/* Copyright (C) 2010 Paul Davis Author: Torben Hohn This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. */ #include #include #include "pbd/compose.h" #include "pbd/debug_rt_alloc.h" #include "ardour/debug.h" #include "ardour/graph.h" #include "ardour/types.h" #include "ardour/session.h" #include "ardour/route.h" #include "ardour/process_thread.h" #include "ardour/audioengine.h" #include #include "i18n.h" using namespace ARDOUR; using namespace PBD; using namespace std; #ifdef DEBUG_RT_ALLOC static Graph* graph = 0; extern "C" { int alloc_allowed () { return !graph->in_process_thread (); } } #endif Graph::Graph (Session & session) : SessionHandleRef (session) , _quit_threads (false) , _execution_sem ("graph_execution", 0) , _callback_start_sem ("graph_start", 0) , _callback_done_sem ("graph_done", 0) , _cleanup_sem ("graph_cleanup", 0) { pthread_mutex_init( &_trigger_mutex, NULL); /* XXX: rather hacky `fix' to stop _trigger_queue.push_back() allocating memory in the RT thread. */ _trigger_queue.reserve (8192); _execution_tokens = 0; _current_chain = 0; _pending_chain = 0; _setup_chain = 1; _quit_threads = false; _graph_empty = true; reset_thread_list (); Config->ParameterChanged.connect_same_thread (processor_usage_connection, boost::bind (&Graph::parameter_changed, this, _1)); #ifdef DEBUG_RT_ALLOC graph = this; pbd_alloc_allowed = &::alloc_allowed; #endif } void Graph::parameter_changed (std::string param) { if (param == X_("processor-usage")) { reset_thread_list (); } } void Graph::reset_thread_list () { uint32_t num_threads = how_many_dsp_threads (); /* don't bother doing anything here if we already have the right number of threads. */ if (_thread_list.size() == num_threads) { return; } Glib::Mutex::Lock lm (_session.engine().process_lock()); pthread_t a_thread; if (!_thread_list.empty()) { drop_threads (); } #if 0 /* XXX this only makes sense when we can use just the AudioEngine thread and still keep the graph current with the route list */ if (num_threads <= 1) { /* no point creating 1 thread - the AudioEngine already gives us one */ return; } #endif if (AudioEngine::instance()->create_process_thread (boost::bind (&Graph::main_thread, this), &a_thread, 100000) == 0) { _thread_list.push_back (a_thread); } for (uint32_t i = 1; i < num_threads; ++i) { if (AudioEngine::instance()->create_process_thread (boost::bind (&Graph::helper_thread, this), &a_thread, 100000) == 0) { _thread_list.push_back (a_thread); } } } void Graph::session_going_away() { drop_threads (); // now drop all references on the nodes. _nodes_rt[0].clear(); _nodes_rt[1].clear(); _init_trigger_list[0].clear(); _init_trigger_list[1].clear(); _trigger_queue.clear(); } void Graph::drop_threads () { _quit_threads = true; for (unsigned int i=0; i< _thread_list.size(); i++) { _execution_sem.signal (); } _callback_start_sem.signal (); for (list::iterator i = _thread_list.begin(); i != _thread_list.end(); ++i) { void* status; pthread_join (*i, &status); } _thread_list.clear (); _execution_tokens = 0; _quit_threads = false; } void Graph::clear_other_chain () { Glib::Mutex::Lock ls (_swap_mutex); while (1) { if (_setup_chain != _pending_chain) { for (node_list_t::iterator ni=_nodes_rt[_setup_chain].begin(); ni!=_nodes_rt[_setup_chain].end(); ni++) { (*ni)->_activation_set[_setup_chain].clear(); } _nodes_rt[_setup_chain].clear (); _init_trigger_list[_setup_chain].clear (); break; } /* setup chain == pending chain - we have to wait till this is no longer true. */ _cleanup_cond.wait (_swap_mutex); } } void Graph::prep() { node_list_t::iterator i; int chain; if (_swap_mutex.trylock()) { // we got the swap mutex. if (_current_chain != _pending_chain) { // printf ("chain swap ! %d -> %d\n", _current_chain, _pending_chain); _setup_chain = _current_chain; _current_chain = _pending_chain; _cleanup_cond.signal (); } _swap_mutex.unlock (); } chain = _current_chain; _graph_empty = true; for (i=_nodes_rt[chain].begin(); i!=_nodes_rt[chain].end(); i++) { (*i)->prep( chain); _graph_empty = false; } _finished_refcount = _init_finished_refcount[chain]; for (i=_init_trigger_list[chain].begin(); i!=_init_trigger_list[chain].end(); i++) { this->trigger( i->get() ); } } void Graph::trigger (GraphNode* n) { pthread_mutex_lock (&_trigger_mutex); _trigger_queue.push_back (n); pthread_mutex_unlock (&_trigger_mutex); } void Graph::dec_ref() { if (g_atomic_int_dec_and_test (&_finished_refcount)) { // ok... this cycle is finished now. // we are the only thread alive. this->restart_cycle(); } } void Graph::restart_cycle() { // we are through. wakeup our caller. again: _callback_done_sem.signal (); // block until we are triggered. _callback_start_sem.wait(); if (_quit_threads) { return; } this->prep(); if (_graph_empty) { goto again; } // returning will restart the cycle. // starting with waking up the others. } static bool is_feedback (boost::shared_ptr routelist, Route* from, boost::shared_ptr to) { for (RouteList::iterator ri=routelist->begin(); ri!=routelist->end(); ri++) { if ((*ri).get() == from) return false; if ((*ri) == to) return true; } assert(0); return false; } static bool is_feedback (boost::shared_ptr routelist, boost::shared_ptr from, Route* to) { for (RouteList::iterator ri=routelist->begin(); ri!=routelist->end(); ri++) { if ((*ri).get() == to) return true; if ((*ri) == from) return false; } assert(0); return false; } void Graph::rechain (boost::shared_ptr routelist) { node_list_t::iterator ni; Glib::Mutex::Lock ls (_swap_mutex); int chain = _setup_chain; DEBUG_TRACE (DEBUG::Graph, string_compose ("============== setup %1\n", chain)); // set all refcounts to 0; _init_finished_refcount[chain] = 0; _init_trigger_list[chain].clear(); _nodes_rt[chain].clear(); for (RouteList::iterator ri=routelist->begin(); ri!=routelist->end(); ri++) { node_ptr_t n = boost::dynamic_pointer_cast (*ri); n->_init_refcount[chain] = 0; n->_activation_set[chain].clear(); _nodes_rt[chain].push_back(n); } // now add refs for the connections. for (ni=_nodes_rt[chain].begin(); ni!=_nodes_rt[chain].end(); ni++) { bool has_input = false; bool has_output = false; boost::shared_ptr rp = boost::dynamic_pointer_cast( *ni); for (RouteList::iterator ri=routelist->begin(); ri!=routelist->end(); ri++) { if (rp->direct_feeds (*ri)) { if (is_feedback (routelist, rp.get(), *ri)) { continue; } has_output = true; (*ni)->_activation_set[chain].insert (boost::dynamic_pointer_cast (*ri) ); } } for (Route::FedBy::iterator fi=rp->fed_by().begin(); fi!=rp->fed_by().end(); fi++) { if (boost::shared_ptr r = fi->r.lock()) { if (!is_feedback (routelist, r, rp.get())) { has_input = true; } } } for (node_set_t::iterator ai=(*ni)->_activation_set[chain].begin(); ai!=(*ni)->_activation_set[chain].end(); ai++) { (*ai)->_init_refcount[chain] += 1; } if (!has_input) _init_trigger_list[chain].push_back (*ni); if (!has_output) _init_finished_refcount[chain] += 1; } _pending_chain = chain; dump(chain); } bool Graph::run_one() { GraphNode* to_run; pthread_mutex_lock (&_trigger_mutex); if (_trigger_queue.size()) { to_run = _trigger_queue.back(); _trigger_queue.pop_back(); } else { to_run = 0; } int et = _execution_tokens; int ts = _trigger_queue.size(); int wakeup = min (et, ts); _execution_tokens -= wakeup; DEBUG_TRACE(DEBUG::ProcessThreads, string_compose ("%1 signals %2\n", pthread_self(), wakeup)); for (int i = 0; i < wakeup; i++) { _execution_sem.signal (); } while (to_run == 0) { _execution_tokens += 1; pthread_mutex_unlock (&_trigger_mutex); DEBUG_TRACE (DEBUG::ProcessThreads, string_compose ("%1 goes to sleep\n", pthread_self())); _execution_sem.wait (); if (_quit_threads) { return true; } DEBUG_TRACE (DEBUG::ProcessThreads, string_compose ("%1 is awake\n", pthread_self())); pthread_mutex_lock (&_trigger_mutex); if (_trigger_queue.size()) { to_run = _trigger_queue.back(); _trigger_queue.pop_back(); } } pthread_mutex_unlock (&_trigger_mutex); to_run->process(); to_run->finish (_current_chain); DEBUG_TRACE(DEBUG::ProcessThreads, string_compose ("%1 has finished run_one()\n", pthread_self())); return false; } static void get_rt() { if (!jack_is_realtime (AudioEngine::instance()->jack())) { return; } int priority = jack_client_real_time_priority (AudioEngine::instance()->jack()); if (priority) { struct sched_param rtparam; memset (&rtparam, 0, sizeof (rtparam)); rtparam.sched_priority = priority; pthread_setschedparam (pthread_self(), SCHED_FIFO, &rtparam); } } void Graph::helper_thread() { suspend_rt_malloc_checks (); ProcessThread* pt = new ProcessThread (); resume_rt_malloc_checks (); pt->get_buffers(); get_rt(); while(1) { if (run_one()) { break; } } pt->drop_buffers(); } void Graph::main_thread() { suspend_rt_malloc_checks (); ProcessThread* pt = new ProcessThread (); resume_rt_malloc_checks (); pt->get_buffers(); get_rt(); again: _callback_start_sem.wait (); DEBUG_TRACE(DEBUG::ProcessThreads, "main thread is awake\n"); if (_quit_threads) { return; } this->prep(); if (_graph_empty && !_quit_threads) { _callback_done_sem.signal (); DEBUG_TRACE(DEBUG::ProcessThreads, "main thread sees graph done, goes back to slee\n"); goto again; } while (1) { DEBUG_TRACE(DEBUG::ProcessThreads, "main thread runs one graph node\n"); if (run_one()) { break; } } pt->drop_buffers(); } void Graph::dump (int chain) { #ifndef NDEBUG node_list_t::iterator ni; node_set_t::iterator ai; chain = _pending_chain; DEBUG_TRACE (DEBUG::Graph, "--------------------------------------------Graph dump:\n"); for (ni=_nodes_rt[chain].begin(); ni!=_nodes_rt[chain].end(); ni++) { boost::shared_ptr rp = boost::dynamic_pointer_cast( *ni); DEBUG_TRACE (DEBUG::Graph, string_compose ("GraphNode: %1 refcount: %2\n", rp->name().c_str(), (*ni)->_init_refcount[chain])); for (ai=(*ni)->_activation_set[chain].begin(); ai!=(*ni)->_activation_set[chain].end(); ai++) { DEBUG_TRACE (DEBUG::Graph, string_compose (" triggers: %1\n", boost::dynamic_pointer_cast(*ai)->name().c_str())); } } DEBUG_TRACE (DEBUG::Graph, "------------- trigger list:\n"); for (ni=_init_trigger_list[chain].begin(); ni!=_init_trigger_list[chain].end(); ni++) { DEBUG_TRACE (DEBUG::Graph, string_compose ("GraphNode: %1 refcount: %2\n", boost::dynamic_pointer_cast(*ni)->name().c_str(), (*ni)->_init_refcount[chain])); } DEBUG_TRACE (DEBUG::Graph, string_compose ("final activation refcount: %1\n", _init_finished_refcount[chain])); #endif } int Graph::silent_process_routes (pframes_t nframes, framepos_t start_frame, framepos_t end_frame, bool can_record, bool rec_monitors_input, bool& need_butler) { _process_nframes = nframes; _process_start_frame = start_frame; _process_end_frame = end_frame; _process_can_record = can_record; _process_rec_monitors_input = rec_monitors_input; _process_silent = true; _process_noroll = false; _process_retval = 0; _process_need_butler = false; if (!_graph_empty) { DEBUG_TRACE(DEBUG::ProcessThreads, "wake graph for silent process\n"); _callback_start_sem.signal (); _callback_done_sem.wait (); } need_butler = _process_need_butler; return _process_retval; } int Graph::process_routes (pframes_t nframes, framepos_t start_frame, framepos_t end_frame, int declick, bool can_record, bool rec_monitors_input, bool& need_butler) { DEBUG_TRACE (DEBUG::ProcessThreads, string_compose ("graph execution from %1 to %2 = %3\n", start_frame, end_frame, nframes)); _process_nframes = nframes; _process_start_frame = start_frame; _process_end_frame = end_frame; _process_can_record = can_record; _process_rec_monitors_input = rec_monitors_input; _process_declick = declick; _process_silent = false; _process_noroll = false; _process_retval = 0; _process_need_butler = false; DEBUG_TRACE(DEBUG::ProcessThreads, "wake graph for non-silent process\n"); _callback_start_sem.signal (); _callback_done_sem.wait (); DEBUG_TRACE (DEBUG::ProcessThreads, "graph execution complete\n"); need_butler = _process_need_butler; return _process_retval; } int Graph::routes_no_roll (pframes_t nframes, framepos_t start_frame, framepos_t end_frame, bool non_rt_pending, bool can_record, int declick) { DEBUG_TRACE (DEBUG::ProcessThreads, string_compose ("no-roll graph execution from %1 to %2 = %3\n", start_frame, end_frame, nframes)); _process_nframes = nframes; _process_start_frame = start_frame; _process_end_frame = end_frame; _process_can_record = can_record; _process_declick = declick; _process_non_rt_pending = non_rt_pending; _process_silent = false; _process_noroll = true; _process_retval = 0; _process_need_butler = false; DEBUG_TRACE(DEBUG::ProcessThreads, "wake graph for no-roll process\n"); _callback_start_sem.signal (); _callback_done_sem.wait (); return _process_retval; } void Graph::process_one_route (Route* route) { bool need_butler = false; int retval; assert (route); DEBUG_TRACE (DEBUG::ProcessThreads, string_compose ("%1 runs route %2\n", pthread_self(), route->name())); if (_process_silent) { retval = route->silent_roll (_process_nframes, _process_start_frame, _process_end_frame, _process_can_record, _process_rec_monitors_input, need_butler); } else if (_process_noroll) { route->set_pending_declick (_process_declick); retval = route->no_roll (_process_nframes, _process_start_frame, _process_end_frame, _process_non_rt_pending, _process_can_record, _process_declick); } else { route->set_pending_declick (_process_declick); retval = route->roll (_process_nframes, _process_start_frame, _process_end_frame, _process_declick, _process_can_record, _process_rec_monitors_input, need_butler); } if (retval) { _process_retval = retval; } if (need_butler) { _process_need_butler = true; } } bool Graph::in_process_thread () const { list::const_iterator i = _thread_list.begin (); while (i != _thread_list.end() && *i != pthread_self ()) { ++i; } return i != _thread_list.end (); }