[b78805a] | 1 | /* |
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[7bf3dcb] | 2 | Copyright (C) 2005 Matthew Davies and Paul Brossier |
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[b78805a] | 3 | |
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[7bf3dcb] | 4 | This program is free software; you can redistribute it and/or modify |
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| 5 | it under the terms of the GNU General Public License as published by |
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| 6 | the Free Software Foundation; either version 2 of the License, or |
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| 7 | (at your option) any later version. |
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[b78805a] | 8 | |
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[7bf3dcb] | 9 | This program is distributed in the hope that it will be useful, |
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| 10 | but WITHOUT ANY WARRANTY; without even the implied warranty of |
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| 11 | MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the |
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| 12 | GNU General Public License for more details. |
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[b78805a] | 13 | |
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[7bf3dcb] | 14 | You should have received a copy of the GNU General Public License |
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| 15 | along with this program; if not, write to the Free Software |
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| 16 | Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. |
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[b78805a] | 17 | |
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| 18 | */ |
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| 19 | |
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| 20 | #include "aubio_priv.h" |
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[6c7d49b] | 21 | #include "fvec.h" |
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[b78805a] | 22 | #include "mathutils.h" |
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[32d6958] | 23 | #include "tempo/beattracking.h" |
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[b78805a] | 24 | |
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[17b7d66] | 25 | /** define to 1 to print out tracking difficulties */ |
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[1812f49] | 26 | #define AUBIO_BEAT_WARNINGS 0 |
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[17b7d66] | 27 | |
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[7bf3dcb] | 28 | uint_t fvec_gettimesig (fvec_t * acf, uint_t acflen, uint_t gp); |
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| 29 | void aubio_beattracking_checkstate (aubio_beattracking_t * bt); |
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| 30 | |
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| 31 | struct _aubio_beattracking_t |
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| 32 | { |
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| 33 | fvec_t *rwv; /** rayleigh weighting for beat period in general model */ |
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| 34 | fvec_t *dfwv; /** exponential weighting for beat alignment in general model */ |
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| 35 | fvec_t *gwv; /** gaussian weighting for beat period in context dependant model */ |
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| 36 | fvec_t *phwv; /** gaussian weighting for beat alignment in context dependant model */ |
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| 37 | fvec_t *dfrev; /** reversed onset detection function */ |
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| 38 | fvec_t *acf; /** vector for autocorrelation function (of current detection function frame) */ |
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| 39 | fvec_t *acfout; /** store result of passing acf through s.i.c.f.b. */ |
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| 40 | fvec_t *phout; |
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| 41 | uint_t timesig; /** time signature of input, set to zero until context dependent model activated */ |
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| 42 | uint_t step; |
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| 43 | uint_t rayparam; /** Rayleigh parameter */ |
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| 44 | smpl_t lastbeat; |
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| 45 | sint_t counter; |
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| 46 | uint_t flagstep; |
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| 47 | smpl_t g_var; |
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| 48 | smpl_t gp; |
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| 49 | smpl_t bp; |
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| 50 | smpl_t rp; |
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| 51 | smpl_t rp1; |
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| 52 | smpl_t rp2; |
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[b78805a] | 53 | }; |
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| 54 | |
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[7bf3dcb] | 55 | aubio_beattracking_t * |
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| 56 | new_aubio_beattracking (uint_t winlen, uint_t channels) |
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| 57 | { |
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| 58 | |
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| 59 | aubio_beattracking_t *p = AUBIO_NEW (aubio_beattracking_t); |
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| 60 | uint_t i = 0; |
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| 61 | /* parameter for rayleigh weight vector - sets preferred tempo to |
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| 62 | * 120bpm [43] */ |
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| 63 | smpl_t rayparam = 48. / 512. * winlen; |
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| 64 | smpl_t dfwvnorm = EXP ((LOG (2.0) / rayparam) * (winlen + 2)); |
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| 65 | /* length over which beat period is found [128] */ |
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| 66 | uint_t laglen = winlen / 4; |
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| 67 | /* step increment - both in detection function samples -i.e. 11.6ms or |
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| 68 | * 1 onset frame [128] */ |
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| 69 | uint_t step = winlen / 4; /* 1.5 seconds */ |
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| 70 | |
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| 71 | p->lastbeat = 0; |
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| 72 | p->counter = 0; |
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| 73 | p->flagstep = 0; |
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| 74 | p->g_var = 3.901; // constthresh empirically derived! |
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| 75 | p->rp = 1; |
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| 76 | p->gp = 0; |
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| 77 | |
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| 78 | p->rayparam = rayparam; |
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| 79 | p->step = step; |
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| 80 | p->rwv = new_fvec (laglen, 1); |
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| 81 | p->gwv = new_fvec (laglen, 1); |
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| 82 | p->dfwv = new_fvec (winlen, 1); |
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| 83 | p->dfrev = new_fvec (winlen, channels); |
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| 84 | p->acf = new_fvec (winlen, channels); |
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| 85 | p->acfout = new_fvec (laglen, channels); |
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| 86 | p->phwv = new_fvec (2 * laglen, 1); |
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| 87 | p->phout = new_fvec (winlen, channels); |
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| 88 | |
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| 89 | p->timesig = 0; |
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| 90 | |
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| 91 | /* exponential weighting, dfwv = 0.5 when i = 43 */ |
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| 92 | for (i = 0; i < winlen; i++) { |
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| 93 | p->dfwv->data[0][i] = (EXP ((LOG (2.0) / rayparam) * (i + 1))) |
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| 94 | / dfwvnorm; |
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| 95 | } |
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| 96 | |
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| 97 | for (i = 0; i < (laglen); i++) { |
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| 98 | p->rwv->data[0][i] = ((smpl_t) (i + 1.) / SQR ((smpl_t) rayparam)) * |
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| 99 | EXP ((-SQR ((smpl_t) (i + 1.)) / (2. * SQR ((smpl_t) rayparam)))); |
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| 100 | } |
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| 101 | |
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| 102 | return p; |
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[b78805a] | 103 | |
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| 104 | } |
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| 105 | |
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[7bf3dcb] | 106 | void |
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| 107 | del_aubio_beattracking (aubio_beattracking_t * p) |
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| 108 | { |
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| 109 | del_fvec (p->rwv); |
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| 110 | del_fvec (p->gwv); |
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| 111 | del_fvec (p->dfwv); |
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| 112 | del_fvec (p->dfrev); |
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| 113 | del_fvec (p->acf); |
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| 114 | del_fvec (p->acfout); |
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| 115 | del_fvec (p->phwv); |
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| 116 | del_fvec (p->phout); |
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| 117 | AUBIO_FREE (p); |
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[b78805a] | 118 | } |
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| 119 | |
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| 120 | |
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[7bf3dcb] | 121 | void |
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| 122 | aubio_beattracking_do (aubio_beattracking_t * bt, fvec_t * dfframe, |
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| 123 | fvec_t * output) |
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| 124 | { |
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| 125 | |
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| 126 | uint_t i, k; |
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| 127 | uint_t step = bt->step; |
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| 128 | uint_t laglen = bt->rwv->length; |
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| 129 | uint_t winlen = bt->dfwv->length; |
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| 130 | uint_t maxindex = 0; |
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| 131 | //number of harmonics in shift invariant comb filterbank |
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| 132 | uint_t numelem = 4; |
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| 133 | |
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| 134 | smpl_t phase; // beat alignment (step - lastbeat) |
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| 135 | smpl_t beat; // beat position |
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| 136 | smpl_t bp; // beat period |
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| 137 | uint_t a, b; // used to build shift invariant comb filterbank |
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| 138 | uint_t kmax; // number of elements used to find beat phase |
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| 139 | |
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| 140 | /* copy dfframe, apply detection function weighting, and revert */ |
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| 141 | fvec_copy (dfframe, bt->dfrev); |
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| 142 | fvec_weight (bt->dfrev, bt->dfwv); |
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| 143 | fvec_rev (bt->dfrev); |
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| 144 | |
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| 145 | /* compute autocorrelation function */ |
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| 146 | aubio_autocorr (dfframe, bt->acf); |
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| 147 | |
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| 148 | /* if timesig is unknown, use metrically unbiased version of filterbank */ |
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| 149 | if (!bt->timesig) { |
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| 150 | numelem = 4; |
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| 151 | } else { |
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| 152 | numelem = bt->timesig; |
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| 153 | } |
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| 154 | |
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| 155 | /* first and last output values are left intentionally as zero */ |
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| 156 | fvec_zeros (bt->acfout); |
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| 157 | |
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| 158 | /* compute shift invariant comb filterbank */ |
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| 159 | for (i = 1; i < laglen - 1; i++) { |
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| 160 | for (a = 1; a <= numelem; a++) { |
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| 161 | for (b = (1 - a); b < a; b++) { |
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| 162 | bt->acfout->data[0][i] += bt->acf->data[0][a * (i + 1) + b - 1] |
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| 163 | * 1. / (2. * a - 1.); |
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| 164 | } |
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| 165 | } |
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| 166 | } |
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| 167 | /* apply Rayleigh weight */ |
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| 168 | fvec_weight (bt->acfout, bt->rwv); |
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| 169 | |
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| 170 | /* find non-zero Rayleigh period */ |
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[1e2c82f] | 171 | maxindex = fvec_max_elem (bt->acfout); |
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[56ef7e1] | 172 | bt->rp = maxindex ? fvec_quadint (bt->acfout, maxindex, 0) : 1; |
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[7bf3dcb] | 173 | //rp = (maxindex==127) ? 43 : maxindex; //rayparam |
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| 174 | bt->rp = (maxindex == bt->acfout->length - 1) ? bt->rayparam : maxindex; //rayparam |
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| 175 | |
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| 176 | /* activate biased filterbank */ |
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| 177 | aubio_beattracking_checkstate (bt); |
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| 178 | #if 0 // debug metronome mode |
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| 179 | bt->bp = 36.9142; |
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[4e19e5b] | 180 | #endif |
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[7bf3dcb] | 181 | bp = bt->bp; |
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| 182 | /* end of biased filterbank */ |
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| 183 | |
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| 184 | |
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| 185 | /* deliberate integer operation, could be set to 3 max eventually */ |
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| 186 | kmax = FLOOR (winlen / bp); |
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| 187 | |
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| 188 | /* initialize output */ |
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| 189 | fvec_zeros (bt->phout); |
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| 190 | for (i = 0; i < bp; i++) { |
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| 191 | for (k = 0; k < kmax; k++) { |
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| 192 | bt->phout->data[0][i] += bt->dfrev->data[0][i + (uint_t) ROUND (bp * k)]; |
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| 193 | } |
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| 194 | } |
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| 195 | fvec_weight (bt->phout, bt->phwv); |
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| 196 | |
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| 197 | /* find Rayleigh period */ |
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[1e2c82f] | 198 | maxindex = fvec_max_elem (bt->phout); |
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[3de10bb] | 199 | if (maxindex >= winlen - 1) { |
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[17b7d66] | 200 | #if AUBIO_BEAT_WARNINGS |
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| 201 | AUBIO_WRN ("no idea what this groove's phase is\n"); |
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| 202 | #endif /* AUBIO_BEAT_WARNINGS */ |
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[3de10bb] | 203 | phase = step - bt->lastbeat; |
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| 204 | } else { |
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[56ef7e1] | 205 | phase = fvec_quadint (bt->phout, maxindex, 0); |
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[3de10bb] | 206 | } |
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[17b7d66] | 207 | /* take back one frame delay */ |
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| 208 | phase += 1.; |
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[7bf3dcb] | 209 | #if 0 // debug metronome mode |
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| 210 | phase = step - bt->lastbeat; |
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[4e19e5b] | 211 | #endif |
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[b78805a] | 212 | |
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[7bf3dcb] | 213 | /* reset output */ |
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| 214 | fvec_zeros (output); |
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| 215 | |
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| 216 | i = 1; |
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| 217 | beat = bp - phase; |
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[17b7d66] | 218 | |
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| 219 | // AUBIO_DBG ("bp: %f, phase: %f, lastbeat: %f, step: %d, winlen: %d\n", |
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| 220 | // bp, phase, bt->lastbeat, step, winlen); |
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| 221 | |
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| 222 | /* the next beat will be earlier than 60% of the tempo period |
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| 223 | skip this one */ |
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| 224 | if ( ( step - bt->lastbeat - phase ) < -0.40 * bp ) { |
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| 225 | #if AUBIO_BEAT_WARNINGS |
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| 226 | AUBIO_WRN ("back off-beat error, skipping this beat\n"); |
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| 227 | #endif /* AUBIO_BEAT_WARNINGS */ |
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| 228 | beat += bp; |
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| 229 | } |
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| 230 | |
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[7bf3dcb] | 231 | /* start counting the beats */ |
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[3de10bb] | 232 | while (beat + bp < 0) { |
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| 233 | beat += bp; |
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| 234 | } |
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| 235 | |
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[7bf3dcb] | 236 | if (beat >= 0) { |
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[3de10bb] | 237 | //AUBIO_DBG ("beat: %d, %f, %f\n", i, bp, beat); |
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[7bf3dcb] | 238 | output->data[0][i] = beat; |
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| 239 | i++; |
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| 240 | } |
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| 241 | |
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| 242 | while (beat + bp <= step) { |
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| 243 | beat += bp; |
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[3de10bb] | 244 | //AUBIO_DBG ("beat: %d, %f, %f\n", i, bp, beat); |
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[7bf3dcb] | 245 | output->data[0][i] = beat; |
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| 246 | i++; |
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| 247 | } |
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| 248 | |
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| 249 | bt->lastbeat = beat; |
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[17b7d66] | 250 | /* store the number of beats in this frame as the first element */ |
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[7bf3dcb] | 251 | output->data[0][0] = i; |
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[b78805a] | 252 | } |
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| 253 | |
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[7bf3dcb] | 254 | uint_t |
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| 255 | fvec_gettimesig (fvec_t * acf, uint_t acflen, uint_t gp) |
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| 256 | { |
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| 257 | sint_t k = 0; |
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| 258 | smpl_t three_energy = 0., four_energy = 0.; |
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| 259 | if (acflen > 6 * gp + 2) { |
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| 260 | for (k = -2; k < 2; k++) { |
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| 261 | three_energy += acf->data[0][3 * gp + k]; |
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| 262 | four_energy += acf->data[0][4 * gp + k]; |
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| 263 | } |
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| 264 | } else { |
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| 265 | /*Expanded to be more accurate in time sig estimation */ |
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| 266 | for (k = -2; k < 2; k++) { |
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| 267 | three_energy += acf->data[0][3 * gp + k] + acf->data[0][6 * gp + k]; |
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| 268 | four_energy += acf->data[0][4 * gp + k] + acf->data[0][2 * gp + k]; |
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| 269 | } |
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| 270 | } |
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| 271 | return (three_energy > four_energy) ? 3 : 4; |
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[b78805a] | 272 | } |
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| 273 | |
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[7bf3dcb] | 274 | void |
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| 275 | aubio_beattracking_checkstate (aubio_beattracking_t * bt) |
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| 276 | { |
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| 277 | uint_t i, j, a, b; |
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| 278 | uint_t flagconst = 0; |
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| 279 | sint_t counter = bt->counter; |
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| 280 | uint_t flagstep = bt->flagstep; |
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| 281 | smpl_t gp = bt->gp; |
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| 282 | smpl_t bp = bt->bp; |
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| 283 | smpl_t rp = bt->rp; |
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| 284 | smpl_t rp1 = bt->rp1; |
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| 285 | smpl_t rp2 = bt->rp2; |
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| 286 | uint_t laglen = bt->rwv->length; |
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| 287 | uint_t acflen = bt->acf->length; |
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| 288 | uint_t step = bt->step; |
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| 289 | fvec_t *acf = bt->acf; |
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| 290 | fvec_t *acfout = bt->acfout; |
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| 291 | |
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| 292 | if (gp) { |
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| 293 | // doshiftfbank again only if context dependent model is in operation |
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| 294 | //acfout = doshiftfbank(acf,gwv,timesig,laglen,acfout); |
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| 295 | //don't need acfout now, so can reuse vector |
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| 296 | // gwv is, in first loop, definitely all zeros, but will have |
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| 297 | // proper values when context dependent model is activated |
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| 298 | fvec_zeros (acfout); |
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| 299 | for (i = 1; i < laglen - 1; i++) { |
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| 300 | for (a = 1; a <= bt->timesig; a++) { |
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| 301 | for (b = (1 - a); b < a; b++) { |
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| 302 | acfout->data[0][i] += acf->data[0][a * (i + 1) + b - 1]; |
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[b78805a] | 303 | } |
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[7bf3dcb] | 304 | } |
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| 305 | } |
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| 306 | fvec_weight (acfout, bt->gwv); |
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[56ef7e1] | 307 | gp = fvec_quadint (acfout, fvec_max_elem (acfout), 0); |
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[7bf3dcb] | 308 | /* |
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| 309 | while(gp<32) gp =gp*2; |
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| 310 | while(gp>64) gp = gp/2; |
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| 311 | */ |
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| 312 | } else { |
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| 313 | //still only using general model |
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| 314 | gp = 0; |
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| 315 | } |
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| 316 | |
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| 317 | //now look for step change - i.e. a difference between gp and rp that |
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| 318 | // is greater than 2*constthresh - always true in first case, since gp = 0 |
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| 319 | if (counter == 0) { |
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| 320 | if (ABS (gp - rp) > 2. * bt->g_var) { |
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| 321 | flagstep = 1; // have observed step change. |
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| 322 | counter = 3; // setup 3 frame counter |
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| 323 | } else { |
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| 324 | flagstep = 0; |
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| 325 | } |
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| 326 | } |
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| 327 | //i.e. 3rd frame after flagstep initially set |
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| 328 | if (counter == 1 && flagstep == 1) { |
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| 329 | //check for consistency between previous beatperiod values |
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| 330 | if (ABS (2. * rp - rp1 - rp2) < bt->g_var) { |
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| 331 | //if true, can activate context dependent model |
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| 332 | flagconst = 1; |
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| 333 | counter = 0; // reset counter and flagstep |
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| 334 | } else { |
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| 335 | //if not consistent, then don't flag consistency! |
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| 336 | flagconst = 0; |
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| 337 | counter = 2; // let it look next time |
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| 338 | } |
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| 339 | } else if (counter > 0) { |
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| 340 | //if counter doesn't = 1, |
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| 341 | counter = counter - 1; |
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| 342 | } |
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| 343 | |
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| 344 | rp2 = rp1; |
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| 345 | rp1 = rp; |
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| 346 | |
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| 347 | if (flagconst) { |
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| 348 | /* first run of new hypothesis */ |
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| 349 | gp = rp; |
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| 350 | bt->timesig = fvec_gettimesig (acf, acflen, gp); |
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| 351 | for (j = 0; j < laglen; j++) |
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| 352 | bt->gwv->data[0][j] = |
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| 353 | EXP (-.5 * SQR ((smpl_t) (j + 1. - gp)) / SQR (bt->g_var)); |
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| 354 | flagconst = 0; |
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| 355 | bp = gp; |
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| 356 | /* flat phase weighting */ |
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| 357 | fvec_ones (bt->phwv); |
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| 358 | } else if (bt->timesig) { |
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| 359 | /* context dependant model */ |
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| 360 | bp = gp; |
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| 361 | /* gaussian phase weighting */ |
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| 362 | if (step > bt->lastbeat) { |
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| 363 | for (j = 0; j < 2 * laglen; j++) { |
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| 364 | bt->phwv->data[0][j] = |
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| 365 | EXP (-.5 * SQR ((smpl_t) (1. + j - step + |
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| 366 | bt->lastbeat)) / (bp / 8.)); |
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| 367 | } |
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| 368 | } else { |
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| 369 | //AUBIO_DBG("NOT using phase weighting as step is %d and lastbeat %d \n", |
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| 370 | // step,bt->lastbeat); |
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| 371 | fvec_ones (bt->phwv); |
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| 372 | } |
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| 373 | } else { |
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| 374 | /* initial state */ |
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| 375 | bp = rp; |
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| 376 | /* flat phase weighting */ |
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| 377 | fvec_ones (bt->phwv); |
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| 378 | } |
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| 379 | |
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| 380 | /* do some further checks on the final bp value */ |
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| 381 | |
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| 382 | /* if tempo is > 206 bpm, half it */ |
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| 383 | while (bp < 25) { |
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[17b7d66] | 384 | #if AUBIO_BEAT_WARNINGS |
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| 385 | AUBIO_WRN ("doubling from %f (%f bpm) to %f (%f bpm)\n", |
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| 386 | bp, 60.*44100./512./bp, bp/2., 60.*44100./512./bp/2. ); |
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[7bf3dcb] | 387 | //AUBIO_DBG("warning, halving the tempo from %f\n", 60.*samplerate/hopsize/bp); |
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[17b7d66] | 388 | #endif /* AUBIO_BEAT_WARNINGS */ |
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[7bf3dcb] | 389 | bp = bp * 2; |
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| 390 | } |
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| 391 | |
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| 392 | //AUBIO_DBG("tempo:\t%3.5f bpm | ", 5168./bp); |
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| 393 | |
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| 394 | /* smoothing */ |
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| 395 | //bp = (uint_t) (0.8 * (smpl_t)bp + 0.2 * (smpl_t)bp2); |
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| 396 | //AUBIO_DBG("tempo:\t%3.5f bpm smoothed | bp2 %d | bp %d | ", 5168./bp, bp2, bp); |
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| 397 | //bp2 = bp; |
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| 398 | //AUBIO_DBG("time signature: %d \n", bt->timesig); |
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| 399 | bt->counter = counter; |
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| 400 | bt->flagstep = flagstep; |
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| 401 | bt->gp = gp; |
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| 402 | bt->bp = bp; |
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| 403 | bt->rp1 = rp1; |
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| 404 | bt->rp2 = rp2; |
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[b78805a] | 405 | } |
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[416c0b5] | 406 | |
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[7bf3dcb] | 407 | smpl_t |
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| 408 | aubio_beattracking_get_bpm (aubio_beattracking_t * bt) |
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| 409 | { |
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| 410 | if (bt->timesig != 0 && bt->counter == 0 && bt->flagstep == 0) { |
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[56ef7e1] | 411 | return 5168. / fvec_quadint (bt->acfout, bt->bp, 0); |
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[7bf3dcb] | 412 | } else { |
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| 413 | return 0.; |
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| 414 | } |
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[416c0b5] | 415 | } |
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[e34b010] | 416 | |
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[7bf3dcb] | 417 | smpl_t |
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| 418 | aubio_beattracking_get_confidence (aubio_beattracking_t * bt) |
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| 419 | { |
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| 420 | if (bt->gp) { |
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[1e2c82f] | 421 | return fvec_max (bt->acfout); |
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[7bf3dcb] | 422 | } else { |
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| 423 | return 0.; |
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| 424 | } |
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[e34b010] | 425 | } |
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