/* Copyright (C) 2003, 2004, 2005, 2006, 2008, 2009 Dean Beeler, Jerome Fisher
* Copyright (C) 2011 Dean Beeler, Jerome Fisher, Sergey V. Mikayev
*
* This program is free software: you can redistribute it and/or modify
* it under the terms of the GNU Lesser General Public License as published by
* the Free Software Foundation, either version 2.1 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 Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public License
* along with this program. If not, see .
*/
//#include
//#include
//#include
#include "mt32emu.h"
#include "mmath.h"
namespace MT32Emu {
#ifdef INACCURATE_SMOOTH_PAN
// Mok wanted an option for smoother panning, and we love Mok.
static const float PAN_NUMERATOR_NORMAL[] = {0.0f, 0.5f, 1.0f, 1.5f, 2.0f, 2.5f, 3.0f, 3.5f, 4.0f, 4.5f, 5.0f, 5.5f, 6.0f, 6.5f, 7.0f};
#else
// CONFIRMED by Mok: These NUMERATOR values (as bytes, not floats, obviously) are sent exactly like this to the LA32.
static const float PAN_NUMERATOR_NORMAL[] = {0.0f, 0.0f, 1.0f, 1.0f, 2.0f, 2.0f, 3.0f, 3.0f, 4.0f, 4.0f, 5.0f, 5.0f, 6.0f, 6.0f, 7.0f};
#endif
static const float PAN_NUMERATOR_MASTER[] = {0.0f, 0.0f, 0.0f, 0.0f, 0.0f, 0.0f, 0.0f, 0.0f, 1.0f, 2.0f, 3.0f, 4.0f, 5.0f, 6.0f, 7.0f};
static const float PAN_NUMERATOR_SLAVE[] = {0.0f, 1.0f, 2.0f, 3.0f, 4.0f, 5.0f, 6.0f, 7.0f, 7.0f, 7.0f, 7.0f, 7.0f, 7.0f, 7.0f, 7.0f};
Partial::Partial(Synth *useSynth, int useDebugPartialNum) :
synth(useSynth), debugPartialNum(useDebugPartialNum), sampleNum(0), tva(new TVA(this, &Ramp)), tvp(new TVP(this)), tvf(new TVF(this, &cutoffModifierRamp)) {
ownerPart = -1;
poly = NULL;
pair = NULL;
}
Partial::~Partial() {
delete tva;
delete tvp;
delete tvf;
}
// Only used for debugging purposes
int Partial::debugGetPartialNum() const {
return debugPartialNum;
}
// Only used for debugging purposes
unsigned long Partial::debugGetSampleNum() const {
return sampleNum;
}
int Partial::getOwnerPart() const {
return ownerPart;
}
bool Partial::isActive() const {
return ownerPart > -1;
}
const Poly *Partial::getPoly() const {
return poly;
}
void Partial::activate(int part) {
// This just marks the partial as being assigned to a part
ownerPart = part;
}
void Partial::deactivate() {
if (!isActive()) {
return;
}
ownerPart = -1;
if (poly != NULL) {
poly->partialDeactivated(this);
if (pair != NULL) {
pair->pair = NULL;
}
}
#if MT32EMU_MONITOR_PARTIALS > 2
synth->printDebug("[+%lu] [Partial %d] Deactivated", sampleNum, debugPartialNum);
synth->printPartialUsage(sampleNum);
#endif
}
// DEPRECATED: This should probably go away eventually, it's currently only used as a kludge to protect our old assumptions that
// rhythm part notes were always played as key MIDDLEC.
int Partial::getKey() const {
if (poly == NULL) {
return -1;
} else if (ownerPart == 8) {
// FIXME: Hack, should go away after new pitch stuff is committed (and possibly some TVF changes)
return MIDDLEC;
} else {
return poly->getKey();
}
}
void Partial::startPartial(const Part *part, Poly *usePoly, const PatchCache *usePatchCache, const MemParams::RhythmTemp *rhythmTemp, Partial *pairPartial) {
if (usePoly == NULL || usePatchCache == NULL) {
synth->printDebug("[Partial %d] *** Error: Starting partial for owner %d, usePoly=%s, usePatchCache=%s", debugPartialNum, ownerPart, usePoly == NULL ? "*** NULL ***" : "OK", usePatchCache == NULL ? "*** NULL ***" : "OK");
return;
}
patchCache = usePatchCache;
poly = usePoly;
mixType = patchCache->structureMix;
structurePosition = patchCache->structurePosition;
Bit8u panSetting = rhythmTemp != NULL ? rhythmTemp->panpot : part->getPatchTemp()->panpot;
float panVal;
if (mixType == 3) {
if (structurePosition == 0) {
panVal = PAN_NUMERATOR_MASTER[panSetting];
} else {
panVal = PAN_NUMERATOR_SLAVE[panSetting];
}
// Do a normal mix independent of any pair partial.
mixType = 0;
pairPartial = NULL;
} else {
panVal = PAN_NUMERATOR_NORMAL[panSetting];
}
// FIXME: Sample analysis suggests that the use of panVal is linear, but there are some some quirks that still need to be resolved.
stereoVolume.leftVol = panVal / 7.0f;
stereoVolume.rightVol = 1.0f - stereoVolume.leftVol;
// SEMI-CONFIRMED: From sample analysis:
// Found that timbres with 3 or 4 partials (i.e. one using two partial pairs) are mixed in two different ways.
// Either partial pairs are added or subtracted, it depends on how the partial pairs are allocated.
// It seems that partials are grouped into quarters and if the partial pairs are allocated in different quarters the subtraction happens.
// Though, this matters little for the majority of timbres, it becomes crucial for timbres which contain several partials that sound very close.
// In this case that timbre can sound totally different depending of the way it is mixed up.
// Most easily this effect can be displayed with the help of a special timbre consisting of several identical square wave partials (3 or 4).
// Say, it is 3-partial timbre. Just play any two notes simultaneously and the polys very probably are mixed differently.
// Moreover, the partial allocator retains the last partial assignment it did and all the subsequent notes will sound the same as the last released one.
// The situation is better with 4-partial timbres since then a whole quarter is assigned for each poly. However, if a 3-partial timbre broke the normal
// whole-quarter assignment or after some partials got aborted, even 4-partial timbres can be found sounding differently.
// This behaviour is also confirmed with two more special timbres: one with identical sawtooth partials, and one with PCM wave 02.
// For my personal taste, this behaviour rather enriches the sounding and should be emulated.
// Also, the current partial allocator model probably needs to be refined.
if (debugPartialNum & 8) {
stereoVolume.leftVol = -stereoVolume.leftVol;
stereoVolume.rightVol = -stereoVolume.rightVol;
}
if (patchCache->PCMPartial) {
pcmNum = patchCache->pcm;
if (synth->controlROMMap->pcmCount > 128) {
// CM-32L, etc. support two "banks" of PCMs, selectable by waveform type parameter.
if (patchCache->waveform > 1) {
pcmNum += 128;
}
}
pcmWave = &synth->pcmWaves[pcmNum];
} else {
pcmWave = NULL;
wavePos = 0.0f;
lastFreq = 0.0;
}
// CONFIRMED: pulseWidthVal calculation is based on information from Mok
pulseWidthVal = (poly->getVelocity() - 64) * (patchCache->srcPartial.wg.pulseWidthVeloSensitivity - 7) + Tables::getInstance().pulseWidth100To255[patchCache->srcPartial.wg.pulseWidth];
if (pulseWidthVal < 0) {
pulseWidthVal = 0;
} else if (pulseWidthVal > 255) {
pulseWidthVal = 255;
}
pcmPosition = 0.0f;
pair = pairPartial;
alreadyOutputed = false;
tva->reset(part, patchCache->partialParam, rhythmTemp);
tvp->reset(part, patchCache->partialParam);
tvf->reset(patchCache->partialParam, tvp->getBasePitch());
}
float Partial::getPCMSample(unsigned int position) {
if (position >= pcmWave->len) {
if (!pcmWave->loop) {
return 0;
}
position = position % pcmWave->len;
}
return synth->pcmROMData[pcmWave->addr + position];
}
unsigned long Partial::generateSamples(float *partialBuf, unsigned long length) {
const Tables &tables = Tables::getInstance();
if (!isActive() || alreadyOutputed) {
return 0;
}
if (poly == NULL) {
synth->printDebug("[Partial %d] *** ERROR: poly is NULL at Partial::generateSamples()!", debugPartialNum);
return 0;
}
alreadyOutputed = true;
// Generate samples
for (sampleNum = 0; sampleNum < length; sampleNum++) {
float sample = 0;
Bit32u ampRampVal = ampRamp.nextValue();
if (ampRamp.checkInterrupt()) {
tva->handleInterrupt();
}
if (!tva->isPlaying()) {
deactivate();
break;
}
Bit16u pitch = tvp->nextPitch();
// SEMI-CONFIRMED: From sample analysis:
// (1) Tested with a single partial playing PCM wave 77 with pitchCoarse 36 and no keyfollow, velocity follow, etc.
// This gives results within +/- 2 at the output (before any DAC bitshifting)
// when sustaining at levels 156 - 255 with no modifiers.
// (2) Tested with a special square wave partial (internal capture ID tva5) at TVA envelope levels 155-255.
// This gives deltas between -1 and 0 compared to the real output. Note that this special partial only produces
// positive amps, so negative still needs to be explored, as well as lower levels.
//
// Also still partially unconfirmed is the behaviour when ramping between levels, as well as the timing.
#if MT32EMU_ACCURATE_WG == 1
float amp = EXP2F((32772 - ampRampVal / 2048) / -2048.0f);
float freq = EXP2F(pitch / 4096.0f - 16.0f) * 32000.0f;
#else
static const float ampFactor = EXP2F(32772 / -2048.0f);
float amp = EXP2I(ampRampVal >> 10) * ampFactor;
static const float freqFactor = EXP2F(-16.0f) * 32000.0f;
float freq = EXP2I(pitch) * freqFactor;
#endif
if (patchCache->PCMPartial) {
// Render PCM waveform
int len = pcmWave->len;
int intPCMPosition = (int)pcmPosition;
if (intPCMPosition >= len && !pcmWave->loop) {
// We're now past the end of a non-looping PCM waveform so it's time to die.
deactivate();
break;
}
Bit32u pcmAddr = pcmWave->addr;
float positionDelta = freq * 2048.0f / synth->myProp.sampleRate;
// Linear interpolation
float firstSample = synth->pcmROMData[pcmAddr + intPCMPosition];
// We observe that for partial structures with ring modulation the interpolation is not applied to the slave PCM partial.
// It's assumed that the multiplication circuitry intended to perform the interpolation on the slave PCM partial
// is borrowed by the ring modulation circuit (or the LA32 chip has a similar lack of resources assigned to each partial pair).
if (pair == NULL || mixType == 0 || structurePosition == 0) {
sample = firstSample + (getPCMSample(intPCMPosition + 1) - firstSample) * (pcmPosition - intPCMPosition);
} else {
sample = firstSample;
}
float newPCMPosition = pcmPosition + positionDelta;
if (pcmWave->loop) {
newPCMPosition = fmod(newPCMPosition, (float)pcmWave->len);
}
pcmPosition = newPCMPosition;
} else {
// Render synthesised waveform
wavePos *= lastFreq / freq;
lastFreq = freq;
Bit32u cutoffModifierRampVal = cutoffModifierRamp.nextValue();
if (cutoffModifierRamp.checkInterrupt()) {
tvf->handleInterrupt();
}
float cutoffModifier = cutoffModifierRampVal / 262144.0f;
// res corresponds to a value set in an LA32 register
Bit8u res = patchCache->srcPartial.tvf.resonance + 1;
// Using tiny exact table for computation of EXP2F(1.0f - (32 - res) / 4.0f)
float resAmp = tables.resAmpMax[res];
// The cutoffModifier may not be supposed to be directly added to the cutoff -
// it may for example need to be multiplied in some way.
// The 240 cutoffVal limit was determined via sample analysis (internal Munt capture IDs: glop3, glop4).
// More research is needed to be sure that this is correct, however.
float cutoffVal = tvf->getBaseCutoff() + cutoffModifier;
if (cutoffVal > 240.0f) {
cutoffVal = 240.0f;
}
// Wave length in samples
float waveLen = synth->myProp.sampleRate / freq;
// Init cosineLen
float cosineLen = 0.5f * waveLen;
if (cutoffVal > 128.0f) {
#if MT32EMU_ACCURATE_WG == 1
cosineLen *= EXP2F((cutoffVal - 128.0f) / -16.0f); // found from sample analysis
#else
static const float cosineLenFactor = EXP2F(128.0f / -16.0f);
cosineLen *= EXP2I(Bit32u((256.0f - cutoffVal) * 256.0f)) * cosineLenFactor;
#endif
}
// Start playing in center of first cosine segment
// relWavePos is shifted by a half of cosineLen
float relWavePos = wavePos + 0.5f * cosineLen;
if (relWavePos > waveLen) {
relWavePos -= waveLen;
}
float pulseLen = 0.5f;
if (pulseWidthVal > 128) {
pulseLen += tables.pulseLenFactor[pulseWidthVal - 128];
}
pulseLen *= waveLen;
float lLen = pulseLen - cosineLen;
// Ignore pulsewidths too high for given freq
if (lLen < 0.0f) {
lLen = 0.0f;
}
// Ignore pulsewidths too high for given freq and cutoff
float hLen = waveLen - lLen - 2 * cosineLen;
if (hLen < 0.0f) {
hLen = 0.0f;
}
// Correct resAmp for cutoff in range 50..66
if ((cutoffVal >= 128.0f) && (cutoffVal < 144.0f)) {
#if MT32EMU_ACCURATE_WG == 1
resAmp *= sinf(FLOAT_PI * (cutoffVal - 128.0f) / 32.0f);
#else
resAmp *= tables.sinf10[Bit32u(64 * (cutoffVal - 128.0f))];
#endif
}
// Produce filtered square wave with 2 cosine waves on slopes
// 1st cosine segment
if (relWavePos < cosineLen) {
#if MT32EMU_ACCURATE_WG == 1
sample = -cosf(FLOAT_PI * relWavePos / cosineLen);
#else
sample = -tables.sinf10[Bit32u(2048.0f * relWavePos / cosineLen) + 1024];
#endif
} else
// high linear segment
if (relWavePos < (cosineLen + hLen)) {
sample = 1.f;
} else
// 2nd cosine segment
if (relWavePos < (2 * cosineLen + hLen)) {
#if MT32EMU_ACCURATE_WG == 1
sample = cosf(FLOAT_PI * (relWavePos - (cosineLen + hLen)) / cosineLen);
#else
sample = tables.sinf10[Bit32u(2048.0f * (relWavePos - (cosineLen + hLen)) / cosineLen) + 1024];
#endif
} else {
// low linear segment
sample = -1.f;
}
if (cutoffVal < 128.0f) {
// Attenuate samples below cutoff 50
// Found by sample analysis
#if MT32EMU_ACCURATE_WG == 1
sample *= EXP2F(-0.125f * (128.0f - cutoffVal));
#else
static const float cutoffAttenuationFactor = EXP2F(-0.125f * 128.0f);
sample *= EXP2I(Bit32u(512.0f * cutoffVal)) * cutoffAttenuationFactor;
#endif
} else {
// Add resonance sine. Effective for cutoff > 50 only
float resSample = 1.0f;
// Now relWavePos counts from the middle of first cosine
relWavePos = wavePos;
// negative segments
if (!(relWavePos < (cosineLen + hLen))) {
resSample = -resSample;
relWavePos -= cosineLen + hLen;
}
// Resonance sine WG
#if MT32EMU_ACCURATE_WG == 1
resSample *= sinf(FLOAT_PI * relWavePos / cosineLen);
#else
resSample *= tables.sinf10[Bit32u(2048.0f * relWavePos / cosineLen) & 4095];
#endif
// Resonance sine amp
float resAmpFadeLog2 = -tables.resAmpFadeFactor[res >> 2] * (relWavePos / cosineLen); // seems to be exact
#if MT32EMU_ACCURATE_WG == 1
float resAmpFade = EXP2F(resAmpFadeLog2);
#else
static const float resAmpFadeFactor = EXP2F(-30.0f);
float resAmpFade = (resAmpFadeLog2 < -30.0f) ? 0.0f : EXP2I(Bit32u((30.0f + resAmpFadeLog2) * 4096.0f)) * resAmpFadeFactor;
#endif
// Now relWavePos set negative to the left from center of any cosine
relWavePos = wavePos;
// negative segment
if (!(wavePos < (waveLen - 0.5f * cosineLen))) {
relWavePos -= waveLen;
} else
// positive segment
if (!(wavePos < (hLen + 0.5f * cosineLen))) {
relWavePos -= cosineLen + hLen;
}
// Fading to zero while within cosine segments to avoid jumps in the wave
// Sample analysis suggests that this window is very close to cosine
if (relWavePos < 0.5f * cosineLen) {
#if MT32EMU_ACCURATE_WG == 1
resAmpFade *= 0.5f * (1.0f - cosf(FLOAT_PI * relWavePos / (0.5f * cosineLen)));
#else
resAmpFade *= 0.5f * (1.0f + tables.sinf10[Bit32s(2048.0f * relWavePos / (0.5f * cosineLen)) + 3072]);
#endif
}
sample += resSample * resAmp * resAmpFade;
}
// sawtooth waves
if ((patchCache->waveform & 1) != 0) {
#if MT32EMU_ACCURATE_WG == 1
sample *= cosf(FLOAT_2PI * wavePos / waveLen);
#else
sample *= tables.sinf10[(Bit32u(4096.0f * wavePos / waveLen) & 4095) + 1024];
#endif
}
wavePos++;
// wavePos isn't supposed to be > waveLen
if (wavePos > waveLen) {
wavePos -= waveLen;
}
}
// Multiply sample with current TVA value
sample *= amp;
*partialBuf++ = sample;
}
unsigned long renderedSamples = sampleNum;
sampleNum = 0;
return renderedSamples;
}
float *Partial::mixBuffersRingMix(float *buf1, float *buf2, unsigned long len) {
if (buf1 == NULL) {
return NULL;
}
if (buf2 == NULL) {
return buf1;
}
while (len--) {
// FIXME: At this point we have no idea whether this is remotely correct...
*buf1 = *buf1 * *buf2 + *buf1;
buf1++;
buf2++;
}
return buf1;
}
float *Partial::mixBuffersRing(float *buf1, float *buf2, unsigned long len) {
if (buf1 == NULL) {
return NULL;
}
if (buf2 == NULL) {
return NULL;
}
while (len--) {
// FIXME: At this point we have no idea whether this is remotely correct...
*buf1 = *buf1 * *buf2;
buf1++;
buf2++;
}
return buf1;
}
bool Partial::hasRingModulatingSlave() const {
return pair != NULL && structurePosition == 0 && (mixType == 1 || mixType == 2);
}
bool Partial::isRingModulatingSlave() const {
return pair != NULL && structurePosition == 1 && (mixType == 1 || mixType == 2);
}
bool Partial::isPCM() const {
return pcmWave != NULL;
}
const ControlROMPCMStruct *Partial::getControlROMPCMStruct() const {
if (pcmWave != NULL) {
return pcmWave->controlROMPCMStruct;
}
return NULL;
}
Synth *Partial::getSynth() const {
return synth;
}
bool Partial::produceOutput(float *leftBuf, float *rightBuf, unsigned long length) {
if (!isActive() || alreadyOutputed || isRingModulatingSlave()) {
return false;
}
if (poly == NULL) {
synth->printDebug("[Partial %d] *** ERROR: poly is NULL at Partial::produceOutput()!", debugPartialNum);
return false;
}
float *partialBuf = &myBuffer[0];
unsigned long numGenerated = generateSamples(partialBuf, length);
if (mixType == 1 || mixType == 2) {
float *pairBuf;
unsigned long pairNumGenerated;
if (pair == NULL) {
pairBuf = NULL;
pairNumGenerated = 0;
} else {
pairBuf = &pair->myBuffer[0];
pairNumGenerated = pair->generateSamples(pairBuf, numGenerated);
// pair will have been set to NULL if it deactivated within generateSamples()
if (pair != NULL) {
if (!isActive()) {
pair->deactivate();
pair = NULL;
} else if (!pair->isActive()) {
pair = NULL;
}
}
}
if (pairNumGenerated > 0) {
if (mixType == 1) {
mixBuffersRingMix(partialBuf, pairBuf, pairNumGenerated);
} else {
mixBuffersRing(partialBuf, pairBuf, pairNumGenerated);
}
}
if (numGenerated > pairNumGenerated) {
if (mixType == 2) {
numGenerated = pairNumGenerated;
deactivate();
}
}
}
for (unsigned int i = 0; i < numGenerated; i++) {
*leftBuf++ = partialBuf[i] * stereoVolume.leftVol;
}
for (unsigned int i = 0; i < numGenerated; i++) {
*rightBuf++ = partialBuf[i] * stereoVolume.rightVol;
}
while (numGenerated < length) {
*leftBuf++ = 0.0f;
*rightBuf++ = 0.0f;
numGenerated++;
}
return true;
}
bool Partial::shouldReverb() {
if (!isActive()) {
return false;
}
return patchCache->reverb;
}
void Partial::startAbort() {
// This is called when the partial manager needs to terminate partials for re-use by a new Poly.
tva->startAbort();
}
void Partial::startDecayAll() {
tva->startDecay();
tvp->startDecay();
tvf->startDecay();
}
}