diff options
Diffstat (limited to 'libs/sigc++2/sigc++')
49 files changed, 25448 insertions, 0 deletions
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, ¬ify); +} + +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, ¬ify); +} + +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, ¬ify); +} + +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, ¬ify); } + + /** 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, ¬ify); + 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 |