/** * Furnace Tracker - multi-system chiptune tracker * Copyright (C) 2021-2023 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. */ #define _USE_MATH_DEFINES #include "amiga.h" #include "../engine.h" #include "../../ta-log.h" #include #define AMIGA_DIVIDER 8 #define AMIGA_VPMASK 7 #define CHIP_DIVIDER 16 #define chWrite(c,a,v) rWrite(((c)<<4)+0xa0+(a),(v)); const char* regCheatSheetAmiga[]={ "DMACON", "96", "INTENA", "9A", "ADKCON", "9E", "AUD0LCH", "A0", "AUD0LCL", "A2", "AUD0LEN", "A4", "AUD0PER", "A6", "AUD0VOL", "A8", "AUD0DAT", "AA", "AUD1LCH", "B0", "AUD1LCL", "B2", "AUD1LEN", "B4", "AUD1PER", "B6", "AUD1VOL", "B8", "AUD1DAT", "BA", "AUD2LCH", "C0", "AUD2LCL", "C2", "AUD2LEN", "C4", "AUD2PER", "C6", "AUD2VOL", "C8", "AUD2DAT", "CA", "AUD3LCH", "D0", "AUD3LCL", "D2", "AUD3LEN", "D4", "AUD3PER", "D6", "AUD3VOL", "D8", "AUD3DAT", "DA", NULL }; const char** DivPlatformAmiga::getRegisterSheet() { return regCheatSheetAmiga; } #define writeAudDat(x) \ chan[i].audDat=x; \ if (i<3 && chan[i].useV) { \ chan[i+1].outVol=(unsigned char)chan[i].audDat^0x80; \ if (chan[i+1].outVol>64) chan[i+1].outVol=64; \ } \ if (i<3 && chan[i].useP) { \ chan[i+1].freq=(unsigned char)chan[i].audDat^0x80; \ if (chan[i+1].freq=64) { output=amiga.audDat[amiga.audByte[i]][i]<<6; } else if (amiga.audVol[i]<=0) { output=0; } else { output=amiga.audDat[amiga.audByte[i]][i]*volTable[amiga.audVol[i]][amiga.volPos]; } if (i==0 || i==3) { outL+=(output*sep1)>>7; outR+=(output*sep2)>>7; } else { outL+=(output*sep2)>>7; outR+=(output*sep1)>>7; } oscBuf[i]->data[oscBuf[i]->needle++]=output<<2; } else { oscBuf[i]->data[oscBuf[i]->needle++]=0; } } // OLD CODE /* for (int i=0; i<4; i++) { chan[i].volPos=(chan[i].volPos+1)&AMIGA_VPMASK; if (!chan[i].active) { oscBuf[i]->data[oscBuf[i]->needle++]=0; continue; } if (chan[i].useWave || (chan[i].sample>=0 && chan[i].samplesong.sampleLen)) { chan[i].audSub-=AMIGA_DIVIDER; if (chan[i].audSub<0) { if (chan[i].useWave) { writeAudDat(chan[i].ws.output[(chan[i].audPos++)&255]^0x80); if (chan[i].audPos>=(unsigned int)(chan[i].audLen<<1)) { chan[i].audPos=0; } } else { DivSample* s=parent->getSample(chan[i].sample); if (s->samples>0) { if (chan[i].audPossamples) { writeAudDat(s->data8[chan[i].audPos++]); } if (s->isLoopable() && chan[i].audPos>=MIN(131071,(unsigned int)s->loopEnd)) { chan[i].audPos=s->loopStart; } else if (chan[i].audPos>=MIN(131071,s->samples)) { chan[i].sample=-1; } } else { chan[i].sample=-1; } } if (bypassLimits) { chan[i].audSub+=MAX(AMIGA_DIVIDER,chan[i].freq); } else { chan[i].audSub+=MAX(114,chan[i].freq); } } } if (!isMuted[i]) { if (chan[i].outVol>=64) { output=chan[i].audDat<<6; } else if (chan[i].outVol<=0) { output=0; } else { output=chan[i].audDat*volTable[chan[i].outVol][chan[i].volPos]; } if (i==0 || i==3) { outL+=(output*sep1)>>7; outR+=(output*sep2)>>7; } else { outL+=(output*sep2)>>7; outR+=(output*sep1)>>7; } oscBuf[i]->data[oscBuf[i]->needle++]=output<<2; } else { oscBuf[i]->data[oscBuf[i]->needle++]=0; } } */ filter[0][0]+=(filtConst*(outL-filter[0][0]))>>12; filter[0][1]+=(filtConst*(filter[0][0]-filter[0][1]))>>12; filter[1][0]+=(filtConst*(outR-filter[1][0]))>>12; filter[1][1]+=(filtConst*(filter[1][0]-filter[1][1]))>>12; buf[0][h]=filter[0][1]; buf[1][h]=filter[1][1]; } } void DivPlatformAmiga::irq(int ch) { } #define UPDATE_DMA(x) \ amiga.dmaLen[x]=amiga.audLen[x]; \ amiga.dmaLoc[x]=amiga.audLoc[x]; \ amiga.audByte[x]=true; \ amiga.audTick[x]=0; void DivPlatformAmiga::rWrite(unsigned short addr, unsigned short val) { if (addr&1) return; //logV("%.3x = %.4x",addr,val); regPool[addr>>1]=val; switch (addr&0x1fe) { case 0x96: { // DMACON if (val&32768) { if (val&1) amiga.audEn[0]=true; if (val&2) amiga.audEn[1]=true; if (val&4) amiga.audEn[2]=true; if (val&8) amiga.audEn[3]=true; if (val&512) amiga.dmaEn=true; } else { if (val&1) { amiga.audEn[0]=false; UPDATE_DMA(0); } if (val&2) { amiga.audEn[1]=false; UPDATE_DMA(1); } if (val&4) { amiga.audEn[2]=false; UPDATE_DMA(2); } if (val&8) { amiga.audEn[3]=false; UPDATE_DMA(3); } if (val&512) { amiga.dmaEn=false; } } break; } case 0x9a: { // INTENA if (val&32768) { if (val&128) amiga.audInt[0]=true; if (val&256) amiga.audInt[1]=true; if (val&512) amiga.audInt[2]=true; if (val&1024) amiga.audInt[3]=true; } else { if (val&128) amiga.audInt[0]=false; if (val&256) amiga.audInt[1]=false; if (val&512) amiga.audInt[2]=false; if (val&1024) amiga.audInt[3]=false; } break; } case 0x9e: { // ADKCON if (val&32768) { if (val&1) amiga.useV[0]=true; if (val&2) amiga.useV[1]=true; if (val&4) amiga.useV[2]=true; if (val&8) amiga.useV[3]=true; if (val&16) amiga.useP[0]=true; if (val&32) amiga.useP[1]=true; if (val&64) amiga.useP[2]=true; if (val&128) amiga.useP[3]=true; } else { if (val&1) amiga.useV[0]=false; if (val&2) amiga.useV[1]=false; if (val&4) amiga.useV[2]=false; if (val&8) amiga.useV[3]=false; if (val&16) amiga.useP[0]=false; if (val&32) amiga.useP[1]=false; if (val&64) amiga.useP[2]=false; if (val&128) amiga.useP[3]=false; } break; } default: { // AUDx if (addr>=0xa0 && addr<0xe0) { const unsigned char ch=((addr-0xa0)>>4)&3; bool updateDMA=false; switch (addr&15) { case 0: // LCH amiga.audLoc[ch]&=0xffff; amiga.audLoc[ch]|=val<<16; updateDMA=true; break; case 2: // LCL amiga.audLoc[ch]&=0xffff0000; amiga.audLoc[ch]|=val&0xfffe; updateDMA=true; break; case 4: // LEN amiga.audLen[ch]=val; updateDMA=true; break; case 6: // PER amiga.audPer[ch]=val; break; case 8: // VOL amiga.audVol[ch]=val; break; case 10: // DAT amiga.audDat[0][ch]=val&0xff; amiga.audDat[1][ch]=val>>8; break; } if (updateDMA && !amiga.audEn[ch]) { UPDATE_DMA(ch); } } break; } } } void DivPlatformAmiga::updateWave(int ch) { if (chan[ch].useWave) { for (int i=0; i>6; chan[i].writeVol=true; } double off=1.0; if (!chan[i].useWave && chan[i].sample>=0 && chan[i].samplesong.sampleLen) { DivSample* s=parent->getSample(chan[i].sample); if (s->centerRate<1) { off=1.0; } else { off=8363.0/(double)s->centerRate; } } if (NEW_ARP_STRAT) { chan[i].handleArp(); } else if (chan[i].std.arp.had) { // TODO: why the off mult? this may be a bug! chan[i].baseFreq=round(off*NOTE_PERIODIC_NOROUND(parent->calcArp(chan[i].note,chan[i].std.arp.val))); chan[i].freqChanged=true; } if (chan[i].useWave && chan[i].std.wave.had) { if (chan[i].wave!=chan[i].std.wave.val || chan[i].ws.activeChanged()) { chan[i].wave=chan[i].std.wave.val; chan[i].ws.changeWave1(chan[i].wave); if (!chan[i].keyOff) chan[i].keyOn=true; } } if (chan[i].useWave && chan[i].active) { chan[i].ws.tick(); } if (chan[i].std.pitch.had) { if (chan[i].std.pitch.mode) { chan[i].pitch2+=chan[i].std.pitch.val; CLAMP_VAR(chan[i].pitch2,-32768,32767); } else { chan[i].pitch2=chan[i].std.pitch.val; } chan[i].freqChanged=true; } if (chan[i].std.phaseReset.had) { if (chan[i].std.phaseReset.val==1) { chan[i].audPos=0; } } if (chan[i].freqChanged || chan[i].keyOn || chan[i].keyOff) { //DivInstrument* ins=parent->getIns(chan[i].ins,DIV_INS_AMIGA); chan[i].freq=off*parent->calcFreq(chan[i].baseFreq,chan[i].pitch,chan[i].fixedArp?chan[i].baseNoteOverride:chan[i].arpOff,chan[i].fixedArp,true,0,chan[i].pitch2,chipClock,CHIP_DIVIDER); if (chan[i].freq>4095) chan[i].freq=4095; if (chan[i].freq<0) chan[i].freq=0; chWrite(i,6,chan[i].freq); if (chan[i].keyOn) { rWrite(0x96,1<=0 && chan[i].samplesong.sampleLen) { DivSample* s=parent->getSample(chan[i].sample); chWrite(i,0,sampleOff[chan[i].sample]>>16); chWrite(i,2,sampleOff[chan[i].sample]); chWrite(i,4,MIN(65535,s->getLoopEndPosition(DIV_SAMPLE_DEPTH_8BIT)>>1)); rWrite(0x96,0x8000|(1<isLoopable()) { int loopPos=(sampleOff[chan[i].sample]+s->getLoopStartPosition(DIV_SAMPLE_DEPTH_8BIT))&(~1); int loopEnd=(s->getLoopEndPosition(DIV_SAMPLE_DEPTH_8BIT)-s->getLoopStartPosition(DIV_SAMPLE_DEPTH_8BIT))>>1; chWrite(i,0,loopPos>>16); chWrite(i,2,loopPos); chWrite(i,4,MIN(65535,loopEnd)); } else { chWrite(i,0,0); chWrite(i,2,i<<8); chWrite(i,4,0); } } else { chWrite(i,0,0); chWrite(i,2,i<<8); chWrite(i,4,0); } } } if (chan[i].keyOff) { rWrite(0x96,1<getIns(chan[c.chan].ins,DIV_INS_AMIGA); if (ins->amiga.useWave) { chan[c.chan].useWave=true; chan[c.chan].audLen=(ins->amiga.waveLen+1)>>1; if (chan[c.chan].insChanged) { if (chan[c.chan].wave<0) { chan[c.chan].wave=0; chan[c.chan].ws.setWidth(chan[c.chan].audLen<<1); chan[c.chan].ws.changeWave1(chan[c.chan].wave); } } } else { if (c.value!=DIV_NOTE_NULL) chan[c.chan].sample=ins->amiga.getSample(c.value); chan[c.chan].useWave=false; } if (c.value!=DIV_NOTE_NULL) { chan[c.chan].baseFreq=round(NOTE_PERIODIC_NOROUND(c.value)); } if (chan[c.chan].useWave || chan[c.chan].sample<0 || chan[c.chan].sample>=parent->song.sampleLen) { chan[c.chan].sample=-1; } if (chan[c.chan].setPos) { chan[c.chan].setPos=false; } else { chan[c.chan].audPos=0; } chan[c.chan].audSub=0; if (c.value!=DIV_NOTE_NULL) { chan[c.chan].freqChanged=true; chan[c.chan].note=c.value; } chan[c.chan].active=true; chan[c.chan].keyOn=true; chan[c.chan].macroInit(ins); if (!parent->song.brokenOutVol && !chan[c.chan].std.vol.will) { chan[c.chan].outVol=chan[c.chan].vol; chan[c.chan].writeVol=true; } if (chan[c.chan].useWave) { chan[c.chan].ws.init(ins,chan[c.chan].audLen<<1,255,chan[c.chan].insChanged); } chan[c.chan].insChanged=false; break; } case DIV_CMD_NOTE_OFF: chan[c.chan].sample=-1; chan[c.chan].active=false; chan[c.chan].keyOff=true; chan[c.chan].macroInit(NULL); break; case DIV_CMD_NOTE_OFF_ENV: case DIV_CMD_ENV_RELEASE: chan[c.chan].std.release(); break; case DIV_CMD_INSTRUMENT: if (chan[c.chan].ins!=c.value || c.value2==1) { chan[c.chan].ins=c.value; chan[c.chan].insChanged=true; } break; case DIV_CMD_VOLUME: if (chan[c.chan].vol!=c.value) { chan[c.chan].vol=c.value; if (!chan[c.chan].std.vol.has) { chan[c.chan].outVol=c.value; chan[c.chan].writeVol=true; } } break; case DIV_CMD_GET_VOLUME: if (chan[c.chan].std.vol.has) { return chan[c.chan].vol; } return chan[c.chan].outVol; break; case DIV_CMD_PITCH: chan[c.chan].pitch=c.value; chan[c.chan].freqChanged=true; break; case DIV_CMD_WAVE: if (!chan[c.chan].useWave) break; chan[c.chan].wave=c.value; chan[c.chan].keyOn=true; chan[c.chan].ws.changeWave1(chan[c.chan].wave); break; case DIV_CMD_NOTE_PORTA: { DivInstrument* ins=parent->getIns(chan[c.chan].ins,DIV_INS_AMIGA); chan[c.chan].sample=ins->amiga.getSample(c.value2); int destFreq=round(NOTE_PERIODIC_NOROUND(c.value2)); bool return2=false; if (destFreq>chan[c.chan].baseFreq) { chan[c.chan].baseFreq+=c.value; if (chan[c.chan].baseFreq>=destFreq) { chan[c.chan].baseFreq=destFreq; return2=true; } } else { chan[c.chan].baseFreq-=c.value; if (chan[c.chan].baseFreq<=destFreq) { chan[c.chan].baseFreq=destFreq; return2=true; } } chan[c.chan].freqChanged=true; if (return2) { chan[c.chan].inPorta=false; return 2; } break; } case DIV_CMD_LEGATO: { chan[c.chan].baseFreq=round(NOTE_PERIODIC_NOROUND(c.value+((HACKY_LEGATO_MESS)?(chan[c.chan].std.arp.val):(0)))); chan[c.chan].freqChanged=true; chan[c.chan].note=c.value; break; } case DIV_CMD_PRE_PORTA: if (chan[c.chan].active && c.value2) { if (parent->song.resetMacroOnPorta) chan[c.chan].macroInit(parent->getIns(chan[c.chan].ins,DIV_INS_AMIGA)); } if (!chan[c.chan].inPorta && c.value && !parent->song.brokenPortaArp && chan[c.chan].std.arp.will && !NEW_ARP_STRAT) chan[c.chan].baseFreq=NOTE_PERIODIC(chan[c.chan].note); chan[c.chan].inPorta=c.value; break; case DIV_CMD_SAMPLE_POS: if (chan[c.chan].useWave) break; chan[c.chan].audPos=c.value; chan[c.chan].setPos=true; break; case DIV_CMD_AMIGA_FILTER: filterOn=c.value; filtConst=filterOn?filtConstOn:filtConstOff; break; case DIV_CMD_AMIGA_AM: chan[c.chan].useV=c.value; break; case DIV_CMD_AMIGA_PM: chan[c.chan].useP=c.value; break; case DIV_CMD_GET_VOLMAX: return 64; break; case DIV_CMD_MACRO_OFF: chan[c.chan].std.mask(c.value,true); break; case DIV_CMD_MACRO_ON: chan[c.chan].std.mask(c.value,false); break; case DIV_ALWAYS_SET_VOLUME: return 1; break; default: break; } return 1; } void DivPlatformAmiga::muteChannel(int ch, bool mute) { isMuted[ch]=mute; } void DivPlatformAmiga::forceIns() { for (int i=0; i<4; i++) { chan[i].insChanged=true; chan[i].freqChanged=true; chan[i].audPos=131072; chan[i].audDat=0; chan[i].sample=-1; } } void* DivPlatformAmiga::getChanState(int ch) { return &chan[ch]; } DivDispatchOscBuffer* DivPlatformAmiga::getOscBuffer(int ch) { return oscBuf[ch]; } void DivPlatformAmiga::reset() { memset(regPool,0,256*sizeof(unsigned short)); for (int i=0; i<4; i++) { chan[i]=DivPlatformAmiga::Channel(); chan[i].std.setEngine(parent); chan[i].ws.setEngine(parent); chan[i].ws.init(NULL,32,255); filter[0][i]=0; filter[1][i]=0; } filterOn=false; filtConst=filterOn?filtConstOn:filtConstOff; amiga=Amiga(); // enable DMA rWrite(0x96,0x8200); } int DivPlatformAmiga::getOutputCount() { return 2; } bool DivPlatformAmiga::keyOffAffectsArp(int ch) { return true; } DivMacroInt* DivPlatformAmiga::getChanMacroInt(int ch) { return &chan[ch].std; } void DivPlatformAmiga::notifyInsChange(int ins) { for (int i=0; i<4; i++) { if (chan[i].ins==ins) { chan[i].insChanged=true; } } } void DivPlatformAmiga::notifyWaveChange(int wave) { for (int i=0; i<4; i++) { if (chan[i].useWave && chan[i].wave==wave) { chan[i].ws.changeWave1(wave); } } } void DivPlatformAmiga::notifyInsDeletion(void* ins) { for (int i=0; i<4; i++) { chan[i].std.notifyInsDeletion((DivInstrument*)ins); } } void DivPlatformAmiga::setFlags(const DivConfig& flags) { if (flags.getInt("clockSel",0)) { chipClock=COLOR_PAL*4.0/5.0; } else { chipClock=COLOR_NTSC; } rate=chipClock/AMIGA_DIVIDER; for (int i=0; i<4; i++) { oscBuf[i]->rate=rate; } int sep=flags.getInt("stereoSep",0)&127; sep1=sep+127; sep2=127-sep; amigaModel=flags.getInt("chipType",0); chipMem=flags.getInt("chipMem",21); if (chipMem<18) chipMem=18; if (chipMem>21) chipMem=21; chipMask=(1<& wlist) { for (DivRegWrite& i: wlist) rWrite(i.addr,i.val); } unsigned char* DivPlatformAmiga::getRegisterPool() { return (unsigned char*)regPool; } int DivPlatformAmiga::getRegisterPoolSize() { return 128; } int DivPlatformAmiga::getRegisterPoolDepth() { return 16; } const void* DivPlatformAmiga::getSampleMem(int index) { return index == 0 ? sampleMem : NULL; } size_t DivPlatformAmiga::getSampleMemCapacity(int index) { return index == 0 ? (1<255) return false; return sampleLoaded[sample]; } void DivPlatformAmiga::renderSamples(int sysID) { memset(sampleMem,0,2097152); memset(sampleOff,0,256*sizeof(unsigned int)); memset(sampleLoaded,0,256*sizeof(bool)); // first 1024 bytes reserved for wavetable size_t memPos=1024; for (int i=0; isong.sampleLen; i++) { DivSample* s=parent->song.sample[i]; if (!s->renderOn[0][sysID]) { sampleOff[i]=0; continue; } if (memPos>=getSampleMemCapacity()) { logW("out of Amiga memory for sample %d!",i); break; } int length=s->getLoopEndPosition(DIV_SAMPLE_DEPTH_8BIT); int actualLength=MIN((int)(getSampleMemCapacity()-memPos),length); if (actualLength>0) { sampleOff[i]=memPos; memcpy(&sampleMem[memPos],s->data8,actualLength); memPos+=actualLength; } // align memPos to short if (memPos&1) memPos++; sampleLoaded[i]=true; } sampleMemLen=memPos; } int DivPlatformAmiga::init(DivEngine* p, int channels, int sugRate, const DivConfig& flags) { parent=p; dumpWrites=false; skipRegisterWrites=false; for (int i=0; i<4; i++) { oscBuf[i]=new DivDispatchOscBuffer; isMuted[i]=false; } // Paula volume is implemented using PWM rather than a multiplication. // sources: // - https://www.youtube.com/watch?v=xyQlmsD7PAg // - https://linusakesson.net/music/paulimba/index.php memset(volTable,0,64*64); for (int i=0; i<64; i++) { for (int j=0; j<64; j++) { volTable[i][j/AMIGA_DIVIDER]+=(j