/* * Copyright (C) 2000-2017 Paul Davis * Copyright (C) 2007-2012 David Robillard * Copyright (C) 2009-2012 Carl Hetherington * Copyright (C) 2013-2019 Robin Gareus * * 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., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. */ #include #include "pbd/xml++.h" #include "ardour/amp.h" #include "ardour/audio_port.h" #include "ardour/audioengine.h" #include "ardour/delivery.h" #include "ardour/io.h" #include "ardour/mtdm.h" #include "ardour/port_insert.h" #include "ardour/session.h" #include "ardour/types.h" #include "pbd/i18n.h" using namespace std; using namespace ARDOUR; using namespace PBD; string PortInsert::name_and_id_new_insert (Session& s, uint32_t& bitslot) { bitslot = s.next_insert_id (); return string_compose (_("insert %1"), bitslot); } PortInsert::PortInsert (Session& s, std::shared_ptr pannable, std::shared_ptr mm) : IOProcessor (s, true, true, name_and_id_new_insert (s, _bitslot), "", DataType::AUDIO, true) , _out (new Delivery (s, _output, pannable, mm, _name, Delivery::Insert)) , _metering (false) , _signal_latency (0) , _mtdm (0) , _latency_detect (false) , _latency_flush_samples (0) , _measured_latency (0) { /* Send */ _out->set_gain_control (std::shared_ptr (new GainControl (_session, Evoral::Parameter(BusSendLevel), std::shared_ptr (new AutomationList (Evoral::Parameter (BusSendLevel), *this))))); _out->set_polarity_control (std::shared_ptr (new AutomationControl (_session, PhaseAutomation, ParameterDescriptor (PhaseAutomation), std::shared_ptr(new AutomationList(Evoral::Parameter(PhaseAutomation), *this)), "polarity-invert"))); _send_meter.reset (new PeakMeter (_session, name())); /* Return */ _gain_control = std::shared_ptr (new GainControl (_session, Evoral::Parameter(InsertReturnLevel), std::shared_ptr (new AutomationList (Evoral::Parameter (InsertReturnLevel), *this)))); _amp.reset (new Amp (_session, _("Return"), _gain_control, true)); _return_meter.reset (new PeakMeter (_session, name())); add_control (_out->gain_control ()); add_control (_out->polarity_control ()); add_control (_gain_control); _io_latency = _session.engine().samples_per_cycle(); input ()->changed.connect_same_thread (*this, boost::bind (&PortInsert::io_changed, this, _1, _2)); output ()->changed.connect_same_thread (*this, boost::bind (&PortInsert::io_changed, this, _1, _2)); } PortInsert::~PortInsert () { _session.unmark_insert_id (_bitslot); delete _mtdm; } void PortInsert::set_pre_fader (bool p) { Processor::set_pre_fader (p); _out->set_pre_fader (p); } void PortInsert::latency_changed () { LatencyChanged (); /* EMIT SIGNAL */ assert (owner ()); static_cast(owner ())->processor_latency_changed (); /* EMIT SIGNAL */ } void PortInsert::start_latency_detection () { if (_latency_detect) { return; } delete _mtdm; _mtdm = new MTDM (_session.sample_rate()); _latency_flush_samples = 0; _latency_detect = true; _measured_latency = 0; } void PortInsert::stop_latency_detection () { if (!_latency_detect) { return; } _latency_flush_samples = effective_latency() + _session.engine().samples_per_cycle(); _latency_detect = false; } void PortInsert::set_measured_latency (samplecnt_t n) { if (_measured_latency == n) { return; } _measured_latency = n; } void PortInsert::run (BufferSet& bufs, samplepos_t start_sample, samplepos_t end_sample, double speed, pframes_t nframes, bool) { const samplecnt_t l = effective_latency (); if (_signal_latency != l) { _signal_latency = l; latency_changed (); } if (_output->n_ports().n_total() == 0) { return; } if (_latency_detect) { if (_input->n_ports().n_audio() != 0) { AudioBuffer& outbuf (_output->ports().nth_audio_port(0)->get_audio_buffer (nframes)); Sample* in = _input->ports().nth_audio_port(0)->get_audio_buffer (nframes).data(); Sample* out = outbuf.data(); _mtdm->process (nframes, in, out); outbuf.set_written (true); } _send_meter->reset (); _return_meter->reset (); return; } else if (_latency_flush_samples) { /* wait for the entire input buffer to drain before picking up input again so that we can't * hear the remnants of whatever MTDM pumped into the pipeline. */ silence (nframes, start_sample); if (_latency_flush_samples > nframes) { _latency_flush_samples -= nframes; } else { _latency_flush_samples = 0; } _send_meter->reset (); _return_meter->reset (); return; } if (!check_active()) { /* deliver silence */ silence (nframes, start_sample); _send_meter->reset (); _return_meter->reset (); return; } _out->run (bufs, start_sample, end_sample, speed, nframes, true); if (_metering) { _send_meter->run (bufs, start_sample, end_sample, speed, nframes, true); } _input->collect_input (bufs, nframes, ChanCount::ZERO); _amp->set_gain_automation_buffer (_session.send_gain_automation_buffer ()); _amp->setup_gain_automation (start_sample, end_sample, nframes); _amp->run (bufs, start_sample, end_sample, speed, nframes, true); if (_metering) { _return_meter->run (bufs, start_sample, end_sample, speed, nframes, true); } } void PortInsert::flush_buffers (samplecnt_t nframes) { _out->flush_buffers (nframes); } XMLNode& PortInsert::state () const { XMLNode& node = IOProcessor::state (); node.set_property ("type", "port"); node.set_property ("bitslot", _bitslot); node.set_property ("latency", _measured_latency); node.set_property ("block-size", _session.get_block_size()); XMLNode* ret = new XMLNode(X_("Return")); ret->add_child_nocopy (_gain_control->get_state()); node.add_child_nocopy (*ret); XMLNode* snd = new XMLNode(X_("Send")); snd->add_child_nocopy (_out->gain_control ()->get_state()); node.add_child_nocopy (*snd); return node; } int PortInsert::set_state (const XMLNode& node, int version) { XMLNodeList nlist = node.children(); XMLNodeIterator niter; XMLPropertyList plist; const XMLNode* insert_node = &node; // legacy sessions: search for child Redirect node for (niter = nlist.begin(); niter != nlist.end(); ++niter) { if ((*niter)->name() == "Redirect") { insert_node = *niter; break; } } IOProcessor::set_state (*insert_node, version); std::string type_str; if (!node.get_property ("type", type_str)) { error << _("XML node describing port insert is missing the `type' field") << endmsg; return -1; } if (type_str != "port") { error << _("non-port insert XML used for port plugin insert") << endmsg; return -1; } uint32_t blocksize = 0; node.get_property ("block-size", blocksize); /* If the period is the same as when the value was saved, * we can recall our latency. */ if (_session.engine().samples_per_cycle () == blocksize && blocksize > 0) { node.get_property ("latency", _measured_latency); } if (!node.property ("ignore-bitslot")) { uint32_t bitslot; if (node.get_property ("bitslot", bitslot)) { _session.unmark_insert_id (_bitslot); _bitslot = bitslot; _session.mark_insert_id (_bitslot); } else { _bitslot = _session.next_insert_id(); } } XMLNode* child = node.child (X_("Send")); if (child && child->children().size () > 0) { _out->gain_control ()->set_state (**child->children().begin(), version); } child = node.child (X_("Return")); if (child && child->children().size () > 0) { _gain_control->set_state (**child->children().begin(), version); } return 0; } ARDOUR::samplecnt_t PortInsert::signal_latency() const { /* because we deliver and collect within the same cycle, * all I/O is necessarily delayed by at least samples_per_cycle(). * * if the return port for insert has its own latency, we * need to take that into account too. */ if (_measured_latency == 0 || _latency_detect) { return _io_latency; } else { return _measured_latency; } } void PortInsert::io_changed (IOChange change, void*) { if (change.type & IOChange::ConnectionsChanged) { if (output ()->connected () && input ()->connected ()) { _io_latency = _input->connected_latency (false) + _output->connected_latency (true); } else { _io_latency = _session.engine().samples_per_cycle (); } } } /** Caller must hold process lock */ bool PortInsert::configure_io (ChanCount in, ChanCount out) { #ifndef PLATFORM_WINDOWS assert (!AudioEngine::instance()->process_lock().trylock()); #endif /* for an insert, processor input corresponds to IO output, and vice versa */ if (_input->ensure_io (in, false, this) != 0) { return false; } if (_output->ensure_io (out, false, this) != 0) { return false; } if (!_send_meter->configure_io (out, out)) { return false; } if (!_return_meter->configure_io (in, in)) { return false; } _out->configure_io (in, out); /* send */ _amp->configure_io (out, in); /* return */ return Processor::configure_io (in, out); } bool PortInsert::can_support_io_configuration (const ChanCount& in, ChanCount& out) { out = in; return true; } bool PortInsert::set_name (const std::string& new_name) { string unique_name = validate_name (new_name, string_compose (_("insert %1"), _bitslot)); if (unique_name.empty ()) { return false; } return IOProcessor::set_name (unique_name); } void PortInsert::activate () { IOProcessor::activate (); _send_meter->activate (); _return_meter->activate (); _amp->activate (); _out->activate (); const samplecnt_t l = effective_latency (); if (_signal_latency != l) { _signal_latency = l; latency_changed (); } } void PortInsert::deactivate () { IOProcessor::deactivate (); _send_meter->deactivate (); _send_meter->reset (); _return_meter->deactivate (); _return_meter->reset (); _amp->deactivate (); _out->deactivate (); const samplecnt_t l = effective_latency (); if (_signal_latency != l) { _signal_latency = l; latency_changed (); } }