/** * 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 "ym2610b.h" #include "../engine.h" #include #include #include "ym2610shared.h" #include "fmshared_OPN.h" static unsigned char konOffs[6]={ 0, 1, 2, 4, 5, 6 }; #define CHIP_DIVIDER 32 const char* DivPlatformYM2610B::getEffectName(unsigned char effect) { switch (effect) { case 0x10: return "10xy: Setup LFO (x: enable; y: speed)"; break; case 0x11: return "11xx: Set feedback (0 to 7)"; break; case 0x12: return "12xx: Set level of operator 1 (0 highest, 7F lowest)"; break; case 0x13: return "13xx: Set level of operator 2 (0 highest, 7F lowest)"; break; case 0x14: return "14xx: Set level of operator 3 (0 highest, 7F lowest)"; break; case 0x15: return "15xx: Set level of operator 4 (0 highest, 7F lowest)"; break; case 0x16: return "16xy: Set operator multiplier (x: operator from 1 to 4; y: multiplier)"; break; case 0x18: return "18xx: Toggle extended channel 3 mode"; break; case 0x19: return "19xx: Set attack of all operators (0 to 1F)"; break; case 0x1a: return "1Axx: Set attack of operator 1 (0 to 1F)"; break; case 0x1b: return "1Bxx: Set attack of operator 2 (0 to 1F)"; break; case 0x1c: return "1Cxx: Set attack of operator 3 (0 to 1F)"; break; case 0x1d: return "1Dxx: Set attack of operator 4 (0 to 1F)"; break; case 0x20: return "20xx: Set SSG channel mode (bit 0: square; bit 1: noise; bit 2: envelope)"; break; case 0x21: return "21xx: Set SSG noise frequency (0 to 1F)"; break; case 0x22: return "22xy: Set SSG envelope mode (x: shape, y: enable for this channel)"; break; case 0x23: return "23xx: Set SSG envelope period low byte"; break; case 0x24: return "24xx: Set SSG envelope period high byte"; break; case 0x25: return "25xx: SSG envelope slide up"; break; case 0x26: return "26xx: SSG envelope slide down"; break; case 0x29: return "29xy: Set SSG auto-envelope (x: numerator; y: denominator)"; break; } return NULL; } double DivPlatformYM2610B::NOTE_ADPCMB(int note) { DivInstrument* ins=parent->getIns(chan[15].ins); if (ins->type!=DIV_INS_AMIGA) return 0; double off=(double)(parent->getSample(ins->amiga.initSample)->centerRate)/8363.0; return off*parent->calcBaseFreq((double)chipClock/144,65535,note,false); } void DivPlatformYM2610B::acquire(short* bufL, short* bufR, size_t start, size_t len) { static int os[2]; for (size_t h=start; hwrite(0x0+((w.addr>>8)<<1),w.addr); fm->write(0x1+((w.addr>>8)<<1),w.val); regPool[w.addr&0x1ff]=w.val; writes.pop(); delay=4; } } fm->generate(&fmout); os[0]=fmout.data[0]+(fmout.data[2]>>1); if (os[0]<-32768) os[0]=-32768; if (os[0]>32767) os[0]=32767; os[1]=fmout.data[1]+(fmout.data[2]>>1); if (os[1]<-32768) os[1]=-32768; if (os[1]>32767) os[1]=32767; bufL[h]=os[0]; bufR[h]=os[1]; } } void DivPlatformYM2610B::tick() { // PSG for (int i=6; i<9; i++) { chan[i].std.next(); if (chan[i].std.hadVol) { chan[i].outVol=MIN(15,chan[i].std.vol)-(15-(chan[i].vol&15)); if (chan[i].outVol<0) chan[i].outVol=0; if (isMuted[i]) { rWrite(0x02+i,0); } else { rWrite(0x02+i,(chan[i].outVol&15)|((chan[i].psgMode&4)<<2)); } } if (chan[i].std.hadArp) { if (!chan[i].inPorta) { if (chan[i].std.arpMode) { chan[i].baseFreq=NOTE_PERIODIC(chan[i].std.arp); } else { chan[i].baseFreq=NOTE_PERIODIC(chan[i].note+chan[i].std.arp); } } chan[i].freqChanged=true; } else { if (chan[i].std.arpMode && chan[i].std.finishedArp) { chan[i].baseFreq=NOTE_PERIODIC(chan[i].note); chan[i].freqChanged=true; } } if (chan[i].std.hadDuty) { ayNoiseFreq=31-chan[i].std.duty; rWrite(0x06,ayNoiseFreq); } if (chan[i].std.hadWave) { chan[i].psgMode=(chan[i].std.wave+1)&7; if (isMuted[i]) { rWrite(0x02+i,0); } else { rWrite(0x02+i,(chan[i].outVol&15)|((chan[i].psgMode&4)<<2)); } } if (chan[i].std.hadEx2) { ayEnvMode=chan[i].std.ex2; rWrite(0x0d,ayEnvMode); } if (chan[i].std.hadEx3) { chan[i].autoEnvNum=chan[i].std.ex3; chan[i].freqChanged=true; if (!chan[i].std.willAlg) chan[i].autoEnvDen=1; } if (chan[i].std.hadAlg) { chan[i].autoEnvDen=chan[i].std.alg; chan[i].freqChanged=true; if (!chan[i].std.willEx3) chan[i].autoEnvNum=1; } if (chan[i].freqChanged || chan[i].keyOn || chan[i].keyOff) { chan[i].freq=parent->calcFreq(chan[i].baseFreq,chan[i].pitch,true); if (chan[i].freq>4095) chan[i].freq=4095; if (chan[i].keyOn) { } if (chan[i].keyOff) { rWrite(0x02+i,0); } rWrite((i-6)<<1,chan[i].freq&0xff); rWrite(1+((i-6)<<1),chan[i].freq>>8); if (chan[i].keyOn) chan[i].keyOn=false; if (chan[i].keyOff) chan[i].keyOff=false; if (chan[i].freqChanged && chan[i].autoEnvNum>0 && chan[i].autoEnvDen>0) { ayEnvPeriod=(chan[i].freq*chan[i].autoEnvDen/chan[i].autoEnvNum)>>4; immWrite(0x0b,ayEnvPeriod); immWrite(0x0c,ayEnvPeriod>>8); } chan[i].freqChanged=false; } } rWrite(0x07, ~((chan[6].psgMode&1)| ((chan[7].psgMode&1)<<1)| ((chan[8].psgMode&1)<<2)| ((chan[6].psgMode&2)<<2)| ((chan[7].psgMode&2)<<3)| ((chan[8].psgMode&2)<<4))); if (ayEnvSlide!=0) { ayEnvSlideLow+=ayEnvSlide; while (ayEnvSlideLow>7) { ayEnvSlideLow-=8; if (ayEnvPeriod<0xffff) { ayEnvPeriod++; immWrite(0x0b,ayEnvPeriod); immWrite(0x0c,ayEnvPeriod>>8); } } while (ayEnvSlideLow<-7) { ayEnvSlideLow+=8; if (ayEnvPeriod>0) { ayEnvPeriod--; immWrite(0x0b,ayEnvPeriod); immWrite(0x0c,ayEnvPeriod>>8); } } } // FM for (int i=0; i<6; i++) { if (i==2 && extMode) continue; chan[i].std.next(); if (chan[i].std.hadVol) { chan[i].outVol=(chan[i].vol*MIN(127,chan[i].std.vol))/127; for (int j=0; j<4; j++) { unsigned short baseAddr=chanOffs[i]|opOffs[j]; DivInstrumentFM::Operator& op=chan[i].state.op[j]; 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); } } } if (chan[i].std.hadArp) { if (!chan[i].inPorta) { if (chan[i].std.arpMode) { chan[i].baseFreq=NOTE_FREQUENCY(chan[i].std.arp); } else { chan[i].baseFreq=NOTE_FREQUENCY(chan[i].note+(signed char)chan[i].std.arp); } } chan[i].freqChanged=true; } else { if (chan[i].std.arpMode && chan[i].std.finishedArp) { chan[i].baseFreq=NOTE_FREQUENCY(chan[i].note); chan[i].freqChanged=true; } } if (chan[i].std.hadAlg) { chan[i].state.alg=chan[i].std.alg; rWrite(chanOffs[i]+ADDR_FB_ALG,(chan[i].state.alg&7)|(chan[i].state.fb<<3)); if (!parent->song.algMacroBehavior) for (int j=0; j<4; j++) { unsigned short baseAddr=chanOffs[i]|opOffs[j]; DivInstrumentFM::Operator& op=chan[i].state.op[j]; 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); } } } } if (chan[i].std.hadFb) { chan[i].state.fb=chan[i].std.fb; rWrite(chanOffs[i]+ADDR_FB_ALG,(chan[i].state.alg&7)|(chan[i].state.fb<<3)); } if (chan[i].std.hadFms) { chan[i].state.fms=chan[i].std.fms; 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].std.hadAms) { chan[i].state.ams=chan[i].std.ams; rWrite(chanOffs[i]+ADDR_LRAF,(isMuted[i]?0:(chan[i].pan<<6))|(chan[i].state.fms&7)|((chan[i].state.ams&3)<<4)); } for (int j=0; j<4; j++) { unsigned short baseAddr=chanOffs[i]|opOffs[j]; DivInstrumentFM::Operator& op=chan[i].state.op[j]; DivMacroInt::IntOp& m=chan[i].std.op[j]; if (m.hadAm) { op.am=m.am; rWrite(baseAddr+ADDR_AM_DR,(op.dr&31)|(op.am<<7)); } if (m.hadAr) { op.ar=m.ar; rWrite(baseAddr+ADDR_RS_AR,(op.ar&31)|(op.rs<<6)); } if (m.hadDr) { op.dr=m.dr; rWrite(baseAddr+ADDR_AM_DR,(op.dr&31)|(op.am<<7)); } if (m.hadMult) { op.mult=m.mult; rWrite(baseAddr+ADDR_MULT_DT,(op.mult&15)|(dtTable[op.dt&7]<<4)); } if (m.hadRr) { op.rr=m.rr; rWrite(baseAddr+ADDR_SL_RR,(op.rr&15)|(op.sl<<4)); } if (m.hadSl) { op.sl=m.sl; rWrite(baseAddr+ADDR_SL_RR,(op.rr&15)|(op.sl<<4)); } if (m.hadTl) { op.tl=127-m.tl; 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); } } if (m.hadRs) { op.rs=m.rs; rWrite(baseAddr+ADDR_RS_AR,(op.ar&31)|(op.rs<<6)); } if (m.hadDt) { op.dt=m.dt; rWrite(baseAddr+ADDR_MULT_DT,(op.mult&15)|(dtTable[op.dt&7]<<4)); } if (m.hadD2r) { op.d2r=m.d2r; rWrite(baseAddr+ADDR_DT2_D2R,op.d2r&31); } if (m.hadSsg) { op.ssgEnv=m.ssg; rWrite(baseAddr+ADDR_SSG,op.ssgEnv&15); } } if (chan[i].keyOn || chan[i].keyOff) { immWrite(0x28,0x00|konOffs[i]); chan[i].keyOff=false; } } // ADPCM-B if (chan[15].furnacePCM) { chan[15].std.next(); if (chan[15].std.hadVol) { chan[15].outVol=(chan[15].vol*MIN(64,chan[15].std.vol))/64; immWrite(0x1b,chan[15].outVol); } if (chan[15].std.hadArp) { if (!chan[15].inPorta) { if (chan[15].std.arpMode) { chan[15].baseFreq=NOTE_ADPCMB(chan[15].std.arp); } else { chan[15].baseFreq=NOTE_ADPCMB(chan[15].note+(signed char)chan[15].std.arp); } } chan[15].freqChanged=true; } else { if (chan[15].std.arpMode && chan[15].std.finishedArp) { chan[15].baseFreq=NOTE_ADPCMB(chan[15].note); chan[15].freqChanged=true; } } } if (chan[15].freqChanged) { chan[15].freq=parent->calcFreq(chan[15].baseFreq,chan[15].pitch,false,4); immWrite(0x19,chan[15].freq&0xff); immWrite(0x1a,(chan[15].freq>>8)&0xff); chan[15].freqChanged=false; } for (int i=0; i<512; i++) { if (pendingWrites[i]!=oldWrites[i]) { immWrite(i,pendingWrites[i]&0xff); oldWrites[i]=pendingWrites[i]; } } for (int i=0; i<6; i++) { if (i==2 && extMode) continue; if (chan[i].freqChanged) { chan[i].freq=parent->calcFreq(chan[i].baseFreq,chan[i].pitch,false,octave(chan[i].baseFreq)); if (chan[i].freq>262143) chan[i].freq=262143; int freqt=toFreq(chan[i].freq); immWrite(chanOffs[i]+ADDR_FREQH,freqt>>8); immWrite(chanOffs[i]+ADDR_FREQ,freqt&0xff); chan[i].freqChanged=false; } if (chan[i].keyOn) { immWrite(0x28,0xf0|konOffs[i]); chan[i].keyOn=false; } } } int DivPlatformYM2610B::octave(int freq) { if (freq>=622.0f*128) { return 128; } else if (freq>=622.0f*64) { return 64; } else if (freq>=622.0f*32) { return 32; } else if (freq>=622.0f*16) { return 16; } else if (freq>=622.0f*8) { return 8; } else if (freq>=622.0f*4) { return 4; } else if (freq>=622.0f*2) { return 2; } else { return 1; } return 1; } int DivPlatformYM2610B::toFreq(int freq) { if (freq>=622.0f*128) { return 0x3800|((freq>>7)&0x7ff); } else if (freq>=622.0f*64) { return 0x3000|((freq>>6)&0x7ff); } else if (freq>=622.0f*32) { return 0x2800|((freq>>5)&0x7ff); } else if (freq>=622.0f*16) { return 0x2000|((freq>>4)&0x7ff); } else if (freq>=622.0f*8) { return 0x1800|((freq>>3)&0x7ff); } else if (freq>=622.0f*4) { return 0x1000|((freq>>2)&0x7ff); } else if (freq>=622.0f*2) { return 0x800|((freq>>1)&0x7ff); } else { return freq&0x7ff; } } int DivPlatformYM2610B::dispatch(DivCommand c) { switch (c.cmd) { case DIV_CMD_NOTE_ON: { if (c.chan>14) { // ADPCM-B DivInstrument* ins=parent->getIns(chan[c.chan].ins); if (ins->type==DIV_INS_AMIGA) { chan[c.chan].furnacePCM=true; } else { chan[c.chan].furnacePCM=false; } if (skipRegisterWrites) break; if (chan[c.chan].furnacePCM) { chan[c.chan].std.init(ins); if (!chan[c.chan].std.willVol) { chan[c.chan].outVol=chan[c.chan].vol; immWrite(0x1b,chan[c.chan].outVol); } DivSample* s=parent->getSample(ins->amiga.initSample); immWrite(0x12,(s->offB>>8)&0xff); immWrite(0x13,s->offB>>16); int end=s->offB+s->lengthB-1; immWrite(0x14,(end>>8)&0xff); immWrite(0x15,end>>16); immWrite(0x11,isMuted[c.chan]?0:(chan[c.chan].pan<<6)); immWrite(0x10,0x80); // start if (c.value!=DIV_NOTE_NULL) { chan[c.chan].note=c.value; chan[c.chan].baseFreq=NOTE_ADPCMB(chan[c.chan].note); chan[c.chan].freqChanged=true; } chan[c.chan].active=true; chan[c.chan].keyOn=true; } else { chan[c.chan].std.init(NULL); chan[c.chan].outVol=chan[c.chan].vol; if ((12*sampleBank+c.value%12)>=parent->song.sampleLen) { immWrite(0x10,0x01); // reset immWrite(0x12,0); immWrite(0x13,0); immWrite(0x14,0); immWrite(0x15,0); break; } DivSample* s=parent->getSample(12*sampleBank+c.value%12); immWrite(0x12,(s->offB>>8)&0xff); immWrite(0x13,s->offB>>16); int end=s->offB+s->lengthB-1; immWrite(0x14,(end>>8)&0xff); immWrite(0x15,end>>16); immWrite(0x11,isMuted[c.chan]?0:(chan[c.chan].pan<<6)); immWrite(0x10,0x80); // start chan[c.chan].baseFreq=(((unsigned int)s->rate)<<16)/(chipClock/144); chan[c.chan].freqChanged=true; } break; } if (c.chan>8) { // ADPCM-A if (skipRegisterWrites) break; if ((12*sampleBank+c.value%12)>=parent->song.sampleLen) { immWrite(0x100,0x80|(1<<(c.chan-9))); immWrite(0x110+c.chan-9,0); immWrite(0x118+c.chan-9,0); immWrite(0x120+c.chan-9,0); immWrite(0x128+c.chan-9,0); break; } DivSample* s=parent->getSample(12*sampleBank+c.value%12); immWrite(0x110+c.chan-9,(s->offA>>8)&0xff); immWrite(0x118+c.chan-9,s->offA>>16); int end=s->offA+s->lengthA-1; immWrite(0x120+c.chan-9,(end>>8)&0xff); immWrite(0x128+c.chan-9,end>>16); immWrite(0x108+(c.chan-9),isMuted[c.chan]?0:((chan[c.chan].pan<<6)|chan[c.chan].vol)); immWrite(0x100,0x00|(1<<(c.chan-9))); break; } DivInstrument* ins=parent->getIns(chan[c.chan].ins); chan[c.chan].std.init(ins); if (c.chan<6) { if (!chan[c.chan].std.willVol) { chan[c.chan].outVol=chan[c.chan].vol; } } if (c.chan>5) { // PSG if (c.value!=DIV_NOTE_NULL) { chan[c.chan].baseFreq=NOTE_PERIODIC(c.value); chan[c.chan].freqChanged=true; chan[c.chan].note=c.value; } chan[c.chan].active=true; chan[c.chan].keyOn=true; if (isMuted[c.chan]) { rWrite(0x02+c.chan,0); } else { rWrite(0x02+c.chan,(chan[c.chan].vol&15)|((chan[c.chan].psgMode&4)<<2)); } break; } if (chan[c.chan].insChanged) { chan[c.chan].state=ins->fm; } for (int i=0; i<4; i++) { unsigned short baseAddr=chanOffs[c.chan]|opOffs[i]; DivInstrumentFM::Operator& op=chan[c.chan].state.op[i]; if (isOutput[chan[c.chan].state.alg][i]) { if (!chan[c.chan].active || chan[c.chan].insChanged) { rWrite(baseAddr+ADDR_TL,127-(((127-op.tl)*(chan[c.chan].outVol&0x7f))/127)); } } else { if (chan[c.chan].insChanged) { rWrite(baseAddr+ADDR_TL,op.tl); } } if (chan[c.chan].insChanged) { 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); } } if (chan[c.chan].insChanged) { rWrite(chanOffs[c.chan]+ADDR_FB_ALG,(chan[c.chan].state.alg&7)|(chan[c.chan].state.fb<<3)); rWrite(chanOffs[c.chan]+ADDR_LRAF,(isMuted[c.chan]?0:(chan[c.chan].pan<<6))|(chan[c.chan].state.fms&7)|((chan[c.chan].state.ams&3)<<4)); } chan[c.chan].insChanged=false; if (c.value!=DIV_NOTE_NULL) { chan[c.chan].baseFreq=NOTE_FREQUENCY(c.value); chan[c.chan].freqChanged=true; chan[c.chan].note=c.value; } chan[c.chan].keyOn=true; chan[c.chan].active=true; break; } case DIV_CMD_NOTE_OFF: if (c.chan>14) { immWrite(0x10,0x01); // reset break; } if (c.chan>8) { immWrite(0x100,0x80|(1<<(c.chan-9))); break; } chan[c.chan].keyOff=true; chan[c.chan].keyOn=false; chan[c.chan].active=false; chan[c.chan].std.init(NULL); break; case DIV_CMD_NOTE_OFF_ENV: if (c.chan>14) { immWrite(0x10,0x01); // reset break; } if (c.chan>8) { immWrite(0x100,0x80|(1<<(c.chan-9))); break; } if (c.chan>5) { chan[c.chan].std.release(); break; } chan[c.chan].keyOff=true; chan[c.chan].keyOn=false; chan[c.chan].active=false; chan[c.chan].std.release(); break; case DIV_CMD_ENV_RELEASE: chan[c.chan].std.release(); break; case DIV_CMD_VOLUME: { chan[c.chan].vol=c.value; if (!chan[c.chan].std.hasVol) { chan[c.chan].outVol=c.value; } if (c.chan>14) { // ADPCM-B immWrite(0x1b,chan[c.chan].outVol); break; } if (c.chan>8) { // ADPCM-A immWrite(0x108+(c.chan-9),isMuted[c.chan]?0:((chan[c.chan].pan<<6)|chan[c.chan].vol)); break; } if (c.chan>5) { // PSG if (isMuted[c.chan]) { rWrite(0x02+c.chan,0); } else { if (chan[c.chan].active) rWrite(0x02+c.chan,(chan[c.chan].vol&15)|((chan[c.chan].psgMode&4)<<2)); } break; } for (int i=0; i<4; i++) { unsigned short baseAddr=chanOffs[c.chan]|opOffs[i]; DivInstrumentFM::Operator& op=chan[c.chan].state.op[i]; if (isOutput[chan[c.chan].state.alg][i]) { rWrite(baseAddr+ADDR_TL,127-(((127-op.tl)*(chan[c.chan].outVol&0x7f))/127)); } else { rWrite(baseAddr+ADDR_TL,op.tl); } } break; } case DIV_CMD_GET_VOLUME: { return chan[c.chan].vol; break; } case DIV_CMD_INSTRUMENT: if (chan[c.chan].ins!=c.value || c.value2==1) { chan[c.chan].insChanged=true; } chan[c.chan].ins=c.value; break; case DIV_CMD_PANNING: { switch (c.value) { case 0x01: chan[c.chan].pan=1; break; case 0x10: chan[c.chan].pan=2; break; default: chan[c.chan].pan=3; break; } if (c.chan>14) { immWrite(0x11,isMuted[c.chan]?0:(chan[c.chan].pan<<6)); break; } if (c.chan>8) { immWrite(0x108+(c.chan-9),isMuted[c.chan]?0:((chan[c.chan].pan<<6)|chan[c.chan].vol)); break; } if (c.chan>5) break; rWrite(chanOffs[c.chan]+ADDR_LRAF,(isMuted[c.chan]?0:(chan[c.chan].pan<<6))|(chan[c.chan].state.fms&7)|((chan[c.chan].state.ams&3)<<4)); break; } case DIV_CMD_PITCH: { chan[c.chan].pitch=c.value; chan[c.chan].freqChanged=true; break; } case DIV_CMD_NOTE_PORTA: { if (c.chan>5) { // PSG int destFreq=NOTE_PERIODIC(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; } int destFreq=NOTE_FREQUENCY(c.value2); int newFreq; bool return2=false; if (destFreq>chan[c.chan].baseFreq) { newFreq=chan[c.chan].baseFreq+c.value*octave(chan[c.chan].baseFreq); if (newFreq>=destFreq) { newFreq=destFreq; return2=true; } } else { newFreq=chan[c.chan].baseFreq-c.value*octave(chan[c.chan].baseFreq); if (newFreq<=destFreq) { newFreq=destFreq; return2=true; } } if (!chan[c.chan].portaPause) { if (octave(chan[c.chan].baseFreq)!=octave(newFreq)) { chan[c.chan].portaPause=true; break; } } chan[c.chan].baseFreq=newFreq; chan[c.chan].portaPause=false; chan[c.chan].freqChanged=true; if (return2) return 2; break; } case DIV_CMD_SAMPLE_BANK: sampleBank=c.value; if (sampleBank>(parent->song.sample.size()/12)) { sampleBank=parent->song.sample.size()/12; } iface.sampleBank=sampleBank; break; case DIV_CMD_LEGATO: { if (c.chan>5) { // PSG chan[c.chan].baseFreq=NOTE_PERIODIC(c.value); } else { chan[c.chan].baseFreq=NOTE_FREQUENCY(c.value); } chan[c.chan].freqChanged=true; break; } case DIV_CMD_FM_LFO: { rWrite(0x22,(c.value&7)|((c.value>>4)<<3)); break; } case DIV_CMD_FM_FB: { if (c.chan>5) break; chan[c.chan].state.fb=c.value&7; rWrite(chanOffs[c.chan]+ADDR_FB_ALG,(chan[c.chan].state.alg&7)|(chan[c.chan].state.fb<<3)); break; } case DIV_CMD_FM_MULT: { if (c.chan>5) break; unsigned short baseAddr=chanOffs[c.chan]|opOffs[orderedOps[c.value]]; DivInstrumentFM::Operator& op=chan[c.chan].state.op[orderedOps[c.value]]; op.mult=c.value2&15; rWrite(baseAddr+ADDR_MULT_DT,(op.mult&15)|(dtTable[op.dt&7]<<4)); break; } case DIV_CMD_FM_TL: { if (c.chan>5) break; unsigned short baseAddr=chanOffs[c.chan]|opOffs[orderedOps[c.value]]; DivInstrumentFM::Operator& op=chan[c.chan].state.op[orderedOps[c.value]]; op.tl=c.value2; if (isOutput[chan[c.chan].state.alg][c.value]) { rWrite(baseAddr+ADDR_TL,127-(((127-op.tl)*(chan[c.chan].outVol&0x7f))/127)); } else { rWrite(baseAddr+ADDR_TL,op.tl); } break; } case DIV_CMD_FM_AR: { if (c.chan>5) break; if (c.value<0) { for (int i=0; i<4; i++) { DivInstrumentFM::Operator& op=chan[c.chan].state.op[i]; op.ar=c.value2&31; unsigned short baseAddr=chanOffs[c.chan]|opOffs[i]; rWrite(baseAddr+ADDR_RS_AR,(op.ar&31)|(op.rs<<6)); } } else { DivInstrumentFM::Operator& op=chan[c.chan].state.op[orderedOps[c.value]]; op.ar=c.value2&31; unsigned short baseAddr=chanOffs[c.chan]|opOffs[orderedOps[c.value]]; rWrite(baseAddr+ADDR_RS_AR,(op.ar&31)|(op.rs<<6)); } break; } case DIV_CMD_STD_NOISE_MODE: if (c.chan<6 || c.chan>8) break; chan[c.chan].psgMode=(c.value+1)&7; if (isMuted[c.chan]) { rWrite(0x02+c.chan,0); } else if (chan[c.chan].active) { rWrite(0x02+c.chan,(chan[c.chan].outVol&15)|((chan[c.chan].psgMode&4)<<2)); } break; case DIV_CMD_STD_NOISE_FREQ: if (c.chan<6 || c.chan>8) break; ayNoiseFreq=31-c.value; rWrite(0x06,ayNoiseFreq); break; case DIV_CMD_AY_ENVELOPE_SET: if (c.chan<6 || c.chan>8) break; ayEnvMode=c.value>>4; rWrite(0x0d,ayEnvMode); if (c.value&15) { chan[c.chan].psgMode|=4; } else { chan[c.chan].psgMode&=~4; } if (isMuted[c.chan]) { rWrite(0x02+c.chan,0); } else { rWrite(0x02+c.chan,(chan[c.chan].vol&15)|((chan[c.chan].psgMode&4)<<2)); } break; case DIV_CMD_AY_ENVELOPE_LOW: if (c.chan<6 || c.chan>8) break; ayEnvPeriod&=0xff00; ayEnvPeriod|=c.value; immWrite(0x0b,ayEnvPeriod); immWrite(0x0c,ayEnvPeriod>>8); break; case DIV_CMD_AY_ENVELOPE_HIGH: if (c.chan<6 || c.chan>8) break; ayEnvPeriod&=0xff; ayEnvPeriod|=c.value<<8; immWrite(0x0b,ayEnvPeriod); immWrite(0x0c,ayEnvPeriod>>8); break; case DIV_CMD_AY_ENVELOPE_SLIDE: if (c.chan<6 || c.chan>8) break; ayEnvSlide=c.value; break; case DIV_CMD_AY_AUTO_ENVELOPE: if (c.chan<6 || c.chan>8) break; chan[c.chan].autoEnvNum=c.value>>4; chan[c.chan].autoEnvDen=c.value&15; chan[c.chan].freqChanged=true; break; case DIV_ALWAYS_SET_VOLUME: return 0; break; case DIV_CMD_GET_VOLMAX: if (c.chan>14) return 255; if (c.chan>8) return 31; if (c.chan>5) return 15; return 127; break; case DIV_CMD_PRE_PORTA: if (c.chan>5) { if (chan[c.chan].active && c.value2) { if (parent->song.resetMacroOnPorta) chan[c.chan].std.init(parent->getIns(chan[c.chan].ins)); } } chan[c.chan].inPorta=c.value; break; case DIV_CMD_PRE_NOTE: break; default: //printf("WARNING: unimplemented command %d\n",c.cmd); break; } return 1; } void DivPlatformYM2610B::muteChannel(int ch, bool mute) { isMuted[ch]=mute; if (ch>14) { // ADPCM-B immWrite(0x11,isMuted[ch]?0:(chan[ch].pan<<6)); } if (ch>8) { // ADPCM-A immWrite(0x108+(ch-9),isMuted[ch]?0:((chan[ch].pan<<6)|chan[ch].vol)); return; } if (ch>5) { // PSG if (isMuted[ch]) { rWrite(0x02+ch,0); } else { rWrite(0x02+ch,(chan[ch].outVol&15)|((chan[ch].psgMode&4)<<2)); } return; } // FM rWrite(chanOffs[ch]+ADDR_LRAF,(isMuted[ch]?0:(chan[ch].pan<<6))|(chan[ch].state.fms&7)|((chan[ch].state.ams&3)<<4)); } void DivPlatformYM2610B::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 (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; } } for (int i=6; i<16; i++) { chan[i].insChanged=true; } immWrite(0x0b,ayEnvPeriod); immWrite(0x0c,ayEnvPeriod>>8); immWrite(0x0d,ayEnvMode); } void* DivPlatformYM2610B::getChanState(int ch) { return &chan[ch]; } unsigned char* DivPlatformYM2610B::getRegisterPool() { return regPool; } int DivPlatformYM2610B::getRegisterPoolSize() { return 512; } void DivPlatformYM2610B::poke(unsigned int addr, unsigned short val) { immWrite(addr,val); } void DivPlatformYM2610B::poke(std::vector& wlist) { for (DivRegWrite& i: wlist) immWrite(i.addr,i.val); } void DivPlatformYM2610B::reset() { while (!writes.empty()) writes.pop(); memset(regPool,0,512); if (dumpWrites) { addWrite(0xffffffff,0); } fm->reset(); for (int i=0; i<16; i++) { chan[i]=DivPlatformYM2610B::Channel(); } for (int i=0; i<6; i++) { chan[i].vol=0x7f; chan[i].outVol=0x7f; } for (int i=6; i<9; i++) { chan[i].vol=0x0f; } for (int i=9; i<15; i++) { chan[i].vol=0x1f; } chan[15].vol=0xff; for (int i=0; i<512; i++) { oldWrites[i]=-1; pendingWrites[i]=-1; } lastBusy=60; dacMode=0; dacPeriod=0; dacPos=0; dacRate=0; dacSample=-1; sampleBank=0; ayEnvPeriod=0; ayEnvMode=0; ayEnvSlide=0; ayEnvSlideLow=0; ayNoiseFreq=0; delay=0; extMode=false; // AY noise immWrite(0x06,ayNoiseFreq); // LFO immWrite(0x22,0x08); // PCM volume immWrite(0x101,0x3f); // A immWrite(0x1b,0xff); // B } bool DivPlatformYM2610B::isStereo() { return true; } bool DivPlatformYM2610B::keyOffAffectsArp(int ch) { return (ch>5); } void DivPlatformYM2610B::notifyInsChange(int ins) { for (int i=0; i<16; i++) { if (chan[i].ins==ins) { chan[i].insChanged=true; } } } void DivPlatformYM2610B::notifyInsDeletion(void* ins) { for (int i=6; i<9; i++) { chan[i].std.notifyInsDeletion((DivInstrument*)ins); } } int DivPlatformYM2610B::init(DivEngine* p, int channels, int sugRate, unsigned int flags) { parent=p; dumpWrites=false; skipRegisterWrites=false; for (int i=0; i<16; i++) { isMuted[i]=false; } chipClock=8000000; rate=chipClock/16; iface.parent=parent; iface.sampleBank=0; fm=new ymfm::ym2610b(iface); reset(); return 16; } void DivPlatformYM2610B::quit() { delete fm; } DivPlatformYM2610B::~DivPlatformYM2610B() { }