/* Copyright (c) 2003-2004 Various contributors * * Permission is hereby granted, free of charge, to any person obtaining a copy * of this software and associated documentation files (the "Software"), to * deal in the Software without restriction, including without limitation the * rights to use, copy, modify, merge, publish, distribute, sublicense, and/or * sell copies of the Software, and to permit persons to whom the Software is * furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS * IN THE SOFTWARE. */ #include #include #include #include "mt32emu.h" using namespace MT32Emu; Partial::Partial(Synth *useSynth) { this->synth = useSynth; ownerPart = -1; poly = NULL; pair = NULL; } Partial::~Partial() { } int Partial::getOwnerPart() { return ownerPart; } bool Partial::isActive() { return ownerPart > -1; } void Partial::activate(int part) { // This just marks the partial as being assigned to a part ownerPart = part; } void Partial::deactivate() { ownerPart = -1; if (poly != NULL) { for (int i = 0; i < 4; i++) { if (poly->partials[i] == this) { poly->partials[i] = NULL; break; } } if (pair != NULL) { pair->pair = NULL; } } } void Partial::initKeyFollow(int key) { // Setup partial keyfollow // Note follow relative to middle C int keyfollow; int realfol = (key * 2 - MIDDLEC * 2) / 2; int antirealfol = (MIDDLEC * 2 - key * 2) / 2; // Calculate keyfollow for pitch switch(patchCache->pitchkeydir) { case -1: keyfollow = (antirealfol * patchCache->pitchkeyfollow) >> 12; break; case 0: keyfollow = 0; break; case 1: keyfollow = (realfol * patchCache->pitchkeyfollow) >> 12; break; default: keyfollow = 0; // Please the compiler } if ((patchCache->pitchkeyfollow>4096) && (patchCache->pitchkeyfollow<4200)) { // Be sure to round up on keys below MIDDLEC if (realfol < 0) keyfollow++; } noteVal = (keyfollow + patchCache->pitchshift); if (noteVal > 108) noteVal = 108; if (noteVal < 12) noteVal = 12; // Calculate keyfollow for filter switch(patchCache->keydir) { case -1: keyfollow = (antirealfol * patchCache->filtkeyfollow) >> 12; break; case 0: keyfollow = key; break; case 1: keyfollow = (realfol * patchCache->filtkeyfollow) >> 12; break; } if (keyfollow > 108) keyfollow = 108; if (keyfollow < -108) keyfollow = -108; filtVal = keytable[keyfollow + 108]; realVal = keytable[realfol + 108]; } void Partial::startPartial(dpoly *usePoly, PatchCache *useCache, Partial *pairPartial) { if (usePoly == NULL || useCache == NULL) { synth->printDebug("*** Error: Starting partial for owner %d, usePoly=%s, useCache=%s", ownerPart, usePoly == NULL ? "*** NULL ***" : "OK", useCache == NULL ? "*** NULL ***" : "OK"); return; } patchCache = useCache; poly = usePoly; mixType = patchCache->structureMix; structurePosition = patchCache->structurePosition; play = true; initKeyFollow(poly->freqnum); // Initialises noteVal, filtVal and realVal lfoPos = 0; pulsewidth = patchCache->pulsewidth + pwveltable[patchCache->pwsens][poly->vel]; if (pulsewidth > 100) { pulsewidth = 100; } else if (pulsewidth < 0) { pulsewidth = 0; } for (int e = 0; e < 3; e++) { envs[e].envpos = 0; envs[e].envstat = -1; envs[e].envbase = 0; envs[e].envdist = 0; envs[e].envsize = 0; envs[e].sustaining = false; envs[e].decaying = false; envs[e].prevlevel = 0; envs[e].counter = 0; envs[e].count = 0; } ampEnvCache = 0; pitchEnvCache = 0; pitchSustain = false; loopPos = 0; partialOff.pcmoffset = partialOff.pcmplace = 0; pair = pairPartial; useNoisePair = pairPartial == NULL && (mixType == 1 || mixType == 2); age = 0; alreadyOutputed = false; memset(history,0,sizeof(history)); } Bit16s *Partial::generateSamples(long length) { if (!isActive() || alreadyOutputed) { return NULL; } if (poly == NULL) { synth->printDebug("*** ERROR: poly is NULL at Partial::generateSamples()!"); return NULL; } alreadyOutputed = true; // Generate samples Bit16s *partialBuf = &myBuffer[0]; while (length--) { Bit32s envval, ampval; Bit32s ptemp = 0; if (envs[EnvelopeType_amp].sustaining) ampval = ampEnvCache; else { if (envs[EnvelopeType_amp].count <= 0) { ampval = getAmpEnvelope(); if (!play) { deactivate(); break; } if (ampval < 0) { //TODO: check what is going on here synth->printDebug("ampval<0! ampval=%ld, active=%d", ampval, isActive()); ampval = 0; } else if (ampval > 127) { ampval = 127; } ampval = voltable[ampval]; int tmpvel; if (patchCache->ampenvdir == 1) tmpvel = 127 - poly->vel; else tmpvel = poly->vel; ampval = (ampval * ampveltable[tmpvel][(int)patchCache->ampEnv.velosens]) >> 8; //if (envs[EnvelopeType_amp].sustaining) ampEnvCache = ampval; } else ampval = ampEnvCache; --envs[EnvelopeType_amp].count; } // Calculate Pitch envelope int lfoat = 0x1000; int pdep; if (pitchSustain) { // Calculate LFO position // LFO does not kick in completely until pitch envelope sustains if (patchCache->lfodepth > 0) { lfoPos++; if (lfoPos >= patchCache->lfoperiod) lfoPos = 0; int lfoatm = (lfoPos << 16) / patchCache->lfoperiod; int lfoatr = sintable[lfoatm]; lfoat = lfoptable[patchCache->lfodepth][lfoatr]; } pdep = pitchEnvCache; } else { envval = getPitchEnvelope(); int pd = patchCache->pitchEnv.depth; pdep = penvtable[pd][envval]; if (pitchSustain) pitchEnvCache = pdep; } int delta; // These two are only for PCM partials, obviously PCMWaveEntry *pcmWave = NULL; // Initialise to please compiler int pcmAddr = 0; // Initialise to please compiler // Get waveform - either PCM or synthesized sawtooth or square if (patchCache->PCMPartial) { // PCM partial int len; pcmWave = &synth->PCMList[patchCache->pcm]; if (pcmWave->aggSound == -1) { delta = wavtabler[pcmWave->pcmnum][noteVal]; pcmAddr = pcmWave->addr; len = pcmWave->len; if (partialOff.pcmplace >= len) { if (pcmWave->loop) { partialOff.pcmplace = partialOff.pcmoffset = 0; // FIXME:KG: Use this?: partialOff.pcmplace %= len; } else { play = false; deactivate(); break; } } } else { int tmppcm = LoopPatterns[pcmWave->aggSound][loopPos]; delta = looptabler[pcmWave->aggSound][loopPos][noteVal]; pcmAddr = synth->PCM[tmppcm].addr; len = synth->PCM[tmppcm].len; if (partialOff.pcmplace >= len) { loopPos++; if (LoopPatterns[pcmWave->aggSound][loopPos] == -1) loopPos = 0; partialOff.pcmplace = partialOff.pcmoffset = 0; } } } else { // Synthesis partial delta = 0x10707; partialOff.pcmplace %= (Bit16u)(divtable[noteVal] >> 15); } // Build delta for position of next sample // Fix delta code Bit64s tdelta = (Bit64s)delta; tdelta = (tdelta * patchCache->fineshift) >> 12; tdelta = (tdelta * pdep) >> 12; tdelta = (tdelta * lfoat) >> 12; tdelta = (tdelta * bendShift) >> 12; delta = (int)tdelta; if (ampval > 0) { if (patchCache->PCMPartial) { // Render PCM sample int ra, rb, dist; int taddr; if (delta < 0x10000) { // Linear sound interpolation taddr = pcmAddr + partialOff.pcmplace; if (taddr >= ROMSIZE) { synth->printDebug("Overflow ROMSIZE!"); taddr = ROMSIZE - 1; } ra = synth->romfile[taddr]; //FIXME:KG: Deal with condition that taddr + 1 is past PCM length rb = synth->romfile[taddr + 1]; dist = rb - ra; ptemp = (ra + ((dist * (Bit32s)(partialOff.pcmoffset >> 8)) >> 8)); } else { // Sound decimation // The right way to do it is to use a lowpass filter on the waveform before selecting // a point. This is too slow. The following approximates this as fast as possible int idelta = delta >> 16; taddr = pcmAddr + partialOff.pcmplace; ra = 0; for (int ix = 0; ix < idelta; ix++) ra += synth->romfile[taddr++]; ptemp = ra / idelta; } } else { // Render synthesised sample int divis = divtable[noteVal] >> 15; int wf = patchCache->waveform; int toff = partialOff.pcmplace; int minorplace = partialOff.pcmoffset >> 14; Bit32s filtval = getFiltEnvelope(); //synth->printDebug("Filtval: %d", filtval); if (wf==0) { // Square waveform. Made by combining two pregenerated bandlimited // sawtooth waveforms // Pulse width is not yet correct int pa, pb; int hdivis = divis >> 1; int divmark = smalldivtable[noteVal]; if (hdivis == 0) { synth->printDebug("ERROR: hdivis=0 generating square wave, this should never happen!"); hdivis = 1; } int ofs = toff % hdivis; int ofs3 = toff + ((divmark * pulsetable[pulsewidth]) >> 16); ofs3 = ofs3 % (hdivis); pa = waveforms[1][noteVal][(ofs << 2)+minorplace]; pb = waveforms[0][noteVal][(ofs3 << 2)+minorplace]; ptemp = (pa + pb) * 4; // Non-bandlimited squarewave /* ofs = (divis*pulsetable[patchCache->pulsewidth])>>8; if (toff < ofs) ptemp = 1 * WGAMP; else ptemp = -1 * WGAMP; */ } else { // Sawtooth. Made by combining the full cosine and half cosine according // to how it looks on the MT-32. What it really does it takes the // square wave and multiplies it by a full cosine int waveoff = (toff << 2) + minorplace; if (toff < sawtable[noteVal][pulsewidth]) ptemp = waveforms[2][noteVal][waveoff % waveformsize[2][noteVal]]; else ptemp = waveforms[3][noteVal][waveoff % waveformsize[3][noteVal]]; ptemp = ptemp * 4; // This is the correct way // Seems slow to me (though bandlimited) -- doesn't seem to // sound any better though /* hdivis = divis >> 1; int divmark = smalldivtable[noteVal]; //int pw = (patchCache->pulsewidth * pulsemod[filtval]) >> 8; ofs = toff % (hdivis); ofs3 = toff + ((divmark*pulsetable[patchCache->pulsewidth])>>16); ofs3 = ofs3 % (hdivis); pa = waveforms[0][noteVal][ofs]; pb = waveforms[1][noteVal][ofs3]; ptemp = ((pa+pb) * waveforms[3][noteVal][toff]) / WGAMP; ptemp = ptemp *4; */ } //Very exact filter if (filtval > ((FILTERGRAN * 15) / 16)) filtval = ((FILTERGRAN * 15) / 16); ptemp = (Bit32s)floor((usefilter)((float)ptemp, &history[0], filtcoeff[filtval][(int)patchCache->filtEnv.resonance], patchCache->filtEnv.resonance)); } } // Add calculated delta to our waveform offset Bit32u absOff = ((partialOff.pcmplace << 16) | partialOff.pcmoffset); absOff += delta; partialOff.pcmplace = (Bit16u)((absOff & 0xFFFF0000) >> 16); partialOff.pcmoffset = (Bit16u)(absOff & 0xFFFF); // Put volume envelope over generated sample ptemp = (ptemp * ampval) >> 9; ptemp = (ptemp * *poly->volumeptr) >> 7; envs[EnvelopeType_amp].envpos++; envs[EnvelopeType_pitch].envpos++; envs[EnvelopeType_filt].envpos++; *partialBuf++ = (Bit16s)ptemp; } // We may have deactivated and broken out of the loop before the end of the buffer, // if so then fill the remainder with 0s. if (++length > 0) memset(partialBuf, 0, length * 2); return &myBuffer[0]; } void Partial::setBend(float factor) { if (!patchCache->useBender || factor == 0.0f) { bendShift = 4096; return; } // NOTE:KG: We can't do this smoothly with lookup tables, unless we use several MB. float bendSemitones = factor * patchCache->benderRange; // -24 .. 24 float mult = powf(2.0f, bendSemitones / 12.0f); synth->printDebug("setBend(): semitones=%f, mult=%f, factor=%f, benderRange=%d\n", bendSemitones, mult, factor, patchCache->benderRange); bendShift = (int)(mult * 4096.0f); } Bit16s *Partial::mixBuffers(Bit16s * buf1, Bit16s *buf2, int len) { if (buf1 == NULL) return buf2; if (buf2 == NULL) return buf1; Bit16s *outBuf = buf1; #if MT32EMU_USE_MMX >= 1 // KG: This seems to be fine int donelen = i386_mixBuffers(buf1, buf2, len); len -= donelen; buf1 += donelen; buf2 += donelen; #endif while (len--) { *buf1 = *buf1 + *buf2; buf1++, buf2++; } return outBuf; } Bit16s *Partial::mixBuffersRingMix(Bit16s * buf1, Bit16s *buf2, int len) { if (buf1 == NULL) return NULL; if (buf2 == NULL) { Bit16s *outBuf = buf1; while (len--) { if (*buf1 < -8192) *buf1 = -8192; else if (*buf1 > 8192) *buf1 = 8192; buf1++; } return outBuf; } Bit16s *outBuf = buf1; #if MT32EMU_USE_MMX >= 1 // KG: This seems to be fine int donelen = i386_mixBuffersRingMix(buf1, buf2, len); len -= donelen; buf1 += donelen; buf2 += donelen; #endif while (len--) { float a, b; a = ((float)*buf1) / 8192.0f; b = ((float)*buf2) / 8192.0f; a = (a * b) + a; if (a>1.0) a = 1.0; if (a<-1.0) a = -1.0; *buf1 = (Bit16s)(a * 8192.0f); buf1++; buf2++; //buf1[i] = (Bit16s)(((Bit32s)buf1[i] * (Bit32s)buf2[i]) >> 10) + buf1[i]; } return outBuf; } Bit16s *Partial::mixBuffersRing(Bit16s * buf1, Bit16s *buf2, int len) { if (buf1 == NULL) { return NULL; } if (buf2 == NULL) { return NULL; } Bit16s *outBuf = buf1; #if MT32EMU_USE_MMX >= 1 // FIXME:KG: Not really checked as working int donelen = i386_mixBuffersRing(buf1, buf2, len); len -= donelen; buf1 += donelen; buf2 += donelen; #endif while (len--) { float a, b; a = ((float)*buf1) / 8192.0f; b = ((float)*buf2) / 8192.0f; a *= b; if (a>1.0) a = 1.0; if (a<-1.0) a = -1.0; *buf1 = (Bit16s)(a * 8192.0f); buf1++; buf2++; } return outBuf; } void Partial::mixBuffersStereo(Bit16s *buf1, Bit16s *buf2, Bit16s *outBuf, int len) { if (buf2 == NULL) { while (len--) { *outBuf++ = *buf1++; *outBuf++ = 0; } } else if (buf1 == NULL) { while (len--) { *outBuf++ = 0; *outBuf++ = *buf2++; } } else { while (len--) { *outBuf++ = *buf1++; *outBuf++ = *buf2++; } } } bool Partial::produceOutput(Bit16s *partialBuf, long length) { if (!isActive() || alreadyOutputed) return false; if (poly == NULL) { synth->printDebug("*** ERROR: poly is NULL at Partial::produceOutput()!"); return false; } Bit16s *pairBuf = NULL; // Check for dependant partial if (pair != NULL) { if (!pair->alreadyOutputed) { // Note: pair may have become NULL after this pairBuf = pair->generateSamples(length); } } else if (useNoisePair) { // Generate noise for pairless ring mix pairBuf = smallnoise; } Bit16s *myBuf = generateSamples(length); if (myBuf == NULL && pairBuf == NULL) return false; Bit16s * p1buf, * p2buf; if (structurePosition == 0 || pairBuf == NULL) { p1buf = myBuf; p2buf = pairBuf; } else { p2buf = myBuf; p1buf = pairBuf; } //synth->printDebug("mixType: %d", mixType); Bit16s *mixedBuf; switch(mixType) { case 0: // Standard sound mix mixedBuf = mixBuffers(p1buf, p2buf, length); break; case 1: // Ring modulation with sound mix mixedBuf = mixBuffersRingMix(p1buf, p2buf, length); break; case 2: // Ring modulation alone mixedBuf = mixBuffersRing(p1buf, p2buf, length); break; case 3: // Stereo mixing. One partial to one speaker channel, one to another. // FIXME:KG: Surely we should be multiplying by the left/right volumes here? mixBuffersStereo(p1buf, p2buf, partialBuf, length); return true; default: mixedBuf = mixBuffers(p1buf, p2buf, length); break; } if (mixedBuf == NULL) return false; Bit16s leftvol, rightvol; leftvol = poly->pansetptr->leftvol; rightvol = poly->pansetptr->rightvol; #if MT32EMU_USE_MMX >= 2 // FIXME:KG: This appears to introduce crackle int donelen = i386_partialProductOutput(length, leftvol, rightvol, partialBuf, mixedBuf); length -= donelen; mixedBuf += donelen; partialBuf += donelen * 2; #endif while (length--) { *partialBuf++ = (Bit16s)(((Bit32s)*mixedBuf * (Bit32s)leftvol) >> 16); *partialBuf++ = (Bit16s)(((Bit32s)*mixedBuf * (Bit32s)rightvol) >> 16); mixedBuf++; } return true; } Bit32s Partial::getFiltEnvelope() { int reshigh; int cutoff,depth,keyfollow, realfollow; envstatus *tStat = &envs[EnvelopeType_filt]; keyfollow = filtVal; realfollow = realVal; int fr = poly->freqnum; if (tStat->decaying) { reshigh = tStat->envbase; reshigh = (reshigh + ((tStat->envdist * tStat->envpos) / tStat->envsize)); if (tStat->envpos >= tStat->envsize) reshigh = 0; } else { if (tStat->envstat==4) { reshigh = patchCache->filtsustain; if (!poly->sustain) { startDecay(EnvelopeType_filt, reshigh); } } else { if ((tStat->envstat==-1) || (tStat->envpos >= tStat->envsize)) { if (tStat->envstat==-1) tStat->envbase = 0; else tStat->envbase = patchCache->filtEnv.envlevel[tStat->envstat]; tStat->envstat++; tStat->envpos = 0; if (tStat->envstat==3) tStat->envsize = lasttimetable[(int)patchCache->filtEnv.envtime[tStat->envstat]]; else tStat->envsize = (envtimetable[(int)patchCache->filtEnv.envtime[tStat->envstat]] * timekeytable[(int)patchCache->filtEnv.envtkf][poly->freqnum]) >> 8; tStat->envsize++; tStat->envdist = patchCache->filtEnv.envlevel[tStat->envstat] - tStat->envbase; } reshigh = tStat->envbase; reshigh = (reshigh + ((tStat->envdist * tStat->envpos) / tStat->envsize)); } tStat->prevlevel = reshigh; } cutoff = patchCache->filtEnv.cutoff; //if (patchCache->waveform==1) reshigh = (reshigh * 3) >> 2; depth = patchCache->filtEnv.envdepth; //int sensedep = (depth * 127-patchCache->filtEnv.envsense) >> 7; depth = (depth * filveltable[poly->vel][(int)patchCache->filtEnv.envsense]) >> 8; int bias = patchCache->tvfbias; int dist; if (bias!=0) { //synth->printDebug("Cutoff before %d", cutoff); if (patchCache->tvfdir == 0) { if (fr < bias) { dist = bias - fr; cutoff = (cutoff * fbiastable[patchCache->tvfblevel][dist]) >> 8; } } else { // > Bias if (fr > bias) { dist = fr - bias; cutoff = (cutoff * fbiastable[patchCache->tvfblevel][dist]) >> 8; } } //synth->printDebug("Cutoff after %d", cutoff); } depth = (depth * fildeptable[patchCache->tvfdepth][fr]) >> 8; reshigh = (reshigh * depth) >> 7; Bit32s tmp; cutoff *= keyfollow; cutoff /= realfollow; reshigh *= keyfollow; reshigh /= realfollow; if (cutoff>100) cutoff = 100; else if (cutoff<0) cutoff = 0; if (reshigh>100) reshigh = 100; else if (reshigh<0) reshigh = 0; tmp = nfilttable[fr][cutoff][reshigh]; //tmp *= keyfollow; //tmp /= realfollow; //synth->printDebug("Cutoff %d, tmp %d, freq %d", cutoff, tmp, tmp * 256); return tmp; } bool Partial::shouldReverb() { if (!isActive()) return false; return poly->reverb; } Bit32s Partial::getAmpEnvelope() { Bit32s tc; envstatus *tStat = &envs[EnvelopeType_amp]; if (!play) return 0; if (tStat->decaying) { tc = tStat->envbase; tc = (tc + ((tStat->envdist * tStat->envpos) / tStat->envsize)); if (tc < 0) tc = 0; if ((tStat->envpos >= tStat->envsize) || (tc == 0)) { play = false; // Don't have to worry about prevlevel storage or anything, this partial's about to die return 0; } } else { if ((tStat->envstat==-1) || (tStat->envpos >= tStat->envsize)) { if (tStat->envstat==-1) tStat->envbase = 0; else tStat->envbase = patchCache->ampEnv.envlevel[tStat->envstat]; tStat->envstat++; tStat->envpos = 0; switch(tStat->envstat) { case 0: //Spot for velocity time follow //Only used for first attack tStat->envsize = (envtimetable[(int)patchCache->ampEnv.envtime[tStat->envstat]] * veltkeytable[(int)patchCache->ampEnv.envvkf][poly->vel]) >> 8; //synth->printDebug("Envstat %d, size %d", tStat->envstat, tStat->envsize); break; case 3: // Final attack envelope uses same time table as the decay //tStat->envsize = decaytimetable[patchCache->ampEnv.envtime[tStat->envstat]]; tStat->envsize = lasttimetable[(int)patchCache->ampEnv.envtime[tStat->envstat]]; //synth->printDebug("Envstat %d, size %d", tStat->envstat, tStat->envsize); break; case 4: //synth->printDebug("Envstat %d, size %d", tStat->envstat, tStat->envsize); tc = patchCache->ampsustain; if (!poly->sustain) startDecay(EnvelopeType_amp, tc); else tStat->sustaining = true; goto PastCalc; default: //Spot for timekey follow //Only used in subsquent envelope parameters, including the decay tStat->envsize = (envtimetable[(int)patchCache->ampEnv.envtime[tStat->envstat]] * timekeytable[(int)patchCache->ampEnv.envtkf][poly->freqnum]) >> 8; //synth->printDebug("Envstat %d, size %d", tStat->envstat, tStat->envsize); break; } tStat->envsize++; tStat->envdist = patchCache->ampEnv.envlevel[tStat->envstat] - tStat->envbase; if (tStat->envdist != 0) { tStat->counter = abs(tStat->envsize / tStat->envdist); //synth->printDebug("Pos %d, envsize %d envdist %d", tStat->envstat, tStat->envsize, tStat->envdist); } else { tStat->counter = 0; //synth->printDebug("Pos %d, envsize %d envdist %d", tStat->envstat, tStat->envsize, tStat->envdist); } } tc = tStat->envbase; tc = (tc + ((tStat->envdist * tStat->envpos) / tStat->envsize)); tStat->count = tStat->counter; PastCalc: tc = (tc * (Bit32s)patchCache->amplevel) >> 7; } // Prevlevel storage is bottle neck tStat->prevlevel = tc; //Bias level crap stuff now int dist, bias; for (int i = 0; i < 2; i++) { if (patchCache->ampblevel[i]!=0) { bias = patchCache->ampbias[i]; if (patchCache->ampdir[i]==0) { // < Bias if (poly->freqnum < bias) { dist = bias-poly->freqnum; tc = (tc * ampbiastable[patchCache->ampblevel[i]][dist]) >> 8; } } else { // > Bias if (poly->freqnum > bias) { dist = poly->freqnum-bias; tc = (tc * ampbiastable[patchCache->ampblevel[i]][dist]) >> 8; } } } } return tc; } Bit32s Partial::getPitchEnvelope() { envstatus *tStat = &envs[EnvelopeType_pitch]; Bit32s tc; pitchSustain = false; if (tStat->decaying) { if (tStat->envpos >= tStat->envsize) tc = patchCache->pitchEnv.level[4]; else { tc = tStat->envbase; tc = (tc + ((tStat->envdist * tStat->envpos) / tStat->envsize)); } } else { if (tStat->envstat==3) { tc = patchCache->pitchsustain; if (poly->sustain) pitchSustain = true; else startDecay(EnvelopeType_pitch, tc); } else { if ((tStat->envstat==-1) || (tStat->envpos >= tStat->envsize)) { tStat->envstat++; tStat->envbase = patchCache->pitchEnv.level[tStat->envstat]; tStat->envsize = (envtimetable[(int)patchCache->pitchEnv.time[tStat->envstat]] * timekeytable[(int)patchCache->pitchEnv.timekeyfollow][poly->freqnum]) >> 8; tStat->envpos = 0; tStat->envsize++; tStat->envdist = patchCache->pitchEnv.level[tStat->envstat+1] - tStat->envbase; } tc = tStat->envbase; tc = (tc + ((tStat->envdist * tStat->envpos) / tStat->envsize)); } tStat->prevlevel = tc; } return tc; } void Partial::startDecayAll() { startDecay(EnvelopeType_amp, envs[EnvelopeType_amp].prevlevel); startDecay(EnvelopeType_filt, envs[EnvelopeType_filt].prevlevel); startDecay(EnvelopeType_pitch, envs[EnvelopeType_pitch].prevlevel); pitchSustain = false; } void Partial::startDecay(EnvelopeType envnum, Bit32s startval) { envstatus *tStat = &envs[envnum]; tStat->sustaining = false; tStat->decaying = true; tStat->envpos = 0; tStat->envbase = startval; switch(envnum) { case EnvelopeType_amp: tStat->envsize = (decaytimetable[(int)patchCache->ampEnv.envtime[4]] * timekeytable[(int)patchCache->ampEnv.envtkf][poly->freqnum]) >> 8; tStat->envdist = -startval; break; case EnvelopeType_filt: tStat->envsize = (decaytimetable[(int)patchCache->filtEnv.envtime[4]] * timekeytable[(int)patchCache->filtEnv.envtkf][poly->freqnum]) >> 8; tStat->envdist = -startval; break; case EnvelopeType_pitch: tStat->envsize = (decaytimetable[(int)patchCache->pitchEnv.time[3]] * timekeytable[(int)patchCache->pitchEnv.timekeyfollow][poly->freqnum]) >> 8 ; tStat->envdist = patchCache->pitchEnv.level[4] - startval; break; default: break; } tStat->envsize++; }