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annotate src/libsamplerate-0.1.9/tests/termination_test.c @ 146:206f0eb279b8

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Remove "other" Vamp SDK repo from sv-dependency-builds
author Chris Cannam <cannam@all-day-breakfast.com>
date Mon, 06 Mar 2017 13:29:58 +0000
parents 4a7071416412
children
rev   line source
cannam@126 1 /*
cannam@126 2 ** Copyright (c) 2002-2016, Erik de Castro Lopo <erikd@mega-nerd.com>
cannam@126 3 ** All rights reserved.
cannam@126 4 **
cannam@126 5 ** This code is released under 2-clause BSD license. Please see the
cannam@126 6 ** file at : https://github.com/erikd/libsamplerate/blob/master/COPYING
cannam@126 7 */
cannam@126 8
cannam@126 9 #include <stdio.h>
cannam@126 10 #include <stdlib.h>
cannam@126 11 #include <math.h>
cannam@126 12
cannam@126 13 #include <samplerate.h>
cannam@126 14
cannam@126 15 #include "util.h"
cannam@126 16
cannam@126 17 #define SHORT_BUFFER_LEN 2048
cannam@126 18 #define LONG_BUFFER_LEN ((1 << 16) - 20)
cannam@126 19
cannam@126 20 static void simple_test (int converter) ;
cannam@126 21 static void stream_test (int converter, double ratio) ;
cannam@126 22 static void init_term_test (int converter, double ratio) ;
cannam@126 23
cannam@126 24 static int next_block_length (int reset) ;
cannam@126 25
cannam@126 26 int
cannam@126 27 main (void)
cannam@126 28 { static double src_ratios [] =
cannam@126 29 { 0.999900, 1.000100, 0.789012, 1.200000, 0.333333, 3.100000,
cannam@126 30 0.125000, 8.000000, 0.099900, 9.990000, 0.100000, 10.00000
cannam@126 31 } ;
cannam@126 32
cannam@126 33 int k ;
cannam@126 34
cannam@126 35 puts ("\n Zero Order Hold interpolator:") ;
cannam@126 36
cannam@126 37 for (k = 0 ; k < ARRAY_LEN (src_ratios) ; k++)
cannam@126 38 init_term_test (SRC_ZERO_ORDER_HOLD, src_ratios [k]) ;
cannam@126 39 puts ("") ;
cannam@126 40 for (k = 0 ; k < ARRAY_LEN (src_ratios) ; k++)
cannam@126 41 stream_test (SRC_ZERO_ORDER_HOLD, src_ratios [k]) ;
cannam@126 42
cannam@126 43
cannam@126 44 puts ("\n Linear interpolator:") ;
cannam@126 45 for (k = 0 ; k < ARRAY_LEN (src_ratios) ; k++)
cannam@126 46 init_term_test (SRC_LINEAR, src_ratios [k]) ;
cannam@126 47 puts ("") ;
cannam@126 48 for (k = 0 ; k < ARRAY_LEN (src_ratios) ; k++)
cannam@126 49 stream_test (SRC_LINEAR, src_ratios [k]) ;
cannam@126 50
cannam@126 51
cannam@126 52 puts ("\n Sinc interpolator:") ;
cannam@126 53 for (k = 0 ; k < ARRAY_LEN (src_ratios) ; k++)
cannam@126 54 init_term_test (SRC_SINC_FASTEST, src_ratios [k]) ;
cannam@126 55 puts ("") ;
cannam@126 56 for (k = 0 ; k < ARRAY_LEN (src_ratios) ; k++)
cannam@126 57 stream_test (SRC_SINC_FASTEST, src_ratios [k]) ;
cannam@126 58
cannam@126 59 puts ("") ;
cannam@126 60
cannam@126 61 simple_test (SRC_SINC_FASTEST) ;
cannam@126 62
cannam@126 63 return 0 ;
cannam@126 64 } /* main */
cannam@126 65
cannam@126 66 static void
cannam@126 67 simple_test (int converter)
cannam@126 68 {
cannam@126 69 int ilen = 199030, olen = 1000, error ;
cannam@126 70
cannam@126 71 {
cannam@126 72 float in [ilen] ;
cannam@126 73 float out [olen] ;
cannam@126 74 double ratio = (1.0 * olen) / ilen ;
cannam@126 75 SRC_DATA src_data =
cannam@126 76 { in, out,
cannam@126 77 ilen, olen,
cannam@126 78 0, 0, 0,
cannam@126 79 ratio
cannam@126 80 } ;
cannam@126 81
cannam@126 82 error = src_simple (&src_data, converter, 1) ;
cannam@126 83 if (error)
cannam@126 84 { printf ("\n\nLine %d : %s\n\n", __LINE__, src_strerror (error)) ;
cannam@126 85 exit (1) ;
cannam@126 86 } ;
cannam@126 87 } ;
cannam@126 88
cannam@126 89 return ;
cannam@126 90 } /* simple_test */
cannam@126 91
cannam@126 92 static void
cannam@126 93 init_term_test (int converter, double src_ratio)
cannam@126 94 { static float input [SHORT_BUFFER_LEN], output [SHORT_BUFFER_LEN] ;
cannam@126 95
cannam@126 96 SRC_DATA src_data ;
cannam@126 97
cannam@126 98 int k, input_len, output_len, error, terminate ;
cannam@126 99
cannam@126 100 printf ("\tinit_term_test (SRC ratio = %7.4f) .......... ", src_ratio) ;
cannam@126 101 fflush (stdout) ;
cannam@126 102
cannam@126 103 /* Calculate maximun input and output lengths. */
cannam@126 104 if (src_ratio >= 1.0)
cannam@126 105 { output_len = SHORT_BUFFER_LEN ;
cannam@126 106 input_len = (int) floor (SHORT_BUFFER_LEN / src_ratio) ;
cannam@126 107 }
cannam@126 108 else
cannam@126 109 { input_len = SHORT_BUFFER_LEN ;
cannam@126 110 output_len = (int) floor (SHORT_BUFFER_LEN * src_ratio) ;
cannam@126 111 } ;
cannam@126 112
cannam@126 113 /* Reduce input_len by 10 so output is longer than necessary. */
cannam@126 114 input_len -= 10 ;
cannam@126 115
cannam@126 116 for (k = 0 ; k < ARRAY_LEN (input) ; k++)
cannam@126 117 input [k] = 1.0 ;
cannam@126 118
cannam@126 119 if (output_len > SHORT_BUFFER_LEN)
cannam@126 120 { printf ("\n\nLine %d : output_len > SHORT_BUFFER_LEN\n\n", __LINE__) ;
cannam@126 121 exit (1) ;
cannam@126 122 } ;
cannam@126 123
cannam@126 124 src_data.data_in = input ;
cannam@126 125 src_data.input_frames = input_len ;
cannam@126 126
cannam@126 127 src_data.src_ratio = src_ratio ;
cannam@126 128
cannam@126 129 src_data.data_out = output ;
cannam@126 130 src_data.output_frames = SHORT_BUFFER_LEN ;
cannam@126 131
cannam@126 132 if ((error = src_simple (&src_data, converter, 1)))
cannam@126 133 { printf ("\n\nLine %d : %s\n\n", __LINE__, src_strerror (error)) ;
cannam@126 134 exit (1) ;
cannam@126 135 } ;
cannam@126 136
cannam@126 137 terminate = (int) ceil ((src_ratio >= 1.0) ? 1 : 1.0 / src_ratio) ;
cannam@126 138
cannam@126 139 if (fabs (src_ratio * input_len - src_data.output_frames_gen) > terminate)
cannam@126 140 { printf ("\n\nLine %d : Bad output frame count.\n\n", __LINE__) ;
cannam@126 141 printf ("\tterminate : %d\n", terminate) ;
cannam@126 142 printf ("\tsrc_ratio : %.4f\n", src_ratio) ;
cannam@126 143 printf ("\tinput_len : %d\n"
cannam@126 144 "\tinput_len * src_ratio : %f\n", input_len, input_len * src_ratio) ;
cannam@126 145 printf ("\toutput_frames_gen : %ld\n\n", src_data.output_frames_gen) ;
cannam@126 146 exit (1) ;
cannam@126 147 } ;
cannam@126 148
cannam@126 149 if (labs (src_data.input_frames_used - input_len) > 1)
cannam@126 150 { printf ("\n\nLine %d : input_frames_used should be %d, is %ld.\n\n",
cannam@126 151 __LINE__, input_len, src_data.input_frames_used) ;
cannam@126 152 printf ("\tsrc_ratio : %.4f\n", src_ratio) ;
cannam@126 153 printf ("\tinput_len : %d\n\tinput_used : %ld\n\n", input_len, src_data.input_frames_used) ;
cannam@126 154 exit (1) ;
cannam@126 155 } ;
cannam@126 156
cannam@126 157 if (fabs (output [0]) < 0.1)
cannam@126 158 { printf ("\n\nLine %d : First output sample is bad.\n\n", __LINE__) ;
cannam@126 159 printf ("\toutput [0] == %f\n\n", output [0]) ;
cannam@126 160 exit (1) ;
cannam@126 161 }
cannam@126 162
cannam@126 163 puts ("ok") ;
cannam@126 164
cannam@126 165 return ;
cannam@126 166 } /* init_term_test */
cannam@126 167
cannam@126 168 static void
cannam@126 169 stream_test (int converter, double src_ratio)
cannam@126 170 { static float input [LONG_BUFFER_LEN], output [LONG_BUFFER_LEN] ;
cannam@126 171
cannam@126 172 SRC_STATE *src_state ;
cannam@126 173 SRC_DATA src_data ;
cannam@126 174
cannam@126 175 int input_len, output_len, current_in, current_out ;
cannam@126 176 int k, error, terminate ;
cannam@126 177
cannam@126 178 printf ("\tstream_test (SRC ratio = %7.4f) .......... ", src_ratio) ;
cannam@126 179 fflush (stdout) ;
cannam@126 180
cannam@126 181 /* Erik */
cannam@126 182 for (k = 0 ; k < LONG_BUFFER_LEN ; k++) input [k] = k * 1.0 ;
cannam@126 183
cannam@126 184 /* Calculate maximun input and output lengths. */
cannam@126 185 if (src_ratio >= 1.0)
cannam@126 186 { output_len = LONG_BUFFER_LEN ;
cannam@126 187 input_len = (int) floor (LONG_BUFFER_LEN / src_ratio) ;
cannam@126 188 }
cannam@126 189 else
cannam@126 190 { input_len = LONG_BUFFER_LEN ;
cannam@126 191 output_len = (int) floor (LONG_BUFFER_LEN * src_ratio) ;
cannam@126 192 } ;
cannam@126 193
cannam@126 194 /* Reduce input_len by 10 so output is longer than necessary. */
cannam@126 195 input_len -= 20 ;
cannam@126 196
cannam@126 197 if (output_len > LONG_BUFFER_LEN)
cannam@126 198 { printf ("\n\nLine %d : output_len > LONG_BUFFER_LEN\n\n", __LINE__) ;
cannam@126 199 exit (1) ;
cannam@126 200 } ;
cannam@126 201
cannam@126 202 current_in = current_out = 0 ;
cannam@126 203
cannam@126 204 /* Perform sample rate conversion. */
cannam@126 205 if ((src_state = src_new (converter, 1, &error)) == NULL)
cannam@126 206 { printf ("\n\nLine %d : src_new() failed : %s\n\n", __LINE__, src_strerror (error)) ;
cannam@126 207 exit (1) ;
cannam@126 208 } ;
cannam@126 209
cannam@126 210 src_data.end_of_input = 0 ; /* Set this later. */
cannam@126 211
cannam@126 212 src_data.data_in = input ;
cannam@126 213
cannam@126 214 src_data.src_ratio = src_ratio ;
cannam@126 215
cannam@126 216 src_data.data_out = output ;
cannam@126 217 src_data.output_frames = ARRAY_LEN (output) / 10 ;
cannam@126 218
cannam@126 219 terminate = 1 + (int) ceil ((src_ratio >= 1.0) ? src_ratio : 1.0 / src_ratio) ;
cannam@126 220
cannam@126 221 while (1)
cannam@126 222 {
cannam@126 223 src_data.input_frames = next_block_length (0) ;
cannam@126 224 src_data.input_frames = MIN (src_data.input_frames, input_len - current_in) ;
cannam@126 225
cannam@126 226 src_data.output_frames = ARRAY_LEN (output) - current_out ;
cannam@126 227 /*-Erik MIN (src_data.output_frames, output_len - current_out) ;-*/
cannam@126 228
cannam@126 229 src_data.end_of_input = (current_in >= input_len) ? 1 : 0 ;
cannam@126 230
cannam@126 231 if ((error = src_process (src_state, &src_data)))
cannam@126 232 { printf ("\n\nLine %d : %s\n\n", __LINE__, src_strerror (error)) ;
cannam@126 233 printf (" src_data.input_frames : %ld\n", src_data.input_frames) ;
cannam@126 234 printf (" src_data.output_frames : %ld\n\n", src_data.output_frames) ;
cannam@126 235 exit (1) ;
cannam@126 236 } ;
cannam@126 237
cannam@126 238 if (src_data.end_of_input && src_data.output_frames_gen == 0)
cannam@126 239 break ;
cannam@126 240
cannam@126 241 if (src_data.input_frames_used > src_data.input_frames)
cannam@126 242 { printf ("\n\nLine %d : input_frames_used > input_frames\n\n", __LINE__) ;
cannam@126 243 printf (" src_data.input_frames : %ld\n", src_data.input_frames) ;
cannam@126 244 printf (" src_data.input_frames_used : %ld\n", src_data.input_frames_used) ;
cannam@126 245 printf (" src_data.output_frames : %ld\n", src_data.output_frames) ;
cannam@126 246 printf (" src_data.output_frames_gen : %ld\n\n", src_data.output_frames_gen) ;
cannam@126 247 exit (1) ;
cannam@126 248 } ;
cannam@126 249
cannam@126 250 if (src_data.input_frames_used < 0)
cannam@126 251 { printf ("\n\nLine %d : input_frames_used (%ld) < 0\n\n", __LINE__, src_data.input_frames_used) ;
cannam@126 252 exit (1) ;
cannam@126 253 } ;
cannam@126 254
cannam@126 255 if (src_data.output_frames_gen < 0)
cannam@126 256 { printf ("\n\nLine %d : output_frames_gen (%ld) < 0\n\n", __LINE__, src_data.output_frames_gen) ;
cannam@126 257 exit (1) ;
cannam@126 258 } ;
cannam@126 259
cannam@126 260 current_in += src_data.input_frames_used ;
cannam@126 261 current_out += src_data.output_frames_gen ;
cannam@126 262
cannam@126 263 if (current_in > input_len + terminate)
cannam@126 264 { printf ("\n\nLine %d : current_in (%d) > input_len (%d + %d)\n\n", __LINE__, current_in, input_len, terminate) ;
cannam@126 265 exit (1) ;
cannam@126 266 } ;
cannam@126 267
cannam@126 268 if (current_out > output_len)
cannam@126 269 { printf ("\n\nLine %d : current_out (%d) > output_len (%d)\n\n", __LINE__, current_out, output_len) ;
cannam@126 270 exit (1) ;
cannam@126 271 } ;
cannam@126 272
cannam@126 273 if (src_data.input_frames_used > input_len)
cannam@126 274 { printf ("\n\nLine %d : input_frames_used (%ld) > %d\n\n", __LINE__, src_data.input_frames_used, input_len) ;
cannam@126 275 exit (1) ;
cannam@126 276 } ;
cannam@126 277
cannam@126 278 if (src_data.output_frames_gen > output_len)
cannam@126 279 { printf ("\n\nLine %d : output_frames_gen (%ld) > %d\n\n", __LINE__, src_data.output_frames_gen, output_len) ;
cannam@126 280 exit (1) ;
cannam@126 281 } ;
cannam@126 282
cannam@126 283 if (src_data.data_in == NULL && src_data.output_frames_gen == 0)
cannam@126 284 break ;
cannam@126 285
cannam@126 286
cannam@126 287 src_data.data_in += src_data.input_frames_used ;
cannam@126 288 src_data.data_out += src_data.output_frames_gen ;
cannam@126 289 } ;
cannam@126 290
cannam@126 291 src_state = src_delete (src_state) ;
cannam@126 292
cannam@126 293 if (fabs (current_out - src_ratio * input_len) > terminate)
cannam@126 294 { printf ("\n\nLine %d : bad output data length %d should be %2.1f +/- %d.\n", __LINE__,
cannam@126 295 current_out, src_ratio * input_len, terminate) ;
cannam@126 296 printf ("\tsrc_ratio : %.4f\n", src_ratio) ;
cannam@126 297 printf ("\tinput_len : %d\n\tinput_used : %d\n", input_len, current_in) ;
cannam@126 298 printf ("\toutput_len : %d\n\toutput_gen : %d\n\n", output_len, current_out) ;
cannam@126 299 exit (1) ;
cannam@126 300 } ;
cannam@126 301
cannam@126 302 if (current_in != input_len)
cannam@126 303 { printf ("\n\nLine %d : unused input.\n", __LINE__) ;
cannam@126 304 printf ("\tinput_len : %d\n", input_len) ;
cannam@126 305 printf ("\tinput_frames_used : %d\n\n", current_in) ;
cannam@126 306 exit (1) ;
cannam@126 307 } ;
cannam@126 308
cannam@126 309 puts ("ok") ;
cannam@126 310
cannam@126 311 return ;
cannam@126 312 } /* stream_test */
cannam@126 313
cannam@126 314 static int
cannam@126 315 next_block_length (int reset)
cannam@126 316 { static int block_lengths [] = /* Should be an odd length. */
cannam@126 317 { /*-2, 500, 5, 400, 10, 300, 20, 200, 50, 100, 70 -*/
cannam@126 318 5, 400, 10, 300, 20, 200, 50, 100, 70
cannam@126 319 } ;
cannam@126 320 static int block_len_index = 0 ;
cannam@126 321
cannam@126 322 if (reset)
cannam@126 323 block_len_index = 0 ;
cannam@126 324 else
cannam@126 325 block_len_index = (block_len_index + 1) % ARRAY_LEN (block_lengths) ;
cannam@126 326
cannam@126 327 return block_lengths [block_len_index] ;
cannam@126 328 } /* next_block_length */
cannam@126 329