/* * libOPNMIDI is a free Software MIDI synthesizer library with OPN2 (YM2612) emulation * * MIDI parser and player (Original code from ADLMIDI): Copyright (c) 2010-2014 Joel Yliluoma * OPNMIDI Library and YM2612 support: Copyright (c) 2017-2020 Vitaly Novichkov * * Library is based on the ADLMIDI, a MIDI player for Linux and Windows with OPL3 emulation: * http://iki.fi/bisqwit/source/adlmidi.html * * 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 3 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. * * You should have received a copy of the GNU General Public License * along with this program. If not, see . */ #include "opnmidi_midiplay.hpp" #include "opnmidi_opn2.hpp" #include "opnmidi_private.hpp" #ifndef OPNMIDI_DISABLE_MIDI_SEQUENCER #include "midi_sequencer.hpp" #endif #include "chips/opn_chip_base.h" // Minimum life time of percussion notes static const double drum_note_min_time = 0.03; enum { MasterVolumeDefault = 127 }; inline bool isXgPercChannel(uint8_t msb, uint8_t lsb) { return (msb == 0x7E || msb == 0x7F) && (lsb == 0); } void OPNMIDIplay::OpnChannel::addAge(int64_t us) { const int64_t neg = 1000 * static_cast(-0x1FFFFFFFl); if(users.empty()) { koff_time_until_neglible_us = std::max(koff_time_until_neglible_us - us, neg); if(koff_time_until_neglible_us < 0) koff_time_until_neglible_us = 0; } else { koff_time_until_neglible_us = 0; for(users_iterator i = users.begin(); !i.is_end(); ++i) { LocationData &d = i->value; if(!d.fixed_sustain) d.kon_time_until_neglible_us = std::max(d.kon_time_until_neglible_us - us, neg); d.vibdelay_us += us; } } } OPNMIDIplay::OPNMIDIplay(unsigned long sampleRate) : m_sysExDeviceId(0), m_synthMode(Mode_XG), m_arpeggioCounter(0) #if defined(ADLMIDI_AUDIO_TICK_HANDLER) , m_audioTickCounter(0) #endif { m_midiDevices.clear(); m_setup.emulator = opn2_getLowestEmulator(); m_setup.runAtPcmRate = false; m_setup.PCM_RATE = sampleRate; m_setup.mindelay = 1.0 / static_cast(m_setup.PCM_RATE); m_setup.maxdelay = 512.0 / static_cast(m_setup.PCM_RATE); m_setup.OpnBank = 0; m_setup.numChips = 2; m_setup.LogarithmicVolumes = false; m_setup.VolumeModel = OPNMIDI_VolumeModel_AUTO; m_setup.lfoEnable = -1; m_setup.lfoFrequency = -1; m_setup.chipType = -1; //m_setup.SkipForward = 0; m_setup.ScaleModulators = 0; m_setup.fullRangeBrightnessCC74 = false; m_setup.delay = 0.0; m_setup.carry = 0.0; m_setup.tick_skip_samples_delay = 0; m_synth.reset(new Synth); #ifndef OPNMIDI_DISABLE_MIDI_SEQUENCER m_sequencer.reset(new MidiSequencer); initSequencerInterface(); #endif resetMIDI(); applySetup(); realTime_ResetState(); } OPNMIDIplay::~OPNMIDIplay() { } void OPNMIDIplay::applySetup() { Synth &synth = *m_synth; synth.m_musicMode = Synth::MODE_MIDI; m_setup.tick_skip_samples_delay = 0; synth.m_runAtPcmRate = m_setup.runAtPcmRate; synth.m_scaleModulators = (m_setup.ScaleModulators != 0); if(m_setup.LogarithmicVolumes != 0) synth.setVolumeScaleModel(OPNMIDI_VolumeModel_NativeOPN2); else synth.setVolumeScaleModel(static_cast(m_setup.VolumeModel)); if(m_setup.VolumeModel == OPNMIDI_VolumeModel_AUTO) synth.m_volumeScale = static_cast(synth.m_insBankSetup.volumeModel); synth.m_numChips = m_setup.numChips; if(m_setup.lfoEnable < 0) synth.m_lfoEnable = (synth.m_insBankSetup.lfoEnable != 0); else synth.m_lfoEnable = (m_setup.lfoEnable != 0); if(m_setup.lfoFrequency < 0) synth.m_lfoFrequency = static_cast(synth.m_insBankSetup.lfoFrequency); else synth.m_lfoFrequency = static_cast(m_setup.lfoFrequency); int chipType; if(m_setup.chipType < 0) chipType = synth.m_insBankSetup.chipType; else chipType = m_setup.chipType; synth.reset(m_setup.emulator, m_setup.PCM_RATE, static_cast(chipType), this); m_chipChannels.clear(); m_chipChannels.resize(synth.m_numChannels, OpnChannel()); resetMIDIDefaults(); #if defined(OPNMIDI_MIDI2VGM) && !defined(OPNMIDI_DISABLE_MIDI_SEQUENCER) m_sequencerInterface->onloopStart = synth.m_loopStartHook; m_sequencerInterface->onloopStart_userData = synth.m_loopStartHookData; m_sequencerInterface->onloopEnd = synth.m_loopEndHook; m_sequencerInterface->onloopEnd_userData = synth.m_loopEndHookData; m_sequencer->setLoopHooksOnly(m_sequencerInterface->onloopStart != NULL); #endif // Reset the arpeggio counter m_arpeggioCounter = 0; } void OPNMIDIplay::partialReset() { Synth &synth = *m_synth; realTime_panic(); m_setup.tick_skip_samples_delay = 0; synth.m_runAtPcmRate = m_setup.runAtPcmRate; synth.reset(m_setup.emulator, m_setup.PCM_RATE, synth.chipFamily(), this); m_chipChannels.clear(); m_chipChannels.resize(synth.m_numChannels); resetMIDIDefaults(); #if defined(OPNMIDI_MIDI2VGM) && !defined(OPNMIDI_DISABLE_MIDI_SEQUENCER) m_sequencerInterface->onloopStart = synth.m_loopStartHook; m_sequencerInterface->onloopStart_userData = synth.m_loopStartHookData; m_sequencerInterface->onloopEnd = synth.m_loopEndHook; m_sequencerInterface->onloopEnd_userData = synth.m_loopEndHookData; m_sequencer->setLoopHooksOnly(m_sequencerInterface->onloopStart != NULL); #endif } void OPNMIDIplay::resetMIDI() { Synth &synth = *m_synth; synth.m_masterVolume = MasterVolumeDefault; m_sysExDeviceId = 0; m_synthMode = Mode_XG; m_arpeggioCounter = 0; m_midiChannels.clear(); m_midiChannels.resize(16, MIDIchannel()); resetMIDIDefaults(); caugh_missing_instruments.clear(); caugh_missing_banks_melodic.clear(); caugh_missing_banks_percussion.clear(); } void OPNMIDIplay::resetMIDIDefaults(int offset) { Synth &synth = *m_synth; for(size_t c = offset, n = m_midiChannels.size(); c < n; ++c) { MIDIchannel &ch = m_midiChannels[c]; if(synth.m_musicMode == Synth::MODE_XMIDI) { ch.def_volume = 127; ch.def_bendsense_lsb = 0; ch.def_bendsense_msb = 12; } else if(synth.m_musicMode == Synth::MODE_RSXX) ch.def_volume = 127; } } void OPNMIDIplay::TickIterators(double s) { Synth &synth = *m_synth; for(uint32_t c = 0, n = synth.m_numChannels; c < n; ++c) { OpnChannel &ch = m_chipChannels[c]; ch.addAge(static_cast(s * 1e6)); } // Resolve "hell of all times" of too short drum notes for(size_t c = 0, n = m_midiChannels.size(); c < n; ++c) { MIDIchannel &ch = m_midiChannels[c]; if(ch.extended_note_count == 0) continue; for(MIDIchannel::notes_iterator inext = ch.activenotes.begin(); !inext.is_end();) { MIDIchannel::notes_iterator i(inext++); MIDIchannel::NoteInfo &ni = i->value; double ttl = ni.ttl; if(ttl <= 0) continue; ni.ttl = ttl = ttl - s; if(ttl <= 0) { --ch.extended_note_count; if(ni.isOnExtendedLifeTime) { noteUpdate(c, i, Upd_Off); ni.isOnExtendedLifeTime = false; } } } } updateVibrato(s); updateArpeggio(s); #if !defined(ADLMIDI_AUDIO_TICK_HANDLER) updateGlide(s); #endif } void OPNMIDIplay::realTime_ResetState() { Synth &synth = *m_synth; for(size_t ch = 0; ch < m_midiChannels.size(); ch++) { MIDIchannel &chan = m_midiChannels[ch]; chan.resetAllControllers(); chan.vibpos = 0.0; chan.lastlrpn = 0; chan.lastmrpn = 0; chan.nrpn = false; if((m_synthMode & Mode_GS) != 0)// Reset custom drum channels on GS chan.is_xg_percussion = false; noteUpdateAll(uint16_t(ch), Upd_All); noteUpdateAll(uint16_t(ch), Upd_Off); } synth.m_masterVolume = MasterVolumeDefault; } bool OPNMIDIplay::realTime_NoteOn(uint8_t channel, uint8_t note, uint8_t velocity) { Synth &synth = *m_synth; if(note >= 127) note = 127; if((synth.m_musicMode == Synth::MODE_RSXX) && (velocity != 0)) { // Check if this is just a note after-touch MIDIchannel::notes_iterator i = m_midiChannels[channel].find_activenote(note); if(!i.is_end()) { MIDIchannel::NoteInfo &ni = i->value; const int veloffset = ni.ains->midiVelocityOffset; velocity = static_cast(std::min(127, std::max(1, static_cast(velocity) + veloffset))); ni.vol = velocity; noteUpdate(channel, i, Upd_Volume); return false; } } if(static_cast(channel) > m_midiChannels.size()) channel = channel % 16; noteOff(channel, note, velocity != 0); // On Note on, Keyoff the note first, just in case keyoff // was omitted; this fixes Dance of sugar-plum fairy // by Microsoft. Now that we've done a Keyoff, // check if we still need to do a Keyon. // vol=0 and event 8x are both Keyoff-only. if(velocity == 0) return false; MIDIchannel &midiChan = m_midiChannels[channel]; size_t midiins = midiChan.patch; bool isPercussion = (channel % 16 == 9) || midiChan.is_xg_percussion; size_t bank = 0; if(midiChan.bank_msb || midiChan.bank_lsb) { if((m_synthMode & Mode_GS) != 0) //in GS mode ignore LSB bank = (midiChan.bank_msb * 256); else bank = (midiChan.bank_msb * 256) + midiChan.bank_lsb; } if(isPercussion) { // == XG bank numbers == // 0x7E00 - XG "SFX Kits" SFX1/SFX2 channel (16128 signed decimal) // 0x7F00 - XG "Drum Kits" Percussion channel (16256 signed decimal) // MIDI instrument defines the patch: if((m_synthMode & Mode_XG) != 0) { // Let XG SFX1/SFX2 bank will go in 128...255 range of LSB in WOPN file) // Let XG Percussion bank will use (0...127 LSB range in WOPN file) // Choose: SFX or Drum Kits bank = midiins + ((bank == 0x7E00) ? 128 : 0); } else { bank = midiins; } midiins = note; // Percussion instrument } if(isPercussion) bank += Synth::PercussionTag; const OpnInstMeta *ains = &Synth::m_emptyInstrument; //Set bank bank const Synth::Bank *bnk = NULL; if((bank & static_cast(~static_cast(Synth::PercussionTag))) > 0) { Synth::BankMap::iterator b = synth.m_insBanks.find(bank); if(b != synth.m_insBanks.end()) bnk = &b->second; if(bnk) ains = &bnk->ins[midiins]; else if(hooks.onDebugMessage) { std::set &missing = (isPercussion) ? caugh_missing_banks_percussion : caugh_missing_banks_melodic; const char *text = (isPercussion) ? "percussion" : "melodic"; if(missing.insert(bank).second) hooks.onDebugMessage(hooks.onDebugMessage_userData, "[%i] Playing missing %s MIDI bank %i (patch %i)", channel, text, bank, midiins); } } //Or fall back to first bank if(ains->flags & OpnInstMeta::Flag_NoSound) { Synth::BankMap::iterator b = synth.m_insBanks.find(bank & Synth::PercussionTag); if(b != synth.m_insBanks.end()) bnk = &b->second; if(bnk) ains = &bnk->ins[midiins]; } const int veloffset = ains->midiVelocityOffset; velocity = static_cast(std::min(127, std::max(1, static_cast(velocity) + veloffset))); int32_t tone = note; if(!isPercussion && (bank > 0)) // For non-zero banks { if(ains->flags & OpnInstMeta::Flag_NoSound) { if(hooks.onDebugMessage) { if(!caugh_missing_instruments.count(static_cast(midiins))) { hooks.onDebugMessage(hooks.onDebugMessage_userData, "[%i] Caught a blank instrument %i (offset %i) in the MIDI bank %u", channel, midiChan.patch, midiins, bank); caugh_missing_instruments.insert(static_cast(midiins)); } } bank = 0; midiins = midiChan.patch; } } if(ains->drumTone) { /*if(ains.tone < 20) tone += ains.tone; else*/ if(ains->drumTone < 128) tone = ains->drumTone; else tone -= ains->drumTone - 128; } MIDIchannel::NoteInfo::Phys voices[MIDIchannel::NoteInfo::MaxNumPhysChans] = { {0, ains->op[0], /*false*/}, {0, ains->op[1], /*pseudo_4op*/}, }; //bool pseudo_4op = ains.flags & opnInstMeta::Flag_Pseudo8op; //if((opn.AdlPercussionMode == 1) && PercussionMap[midiins & 0xFF]) i[1] = i[0]; bool isBlankNote = (ains->flags & OpnInstMeta::Flag_NoSound) != 0; if(hooks.onDebugMessage) { if(!caugh_missing_instruments.count(static_cast(midiins)) && isBlankNote) { hooks.onDebugMessage(hooks.onDebugMessage_userData, "[%i] Playing missing instrument %i", channel, midiins); caugh_missing_instruments.insert(static_cast(midiins)); } } if(isBlankNote) { // Don't even try to play the blank instrument! But, insert the dummy note. MIDIchannel::notes_iterator i = midiChan.ensure_find_or_create_activenote(note); MIDIchannel::NoteInfo &dummy = i->value; dummy.isBlank = true; dummy.isOnExtendedLifeTime = false; dummy.ttl = 0; dummy.ains = NULL; dummy.chip_channels_count = 0; // Record the last note on MIDI channel as source of portamento midiChan.portamentoSource = static_cast(note); return false; } // Allocate AdLib channel (the physical sound channel for the note) int32_t adlchannel[MIDIchannel::NoteInfo::MaxNumPhysChans] = { -1, -1 }; for(uint32_t ccount = 0; ccount < MIDIchannel::NoteInfo::MaxNumPhysChans; ++ccount) { if(ccount == 1) { if(voices[0] == voices[1]) break; // No secondary channel if(adlchannel[0] == -1) break; // No secondary if primary failed } int32_t c = -1; int32_t bs = -0x7FFFFFFFl; for(size_t a = 0; a < static_cast(synth.m_numChannels); ++a) { if(ccount == 1 && static_cast(a) == adlchannel[0]) continue; // ^ Don't use the same channel for primary&secondary // ===== Kept for future pseudo-8-op mode //if(voices[0] == voices[1] || pseudo_4op) //{ // // Only use regular channels // uint8_t expected_mode = 0; // if(opn.AdlPercussionMode == 1) // { // if(cmf_percussion_mode) // expected_mode = MidCh < 11 ? 0 : (3 + MidCh - 11); // CMF // else // expected_mode = PercussionMap[midiins & 0xFF]; // } // if(opn.four_op_category[a] != expected_mode) // continue; //} int64_t s = calculateChipChannelGoodness(a, voices[ccount]); if(s > bs) { bs = static_cast(s); // Best candidate wins c = static_cast(a); } } if(c < 0) { if(hooks.onDebugMessage) hooks.onDebugMessage(hooks.onDebugMessage_userData, "ignored unplaceable note [bank %i, inst %i, note %i, MIDI channel %i]", bank, midiChan.patch, note, channel); continue; // Could not play this note. Ignore it. } prepareChipChannelForNewNote(static_cast(c), voices[ccount]); adlchannel[ccount] = c; } if(adlchannel[0] < 0 && adlchannel[1] < 0) { // The note could not be played, at all. return false; } //if(hooks.onDebugMessage) // hooks.onDebugMessage(hooks.onDebugMessage_userData, "i1=%d:%d, i2=%d:%d", i[0],adlchannel[0], i[1],adlchannel[1]); if(midiChan.softPedal) // Apply Soft Pedal level reducing velocity = static_cast(std::floor(static_cast(velocity) * 0.8f)); // Allocate active note for MIDI channel MIDIchannel::notes_iterator ir = midiChan.ensure_find_or_create_activenote(note); MIDIchannel::NoteInfo &ni = ir->value; ni.vol = velocity; ni.vibrato = midiChan.noteAftertouch[note]; ni.noteTone = static_cast(tone); ni.currentTone = tone; ni.glideRate = HUGE_VAL; ni.midiins = midiins; ni.isPercussion = isPercussion; ni.isBlank = isBlankNote; ni.isOnExtendedLifeTime = false; ni.ttl = 0; ni.ains = ains; ni.chip_channels_count = 0; int8_t currentPortamentoSource = midiChan.portamentoSource; double currentPortamentoRate = midiChan.portamentoRate; bool portamentoEnable = midiChan.portamentoEnable && currentPortamentoRate != HUGE_VAL && !isPercussion; // Record the last note on MIDI channel as source of portamento midiChan.portamentoSource = static_cast(note); // midiChan.portamentoSource = portamentoEnable ? (int8_t)note : (int8_t)-1; // Enable gliding on portamento note if (portamentoEnable && currentPortamentoSource >= 0) { ni.currentTone = currentPortamentoSource; ni.glideRate = currentPortamentoRate; ++midiChan.gliding_note_count; } // Enable life time extension on percussion note if (isPercussion) { ni.ttl = drum_note_min_time; ++midiChan.extended_note_count; } for(unsigned ccount = 0; ccount < MIDIchannel::NoteInfo::MaxNumPhysChans; ++ccount) { int32_t c = adlchannel[ccount]; if(c < 0) continue; uint16_t chipChan = static_cast(adlchannel[ccount]); ni.phys_ensure_find_or_create(chipChan)->assign(voices[ccount]); } noteUpdate(channel, ir, Upd_All | Upd_Patch); for(unsigned ccount = 0; ccount < MIDIchannel::NoteInfo::MaxNumPhysChans; ++ccount) { int32_t c = adlchannel[ccount]; if(c < 0) continue; m_chipChannels[c].recent_ins = voices[ccount]; m_chipChannels[c].addAge(0); } return true; } void OPNMIDIplay::realTime_NoteOff(uint8_t channel, uint8_t note) { if(static_cast(channel) > m_midiChannels.size()) channel = channel % 16; noteOff(channel, note); } void OPNMIDIplay::realTime_NoteAfterTouch(uint8_t channel, uint8_t note, uint8_t atVal) { if(static_cast(channel) > m_midiChannels.size()) channel = channel % 16; MIDIchannel &chan = m_midiChannels[channel]; MIDIchannel::notes_iterator i = m_midiChannels[channel].find_activenote(note); if(!i.is_end()) { i->value.vibrato = atVal; } uint8_t oldAtVal = chan.noteAftertouch[note % 128]; if(atVal != oldAtVal) { chan.noteAftertouch[note % 128] = atVal; bool inUse = atVal != 0; for(unsigned n = 0; !inUse && n < 128; ++n) inUse = chan.noteAftertouch[n] != 0; chan.noteAfterTouchInUse = inUse; } } void OPNMIDIplay::realTime_ChannelAfterTouch(uint8_t channel, uint8_t atVal) { if(static_cast(channel) > m_midiChannels.size()) channel = channel % 16; m_midiChannels[channel].aftertouch = atVal; } void OPNMIDIplay::realTime_Controller(uint8_t channel, uint8_t type, uint8_t value) { if(static_cast(channel) > m_midiChannels.size()) channel = channel % 16; switch(type) { case 1: // Adjust vibrato //UI.PrintLn("%u:vibrato %d", MidCh,value); m_midiChannels[channel].vibrato = value; break; case 0: // Set bank msb (GM bank) m_midiChannels[channel].bank_msb = value; if((m_synthMode & Mode_GS) == 0)// Don't use XG drums on GS synth mode m_midiChannels[channel].is_xg_percussion = isXgPercChannel(m_midiChannels[channel].bank_msb, m_midiChannels[channel].bank_lsb); break; case 32: // Set bank lsb (XG bank) m_midiChannels[channel].bank_lsb = value; if((m_synthMode & Mode_GS) == 0)// Don't use XG drums on GS synth mode m_midiChannels[channel].is_xg_percussion = isXgPercChannel(m_midiChannels[channel].bank_msb, m_midiChannels[channel].bank_lsb); break; case 5: // Set portamento msb m_midiChannels[channel].portamento = static_cast((m_midiChannels[channel].portamento & 0x007F) | (value << 7)); updatePortamento(channel); break; case 37: // Set portamento lsb m_midiChannels[channel].portamento = static_cast((m_midiChannels[channel].portamento & 0x3F80) | (value)); updatePortamento(channel); break; case 65: // Enable/disable portamento m_midiChannels[channel].portamentoEnable = value >= 64; updatePortamento(channel); break; case 7: // Change volume m_midiChannels[channel].volume = value; noteUpdateAll(channel, Upd_Volume); break; case 74: // Change brightness m_midiChannels[channel].brightness = value; noteUpdateAll(channel, Upd_Volume); break; case 64: // Enable/disable sustain m_midiChannels[channel].sustain = (value >= 64); if(!m_midiChannels[channel].sustain) killSustainingNotes(channel, -1, OpnChannel::LocationData::Sustain_Pedal); break; case 66: // Enable/disable sostenuto if(value >= 64) //Find notes and mark them as sostenutoed markSostenutoNotes(channel); else killSustainingNotes(channel, -1, OpnChannel::LocationData::Sustain_Sostenuto); break; case 67: // Enable/disable soft-pedal m_midiChannels[channel].softPedal = (value >= 64); break; case 11: // Change expression (another volume factor) m_midiChannels[channel].expression = value; noteUpdateAll(channel, Upd_Volume); break; case 10: // Change panning m_midiChannels[channel].panning = value; noteUpdateAll(channel, Upd_Pan); break; case 121: // Reset all controllers m_midiChannels[channel].resetAllControllers121(); noteUpdateAll(channel, Upd_Pan + Upd_Volume + Upd_Pitch); // Kill all sustained notes killSustainingNotes(channel, -1, OpnChannel::LocationData::Sustain_ANY); break; case 120: // All sounds off noteUpdateAll(channel, Upd_OffMute); break; case 123: // All notes off noteUpdateAll(channel, Upd_Off); break; case 91: break; // Reverb effect depth. We don't do per-channel reverb. case 92: break; // Tremolo effect depth. We don't do... case 93: break; // Chorus effect depth. We don't do. case 94: break; // Celeste effect depth. We don't do. case 95: break; // Phaser effect depth. We don't do. case 98: m_midiChannels[channel].lastlrpn = value; m_midiChannels[channel].nrpn = true; break; case 99: m_midiChannels[channel].lastmrpn = value; m_midiChannels[channel].nrpn = true; break; case 100: m_midiChannels[channel].lastlrpn = value; m_midiChannels[channel].nrpn = false; break; case 101: m_midiChannels[channel].lastmrpn = value; m_midiChannels[channel].nrpn = false; break; case 113: break; // Related to pitch-bender, used by missimp.mid in Duke3D case 6: setRPN(channel, value, true); break; case 38: setRPN(channel, value, false); break; //case 103: // cmf_percussion_mode = (value != 0); // break; // CMF (ctrl 0x67) rhythm mode default: break; //UI.PrintLn("Ctrl %d <- %d (ch %u)", ctrlno, value, MidCh); } } void OPNMIDIplay::realTime_PatchChange(uint8_t channel, uint8_t patch) { if(static_cast(channel) > m_midiChannels.size()) channel = channel % 16; m_midiChannels[channel].patch = patch; } void OPNMIDIplay::realTime_PitchBend(uint8_t channel, uint16_t pitch) { if(static_cast(channel) > m_midiChannels.size()) channel = channel % 16; m_midiChannels[channel].bend = int(pitch) - 8192; noteUpdateAll(channel, Upd_Pitch); } void OPNMIDIplay::realTime_PitchBend(uint8_t channel, uint8_t msb, uint8_t lsb) { if(static_cast(channel) > m_midiChannels.size()) channel = channel % 16; m_midiChannels[channel].bend = int(lsb) + int(msb) * 128 - 8192; noteUpdateAll(channel, Upd_Pitch); } void OPNMIDIplay::realTime_BankChangeLSB(uint8_t channel, uint8_t lsb) { if(static_cast(channel) > m_midiChannels.size()) channel = channel % 16; m_midiChannels[channel].bank_lsb = lsb; } void OPNMIDIplay::realTime_BankChangeMSB(uint8_t channel, uint8_t msb) { if(static_cast(channel) > m_midiChannels.size()) channel = channel % 16; m_midiChannels[channel].bank_msb = msb; } void OPNMIDIplay::realTime_BankChange(uint8_t channel, uint16_t bank) { if(static_cast(channel) > m_midiChannels.size()) channel = channel % 16; m_midiChannels[channel].bank_lsb = uint8_t(bank & 0xFF); m_midiChannels[channel].bank_msb = uint8_t((bank >> 8) & 0xFF); } void OPNMIDIplay::setDeviceId(uint8_t id) { m_sysExDeviceId = id; } bool OPNMIDIplay::realTime_SysEx(const uint8_t *msg, size_t size) { if(size < 4 || msg[0] != 0xF0 || msg[size - 1] != 0xF7) return false; unsigned manufacturer = msg[1]; unsigned dev = msg[2]; msg += 3; size -= 4; switch(manufacturer) { default: break; case Manufacturer_UniversalNonRealtime: case Manufacturer_UniversalRealtime: return doUniversalSysEx( dev, manufacturer == Manufacturer_UniversalRealtime, msg, size); case Manufacturer_Roland: return doRolandSysEx(dev, msg, size); case Manufacturer_Yamaha: return doYamahaSysEx(dev, msg, size); } return false; } bool OPNMIDIplay::doUniversalSysEx(unsigned dev, bool realtime, const uint8_t *data, size_t size) { bool devicematch = dev == 0x7F || dev == m_sysExDeviceId; if(size < 2 || !devicematch) return false; unsigned address = (((unsigned)data[0] & 0x7F) << 8) | (((unsigned)data[1] & 0x7F)); data += 2; size -= 2; switch(((unsigned)realtime << 16) | address) { case (0 << 16) | 0x0901: // GM System On if(hooks.onDebugMessage) hooks.onDebugMessage(hooks.onDebugMessage_userData, "SysEx: GM System On"); m_synthMode = Mode_GM; realTime_ResetState(); return true; case (0 << 16) | 0x0902: // GM System Off if(hooks.onDebugMessage) hooks.onDebugMessage(hooks.onDebugMessage_userData, "SysEx: GM System Off"); m_synthMode = Mode_XG;//TODO: TEMPORARY, make something RIGHT realTime_ResetState(); return true; case (1 << 16) | 0x0401: // MIDI Master Volume if(size != 2) break; unsigned volume = (((unsigned)data[0] & 0x7F)) | (((unsigned)data[1] & 0x7F) << 7); if(m_synth.get()) m_synth->m_masterVolume = static_cast(volume >> 7); for(size_t ch = 0; ch < m_midiChannels.size(); ch++) noteUpdateAll(uint16_t(ch), Upd_Volume); return true; } return false; } bool OPNMIDIplay::doRolandSysEx(unsigned dev, const uint8_t *data, size_t size) { bool devicematch = dev == 0x7F || (dev & 0x0F) == m_sysExDeviceId; if(size < 6 || !devicematch) return false; unsigned model = data[0] & 0x7F; unsigned mode = data[1] & 0x7F; unsigned checksum = data[size - 1] & 0x7F; data += 2; size -= 3; #if !defined(OPNMIDI_SKIP_ROLAND_CHECKSUM) { unsigned checkvalue = 0; for(size_t i = 0; i < size; ++i) checkvalue += data[i] & 0x7F; checkvalue = (128 - (checkvalue & 127)) & 127; if(checkvalue != checksum) { if(hooks.onDebugMessage) hooks.onDebugMessage(hooks.onDebugMessage_userData, "SysEx: Caught invalid roland SysEx message!"); return false; } } #endif unsigned address = (((unsigned)data[0] & 0x7F) << 16) | (((unsigned)data[1] & 0x7F) << 8) | (((unsigned)data[2] & 0x7F)); unsigned target_channel = 0; /* F0 41 10 42 12 40 00 7F 00 41 F7 */ if((address & 0xFFF0FF) == 0x401015) // Turn channel 1 into percussion { address = 0x401015; target_channel = data[1] & 0x0F; } data += 3; size -= 3; if(mode != RolandMode_Send) // don't have MIDI-Out reply ability return false; // Mode Set // F0 {41 10 42 12} {40 00 7F} {00 41} F7 // Custom drum channels // F0 {41 10 42 12} {40 1 15} { } F7 switch((model << 24) | address) { case (RolandModel_GS << 24) | 0x00007F: // System Mode Set { if(size != 1 || (dev & 0xF0) != 0x10) break; unsigned gs_mode = data[0] & 0x7F; ADL_UNUSED(gs_mode);//TODO: Hook this correctly! if(hooks.onDebugMessage) hooks.onDebugMessage(hooks.onDebugMessage_userData, "SysEx: Caught Roland System Mode Set: %02X", gs_mode); m_synthMode = Mode_GS; realTime_ResetState(); return true; } case (RolandModel_GS << 24) | 0x40007F: // Mode Set { if(size != 1 || (dev & 0xF0) != 0x10) break; unsigned value = data[0] & 0x7F; ADL_UNUSED(value);//TODO: Hook this correctly! if(hooks.onDebugMessage) hooks.onDebugMessage(hooks.onDebugMessage_userData, "SysEx: Caught Roland Mode Set: %02X", value); m_synthMode = Mode_GS; realTime_ResetState(); return true; } case (RolandModel_GS << 24) | 0x401015: // Percussion channel { if(size != 1 || (dev & 0xF0) != 0x10) break; if(m_midiChannels.size() < 16) break; unsigned value = data[0] & 0x7F; const uint8_t channels_map[16] = { 9, 0, 1, 2, 3, 4, 5, 6, 7, 8, 10, 11, 12, 13, 14, 15 }; if(hooks.onDebugMessage) hooks.onDebugMessage(hooks.onDebugMessage_userData, "SysEx: Caught Roland Percussion set: %02X on channel %u (from %X)", value, channels_map[target_channel], target_channel); m_midiChannels[channels_map[target_channel]].is_xg_percussion = ((value == 0x01)) || ((value == 0x02)); return true; } } return false; } bool OPNMIDIplay::doYamahaSysEx(unsigned dev, const uint8_t *data, size_t size) { bool devicematch = dev == 0x7F || (dev & 0x0F) == m_sysExDeviceId; if(size < 1 || !devicematch) return false; unsigned model = data[0] & 0x7F; ++data; --size; switch((model << 8) | (dev & 0xF0)) { case (YamahaModel_XG << 8) | 0x10: // parameter change { if(size < 3) break; unsigned address = (((unsigned)data[0] & 0x7F) << 16) | (((unsigned)data[1] & 0x7F) << 8) | (((unsigned)data[2] & 0x7F)); data += 3; size -= 3; switch(address) { case 0x00007E: // XG System On if(size != 1) break; unsigned value = data[0] & 0x7F; ADL_UNUSED(value);//TODO: Hook this correctly! if(hooks.onDebugMessage) hooks.onDebugMessage(hooks.onDebugMessage_userData, "SysEx: Caught Yamaha XG System On: %02X", value); m_synthMode = Mode_XG; realTime_ResetState(); return true; } break; } } return false; } void OPNMIDIplay::realTime_panic() { panic(); killSustainingNotes(-1, -1, OpnChannel::LocationData::Sustain_ANY); } void OPNMIDIplay::realTime_deviceSwitch(size_t track, const char *data, size_t length) { const std::string indata(data, length); m_currentMidiDevice[track] = chooseDevice(indata); } size_t OPNMIDIplay::realTime_currentDevice(size_t track) { if(m_currentMidiDevice.empty()) return 0; return m_currentMidiDevice[track]; } #if defined(ADLMIDI_AUDIO_TICK_HANDLER) void OPNMIDIplay::AudioTick(uint32_t chipId, uint32_t rate) { if(chipId != 0) // do first chip ticks only return; uint32_t tickNumber = m_audioTickCounter++; double timeDelta = 1.0 / rate; enum { portamentoInterval = 32 }; // for efficiency, set rate limit on pitch updates if(tickNumber % portamentoInterval == 0) { double portamentoDelta = timeDelta * portamentoInterval; UpdateGlide(portamentoDelta); } } #endif void OPNMIDIplay::noteUpdate(size_t midCh, OPNMIDIplay::MIDIchannel::notes_iterator i, unsigned props_mask, int32_t select_adlchn) { Synth &synth = *m_synth; MIDIchannel::NoteInfo &info = i->value; const int16_t noteTone = info.noteTone; const double currentTone = info.currentTone; const uint8_t vol = info.vol; const size_t midiins = info.midiins; const OpnInstMeta &ains = *info.ains; OpnChannel::Location my_loc; my_loc.MidCh = static_cast(midCh); my_loc.note = info.note; if(info.isBlank) { if(props_mask & Upd_Off) m_midiChannels[midCh].activenotes.erase(i); return; } for(unsigned ccount = 0, ctotal = info.chip_channels_count; ccount < ctotal; ccount++) { const MIDIchannel::NoteInfo::Phys &ins = info.chip_channels[ccount]; uint16_t c = ins.chip_chan; if(select_adlchn >= 0 && c != select_adlchn) continue; if(props_mask & Upd_Patch) { synth.setPatch(c, ins.ains); OpnChannel::users_iterator ci = m_chipChannels[c].find_or_create_user(my_loc); if(!ci.is_end()) // inserts if necessary { OpnChannel::LocationData &d = ci->value; d.sustained = OpnChannel::LocationData::Sustain_None; d.vibdelay_us = 0; d.fixed_sustain = (ains.soundKeyOnMs == static_cast(opnNoteOnMaxTime)); d.kon_time_until_neglible_us = 1000 * ains.soundKeyOnMs; d.ins = ins; } } } for(unsigned ccount = 0; ccount < info.chip_channels_count; ccount++) { const MIDIchannel::NoteInfo::Phys &ins = info.chip_channels[ccount]; uint16_t c = ins.chip_chan; if(select_adlchn >= 0 && c != select_adlchn) continue; if(props_mask & Upd_Off) // note off { if(m_midiChannels[midCh].sustain == 0) { OpnChannel::users_iterator k = m_chipChannels[c].find_user(my_loc); bool do_erase_user = (!k.is_end() && ((k->value.sustained & OpnChannel::LocationData::Sustain_Sostenuto) == 0)); if(do_erase_user) m_chipChannels[c].users.erase(k); if(hooks.onNote) hooks.onNote(hooks.onNote_userData, c, noteTone, static_cast(midiins), 0, 0.0); if(do_erase_user && m_chipChannels[c].users.empty()) { synth.noteOff(c); if(props_mask & Upd_Mute) // Mute the note { synth.touchNote(c, 0); m_chipChannels[c].koff_time_until_neglible_us = 0; } else { m_chipChannels[c].koff_time_until_neglible_us = 1000 * int64_t(ains.soundKeyOffMs); } } } else { // Sustain: Forget about the note, but don't key it off. // Also will avoid overwriting it very soon. OpnChannel::users_iterator d = m_chipChannels[c].find_or_create_user(my_loc); if(!d.is_end()) d->value.sustained |= OpnChannel::LocationData::Sustain_Pedal; // note: not erased! if(hooks.onNote) hooks.onNote(hooks.onNote_userData, c, noteTone, static_cast(midiins), -1, 0.0); } info.phys_erase_at(&ins); // decrements channel count --ccount; // adjusts index accordingly continue; } if(props_mask & Upd_Pan) synth.setPan(c, m_midiChannels[midCh].panning); if(props_mask & Upd_Volume) { const MIDIchannel &ch = m_midiChannels[midCh]; bool is_percussion = (midCh == 9) || ch.is_xg_percussion; uint_fast32_t brightness = is_percussion ? 127 : ch.brightness; if(!m_setup.fullRangeBrightnessCC74) { // Simulate post-High-Pass filter result which affects sounding by half level only if(brightness >= 64) brightness = 127; else brightness *= 2; } synth.touchNote(c, vol, ch.volume, ch.expression, static_cast(brightness)); } if(props_mask & Upd_Pitch) { OpnChannel::users_iterator d = m_chipChannels[c].find_user(my_loc); // Don't bend a sustained note if(d.is_end() || (d->value.sustained == OpnChannel::LocationData::Sustain_None)) { MIDIchannel &chan = m_midiChannels[midCh]; double midibend = chan.bend * chan.bendsense; double bend = midibend + ins.ains.noteOffset; double phase = 0.0; uint8_t vibrato = std::max(chan.vibrato, chan.aftertouch); vibrato = std::max(vibrato, info.vibrato); if((ains.flags & OpnInstMeta::Flag_Pseudo8op) && ins.ains == ains.op[1]) { phase = ains.voice2_fine_tune; } if(vibrato && (d.is_end() || d->value.vibdelay_us >= chan.vibdelay_us)) bend += static_cast(vibrato) * chan.vibdepth * std::sin(chan.vibpos); synth.noteOn(c, currentTone + bend + phase); if(hooks.onNote) hooks.onNote(hooks.onNote_userData, c, noteTone, static_cast(midiins), vol, midibend); } } } if(info.chip_channels_count == 0) { m_midiChannels[midCh].cleanupNote(i); m_midiChannels[midCh].activenotes.erase(i); } } void OPNMIDIplay::noteUpdateAll(size_t midCh, unsigned props_mask) { for(MIDIchannel::notes_iterator i = m_midiChannels[midCh].activenotes.begin(); !i.is_end();) { MIDIchannel::notes_iterator j(i++); noteUpdate(midCh, j, props_mask); } } const std::string &OPNMIDIplay::getErrorString() { return errorStringOut; } void OPNMIDIplay::setErrorString(const std::string &err) { errorStringOut = err; } int64_t OPNMIDIplay::calculateChipChannelGoodness(size_t c, const MIDIchannel::NoteInfo::Phys &ins) const { Synth &synth = *m_synth; const OpnChannel &chan = m_chipChannels[c]; int64_t koff_ms = chan.koff_time_until_neglible_us / 1000; int64_t s = -koff_ms; // Rate channel with a releasing note if(s < 0 && chan.users.empty()) { s -= 40000; // If it's same instrument, better chance to get it when no free channels if(chan.recent_ins == ins) s = (synth.m_musicMode == Synth::MODE_CMF) ? 0 : -koff_ms; return s; } // Same midi-instrument = some stability for(OpnChannel::const_users_iterator j = chan.users.begin(); !j.is_end(); ++j) { const OpnChannel::LocationData &jd = j->value; int64_t kon_ms = jd.kon_time_until_neglible_us / 1000; s -= (jd.sustained == OpnChannel::LocationData::Sustain_None) ? (4000000 + kon_ms) : (500000 + (kon_ms / 2)); MIDIchannel::notes_iterator k = const_cast(m_midiChannels[jd.loc.MidCh]).find_activenote(jd.loc.note); if(!k.is_end()) { const MIDIchannel::NoteInfo &info = k->value; // Same instrument = good if(jd.ins == ins) { s += 300; // Arpeggio candidate = even better if(jd.vibdelay_us < 70000 || jd.kon_time_until_neglible_us > 20000000) s += 10; } // Percussion is inferior to melody s += info.isPercussion ? 50 : 0; } // If there is another channel to which this note // can be evacuated to in the case of congestion, // increase the score slightly. // unsigned n_evacuation_stations = 0; // for(unsigned c2 = 0; c2 < opn.NumChannels; ++c2) // { // if(c2 == c) continue; // if(opn.four_op_category[c2] // != opn.four_op_category[c]) continue; // for(AdlChannel::const_users_iterator m = m_chipChannels[c2].users.begin(); !m.is_end(); ++m) // { // const AdlChannel::LocationData &md = m->value; // if(md.sustained != OpnChannel::LocationData::Sustain_None) continue; // if(md.vibdelay >= 200000) continue; // if(md.ins != jd.ins) continue; // n_evacuation_stations += 1; // } // } // s += n_evacuation_stations * 4; } return s; } void OPNMIDIplay::prepareChipChannelForNewNote(size_t c, const MIDIchannel::NoteInfo::Phys &ins) { if(m_chipChannels[c].users.empty()) return; // Nothing to do Synth &synth = *m_synth; //bool doing_arpeggio = false; for(OpnChannel::users_iterator jnext = m_chipChannels[c].users.begin(); !jnext.is_end();) { OpnChannel::users_iterator j = jnext; OpnChannel::LocationData &jd = jnext->value; ++jnext; if(jd.sustained == OpnChannel::LocationData::Sustain_None) { // Collision: Kill old note, // UNLESS we're going to do arpeggio MIDIchannel::notes_iterator i (m_midiChannels[jd.loc.MidCh].ensure_find_activenote(jd.loc.note)); // Check if we can do arpeggio. if((jd.vibdelay_us < 70000 || jd.kon_time_until_neglible_us > 20000000) && jd.ins == ins) { // Do arpeggio together with this note. //doing_arpeggio = true; continue; } killOrEvacuate(c, j, i); // ^ will also erase j from ch[c].users. } } // Kill all sustained notes on this channel // Don't keep them for arpeggio, because arpeggio requires // an intact "activenotes" record. This is a design flaw. killSustainingNotes(-1, static_cast(c), OpnChannel::LocationData::Sustain_ANY); // Keyoff the channel so that it can be retriggered, // unless the new note will be introduced as just an arpeggio. if(m_chipChannels[c].users.empty()) synth.noteOff(c); } void OPNMIDIplay::killOrEvacuate(size_t from_channel, OpnChannel::users_iterator j, OPNMIDIplay::MIDIchannel::notes_iterator i) { Synth &synth = *m_synth; uint32_t maxChannels = OPN_MAX_CHIPS * 6; OpnChannel::LocationData &jd = j->value; MIDIchannel::NoteInfo &info = i->value; // Before killing the note, check if it can be // evacuated to another channel as an arpeggio // instrument. This helps if e.g. all channels // are full of strings and we want to do percussion. // FIXME: This does not care about four-op entanglements. for(uint32_t c = 0; c < synth.m_numChannels; ++c) { uint16_t cs = static_cast(c); if(c >= maxChannels) break; if(c == from_channel) continue; //if(opn.four_op_category[c] != opn.four_op_category[from_channel]) // continue; OpnChannel &adlch = m_chipChannels[c]; if(adlch.users.size() == adlch.users.capacity()) continue; // no room for more arpeggio on channel if(!m_chipChannels[cs].find_user(jd.loc).is_end()) continue; // channel already has this note playing (sustained) // avoid introducing a duplicate location. for(OpnChannel::users_iterator m = adlch.users.begin(); !m.is_end(); ++m) { OpnChannel::LocationData &mv = m->value; if(mv.vibdelay_us >= 200000 && mv.kon_time_until_neglible_us < 10000000) continue; if(mv.ins != jd.ins) continue; if(hooks.onNote) { hooks.onNote(hooks.onNote_userData, static_cast(from_channel), info.noteTone, static_cast(info.midiins), 0, 0.0); hooks.onNote(hooks.onNote_userData, static_cast(c), info.noteTone, static_cast(info.midiins), info.vol, 0.0); } info.phys_erase(static_cast(from_channel)); info.phys_ensure_find_or_create(cs)->assign(jd.ins); m_chipChannels[cs].users.push_back(jd); m_chipChannels[from_channel].users.erase(j); return; } } /*UI.PrintLn( "collision @%u: [%ld] <- ins[%3u]", c, //ch[c].midiins<128?'M':'P', ch[c].midiins&127, ch[c].age, //adlins[ch[c].insmeta].ms_sound_kon, ins );*/ // Kill it noteUpdate(jd.loc.MidCh, i, Upd_Off, static_cast(from_channel)); } void OPNMIDIplay::panic() { for(uint8_t chan = 0; chan < m_midiChannels.size(); chan++) { for(uint8_t note = 0; note < 128; note++) realTime_NoteOff(chan, note); } } void OPNMIDIplay::killSustainingNotes(int32_t midCh, int32_t this_adlchn, uint32_t sustain_type) { Synth &synth = *m_synth; uint32_t first = 0, last = synth.m_numChannels; if(this_adlchn >= 0) { first = static_cast(this_adlchn); last = first + 1; } for(uint32_t c = first; c < last; ++c) { if(m_chipChannels[c].users.empty()) continue; // Nothing to do for(OpnChannel::users_iterator jnext = m_chipChannels[c].users.begin(); !jnext.is_end();) { OpnChannel::users_iterator j = jnext; OpnChannel::LocationData &jd = j->value; ++jnext; if((midCh < 0 || jd.loc.MidCh == midCh) && ((jd.sustained & sustain_type) != 0)) { int midiins = '?'; if(hooks.onNote) hooks.onNote(hooks.onNote_userData, static_cast(c), jd.loc.note, midiins, 0, 0.0); jd.sustained &= ~sustain_type; if(jd.sustained == OpnChannel::LocationData::Sustain_None) m_chipChannels[c].users.erase(j);//Remove only when note is clean from any holders } } // Keyoff the channel, if there are no users left. if(m_chipChannels[c].users.empty()) synth.noteOff(c); } } void OPNMIDIplay::markSostenutoNotes(int32_t midCh) { Synth &synth = *m_synth; uint32_t first = 0, last = synth.m_numChannels; for(uint32_t c = first; c < last; ++c) { if(m_chipChannels[c].users.empty()) continue; // Nothing to do for(OpnChannel::users_iterator jnext = m_chipChannels[c].users.begin(); !jnext.is_end();) { OpnChannel::users_iterator j = jnext; OpnChannel::LocationData &jd = j->value; ++jnext; if((jd.loc.MidCh == midCh) && (jd.sustained == OpnChannel::LocationData::Sustain_None)) jd.sustained |= OpnChannel::LocationData::Sustain_Sostenuto; } } } void OPNMIDIplay::setRPN(size_t midCh, unsigned value, bool MSB) { bool nrpn = m_midiChannels[midCh].nrpn; unsigned addr = m_midiChannels[midCh].lastmrpn * 0x100 + m_midiChannels[midCh].lastlrpn; switch(addr + nrpn * 0x10000 + MSB * 0x20000) { case 0x0000 + 0*0x10000 + 1*0x20000: // Pitch-bender sensitivity m_midiChannels[midCh].bendsense_msb = static_cast(value); m_midiChannels[midCh].updateBendSensitivity(); break; case 0x0000 + 0*0x10000 + 0*0x20000: // Pitch-bender sensitivity LSB m_midiChannels[midCh].bendsense_lsb = static_cast(value); m_midiChannels[midCh].updateBendSensitivity(); break; case 0x0108 + 1*0x10000 + 1*0x20000: // Vibrato speed if((m_synthMode & Mode_XG) != 0) // Vibrato speed { if(value == 64) m_midiChannels[midCh].vibspeed = 1.0; else if(value < 100) m_midiChannels[midCh].vibspeed = 1.0 / (1.6e-2 * (value ? value : 1)); else m_midiChannels[midCh].vibspeed = 1.0 / (0.051153846 * value - 3.4965385); m_midiChannels[midCh].vibspeed *= 2 * 3.141592653 * 5.0; } break; case 0x0109 + 1*0x10000 + 1*0x20000: if((m_synthMode & Mode_XG) != 0) // Vibrato depth { m_midiChannels[midCh].vibdepth = ((static_cast(value) - 64) * 0.15) * 0.01; } break; case 0x010A + 1*0x10000 + 1*0x20000: if((m_synthMode & Mode_XG) != 0) // Vibrato delay in millisecons { m_midiChannels[midCh].vibdelay_us = value ? int64_t(209.2 * std::exp(0.0795 * static_cast(value))) : 0; } break; default:/* UI.PrintLn("%s %04X <- %d (%cSB) (ch %u)", "NRPN"+!nrpn, addr, value, "LM"[MSB], MidCh);*/ break; } } void OPNMIDIplay::updatePortamento(size_t midCh) { double rate = HUGE_VAL; uint16_t midival = m_midiChannels[midCh].portamento; if(m_midiChannels[midCh].portamentoEnable && midival > 0) rate = 350.0 * std::pow(2.0, -0.062 * (1.0 / 128) * midival); m_midiChannels[midCh].portamentoRate = rate; } void OPNMIDIplay::noteOff(size_t midCh, uint8_t note, bool forceNow) { MIDIchannel &ch = m_midiChannels[midCh]; MIDIchannel::notes_iterator i = ch.find_activenote(note); if(!i.is_end()) { MIDIchannel::NoteInfo &ni = i->value; if(forceNow || ni.ttl <= 0) noteUpdate(midCh, i, Upd_Off); else ni.isOnExtendedLifeTime = true; } } void OPNMIDIplay::updateVibrato(double amount) { for(size_t a = 0, b = m_midiChannels.size(); a < b; ++a) { if(m_midiChannels[a].hasVibrato() && !m_midiChannels[a].activenotes.empty()) { noteUpdateAll(static_cast(a), Upd_Pitch); m_midiChannels[a].vibpos += amount * m_midiChannels[a].vibspeed; } else m_midiChannels[a].vibpos = 0.0; } } size_t OPNMIDIplay::chooseDevice(const std::string &name) { std::map::iterator i = m_midiDevices.find(name); if(i != m_midiDevices.end()) return i->second; size_t n = m_midiDevices.size() * 16; m_midiDevices.insert(std::make_pair(name, n)); m_midiChannels.resize(n + 16); resetMIDIDefaults(static_cast(n)); return n; } void OPNMIDIplay::updateArpeggio(double) // amount = amount of time passed { // If there is an adlib channel that has multiple notes // simulated on the same channel, arpeggio them. Synth &synth = *m_synth; #if 0 const unsigned desired_arpeggio_rate = 40; // Hz (upper limit) #if 1 static unsigned cache = 0; amount = amount; // Ignore amount. Assume we get a constant rate. cache += MaxSamplesAtTime * desired_arpeggio_rate; if(cache < PCM_RATE) return; cache %= PCM_RATE; #else static double arpeggio_cache = 0; arpeggio_cache += amount * desired_arpeggio_rate; if(arpeggio_cache < 1.0) return; arpeggio_cache = 0.0; #endif #endif ++m_arpeggioCounter; for(uint32_t c = 0; c < synth.m_numChannels; ++c) { retry_arpeggio: if(c > uint32_t(std::numeric_limits::max())) break; size_t n_users = m_chipChannels[c].users.size(); if(n_users > 1) { OpnChannel::users_iterator i = m_chipChannels[c].users.begin(); size_t rate_reduction = 3; if(n_users >= 3) rate_reduction = 2; if(n_users >= 4) rate_reduction = 1; for(size_t count = (m_arpeggioCounter / rate_reduction) % n_users, n = 0; n < count; ++n) ++i; OpnChannel::LocationData &d = i->value; if(d.sustained == OpnChannel::LocationData::Sustain_None) { if(d.kon_time_until_neglible_us <= 0) { noteUpdate( d.loc.MidCh, m_midiChannels[ d.loc.MidCh ].ensure_find_activenote(d.loc.note), Upd_Off, static_cast(c)); goto retry_arpeggio; } noteUpdate( d.loc.MidCh, m_midiChannels[ d.loc.MidCh ].ensure_find_activenote(d.loc.note), Upd_Pitch | Upd_Volume | Upd_Pan, static_cast(c)); } } } } void OPNMIDIplay::updateGlide(double amount) { size_t num_channels = m_midiChannels.size(); for(size_t channel = 0; channel < num_channels; ++channel) { MIDIchannel &midiChan = m_midiChannels[channel]; if(midiChan.gliding_note_count == 0) continue; for(MIDIchannel::notes_iterator it = midiChan.activenotes.begin(); !it.is_end(); ++it) { MIDIchannel::NoteInfo &info = it->value; double finalTone = info.noteTone; double previousTone = info.currentTone; bool directionUp = previousTone < finalTone; double toneIncr = amount * (directionUp ? +info.glideRate : -info.glideRate); double currentTone = previousTone + toneIncr; bool glideFinished = !(directionUp ? (currentTone < finalTone) : (currentTone > finalTone)); currentTone = glideFinished ? finalTone : currentTone; if(int64_t(currentTone * 1000000.0) != int64_t(previousTone * 1000000.0)) { info.currentTone = currentTone; noteUpdate(static_cast(channel), it, Upd_Pitch); } } } } void OPNMIDIplay::describeChannels(char *str, char *attr, size_t size) { if (!str || size <= 0) return; Synth &synth = *m_synth; uint32_t numChannels = synth.m_numChannels; uint32_t index = 0; while(index < numChannels && index < size - 1) { const OpnChannel &adlChannel = m_chipChannels[index]; OpnChannel::const_users_iterator loc = adlChannel.users.begin(); OpnChannel::const_users_iterator locnext(loc); if(!loc.is_end()) ++locnext; if(loc.is_end()) // off { str[index] = '-'; } else if(!locnext.is_end()) // arpeggio { str[index] = '@'; } else // on { str[index] = '+'; } uint8_t attribute = 0; if (!loc.is_end()) // 4-bit color index of MIDI channel attribute |= uint8_t(loc->value.loc.MidCh & 0xF); attr[index] = static_cast(attribute); ++index; } str[index] = 0; attr[index] = 0; } /* TODO */ //#ifndef ADLMIDI_DISABLE_CPP_EXTRAS //ADLMIDI_EXPORT AdlInstrumentTester::AdlInstrumentTester(ADL_MIDIPlayer *device) //{ // cur_gm = 0; // ins_idx = 0; // play = reinterpret_cast(device->adl_midiPlayer); // if(!play) // return; // opl = &play->opl; //} //ADLMIDI_EXPORT AdlInstrumentTester::~AdlInstrumentTester() //{} //ADLMIDI_EXPORT void AdlInstrumentTester::FindAdlList() //{ // const unsigned NumBanks = (unsigned)adl_getBanksCount(); // std::set adl_ins_set; // for(unsigned bankno = 0; bankno < NumBanks; ++bankno) // adl_ins_set.insert(banks[bankno][cur_gm]); // adl_ins_list.assign(adl_ins_set.begin(), adl_ins_set.end()); // ins_idx = 0; // NextAdl(0); // opl->Silence(); //} //ADLMIDI_EXPORT void AdlInstrumentTester::Touch(unsigned c, unsigned volume) // Volume maxes at 127*127*127 //{ // if(opl->LogarithmicVolumes) // opl->Touch_Real(c, volume * 127 / (127 * 127 * 127) / 2); // else // { // // The formula below: SOLVE(V=127^3 * 2^( (A-63.49999) / 8), A) // opl->Touch_Real(c, volume > 8725 ? static_cast(std::log((double)volume) * 11.541561 + (0.5 - 104.22845)) : 0); // // The incorrect formula below: SOLVE(V=127^3 * (2^(A/63)-1), A) // //Touch_Real(c, volume>11210 ? 91.61112 * std::log(4.8819E-7*volume + 1.0)+0.5 : 0); // } //} //ADLMIDI_EXPORT void AdlInstrumentTester::DoNote(int note) //{ // if(adl_ins_list.empty()) FindAdlList(); // const unsigned meta = adl_ins_list[ins_idx]; // const adlinsdata &ains = opl->GetAdlMetaIns(meta); // int tone = (cur_gm & 128) ? (cur_gm & 127) : (note + 50); // if(ains.tone) // { // /*if(ains.tone < 20) // tone += ains.tone; // else */ // if(ains.tone < 128) // tone = ains.tone; // else // tone -= ains.tone - 128; // } // double hertz = 172.00093 * std::exp(0.057762265 * (tone + 0.0)); // int i[2] = { ains.adlno1, ains.adlno2 }; // int32_t adlchannel[2] = { 0, 3 }; // if(i[0] == i[1]) // { // adlchannel[1] = -1; // adlchannel[0] = 6; // single-op // if(play->hooks.onDebugMessage) // { // play->hooks.onDebugMessage(play->hooks.onDebugMessage_userData, // "noteon at %d(%d) for %g Hz\n", adlchannel[0], i[0], hertz); // } // } // else // { // if(play->hooks.onDebugMessage) // { // play->hooks.onDebugMessage(play->hooks.onDebugMessage_userData, // "noteon at %d(%d) and %d(%d) for %g Hz\n", adlchannel[0], i[0], adlchannel[1], i[1], hertz); // } // } // opl->NoteOff(0); // opl->NoteOff(3); // opl->NoteOff(6); // for(unsigned c = 0; c < 2; ++c) // { // if(adlchannel[c] < 0) continue; // opl->Patch((uint16_t)adlchannel[c], (uint16_t)i[c]); // opl->Touch_Real((uint16_t)adlchannel[c], 127 * 127 * 100); // opl->Pan((uint16_t)adlchannel[c], 0x30); // opl->NoteOn((uint16_t)adlchannel[c], hertz); // } //} //ADLMIDI_EXPORT void AdlInstrumentTester::NextGM(int offset) //{ // cur_gm = (cur_gm + 256 + (uint32_t)offset) & 0xFF; // FindAdlList(); //} //ADLMIDI_EXPORT void AdlInstrumentTester::NextAdl(int offset) //{ // if(adl_ins_list.empty()) FindAdlList(); // const unsigned NumBanks = (unsigned)adl_getBanksCount(); // ins_idx = (uint32_t)((int32_t)ins_idx + (int32_t)adl_ins_list.size() + offset) % adl_ins_list.size(); // #if 0 // UI.Color(15); // std::fflush(stderr); // std::printf("SELECTED G%c%d\t%s\n", // cur_gm < 128 ? 'M' : 'P', cur_gm < 128 ? cur_gm + 1 : cur_gm - 128, // "<-> select GM, ^v select ins, qwe play note"); // std::fflush(stdout); // UI.Color(7); // std::fflush(stderr); // #endif // for(unsigned a = 0; a < adl_ins_list.size(); ++a) // { // const unsigned i = adl_ins_list[a]; // const adlinsdata &ains = opl->GetAdlMetaIns(i); // char ToneIndication[8] = " "; // if(ains.tone) // { // /*if(ains.tone < 20) // snprintf(ToneIndication, 8, "+%-2d", ains.tone); // else*/ // if(ains.tone < 128) // snprintf(ToneIndication, 8, "=%-2d", ains.tone); // else // snprintf(ToneIndication, 8, "-%-2d", ains.tone - 128); // } // std::printf("%s%s%s%u\t", // ToneIndication, // ains.adlno1 != ains.adlno2 ? "[2]" : " ", // (ins_idx == a) ? "->" : "\t", // i // ); // for(unsigned bankno = 0; bankno < NumBanks; ++bankno) // if(banks[bankno][cur_gm] == i) // std::printf(" %u", bankno); // std::printf("\n"); // } //} //ADLMIDI_EXPORT bool AdlInstrumentTester::HandleInputChar(char ch) //{ // static const char notes[] = "zsxdcvgbhnjmq2w3er5t6y7ui9o0p"; // // c'd'ef'g'a'bC'D'EF'G'A'Bc'd'e // switch(ch) // { // case '/': // case 'H': // case 'A': // NextAdl(-1); // break; // case '*': // case 'P': // case 'B': // NextAdl(+1); // break; // case '-': // case 'K': // case 'D': // NextGM(-1); // break; // case '+': // case 'M': // case 'C': // NextGM(+1); // break; // case 3: // #if !((!defined(__WIN32__) || defined(__CYGWIN__)) && !defined(__DJGPP__)) // case 27: // #endif // return false; // default: // const char *p = std::strchr(notes, ch); // if(p && *p) // DoNote((int)(p - notes) - 12); // } // return true; //} //#endif//ADLMIDI_DISABLE_CPP_EXTRAS