/* * Carla LinuxSampler Plugin * Copyright (C) 2011-2013 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 GPL.txt file */ #include "CarlaPluginInternal.hpp" #ifdef WANT_LINUXSAMPLER #include "linuxsampler/EngineFactory.h" #include #include namespace LinuxSampler { // ----------------------------------------------------------------------- // LinuxSampler static values static const float VOLUME_MAX = 3.16227766f; // +10 dB static const float VOLUME_MIN = 0.0f; // -inf dB // ----------------------------------------------------------------------- // LinuxSampler AudioOutputDevice Plugin class AudioOutputDevicePlugin : public AudioOutputDevice { public: AudioOutputDevicePlugin(CarlaBackend::CarlaEngine* const engine, CarlaBackend::CarlaPlugin* const plugin) : AudioOutputDevice(std::map()), kEngine(engine), kPlugin(plugin) { CARLA_ASSERT(engine != nullptr); CARLA_ASSERT(plugin != nullptr); } // ------------------------------------------------------------------- // LinuxSampler virtual methods void Play() override { } bool IsPlaying() override { return (kEngine->isRunning() && kPlugin->enabled()); } void Stop() override { } uint MaxSamplesPerCycle() override { return kEngine->getBufferSize(); } uint SampleRate() override { return kEngine->getSampleRate(); } String Driver() override { return "AudioOutputDevicePlugin"; } AudioChannel* CreateChannel(uint channelNr) override { return new AudioChannel(channelNr, nullptr, 0); } // ------------------------------------------------------------------- // Give public access to the RenderAudio call int Render(const uint samples) { return RenderAudio(samples); } private: CarlaBackend::CarlaEngine* const kEngine; CarlaBackend::CarlaPlugin* const kPlugin; }; // ----------------------------------------------------------------------- // LinuxSampler MidiInputDevice Plugin class MidiInputDevicePlugin : public MidiInputDevice { public: MidiInputDevicePlugin(Sampler* const sampler) : MidiInputDevice(std::map(), sampler) { } // ------------------------------------------------------------------- // LinuxSampler virtual methods void Listen() override { } void StopListen() override { } String Driver() override { return "MidiInputDevicePlugin"; } MidiInputPort* CreateMidiPort() override { return new MidiInputPortPlugin(this, Ports.size()); } // ------------------------------------------------------------------- // Properly delete port (destructor is protected) void DeleteMidiPort(MidiInputPort* const port) { delete (MidiInputPortPlugin*)port; } // ------------------------------------------------------------------- // MIDI Port implementation for this plugin MIDI input driver // (Constructor and destructor are protected) class MidiInputPortPlugin : public MidiInputPort { protected: MidiInputPortPlugin(MidiInputDevicePlugin* const device, const int portNumber) : MidiInputPort(device, portNumber) {} friend class MidiInputDevicePlugin; }; }; } // namespace LinuxSampler // ----------------------------------------------------------------------- CARLA_BACKEND_START_NAMESPACE #if 0 } #endif class LinuxSamplerPlugin : public CarlaPlugin { public: LinuxSamplerPlugin(CarlaEngine* const engine, const unsigned short id, const bool isGIG, const bool use16Outs) : CarlaPlugin(engine, id), kIsGIG(isGIG), kUses16Outs(use16Outs), fSampler(new LinuxSampler::Sampler()), fSamplerChannel(nullptr), fEngine(nullptr), fEngineChannel(nullptr), fAudioOutputDevice(new LinuxSampler::AudioOutputDevicePlugin(engine, this)), fMidiInputDevice(new LinuxSampler::MidiInputDevicePlugin(fSampler)), fMidiInputPort(fMidiInputDevice->CreateMidiPort()), fInstrument(nullptr) { carla_debug("LinuxSamplerPlugin::LinuxSamplerPlugin(%p, %i, %s)", engine, id, bool2str(isGIG)); } ~LinuxSamplerPlugin() override { carla_debug("LinuxSamplerPlugin::~LinuxSamplerPlugin()"); kData->singleMutex.lock(); kData->masterMutex.lock(); if (kData->active) { deactivate(); kData->active = false; } if (fEngine != nullptr) { if (fSamplerChannel != nullptr) { fMidiInputPort->Disconnect(fSamplerChannel->GetEngineChannel()); fEngineChannel->DisconnectAudioOutputDevice(); fSampler->RemoveSamplerChannel(fSamplerChannel); } LinuxSampler::EngineFactory::Destroy(fEngine); } // destructor is private fMidiInputDevice->DeleteMidiPort(fMidiInputPort); delete fMidiInputDevice; delete fAudioOutputDevice; delete fSampler; fInstrumentIds.clear(); clearBuffers(); } // ------------------------------------------------------------------- // Information (base) PluginType type() const override { return kIsGIG ? PLUGIN_GIG : PLUGIN_SFZ; } PluginCategory category() override { return PLUGIN_CATEGORY_SYNTH; } // ------------------------------------------------------------------- // Information (count) // nothing // ------------------------------------------------------------------- // Information (current data) // nothing // ------------------------------------------------------------------- // Information (per-plugin data) unsigned int availableOptions() override { unsigned int options = 0x0; options |= PLUGIN_OPTION_MAP_PROGRAM_CHANGES; options |= PLUGIN_OPTION_SEND_CONTROL_CHANGES; options |= PLUGIN_OPTION_SEND_PITCHBEND; options |= PLUGIN_OPTION_SEND_ALL_SOUND_OFF; return options; } void getLabel(char* const strBuf) override { std::strncpy(strBuf, (const char*)fLabel, STR_MAX); } void getMaker(char* const strBuf) override { std::strncpy(strBuf, (const char*)fMaker, STR_MAX); } void getCopyright(char* const strBuf) override { getMaker(strBuf); } void getRealName(char* const strBuf) override { std::strncpy(strBuf, (const char*)fRealName, STR_MAX); } // ------------------------------------------------------------------- // Set data (state) // nothing // ------------------------------------------------------------------- // Set data (internal stuff) // nothing // ------------------------------------------------------------------- // Set data (plugin-specific stuff) void setMidiProgram(int32_t index, const bool sendGui, const bool sendOsc, const bool sendCallback) override { CARLA_ASSERT(index >= -1 && index < static_cast(kData->midiprog.count)); if (index < -1) index = -1; else if (index > static_cast(kData->midiprog.count)) return; if (kData->ctrlChannel < 0 || kData->ctrlChannel >= 16) return; if (index >= 0) { const uint32_t bank = kData->midiprog.data[index].bank; const uint32_t program = kData->midiprog.data[index].program; const uint32_t rIndex = bank*128 + program; const ScopedSingleProcessLocker spl(this, (sendGui || sendOsc || sendCallback)); if (kData->engine->isOffline()) { fEngineChannel->PrepareLoadInstrument((const char*)fFilename, rIndex); fEngineChannel->LoadInstrument(); } else { fInstrument->LoadInstrumentInBackground(fInstrumentIds[rIndex], fEngineChannel); } } CarlaPlugin::setMidiProgram(index, sendGui, sendOsc, sendCallback); } // ------------------------------------------------------------------- // Plugin state void reload() override { carla_debug("LinuxSamplerPlugin::reload() - start"); CARLA_ASSERT(kData->engine != nullptr); CARLA_ASSERT(fInstrument != nullptr); if (kData->engine == nullptr) return; if (fInstrument == nullptr) return; const ProcessMode processMode(kData->engine->getProccessMode()); // Safely disable plugin for reload const ScopedDisabler sd(this); if (kData->active) deactivate(); clearBuffers(); uint32_t aOuts; aOuts = 2; kData->audioOut.createNew(aOuts); const int portNameSize = kData->engine->maxPortNameSize(); CarlaString portName; // --------------------------------------- // Audio Outputs { // out-left portName.clear(); if (processMode == PROCESS_MODE_SINGLE_CLIENT) { portName = fName; portName += ":"; } portName += "out-left"; portName.truncate(portNameSize); kData->audioOut.ports[0].port = (CarlaEngineAudioPort*)kData->client->addPort(kEnginePortTypeAudio, portName, false); kData->audioOut.ports[0].rindex = 0; // out-right portName.clear(); if (processMode == PROCESS_MODE_SINGLE_CLIENT) { portName = fName; portName += ":"; } portName += "out-right"; portName.truncate(portNameSize); kData->audioOut.ports[1].port = (CarlaEngineAudioPort*)kData->client->addPort(kEnginePortTypeAudio, portName, false); kData->audioOut.ports[1].rindex = 1; } // --------------------------------------- // Event Input { portName.clear(); if (processMode == PROCESS_MODE_SINGLE_CLIENT) { portName = fName; portName += ":"; } portName += "event-in"; portName.truncate(portNameSize); kData->event.portIn = (CarlaEngineEventPort*)kData->client->addPort(kEnginePortTypeEvent, portName, true); } // --------------------------------------- // plugin hints fHints = 0x0; fHints |= PLUGIN_IS_SYNTH; fHints |= PLUGIN_CAN_VOLUME; fHints |= PLUGIN_CAN_BALANCE; // extra plugin hints kData->extraHints = 0x0; kData->extraHints |= PLUGIN_HINT_HAS_MIDI_IN; kData->extraHints |= PLUGIN_HINT_CAN_RUN_RACK; bufferSizeChanged(kData->engine->getBufferSize()); reloadPrograms(true); if (kData->active) activate(); carla_debug("LinuxSamplerPlugin::reload() - end"); } void reloadPrograms(bool init) override { carla_debug("LinuxSamplerPlugin::reloadPrograms(%s)", bool2str(init)); // Delete old programs kData->midiprog.clear(); // Query new programs uint32_t i, count = fInstrumentIds.size(); // sound kits must always have at least 1 midi-program CARLA_ASSERT(count > 0); if (count == 0) return; kData->midiprog.createNew(count); LinuxSampler::InstrumentManager::instrument_info_t info; for (i=0; i < kData->midiprog.count; ++i) { kData->midiprog.data[i].bank = i / 128; kData->midiprog.data[i].program = i % 128; try { info = fInstrument->GetInstrumentInfo(fInstrumentIds[i]); } catch (const LinuxSampler::InstrumentManagerException&) { continue; } kData->midiprog.data[i].name = carla_strdup(info.InstrumentName.c_str()); } #ifndef BUILD_BRIDGE // Update OSC Names if (kData->engine->isOscControlRegistered()) { kData->engine->osc_send_control_set_midi_program_count(fId, count); for (i=0; i < count; ++i) kData->engine->osc_send_control_set_midi_program_data(fId, i, kData->midiprog.data[i].bank, kData->midiprog.data[i].program, kData->midiprog.data[i].name); } #endif if (init) { setMidiProgram(0, false, false, false); } else { kData->engine->callback(CALLBACK_RELOAD_PROGRAMS, fId, 0, 0, 0.0f, nullptr); } } // ------------------------------------------------------------------- // Plugin processing void activate() override { CARLA_ASSERT(fAudioOutputDevice != nullptr); fAudioOutputDevice->Play(); } void deactivate() override { CARLA_ASSERT(fAudioOutputDevice != nullptr); fAudioOutputDevice->Stop(); } void process(float** const, float** const outBuffer, const uint32_t frames) override { uint32_t i, k; // -------------------------------------------------------------------------------------------------------- // Check if active if (! kData->active) { // disable any output sound for (i=0; i < kData->audioOut.count; ++i) carla_zeroFloat(outBuffer[i], frames); return; } // -------------------------------------------------------------------------------------------------------- // Check if needs reset if (kData->needsReset) { if (fOptions & PLUGIN_OPTION_SEND_ALL_SOUND_OFF) { for (k=0, i=MAX_MIDI_CHANNELS; k < MAX_MIDI_CHANNELS; ++k) { fMidiInputPort->DispatchControlChange(MIDI_CONTROL_ALL_NOTES_OFF, 0, k); fMidiInputPort->DispatchControlChange(MIDI_CONTROL_ALL_SOUND_OFF, 0, k); } } else if (kData->ctrlChannel >= 0 && kData->ctrlChannel < MAX_MIDI_CHANNELS) { for (k=0; k < MAX_MIDI_NOTE; ++k) fMidiInputPort->DispatchNoteOff(k, 0, kData->ctrlChannel); } kData->needsReset = false; } // -------------------------------------------------------------------------------------------------------- // Event Input and Processing { // ---------------------------------------------------------------------------------------------------- // MIDI Input (External) if (kData->extNotes.mutex.tryLock()) { while (! kData->extNotes.data.isEmpty()) { const ExternalMidiNote& note(kData->extNotes.data.getFirst(true)); CARLA_ASSERT(note.channel >= 0 && note.channel < MAX_MIDI_CHANNELS); if (note.velo > 0) fMidiInputPort->DispatchNoteOn(note.note, note.velo, note.channel, 0); else fMidiInputPort->DispatchNoteOff(note.note, note.velo, note.channel, 0); } kData->extNotes.mutex.unlock(); } // End of MIDI Input (External) // ---------------------------------------------------------------------------------------------------- // Event Input (System) bool allNotesOffSent = false; bool sampleAccurate = (fOptions & PLUGIN_OPTION_FIXED_BUFFER) == 0; uint32_t time, nEvents = kData->event.portIn->getEventCount(); uint32_t startTime = 0; uint32_t timeOffset = 0; uint32_t nextBankId = 0; if (kData->midiprog.current >= 0 && kData->midiprog.count > 0) nextBankId = kData->midiprog.data[kData->midiprog.current].bank; for (i=0; i < nEvents; ++i) { const EngineEvent& event(kData->event.portIn->getEvent(i)); time = event.time; if (time >= frames) continue; CARLA_ASSERT_INT2(time >= timeOffset, time, timeOffset); if (time > timeOffset && sampleAccurate) { if (processSingle(outBuffer, time - timeOffset, timeOffset)) { startTime = 0; timeOffset = time; if (kData->midiprog.current >= 0 && kData->midiprog.count > 0) nextBankId = kData->midiprog.data[kData->midiprog.current].bank; else nextBankId = 0; } else startTime += timeOffset; } // Control change switch (event.type) { case kEngineEventTypeNull: break; case kEngineEventTypeControl: { const EngineControlEvent& ctrlEvent = event.ctrl; switch (ctrlEvent.type) { case kEngineControlEventTypeNull: break; case kEngineControlEventTypeParameter: { #ifndef BUILD_BRIDGE // Control backend stuff if (event.channel == kData->ctrlChannel) { double value; if (MIDI_IS_CONTROL_BREATH_CONTROLLER(ctrlEvent.param) && (fHints & PLUGIN_CAN_DRYWET) > 0) { value = ctrlEvent.value; setDryWet(value, false, false); postponeRtEvent(kPluginPostRtEventParameterChange, PARAMETER_DRYWET, 0, value); continue; } if (MIDI_IS_CONTROL_CHANNEL_VOLUME(ctrlEvent.param) && (fHints & PLUGIN_CAN_VOLUME) > 0) { value = ctrlEvent.value*127/100; setVolume(value, false, false); postponeRtEvent(kPluginPostRtEventParameterChange, PARAMETER_VOLUME, 0, value); continue; } if (MIDI_IS_CONTROL_BALANCE(ctrlEvent.param) && (fHints & PLUGIN_CAN_BALANCE) > 0) { double left, right; value = ctrlEvent.value/0.5 - 1.0; if (value < 0.0) { left = -1.0; right = (value*2)+1.0; } else if (value > 0.0) { left = (value*2)-1.0; right = 1.0; } else { left = -1.0; right = 1.0; } setBalanceLeft(left, false, false); setBalanceRight(right, false, false); postponeRtEvent(kPluginPostRtEventParameterChange, PARAMETER_BALANCE_LEFT, 0, left); postponeRtEvent(kPluginPostRtEventParameterChange, PARAMETER_BALANCE_RIGHT, 0, right); continue; } } #endif // Control plugin parameters for (k=0; k < kData->param.count; ++k) { if (kData->param.data[k].midiChannel != event.channel) continue; if (kData->param.data[k].midiCC != ctrlEvent.param) continue; if (kData->param.data[k].type != PARAMETER_INPUT) continue; if ((kData->param.data[k].hints & PARAMETER_IS_AUTOMABLE) == 0) continue; double value; if (kData->param.data[k].hints & PARAMETER_IS_BOOLEAN) { value = (ctrlEvent.value < 0.5f) ? kData->param.ranges[k].min : kData->param.ranges[k].max; } else { value = kData->param.ranges[i].unnormalizeValue(ctrlEvent.value); if (kData->param.data[k].hints & PARAMETER_IS_INTEGER) value = std::rint(value); } setParameterValue(k, value, false, false, false); postponeRtEvent(kPluginPostRtEventParameterChange, static_cast(k), 0, value); } break; } case kEngineControlEventTypeMidiBank: if (event.channel == kData->ctrlChannel && (fOptions & PLUGIN_OPTION_MAP_PROGRAM_CHANGES) != 0) nextBankId = ctrlEvent.param; break; case kEngineControlEventTypeMidiProgram: if (event.channel == kData->ctrlChannel && (fOptions & PLUGIN_OPTION_MAP_PROGRAM_CHANGES) != 0) { const uint32_t nextProgramId = ctrlEvent.param; for (k=0; k < kData->midiprog.count; ++k) { if (kData->midiprog.data[k].bank == nextBankId && kData->midiprog.data[k].program == nextProgramId) { setMidiProgram(k, false, false, false); postponeRtEvent(kPluginPostRtEventMidiProgramChange, k, 0, 0.0f); break; } } } break; case kEngineControlEventTypeAllSoundOff: if (fOptions & PLUGIN_OPTION_SEND_ALL_SOUND_OFF) { fMidiInputPort->DispatchControlChange(MIDI_CONTROL_ALL_SOUND_OFF, 0, event.channel, sampleAccurate ? startTime : time); } break; case kEngineControlEventTypeAllNotesOff: if (fOptions & PLUGIN_OPTION_SEND_ALL_SOUND_OFF) { if (event.channel == kData->ctrlChannel && ! allNotesOffSent) { allNotesOffSent = true; sendMidiAllNotesOffToCallback(); } fMidiInputPort->DispatchControlChange(MIDI_CONTROL_ALL_NOTES_OFF, 0, event.channel, sampleAccurate ? startTime : time); } break; } break; } case kEngineEventTypeMidi: { const EngineMidiEvent& midiEvent(event.midi); uint8_t status = MIDI_GET_STATUS_FROM_DATA(midiEvent.data); uint8_t channel = event.channel; // Fix bad note-off (per DSSI spec) if (MIDI_IS_STATUS_NOTE_ON(status) && midiEvent.data[2] == 0) status -= 0x10; int32_t fragmentPos = sampleAccurate ? startTime : time; if (MIDI_IS_STATUS_NOTE_OFF(status)) { const uint8_t note = midiEvent.data[1]; fMidiInputPort->DispatchNoteOff(note, 0, channel, fragmentPos); postponeRtEvent(kPluginPostRtEventNoteOff, channel, note, 0.0f); } else if (MIDI_IS_STATUS_NOTE_ON(status)) { const uint8_t note = midiEvent.data[1]; const uint8_t velo = midiEvent.data[2]; fMidiInputPort->DispatchNoteOn(note, velo, channel, fragmentPos); postponeRtEvent(kPluginPostRtEventNoteOn, channel, note, velo); } else if (MIDI_IS_STATUS_POLYPHONIC_AFTERTOUCH(status) && (fOptions & PLUGIN_OPTION_SEND_NOTE_AFTERTOUCH) != 0) { //const uint8_t note = midiEvent.data[1]; //const uint8_t pressure = midiEvent.data[2]; // unsupported } else if (MIDI_IS_STATUS_CONTROL_CHANGE(status) && (fOptions & PLUGIN_OPTION_SEND_CONTROL_CHANGES) != 0) { const uint8_t control = midiEvent.data[1]; const uint8_t value = midiEvent.data[2]; fMidiInputPort->DispatchControlChange(control, value, channel, fragmentPos); } else if (MIDI_IS_STATUS_AFTERTOUCH(status) && (fOptions & PLUGIN_OPTION_SEND_CHANNEL_PRESSURE) != 0) { //const uint8_t pressure = midiEvent.data[1]; // unsupported } else if (MIDI_IS_STATUS_PITCH_WHEEL_CONTROL(status) && (fOptions & PLUGIN_OPTION_SEND_PITCHBEND) != 0) { const uint8_t lsb = midiEvent.data[1]; const uint8_t msb = midiEvent.data[2]; fMidiInputPort->DispatchPitchbend(((msb << 7) | lsb) - 8192, channel, fragmentPos); } break; } } } kData->postRtEvents.trySplice(); if (frames > timeOffset) processSingle(outBuffer, frames - timeOffset, timeOffset); } // End of Event Input and Processing } bool processSingle(float** const outBuffer, const uint32_t frames, const uint32_t timeOffset) { CARLA_ASSERT(outBuffer != nullptr); CARLA_ASSERT(frames > 0); if (outBuffer == nullptr) return false; if (frames == 0) return false; uint32_t i, k; // -------------------------------------------------------------------------------------------------------- // Try lock, silence otherwise if (kData->engine->isOffline()) { kData->singleMutex.lock(); } else if (! kData->singleMutex.tryLock()) { for (i=0; i < kData->audioOut.count; ++i) { for (k=0; k < frames; ++k) outBuffer[i][k+timeOffset] = 0.0f; } return false; } // -------------------------------------------------------------------------------------------------------- // Run plugin fAudioOutputDevice->Channel(0)->SetBuffer(outBuffer[0] + timeOffset); fAudioOutputDevice->Channel(1)->SetBuffer(outBuffer[1] + timeOffset); // QUESTION: Need to clear it before? fAudioOutputDevice->Render(frames); #ifndef BUILD_BRIDGE // -------------------------------------------------------------------------------------------------------- // Post-processing (dry/wet, volume and balance) { const bool doVolume = (fHints & PLUGIN_CAN_VOLUME) > 0 && kData->postProc.volume != 1.0f; const bool doBalance = (fHints & PLUGIN_CAN_BALANCE) > 0 && (kData->postProc.balanceLeft != -1.0f || kData->postProc.balanceRight != 1.0f); float oldBufLeft[doBalance ? frames : 1]; for (i=0; i < kData->audioOut.count; ++i) { // Balance if (doBalance) { if (i % 2 == 0) carla_copyFloat(oldBufLeft, outBuffer[i], frames); float balRangeL = (kData->postProc.balanceLeft + 1.0f)/2.0f; float balRangeR = (kData->postProc.balanceRight + 1.0f)/2.0f; for (k=0; k < frames; ++k) { if (i % 2 == 0) { // left outBuffer[i][k] = oldBufLeft[k] * (1.0f - balRangeL); outBuffer[i][k] += outBuffer[i+1][k] * (1.0f - balRangeR); } else { // right outBuffer[i][k] = outBuffer[i][k] * balRangeR; outBuffer[i][k] += oldBufLeft[k] * balRangeL; } } } // Volume if (doVolume) { for (k=0; k < frames; ++k) outBuffer[i][k+timeOffset] *= kData->postProc.volume; } } } // End of Post-processing #endif // -------------------------------------------------------------------------------------------------------- kData->singleMutex.unlock(); return true; } // ------------------------------------------------------------------- // Plugin buffers // nothing // ------------------------------------------------------------------- const void* getExtraStuff() override { return kUses16Outs ? (const void*)0x1 : nullptr; } bool init(const char* filename, const char* const name, const char* label) { CARLA_ASSERT(kData->engine != nullptr); CARLA_ASSERT(kData->client == nullptr); CARLA_ASSERT(filename != nullptr); CARLA_ASSERT(label != nullptr); // --------------------------------------------------------------- // first checks if (kData->engine == nullptr) { return false; } if (kData->client != nullptr) { kData->engine->setLastError("Plugin client is already registered"); return false; } if (filename == nullptr) { kData->engine->setLastError("null filename"); return false; } if (label == nullptr) { kData->engine->setLastError("null label"); return false; } // --------------------------------------------------------------- // Check if file exists { QFileInfo file(filename); if (! (file.exists() && file.isFile() && file.isReadable())) { kData->engine->setLastError("Requested file is not valid or does not exist"); return false; } } // --------------------------------------------------------------- // Create the LinuxSampler Engine const char* const stype = kIsGIG ? "gig" : "sfz"; try { fEngine = LinuxSampler::EngineFactory::Create(stype); } catch (LinuxSampler::Exception& e) { kData->engine->setLastError(e.what()); return false; } // --------------------------------------------------------------- // Get the Engine's Instrument Manager fInstrument = fEngine->GetInstrumentManager(); if (fInstrument == nullptr) { kData->engine->setLastError("Failed to get LinuxSampler instrument manager"); LinuxSampler::EngineFactory::Destroy(fEngine); fEngine = nullptr; return false; } // --------------------------------------------------------------- // Load the Instrument via filename try { fInstrumentIds = fInstrument->GetInstrumentFileContent(filename); } catch (const LinuxSampler::InstrumentManagerException& e) { kData->engine->setLastError(e.what()); LinuxSampler::EngineFactory::Destroy(fEngine); fEngine = nullptr; return false; } // --------------------------------------------------------------- // Get info if (fInstrumentIds.size() == 0) { kData->engine->setLastError("Failed to find any instruments"); LinuxSampler::EngineFactory::Destroy(fEngine); fEngine = nullptr; return false; } LinuxSampler::InstrumentManager::instrument_info_t info; try { info = fInstrument->GetInstrumentInfo(fInstrumentIds[0]); } catch (const LinuxSampler::InstrumentManagerException& e) { kData->engine->setLastError(e.what()); LinuxSampler::EngineFactory::Destroy(fEngine); fEngine = nullptr; return false; } fRealName = info.InstrumentName.c_str(); fLabel = info.Product.c_str(); fMaker = info.Artists.c_str(); fFilename = filename; if (name != nullptr) fName = kData->engine->getUniquePluginName(name); else fName = kData->engine->getUniquePluginName((const char*)fRealName); // --------------------------------------------------------------- // Register client kData->client = kData->engine->addClient(this); if (kData->client == nullptr || ! kData->client->isOk()) { kData->engine->setLastError("Failed to register plugin client"); LinuxSampler::EngineFactory::Destroy(fEngine); fEngine = nullptr; return false; } // --------------------------------------------------------------- // Init LinuxSampler stuff fSamplerChannel = fSampler->AddSamplerChannel(); fSamplerChannel->SetEngineType(stype); fSamplerChannel->SetAudioOutputDevice(fAudioOutputDevice); fEngineChannel = fSamplerChannel->GetEngineChannel(); fEngineChannel->Connect(fAudioOutputDevice); fEngineChannel->Volume(LinuxSampler::VOLUME_MAX); fMidiInputPort->Connect(fSamplerChannel->GetEngineChannel(), LinuxSampler::midi_chan_all); // --------------------------------------------------------------- // load plugin settings { // set default options fOptions = 0x0; fOptions |= PLUGIN_OPTION_MAP_PROGRAM_CHANGES; fOptions |= PLUGIN_OPTION_SEND_PITCHBEND; fOptions |= PLUGIN_OPTION_SEND_ALL_SOUND_OFF; // load settings kData->idStr = kIsGIG ? "GIG" : "SFZ"; kData->idStr += "/"; kData->idStr += label; fOptions = kData->loadSettings(fOptions, availableOptions()); } return true; } // ------------------------------------------------------------------- static CarlaPlugin* newLinuxSampler(const Initializer& init, bool isGIG, const bool use16Outs); private: const bool kIsGIG; // sfz if false const bool kUses16Outs; CarlaString fRealName; CarlaString fLabel; CarlaString fMaker; LinuxSampler::Sampler* fSampler; LinuxSampler::SamplerChannel* fSamplerChannel; LinuxSampler::Engine* fEngine; LinuxSampler::EngineChannel* fEngineChannel; LinuxSampler::AudioOutputDevicePlugin* fAudioOutputDevice; LinuxSampler::MidiInputDevicePlugin* fMidiInputDevice; LinuxSampler::MidiInputPort* fMidiInputPort; LinuxSampler::InstrumentManager* fInstrument; std::vector fInstrumentIds; CARLA_DECLARE_NON_COPYABLE_WITH_LEAK_DETECTOR(LinuxSamplerPlugin) }; CarlaPlugin* LinuxSamplerPlugin::newLinuxSampler(const Initializer& init, const bool isGIG, const bool use16Outs) { carla_debug("LinuxSamplerPlugin::newLinuxSampler({%p, \"%s\", \"%s\", \"%s\"}, %s, %s)", init.engine, init.filename, init.name, init.label, bool2str(isGIG), bool2str(use16Outs)); if (init.engine->getProccessMode() == PROCESS_MODE_CONTINUOUS_RACK && use16Outs) { init.engine->setLastError("Carla's rack mode can only work with Stereo modules, please choose the 2-channel only sample-library version"); return nullptr; } LinuxSamplerPlugin* const plugin(new LinuxSamplerPlugin(init.engine, init.id, isGIG, use16Outs)); if (! plugin->init(init.filename, init.name, init.label)) { delete plugin; return nullptr; } plugin->reload(); return plugin; } CARLA_BACKEND_END_NAMESPACE #else // WANT_LINUXSAMPLER # warning linuxsampler not available (no GIG and SFZ support) #endif CARLA_BACKEND_START_NAMESPACE CarlaPlugin* CarlaPlugin::newGIG(const Initializer& init, const bool use16Outs) { carla_debug("CarlaPlugin::newGIG({%p, \"%s\", \"%s\", \"%s\"}, %s)", init.engine, init.filename, init.name, init.label, bool2str(use16Outs)); #ifdef WANT_LINUXSAMPLER return LinuxSamplerPlugin::newLinuxSampler(init, true, use16Outs); #else init.engine->setLastError("linuxsampler support not available"); return nullptr; #endif } CarlaPlugin* CarlaPlugin::newSFZ(const Initializer& init, const bool use16Outs) { carla_debug("CarlaPlugin::newSFZ({%p, \"%s\", \"%s\", \"%s\"}, %s)", init.engine, init.filename, init.name, init.label, bool2str(use16Outs)); #ifdef WANT_LINUXSAMPLER return LinuxSamplerPlugin::newLinuxSampler(init, false, use16Outs); #else init.engine->setLastError("linuxsampler support not available"); return nullptr; #endif } CARLA_BACKEND_END_NAMESPACE