/* * libADLMIDI is a free MIDI to WAV conversion library with OPL3 emulation * * Original ADLMIDI code: Copyright (c) 2010-2014 Joel Yliluoma * ADLMIDI Library API: Copyright (c) 2015-2018 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 "adlmidi_private.hpp" /* Unify MIDI player casting and interface between ADLMIDI and OPNMIDI */ #define GET_MIDI_PLAYER(device) reinterpret_cast((device)->adl_midiPlayer) typedef MIDIplay MidiPlayer; static ADL_Version adl_version = { ADLMIDI_VERSION_MAJOR, ADLMIDI_VERSION_MINOR, ADLMIDI_VERSION_PATCHLEVEL }; static const ADLMIDI_AudioFormat adl_DefaultAudioFormat = { ADLMIDI_SampleType_S16, sizeof(int16_t), 2 * sizeof(int16_t), }; /*---------------------------EXPORTS---------------------------*/ ADLMIDI_EXPORT struct ADL_MIDIPlayer *adl_init(long sample_rate) { ADL_MIDIPlayer *midi_device; midi_device = (ADL_MIDIPlayer *)malloc(sizeof(ADL_MIDIPlayer)); if(!midi_device) { ADLMIDI_ErrorString = "Can't initialize ADLMIDI: out of memory!"; return NULL; } MIDIplay *player = new(std::nothrow) MIDIplay(static_cast(sample_rate)); if(!player) { free(midi_device); ADLMIDI_ErrorString = "Can't initialize ADLMIDI: out of memory!"; return NULL; } midi_device->adl_midiPlayer = player; adlCalculateFourOpChannels(player); return midi_device; } ADLMIDI_EXPORT void adl_close(struct ADL_MIDIPlayer *device) { if(!device) return; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); delete play; device->adl_midiPlayer = NULL; free(device); device = NULL; } ADLMIDI_EXPORT int adl_setDeviceIdentifier(ADL_MIDIPlayer *device, unsigned id) { if(!device || id > 0x0f) return -1; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); play->setDeviceId(static_cast(id)); return 0; } ADLMIDI_EXPORT int adl_setNumChips(ADL_MIDIPlayer *device, int numChips) { if(device == NULL) return -2; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); #ifdef ADLMIDI_HW_OPL ADL_UNUSED(numChips); play->m_setup.numChips = 1; #else play->m_setup.numChips = static_cast(numChips); #endif if(play->m_setup.numChips < 1 || play->m_setup.numChips > ADL_MAX_CHIPS) { play->setErrorString("number of chips may only be 1.." ADL_MAX_CHIPS_STR ".\n"); return -1; } int maxFourOps = static_cast(play->m_setup.numChips * 6); if(play->m_setup.numFourOps > maxFourOps) play->m_setup.numFourOps = maxFourOps; else if(play->m_setup.numFourOps < -1) play->m_setup.numFourOps = -1; if(!play->m_synth.setupLocked()) { play->m_synth.m_numChips = play->m_setup.numChips; if(play->m_setup.numFourOps < 0) adlCalculateFourOpChannels(play, true); else play->m_synth.m_numFourOps = static_cast(play->m_setup.numFourOps); play->partialReset(); return 0; } return 0; } ADLMIDI_EXPORT int adl_getNumChips(struct ADL_MIDIPlayer *device) { if(device == NULL) return -2; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); return (int)play->m_setup.numChips; } ADLMIDI_EXPORT int adl_getNumChipsObtained(struct ADL_MIDIPlayer *device) { if(device == NULL) return -2; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); return (int)play->m_synth.m_numChips; } ADLMIDI_EXPORT int adl_setBank(ADL_MIDIPlayer *device, int bank) { #ifdef DISABLE_EMBEDDED_BANKS ADL_UNUSED(bank); MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); play->setErrorString("This build of libADLMIDI has no embedded banks. " "Please load banks by using adl_openBankFile() or " "adl_openBankData() functions instead of adl_setBank()."); return -1; #else const uint32_t NumBanks = static_cast(maxAdlBanks()); int32_t bankno = bank; if(bankno < 0) bankno = 0; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); if(static_cast(bankno) >= NumBanks) { char errBuf[150]; snprintf(errBuf, 150, "Embedded bank number may only be 0..%u!\n", static_cast(NumBanks - 1)); play->setErrorString(errBuf); return -1; } play->m_setup.bankId = static_cast(bankno); play->m_synth.setEmbeddedBank(play->m_setup.bankId); play->applySetup(); return 0; #endif } ADLMIDI_EXPORT int adl_getBanksCount() { #ifndef DISABLE_EMBEDDED_BANKS return maxAdlBanks(); #else return 0; #endif } ADLMIDI_EXPORT const char *const *adl_getBankNames() { #ifndef DISABLE_EMBEDDED_BANKS return banknames; #else return NULL; #endif } ADLMIDI_EXPORT int adl_reserveBanks(ADL_MIDIPlayer *device, unsigned banks) { if(!device) return -1; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); OPL3::BankMap &map = play->m_synth.m_insBanks; map.reserve(banks); return (int)map.capacity(); } ADLMIDI_EXPORT int adl_getBank(ADL_MIDIPlayer *device, const ADL_BankId *idp, int flags, ADL_Bank *bank) { if(!device || !idp || !bank) return -1; ADL_BankId id = *idp; if(id.lsb > 127 || id.msb > 127 || id.percussive > 1) return -1; size_t idnumber = ((id.msb << 8) | id.lsb | (id.percussive ? size_t(OPL3::PercussionTag) : 0)); MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); OPL3::BankMap &map = play->m_synth.m_insBanks; OPL3::BankMap::iterator it; if(!(flags & ADLMIDI_Bank_Create)) { it = map.find(idnumber); if(it == map.end()) return -1; } else { std::pair value; value.first = idnumber; memset(&value.second, 0, sizeof(value.second)); for (unsigned i = 0; i < 128; ++i) value.second.ins[i].flags = adlinsdata::Flag_NoSound; std::pair ir; if(flags & ADLMIDI_Bank_CreateRt) { ir = map.insert(value, OPL3::BankMap::do_not_expand_t()); if(ir.first == map.end()) return -1; } else ir = map.insert(value); it = ir.first; } it.to_ptrs(bank->pointer); return 0; } ADLMIDI_EXPORT int adl_getBankId(ADL_MIDIPlayer *device, const ADL_Bank *bank, ADL_BankId *id) { if(!device || !bank) return -1; OPL3::BankMap::iterator it = OPL3::BankMap::iterator::from_ptrs(bank->pointer); OPL3::BankMap::key_type idnumber = it->first; id->msb = (idnumber >> 8) & 127; id->lsb = idnumber & 127; id->percussive = (idnumber & OPL3::PercussionTag) ? 1 : 0; return 0; } ADLMIDI_EXPORT int adl_removeBank(ADL_MIDIPlayer *device, ADL_Bank *bank) { if(!device || !bank) return -1; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); OPL3::BankMap &map = play->m_synth.m_insBanks; OPL3::BankMap::iterator it = OPL3::BankMap::iterator::from_ptrs(bank->pointer); size_t size = map.size(); map.erase(it); return (map.size() != size) ? 0 : -1; } ADLMIDI_EXPORT int adl_getFirstBank(ADL_MIDIPlayer *device, ADL_Bank *bank) { if(!device) return -1; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); OPL3::BankMap &map = play->m_synth.m_insBanks; OPL3::BankMap::iterator it = map.begin(); if(it == map.end()) return -1; it.to_ptrs(bank->pointer); return 0; } ADLMIDI_EXPORT int adl_getNextBank(ADL_MIDIPlayer *device, ADL_Bank *bank) { if(!device) return -1; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); OPL3::BankMap &map = play->m_synth.m_insBanks; OPL3::BankMap::iterator it = OPL3::BankMap::iterator::from_ptrs(bank->pointer); if(++it == map.end()) return -1; it.to_ptrs(bank->pointer); return 0; } ADLMIDI_EXPORT int adl_getInstrument(ADL_MIDIPlayer *device, const ADL_Bank *bank, unsigned index, ADL_Instrument *ins) { if(!device || !bank || index > 127 || !ins) return -1; OPL3::BankMap::iterator it = OPL3::BankMap::iterator::from_ptrs(bank->pointer); cvt_FMIns_to_ADLI(*ins, it->second.ins[index]); ins->version = 0; return 0; } ADLMIDI_EXPORT int adl_setInstrument(ADL_MIDIPlayer *device, ADL_Bank *bank, unsigned index, const ADL_Instrument *ins) { if(!device || !bank || index > 127 || !ins) return -1; if(ins->version != 0) return -1; OPL3::BankMap::iterator it = OPL3::BankMap::iterator::from_ptrs(bank->pointer); cvt_ADLI_to_FMIns(it->second.ins[index], *ins); return 0; } ADLMIDI_EXPORT int adl_loadEmbeddedBank(struct ADL_MIDIPlayer *device, ADL_Bank *bank, int num) { if(!device) return -1; #ifdef DISABLE_EMBEDDED_BANKS ADL_UNUSED(bank); ADL_UNUSED(num); MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); play->setErrorString("This build of libADLMIDI has no embedded banks. " "Please load banks by using adl_openBankFile() or " "adl_openBankData() functions instead of adl_loadEmbeddedBank()."); return -1; #else if(num < 0 || num >= maxAdlBanks()) return -1; OPL3::BankMap::iterator it = OPL3::BankMap::iterator::from_ptrs(bank->pointer); size_t id = it->first; for (unsigned i = 0; i < 128; ++i) { size_t insno = i + ((id & OPL3::PercussionTag) ? 128 : 0); size_t adlmeta = ::banks[num][insno]; it->second.ins[i] = adlinsdata2::from_adldata(::adlins[adlmeta]); } return 0; #endif } ADLMIDI_EXPORT int adl_setNumFourOpsChn(ADL_MIDIPlayer *device, int ops4) { if(!device) return -1; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); if(ops4 > 6 * static_cast(play->m_setup.numChips)) { char errBuff[250]; snprintf(errBuff, 250, "number of four-op channels may only be 0..%u when %u OPL3 cards are used.\n", (6 * (play->m_setup.numChips)), play->m_setup.numChips); play->setErrorString(errBuff); return -1; } play->m_setup.numFourOps = ops4; if(!play->m_synth.setupLocked()) { if(play->m_setup.numFourOps < 0) adlCalculateFourOpChannels(play, true); else play->m_synth.m_numFourOps = static_cast(play->m_setup.numFourOps); play->m_synth.updateChannelCategories(); } return 0; } ADLMIDI_EXPORT int adl_getNumFourOpsChn(struct ADL_MIDIPlayer *device) { if(!device) return -2; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); return play->m_setup.numFourOps; } ADLMIDI_EXPORT int adl_getNumFourOpsChnObtained(struct ADL_MIDIPlayer *device) { if(!device) return -2; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); return (int)play->m_synth.m_numFourOps; } ADLMIDI_EXPORT void adl_setPercMode(ADL_MIDIPlayer *device, int percmod) { if(!device) return; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); play->m_setup.rhythmMode = percmod; if(!play->m_synth.setupLocked()) { play->m_synth.m_rhythmMode = play->m_setup.rhythmMode < 0 ? (play->m_synth.m_insBankSetup.adLibPercussions) : (play->m_setup.rhythmMode != 0); play->m_synth.updateChannelCategories(); } } ADLMIDI_EXPORT void adl_setHVibrato(ADL_MIDIPlayer *device, int hvibro) { if(!device) return; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); play->m_setup.deepVibratoMode = hvibro; if(!play->m_synth.setupLocked()) { play->m_synth.m_deepVibratoMode = play->m_setup.deepVibratoMode < 0 ? play->m_synth.m_insBankSetup.deepVibrato : (play->m_setup.deepVibratoMode != 0); play->m_synth.commitDeepFlags(); } } ADLMIDI_EXPORT int adl_getHVibrato(struct ADL_MIDIPlayer *device) { if(!device) return -1; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); return play->m_synth.m_deepVibratoMode; } ADLMIDI_EXPORT void adl_setHTremolo(ADL_MIDIPlayer *device, int htremo) { if(!device) return; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); play->m_setup.deepTremoloMode = htremo; if(!play->m_synth.setupLocked()) { play->m_synth.m_deepTremoloMode = play->m_setup.deepTremoloMode < 0 ? play->m_synth.m_insBankSetup.deepTremolo : (play->m_setup.deepTremoloMode != 0); play->m_synth.commitDeepFlags(); } } ADLMIDI_EXPORT int adl_getHTremolo(struct ADL_MIDIPlayer *device) { if(!device) return -1; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); return play->m_synth.m_deepTremoloMode; } ADLMIDI_EXPORT void adl_setScaleModulators(ADL_MIDIPlayer *device, int smod) { if(!device) return; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); play->m_setup.scaleModulators = smod; if(!play->m_synth.setupLocked()) { play->m_synth.m_scaleModulators = play->m_setup.scaleModulators < 0 ? play->m_synth.m_insBankSetup.scaleModulators : (play->m_setup.scaleModulators != 0); } } ADLMIDI_EXPORT void adl_setFullRangeBrightness(struct ADL_MIDIPlayer *device, int fr_brightness) { if(!device) return; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); play->m_setup.fullRangeBrightnessCC74 = (fr_brightness != 0); } ADLMIDI_EXPORT void adl_setLoopEnabled(ADL_MIDIPlayer *device, int loopEn) { if(!device) return; #ifndef ADLMIDI_DISABLE_MIDI_SEQUENCER MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); play->m_sequencer.setLoopEnabled(loopEn != 0); #else ADL_UNUSED(loopEn); #endif } ADLMIDI_EXPORT void adl_setSoftPanEnabled(ADL_MIDIPlayer *device, int softPanEn) { if(!device) return; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); play->m_synth.m_softPanning = (softPanEn != 0); } /* !!!DEPRECATED!!! */ ADLMIDI_EXPORT void adl_setLogarithmicVolumes(struct ADL_MIDIPlayer *device, int logvol) { if(!device) return; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); play->m_setup.logarithmicVolumes = (logvol != 0); if(!play->m_synth.setupLocked()) { if(play->m_setup.logarithmicVolumes) play->m_synth.setVolumeScaleModel(ADLMIDI_VolumeModel_NativeOPL3); else play->m_synth.setVolumeScaleModel(static_cast(play->m_synth.m_volumeScale)); } } ADLMIDI_EXPORT void adl_setVolumeRangeModel(struct ADL_MIDIPlayer *device, int volumeModel) { if(!device) return; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); play->m_setup.volumeScaleModel = volumeModel; if(!play->m_synth.setupLocked()) { if(play->m_setup.volumeScaleModel == ADLMIDI_VolumeModel_AUTO)//Use bank default volume model play->m_synth.m_volumeScale = (OPL3::VolumesScale)play->m_synth.m_insBankSetup.volumeModel; else play->m_synth.setVolumeScaleModel(static_cast(volumeModel)); } } ADLMIDI_EXPORT int adl_getVolumeRangeModel(struct ADL_MIDIPlayer *device) { if(!device) return -1; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); return play->m_synth.getVolumeScaleModel(); } ADLMIDI_EXPORT int adl_openBankFile(struct ADL_MIDIPlayer *device, const char *filePath) { if(device) { MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); play->m_setup.tick_skip_samples_delay = 0; if(!play->LoadBank(filePath)) { std::string err = play->getErrorString(); if(err.empty()) play->setErrorString("ADL MIDI: Can't load file"); return -1; } else return adlCalculateFourOpChannels(play, true); } ADLMIDI_ErrorString = "Can't load file: ADLMIDI is not initialized"; return -1; } ADLMIDI_EXPORT int adl_openBankData(struct ADL_MIDIPlayer *device, const void *mem, unsigned long size) { if(device) { MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); play->m_setup.tick_skip_samples_delay = 0; if(!play->LoadBank(mem, static_cast(size))) { std::string err = play->getErrorString(); if(err.empty()) play->setErrorString("ADL MIDI: Can't load data from memory"); return -1; } else return adlCalculateFourOpChannels(play, true); } ADLMIDI_ErrorString = "Can't load file: ADL MIDI is not initialized"; return -1; } ADLMIDI_EXPORT int adl_openFile(ADL_MIDIPlayer *device, const char *filePath) { if(device) { MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); #ifndef ADLMIDI_DISABLE_MIDI_SEQUENCER play->m_setup.tick_skip_samples_delay = 0; if(!play->LoadMIDI(filePath)) { std::string err = play->getErrorString(); if(err.empty()) play->setErrorString("ADL MIDI: Can't load file"); return -1; } else return 0; #else ADL_UNUSED(filePath); play->setErrorString("ADLMIDI: MIDI Sequencer is not supported in this build of library!"); return -1; #endif //ADLMIDI_DISABLE_MIDI_SEQUENCER } ADLMIDI_ErrorString = "Can't load file: ADL MIDI is not initialized"; return -1; } ADLMIDI_EXPORT int adl_openData(ADL_MIDIPlayer *device, const void *mem, unsigned long size) { if(device) { MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); #ifndef ADLMIDI_DISABLE_MIDI_SEQUENCER play->m_setup.tick_skip_samples_delay = 0; if(!play->LoadMIDI(mem, static_cast(size))) { std::string err = play->getErrorString(); if(err.empty()) play->setErrorString("ADL MIDI: Can't load data from memory"); return -1; } else return 0; #else ADL_UNUSED(mem); ADL_UNUSED(size); play->setErrorString("ADLMIDI: MIDI Sequencer is not supported in this build of library!"); return -1; #endif //ADLMIDI_DISABLE_MIDI_SEQUENCER } ADLMIDI_ErrorString = "Can't load file: ADL MIDI is not initialized"; return -1; } ADLMIDI_EXPORT const char *adl_emulatorName() { return ""; } ADLMIDI_EXPORT const char *adl_chipEmulatorName(struct ADL_MIDIPlayer *device) { if(device) { #ifndef ADLMIDI_HW_OPL MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); if(!play->m_synth.m_chips.empty()) return play->m_synth.m_chips[0]->emulatorName(); #else return "Hardware OPL3 chip on 0x330"; #endif } return "Unknown"; } ADLMIDI_EXPORT int adl_switchEmulator(struct ADL_MIDIPlayer *device, int emulator) { if(device) { MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); if(adl_isEmulatorAvailable(emulator)) { play->m_setup.emulator = emulator; play->partialReset(); return 0; } play->setErrorString("OPL3 MIDI: Unknown emulation core!"); } return -1; } ADLMIDI_EXPORT int adl_setRunAtPcmRate(ADL_MIDIPlayer *device, int enabled) { if(device) { MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); play->m_setup.runAtPcmRate = (enabled != 0); if(!play->m_synth.setupLocked()) play->partialReset(); return 0; } return -1; } ADLMIDI_EXPORT const char *adl_linkedLibraryVersion() { #if !defined(ADLMIDI_ENABLE_HQ_RESAMPLER) return ADLMIDI_VERSION; #else return ADLMIDI_VERSION " (HQ)"; #endif } ADLMIDI_EXPORT const ADL_Version *adl_linkedVersion() { return &adl_version; } ADLMIDI_EXPORT const char *adl_errorString() { return ADLMIDI_ErrorString.c_str(); } ADLMIDI_EXPORT const char *adl_errorInfo(struct ADL_MIDIPlayer *device) { if(!device) return adl_errorString(); MidiPlayer *play = GET_MIDI_PLAYER(device); if(!play) return adl_errorString(); return play->getErrorString().c_str(); } ADLMIDI_EXPORT void adl_reset(struct ADL_MIDIPlayer *device) { if(!device) return; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); play->partialReset(); play->resetMIDI(); } ADLMIDI_EXPORT double adl_totalTimeLength(struct ADL_MIDIPlayer *device) { #ifndef ADLMIDI_DISABLE_MIDI_SEQUENCER if(!device) return -1.0; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); return play->m_sequencer.timeLength(); #else ADL_UNUSED(device); return -1.0; #endif } ADLMIDI_EXPORT double adl_loopStartTime(struct ADL_MIDIPlayer *device) { #ifndef ADLMIDI_DISABLE_MIDI_SEQUENCER if(!device) return -1.0; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); return play->m_sequencer.getLoopStart(); #else ADL_UNUSED(device); return -1.0; #endif } ADLMIDI_EXPORT double adl_loopEndTime(struct ADL_MIDIPlayer *device) { #ifndef ADLMIDI_DISABLE_MIDI_SEQUENCER if(!device) return -1.0; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); return play->m_sequencer.getLoopEnd(); #else ADL_UNUSED(device); return -1.0; #endif } ADLMIDI_EXPORT double adl_positionTell(struct ADL_MIDIPlayer *device) { #ifndef ADLMIDI_DISABLE_MIDI_SEQUENCER if(!device) return -1.0; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); return play->m_sequencer.tell(); #else ADL_UNUSED(device); return -1.0; #endif } ADLMIDI_EXPORT void adl_positionSeek(struct ADL_MIDIPlayer *device, double seconds) { #ifndef ADLMIDI_DISABLE_MIDI_SEQUENCER if(seconds < 0.0) return;//Seeking negative position is forbidden! :-P if(!device) return; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); play->realTime_panic(); play->m_setup.delay = play->m_sequencer.seek(seconds, play->m_setup.mindelay); play->m_setup.carry = 0.0; #else ADL_UNUSED(device); ADL_UNUSED(seconds); #endif } ADLMIDI_EXPORT void adl_positionRewind(struct ADL_MIDIPlayer *device) { #ifndef ADLMIDI_DISABLE_MIDI_SEQUENCER if(!device) return; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); play->realTime_panic(); play->m_sequencer.rewind(); #else ADL_UNUSED(device); #endif } ADLMIDI_EXPORT void adl_setTempo(struct ADL_MIDIPlayer *device, double tempo) { #ifndef ADLMIDI_DISABLE_MIDI_SEQUENCER if(!device || (tempo <= 0.0)) return; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); play->m_sequencer.setTempo(tempo); #else ADL_UNUSED(device); ADL_UNUSED(tempo); #endif } ADLMIDI_EXPORT int adl_describeChannels(struct ADL_MIDIPlayer *device, char *str, char *attr, size_t size) { if(!device) return -1; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); play->describeChannels(str, attr, size); return 0; } ADLMIDI_EXPORT const char *adl_metaMusicTitle(struct ADL_MIDIPlayer *device) { #ifndef ADLMIDI_DISABLE_MIDI_SEQUENCER if(!device) return ""; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); return play->m_sequencer.getMusicTitle().c_str(); #else ADL_UNUSED(device); return ""; #endif } ADLMIDI_EXPORT const char *adl_metaMusicCopyright(struct ADL_MIDIPlayer *device) { #ifndef ADLMIDI_DISABLE_MIDI_SEQUENCER if(!device) return ""; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); return play->m_sequencer.getMusicCopyright().c_str(); #else ADL_UNUSED(device); return ""; #endif } ADLMIDI_EXPORT size_t adl_metaTrackTitleCount(struct ADL_MIDIPlayer *device) { #ifndef ADLMIDI_DISABLE_MIDI_SEQUENCER if(!device) return 0; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); return play->m_sequencer.getTrackTitles().size(); #else ADL_UNUSED(device); return 0; #endif } ADLMIDI_EXPORT const char *adl_metaTrackTitle(struct ADL_MIDIPlayer *device, size_t index) { #ifndef ADLMIDI_DISABLE_MIDI_SEQUENCER if(!device) return ""; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); const std::vector &titles = play->m_sequencer.getTrackTitles(); if(index >= titles.size()) return "INVALID"; return titles[index].c_str(); #else ADL_UNUSED(device); ADL_UNUSED(index); return "NOT SUPPORTED"; #endif } ADLMIDI_EXPORT size_t adl_metaMarkerCount(struct ADL_MIDIPlayer *device) { #ifndef ADLMIDI_DISABLE_MIDI_SEQUENCER if(!device) return 0; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); return play->m_sequencer.getMarkers().size(); #else ADL_UNUSED(device); return 0; #endif } ADLMIDI_EXPORT Adl_MarkerEntry adl_metaMarker(struct ADL_MIDIPlayer *device, size_t index) { struct Adl_MarkerEntry marker; #ifndef ADLMIDI_DISABLE_MIDI_SEQUENCER if(!device) { marker.label = "INVALID"; marker.pos_time = 0.0; marker.pos_ticks = 0; return marker; } MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); const std::vector &markers = play->m_sequencer.getMarkers(); if(index >= markers.size()) { marker.label = "INVALID"; marker.pos_time = 0.0; marker.pos_ticks = 0; return marker; } const MidiSequencer::MIDI_MarkerEntry &mk = markers[index]; marker.label = mk.label.c_str(); marker.pos_time = mk.pos_time; marker.pos_ticks = (unsigned long)mk.pos_ticks; #else ADL_UNUSED(device); ADL_UNUSED(index); marker.label = "NOT SUPPORTED"; marker.pos_time = 0.0; marker.pos_ticks = 0; #endif return marker; } ADLMIDI_EXPORT void adl_setRawEventHook(struct ADL_MIDIPlayer *device, ADL_RawEventHook rawEventHook, void *userData) { #ifndef ADLMIDI_DISABLE_MIDI_SEQUENCER if(!device) return; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); play->m_sequencerInterface.onEvent = rawEventHook; play->m_sequencerInterface.onEvent_userData = userData; #else ADL_UNUSED(device); ADL_UNUSED(rawEventHook); ADL_UNUSED(userData); #endif } /* Set note hook */ ADLMIDI_EXPORT void adl_setNoteHook(struct ADL_MIDIPlayer *device, ADL_NoteHook noteHook, void *userData) { if(!device) return; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); play->hooks.onNote = noteHook; play->hooks.onNote_userData = userData; } /* Set debug message hook */ ADLMIDI_EXPORT void adl_setDebugMessageHook(struct ADL_MIDIPlayer *device, ADL_DebugMessageHook debugMessageHook, void *userData) { if(!device) return; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); play->hooks.onDebugMessage = debugMessageHook; play->hooks.onDebugMessage_userData = userData; #ifndef ADLMIDI_DISABLE_MIDI_SEQUENCER play->m_sequencerInterface.onDebugMessage = debugMessageHook; play->m_sequencerInterface.onDebugMessage_userData = userData; #endif } #ifndef ADLMIDI_HW_OPL # ifndef __WATCOMC__ template static void CopySamplesRaw(ADL_UInt8 *dstLeft, ADL_UInt8 *dstRight, const int32_t *src, size_t frameCount, unsigned sampleOffset) { for(size_t i = 0; i < frameCount; ++i) { *(Dst *)(dstLeft + (i * sampleOffset)) = src[2 * i]; *(Dst *)(dstRight + (i * sampleOffset)) = src[(2 * i) + 1]; } } template static void CopySamplesTransformed(ADL_UInt8 *dstLeft, ADL_UInt8 *dstRight, const int32_t *src, size_t frameCount, unsigned sampleOffset, Ret(&transform)(int32_t)) { for(size_t i = 0; i < frameCount; ++i) { *(Dst *)(dstLeft + (i * sampleOffset)) = static_cast(transform(src[2 * i])); *(Dst *)(dstRight + (i * sampleOffset)) = static_cast(transform(src[(2 * i) + 1])); } } static int SendStereoAudio(int samples_requested, ssize_t in_size, int32_t *_in, ssize_t out_pos, ADL_UInt8 *left, ADL_UInt8 *right, const ADLMIDI_AudioFormat *format) { if(!in_size) return 0; size_t outputOffset = static_cast(out_pos); size_t inSamples = static_cast(in_size * 2); size_t maxSamples = static_cast(samples_requested) - outputOffset; size_t toCopy = std::min(maxSamples, inSamples); ADLMIDI_SampleType sampleType = format->type; const unsigned containerSize = format->containerSize; const unsigned sampleOffset = format->sampleOffset; left += (outputOffset / 2) * sampleOffset; right += (outputOffset / 2) * sampleOffset; typedef int32_t(&pfnConvert)(int32_t); typedef float(&ffnConvert)(int32_t); typedef double(&dfnConvert)(int32_t); switch(sampleType) { case ADLMIDI_SampleType_S8: case ADLMIDI_SampleType_U8: { pfnConvert cvt = (sampleType == ADLMIDI_SampleType_S8) ? adl_cvtS8 : adl_cvtU8; switch(containerSize) { case sizeof(int8_t): CopySamplesTransformed(left, right, _in, toCopy / 2, sampleOffset, cvt); break; case sizeof(int16_t): CopySamplesTransformed(left, right, _in, toCopy / 2, sampleOffset, cvt); break; case sizeof(int32_t): CopySamplesTransformed(left, right, _in, toCopy / 2, sampleOffset, cvt); break; default: return -1; } break; } case ADLMIDI_SampleType_S16: case ADLMIDI_SampleType_U16: { pfnConvert cvt = (sampleType == ADLMIDI_SampleType_S16) ? adl_cvtS16 : adl_cvtU16; switch(containerSize) { case sizeof(int16_t): CopySamplesTransformed(left, right, _in, toCopy / 2, sampleOffset, cvt); break; case sizeof(int32_t): CopySamplesRaw(left, right, _in, toCopy / 2, sampleOffset); break; default: return -1; } break; } case ADLMIDI_SampleType_S24: case ADLMIDI_SampleType_U24: { pfnConvert cvt = (sampleType == ADLMIDI_SampleType_S24) ? adl_cvtS24 : adl_cvtU24; switch(containerSize) { case sizeof(int32_t): CopySamplesTransformed(left, right, _in, toCopy / 2, sampleOffset, cvt); break; default: return -1; } break; } case ADLMIDI_SampleType_S32: case ADLMIDI_SampleType_U32: { pfnConvert cvt = (sampleType == ADLMIDI_SampleType_S32) ? adl_cvtS32 : adl_cvtU32; switch(containerSize) { case sizeof(int32_t): CopySamplesTransformed(left, right, _in, toCopy / 2, sampleOffset, cvt); break; default: return -1; } break; } case ADLMIDI_SampleType_F32: { if(containerSize != sizeof(float)) return -1; ffnConvert cvt = adl_cvtReal; CopySamplesTransformed(left, right, _in, toCopy / 2, sampleOffset, cvt); break; } case ADLMIDI_SampleType_F64: { if(containerSize != sizeof(double)) return -1; dfnConvert cvt = adl_cvtReal; CopySamplesTransformed(left, right, _in, toCopy / 2, sampleOffset, cvt); break; } default: return -1; } return 0; } # else // __WATCOMC__ /* Workaround for OpenWattcom where templates are declared above are causing compiler to be crashed */ static void CopySamplesTransformed(ADL_UInt8 *dstLeft, ADL_UInt8 *dstRight, const int32_t *src, size_t frameCount, unsigned sampleOffset, int32_t(&transform)(int32_t)) { for(size_t i = 0; i < frameCount; ++i) { *(int16_t *)(dstLeft + (i * sampleOffset)) = (int16_t)transform(src[2 * i]); *(int16_t *)(dstRight + (i * sampleOffset)) = (int16_t)transform(src[(2 * i) + 1]); } } static int SendStereoAudio(int samples_requested, ssize_t in_size, int32_t *_in, ssize_t out_pos, ADL_UInt8 *left, ADL_UInt8 *right, const ADLMIDI_AudioFormat *format) { if(!in_size) return 0; size_t outputOffset = static_cast(out_pos); size_t inSamples = static_cast(in_size * 2); size_t maxSamples = static_cast(samples_requested) - outputOffset; size_t toCopy = std::min(maxSamples, inSamples); ADLMIDI_SampleType sampleType = format->type; const unsigned containerSize = format->containerSize; const unsigned sampleOffset = format->sampleOffset; left += (outputOffset / 2) * sampleOffset; right += (outputOffset / 2) * sampleOffset; if(sampleType == ADLMIDI_SampleType_U16) { switch(containerSize) { case sizeof(int16_t): CopySamplesTransformed(left, right, _in, toCopy / 2, sampleOffset, adl_cvtS16); break; default: return -1; } } else return -1; return 0; } # endif // __WATCOM__ #endif // ADLMIDI_HW_OPL ADLMIDI_EXPORT int adl_play(struct ADL_MIDIPlayer *device, int sampleCount, short *out) { return adl_playFormat(device, sampleCount, (ADL_UInt8 *)out, (ADL_UInt8 *)(out + 1), &adl_DefaultAudioFormat); } ADLMIDI_EXPORT int adl_playFormat(ADL_MIDIPlayer *device, int sampleCount, ADL_UInt8 *out_left, ADL_UInt8 *out_right, const ADLMIDI_AudioFormat *format) { #if defined(ADLMIDI_DISABLE_MIDI_SEQUENCER) || defined(ADLMIDI_HW_OPL) ADL_UNUSED(device); ADL_UNUSED(sampleCount); ADL_UNUSED(out_left); ADL_UNUSED(out_right); ADL_UNUSED(format); return 0; #endif #if !defined(ADLMIDI_DISABLE_MIDI_SEQUENCER) && !defined(ADLMIDI_HW_OPL) sampleCount -= sampleCount % 2; //Avoid even sample requests if(sampleCount < 0) return 0; if(!device) return 0; MidiPlayer *player = GET_MIDI_PLAYER(device); assert(player); MidiPlayer::Setup &setup = player->m_setup; ssize_t gotten_len = 0; ssize_t n_periodCountStereo = 512; //ssize_t n_periodCountPhys = n_periodCountStereo * 2; int left = sampleCount; bool hasSkipped = setup.tick_skip_samples_delay > 0; while(left > 0) { {//... const double eat_delay = setup.delay < setup.maxdelay ? setup.delay : setup.maxdelay; if(hasSkipped) { size_t samples = setup.tick_skip_samples_delay > sampleCount ? sampleCount : setup.tick_skip_samples_delay; n_periodCountStereo = samples / 2; } else { setup.delay -= eat_delay; setup.carry += double(setup.PCM_RATE) * eat_delay; n_periodCountStereo = static_cast(setup.carry); setup.carry -= double(n_periodCountStereo); } //if(setup.SkipForward > 0) // setup.SkipForward -= 1; //else { if((player->m_sequencer.positionAtEnd()) && (setup.delay <= 0.0)) break;//Stop to fetch samples at reaching the song end with disabled loop ssize_t leftSamples = left / 2; if(n_periodCountStereo > leftSamples) { setup.tick_skip_samples_delay = (n_periodCountStereo - leftSamples) * 2; n_periodCountStereo = leftSamples; } //! Count of stereo samples ssize_t in_generatedStereo = (n_periodCountStereo > 512) ? 512 : n_periodCountStereo; //! Total count of samples ssize_t in_generatedPhys = in_generatedStereo * 2; //! Unsigned total sample count //fill buffer with zeros int32_t *out_buf = player->m_outBuf; std::memset(out_buf, 0, static_cast(in_generatedPhys) * sizeof(out_buf[0])); unsigned int chips = player->m_synth.m_numChips; if(chips == 1) { player->m_synth.m_chips[0]->generate32(out_buf, (size_t)in_generatedStereo); } else if(n_periodCountStereo > 0) { /* Generate data from every chip and mix result */ for(size_t card = 0; card < chips; ++card) player->m_synth.m_chips[card]->generateAndMix32(out_buf, (size_t)in_generatedStereo); } /* Process it */ if(SendStereoAudio(sampleCount, in_generatedStereo, out_buf, gotten_len, out_left, out_right, format) == -1) return 0; left -= (int)in_generatedPhys; gotten_len += (in_generatedPhys) /* - setup.stored_samples*/; } if(hasSkipped) { setup.tick_skip_samples_delay -= n_periodCountStereo * 2; hasSkipped = setup.tick_skip_samples_delay > 0; } else setup.delay = player->Tick(eat_delay, setup.mindelay); }//... } return static_cast(gotten_len); #endif //ADLMIDI_DISABLE_MIDI_SEQUENCER } ADLMIDI_EXPORT int adl_generate(struct ADL_MIDIPlayer *device, int sampleCount, short *out) { return adl_generateFormat(device, sampleCount, (ADL_UInt8 *)out, (ADL_UInt8 *)(out + 1), &adl_DefaultAudioFormat); } ADLMIDI_EXPORT int adl_generateFormat(struct ADL_MIDIPlayer *device, int sampleCount, ADL_UInt8 *out_left, ADL_UInt8 *out_right, const ADLMIDI_AudioFormat *format) { #ifdef ADLMIDI_HW_OPL ADL_UNUSED(device); ADL_UNUSED(sampleCount); ADL_UNUSED(out_left); ADL_UNUSED(out_right); ADL_UNUSED(format); return 0; #else sampleCount -= sampleCount % 2; //Avoid even sample requests if(sampleCount < 0) return 0; if(!device) return 0; MidiPlayer *player = GET_MIDI_PLAYER(device); assert(player); MidiPlayer::Setup &setup = player->m_setup; ssize_t gotten_len = 0; ssize_t n_periodCountStereo = 512; int left = sampleCount; double delay = double(sampleCount) / double(setup.PCM_RATE); while(left > 0) { {//... const double eat_delay = delay < setup.maxdelay ? delay : setup.maxdelay; delay -= eat_delay; setup.carry += double(setup.PCM_RATE) * eat_delay; n_periodCountStereo = static_cast(setup.carry); setup.carry -= double(n_periodCountStereo); { ssize_t leftSamples = left / 2; if(n_periodCountStereo > leftSamples) n_periodCountStereo = leftSamples; //! Count of stereo samples ssize_t in_generatedStereo = (n_periodCountStereo > 512) ? 512 : n_periodCountStereo; //! Total count of samples ssize_t in_generatedPhys = in_generatedStereo * 2; //! Unsigned total sample count //fill buffer with zeros int32_t *out_buf = player->m_outBuf; std::memset(out_buf, 0, static_cast(in_generatedPhys) * sizeof(out_buf[0])); unsigned int chips = player->m_synth.m_numChips; if(chips == 1) player->m_synth.m_chips[0]->generate32(out_buf, (size_t)in_generatedStereo); else if(n_periodCountStereo > 0) { /* Generate data from every chip and mix result */ for(unsigned card = 0; card < chips; ++card) player->m_synth.m_chips[card]->generateAndMix32(out_buf, (size_t)in_generatedStereo); } /* Process it */ if(SendStereoAudio(sampleCount, in_generatedStereo, out_buf, gotten_len, out_left, out_right, format) == -1) return 0; left -= (int)in_generatedPhys; gotten_len += (in_generatedPhys) /* - setup.stored_samples*/; } player->TickIterators(eat_delay); }//... } return static_cast(gotten_len); #endif } ADLMIDI_EXPORT double adl_tickEvents(struct ADL_MIDIPlayer *device, double seconds, double granulality) { #ifndef ADLMIDI_DISABLE_MIDI_SEQUENCER if(!device) return -1.0; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); return play->Tick(seconds, granulality); #else ADL_UNUSED(device); ADL_UNUSED(seconds); ADL_UNUSED(granulality); return -1.0; #endif } ADLMIDI_EXPORT int adl_atEnd(struct ADL_MIDIPlayer *device) { #ifndef ADLMIDI_DISABLE_MIDI_SEQUENCER if(!device) return 1; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); return (int)play->m_sequencer.positionAtEnd(); #else ADL_UNUSED(device); return 1; #endif } ADLMIDI_EXPORT size_t adl_trackCount(struct ADL_MIDIPlayer *device) { #ifndef ADLMIDI_DISABLE_MIDI_SEQUENCER if(!device) return 0; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); return play->m_sequencer.getTrackCount(); #else ADL_UNUSED(device); return 0; #endif } ADLMIDI_EXPORT int adl_setTrackOptions(struct ADL_MIDIPlayer *device, size_t trackNumber, unsigned trackOptions) { #ifndef ADLMIDI_DISABLE_MIDI_SEQUENCER if(!device) return -1; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); MidiSequencer &seq = play->m_sequencer; unsigned enableFlag = trackOptions & 3; trackOptions &= ~3u; // handle on/off/solo switch(enableFlag) { default: break; case ADLMIDI_TrackOption_On: case ADLMIDI_TrackOption_Off: if(!seq.setTrackEnabled(trackNumber, enableFlag == ADLMIDI_TrackOption_On)) return -1; break; case ADLMIDI_TrackOption_Solo: seq.setSoloTrack(trackNumber); break; } // handle others... if(trackOptions != 0) return -1; return 0; #else ADL_UNUSED(device); ADL_UNUSED(trackNumber); ADL_UNUSED(trackOptions); return -1; #endif } ADLMIDI_EXPORT int adl_setTriggerHandler(struct ADL_MIDIPlayer *device, ADL_TriggerHandler handler, void *userData) { #ifndef ADLMIDI_DISABLE_MIDI_SEQUENCER if(!device) return -1; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); MidiSequencer &seq = play->m_sequencer; seq.setTriggerHandler(handler, userData); return 0; #else ADL_UNUSED(device); ADL_UNUSED(handler); ADL_UNUSED(userData); return -1; #endif } ADLMIDI_EXPORT void adl_panic(struct ADL_MIDIPlayer *device) { if(!device) return; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); play->realTime_panic(); } ADLMIDI_EXPORT void adl_rt_resetState(struct ADL_MIDIPlayer *device) { if(!device) return; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); play->realTime_ResetState(); } ADLMIDI_EXPORT int adl_rt_noteOn(struct ADL_MIDIPlayer *device, ADL_UInt8 channel, ADL_UInt8 note, ADL_UInt8 velocity) { if(!device) return 0; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); return (int)play->realTime_NoteOn(channel, note, velocity); } ADLMIDI_EXPORT void adl_rt_noteOff(struct ADL_MIDIPlayer *device, ADL_UInt8 channel, ADL_UInt8 note) { if(!device) return; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); play->realTime_NoteOff(channel, note); } ADLMIDI_EXPORT void adl_rt_noteAfterTouch(struct ADL_MIDIPlayer *device, ADL_UInt8 channel, ADL_UInt8 note, ADL_UInt8 atVal) { if(!device) return; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); play->realTime_NoteAfterTouch(channel, note, atVal); } ADLMIDI_EXPORT void adl_rt_channelAfterTouch(struct ADL_MIDIPlayer *device, ADL_UInt8 channel, ADL_UInt8 atVal) { if(!device) return; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); play->realTime_ChannelAfterTouch(channel, atVal); } ADLMIDI_EXPORT void adl_rt_controllerChange(struct ADL_MIDIPlayer *device, ADL_UInt8 channel, ADL_UInt8 type, ADL_UInt8 value) { if(!device) return; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); play->realTime_Controller(channel, type, value); } ADLMIDI_EXPORT void adl_rt_patchChange(struct ADL_MIDIPlayer *device, ADL_UInt8 channel, ADL_UInt8 patch) { if(!device) return; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); play->realTime_PatchChange(channel, patch); } ADLMIDI_EXPORT void adl_rt_pitchBend(struct ADL_MIDIPlayer *device, ADL_UInt8 channel, ADL_UInt16 pitch) { if(!device) return; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); play->realTime_PitchBend(channel, pitch); } ADLMIDI_EXPORT void adl_rt_pitchBendML(struct ADL_MIDIPlayer *device, ADL_UInt8 channel, ADL_UInt8 msb, ADL_UInt8 lsb) { if(!device) return; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); play->realTime_PitchBend(channel, msb, lsb); } ADLMIDI_EXPORT void adl_rt_bankChangeLSB(struct ADL_MIDIPlayer *device, ADL_UInt8 channel, ADL_UInt8 lsb) { if(!device) return; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); play->realTime_BankChangeLSB(channel, lsb); } ADLMIDI_EXPORT void adl_rt_bankChangeMSB(struct ADL_MIDIPlayer *device, ADL_UInt8 channel, ADL_UInt8 msb) { if(!device) return; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); play->realTime_BankChangeMSB(channel, msb); } ADLMIDI_EXPORT void adl_rt_bankChange(struct ADL_MIDIPlayer *device, ADL_UInt8 channel, ADL_SInt16 bank) { if(!device) return; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); play->realTime_BankChange(channel, (uint16_t)bank); } ADLMIDI_EXPORT int adl_rt_systemExclusive(struct ADL_MIDIPlayer *device, const ADL_UInt8 *msg, size_t size) { if(!device) return -1; MidiPlayer *play = GET_MIDI_PLAYER(device); assert(play); return play->realTime_SysEx(msg, size); }