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annotate src/libsamplerate-0.1.8/tests/calc_snr.c @ 0:c7265573341e

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Import initial set of sources
author Chris Cannam
date Mon, 18 Mar 2013 14:12:14 +0000
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Chris@0 1 /*
Chris@0 2 ** Copyright (C) 2002-2011 Erik de Castro Lopo <erikd@mega-nerd.com>
Chris@0 3 **
Chris@0 4 ** This program is free software; you can redistribute it and/or modify
Chris@0 5 ** it under the terms of the GNU General Public License as published by
Chris@0 6 ** the Free Software Foundation; either version 2 of the License, or
Chris@0 7 ** (at your option) any later version.
Chris@0 8 **
Chris@0 9 ** This program is distributed in the hope that it will be useful,
Chris@0 10 ** but WITHOUT ANY WARRANTY; without even the implied warranty of
Chris@0 11 ** MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
Chris@0 12 ** GNU General Public License for more details.
Chris@0 13 **
Chris@0 14 ** You should have received a copy of the GNU General Public License
Chris@0 15 ** along with this program; if not, write to the Free Software
Chris@0 16 ** Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307, USA.
Chris@0 17 */
Chris@0 18
Chris@0 19 #include "config.h"
Chris@0 20
Chris@0 21 #include "util.h"
Chris@0 22
Chris@0 23 #if (HAVE_FFTW3 == 1)
Chris@0 24
Chris@0 25 #include <stdio.h>
Chris@0 26 #include <stdlib.h>
Chris@0 27 #include <string.h>
Chris@0 28 #include <math.h>
Chris@0 29
Chris@0 30 #include <fftw3.h>
Chris@0 31
Chris@0 32 #define MAX_SPEC_LEN (1<<18)
Chris@0 33 #define MAX_PEAKS 10
Chris@0 34
Chris@0 35 static void log_mag_spectrum (double *input, int len, double *magnitude) ;
Chris@0 36 static void smooth_mag_spectrum (double *magnitude, int len) ;
Chris@0 37 static double find_snr (const double *magnitude, int len, int expected_peaks) ;
Chris@0 38
Chris@0 39 typedef struct
Chris@0 40 { double peak ;
Chris@0 41 int index ;
Chris@0 42 } PEAK_DATA ;
Chris@0 43
Chris@0 44 double
Chris@0 45 calculate_snr (float *data, int len, int expected_peaks)
Chris@0 46 { static double magnitude [MAX_SPEC_LEN] ;
Chris@0 47 static double datacopy [MAX_SPEC_LEN] ;
Chris@0 48
Chris@0 49 double snr = 200.0 ;
Chris@0 50 int k ;
Chris@0 51
Chris@0 52 if (len > MAX_SPEC_LEN)
Chris@0 53 { printf ("%s : line %d : data length too large.\n", __FILE__, __LINE__) ;
Chris@0 54 exit (1) ;
Chris@0 55 } ;
Chris@0 56
Chris@0 57 for (k = 0 ; k < len ; k++)
Chris@0 58 datacopy [k] = data [k] ;
Chris@0 59
Chris@0 60 /* Pad the data just a little to speed up the FFT. */
Chris@0 61 while ((len & 0x1F) && len < MAX_SPEC_LEN)
Chris@0 62 { datacopy [len] = 0.0 ;
Chris@0 63 len ++ ;
Chris@0 64 } ;
Chris@0 65
Chris@0 66 log_mag_spectrum (datacopy, len, magnitude) ;
Chris@0 67 smooth_mag_spectrum (magnitude, len / 2) ;
Chris@0 68
Chris@0 69 snr = find_snr (magnitude, len, expected_peaks) ;
Chris@0 70
Chris@0 71 return snr ;
Chris@0 72 } /* calculate_snr */
Chris@0 73
Chris@0 74 /*==============================================================================
Chris@0 75 ** There is a slight problem with trying to measure SNR with the method used
Chris@0 76 ** here; the side lobes of the windowed FFT can look like a noise/aliasing peak.
Chris@0 77 ** The solution is to smooth the magnitude spectrum by wiping out troughs
Chris@0 78 ** between adjacent peaks as done here.
Chris@0 79 ** This removes side lobe peaks without affecting noise/aliasing peaks.
Chris@0 80 */
Chris@0 81
Chris@0 82 static void linear_smooth (double *mag, PEAK_DATA *larger, PEAK_DATA *smaller) ;
Chris@0 83
Chris@0 84 static void
Chris@0 85 smooth_mag_spectrum (double *mag, int len)
Chris@0 86 { PEAK_DATA peaks [2] ;
Chris@0 87
Chris@0 88 int k ;
Chris@0 89
Chris@0 90 memset (peaks, 0, sizeof (peaks)) ;
Chris@0 91
Chris@0 92 /* Find first peak. */
Chris@0 93 for (k = 1 ; k < len - 1 ; k++)
Chris@0 94 { if (mag [k - 1] < mag [k] && mag [k] >= mag [k + 1])
Chris@0 95 { peaks [0].peak = mag [k] ;
Chris@0 96 peaks [0].index = k ;
Chris@0 97 break ;
Chris@0 98 } ;
Chris@0 99 } ;
Chris@0 100
Chris@0 101 /* Find subsequent peaks ans smooth between peaks. */
Chris@0 102 for (k = peaks [0].index + 1 ; k < len - 1 ; k++)
Chris@0 103 { if (mag [k - 1] < mag [k] && mag [k] >= mag [k + 1])
Chris@0 104 { peaks [1].peak = mag [k] ;
Chris@0 105 peaks [1].index = k ;
Chris@0 106
Chris@0 107 if (peaks [1].peak > peaks [0].peak)
Chris@0 108 linear_smooth (mag, &peaks [1], &peaks [0]) ;
Chris@0 109 else
Chris@0 110 linear_smooth (mag, &peaks [0], &peaks [1]) ;
Chris@0 111 peaks [0] = peaks [1] ;
Chris@0 112 } ;
Chris@0 113 } ;
Chris@0 114
Chris@0 115 } /* smooth_mag_spectrum */
Chris@0 116
Chris@0 117 static void
Chris@0 118 linear_smooth (double *mag, PEAK_DATA *larger, PEAK_DATA *smaller)
Chris@0 119 { int k ;
Chris@0 120
Chris@0 121 if (smaller->index < larger->index)
Chris@0 122 { for (k = smaller->index + 1 ; k < larger->index ; k++)
Chris@0 123 mag [k] = (mag [k] < mag [k - 1]) ? 0.999 * mag [k - 1] : mag [k] ;
Chris@0 124 }
Chris@0 125 else
Chris@0 126 { for (k = smaller->index - 1 ; k >= larger->index ; k--)
Chris@0 127 mag [k] = (mag [k] < mag [k + 1]) ? 0.999 * mag [k + 1] : mag [k] ;
Chris@0 128 } ;
Chris@0 129
Chris@0 130 } /* linear_smooth */
Chris@0 131
Chris@0 132 /*==============================================================================
Chris@0 133 */
Chris@0 134
Chris@0 135 static int
Chris@0 136 peak_compare (const void *vp1, const void *vp2)
Chris@0 137 { const PEAK_DATA *peak1, *peak2 ;
Chris@0 138
Chris@0 139 peak1 = (const PEAK_DATA*) vp1 ;
Chris@0 140 peak2 = (const PEAK_DATA*) vp2 ;
Chris@0 141
Chris@0 142 return (peak1->peak < peak2->peak) ? 1 : -1 ;
Chris@0 143 } /* peak_compare */
Chris@0 144
Chris@0 145 static double
Chris@0 146 find_snr (const double *magnitude, int len, int expected_peaks)
Chris@0 147 { PEAK_DATA peaks [MAX_PEAKS] ;
Chris@0 148
Chris@0 149 int k, peak_count = 0 ;
Chris@0 150 double snr ;
Chris@0 151
Chris@0 152 memset (peaks, 0, sizeof (peaks)) ;
Chris@0 153
Chris@0 154 /* Find the MAX_PEAKS largest peaks. */
Chris@0 155 for (k = 1 ; k < len - 1 ; k++)
Chris@0 156 { if (magnitude [k - 1] < magnitude [k] && magnitude [k] >= magnitude [k + 1])
Chris@0 157 { if (peak_count < MAX_PEAKS)
Chris@0 158 { peaks [peak_count].peak = magnitude [k] ;
Chris@0 159 peaks [peak_count].index = k ;
Chris@0 160 peak_count ++ ;
Chris@0 161 qsort (peaks, peak_count, sizeof (PEAK_DATA), peak_compare) ;
Chris@0 162 }
Chris@0 163 else if (magnitude [k] > peaks [MAX_PEAKS - 1].peak)
Chris@0 164 { peaks [MAX_PEAKS - 1].peak = magnitude [k] ;
Chris@0 165 peaks [MAX_PEAKS - 1].index = k ;
Chris@0 166 qsort (peaks, MAX_PEAKS, sizeof (PEAK_DATA), peak_compare) ;
Chris@0 167 } ;
Chris@0 168 } ;
Chris@0 169 } ;
Chris@0 170
Chris@0 171 if (peak_count < expected_peaks)
Chris@0 172 { printf ("\n%s : line %d : bad peak_count (%d), expected %d.\n\n", __FILE__, __LINE__, peak_count, expected_peaks) ;
Chris@0 173 return -1.0 ;
Chris@0 174 } ;
Chris@0 175
Chris@0 176 /* Sort the peaks. */
Chris@0 177 qsort (peaks, peak_count, sizeof (PEAK_DATA), peak_compare) ;
Chris@0 178
Chris@0 179 snr = peaks [0].peak ;
Chris@0 180 for (k = 1 ; k < peak_count ; k++)
Chris@0 181 if (fabs (snr - peaks [k].peak) > 10.0)
Chris@0 182 return fabs (peaks [k].peak) ;
Chris@0 183
Chris@0 184 return snr ;
Chris@0 185 } /* find_snr */
Chris@0 186
Chris@0 187 static void
Chris@0 188 log_mag_spectrum (double *input, int len, double *magnitude)
Chris@0 189 { fftw_plan plan = NULL ;
Chris@0 190
Chris@0 191 double maxval ;
Chris@0 192 int k ;
Chris@0 193
Chris@0 194 if (input == NULL || magnitude == NULL)
Chris@0 195 return ;
Chris@0 196
Chris@0 197 plan = fftw_plan_r2r_1d (len, input, magnitude, FFTW_R2HC, FFTW_ESTIMATE | FFTW_PRESERVE_INPUT) ;
Chris@0 198 if (plan == NULL)
Chris@0 199 { printf ("%s : line %d : create plan failed.\n", __FILE__, __LINE__) ;
Chris@0 200 exit (1) ;
Chris@0 201 } ;
Chris@0 202
Chris@0 203 fftw_execute (plan) ;
Chris@0 204
Chris@0 205 fftw_destroy_plan (plan) ;
Chris@0 206
Chris@0 207 /* (k < N/2 rounded up) */
Chris@0 208 maxval = 0.0 ;
Chris@0 209 for (k = 1 ; k < len / 2 ; k++)
Chris@0 210 { magnitude [k] = sqrt (magnitude [k] * magnitude [k] + magnitude [len - k - 1] * magnitude [len - k - 1]) ;
Chris@0 211 maxval = (maxval < magnitude [k]) ? magnitude [k] : maxval ;
Chris@0 212 } ;
Chris@0 213
Chris@0 214 memset (magnitude + len / 2, 0, len / 2 * sizeof (magnitude [0])) ;
Chris@0 215
Chris@0 216 /* Don't care about DC component. Make it zero. */
Chris@0 217 magnitude [0] = 0.0 ;
Chris@0 218
Chris@0 219 /* log magnitude. */
Chris@0 220 for (k = 0 ; k < len ; k++)
Chris@0 221 { magnitude [k] = magnitude [k] / maxval ;
Chris@0 222 magnitude [k] = (magnitude [k] < 1e-15) ? -200.0 : 20.0 * log10 (magnitude [k]) ;
Chris@0 223 } ;
Chris@0 224
Chris@0 225 return ;
Chris@0 226 } /* log_mag_spectrum */
Chris@0 227
Chris@0 228 #else /* ! (HAVE_LIBFFTW && HAVE_LIBRFFTW) */
Chris@0 229
Chris@0 230 double
Chris@0 231 calculate_snr (float *data, int len, int expected_peaks)
Chris@0 232 { double snr = 200.0 ;
Chris@0 233
Chris@0 234 data = data ;
Chris@0 235 len = len ;
Chris@0 236 expected_peaks = expected_peaks ;
Chris@0 237
Chris@0 238 return snr ;
Chris@0 239 } /* calculate_snr */
Chris@0 240
Chris@0 241 #endif
Chris@0 242