#include "amuse/SoundMacroState.hpp" #include "amuse/Voice.hpp" #include "amuse/Engine.hpp" #include "amuse/Common.hpp" #include "amuse/AudioGroup.hpp" #include "amuse/AudioGroupPool.hpp" #include #ifndef M_PIF #define M_PIF 3.14159265358979323846f /* pi */ #endif namespace amuse { void SoundMacroState::Header::swapBig() { m_size = SBig(m_size); } void SoundMacroState::Command::swapBig() { uint32_t* words = reinterpret_cast(this); words[0] = SBig(words[0]); words[1] = SBig(words[1]); } void SoundMacroState::LFOSel::addComponent(uint8_t midiCtrl, float scale, Combine combine, VarType varType) { m_comps.push_back({midiCtrl, scale, combine, varType}); } float SoundMacroState::LFOSel::evaluate(Voice& vox, const SoundMacroState& st) { float value = 0.f; /* Iterate each component */ for (auto it=m_comps.cbegin() ; it != m_comps.cend() ; ++it) { const Component& comp = *it; float thisValue = 0.f; /* Load selected data */ if (comp.m_varType == VarType::Ctrl) { switch (comp.m_midiCtrl) { case 128: /* Pitchbend */ thisValue = vox.getPitchWheel(); break; case 129: /* Aftertouch */ thisValue = vox.getAftertouch(); break; case 130: /* LFO1 */ if (st.m_lfoPeriods[0]) thisValue = std::sin(st.m_execTime / st.m_lfoPeriods[0] * 2.f * M_PIF); break; case 131: /* LFO2 */ if (st.m_lfoPeriods[1]) thisValue = std::sin(st.m_execTime / st.m_lfoPeriods[1] * 2.f * M_PIF); break; case 132: /* Surround panning */ thisValue = st.m_curSpan * 64.f + 64.f; break; case 133: /* Macro-starting key */ thisValue = st.m_initKey; break; case 134: /* Macro-starting velocity */ thisValue = st.m_initVel; break; case 135: /* Time since macro-start (ms) */ thisValue = st.m_execTime * 1000.f; break; default: thisValue = vox.getCtrlValue(comp.m_midiCtrl); break; } } else if (comp.m_varType == VarType::Var) thisValue = st.m_variables[std::max(0, std::min(255, int(comp.m_midiCtrl)))]; /* Apply scale */ thisValue *= comp.m_scale; /* Combine */ if (it != m_comps.cbegin()) { switch (comp.m_combine) { case Combine::Add: value += thisValue; break; case Combine::Mult: value *= thisValue; break; default: break; } } else value = thisValue; } return value; } void SoundMacroState::initialize(const unsigned char* ptr) { initialize(ptr, 1000.f, 0, 0, 0); } void SoundMacroState::initialize(const unsigned char* ptr, float ticksPerSec, uint8_t midiKey, uint8_t midiVel, uint8_t midiMod) { m_ptr = ptr; m_curVol = 1.f; m_volDirty = true; m_curPan = 0.f; m_panDirty = true; m_curSpan = 0.f; m_spanDirty = true; m_ticksPerSec = ticksPerSec; m_initKey = 0; m_initVel = 0; m_initMod = 0; m_curVel = 0; m_curMod = 0; m_curKey = 0; m_pitchSweep1 = 0; m_pitchSweep1Times = 0; m_pitchSweep2 = 0; m_pitchSweep2Times = 0; m_pitchDirty = true; m_random.seed(); m_pc.clear(); m_pc.push_back(-1); m_execTime = 0.f; m_keyoff = false; m_sampleEnd = false; m_envelopeTime = -1.f; m_panningTime = -1.f; m_loopCountdown = -1; m_lastPlayMacroVid = -1; m_useAdsrControllers = false; m_portamentoMode = 0; m_vibratoLevel = 0; m_vibratoModLevel = 0; m_vibratoPeriod = 0.f; m_tremoloScale = 0.f; m_tremoloModScale = 0.f; m_lfoPeriods[0] = 0.f; m_lfoPeriods[1] = 0.f; m_header = *reinterpret_cast(ptr); m_header.swapBig(); } bool SoundMacroState::advance(Voice& vox, float dt) { /* Nothing if uninitialized or finished */ if (m_pc.back() == -1) return true; /* Process active envelope */ if (m_envelopeTime >= 0.f) { m_envelopeTime += dt; float start = m_envelopeStart / 127.f; float end = m_envelopeEnd / 127.f; float t = std::max(0.f, std::min(1.f, m_envelopeTime / m_envelopeDur)); if (m_envelopeCurve) t = (*m_envelopeCurve)[int(t*127.f)] / 127.f; m_curVol = (start * (1.0f - t)) + (end * t); m_volDirty = true; /* Done with envelope */ if (m_envelopeTime > m_envelopeDur) m_envelopeTime = -1.f; } /* Apply tremolo */ float totalVol = m_curVol; if (m_tremoloSel && (m_tremoloScale || m_tremoloModScale)) { float t = m_tremoloSel.evaluate(vox, *this); if (m_tremoloScale && m_tremoloModScale) { float fac = (1.0f - t) + (m_tremoloScale * t); float modT = vox.getModWheel() / 127.f; float modFac = (1.0f - modT) + (m_tremoloModScale * modT); totalVol *= fac * modFac; } else if (m_tremoloScale) { float fac = (1.0f - t) + (m_tremoloScale * t); totalVol *= fac; } else if (m_tremoloModScale) { float modT = vox.getModWheel() / 127.f; float modFac = (1.0f - modT) + (m_tremoloModScale * modT); totalVol *= modFac; } m_volDirty = true; } /* Apply total volume */ if (m_volDirty) { vox.setVolume(totalVol); m_volDirty = false; } /* Process active pan-sweep */ if (m_panningTime >= 0.f) { m_panningTime += dt; float start = (m_panPos - 64) / 64.f; float end = (m_panPos + m_panWidth - 64) / 64.f; float t = std::max(0.f, std::min(1.f, m_panningTime / m_panningDur)); vox.setPanning((start * (1.0f - t)) + (end * t)); /* Done with panning */ if (m_panningTime > m_panningDur) m_panningTime = -1.f; } /* Process active span-sweep */ if (m_spanningTime >= 0.f) { m_spanningTime += dt; float start = (m_spanPos - 64) / 64.f; float end = (m_spanPos + m_spanWidth - 64) / 64.f; float t = std::max(0.f, std::min(1.f, m_spanningTime / m_spanningDur)); vox.setSurroundPanning((start * (1.0f - t)) + (end * t)); /* Done with spanning */ if (m_spanningTime > m_spanningDur) m_spanningTime = -1.f; } /* Process pitch sweep 1 */ if (m_pitchSweep1Times) { m_pitchSweep1 += m_pitchSweep1Add; --m_pitchSweep1Times; m_pitchDirty = true; } /* Process pitch sweep 2 */ if (m_pitchSweep2Times) { m_pitchSweep2 += m_pitchSweep2Add; --m_pitchSweep2Times; m_pitchDirty = true; } /* Apply total pitch */ if (m_pitchDirty) { vox.setPitchKey(m_curKey + m_pitchSweep1 + m_pitchSweep2); m_pitchDirty = false; } /* Loop through as many commands as we can for this time period */ while (true) { /* Advance wait timer if active, returning if waiting */ if (m_inWait) { m_waitCountdown -= dt; if (m_waitCountdown < 0.f) m_inWait = false; else { m_execTime += dt; return false; } } /* Load next command based on counter */ const Command* commands = reinterpret_cast(m_ptr + sizeof(Header)); Command cmd = commands[m_pc.back()++]; cmd.swapBig(); /* Perform function of command */ switch (cmd.m_op) { case Op::End: case Op::Stop: m_pc.back() = -1; return true; case Op::SplitKey: { uint8_t keyNumber = cmd.m_data[0]; ObjectId macroId = *reinterpret_cast(&cmd.m_data[1]); int16_t macroStep = *reinterpret_cast(&cmd.m_data[3]); if (m_initKey >= keyNumber) { /* Do Branch */ if (macroId == m_header.m_macroId) m_pc.back() = macroStep; else vox.loadSoundMacro(macroId, macroStep); } break; } case Op::SplitVel: { uint8_t velocity = cmd.m_data[0]; ObjectId macroId = *reinterpret_cast(&cmd.m_data[1]); int16_t macroStep = *reinterpret_cast(&cmd.m_data[3]); if (m_curVel >= velocity) { /* Do Branch */ if (macroId == m_header.m_macroId) m_pc.back() = macroStep; else vox.loadSoundMacro(macroId, macroStep); } break; } case Op::WaitTicks: { bool keyRelease = cmd.m_data[0]; bool random = cmd.m_data[1]; bool sampleEnd = cmd.m_data[2]; bool absolute = cmd.m_data[3]; bool ms = cmd.m_data[4]; int16_t time = *reinterpret_cast(&cmd.m_data[5]); /* Set wait state */ float q = ms ? 1000.f : m_ticksPerSec; float secTime = time / q; if (absolute) { if (secTime <= m_execTime) break; m_waitCountdown = secTime - m_execTime; } else m_waitCountdown = secTime; /* Randomize at the proper resolution */ if (random) secTime = std::fmod(m_random() / q, secTime); m_inWait = true; m_keyoffWait = keyRelease; m_sampleEndWait = sampleEnd; break; } case Op::Loop: { bool keyRelease = cmd.m_data[0]; bool random = cmd.m_data[1]; bool sampleEnd = cmd.m_data[2]; int16_t step = *reinterpret_cast(&cmd.m_data[3]); int16_t times = *reinterpret_cast(&cmd.m_data[5]); if ((keyRelease && m_keyoff) || (sampleEnd && m_sampleEnd)) { /* Break out of loop */ m_loopCountdown = -1; break; } if (random) times = m_random() % times; if (m_loopCountdown == -1 && times != -1) m_loopCountdown = times; if (m_loopCountdown > 0) { /* Loop back to step */ --m_loopCountdown; m_pc.back() = step; } else /* Break out of loop */ m_loopCountdown = -1; break; } case Op::Goto: { ObjectId macroId = *reinterpret_cast(&cmd.m_data[1]); int16_t macroStep = *reinterpret_cast(&cmd.m_data[3]); /* Do Branch */ if (macroId == m_header.m_macroId) m_pc.back() = macroStep; else vox.loadSoundMacro(macroId, macroStep); break; } case Op::WaitMs: { bool keyRelease = cmd.m_data[0]; bool random = cmd.m_data[1]; bool sampleEnd = cmd.m_data[2]; bool absolute = cmd.m_data[3]; int16_t time = *reinterpret_cast(&cmd.m_data[5]); /* Set wait state */ float secTime = time / 1000.f; if (absolute) { if (secTime <= m_execTime) break; m_waitCountdown = secTime - m_execTime; } else m_waitCountdown = secTime; /* Randomize at the proper resolution */ if (random) secTime = std::fmod(m_random() / 1000.f, secTime); m_inWait = true; m_keyoffWait = keyRelease; m_sampleEndWait = sampleEnd; break; } case Op::PlayMacro: { int8_t addNote = cmd.m_data[0]; ObjectId macroId = *reinterpret_cast(&cmd.m_data[1]); int16_t macroStep = *reinterpret_cast(&cmd.m_data[3]); //int8_t priority = cmd.m_data[5]; //int8_t maxVoices = cmd.m_data[6]; Voice* sibVox = vox.startSiblingMacro(addNote, macroId, macroStep); if (sibVox) m_lastPlayMacroVid = sibVox->vid(); break; } case Op::SendKeyOff: { uint8_t vid = cmd.m_data[0]; bool lastStarted = cmd.m_data[1]; if (lastStarted) { if (m_lastPlayMacroVid != -1) { Voice* otherVox = vox.getEngine().findVoice(m_lastPlayMacroVid); if (otherVox) otherVox->keyOff(); } } else { Voice* otherVox = vox.getEngine().findVoice(m_variables[vid]); if (otherVox) otherVox->keyOff(); } break; } case Op::SplitMod: { uint8_t mod = cmd.m_data[0]; ObjectId macroId = *reinterpret_cast(&cmd.m_data[1]); int16_t macroStep = *reinterpret_cast(&cmd.m_data[3]); if (m_curMod >= mod) { /* Do Branch */ if (macroId == m_header.m_macroId) m_pc.back() = macroStep; else vox.loadSoundMacro(macroId, macroStep); } break; } case Op::PianoPan: { int8_t scale = cmd.m_data[0]; int8_t cenKey = cmd.m_data[1]; int8_t cenPan = cmd.m_data[2]; int32_t pan = int32_t(m_initKey - cenKey) * scale / 127 + cenPan; pan = std::max(-127, std::min(127, pan)); vox.setPanning(pan / 127.f); break; } case Op::SetAdsr: { ObjectId tableId = *reinterpret_cast(&cmd.m_data[0]); vox.setAdsr(tableId); break; } case Op::ScaleVolume: { int8_t scale = cmd.m_data[0]; int8_t add = cmd.m_data[1]; ObjectId curve = *reinterpret_cast(&cmd.m_data[2]); bool orgVel = cmd.m_data[4]; int32_t eval = int32_t(orgVel ? m_initVel : m_curVel) * scale / 127 + add; eval = std::max(0, std::min(127, eval)); if (curve.id != 0) { const Curve* curveData = vox.getAudioGroup().getPool().tableAsCurves(curve); if (curveData) { m_curVol = (*curveData)[eval] / 127.f; m_volDirty = true; break; } } m_curVol = eval / 127.f; m_volDirty = true; break; } case Op::Panning: { int8_t panPos = cmd.m_data[0]; int16_t timeMs = *reinterpret_cast(&cmd.m_data[1]); int8_t width = cmd.m_data[3]; m_panningTime = 0.f; m_panningDur = timeMs / 1000.f; m_panPos = panPos; m_panWidth = width; break; } case Op::Envelope: { int8_t scale = cmd.m_data[0]; int8_t add = cmd.m_data[1]; ObjectId curve = *reinterpret_cast(&cmd.m_data[2]); bool ms = cmd.m_data[4]; int16_t fadeTime = *reinterpret_cast(&cmd.m_data[5]); float q = ms ? 1000.f : m_ticksPerSec; float secTime = fadeTime / q; int32_t eval = int32_t(m_curVel) * scale / 127 + add; eval = std::max(0, std::min(127, eval)); m_envelopeTime = 0.f; m_envelopeDur = secTime; m_envelopeStart = m_curVel; m_envelopeEnd = eval; if (curve.id != 0) m_envelopeCurve = vox.getAudioGroup().getPool().tableAsCurves(curve); else m_envelopeCurve = nullptr; break; } case Op::StartSample: { int16_t smpId = *reinterpret_cast(&cmd.m_data[0]); int8_t mode = cmd.m_data[2]; int32_t offset = *reinterpret_cast(&cmd.m_data[3]); switch (mode) { case 1: offset = offset * (127 - m_curVel) / 127; break; case 2: offset = offset * m_curVel / 127; break; default: break; } vox.startSample(smpId, offset); break; } case Op::StopSample: { vox.stopSample(); break; } case Op::KeyOff: { vox.keyOff(); break; } case Op::SplitRnd: { uint8_t rndVal = cmd.m_data[0]; ObjectId macroId = *reinterpret_cast(&cmd.m_data[1]); int16_t macroStep = *reinterpret_cast(&cmd.m_data[3]); if (rndVal <= m_random() % 256) { /* Do branch */ if (macroId == m_header.m_macroId) m_pc.back() = macroStep; else vox.loadSoundMacro(macroId, macroStep); } break; } case Op::FadeIn: { int8_t scale = cmd.m_data[0]; int8_t add = cmd.m_data[1]; ObjectId curve = *reinterpret_cast(&cmd.m_data[2]); bool ms = cmd.m_data[4]; int16_t fadeTime = *reinterpret_cast(&cmd.m_data[5]); float q = ms ? 1000.f : m_ticksPerSec; float secTime = fadeTime / q; int32_t eval = int32_t(m_curVel) * scale / 127 + add; eval = std::max(0, std::min(127, eval)); m_envelopeTime = 0.f; m_envelopeDur = secTime; m_envelopeStart = 0.f; m_envelopeEnd = eval; if (curve.id != 0) m_envelopeCurve = vox.getAudioGroup().getPool().tableAsCurves(curve); else m_envelopeCurve = nullptr; break; } case Op::Spanning: { int8_t panPos = cmd.m_data[0]; int16_t timeMs = *reinterpret_cast(&cmd.m_data[1]); int8_t width = cmd.m_data[3]; m_spanningTime = 0.f; m_spanningDur = timeMs / 1000.f; m_spanPos = panPos; m_spanWidth = width; break; } case Op::SetAdsrCtrl: { m_useAdsrControllers = true; m_midiAttack = cmd.m_data[0]; m_midiDecay = cmd.m_data[1]; m_midiSustain = cmd.m_data[2]; m_midiRelease = cmd.m_data[3]; break; } case Op::RndNote: { int32_t noteLo = int32_t(cmd.m_data[0]); int8_t detune = cmd.m_data[1]; int32_t noteHi = int32_t(cmd.m_data[2]); int8_t free = cmd.m_data[3]; int8_t rel = cmd.m_data[4]; if (rel) { noteLo = m_initKey - noteLo; noteHi = noteLo + noteHi; } noteLo *= 100; noteHi *= 100; m_curKey = m_random() % (noteHi - noteLo) + noteLo; if (!free) m_curKey = m_curKey / 100 * 100 + detune; m_pitchDirty = true; break; } case Op::AddNote: { int32_t add = int32_t(cmd.m_data[0]); int8_t detune = cmd.m_data[1]; int8_t orgKey = int32_t(cmd.m_data[2]); int8_t ms = cmd.m_data[4]; int16_t timeMs = *reinterpret_cast(&cmd.m_data[5]); m_curKey = (orgKey ? m_initKey : m_curKey) + add * 100 + detune; /* Set wait state */ if (timeMs) { float q = ms ? 1000.f : m_ticksPerSec; float secTime = timeMs / q; m_waitCountdown = secTime; m_inWait = true; } m_pitchDirty = true; break; } case Op::SetNote: { int32_t key = int32_t(cmd.m_data[0]); int8_t detune = cmd.m_data[1]; int8_t ms = cmd.m_data[4]; int16_t timeMs = *reinterpret_cast(&cmd.m_data[5]); m_curKey = key * 100 + detune; /* Set wait state */ if (timeMs) { float q = ms ? 1000.f : m_ticksPerSec; float secTime = timeMs / q; m_waitCountdown = secTime; m_inWait = true; } m_pitchDirty = true; break; } case Op::LastNote: { int32_t add = int32_t(cmd.m_data[0]); int8_t detune = cmd.m_data[1]; int8_t ms = cmd.m_data[4]; int16_t timeMs = *reinterpret_cast(&cmd.m_data[5]); m_curKey = (add + vox.getLastNote()) * 100 + detune; /* Set wait state */ if (timeMs) { float q = ms ? 1000.f : m_ticksPerSec; float secTime = timeMs / q; m_waitCountdown = secTime; m_inWait = true; } m_pitchDirty = true; break; } case Op::Portamento: { m_portamentoMode = cmd.m_data[0]; m_portamentoType = cmd.m_data[1]; int8_t ms = cmd.m_data[4]; int16_t timeMs = *reinterpret_cast(&cmd.m_data[5]); float q = ms ? 1000.f : m_ticksPerSec; m_portamentoTime = timeMs / q; break; } case Op::Vibrato: { m_vibratoModLevel = m_vibratoLevel = cmd.m_data[0] * 100 + cmd.m_data[1]; m_vibratoModWheel = cmd.m_data[2]; int8_t ms = cmd.m_data[4]; int16_t timeMs = *reinterpret_cast(&cmd.m_data[5]); float q = ms ? 1000.f : m_ticksPerSec; m_vibratoPeriod = timeMs / q; break; } case Op::PitchSweep1: { m_pitchSweep1 = 0; m_pitchSweep1Times = int32_t(cmd.m_data[0]); m_pitchSweep1Add = *reinterpret_cast(&cmd.m_data[1]); int8_t ms = cmd.m_data[4]; int16_t timeMs = *reinterpret_cast(&cmd.m_data[5]); /* Set wait state */ if (timeMs) { float q = ms ? 1000.f : m_ticksPerSec; float secTime = timeMs / q; m_waitCountdown = secTime; m_inWait = true; } break; } case Op::PitchSweep2: { m_pitchSweep2 = 0; m_pitchSweep2Times = int32_t(cmd.m_data[0]); m_pitchSweep2Add = *reinterpret_cast(&cmd.m_data[1]); int8_t ms = cmd.m_data[4]; int16_t timeMs = *reinterpret_cast(&cmd.m_data[5]); /* Set wait state */ if (timeMs) { float q = ms ? 1000.f : m_ticksPerSec; float secTime = timeMs / q; m_waitCountdown = secTime; m_inWait = true; } break; } case Op::SetPitch: { uint32_t hz = *reinterpret_cast(&cmd.m_data[0]) >> 8; uint16_t fine = *reinterpret_cast(&cmd.m_data[3]); vox.setPitchFrequency(hz, fine); break; } case Op::SetPitchAdsr: { ObjectId adsr = *reinterpret_cast(&cmd.m_data[0]); int8_t keys = cmd.m_data[3]; int8_t cents = cmd.m_data[4]; vox.setPitchAdsr(adsr, keys * 100 + cents); break; } case Op::ScaleVolumeDLS: { int16_t scale = *reinterpret_cast(&cmd.m_data[0]); bool orgVel = cmd.m_data[2]; m_curVol = int32_t(orgVel ? m_initVel : m_curVel) * scale / 4096.f / 127.f; m_volDirty = true; break; } case Op::Mod2Vibrange: { int8_t keys = cmd.m_data[0]; int8_t cents = cmd.m_data[1]; m_vibratoModLevel = keys * 100 + cents; break; } case Op::SetupTremolo: { int16_t scale = *reinterpret_cast(&cmd.m_data[0]); int16_t modScale = *reinterpret_cast(&cmd.m_data[3]); m_tremoloScale = scale / 4096.f; m_tremoloModScale = modScale / 4096.f; break; } case Op::Return: case Op::GoSub: case Op::TrapEvent: case Op::SendMessage: case Op::GetMessage: case Op::GetVid: case Op::AddAgeCount: case Op::SetAgeCount: case Op::SendFlag: case Op::PitchWheelR: case Op::SetPriority: case Op::AddPriority: case Op::AgeCntSpeed: case Op::AgeCntVel: break; case Op::VolSelect: { uint8_t ctrl = cmd.m_data[0]; int16_t perc = *reinterpret_cast(&cmd.m_data[1]); LFOSel::Combine combine = LFOSel::Combine(cmd.m_data[3]); LFOSel::VarType vtype = LFOSel::VarType(cmd.m_data[4]); uint8_t fine = cmd.m_data[5]; m_volumeSel.addComponent(ctrl, (perc + fine / 100.f) / 100.f, combine, vtype); break; } case Op::PanSelect: { uint8_t ctrl = cmd.m_data[0]; int16_t perc = *reinterpret_cast(&cmd.m_data[1]); LFOSel::Combine combine = LFOSel::Combine(cmd.m_data[3]); LFOSel::VarType vtype = LFOSel::VarType(cmd.m_data[4]); uint8_t fine = cmd.m_data[5]; m_panSel.addComponent(ctrl, (perc + fine / 100.f) / 100.f, combine, vtype); break; } case Op::PitchWheelSelect: { uint8_t ctrl = cmd.m_data[0]; int16_t perc = *reinterpret_cast(&cmd.m_data[1]); LFOSel::Combine combine = LFOSel::Combine(cmd.m_data[3]); LFOSel::VarType vtype = LFOSel::VarType(cmd.m_data[4]); uint8_t fine = cmd.m_data[5]; m_pitchWheelSel.addComponent(ctrl, (perc + fine / 100.f) / 100.f, combine, vtype); break; } case Op::ModWheelSelect: { uint8_t ctrl = cmd.m_data[0]; int16_t perc = *reinterpret_cast(&cmd.m_data[1]); LFOSel::Combine combine = LFOSel::Combine(cmd.m_data[3]); LFOSel::VarType vtype = LFOSel::VarType(cmd.m_data[4]); uint8_t fine = cmd.m_data[5]; m_modWheelSel.addComponent(ctrl, (perc + fine / 100.f) / 100.f, combine, vtype); break; } case Op::PedalSelect: { uint8_t ctrl = cmd.m_data[0]; int16_t perc = *reinterpret_cast(&cmd.m_data[1]); LFOSel::Combine combine = LFOSel::Combine(cmd.m_data[3]); LFOSel::VarType vtype = LFOSel::VarType(cmd.m_data[4]); uint8_t fine = cmd.m_data[5]; m_pedalSel.addComponent(ctrl, (perc + fine / 100.f) / 100.f, combine, vtype); break; } case Op::PortASelect: { uint8_t ctrl = cmd.m_data[0]; int16_t perc = *reinterpret_cast(&cmd.m_data[1]); LFOSel::Combine combine = LFOSel::Combine(cmd.m_data[3]); LFOSel::VarType vtype = LFOSel::VarType(cmd.m_data[4]); uint8_t fine = cmd.m_data[5]; m_portASel.addComponent(ctrl, (perc + fine / 100.f) / 100.f, combine, vtype); break; } case Op::ReverbSelect: { uint8_t ctrl = cmd.m_data[0]; int16_t perc = *reinterpret_cast(&cmd.m_data[1]); LFOSel::Combine combine = LFOSel::Combine(cmd.m_data[3]); LFOSel::VarType vtype = LFOSel::VarType(cmd.m_data[4]); uint8_t fine = cmd.m_data[5]; m_reverbSel.addComponent(ctrl, (perc + fine / 100.f) / 100.f, combine, vtype); break; } case Op::SpanSelect: { uint8_t ctrl = cmd.m_data[0]; int16_t perc = *reinterpret_cast(&cmd.m_data[1]); LFOSel::Combine combine = LFOSel::Combine(cmd.m_data[3]); LFOSel::VarType vtype = LFOSel::VarType(cmd.m_data[4]); uint8_t fine = cmd.m_data[5]; m_spanSel.addComponent(ctrl, (perc + fine / 100.f) / 100.f, combine, vtype); break; } case Op::DopplerSelect: { uint8_t ctrl = cmd.m_data[0]; int16_t perc = *reinterpret_cast(&cmd.m_data[1]); LFOSel::Combine combine = LFOSel::Combine(cmd.m_data[3]); LFOSel::VarType vtype = LFOSel::VarType(cmd.m_data[4]); uint8_t fine = cmd.m_data[5]; m_dopplerSel.addComponent(ctrl, (perc + fine / 100.f) / 100.f, combine, vtype); break; } case Op::TremoloSelect: { uint8_t ctrl = cmd.m_data[0]; int16_t perc = *reinterpret_cast(&cmd.m_data[1]); LFOSel::Combine combine = LFOSel::Combine(cmd.m_data[3]); LFOSel::VarType vtype = LFOSel::VarType(cmd.m_data[4]); uint8_t fine = cmd.m_data[5]; m_tremoloSel.addComponent(ctrl, (perc + fine / 100.f) / 100.f, combine, vtype); break; } case Op::PreASelect: { uint8_t ctrl = cmd.m_data[0]; int16_t perc = *reinterpret_cast(&cmd.m_data[1]); LFOSel::Combine combine = LFOSel::Combine(cmd.m_data[3]); LFOSel::VarType vtype = LFOSel::VarType(cmd.m_data[4]); uint8_t fine = cmd.m_data[5]; m_preAuxASel.addComponent(ctrl, (perc + fine / 100.f) / 100.f, combine, vtype); break; } case Op::PreBSelect: { uint8_t ctrl = cmd.m_data[0]; int16_t perc = *reinterpret_cast(&cmd.m_data[1]); LFOSel::Combine combine = LFOSel::Combine(cmd.m_data[3]); LFOSel::VarType vtype = LFOSel::VarType(cmd.m_data[4]); uint8_t fine = cmd.m_data[5]; m_preAuxBSel.addComponent(ctrl, (perc + fine / 100.f) / 100.f, combine, vtype); break; } case Op::PostBSelect: { uint8_t ctrl = cmd.m_data[0]; int16_t perc = *reinterpret_cast(&cmd.m_data[1]); LFOSel::Combine combine = LFOSel::Combine(cmd.m_data[3]); LFOSel::VarType vtype = LFOSel::VarType(cmd.m_data[4]); uint8_t fine = cmd.m_data[5]; m_postAuxB.addComponent(ctrl, (perc + fine / 100.f) / 100.f, combine, vtype); break; } case Op::AuxAFXSelect: { uint8_t ctrl = cmd.m_data[0]; int16_t perc = *reinterpret_cast(&cmd.m_data[1]); LFOSel::Combine combine = LFOSel::Combine(cmd.m_data[3]); LFOSel::VarType vtype = LFOSel::VarType(cmd.m_data[4]); uint8_t fine = cmd.m_data[5]; m_auxAFxSel.addComponent(ctrl, (perc + fine / 100.f) / 100.f, combine, vtype); break; } case Op::AuxBFXSelect: { uint8_t ctrl = cmd.m_data[0]; int16_t perc = *reinterpret_cast(&cmd.m_data[1]); LFOSel::Combine combine = LFOSel::Combine(cmd.m_data[3]); LFOSel::VarType vtype = LFOSel::VarType(cmd.m_data[4]); uint8_t fine = cmd.m_data[5]; m_auxBFxSel.addComponent(ctrl, (perc + fine / 100.f) / 100.f, combine, vtype); break; } case Op::SetupLFO: { uint8_t number = cmd.m_data[0]; int16_t period = *reinterpret_cast(&cmd.m_data[1]); if (number <= 1) m_lfoPeriods[number] = period / 1000.f; break; } case Op::ModeSelect: case Op::SetKeygroup: case Op::SRCmodeSelect: case Op::AddVars: case Op::SubVars: case Op::MulVars: case Op::DivVars: case Op::AddIVars: case Op::IfEqual: case Op::IfLess: default: break; } } m_execTime += dt; return false; } void SoundMacroState::keyoff() { m_keyoff = true; if (m_inWait && m_keyoffWait) m_inWait = false; } void SoundMacroState::sampleEnd() { m_sampleEnd = true; if (m_inWait && m_sampleEndWait) m_inWait = false; } }