/* Copyright (C) 2003, 2004, 2005, 2006, 2008, 2009 Dean Beeler, Jerome Fisher * Copyright (C) 2011 Dean Beeler, Jerome Fisher, Sergey V. Mikayev * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU Lesser General Public License as published by * the Free Software Foundation, either version 2.1 of the License, or * (at your option) 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 Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public License * along with this program. If not, see . */ //#include //#include //#include //#include #define FORBIDDEN_SYMBOL_EXCEPTION_printf #define FORBIDDEN_SYMBOL_EXCEPTION_vprintf #include "mt32emu.h" #include "mmath.h" #include "PartialManager.h" #if MT32EMU_USE_AREVERBMODEL == 1 #include "AReverbModel.h" #else #include "FreeverbModel.h" #endif #include "DelayReverb.h" namespace MT32Emu { const ControlROMMap ControlROMMaps[7] = { // ID IDc IDbytes PCMmap PCMc tmbrA tmbrAO, tmbrAC tmbrB tmbrBO, tmbrBC tmbrR trC rhythm rhyC rsrv panpot prog rhyMax patMax sysMax timMax {0x4014, 22, "\000 ver1.04 14 July 87 ", 0x3000, 128, 0x8000, 0x0000, false, 0xC000, 0x4000, false, 0x3200, 30, 0x73A6, 85, 0x57C7, 0x57E2, 0x57D0, 0x5252, 0x525E, 0x526E, 0x520A}, {0x4014, 22, "\000 ver1.05 06 Aug, 87 ", 0x3000, 128, 0x8000, 0x0000, false, 0xC000, 0x4000, false, 0x3200, 30, 0x7414, 85, 0x57C7, 0x57E2, 0x57D0, 0x5252, 0x525E, 0x526E, 0x520A}, {0x4014, 22, "\000 ver1.06 31 Aug, 87 ", 0x3000, 128, 0x8000, 0x0000, false, 0xC000, 0x4000, false, 0x3200, 30, 0x7414, 85, 0x57D9, 0x57F4, 0x57E2, 0x5264, 0x5270, 0x5280, 0x521C}, {0x4010, 22, "\000 ver1.07 10 Oct, 87 ", 0x3000, 128, 0x8000, 0x0000, false, 0xC000, 0x4000, false, 0x3200, 30, 0x73fe, 85, 0x57B1, 0x57CC, 0x57BA, 0x523C, 0x5248, 0x5258, 0x51F4}, // MT-32 revision 1 {0x4010, 22, "\000verX.XX 30 Sep, 88 ", 0x3000, 128, 0x8000, 0x0000, false, 0xC000, 0x4000, false, 0x3200, 30, 0x741C, 85, 0x57E5, 0x5800, 0x57EE, 0x5270, 0x527C, 0x528C, 0x5228}, // MT-32 Blue Ridge mod {0x2205, 22, "\000CM32/LAPC1.00 890404", 0x8100, 256, 0x8000, 0x8000, false, 0x8080, 0x8000, false, 0x8500, 64, 0x8580, 85, 0x4F65, 0x4F80, 0x4F6E, 0x48A1, 0x48A5, 0x48BE, 0x48D5}, {0x2205, 22, "\000CM32/LAPC1.02 891205", 0x8100, 256, 0x8000, 0x8000, true, 0x8080, 0x8000, true, 0x8500, 64, 0x8580, 85, 0x4F93, 0x4FAE, 0x4F9C, 0x48CB, 0x48CF, 0x48E8, 0x48FF} // CM-32L // (Note that all but CM-32L ROM actually have 86 entries for rhythmTemp) }; static inline Bit16s *streamOffset(Bit16s *stream, Bit32u pos) { return stream == NULL ? NULL : stream + pos; } static inline void clearIfNonNull(Bit16s *stream, Bit32u len) { if (stream != NULL) { memset(stream, 0, len * sizeof(Bit16s)); } } static inline void mix(float *target, const float *stream, Bit32u len) { while (len--) { *target += *stream; stream++; target++; } } static inline void clearFloats(float *leftBuf, float *rightBuf, Bit32u len) { // FIXME: Use memset() where compatibility is guaranteed (if this turns out to be a win) while (len--) { *leftBuf++ = 0.0f; *rightBuf++ = 0.0f; } } static inline Bit16s clipBit16s(Bit32s a) { // Clamp values above 32767 to 32767, and values below -32768 to -32768 if ((a + 32768) & ~65535) { return (a >> 31) ^ 32767; } return a; } static void floatToBit16s_nice(Bit16s *target, const float *source, Bit32u len, float outputGain) { float gain = outputGain * 16384.0f; while (len--) { // Since we're not shooting for accuracy here, don't worry about the rounding mode. *target = clipBit16s((Bit32s)(*source * gain)); source++; target++; } } static void floatToBit16s_pure(Bit16s *target, const float *source, Bit32u len, float /*outputGain*/) { while (len--) { *target = clipBit16s((Bit32s)floor(*source * 8192.0f)); source++; target++; } } static void floatToBit16s_reverb(Bit16s *target, const float *source, Bit32u len, float outputGain) { float gain = outputGain * 8192.0f; while (len--) { *target = clipBit16s((Bit32s)floor(*source * gain)); source++; target++; } } static void floatToBit16s_generation1(Bit16s *target, const float *source, Bit32u len, float outputGain) { float gain = outputGain * 8192.0f; while (len--) { *target = clipBit16s((Bit32s)floor(*source * gain)); *target = (*target & 0x8000) | ((*target << 1) & 0x7FFE); source++; target++; } } static void floatToBit16s_generation2(Bit16s *target, const float *source, Bit32u len, float outputGain) { float gain = outputGain * 8192.0f; while (len--) { *target = clipBit16s((Bit32s)floor(*source * gain)); *target = (*target & 0x8000) | ((*target << 1) & 0x7FFE) | ((*target >> 14) & 0x0001); source++; target++; } } Bit8u Synth::calcSysexChecksum(const Bit8u *data, Bit32u len, Bit8u checksum) { for (unsigned int i = 0; i < len; i++) { checksum = checksum + data[i]; } checksum = checksum & 0x7f; if (checksum) { checksum = 0x80 - checksum; } return checksum; } Synth::Synth() { isOpen = false; reverbEnabled = true; reverbOverridden = false; #if MT32EMU_USE_AREVERBMODEL == 1 reverbModels[0] = new AReverbModel(&AReverbModel::REVERB_MODE_0_SETTINGS); reverbModels[1] = new AReverbModel(&AReverbModel::REVERB_MODE_1_SETTINGS); reverbModels[2] = new AReverbModel(&AReverbModel::REVERB_MODE_2_SETTINGS); #else reverbModels[0] = new FreeverbModel(0.76f, 0.687770909f, 0.63f, 0, 0.5f); reverbModels[1] = new FreeverbModel(2.0f, 0.712025098f, 0.86f, 1, 0.5f); reverbModels[2] = new FreeverbModel(0.4f, 0.939522749f, 0.38f, 2, 0.05f); #endif reverbModels[3] = new DelayReverb(); reverbModel = NULL; setDACInputMode(DACInputMode_NICE); setOutputGain(1.0f); setReverbOutputGain(0.68f); partialManager = NULL; memset(parts, 0, sizeof(parts)); renderedSampleCount = 0; } Synth::~Synth() { close(); // Make sure we're closed and everything is freed for (int i = 0; i < 4; i++) { delete reverbModels[i]; } } int Synth::report(ReportType type, const void *data) { if (myProp.report != NULL) { return myProp.report(myProp.userData, type, data); } return 0; } unsigned int Synth::getSampleRate() const { return myProp.sampleRate; } void Synth::printDebug(const char *fmt, ...) { va_list ap; va_start(ap, fmt); if (myProp.printDebug != NULL) { myProp.printDebug(myProp.userData, fmt, ap); } else { #if MT32EMU_DEBUG_SAMPLESTAMPS > 0 printf("[%u] ", renderedSampleCount); #endif vprintf(fmt, ap); printf("\n"); } va_end(ap); } void Synth::setReverbEnabled(bool newReverbEnabled) { reverbEnabled = newReverbEnabled; } bool Synth::isReverbEnabled() const { return reverbEnabled; } void Synth::setReverbOverridden(bool newReverbOverridden) { reverbOverridden = newReverbOverridden; } bool Synth::isReverbOverridden() const { return reverbOverridden; } void Synth::setDACInputMode(DACInputMode mode) { switch(mode) { case DACInputMode_GENERATION1: la32FloatToBit16sFunc = floatToBit16s_generation1; reverbFloatToBit16sFunc = floatToBit16s_reverb; break; case DACInputMode_GENERATION2: la32FloatToBit16sFunc = floatToBit16s_generation2; reverbFloatToBit16sFunc = floatToBit16s_reverb; break; case DACInputMode_PURE: la32FloatToBit16sFunc = floatToBit16s_pure; reverbFloatToBit16sFunc = floatToBit16s_pure; break; case DACInputMode_NICE: default: la32FloatToBit16sFunc = floatToBit16s_nice; reverbFloatToBit16sFunc = floatToBit16s_reverb; break; } } void Synth::setOutputGain(float newOutputGain) { outputGain = newOutputGain; } void Synth::setReverbOutputGain(float newReverbOutputGain) { reverbOutputGain = newReverbOutputGain; } Common::File *Synth::openFile(const char *filename) { if (myProp.openFile != NULL) { return myProp.openFile(myProp.userData, filename); } char pathBuf[2048]; if (myProp.baseDir != NULL) { strcpy(&pathBuf[0], myProp.baseDir); strcat(&pathBuf[0], filename); filename = pathBuf; } Common::File *file = new Common::File(); if (!file->open(filename)) { delete file; return NULL; } return file; } void Synth::closeFile(Common::File *file) { if (myProp.closeFile != NULL) { myProp.closeFile(myProp.userData, file); } else { file->close(); delete file; } } LoadResult Synth::loadControlROM(const char *filename) { Common::File *file = openFile(filename); // ROM File if (file == NULL) { return LoadResult_NotFound; } size_t fileSize = file->size(); if (fileSize != CONTROL_ROM_SIZE) { printDebug("Control ROM file %s size mismatch: %i", filename, fileSize); } file->read(controlROMData, CONTROL_ROM_SIZE); if (file->err()) { closeFile(file); return LoadResult_Unreadable; } closeFile(file); // Control ROM successfully loaded, now check whether it's a known type controlROMMap = NULL; for (unsigned int i = 0; i < sizeof(ControlROMMaps) / sizeof(ControlROMMaps[0]); i++) { if (memcmp(&controlROMData[ControlROMMaps[i].idPos], ControlROMMaps[i].idBytes, ControlROMMaps[i].idLen) == 0) { controlROMMap = &ControlROMMaps[i]; return LoadResult_OK; } } printDebug("%s does not match a known control ROM type", filename); return LoadResult_Invalid; } LoadResult Synth::loadPCMROM(const char *filename) { Common::File *file = openFile(filename); // ROM File if (file == NULL) { return LoadResult_NotFound; } size_t fileSize = file->size(); if (fileSize < (size_t)(2 * pcmROMSize)) { printDebug("PCM ROM file is too short (expected %d, got %d)", 2 * pcmROMSize, fileSize); closeFile(file); return LoadResult_Invalid; } if (file->err()) { closeFile(file); return LoadResult_Unreadable; } LoadResult rc = LoadResult_OK; for (int i = 0; i < pcmROMSize; i++) { Bit8u s = file->readByte(); Bit8u c = file->readByte(); int order[16] = {0, 9, 1, 2, 3, 4, 5, 6, 7, 10, 11, 12, 13, 14, 15, 8}; signed short log = 0; for (int u = 0; u < 15; u++) { int bit; if (order[u] < 8) { bit = (s >> (7 - order[u])) & 0x1; } else { bit = (c >> (7 - (order[u] - 8))) & 0x1; } log = log | (short)(bit << (15 - u)); } bool negative = log < 0; log &= 0x7FFF; // CONFIRMED from sample analysis to be 99.99%+ accurate with current TVA multiplier float lin = EXP2F((32787 - log) / -2048.0f); if (negative) { lin = -lin; } pcmROMData[i] = lin; } closeFile(file); return rc; } bool Synth::initPCMList(Bit16u mapAddress, Bit16u count) { ControlROMPCMStruct *tps = (ControlROMPCMStruct *)&controlROMData[mapAddress]; for (int i = 0; i < count; i++) { int rAddr = tps[i].pos * 0x800; int rLenExp = (tps[i].len & 0x70) >> 4; int rLen = 0x800 << rLenExp; if (rAddr + rLen > pcmROMSize) { printDebug("Control ROM error: Wave map entry %d points to invalid PCM address 0x%04X, length 0x%04X", i, rAddr, rLen); return false; } pcmWaves[i].addr = rAddr; pcmWaves[i].len = rLen; pcmWaves[i].loop = (tps[i].len & 0x80) != 0; pcmWaves[i].controlROMPCMStruct = &tps[i]; //int pitch = (tps[i].pitchMSB << 8) | tps[i].pitchLSB; //bool unaffectedByMasterTune = (tps[i].len & 0x01) == 0; //printDebug("PCM %d: pos=%d, len=%d, pitch=%d, loop=%s, unaffectedByMasterTune=%s", i, rAddr, rLen, pitch, pcmWaves[i].loop ? "YES" : "NO", unaffectedByMasterTune ? "YES" : "NO"); } return false; } bool Synth::initCompressedTimbre(int timbreNum, const Bit8u *src, unsigned int srcLen) { // "Compressed" here means that muted partials aren't present in ROM (except in the case of partial 0 being muted). // Instead the data from the previous unmuted partial is used. if (srcLen < sizeof(TimbreParam::CommonParam)) { return false; } TimbreParam *timbre = &mt32ram.timbres[timbreNum].timbre; timbresMemoryRegion->write(timbreNum, 0, src, sizeof(TimbreParam::CommonParam), true); unsigned int srcPos = sizeof(TimbreParam::CommonParam); unsigned int memPos = sizeof(TimbreParam::CommonParam); for (int t = 0; t < 4; t++) { if (t != 0 && ((timbre->common.partialMute >> t) & 0x1) == 0x00) { // This partial is muted - we'll copy the previously copied partial, then srcPos -= sizeof(TimbreParam::PartialParam); } else if (srcPos + sizeof(TimbreParam::PartialParam) >= srcLen) { return false; } timbresMemoryRegion->write(timbreNum, memPos, src + srcPos, sizeof(TimbreParam::PartialParam)); srcPos += sizeof(TimbreParam::PartialParam); memPos += sizeof(TimbreParam::PartialParam); } return true; } bool Synth::initTimbres(Bit16u mapAddress, Bit16u offset, int count, int startTimbre, bool compressed) { const Bit8u *timbreMap = &controlROMData[mapAddress]; for (Bit16u i = 0; i < count * 2; i += 2) { Bit16u address = (timbreMap[i + 1] << 8) | timbreMap[i]; if (!compressed && (address + offset + sizeof(TimbreParam) > CONTROL_ROM_SIZE)) { printDebug("Control ROM error: Timbre map entry 0x%04x for timbre %d points to invalid timbre address 0x%04x", i, startTimbre, address); return false; } address += offset; if (compressed) { if (!initCompressedTimbre(startTimbre, &controlROMData[address], CONTROL_ROM_SIZE - address)) { printDebug("Control ROM error: Timbre map entry 0x%04x for timbre %d points to invalid timbre at 0x%04x", i, startTimbre, address); return false; } } else { timbresMemoryRegion->write(startTimbre, 0, &controlROMData[address], sizeof(TimbreParam), true); } startTimbre++; } return true; } bool Synth::open(SynthProperties &useProp) { if (isOpen) { return false; } prerenderReadIx = prerenderWriteIx = 0; myProp = useProp; #if MT32EMU_MONITOR_INIT printDebug("Initialising Constant Tables"); #endif tables.init(); #if !MT32EMU_REDUCE_REVERB_MEMORY for (int i = 0; i < 4; i++) { reverbModels[i]->open(useProp.sampleRate); } #endif if (useProp.baseDir != NULL) { char *baseDirCopy = new char[strlen(useProp.baseDir) + 1]; strcpy(baseDirCopy, useProp.baseDir); myProp.baseDir = baseDirCopy; } // This is to help detect bugs memset(&mt32ram, '?', sizeof(mt32ram)); #if MT32EMU_MONITOR_INIT printDebug("Loading Control ROM"); #endif if (loadControlROM("CM32L_CONTROL.ROM") != LoadResult_OK) { if (loadControlROM("MT32_CONTROL.ROM") != LoadResult_OK) { printDebug("Init Error - Missing or invalid MT32_CONTROL.ROM"); //report(ReportType_errorControlROM, &errno); return false; } } initMemoryRegions(); // 512KB PCM ROM for MT-32, etc. // 1MB PCM ROM for CM-32L, LAPC-I, CM-64, CM-500 // Note that the size below is given in samples (16-bit), not bytes pcmROMSize = controlROMMap->pcmCount == 256 ? 512 * 1024 : 256 * 1024; pcmROMData = new float[pcmROMSize]; #if MT32EMU_MONITOR_INIT printDebug("Loading PCM ROM"); #endif if (loadPCMROM("CM32L_PCM.ROM") != LoadResult_OK) { if (loadPCMROM("MT32_PCM.ROM") != LoadResult_OK) { printDebug("Init Error - Missing MT32_PCM.ROM"); //report(ReportType_errorPCMROM, &errno); return false; } } #if MT32EMU_MONITOR_INIT printDebug("Initialising Timbre Bank A"); #endif if (!initTimbres(controlROMMap->timbreAMap, controlROMMap->timbreAOffset, 0x40, 0, controlROMMap->timbreACompressed)) { return false; } #if MT32EMU_MONITOR_INIT printDebug("Initialising Timbre Bank B"); #endif if (!initTimbres(controlROMMap->timbreBMap, controlROMMap->timbreBOffset, 0x40, 64, controlROMMap->timbreBCompressed)) { return false; } #if MT32EMU_MONITOR_INIT printDebug("Initialising Timbre Bank R"); #endif if (!initTimbres(controlROMMap->timbreRMap, 0, controlROMMap->timbreRCount, 192, true)) { return false; } #if MT32EMU_MONITOR_INIT printDebug("Initialising Timbre Bank M"); #endif // CM-64 seems to initialise all bytes in this bank to 0. memset(&mt32ram.timbres[128], 0, sizeof(mt32ram.timbres[128]) * 64); partialManager = new PartialManager(this, parts); pcmWaves = new PCMWaveEntry[controlROMMap->pcmCount]; #if MT32EMU_MONITOR_INIT printDebug("Initialising PCM List"); #endif initPCMList(controlROMMap->pcmTable, controlROMMap->pcmCount); #if MT32EMU_MONITOR_INIT printDebug("Initialising Rhythm Temp"); #endif memcpy(mt32ram.rhythmTemp, &controlROMData[controlROMMap->rhythmSettings], controlROMMap->rhythmSettingsCount * 4); #if MT32EMU_MONITOR_INIT printDebug("Initialising Patches"); #endif for (Bit8u i = 0; i < 128; i++) { PatchParam *patch = &mt32ram.patches[i]; patch->timbreGroup = i / 64; patch->timbreNum = i % 64; patch->keyShift = 24; patch->fineTune = 50; patch->benderRange = 12; patch->assignMode = 0; patch->reverbSwitch = 1; patch->dummy = 0; } #if MT32EMU_MONITOR_INIT printDebug("Initialising System"); #endif // The MT-32 manual claims that "Standard pitch" is 442Hz. mt32ram.system.masterTune = 0x4A; // Confirmed on CM-64 mt32ram.system.reverbMode = 0; // Confirmed mt32ram.system.reverbTime = 5; // Confirmed mt32ram.system.reverbLevel = 3; // Confirmed memcpy(mt32ram.system.reserveSettings, &controlROMData[controlROMMap->reserveSettings], 9); // Confirmed for (Bit8u i = 0; i < 9; i++) { // This is the default: {1, 2, 3, 4, 5, 6, 7, 8, 9} // An alternative configuration can be selected by holding "Master Volume" // and pressing "PART button 1" on the real MT-32's frontpanel. // The channel assignment is then {0, 1, 2, 3, 4, 5, 6, 7, 9} mt32ram.system.chanAssign[i] = i + 1; } mt32ram.system.masterVol = 100; // Confirmed refreshSystem(); for (int i = 0; i < 9; i++) { MemParams::PatchTemp *patchTemp = &mt32ram.patchTemp[i]; // Note that except for the rhythm part, these patch fields will be set in setProgram() below anyway. patchTemp->patch.timbreGroup = 0; patchTemp->patch.timbreNum = 0; patchTemp->patch.keyShift = 24; patchTemp->patch.fineTune = 50; patchTemp->patch.benderRange = 12; patchTemp->patch.assignMode = 0; patchTemp->patch.reverbSwitch = 1; patchTemp->patch.dummy = 0; patchTemp->outputLevel = 80; patchTemp->panpot = controlROMData[controlROMMap->panSettings + i]; memset(patchTemp->dummyv, 0, sizeof(patchTemp->dummyv)); patchTemp->dummyv[1] = 127; if (i < 8) { parts[i] = new Part(this, i); parts[i]->setProgram(controlROMData[controlROMMap->programSettings + i]); } else { parts[i] = new RhythmPart(this, i); } } // For resetting mt32 mid-execution mt32default = mt32ram; isOpen = true; isEnabled = false; #if MT32EMU_MONITOR_INIT printDebug("*** Initialisation complete ***"); #endif return true; } void Synth::close() { if (!isOpen) { return; } delete partialManager; partialManager = NULL; for (int i = 0; i < 9; i++) { delete parts[i]; parts[i] = NULL; } delete[] myProp.baseDir; myProp.baseDir = NULL; delete[] pcmWaves; delete[] pcmROMData; deleteMemoryRegions(); for (int i = 0; i < 4; i++) { reverbModels[i]->close(); } reverbModel = NULL; isOpen = false; } void Synth::playMsg(Bit32u msg) { // FIXME: Implement active sensing unsigned char code = (unsigned char)((msg & 0x0000F0) >> 4); unsigned char chan = (unsigned char)(msg & 0x00000F); unsigned char note = (unsigned char)((msg & 0x00FF00) >> 8); unsigned char velocity = (unsigned char)((msg & 0xFF0000) >> 16); isEnabled = true; //printDebug("Playing chan %d, code 0x%01x note: 0x%02x", chan, code, note); char part = chantable[chan]; if (part < 0 || part > 8) { #if MT32EMU_MONITOR_MIDI > 0 printDebug("Play msg on unreg chan %d (%d): code=0x%01x, vel=%d", chan, part, code, velocity); #endif return; } playMsgOnPart(part, code, note, velocity); } void Synth::playMsgOnPart(unsigned char part, unsigned char code, unsigned char note, unsigned char velocity) { Bit32u bend; //printDebug("Synth::playMsgOnPart(%02x, %02x, %02x, %02x)", part, code, note, velocity); switch (code) { case 0x8: //printDebug("Note OFF - Part %d", part); // The MT-32 ignores velocity for note off parts[part]->noteOff(note); break; case 0x9: //printDebug("Note ON - Part %d, Note %d Vel %d", part, note, velocity); if (velocity == 0) { // MIDI defines note-on with velocity 0 as being the same as note-off with velocity 40 parts[part]->noteOff(note); } else { parts[part]->noteOn(note, velocity); } break; case 0xB: // Control change switch (note) { case 0x01: // Modulation //printDebug("Modulation: %d", velocity); parts[part]->setModulation(velocity); break; case 0x06: parts[part]->setDataEntryMSB(velocity); break; case 0x07: // Set volume //printDebug("Volume set: %d", velocity); parts[part]->setVolume(velocity); break; case 0x0A: // Pan //printDebug("Pan set: %d", velocity); parts[part]->setPan(velocity); break; case 0x0B: //printDebug("Expression set: %d", velocity); parts[part]->setExpression(velocity); break; case 0x40: // Hold (sustain) pedal //printDebug("Hold pedal set: %d", velocity); parts[part]->setHoldPedal(velocity >= 64); break; case 0x62: case 0x63: parts[part]->setNRPN(); break; case 0x64: parts[part]->setRPNLSB(velocity); break; case 0x65: parts[part]->setRPNMSB(velocity); break; case 0x79: // Reset all controllers //printDebug("Reset all controllers"); parts[part]->resetAllControllers(); break; case 0x7B: // All notes off //printDebug("All notes off"); parts[part]->allNotesOff(); break; case 0x7C: case 0x7D: case 0x7E: case 0x7F: // CONFIRMED:Mok: A real LAPC-I responds to these controllers as follows: parts[part]->setHoldPedal(false); parts[part]->allNotesOff(); break; default: #if MT32EMU_MONITOR_MIDI > 0 printDebug("Unknown MIDI Control code: 0x%02x - vel 0x%02x", note, velocity); #endif break; } break; case 0xC: // Program change //printDebug("Program change %01x", note); parts[part]->setProgram(note); break; case 0xE: // Pitch bender bend = (velocity << 7) | (note); //printDebug("Pitch bender %02x", bend); parts[part]->setBend(bend); break; default: #if MT32EMU_MONITOR_MIDI > 0 printDebug("Unknown Midi code: 0x%01x - %02x - %02x", code, note, velocity); #endif break; } //midiOutShortMsg(m_out, msg); } void Synth::playSysex(const Bit8u *sysex, Bit32u len) { if (len < 2) { printDebug("playSysex: Message is too short for sysex (%d bytes)", len); } if (sysex[0] != 0xF0) { printDebug("playSysex: Message lacks start-of-sysex (0xF0)"); return; } // Due to some programs (e.g. Java) sending buffers with junk at the end, we have to go through and find the end marker rather than relying on len. Bit32u endPos; for (endPos = 1; endPos < len; endPos++) { if (sysex[endPos] == 0xF7) { break; } } if (endPos == len) { printDebug("playSysex: Message lacks end-of-sysex (0xf7)"); return; } playSysexWithoutFraming(sysex + 1, endPos - 1); } void Synth::playSysexWithoutFraming(const Bit8u *sysex, Bit32u len) { if (len < 4) { printDebug("playSysexWithoutFraming: Message is too short (%d bytes)!", len); return; } if (sysex[0] != SYSEX_MANUFACTURER_ROLAND) { printDebug("playSysexWithoutFraming: Header not intended for this device manufacturer: %02x %02x %02x %02x", (int)sysex[0], (int)sysex[1], (int)sysex[2], (int)sysex[3]); return; } if (sysex[2] == SYSEX_MDL_D50) { printDebug("playSysexWithoutFraming: Header is intended for model D-50 (not yet supported): %02x %02x %02x %02x", (int)sysex[0], (int)sysex[1], (int)sysex[2], (int)sysex[3]); return; } else if (sysex[2] != SYSEX_MDL_MT32) { printDebug("playSysexWithoutFraming: Header not intended for model MT-32: %02x %02x %02x %02x", (int)sysex[0], (int)sysex[1], (int)sysex[2], (int)sysex[3]); return; } playSysexWithoutHeader(sysex[1], sysex[3], sysex + 4, len - 4); } void Synth::playSysexWithoutHeader(unsigned char device, unsigned char command, const Bit8u *sysex, Bit32u len) { if (device > 0x10) { // We have device ID 0x10 (default, but changeable, on real MT-32), < 0x10 is for channels printDebug("playSysexWithoutHeader: Message is not intended for this device ID (provided: %02x, expected: 0x10 or channel)", (int)device); return; } // This is checked early in the real devices (before any sysex length checks or further processing) // FIXME: Response to SYSEX_CMD_DAT reset with partials active (and in general) is untested. if ((command == SYSEX_CMD_DT1 || command == SYSEX_CMD_DAT) && sysex[0] == 0x7F) { reset(); return; } if (len < 4) { printDebug("playSysexWithoutHeader: Message is too short (%d bytes)!", len); return; } unsigned char checksum = calcSysexChecksum(sysex, len - 1, 0); if (checksum != sysex[len - 1]) { printDebug("playSysexWithoutHeader: Message checksum is incorrect (provided: %02x, expected: %02x)!", sysex[len - 1], checksum); return; } len -= 1; // Exclude checksum switch (command) { case SYSEX_CMD_DAT: if (hasActivePartials()) { printDebug("playSysexWithoutHeader: Got SYSEX_CMD_DAT but partials are active - ignoring"); // FIXME: We should send SYSEX_CMD_RJC in this case break; } // Deliberate fall-through case SYSEX_CMD_DT1: writeSysex(device, sysex, len); break; case SYSEX_CMD_RQD: if (hasActivePartials()) { printDebug("playSysexWithoutHeader: Got SYSEX_CMD_RQD but partials are active - ignoring"); // FIXME: We should send SYSEX_CMD_RJC in this case break; } // Deliberate fall-through case SYSEX_CMD_RQ1: readSysex(device, sysex, len); break; default: printDebug("playSysexWithoutHeader: Unsupported command %02x", command); return; } } void Synth::readSysex(unsigned char /*device*/, const Bit8u * /*sysex*/, Bit32u /*len*/) const { // NYI } void Synth::writeSysex(unsigned char device, const Bit8u *sysex, Bit32u len) { Bit32u addr = (sysex[0] << 16) | (sysex[1] << 8) | (sysex[2]); addr = MT32EMU_MEMADDR(addr); sysex += 3; len -= 3; //printDebug("Sysex addr: 0x%06x", MT32EMU_SYSEXMEMADDR(addr)); // NOTE: Please keep both lower and upper bounds in each check, for ease of reading // Process channel-specific sysex by converting it to device-global if (device < 0x10) { #if MT32EMU_MONITOR_SYSEX > 0 printDebug("WRITE-CHANNEL: Channel %d temp area 0x%06x", device, MT32EMU_SYSEXMEMADDR(addr)); #endif if (/*addr >= MT32EMU_MEMADDR(0x000000) && */addr < MT32EMU_MEMADDR(0x010000)) { int offset; if (chantable[device] == -1) { #if MT32EMU_MONITOR_SYSEX > 0 printDebug(" (Channel not mapped to a part... 0 offset)"); #endif offset = 0; } else if (chantable[device] == 8) { #if MT32EMU_MONITOR_SYSEX > 0 printDebug(" (Channel mapped to rhythm... 0 offset)"); #endif offset = 0; } else { offset = chantable[device] * sizeof(MemParams::PatchTemp); #if MT32EMU_MONITOR_SYSEX > 0 printDebug(" (Setting extra offset to %d)", offset); #endif } addr += MT32EMU_MEMADDR(0x030000) + offset; } else if (/*addr >= MT32EMU_MEMADDR(0x010000) && */ addr < MT32EMU_MEMADDR(0x020000)) { addr += MT32EMU_MEMADDR(0x030110) - MT32EMU_MEMADDR(0x010000); } else if (/*addr >= MT32EMU_MEMADDR(0x020000) && */ addr < MT32EMU_MEMADDR(0x030000)) { int offset; if (chantable[device] == -1) { #if MT32EMU_MONITOR_SYSEX > 0 printDebug(" (Channel not mapped to a part... 0 offset)"); #endif offset = 0; } else if (chantable[device] == 8) { #if MT32EMU_MONITOR_SYSEX > 0 printDebug(" (Channel mapped to rhythm... 0 offset)"); #endif offset = 0; } else { offset = chantable[device] * sizeof(TimbreParam); #if MT32EMU_MONITOR_SYSEX > 0 printDebug(" (Setting extra offset to %d)", offset); #endif } addr += MT32EMU_MEMADDR(0x040000) - MT32EMU_MEMADDR(0x020000) + offset; } else { #if MT32EMU_MONITOR_SYSEX > 0 printDebug(" Invalid channel"); #endif return; } } // Process device-global sysex (possibly converted from channel-specific sysex above) for (;;) { // Find the appropriate memory region const MemoryRegion *region = findMemoryRegion(addr); if (region == NULL) { printDebug("Sysex write to unrecognised address %06x, len %d", MT32EMU_SYSEXMEMADDR(addr), len); break; } writeMemoryRegion(region, addr, region->getClampedLen(addr, len), sysex); Bit32u next = region->next(addr, len); if (next == 0) { break; } addr += next; sysex += next; len -= next; } } void Synth::readMemory(Bit32u addr, Bit32u len, Bit8u *data) { const MemoryRegion *region = findMemoryRegion(addr); if (region != NULL) { readMemoryRegion(region, addr, len, data); } } void Synth::initMemoryRegions() { // Timbre max tables are slightly more complicated than the others, which are used directly from the ROM. // The ROM (sensibly) just has maximums for TimbreParam.commonParam followed by just one TimbreParam.partialParam, // so we produce a table with all partialParams filled out, as well as padding for PaddedTimbre, for quick lookup. paddedTimbreMaxTable = new Bit8u[sizeof(MemParams::PaddedTimbre)]; memcpy(&paddedTimbreMaxTable[0], &controlROMData[controlROMMap->timbreMaxTable], sizeof(TimbreParam::CommonParam) + sizeof(TimbreParam::PartialParam)); // commonParam and one partialParam int pos = sizeof(TimbreParam::CommonParam) + sizeof(TimbreParam::PartialParam); for (int i = 0; i < 3; i++) { memcpy(&paddedTimbreMaxTable[pos], &controlROMData[controlROMMap->timbreMaxTable + sizeof(TimbreParam::CommonParam)], sizeof(TimbreParam::PartialParam)); pos += sizeof(TimbreParam::PartialParam); } memset(&paddedTimbreMaxTable[pos], 0, 10); // Padding patchTempMemoryRegion = new PatchTempMemoryRegion(this, (Bit8u *)&mt32ram.patchTemp[0], &controlROMData[controlROMMap->patchMaxTable]); rhythmTempMemoryRegion = new RhythmTempMemoryRegion(this, (Bit8u *)&mt32ram.rhythmTemp[0], &controlROMData[controlROMMap->rhythmMaxTable]); timbreTempMemoryRegion = new TimbreTempMemoryRegion(this, (Bit8u *)&mt32ram.timbreTemp[0], paddedTimbreMaxTable); patchesMemoryRegion = new PatchesMemoryRegion(this, (Bit8u *)&mt32ram.patches[0], &controlROMData[controlROMMap->patchMaxTable]); timbresMemoryRegion = new TimbresMemoryRegion(this, (Bit8u *)&mt32ram.timbres[0], paddedTimbreMaxTable); systemMemoryRegion = new SystemMemoryRegion(this, (Bit8u *)&mt32ram.system, &controlROMData[controlROMMap->systemMaxTable]); displayMemoryRegion = new DisplayMemoryRegion(this); resetMemoryRegion = new ResetMemoryRegion(this); } void Synth::deleteMemoryRegions() { delete patchTempMemoryRegion; patchTempMemoryRegion = NULL; delete rhythmTempMemoryRegion; rhythmTempMemoryRegion = NULL; delete timbreTempMemoryRegion; timbreTempMemoryRegion = NULL; delete patchesMemoryRegion; patchesMemoryRegion = NULL; delete timbresMemoryRegion; timbresMemoryRegion = NULL; delete systemMemoryRegion; systemMemoryRegion = NULL; delete displayMemoryRegion; displayMemoryRegion = NULL; delete resetMemoryRegion; resetMemoryRegion = NULL; delete[] paddedTimbreMaxTable; paddedTimbreMaxTable = NULL; } MemoryRegion *Synth::findMemoryRegion(Bit32u addr) { MemoryRegion *regions[] = { patchTempMemoryRegion, rhythmTempMemoryRegion, timbreTempMemoryRegion, patchesMemoryRegion, timbresMemoryRegion, systemMemoryRegion, displayMemoryRegion, resetMemoryRegion, NULL }; for (int pos = 0; regions[pos] != NULL; pos++) { if (regions[pos]->contains(addr)) { return regions[pos]; } } return NULL; } void Synth::readMemoryRegion(const MemoryRegion *region, Bit32u addr, Bit32u len, Bit8u *data) { unsigned int first = region->firstTouched(addr); //unsigned int last = region->lastTouched(addr, len); unsigned int off = region->firstTouchedOffset(addr); len = region->getClampedLen(addr, len); unsigned int m; if (region->isReadable()) { region->read(first, off, data, len); } else { // FIXME: We might want to do these properly in future for (m = 0; m < len; m += 2) { data[m] = 0xff; if (m + 1 < len) { data[m+1] = (Bit8u)region->type; } } } } void Synth::writeMemoryRegion(const MemoryRegion *region, Bit32u addr, Bit32u len, const Bit8u *data) { unsigned int first = region->firstTouched(addr); unsigned int last = region->lastTouched(addr, len); unsigned int off = region->firstTouchedOffset(addr); switch (region->type) { case MR_PatchTemp: region->write(first, off, data, len); //printDebug("Patch temp: Patch %d, offset %x, len %d", off/16, off % 16, len); for (unsigned int i = first; i <= last; i++) { int absTimbreNum = mt32ram.patchTemp[i].patch.timbreGroup * 64 + mt32ram.patchTemp[i].patch.timbreNum; char timbreName[11]; memcpy(timbreName, mt32ram.timbres[absTimbreNum].timbre.common.name, 10); timbreName[10] = 0; #if MT32EMU_MONITOR_SYSEX > 0 printDebug("WRITE-PARTPATCH (%d-%d@%d..%d): %d; timbre=%d (%s), outlevel=%d", first, last, off, off + len, i, absTimbreNum, timbreName, mt32ram.patchTemp[i].outputLevel); #endif if (parts[i] != NULL) { if (i != 8) { // Note: Confirmed on CM-64 that we definitely *should* update the timbre here, // but only in the case that the sysex actually writes to those values if (i == first && off > 2) { #if MT32EMU_MONITOR_SYSEX > 0 printDebug(" (Not updating timbre, since those values weren't touched)"); #endif } else { parts[i]->setTimbre(&mt32ram.timbres[parts[i]->getAbsTimbreNum()].timbre); } } parts[i]->refresh(); } } break; case MR_RhythmTemp: region->write(first, off, data, len); for (unsigned int i = first; i <= last; i++) { int timbreNum = mt32ram.rhythmTemp[i].timbre; char timbreName[11]; if (timbreNum < 94) { memcpy(timbreName, mt32ram.timbres[128 + timbreNum].timbre.common.name, 10); timbreName[10] = 0; } else { strcpy(timbreName, "[None]"); } #if MT32EMU_MONITOR_SYSEX > 0 printDebug("WRITE-RHYTHM (%d-%d@%d..%d): %d; level=%02x, panpot=%02x, reverb=%02x, timbre=%d (%s)", first, last, off, off + len, i, mt32ram.rhythmTemp[i].outputLevel, mt32ram.rhythmTemp[i].panpot, mt32ram.rhythmTemp[i].reverbSwitch, mt32ram.rhythmTemp[i].timbre, timbreName); #endif } if (parts[8] != NULL) { parts[8]->refresh(); } break; case MR_TimbreTemp: region->write(first, off, data, len); for (unsigned int i = first; i <= last; i++) { char instrumentName[11]; memcpy(instrumentName, mt32ram.timbreTemp[i].common.name, 10); instrumentName[10] = 0; #if MT32EMU_MONITOR_SYSEX > 0 printDebug("WRITE-PARTTIMBRE (%d-%d@%d..%d): timbre=%d (%s)", first, last, off, off + len, i, instrumentName); #endif if (parts[i] != NULL) { parts[i]->refresh(); } } break; case MR_Patches: region->write(first, off, data, len); #if MT32EMU_MONITOR_SYSEX > 0 for (unsigned int i = first; i <= last; i++) { PatchParam *patch = &mt32ram.patches[i]; int patchAbsTimbreNum = patch->timbreGroup * 64 + patch->timbreNum; char instrumentName[11]; memcpy(instrumentName, mt32ram.timbres[patchAbsTimbreNum].timbre.common.name, 10); instrumentName[10] = 0; Bit8u *n = (Bit8u *)patch; printDebug("WRITE-PATCH (%d-%d@%d..%d): %d; timbre=%d (%s) %02X%02X%02X%02X%02X%02X%02X%02X", first, last, off, off + len, i, patchAbsTimbreNum, instrumentName, n[0], n[1], n[2], n[3], n[4], n[5], n[6], n[7]); } #endif break; case MR_Timbres: // Timbres first += 128; last += 128; region->write(first, off, data, len); for (unsigned int i = first; i <= last; i++) { #if MT32EMU_MONITOR_TIMBRES >= 1 TimbreParam *timbre = &mt32ram.timbres[i].timbre; char instrumentName[11]; memcpy(instrumentName, timbre->common.name, 10); instrumentName[10] = 0; printDebug("WRITE-TIMBRE (%d-%d@%d..%d): %d; name=\"%s\"", first, last, off, off + len, i, instrumentName); #if MT32EMU_MONITOR_TIMBRES >= 2 #define DT(x) printDebug(" " #x ": %d", timbre->x) DT(common.partialStructure12); DT(common.partialStructure34); DT(common.partialMute); DT(common.noSustain); #define DTP(x) \ DT(partial[x].wg.pitchCoarse); \ DT(partial[x].wg.pitchFine); \ DT(partial[x].wg.pitchKeyfollow); \ DT(partial[x].wg.pitchBenderEnabled); \ DT(partial[x].wg.waveform); \ DT(partial[x].wg.pcmWave); \ DT(partial[x].wg.pulseWidth); \ DT(partial[x].wg.pulseWidthVeloSensitivity); \ DT(partial[x].pitchEnv.depth); \ DT(partial[x].pitchEnv.veloSensitivity); \ DT(partial[x].pitchEnv.timeKeyfollow); \ DT(partial[x].pitchEnv.time[0]); \ DT(partial[x].pitchEnv.time[1]); \ DT(partial[x].pitchEnv.time[2]); \ DT(partial[x].pitchEnv.time[3]); \ DT(partial[x].pitchEnv.level[0]); \ DT(partial[x].pitchEnv.level[1]); \ DT(partial[x].pitchEnv.level[2]); \ DT(partial[x].pitchEnv.level[3]); \ DT(partial[x].pitchEnv.level[4]); \ DT(partial[x].pitchLFO.rate); \ DT(partial[x].pitchLFO.depth); \ DT(partial[x].pitchLFO.modSensitivity); \ DT(partial[x].tvf.cutoff); \ DT(partial[x].tvf.resonance); \ DT(partial[x].tvf.keyfollow); \ DT(partial[x].tvf.biasPoint); \ DT(partial[x].tvf.biasLevel); \ DT(partial[x].tvf.envDepth); \ DT(partial[x].tvf.envVeloSensitivity); \ DT(partial[x].tvf.envDepthKeyfollow); \ DT(partial[x].tvf.envTimeKeyfollow); \ DT(partial[x].tvf.envTime[0]); \ DT(partial[x].tvf.envTime[1]); \ DT(partial[x].tvf.envTime[2]); \ DT(partial[x].tvf.envTime[3]); \ DT(partial[x].tvf.envTime[4]); \ DT(partial[x].tvf.envLevel[0]); \ DT(partial[x].tvf.envLevel[1]); \ DT(partial[x].tvf.envLevel[2]); \ DT(partial[x].tvf.envLevel[3]); \ DT(partial[x].tva.level); \ DT(partial[x].tva.veloSensitivity); \ DT(partial[x].tva.biasPoint1); \ DT(partial[x].tva.biasLevel1); \ DT(partial[x].tva.biasPoint2); \ DT(partial[x].tva.biasLevel2); \ DT(partial[x].tva.envTimeKeyfollow); \ DT(partial[x].tva.envTimeVeloSensitivity); \ DT(partial[x].tva.envTime[0]); \ DT(partial[x].tva.envTime[1]); \ DT(partial[x].tva.envTime[2]); \ DT(partial[x].tva.envTime[3]); \ DT(partial[x].tva.envTime[4]); \ DT(partial[x].tva.envLevel[0]); \ DT(partial[x].tva.envLevel[1]); \ DT(partial[x].tva.envLevel[2]); \ DT(partial[x].tva.envLevel[3]); DTP(0); DTP(1); DTP(2); DTP(3); #undef DTP #undef DT #endif #endif // FIXME:KG: Not sure if the stuff below should be done (for rhythm and/or parts)... // Does the real MT-32 automatically do this? for (unsigned int part = 0; part < 9; part++) { if (parts[part] != NULL) { parts[part]->refreshTimbre(i); } } } break; case MR_System: region->write(0, off, data, len); report(ReportType_devReconfig, NULL); // FIXME: We haven't properly confirmed any of this behaviour // In particular, we tend to reset things such as reverb even if the write contained // the same parameters as were already set, which may be wrong. // On the other hand, the real thing could be resetting things even when they aren't touched // by the write at all. #if MT32EMU_MONITOR_SYSEX > 0 printDebug("WRITE-SYSTEM:"); #endif if (off <= SYSTEM_MASTER_TUNE_OFF && off + len > SYSTEM_MASTER_TUNE_OFF) { refreshSystemMasterTune(); } if (off <= SYSTEM_REVERB_LEVEL_OFF && off + len > SYSTEM_REVERB_MODE_OFF) { refreshSystemReverbParameters(); } if (off <= SYSTEM_RESERVE_SETTINGS_END_OFF && off + len > SYSTEM_RESERVE_SETTINGS_START_OFF) { refreshSystemReserveSettings(); } if (off <= SYSTEM_CHAN_ASSIGN_END_OFF && off + len > SYSTEM_CHAN_ASSIGN_START_OFF) { int firstPart = off - SYSTEM_CHAN_ASSIGN_START_OFF; if(firstPart < 0) firstPart = 0; int lastPart = off + len - SYSTEM_CHAN_ASSIGN_START_OFF; if(lastPart > 9) lastPart = 9; refreshSystemChanAssign(firstPart, lastPart); } if (off <= SYSTEM_MASTER_VOL_OFF && off + len > SYSTEM_MASTER_VOL_OFF) { refreshSystemMasterVol(); } break; case MR_Display: char buf[MAX_SYSEX_SIZE]; memcpy(&buf, &data[0], len); buf[len] = 0; #if MT32EMU_MONITOR_SYSEX > 0 printDebug("WRITE-LCD: %s", buf); #endif report(ReportType_lcdMessage, buf); break; case MR_Reset: reset(); break; } } void Synth::refreshSystemMasterTune() { #if MT32EMU_MONITOR_SYSEX > 0 //FIXME:KG: This is just an educated guess. // The LAPC-I documentation claims a range of 427.5Hz-452.6Hz (similar to what we have here) // The MT-32 documentation claims a range of 432.1Hz-457.6Hz float masterTune = 440.0f * EXP2F((mt32ram.system.masterTune - 64.0f) / (128.0f * 12.0f)); printDebug(" Master Tune: %f", masterTune); #endif } void Synth::refreshSystemReverbParameters() { #if MT32EMU_MONITOR_SYSEX > 0 printDebug(" Reverb: mode=%d, time=%d, level=%d", mt32ram.system.reverbMode, mt32ram.system.reverbTime, mt32ram.system.reverbLevel); #endif if (reverbOverridden && reverbModel != NULL) { #if MT32EMU_MONITOR_SYSEX > 0 printDebug(" (Reverb overridden - ignoring)"); #endif return; } report(ReportType_newReverbMode, &mt32ram.system.reverbMode); report(ReportType_newReverbTime, &mt32ram.system.reverbTime); report(ReportType_newReverbLevel, &mt32ram.system.reverbLevel); ReverbModel *newReverbModel = reverbModels[mt32ram.system.reverbMode]; #if MT32EMU_REDUCE_REVERB_MEMORY if (reverbModel != newReverbModel) { if (reverbModel != NULL) { reverbModel->close(); } newReverbModel->open(myProp.sampleRate); } #endif reverbModel = newReverbModel; reverbModel->setParameters(mt32ram.system.reverbTime, mt32ram.system.reverbLevel); } void Synth::refreshSystemReserveSettings() { Bit8u *rset = mt32ram.system.reserveSettings; #if MT32EMU_MONITOR_SYSEX > 0 printDebug(" Partial reserve: 1=%02d 2=%02d 3=%02d 4=%02d 5=%02d 6=%02d 7=%02d 8=%02d Rhythm=%02d", rset[0], rset[1], rset[2], rset[3], rset[4], rset[5], rset[6], rset[7], rset[8]); #endif partialManager->setReserve(rset); } void Synth::refreshSystemChanAssign(unsigned int firstPart, unsigned int lastPart) { memset(chantable, -1, sizeof(chantable)); // CONFIRMED: In the case of assigning a channel to multiple parts, the lower part wins. for (unsigned int i = 0; i <= 8; i++) { if (parts[i] != NULL && i >= firstPart && i <= lastPart) { // CONFIRMED: Decay is started for all polys, and all controllers are reset, for every part whose assignment was touched by the sysex write. parts[i]->allSoundOff(); parts[i]->resetAllControllers(); } int chan = mt32ram.system.chanAssign[i]; if (chan != 16 && chantable[chan] == -1) { chantable[chan] = i; } } #if MT32EMU_MONITOR_SYSEX > 0 Bit8u *rset = mt32ram.system.chanAssign; printDebug(" Part assign: 1=%02d 2=%02d 3=%02d 4=%02d 5=%02d 6=%02d 7=%02d 8=%02d Rhythm=%02d", rset[0], rset[1], rset[2], rset[3], rset[4], rset[5], rset[6], rset[7], rset[8]); #endif } void Synth::refreshSystemMasterVol() { #if MT32EMU_MONITOR_SYSEX > 0 printDebug(" Master volume: %d", mt32ram.system.masterVol); #endif } void Synth::refreshSystem() { refreshSystemMasterTune(); refreshSystemReverbParameters(); refreshSystemReserveSettings(); refreshSystemChanAssign(0, 8); refreshSystemMasterVol(); } void Synth::reset() { #if MT32EMU_MONITOR_SYSEX > 0 printDebug("RESET"); #endif report(ReportType_devReset, NULL); partialManager->deactivateAll(); mt32ram = mt32default; for (int i = 0; i < 9; i++) { parts[i]->reset(); if (i != 8) { parts[i]->setProgram(controlROMData[controlROMMap->programSettings + i]); } else { parts[8]->refresh(); } } refreshSystem(); isEnabled = false; } void Synth::render(Bit16s *stream, Bit32u len) { if (!isEnabled) { memset(stream, 0, len * sizeof(Bit16s) * 2); return; } while (len > 0) { Bit32u thisLen = len > MAX_SAMPLES_PER_RUN ? MAX_SAMPLES_PER_RUN : len; renderStreams(tmpNonReverbLeft, tmpNonReverbRight, tmpReverbDryLeft, tmpReverbDryRight, tmpReverbWetLeft, tmpReverbWetRight, thisLen); for (Bit32u i = 0; i < thisLen; i++) { stream[0] = clipBit16s((Bit32s)tmpNonReverbLeft[i] + (Bit32s)tmpReverbDryLeft[i] + (Bit32s)tmpReverbWetLeft[i]); stream[1] = clipBit16s((Bit32s)tmpNonReverbRight[i] + (Bit32s)tmpReverbDryRight[i] + (Bit32s)tmpReverbWetRight[i]); stream += 2; } len -= thisLen; } } bool Synth::prerender() { int newPrerenderWriteIx = (prerenderWriteIx + 1) % MAX_PRERENDER_SAMPLES; if (newPrerenderWriteIx == prerenderReadIx) { // The prerender buffer is full return false; } doRenderStreams( prerenderNonReverbLeft + prerenderWriteIx, prerenderNonReverbRight + prerenderWriteIx, prerenderReverbDryLeft + prerenderWriteIx, prerenderReverbDryRight + prerenderWriteIx, prerenderReverbWetLeft + prerenderWriteIx, prerenderReverbWetRight + prerenderWriteIx, 1); prerenderWriteIx = newPrerenderWriteIx; return true; } static inline void maybeCopy(Bit16s *out, Bit32u outPos, Bit16s *in, Bit32u inPos, Bit32u len) { if (out == NULL) { return; } memcpy(out + outPos, in + inPos, len * sizeof(Bit16s)); } void Synth::copyPrerender(Bit16s *nonReverbLeft, Bit16s *nonReverbRight, Bit16s *reverbDryLeft, Bit16s *reverbDryRight, Bit16s *reverbWetLeft, Bit16s *reverbWetRight, Bit32u pos, Bit32u len) { maybeCopy(nonReverbLeft, pos, prerenderNonReverbLeft, prerenderReadIx, len); maybeCopy(nonReverbRight, pos, prerenderNonReverbRight, prerenderReadIx, len); maybeCopy(reverbDryLeft, pos, prerenderReverbDryLeft, prerenderReadIx, len); maybeCopy(reverbDryRight, pos, prerenderReverbDryRight, prerenderReadIx, len); maybeCopy(reverbWetLeft, pos, prerenderReverbWetLeft, prerenderReadIx, len); maybeCopy(reverbWetRight, pos, prerenderReverbWetRight, prerenderReadIx, len); } void Synth::checkPrerender(Bit16s *nonReverbLeft, Bit16s *nonReverbRight, Bit16s *reverbDryLeft, Bit16s *reverbDryRight, Bit16s *reverbWetLeft, Bit16s *reverbWetRight, Bit32u &pos, Bit32u &len) { if (prerenderReadIx > prerenderWriteIx) { // There's data in the prerender buffer, and the write index has wrapped. Bit32u prerenderCopyLen = MAX_PRERENDER_SAMPLES - prerenderReadIx; if (prerenderCopyLen > len) { prerenderCopyLen = len; } copyPrerender(nonReverbLeft, nonReverbRight, reverbDryLeft, reverbDryRight, reverbWetLeft, reverbWetRight, pos, prerenderCopyLen); len -= prerenderCopyLen; pos += prerenderCopyLen; prerenderReadIx = (prerenderReadIx + prerenderCopyLen) % MAX_PRERENDER_SAMPLES; } if (prerenderReadIx < prerenderWriteIx) { // There's data in the prerender buffer, and the write index is ahead of the read index. Bit32u prerenderCopyLen = prerenderWriteIx - prerenderReadIx; if (prerenderCopyLen > len) { prerenderCopyLen = len; } copyPrerender(nonReverbLeft, nonReverbRight, reverbDryLeft, reverbDryRight, reverbWetLeft, reverbWetRight, pos, prerenderCopyLen); len -= prerenderCopyLen; pos += prerenderCopyLen; prerenderReadIx += prerenderCopyLen; } if (prerenderReadIx == prerenderWriteIx) { // If the ring buffer's empty, reset it to start at 0 to minimise wrapping, // which requires two writes instead of one. prerenderReadIx = prerenderWriteIx = 0; } } void Synth::renderStreams(Bit16s *nonReverbLeft, Bit16s *nonReverbRight, Bit16s *reverbDryLeft, Bit16s *reverbDryRight, Bit16s *reverbWetLeft, Bit16s *reverbWetRight, Bit32u len) { if (!isEnabled) { clearIfNonNull(nonReverbLeft, len); clearIfNonNull(nonReverbRight, len); clearIfNonNull(reverbDryLeft, len); clearIfNonNull(reverbDryRight, len); clearIfNonNull(reverbWetLeft, len); clearIfNonNull(reverbWetRight, len); return; } Bit32u pos = 0; // First, check for data in the prerender buffer and spit that out before generating anything new. // Note that the prerender buffer is rarely used - see comments elsewhere for details. checkPrerender(nonReverbLeft, nonReverbRight, reverbDryLeft, reverbDryRight, reverbWetLeft, reverbWetRight, pos, len); while (len > 0) { Bit32u thisLen = len > MAX_SAMPLES_PER_RUN ? MAX_SAMPLES_PER_RUN : len; doRenderStreams( streamOffset(nonReverbLeft, pos), streamOffset(nonReverbRight, pos), streamOffset(reverbDryLeft, pos), streamOffset(reverbDryRight, pos), streamOffset(reverbWetLeft, pos), streamOffset(reverbWetRight, pos), thisLen); len -= thisLen; pos += thisLen; } } // FIXME: Using more temporary buffers than we need to void Synth::doRenderStreams(Bit16s *nonReverbLeft, Bit16s *nonReverbRight, Bit16s *reverbDryLeft, Bit16s *reverbDryRight, Bit16s *reverbWetLeft, Bit16s *reverbWetRight, Bit32u len) { clearFloats(&tmpBufMixLeft[0], &tmpBufMixRight[0], len); if (!reverbEnabled) { for (unsigned int i = 0; i < MT32EMU_MAX_PARTIALS; i++) { if (partialManager->produceOutput(i, &tmpBufPartialLeft[0], &tmpBufPartialRight[0], len)) { mix(&tmpBufMixLeft[0], &tmpBufPartialLeft[0], len); mix(&tmpBufMixRight[0], &tmpBufPartialRight[0], len); } } if (nonReverbLeft != NULL) { la32FloatToBit16sFunc(nonReverbLeft, &tmpBufMixLeft[0], len, outputGain); } if (nonReverbRight != NULL) { la32FloatToBit16sFunc(nonReverbRight, &tmpBufMixRight[0], len, outputGain); } clearIfNonNull(reverbDryLeft, len); clearIfNonNull(reverbDryRight, len); clearIfNonNull(reverbWetLeft, len); clearIfNonNull(reverbWetRight, len); } else { for (unsigned int i = 0; i < MT32EMU_MAX_PARTIALS; i++) { if (!partialManager->shouldReverb(i)) { if (partialManager->produceOutput(i, &tmpBufPartialLeft[0], &tmpBufPartialRight[0], len)) { mix(&tmpBufMixLeft[0], &tmpBufPartialLeft[0], len); mix(&tmpBufMixRight[0], &tmpBufPartialRight[0], len); } } } if (nonReverbLeft != NULL) { la32FloatToBit16sFunc(nonReverbLeft, &tmpBufMixLeft[0], len, outputGain); } if (nonReverbRight != NULL) { la32FloatToBit16sFunc(nonReverbRight, &tmpBufMixRight[0], len, outputGain); } clearFloats(&tmpBufMixLeft[0], &tmpBufMixRight[0], len); for (unsigned int i = 0; i < MT32EMU_MAX_PARTIALS; i++) { if (partialManager->shouldReverb(i)) { if (partialManager->produceOutput(i, &tmpBufPartialLeft[0], &tmpBufPartialRight[0], len)) { mix(&tmpBufMixLeft[0], &tmpBufPartialLeft[0], len); mix(&tmpBufMixRight[0], &tmpBufPartialRight[0], len); } } } if (reverbDryLeft != NULL) { la32FloatToBit16sFunc(reverbDryLeft, &tmpBufMixLeft[0], len, outputGain); } if (reverbDryRight != NULL) { la32FloatToBit16sFunc(reverbDryRight, &tmpBufMixRight[0], len, outputGain); } // FIXME: Note that on the real devices, reverb input and output are signed linear 16-bit (well, kinda, there's some fudging) PCM, not float. reverbModel->process(&tmpBufMixLeft[0], &tmpBufMixRight[0], &tmpBufReverbOutLeft[0], &tmpBufReverbOutRight[0], len); if (reverbWetLeft != NULL) { reverbFloatToBit16sFunc(reverbWetLeft, &tmpBufReverbOutLeft[0], len, reverbOutputGain); } if (reverbWetRight != NULL) { reverbFloatToBit16sFunc(reverbWetRight, &tmpBufReverbOutRight[0], len, reverbOutputGain); } } partialManager->clearAlreadyOutputed(); renderedSampleCount += len; } void Synth::printPartialUsage(unsigned long sampleOffset) { unsigned int partialUsage[9]; partialManager->getPerPartPartialUsage(partialUsage); if (sampleOffset > 0) { printDebug("[+%lu] Partial Usage: 1:%02d 2:%02d 3:%02d 4:%02d 5:%02d 6:%02d 7:%02d 8:%02d R: %02d TOTAL: %02d", sampleOffset, partialUsage[0], partialUsage[1], partialUsage[2], partialUsage[3], partialUsage[4], partialUsage[5], partialUsage[6], partialUsage[7], partialUsage[8], MT32EMU_MAX_PARTIALS - partialManager->getFreePartialCount()); } else { printDebug("Partial Usage: 1:%02d 2:%02d 3:%02d 4:%02d 5:%02d 6:%02d 7:%02d 8:%02d R: %02d TOTAL: %02d", partialUsage[0], partialUsage[1], partialUsage[2], partialUsage[3], partialUsage[4], partialUsage[5], partialUsage[6], partialUsage[7], partialUsage[8], MT32EMU_MAX_PARTIALS - partialManager->getFreePartialCount()); } } bool Synth::hasActivePartials() const { if (prerenderReadIx != prerenderWriteIx) { // Data in the prerender buffer means that the current isActive() states are "in the future". // It also means that partials are definitely active at this render point. return true; } for (int partialNum = 0; partialNum < MT32EMU_MAX_PARTIALS; partialNum++) { if (partialManager->getPartial(partialNum)->isActive()) { return true; } } return false; } bool Synth::isActive() const { if (hasActivePartials()) { return true; } if (reverbEnabled) { return reverbModel->isActive(); } return false; } const Partial *Synth::getPartial(unsigned int partialNum) const { return partialManager->getPartial(partialNum); } const Part *Synth::getPart(unsigned int partNum) const { if (partNum > 8) { return NULL; } return parts[partNum]; } void MemoryRegion::read(unsigned int entry, unsigned int off, Bit8u *dst, unsigned int len) const { off += entry * entrySize; // This method should never be called with out-of-bounds parameters, // or on an unsupported region - seeing any of this debug output indicates a bug in the emulator if (off > entrySize * entries - 1) { #if MT32EMU_MONITOR_SYSEX > 0 synth->printDebug("read[%d]: parameters start out of bounds: entry=%d, off=%d, len=%d", type, entry, off, len); #endif return; } if (off + len > entrySize * entries) { #if MT32EMU_MONITOR_SYSEX > 0 synth->printDebug("read[%d]: parameters end out of bounds: entry=%d, off=%d, len=%d", type, entry, off, len); #endif len = entrySize * entries - off; } Bit8u *src = getRealMemory(); if (src == NULL) { #if MT32EMU_MONITOR_SYSEX > 0 synth->printDebug("read[%d]: unreadable region: entry=%d, off=%d, len=%d", type, entry, off, len); #endif return; } memcpy(dst, src + off, len); } void MemoryRegion::write(unsigned int entry, unsigned int off, const Bit8u *src, unsigned int len, bool init) const { unsigned int memOff = entry * entrySize + off; // This method should never be called with out-of-bounds parameters, // or on an unsupported region - seeing any of this debug output indicates a bug in the emulator if (off > entrySize * entries - 1) { #if MT32EMU_MONITOR_SYSEX > 0 synth->printDebug("write[%d]: parameters start out of bounds: entry=%d, off=%d, len=%d", type, entry, off, len); #endif return; } if (off + len > entrySize * entries) { #if MT32EMU_MONITOR_SYSEX > 0 synth->printDebug("write[%d]: parameters end out of bounds: entry=%d, off=%d, len=%d", type, entry, off, len); #endif len = entrySize * entries - off; } Bit8u *dest = getRealMemory(); if (dest == NULL) { #if MT32EMU_MONITOR_SYSEX > 0 synth->printDebug("write[%d]: unwritable region: entry=%d, off=%d, len=%d", type, entry, off, len); #endif } for (unsigned int i = 0; i < len; i++) { Bit8u desiredValue = src[i]; Bit8u maxValue = getMaxValue(memOff); // maxValue == 0 means write-protected unless called from initialisation code, in which case it really means the maximum value is 0. if (maxValue != 0 || init) { if (desiredValue > maxValue) { #if MT32EMU_MONITOR_SYSEX > 0 synth->printDebug("write[%d]: Wanted 0x%02x at %d, but max 0x%02x", type, desiredValue, memOff, maxValue); #endif desiredValue = maxValue; } dest[memOff] = desiredValue; } else if (desiredValue != 0) { #if MT32EMU_MONITOR_SYSEX > 0 // Only output debug info if they wanted to write non-zero, since a lot of things cause this to spit out a lot of debug info otherwise. synth->printDebug("write[%d]: Wanted 0x%02x at %d, but write-protected", type, desiredValue, memOff); #endif } memOff++; } } }