Revert "PitchShift effect quality and performance tweaks for different pitch scale values"
This commit is contained in:
Rémi Verschelde
GitHub
parent
62765fb7ca
commit
dae0135ae5
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@ -74,7 +74,7 @@
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*
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*****************************************************************************/
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void SMBPitchShift::PitchShift(float pitchShift, int64_t numSampsToProcess, int64_t fftFrameSize, int64_t osamp, float sampleRate, float *indata, float *outdata,int stride) {
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void SMBPitchShift::PitchShift(float pitchShift, long numSampsToProcess, long fftFrameSize, long osamp, float sampleRate, float *indata, float *outdata,int stride) {
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/*
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@ -85,32 +85,19 @@ void SMBPitchShift::PitchShift(float pitchShift, int64_t numSampsToProcess, int6
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*/
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double magn, phase, tmp, window, real, imag;
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double freqPerBin, expct, reciprocalFftFrameSize;
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int64_t i,k, qpd, index, inFifoLatency, stepSize, fftFrameSize2;
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double freqPerBin, expct;
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long i,k, qpd, index, inFifoLatency, stepSize, fftFrameSize2;
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/* set up some handy variables */
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fftFrameSize2 = fftFrameSize/2;
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reciprocalFftFrameSize = 1./fftFrameSize;
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stepSize = fftFrameSize/osamp;
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freqPerBin = reciprocalFftFrameSize * sampleRate;
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expct = Math_TAU * reciprocalFftFrameSize * stepSize;
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freqPerBin = sampleRate/(double)fftFrameSize;
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expct = 2.*Math_PI*(double)stepSize/(double)fftFrameSize;
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inFifoLatency = fftFrameSize-stepSize;
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if (gRover == 0) {
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gRover = inFifoLatency;
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}
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if (gRover == 0) { gRover = inFifoLatency;
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}
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// If pitchShift changes clear arrays to prevent some artifacts and quality loss.
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if (lastPitchShift != pitchShift) {
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lastPitchShift = pitchShift;
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memset(gInFIFO, 0, MAX_FRAME_LENGTH * sizeof(float));
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memset(gOutFIFO, 0, MAX_FRAME_LENGTH * sizeof(float));
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memset(gFFTworksp, 0, 2 * MAX_FRAME_LENGTH * sizeof(double));
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memset(gLastPhase, 0, (MAX_FRAME_LENGTH / 2 + 1) * sizeof(double));
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memset(gSumPhase, 0, (MAX_FRAME_LENGTH / 2 + 1) * sizeof(double));
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memset(gOutputAccum, 0, 2 * MAX_FRAME_LENGTH * sizeof(double));
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memset(gAnaFreq, 0, MAX_FRAME_LENGTH * sizeof(double));
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memset(gAnaMagn, 0, MAX_FRAME_LENGTH * sizeof(double));
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}
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/* initialize our static arrays */
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/* main processing loop */
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for (i = 0; i < numSampsToProcess; i++){
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@ -125,7 +112,7 @@ void SMBPitchShift::PitchShift(float pitchShift, int64_t numSampsToProcess, int6
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/* do windowing and re,im interleave */
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for (k = 0; k < fftFrameSize;k++) {
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window = -.5*cos(Math_TAU * reciprocalFftFrameSize * k)+.5;
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window = -.5*cos(2.*Math_PI*(double)k/(double)fftFrameSize)+.5;
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gFFTworksp[2*k] = gInFIFO[k] * window;
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gFFTworksp[2*k+1] = 0.;
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}
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@ -137,7 +124,6 @@ void SMBPitchShift::PitchShift(float pitchShift, int64_t numSampsToProcess, int6
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/* this is the analysis step */
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for (k = 0; k <= fftFrameSize2; k++) {
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/* de-interlace FFT buffer */
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real = gFFTworksp[2*k];
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imag = gFFTworksp[2*k+1];
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@ -155,15 +141,13 @@ void SMBPitchShift::PitchShift(float pitchShift, int64_t numSampsToProcess, int6
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/* map delta phase into +/- Pi interval */
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qpd = tmp/Math_PI;
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if (qpd >= 0) {
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qpd += qpd&1;
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} else {
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qpd -= qpd&1;
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}
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if (qpd >= 0) { qpd += qpd&1;
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} else { qpd -= qpd&1;
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}
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tmp -= Math_PI*(double)qpd;
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/* get deviation from bin frequency from the +/- Pi interval */
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tmp = osamp*tmp/Math_TAU;
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tmp = osamp*tmp/(2.*Math_PI);
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/* compute the k-th partials' true frequency */
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tmp = (double)k*freqPerBin + tmp*freqPerBin;
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@ -176,8 +160,8 @@ void SMBPitchShift::PitchShift(float pitchShift, int64_t numSampsToProcess, int6
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/* ***************** PROCESSING ******************* */
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/* this does the actual pitch shifting */
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memset(gSynMagn, 0, fftFrameSize*sizeof(double));
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memset(gSynFreq, 0, fftFrameSize*sizeof(double));
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memset(gSynMagn, 0, fftFrameSize*sizeof(float));
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memset(gSynFreq, 0, fftFrameSize*sizeof(float));
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for (k = 0; k <= fftFrameSize2; k++) {
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index = k*pitchShift;
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if (index <= fftFrameSize2) {
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@ -200,7 +184,7 @@ void SMBPitchShift::PitchShift(float pitchShift, int64_t numSampsToProcess, int6
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tmp /= freqPerBin;
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/* take osamp into account */
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tmp = Math_TAU*tmp/osamp;
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tmp = 2.*Math_PI*tmp/osamp;
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/* add the overlap phase advance back in */
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tmp += (double)k*expct;
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@ -215,35 +199,33 @@ void SMBPitchShift::PitchShift(float pitchShift, int64_t numSampsToProcess, int6
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}
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/* zero negative frequencies */
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for (k = fftFrameSize+2; k < 2*MAX_FRAME_LENGTH; k++) {
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gFFTworksp[k] = 0.;
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}
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for (k = fftFrameSize+2; k < 2*fftFrameSize; k++) { gFFTworksp[k] = 0.;
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}
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/* do inverse transform */
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smbFft(gFFTworksp, fftFrameSize, 1);
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/* do windowing and add to output accumulator */
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for(k=0; k < fftFrameSize; k++) {
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window = -.5*cos(Math_TAU * reciprocalFftFrameSize * k)+.5;
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window = -.5*cos(2.*Math_PI*(double)k/(double)fftFrameSize)+.5;
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gOutputAccum[k] += 2.*window*gFFTworksp[2*k]/(fftFrameSize2*osamp);
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}
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for (k = 0; k < stepSize; k++) {
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gOutFIFO[k] = gOutputAccum[k];
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}
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for (k = 0; k < stepSize; k++) { gOutFIFO[k] = gOutputAccum[k];
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}
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/* shift accumulator */
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memmove(gOutputAccum, gOutputAccum+stepSize, fftFrameSize*sizeof(double));
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memmove(gOutputAccum, gOutputAccum+stepSize, fftFrameSize*sizeof(float));
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/* move input FIFO */
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for (k = 0; k < inFifoLatency; k++) {
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gInFIFO[k] = gInFIFO[k+stepSize];
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}
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for (k = 0; k < inFifoLatency; k++) { gInFIFO[k] = gInFIFO[k+stepSize];
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}
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}
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}
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}
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void SMBPitchShift::smbFft(double *fftBuffer, int64_t fftFrameSize, int64_t sign)
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void SMBPitchShift::smbFft(float *fftBuffer, long fftFrameSize, long sign)
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/*
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FFT routine, (C)1996 S.M.Bernsee. Sign = -1 is FFT, 1 is iFFT (inverse)
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Fills fftBuffer[0...2*fftFrameSize-1] with the Fourier transform of the
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@ -256,16 +238,14 @@ void SMBPitchShift::smbFft(double *fftBuffer, int64_t fftFrameSize, int64_t sign
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of the frequencies of interest is in fftBuffer[0...fftFrameSize].
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*/
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{
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double wr, wi, arg, *p1, *p2, temp;
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double tr, ti, ur, ui, *p1r, *p1i, *p2r, *p2i;
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int64_t i, bitm, j, le, le2, k, logN;
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logN = (int64_t)(log(fftFrameSize) / log(2.) + .5);
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float wr, wi, arg, *p1, *p2, temp;
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float tr, ti, ur, ui, *p1r, *p1i, *p2r, *p2i;
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long i, bitm, j, le, le2, k;
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for (i = 2; i < 2*fftFrameSize-2; i += 2) {
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for (bitm = 2, j = 0; bitm < 2*fftFrameSize; bitm <<= 1) {
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if (i & bitm) {
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j++;
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}
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if (i & bitm) { j++;
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}
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j <<= 1;
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}
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if (i < j) {
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@ -275,8 +255,7 @@ void SMBPitchShift::smbFft(double *fftBuffer, int64_t fftFrameSize, int64_t sign
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*p1 = *p2; *p2 = temp;
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}
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}
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for (k = 0, le = 2; k < logN; k++) {
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for (k = 0, le = 2; k < (long)(log((double)fftFrameSize)/log(2.)+.5); k++) {
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le <<= 1;
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le2 = le>>1;
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ur = 1.0;
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@ -309,14 +288,6 @@ void SMBPitchShift::smbFft(double *fftBuffer, int64_t fftFrameSize, int64_t sign
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void AudioEffectPitchShiftInstance::process(const AudioFrame *p_src_frames, AudioFrame *p_dst_frames, int p_frame_count) {
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float sample_rate = AudioServer::get_singleton()->get_mix_rate();
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// For pitch_scale 1.0 it's cheaper to just pass samples without processing them.
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if (Math::is_equal_approx(base->pitch_scale, 1.0f)) {
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for (int i = 0; i < p_frame_count; i++) {
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p_dst_frames[i] = p_src_frames[i];
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}
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return;
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}
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float *in_l = (float *)p_src_frames;
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float *in_r = in_l + 1;
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@ -390,4 +361,7 @@ AudioEffectPitchShift::AudioEffectPitchShift() {
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pitch_scale = 1.0;
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oversampling = 4;
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fft_size = FFT_SIZE_2048;
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wet = 0.0;
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dry = 0.0;
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filter = false;
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}
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@ -40,33 +40,31 @@ class SMBPitchShift {
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float gInFIFO[MAX_FRAME_LENGTH];
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float gOutFIFO[MAX_FRAME_LENGTH];
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double gFFTworksp[2 * MAX_FRAME_LENGTH];
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double gLastPhase[MAX_FRAME_LENGTH / 2 + 1];
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double gSumPhase[MAX_FRAME_LENGTH / 2 + 1];
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double gOutputAccum[2 * MAX_FRAME_LENGTH];
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double gAnaFreq[MAX_FRAME_LENGTH];
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double gAnaMagn[MAX_FRAME_LENGTH];
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double gSynFreq[MAX_FRAME_LENGTH];
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double gSynMagn[MAX_FRAME_LENGTH];
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int64_t gRover;
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float lastPitchShift;
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float gFFTworksp[2 * MAX_FRAME_LENGTH];
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float gLastPhase[MAX_FRAME_LENGTH / 2 + 1];
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float gSumPhase[MAX_FRAME_LENGTH / 2 + 1];
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float gOutputAccum[2 * MAX_FRAME_LENGTH];
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float gAnaFreq[MAX_FRAME_LENGTH];
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float gAnaMagn[MAX_FRAME_LENGTH];
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float gSynFreq[MAX_FRAME_LENGTH];
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float gSynMagn[MAX_FRAME_LENGTH];
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long gRover;
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void smbFft(double *fftBuffer, int64_t fftFrameSize, int64_t sign);
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void smbFft(float *fftBuffer, long fftFrameSize, long sign);
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public:
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void PitchShift(float pitchShift, int64_t numSampsToProcess, int64_t fftFrameSize, int64_t osamp, float sampleRate, float *indata, float *outdata, int stride);
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void PitchShift(float pitchShift, long numSampsToProcess, long fftFrameSize, long osamp, float sampleRate, float *indata, float *outdata, int stride);
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SMBPitchShift() {
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gRover = 0;
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memset(gInFIFO, 0, MAX_FRAME_LENGTH * sizeof(float));
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memset(gOutFIFO, 0, MAX_FRAME_LENGTH * sizeof(float));
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memset(gFFTworksp, 0, 2 * MAX_FRAME_LENGTH * sizeof(double));
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memset(gLastPhase, 0, (MAX_FRAME_LENGTH / 2 + 1) * sizeof(double));
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memset(gSumPhase, 0, (MAX_FRAME_LENGTH / 2 + 1) * sizeof(double));
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memset(gOutputAccum, 0, 2 * MAX_FRAME_LENGTH * sizeof(double));
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memset(gAnaFreq, 0, MAX_FRAME_LENGTH * sizeof(double));
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memset(gAnaMagn, 0, MAX_FRAME_LENGTH * sizeof(double));
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lastPitchShift = 1.0;
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memset(gFFTworksp, 0, 2 * MAX_FRAME_LENGTH * sizeof(float));
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memset(gLastPhase, 0, (MAX_FRAME_LENGTH / 2 + 1) * sizeof(float));
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memset(gSumPhase, 0, (MAX_FRAME_LENGTH / 2 + 1) * sizeof(float));
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memset(gOutputAccum, 0, 2 * MAX_FRAME_LENGTH * sizeof(float));
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memset(gAnaFreq, 0, MAX_FRAME_LENGTH * sizeof(float));
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memset(gAnaMagn, 0, MAX_FRAME_LENGTH * sizeof(float));
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}
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};
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@ -103,6 +101,9 @@ public:
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float pitch_scale;
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int oversampling;
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FFTSize fft_size;
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float wet;
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float dry;
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bool filter;
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protected:
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static void _bind_methods();
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