/*
This file is part of Ingen.
Copyright 2007-2017 David Robillard
Ingen is free software: you can redistribute it and/or modify it under the
terms of the GNU Affero General Public License as published by the Free
Software Foundation, either version 3 of the License, or any later version.
Ingen 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 Affero General Public License for details.
You should have received a copy of the GNU Affero General Public License
along with Ingen. If not, see .
*/
#include "ingen_config.h"
#include
#include
#include
#include "lv2/lv2plug.in/ns/ext/buf-size/buf-size.h"
#include "lv2/lv2plug.in/ns/ext/state/state.h"
#include "events/CreateGraph.hpp"
#include "ingen/AtomReader.hpp"
#include "ingen/Configuration.hpp"
#include "ingen/Log.hpp"
#include "ingen/Store.hpp"
#include "ingen/StreamWriter.hpp"
#include "ingen/Tee.hpp"
#include "ingen/URIs.hpp"
#include "ingen/World.hpp"
#include "ingen/types.hpp"
#include "raul/Maid.hpp"
#include "BlockFactory.hpp"
#include "Broadcaster.hpp"
#include "BufferFactory.hpp"
#include "ControlBindings.hpp"
#include "Driver.hpp"
#include "Engine.hpp"
#include "Event.hpp"
#include "EventWriter.hpp"
#include "GraphImpl.hpp"
#include "LV2Options.hpp"
#include "PostProcessor.hpp"
#include "PreProcessContext.hpp"
#include "PreProcessor.hpp"
#include "RunContext.hpp"
#include "ThreadManager.hpp"
#include "UndoStack.hpp"
#include "Worker.hpp"
#ifdef HAVE_SOCKET
#include "SocketListener.hpp"
#endif
using namespace std;
namespace Ingen {
namespace Server {
INGEN_THREAD_LOCAL unsigned ThreadManager::flags(0);
bool ThreadManager::single_threaded(true);
Engine::Engine(Ingen::World* world)
: _world(world)
, _maid(new Raul::Maid)
, _block_factory(new BlockFactory(world))
, _broadcaster(new Broadcaster())
, _buffer_factory(new BufferFactory(*this, world->uris()))
, _control_bindings(NULL)
, _event_writer(new EventWriter(*this))
, _interface(_event_writer)
, _atom_interface(nullptr)
, _options(new LV2Options(world->uris()))
, _undo_stack(new UndoStack(_world->uris(), _world->uri_map()))
, _redo_stack(new UndoStack(_world->uris(), _world->uri_map()))
, _pre_processor(new PreProcessor(*this))
, _post_processor(new PostProcessor(*this))
, _root_graph(NULL)
, _worker(new Worker(world->log(), event_queue_size()))
, _sync_worker(new Worker(world->log(), event_queue_size(), true))
, _listener(NULL)
, _cycle_start_time(0)
, _rand_engine(0)
, _uniform_dist(0.0f, 1.0f)
, _quit_flag(false)
, _reset_load_flag(false)
, _atomic_bundles(world->conf().option("atomic-bundles").get())
, _activated(false)
{
if (!world->store()) {
world->set_store(SPtr(new Store()));
}
_control_bindings = new ControlBindings(*this);
for (int i = 0; i < world->conf().option("threads").get(); ++i) {
Raul::RingBuffer* ring = new Raul::RingBuffer(24 * event_queue_size());
_notifications.push_back(ring);
_run_contexts.push_back(new RunContext(*this, ring, i, i > 0));
}
_world->lv2_features().add_feature(_worker->schedule_feature());
_world->lv2_features().add_feature(_options);
_world->lv2_features().add_feature(
SPtr(
new LV2Features::EmptyFeature(LV2_BUF_SIZE__powerOf2BlockLength)));
_world->lv2_features().add_feature(
SPtr(
new LV2Features::EmptyFeature(LV2_BUF_SIZE__fixedBlockLength)));
_world->lv2_features().add_feature(
SPtr(
new LV2Features::EmptyFeature(LV2_BUF_SIZE__boundedBlockLength)));
_world->lv2_features().add_feature(
SPtr(
new LV2Features::EmptyFeature(LV2_STATE__loadDefaultState)));
if (world->conf().option("dump").get()) {
SPtr tee(new Tee());
SPtr dumper(new StreamWriter(world->uri_map(),
world->uris(),
Raul::URI("ingen:/engine"),
stderr,
ColorContext::Color::MAGENTA));
tee->add_sink(_event_writer);
tee->add_sink(dumper);
_interface = tee;
}
_atom_interface = new AtomReader(
world->uri_map(), world->uris(), world->log(), *_interface.get());
}
Engine::~Engine()
{
_root_graph = NULL;
deactivate();
// Process all pending events
const FrameTime end = std::numeric_limits::max();
RunContext& ctx = run_context();
locate(ctx.end(), end - ctx.end());
_post_processor->set_end_time(end);
_post_processor->process();
while (!_pre_processor->empty()) {
_pre_processor->process(ctx, *_post_processor, 1);
_post_processor->process();
}
delete _atom_interface;
// Delete run contexts
_quit_flag = true;
_tasks_available.notify_all();
for (RunContext* ctx : _run_contexts) {
ctx->join();
delete ctx;
}
for (Raul::RingBuffer* ring : _notifications) {
delete ring;
}
const SPtr store = this->store();
if (store) {
for (auto& s : *store.get()) {
if (!dynamic_ptr_cast(s.second)->parent()) {
s.second.reset();
}
}
store->clear();
}
_world->set_store(SPtr());
#ifdef HAVE_SOCKET
delete _listener;
#endif
delete _pre_processor;
delete _post_processor;
delete _undo_stack;
delete _redo_stack;
delete _block_factory;
delete _control_bindings;
delete _broadcaster;
delete _sync_worker;
delete _worker;
delete _maid;
_driver.reset();
delete _buffer_factory;
munlockall();
}
void
Engine::listen()
{
#ifdef HAVE_SOCKET
_listener = new SocketListener(*this);
#endif
}
void
Engine::advance(SampleCount nframes)
{
for (RunContext* ctx : _run_contexts) {
ctx->locate(ctx->start() + nframes, block_length());
}
}
void
Engine::locate(FrameTime s, SampleCount nframes)
{
for (RunContext* ctx : _run_contexts) {
ctx->locate(s, nframes);
}
}
void
Engine::flush_events(const std::chrono::milliseconds& sleep_ms)
{
bool finished = !pending_events();
while (!finished) {
// Run one audio block to execute prepared events
run(block_length());
advance(block_length());
// Run one main iteration to post-process events
main_iteration();
// Sleep before continuing if there are still events to process
if (!(finished = !pending_events())) {
std::this_thread::sleep_for(sleep_ms);
}
}
}
void
Engine::emit_notifications(FrameTime end)
{
for (RunContext* ctx : _run_contexts) {
ctx->emit_notifications(end);
}
}
bool
Engine::pending_notifications()
{
for (const RunContext* ctx : _run_contexts) {
if (ctx->pending_notifications()) {
return true;
}
}
return false;
}
bool
Engine::wait_for_tasks()
{
if (!_quit_flag) {
std::unique_lock lock(_tasks_mutex);
_tasks_available.wait(lock);
}
return !_quit_flag;
}
void
Engine::signal_tasks()
{
_tasks_available.notify_all();
}
Task*
Engine::steal_task(unsigned start_thread)
{
for (unsigned i = 0; i < _run_contexts.size(); ++i) {
const unsigned id = (start_thread + i) % _run_contexts.size();
RunContext* const ctx = _run_contexts[id];
Task* par = ctx->task();
if (par) {
Task* t = par->steal(*ctx);
if (t) {
return t;
}
}
}
return NULL;
}
SPtr
Engine::store() const
{
return _world->store();
}
SampleRate
Engine::sample_rate() const
{
return _driver->sample_rate();
}
SampleCount
Engine::block_length() const
{
return _driver->block_length();
}
size_t
Engine::sequence_size() const
{
return _driver->seq_size();
}
size_t
Engine::event_queue_size() const
{
return world()->conf().option("queue-size").get();
}
void
Engine::quit()
{
_quit_flag = true;
}
Properties
Engine::load_properties() const
{
const Ingen::URIs& uris = world()->uris();
return { { uris.ingen_meanRunLoad,
uris.forge.make(floorf(_run_load.mean) / 100.0f) },
{ uris.ingen_minRunLoad,
uris.forge.make(_run_load.min / 100.0f) },
{ uris.ingen_maxRunLoad,
uris.forge.make(_run_load.max / 100.0f) } };
}
bool
Engine::main_iteration()
{
_post_processor->process();
_maid->cleanup();
if (_run_load.changed) {
_broadcaster->put(Raul::URI("ingen:/engine"), load_properties());
_run_load.changed = false;
}
return !_quit_flag;
}
void
Engine::set_driver(SPtr driver)
{
_driver = driver;
for (RunContext* ctx : _run_contexts) {
ctx->set_priority(driver->real_time_priority());
ctx->set_rate(driver->sample_rate());
}
_buffer_factory->set_block_length(driver->block_length());
_options->set(sample_rate(),
block_length(),
buffer_factory()->default_size(_world->uris().atom_Sequence));
}
SampleCount
Engine::event_time()
{
if (ThreadManager::single_threaded) {
return 0;
}
return _driver->frame_time() + _driver->block_length();
}
uint64_t
Engine::current_time() const
{
return _clock.now_microseconds();
}
void
Engine::reset_load()
{
_reset_load_flag = true;
}
bool
Engine::activate()
{
if (!_driver) {
return false;
}
ThreadManager::single_threaded = true;
const Ingen::URIs& uris = world()->uris();
if (!_root_graph) {
// No root graph has been loaded, create an empty one
const Properties properties = {
{uris.rdf_type, uris.ingen_Graph},
{uris.ingen_polyphony,
Property(_world->forge().make(1),
Resource::Graph::INTERNAL)}};
enqueue_event(
new Events::CreateGraph(
*this, SPtr(), -1, 0, Raul::Path("/"), properties));
flush_events(std::chrono::milliseconds(10));
if (!_root_graph) {
return false;
}
}
_driver->activate();
_root_graph->enable();
ThreadManager::single_threaded = false;
_activated = true;
return true;
}
void
Engine::deactivate()
{
if (_driver) {
_driver->deactivate();
}
if (_root_graph) {
_root_graph->deactivate();
}
ThreadManager::single_threaded = true;
_activated = false;
}
unsigned
Engine::run(uint32_t sample_count)
{
RunContext& ctx = run_context();
_cycle_start_time = current_time();
post_processor()->set_end_time(ctx.end());
// Process events that came in during the last cycle
// (Aiming for jitter-free 1 block event latency, ideally)
const unsigned n_processed_events = process_events();
// Reset load if graph structure has changed
if (_reset_load_flag) {
_run_load = Load();
_reset_load_flag = false;
}
// Run root graph
if (_root_graph) {
// Apply control bindings to input
control_bindings()->pre_process(
ctx, _root_graph->port_impl(0)->buffer(0).get());
// Run root graph for this cycle
_root_graph->process(ctx);
// Emit control binding feedback
control_bindings()->post_process(
ctx, _root_graph->port_impl(1)->buffer(0).get());
}
// Update load for this cycle
if (ctx.duration() > 0) {
_run_load.update(current_time() - _cycle_start_time, ctx.duration());
}
return n_processed_events;
}
bool
Engine::pending_events()
{
return !_pre_processor->empty() || _post_processor->pending();
}
void
Engine::enqueue_event(Event* ev, Event::Mode mode)
{
_pre_processor->event(ev, mode);
}
unsigned
Engine::process_events()
{
const size_t MAX_EVENTS_PER_CYCLE = run_context().nframes() / 8;
return _pre_processor->process(
run_context(), *_post_processor, MAX_EVENTS_PER_CYCLE);
}
unsigned
Engine::process_all_events()
{
return _pre_processor->process(run_context(), *_post_processor, 0);
}
void
Engine::register_client(SPtr client)
{
log().info(fmt("Registering client <%1%>\n") % client->uri().c_str());
_broadcaster->register_client(client);
}
bool
Engine::unregister_client(SPtr client)
{
log().info(fmt("Unregistering client <%1%>\n") % client->uri().c_str());
return _broadcaster->unregister_client(client);
}
} // namespace Server
} // namespace Ingen