/** * Furnace Tracker - multi-system chiptune tracker * Copyright (C) 2021-2022 tildearrow and contributors * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (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 General Public License for more details. * * You should have received a copy of the GNU General Public License along * with this program; if not, write to the Free Software Foundation, Inc., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. */ #include "dataErrors.h" #include "song.h" #include #define _USE_MATH_DEFINES #include "engine.h" #include "instrument.h" #include "safeReader.h" #include "../ta-log.h" #include "../fileutils.h" #include "../audio/sdl.h" #include #ifndef _WIN32 #include #include #include #endif #ifdef HAVE_JACK #include "../audio/jack.h" #endif #include #include #include void process(void* u, float** in, float** out, int inChans, int outChans, unsigned int size) { ((DivEngine*)u)->nextBuf(in,out,inChans,outChans,size); } const char* DivEngine::getEffectDesc(unsigned char effect, int chan) { switch (effect) { case 0x00: return "00xy: Arpeggio"; case 0x01: return "01xx: Pitch slide up"; case 0x02: return "02xx: Pitch slide down"; case 0x03: return "03xx: Portamento"; case 0x04: return "04xy: Vibrato (x: speed; y: depth)"; case 0x07: return "07xy: Tremolo (x: speed; y: depth)"; case 0x08: return "08xy: Set panning (x: left; y: right)"; case 0x09: return "09xx: Set speed 1"; case 0x0a: return "0Axy: Volume slide (0y: down; x0: up)"; case 0x0b: return "0Bxx: Jump to pattern"; case 0x0c: return "0Cxx: Retrigger"; case 0x0d: return "0Dxx: Jump to next pattern"; case 0x0f: return "0Fxx: Set speed 2"; case 0xc0: case 0xc1: case 0xc2: case 0xc3: return "Cxxx: Set tick rate (hz)"; case 0xe0: return "E0xx: Set arp speed"; case 0xe1: return "E1xy: Note slide up (x: speed; y: semitones)"; case 0xe2: return "E2xy: Note slide down (x: speed; y: semitones)"; case 0xe3: return "E3xx: Set vibrato shape (0: up/down; 1: up only; 2: down only)"; case 0xe4: return "E4xx: Set vibrato range"; case 0xe5: return "E5xx: Set pitch (80: center)"; case 0xea: return "EAxx: Legato"; case 0xeb: return "EBxx: Set sample bank"; case 0xec: return "ECxx: Note cut"; case 0xed: return "EDxx: Note delay"; case 0xee: return "EExx: Send external command"; case 0xef: return "EFxx: Set global tuning (quirky!)"; case 0xf0: return "F0xx: Set tick rate (bpm)"; case 0xf1: return "F1xx: Single tick note slide up"; case 0xf2: return "F2xx: Single tick note slide down"; case 0xf3: return "F3xx: Fine volume slide up"; case 0xf4: return "F4xx: Fine volume slide down"; case 0xf8: return "F8xx: Single tick volume slide up"; case 0xf9: return "F9xx: Single tick volume slide down"; case 0xfa: return "FAxx: Fast volume slide (0y: down; x0: up)"; case 0xff: return "FFxx: Stop song"; default: if ((effect&0xf0)==0x90) { return "9xxx: Set sample offset*256"; } else if (chan>=0 && changetEffectName(effect); if (ret!=NULL) return ret; } break; } return "Invalid effect"; } void DivEngine::walkSong(int& loopOrder, int& loopRow, int& loopEnd) { loopOrder=0; loopRow=0; loopEnd=-1; int nextOrder=-1; int nextRow=0; int effectVal=0; DivPattern* pat[DIV_MAX_CHANS]; for (int i=0; idata[j][5+(l<<1)]; if (effectVal<0) effectVal=0; if (pat[k]->data[j][4+(l<<1)]==0x0d) { if (nextOrder==-1 && (idata[j][4+(l<<1)]==0x0b) { if (nextOrder==-1) { nextOrder=effectVal; nextRow=0; } } } } if (nextOrder!=-1) { if (nextOrder<=i) { loopOrder=nextOrder; loopRow=nextRow; loopEnd=i; return; } i=nextOrder-1; nextOrder=-1; break; } } } } void _runExportThread(DivEngine* caller) { caller->runExportThread(); } bool DivEngine::isExporting() { return exporting; } #define EXPORT_BUFSIZE 2048 void DivEngine::runExportThread() { switch (exportMode) { case DIV_EXPORT_MODE_ONE: { SNDFILE* sf; SF_INFO si; si.samplerate=got.rate; si.channels=2; si.format=SF_FORMAT_WAV|SF_FORMAT_PCM_16; sf=sf_open(exportPath.c_str(),SFM_WRITE,&si); if (sf==NULL) { logE("could not open file for writing! (%s)\n",sf_strerror(NULL)); exporting=false; return; } float* outBuf[3]; outBuf[0]=new float[EXPORT_BUFSIZE]; outBuf[1]=new float[EXPORT_BUFSIZE]; outBuf[2]=new float[EXPORT_BUFSIZE*2]; // take control of audio output deinitAudioBackend(); playSub(false); logI("rendering to file...\n"); while (playing) { nextBuf(NULL,outBuf,0,2,EXPORT_BUFSIZE); for (int i=0; iEXPORT_BUFSIZE) { logE("error: total processed is bigger than export bufsize! %d>%d\n",totalProcessed,EXPORT_BUFSIZE); } if (sf_writef_float(sf,outBuf[2],totalProcessed)!=(int)totalProcessed) { logE("error: failed to write entire buffer!\n"); break; } } delete[] outBuf[0]; delete[] outBuf[1]; delete[] outBuf[2]; if (sf_close(sf)!=0) { logE("could not close audio file!\n"); } exporting=false; if (initAudioBackend()) { for (int i=0; isetRun(true)) { logE("error while activating audio!\n"); } } logI("done!\n"); break; } case DIV_EXPORT_MODE_MANY_SYS: { SNDFILE* sf[32]; SF_INFO si[32]; String fname[32]; for (int i=0; iisStereo()) { si[i].channels=2; } else { si[i].channels=1; } si[i].format=SF_FORMAT_WAV|SF_FORMAT_PCM_16; } for (int i=0; iisStereo()) { sysBuf[j]=disCont[i].bbOut[0][j]; } else { sysBuf[j<<1]=disCont[i].bbOut[0][j]; sysBuf[1+(j<<1)]=disCont[i].bbOut[1][j]; } } if (totalProcessed>EXPORT_BUFSIZE) { logE("error: total processed is bigger than export bufsize! (%d) %d>%d\n",i,totalProcessed,EXPORT_BUFSIZE); } if (sf_writef_short(sf[i],sysBuf,totalProcessed)!=(int)totalProcessed) { logE("error: failed to write entire buffer! (%d)\n",i); break; } } } delete[] outBuf[0]; delete[] outBuf[1]; delete[] sysBuf; for (int i=0; isetRun(true)) { logE("error while activating audio!\n"); } } logI("done!\n"); break; } case DIV_EXPORT_MODE_MANY_CHAN: { // take control of audio output deinitAudioBackend(); float* outBuf[3]; outBuf[0]=new float[EXPORT_BUFSIZE]; outBuf[1]=new float[EXPORT_BUFSIZE]; outBuf[2]=new float[EXPORT_BUFSIZE*2]; int loopCount=remainingLoops; logI("rendering to files...\n"); for (int i=0; imuteChannel(dispatchChanOfChan[j],isMuted[j]); } } curOrder=0; remainingLoops=loopCount; playSub(false); while (playing) { nextBuf(NULL,outBuf,0,2,EXPORT_BUFSIZE); for (int j=0; jEXPORT_BUFSIZE) { logE("error: total processed is bigger than export bufsize! %d>%d\n",totalProcessed,EXPORT_BUFSIZE); } if (sf_writef_float(sf,outBuf[2],totalProcessed)!=(int)totalProcessed) { logE("error: failed to write entire buffer!\n"); break; } } if (sf_close(sf)!=0) { logE("could not close audio file!\n"); } } exporting=false; delete[] outBuf[0]; delete[] outBuf[1]; delete[] outBuf[2]; for (int i=0; imuteChannel(dispatchChanOfChan[i],false); } } if (initAudioBackend()) { for (int i=0; isetRun(true)) { logE("error while activating audio!\n"); } } logI("done!\n"); break; } } } bool DivEngine::saveAudio(const char* path, int loops, DivAudioExportModes mode) { exportPath=path; exportMode=mode; exporting=true; stop(); repeatPattern=false; setOrder(0); remainingLoops=loops; exportThread=new std::thread(_runExportThread,this); return true; } void DivEngine::waitAudioFile() { if (exportThread!=NULL) { exportThread->join(); } } bool DivEngine::haltAudioFile() { stop(); return true; } void DivEngine::notifyInsChange(int ins) { BUSY_BEGIN; for (int i=0; inotifyInsChange(ins); } BUSY_END; } void DivEngine::notifyWaveChange(int wave) { BUSY_BEGIN; for (int i=0; inotifyWaveChange(wave); } BUSY_END; } void DivEngine::renderSamplesP() { BUSY_BEGIN; renderSamples(); BUSY_END; } void DivEngine::renderSamples() { sPreview.sample=-1; sPreview.pos=0; // step 1: render samples for (int i=0; irender(); } // step 2: allocate ADPCM-A samples if (adpcmAMem==NULL) adpcmAMem=new unsigned char[16777216]; size_t memPos=0; for (int i=0; ilengthA+255)&(~0xff); if ((memPos&0xf00000)!=((memPos+paddedLen)&0xf00000)) { memPos=(memPos+0xfffff)&0xf00000; } if (memPos>=16777216) { logW("out of ADPCM-A memory for sample %d!\n",i); break; } if (memPos+paddedLen>=16777216) { memcpy(adpcmAMem+memPos,s->dataA,16777216-memPos); logW("out of ADPCM-A memory for sample %d!\n",i); } else { memcpy(adpcmAMem+memPos,s->dataA,paddedLen); } s->offA=memPos; memPos+=paddedLen; } adpcmAMemLen=memPos+256; // step 2: allocate ADPCM-B samples if (adpcmBMem==NULL) adpcmBMem=new unsigned char[16777216]; memPos=0; for (int i=0; ilengthB+255)&(~0xff); if ((memPos&0xf00000)!=((memPos+paddedLen)&0xf00000)) { memPos=(memPos+0xfffff)&0xf00000; } if (memPos>=16777216) { logW("out of ADPCM-B memory for sample %d!\n",i); break; } if (memPos+paddedLen>=16777216) { memcpy(adpcmBMem+memPos,s->dataB,16777216-memPos); logW("out of ADPCM-B memory for sample %d!\n",i); } else { memcpy(adpcmBMem+memPos,s->dataB,paddedLen); } s->offB=memPos; memPos+=paddedLen; } adpcmBMemLen=memPos+256; // step 4: allocate qsound pcm samples if (qsoundMem==NULL) qsoundMem=new unsigned char[16777216]; memset(qsoundMem,0,16777216); memPos=0; for (int i=0; ilength8; if (length>65536-16) { length=65536-16; } if ((memPos&0xff0000)!=((memPos+length)&0xff0000)) { memPos=(memPos+0xffff)&0xff0000; } if (memPos>=16777216) { logW("out of QSound PCM memory for sample %d!\n",i); break; } if (memPos+length>=16777216) { for (unsigned int i=0; i<16777216-(memPos+length); i++) { qsoundMem[(memPos+i)^0x8000]=s->data8[i]; } logW("out of QSound PCM memory for sample %d!\n",i); } else { for (int i=0; idata8[i]; } } s->offQSound=memPos^0x8000; memPos+=length+16; } qsoundMemLen=memPos+256; // step 4: allocate x1-010 pcm samples if (x1_010Mem==NULL) x1_010Mem=new unsigned char[1048576]; memset(x1_010Mem,0,1048576); memPos=0; for (int i=0; ilength8+4095)&(~0xfff); // fit sample bank size to 128KB for Seta 2 external bankswitching logic (not emulated yet!) if (paddedLen>131072) { paddedLen=131072; } if ((memPos&0xfe0000)!=((memPos+paddedLen)&0xfe0000)) { memPos=(memPos+0x1ffff)&0xfe0000; } if (memPos>=1048576) { logW("out of X1-010 memory for sample %d!\n",i); break; } if (memPos+paddedLen>=1048576) { memcpy(x1_010Mem+memPos,s->data8,1048576-memPos); logW("out of X1-010 memory for sample %d!\n",i); } else { memcpy(x1_010Mem+memPos,s->data8,paddedLen); } s->offX1_010=memPos; memPos+=paddedLen; } x1_010MemLen=memPos+256; } void DivEngine::createNew(const int* description) { quitDispatch(); BUSY_BEGIN; saveLock.lock(); song.unload(); song=DivSong(); if (description!=NULL) { if (description[0]!=0) { int index=0; for (int i=0; description[i]; i+=4) { song.system[index]=(DivSystem)description[i]; song.systemVol[index]=description[i+1]; song.systemPan[index]=description[i+2]; song.systemFlags[index]=description[i+3]; index++; if (index>=32) break; } song.systemLen=index; } } recalcChans(); renderSamples(); saveLock.unlock(); BUSY_END; initDispatch(); BUSY_BEGIN; reset(); BUSY_END; } void DivEngine::changeSystem(int index, DivSystem which) { quitDispatch(); BUSY_BEGIN; saveLock.lock(); song.system[index]=which; song.systemFlags[index]=0; recalcChans(); saveLock.unlock(); BUSY_END; initDispatch(); BUSY_BEGIN; renderSamples(); reset(); BUSY_END; } bool DivEngine::addSystem(DivSystem which) { if (song.systemLen>32) { lastError="max number of systems is 32"; return false; } // this was DIV_MAX_CHANS but I am setting it to 63 for now due to an ImGui limitation if (chans+getChannelCount(which)>63) { lastError="max number of total channels is 63"; return false; } quitDispatch(); BUSY_BEGIN; saveLock.lock(); song.system[song.systemLen]=which; song.systemVol[song.systemLen]=64; song.systemPan[song.systemLen]=0; song.systemFlags[song.systemLen++]=0; recalcChans(); saveLock.unlock(); BUSY_END; initDispatch(); BUSY_BEGIN; renderSamples(); reset(); BUSY_END; return true; } bool DivEngine::removeSystem(int index) { if (song.systemLen<=1) { lastError="cannot remove the last one"; return false; } if (index<0 || index>=song.systemLen) { lastError="invalid index"; return false; } quitDispatch(); BUSY_BEGIN; saveLock.lock(); song.system[index]=DIV_SYSTEM_NULL; song.systemLen--; for (int i=index; i=song.systemLen) return; BUSY_BEGIN; disCont[sys].dispatch->poke(addr,val); BUSY_END; } void DivEngine::poke(int sys, std::vector& wlist) { if (sys<0 || sys>=song.systemLen) return; BUSY_BEGIN; disCont[sys].dispatch->poke(wlist); BUSY_END; } String DivEngine::getLastError() { return lastError; } String DivEngine::getWarnings() { return warnings; } DivInstrument* DivEngine::getIns(int index) { if (index<0 || index>=song.insLen) return &song.nullIns; return song.ins[index]; } DivWavetable* DivEngine::getWave(int index) { if (index<0 || index>=song.waveLen) { if (song.waveLen>0) { return song.wave[0]; } else { return &song.nullWave; } } return song.wave[index]; } DivSample* DivEngine::getSample(int index) { if (index<0 || index>=song.sampleLen) return &song.nullSample; return song.sample[index]; } void DivEngine::setLoops(int loops) { remainingLoops=loops; } DivChannelState* DivEngine::getChanState(int ch) { if (ch<0 || ch>=chans) return NULL; return &chan[ch]; } void* DivEngine::getDispatchChanState(int ch) { if (ch<0 || ch>=chans) return NULL; return disCont[dispatchOfChan[ch]].dispatch->getChanState(dispatchChanOfChan[ch]); } unsigned char* DivEngine::getRegisterPool(int sys, int& size, int& depth) { if (sys<0 || sys>=song.systemLen) return NULL; if (disCont[sys].dispatch==NULL) return NULL; size=disCont[sys].dispatch->getRegisterPoolSize(); depth=disCont[sys].dispatch->getRegisterPoolDepth(); return disCont[sys].dispatch->getRegisterPool(); } void DivEngine::enableCommandStream(bool enable) { cmdStreamEnabled=enable; } void DivEngine::getCommandStream(std::vector& where) { BUSY_BEGIN; where.clear(); for (DivCommand& i: cmdStream) { where.push_back(i); } cmdStream.clear(); BUSY_END; } void DivEngine::playSub(bool preserveDrift, int goalRow) { for (int i=0; isetSkipRegisterWrites(false); reset(); if (preserveDrift && curOrder==0) return; bool oldRepeatPattern=repeatPattern; repeatPattern=false; int goal=curOrder; curOrder=0; curRow=0; stepPlay=0; int prevDrift; prevDrift=clockDrift; clockDrift=0; cycles=0; if (preserveDrift) { endOfSong=false; } else { ticks=1; totalTicks=0; totalSeconds=0; totalTicksR=0; } speedAB=false; playing=true; for (int i=0; isetSkipRegisterWrites(true); while (playing && curOrdersetSkipRegisterWrites(false); if (goal>0 || goalRow>0) { for (int i=0; iforceIns(); } for (int i=0; i4095) pitch=4095; return period? ((base*(reversePitchTable[pitch]))/whatTheFuck): (((base*(pitchTable[pitch]))>>10)*whatTheFuck)/1024; } return period? base-pitch: base+((pitch*octave)>>1); } void DivEngine::play() { BUSY_BEGIN_SOFT; sPreview.sample=-1; sPreview.wave=-1; sPreview.pos=0; if (stepPlay==0) { freelance=false; playSub(false); } else { stepPlay=0; } for (int i=0; inotifyPlaybackStop(); } BUSY_END; } void DivEngine::halt() { BUSY_BEGIN; halted=true; BUSY_END; } void DivEngine::resume() { BUSY_BEGIN; halted=false; haltOn=DIV_HALT_NONE; BUSY_END; } void DivEngine::haltWhen(DivHaltPositions when) { BUSY_BEGIN; halted=false; haltOn=when; BUSY_END; } bool DivEngine::isHalted() { return halted; } const char** DivEngine::getRegisterSheet(int sys) { if (sys<0 || sys>=song.systemLen) return NULL; return disCont[sys].dispatch->getRegisterSheet(); } void DivEngine::recalcChans() { chans=0; int chanIndex=0; for (int i=0; idispatch(DivCommand(DIV_CMD_GET_VOLMAX,dispatchChanOfChan[i]))<<8)|0xff; chan[i].volume=chan[i].volMax; if (!song.linearPitch) chan[i].vibratoFine=4; } extValue=0; extValuePresent=0; speed1=song.speed1; speed2=song.speed2; firstTick=false; nextSpeed=speed1; divider=60; if (song.customTempo) { divider=song.hz; } else { if (song.pal) { divider=60; } else { divider=50; } } globalPitch=0; for (int i=0; ireset(); disCont[i].clear(); } } void DivEngine::syncReset() { BUSY_BEGIN; reset(); BUSY_END; } const int sampleRates[6]={ 4000, 8000, 11025, 16000, 22050, 32000 }; int DivEngine::fileToDivRate(int frate) { if (frate<0) frate=0; if (frate>5) frate=5; return sampleRates[frate]; } int DivEngine::divToFileRate(int drate) { if (drate>26000) { return 5; } else if (drate>18000) { return 4; } else if (drate>14000) { return 3; } else if (drate>9500) { return 2; } else if (drate>6000) { return 1; } else { return 0; } return 4; } int DivEngine::getEffectiveSampleRate(int rate) { if (rate<1) return 0; switch (song.system[0]) { case DIV_SYSTEM_YMU759: return 8000; case DIV_SYSTEM_YM2612: case DIV_SYSTEM_YM2612_EXT: return 1278409/(1280000/rate); case DIV_SYSTEM_PCE: return 1789773/(1789773/rate); case DIV_SYSTEM_SEGAPCM: case DIV_SYSTEM_SEGAPCM_COMPAT: return (31250*MIN(255,(rate*255/31250)))/255; case DIV_SYSTEM_QSOUND: return (24038*MIN(65535,(rate*4096/24038)))/4096; case DIV_SYSTEM_YM2610: case DIV_SYSTEM_YM2610_EXT: case DIV_SYSTEM_YM2610_FULL: case DIV_SYSTEM_YM2610_FULL_EXT: case DIV_SYSTEM_YM2610B: case DIV_SYSTEM_YM2610B_EXT: return 18518; case DIV_SYSTEM_VERA: return (48828*MIN(128,(rate*128/48828)))/128; case DIV_SYSTEM_X1_010: return (31250*MIN(255,(rate*16/31250)))/16; // TODO: support variable clock case default: break; } return rate; } void DivEngine::previewSample(int sample, int note) { BUSY_BEGIN; if (sample<0 || sample>=(int)song.sample.size()) { sPreview.sample=-1; sPreview.pos=0; BUSY_END; return; } blip_clear(samp_bb); double rate=song.sample[sample]->rate; if (note>=0) { rate=(song.tuning*pow(2.0,(double)(note+3)/12.0)*((double)song.sample[sample]->centerRate/8363.0)); if (rate<=0) rate=song.sample[sample]->rate; } if (rate<100) rate=100; blip_set_rates(samp_bb,rate,got.rate); samp_prevSample=0; sPreview.pos=0; sPreview.sample=sample; sPreview.wave=-1; BUSY_END; } void DivEngine::stopSamplePreview() { BUSY_BEGIN; sPreview.sample=-1; sPreview.pos=0; BUSY_END; } void DivEngine::previewWave(int wave, int note) { BUSY_BEGIN; if (wave<0 || wave>=(int)song.wave.size()) { sPreview.wave=-1; sPreview.pos=0; BUSY_END; return; } if (song.wave[wave]->len<=0) { BUSY_END; return; } blip_clear(samp_bb); double rate=song.wave[wave]->len*((song.tuning*0.0625)*pow(2.0,(double)(note+3)/12.0)); if (rate<100) rate=100; blip_set_rates(samp_bb,rate,got.rate); samp_prevSample=0; sPreview.pos=0; sPreview.sample=-1; sPreview.wave=wave; BUSY_END; } void DivEngine::stopWavePreview() { BUSY_BEGIN; sPreview.wave=-1; sPreview.pos=0; BUSY_END; } String DivEngine::getConfigPath() { return configPath; } int DivEngine::getMaxVolumeChan(int ch) { return chan[ch].volMax>>8; } unsigned char DivEngine::getOrder() { return curOrder; } int DivEngine::getRow() { return curRow; } unsigned char DivEngine::getSpeed1() { return speed1; } unsigned char DivEngine::getSpeed2() { return speed2; } float DivEngine::getHz() { if (song.customTempo) { return song.hz; } else if (song.pal) { return 60.0; } else { return 50.0; } return 60.0; } float DivEngine::getCurHz() { return divider; } int DivEngine::getTotalSeconds() { return totalSeconds; } int DivEngine::getTotalTicks() { return totalTicks; } bool DivEngine::getRepeatPattern() { return repeatPattern; } void DivEngine::setRepeatPattern(bool value) { BUSY_BEGIN; repeatPattern=value; BUSY_END; } bool DivEngine::hasExtValue() { return extValuePresent; } unsigned char DivEngine::getExtValue() { return extValue; } bool DivEngine::isPlaying() { return (playing && !freelance); } bool DivEngine::isStepping() { return !(stepPlay==0); } bool DivEngine::isChannelMuted(int chan) { return isMuted[chan]; } void DivEngine::toggleMute(int chan) { muteChannel(chan,!isMuted[chan]); } void DivEngine::toggleSolo(int chan) { bool solo=false; for (int i=0; imuteChannel(dispatchChanOfChan[i],isMuted[i]); } } } else { for (int i=0; imuteChannel(dispatchChanOfChan[i],isMuted[i]); } } } BUSY_END; } void DivEngine::muteChannel(int chan, bool mute) { BUSY_BEGIN; isMuted[chan]=mute; if (disCont[dispatchOfChan[chan]].dispatch!=NULL) { disCont[dispatchOfChan[chan]].dispatch->muteChannel(dispatchChanOfChan[chan],isMuted[chan]); } BUSY_END; } void DivEngine::unmuteAll() { BUSY_BEGIN; for (int i=0; imuteChannel(dispatchChanOfChan[i],isMuted[i]); } } BUSY_END; } int DivEngine::addInstrument(int refChan) { BUSY_BEGIN; DivInstrument* ins=new DivInstrument; int insCount=(int)song.ins.size(); ins->name=fmt::sprintf("Instrument %d",insCount); ins->type=getPreferInsType(refChan); saveLock.lock(); song.ins.push_back(ins); song.insLen=insCount+1; saveLock.unlock(); BUSY_END; return insCount; } enum DivInsFormats { DIV_INSFORMAT_DMP, DIV_INSFORMAT_TFI, DIV_INSFORMAT_VGI, DIV_INSFORMAT_FTI, DIV_INSFORMAT_BTI, DIV_INSFORMAT_S3I, DIV_INSFORMAT_SBI, }; // TODO: re-organize this function to: // - support replacing instruments // - support instrument formats which contain multiple instruments bool DivEngine::addInstrumentFromFile(const char* path) { warnings=""; const char* pathRedux=strrchr(path,DIR_SEPARATOR); if (pathRedux==NULL) { pathRedux=path; } else { pathRedux++; } String stripPath; const char* pathReduxEnd=strrchr(pathRedux,'.'); if (pathReduxEnd==NULL) { stripPath=pathRedux; } else { for (const char* i=pathRedux; i!=pathReduxEnd && (*i); i++) { stripPath+=*i; } } FILE* f=ps_fopen(path,"rb"); if (f==NULL) { lastError=strerror(errno); return false; } unsigned char* buf; ssize_t len; if (fseek(f,0,SEEK_END)!=0) { lastError=strerror(errno); fclose(f); return false; } len=ftell(f); if (len<0) { lastError=strerror(errno); fclose(f); return false; } if (len==0) { lastError=strerror(errno); fclose(f); return false; } if (fseek(f,0,SEEK_SET)!=0) { lastError=strerror(errno); fclose(f); return false; } buf=new unsigned char[len]; if (fread(buf,1,len,f)!=(size_t)len) { logW("did not read entire instrument file buffer!\n"); lastError="did not read entire instrument file!"; delete[] buf; return false; } fclose(f); SafeReader reader=SafeReader(buf,len); unsigned char magic[16]; bool isFurnaceInstr=false; try { reader.read(magic,16); if (memcmp("-Furnace instr.-",magic,16)==0) { isFurnaceInstr=true; } } catch (EndOfFileException& e) { reader.seek(0,SEEK_SET); } DivInstrument* ins=new DivInstrument; if (isFurnaceInstr) { try { short version=reader.readS(); reader.readS(); // reserved if (version>DIV_ENGINE_VERSION) { warnings="this instrument is made with a more recent version of Furnace!"; } unsigned int dataPtr=reader.readI(); reader.seek(dataPtr,SEEK_SET); if (ins->readInsData(reader,version)!=DIV_DATA_SUCCESS) { lastError="invalid instrument header/data!"; delete ins; delete[] buf; return false; } } catch (EndOfFileException& e) { lastError="premature end of file"; logE("premature end of file!\n"); delete ins; delete[] buf; return false; } } else { // read as a different format const char* ext=strrchr(path,'.'); DivInsFormats format=DIV_INSFORMAT_DMP; if (ext!=NULL) { String extS; for (; *ext; ext++) { char i=*ext; if (i>='A' && i<='Z') { i+='a'-'A'; } extS+=i; } if (extS==String(".dmp")) { format=DIV_INSFORMAT_DMP; } else if (extS==String(".tfi")) { format=DIV_INSFORMAT_TFI; } else if (extS==String(".vgi")) { format=DIV_INSFORMAT_VGI; } else if (extS==String(".fti")) { format=DIV_INSFORMAT_FTI; } else if (extS==String(".bti")) { format=DIV_INSFORMAT_BTI; } else if (extS==String(".s3i")) { format = DIV_INSFORMAT_S3I; } else if (extS==String(".sbi")) { format = DIV_INSFORMAT_SBI; } } // TDOO these really should be re-organized to separate functions per instrument file type. switch (format) { case DIV_INSFORMAT_DMP: { // this is a ridiculous mess unsigned char version=0; unsigned char sys=0; try { reader.seek(0,SEEK_SET); version=reader.readC(); } catch (EndOfFileException& e) { lastError="premature end of file"; logE("premature end of file!\n"); delete ins; delete[] buf; return false; } if (version>11) { lastError="unknown instrument version!"; delete ins; delete[] buf; return false; } ins->name=stripPath; if (version>=11) { // 1.0 try { sys=reader.readC(); switch (sys) { case 1: // YMU759 ins->type=DIV_INS_FM; break; case 2: // Genesis ins->type=DIV_INS_FM; break; case 3: // SMS ins->type=DIV_INS_STD; break; case 4: // Game Boy ins->type=DIV_INS_GB; break; case 5: // PC Engine ins->type=DIV_INS_PCE; break; case 6: // NES ins->type=DIV_INS_STD; break; case 7: case 0x17: // C64 ins->type=DIV_INS_C64; break; case 8: // Arcade ins->type=DIV_INS_FM; break; default: lastError="unknown instrument type!"; delete ins; delete[] buf; return false; break; } } catch (EndOfFileException& e) { lastError="premature end of file"; logE("premature end of file!\n"); delete ins; delete[] buf; return false; } } try { bool mode=true; if (version>1) { mode=reader.readC(); if (mode==0) { if (version<11) { ins->type=DIV_INS_STD; } } else { ins->type=DIV_INS_FM; } } else { ins->type=DIV_INS_FM; } if (mode) { // FM if (version<10) { if (version>1) { ins->fm.ops=reader.readC()?4:2; } else { ins->fm.ops=reader.readC()?2:4; } } if (version>1) { // HELP! in which version of the format did we start storing FMS! ins->fm.fms=reader.readC(); } ins->fm.fb=reader.readC(); ins->fm.alg=reader.readC(); // DITTO if (sys!=1) ins->fm.ams=reader.readC(); for (int j=0; jfm.ops; j++) { ins->fm.op[j].mult=reader.readC(); ins->fm.op[j].tl=reader.readC(); ins->fm.op[j].ar=reader.readC(); ins->fm.op[j].dr=reader.readC(); ins->fm.op[j].sl=reader.readC(); ins->fm.op[j].rr=reader.readC(); ins->fm.op[j].am=reader.readC(); // what the hell how do I tell! if (sys==1) { // YMU759 ins->fm.op[j].ws=reader.readC(); ins->fm.op[j].ksl=reader.readC(); ins->fm.op[j].vib=reader.readC(); ins->fm.op[j].egt=reader.readC(); ins->fm.op[j].sus=reader.readC(); ins->fm.op[j].ksr=reader.readC(); ins->fm.op[j].dvb=reader.readC(); ins->fm.op[j].dam=reader.readC(); } else { ins->fm.op[j].rs=reader.readC(); ins->fm.op[j].dt=reader.readC(); ins->fm.op[j].dt2=ins->fm.op[j].dt>>4; ins->fm.op[j].dt&=15; ins->fm.op[j].d2r=reader.readC(); ins->fm.op[j].ssgEnv=reader.readC(); } } } else { // STD if (ins->type!=DIV_INS_GB) { ins->std.volMacroLen=reader.readC(); if (version>5) { for (int i=0; istd.volMacroLen; i++) { ins->std.volMacro[i]=reader.readI(); } } else { for (int i=0; istd.volMacroLen; i++) { ins->std.volMacro[i]=reader.readC(); } } if (version<11) for (int i=0; istd.volMacroLen; i++) { if (ins->std.volMacro[i]>15 && ins->type==DIV_INS_STD) ins->type=DIV_INS_PCE; } if (ins->std.volMacroLen>0) { ins->std.volMacroOpen=true; ins->std.volMacroLoop=reader.readC(); } else { ins->std.volMacroOpen=false; } } ins->std.arpMacroLen=reader.readC(); if (version>5) { for (int i=0; istd.arpMacroLen; i++) { ins->std.arpMacro[i]=reader.readI(); } } else { for (int i=0; istd.arpMacroLen; i++) { ins->std.arpMacro[i]=reader.readC(); } } if (ins->std.arpMacroLen>0) { ins->std.arpMacroOpen=true; ins->std.arpMacroLoop=reader.readC(); } else { ins->std.arpMacroOpen=false; } if (version>8) { // TODO: when? ins->std.arpMacroMode=reader.readC(); } ins->std.dutyMacroLen=reader.readC(); if (version>5) { for (int i=0; istd.dutyMacroLen; i++) { ins->std.dutyMacro[i]=reader.readI(); } } else { for (int i=0; istd.dutyMacroLen; i++) { ins->std.dutyMacro[i]=reader.readC(); } } if (ins->std.dutyMacroLen>0) { ins->std.dutyMacroOpen=true; ins->std.dutyMacroLoop=reader.readC(); } else { ins->std.dutyMacroOpen=false; } ins->std.waveMacroLen=reader.readC(); if (version>5) { for (int i=0; istd.waveMacroLen; i++) { ins->std.waveMacro[i]=reader.readI(); } } else { for (int i=0; istd.waveMacroLen; i++) { ins->std.waveMacro[i]=reader.readC(); } } if (ins->std.waveMacroLen>0) { ins->std.waveMacroOpen=true; ins->std.waveMacroLoop=reader.readC(); } else { ins->std.waveMacroOpen=false; } if (ins->type==DIV_INS_C64) { ins->c64.triOn=reader.readC(); ins->c64.sawOn=reader.readC(); ins->c64.pulseOn=reader.readC(); ins->c64.noiseOn=reader.readC(); ins->c64.a=reader.readC(); ins->c64.d=reader.readC(); ins->c64.s=reader.readC(); ins->c64.r=reader.readC(); ins->c64.duty=(reader.readC()*4095)/100; ins->c64.ringMod=reader.readC(); ins->c64.oscSync=reader.readC(); ins->c64.toFilter=reader.readC(); if (version<0x07) { // TODO: UNSURE ins->c64.volIsCutoff=reader.readI(); } else { ins->c64.volIsCutoff=reader.readC(); } ins->c64.initFilter=reader.readC(); ins->c64.res=reader.readC(); ins->c64.cut=(reader.readC()*2047)/100; ins->c64.hp=reader.readC(); ins->c64.bp=reader.readC(); ins->c64.lp=reader.readC(); ins->c64.ch3off=reader.readC(); } if (ins->type==DIV_INS_GB) { ins->gb.envVol=reader.readC(); ins->gb.envDir=reader.readC(); ins->gb.envLen=reader.readC(); ins->gb.soundLen=reader.readC(); } } } catch (EndOfFileException& e) { lastError="premature end of file"; logE("premature end of file!\n"); delete ins; delete[] buf; return false; } break; } case DIV_INSFORMAT_TFI: try { reader.seek(0,SEEK_SET); ins->type=DIV_INS_FM; ins->name=stripPath; ins->fm.alg=reader.readC(); ins->fm.fb=reader.readC(); for (int i=0; i<4; i++) { DivInstrumentFM::Operator& op=ins->fm.op[i]; op.mult=reader.readC(); op.dt=reader.readC(); op.tl=reader.readC(); op.rs=reader.readC(); op.ar=reader.readC(); op.dr=reader.readC(); op.d2r=reader.readC(); op.rr=reader.readC(); op.sl=reader.readC(); op.ssgEnv=reader.readC(); } } catch (EndOfFileException& e) { lastError="premature end of file"; logE("premature end of file!\n"); delete ins; delete[] buf; return false; } break; case DIV_INSFORMAT_VGI: try { reader.seek(0,SEEK_SET); ins->type=DIV_INS_FM; ins->name=stripPath; ins->fm.alg=reader.readC(); ins->fm.fb=reader.readC(); unsigned char fmsams=reader.readC(); ins->fm.fms=fmsams&7; ins->fm.ams=fmsams>>4; for (int i=0; i<4; i++) { DivInstrumentFM::Operator& op=ins->fm.op[i]; op.mult=reader.readC(); op.dt=reader.readC(); op.tl=reader.readC(); op.rs=reader.readC(); op.ar=reader.readC(); op.dr=reader.readC(); if (op.dr&0x80) { op.am=1; op.dr&=0x7f; } op.d2r=reader.readC(); op.rr=reader.readC(); op.sl=reader.readC(); op.ssgEnv=reader.readC(); } } catch (EndOfFileException& e) { lastError="premature end of file"; logE("premature end of file!\n"); delete ins; delete[] buf; return false; } break; case DIV_INSFORMAT_FTI: break; case DIV_INSFORMAT_BTI: break; case DIV_INSFORMAT_S3I: try { reader.seek(0, SEEK_SET); uint8_t s3i_type = reader.readC(); if (s3i_type >= 2) { ins->type = DIV_INS_OPL; // skip internal filename - we'll use the long name description reader.seek(12, SEEK_CUR); // skip reserved bytes reader.seek(3, SEEK_CUR); // 12-byte opl value uint8_t s3i_Mcharacteristics = reader.readC(); uint8_t s3i_Ccharacteristics = reader.readC(); uint8_t s3i_Mscaling_output = reader.readC(); uint8_t s3i_Cscaling_output = reader.readC(); uint8_t s3i_Meg_AD = reader.readC(); uint8_t s3i_Ceg_AD = reader.readC(); uint8_t s3i_Meg_SR = reader.readC(); uint8_t s3i_Ceg_SR = reader.readC(); uint8_t s3i_Mwave = reader.readC(); uint8_t s3i_Cwave = reader.readC(); uint8_t s3i_FeedConnect = reader.readC(); DivInstrumentFM::Operator& opM = ins->fm.op[0]; DivInstrumentFM::Operator& opC = ins->fm.op[1]; ins->fm.ops = 2; opM.mult = s3i_Mcharacteristics & 0xF; opM.ksr = ((s3i_Mcharacteristics >> 4) & 0x1); opM.sus = ((s3i_Mcharacteristics >> 5) & 0x1); opM.vib = ((s3i_Mcharacteristics >> 6) & 0x1); opM.am = ((s3i_Mcharacteristics >> 7) & 0x1); opM.tl = s3i_Mscaling_output & 0x3F; opM.ksl = ((s3i_Mscaling_output >> 6) & 0x3); opM.ar = ((s3i_Meg_AD >> 4) & 0xF); opM.dr = (s3i_Meg_AD & 0xF); opM.rr = (s3i_Meg_SR & 0xF); opM.sl = ((s3i_Meg_SR >> 4) & 0xF); opM.ws = s3i_Mwave; ins->fm.alg = (s3i_FeedConnect & 0x1); ins->fm.fb = ((s3i_FeedConnect >> 1) & 0x7); opC.mult = s3i_Ccharacteristics & 0xF; opC.ksr = ((s3i_Ccharacteristics >> 4) & 0x1); opC.sus = ((s3i_Ccharacteristics >> 5) & 0x1); opC.vib = ((s3i_Ccharacteristics >> 6) & 0x1); opC.am = ((s3i_Ccharacteristics >> 7) & 0x1); opC.tl = s3i_Cscaling_output & 0x3F; opC.ksl = ((s3i_Cscaling_output >> 6) & 0x3); opC.ar = ((s3i_Ceg_AD >> 4) & 0xF); opC.dr = (s3i_Ceg_AD & 0xF); opC.rr = (s3i_Ceg_SR & 0xF); opC.sl = ((s3i_Ceg_SR >> 4) & 0xF); opC.ws = s3i_Cwave; // Skip more stuff we don't need reader.seek(21, SEEK_CUR); } else { logE("S3I PCM samples currently not supported."); } ins->name = reader.readString(28); int s3i_signature = reader.readI(); if (s3i_signature != 0x49524353) { logW("S3I signature invalid."); }; } catch (EndOfFileException& e) { lastError = "premature end of file"; logE("premature end of file!\n"); delete ins; delete[] buf; return false; } break; case DIV_INSFORMAT_SBI: try { reader.seek(0, SEEK_SET); ins->type = DIV_INS_OPL; int sbi_header = reader.readI(); // SBI header determines format bool is_2op = (sbi_header == 0x1A494253); // SBI\x1A bool is_4op = (sbi_header == 0x1A504F34); // 4OP\x1A bool is_6op = (sbi_header == 0x1A504F36); // 6OP\x1A - Freq Monster 801-specific // 32-byte null terminated instrument name ins->name = reader.readString(32); // 2op SBI uint8_t sbi_Mcharacteristics = reader.readC(); uint8_t sbi_Ccharacteristics = reader.readC(); uint8_t sbi_Mscaling_output = reader.readC(); uint8_t sbi_Cscaling_output = reader.readC(); uint8_t sbi_Meg_AD = reader.readC(); uint8_t sbi_Ceg_AD = reader.readC(); uint8_t sbi_Meg_SR = reader.readC(); uint8_t sbi_Ceg_SR = reader.readC(); uint8_t sbi_Mwave = reader.readC(); uint8_t sbi_Cwave = reader.readC(); uint8_t sbi_FeedConnect = reader.readC(); // 4op SBI uint8_t sbi_M4characteristics; uint8_t sbi_C4characteristics; uint8_t sbi_M4scaling_output; uint8_t sbi_C4scaling_output; uint8_t sbi_M4eg_AD; uint8_t sbi_C4eg_AD; uint8_t sbi_M4eg_SR; uint8_t sbi_C4eg_SR; uint8_t sbi_M4wave; uint8_t sbi_C4wave; uint8_t sbi_4opConnect; if (is_2op) { DivInstrumentFM::Operator& opM = ins->fm.op[0]; DivInstrumentFM::Operator& opC = ins->fm.op[1]; ins->fm.ops = 2; opM.mult = sbi_Mcharacteristics & 0xF; opM.ksr = ((sbi_Mcharacteristics >> 4) & 0x1); opM.sus = ((sbi_Mcharacteristics >> 5) & 0x1); opM.vib = ((sbi_Mcharacteristics >> 6) & 0x1); opM.am = ((sbi_Mcharacteristics >> 7) & 0x1); opM.tl = sbi_Mscaling_output & 0x3F; opM.ksl = ((sbi_Mscaling_output >> 6) & 0x3); opM.ar = ((sbi_Meg_AD >> 4) & 0xF); opM.dr = (sbi_Meg_AD & 0xF); opM.rr = (sbi_Meg_SR & 0xF); opM.sl = ((sbi_Meg_SR >> 4) & 0xF); opM.ws = sbi_Mwave; ins->fm.alg = (sbi_FeedConnect & 0x1); ins->fm.fb = ((sbi_FeedConnect >> 1) & 0x7); opC.mult = sbi_Ccharacteristics & 0xF; opC.ksr = ((sbi_Ccharacteristics >> 4) & 0x1); opC.sus = ((sbi_Ccharacteristics >> 5) & 0x1); opC.vib = ((sbi_Ccharacteristics >> 6) & 0x1); opC.am = ((sbi_Ccharacteristics >> 7) & 0x1); opC.tl = sbi_Cscaling_output & 0x3F; opC.ksl = ((sbi_Cscaling_output >> 6) & 0x3); opC.ar = ((sbi_Ceg_AD >> 4) & 0xF); opC.dr = (sbi_Ceg_AD & 0xF); opC.rr = (sbi_Ceg_SR & 0xF); opC.sl = ((sbi_Ceg_SR >> 4) & 0xF); opC.ws = sbi_Cwave; // Ignore rest of file - rest is 'reserved padding'. reader.seek(0, SEEK_END); } if (is_4op || is_6op) { // Operator placement is different so need to place in correct registers. // Note: 6op is an unofficial extension of 4op SBIs by Darron Broad (Freq Monster 801). // We'll only use the 4op portion here for pure OPL3. DivInstrumentFM::Operator& opM = ins->fm.op[0]; DivInstrumentFM::Operator& opC = ins->fm.op[2]; DivInstrumentFM::Operator& opM4 = ins->fm.op[1]; DivInstrumentFM::Operator& opC4 = ins->fm.op[3]; ins->fm.ops = 4; sbi_M4characteristics = reader.readC(); sbi_C4characteristics = reader.readC(); sbi_M4scaling_output = reader.readC(); sbi_C4scaling_output = reader.readC(); sbi_M4eg_AD = reader.readC(); sbi_C4eg_AD = reader.readC(); sbi_M4eg_SR = reader.readC(); sbi_C4eg_SR = reader.readC(); sbi_M4wave = reader.readC(); sbi_C4wave = reader.readC(); sbi_4opConnect = reader.readC(); ins->fm.alg = (sbi_FeedConnect & 0x1) | ((sbi_4opConnect & 0x1) << 1); ins->fm.fb = ((sbi_FeedConnect >> 1) & 0x7); opM.mult = sbi_Mcharacteristics & 0xF; opM.ksr = ((sbi_Mcharacteristics >> 4) & 0x1); opM.sus = ((sbi_Mcharacteristics >> 5) & 0x1); opM.vib = ((sbi_Mcharacteristics >> 6) & 0x1); opM.am = ((sbi_Mcharacteristics >> 7) & 0x1); opM.tl = sbi_Mscaling_output & 0x3F; opM.ksl = ((sbi_Mscaling_output >> 6) & 0x3); opM.ar = ((sbi_Meg_AD >> 4) & 0xF); opM.dr = (sbi_Meg_AD & 0xF); opM.rr = (sbi_Meg_SR & 0xF); opM.sl = ((sbi_Meg_SR >> 4) & 0xF); opM.ws = sbi_Mwave; opC.mult = sbi_Ccharacteristics & 0xF; opC.ksr = ((sbi_Ccharacteristics >> 4) & 0x1); opC.sus = ((sbi_Ccharacteristics >> 5) & 0x1); opC.vib = ((sbi_Ccharacteristics >> 6) & 0x1); opC.am = ((sbi_Ccharacteristics >> 7) & 0x1); opC.tl = sbi_Cscaling_output & 0x3F; opC.ksl = ((sbi_Cscaling_output >> 6) & 0x3); opC.ar = ((sbi_Ceg_AD >> 4) & 0xF); opC.dr = (sbi_Ceg_AD & 0xF); opC.rr = (sbi_Ceg_SR & 0xF); opC.sl = ((sbi_Ceg_SR >> 4) & 0xF); opC.ws = sbi_Cwave; opM4.mult = sbi_M4characteristics & 0xF; opM4.ksr = ((sbi_M4characteristics >> 4) & 0x1); opM4.sus = ((sbi_M4characteristics >> 5) & 0x1); opM4.vib = ((sbi_M4characteristics >> 6) & 0x1); opM4.am = ((sbi_M4characteristics >> 7) & 0x1); opM4.tl = sbi_M4scaling_output & 0x3F; opM4.ksl = ((sbi_M4scaling_output >> 6) & 0x3); opM4.ar = ((sbi_M4eg_AD >> 4) & 0xF); opM4.dr = (sbi_M4eg_AD & 0xF); opM4.rr = (sbi_M4eg_SR & 0xF); opM4.sl = ((sbi_M4eg_SR >> 4) & 0xF); opM4.ws = sbi_M4wave; opC4.mult = sbi_C4characteristics & 0xF; opC4.ksr = ((sbi_C4characteristics >> 4) & 0x1); opC4.sus = ((sbi_C4characteristics >> 5) & 0x1); opC4.vib = ((sbi_C4characteristics >> 6) & 0x1); opC4.am = ((sbi_C4characteristics >> 7) & 0x1); opC4.tl = sbi_C4scaling_output & 0x3F; opC4.ksl = ((sbi_C4scaling_output >> 6) & 0x3); opC4.ar = ((sbi_C4eg_AD >> 4) & 0xF); opC4.dr = (sbi_C4eg_AD & 0xF); opC4.rr = (sbi_C4eg_SR & 0xF); opC4.sl = ((sbi_C4eg_SR >> 4) & 0xF); opC4.ws = sbi_C4wave; // Ignore rest of file once we've read in all we need. // Note: Freq Monster 801 adds a ton of other additional fields irrelevant to chip registers. reader.seek(0, SEEK_END); } } catch (EndOfFileException& e) { lastError = "premature end of file"; logE("premature end of file!\n"); delete ins; delete[] buf; return false; } break; } if (reader.tell()=0 && index<(int)song.ins.size()) { for (int i=0; inotifyInsDeletion(song.ins[index]); } delete song.ins[index]; song.ins.erase(song.ins.begin()+index); song.insLen=song.ins.size(); for (int i=0; idata[k][2]>index) { song.pat[i].data[j]->data[k][2]--; } } } } } saveLock.unlock(); BUSY_END; } int DivEngine::addWave() { BUSY_BEGIN; saveLock.lock(); DivWavetable* wave=new DivWavetable; int waveCount=(int)song.wave.size(); song.wave.push_back(wave); song.waveLen=waveCount+1; saveLock.unlock(); BUSY_END; return waveCount; } bool DivEngine::addWaveFromFile(const char* path) { FILE* f=ps_fopen(path,"rb"); if (f==NULL) { return false; } unsigned char* buf; ssize_t len; if (fseek(f,0,SEEK_END)!=0) { fclose(f); return false; } len=ftell(f); if (len<0) { fclose(f); return false; } if (len==0) { fclose(f); return false; } if (fseek(f,0,SEEK_SET)!=0) { fclose(f); return false; } buf=new unsigned char[len]; if (fread(buf,1,len,f)!=(size_t)len) { logW("did not read entire wavetable file buffer!\n"); delete[] buf; return false; } fclose(f); SafeReader reader=SafeReader(buf,len); unsigned char magic[16]; bool isFurnaceTable=false; try { reader.read(magic,16); if (memcmp("-Furnace waveta-",magic,16)==0) { isFurnaceTable=true; } } catch (EndOfFileException& e) { reader.seek(0,SEEK_SET); } DivWavetable* wave=new DivWavetable; try { if (isFurnaceTable) { reader.seek(16,SEEK_SET); short version=reader.readS(); reader.readS(); // reserved reader.seek(20,SEEK_SET); if (wave->readWaveData(reader,version)!=DIV_DATA_SUCCESS) { lastError="invalid wavetable header/data!"; delete wave; delete[] buf; return false; } } else { try { // read as .dmw reader.seek(0,SEEK_SET); int len=reader.readI(); wave->max=(unsigned char)reader.readC(); if (wave->max==255) { // new wavetable format unsigned char waveVersion=reader.readC(); logI("reading modern .dmw...\n"); logD("wave version %d\n",waveVersion); wave->max=reader.readC(); for (int i=0; idata[i]=reader.readI(); } } else if (reader.size()==(size_t)(len+5)) { // read as .dmw logI("reading .dmw...\n"); if (len>256) len=256; for (int i=0; idata[i]=(unsigned char)reader.readC(); } } else { // read as binary logI("reading binary...\n"); len=reader.size(); if (len>256) len=256; reader.seek(0,SEEK_SET); for (int i=0; idata[i]=(unsigned char)reader.readC(); if (wave->maxdata[i]) wave->max=wave->data[i]; } wave->len=len; } } catch (EndOfFileException& e) { // read as binary len=reader.size(); logI("reading binary for being too small...\n"); if (len>256) len=256; reader.seek(0,SEEK_SET); for (int i=0; idata[i]=(unsigned char)reader.readC(); if (wave->maxdata[i]) wave->max=wave->data[i]; } wave->len=len; } } } catch (EndOfFileException& e) { delete wave; delete[] buf; return false; } BUSY_BEGIN; saveLock.lock(); int waveCount=(int)song.wave.size(); song.wave.push_back(wave); song.waveLen=waveCount+1; saveLock.unlock(); BUSY_END; return true; } void DivEngine::delWave(int index) { BUSY_BEGIN; saveLock.lock(); if (index>=0 && index<(int)song.wave.size()) { delete song.wave[index]; song.wave.erase(song.wave.begin()+index); song.waveLen=song.wave.size(); } saveLock.unlock(); BUSY_END; } int DivEngine::addSample() { BUSY_BEGIN; saveLock.lock(); DivSample* sample=new DivSample; int sampleCount=(int)song.sample.size(); sample->name=fmt::sprintf("Sample %d",sampleCount); song.sample.push_back(sample); song.sampleLen=sampleCount+1; saveLock.unlock(); renderSamples(); BUSY_END; return sampleCount; } int DivEngine::addSampleFromFile(const char* path) { BUSY_BEGIN; SF_INFO si; SNDFILE* f=sf_open(path,SFM_READ,&si); if (f==NULL) { BUSY_END; int err=sf_error(NULL); if (err==SF_ERR_SYSTEM) { lastError=fmt::sprintf("could not open file! (%s %s)",sf_error_number(err),strerror(errno)); } else { lastError=fmt::sprintf("could not open file! (%s)",sf_error_number(err)); } return -1; } if (si.frames>16777215) { lastError="this sample is too big! max sample size is 16777215."; sf_close(f); BUSY_END; return -1; } short* buf=new short[si.channels*si.frames]; if (sf_readf_short(f,buf,si.frames)!=si.frames) { logW("sample read size mismatch!\n"); } DivSample* sample=new DivSample; int sampleCount=(int)song.sample.size(); const char* sName=strrchr(path,DIR_SEPARATOR); if (sName==NULL) { sName=path; } else { sName++; } sample->name=sName; int index=0; if ((si.format&SF_FORMAT_SUBMASK)==SF_FORMAT_PCM_U8) { sample->depth=8; } else { sample->depth=16; } sample->init(si.frames); for (int i=0; idata8[index++]=averaged>>8; } else { sample->data16[index++]=averaged; } } delete[] buf; sample->rate=si.samplerate; if (sample->rate<4000) sample->rate=4000; if (sample->rate>96000) sample->rate=96000; sample->centerRate=si.samplerate; SF_INSTRUMENT inst; if (sf_command(f, SFC_GET_INSTRUMENT, &inst, sizeof(inst)) == SF_TRUE) { // There's no documentation on libsndfile detune range, but the code // implies -50..50. Yet when loading a file you can get a >50 value. if(inst.detune > 50) inst.detune = inst.detune - 100; short pitch = ((0x3c-inst.basenote)*100) + inst.detune; sample->centerRate=si.samplerate*pow(2.0,pitch/(12.0 * 100.0)); if(inst.loop_count && inst.loops[0].mode == SF_LOOP_FORWARD) { sample->loopStart=inst.loops[0].start; if(inst.loops[0].end < (unsigned int)sampleCount) sampleCount=inst.loops[0].end; } } if (sample->centerRate<4000) sample->centerRate=4000; if (sample->centerRate>64000) sample->centerRate=64000; sf_close(f); saveLock.lock(); song.sample.push_back(sample); song.sampleLen=sampleCount+1; saveLock.unlock(); renderSamples(); BUSY_END; return sampleCount; } void DivEngine::delSample(int index) { BUSY_BEGIN; saveLock.lock(); if (index>=0 && index<(int)song.sample.size()) { delete song.sample[index]; song.sample.erase(song.sample.begin()+index); song.sampleLen=song.sample.size(); renderSamples(); } saveLock.unlock(); BUSY_END; } void DivEngine::addOrder(bool duplicate, bool where) { unsigned char order[DIV_MAX_CHANS]; if (song.ordersLen>=0x7e) return; BUSY_BEGIN_SOFT; if (duplicate) { for (int i=0; icurOrder; j--) { song.orders.ord[i][j]=song.orders.ord[i][j-1]; } song.orders.ord[i][curOrder+1]=order[i]; } song.ordersLen++; saveLock.unlock(); curOrder++; if (playing && !freelance) { playSub(false); } } BUSY_END; } void DivEngine::deepCloneOrder(bool where) { unsigned char order[DIV_MAX_CHANS]; if (song.ordersLen>=0x7e) return; warnings=""; BUSY_BEGIN_SOFT; for (int i=0; idata,oldPat->data,256*32*sizeof(short)); logD("found at %d\n",j); didNotFind=false; break; } } if (didNotFind) { addWarning(fmt::sprintf("no free patterns in channel %d!",i)); } } if (where) { // at the end saveLock.lock(); for (int i=0; icurOrder; j--) { song.orders.ord[i][j]=song.orders.ord[i][j-1]; } song.orders.ord[i][curOrder+1]=order[i]; } song.ordersLen++; saveLock.unlock(); curOrder++; if (playing && !freelance) { playSub(false); } } BUSY_END; } void DivEngine::deleteOrder() { if (song.ordersLen<=1) return; BUSY_BEGIN_SOFT; saveLock.lock(); for (int i=0; i=song.ordersLen) curOrder=song.ordersLen-1; if (playing && !freelance) { playSub(false); } BUSY_END; } void DivEngine::moveOrderUp() { BUSY_BEGIN_SOFT; if (curOrder<1) { BUSY_END; return; } saveLock.lock(); for (int i=0; i=song.ordersLen-1) { BUSY_END; return; } saveLock.lock(); for (int i=0; idata[k][2]==one) { song.pat[i].data[j]->data[k][2]=two; } else if (song.pat[i].data[j]->data[k][2]==two) { song.pat[i].data[j]->data[k][2]=one; } } } } } bool DivEngine::moveInsUp(int which) { if (which<1 || which>=(int)song.ins.size()) return false; BUSY_BEGIN; DivInstrument* prev=song.ins[which]; saveLock.lock(); song.ins[which]=song.ins[which-1]; song.ins[which-1]=prev; exchangeIns(which,which-1); saveLock.unlock(); BUSY_END; return true; } bool DivEngine::moveWaveUp(int which) { if (which<1 || which>=(int)song.wave.size()) return false; BUSY_BEGIN; DivWavetable* prev=song.wave[which]; saveLock.lock(); song.wave[which]=song.wave[which-1]; song.wave[which-1]=prev; saveLock.unlock(); BUSY_END; return true; } bool DivEngine::moveSampleUp(int which) { if (which<1 || which>=(int)song.sample.size()) return false; BUSY_BEGIN; DivSample* prev=song.sample[which]; saveLock.lock(); song.sample[which]=song.sample[which-1]; song.sample[which-1]=prev; saveLock.unlock(); BUSY_END; return true; } bool DivEngine::moveInsDown(int which) { if (which<0 || which>=((int)song.ins.size())-1) return false; BUSY_BEGIN; DivInstrument* prev=song.ins[which]; saveLock.lock(); song.ins[which]=song.ins[which+1]; song.ins[which+1]=prev; exchangeIns(which,which+1); saveLock.unlock(); BUSY_END; return true; } bool DivEngine::moveWaveDown(int which) { if (which<0 || which>=((int)song.wave.size())-1) return false; BUSY_BEGIN; DivWavetable* prev=song.wave[which]; saveLock.lock(); song.wave[which]=song.wave[which+1]; song.wave[which+1]=prev; saveLock.unlock(); BUSY_END; return true; } bool DivEngine::moveSampleDown(int which) { if (which<0 || which>=((int)song.sample.size())-1) return false; BUSY_BEGIN; DivSample* prev=song.sample[which]; saveLock.lock(); song.sample[which]=song.sample[which+1]; song.sample[which+1]=prev; saveLock.unlock(); BUSY_END; return true; } void DivEngine::noteOn(int chan, int ins, int note, int vol) { if (chan<0 || chan>=chans) return; BUSY_BEGIN; pendingNotes.push(DivNoteEvent(chan,ins,note,vol,true)); if (!playing) { reset(); freelance=true; playing=true; } BUSY_END; } void DivEngine::noteOff(int chan) { if (chan<0 || chan>=chans) return; BUSY_BEGIN; pendingNotes.push(DivNoteEvent(chan,-1,-1,-1,false)); if (!playing) { reset(); freelance=true; playing=true; } BUSY_END; } void DivEngine::setOrder(unsigned char order) { BUSY_BEGIN_SOFT; curOrder=order; if (order>=song.ordersLen) curOrder=0; if (playing && !freelance) { playSub(false); } BUSY_END; } void DivEngine::setSysFlags(int system, unsigned int flags, bool restart) { BUSY_BEGIN_SOFT; saveLock.lock(); song.systemFlags[system]=flags; saveLock.unlock(); disCont[system].dispatch->setFlags(song.systemFlags[system]); disCont[system].setRates(got.rate); if (restart && isPlaying()) { playSub(false); } BUSY_END; } void DivEngine::setSongRate(float hz, bool pal) { BUSY_BEGIN; saveLock.lock(); song.pal=!pal; song.hz=hz; // what? song.customTempo=true; divider=60; if (song.customTempo) { divider=song.hz; } else { if (song.pal) { divider=60; } else { divider=50; } } saveLock.unlock(); BUSY_END; } void DivEngine::setAudio(DivAudioEngines which) { audioEngine=which; } void DivEngine::setView(DivStatusView which) { view=which; } bool DivEngine::getMetronome() { return metronome; } void DivEngine::setMetronome(bool enable) { metronome=enable; metroAmp=0; } void DivEngine::setConsoleMode(bool enable) { consoleMode=enable; } bool DivEngine::switchMaster() { deinitAudioBackend(); quitDispatch(); initDispatch(); if (initAudioBackend()) { for (int i=0; isetRun(true)) { logE("error while activating audio!\n"); return false; } } else { return false; } return true; } void DivEngine::synchronized(const std::function& what) { BUSY_BEGIN; what(); BUSY_END; } void DivEngine::lockSave(const std::function& what) { saveLock.lock(); what(); saveLock.unlock(); } void DivEngine::lockEngine(const std::function& what) { BUSY_BEGIN; saveLock.lock(); what(); saveLock.unlock(); BUSY_END; } TAAudioDesc& DivEngine::getAudioDescWant() { return want; } TAAudioDesc& DivEngine::getAudioDescGot() { return got; } std::vector& DivEngine::getAudioDevices() { return audioDevs; } std::vector& DivEngine::getMidiIns() { return midiIns; } std::vector& DivEngine::getMidiOuts() { return midiOuts; } void DivEngine::rescanAudioDevices() { audioDevs.clear(); if (output!=NULL) { audioDevs=output->listAudioDevices(); if (output->midiIn!=NULL) { midiIns=output->midiIn->listDevices(); } if (output->midiOut!=NULL) { midiOuts=output->midiOut->listDevices(); } } } void DivEngine::initDispatch() { BUSY_BEGIN; for (int i=0; ilistAudioDevices(); want.deviceName=getConfString("audioDevice",""); want.bufsize=getConfInt("audioBufSize",1024); want.rate=getConfInt("audioRate",44100); want.fragments=2; want.inChans=0; want.outChans=2; want.outFormat=TA_AUDIO_FORMAT_F32; want.name="Furnace"; output->setCallback(process,this); if (!output->init(want,got)) { logE("error while initializing audio!\n"); delete output; output=NULL; audioEngine=DIV_AUDIO_NULL; return false; } if (output->initMidi(false)) { midiIns=output->midiIn->listDevices(); midiOuts=output->midiOut->listDevices(); } else { logW("error while initializing MIDI!\n"); } if (output->midiIn) { String inName=getConfString("midiInDevice",""); if (!inName.empty()) { // try opening device logI("opening MIDI input.\n"); if (!output->midiIn->openDevice(inName)) { logW("could not open MIDI input device!\n"); } } } return true; } bool DivEngine::deinitAudioBackend() { if (output!=NULL) { if (output->midiIn) { if (output->midiIn->isDeviceOpen()) { logI("closing MIDI input.\n"); output->midiIn->closeDevice(); } } output->quitMidi(); output->quit(); delete output; output=NULL; audioEngine=DIV_AUDIO_NULL; } return true; } #ifdef _WIN32 #include "winStuff.h" #endif bool DivEngine::init() { // init config #ifdef _WIN32 configPath=getWinConfigPath(); #else struct stat st; char* home=getenv("HOME"); if (home==NULL) { int uid=getuid(); struct passwd* entry=getpwuid(uid); if (entry==NULL) { logW("unable to determine config directory! (%s)\n",strerror(errno)); configPath="."; } else { configPath=entry->pw_dir; #ifdef __APPLE__ CHECK_CONFIG_DIR_MAC(); #else CHECK_CONFIG_DIR(); #endif } } else { configPath=home; #ifdef __APPLE__ CHECK_CONFIG_DIR_MAC(); #else CHECK_CONFIG_DIR(); #endif } #endif logD("config path: %s\n",configPath.c_str()); loadConf(); // init the rest of engine bool haveAudio=false; if (!initAudioBackend()) { logE("no audio output available!\n"); } else { haveAudio=true; } samp_bb=blip_new(32768); if (samp_bb==NULL) { logE("not enough memory!\n"); return false; } samp_bbOut=new short[32768]; samp_bbIn=new short[32768]; samp_bbInLen=32768; blip_set_rates(samp_bb,44100,got.rate); for (int i=0; i<64; i++) { vibTable[i]=127*sin(((double)i/64.0)*(2*M_PI)); } for (int i=0; i<4096; i++) { reversePitchTable[i]=round(1024.0*pow(2.0,(2048.0-(double)i)/(12.0*128.0))); pitchTable[i]=round(1024.0*pow(2.0,((double)i-2048.0)/(12.0*128.0))); } for (int i=0; isetRun(true)) { logE("error while activating!\n"); return false; } } return true; } bool DivEngine::quit() { deinitAudioBackend(); quitDispatch(); logI("saving config.\n"); saveConf(); active=false; delete[] oscBuf[0]; delete[] oscBuf[1]; return true; }