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1 #include "audioDB.h"
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2
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3 #include <gsl/gsl_sf.h>
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4 #include <gsl/gsl_rng.h>
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5
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6 static
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7 double yfun(double d) {
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8 return gsl_sf_log(d) - gsl_sf_psi(d);
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9 }
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10
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11 static
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12 double yinv(double y) {
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13 double a = 1.0e-5;
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14 double b = 1000.0;
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15
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16 double ay = yfun(a);
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17 double by = yfun(b);
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18
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19 double c = 0;
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20 double cy;
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21
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22 /* FIXME: simple binary search; there's probably some clever solver
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23 in gsl somewhere which is less sucky. */
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24 while ((b - a) > 1.0e-5) {
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25 c = (a + b) / 2;
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26 cy = yfun(c);
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27 if (cy > y) {
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28 a = c;
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29 ay = cy;
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30 } else {
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31 b = c;
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32 by = cy;
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33 }
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34 }
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35
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36 return c;
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37 }
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38
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39 unsigned audioDB::random_track(unsigned *propTable, unsigned total, gsl_rng *rng) {
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40 /* FIXME: make this O(1) by using the alias-rejection method, or
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41 some other sensible method of sampling from a discrete
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42 distribution. */
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43 double thing = gsl_rng_uniform(rng);
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44 unsigned sofar = 0;
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45 for (unsigned int i = 0; i < dbH->numFiles; i++) {
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46 sofar += propTable[i];
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47 if (thing < ((double) sofar / (double) total)) {
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48 return i;
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49 }
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50 }
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51 error("fell through in random_track()");
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52
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53 /* FIXME: decorate error's declaration so that this isn't necessary */
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54 return 0;
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55 }
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56
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57 void audioDB::sample(const char *dbName) {
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58 initTables(dbName, 0);
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59
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60 gsl_rng *rng = gsl_rng_alloc(gsl_rng_mt19937);
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61
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62 /* FIXME: in Real Life we'll want to initialize the RNG using
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63 /dev/random or the current time or something, like this:
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64
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65 unsigned int seed;
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66 int fd = open("/dev/urandom", O_RDONLY);
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67 read(fd, &seed, 4);
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68
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69 gsl_rng_set(rng, seed);
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70 */
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71
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72 // build track offset table (FIXME: cut'n'pasted from query.cpp)
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73 off_t *trackOffsetTable = new off_t[dbH->numFiles];
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74 unsigned cumTrack=0;
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75 for(unsigned int k = 0; k < dbH->numFiles; k++){
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76 trackOffsetTable[k] = cumTrack;
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77 cumTrack += trackTable[k] * dbH->dim;
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78 }
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79
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80 unsigned *propTable = new unsigned[dbH->numFiles];
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81 unsigned total = 0;
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82 unsigned count = 0;
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83
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84 for (unsigned int i = 0; i < dbH->numFiles; i++) {
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85 /* what kind of a stupid language doesn't have binary max(), let
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86 alone nary? */
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87 unsigned int prop = trackTable[i] - sequenceLength + 1;
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88 prop = prop > 0 ? prop : 0;
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89 if (prop > 0)
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90 count++;
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91 propTable[i] = prop;
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92 total += prop;
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93 }
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94
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95 if (total == 0) {
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96 error("no sequences of this sequence length in the database", dbName);
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97 }
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98
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99 unsigned int vlen = dbH->dim * sequenceLength;
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100 double *v1 = new double[vlen];
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101 double *v2 = new double[vlen];
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102 double v1norm, v2norm, v1v2;
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103
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104 double sumdist = 0;
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105 double sumlogdist = 0;
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106
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107 for (unsigned int i = 0; i < nsamples;) {
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108 unsigned track1 = random_track(propTable, total, rng);
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109 unsigned track2 = random_track(propTable, total, rng);
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110
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111 if(track1 == track2)
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112 continue;
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113
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114 unsigned i1 = gsl_rng_uniform_int(rng, propTable[track1]);
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115 unsigned i2 = gsl_rng_uniform_int(rng, propTable[track2]);
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116
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117 VERB_LOG(1, "%d %d, %d %d | ", track1, i1, track2, i2);
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118
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119 /* FIXME: this seeking, reading and distance calculation should
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120 share more code with the query loop */
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121 lseek(dbfid, dbH->dataOffset + trackOffsetTable[track1] * sizeof(double) + i1 * dbH->dim * sizeof(double), SEEK_SET);
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122 read(dbfid, v1, dbH->dim * sequenceLength * sizeof(double));
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123
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124 lseek(dbfid, dbH->dataOffset + trackOffsetTable[track2] * sizeof(double) + i2 * dbH->dim * sizeof(double), SEEK_SET);
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125 read(dbfid, v2, dbH->dim * sequenceLength * sizeof(double));
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126
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127 v1norm = 0;
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128 v2norm = 0;
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129 v1v2 = 0;
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130
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131 for (unsigned int j = 0; j < vlen; j++) {
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132 v1norm += v1[j]*v1[j];
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133 v2norm += v2[j]*v2[j];
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134 v1v2 += v1[j]*v2[j];
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135 }
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136
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137 /* FIXME: we must deal with infinities better than this; there
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138 could be all sorts of NaNs from arbitrary features. Best
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139 include power thresholds or something... */
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140 if(isfinite(v1norm) && isfinite(v2norm) && isfinite(v1v2)) {
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141
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142 VERB_LOG(1, "%f %f %f | ", v1norm, v2norm, v1v2);
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143 /* assume normalizedDistance == true for now */
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144 /* FIXME: not convinced that the statistics we calculated in
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145 TASLP paper are technically valid for normalizedDistance */
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146
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147 double dist = 2 - 2 * v1v2 / sqrt(v1norm * v2norm);
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148 // double dist = v1norm + v2norm - 2*v1v2;
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149
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150 VERB_LOG(1, "%f %f\n", dist, log(dist));
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151 sumdist += dist;
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152 sumlogdist += log(dist);
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153 i++;
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154 } else {
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155 VERB_LOG(1, "infinity/NaN found: %f %f %f\n", v1norm, v2norm, v1v2);
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156 }
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157 }
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158
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159 /* FIXME: the mean isn't really what we should be reporting here */
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160 unsigned meanN = total / count;
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161
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162 double sigma2 = sumdist / (sequenceLength * dbH->dim * nsamples);
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163 double d = 2 * yinv(log(sumdist/nsamples) - sumlogdist/nsamples);
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164
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165 std::cout << "Summary statistics" << std::endl;
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166 std::cout << "number of samples: " << nsamples << std::endl;
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167 std::cout << "sum of distances (S): " << sumdist << std::endl;
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168 std::cout << "sum of log distances (L): " << sumlogdist << std::endl;
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169
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170 /* FIXME: we'll also want some more summary statistics based on
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171 propTable, for the minimum-of-X estimate */
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172 std::cout << "mean number of applicable sequences (N): " << meanN << std::endl;
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173 std::cout << std::endl;
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174 std::cout << "Estimated parameters" << std::endl;
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175 std::cout << "sigma^2: " << sigma2 << "; ";
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176 std::cout << "Msigma^2: " << sumdist / nsamples << std::endl;
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177 std::cout << "d: " << d << std::endl;
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178
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179 double logw = (2 / d) * gsl_sf_log(-gsl_sf_log(0.99));
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180 double logxthresh = gsl_sf_log(sumdist / nsamples) + logw
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181 - (2 / d) * gsl_sf_log(meanN)
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182 - gsl_sf_log(d/2)
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183 - (2 / d) * gsl_sf_log(2 / d)
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184 + (2 / d) * gsl_sf_lngamma(d / 2);
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185
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186 std::cout << "track xthresh: " << exp(logxthresh) << std::endl;
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187
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188 delete[] propTable;
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189 delete[] v1;
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190 delete[] v2;
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191 }
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