ref: d2af4085e1b9f8c0af6aad661a7059ac8690e037
dir: /src/utils/hist.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 "utils/scale.h" #include "mathutils.h" //fvec_min fvec_max #include "utils/hist.h" /******** * Object Structure */ struct _aubio_hist_t { fvec_t * hist; uint_t nelems; fvec_t * cent; aubio_scale_t *scaler; }; /** * Object creation/deletion calls */ aubio_hist_t * new_aubio_hist (smpl_t flow, smpl_t fhig, uint_t nelems){ aubio_hist_t * s = AUBIO_NEW(aubio_hist_t); smpl_t step = (fhig-flow)/(smpl_t)(nelems); smpl_t accum = step; uint_t i; if ((sint_t)nelems <= 0) { AUBIO_FREE(s); return NULL; } s->nelems = nelems; s->hist = new_fvec(nelems); s->cent = new_fvec(nelems); /* use scale to map flow/fhig -> 0/nelems */ s->scaler = new_aubio_scale(flow,fhig,0,nelems); /* calculate centers now once */ s->cent->data[0] = flow + 0.5 * step; for (i=1; i < s->nelems; i++, accum+=step ) s->cent->data[i] = s->cent->data[0] + accum; return s; } void del_aubio_hist(aubio_hist_t *s) { del_fvec(s->hist); del_fvec(s->cent); del_aubio_scale(s->scaler); AUBIO_FREE(s); } /*** * do it */ void aubio_hist_do (aubio_hist_t *s, fvec_t *input) { uint_t j; sint_t tmp; aubio_scale_do(s->scaler, input); /* reset data */ fvec_zeros(s->hist); /* run accum */ for (j=0; j < input->length; j++) { tmp = (sint_t)FLOOR(input->data[j]); if ((tmp >= 0) && (tmp < (sint_t)s->nelems)) { s->hist->data[tmp] += 1; } } } void aubio_hist_do_notnull (aubio_hist_t *s, fvec_t *input) { uint_t j; sint_t tmp; aubio_scale_do(s->scaler, input); /* reset data */ fvec_zeros(s->hist); /* run accum */ for (j=0; j < input->length; j++) { if (input->data[j] != 0) { tmp = (sint_t)FLOOR(input->data[j]); if ((tmp >= 0) && (tmp < (sint_t)s->nelems)) s->hist->data[tmp] += 1; } } } void aubio_hist_dyn_notnull (aubio_hist_t *s, fvec_t *input) { uint_t i; sint_t tmp; smpl_t ilow = fvec_min(input); smpl_t ihig = fvec_max(input); smpl_t step = (ihig-ilow)/(smpl_t)(s->nelems); /* readapt */ aubio_scale_set_limits (s->scaler, ilow, ihig, 0, s->nelems); /* recalculate centers */ s->cent->data[0] = ilow + 0.5f * step; for (i=1; i < s->nelems; i++) s->cent->data[i] = s->cent->data[0] + i * step; /* scale */ aubio_scale_do(s->scaler, input); /* reset data */ fvec_zeros(s->hist); /* run accum */ for (i=0; i < input->length; i++) { if (input->data[i] != 0) { tmp = (sint_t)FLOOR(input->data[i]); if ((tmp >= 0) && (tmp < (sint_t)s->nelems)) s->hist->data[tmp] += 1; } } } void aubio_hist_weight (aubio_hist_t *s) { uint_t j; for (j=0; j < s->nelems; j++) { s->hist->data[j] *= s->cent->data[j]; } } smpl_t aubio_hist_mean (const aubio_hist_t *s) { uint_t j; smpl_t tmp = 0.0; for (j=0; j < s->nelems; j++) tmp += s->hist->data[j]; return tmp/(smpl_t)(s->nelems); }