ref: cf31ff1ab7505063cf41b960c3cd56d602839082
dir: /src/pitch/pitchmcomb.c/
/* Copyright (C) 2003-2009 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" #include "fvec.h" #include "cvec.h" #include "mathutils.h" #include "pitch/pitchmcomb.h" #define CAND_SWAP(a,b) { register aubio_spectralcandidate_t *t=(a);(a)=(b);(b)=t; } typedef struct _aubio_spectralpeak_t aubio_spectralpeak_t; typedef struct _aubio_spectralcandidate_t aubio_spectralcandidate_t; uint_t aubio_pitchmcomb_get_root_peak (aubio_spectralpeak_t * peaks, uint_t length); uint_t aubio_pitchmcomb_quadpick (aubio_spectralpeak_t * spectral_peaks, const fvec_t * X); void aubio_pitchmcomb_spectral_pp (aubio_pitchmcomb_t * p, const fvec_t * oldmag); void aubio_pitchmcomb_combdet (aubio_pitchmcomb_t * p, const fvec_t * newmag); /* not used but useful : sort by amplitudes (or anything else) * sort_pitchpeak(peaks, length); */ #if 0 /** spectral_peak comparison function (must return signed int) */ static sint_t aubio_pitchmcomb_sort_peak_comp (const void *x, const void *y); /** sort spectral_peak against their mag */ void aubio_pitchmcomb_sort_peak (aubio_spectralpeak_t * peaks, uint_t nbins); /** select the best candidates */ uint_t aubio_pitch_cands (aubio_pitchmcomb_t * p, const cvec_t * fftgrain, smpl_t * cands); #endif /** sort spectral_candidate against their comb ene */ void aubio_pitchmcomb_sort_cand_ene (aubio_spectralcandidate_t ** candidates, uint_t nbins); #if 0 /** sort spectral_candidate against their frequency */ void aubio_pitchmcomb_sort_cand_freq (aubio_spectralcandidate_t ** candidates, uint_t nbins); #endif struct _aubio_pitchmcomb_t { smpl_t threshold; /**< offset threshold [0.033 or 0.01] */ smpl_t alpha; /**< normalisation exponent [9] */ smpl_t cutoff; /**< low-pass filter cutoff [0.34, 1] */ smpl_t tol; /**< tolerance [0.05] */ // smpl_t tau; /**< frequency precision [44100/4096] */ uint_t win_post; /**< median filter window length */ uint_t win_pre; /**< median filter window */ uint_t ncand; /**< maximum number of candidates (combs) */ uint_t npartials; /**< maximum number of partials per combs */ uint_t count; /**< picked picks */ uint_t goodcandidate; /**< best candidate */ uint_t spec_partition; /**< spectrum partition to consider */ aubio_spectralpeak_t *peaks; /**< up to length win/spec_partition */ aubio_spectralcandidate_t **candidates; /** up to five candidates */ /* some scratch pads */ /** \bug (unnecessary copied from fftgrain?) */ fvec_t *newmag; /**< vec to store mag */ fvec_t *scratch; /**< vec to store modified mag */ fvec_t *scratch2; /**< vec to compute moving median */ fvec_t *theta; /**< vec to store phase */ smpl_t phasediff; smpl_t phasefreq; /** threshfn: name or handle of fn for computing adaptive threshold [median] */ /** aubio_thresholdfn_t thresholdfn; */ /** picker: name or handle of fn for picking event times [quadpick] */ /** aubio_pickerfn_t pickerfn; */ }; /** spectral peak object */ struct _aubio_spectralpeak_t { uint_t bin; /**< bin [0-(length-1)] */ smpl_t ebin; /**< estimated bin */ smpl_t mag; /**< peak magnitude */ }; /** spectral candidates array object */ struct _aubio_spectralcandidate_t { smpl_t ebin; /**< interpolated bin */ smpl_t *ecomb; /**< comb */ smpl_t ene; /**< candidate energy */ smpl_t len; /**< length */ }; void aubio_pitchmcomb_do (aubio_pitchmcomb_t * p, const cvec_t * fftgrain, fvec_t * output) { uint_t j; smpl_t instfreq; fvec_t *newmag = (fvec_t *) p->newmag; //smpl_t hfc; //fe=instfreq(theta1,theta,ops); //theta1=theta; /* copy incoming grain to newmag */ for (j = 0; j < newmag->length; j++) newmag->data[j] = fftgrain->norm[j]; /* detect only if local energy > 10. */ //if (aubio_level_lin (newmag) * newmag->length > 10.) { //hfc = fvec_local_hfc(newmag); //not used aubio_pitchmcomb_spectral_pp (p, newmag); aubio_pitchmcomb_combdet (p, newmag); //aubio_pitchmcomb_sort_cand_freq(p->candidates,p->ncand); //return p->candidates[p->goodcandidate]->ebin; j = (uint_t) FLOOR (p->candidates[p->goodcandidate]->ebin + .5); instfreq = aubio_unwrap2pi (fftgrain->phas[j] - p->theta->data[j] - j * p->phasediff); instfreq *= p->phasefreq; /* store phase for next run */ for (j = 0; j < p->theta->length; j++) { p->theta->data[j] = fftgrain->phas[j]; } //return p->candidates[p->goodcandidate]->ebin; output->data[0] = FLOOR (p->candidates[p->goodcandidate]->ebin + .5) + instfreq; /*} else { return -1.; } */ } #if 0 uint_t aubio_pitch_cands (aubio_pitchmcomb_t * p, const cvec_t * fftgrain, smpl_t * cands) { uint_t j; uint_t k; fvec_t *newmag = (fvec_t *) p->newmag; aubio_spectralcandidate_t **scands = (aubio_spectralcandidate_t **) (p->candidates); //smpl_t hfc; //fe=instfreq(theta1,theta,ops); //theta1=theta; /* copy incoming grain to newmag */ for (j = 0; j < newmag->length; j++) newmag->data[j] = fftgrain->norm[j]; /* detect only if local energy > 10. */ if (aubio_level_lin (newmag) * newmag->length > 10.) { /* hfc = fvec_local_hfc(newmag); do not use */ aubio_pitchmcomb_spectral_pp (p, newmag); aubio_pitchmcomb_combdet (p, newmag); aubio_pitchmcomb_sort_cand_freq (scands, p->ncand); /* store ncand comb energies in cands[1:ncand] */ for (k = 0; k < p->ncand; k++) cands[k] = p->candidates[k]->ene; /* store ncand[end] freq in cands[end] */ cands[p->ncand] = p->candidates[p->ncand - 1]->ebin; return 1; } else { for (k = 0; k < p->ncand; k++) cands[k] = 0; return 0; } } #endif void aubio_pitchmcomb_spectral_pp (aubio_pitchmcomb_t * p, const fvec_t * newmag) { fvec_t *mag = (fvec_t *) p->scratch; fvec_t *tmp = (fvec_t *) p->scratch2; uint_t j; uint_t length = mag->length; /* copy newmag to mag (scracth) */ for (j = 0; j < length; j++) { mag->data[j] = newmag->data[j]; } fvec_min_removal (mag); /* min removal */ fvec_alpha_normalise (mag, p->alpha); /* alpha normalisation */ /* skipped *//* low pass filtering */ /** \bug fvec_moving_thres may write out of bounds */ fvec_adapt_thres (mag, tmp, p->win_post, p->win_pre); /* adaptative threshold */ fvec_add (mag, -p->threshold); /* fixed threshold */ { aubio_spectralpeak_t *peaks = (aubio_spectralpeak_t *) p->peaks; uint_t count; /* return bin and ebin */ count = aubio_pitchmcomb_quadpick (peaks, mag); for (j = 0; j < count; j++) peaks[j].mag = newmag->data[peaks[j].bin]; /* reset non peaks */ for (j = count; j < length; j++) peaks[j].mag = 0.; p->peaks = peaks; p->count = count; } } void aubio_pitchmcomb_combdet (aubio_pitchmcomb_t * p, const fvec_t * newmag) { aubio_spectralpeak_t *peaks = (aubio_spectralpeak_t *) p->peaks; aubio_spectralcandidate_t **candidate = (aubio_spectralcandidate_t **) p->candidates; /* parms */ uint_t N = p->npartials; /* maximum number of partials to be considered 10 */ uint_t M = p->ncand; /* maximum number of combs to be considered 5 */ uint_t length = newmag->length; uint_t count = p->count; uint_t k; uint_t l; uint_t d; uint_t curlen = 0; smpl_t delta2; smpl_t xx; uint_t position = 0; uint_t root_peak = 0; uint_t tmpl = 0; smpl_t tmpene = 0.; /* get the biggest peak in the spectrum */ root_peak = aubio_pitchmcomb_get_root_peak (peaks, count); /* not enough partials in highest notes, could be forced */ //if (peaks[root_peak].ebin >= aubio_miditofreq(85.)/p->tau) N=2; //if (peaks[root_peak].ebin >= aubio_miditofreq(90.)/p->tau) N=1; /* now calculate the energy of each of the 5 combs */ for (l = 0; l < M; l++) { smpl_t scaler = (1. / (l + 1.)); candidate[l]->ene = 0.; /* reset ene and len sums */ candidate[l]->len = 0.; candidate[l]->ebin = scaler * peaks[root_peak].ebin; /* if less than N peaks available, curlen < N */ if (candidate[l]->ebin != 0.) curlen = (uint_t) FLOOR (length / (candidate[l]->ebin)); curlen = (N < curlen) ? N : curlen; /* fill candidate[l]->ecomb[k] with (k+1)*candidate[l]->ebin */ for (k = 0; k < curlen; k++) candidate[l]->ecomb[k] = (candidate[l]->ebin) * (k + 1.); for (k = curlen; k < length; k++) candidate[l]->ecomb[k] = 0.; /* for each in candidate[l]->ecomb[k] */ for (k = 0; k < curlen; k++) { xx = 100000.; /** get the candidate->ecomb the closer to peaks.ebin * (to cope with the inharmonicity)*/ for (d = 0; d < count; d++) { delta2 = ABS (candidate[l]->ecomb[k] - peaks[d].ebin); if (delta2 <= xx) { position = d; xx = delta2; } } /* for a Q factor of 17, maintaining "constant Q filtering", * and sum energy and length over non null combs */ if (17. * xx < candidate[l]->ecomb[k]) { candidate[l]->ecomb[k] = peaks[position].ebin; candidate[l]->ene += /* ecomb rounded to nearest int */ POW (newmag->data[(uint_t) FLOOR (candidate[l]->ecomb[k] + .5)], 0.25); candidate[l]->len += 1. / curlen; } else candidate[l]->ecomb[k] = 0.; } /* punishment */ /*if (candidate[l]->len<0.6) candidate[l]->ene=0.; */ /* remember best candidate energy (in polyphonic, could check for * tmpene*1.1 < candidate->ene to reduce jumps towards low frequencies) */ if (tmpene < candidate[l]->ene) { tmpl = l; tmpene = candidate[l]->ene; } } //p->candidates=candidate; //p->peaks=peaks; p->goodcandidate = tmpl; } /** T=quadpick(X): return indices of elements of X which are peaks and positive * exact peak positions are retrieved by quadratic interpolation * * \bug peak-picking too picky, sometimes counts too many peaks ? */ uint_t aubio_pitchmcomb_quadpick (aubio_spectralpeak_t * spectral_peaks, const fvec_t * X) { uint_t j, ispeak, count = 0; for (j = 1; j < X->length - 1; j++) { ispeak = fvec_peakpick (X, j); if (ispeak) { count += ispeak; spectral_peaks[count - 1].bin = j; spectral_peaks[count - 1].ebin = fvec_quadratic_peak_pos (X, j); } } return count; } /* get predominant partial */ uint_t aubio_pitchmcomb_get_root_peak (aubio_spectralpeak_t * peaks, uint_t length) { uint_t i, pos = 0; smpl_t tmp = 0.; for (i = 0; i < length; i++) if (tmp <= peaks[i].mag) { pos = i; tmp = peaks[i].mag; } return pos; } #if 0 void aubio_pitchmcomb_sort_peak (aubio_spectralpeak_t * peaks, uint_t nbins) { qsort (peaks, nbins, sizeof (aubio_spectralpeak_t), aubio_pitchmcomb_sort_peak_comp); } static sint_t aubio_pitchmcomb_sort_peak_comp (const void *x, const void *y) { return (((aubio_spectralpeak_t *) y)->mag - ((aubio_spectralpeak_t *) x)->mag); } void aubio_pitchmcomb_sort_cand_ene (aubio_spectralcandidate_t ** candidates, uint_t nbins) { uint_t cur = 0; uint_t run = 0; for (cur = 0; cur < nbins; cur++) { for (run = cur + 1; run < nbins; run++) { if (candidates[run]->ene > candidates[cur]->ene) CAND_SWAP (candidates[run], candidates[cur]); } } } void aubio_pitchmcomb_sort_cand_freq (aubio_spectralcandidate_t ** candidates, uint_t nbins) { uint_t cur = 0; uint_t run = 0; for (cur = 0; cur < nbins; cur++) { for (run = cur + 1; run < nbins; run++) { if (candidates[run]->ebin < candidates[cur]->ebin) CAND_SWAP (candidates[run], candidates[cur]); } } } #endif aubio_pitchmcomb_t * new_aubio_pitchmcomb (uint_t bufsize, uint_t hopsize) { aubio_pitchmcomb_t *p = AUBIO_NEW (aubio_pitchmcomb_t); /* bug: should check if size / 8 > post+pre+1 */ uint_t i, j; uint_t spec_size; p->spec_partition = 2; p->ncand = 5; p->npartials = 5; p->cutoff = 1.; p->threshold = 0.01; p->win_post = 8; p->win_pre = 7; // p->tau = samplerate/bufsize; p->alpha = 9.; p->goodcandidate = 0; p->phasefreq = bufsize / hopsize / TWO_PI; p->phasediff = TWO_PI * hopsize / bufsize; spec_size = bufsize / p->spec_partition + 1; //p->pickerfn = quadpick; //p->biquad = new_biquad(0.1600,0.3200,0.1600, -0.5949, 0.2348); /* allocate temp memory */ p->newmag = new_fvec (spec_size); /* array for median */ p->scratch = new_fvec (spec_size); /* array for phase */ p->theta = new_fvec (spec_size); /* array for adaptative threshold */ p->scratch2 = new_fvec (p->win_post + p->win_pre + 1); /* array of spectral peaks */ p->peaks = AUBIO_ARRAY (aubio_spectralpeak_t, spec_size); for (i = 0; i < spec_size; i++) { p->peaks[i].bin = 0.; p->peaks[i].ebin = 0.; p->peaks[i].mag = 0.; } /* array of pointers to spectral candidates */ p->candidates = AUBIO_ARRAY (aubio_spectralcandidate_t *, p->ncand); for (i = 0; i < p->ncand; i++) { p->candidates[i] = AUBIO_NEW (aubio_spectralcandidate_t); p->candidates[i]->ecomb = AUBIO_ARRAY (smpl_t, spec_size); for (j = 0; j < spec_size; j++) { p->candidates[i]->ecomb[j] = 0.; } p->candidates[i]->ene = 0.; p->candidates[i]->ebin = 0.; p->candidates[i]->len = 0.; } return p; } void del_aubio_pitchmcomb (aubio_pitchmcomb_t * p) { uint_t i; del_fvec (p->newmag); del_fvec (p->scratch); del_fvec (p->theta); del_fvec (p->scratch2); AUBIO_FREE (p->peaks); for (i = 0; i < p->ncand; i++) { AUBIO_FREE (p->candidates[i]->ecomb); AUBIO_FREE (p->candidates[i]); } AUBIO_FREE (p->candidates); AUBIO_FREE (p); }