/* Copyright (C) 2003, 2004, 2005, 2006, 2008, 2009 Dean Beeler, Jerome Fisher
* Copyright (C) 2011-2016 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 "internals.h"
#include "LA32WaveGenerator.h"
#include "Tables.h"
#if MT32EMU_USE_FLOAT_SAMPLES
#define MT32EMU_LA32_WAVE_GENERATOR_CPP
#include "LA32FloatWaveGenerator.cpp"
#undef MT32EMU_LA32_WAVE_GENERATOR_CPP
#else
namespace MT32Emu {
static const Bit32u SINE_SEGMENT_RELATIVE_LENGTH = 1 << 18;
static const Bit32u MIDDLE_CUTOFF_VALUE = 128 << 18;
static const Bit32u RESONANCE_DECAY_THRESHOLD_CUTOFF_VALUE = 144 << 18;
static const Bit32u MAX_CUTOFF_VALUE = 240 << 18;
static const LogSample SILENCE = {65535, LogSample::POSITIVE};
Bit16u LA32Utilites::interpolateExp(const Bit16u fract) {
Bit16u expTabIndex = fract >> 3;
Bit16u extraBits = ~fract & 7;
Bit16u expTabEntry2 = 8191 - Tables::getInstance().exp9[expTabIndex];
Bit16u expTabEntry1 = expTabIndex == 0 ? 8191 : (8191 - Tables::getInstance().exp9[expTabIndex - 1]);
return expTabEntry2 + (((expTabEntry1 - expTabEntry2) * extraBits) >> 3);
}
Bit16s LA32Utilites::unlog(const LogSample &logSample) {
//Bit16s sample = (Bit16s)EXP2F(13.0f - logSample.logValue / 1024.0f);
Bit32u intLogValue = logSample.logValue >> 12;
Bit16u fracLogValue = logSample.logValue & 4095;
Bit16s sample = interpolateExp(fracLogValue) >> intLogValue;
return logSample.sign == LogSample::POSITIVE ? sample : -sample;
}
void LA32Utilites::addLogSamples(LogSample &logSample1, const LogSample &logSample2) {
Bit32u logSampleValue = logSample1.logValue + logSample2.logValue;
logSample1.logValue = logSampleValue < 65536 ? Bit16u(logSampleValue) : 65535;
logSample1.sign = logSample1.sign == logSample2.sign ? LogSample::POSITIVE : LogSample::NEGATIVE;
}
Bit32u LA32WaveGenerator::getSampleStep() {
// sampleStep = EXP2F(pitch / 4096.0f + 4.0f)
Bit32u sampleStep = LA32Utilites::interpolateExp(~pitch & 4095);
sampleStep <<= pitch >> 12;
sampleStep >>= 8;
sampleStep &= ~1;
return sampleStep;
}
Bit32u LA32WaveGenerator::getResonanceWaveLengthFactor(Bit32u effectiveCutoffValue) {
// resonanceWaveLengthFactor = (Bit32u)EXP2F(12.0f + effectiveCutoffValue / 4096.0f);
Bit32u resonanceWaveLengthFactor = LA32Utilites::interpolateExp(~effectiveCutoffValue & 4095);
resonanceWaveLengthFactor <<= effectiveCutoffValue >> 12;
return resonanceWaveLengthFactor;
}
Bit32u LA32WaveGenerator::getHighLinearLength(Bit32u effectiveCutoffValue) {
// Ratio of positive segment to wave length
Bit32u effectivePulseWidthValue = 0;
if (pulseWidth > 128) {
effectivePulseWidthValue = (pulseWidth - 128) << 6;
}
Bit32u highLinearLength = 0;
// highLinearLength = EXP2F(19.0f - effectivePulseWidthValue / 4096.0f + effectiveCutoffValue / 4096.0f) - 2 * SINE_SEGMENT_RELATIVE_LENGTH;
if (effectivePulseWidthValue < effectiveCutoffValue) {
Bit32u expArg = effectiveCutoffValue - effectivePulseWidthValue;
highLinearLength = LA32Utilites::interpolateExp(~expArg & 4095);
highLinearLength <<= 7 + (expArg >> 12);
highLinearLength -= 2 * SINE_SEGMENT_RELATIVE_LENGTH;
}
return highLinearLength;
}
void LA32WaveGenerator::computePositions(Bit32u highLinearLength, Bit32u lowLinearLength, Bit32u resonanceWaveLengthFactor) {
// Assuming 12-bit multiplication used here
squareWavePosition = resonanceSinePosition = (wavePosition >> 8) * (resonanceWaveLengthFactor >> 4);
if (squareWavePosition < SINE_SEGMENT_RELATIVE_LENGTH) {
phase = POSITIVE_RISING_SINE_SEGMENT;
return;
}
squareWavePosition -= SINE_SEGMENT_RELATIVE_LENGTH;
if (squareWavePosition < highLinearLength) {
phase = POSITIVE_LINEAR_SEGMENT;
return;
}
squareWavePosition -= highLinearLength;
if (squareWavePosition < SINE_SEGMENT_RELATIVE_LENGTH) {
phase = POSITIVE_FALLING_SINE_SEGMENT;
return;
}
squareWavePosition -= SINE_SEGMENT_RELATIVE_LENGTH;
resonanceSinePosition = squareWavePosition;
if (squareWavePosition < SINE_SEGMENT_RELATIVE_LENGTH) {
phase = NEGATIVE_FALLING_SINE_SEGMENT;
return;
}
squareWavePosition -= SINE_SEGMENT_RELATIVE_LENGTH;
if (squareWavePosition < lowLinearLength) {
phase = NEGATIVE_LINEAR_SEGMENT;
return;
}
squareWavePosition -= lowLinearLength;
phase = NEGATIVE_RISING_SINE_SEGMENT;
}
void LA32WaveGenerator::advancePosition() {
wavePosition += getSampleStep();
wavePosition %= 4 * SINE_SEGMENT_RELATIVE_LENGTH;
Bit32u effectiveCutoffValue = (cutoffVal > MIDDLE_CUTOFF_VALUE) ? (cutoffVal - MIDDLE_CUTOFF_VALUE) >> 10 : 0;
Bit32u resonanceWaveLengthFactor = getResonanceWaveLengthFactor(effectiveCutoffValue);
Bit32u highLinearLength = getHighLinearLength(effectiveCutoffValue);
Bit32u lowLinearLength = (resonanceWaveLengthFactor << 8) - 4 * SINE_SEGMENT_RELATIVE_LENGTH - highLinearLength;
computePositions(highLinearLength, lowLinearLength, resonanceWaveLengthFactor);
resonancePhase = ResonancePhase(((resonanceSinePosition >> 18) + (phase > POSITIVE_FALLING_SINE_SEGMENT ? 2 : 0)) & 3);
}
void LA32WaveGenerator::generateNextSquareWaveLogSample() {
Bit32u logSampleValue;
switch (phase) {
case POSITIVE_RISING_SINE_SEGMENT:
case NEGATIVE_FALLING_SINE_SEGMENT:
logSampleValue = Tables::getInstance().logsin9[(squareWavePosition >> 9) & 511];
break;
case POSITIVE_FALLING_SINE_SEGMENT:
case NEGATIVE_RISING_SINE_SEGMENT:
logSampleValue = Tables::getInstance().logsin9[~(squareWavePosition >> 9) & 511];
break;
case POSITIVE_LINEAR_SEGMENT:
case NEGATIVE_LINEAR_SEGMENT:
default:
logSampleValue = 0;
break;
}
logSampleValue <<= 2;
logSampleValue += amp >> 10;
if (cutoffVal < MIDDLE_CUTOFF_VALUE) {
logSampleValue += (MIDDLE_CUTOFF_VALUE - cutoffVal) >> 9;
}
squareLogSample.logValue = logSampleValue < 65536 ? Bit16u(logSampleValue) : 65535;
squareLogSample.sign = phase < NEGATIVE_FALLING_SINE_SEGMENT ? LogSample::POSITIVE : LogSample::NEGATIVE;
}
void LA32WaveGenerator::generateNextResonanceWaveLogSample() {
Bit32u logSampleValue;
if (resonancePhase == POSITIVE_FALLING_RESONANCE_SINE_SEGMENT || resonancePhase == NEGATIVE_RISING_RESONANCE_SINE_SEGMENT) {
logSampleValue = Tables::getInstance().logsin9[~(resonanceSinePosition >> 9) & 511];
} else {
logSampleValue = Tables::getInstance().logsin9[(resonanceSinePosition >> 9) & 511];
}
logSampleValue <<= 2;
logSampleValue += amp >> 10;
// From the digital captures, the decaying speed of the resonance sine is found a bit different for the positive and the negative segments
Bit32u decayFactor = phase < NEGATIVE_FALLING_SINE_SEGMENT ? resAmpDecayFactor : resAmpDecayFactor + 1;
// Unsure about resonanceSinePosition here. It's possible that dedicated counter & decrement are used. Although, cutoff is finely ramped, so maybe not.
logSampleValue += resonanceAmpSubtraction + (((resonanceSinePosition >> 4) * decayFactor) >> 8);
// To ensure the output wave has no breaks, two different windows are appied to the beginning and the ending of the resonance sine segment
if (phase == POSITIVE_RISING_SINE_SEGMENT || phase == NEGATIVE_FALLING_SINE_SEGMENT) {
// The window is synchronous sine here
logSampleValue += Tables::getInstance().logsin9[(squareWavePosition >> 9) & 511] << 2;
} else if (phase == POSITIVE_FALLING_SINE_SEGMENT || phase == NEGATIVE_RISING_SINE_SEGMENT) {
// The window is synchronous square sine here
logSampleValue += Tables::getInstance().logsin9[~(squareWavePosition >> 9) & 511] << 3;
}
if (cutoffVal < MIDDLE_CUTOFF_VALUE) {
// For the cutoff values below the cutoff middle point, it seems the amp of the resonance wave is expotentially decayed
logSampleValue += 31743 + ((MIDDLE_CUTOFF_VALUE - cutoffVal) >> 9);
} else if (cutoffVal < RESONANCE_DECAY_THRESHOLD_CUTOFF_VALUE) {
// For the cutoff values below this point, the amp of the resonance wave is sinusoidally decayed
Bit32u sineIx = (cutoffVal - MIDDLE_CUTOFF_VALUE) >> 13;
logSampleValue += Tables::getInstance().logsin9[sineIx] << 2;
}
// After all the amp decrements are added, it should be safe now to adjust the amp of the resonance wave to what we see on captures
logSampleValue -= 1 << 12;
resonanceLogSample.logValue = logSampleValue < 65536 ? Bit16u(logSampleValue) : 65535;
resonanceLogSample.sign = resonancePhase < NEGATIVE_FALLING_RESONANCE_SINE_SEGMENT ? LogSample::POSITIVE : LogSample::NEGATIVE;
}
void LA32WaveGenerator::generateNextSawtoothCosineLogSample(LogSample &logSample) const {
Bit32u sawtoothCosinePosition = wavePosition + (1 << 18);
if ((sawtoothCosinePosition & (1 << 18)) > 0) {
logSample.logValue = Tables::getInstance().logsin9[~(sawtoothCosinePosition >> 9) & 511];
} else {
logSample.logValue = Tables::getInstance().logsin9[(sawtoothCosinePosition >> 9) & 511];
}
logSample.logValue <<= 2;
logSample.sign = ((sawtoothCosinePosition & (1 << 19)) == 0) ? LogSample::POSITIVE : LogSample::NEGATIVE;
}
void LA32WaveGenerator::pcmSampleToLogSample(LogSample &logSample, const Bit16s pcmSample) const {
Bit32u logSampleValue = (32787 - (pcmSample & 32767)) << 1;
logSampleValue += amp >> 10;
logSample.logValue = logSampleValue < 65536 ? Bit16u(logSampleValue) : 65535;
logSample.sign = pcmSample < 0 ? LogSample::NEGATIVE : LogSample::POSITIVE;
}
void LA32WaveGenerator::generateNextPCMWaveLogSamples() {
// This should emulate the ladder we see in the PCM captures for pitches 01, 02, 07, etc.
// The most probable cause is the factor in the interpolation formula is one bit less
// accurate than the sample position counter
pcmInterpolationFactor = (wavePosition & 255) >> 1;
Bit32u pcmWaveTableIx = wavePosition >> 8;
pcmSampleToLogSample(firstPCMLogSample, pcmWaveAddress[pcmWaveTableIx]);
if (pcmWaveInterpolated) {
pcmWaveTableIx++;
if (pcmWaveTableIx < pcmWaveLength) {
pcmSampleToLogSample(secondPCMLogSample, pcmWaveAddress[pcmWaveTableIx]);
} else {
if (pcmWaveLooped) {
pcmWaveTableIx -= pcmWaveLength;
pcmSampleToLogSample(secondPCMLogSample, pcmWaveAddress[pcmWaveTableIx]);
} else {
secondPCMLogSample = SILENCE;
}
}
} else {
secondPCMLogSample = SILENCE;
}
// pcmSampleStep = (Bit32u)EXP2F(pitch / 4096.0f + 3.0f);
Bit32u pcmSampleStep = LA32Utilites::interpolateExp(~pitch & 4095);
pcmSampleStep <<= pitch >> 12;
// Seeing the actual lengths of the PCM wave for pitches 00..12,
// the pcmPosition counter can be assumed to have 8-bit fractions
pcmSampleStep >>= 9;
wavePosition += pcmSampleStep;
if (wavePosition >= (pcmWaveLength << 8)) {
if (pcmWaveLooped) {
wavePosition -= pcmWaveLength << 8;
} else {
deactivate();
}
}
}
void LA32WaveGenerator::initSynth(const bool useSawtoothWaveform, const Bit8u usePulseWidth, const Bit8u useResonance) {
sawtoothWaveform = useSawtoothWaveform;
pulseWidth = usePulseWidth;
resonance = useResonance;
wavePosition = 0;
squareWavePosition = 0;
phase = POSITIVE_RISING_SINE_SEGMENT;
resonanceSinePosition = 0;
resonancePhase = POSITIVE_RISING_RESONANCE_SINE_SEGMENT;
resonanceAmpSubtraction = (32 - resonance) << 10;
resAmpDecayFactor = Tables::getInstance().resAmpDecayFactor[resonance >> 2] << 2;
pcmWaveAddress = NULL;
active = true;
}
void LA32WaveGenerator::initPCM(const Bit16s * const usePCMWaveAddress, const Bit32u usePCMWaveLength, const bool usePCMWaveLooped, const bool usePCMWaveInterpolated) {
pcmWaveAddress = usePCMWaveAddress;
pcmWaveLength = usePCMWaveLength;
pcmWaveLooped = usePCMWaveLooped;
pcmWaveInterpolated = usePCMWaveInterpolated;
wavePosition = 0;
active = true;
}
void LA32WaveGenerator::generateNextSample(const Bit32u useAmp, const Bit16u usePitch, const Bit32u useCutoffVal) {
if (!active) {
return;
}
amp = useAmp;
pitch = usePitch;
if (isPCMWave()) {
generateNextPCMWaveLogSamples();
return;
}
// 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.
cutoffVal = (useCutoffVal > MAX_CUTOFF_VALUE) ? MAX_CUTOFF_VALUE : useCutoffVal;
generateNextSquareWaveLogSample();
generateNextResonanceWaveLogSample();
if (sawtoothWaveform) {
LogSample cosineLogSample;
generateNextSawtoothCosineLogSample(cosineLogSample);
LA32Utilites::addLogSamples(squareLogSample, cosineLogSample);
LA32Utilites::addLogSamples(resonanceLogSample, cosineLogSample);
}
advancePosition();
}
LogSample LA32WaveGenerator::getOutputLogSample(const bool first) const {
if (!isActive()) {
return SILENCE;
}
if (isPCMWave()) {
return first ? firstPCMLogSample : secondPCMLogSample;
}
return first ? squareLogSample : resonanceLogSample;
}
void LA32WaveGenerator::deactivate() {
active = false;
}
bool LA32WaveGenerator::isActive() const {
return active;
}
bool LA32WaveGenerator::isPCMWave() const {
return pcmWaveAddress != NULL;
}
Bit32u LA32WaveGenerator::getPCMInterpolationFactor() const {
return pcmInterpolationFactor;
}
void LA32PartialPair::init(const bool useRingModulated, const bool useMixed) {
ringModulated = useRingModulated;
mixed = useMixed;
}
void LA32PartialPair::initSynth(const PairType useMaster, const bool sawtoothWaveform, const Bit8u pulseWidth, const Bit8u resonance) {
if (useMaster == MASTER) {
master.initSynth(sawtoothWaveform, pulseWidth, resonance);
} else {
slave.initSynth(sawtoothWaveform, pulseWidth, resonance);
}
}
void LA32PartialPair::initPCM(const PairType useMaster, const Bit16s *pcmWaveAddress, const Bit32u pcmWaveLength, const bool pcmWaveLooped) {
if (useMaster == MASTER) {
master.initPCM(pcmWaveAddress, pcmWaveLength, pcmWaveLooped, true);
} else {
slave.initPCM(pcmWaveAddress, pcmWaveLength, pcmWaveLooped, !ringModulated);
}
}
void LA32PartialPair::generateNextSample(const PairType useMaster, const Bit32u amp, const Bit16u pitch, const Bit32u cutoff) {
if (useMaster == MASTER) {
master.generateNextSample(amp, pitch, cutoff);
} else {
slave.generateNextSample(amp, pitch, cutoff);
}
}
Bit16s LA32PartialPair::unlogAndMixWGOutput(const LA32WaveGenerator &wg) {
if (!wg.isActive()) {
return 0;
}
Bit16s firstSample = LA32Utilites::unlog(wg.getOutputLogSample(true));
Bit16s secondSample = LA32Utilites::unlog(wg.getOutputLogSample(false));
if (wg.isPCMWave()) {
return Bit16s(firstSample + (((Bit32s(secondSample) - Bit32s(firstSample)) * wg.getPCMInterpolationFactor()) >> 7));
}
return firstSample + secondSample;
}
Bit16s LA32PartialPair::nextOutSample() {
if (!ringModulated) {
return unlogAndMixWGOutput(master) + unlogAndMixWGOutput(slave);
}
/*
* SEMI-CONFIRMED: Ring modulation model derived from sample analysis of specially constructed patches which exploit distortion.
* LA32 ring modulator found to produce distorted output in case if the absolute value of maximal amplitude of one of the input partials exceeds 8191.
* This is easy to reproduce using synth partials with resonance values close to the maximum. It looks like an integer overflow happens in this case.
* As the distortion is strictly bound to the amplitude of the complete mixed square + resonance wave in the linear space,
* it is reasonable to assume the ring modulation is performed also in the linear space by sample multiplication.
* Most probably the overflow is caused by limited precision of the multiplication circuit as the very similar distortion occurs with panning.
*/
Bit16s nonOverdrivenMasterSample = unlogAndMixWGOutput(master); // Store master partial sample for further mixing
Bit16s masterSample = nonOverdrivenMasterSample << 2;
masterSample >>= 2;
/* SEMI-CONFIRMED from sample analysis:
* 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).
*/
Bit16s slaveSample = slave.isPCMWave() ? LA32Utilites::unlog(slave.getOutputLogSample(true)) : unlogAndMixWGOutput(slave);
slaveSample <<= 2;
slaveSample >>= 2;
Bit16s ringModulatedSample = Bit16s((Bit32s(masterSample) * Bit32s(slaveSample)) >> 13);
return mixed ? nonOverdrivenMasterSample + ringModulatedSample : ringModulatedSample;
}
void LA32PartialPair::deactivate(const PairType useMaster) {
if (useMaster == MASTER) {
master.deactivate();
} else {
slave.deactivate();
}
}
bool LA32PartialPair::isActive(const PairType useMaster) const {
return useMaster == MASTER ? master.isActive() : slave.isActive();
}
} // namespace MT32Emu
#endif // #if MT32EMU_USE_FLOAT_SAMPLES