/** * 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 "genesisext.h" #include "../engine.h" #include #include "genesisshared.h" #define CHIP_FREQBASE 9440540 int DivPlatformGenesisExt::dispatch(DivCommand c) { if (c.chan<2) { return DivPlatformGenesis::dispatch(c); } if (c.chan>5) { c.chan-=3; return DivPlatformGenesis::dispatch(c); } int ch=c.chan-2; int ordch=orderedOps[ch]; switch (c.cmd) { case DIV_CMD_NOTE_ON: { DivInstrument* ins=parent->getIns(opChan[ch].ins,DIV_INS_FM); if (opChan[ch].insChanged) { chan[2].state.alg=ins->fm.alg; chan[2].state.fb=ins->fm.fb; chan[2].state.fms=ins->fm.fms; chan[2].state.ams=ins->fm.ams; chan[2].state.op[ordch]=ins->fm.op[ordch]; } unsigned short baseAddr=chanOffs[2]|opOffs[ordch]; DivInstrumentFM::Operator& op=chan[2].state.op[ordch]; // TODO: how does this work?! if (isOpMuted[ch]) { rWrite(baseAddr+0x40,127); } else { if (opChan[ch].insChanged) { rWrite(baseAddr+0x40,127-(((127-op.tl)*(opChan[ch].vol&0x7f))/127)); } } if (opChan[ch].insChanged) { rWrite(baseAddr+0x30,(op.mult&15)|(dtTable[op.dt&7]<<4)); rWrite(baseAddr+0x50,(op.ar&31)|(op.rs<<6)); rWrite(baseAddr+0x60,(op.dr&31)|(op.am<<7)); rWrite(baseAddr+0x70,op.d2r&31); rWrite(baseAddr+0x80,(op.rr&15)|(op.sl<<4)); rWrite(baseAddr+0x90,op.ssgEnv&15); } if (opChan[ch].insChanged) { // TODO how does this work? rWrite(chanOffs[2]+0xb0,(chan[2].state.alg&7)|(chan[2].state.fb<<3)); rWrite(chanOffs[2]+0xb4,(opChan[ch].pan<<6)|(chan[2].state.fms&7)|((chan[2].state.ams&3)<<4)); } opChan[ch].insChanged=false; if (c.value!=DIV_NOTE_NULL) { opChan[ch].baseFreq=NOTE_FNUM_BLOCK(c.value,11); opChan[ch].portaPause=false; opChan[ch].freqChanged=true; } opChan[ch].keyOn=true; opChan[ch].active=true; break; } case DIV_CMD_NOTE_OFF: opChan[ch].keyOff=true; opChan[ch].keyOn=false; opChan[ch].active=false; break; case DIV_CMD_VOLUME: { opChan[ch].vol=c.value; unsigned short baseAddr=chanOffs[2]|opOffs[ordch]; DivInstrumentFM::Operator& op=chan[2].state.op[ordch]; if (isOpMuted[ch]) { rWrite(baseAddr+0x40,127); } else { rWrite(baseAddr+0x40,127-(((127-op.tl)*(opChan[ch].vol&0x7f))/127)); } break; } case DIV_CMD_GET_VOLUME: { return opChan[ch].vol; break; } case DIV_CMD_INSTRUMENT: if (opChan[ch].ins!=c.value || c.value2==1) { opChan[ch].insChanged=true; } opChan[ch].ins=c.value; break; case DIV_CMD_PANNING: { if (c.value==0 && c.value2==0) { opChan[ch].pan=3; } else { opChan[ch].pan=(c.value2>0)|((c.value>0)<<1); } if (parent->song.sharedExtStat) { for (int i=0; i<4; i++) { if (ch==i) continue; opChan[i].pan=opChan[ch].pan; } } rWrite(chanOffs[2]+0xb4,(opChan[ch].pan<<6)|(chan[2].state.fms&7)|((chan[2].state.ams&3)<<4)); break; } case DIV_CMD_PITCH: { opChan[ch].pitch=c.value; opChan[ch].freqChanged=true; break; } case DIV_CMD_NOTE_PORTA: { if (parent->song.linearPitch==2) { int destFreq=NOTE_FREQUENCY(c.value2); bool return2=false; if (destFreq>opChan[ch].baseFreq) { opChan[ch].baseFreq+=c.value; if (opChan[ch].baseFreq>=destFreq) { opChan[ch].baseFreq=destFreq; return2=true; } } else { opChan[ch].baseFreq-=c.value; if (opChan[ch].baseFreq<=destFreq) { opChan[ch].baseFreq=destFreq; return2=true; } } opChan[ch].freqChanged=true; if (return2) { //opChan[ch].inPorta=false; return 2; } break; } int boundaryBottom=parent->calcBaseFreq(chipClock,CHIP_FREQBASE,0,false); int boundaryTop=parent->calcBaseFreq(chipClock,CHIP_FREQBASE,12,false); int destFreq=NOTE_FNUM_BLOCK(c.value2,11); int newFreq; bool return2=false; if (opChan[ch].portaPause) { opChan[ch].baseFreq=opChan[ch].portaPauseFreq; } if (destFreq>opChan[ch].baseFreq) { newFreq=opChan[ch].baseFreq+c.value; if (newFreq>=destFreq) { newFreq=destFreq; return2=true; } } else { newFreq=opChan[ch].baseFreq-c.value; if (newFreq<=destFreq) { newFreq=destFreq; return2=true; } } // what the heck! if (!opChan[ch].portaPause) { if ((newFreq&0x7ff)>boundaryTop && (newFreq&0xf800)<0x3800) { if (parent->song.fbPortaPause) { opChan[ch].portaPauseFreq=(boundaryBottom)|((newFreq+0x800)&0xf800); opChan[ch].portaPause=true; break; } else { newFreq=(newFreq>>1)|((newFreq+0x800)&0xf800); } } if ((newFreq&0x7ff)0) { if (parent->song.fbPortaPause) { opChan[ch].portaPauseFreq=newFreq=(boundaryTop-1)|((newFreq-0x800)&0xf800); opChan[ch].portaPause=true; break; } else { newFreq=(newFreq<<1)|((newFreq-0x800)&0xf800); } } } opChan[ch].portaPause=false; opChan[ch].freqChanged=true; opChan[ch].baseFreq=newFreq; if (return2) return 2; break; } case DIV_CMD_SAMPLE_MODE: { // not ignored actually! if (!parent->song.ignoreDACModeOutsideIntendedChannel) { dacMode=c.value; rWrite(0x2b,c.value<<7); } break; } case DIV_CMD_SAMPLE_BANK: if (!parent->song.ignoreDACModeOutsideIntendedChannel) { sampleBank=c.value; if (sampleBank>(parent->song.sample.size()/12)) { sampleBank=parent->song.sample.size()/12; } } break; case DIV_CMD_LEGATO: { opChan[ch].baseFreq=NOTE_FNUM_BLOCK(c.value,11); opChan[ch].freqChanged=true; break; } case DIV_CMD_FM_LFO: { lfoValue=(c.value&7)|((c.value>>4)<<3); rWrite(0x22,lfoValue); break; } case DIV_CMD_FM_MULT: { // TODO unsigned short baseAddr=chanOffs[2]|opOffs[orderedOps[c.value]]; DivInstrumentFM::Operator& op=chan[2].state.op[orderedOps[c.value]]; op.mult=c.value2&15; rWrite(baseAddr+0x30,(op.mult&15)|(dtTable[op.dt&7]<<4)); break; } case DIV_CMD_FM_TL: { // TODO unsigned short baseAddr=chanOffs[2]|opOffs[orderedOps[c.value]]; DivInstrumentFM::Operator& op=chan[2].state.op[orderedOps[c.value]]; op.tl=c.value2; if (isOpMuted[ch]) { rWrite(baseAddr+0x40,127); } else if (isOutput[chan[2].state.alg][c.value]) { rWrite(baseAddr+0x40,127-(((127-op.tl)*(opChan[ch].vol&0x7f))/127)); } else { rWrite(baseAddr+0x40,op.tl); } break; } case DIV_CMD_FM_AR: { if (c.value<0) { for (int i=0; i<4; i++) { DivInstrumentFM::Operator& op=chan[2].state.op[i]; op.ar=c.value2&31; unsigned short baseAddr=chanOffs[2]|opOffs[i]; rWrite(baseAddr+0x50,(op.ar&31)|(op.rs<<6)); } } else { DivInstrumentFM::Operator& op=chan[2].state.op[orderedOps[c.value]]; op.ar=c.value2&31; unsigned short baseAddr=chanOffs[2]|opOffs[orderedOps[c.value]]; rWrite(baseAddr+0x50,(op.ar&31)|(op.rs<<6)); } break; } case DIV_CMD_FM_RS: { if (c.value<0) { for (int i=0; i<4; i++) { DivInstrumentFM::Operator& op=chan[2].state.op[i]; op.rs=c.value2&3; unsigned short baseAddr=chanOffs[2]|opOffs[i]; rWrite(baseAddr+ADDR_RS_AR,(op.ar&31)|(op.rs<<6)); } } else if (c.value<4) { DivInstrumentFM::Operator& op=chan[2].state.op[orderedOps[c.value]]; op.rs=c.value2&3; unsigned short baseAddr=chanOffs[2]|opOffs[orderedOps[c.value]]; rWrite(baseAddr+ADDR_RS_AR,(op.ar&31)|(op.rs<<6)); } break; } case DIV_CMD_FM_AM: { if (c.value<0) { for (int i=0; i<4; i++) { DivInstrumentFM::Operator& op=chan[2].state.op[i]; op.am=c.value2&1; unsigned short baseAddr=chanOffs[2]|opOffs[i]; rWrite(baseAddr+ADDR_AM_DR,(op.dr&31)|(op.am<<7)); } } else if (c.value<4) { DivInstrumentFM::Operator& op=chan[2].state.op[orderedOps[c.value]]; op.am=c.value2&1; unsigned short baseAddr=chanOffs[2]|opOffs[orderedOps[c.value]]; rWrite(baseAddr+ADDR_AM_DR,(op.dr&31)|(op.am<<7)); } break; } case DIV_CMD_FM_DR: { if (c.value<0) { for (int i=0; i<4; i++) { DivInstrumentFM::Operator& op=chan[2].state.op[i]; op.dr=c.value2&31; unsigned short baseAddr=chanOffs[2]|opOffs[i]; rWrite(baseAddr+ADDR_AM_DR,(op.dr&31)|(op.am<<7)); } } else if (c.value<4) { DivInstrumentFM::Operator& op=chan[2].state.op[orderedOps[c.value]]; op.dr=c.value2&31; unsigned short baseAddr=chanOffs[2]|opOffs[orderedOps[c.value]]; rWrite(baseAddr+ADDR_AM_DR,(op.dr&31)|(op.am<<7)); } break; } case DIV_CMD_FM_SL: { if (c.value<0) { for (int i=0; i<4; i++) { DivInstrumentFM::Operator& op=chan[2].state.op[i]; op.sl=c.value2&15; unsigned short baseAddr=chanOffs[2]|opOffs[i]; rWrite(baseAddr+ADDR_SL_RR,(op.rr&15)|(op.sl<<4)); } } else if (c.value<4) { DivInstrumentFM::Operator& op=chan[2].state.op[orderedOps[c.value]]; op.sl=c.value2&15; unsigned short baseAddr=chanOffs[2]|opOffs[orderedOps[c.value]]; rWrite(baseAddr+ADDR_SL_RR,(op.rr&15)|(op.sl<<4)); } break; } case DIV_CMD_FM_RR: { if (c.value<0) { for (int i=0; i<4; i++) { DivInstrumentFM::Operator& op=chan[2].state.op[i]; op.rr=c.value2&15; unsigned short baseAddr=chanOffs[2]|opOffs[i]; rWrite(baseAddr+ADDR_SL_RR,(op.rr&15)|(op.sl<<4)); } } else if (c.value<4) { DivInstrumentFM::Operator& op=chan[2].state.op[orderedOps[c.value]]; op.rr=c.value2&15; unsigned short baseAddr=chanOffs[2]|opOffs[orderedOps[c.value]]; rWrite(baseAddr+ADDR_SL_RR,(op.rr&15)|(op.sl<<4)); } break; } case DIV_CMD_FM_D2R: { if (c.value<0) { for (int i=0; i<4; i++) { DivInstrumentFM::Operator& op=chan[2].state.op[i]; op.d2r=c.value2&31; unsigned short baseAddr=chanOffs[2]|opOffs[i]; rWrite(baseAddr+ADDR_DT2_D2R,op.d2r&31); } } else if (c.value<4) { DivInstrumentFM::Operator& op=chan[2].state.op[orderedOps[c.value]]; op.d2r=c.value2&31; unsigned short baseAddr=chanOffs[2]|opOffs[orderedOps[c.value]]; rWrite(baseAddr+ADDR_DT2_D2R,op.d2r&31); } break; } case DIV_CMD_FM_DT: { if (c.value<0) { for (int i=0; i<4; i++) { DivInstrumentFM::Operator& op=chan[2].state.op[i]; op.dt=c.value&7; unsigned short baseAddr=chanOffs[2]|opOffs[i]; rWrite(baseAddr+ADDR_MULT_DT,(op.mult&15)|(dtTable[op.dt&7]<<4)); } } else if (c.value<4) { DivInstrumentFM::Operator& op=chan[2].state.op[orderedOps[c.value]]; op.dt=c.value2&7; unsigned short baseAddr=chanOffs[2]|opOffs[orderedOps[c.value]]; rWrite(baseAddr+ADDR_MULT_DT,(op.mult&15)|(dtTable[op.dt&7]<<4)); } break; } case DIV_CMD_FM_SSG: { if (c.value<0) { for (int i=0; i<4; i++) { DivInstrumentFM::Operator& op=chan[2].state.op[i]; op.ssgEnv=8^(c.value2&15); unsigned short baseAddr=chanOffs[2]|opOffs[i]; rWrite(baseAddr+ADDR_SSG,op.ssgEnv&15); } } else if (c.value<4) { DivInstrumentFM::Operator& op=chan[2].state.op[orderedOps[c.value]]; op.ssgEnv=8^(c.value2&15); unsigned short baseAddr=chanOffs[2]|opOffs[orderedOps[c.value]]; rWrite(baseAddr+ADDR_SSG,op.ssgEnv&15); } break; } case DIV_CMD_GET_VOLMAX: return 127; break; case DIV_ALWAYS_SET_VOLUME: return 0; break; case DIV_CMD_PRE_PORTA: break; default: //printf("WARNING: unimplemented command %d\n",c.cmd); break; } return 1; } void DivPlatformGenesisExt::muteChannel(int ch, bool mute) { if (ch<2) { DivPlatformGenesis::muteChannel(ch,mute); return; } if (ch>5) { DivPlatformGenesis::muteChannel(ch-3,mute); return; } isOpMuted[ch-2]=mute; int ordch=orderedOps[ch-2]; unsigned short baseAddr=chanOffs[2]|opOffs[ordch]; DivInstrumentFM::Operator op=chan[2].state.op[ordch]; if (isOpMuted[ch-2]) { rWrite(baseAddr+0x40,127); immWrite(baseAddr+0x40,127); } else if (isOutput[chan[2].state.alg][ordch]) { rWrite(baseAddr+0x40,127-(((127-op.tl)*(opChan[ch-2].vol&0x7f))/127)); immWrite(baseAddr+0x40,127-(((127-op.tl)*(opChan[ch-2].vol&0x7f))/127)); } else { rWrite(baseAddr+0x40,op.tl); immWrite(baseAddr+0x40,op.tl); } } static int opChanOffsL[4]={ 0xa9, 0xaa, 0xa8, 0xa2 }; static int opChanOffsH[4]={ 0xad, 0xae, 0xac, 0xa6 }; void DivPlatformGenesisExt::tick(bool sysTick) { if (extMode) { bool writeSomething=false; unsigned char writeMask=2; for (int i=0; i<4; i++) { writeMask|=opChan[i].active<<(4+i); if (opChan[i].keyOn || opChan[i].keyOff) { writeSomething=true; writeMask&=~(1<<(4+i)); opChan[i].keyOff=false; } } if (writeSomething) { immWrite(0x28,writeMask); } } DivPlatformGenesis::tick(sysTick); bool writeNoteOn=false; unsigned char writeMask=2; if (extMode) for (int i=0; i<4; i++) { if (opChan[i].freqChanged) { if (parent->song.linearPitch==2) { opChan[i].freq=parent->calcFreq(opChan[i].baseFreq,opChan[i].pitch,false,4,opChan[i].pitch2,chipClock,CHIP_FREQBASE,11); } else { int fNum=parent->calcFreq(opChan[i].baseFreq&0x7ff,opChan[i].pitch,false,4,opChan[i].pitch2); int block=(opChan[i].baseFreq&0xf800)>>11; if (fNum<0) fNum=0; if (fNum>2047) { while (block<7) { fNum>>=1; block++; } if (fNum>2047) fNum=2047; } opChan[i].freq=(block<<11)|fNum; } if (opChan[i].freq>0x3fff) opChan[i].freq=0x3fff; immWrite(opChanOffsH[i],opChan[i].freq>>8); immWrite(opChanOffsL[i],opChan[i].freq&0xff); } writeMask|=opChan[i].active<<(4+i); if (opChan[i].keyOn) { writeNoteOn=true; writeMask|=1<<(4+i); opChan[i].keyOn=false; } } if (writeNoteOn) { immWrite(0x28,writeMask); } } void DivPlatformGenesisExt::forceIns() { for (int i=0; i<6; i++) { for (int j=0; j<4; j++) { unsigned short baseAddr=chanOffs[i]|opOffs[j]; DivInstrumentFM::Operator& op=chan[i].state.op[j]; if (i==2) { // extended channel if (isOpMuted[j]) { rWrite(baseAddr+0x40,127); } else if (isOutput[chan[i].state.alg][j]) { rWrite(baseAddr+0x40,127-(((127-op.tl)*(opChan[j].vol&0x7f))/127)); } else { rWrite(baseAddr+0x40,op.tl); } } else { if (isMuted[i]) { rWrite(baseAddr+ADDR_TL,127); } else { if (isOutput[chan[i].state.alg][j]) { rWrite(baseAddr+ADDR_TL,127-(((127-op.tl)*(chan[i].outVol&0x7f))/127)); } else { rWrite(baseAddr+ADDR_TL,op.tl); } } } rWrite(baseAddr+ADDR_MULT_DT,(op.mult&15)|(dtTable[op.dt&7]<<4)); rWrite(baseAddr+ADDR_RS_AR,(op.ar&31)|(op.rs<<6)); rWrite(baseAddr+ADDR_AM_DR,(op.dr&31)|(op.am<<7)); rWrite(baseAddr+ADDR_DT2_D2R,op.d2r&31); rWrite(baseAddr+ADDR_SL_RR,(op.rr&15)|(op.sl<<4)); rWrite(baseAddr+ADDR_SSG,op.ssgEnv&15); } rWrite(chanOffs[i]+ADDR_FB_ALG,(chan[i].state.alg&7)|(chan[i].state.fb<<3)); rWrite(chanOffs[i]+ADDR_LRAF,(isMuted[i]?0:(chan[i].pan<<6))|(chan[i].state.fms&7)|((chan[i].state.ams&3)<<4)); if (chan[i].active) { chan[i].keyOn=true; chan[i].freqChanged=true; } } if (dacMode) { rWrite(0x2b,0x80); } immWrite(0x22,lfoValue); for (int i=0; i<4; i++) { opChan[i].insChanged=true; if (opChan[i].active) { opChan[i].keyOn=true; opChan[i].freqChanged=true; } } } void* DivPlatformGenesisExt::getChanState(int ch) { if (ch>=6) return &chan[ch-3]; if (ch>=2) return &opChan[ch-2]; return &chan[ch]; } DivDispatchOscBuffer* DivPlatformGenesisExt::getOscBuffer(int ch) { if (ch>=6) return oscBuf[ch-3]; if (ch<3) return oscBuf[ch]; return NULL; } void DivPlatformGenesisExt::reset() { DivPlatformGenesis::reset(); for (int i=0; i<4; i++) { opChan[i]=DivPlatformGenesisExt::OpChannel(); opChan[i].vol=127; } // channel 3 mode immWrite(0x27,0x40); extMode=true; } bool DivPlatformGenesisExt::keyOffAffectsArp(int ch) { return (ch>8); } bool DivPlatformGenesisExt::keyOffAffectsPorta(int ch) { return (ch>8); } void DivPlatformGenesisExt::notifyInsChange(int ins) { DivPlatformGenesis::notifyInsChange(ins); for (int i=0; i<4; i++) { if (opChan[i].ins==ins) { opChan[i].insChanged=true; } } } int DivPlatformGenesisExt::getPortaFloor(int ch) { return (ch>8)?12:0; } int DivPlatformGenesisExt::init(DivEngine* parent, int channels, int sugRate, unsigned int flags) { DivPlatformGenesis::init(parent,channels,sugRate,flags); for (int i=0; i<4; i++) { isOpMuted[i]=false; } reset(); return 13; } void DivPlatformGenesisExt::quit() { DivPlatformGenesis::quit(); } DivPlatformGenesisExt::~DivPlatformGenesisExt() { }