#include #include "global.h" #include #define DEFAULT_LEN_1CH 0x1A0 #define DEFAULT_LEN_2CH 0x340 #define DMEM_TEMP 0x3C0 #define DMEM_UNCOMPRESSED_NOTE 0x580 #define DMEM_NOTE_PAN_TEMP 0x5C0 #define DMEM_SCRATCH2 0x760 // = DMEM_TEMP + DEFAULT_LEN_2CH + a bit more #define DMEM_COMPRESSED_ADPCM_DATA 0x940 // = DMEM_LEFT_CH #define DMEM_LEFT_CH 0x940 #define DMEM_RIGHT_CH 0xAE0 #define DMEM_WET_TEMP 0x3E0 #define DMEM_WET_SCRATCH 0x720 // = DMEM_WET_TEMP + DEFAULT_LEN_2CH #define DMEM_WET_LEFT_CH 0xC80 #define DMEM_WET_RIGHT_CH 0xE20 // = DMEM_WET_LEFT_CH + DEFAULT_LEN_1CH Acmd* AudioSynth_LoadRingBufferPart(Acmd* cmd, u16 dmem, u16 startPos, s32 length, SynthesisReverb* reverb); Acmd* AudioSynth_SaveBufferOffset(Acmd* cmd, u16 dmem, u16 offset, s32 length, s16* buf); Acmd* AudioSynth_SaveRingBufferPart(Acmd* cmd, u16 dmem, u16 startPos, s32 length, SynthesisReverb* reverb); Acmd* AudioSynth_DoOneAudioUpdate(s16* aiBuf, s32 aiBufLen, Acmd* cmd, s32 updateIndex); Acmd* AudioSynth_ProcessNote(s32 noteIndex, NoteSubEu* noteSubEu, NoteSynthesisState* synthState, s16* aiBuf, s32 aiBufLen, Acmd* cmd, s32 updateIndex); Acmd* AudioSynth_LoadWaveSamples(Acmd* cmd, NoteSubEu* noteSubEu, NoteSynthesisState* synthState, s32 nSamplesToLoad); Acmd* AudioSynth_NoteApplyHeadsetPanEffects(Acmd* cmd, NoteSubEu* noteSubEu, NoteSynthesisState* synthState, s32 bufLen, s32 flags, s32 side); Acmd* AudioSynth_ProcessEnvelope(Acmd* cmd, NoteSubEu* noteSubEu, NoteSynthesisState* synthState, s32 aiBufLen, u16 inBuf, s32 headsetPanSettings, s32 flags); Acmd* AudioSynth_FinalResample(Acmd* cmd, NoteSynthesisState* synthState, s32 count, u16 pitch, u16 inpDmem, s32 resampleFlags); u32 D_801304A0 = 0x13000000; u32 D_801304A4 = 0x5CAEC8E2; u32 D_801304A8 = 0x945CC8E2; u32 D_801304AC = 0x94AEC8E2; u16 D_801304B0[] = { 0x7FFF, 0xD001, 0x3FFF, 0xF001, 0x5FFF, 0x9001, 0x7FFF, 0x8001, }; u8 D_801304C0[] = { 0x40, 0x20, 0x10, 0x8 }; void AudioSynth_InitNextRingBuf(s32 chunkLen, s32 bufIndex, s32 reverbIndex) { ReverbRingBufferItem* bufItem; s32 pad[3]; SynthesisReverb* reverb = &gAudioContext.synthesisReverbs[reverbIndex]; s32 temp_a0_2; s32 temp_a0_4; s32 sampleCnt; s32 extraSamples; s32 i; s32 j; if (reverb->downsampleRate >= 2) { if (reverb->framesToIgnore == 0) { bufItem = &reverb->items[reverb->curFrame][bufIndex]; Audio_InvalDCache(bufItem->toDownsampleLeft, DEFAULT_LEN_2CH); for (j = 0, i = 0; i < bufItem->lengthA / 2; j += reverb->downsampleRate, i++) { reverb->leftRingBuf[bufItem->startPos + i] = bufItem->toDownsampleLeft[j]; reverb->rightRingBuf[bufItem->startPos + i] = bufItem->toDownsampleRight[j]; } for (i = 0; i < bufItem->lengthB / 2; j += reverb->downsampleRate, i++) { reverb->leftRingBuf[i] = bufItem->toDownsampleLeft[j]; reverb->rightRingBuf[i] = bufItem->toDownsampleRight[j]; } } } bufItem = &reverb->items[reverb->curFrame][bufIndex]; sampleCnt = chunkLen / reverb->downsampleRate; extraSamples = (sampleCnt + reverb->nextRingBufPos) - reverb->bufSizePerChan; temp_a0_2 = reverb->nextRingBufPos; if (extraSamples < 0) { bufItem->lengthA = sampleCnt * 2; bufItem->lengthB = 0; bufItem->startPos = reverb->nextRingBufPos; reverb->nextRingBufPos += sampleCnt; } else { bufItem->lengthA = (sampleCnt - extraSamples) * 2; bufItem->lengthB = extraSamples * 2; bufItem->startPos = reverb->nextRingBufPos; reverb->nextRingBufPos = extraSamples; } bufItem->numSamplesAfterDownsampling = sampleCnt; bufItem->chunkLen = chunkLen; if (reverb->unk_14 != 0) { temp_a0_4 = reverb->unk_14 + temp_a0_2; if (temp_a0_4 >= reverb->bufSizePerChan) { temp_a0_4 -= reverb->bufSizePerChan; } bufItem = &reverb->items2[reverb->curFrame][bufIndex]; sampleCnt = chunkLen / reverb->downsampleRate; extraSamples = (temp_a0_4 + sampleCnt) - reverb->bufSizePerChan; if (extraSamples < 0) { bufItem->lengthA = sampleCnt * 2; bufItem->lengthB = 0; bufItem->startPos = temp_a0_4; } else { bufItem->lengthA = (sampleCnt - extraSamples) * 2; bufItem->lengthB = extraSamples * 2; bufItem->startPos = temp_a0_4; } bufItem->numSamplesAfterDownsampling = sampleCnt; bufItem->chunkLen = chunkLen; } } void func_800DB03C(s32 arg0) { NoteSubEu* subEu; NoteSubEu* subEu2; s32 baseIndex; s32 i; baseIndex = gAudioContext.numNotes * arg0; for (i = 0; i < gAudioContext.numNotes; i++) { subEu = &gAudioContext.notes[i].noteSubEu; subEu2 = &gAudioContext.noteSubsEu[baseIndex + i]; if (subEu->bitField0.enabled) { subEu->bitField0.needsInit = false; } else { subEu2->bitField0.enabled = false; } subEu->unk_06 = 0; } } Acmd* AudioSynth_Update(Acmd* cmdStart, s32* cmdCnt, s16* aiStart, s32 aiBufLen) { s32 chunkLen; s16* aiBufP; Acmd* cmdP; s32 i; s32 j; SynthesisReverb* reverb; cmdP = cmdStart; for (i = gAudioContext.audioBufferParameters.updatesPerFrame; i > 0; i--) { AudioSeq_ProcessSequences(i - 1); func_800DB03C(gAudioContext.audioBufferParameters.updatesPerFrame - i); } aiBufP = aiStart; gAudioContext.curLoadedBook = NULL; for (i = gAudioContext.audioBufferParameters.updatesPerFrame; i > 0; i--) { if (i == 1) { chunkLen = aiBufLen; } else if ((aiBufLen / i) >= gAudioContext.audioBufferParameters.samplesPerUpdateMax) { chunkLen = gAudioContext.audioBufferParameters.samplesPerUpdateMax; } else if (gAudioContext.audioBufferParameters.samplesPerUpdateMin >= (aiBufLen / i)) { chunkLen = gAudioContext.audioBufferParameters.samplesPerUpdateMin; } else { chunkLen = gAudioContext.audioBufferParameters.samplesPerUpdate; } for (j = 0; j < gAudioContext.numSynthesisReverbs; j++) { if (gAudioContext.synthesisReverbs[j].useReverb) { AudioSynth_InitNextRingBuf(chunkLen, gAudioContext.audioBufferParameters.updatesPerFrame - i, j); } } cmdP = AudioSynth_DoOneAudioUpdate(aiBufP, chunkLen, cmdP, gAudioContext.audioBufferParameters.updatesPerFrame - i); aiBufLen -= chunkLen; aiBufP += chunkLen * 2; } for (j = 0; j < gAudioContext.numSynthesisReverbs; j++) { if (gAudioContext.synthesisReverbs[j].framesToIgnore != 0) { gAudioContext.synthesisReverbs[j].framesToIgnore--; } gAudioContext.synthesisReverbs[j].curFrame ^= 1; } *cmdCnt = cmdP - cmdStart; return cmdP; } void func_800DB2C0(s32 updateIndexStart, s32 noteIndex) { NoteSubEu* temp_v1; s32 i; for (i = updateIndexStart + 1; i < gAudioContext.audioBufferParameters.updatesPerFrame; i++) { temp_v1 = &gAudioContext.noteSubsEu[(gAudioContext.numNotes * i) + noteIndex]; if (!temp_v1->bitField0.needsInit) { temp_v1->bitField0.enabled = 0; } else { break; } } } Acmd* AudioSynth_LoadRingBuffer1AtTemp(Acmd* cmd, SynthesisReverb* reverb, s16 bufIndex) { ReverbRingBufferItem* bufItem = &reverb->items[reverb->curFrame][bufIndex]; cmd = AudioSynth_LoadRingBufferPart(cmd, DMEM_WET_TEMP, bufItem->startPos, bufItem->lengthA, reverb); if (bufItem->lengthB != 0) { // Ring buffer wrapped cmd = AudioSynth_LoadRingBufferPart(cmd, DMEM_WET_TEMP + bufItem->lengthA, 0, bufItem->lengthB, reverb); } return cmd; } Acmd* AudioSynth_SaveRingBuffer1AtTemp(Acmd* cmd, SynthesisReverb* reverb, s16 bufIndex) { ReverbRingBufferItem* bufItem = &reverb->items[reverb->curFrame][bufIndex]; cmd = AudioSynth_SaveRingBufferPart(cmd, DMEM_WET_TEMP, bufItem->startPos, bufItem->lengthA, reverb); if (bufItem->lengthB != 0) { // Ring buffer wrapped cmd = AudioSynth_SaveRingBufferPart(cmd, DMEM_WET_TEMP + bufItem->lengthA, 0, bufItem->lengthB, reverb); } return cmd; } Acmd* AudioSynth_LeakReverb(Acmd* cmd, SynthesisReverb* reverb) { // Leak some audio from the left reverb channel into the right reverb channel and vice versa (pan) aDMEMMove(cmd++, DMEM_WET_LEFT_CH, DMEM_WET_SCRATCH, DEFAULT_LEN_1CH); aMix(cmd++, 0x1A, reverb->leakRtl, DMEM_WET_RIGHT_CH, DMEM_WET_LEFT_CH); aMix(cmd++, 0x1A, reverb->leakLtr, DMEM_WET_SCRATCH, DMEM_WET_RIGHT_CH); return cmd; } Acmd* func_800DB4E4(Acmd* cmd, s32 arg1, SynthesisReverb* reverb, s16 arg3) { ReverbRingBufferItem* item = &reverb->items[reverb->curFrame][arg3]; s16 offsetA; s16 offsetB; offsetA = (item->startPos & 7) * 2; offsetB = ALIGN16(offsetA + item->lengthA); cmd = AudioSynth_LoadRingBufferPart(cmd, DMEM_WET_TEMP, item->startPos - (offsetA / 2), DEFAULT_LEN_1CH, reverb); if (item->lengthB != 0) { // Ring buffer wrapped cmd = AudioSynth_LoadRingBufferPart(cmd, DMEM_WET_TEMP + offsetB, 0, DEFAULT_LEN_1CH - offsetB, reverb); } aSetBuffer(cmd++, 0, DMEM_WET_TEMP + offsetA, DMEM_WET_LEFT_CH, arg1 * 2); aResample(cmd++, reverb->resampleFlags, reverb->unk_0E, reverb->unk_30); aSetBuffer(cmd++, 0, DMEM_WET_TEMP + DEFAULT_LEN_1CH + offsetA, DMEM_WET_RIGHT_CH, arg1 * 2); aResample(cmd++, reverb->resampleFlags, reverb->unk_0E, reverb->unk_34); return cmd; } Acmd* func_800DB680(Acmd* cmd, SynthesisReverb* reverb, s16 bufIndex) { ReverbRingBufferItem* bufItem = &reverb->items[reverb->curFrame][bufIndex]; aSetBuffer(cmd++, 0, DMEM_WET_LEFT_CH, DMEM_WET_SCRATCH, bufItem->unk_18 * 2); aResample(cmd++, reverb->resampleFlags, bufItem->unk_16, reverb->unk_38); cmd = AudioSynth_SaveBufferOffset(cmd, DMEM_WET_SCRATCH, bufItem->startPos, bufItem->lengthA, reverb->leftRingBuf); if (bufItem->lengthB != 0) { // Ring buffer wrapped cmd = AudioSynth_SaveBufferOffset(cmd, DMEM_WET_SCRATCH + bufItem->lengthA, 0, bufItem->lengthB, reverb->leftRingBuf); } aSetBuffer(cmd++, 0, DMEM_WET_RIGHT_CH, DMEM_WET_SCRATCH, bufItem->unk_18 * 2); aResample(cmd++, reverb->resampleFlags, bufItem->unk_16, reverb->unk_3C); cmd = AudioSynth_SaveBufferOffset(cmd, DMEM_WET_SCRATCH, bufItem->startPos, bufItem->lengthA, reverb->rightRingBuf); if (bufItem->lengthB != 0) { // Ring buffer wrapped cmd = AudioSynth_SaveBufferOffset(cmd, DMEM_WET_SCRATCH + bufItem->lengthA, 0, bufItem->lengthB, reverb->rightRingBuf); } return cmd; } Acmd* func_800DB828(Acmd* cmd, s32 arg1, SynthesisReverb* reverb, s16 arg3) { ReverbRingBufferItem* item = &reverb->items[reverb->curFrame][arg3]; s16 offsetA; s16 offsetB; item->unk_14 = (item->unk_18 << 0xF) / arg1; offsetA = (item->startPos & 7) * 2; item->unk_16 = (arg1 << 0xF) / item->unk_18; offsetB = ALIGN16(offsetA + item->lengthA); cmd = AudioSynth_LoadRingBufferPart(cmd, DMEM_WET_TEMP, item->startPos - (offsetA / 2), DEFAULT_LEN_1CH, reverb); if (item->lengthB != 0) { // Ring buffer wrapped cmd = AudioSynth_LoadRingBufferPart(cmd, DMEM_WET_TEMP + offsetB, 0, DEFAULT_LEN_1CH - offsetB, reverb); } aSetBuffer(cmd++, 0, DMEM_WET_TEMP + offsetA, DMEM_WET_LEFT_CH, arg1 * 2); aResample(cmd++, reverb->resampleFlags, item->unk_14, reverb->unk_30); aSetBuffer(cmd++, 0, DMEM_WET_TEMP + DEFAULT_LEN_1CH + offsetA, DMEM_WET_RIGHT_CH, arg1 * 2); aResample(cmd++, reverb->resampleFlags, item->unk_14, reverb->unk_34); return cmd; } Acmd* AudioSynth_FilterReverb(Acmd* cmd, s32 count, SynthesisReverb* reverb) { // Apply a filter (convolution) to each reverb channel. if (reverb->filterLeft != NULL) { aFilter(cmd++, 2, count, reverb->filterLeft); aFilter(cmd++, reverb->resampleFlags, DMEM_WET_LEFT_CH, reverb->filterLeftState); } if (reverb->filterRight != NULL) { aFilter(cmd++, 2, count, reverb->filterRight); aFilter(cmd++, reverb->resampleFlags, DMEM_WET_RIGHT_CH, reverb->filterRightState); } return cmd; } Acmd* AudioSynth_MaybeMixRingBuffer1(Acmd* cmd, SynthesisReverb* reverb, s32 arg2) { SynthesisReverb* temp_a3; temp_a3 = &gAudioContext.synthesisReverbs[reverb->unk_05]; if (temp_a3->downsampleRate == 1) { cmd = AudioSynth_LoadRingBuffer1AtTemp(cmd, temp_a3, arg2); aMix(cmd++, 0x34, reverb->unk_08, DMEM_WET_LEFT_CH, DMEM_WET_TEMP); cmd = AudioSynth_SaveRingBuffer1AtTemp(cmd, temp_a3, arg2); } return cmd; } void func_800DBB94(void) { } void AudioSynth_ClearBuffer(Acmd* cmd, s32 arg1, s32 arg2) { aClearBuffer(cmd, arg1, arg2); } void func_800DBBBC(void) { } void func_800DBBC4(void) { } void func_800DBBCC(void) { } void AudioSynth_Mix(Acmd* cmd, s32 arg1, s32 arg2, s32 arg3, s32 arg4) { aMix(cmd, arg1, arg2, arg3, arg4); } void func_800DBC08(void) { } void func_800DBC10(void) { } void func_800DBC18(void) { } void AudioSynth_SetBuffer(Acmd* cmd, s32 flags, s32 dmemIn, s32 dmemOut, s32 count) { aSetBuffer(cmd, flags, dmemIn, dmemOut, count); } void func_800DBC54(void) { } void func_800DBC5C(void) { } // possible fake match? void AudioSynth_DMemMove(Acmd* cmd, s32 dmemIn, s32 dmemOut, s32 count) { aDMEMMove(cmd, dmemIn, dmemOut, count); } void func_800DBC90(void) { } void func_800DBC98(void) { } void func_800DBCA0(void) { } void func_800DBCA8(void) { } void AudioSynth_InterL(Acmd* cmd, s32 dmemIn, s32 dmemOut, s32 count) { aInterl(cmd, dmemIn, dmemOut, count); } void AudioSynth_EnvSetup1(Acmd* cmd, s32 arg1, s32 arg2, s32 arg3, s32 arg4) { aEnvSetup1(cmd, arg1, arg2, arg3, arg4); } void func_800DBD08(void) { } void AudioSynth_LoadBuffer(Acmd* cmd, s32 arg1, s32 arg2, uintptr_t arg3) { aLoadBuffer(cmd, arg3, arg1, arg2); } void AudioSynth_SaveBuffer(Acmd* cmd, s32 arg1, s32 arg2, uintptr_t arg3) { aSaveBuffer(cmd, arg1, arg3, arg2); } void AudioSynth_EnvSetup2(Acmd* cmd, s32 volLeft, s32 volRight) { aEnvSetup2(cmd, volLeft, volRight); } void func_800DBD7C(void) { } void func_800DBD84(void) { } void func_800DBD8C(void) { } void AudioSynth_S8Dec(Acmd* cmd, s32 flags, s16* state) { aS8Dec(cmd, flags, state); } void AudioSynth_HiLoGain(Acmd* cmd, s32 gain, s32 dmemIn, s32 dmemOut, s32 count) { aHiLoGain(cmd, gain, count, dmemIn, dmemOut); } void AudioSynth_UnkCmd19(Acmd* cmd, s32 arg1, s32 arg2, s32 arg3, s32 arg4) { aUnkCmd19(cmd, arg1, arg2, arg3, arg4); } void func_800DBE18(void) { } void func_800DBE20(void) { } void func_800DBE28(void) { } void func_800DBE30(void) { } void AudioSynth_UnkCmd3(Acmd* cmd, s32 arg1, s32 arg2, s32 arg3) { aUnkCmd3(cmd, arg1, arg2, arg3); } void func_800DBE5C(void) { } void func_800DBE64(void) { } void func_800DBE6C(void) { } void AudioSynth_LoadFilter(Acmd* cmd, s32 flags, s32 countOrBuf, uintptr_t addr) { aFilter(cmd, flags, countOrBuf, addr); } void AudioSynth_LoadFilterCount(Acmd* cmd, s32 count, uintptr_t addr) { aFilter(cmd, 2, count, addr); } Acmd* AudioSynth_LoadRingBuffer1(Acmd* cmd, s32 arg1, SynthesisReverb* reverb, s16 bufIndex) { ReverbRingBufferItem* ringBufferItem = &reverb->items[reverb->curFrame][bufIndex]; cmd = AudioSynth_LoadRingBufferPart(cmd, DMEM_WET_LEFT_CH, ringBufferItem->startPos, ringBufferItem->lengthA, reverb); if (ringBufferItem->lengthB != 0) { // Ring buffer wrapped cmd = AudioSynth_LoadRingBufferPart(cmd, DMEM_WET_LEFT_CH + ringBufferItem->lengthA, 0, ringBufferItem->lengthB, reverb); } return cmd; } Acmd* AudioSynth_LoadRingBuffer2(Acmd* cmd, s32 arg1, SynthesisReverb* reverb, s16 bufIndex) { ReverbRingBufferItem* bufItem = &reverb->items2[reverb->curFrame][bufIndex]; cmd = AudioSynth_LoadRingBufferPart(cmd, DMEM_WET_LEFT_CH, bufItem->startPos, bufItem->lengthA, reverb); if (bufItem->lengthB != 0) { // Ring buffer wrapped cmd = AudioSynth_LoadRingBufferPart(cmd, DMEM_WET_LEFT_CH + bufItem->lengthA, 0, bufItem->lengthB, reverb); } return cmd; } Acmd* AudioSynth_LoadRingBufferPart(Acmd* cmd, u16 dmem, u16 startPos, s32 length, SynthesisReverb* reverb) { aLoadBuffer(cmd++, &reverb->leftRingBuf[startPos], dmem, length); aLoadBuffer(cmd++, &reverb->rightRingBuf[startPos], dmem + DEFAULT_LEN_1CH, length); return cmd; } Acmd* AudioSynth_SaveRingBufferPart(Acmd* cmd, u16 dmem, u16 startPos, s32 length, SynthesisReverb* reverb) { aSaveBuffer(cmd++, dmem, &reverb->leftRingBuf[startPos], length); aSaveBuffer(cmd++, dmem + DEFAULT_LEN_1CH, &reverb->rightRingBuf[startPos], length); return cmd; } Acmd* AudioSynth_SaveBufferOffset(Acmd* cmd, u16 dmem, u16 offset, s32 length, s16* buf) { aSaveBuffer(cmd++, dmem, &buf[offset], length); return cmd; } Acmd* AudioSynth_MaybeLoadRingBuffer2(Acmd* cmd, s32 arg1, SynthesisReverb* reverb, s16 bufIndex) { if (reverb->downsampleRate == 1) { cmd = AudioSynth_LoadRingBuffer2(cmd, arg1, reverb, bufIndex); } return cmd; } Acmd* func_800DC164(Acmd* cmd, s32 arg1, SynthesisReverb* reverb, s16 arg3) { // Sets DMEM_WET_{LEFT,RIGHT}_CH, clobbers DMEM_TEMP if (reverb->downsampleRate == 1) { if (reverb->unk_18 != 0) { cmd = func_800DB828(cmd, arg1, reverb, arg3); } else { cmd = AudioSynth_LoadRingBuffer1(cmd, arg1, reverb, arg3); } } else { cmd = func_800DB4E4(cmd, arg1, reverb, arg3); } return cmd; } Acmd* AudioSynth_SaveReverbSamples(Acmd* cmd, SynthesisReverb* reverb, s16 bufIndex) { ReverbRingBufferItem* bufItem = &reverb->items[reverb->curFrame][bufIndex]; if (reverb->downsampleRate == 1) { if (reverb->unk_18 != 0) { cmd = func_800DB680(cmd, reverb, bufIndex); } else { // Put the oldest samples in the ring buffer into the wet channels cmd = AudioSynth_SaveRingBufferPart(cmd, DMEM_WET_LEFT_CH, bufItem->startPos, bufItem->lengthA, reverb); if (bufItem->lengthB != 0) { // Ring buffer wrapped cmd = AudioSynth_SaveRingBufferPart(cmd, DMEM_WET_LEFT_CH + bufItem->lengthA, 0, bufItem->lengthB, reverb); } } } else { // Downsampling is done later by CPU when RSP is done, therefore we need to have // double buffering. Left and right buffers are adjacent in memory. AudioSynth_SaveBuffer(cmd++, DMEM_WET_LEFT_CH, DEFAULT_LEN_2CH, reverb->items[reverb->curFrame][bufIndex].toDownsampleLeft); } reverb->resampleFlags = 0; return cmd; } Acmd* AudioSynth_SaveRingBuffer2(Acmd* cmd, SynthesisReverb* reverb, s16 bufIndex) { ReverbRingBufferItem* bufItem = &reverb->items2[reverb->curFrame][bufIndex]; cmd = AudioSynth_SaveRingBufferPart(cmd, DMEM_WET_LEFT_CH, bufItem->startPos, bufItem->lengthA, reverb); if (bufItem->lengthB != 0) { // Ring buffer wrapped cmd = AudioSynth_SaveRingBufferPart(cmd, DMEM_WET_LEFT_CH + bufItem->lengthA, 0, bufItem->lengthB, reverb); } return cmd; } Acmd* AudioSynth_DoOneAudioUpdate(s16* aiBuf, s32 aiBufLen, Acmd* cmd, s32 updateIndex) { u8 noteIndices[0x5C]; s16 count; s16 reverbIndex; SynthesisReverb* reverb; s32 useReverb; s32 t; s32 i; NoteSubEu* noteSubEu; NoteSubEu* noteSubEu2; s32 unk14; //if (aiBufLen == 0) //return; t = gAudioContext.numNotes * updateIndex; count = 0; if (gAudioContext.numSynthesisReverbs == 0) { for (i = 0; i < gAudioContext.numNotes; i++) { if (gAudioContext.noteSubsEu[t + i].bitField0.enabled) { noteIndices[count++] = i; } } } else { for (reverbIndex = 0; reverbIndex < gAudioContext.numSynthesisReverbs; reverbIndex++) { for (i = 0; i < gAudioContext.numNotes; i++) { noteSubEu = &gAudioContext.noteSubsEu[t + i]; if (noteSubEu->bitField0.enabled && noteSubEu->bitField1.reverbIndex == reverbIndex) { noteIndices[count++] = i; } } } for (i = 0; i < gAudioContext.numNotes; i++) { noteSubEu = &gAudioContext.noteSubsEu[t + i]; if (noteSubEu->bitField0.enabled && noteSubEu->bitField1.reverbIndex >= gAudioContext.numSynthesisReverbs) { noteIndices[count++] = i; } } } aClearBuffer(cmd++, DMEM_LEFT_CH, DEFAULT_LEN_2CH); i = 0; for (reverbIndex = 0; reverbIndex < gAudioContext.numSynthesisReverbs; reverbIndex++) { reverb = &gAudioContext.synthesisReverbs[reverbIndex]; useReverb = reverb->useReverb; if (useReverb) { cmd = func_800DC164(cmd, aiBufLen, reverb, updateIndex); aMix(cmd++, 0x34, reverb->unk_0A, DMEM_WET_LEFT_CH, DMEM_LEFT_CH); unk14 = reverb->unk_14; if (unk14) { aDMEMMove(cmd++, DMEM_WET_LEFT_CH, DMEM_WET_TEMP, DEFAULT_LEN_2CH); } aMix(cmd++, 0x34, reverb->unk_0C + 0x8000, DMEM_WET_LEFT_CH, DMEM_WET_LEFT_CH); if (reverb->leakRtl != 0 || reverb->leakLtr != 0) { cmd = AudioSynth_LeakReverb(cmd, reverb); } if (unk14) { cmd = AudioSynth_SaveReverbSamples(cmd, reverb, updateIndex); if (reverb->unk_05 != -1) { cmd = AudioSynth_MaybeMixRingBuffer1(cmd, reverb, updateIndex); } cmd = AudioSynth_MaybeLoadRingBuffer2(cmd, aiBufLen, reverb, updateIndex); aMix(cmd++, 0x34, reverb->unk_16, DMEM_WET_TEMP, DMEM_WET_LEFT_CH); } } while (i < count) { noteSubEu2 = &gAudioContext.noteSubsEu[noteIndices[i] + t]; if (noteSubEu2->bitField1.reverbIndex == reverbIndex) { cmd = AudioSynth_ProcessNote(noteIndices[i], noteSubEu2, &gAudioContext.notes[noteIndices[i]].synthesisState, aiBuf, aiBufLen, cmd, updateIndex); } else { break; } i++; } if (useReverb) { if (reverb->filterLeft != NULL || reverb->filterRight != NULL) { cmd = AudioSynth_FilterReverb(cmd, aiBufLen * 2, reverb); } if (unk14) { cmd = AudioSynth_SaveRingBuffer2(cmd, reverb, updateIndex); } else { cmd = AudioSynth_SaveReverbSamples(cmd, reverb, updateIndex); if (reverb->unk_05 != -1) { cmd = AudioSynth_MaybeMixRingBuffer1(cmd, reverb, updateIndex); } } } } while (i < count) { cmd = AudioSynth_ProcessNote(noteIndices[i], &gAudioContext.noteSubsEu[t + noteIndices[i]], &gAudioContext.notes[noteIndices[i]].synthesisState, aiBuf, aiBufLen, cmd, updateIndex); i++; } updateIndex = aiBufLen * 2; aInterleave(cmd++, DMEM_TEMP, DMEM_LEFT_CH, DMEM_RIGHT_CH, updateIndex); aSaveBuffer(cmd++, DMEM_TEMP, aiBuf, updateIndex * 2); return cmd; } Acmd* AudioSynth_ProcessNote(s32 noteIndex, NoteSubEu* noteSubEu, NoteSynthesisState* synthState, s16* aiBuf, s32 aiBufLen, Acmd* cmd, s32 updateIndex) { s32 pad1[3]; SoundFontSample* audioFontSample; AdpcmLoop* loopInfo; s32 nSamplesUntilLoopEnd; s32 nSamplesInThisIteration; s32 noteFinished; s32 restart; s32 flags; u16 resamplingRateFixedPoint; s32 nSamplesInFirstFrame; s32 nTrailingSamplesToIgnore; s32 phi_a1_2; s32 frameIndex; s32 skipBytes; s32 temp_v1_6; void* buf; s32 nSamplesToDecode; uintptr_t sampleAddr; u32 samplesLenFixedPoint; s32 samplesLenAdjusted; s32 nSamplesProcessed; uintptr_t loopEndPos; s32 nSamplesToProcess; s32 phi_s4; s32 nFirstFrameSamplesToIgnore; s32 pad2[7]; s32 frameSize; s32 nFramesToDecode; s32 skipInitialSamples; intptr_t sampleDataStart; u8* sampleData; s32 nParts; s32 curPart; intptr_t sampleDataStartPad; s32 side; s32 resampledTempLen; u16 noteSamplesDmemAddrBeforeResampling; intptr_t sampleDataOffset; s32 thing; s32 s5; Note* note; u32 nSamplesToLoad; u16 unk7; u16 unkE; s16* filter; s32 bookOffset; s32 finished; s32 aligned; s16 addr; u16 unused; bookOffset = noteSubEu->bitField1.bookOffset; finished = noteSubEu->bitField0.finished; note = &gAudioContext.notes[noteIndex]; flags = A_CONTINUE; if (noteSubEu->bitField0.needsInit == true) { flags = A_INIT; synthState->restart = 0; synthState->samplePosInt = note->unk_BC; synthState->samplePosFrac = 0; synthState->curVolLeft = 0; synthState->curVolRight = 0; synthState->prevHeadsetPanRight = 0; synthState->prevHeadsetPanLeft = 0; synthState->reverbVol = noteSubEu->reverbVol; synthState->numParts = 0; synthState->unk_1A = 1; note->noteSubEu.bitField0.finished = false; finished = false; } resamplingRateFixedPoint = noteSubEu->resamplingRateFixedPoint; nParts = noteSubEu->bitField1.hasTwoParts + 1; samplesLenFixedPoint = (resamplingRateFixedPoint * aiBufLen * 2) + synthState->samplePosFrac; nSamplesToLoad = samplesLenFixedPoint >> 16; synthState->samplePosFrac = samplesLenFixedPoint & 0xFFFF; // Partially-optimized out no-op ifs required for matching. SM64 decomp // makes it clear that this is how it should look. if (synthState->numParts == 1 && nParts == 2) { } else if (synthState->numParts == 2 && nParts == 1) { } else { } synthState->numParts = nParts; if (noteSubEu->bitField1.isSyntheticWave) { cmd = AudioSynth_LoadWaveSamples(cmd, noteSubEu, synthState, nSamplesToLoad); noteSamplesDmemAddrBeforeResampling = DMEM_UNCOMPRESSED_NOTE + (synthState->samplePosInt * 2); synthState->samplePosInt += nSamplesToLoad; } else { audioFontSample = noteSubEu->sound.soundFontSound->sample; loopInfo = audioFontSample->loop; loopEndPos = loopInfo->end; sampleAddr = audioFontSample->sampleAddr; resampledTempLen = 0; for (curPart = 0; curPart < nParts; curPart++) { nSamplesProcessed = 0; s5 = 0; if (nParts == 1) { samplesLenAdjusted = nSamplesToLoad; } else if (nSamplesToLoad & 1) { samplesLenAdjusted = (nSamplesToLoad & ~1) + (curPart * 2); } else { samplesLenAdjusted = nSamplesToLoad; } if (audioFontSample->codec == CODEC_ADPCM || audioFontSample->codec == CODEC_SMALL_ADPCM) { if (gAudioContext.curLoadedBook != audioFontSample->book->book) { u32 nEntries; switch (bookOffset) { case 1: gAudioContext.curLoadedBook = &D_8012FBA8[1]; break; case 2: case 3: default: gAudioContext.curLoadedBook = audioFontSample->book->book; break; } nEntries = 16 * audioFontSample->book->order * audioFontSample->book->npredictors; aLoadADPCM(cmd++, nEntries, gAudioContext.curLoadedBook); } } while (nSamplesProcessed != samplesLenAdjusted) { noteFinished = false; restart = false; phi_s4 = 0; nFirstFrameSamplesToIgnore = synthState->samplePosInt & 0xF; nSamplesUntilLoopEnd = loopEndPos - synthState->samplePosInt; nSamplesToProcess = samplesLenAdjusted - nSamplesProcessed; if (nFirstFrameSamplesToIgnore == 0 && !synthState->restart) { nFirstFrameSamplesToIgnore = 16; } nSamplesInFirstFrame = 16 - nFirstFrameSamplesToIgnore; if (nSamplesToProcess < nSamplesUntilLoopEnd) { nFramesToDecode = (s32)(nSamplesToProcess - nSamplesInFirstFrame + 15) / 16; nSamplesToDecode = nFramesToDecode * 16; nTrailingSamplesToIgnore = nSamplesInFirstFrame + nSamplesToDecode - nSamplesToProcess; } else { nSamplesToDecode = nSamplesUntilLoopEnd - nSamplesInFirstFrame; nTrailingSamplesToIgnore = 0; if (nSamplesToDecode <= 0) { nSamplesToDecode = 0; nSamplesInFirstFrame = nSamplesUntilLoopEnd; } nFramesToDecode = (nSamplesToDecode + 15) / 16; if (loopInfo->count != 0) { // Loop around and restart restart = true; } else { noteFinished = true; } } switch (audioFontSample->codec) { case CODEC_ADPCM: frameSize = 9; skipInitialSamples = 16; sampleDataStart = 0; break; case CODEC_SMALL_ADPCM: frameSize = 5; skipInitialSamples = 16; sampleDataStart = 0; break; case CODEC_S8: frameSize = 16; skipInitialSamples = 16; sampleDataStart = 0; break; case CODEC_S16_INMEMORY: AudioSynth_ClearBuffer(cmd++, DMEM_UNCOMPRESSED_NOTE, (samplesLenAdjusted * 2) + 0x20); flags = A_CONTINUE; skipBytes = 0; nSamplesProcessed = samplesLenAdjusted; s5 = samplesLenAdjusted; goto skip; case CODEC_S16: AudioSynth_ClearBuffer(cmd++, DMEM_UNCOMPRESSED_NOTE, (samplesLenAdjusted * 2) + 0x20); AudioSynth_LoadBuffer(cmd++, DMEM_UNCOMPRESSED_NOTE, ALIGN16(nSamplesToLoad * 2), audioFontSample->sampleAddr + (synthState->samplePosInt * 2)); flags = A_CONTINUE; skipBytes = 0; nSamplesProcessed = samplesLenAdjusted; s5 = samplesLenAdjusted; goto skip; case CODEC_REVERB: break; } if (nFramesToDecode != 0) { frameIndex = (synthState->samplePosInt + skipInitialSamples - nFirstFrameSamplesToIgnore) / 16; sampleDataOffset = frameIndex * frameSize; if (audioFontSample->medium == MEDIUM_RAM) { sampleData = (u8*)(sampleDataStart + sampleDataOffset + sampleAddr); } else if (audioFontSample->medium == MEDIUM_UNK) { return cmd; } else { sampleData = AudioLoad_DmaSampleData(sampleDataStart + sampleDataOffset + sampleAddr, ALIGN16((nFramesToDecode * frameSize) + 0x10), flags, &synthState->sampleDmaIndex, audioFontSample->medium); } if (sampleData == NULL) { return cmd; } sampleDataStartPad = (uintptr_t)sampleData & 0xF; aligned = ALIGN16((nFramesToDecode * frameSize) + 16); addr = DMEM_COMPRESSED_ADPCM_DATA - aligned; aLoadBuffer(cmd++, sampleData - sampleDataStartPad, addr, aligned); } else { nSamplesToDecode = 0; sampleDataStartPad = 0; } if (synthState->restart) { aSetLoop(cmd++, audioFontSample->loop->state); flags = A_LOOP; synthState->restart = false; } nSamplesInThisIteration = nSamplesToDecode + nSamplesInFirstFrame - nTrailingSamplesToIgnore; if (nSamplesProcessed == 0) { skipBytes = nFirstFrameSamplesToIgnore * 2; } else { phi_s4 = ALIGN16(s5 + 16); } switch (audioFontSample->codec) { case CODEC_ADPCM: aligned = ALIGN16((nFramesToDecode * frameSize) + 0x10); addr = DMEM_COMPRESSED_ADPCM_DATA - aligned; aSetBuffer(cmd++, 0, addr + sampleDataStartPad, DMEM_UNCOMPRESSED_NOTE + phi_s4, nSamplesToDecode * 2); aADPCMdec(cmd++, flags, synthState->synthesisBuffers->adpcmdecState); break; case CODEC_SMALL_ADPCM: aligned = ALIGN16((nFramesToDecode * frameSize) + 0x10); addr = DMEM_COMPRESSED_ADPCM_DATA - aligned; aSetBuffer(cmd++, 0, addr + sampleDataStartPad, DMEM_UNCOMPRESSED_NOTE + phi_s4, nSamplesToDecode * 2); aADPCMdec(cmd++, flags | 4, synthState->synthesisBuffers->adpcmdecState); break; case CODEC_S8: aligned = ALIGN16((nFramesToDecode * frameSize) + 0x10); addr = DMEM_COMPRESSED_ADPCM_DATA - aligned; AudioSynth_SetBuffer(cmd++, 0, addr + sampleDataStartPad, DMEM_UNCOMPRESSED_NOTE + phi_s4, nSamplesToDecode * 2); AudioSynth_S8Dec(cmd++, flags, synthState->synthesisBuffers->adpcmdecState); break; } if (nSamplesProcessed != 0) { aDMEMMove(cmd++, DMEM_UNCOMPRESSED_NOTE + phi_s4 + (nFirstFrameSamplesToIgnore * 2), DMEM_UNCOMPRESSED_NOTE + s5, nSamplesInThisIteration * 2); } nSamplesProcessed += nSamplesInThisIteration; switch (flags) { case A_INIT: skipBytes = 0x20; s5 = (nSamplesToDecode + 0x10) * 2; break; case A_LOOP: s5 = nSamplesInThisIteration * 2 + s5; break; default: if (s5 != 0) { s5 = nSamplesInThisIteration * 2 + s5; } else { s5 = (nFirstFrameSamplesToIgnore + nSamplesInThisIteration) * 2; } break; } flags = A_CONTINUE; skip: if (noteFinished) { AudioSynth_ClearBuffer(cmd++, DMEM_UNCOMPRESSED_NOTE + s5, (samplesLenAdjusted - nSamplesProcessed) * 2); finished = true; note->noteSubEu.bitField0.finished = true; func_800DB2C0(updateIndex, noteIndex); break; } else { if (restart) { synthState->restart = true; synthState->samplePosInt = loopInfo->start; } else { synthState->samplePosInt += nSamplesToProcess; } } } switch (nParts) { case 1: noteSamplesDmemAddrBeforeResampling = DMEM_UNCOMPRESSED_NOTE + skipBytes; break; case 2: switch (curPart) { case 0: AudioSynth_InterL(cmd++, DMEM_UNCOMPRESSED_NOTE + skipBytes, DMEM_TEMP + 0x20, ((samplesLenAdjusted / 2) + 7) & ~7); resampledTempLen = samplesLenAdjusted; noteSamplesDmemAddrBeforeResampling = DMEM_TEMP + 0x20; if (finished) { AudioSynth_ClearBuffer(cmd++, noteSamplesDmemAddrBeforeResampling + resampledTempLen, samplesLenAdjusted + 0x10); } break; case 1: AudioSynth_InterL(cmd++, DMEM_UNCOMPRESSED_NOTE + skipBytes, DMEM_TEMP + 0x20 + resampledTempLen, ((samplesLenAdjusted / 2) + 7) & ~7); break; } } if (finished) { break; } } } flags = A_CONTINUE; if (noteSubEu->bitField0.needsInit == true) { noteSubEu->bitField0.needsInit = false; flags = A_INIT; } cmd = AudioSynth_FinalResample(cmd, synthState, aiBufLen * 2, resamplingRateFixedPoint, noteSamplesDmemAddrBeforeResampling, flags); if (bookOffset == 3) { AudioSynth_UnkCmd19(cmd++, DMEM_TEMP, DMEM_TEMP, aiBufLen * 2, 0); } if (bookOffset == 2) { AudioSynth_UnkCmd3(cmd++, DMEM_TEMP, DMEM_TEMP, aiBufLen * 2); } phi_a1_2 = noteSubEu->unk_2; if (phi_a1_2 != 0) { if (phi_a1_2 < 0x10) { phi_a1_2 = 0x10; } AudioSynth_HiLoGain(cmd++, phi_a1_2, DMEM_TEMP, 0, (aiBufLen * 2) + 0x20); } filter = noteSubEu->filter; if (filter != 0) { AudioSynth_LoadFilterCount(cmd++, aiBufLen * 2, filter); AudioSynth_LoadFilter(cmd++, flags, DMEM_TEMP, synthState->synthesisBuffers->mixEnvelopeState); } unk7 = noteSubEu->unk_07; unkE = noteSubEu->unk_0E; buf = &synthState->synthesisBuffers->panSamplesBuffer[0x18]; if (unk7 != 0 && noteSubEu->unk_0E != 0) { AudioSynth_DMemMove(cmd++, DMEM_TEMP, DMEM_SCRATCH2, aiBufLen * 2); thing = DMEM_SCRATCH2 - unk7; if (synthState->unk_1A != 0) { AudioSynth_ClearBuffer(cmd++, thing, unk7); synthState->unk_1A = 0; } else { AudioSynth_LoadBuffer(cmd++, thing, unk7, buf); } AudioSynth_SaveBuffer(cmd++, DMEM_TEMP + (aiBufLen * 2) - unk7, unk7, buf); AudioSynth_Mix(cmd++, (aiBufLen * 2) >> 4, unkE, DMEM_SCRATCH2, thing); AudioSynth_DMemMove(cmd++, thing, DMEM_TEMP, aiBufLen * 2); } else { synthState->unk_1A = 1; } if (noteSubEu->headsetPanRight != 0 || synthState->prevHeadsetPanRight != 0) { side = 1; } else if (noteSubEu->headsetPanLeft != 0 || synthState->prevHeadsetPanLeft != 0) { side = 2; } else { side = 0; } cmd = AudioSynth_ProcessEnvelope(cmd, noteSubEu, synthState, aiBufLen, DMEM_TEMP, side, flags); if (noteSubEu->bitField1.usesHeadsetPanEffects2) { if (!(flags & A_INIT)) { flags = A_CONTINUE; } cmd = AudioSynth_NoteApplyHeadsetPanEffects(cmd, noteSubEu, synthState, aiBufLen * 2, flags, side); } return cmd; } Acmd* AudioSynth_FinalResample(Acmd* cmd, NoteSynthesisState* synthState, s32 count, u16 pitch, u16 inpDmem, s32 resampleFlags) { if (pitch == 0) { AudioSynth_ClearBuffer(cmd++, DMEM_TEMP, count); } else { aSetBuffer(cmd++, 0, inpDmem, DMEM_TEMP, count); aResample(cmd++, resampleFlags, pitch, synthState->synthesisBuffers->finalResampleState); } return cmd; } Acmd* AudioSynth_ProcessEnvelope(Acmd* cmd, NoteSubEu* noteSubEu, NoteSynthesisState* synthState, s32 aiBufLen, u16 inBuf, s32 headsetPanSettings, s32 flags) { u32 phi_a1; u16 curVolLeft; u16 targetVolLeft; s32 phi_t1; s16 reverbVol; u16 curVolRight; s16 rampLeft; s16 rampRight; s16 rampReverb; s16 sourceReverbVol; u16 targetVolRight; s32 pad; curVolLeft = synthState->curVolLeft; targetVolLeft = noteSubEu->targetVolLeft; targetVolLeft <<= 4; reverbVol = noteSubEu->reverbVol; curVolRight = synthState->curVolRight; targetVolRight = noteSubEu->targetVolRight; targetVolRight <<= 4; if (targetVolLeft != curVolLeft) { rampLeft = (targetVolLeft - curVolLeft) / (aiBufLen >> 3); } else { rampLeft = 0; } if (targetVolRight != curVolRight) { rampRight = (targetVolRight - curVolRight) / (aiBufLen >> 3); } else { rampRight = 0; } sourceReverbVol = synthState->reverbVol; phi_t1 = sourceReverbVol & 0x7F; if (sourceReverbVol != reverbVol) { rampReverb = (((reverbVol & 0x7F) - phi_t1) << 9) / (aiBufLen >> 3); synthState->reverbVol = reverbVol; } else { rampReverb = 0; } synthState->curVolLeft = curVolLeft + (rampLeft * (aiBufLen >> 3)); synthState->curVolRight = curVolRight + (rampRight * (aiBufLen >> 3)); if (noteSubEu->bitField1.usesHeadsetPanEffects2) { AudioSynth_ClearBuffer(cmd++, DMEM_NOTE_PAN_TEMP, DEFAULT_LEN_1CH); AudioSynth_EnvSetup1(cmd++, phi_t1 * 2, rampReverb, rampLeft, rampRight); AudioSynth_EnvSetup2(cmd++, curVolLeft, curVolRight); switch (headsetPanSettings) { case 1: phi_a1 = D_801304A4; break; case 2: phi_a1 = D_801304A8; break; default: phi_a1 = D_801304AC; break; } } else { aEnvSetup1(cmd++, phi_t1 * 2, rampReverb, rampLeft, rampRight); aEnvSetup2(cmd++, curVolLeft, curVolRight); phi_a1 = D_801304AC; } aEnvMixer(cmd++, inBuf, aiBufLen, (sourceReverbVol & 0x80) >> 7, noteSubEu->bitField0.stereoHeadsetEffects, noteSubEu->bitField0.usesHeadsetPanEffects, noteSubEu->bitField0.stereoStrongRight, noteSubEu->bitField0.stereoStrongLeft, phi_a1, D_801304A0); return cmd; } Acmd* AudioSynth_LoadWaveSamples(Acmd* cmd, NoteSubEu* noteSubEu, NoteSynthesisState* synthState, s32 nSamplesToLoad) { s32 temp_v0; s32 unk6 = noteSubEu->unk_06; s32 samplePosInt = synthState->samplePosInt; s32 repeats; if (noteSubEu->bitField1.bookOffset != 0) { AudioSynth_LoadBuffer(cmd++, DMEM_UNCOMPRESSED_NOTE, ALIGN16(nSamplesToLoad * 2), gWaveSamples[8]); gWaveSamples[8] += nSamplesToLoad * 2; return cmd; } else { aLoadBuffer(cmd++, noteSubEu->sound.samples, DMEM_UNCOMPRESSED_NOTE, 0x80); if (unk6 != 0) { samplePosInt = (samplePosInt * D_801304C0[unk6 >> 2]) / D_801304C0[unk6 & 3]; } samplePosInt &= 0x3F; temp_v0 = 0x40 - samplePosInt; if (temp_v0 < nSamplesToLoad) { repeats = ((nSamplesToLoad - temp_v0 + 0x3F) / 0x40); if (repeats != 0) { aDuplicate(cmd++, repeats, DMEM_UNCOMPRESSED_NOTE, DMEM_UNCOMPRESSED_NOTE + 0x80); } } synthState->samplePosInt = samplePosInt; } return cmd; } Acmd* AudioSynth_NoteApplyHeadsetPanEffects(Acmd* cmd, NoteSubEu* noteSubEu, NoteSynthesisState* synthState, s32 bufLen, s32 flags, s32 side) { u16 dest; u16 pitch; u8 prevPanShift; u8 panShift; switch (side) { case 1: dest = DMEM_LEFT_CH; panShift = noteSubEu->headsetPanRight; prevPanShift = synthState->prevHeadsetPanRight; synthState->prevHeadsetPanLeft = 0; synthState->prevHeadsetPanRight = panShift; break; case 2: dest = DMEM_RIGHT_CH; panShift = noteSubEu->headsetPanLeft; prevPanShift = synthState->prevHeadsetPanLeft; synthState->prevHeadsetPanLeft = panShift; synthState->prevHeadsetPanRight = 0; break; default: return cmd; } if (flags != A_INIT) { // Slightly adjust the sample rate in order to fit a change in pan shift if (panShift != prevPanShift) { pitch = (((bufLen << 0xF) / 2) - 1) / ((bufLen + panShift - prevPanShift - 2) / 2); aSetBuffer(cmd++, 0, DMEM_NOTE_PAN_TEMP, DMEM_TEMP, bufLen + panShift - prevPanShift); aResampleZoh(cmd++, pitch, 0); } else { aDMEMMove(cmd++, DMEM_NOTE_PAN_TEMP, DMEM_TEMP, bufLen); } if (prevPanShift != 0) { aLoadBuffer(cmd++, &synthState->synthesisBuffers->panResampleState[0x8], DMEM_NOTE_PAN_TEMP, ALIGN16(prevPanShift)); aDMEMMove(cmd++, DMEM_TEMP, DMEM_NOTE_PAN_TEMP + prevPanShift, bufLen + panShift - prevPanShift); } else { aDMEMMove(cmd++, DMEM_TEMP, DMEM_NOTE_PAN_TEMP, bufLen + panShift); } } else { // Just shift right aDMEMMove(cmd++, DMEM_NOTE_PAN_TEMP, DMEM_TEMP, bufLen); aClearBuffer(cmd++, DMEM_NOTE_PAN_TEMP, panShift); aDMEMMove(cmd++, DMEM_TEMP, DMEM_NOTE_PAN_TEMP + panShift, bufLen); } if (panShift) { // Save excessive samples for next iteration aSaveBuffer(cmd++, DMEM_NOTE_PAN_TEMP + bufLen, &synthState->synthesisBuffers->panResampleState[0x8], ALIGN16(panShift)); } aAddMixer(cmd++, ALIGN64(bufLen), DMEM_NOTE_PAN_TEMP, dest); return cmd; }