/** * 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 "opl.h" #include "../engine.h" #include "../../ta-log.h" #include #include #define rWrite(a,v) if (!skipRegisterWrites) {pendingWrites[a]=v;} #define immWrite(a,v) if (!skipRegisterWrites) {writes.emplace(a,v); if (dumpWrites) {addWrite(a,v);} } #define CHIP_FREQBASE chipFreqBase // N = invalid #define N 255 const unsigned char slotsOPL2i[4][20]={ {0, 1, 2, 6, 7, 8, 12, 13, 14}, // OP1 {3, 4, 5, 9, 10, 11, 15, 16, 17}, // OP2 {N, N, N, N, N, N, N, N, N}, {N, N, N, N, N, N, N, N, N} }; const unsigned char slotsOPL2Drumsi[4][20]={ {0, 1, 2, 6, 7, 8, 12, 16, 14, 17, 13}, // OP1 {3, 4, 5, 9, 10, 11, 15, N, N, N, N}, // OP2 {N, N, N, N, N, N, N, N, N, N, N}, {N, N, N, N, N, N, N, N, N, N, N} }; const unsigned short chanMapOPL2[20]={ 0, 1, 2, 3, 4, 5, 6, 7, 8, N, N, N, N, N, N, N, N, N, N, N }; const unsigned short chanMapOPL2Drums[20]={ 0, 1, 2, 3, 4, 5, 6, 7, 8, 8, 7, N, N, N, N, N, N, N, N, N }; const unsigned char outChanMapOPL2[18]={ 0, 1, 2, 3, 4, 5, 6, 7, 8, N, N, N, N, N, N, N, N, N }; const unsigned char* slotsOPL2[4]={ slotsOPL2i[0], slotsOPL2i[1], slotsOPL2i[2], slotsOPL2i[3] }; const unsigned char* slotsOPL2Drums[4]={ slotsOPL2Drumsi[0], slotsOPL2Drumsi[1], slotsOPL2Drumsi[2], slotsOPL2Drumsi[3] }; const unsigned char slotsOPL3i[4][20]={ {0, 6, 1, 7, 2, 8, 18, 24, 19, 25, 20, 26, 30, 31, 32, 12, 13, 14}, // OP1 {3, 9, 4, 10, 5, 11, 21, 27, 22, 28, 23, 29, 33, 34, 35, 15, 16, 17}, // OP2 {6, N, 7, N, 8, N, 24, N, 25, N, 26, N, N, N, N, N, N, N}, // OP3 {9, N, 10, N, 11, N, 27, N, 28, N, 29, N, N, N, N, N, N, N} // OP4 }; const unsigned char slotsOPL3Drumsi[4][20]={ {0, 6, 1, 7, 2, 8, 18, 24, 19, 25, 20, 26, 30, 31, 32, 12, 16, 14, 17, 13}, // OP1 {3, 9, 4, 10, 5, 11, 21, 27, 22, 28, 23, 29, 33, 34, 35, 15, N, N, N, N}, // OP2 {6, N, 7, N, 8, N, 24, N, 25, N, 26, N, N, N, N, N, N, N, N, N}, // OP3 {9, N, 10, N, 11, N, 27, N, 28, N, 29, N, N, N, N, N, N, N, N, N} // OP4 }; const unsigned short chanMapOPL3[20]={ 0, 3, 1, 4, 2, 5, 0x100, 0x103, 0x101, 0x104, 0x102, 0x105, 0x106, 0x107, 0x108, 6, 7, 8, N, N }; const unsigned short chanMapOPL3Drums[20]={ 0, 3, 1, 4, 2, 5, 0x100, 0x103, 0x101, 0x104, 0x102, 0x105, 0x106, 0x107, 0x108, 6, 7, 8, 8, 7 }; const unsigned char outChanMapOPL3[18]={ 0, 3, 1, 4, 2, 5, 9, 12, 10, 13, 11, 14, 15, 16, 17, 6, 7, 8 }; const unsigned char* slotsOPL3[4]={ slotsOPL3i[0], slotsOPL3i[1], slotsOPL3i[2], slotsOPL3i[3] }; const unsigned char* slotsOPL3Drums[4]={ slotsOPL3Drumsi[0], slotsOPL3Drumsi[1], slotsOPL3Drumsi[2], slotsOPL3Drumsi[3] }; const unsigned int slotMap[36]={ 0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x08, 0x09, 0x0a, 0x0b, 0x0c, 0x0d, 0x10, 0x11, 0x12, 0x13, 0x14, 0x15, 0x100, 0x101, 0x102, 0x103, 0x104, 0x105, 0x108, 0x109, 0x10a, 0x10b, 0x10c, 0x10d, 0x110, 0x111, 0x112, 0x113, 0x114, 0x115, }; const bool isOutputL[2][4][4]={ { // 2-op {false, true, false, false}, // 1 > 2 { true, true, false, false}, // 1 + 2 {false, true, false, false}, // ditto, 0 { true, true, false, false}, // ditto, 1 }, { // 4-op {false, false, false, true}, // 1 > 2 > 3 > 4 { true, false, false, true}, // 1 + (2 > 3 > 4) {false, true, false, true}, // (1 > 2) + (3 > 4) { true, false, true, true} // 1 + (2 > 3) + 4 } }; #undef N const int orderedOpsL[4]={ 0,2,1,3 }; #define ADDR_AM_VIB_SUS_KSR_MULT 0x20 #define ADDR_KSL_TL 0x40 #define ADDR_AR_DR 0x60 #define ADDR_SL_RR 0x80 #define ADDR_WS 0xe0 #define ADDR_FREQ 0xa0 #define ADDR_FREQH 0xb0 #define ADDR_LR_FB_ALG 0xc0 const char* DivPlatformOPL::getEffectName(unsigned char effect) { switch (effect) { case 0x10: return "10xx: Set global AM depth (0: 1dB, 1: 4.8dB)"; break; case 0x11: return "11xx: Set feedback (0 to 7)"; break; case 0x12: return "12xx: Set level of operator 1 (0 highest, 3F lowest)"; break; case 0x13: return "13xx: Set level of operator 2 (0 highest, 3F lowest)"; break; case 0x14: return "14xx: Set level of operator 3 (0 highest, 3F lowest; 4-op only)"; break; case 0x15: return "15xx: Set level of operator 4 (0 highest, 3F lowest; 4-op only)"; break; case 0x16: return "16xy: Set operator multiplier (x: operator from 1 to 4; y: multiplier)"; break; case 0x17: return "17xx: Set global vibrato depth (0: normal, 1: double)"; break; case 0x18: if (properDrumsSys) { return "18xx: Toggle drums mode (1: enabled; 0: disabled)"; } break; case 0x19: return "19xx: Set attack of all operators (0 to F)"; break; case 0x1a: return "1Axx: Set attack of operator 1 (0 to F)"; break; case 0x1b: return "1Bxx: Set attack of operator 2 (0 to F)"; break; case 0x1c: return "1Cxx: Set attack of operator 3 (0 to F; 4-op only)"; break; case 0x1d: return "1Dxx: Set attack of operator 4 (0 to F; 4-op only)"; break; case 0x2a: return "2Axy: Set waveform (x: operator from 1 to 4 (0 for all ops); y: waveform from 0 to 3 in OPL2 and 0 to 7 in OPL3)"; break; case 0x30: return "30xx: Toggle hard envelope reset on new notes"; break; case 0x50: return "50xy: Set AM (x: operator from 1 to 4 (0 for all ops); y: AM)"; break; case 0x51: return "51xy: Set sustain level (x: operator from 1 to 4 (0 for all ops); y: sustain)"; break; case 0x52: return "52xy: Set release (x: operator from 1 to 4 (0 for all ops); y: release)"; break; case 0x53: return "53xy: Set vibrato (x: operator from 1 to 4 (0 for all ops); y: enabled)"; break; case 0x54: return "54xy: Set key scale level (x: operator from 1 to 4 (0 for all ops); y: level from 0 to 3)"; break; case 0x55: return "55xy: Set envelope sustain (x: operator from 1 to 4 (0 for all ops); y: enabled)"; break; case 0x56: return "56xx: Set decay of all operators (0 to F)"; break; case 0x57: return "57xx: Set decay of operator 1 (0 to F)"; break; case 0x58: return "58xx: Set decay of operator 2 (0 to F)"; break; case 0x59: return "59xx: Set decay of operator 3 (0 to F; 4-op only)"; break; case 0x5a: return "5Axx: Set decay of operator 4 (0 to F; 4-op only)"; break; case 0x5b: return "5Bxy: Set whether key will scale envelope (x: operator from 1 to 4 (0 for all ops); y: enabled)"; break; } return NULL; } void DivPlatformOPL::acquire_nuked(short* bufL, short* bufR, size_t start, size_t len) { static short o[2]; static int os[2]; static ymfm::ymfm_output<2> aOut; for (size_t h=start; h=0) { adpcmB->write(w.addr-7,(w.val&15)|0x80); OPL3_WriteReg(&fm,w.addr,w.val&0xc0); } else { OPL3_WriteReg(&fm,w.addr,w.val); } break; case 7: case 9: case 10: case 11: case 12: case 13: case 14: case 15: case 16: case 17: case 18: case 21: case 22: case 23: if (adpcmChan>=0) { adpcmB->write(w.addr-7,w.val); } else { OPL3_WriteReg(&fm,w.addr,w.val); } break; default: OPL3_WriteReg(&fm,w.addr,w.val); break; } regPool[w.addr&511]=w.val; writes.pop(); } OPL3_Generate(&fm,o); os[0]+=o[0]; os[1]+=o[1]; if (adpcmChan>=0) { adpcmB->clock(); aOut.clear(); adpcmB->output<2>(aOut,0); if (!isMuted[adpcmChan]) { os[0]-=aOut.data[0]>>3; os[1]-=aOut.data[0]>>3; oscBuf[adpcmChan]->data[oscBuf[adpcmChan]->needle++]+=aOut.data[0]; } else { oscBuf[adpcmChan]->data[oscBuf[adpcmChan]->needle++]=0; } } for (int i=0; idata[oscBuf[i]->needle]=0; if (fm.channel[i].out[0]!=NULL) { oscBuf[i]->data[oscBuf[i]->needle]+=*fm.channel[ch].out[0]; } if (fm.channel[i].out[1]!=NULL) { oscBuf[i]->data[oscBuf[i]->needle]+=*fm.channel[ch].out[1]; } oscBuf[i]->data[oscBuf[i]->needle]<<=1; oscBuf[i]->needle++; } if (os[0]<-32768) os[0]=-32768; if (os[0]>32767) os[0]=32767; if (os[1]<-32768) os[1]=-32768; if (os[1]>32767) os[1]=32767; bufL[h]=os[0]; bufR[h]=os[1]; } } void DivPlatformOPL::acquire(short* bufL, short* bufR, size_t start, size_t len) { //if (useYMFM) { // acquire_ymfm(bufL,bufR,start,len); //} else { acquire_nuked(bufL,bufR,start,len); //} } double DivPlatformOPL::NOTE_ADPCMB(int note) { if (adpcmChan<0) return 0; if (chan[adpcmChan].sample>=0 && chan[adpcmChan].samplesong.sampleLen) { double off=65535.0*(double)(parent->getSample(chan[adpcmChan].sample)->centerRate)/8363.0; return parent->calcBaseFreq((double)chipClock/144,off,note,false); } return 0; } void DivPlatformOPL::tick(bool sysTick) { for (int i=0; i=melodicChans) { rWrite(baseAddr+ADDR_KSL_TL,(63-(((63-op.tl)*(chan[i].outVol&0x3f))/63))|(op.ksl<<6)); } else { rWrite(baseAddr+ADDR_KSL_TL,op.tl|(op.ksl<<6)); } } } } if (chan[i].std.arp.had) { if (!chan[i].inPorta) { if (chan[i].std.arp.mode) { chan[i].baseFreq=NOTE_FREQUENCY(chan[i].std.arp.val); } else { chan[i].baseFreq=NOTE_FREQUENCY(chan[i].note+(signed char)chan[i].std.arp.val); } } chan[i].freqChanged=true; } else { if (chan[i].std.arp.mode && chan[i].std.arp.finished) { chan[i].baseFreq=NOTE_FREQUENCY(chan[i].note); chan[i].freqChanged=true; } } if (oplType==3 && chan[i].std.panL.had) { chan[i].pan=((chan[i].std.panL.val&1)<<1)|((chan[i].std.panL.val&2)>>1); } 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,-2048,2048); } 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].keyOn=true; } } if (chan[i].std.alg.had) { chan[i].state.alg=chan[i].std.alg.val; } if (chan[i].std.fb.had) { chan[i].state.fb=chan[i].std.fb.val; } if (chan[i].std.alg.had || chan[i].std.fb.had || (oplType==3 && chan[i].std.panL.had)) { if (isMuted[i]) { rWrite(chanMap[i]+ADDR_LR_FB_ALG,(chan[i].state.alg&1)|(chan[i].state.fb<<1)); if (ops==4) { rWrite(chanMap[i+1]+ADDR_LR_FB_ALG,((chan[i].state.alg>>1)&1)|(chan[i].state.fb<<1)); } } else { rWrite(chanMap[i]+ADDR_LR_FB_ALG,(chan[i].state.alg&1)|(chan[i].state.fb<<1)|((chan[i].pan&3)<<4)); if (ops==4) { rWrite(chanMap[i+1]+ADDR_LR_FB_ALG,((chan[i].state.alg>>1)&1)|(chan[i].state.fb<<1)|((chan[i].pan&3)<<4)); } } } for (int j=0; j1) { if (m.ws.had) { op.ws=m.ws.val; rWrite(baseAddr+ADDR_WS,op.ws&((oplType==3)?7:3)); } } if (m.tl.had) { op.tl=63-m.tl.val; } if (m.ksl.had) { op.ksl=m.ksl.val; } if (m.tl.had || m.ksl.had) { if (isMuted[i]) { rWrite(baseAddr+ADDR_KSL_TL,63|(op.ksl<<6)); } else { if (isOutputL[ops==4][chan[i].state.alg][j] || i>=melodicChans) { rWrite(baseAddr+ADDR_KSL_TL,(63-(((63-op.tl)*(chan[i].outVol&0x3f))/63))|(op.ksl<<6)); } else { rWrite(baseAddr+ADDR_KSL_TL,op.tl|(op.ksl<<6)); } } } } if (i=0) { if (chan[adpcmChan].furnacePCM) { chan[adpcmChan].std.next(); if (chan[adpcmChan].std.vol.had) { chan[adpcmChan].outVol=(chan[adpcmChan].vol*MIN(64,chan[adpcmChan].std.vol.val))/64; immWrite(18,chan[adpcmChan].outVol); } if (chan[adpcmChan].std.arp.had) { if (!chan[adpcmChan].inPorta) { if (chan[adpcmChan].std.arp.mode) { chan[adpcmChan].baseFreq=NOTE_ADPCMB(chan[adpcmChan].std.arp.val); } else { chan[adpcmChan].baseFreq=NOTE_ADPCMB(chan[adpcmChan].note+(signed char)chan[adpcmChan].std.arp.val); } } chan[adpcmChan].freqChanged=true; } else { if (chan[adpcmChan].std.arp.mode && chan[adpcmChan].std.arp.finished) { chan[adpcmChan].baseFreq=NOTE_ADPCMB(chan[adpcmChan].note); chan[adpcmChan].freqChanged=true; } } } if (chan[adpcmChan].freqChanged) { if (chan[adpcmChan].sample>=0 && chan[adpcmChan].samplesong.sampleLen) { double off=65535.0*(double)(parent->getSample(chan[adpcmChan].sample)->centerRate)/8363.0; chan[adpcmChan].freq=parent->calcFreq(chan[adpcmChan].baseFreq,chan[adpcmChan].pitch,false,4,chan[adpcmChan].pitch2,(double)chipClock/144,off); } else { chan[adpcmChan].freq=0; } immWrite(16,chan[adpcmChan].freq&0xff); immWrite(17,(chan[adpcmChan].freq>>8)&0xff); chan[adpcmChan].freqChanged=false; } } for (int i=0; i<512; i++) { if (pendingWrites[i]!=oldWrites[i]) { immWrite(i,pendingWrites[i]&0xff); oldWrites[i]=pendingWrites[i]; } } bool updateDrums=false; for (int i=0; icalcFreq(chan[i].baseFreq,chan[i].pitch,false,octave(chan[i].baseFreq),chan[i].pitch2,chipClock,CHIP_FREQBASE); if (chan[i].fixedFreq>0) chan[i].freq=chan[i].fixedFreq; if (chan[i].freq>131071) chan[i].freq=131071; int freqt=toFreq(chan[i].freq)+chan[i].pitch2; chan[i].freqH=freqt>>8; chan[i].freqL=freqt&0xff; immWrite(chanMap[i]+ADDR_FREQ,chan[i].freqL); } if (i=OPLL_C_NUM*64) { return 128; } else if (freq>=OPLL_C_NUM*32) { return 64; } else if (freq>=OPLL_C_NUM*16) { return 32; } else if (freq>=OPLL_C_NUM*8) { return 16; } else if (freq>=OPLL_C_NUM*4) { return 8; } else if (freq>=OPLL_C_NUM*2) { return 4; } else if (freq>=OPLL_C_NUM) { return 2; } else { return 1; } return 1; } int DivPlatformOPL::toFreq(int freq) { if (freq>=OPLL_C_NUM*64) { return 0x1c00|((freq>>7)&0x3ff); } else if (freq>=OPLL_C_NUM*32) { return 0x1800|((freq>>6)&0x3ff); } else if (freq>=OPLL_C_NUM*16) { return 0x1400|((freq>>5)&0x3ff); } else if (freq>=OPLL_C_NUM*8) { return 0x1000|((freq>>4)&0x3ff); } else if (freq>=OPLL_C_NUM*4) { return 0xc00|((freq>>3)&0x3ff); } else if (freq>=OPLL_C_NUM*2) { return 0x800|((freq>>2)&0x3ff); } else if (freq>=OPLL_C_NUM) { return 0x400|((freq>>1)&0x3ff); } else { return freq&0x3ff; } } void DivPlatformOPL::muteChannel(int ch, bool mute) { isMuted[ch]=mute; if (ch==adpcmChan) return; if (oplType<3 && ch=melodicChans) { rWrite(baseAddr+ADDR_KSL_TL,(63-(((63-op.tl)*(chan[ch].outVol&0x3f))/63))|(op.ksl<<6)); } else { rWrite(baseAddr+ADDR_KSL_TL,op.tl|(op.ksl<<6)); } } } if (isMuted[ch]) { rWrite(chanMap[ch]+ADDR_LR_FB_ALG,(chan[ch].state.alg&1)|(chan[ch].state.fb<<1)); if (ops==4) { rWrite(chanMap[ch+1]+ADDR_LR_FB_ALG,((chan[ch].state.alg>>1)&1)|(chan[ch].state.fb<<1)); } } else { rWrite(chanMap[ch]+ADDR_LR_FB_ALG,(chan[ch].state.alg&1)|(chan[ch].state.fb<<1)|((chan[ch].pan&3)<<4)); if (ops==4) { rWrite(chanMap[ch+1]+ADDR_LR_FB_ALG,((chan[ch].state.alg>>1)&1)|(chan[ch].state.fb<<1)|((chan[ch].pan&3)<<4)); } } } int DivPlatformOPL::dispatch(DivCommand c) { if (c.chan>=totalChans && c.chan!=adpcmChan) return 0; // ineffective in 4-op mode if (oplType==3 && c.chan!=adpcmChan && c.chan<14 && (c.chan&1) && c.cmd!=DIV_CMD_GET_VOLMAX && c.cmd!=DIV_ALWAYS_SET_VOLUME) { if (chan[c.chan-1].fourOp) return 0; } switch (c.cmd) { case DIV_CMD_NOTE_ON: { if (c.chan==adpcmChan) { // ADPCM DivInstrument* ins=parent->getIns(chan[c.chan].ins,DIV_INS_FM); 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].macroInit(ins); if (!chan[c.chan].std.vol.will) { chan[c.chan].outVol=chan[c.chan].vol; immWrite(18,chan[c.chan].outVol); } chan[c.chan].sample=ins->amiga.getSample(c.value); if (chan[c.chan].sample>=0 && chan[c.chan].samplesong.sampleLen) { DivSample* s=parent->getSample(chan[c.chan].sample); immWrite(9,(s->offB>>2)&0xff); immWrite(10,(s->offB>>10)&0xff); int end=s->offB+s->lengthB-1; immWrite(11,(end>>2)&0xff); immWrite(12,(end>>10)&0xff); immWrite(8,2); immWrite(7,(s->loopStart>=0)?0xb0:0xa0); // start/repeat 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 { immWrite(7,0x01); // reset immWrite(9,0); immWrite(10,0); immWrite(11,0); immWrite(12,0); break; } } else { chan[c.chan].sample=-1; chan[c.chan].macroInit(NULL); chan[c.chan].outVol=chan[c.chan].vol; if ((12*sampleBank+c.value%12)>=parent->song.sampleLen) { immWrite(7,0x01); // reset immWrite(9,0); immWrite(10,0); immWrite(11,0); immWrite(12,0); break; } DivSample* s=parent->getSample(12*sampleBank+c.value%12); immWrite(9,(s->offB>>2)&0xff); immWrite(10,(s->offB>>10)&0xff); int end=s->offB+s->lengthB-1; immWrite(11,(end>>2)&0xff); immWrite(12,(end>>10)&0xff); immWrite(8,2); immWrite(7,(s->loopStart>=0)?0xb0:0xa0); // start/repeat int freq=(65536.0*(double)s->rate)/(double)rate; immWrite(16,freq&0xff); immWrite(17,(freq>>8)&0xff); } break; } DivInstrument* ins=parent->getIns(chan[c.chan].ins,DIV_INS_OPL); if (chan[c.chan].insChanged) { chan[c.chan].state=ins->fm; } chan[c.chan].macroInit(ins); if (!chan[c.chan].std.vol.will) { chan[c.chan].outVol=chan[c.chan].vol; } if (chan[c.chan].insChanged) { int ops=(slots[3][c.chan]!=255 && chan[c.chan].state.ops==4 && oplType==3)?4:2; chan[c.chan].fourOp=(ops==4); if (chan[c.chan].fourOp) { chan[c.chan+1].macroInit(NULL); } update4OpMask=true; for (int i=0; i=melodicChans) { rWrite(baseAddr+ADDR_KSL_TL,(63-(((63-op.tl)*(chan[c.chan].outVol&0x3f))/63))|(op.ksl<<6)); } else { rWrite(baseAddr+ADDR_KSL_TL,op.tl|(op.ksl<<6)); } } rWrite(baseAddr+ADDR_AM_VIB_SUS_KSR_MULT,(op.am<<7)|(op.vib<<6)|(op.sus<<5)|(op.ksr<<4)|op.mult); rWrite(baseAddr+ADDR_AR_DR,(op.ar<<4)|op.dr); rWrite(baseAddr+ADDR_SL_RR,(op.sl<<4)|op.rr); if (oplType>1) { rWrite(baseAddr+ADDR_WS,op.ws&((oplType==3)?7:3)); } } if (isMuted[c.chan]) { oldWrites[chanMap[c.chan]+ADDR_LR_FB_ALG]=-1; rWrite(chanMap[c.chan]+ADDR_LR_FB_ALG,(chan[c.chan].state.alg&1)|(chan[c.chan].state.fb<<1)); if (ops==4) { oldWrites[chanMap[c.chan+1]+ADDR_LR_FB_ALG]=-1; rWrite(chanMap[c.chan+1]+ADDR_LR_FB_ALG,((chan[c.chan].state.alg>>1)&1)|(chan[c.chan].state.fb<<1)); } } else { oldWrites[chanMap[c.chan]+ADDR_LR_FB_ALG]=-1; rWrite(chanMap[c.chan]+ADDR_LR_FB_ALG,(chan[c.chan].state.alg&1)|(chan[c.chan].state.fb<<1)|((chan[c.chan].pan&3)<<4)); if (ops==4) { oldWrites[chanMap[c.chan+1]+ADDR_LR_FB_ALG]=-1; rWrite(chanMap[c.chan+1]+ADDR_LR_FB_ALG,((chan[c.chan].state.alg>>1)&1)|(chan[c.chan].state.fb<<1)|((chan[c.chan].pan&3)<<4)); } } } chan[c.chan].insChanged=false; if (c.value!=DIV_NOTE_NULL) { if (c.chan>=melodicChans && chan[c.chan].state.opllPreset==16 && chan[c.chan].state.fixedDrums) { // drums if (c.chan==melodicChans) { chan[c.chan].fixedFreq=(chan[c.chan].state.kickFreq&1023)<<(chan[c.chan].state.kickFreq>>10); } else if (c.chan==melodicChans+1 || c.chan==melodicChans+4) { chan[c.chan].fixedFreq=(chan[c.chan].state.snareHatFreq&1023)<<(chan[c.chan].state.snareHatFreq>>10); } else if (c.chan==melodicChans+2 || c.chan==melodicChans+3) { chan[c.chan].fixedFreq=(chan[c.chan].state.tomTopFreq&1023)<<(chan[c.chan].state.tomTopFreq>>10); } else { chan[c.chan].baseFreq=NOTE_FREQUENCY(c.value); chan[c.chan].fixedFreq=0; } } else { chan[c.chan].baseFreq=NOTE_FREQUENCY(c.value); chan[c.chan].fixedFreq=0; } chan[c.chan].note=c.value; chan[c.chan].freqChanged=true; } chan[c.chan].keyOn=true; chan[c.chan].active=true; break; } case DIV_CMD_NOTE_OFF: if (c.chan==adpcmChan) { immWrite(7,0x01); // reset break; } chan[c.chan].keyOff=true; chan[c.chan].keyOn=false; chan[c.chan].active=false; break; case DIV_CMD_NOTE_OFF_ENV: if (c.chan==adpcmChan) { immWrite(7,0x01); // reset 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: { if (pretendYMU && c.chan!=adpcmChan) { c.value=pow(((double)c.value/127.0),0.5)*63.0; if (c.value<0) c.value=0; if (c.value>63) c.value=63; } chan[c.chan].vol=c.value; if (!chan[c.chan].std.vol.has) { chan[c.chan].outVol=c.value; } if (c.chan==adpcmChan) { // ADPCM-B immWrite(18,chan[c.chan].outVol); break; } int ops=(slots[3][c.chan]!=255 && chan[c.chan].state.ops==4 && oplType==3)?4:2; for (int i=0; i=melodicChans) { rWrite(baseAddr+ADDR_KSL_TL,(63-(((63-op.tl)*(chan[c.chan].outVol&0x3f))/63))|(op.ksl<<6)); } else { rWrite(baseAddr+ADDR_KSL_TL,op.tl|(op.ksl<<6)); } } } break; } case DIV_CMD_GET_VOLUME: { if (pretendYMU && c.chan!=adpcmChan) { return pow(((double)chan[c.chan].vol/63.0),2.0)*127.0; } 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: { if (oplType!=3) break; if (c.chan==adpcmChan) break; if (c.value==0 && c.value2==0) { chan[c.chan].pan=3; } else { chan[c.chan].pan=(c.value>0)|((c.value2>0)<<1); } int ops=(slots[3][c.chan]!=255 && chan[c.chan].state.ops==4 && oplType==3)?4:2; if (isMuted[c.chan]) { rWrite(chanMap[c.chan]+ADDR_LR_FB_ALG,(chan[c.chan].state.alg&1)|(chan[c.chan].state.fb<<1)); if (ops==4) { rWrite(chanMap[c.chan+1]+ADDR_LR_FB_ALG,((chan[c.chan].state.alg>>1)&1)|(chan[c.chan].state.fb<<1)); } } else { rWrite(chanMap[c.chan]+ADDR_LR_FB_ALG,(chan[c.chan].state.alg&1)|(chan[c.chan].state.fb<<1)|((chan[c.chan].pan&3)<<4)); if (ops==4) { rWrite(chanMap[c.chan+1]+ADDR_LR_FB_ALG,((chan[c.chan].state.alg>>1)&1)|(chan[c.chan].state.fb<<1)|((chan[c.chan].pan&3)<<4)); } } break; } case DIV_CMD_PITCH: { if (c.chan==adpcmChan) { if (!chan[c.chan].furnacePCM) break; } chan[c.chan].pitch=c.value; chan[c.chan].freqChanged=true; break; } case DIV_CMD_NOTE_PORTA: { int destFreq=(c.chan==adpcmChan)?(NOTE_ADPCMB(c.value2)):(NOTE_FREQUENCY(c.value2)); int newFreq; bool return2=false; if (destFreq>chan[c.chan].baseFreq) { newFreq=chan[c.chan].baseFreq+c.value*((parent->song.linearPitch==2)?1:octave(chan[c.chan].baseFreq)); if (newFreq>=destFreq) { newFreq=destFreq; return2=true; } } else { newFreq=chan[c.chan].baseFreq-c.value*((parent->song.linearPitch==2)?1:octave(chan[c.chan].baseFreq)); if (newFreq<=destFreq) { newFreq=destFreq; return2=true; } } if (!chan[c.chan].portaPause && parent->song.linearPitch!=2) { 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) { chan[c.chan].inPorta=false; return 2; } break; } case DIV_CMD_SAMPLE_BANK: if (adpcmChan<0) break; sampleBank=c.value; if (sampleBank>(int)(parent->song.sample.size()/12)) { sampleBank=parent->song.sample.size()/12; } iface.sampleBank=sampleBank; break; case DIV_CMD_LEGATO: { chan[c.chan].baseFreq=(c.chan==adpcmChan)?(NOTE_ADPCMB(c.value)):(NOTE_FREQUENCY(c.value)); chan[c.chan].note=c.value; chan[c.chan].freqChanged=true; break; } case DIV_CMD_FM_LFO: { if (c.chan==adpcmChan) break; if (c.value&2) { dvb=c.value&1; } else { dam=c.value&1; } immWrite(0xbd,(dam<<7)|(dvb<<6)|(properDrums<<5)|drumState); break; } case DIV_CMD_FM_FB: { if (c.chan==adpcmChan) break; chan[c.chan].state.fb=c.value&7; int ops=(slots[3][c.chan]!=255 && chan[c.chan].state.ops==4 && oplType==3)?4:2; if (isMuted[c.chan]) { rWrite(chanMap[c.chan]+ADDR_LR_FB_ALG,(chan[c.chan].state.alg&1)|(chan[c.chan].state.fb<<1)); if (ops==4) { rWrite(chanMap[c.chan+1]+ADDR_LR_FB_ALG,((chan[c.chan].state.alg>>1)&1)|(chan[c.chan].state.fb<<1)); } } else { rWrite(chanMap[c.chan]+ADDR_LR_FB_ALG,(chan[c.chan].state.alg&1)|(chan[c.chan].state.fb<<1)|((chan[c.chan].pan&3)<<4)); if (ops==4) { rWrite(chanMap[c.chan+1]+ADDR_LR_FB_ALG,((chan[c.chan].state.alg>>1)&1)|(chan[c.chan].state.fb<<1)|((chan[c.chan].pan&3)<<4)); } } break; } case DIV_CMD_FM_MULT: { if (c.chan==adpcmChan) break; int ops=(slots[3][c.chan]!=255 && chan[c.chan].state.ops==4 && oplType==3)?4:2; if (c.value>=ops) break; DivInstrumentFM::Operator& op=chan[c.chan].state.op[(ops==4)?orderedOpsL[c.value]:c.value]; op.mult=c.value2&15; unsigned char slot=slots[c.value][c.chan]; if (slot==255) break; unsigned short baseAddr=slotMap[slot]; rWrite(baseAddr+ADDR_AM_VIB_SUS_KSR_MULT,(op.am<<7)|(op.vib<<6)|(op.sus<<5)|(op.ksr<<4)|op.mult); break; } case DIV_CMD_FM_TL: { if (c.chan==adpcmChan) break; int ops=(slots[3][c.chan]!=255 && chan[c.chan].state.ops==4 && oplType==3)?4:2; if (c.value>=ops) break; DivInstrumentFM::Operator& op=chan[c.chan].state.op[(ops==4)?orderedOpsL[c.value]:c.value]; op.tl=c.value2&63; unsigned char slot=slots[c.value][c.chan]; if (slot==255) break; unsigned short baseAddr=slotMap[slot]; if (isMuted[c.chan]) { rWrite(baseAddr+ADDR_KSL_TL,63|(op.ksl<<6)); } else { if (isOutputL[ops==4][chan[c.chan].state.alg][c.value] || c.chan>=melodicChans) { rWrite(baseAddr+ADDR_KSL_TL,(63-(((63-op.tl)*(chan[c.chan].outVol&0x3f))/63))|(op.ksl<<6)); } else { rWrite(baseAddr+ADDR_KSL_TL,op.tl|(op.ksl<<6)); } } break; } case DIV_CMD_FM_AR: { if (c.chan==adpcmChan) break; int ops=(slots[3][c.chan]!=255 && chan[c.chan].state.ops==4 && oplType==3)?4:2; if (c.value<0) { for (int i=0; i=ops) break; DivInstrumentFM::Operator& op=chan[c.chan].state.op[(ops==4)?orderedOpsL[c.value]:c.value]; op.ar=c.value2&15; unsigned char slot=slots[c.value][c.chan]; if (slot==255) break; unsigned short baseAddr=slotMap[slot]; rWrite(baseAddr+ADDR_AR_DR,(op.ar<<4)|op.dr); } break; } case DIV_CMD_FM_DR: { if (c.chan==adpcmChan) break; int ops=(slots[3][c.chan]!=255 && chan[c.chan].state.ops==4 && oplType==3)?4:2; if (c.value<0) { for (int i=0; i=ops) break; DivInstrumentFM::Operator& op=chan[c.chan].state.op[(ops==4)?orderedOpsL[c.value]:c.value]; op.dr=c.value2&15; unsigned char slot=slots[c.value][c.chan]; if (slot==255) break; unsigned short baseAddr=slotMap[slot]; rWrite(baseAddr+ADDR_AR_DR,(op.ar<<4)|op.dr); } break; } case DIV_CMD_FM_SL: { if (c.chan==adpcmChan) break; int ops=(slots[3][c.chan]!=255 && chan[c.chan].state.ops==4 && oplType==3)?4:2; if (c.value<0) { for (int i=0; i=ops) break; DivInstrumentFM::Operator& op=chan[c.chan].state.op[(ops==4)?orderedOpsL[c.value]:c.value]; op.sl=c.value2&15; unsigned char slot=slots[c.value][c.chan]; if (slot==255) break; unsigned short baseAddr=slotMap[slot]; rWrite(baseAddr+ADDR_SL_RR,(op.sl<<4)|op.rr); } break; } case DIV_CMD_FM_RR: { if (c.chan==adpcmChan) break; int ops=(slots[3][c.chan]!=255 && chan[c.chan].state.ops==4 && oplType==3)?4:2; if (c.value<0) { for (int i=0; i=ops) break; DivInstrumentFM::Operator& op=chan[c.chan].state.op[(ops==4)?orderedOpsL[c.value]:c.value]; op.rr=c.value2&15; unsigned char slot=slots[c.value][c.chan]; if (slot==255) break; unsigned short baseAddr=slotMap[slot]; rWrite(baseAddr+ADDR_SL_RR,(op.sl<<4)|op.rr); } break; } case DIV_CMD_FM_AM: { if (c.chan==adpcmChan) break; int ops=(slots[3][c.chan]!=255 && chan[c.chan].state.ops==4 && oplType==3)?4:2; if (c.value<0) { for (int i=0; i=ops) break; DivInstrumentFM::Operator& op=chan[c.chan].state.op[(ops==4)?orderedOpsL[c.value]:c.value]; op.am=c.value2&1; unsigned char slot=slots[c.value][c.chan]; if (slot==255) break; unsigned short baseAddr=slotMap[slot]; rWrite(baseAddr+ADDR_AM_VIB_SUS_KSR_MULT,(op.am<<7)|(op.vib<<6)|(op.sus<<5)|(op.ksr<<4)|op.mult); } break; } case DIV_CMD_FM_VIB: { if (c.chan==adpcmChan) break; int ops=(slots[3][c.chan]!=255 && chan[c.chan].state.ops==4 && oplType==3)?4:2; if (c.value<0) { for (int i=0; i=ops) break; DivInstrumentFM::Operator& op=chan[c.chan].state.op[(ops==4)?orderedOpsL[c.value]:c.value]; op.vib=c.value2&1; unsigned char slot=slots[c.value][c.chan]; if (slot==255) break; unsigned short baseAddr=slotMap[slot]; rWrite(baseAddr+ADDR_AM_VIB_SUS_KSR_MULT,(op.am<<7)|(op.vib<<6)|(op.sus<<5)|(op.ksr<<4)|op.mult); } break; } case DIV_CMD_FM_SUS: { if (c.chan==adpcmChan) break; int ops=(slots[3][c.chan]!=255 && chan[c.chan].state.ops==4 && oplType==3)?4:2; if (c.value<0) { for (int i=0; i=ops) break; DivInstrumentFM::Operator& op=chan[c.chan].state.op[(ops==4)?orderedOpsL[c.value]:c.value]; op.sus=c.value2&1; unsigned char slot=slots[c.value][c.chan]; if (slot==255) break; unsigned short baseAddr=slotMap[slot]; rWrite(baseAddr+ADDR_AM_VIB_SUS_KSR_MULT,(op.am<<7)|(op.vib<<6)|(op.sus<<5)|(op.ksr<<4)|op.mult); } break; } case DIV_CMD_FM_KSR: { if (c.chan==adpcmChan) break; int ops=(slots[3][c.chan]!=255 && chan[c.chan].state.ops==4 && oplType==3)?4:2; if (c.value<0) { for (int i=0; i=ops) break; DivInstrumentFM::Operator& op=chan[c.chan].state.op[(ops==4)?orderedOpsL[c.value]:c.value]; op.ksr=c.value2&1; unsigned char slot=slots[c.value][c.chan]; if (slot==255) break; unsigned short baseAddr=slotMap[slot]; rWrite(baseAddr+ADDR_AM_VIB_SUS_KSR_MULT,(op.am<<7)|(op.vib<<6)|(op.sus<<5)|(op.ksr<<4)|op.mult); } break; } case DIV_CMD_FM_WS: { if (c.chan==adpcmChan) break; if (oplType<2) break; int ops=(slots[3][c.chan]!=255 && chan[c.chan].state.ops==4 && oplType==3)?4:2; if (c.value<0) { for (int i=0; i=ops) break; DivInstrumentFM::Operator& op=chan[c.chan].state.op[(ops==4)?orderedOpsL[c.value]:c.value]; op.ws=c.value2&7; unsigned char slot=slots[c.value][c.chan]; if (slot==255) break; unsigned short baseAddr=slotMap[slot]; rWrite(baseAddr+ADDR_WS,op.ws&((oplType==3)?7:3)); } break; } case DIV_CMD_FM_RS: { if (c.chan==adpcmChan) break; if (oplType<2) break; int ops=(slots[3][c.chan]!=255 && chan[c.chan].state.ops==4 && oplType==3)?4:2; if (c.value<0) { for (int i=0; i=melodicChans) { rWrite(baseAddr+ADDR_KSL_TL,(63-(((63-op.tl)*(chan[c.chan].outVol&0x3f))/63))|(op.ksl<<6)); } else { rWrite(baseAddr+ADDR_KSL_TL,op.tl|(op.ksl<<6)); } } } } else { if (c.value>=ops) break; DivInstrumentFM::Operator& op=chan[c.chan].state.op[(ops==4)?orderedOpsL[c.value]:c.value]; op.ksl=c.value2&3; unsigned char slot=slots[c.value][c.chan]; if (slot==255) break; unsigned short baseAddr=slotMap[slot]; if (isMuted[c.chan]) { rWrite(baseAddr+ADDR_KSL_TL,63|(op.ksl<<6)); } else { if (isOutputL[ops==4][chan[c.chan].state.alg][c.value] || c.chan>=melodicChans) { rWrite(baseAddr+ADDR_KSL_TL,(63-(((63-op.tl)*(chan[c.chan].outVol&0x3f))/63))|(op.ksl<<6)); } else { rWrite(baseAddr+ADDR_KSL_TL,op.tl|(op.ksl<<6)); } } } break; } case DIV_CMD_FM_EXTCH: { if (!properDrumsSys) break; properDrums=c.value; immWrite(0xbd,(dam<<7)|(dvb<<6)|(properDrums<<5)|drumState); slots=properDrums?slotsDrums:slotsNonDrums; if (oplType==3) { chanMap=properDrums?chanMapOPL3Drums:chanMapOPL3; melodicChans=properDrums?15:18; totalChans=properDrums?20:18; } else { chanMap=properDrums?chanMapOPL2Drums:chanMapOPL2; melodicChans=properDrums?6:9; totalChans=properDrums?11:9; } break; } case DIV_CMD_FM_HARD_RESET: if (c.chan==adpcmChan) break; chan[c.chan].hardReset=c.value; break; case DIV_ALWAYS_SET_VOLUME: return 0; break; case DIV_CMD_GET_VOLMAX: if (c.chan==adpcmChan) return 255; if (pretendYMU) return 127; return 63; break; case DIV_CMD_PRE_PORTA: 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 DivPlatformOPL::forceIns() { if (oplType==3) { chanMap=properDrums?chanMapOPL3Drums:chanMapOPL3; melodicChans=properDrums?15:18; totalChans=properDrums?20:18; } else { chanMap=properDrums?chanMapOPL2Drums:chanMapOPL2; melodicChans=properDrums?6:9; totalChans=properDrums?11:9; } for (int i=0; i=melodicChans) { rWrite(baseAddr+ADDR_KSL_TL,(63-(((63-op.tl)*(chan[i].outVol&0x3f))/63))|(op.ksl<<6)); } else { rWrite(baseAddr+ADDR_KSL_TL,op.tl|(op.ksl<<6)); } } rWrite(baseAddr+ADDR_AM_VIB_SUS_KSR_MULT,(op.am<<7)|(op.vib<<6)|(op.sus<<5)|(op.ksr<<4)|op.mult); rWrite(baseAddr+ADDR_AR_DR,(op.ar<<4)|op.dr); rWrite(baseAddr+ADDR_SL_RR,(op.sl<<4)|op.rr); if (oplType>1) { rWrite(baseAddr+ADDR_WS,op.ws&((oplType==3)?7:3)); } } if (isMuted[i]) { rWrite(chanMap[i]+ADDR_LR_FB_ALG,(chan[i].state.alg&1)|(chan[i].state.fb<<1)); if (ops==4) { rWrite(chanMap[i+1]+ADDR_LR_FB_ALG,((chan[i].state.alg>>1)&1)|(chan[i].state.fb<<1)); } } else { rWrite(chanMap[i]+ADDR_LR_FB_ALG,(chan[i].state.alg&1)|(chan[i].state.fb<<1)|((chan[i].pan&3)<<4)); if (ops==4) { rWrite(chanMap[i+1]+ADDR_LR_FB_ALG,((chan[i].state.alg>>1)&1)|(chan[i].state.fb<<1)|((chan[i].pan&3)<<4)); } } } immWrite(0xbd,(dam<<7)|(dvb<<6)|(properDrums<<5)|drumState); update4OpMask=true; } void DivPlatformOPL::toggleRegisterDump(bool enable) { DivDispatch::toggleRegisterDump(enable); } void* DivPlatformOPL::getChanState(int ch) { return &chan[ch]; } DivDispatchOscBuffer* DivPlatformOPL::getOscBuffer(int ch) { if (ch>=18) return NULL; return oscBuf[ch]; } unsigned char* DivPlatformOPL::getRegisterPool() { return regPool; } int DivPlatformOPL::getRegisterPoolSize() { return (oplType<3)?256:512; } void DivPlatformOPL::reset() { while (!writes.empty()) writes.pop(); memset(regPool,0,512); /* if (useYMFM) { fm_ymfm->reset(); } */ OPL3_Reset(&fm,rate); if (dumpWrites) { addWrite(0xffffffff,0); } properDrums=properDrumsSys; if (oplType==3) { chanMap=properDrums?chanMapOPL3Drums:chanMapOPL3; outChanMap=outChanMapOPL3; melodicChans=properDrums?15:18; totalChans=properDrums?20:18; } else { chanMap=properDrums?chanMapOPL2Drums:chanMapOPL2; outChanMap=outChanMapOPL2; melodicChans=properDrums?6:9; totalChans=properDrums?11:9; } for (int i=0; i=0) { chan[adpcmChan]=DivPlatformOPL::Channel(); chan[adpcmChan].std.setEngine(parent); chan[adpcmChan].vol=0xff; chan[adpcmChan].outVol=0xff; adpcmB->reset(); // volume immWrite(18,0xff); // ADPCM limit immWrite(20,0xff); immWrite(19,0xff); } if (oplType<3) for (int i=0; i& wlist) { for (DivRegWrite& i: wlist) immWrite(i.addr,i.val); } int DivPlatformOPL::getPortaFloor(int ch) { return (ch>5)?12:0; } void DivPlatformOPL::setYMFM(bool use) { useYMFM=use; } void DivPlatformOPL::setOPLType(int type, bool drums) { pretendYMU=false; adpcmChan=-1; switch (type) { case 1: case 2: case 8950: slotsNonDrums=slotsOPL2; slotsDrums=slotsOPL2Drums; slots=drums?slotsDrums:slotsNonDrums; chanMap=drums?chanMapOPL2Drums:chanMapOPL2; outChanMap=outChanMapOPL2; chipFreqBase=9440540*0.25; chans=9; melodicChans=drums?6:9; totalChans=drums?11:9; if (type==8950) { adpcmChan=drums?11:9; } break; case 3: case 759: slotsNonDrums=slotsOPL3; slotsDrums=slotsOPL3Drums; slots=drums?slotsDrums:slotsNonDrums; chanMap=drums?chanMapOPL3Drums:chanMapOPL3; outChanMap=outChanMapOPL3; chipFreqBase=9440540; chans=18; melodicChans=drums?15:18; totalChans=drums?20:18; if (type==759) { pretendYMU=true; adpcmChan=16; } break; } if (type==759) { oplType=3; } else if (type==8950) { oplType=1; } else { oplType=type; } properDrumsSys=drums; } void DivPlatformOPL::setFlags(unsigned int flags) { /* if (flags==3) { chipClock=COLOR_NTSC*12.0/7.0; } else if (flags==2) { chipClock=8000000.0; } else if (flags==1) { chipClock=COLOR_PAL*12.0/7.0; } else { chipClock=COLOR_NTSC*15.0/7.0; } ladder=flags&0x80000000; OPN2_SetChipType(ladder?ym3438_mode_ym2612:0); if (useYMFM) { if (fm_ymfm!=NULL) delete fm_ymfm; if (ladder) { fm_ymfm=new ymfm::ym2612(iface); } else { fm_ymfm=new ymfm::ym3438(iface); } rate=chipClock/144; } else { rate=chipClock/36; }*/ if (oplType==3) { chipClock=COLOR_NTSC*4.0; rate=chipClock/288; } else { chipClock=COLOR_NTSC; rate=chipClock/72; } if (pretendYMU) { rate=48000; chipClock=rate*288; } for (int i=0; i<18; i++) { oscBuf[i]->rate=rate; } } const void* DivPlatformOPL::getSampleMem(int index) { return (index==0 && adpcmChan>=0) ? adpcmBMem : NULL; } size_t DivPlatformOPL::getSampleMemCapacity(int index) { return (index==0 && adpcmChan>=0) ? 262144 : 0; } size_t DivPlatformOPL::getSampleMemUsage(int index) { return (index==0 && adpcmChan>=0) ? adpcmBMemLen : 0; } void DivPlatformOPL::renderSamples() { if (adpcmChan<0) return; memset(adpcmBMem,0,getSampleMemCapacity(0)); size_t memPos=0; for (int i=0; isong.sampleLen; i++) { DivSample* s=parent->song.sample[i]; int paddedLen=(s->lengthB+255)&(~0xff); if ((memPos&0xf00000)!=((memPos+paddedLen)&0xf00000)) { memPos=(memPos+0xfffff)&0xf00000; } if (memPos>=getSampleMemCapacity(0)) { logW("out of ADPCM memory for sample %d!",i); break; } if (memPos+paddedLen>=getSampleMemCapacity(0)) { memcpy(adpcmBMem+memPos,s->dataB,getSampleMemCapacity(0)-memPos); logW("out of ADPCM memory for sample %d!",i); } else { memcpy(adpcmBMem+memPos,s->dataB,paddedLen); } s->offB=memPos; memPos+=paddedLen; } adpcmBMemLen=memPos+256; } int DivPlatformOPL::init(DivEngine* p, int channels, int sugRate, unsigned int flags) { parent=p; dumpWrites=false; skipRegisterWrites=false; for (int i=0; i<20; i++) { isMuted[i]=false; } for (int i=0; i<18; i++) { oscBuf[i]=new DivDispatchOscBuffer; } setFlags(flags); if (adpcmChan>=0) { adpcmBMem=new unsigned char[getSampleMemCapacity(0)]; adpcmBMemLen=0; iface.adpcmBMem=adpcmBMem; iface.sampleBank=0; adpcmB=new ymfm::adpcm_b_engine(iface,2); } reset(); return totalChans; } void DivPlatformOPL::quit() { for (int i=0; i<18; i++) { delete oscBuf[i]; } if (adpcmChan>=0) { delete adpcmB; delete[] adpcmBMem; } } DivPlatformOPL::~DivPlatformOPL() { }