ref: 6f50522ff66bbebd9d899f71b6da71288c0a8d0d
dir: /modules/paulstretch.c/
/*
* PaulStretch
*
* An implementation of the PaulStretch algorithm by Paul Nasca Octavian.
* This code is based off the Python Numpy/Scipy implementation of
* PaulStretch, found here: https://github.com/paulnasca/paulstretch_python
*
* This implementation has been placed in the public domain.
*/
#include <stdlib.h>
#include <string.h>
#include <math.h>
#include "soundpipe.h"
#include "kiss_fftr.h"
#ifndef M_PI
#define M_PI 3.14159265358979323846
#endif
static void compute_block(sp_data *sp, sp_paulstretch *p) {
uint32_t istart_pos = floor(p->start_pos);
uint32_t pos;
uint32_t i;
uint32_t windowsize = p->windowsize;
uint32_t half_windowsize = p->half_windowsize;
SPFLOAT *buf = p->buf;
SPFLOAT *hinv_buf = p->hinv_buf;
SPFLOAT *old_windowed_buf= p->old_windowed_buf;
SPFLOAT *tbl = p->ft->tbl;
SPFLOAT *window = p->window;
SPFLOAT *output= p->output;
for (i = 0; i < windowsize; i++) {
/* Loop through buffer */
pos = (istart_pos + i);
if (p->wrap) {
pos %= p->ft->size;
}
if (pos < p->ft->size) {
buf[i] = tbl[pos] * window[i];
} else {
buf[i] = 0;
}
}
kiss_fftr(p->fft, buf, p->tmp1);
for (i = 0; i < windowsize / 2; i++) {
SPFLOAT mag = sqrt(p->tmp1[i].r*p->tmp1[i].r + p->tmp1[i].i*p->tmp1[i].i);
SPFLOAT ph = ((SPFLOAT)sp_rand(sp) / SP_RANDMAX) * 2 * M_PI;
p->tmp1[i].r = mag * cos(ph);
p->tmp1[i].i = mag * sin(ph);
}
kiss_fftri(p->ifft, p->tmp1, buf);
for (i = 0; i < windowsize; i++) {
buf[i] *= window[i];
if (i < half_windowsize) {
output[i] = (SPFLOAT)(buf[i] + old_windowed_buf[half_windowsize + i]) / windowsize;
output[i] *= hinv_buf[i];
}
old_windowed_buf[i] = buf[i];
}
p->start_pos += p->displace_pos;
}
int sp_paulstretch_create(sp_paulstretch **p)
{
*p = malloc(sizeof(sp_paulstretch));
return SP_OK;
}
int sp_paulstretch_destroy(sp_paulstretch **p)
{
sp_paulstretch *pp = *p;
free(pp->window);
free(pp->old_windowed_buf);
free(pp->hinv_buf);
free(pp->buf);
free(pp->output);
kiss_fftr_free(pp->fft);
kiss_fftr_free(pp->ifft);
KISS_FFT_FREE(pp->tmp1);
free(*p);
return SP_OK;
}
int sp_paulstretch_init(sp_data *sp, sp_paulstretch *p, sp_ftbl *ft, SPFLOAT windowsize, SPFLOAT stretch)
{
uint32_t i;
SPFLOAT hinv_sqrt2;
kiss_fft_cpx *tmp1;
p->ft = ft;
p->windowsize = (uint32_t)(sp->sr * windowsize);
p->stretch = stretch;
if (p->windowsize < 16) p->windowsize = 16;
p->half_windowsize = p->windowsize / 2;
p->displace_pos = (p->windowsize * 0.5) / p->stretch;
p->window = calloc(1, sizeof(SPFLOAT) * p->windowsize);
p->old_windowed_buf = calloc(1, sizeof(SPFLOAT) * p->windowsize);
p->hinv_buf = calloc(1, sizeof(SPFLOAT) * p->half_windowsize);
p->buf = calloc(1, sizeof(SPFLOAT) * p->windowsize);
p->output = calloc(1, sizeof(SPFLOAT) * p->half_windowsize);
/* Create Hann window */
for (i = 0; i < p->windowsize; i++) {
p->window[i] = 0.5 - cos(i * 2.0 * M_PI / (p->windowsize - 1)) * 0.5;
}
/* creatve inverse hann window */
hinv_sqrt2 = (1 + sqrt(0.5)) * 0.5;
for (i = 0; i < p->half_windowsize; i++) {
p->hinv_buf[i] = hinv_sqrt2 - (1.0 - hinv_sqrt2) * cos(i * 2.0 * M_PI / p->half_windowsize);
}
p->start_pos = 0.0;
p->counter = 0;
/* set up kissfft */
p->fft = kiss_fftr_alloc(p->windowsize, 0, NULL, NULL);
p->ifft = kiss_fftr_alloc(p->windowsize, 1, NULL, NULL);
tmp1 = malloc(sizeof(kiss_fft_cpx) * p->windowsize);
memset(tmp1, 0, sizeof(SPFLOAT) * p->windowsize);
p->tmp1 = tmp1;
/* turn on wrap mode by default */
p->wrap = 1;
return SP_OK;
}
int sp_paulstretch_compute(sp_data *sp, sp_paulstretch *p, SPFLOAT *in, SPFLOAT *out)
{
if (p->counter == 0) compute_block(sp, p);
*out = p->output[p->counter];
p->counter = (p->counter + 1) % p->half_windowsize;
return SP_OK;
}