the last slot invoked.
+ *
+ * @deprecated Use the unnumbered template sigc::signal instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6, class T_accumulator=::sigc::nil>
+class Signal6
+  : public ::sigc::signal6<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6, T_accumulator>
+{
+public:
+  typedef ::sigc::signal6<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6, T_accumulator> parent_type;
+  typedef typename parent_type::result_type result_type;
+  typedef typename parent_type::slot_type slot_type;
+
+  Signal6() {}
+  Signal6(const Signal6& src)
+    : ::sigc::signal6<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6, T_accumulator>(src) {}
+
+  /** Creates a functor that calls emit() on this signal.
+   * @code
+   * sigc::mem_fun(mysignal, &sigc::signal6::emit)
+   * @endcode
+   * yields the same result.
+   * @return A functor that calls emit() on this signal.
+   */
+  slot_type slot() const
+    { return ::sigc::bound_const_mem_functor6<result_type, parent_type, typename ::sigc::type_trait<T_arg1>::take,typename ::sigc::type_trait<T_arg2>::take,typename ::sigc::type_trait<T_arg3>::take,typename ::sigc::type_trait<T_arg4>::take,typename ::sigc::type_trait<T_arg5>::take,typename ::sigc::type_trait<T_arg6>::take>(this, &parent_type::emit); }
+};
+
+/** Signal declaration.
+ * Signal7 can be used to connect() slots that are invoked
+ * during subsequent calls to emit(). Any functor or slot
+ * can be passed into connect(). It is converted into a slot
+ * implicitely.
+ *
+ * If you want to connect one signal to another, use slot()
+ * to retrieve a functor that emits the signal when invoked.
+ *
+ * Be careful if you directly pass one signal into the connect()
+ * method of another: a shallow copy of the signal is made and
+ * the signal's slots are not disconnected until both the signal
+ * and its clone are destroyed which is probably not what you want!
+ *
+ * An STL-style list interface for the signal's list of slots
+ * can be retrieved with slots(). This interface supports
+ * iteration, insertion and removal of slots.
+ *
+ * The following template arguments are used:
+ * - @e T_return The desired return type for the emit() function (may be overridden by the accumulator).
+ * - @e T_arg1 Argument type used in the definition of emit().
+ * - @e T_arg2 Argument type used in the definition of emit().
+ * - @e T_arg3 Argument type used in the definition of emit().
+ * - @e T_arg4 Argument type used in the definition of emit().
+ * - @e T_arg5 Argument type used in the definition of emit().
+ * - @e T_arg6 Argument type used in the definition of emit().
+ * - @e T_arg7 Argument type used in the definition of emit().
+ * - @e T_accumulator The accumulator type used for emission. The default @p nil means that no accumulator should be used. Signal emission returns the return value of the last slot invoked.
+ *
+ * @deprecated Use the unnumbered template sigc::signal instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7, class T_accumulator=::sigc::nil>
+class Signal7
+  : public ::sigc::signal7<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7, T_accumulator>
+{
+public:
+  typedef ::sigc::signal7<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7, T_accumulator> parent_type;
+  typedef typename parent_type::result_type result_type;
+  typedef typename parent_type::slot_type slot_type;
+
+  Signal7() {}
+  Signal7(const Signal7& src)
+    : ::sigc::signal7<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7, T_accumulator>(src) {}
+
+  /** Creates a functor that calls emit() on this signal.
+   * @code
+   * sigc::mem_fun(mysignal, &sigc::signal7::emit)
+   * @endcode
+   * yields the same result.
+   * @return A functor that calls emit() on this signal.
+   */
+  slot_type slot() const
+    { return ::sigc::bound_const_mem_functor7<result_type, parent_type, typename ::sigc::type_trait<T_arg1>::take,typename ::sigc::type_trait<T_arg2>::take,typename ::sigc::type_trait<T_arg3>::take,typename ::sigc::type_trait<T_arg4>::take,typename ::sigc::type_trait<T_arg5>::take,typename ::sigc::type_trait<T_arg6>::take,typename ::sigc::type_trait<T_arg7>::take>(this, &parent_type::emit); }
+};
+
+
+}
+
+#endif /* LIBSIGC_DISABLE_DEPRECATED */
+
+#endif /* _SIGC_SIGNAL_H_ */
diff --git a/libs/sigc++2/sigc++/signal_base.cc b/libs/sigc++2/sigc++/signal_base.cc
new file mode 100644
index 0000000000..568cf061c8
--- /dev/null
+++ b/libs/sigc++2/sigc++/signal_base.cc
@@ -0,0 +1,151 @@
+// -*- c++ -*-
+/*
+ * Copyright 2003, The libsigc++ Development Team
+ *
+ *  This library is free software; you can redistribute it and/or
+ *  modify it under the terms of the GNU Lesser General Public
+ *  License as published by the Free Software Foundation; either
+ *  version 2.1 of the License, or (at your option) any later version.
+ *
+ *  This library is distributed in the hope that it will be useful,
+ *  but WITHOUT ANY WARRANTY; without even the implied warranty of
+ *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
+ *  Lesser General Public License for more details.
+ *
+ *  You should have received a copy of the GNU Lesser General Public
+ *  License along with this library; if not, write to the Free Software
+ *  Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
+ *
+ */
+#include <sigc++/signal_base.h>
+
+namespace sigc {
+namespace internal {
+
+signal_impl::signal_impl()
+: ref_count_(0), exec_count_(0), deferred_(0)
+{}
+
+// only MSVC needs this to guarantee that all new/delete are executed from the DLL module
+#ifdef SIGC_NEW_DELETE_IN_LIBRARY_ONLY
+void* signal_impl::operator new(size_t size_)
+{
+  return malloc(size_);
+}
+
+void signal_impl::operator delete(void* p)
+{
+  free(p);
+}
+#endif
+
+void signal_impl::clear()
+{
+  slots_.clear();
+}
+
+signal_impl::size_type signal_impl::size() const
+{
+  return slots_.size();
+}
+
+signal_impl::iterator_type signal_impl::connect(const slot_base& slot_)
+{
+  return insert(slots_.end(), slot_);
+}
+
+signal_impl::iterator_type signal_impl::erase(iterator_type i)
+{
+  return slots_.erase(i);
+}
+    
+signal_impl::iterator_type signal_impl::insert(signal_impl::iterator_type i, const slot_base& slot_)
+{
+  iterator_type temp = slots_.insert(i, slot_);
+  temp->set_parent(this, &notify);
+  return temp;
+}
+
+void signal_impl::sweep()
+{
+  iterator_type i = slots_.begin();
+  while (i != slots_.end())
+    if ((*i).empty())
+      i = slots_.erase(i);
+    else
+      ++i;
+}
+
+void* signal_impl::notify(void* d)
+{
+  signal_impl* self = (signal_impl*)d;
+  if (self->exec_count_ == 0)
+    self->sweep();
+  else                       // This is occuring during signal emission.
+    self->deferred_ = true;  // => sweep() will be called from ~signal_exec().
+  return 0;                  // This is safer because we don't have to care about our iterators in emit().
+}
+
+} /* namespace internal */
+
+signal_base::signal_base()
+: impl_(0)
+{}
+
+signal_base::signal_base(const signal_base& src)
+: trackable(),
+  impl_(src.impl())
+{
+  impl_->reference();
+}
+
+signal_base::~signal_base()
+{
+  if (impl_)
+    impl_->unreference();
+}
+
+void signal_base::clear()
+{
+  if (impl_)
+    impl_->clear();
+}
+
+signal_base::size_type signal_base::size() const
+{
+  return (impl_ ? impl_->size() : 0);
+}
+
+signal_base::iterator_type signal_base::connect(const slot_base& slot_)
+{
+  return impl()->connect(slot_);
+}
+
+signal_base::iterator_type signal_base::insert(iterator_type i, const slot_base& slot_)
+{
+  return impl()->insert(i, slot_);
+}
+
+signal_base::iterator_type signal_base::erase(iterator_type i)
+{
+  return impl()->erase(i);
+}
+
+signal_base& signal_base::operator = (const signal_base& src)
+{
+  if (impl_) impl_->unreference();
+  impl_ = src.impl();
+  impl_->reference();
+  return *this;
+}
+
+internal::signal_impl* signal_base::impl() const
+{
+  if (!impl_) {
+    impl_ = new internal::signal_impl;
+    impl_->reference();  // start with a reference count of 1
+  }
+  return impl_;
+}
+
+} /* sigc */
diff --git a/libs/sigc++2/sigc++/signal_base.h b/libs/sigc++2/sigc++/signal_base.h
new file mode 100644
index 0000000000..3af33d3e99
--- /dev/null
+++ b/libs/sigc++2/sigc++/signal_base.h
@@ -0,0 +1,261 @@
+// -*- c++ -*-
+/*
+ * Copyright 2002, The libsigc++ Development Team
+ *
+ *  This library is free software; you can redistribute it and/or
+ *  modify it under the terms of the GNU Lesser General Public
+ *  License as published by the Free Software Foundation; either
+ *  version 2.1 of the License, or (at your option) any later version.
+ *
+ *  This library is distributed in the hope that it will be useful,
+ *  but WITHOUT ANY WARRANTY; without even the implied warranty of
+ *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
+ *  Lesser General Public License for more details.
+ *
+ *  You should have received a copy of the GNU Lesser General Public
+ *  License along with this library; if not, write to the Free Software
+ *  Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
+ *
+ */
+
+#ifndef _SIGC_SIGNAL_BASE_H_
+#define _SIGC_SIGNAL_BASE_H_
+
+#include <list>
+#include <sigc++config.h>
+#include <sigc++/type_traits.h>
+#include <sigc++/trackable.h>
+#include <sigc++/functors/slot.h>
+#include <sigc++/functors/mem_fun.h>
+
+namespace sigc
+{
+
+namespace internal
+{
+
+/** Implementation of the signal interface.
+ * signal_impl manages a list of slots. When a slot becomes
+ * invalid (because some referred object dies), notify() is executed.
+ * notify() either calls sweep() directly or defers the execution of
+ * sweep() when the signal is being emitted. sweep() removes all
+ * invalid slot from the list.
+ */
+struct SIGC_API signal_impl
+{
+  typedef size_t size_type;
+  typedef std::list<slot_base>::iterator       iterator_type;
+  typedef std::list<slot_base>::const_iterator const_iterator_type;
+
+  signal_impl();
+
+  // only MSVC needs this to guarantee that all new/delete are executed from the DLL module
+#ifdef SIGC_NEW_DELETE_IN_LIBRARY_ONLY
+  void* operator new(size_t size_);
+  void operator delete(void* p);
+#endif
+
+  /// Increments the reference counter.
+  inline void reference()
+    { ++ref_count_; }
+
+  /// Increments the reference and execution counter.
+  inline void reference_exec()
+    { ++ref_count_; ++exec_count_; }
+
+  /** Decrements the reference counter.
+   * The object is deleted when the reference counter reaches zero.
+   */
+  inline void unreference()
+    { if (!(--ref_count_)) delete this; }
+
+  /** Decrements the reference and execution counter.
+   * Invokes sweep() if the execution counter reaches zero and the
+   * removal of one or more slots has been deferred.
+   */
+  inline void unreference_exec()
+    {
+      if (!(--ref_count_)) delete this;
+      else if (!(--exec_count_) && deferred_) sweep();
+    }
+
+  /** Returns whether the list of slots is empty.
+   * @return @p true if the list of slots is empty.
+   */
+  inline bool empty() const
+    { return slots_.empty(); }
+
+  /// Empties the list of slots.
+  void clear();
+
+  /** Returns the number of slots in the list.
+   * @return The number of slots in the list.
+   */
+  size_type size() const;
+
+  /** Adds a slot at the bottom of the list of slots.
+   * @param slot_ The slot to add to the list of slots.
+   * @return An iterator pointing to the new slot in the list.
+   */
+  iterator_type connect(const slot_base& slot_);
+
+  /** Adds a slot at the given position into the list of slots.
+   * @param i An iterator indicating the position where @p slot_ should be inserted.
+   * @param slot_ The slot to add to the list of slots.
+   * @return An iterator pointing to the new slot in the list.
+   */
+  iterator_type insert(iterator_type i, const slot_base& slot_);
+
+  /** Removes the slot at the given position from the list of slots.
+   * @param i An iterator pointing to the slot to be removed.
+   * @return An iterator pointing to the slot in the list after the one removed.
+   */
+  iterator_type erase(iterator_type i);
+
+  /// Removes invalid slots from the list of slots.
+  void sweep();
+
+  /** Callback that is executed when some slot becomes invalid.
+   * This callback is registered in every slot when inserted into
+   * the list of slots. It is executed when a slot becomes invalid
+   * because of some referred object being destroyed.
+   * It either calls sweep() directly or defers the execution of
+   * sweep() when the signal is being emitted.
+   * @param d The signal object (@p this).
+   */
+  static void* notify(void* d);
+
+  /** Reference counter.
+   * The object is destroyed when @em ref_count_ reaches zero.
+   */
+  short ref_count_;
+
+  /** Execution counter.
+   * Indicates whether the signal is being emitted.
+   */
+  short exec_count_;
+
+  /// Indicates whether the execution of sweep() is being deferred.
+  bool deferred_;
+
+  /// The list of slots.
+  std::list<slot_base> slots_;
+};
+
+/// Exception safe sweeper for cleaning up invalid slots on the slot list.
+struct SIGC_API signal_exec
+{
+  /// The parent sigc::signal_impl object.
+  signal_impl* sig_;
+
+  /** Increments the reference and execution counter of the parent sigc::signal_impl object.
+   * @param sig The parent sigc::signal_impl object.
+   */
+  inline signal_exec(const signal_impl* sig)
+    : sig_(const_cast<signal_impl*>(sig) )
+    { sig_->reference_exec(); }
+
+  /// Decrements the reference and execution counter of the parent sigc::signal_impl object.
+  inline ~signal_exec()
+    { sig_->unreference_exec(); }
+};
+
+} /* namespace internal */
+
+
+/** @defgroup signal Signals
+ * Use sigc::signal::connect() with sigc::mem_fun() and sigc::ptr_fun() to connect a method or function with a signal.
+ *
+ * @code
+ * signal_clicked.connect( sigc::mem_fun(*this, &MyWindow::on_clicked) );
+ * @endcode
+ *
+ * When the signal is emitted your method will be called.
+ *
+ * signal::connect() returns a connection, which you can later use to disconnect your method.
+ * If the type of your object inherits from sigc::trackable the method is disconnected
+ * automatically when your object is destroyed.
+ *
+ * When signals are copied they share the underlying information,
+ * so you can have a protected/private sigc::signal member and a public accessor method.
+ *
+ * signal and slot objects provide the core functionality of this
+ * library. A slot is a container for an arbitrary functor.
+ * A signal is a list of slots that are executed on emission.
+ * For compile time type safety a list of template arguments
+ * must be provided for the signal template that determines the
+ * parameter list for emission. Functors and closures are converted
+ * into slots implicitely on connection, triggering compiler errors
+ * if the given functor or closure cannot be invoked with the
+ * parameter list of the signal to connect to.
+ */
+
+/** Base class for the sigc::signal# templates.
+ * signal_base integrates most of the interface of the derived sigc::signal#
+ * templates. The implementation, however, resides in sigc::internal::signal_impl.
+ * A sigc::internal::signal_impl object is dynamically allocated from signal_base
+ * when first connecting a slot to the signal. This ensures that empty signals
+ * don't waste memory.
+ *
+ * @ingroup signal
+ */
+struct SIGC_API signal_base : public trackable
+{
+  typedef size_t size_type;
+
+  signal_base();
+
+  signal_base(const signal_base& src);
+
+  ~signal_base();
+
+  signal_base& operator = (const signal_base& src);
+
+  /** Returns whether the list of slots is empty.
+   * @return @p true if the list of slots is empty.
+   */
+  inline bool empty() const
+    { return (!impl_ || impl_->empty()); }
+
+  /// Empties the list of slots.
+  void clear();
+
+  /** Returns the number of slots in the list.
+   * @return The number of slots in the list.
+   */
+  size_type size() const;
+
+protected:
+  typedef internal::signal_impl::iterator_type iterator_type;
+
+  /** Adds a slot at the bottom of the list of slots.
+   * @param slot_ The slot to add to the list of slots.
+   * @return An iterator pointing to the new slot in the list.
+   */
+  iterator_type connect(const slot_base& slot_);
+
+  /** Adds a slot at the given position into the list of slots.
+   * @param i An iterator indicating the position where @e slot_ should be inserted.
+   * @param slot_ The slot to add to the list of slots.
+   * @return An iterator pointing to the new slot in the list.
+   */
+  iterator_type insert(iterator_type i, const slot_base& slot_);
+
+  /** Removes the slot at the given position from the list of slots.
+   * @param i An iterator pointing to the slot to be removed.
+   * @return An iterator pointing to the slot in the list after the one removed.
+   */
+  iterator_type erase(iterator_type i);
+
+  /** Returns the signal_impl object encapsulating the list of slots.
+   * @return The signal_impl object encapsulating the list of slots.
+   */
+  internal::signal_impl* impl() const;
+
+  /// The signal_impl object encapsulating the slot list.
+  mutable internal::signal_impl* impl_;
+};
+
+} //namespace sigc
+
+#endif /* _SIGC_SIGNAL_BASE_H_ */
diff --git a/libs/sigc++2/sigc++/slot.h b/libs/sigc++2/sigc++/slot.h
new file mode 100644
index 0000000000..f7fbe3cd2e
--- /dev/null
+++ b/libs/sigc++2/sigc++/slot.h
@@ -0,0 +1,614 @@
+// -*- c++ -*-
+/* Do not edit! -- generated file */
+
+
+#ifndef _SIGC_MACROS_SLOTHM4_
+#define _SIGC_MACROS_SLOTHM4_
+
+#include <sigc++/functors/slot.h>
+
+#ifndef LIBSIGC_DISABLE_DEPRECATED
+
+namespace SigC {
+
+// SlotN
+/** Converts an arbitrary functor to a unified type which is opaque.
+ * Slot0 itself is a functor or to be more precise a closure. It contains
+ * a single, arbitrary functor (or closure) that is executed in operator()().
+ *
+ * The template arguments determine the function signature of operator()():
+ * - @e T_return The return type of operator()().
+ *
+ * To use simply assign the slot to the desired functor. If the functor
+ * is not compatible with the parameter list defined with the template
+ * arguments compiler errors are triggered. When called the slot
+ * will invoke the functor with minimal copies.
+ * block() and unblock() can be used to block the functor's invocation
+ * from operator()() temporarily.
+ *
+ * @par Example:
+ *   @code
+ *   #include <sigc++/slot.h>
+ *   void foo(int) {}
+ *   SigC::Slot1<void, long> s = SigC::slot(&foo);
+ *   s(19);
+ *   @endcode
+ *
+ * @deprecated Use the unnumbered template sigc::slot instead.
+ * @ingroup compat
+ */
+template <class T_return>
+class Slot0
+  : public ::sigc::slot<T_return>
+{
+public:
+  typedef ::sigc::slot<T_return> parent_type;
+
+  /// Constructs an empty slot.
+  Slot0() {}
+
+  /** Constructs a slot from an arbitrary functor.
+   * @param _A_func The desired functor the new slot should be assigned to.
+   */
+  template <class T_functor>
+  Slot0(const T_functor& _A_func)
+    : ::sigc::slot<T_return>(_A_func) {}
+
+  /** Constructs a slot, copying an existing one.
+   * @param src The existing slot to copy.
+   */
+  Slot0(const parent_type& src)
+    : parent_type(src) {}
+
+  /** Overrides this slot making a copy from another slot.
+   * @param src The slot from which to make a copy.
+   * @return @p this.
+   */
+  Slot0& operator=(const parent_type& src)
+    { parent_type::operator=(src); return *this; }
+};
+
+/** Converts an arbitrary functor to a unified type which is opaque.
+ * Slot1 itself is a functor or to be more precise a closure. It contains
+ * a single, arbitrary functor (or closure) that is executed in operator()().
+ *
+ * The template arguments determine the function signature of operator()():
+ * - @e T_return The return type of operator()().
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ *
+ * To use simply assign the slot to the desired functor. If the functor
+ * is not compatible with the parameter list defined with the template
+ * arguments compiler errors are triggered. When called the slot
+ * will invoke the functor with minimal copies.
+ * block() and unblock() can be used to block the functor's invocation
+ * from operator()() temporarily.
+ *
+ * @par Example:
+ *   @code
+ *   #include <sigc++/slot.h>
+ *   void foo(int) {}
+ *   SigC::Slot1<void, long> s = SigC::slot(&foo);
+ *   s(19);
+ *   @endcode
+ *
+ * @deprecated Use the unnumbered template sigc::slot instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1>
+class Slot1
+  : public ::sigc::slot<T_return, T_arg1>
+{
+public:
+  typedef ::sigc::slot<T_return, T_arg1> parent_type;
+
+  /// Constructs an empty slot.
+  Slot1() {}
+
+  /** Constructs a slot from an arbitrary functor.
+   * @param _A_func The desired functor the new slot should be assigned to.
+   */
+  template <class T_functor>
+  Slot1(const T_functor& _A_func)
+    : ::sigc::slot<T_return, T_arg1>(_A_func) {}
+
+  /** Constructs a slot, copying an existing one.
+   * @param src The existing slot to copy.
+   */
+  Slot1(const parent_type& src)
+    : parent_type(src) {}
+
+  /** Overrides this slot making a copy from another slot.
+   * @param src The slot from which to make a copy.
+   * @return @p this.
+   */
+  Slot1& operator=(const parent_type& src)
+    { parent_type::operator=(src); return *this; }
+};
+
+/** Converts an arbitrary functor to a unified type which is opaque.
+ * Slot2 itself is a functor or to be more precise a closure. It contains
+ * a single, arbitrary functor (or closure) that is executed in operator()().
+ *
+ * The template arguments determine the function signature of operator()():
+ * - @e T_return The return type of operator()().
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ *
+ * To use simply assign the slot to the desired functor. If the functor
+ * is not compatible with the parameter list defined with the template
+ * arguments compiler errors are triggered. When called the slot
+ * will invoke the functor with minimal copies.
+ * block() and unblock() can be used to block the functor's invocation
+ * from operator()() temporarily.
+ *
+ * @par Example:
+ *   @code
+ *   #include <sigc++/slot.h>
+ *   void foo(int) {}
+ *   SigC::Slot1<void, long> s = SigC::slot(&foo);
+ *   s(19);
+ *   @endcode
+ *
+ * @deprecated Use the unnumbered template sigc::slot instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2>
+class Slot2
+  : public ::sigc::slot<T_return, T_arg1,T_arg2>
+{
+public:
+  typedef ::sigc::slot<T_return, T_arg1,T_arg2> parent_type;
+
+  /// Constructs an empty slot.
+  Slot2() {}
+
+  /** Constructs a slot from an arbitrary functor.
+   * @param _A_func The desired functor the new slot should be assigned to.
+   */
+  template <class T_functor>
+  Slot2(const T_functor& _A_func)
+    : ::sigc::slot<T_return, T_arg1,T_arg2>(_A_func) {}
+
+  /** Constructs a slot, copying an existing one.
+   * @param src The existing slot to copy.
+   */
+  Slot2(const parent_type& src)
+    : parent_type(src) {}
+
+  /** Overrides this slot making a copy from another slot.
+   * @param src The slot from which to make a copy.
+   * @return @p this.
+   */
+  Slot2& operator=(const parent_type& src)
+    { parent_type::operator=(src); return *this; }
+};
+
+/** Converts an arbitrary functor to a unified type which is opaque.
+ * Slot3 itself is a functor or to be more precise a closure. It contains
+ * a single, arbitrary functor (or closure) that is executed in operator()().
+ *
+ * The template arguments determine the function signature of operator()():
+ * - @e T_return The return type of operator()().
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ *
+ * To use simply assign the slot to the desired functor. If the functor
+ * is not compatible with the parameter list defined with the template
+ * arguments compiler errors are triggered. When called the slot
+ * will invoke the functor with minimal copies.
+ * block() and unblock() can be used to block the functor's invocation
+ * from operator()() temporarily.
+ *
+ * @par Example:
+ *   @code
+ *   #include <sigc++/slot.h>
+ *   void foo(int) {}
+ *   SigC::Slot1<void, long> s = SigC::slot(&foo);
+ *   s(19);
+ *   @endcode
+ *
+ * @deprecated Use the unnumbered template sigc::slot instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3>
+class Slot3
+  : public ::sigc::slot<T_return, T_arg1,T_arg2,T_arg3>
+{
+public:
+  typedef ::sigc::slot<T_return, T_arg1,T_arg2,T_arg3> parent_type;
+
+  /// Constructs an empty slot.
+  Slot3() {}
+
+  /** Constructs a slot from an arbitrary functor.
+   * @param _A_func The desired functor the new slot should be assigned to.
+   */
+  template <class T_functor>
+  Slot3(const T_functor& _A_func)
+    : ::sigc::slot<T_return, T_arg1,T_arg2,T_arg3>(_A_func) {}
+
+  /** Constructs a slot, copying an existing one.
+   * @param src The existing slot to copy.
+   */
+  Slot3(const parent_type& src)
+    : parent_type(src) {}
+
+  /** Overrides this slot making a copy from another slot.
+   * @param src The slot from which to make a copy.
+   * @return @p this.
+   */
+  Slot3& operator=(const parent_type& src)
+    { parent_type::operator=(src); return *this; }
+};
+
+/** Converts an arbitrary functor to a unified type which is opaque.
+ * Slot4 itself is a functor or to be more precise a closure. It contains
+ * a single, arbitrary functor (or closure) that is executed in operator()().
+ *
+ * The template arguments determine the function signature of operator()():
+ * - @e T_return The return type of operator()().
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ *
+ * To use simply assign the slot to the desired functor. If the functor
+ * is not compatible with the parameter list defined with the template
+ * arguments compiler errors are triggered. When called the slot
+ * will invoke the functor with minimal copies.
+ * block() and unblock() can be used to block the functor's invocation
+ * from operator()() temporarily.
+ *
+ * @par Example:
+ *   @code
+ *   #include <sigc++/slot.h>
+ *   void foo(int) {}
+ *   SigC::Slot1<void, long> s = SigC::slot(&foo);
+ *   s(19);
+ *   @endcode
+ *
+ * @deprecated Use the unnumbered template sigc::slot instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+class Slot4
+  : public ::sigc::slot<T_return, T_arg1,T_arg2,T_arg3,T_arg4>
+{
+public:
+  typedef ::sigc::slot<T_return, T_arg1,T_arg2,T_arg3,T_arg4> parent_type;
+
+  /// Constructs an empty slot.
+  Slot4() {}
+
+  /** Constructs a slot from an arbitrary functor.
+   * @param _A_func The desired functor the new slot should be assigned to.
+   */
+  template <class T_functor>
+  Slot4(const T_functor& _A_func)
+    : ::sigc::slot<T_return, T_arg1,T_arg2,T_arg3,T_arg4>(_A_func) {}
+
+  /** Constructs a slot, copying an existing one.
+   * @param src The existing slot to copy.
+   */
+  Slot4(const parent_type& src)
+    : parent_type(src) {}
+
+  /** Overrides this slot making a copy from another slot.
+   * @param src The slot from which to make a copy.
+   * @return @p this.
+   */
+  Slot4& operator=(const parent_type& src)
+    { parent_type::operator=(src); return *this; }
+};
+
+/** Converts an arbitrary functor to a unified type which is opaque.
+ * Slot5 itself is a functor or to be more precise a closure. It contains
+ * a single, arbitrary functor (or closure) that is executed in operator()().
+ *
+ * The template arguments determine the function signature of operator()():
+ * - @e T_return The return type of operator()().
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_arg5 Argument type used in the definition of operator()().
+ *
+ * To use simply assign the slot to the desired functor. If the functor
+ * is not compatible with the parameter list defined with the template
+ * arguments compiler errors are triggered. When called the slot
+ * will invoke the functor with minimal copies.
+ * block() and unblock() can be used to block the functor's invocation
+ * from operator()() temporarily.
+ *
+ * @par Example:
+ *   @code
+ *   #include <sigc++/slot.h>
+ *   void foo(int) {}
+ *   SigC::Slot1<void, long> s = SigC::slot(&foo);
+ *   s(19);
+ *   @endcode
+ *
+ * @deprecated Use the unnumbered template sigc::slot instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+class Slot5
+  : public ::sigc::slot<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+{
+public:
+  typedef ::sigc::slot<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5> parent_type;
+
+  /// Constructs an empty slot.
+  Slot5() {}
+
+  /** Constructs a slot from an arbitrary functor.
+   * @param _A_func The desired functor the new slot should be assigned to.
+   */
+  template <class T_functor>
+  Slot5(const T_functor& _A_func)
+    : ::sigc::slot<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_func) {}
+
+  /** Constructs a slot, copying an existing one.
+   * @param src The existing slot to copy.
+   */
+  Slot5(const parent_type& src)
+    : parent_type(src) {}
+
+  /** Overrides this slot making a copy from another slot.
+   * @param src The slot from which to make a copy.
+   * @return @p this.
+   */
+  Slot5& operator=(const parent_type& src)
+    { parent_type::operator=(src); return *this; }
+};
+
+/** Converts an arbitrary functor to a unified type which is opaque.
+ * Slot6 itself is a functor or to be more precise a closure. It contains
+ * a single, arbitrary functor (or closure) that is executed in operator()().
+ *
+ * The template arguments determine the function signature of operator()():
+ * - @e T_return The return type of operator()().
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_arg5 Argument type used in the definition of operator()().
+ * - @e T_arg6 Argument type used in the definition of operator()().
+ *
+ * To use simply assign the slot to the desired functor. If the functor
+ * is not compatible with the parameter list defined with the template
+ * arguments compiler errors are triggered. When called the slot
+ * will invoke the functor with minimal copies.
+ * block() and unblock() can be used to block the functor's invocation
+ * from operator()() temporarily.
+ *
+ * @par Example:
+ *   @code
+ *   #include <sigc++/slot.h>
+ *   void foo(int) {}
+ *   SigC::Slot1<void, long> s = SigC::slot(&foo);
+ *   s(19);
+ *   @endcode
+ *
+ * @deprecated Use the unnumbered template sigc::slot instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+class Slot6
+  : public ::sigc::slot<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+{
+public:
+  typedef ::sigc::slot<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6> parent_type;
+
+  /// Constructs an empty slot.
+  Slot6() {}
+
+  /** Constructs a slot from an arbitrary functor.
+   * @param _A_func The desired functor the new slot should be assigned to.
+   */
+  template <class T_functor>
+  Slot6(const T_functor& _A_func)
+    : ::sigc::slot<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_func) {}
+
+  /** Constructs a slot, copying an existing one.
+   * @param src The existing slot to copy.
+   */
+  Slot6(const parent_type& src)
+    : parent_type(src) {}
+
+  /** Overrides this slot making a copy from another slot.
+   * @param src The slot from which to make a copy.
+   * @return @p this.
+   */
+  Slot6& operator=(const parent_type& src)
+    { parent_type::operator=(src); return *this; }
+};
+
+/** Converts an arbitrary functor to a unified type which is opaque.
+ * Slot7 itself is a functor or to be more precise a closure. It contains
+ * a single, arbitrary functor (or closure) that is executed in operator()().
+ *
+ * The template arguments determine the function signature of operator()():
+ * - @e T_return The return type of operator()().
+ * - @e T_arg1 Argument type used in the definition of operator()().
+ * - @e T_arg2 Argument type used in the definition of operator()().
+ * - @e T_arg3 Argument type used in the definition of operator()().
+ * - @e T_arg4 Argument type used in the definition of operator()().
+ * - @e T_arg5 Argument type used in the definition of operator()().
+ * - @e T_arg6 Argument type used in the definition of operator()().
+ * - @e T_arg7 Argument type used in the definition of operator()().
+ *
+ * To use simply assign the slot to the desired functor. If the functor
+ * is not compatible with the parameter list defined with the template
+ * arguments compiler errors are triggered. When called the slot
+ * will invoke the functor with minimal copies.
+ * block() and unblock() can be used to block the functor's invocation
+ * from operator()() temporarily.
+ *
+ * @par Example:
+ *   @code
+ *   #include <sigc++/slot.h>
+ *   void foo(int) {}
+ *   SigC::Slot1<void, long> s = SigC::slot(&foo);
+ *   s(19);
+ *   @endcode
+ *
+ * @deprecated Use the unnumbered template sigc::slot instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+class Slot7
+  : public ::sigc::slot<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+{
+public:
+  typedef ::sigc::slot<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7> parent_type;
+
+  /// Constructs an empty slot.
+  Slot7() {}
+
+  /** Constructs a slot from an arbitrary functor.
+   * @param _A_func The desired functor the new slot should be assigned to.
+   */
+  template <class T_functor>
+  Slot7(const T_functor& _A_func)
+    : ::sigc::slot<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>(_A_func) {}
+
+  /** Constructs a slot, copying an existing one.
+   * @param src The existing slot to copy.
+   */
+  Slot7(const parent_type& src)
+    : parent_type(src) {}
+
+  /** Overrides this slot making a copy from another slot.
+   * @param src The slot from which to make a copy.
+   * @return @p this.
+   */
+  Slot7& operator=(const parent_type& src)
+    { parent_type::operator=(src); return *this; }
+};
+
+
+
+#ifndef DOXYGEN_SHOULD_SKIP_THIS
+/* gcc 3.2 reports a strange conflict between SigC::slot() and sigc::slot<>
+ * when "using namespace SigC" and later using a slot(obj,func) overload
+ * without the prefix "SigC::". Probably a compiler bug. I will investigate.
+ *
+ * This ugly hack avoids the error:
+ */
+// #define slot(...) make_slot(__VA_ARGS__) /* only works for gcc */
+#endif
+
+
+// slot()
+/** Creates a functor of type SigC::Slot0 that wraps an existing non-member function.
+ *
+ * @param _A_func Pointer to function that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::ptr_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return>
+inline Slot0<T_return>
+slot(T_return (*_A_func)())
+{ return Slot0<T_return>(_A_func); }
+
+/** Creates a functor of type SigC::Slot1 that wraps an existing non-member function.
+ *
+ * @param _A_func Pointer to function that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::ptr_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1>
+inline Slot1<T_return, T_arg1>
+slot(T_return (*_A_func)(T_arg1))
+{ return Slot1<T_return, T_arg1>(_A_func); }
+
+/** Creates a functor of type SigC::Slot2 that wraps an existing non-member function.
+ *
+ * @param _A_func Pointer to function that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::ptr_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2>
+inline Slot2<T_return, T_arg1,T_arg2>
+slot(T_return (*_A_func)(T_arg1,T_arg2))
+{ return Slot2<T_return, T_arg1,T_arg2>(_A_func); }
+
+/** Creates a functor of type SigC::Slot3 that wraps an existing non-member function.
+ *
+ * @param _A_func Pointer to function that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::ptr_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3>
+inline Slot3<T_return, T_arg1,T_arg2,T_arg3>
+slot(T_return (*_A_func)(T_arg1,T_arg2,T_arg3))
+{ return Slot3<T_return, T_arg1,T_arg2,T_arg3>(_A_func); }
+
+/** Creates a functor of type SigC::Slot4 that wraps an existing non-member function.
+ *
+ * @param _A_func Pointer to function that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::ptr_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4>
+inline Slot4<T_return, T_arg1,T_arg2,T_arg3,T_arg4>
+slot(T_return (*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4))
+{ return Slot4<T_return, T_arg1,T_arg2,T_arg3,T_arg4>(_A_func); }
+
+/** Creates a functor of type SigC::Slot5 that wraps an existing non-member function.
+ *
+ * @param _A_func Pointer to function that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::ptr_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5>
+inline Slot5<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>
+slot(T_return (*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5))
+{ return Slot5<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5>(_A_func); }
+
+/** Creates a functor of type SigC::Slot6 that wraps an existing non-member function.
+ *
+ * @param _A_func Pointer to function that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::ptr_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6>
+inline Slot6<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>
+slot(T_return (*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6))
+{ return Slot6<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6>(_A_func); }
+
+/** Creates a functor of type SigC::Slot7 that wraps an existing non-member function.
+ *
+ * @param _A_func Pointer to function that should be wrapped.
+ * @return Functor that executes _A_func on invokation.
+ *
+ * @deprecated Use sigc::ptr_fun() instead.
+ * @ingroup compat
+ */
+template <class T_return, class T_arg1,class T_arg2,class T_arg3,class T_arg4,class T_arg5,class T_arg6,class T_arg7>
+inline Slot7<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>
+slot(T_return (*_A_func)(T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7))
+{ return Slot7<T_return, T_arg1,T_arg2,T_arg3,T_arg4,T_arg5,T_arg6,T_arg7>(_A_func); }
+
+
+
+}
+
+#endif
+#endif /* _SIGC_MACROS_SLOTHM4_ */
diff --git a/libs/sigc++2/sigc++/trackable.cc b/libs/sigc++2/sigc++/trackable.cc
new file mode 100644
index 0000000000..46e2592ffb
--- /dev/null
+++ b/libs/sigc++2/sigc++/trackable.cc
@@ -0,0 +1,124 @@
+// -*- c++ -*-
+/*
+ * Copyright 2002, The libsigc++ Development Team
+ *
+ *  This library is free software; you can redistribute it and/or
+ *  modify it under the terms of the GNU Lesser General Public
+ *  License as published by the Free Software Foundation; either
+ *  version 2.1 of the License, or (at your option) any later version.
+ *
+ *  This library is distributed in the hope that it will be useful,
+ *  but WITHOUT ANY WARRANTY; without even the implied warranty of
+ *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
+ *  Lesser General Public License for more details.
+ *
+ *  You should have received a copy of the GNU Lesser General Public
+ *  License along with this library; if not, write to the Free Software
+ *  Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
+ *
+ */
+
+#include <sigc++/trackable.h>
+#include <iostream>
+using namespace std;
+
+namespace sigc
+{
+
+trackable::trackable()
+: callback_list_(0)
+{}
+
+/* Don't copy the notification list.
+   The objects watching src don't need to be notified when the new object dies. */
+trackable::trackable(const trackable& /*src*/)
+: callback_list_(0)
+{}
+
+trackable& trackable::operator=(const trackable& src)
+{
+  if(this != &src)
+    notify_callbacks(); //Make sure that we have finished with existing stuff before replacing it.
+  
+  return *this;
+}
+
+trackable::~trackable()
+{
+  notify_callbacks();
+}
+
+void trackable::add_destroy_notify_callback(void* data, func_destroy_notify func) const
+{
+  callback_list()->add_callback(data, func);
+}
+
+void trackable::remove_destroy_notify_callback(void* data) const
+{
+  callback_list()->remove_callback(data);
+}
+
+void trackable::notify_callbacks()
+{
+  if (callback_list_)
+    delete callback_list_; //This invokes all of the callbacks.
+
+  callback_list_ = 0;
+}
+
+internal::trackable_callback_list* trackable::callback_list() const
+{
+  if (!callback_list_)
+    callback_list_ = new internal::trackable_callback_list;
+
+  return callback_list_;
+}
+
+      
+namespace internal
+{
+
+trackable_callback_list::~trackable_callback_list()
+{
+  clearing_ = true;
+
+  for (callback_list::iterator i = callbacks_.begin(); i != callbacks_.end(); ++i)
+    (*i).func_((*i).data_);
+}
+
+void trackable_callback_list::add_callback(void* data, func_destroy_notify func)
+{
+  if (!clearing_)  // TODO: Is it okay to silently ignore attempts to add dependencies when the list is being cleared?
+                   //       I'd consider this a serious application bug, since the app is likely to segfault.
+                   //       But then, how should we handle it? Throw an exception? Martin.
+    callbacks_.push_back(trackable_callback(data, func));
+}
+
+void trackable_callback_list::clear()
+{
+  clearing_ = true;
+
+  for (callback_list::iterator i = callbacks_.begin(); i != callbacks_.end(); ++i)
+    (*i).func_((*i).data_);
+
+  callbacks_.clear();
+
+  clearing_ = false;
+}
+
+void trackable_callback_list::remove_callback(void* data)
+{
+  if (clearing_) return; // No circular notices
+
+  for (callback_list::iterator i = callbacks_.begin(); i != callbacks_.end(); ++i)
+    if ((*i).data_ == data)
+    {
+      callbacks_.erase(i);
+      return;
+    }
+}
+
+} /* namespace internal */
+
+
+} /* namespace sigc */
diff --git a/libs/sigc++2/sigc++/trackable.h b/libs/sigc++2/sigc++/trackable.h
new file mode 100644
index 0000000000..4563738dd6
--- /dev/null
+++ b/libs/sigc++2/sigc++/trackable.h
@@ -0,0 +1,148 @@
+/*
+ * Copyright 2002, The libsigc++ Development Team
+ *
+ *  This library is free software; you can redistribute it and/or
+ *  modify it under the terms of the GNU Lesser General Public
+ *  License as published by the Free Software Foundation; either
+ *  version 2.1 of the License, or (at your option) any later version.
+ *
+ *  This library is distributed in the hope that it will be useful,
+ *  but WITHOUT ANY WARRANTY; without even the implied warranty of
+ *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
+ *  Lesser General Public License for more details.
+ *
+ *  You should have received a copy of the GNU Lesser General Public
+ *  License along with this library; if not, write to the Free Software
+ *  Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
+ *
+ */
+#ifndef _SIGC_TRACKABLE_HPP_
+#define _SIGC_TRACKABLE_HPP_
+#include <list>
+#include <sigc++config.h>
+
+namespace sigc {
+
+namespace internal {
+
+typedef void* (*func_destroy_notify) (void* data);
+
+/** Destroy notification callback.
+ * A destroy notification callback consists of a data pointer and a
+ * function pointer. The function is executed from the owning callback
+ * list (of type sigc::internal::trackable_callback_list) when its parent
+ * object (of type sigc::trackable) is destroyed or overwritten.
+ */
+struct SIGC_API trackable_callback
+{
+  void* data_;
+  func_destroy_notify func_;
+  trackable_callback(void* data, func_destroy_notify func)
+    : data_(data), func_(func) {}
+};
+
+/** Callback list.
+ * A callback list holds an STL list of callbacks of type
+ * trackable_callback. Callbacks are added and removed with
+ * add_callback(), remove_callback() and clear(). The callbacks
+ * are invoked from clear() and from the destructor.
+ */
+struct SIGC_API trackable_callback_list
+{
+  /** Add a callback function.
+   * @param data Data that will be sent as a parameter to teh callback function.
+   * @param func The callback function.
+   * 
+   */
+  void add_callback(void* data, func_destroy_notify func);
+
+  /** Remove the callback which has this data associated with it.
+   * @param data The data that was given as a parameter to add_callback().
+   */
+  void remove_callback(void* data);
+
+  /** This invokes all of the callback functions.
+   */
+  void clear();
+
+  trackable_callback_list()
+    : clearing_(false) {}
+
+  /** This invokes all of the callback functions.
+   */
+  ~trackable_callback_list();
+
+private:
+  typedef std::list<trackable_callback> callback_list;
+  callback_list callbacks_;
+  bool          clearing_;
+};
+
+} /* namespace internal */
+
+
+/** Base class for objects with auto-disconnection.
+ * trackable must be inherited when objects shall automatically
+ * invalidate slots referring to them on destruction.
+ * A slot built from a member function of a trackable derived
+ * type installs a callback that is invoked when the trackable object
+ * is destroyed or overwritten.
+ *
+ * add_destroy_notify_callback() and remove_destroy_notify_callback()
+ * can be used to manually install and remove callbacks when
+ * notification of the object dying is needed.
+ *
+ * notify_callbacks() invokes and removes all previously installed
+ * callbacks and can therefore be used to disconnect from all signals.
+ *
+ * Note that there is no virtual destructor. Don't use @p trackable*
+ * as pointer type for managing your data or the destructors of
+ * your derived types won't be called when deleting your objects.
+ *
+ * @ingroup signal
+ */
+struct SIGC_API trackable
+{
+  trackable();
+
+  trackable(const trackable& src);
+
+  trackable& operator=(const trackable& src);
+
+  ~trackable();
+
+  /*virtual ~trackable() {} */  /* we would need a virtual dtor for users
+                                   who insist on using "trackable*" as
+                                   pointer type for their own derived objects */
+
+  
+  typedef internal::func_destroy_notify func_destroy_notify;
+  
+  /** Add a callback that is executed (notified) when the trackable object is detroyed.
+   * @param data Passed into func upon notification.
+   * @param func Callback executed upon destruction of the object.
+   */
+  void add_destroy_notify_callback(void* data, func_destroy_notify func) const;
+
+  /** Remove a callback previously installed with add_destroy_notify_callback().
+   * The callback is not executed.
+   * @param data Parameter passed into previous call to add_destroy_notify_callback().
+   */
+  void remove_destroy_notify_callback(void* data) const;
+
+  /// Execute and remove all previously installed callbacks.
+  void notify_callbacks();
+
+#ifndef DOXYGEN_SHOULD_SKIP_THIS
+private:
+  /* The callbacks are held in a list of type trackable_callback_list.
+   * This list is allocated dynamically when the first callback is added.
+   */
+  internal::trackable_callback_list* callback_list() const;
+  mutable internal::trackable_callback_list* callback_list_;
+#endif
+};
+
+} /* namespace sigc */
+
+#endif /* _SIGC_TRACKABLE_HPP_ */
diff --git a/libs/sigc++2/sigc++/type_traits.h b/libs/sigc++2/sigc++/type_traits.h
new file mode 100644
index 0000000000..c6d6dbbc81
--- /dev/null
+++ b/libs/sigc++2/sigc++/type_traits.h
@@ -0,0 +1,121 @@
+/*
+ * Copyright 2002, The libsigc++ Development Team
+ *
+ *  This library is free software; you can redistribute it and/or
+ *  modify it under the terms of the GNU Lesser General Public
+ *  License as published by the Free Software Foundation; either
+ *  version 2.1 of the License, or (at your option) any later version.
+ *
+ *  This library is distributed in the hope that it will be useful,
+ *  but WITHOUT ANY WARRANTY; without even the implied warranty of
+ *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
+ *  Lesser General Public License for more details.
+ *
+ *  You should have received a copy of the GNU Lesser General Public
+ *  License along with this library; if not, write to the Free Software
+ *  Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
+ *
+ */
+#ifndef _SIGC_TYPE_TRAIT_H_
+#define _SIGC_TYPE_TRAIT_H_
+
+#include <sigc++/reference_wrapper.h>
+
+namespace sigc {
+
+template <class T_type>
+struct type_trait
+{
+  typedef T_type  type;
+  typedef T_type& pass;
+  typedef const T_type& take;
+  typedef T_type* pointer;
+};
+
+template <class T_type, int N>
+struct type_trait<T_type[N]>
+{
+  typedef T_type*  type;
+  typedef T_type*& pass;
+  typedef const T_type*& take;
+  typedef T_type** pointer;
+};
+
+template <class T_type>
+struct type_trait<T_type&>
+{
+  typedef T_type  type;
+  typedef T_type& pass;
+  typedef T_type& take;
+  typedef T_type* pointer;
+};
+
+template <class T_type>
+struct type_trait<const T_type&>
+{
+  typedef const T_type  type;
+  typedef const T_type& pass;
+  typedef const T_type& take;
+  typedef const T_type* pointer;
+};
+
+template <class T_type>
+struct type_trait<reference_wrapper<T_type> >
+{
+  typedef T_type  type;
+  typedef T_type& pass;
+  typedef T_type& take;
+  typedef T_type* pointer;
+};
+
+template <class T_type>
+struct type_trait<const_reference_wrapper<T_type> >
+{
+  typedef T_type  type;
+  typedef T_type& pass;
+  typedef const T_type& take;
+  typedef T_type* pointer;
+};
+
+template<>
+struct type_trait<void>
+{
+  typedef void  type;
+  typedef void  pass;
+  typedef void  take;
+  typedef void* pointer;
+};
+
+
+/** From Esa Pulkkin:
+ * Compile-time determination of base-class relationship in C++
+ * (adapted to match the syntax of boost's type_traits library).
+ */
+template <class T_base, class T_derived>
+struct is_base_and_derived
+{
+private:
+  struct big {
+    char memory[64];
+  };
+
+  struct test {
+    static big  is_base_class_(...);
+    static char is_base_class_(typename type_trait<T_base>::pointer);
+  };
+
+public:
+  static const bool value =
+    sizeof(test::is_base_class_((typename type_trait<T_derived>::pointer)0)) ==
+    sizeof(char);
+};
+
+template <class T_base>
+struct is_base_and_derived<T_base, T_base>
+{
+  static const bool value = true;
+};
+
+} /* namespace sigc */
+
+#endif /* _SIGC_TYPE_TRAIT_H_ */
diff --git a/libs/sigc++2/sigc++/visit_each.h b/libs/sigc++2/sigc++/visit_each.h
new file mode 100644
index 0000000000..7b7978531f
--- /dev/null
+++ b/libs/sigc++2/sigc++/visit_each.h
@@ -0,0 +1,128 @@
+// -*- c++ -*- 
+/*
+ * Copyright 2002, The libsigc++ Development Team
+ *
+ *  This library is free software; you can redistribute it and/or
+ *  modify it under the terms of the GNU Lesser General Public
+ *  License as published by the Free Software Foundation; either
+ *  version 2.1 of the License, or (at your option) any later version.
+ *
+ *  This library is distributed in the hope that it will be useful,
+ *  but WITHOUT ANY WARRANTY; without even the implied warranty of
+ *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
+ *  Lesser General Public License for more details.
+ *
+ *  You should have received a copy of the GNU Lesser General Public
+ *  License along with this library; if not, write to the Free Software
+ *  Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
+ *
+ */
+#ifndef _SIGC_VISIT_EACH_HPP_
+#define _SIGC_VISIT_EACH_HPP_
+
+#include <sigc++/type_traits.h>
+
+namespace sigc {
+
+namespace internal {
+
+/// Helper struct for visit_each_type().
+template <class T_target, class T_action>
+struct limit_derived_target
+{
+  typedef limit_derived_target<T_target, T_action> T_self;
+
+  template <bool I_derived, class T_type> struct with_type;
+
+  template <class T_type> struct with_type<false,T_type>
+  { static void execute_(const T_type&, const T_self&) {} };
+
+  template <class T_type> struct with_type<true,T_type>
+  { static void execute_(const T_type& _A_type, const T_self& _A_action)
+      { _A_action.action_(_A_type); }
+  };
+
+  template <class T_type>
+  void operator()(const T_type& _A_type) const
+  { with_type<is_base_and_derived<T_target,T_type>::value,T_type>::execute_(_A_type,*this); }
+
+  limit_derived_target(const T_action& _A_action): action_(_A_action) {}
+
+  T_action action_;
+};
+
+/// Helper struct for visit_each_type().
+template <class T_target, class T_action>
+struct limit_derived_target<T_target*, T_action>
+{
+  typedef limit_derived_target<T_target*, T_action> T_self;
+
+  template <bool I_derived, class T_type> struct with_type;
+
+  template <class T_type> struct with_type<false,T_type>
+  { static void execute_(const T_type&, const T_self&) {} };
+
+  template <class T_type> struct with_type<true,T_type>
+  { static void execute_(const T_type& _A_type, const T_self& _A_action) 
+     { _A_action.action_(&_A_type); }
+  };
+
+  template <class T_type>
+  void operator()(const T_type& _A_type) const
+  { with_type<is_base_and_derived<T_target,T_type>::value,T_type>::execute_(_A_type,*this); }
+
+  limit_derived_target(const T_action& _A_action): action_(_A_action) {}
+
+  T_action action_;
+};
+
+} /* namespace internal */
+
+
+/** This function performs a functor on each of the targets of a functor.
+ * All unknown types just call @e _A_action on them.
+ * Add overloads that specialize the @e T_functor argument for your own
+ * functor types, so that subobjects get visited. This is needed to enable
+ * auto-disconnection support for your functor types.
+ *
+ * @par Example:
+ *   @code
+ *   struct some_functor
+ *   {
+ *     void operator()() {}
+ *     some_possibly_sigc_trackable_derived_type some_data_member;
+ *     some_other_functor_type some_other_functor;
+ *   }
+ *
+ *   namespace sigc
+ *   {
+ *     template <class T_action>
+ *     void visit_each(const T_action& _A_action,
+ *                     const some_functor& _A_target)
+ *     {
+ *       visit_each(_A_action, _A_target.some_data_member);
+ *       visit_each(_A_action, _A_target.some_other_functor);
+ *     }
+ *   }
+ *   @endcode
+ *
+ * @ingroup functors
+ */
+template <class T_action, class T_functor>
+void visit_each(const T_action& _A_action, const T_functor& _A_functor)
+{ _A_action(_A_functor); }
+
+/** This function performs a functor on each of the targets
+ * of a functor limited to a restricted type.
+ *
+ * @ingroup functors
+ */
+template <class T_type, class T_action, class T_functor>
+void visit_each_type(const T_action& _A_action, const T_functor& _A_functor)
+{ 
+  internal::limit_derived_target<T_type,T_action> limited_action(_A_action);
+  visit_each(limited_action,_A_functor);
+}
+
+} /* namespace sigc */
+#endif
diff --git a/libs/sigc++2/sigc++config.h.in b/libs/sigc++2/sigc++config.h.in
new file mode 100644
index 0000000000..357873fae6
--- /dev/null
+++ b/libs/sigc++2/sigc++config.h.in
@@ -0,0 +1,10 @@
+/* sigc++config.h.in. (Generated manually.) */
+
+/* configure checks */
+#undef SIGC_GCC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+#undef SIGC_MSVC_TEMPLATE_SPECIALIZATION_OPERATOR_OVERLOAD
+
+/* platform specific macros */
+// #define LIBSIGC_DISABLE_DEPRECATED
+// #define SIGC_NEW_DELETE_IN_LIBRARY_ONLY // only defined for MSVC to keep ABI compatibility
+#define SIGC_API