ref: 986c04cc23d6310d5da15e8f5767232a4571abde
dir: /src/effects/timestretch_rubberband.c/
/* Copyright (C) 2016 Paul Brossier <piem@aubio.org> This file is part of aubio. aubio is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. aubio 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 General Public License for more details. You should have received a copy of the GNU General Public License along with aubio. If not, see <http://www.gnu.org/licenses/>. */ #include "aubio_priv.h" #ifdef HAVE_RUBBERBAND #include "fvec.h" #include "fmat.h" #include "io/source.h" #include "effects/timestretch.h" #include <rubberband/rubberband-c.h> #define MIN_STRETCH_RATIO 0.025 #define MAX_STRETCH_RATIO 40. #define HAVE_THREADS 1 #if 0 #undef HAVE_THREADS #endif #ifdef HAVE_THREADS #include <pthread.h> #endif /** generic time stretching structure */ struct _aubio_timestretch_t { uint_t samplerate; /**< samplerate */ uint_t hopsize; /**< hop size */ smpl_t stretchratio; /**< time ratio */ smpl_t pitchscale; /**< pitch scale */ RubberBandState rb; RubberBandOptions rboptions; }; extern RubberBandOptions aubio_get_rubberband_opts(const char_t *mode); static void aubio_timestretch_warmup (aubio_timestretch_t * p); aubio_timestretch_t * new_aubio_timestretch (const char_t * mode, smpl_t stretchratio, uint_t hopsize, uint_t samplerate) { aubio_timestretch_t *p = AUBIO_NEW (aubio_timestretch_t); p->hopsize = hopsize; p->pitchscale = 1.; if (stretchratio <= MAX_STRETCH_RATIO && stretchratio >= MIN_STRETCH_RATIO) { p->stretchratio = stretchratio; } else { AUBIO_ERR("timestretch: stretchratio should be in the range [%.3f, %.3f], got %f\n", MIN_STRETCH_RATIO, MAX_STRETCH_RATIO, stretchratio); goto beach; } p->rboptions = aubio_get_rubberband_opts(mode); if (p->rboptions < 0) { AUBIO_ERR("timestretch: unknown time stretching method %s\n", mode); goto beach; } p->rb = rubberband_new(samplerate, 1, p->rboptions, p->stretchratio, p->pitchscale); if (!p->rb) goto beach; p->samplerate = samplerate; //aubio_timestretch_warmup(p); return p; beach: del_aubio_timestretch(p); return NULL; } static void aubio_timestretch_warmup (aubio_timestretch_t * p) { // warm up rubber band //AUBIO_WRN("timestretch: warming-up\n"); unsigned int latency = MAX(p->hopsize, rubberband_get_latency(p->rb)); fvec_t *input = new_fvec(p->hopsize); while (aubio_timestretch_push(p, input, input->length) < (int)latency) { //sint_t available = aubio_timestretch_get_available(p); //AUBIO_WRN("timestretch: warmup got %d, latency: %d\n", available, latency); } del_fvec(input); } void del_aubio_timestretch (aubio_timestretch_t * p) { if (p->rb) { rubberband_delete(p->rb); } AUBIO_FREE (p); } uint_t aubio_timestretch_get_samplerate (aubio_timestretch_t * p) { return p->samplerate; } uint_t aubio_timestretch_get_latency (aubio_timestretch_t * p) { return rubberband_get_latency(p->rb); } uint_t aubio_timestretch_set_stretch (aubio_timestretch_t * p, smpl_t stretch) { if (!p->rb) { AUBIO_WRN("timestretch: could not set stretch ratio, rubberband not created\n"); return AUBIO_FAIL; } if (stretch >= MIN_STRETCH_RATIO && stretch <= MAX_STRETCH_RATIO) { p->stretchratio = stretch; rubberband_set_time_ratio(p->rb, 1./p->stretchratio); return AUBIO_OK; } else { AUBIO_WRN("timestretch: could not set stretch ratio to %.2f\n", stretch); return AUBIO_FAIL; } } smpl_t aubio_timestretch_get_stretch (aubio_timestretch_t * p) { return p->stretchratio; } uint_t aubio_timestretch_set_pitchscale (aubio_timestretch_t * p, smpl_t pitchscale) { if (!p->rb) { AUBIO_WRN("timestretch: could not set pitch scale, rubberband not created\n"); return AUBIO_FAIL; } if (pitchscale >= 0.0625 && pitchscale <= 4.) { p->pitchscale = pitchscale; rubberband_set_pitch_scale(p->rb, p->pitchscale); return AUBIO_OK; } else { AUBIO_WRN("timestretch: could not set pitchscale to %.2f\n", pitchscale); return AUBIO_FAIL; } } smpl_t aubio_timestretch_get_pitchscale (aubio_timestretch_t * p) { return p->pitchscale; } uint_t aubio_timestretch_set_transpose(aubio_timestretch_t * p, smpl_t transpose) { if (transpose >= -24. && transpose <= 24.) { smpl_t pitchscale = POW(2., transpose / 12.); return aubio_timestretch_set_pitchscale(p, pitchscale); } else { AUBIO_WRN("timestretch: could not set transpose to %.2f\n", transpose); return AUBIO_FAIL; } } smpl_t aubio_timestretch_get_transpose(aubio_timestretch_t * p) { return 12. * LOG(p->pitchscale) / LOG(2.0); } sint_t aubio_timestretch_push(aubio_timestretch_t *p, fvec_t *input, uint_t length) { // push new samples to rubberband, return available int available; int eof = (input->length != length) ? 1 : 0; rubberband_process(p->rb, (const float* const*)&(input->data), length, eof); available = rubberband_available(p->rb); //AUBIO_WRN("timestretch: processed %d, %d available, eof: %d\n", // length, available, eof); return available; } sint_t aubio_timestretch_get_available(aubio_timestretch_t *p) { return rubberband_available(p->rb); } void aubio_timestretch_do(aubio_timestretch_t * p, fvec_t * out, uint_t * read) { // now retrieve the samples and write them into out->data int available = rubberband_available(p->rb); if (available >= (int)out->length) { rubberband_retrieve(p->rb, (float* const*)&(out->data), out->length); *read = out->length; } else if (available > 0) { // this occurs each time the end of file is reached //AUBIO_WRN("timestretch: short read\n"); rubberband_retrieve(p->rb, (float* const*)&(out->data), available); fvec_t zeros; zeros.length = out->length - available; zeros.data = out->data + available; fvec_zeros(&zeros); *read = available; } else { // this may occur if the previous was a short read available == hopsize fvec_zeros(out); *read = 0; } } uint_t aubio_timestretch_reset(aubio_timestretch_t *p) { uint_t err = AUBIO_OK; if (p->rb) { rubberband_reset(p->rb); } return err; } #endif