ref: b1c948bece6ebed49f1906e2542edd8e7f05cea0
dir: /src/pitchfcomb.c/
/* Copyright (C) 2004, 2005 Mario Lang <mlang@delysid.org> This program 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 2 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 General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. */ #include "aubio_priv.h" #include "sample.h" #include "mathutils.h" #include "fft.h" #include "pitchfcomb.h" #define MAX_PEAKS 8 typedef struct { smpl_t freq; smpl_t db; } aubio_fpeak_t; struct _aubio_pitchfcomb_t { uint_t fftSize; uint_t stepSize; uint_t rate; fvec_t * winput; fvec_t * win; cvec_t * fftOut; fvec_t * fftLastPhase; aubio_mfft_t * fft; //aubio_pvoc_t * pvoc; }; aubio_pitchfcomb_t * new_aubio_pitchfcomb (uint_t bufsize, uint_t hopsize, uint_t samplerate) { aubio_pitchfcomb_t * p = AUBIO_NEW(aubio_pitchfcomb_t); p->rate = samplerate; p->fftSize = bufsize; p->stepSize = hopsize; p->winput = new_fvec(bufsize,1); p->fftOut = new_cvec(bufsize,1); p->fftLastPhase = new_fvec(bufsize,1); p->fft = new_aubio_mfft(bufsize, 1); p->win = new_fvec(bufsize,1); aubio_window(p->win->data[0], bufsize, aubio_win_hanning); return p; } /* input must be stepsize long */ smpl_t aubio_pitchfcomb_detect (aubio_pitchfcomb_t * p, fvec_t * input) { uint_t k, l, maxharm = 0; smpl_t freqPerBin = p->rate/(smpl_t)p->fftSize, phaseDifference = TWO_PI*(smpl_t)p->stepSize/(smpl_t)p->fftSize; aubio_fpeak_t peaks[MAX_PEAKS]; for (k=0; k<MAX_PEAKS; k++) { peaks[k].db = -200.; peaks[k].freq = 0.; } for (k=0; k < input->length; k++){ p->winput->data[0][k] = p->win->data[0][k] * input->data[0][k]; } aubio_mfft_do(p->fft,p->winput,p->fftOut); for (k=0; k<=p->fftSize/2; k++) { smpl_t magnitude = 20.*LOG10(2.*p->fftOut->norm[0][k]/(smpl_t)p->fftSize), phase = p->fftOut->phas[0][k], tmp, freq; /* compute phase difference */ tmp = phase - p->fftLastPhase->data[0][k]; p->fftLastPhase->data[0][k] = phase; /* subtract expected phase difference */ tmp -= (smpl_t)k*phaseDifference; /* map delta phase into +/- Pi interval */ tmp = aubio_unwrap2pi(tmp); /* get deviation from bin frequency from the +/- Pi interval */ tmp = p->fftSize/(smpl_t)p->stepSize*tmp/(TWO_PI); /* compute the k-th partials' true frequency */ freq = (smpl_t)k*freqPerBin + tmp*freqPerBin; if (freq > 0.0 && magnitude > peaks[0].db) { // && magnitude < 0) { memmove(peaks+1, peaks, sizeof(aubio_fpeak_t)*(MAX_PEAKS-1)); peaks[0].freq = freq; peaks[0].db = magnitude; } } k = 0; for (l=1; l<MAX_PEAKS && peaks[l].freq > 0.0; l++) { sint_t harmonic; for (harmonic=5; harmonic>1; harmonic--) { if (peaks[0].freq / peaks[l].freq < harmonic+.02 && peaks[0].freq / peaks[l].freq > harmonic-.02) { if (harmonic > (sint_t)maxharm && peaks[0].db < peaks[l].db/2) { maxharm = harmonic; k = l; } } } } /* quick hack to clean output a bit */ if (peaks[k].freq > 5000.) return 0.; return peaks[k].freq; } void del_aubio_pitchfcomb (aubio_pitchfcomb_t * p) { del_cvec(p->fftOut); del_fvec(p->fftLastPhase); del_fvec(p->win); del_fvec(p->winput); del_aubio_mfft(p->fft); AUBIO_FREE(p); }