/* * Carla Plugin Host * Copyright (C) 2011-2014 Filipe Coelho * * 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 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. * * For a full copy of the GNU General Public License see the doc/GPL.txt file. */ #include "CarlaEngineInternal.hpp" #include "CarlaPlugin.hpp" #include "CarlaMIDI.h" #include "CarlaMathUtils.hpp" // ----------------------------------------------------------------------- CARLA_BACKEND_START_NAMESPACE #if 0 } // Fix editor indentation #endif // ----------------------------------------------------------------------- // EngineControlEvent void EngineControlEvent::dumpToMidiData(const uint8_t channel, uint8_t& size, uint8_t data[3]) const noexcept { size = 0; switch (type) { case kEngineControlEventTypeNull: break; case kEngineControlEventTypeParameter: if (param >= MAX_MIDI_VALUE) { // out of bounds. do nothing } else if (MIDI_IS_CONTROL_BANK_SELECT(param)) { size = 3; data[0] = static_cast(MIDI_STATUS_CONTROL_CHANGE | (channel & MIDI_CHANNEL_BIT)); data[1] = MIDI_CONTROL_BANK_SELECT; data[2] = uint8_t(carla_fixValue(0.0f, float(MAX_MIDI_VALUE-1), value)); } else { size = 3; data[0] = static_cast(MIDI_STATUS_CONTROL_CHANGE | (channel & MIDI_CHANNEL_BIT)); data[1] = static_cast(param); data[2] = uint8_t(carla_fixValue(0.0f, 1.0f, value) * float(MAX_MIDI_VALUE-1)); } break; case kEngineControlEventTypeMidiBank: size = 3; data[0] = static_cast(MIDI_STATUS_CONTROL_CHANGE | (channel & MIDI_CHANNEL_BIT)); data[1] = MIDI_CONTROL_BANK_SELECT; data[2] = uint8_t(carla_fixValue(0, MAX_MIDI_VALUE-1, param)); break; case kEngineControlEventTypeMidiProgram: size = 2; data[0] = static_cast(MIDI_STATUS_PROGRAM_CHANGE | (channel & MIDI_CHANNEL_BIT)); data[1] = uint8_t(carla_fixValue(0, MAX_MIDI_VALUE-1, param)); break; case kEngineControlEventTypeAllSoundOff: size = 2; data[0] = static_cast(MIDI_STATUS_CONTROL_CHANGE | (channel & MIDI_CHANNEL_BIT)); data[1] = MIDI_CONTROL_ALL_SOUND_OFF; break; case kEngineControlEventTypeAllNotesOff: size = 2; data[0] = static_cast(MIDI_STATUS_CONTROL_CHANGE | (channel & MIDI_CHANNEL_BIT)); data[1] = MIDI_CONTROL_ALL_NOTES_OFF; break; } } // ----------------------------------------------------------------------- // EngineEvent void EngineEvent::fillFromMidiData(const uint8_t size, const uint8_t* const data) noexcept { if (size == 0 || data == nullptr || data[0] < MIDI_STATUS_NOTE_OFF) { type = kEngineEventTypeNull; channel = 0; return; } // get channel channel = uint8_t(MIDI_GET_CHANNEL_FROM_DATA(data)); // get status const uint8_t midiStatus(uint8_t(MIDI_GET_STATUS_FROM_DATA(data))); if (midiStatus == MIDI_STATUS_CONTROL_CHANGE) { type = kEngineEventTypeControl; const uint8_t midiControl(data[1]); if (MIDI_IS_CONTROL_BANK_SELECT(midiControl)) { CARLA_SAFE_ASSERT_INT(size == 3, size); const uint8_t midiBank(data[2]); ctrl.type = kEngineControlEventTypeMidiBank; ctrl.param = midiBank; ctrl.value = 0.0f; } else if (midiControl == MIDI_CONTROL_ALL_SOUND_OFF) { CARLA_SAFE_ASSERT_INT(size == 2, size); ctrl.type = kEngineControlEventTypeAllSoundOff; ctrl.param = 0; ctrl.value = 0.0f; } else if (midiControl == MIDI_CONTROL_ALL_NOTES_OFF) { CARLA_SAFE_ASSERT_INT(size == 2, size); ctrl.type = kEngineControlEventTypeAllNotesOff; ctrl.param = 0; ctrl.value = 0.0f; } else { CARLA_SAFE_ASSERT_INT2(size == 3, size, midiControl); const uint8_t midiValue(carla_fixValue(0, 127, data[2])); // ensures 0.0<->1.0 value range ctrl.type = kEngineControlEventTypeParameter; ctrl.param = midiControl; ctrl.value = float(midiValue)/127.0f; } } else if (midiStatus == MIDI_STATUS_PROGRAM_CHANGE) { CARLA_SAFE_ASSERT_INT2(size == 2, size, data[1]); type = kEngineEventTypeControl; const uint8_t midiProgram(data[1]); ctrl.type = kEngineControlEventTypeMidiProgram; ctrl.param = midiProgram; ctrl.value = 0.0f; } else { type = kEngineEventTypeMidi; midi.port = 0; midi.size = size; if (size > EngineMidiEvent::kDataSize) { midi.dataExt = data; std::memset(midi.data, 0, sizeof(uint8_t)*EngineMidiEvent::kDataSize); } else { midi.data[0] = midiStatus; uint8_t i=1; for (; i < midi.size; ++i) midi.data[i] = data[i]; for (; i < EngineMidiEvent::kDataSize; ++i) midi.data[i] = 0; midi.dataExt = nullptr; } } } // ----------------------------------------------------------------------- // EngineOptions EngineOptions::EngineOptions() noexcept #ifdef CARLA_OS_LINUX : processMode(ENGINE_PROCESS_MODE_MULTIPLE_CLIENTS), transportMode(ENGINE_TRANSPORT_MODE_JACK), #else : processMode(ENGINE_PROCESS_MODE_CONTINUOUS_RACK), transportMode(ENGINE_TRANSPORT_MODE_INTERNAL), #endif forceStereo(false), preferPluginBridges(false), preferUiBridges(true), uisAlwaysOnTop(true), maxParameters(MAX_DEFAULT_PARAMETERS), uiBridgesTimeout(4000), audioNumPeriods(2), audioBufferSize(512), audioSampleRate(44100), audioDevice(nullptr), binaryDir(nullptr), resourceDir(nullptr) {} EngineOptions::~EngineOptions() { if (audioDevice != nullptr) { delete[] audioDevice; audioDevice = nullptr; } if (binaryDir != nullptr) { delete[] binaryDir; binaryDir = nullptr; } if (resourceDir != nullptr) { delete[] resourceDir; resourceDir = nullptr; } } // ----------------------------------------------------------------------- // EngineTimeInfoBBT EngineTimeInfoBBT::EngineTimeInfoBBT() noexcept : bar(0), beat(0), tick(0), barStartTick(0.0), beatsPerBar(0.0f), beatType(0.0f), ticksPerBeat(0.0), beatsPerMinute(0.0) {} // ----------------------------------------------------------------------- // EngineTimeInfo EngineTimeInfo::EngineTimeInfo() noexcept : playing(false), frame(0), usecs(0), valid(0x0) {} void EngineTimeInfo::clear() noexcept { playing = false; frame = 0; usecs = 0; valid = 0x0; } bool EngineTimeInfo::operator==(const EngineTimeInfo& timeInfo) const noexcept { if (timeInfo.playing != playing || timeInfo.frame != frame || timeInfo.valid != valid) return false; if ((valid & kValidBBT) == 0) return true; if (timeInfo.bbt.beatsPerMinute != bbt.beatsPerMinute) return false; return true; } bool EngineTimeInfo::operator!=(const EngineTimeInfo& timeInfo) const noexcept { return !operator==(timeInfo); } // ----------------------------------------------------------------------- // EngineRackBuffers EngineRackBuffers::EngineRackBuffers(const uint32_t bufferSize) : lastConnectionId(0) { resize(bufferSize); } EngineRackBuffers::~EngineRackBuffers() { clear(); } void EngineRackBuffers::clear() { lastConnectionId = 0; if (in[0] != nullptr) { delete[] in[0]; in[0] = nullptr; } if (in[1] != nullptr) { delete[] in[1]; in[1] = nullptr; } if (out[0] != nullptr) { delete[] out[0]; out[0] = nullptr; } if (out[1] != nullptr) { delete[] out[1]; out[1] = nullptr; } connectedIns[0].clear(); connectedIns[1].clear(); connectedOuts[0].clear(); connectedOuts[1].clear(); usedConnections.clear(); } void EngineRackBuffers::resize(const uint32_t bufferSize) { if (bufferSize > 0) { in[0] = new float[bufferSize]; in[1] = new float[bufferSize]; out[0] = new float[bufferSize]; out[1] = new float[bufferSize]; } else { in[0] = nullptr; in[1] = nullptr; out[0] = nullptr; out[1] = nullptr; } } const char* const* EngineRackBuffers::getConnections() const { if (usedConnections.count() == 0) return nullptr; LinkedList connList; char strBuf[STR_MAX+1]; for (LinkedList::Itenerator it=usedConnections.begin(); it.valid(); it.next()) { const ConnectionToId& connection(it.getValue()); const int otherPort((connection.portOut >= 0) ? connection.portOut : connection.portIn); const int carlaPort((otherPort == connection.portOut) ? connection.portIn : connection.portOut); if (otherPort >= RACK_PATCHBAY_GROUP_MIDI_OUT*1000) { CARLA_SAFE_ASSERT_CONTINUE(carlaPort == RACK_PATCHBAY_PORT_MIDI_IN); const int portId(otherPort-RACK_PATCHBAY_GROUP_MIDI_OUT*1000); std::sprintf(strBuf, "MidiOut:%i", portId+1); connList.append(carla_strdup(strBuf)); connList.append(carla_strdup("Carla:MidiOut")); } else if (otherPort >= RACK_PATCHBAY_GROUP_MIDI_IN*1000) { CARLA_SAFE_ASSERT_CONTINUE(carlaPort == RACK_PATCHBAY_PORT_MIDI_OUT); const int portId(otherPort-RACK_PATCHBAY_GROUP_MIDI_IN*1000); connList.append(carla_strdup("Carla:MidiIn")); std::sprintf(strBuf, "MidiIn:%i", portId+1); connList.append(carla_strdup(strBuf)); } else if (otherPort >= RACK_PATCHBAY_GROUP_AUDIO_OUT*1000) { CARLA_SAFE_ASSERT_CONTINUE(carlaPort == RACK_PATCHBAY_PORT_AUDIO_OUT1 || carlaPort == RACK_PATCHBAY_PORT_AUDIO_OUT2); const int portId(otherPort-RACK_PATCHBAY_GROUP_AUDIO_OUT*1000); std::sprintf(strBuf, "AudioOut:%i", portId+1); connList.append(carla_strdup(strBuf)); connList.append(carla_strdup((carlaPort == RACK_PATCHBAY_PORT_AUDIO_OUT1) ? "Carla:AudioOut1" : "Carla:AudioOut2")); } else if (otherPort >= RACK_PATCHBAY_GROUP_AUDIO_IN*1000) { CARLA_SAFE_ASSERT_CONTINUE(carlaPort == RACK_PATCHBAY_PORT_AUDIO_IN1 || carlaPort == RACK_PATCHBAY_PORT_AUDIO_IN2); const int portId(otherPort-RACK_PATCHBAY_GROUP_AUDIO_IN*1000); connList.append(carla_strdup((carlaPort == RACK_PATCHBAY_PORT_AUDIO_IN1) ? "Carla:AudioIn1" : "Carla:AudioIn2")); std::sprintf(strBuf, "AudioIn:%i", portId+1); connList.append(carla_strdup(strBuf)); } else { CARLA_SAFE_ASSERT_RETURN(false, nullptr); } } const size_t connCount(connList.count()); if (connCount == 0) return nullptr; const char** const retConns = new const char*[connCount+1]; for (size_t i=0; i < connCount; ++i) retConns[i] = connList.getAt(i); retConns[connCount] = nullptr; connList.clear(); return retConns; } // ----------------------------------------------------------------------- // EnginePatchbayBuffers EnginePatchbayBuffers::EnginePatchbayBuffers(const uint32_t bufferSize) { resize(bufferSize); } EnginePatchbayBuffers::~EnginePatchbayBuffers() { clear(); } void EnginePatchbayBuffers::clear() { } void EnginePatchbayBuffers::resize(const uint32_t /*bufferSize*/) { } const char* const* EnginePatchbayBuffers::getConnections() const { return nullptr; } // ----------------------------------------------------------------------- // InternalAudio EngineInternalAudio::EngineInternalAudio() noexcept : isReady(false), usePatchbay(false), inCount(0), outCount(0) { rack = nullptr; } EngineInternalAudio::~EngineInternalAudio() noexcept { CARLA_SAFE_ASSERT(! isReady); CARLA_SAFE_ASSERT(rack == nullptr); } void EngineInternalAudio::initPatchbay() noexcept { if (usePatchbay) { CARLA_SAFE_ASSERT_RETURN(patchbay != nullptr,); // TODO } else { CARLA_SAFE_ASSERT_RETURN(rack != nullptr,); rack->lastConnectionId = 0; rack->usedConnections.clear(); } } void EngineInternalAudio::clear() { isReady = false; inCount = 0; outCount = 0; if (usePatchbay) { CARLA_SAFE_ASSERT_RETURN(patchbay != nullptr,); delete patchbay; patchbay = nullptr; } else { CARLA_SAFE_ASSERT_RETURN(rack != nullptr,); delete rack; rack = nullptr; } } void EngineInternalAudio::create(const uint32_t bufferSize) { if (usePatchbay) { CARLA_SAFE_ASSERT_RETURN(patchbay == nullptr,); patchbay = new EnginePatchbayBuffers(bufferSize); } else { CARLA_SAFE_ASSERT_RETURN(rack == nullptr,); rack = new EngineRackBuffers(bufferSize); } isReady = true; } void EngineInternalAudio::resize(const uint32_t bufferSize) { if (usePatchbay) { CARLA_SAFE_ASSERT_RETURN(patchbay != nullptr,); patchbay->resize(bufferSize); } else { CARLA_SAFE_ASSERT_RETURN(rack != nullptr,); rack->resize(bufferSize); } } // ----------------------------------------------------------------------- // InternalEvents EngineInternalEvents::EngineInternalEvents() noexcept : in(nullptr), out(nullptr) {} EngineInternalEvents::~EngineInternalEvents() noexcept { CARLA_ASSERT(in == nullptr); CARLA_ASSERT(out == nullptr); } // ----------------------------------------------------------------------- // InternalTime EngineInternalTime::EngineInternalTime() noexcept : playing(false), frame(0) {} // ----------------------------------------------------------------------- // NextAction EngineNextAction::EngineNextAction() noexcept : opcode(kEnginePostActionNull), pluginId(0), value(0) {} EngineNextAction::~EngineNextAction() noexcept { CARLA_ASSERT(opcode == kEnginePostActionNull); } void EngineNextAction::ready() noexcept { mutex.lock(); mutex.unlock(); } // ----------------------------------------------------------------------- // EnginePluginData void EnginePluginData::clear() noexcept { plugin = nullptr; insPeak[0] = insPeak[1] = 0.0f; outsPeak[0] = outsPeak[1] = 0.0f; } // ----------------------------------------------------------------------- // CarlaEngineProtectedData CarlaEngineProtectedData::CarlaEngineProtectedData(CarlaEngine* const engine) : osc(engine), thread(engine), oscData(nullptr), callback(nullptr), callbackPtr(nullptr), hints(0x0), bufferSize(0), sampleRate(0.0), aboutToClose(false), curPluginCount(0), maxPluginNumber(0), nextPluginId(0), plugins(nullptr) {} CarlaEngineProtectedData::~CarlaEngineProtectedData() noexcept { CARLA_SAFE_ASSERT(curPluginCount == 0); CARLA_SAFE_ASSERT(maxPluginNumber == 0); CARLA_SAFE_ASSERT(nextPluginId == 0); CARLA_SAFE_ASSERT(plugins == nullptr); } // ----------------------------------------------------------------------- void CarlaEngineProtectedData::doPluginRemove() noexcept { CARLA_SAFE_ASSERT_RETURN(curPluginCount > 0,); CARLA_SAFE_ASSERT_RETURN(nextAction.pluginId < curPluginCount,); --curPluginCount; // move all plugins 1 spot backwards for (unsigned int i=nextAction.pluginId; i < curPluginCount; ++i) { CarlaPlugin* const plugin(plugins[i+1].plugin); CARLA_SAFE_ASSERT_BREAK(plugin != nullptr); plugin->setId(i); plugins[i].plugin = plugin; plugins[i].insPeak[0] = 0.0f; plugins[i].insPeak[1] = 0.0f; plugins[i].outsPeak[0] = 0.0f; plugins[i].outsPeak[1] = 0.0f; } const unsigned int id(curPluginCount); // reset last plugin (now removed) plugins[id].plugin = nullptr; plugins[id].insPeak[0] = 0.0f; plugins[id].insPeak[1] = 0.0f; plugins[id].outsPeak[0] = 0.0f; plugins[id].outsPeak[1] = 0.0f; } void CarlaEngineProtectedData::doPluginsSwitch() noexcept { CARLA_SAFE_ASSERT_RETURN(curPluginCount >= 2,); const unsigned int idA(nextAction.pluginId); const unsigned int idB(nextAction.value); CARLA_SAFE_ASSERT_RETURN(idA < curPluginCount,); CARLA_SAFE_ASSERT_RETURN(idB < curPluginCount,); CARLA_SAFE_ASSERT_RETURN(plugins[idA].plugin != nullptr,); CARLA_SAFE_ASSERT_RETURN(plugins[idB].plugin != nullptr,); #if 0 std::swap(plugins[idA].plugin, plugins[idB].plugin); #else CarlaPlugin* const tmp(plugins[idA].plugin); plugins[idA].plugin = plugins[idB].plugin; plugins[idB].plugin = tmp; #endif } void CarlaEngineProtectedData::doNextPluginAction(const bool unlock) noexcept { switch (nextAction.opcode) { case kEnginePostActionNull: break; case kEnginePostActionZeroCount: curPluginCount = 0; break; case kEnginePostActionRemovePlugin: doPluginRemove(); break; case kEnginePostActionSwitchPlugins: doPluginsSwitch(); break; } nextAction.opcode = kEnginePostActionNull; nextAction.pluginId = 0; nextAction.value = 0; if (unlock) nextAction.mutex.unlock(); } // ----------------------------------------------------------------------- #ifndef BUILD_BRIDGE void CarlaEngineProtectedData::processRack(float* inBufReal[2], float* outBuf[2], const uint32_t frames, const bool isOffline) { CARLA_SAFE_ASSERT_RETURN(bufEvents.in != nullptr,); CARLA_SAFE_ASSERT_RETURN(bufEvents.out != nullptr,); // safe copy float inBuf0[frames]; float inBuf1[frames]; float* inBuf[2] = { inBuf0, inBuf1 }; // initialize audio inputs FLOAT_COPY(inBuf0, inBufReal[0], frames); FLOAT_COPY(inBuf1, inBufReal[1], frames); // initialize audio outputs (zero) FLOAT_CLEAR(outBuf[0], frames); FLOAT_CLEAR(outBuf[1], frames); // initialize event outputs (zero) carla_zeroStruct(bufEvents.out, kMaxEngineEventInternalCount); bool processed = false; uint32_t oldAudioInCount = 0; uint32_t oldMidiOutCount = 0; // process plugins for (unsigned int i=0; i < curPluginCount; ++i) { CarlaPlugin* const plugin = plugins[i].plugin; if (plugin == nullptr || ! plugin->isEnabled() || ! plugin->tryLock(isOffline)) continue; if (processed) { // initialize audio inputs (from previous outputs) FLOAT_COPY(inBuf0, outBuf[0], frames); FLOAT_COPY(inBuf1, outBuf[1], frames); // initialize audio outputs (zero) FLOAT_CLEAR(outBuf[0], frames); FLOAT_CLEAR(outBuf[1], frames); // if plugin has no midi out, add previous events if (oldMidiOutCount == 0 && bufEvents.in[0].type != kEngineEventTypeNull) { if (bufEvents.out[0].type != kEngineEventTypeNull) { // TODO: carefully add to input, sorted events } // else nothing needed } else { // initialize event inputs from previous outputs carla_copyStruct(bufEvents.in, bufEvents.out, kMaxEngineEventInternalCount); // initialize event outputs (zero) carla_zeroStruct(bufEvents.out, kMaxEngineEventInternalCount); } } oldAudioInCount = plugin->getAudioInCount(); oldMidiOutCount = plugin->getMidiOutCount(); // process plugin->initBuffers(); plugin->process(inBuf, outBuf, frames); plugin->unlock(); // if plugin has no audio inputs, add input buffer if (oldAudioInCount == 0) { FLOAT_ADD(outBuf[0], inBuf0, frames); FLOAT_ADD(outBuf[1], inBuf1, frames); } // set peaks { EnginePluginData& pluginData(plugins[i]); #ifdef HAVE_JUCE float tmpMin, tmpMax; if (oldAudioInCount > 0) { FloatVectorOperations::findMinAndMax(inBuf0, static_cast(frames), tmpMin, tmpMax); pluginData.insPeak[0] = carla_max(std::abs(tmpMin), std::abs(tmpMax), 1.0f); FloatVectorOperations::findMinAndMax(inBuf1, static_cast(frames), tmpMin, tmpMax); pluginData.insPeak[1] = carla_max(std::abs(tmpMin), std::abs(tmpMax), 1.0f); } else { pluginData.insPeak[0] = 0.0f; pluginData.insPeak[1] = 0.0f; } if (plugin->getAudioOutCount() > 0) { FloatVectorOperations::findMinAndMax(outBuf[0], static_cast(frames), tmpMin, tmpMax); pluginData.outsPeak[0] = carla_max(std::abs(tmpMin), std::abs(tmpMax), 1.0f); FloatVectorOperations::findMinAndMax(outBuf[1], static_cast(frames), tmpMin, tmpMax); pluginData.outsPeak[1] = carla_max(std::abs(tmpMin), std::abs(tmpMax), 1.0f); } else { pluginData.outsPeak[0] = 0.0f; pluginData.outsPeak[1] = 0.0f; } #else float peak1, peak2; if (oldAudioInCount > 0) { peak1 = peak2 = 0.0f; for (uint32_t k=0; k < frames; ++k) { peak1 = carla_max(peak1, std::fabs(inBuf0[k]), 1.0f); peak2 = carla_max(peak2, std::fabs(inBuf1[k]), 1.0f); } pluginData.insPeak[0] = peak1; pluginData.insPeak[1] = peak2; } else { pluginData.insPeak[0] = 0.0f; pluginData.insPeak[1] = 0.0f; } if (plugin->getAudioOutCount() > 0) { peak1 = peak2 = 0.0f; for (uint32_t k=0; k < frames; ++k) { peak1 = carla_max(peak1, std::fabs(outBuf[0][k]), 1.0f); peak2 = carla_max(peak2, std::fabs(outBuf[1][k]), 1.0f); } pluginData.outsPeak[0] = peak1; pluginData.outsPeak[1] = peak2; } else { pluginData.outsPeak[0] = 0.0f; pluginData.outsPeak[1] = 0.0f; } #endif } processed = true; } } void CarlaEngineProtectedData::processRackFull(float** const inBuf, const uint32_t inCount, float** const outBuf, const uint32_t outCount, const uint32_t nframes, const bool isOffline) { EngineRackBuffers* const rack(bufAudio.rack); const CarlaMutex::ScopedLocker sl(rack->connectLock); // connect input buffers if (rack->connectedIns[0].count() == 0) { FLOAT_CLEAR(rack->in[0], nframes); } else { bool first = true; for (LinkedList::Itenerator it = rack->connectedIns[0].begin(); it.valid(); it.next()) { const int& port(it.getValue()); CARLA_SAFE_ASSERT_CONTINUE(port >= 0 && port < static_cast(inCount)); if (first) { FLOAT_COPY(rack->in[0], inBuf[port], nframes); first = false; } else { FLOAT_ADD(rack->in[0], inBuf[port], nframes); } } if (first) FLOAT_CLEAR(rack->in[0], nframes); } if (rack->connectedIns[1].count() == 0) { FLOAT_CLEAR(rack->in[1], nframes); } else { bool first = true; for (LinkedList::Itenerator it = rack->connectedIns[1].begin(); it.valid(); it.next()) { const int& port(it.getValue()); CARLA_SAFE_ASSERT_CONTINUE(port >= 0 && port < static_cast(inCount)); if (first) { FLOAT_COPY(rack->in[1], inBuf[port], nframes); first = false; } else { FLOAT_ADD(rack->in[1], inBuf[port], nframes); } } if (first) FLOAT_CLEAR(rack->in[1], nframes); } FLOAT_CLEAR(rack->out[0], nframes); FLOAT_CLEAR(rack->out[1], nframes); // process processRack(rack->in, rack->out, nframes, isOffline); // connect output buffers if (rack->connectedOuts[0].count() != 0) { for (LinkedList::Itenerator it = rack->connectedOuts[0].begin(); it.valid(); it.next()) { const int& port(it.getValue()); CARLA_SAFE_ASSERT_CONTINUE(port >= 0 && port < static_cast(outCount)); FLOAT_ADD(outBuf[port], rack->out[0], nframes); } } if (rack->connectedOuts[1].count() != 0) { for (LinkedList::Itenerator it = rack->connectedOuts[1].begin(); it.valid(); it.next()) { const int& port(it.getValue()); CARLA_SAFE_ASSERT_CONTINUE(port >= 0 && port < static_cast(outCount)); FLOAT_ADD(outBuf[port], rack->out[1], nframes); } } } #endif // ----------------------------------------------------------------------- // ScopedActionLock CarlaEngineProtectedData::ScopedActionLock::ScopedActionLock(CarlaEngineProtectedData* const data, const EnginePostAction action, const unsigned int pluginId, const unsigned int value, const bool lockWait) noexcept : fData(data) { fData->nextAction.mutex.lock(); CARLA_SAFE_ASSERT_RETURN(fData->nextAction.opcode == kEnginePostActionNull,); fData->nextAction.opcode = action; fData->nextAction.pluginId = pluginId; fData->nextAction.value = value; if (lockWait) { // block wait for unlock on processing side carla_stdout("ScopedPluginAction(%i) - blocking START", pluginId); fData->nextAction.mutex.lock(); carla_stdout("ScopedPluginAction(%i) - blocking DONE", pluginId); } else { fData->doNextPluginAction(false); } } CarlaEngineProtectedData::ScopedActionLock::~ScopedActionLock() noexcept { fData->nextAction.mutex.unlock(); } // ----------------------------------------------------------------------- CARLA_BACKEND_END_NAMESPACE