1 | /* |
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2 | Copyright (C) 2005 Matthew Davies and Paul Brossier |
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3 | |
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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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8 | |
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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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13 | |
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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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17 | |
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18 | */ |
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19 | |
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20 | #include "aubio_priv.h" |
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21 | #include "sample.h" |
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22 | #include "mathutils.h" |
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23 | #include "beattracking.h" |
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24 | |
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25 | uint_t fvec_gettimesig(smpl_t * acf, uint_t acflen, uint_t gp); |
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26 | void aubio_beattracking_checkstate(aubio_beattracking_t * bt); |
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27 | smpl_t fvec_getperiod(aubio_beattracking_t * bt); |
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28 | |
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29 | struct _aubio_beattracking_t { |
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30 | fvec_t * rwv; /** rayleigh weight vector - rayleigh distribution function */ |
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31 | fvec_t * gwv; /** rayleigh weight vector - rayleigh distribution function */ |
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32 | fvec_t * dfwv; /** detection function weighting - exponential curve */ |
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33 | fvec_t * dfrev; /** reversed onset detection function */ |
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34 | fvec_t * acf; /** vector for autocorrelation function (of current detection function frame) */ |
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35 | fvec_t * acfout; /** store result of passing acf through s.i.c.f.b. */ |
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36 | fvec_t * phwv; /** beat expectation alignment weighting */ |
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37 | fvec_t * phout; |
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38 | uint_t timesig; /** time signature of input, set to zero until context dependent model activated */ |
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39 | uint_t step; |
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40 | fvec_t * locacf; /** vector to store harmonics of filterbank of acf */ |
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41 | fvec_t * inds; /** vector for max index outputs for each harmonic */ |
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42 | uint_t rayparam; /** Rayleigh parameter */ |
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43 | uint_t lastbeat; |
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44 | sint_t counter; |
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45 | uint_t flagstep; |
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46 | smpl_t g_var; |
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47 | uint_t gp; |
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48 | uint_t bp; |
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49 | uint_t rp; |
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50 | uint_t rp1; |
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51 | uint_t rp2; |
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52 | }; |
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53 | |
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54 | aubio_beattracking_t * new_aubio_beattracking(uint_t winlen, |
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55 | uint_t channels) { |
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56 | |
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57 | aubio_beattracking_t * p = AUBIO_NEW(aubio_beattracking_t); |
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58 | uint_t i = 0; |
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59 | /* parameter for rayleigh weight vector - sets preferred tempo to |
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60 | * 120bpm [43] */ |
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61 | smpl_t rayparam = 48./512. * winlen; |
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62 | smpl_t dfwvnorm = EXP((LOG(2.0)/rayparam)*(winlen+2)); |
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63 | /** length over which beat period is found [128] */ |
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64 | uint_t laglen = winlen/4; |
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65 | /** step increment - both in detection function samples -i.e. 11.6ms or |
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66 | * 1 onset frame [128] */ |
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67 | uint_t step = winlen/4; /* 1.5 seconds */ |
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68 | |
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69 | uint_t maxnumelem = 4; /* max number of index output */ |
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70 | p->lastbeat = 0; |
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71 | p->counter = 0; |
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72 | p->flagstep = 0; |
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73 | p->g_var = 3.901; // constthresh empirically derived! |
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74 | p->rp = 1; |
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75 | p->gp = 0; |
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76 | |
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77 | p->rayparam = rayparam; |
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78 | p->step = step; |
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79 | p->rwv = new_fvec(laglen,channels); |
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80 | p->gwv = new_fvec(laglen,channels); |
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81 | p->dfwv = new_fvec(winlen,channels); |
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82 | p->dfrev = new_fvec(winlen,channels); |
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83 | p->acf = new_fvec(winlen,channels); |
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84 | p->acfout = new_fvec(laglen,channels); |
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85 | p->phwv = new_fvec(2*laglen,channels); |
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86 | p->phout = new_fvec(winlen,channels); |
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87 | |
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88 | p->timesig = 0; |
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89 | |
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90 | p->inds = new_fvec(maxnumelem,channels); |
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91 | p->locacf = new_fvec(winlen,channels); |
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92 | |
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93 | /* exponential weighting, dfwv = 0.5 when i = 43 */ |
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94 | for (i=0;i<winlen;i++) { |
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95 | p->dfwv->data[0][i] = (EXP((LOG(2.0)/rayparam)*(i+1))) |
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96 | / dfwvnorm; |
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97 | } |
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98 | |
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99 | for (i=0;i<(laglen);i++){ |
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100 | p->rwv->data[0][i] = ((smpl_t)(i+1.) / SQR((smpl_t)rayparam)) * |
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101 | EXP((-SQR((smpl_t)(i+1.)) / (2.*SQR((smpl_t)rayparam)))); |
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102 | } |
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103 | |
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104 | return p; |
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105 | |
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106 | } |
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107 | |
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108 | void del_aubio_beattracking(aubio_beattracking_t * p) { |
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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 | del_fvec(p->locacf); |
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118 | del_fvec(p->inds); |
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119 | AUBIO_FREE(p); |
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120 | } |
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121 | |
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122 | |
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123 | void aubio_beattracking_do(aubio_beattracking_t * bt, fvec_t * dfframe, fvec_t * output) { |
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124 | |
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125 | uint_t i,k; |
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126 | /* current beat period value found using gaussian weighting (from context dependent model) */ |
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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 | smpl_t * phout = bt->phout->data[0]; |
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131 | smpl_t * phwv = bt->phwv->data[0]; |
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132 | smpl_t * dfrev = bt->dfrev->data[0]; |
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133 | smpl_t * dfwv = bt->dfwv->data[0]; |
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134 | smpl_t * rwv = bt->rwv->data[0]; |
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135 | smpl_t * acfout = bt->acfout->data[0]; |
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136 | smpl_t * acf = bt->acf->data[0]; |
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137 | uint_t maxindex = 0; |
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138 | //number of harmonics in shift invariant comb filterbank |
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139 | uint_t numelem = 4; |
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140 | |
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141 | //smpl_t myperiod = 0.; |
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142 | //smpl_t * out = output->data[0]; |
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143 | |
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144 | //parameters for making s.i.c.f.b. |
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145 | uint_t a,b; |
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146 | //beat alignment |
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147 | uint_t phase; |
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148 | uint_t kmax; |
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149 | sint_t beat; |
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150 | uint_t bp; |
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151 | |
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152 | for (i = 0; i < winlen; i++){ |
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153 | dfrev[winlen-1-i] = 0.; |
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154 | dfrev[winlen-1-i] = dfframe->data[0][i]*dfwv[i]; |
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155 | } |
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156 | |
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157 | /* find autocorrelation function */ |
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158 | aubio_autocorr(dfframe,bt->acf); |
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159 | /* |
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160 | for (i = 0; i < winlen; i++){ |
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161 | AUBIO_DBG("%f,",acf[i]); |
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162 | } |
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163 | AUBIO_DBG("\n"); |
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164 | */ |
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165 | |
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166 | /* get acfout - assume Rayleigh weightvector only */ |
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167 | /* if timesig is unknown, use metrically unbiased version of filterbank */ |
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168 | if(!bt->timesig) |
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169 | numelem = 4; |
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170 | // AUBIO_DBG("using unbiased filterbank, timesig: %d\n", timesig); |
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171 | else |
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172 | numelem = bt->timesig; |
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173 | // AUBIO_DBG("using biased filterbank, timesig: %d\n", timesig); |
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174 | |
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175 | /* first and last output values are left intentionally as zero */ |
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176 | for (i=0; i < bt->acfout->length; i++) |
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177 | acfout[i] = 0.; |
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178 | |
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179 | for(i=1;i<laglen-1;i++){ |
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180 | for (a=1; a<=numelem; a++){ |
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181 | for(b=(1-a); b<a; b++){ |
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182 | acfout[i] += acf[a*(i+1)+b-1] |
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183 | * 1./(2.*a-1.)*rwv[i]; |
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184 | } |
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185 | } |
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186 | } |
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187 | |
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188 | /* find non-zero Rayleigh period */ |
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189 | maxindex = vec_max_elem(bt->acfout); |
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190 | bt->rp = maxindex ? maxindex : 1; |
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191 | //rp = (maxindex==127) ? 43 : maxindex; //rayparam |
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192 | bt->rp = (maxindex==bt->acfout->length-1) ? bt->rayparam : maxindex; //rayparam |
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193 | |
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194 | // get float period |
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195 | //myperiod = fvec_getperiod(bt); |
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196 | //AUBIO_DBG("\nrp = %d myperiod = %f\n",bt->rp,myperiod); |
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197 | //AUBIO_DBG("accurate tempo is %f bpm\n",5168./myperiod); |
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198 | |
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199 | /* activate biased filterbank */ |
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200 | aubio_beattracking_checkstate(bt); |
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201 | bp = bt->bp; |
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202 | /* end of biased filterbank */ |
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203 | |
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204 | /* initialize output */ |
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205 | for(i=0;i<bt->phout->length;i++) {phout[i] = 0.;} |
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206 | |
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207 | /* deliberate integer operation, could be set to 3 max eventually */ |
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208 | kmax = winlen/bp; |
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209 | |
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210 | for(i=0;i<bp;i++){ |
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211 | phout[i] = 0.; |
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212 | for(k=0;k<kmax;k++){ |
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213 | phout[i] += dfrev[i+bp*k] * phwv[i]; |
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214 | } |
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215 | } |
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216 | |
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217 | /* find Rayleigh period */ |
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218 | maxindex = vec_max_elem(bt->phout); |
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219 | if (maxindex == winlen-1) maxindex = 0; |
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220 | phase = 1 + maxindex; |
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221 | |
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222 | /* debug */ |
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223 | //AUBIO_DBG("beat period = %d, rp1 = %d, rp2 = %d\n", bp, rp1, rp2); |
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224 | //AUBIO_DBG("rp = %d, gp = %d, phase = %d\n", bt->rp, bt->gp, phase); |
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225 | |
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226 | /* reset output */ |
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227 | for (i = 0; i < laglen; i++) |
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228 | output->data[0][i] = 0.; |
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229 | |
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230 | i = 1; |
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231 | beat = bp - phase; |
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232 | /* start counting the beats */ |
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233 | if(beat >= 0) |
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234 | { |
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235 | output->data[0][i] = (smpl_t)beat; |
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236 | i++; |
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237 | } |
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238 | |
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239 | while( beat+bp < step ) |
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240 | { |
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241 | beat += bp; |
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242 | output->data[0][i] = (smpl_t)beat; |
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243 | i++; |
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244 | } |
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245 | |
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246 | bt->lastbeat = beat; |
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247 | /* store the number of beat found in this frame as the first element */ |
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248 | output->data[0][0] = i; |
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249 | } |
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250 | |
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251 | uint_t fvec_gettimesig(smpl_t * acf, uint_t acflen, uint_t gp){ |
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252 | sint_t k = 0; |
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253 | smpl_t three_energy = 0., four_energy = 0.; |
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254 | if( acflen > 6 * gp + 2 ){ |
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255 | for(k=-2;k<2;k++){ |
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256 | three_energy += acf[3*gp+k]; |
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257 | four_energy += acf[4*gp+k]; |
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258 | } |
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259 | } |
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260 | else{ /*Expanded to be more accurate in time sig estimation*/ |
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261 | for(k=-2;k<2;k++){ |
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262 | three_energy += acf[3*gp+k]+acf[6*gp+k]; |
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263 | four_energy += acf[4*gp+k]+acf[2*gp+k]; |
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264 | } |
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265 | } |
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266 | return (three_energy > four_energy) ? 3 : 4; |
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267 | } |
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268 | |
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269 | smpl_t fvec_getperiod(aubio_beattracking_t * bt){ |
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270 | /*function to make a more accurate beat period measurement.*/ |
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271 | |
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272 | smpl_t period = 0.; |
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273 | smpl_t maxval = 0.; |
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274 | uint_t numelem = 4; |
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275 | |
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276 | sint_t a,b; |
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277 | uint_t i,j; |
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278 | uint_t acfmi = bt->rp; //acfout max index |
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279 | uint_t maxind = 0; |
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280 | |
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281 | if(!bt->timesig) |
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282 | numelem = 4; |
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283 | else |
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284 | numelem = bt->timesig; |
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285 | |
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286 | for (i=0;i<numelem;i++) // initialize |
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287 | bt->inds->data[0][i] = 0.; |
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288 | |
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289 | for (i=0;i<bt->locacf->length;i++) // initialize |
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290 | bt->locacf->data[0][i] = 0.; |
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291 | |
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292 | // get appropriate acf elements from acf and store in locacf |
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293 | for (a=1;a<=4;a++){ |
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294 | for(b=(1-a);b<a;b++){ |
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295 | bt->locacf->data[0][a*(acfmi)+b-1] = |
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296 | bt->acf->data[0][a*(acfmi)+b-1]; |
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297 | } |
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298 | } |
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299 | |
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300 | for(i=0;i<numelem;i++){ |
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301 | |
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302 | maxind = 0; |
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303 | maxval = 0.0; |
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304 | |
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305 | for (j=0;j<(acfmi*(i+1)+(i)); j++){ |
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306 | if(bt->locacf->data[0][j]>maxval){ |
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307 | maxval = bt->locacf->data[0][j]; |
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308 | maxind = j; |
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309 | } |
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310 | //bt->locacf->data[0][maxind] = 0.; |
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311 | bt->locacf->data[0][j] = 0.; |
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312 | } |
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313 | //AUBIO_DBG("\n maxind is %d\n",maxind); |
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314 | bt->inds->data[0][i] = maxind; |
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315 | |
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316 | } |
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317 | |
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318 | for (i=0;i<numelem;i++){ |
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319 | period += bt->inds->data[0][i]/(i+1.);} |
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320 | |
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321 | period = period/numelem; |
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322 | |
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323 | return (period); |
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324 | } |
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325 | |
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326 | |
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327 | void aubio_beattracking_checkstate(aubio_beattracking_t * bt) { |
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328 | uint_t i,j,a,b; |
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329 | uint_t flagconst = 0; |
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330 | sint_t counter = bt->counter; |
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331 | uint_t flagstep = bt->flagstep; |
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332 | uint_t gp = bt->gp; |
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333 | uint_t bp = bt->bp; |
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334 | uint_t rp = bt->rp; |
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335 | uint_t rp1 = bt->rp1; |
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336 | uint_t rp2 = bt->rp2; |
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337 | uint_t laglen = bt->rwv->length; |
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338 | uint_t acflen = bt->acf->length; |
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339 | uint_t step = bt->step; |
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340 | smpl_t * acf = bt->acf->data[0]; |
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341 | smpl_t * acfout = bt->acfout->data[0]; |
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342 | smpl_t * gwv = bt->gwv->data[0]; |
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343 | smpl_t * phwv = bt->phwv->data[0]; |
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344 | |
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345 | if (gp) { |
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346 | // doshiftfbank again only if context dependent model is in operation |
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347 | //acfout = doshiftfbank(acf,gwv,timesig,laglen,acfout); |
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348 | //don't need acfout now, so can reuse vector |
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349 | // gwv is, in first loop, definitely all zeros, but will have |
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350 | // proper values when context dependent model is activated |
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351 | for (i=0; i < bt->acfout->length; i++) |
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352 | acfout[i] = 0.; |
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353 | for(i=1;i<laglen-1;i++){ |
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354 | for (a=1;a<=bt->timesig;a++){ |
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355 | for(b=(1-a);b<a;b++){ |
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356 | acfout[i] += acf[a*(i+1)+b-1] |
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357 | * 1. * gwv[i]; |
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358 | } |
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359 | } |
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360 | } |
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361 | gp = vec_max_elem(bt->acfout); |
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362 | /* |
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363 | while(gp<32) gp =gp*2; |
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364 | while(gp>64) gp = gp/2; |
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365 | */ |
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366 | } else { |
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367 | //still only using general model |
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368 | gp = 0; |
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369 | } |
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370 | |
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371 | //now look for step change - i.e. a difference between gp and rp that |
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372 | // is greater than 2*constthresh - always true in first case, since gp = 0 |
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373 | if(counter == 0){ |
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374 | if(ABS(gp - rp) > 2.*bt->g_var) { |
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375 | flagstep = 1; // have observed step change. |
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376 | counter = 3; // setup 3 frame counter |
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377 | } else { |
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378 | flagstep = 0; |
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379 | } |
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380 | } |
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381 | |
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382 | //i.e. 3rd frame after flagstep initially set |
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383 | if (counter==1 && flagstep==1) { |
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384 | //check for consistency between previous beatperiod values |
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385 | if(ABS(2.*rp - rp1 -rp2) < bt->g_var) { |
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386 | //if true, can activate context dependent model |
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387 | flagconst = 1; |
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388 | counter = 0; // reset counter and flagstep |
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389 | } else { |
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390 | //if not consistent, then don't flag consistency! |
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391 | flagconst = 0; |
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392 | counter = 2; // let it look next time |
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393 | } |
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394 | } else if (counter > 0) { |
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395 | //if counter doesn't = 1, |
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396 | counter = counter-1; |
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397 | } |
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398 | |
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399 | rp2 = rp1; rp1 = rp; |
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400 | |
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401 | if (flagconst) { |
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402 | /* first run of new hypothesis */ |
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403 | gp = rp; |
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404 | bt->timesig = fvec_gettimesig(acf,acflen, gp); |
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405 | for(j=0;j<laglen;j++) |
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406 | gwv[j] = EXP(-.5*SQR((smpl_t)(j+1.-gp))/SQR(bt->g_var)); |
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407 | flagconst = 0; |
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408 | bp = gp; |
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409 | /* flat phase weighting */ |
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410 | for(j=0;j<2*laglen;j++) {phwv[j] = 1.;} |
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411 | } else if (bt->timesig) { |
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412 | /* context dependant model */ |
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413 | bp = gp; |
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414 | /* gaussian phase weighting */ |
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415 | if (step > bt->lastbeat) { |
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416 | for(j=0;j<2*laglen;j++) { |
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417 | phwv[j] = EXP(-.5*SQR((smpl_t)(1.+j-step+bt->lastbeat))/(bp/8.)); |
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418 | } |
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419 | } else { |
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420 | //AUBIO_DBG("NOT using phase weighting as step is %d and lastbeat %d \n", |
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421 | // step,bt->lastbeat); |
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422 | for(j=0;j<2*laglen;j++) {phwv[j] = 1.;} |
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423 | } |
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424 | } else { |
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425 | /* initial state */ |
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426 | bp = rp; |
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427 | /* flat phase weighting */ |
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428 | for(j=0;j<2*laglen;j++) {phwv[j] = 1.;} |
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429 | } |
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430 | |
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431 | /* do some further checks on the final bp value */ |
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432 | |
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433 | /* if tempo is > 206 bpm, half it */ |
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434 | while (bp < 25) { |
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435 | //AUBIO_DBG("warning, doubling the beat period from %d\n", bp); |
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436 | //AUBIO_DBG("warning, halving the tempo from %f\n", 60.*samplerate/hopsize/bp); |
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437 | bp = bp*2; |
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438 | } |
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439 | |
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440 | //AUBIO_DBG("tempo:\t%3.5f bpm | ", 5168./bp); |
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441 | |
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442 | /* smoothing */ |
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443 | //bp = (uint_t) (0.8 * (smpl_t)bp + 0.2 * (smpl_t)bp2); |
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444 | //AUBIO_DBG("tempo:\t%3.5f bpm smoothed | bp2 %d | bp %d | ", 5168./bp, bp2, bp); |
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445 | //bp2 = bp; |
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446 | //AUBIO_DBG("time signature: %d \n", bt->timesig); |
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447 | bt->counter = counter; |
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448 | bt->flagstep = flagstep; |
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449 | bt->gp = gp; |
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450 | bt->bp = bp; |
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451 | bt->rp1 = rp1; |
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452 | bt->rp2 = rp2; |
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453 | |
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454 | } |
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455 | |
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456 | smpl_t aubio_beattracking_get_bpm(aubio_beattracking_t * bt) { |
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457 | if (bt->timesig != 0 && bt->counter == 0 && bt->flagstep == 0) { |
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458 | return 5168. / (smpl_t)bt->gp; |
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459 | } else { |
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460 | return 0.; |
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461 | } |
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462 | } |
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463 | |
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464 | smpl_t aubio_beattracking_get_confidence(aubio_beattracking_t * bt) { |
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465 | if (bt->gp) return vec_max(bt->acfout); |
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466 | else return 0.; |
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467 | } |
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