wav.c revision 1.15
1 1.15 mrg /* $NetBSD: wav.c,v 1.15 2019/11/09 12:46:44 mrg Exp $ */ 2 1.3 mrg 3 1.1 mrg /* 4 1.15 mrg * Copyright (c) 2002, 2009, 2013, 2015, 2019 Matthew R. Green 5 1.1 mrg * All rights reserved. 6 1.1 mrg * 7 1.1 mrg * Redistribution and use in source and binary forms, with or without 8 1.1 mrg * modification, are permitted provided that the following conditions 9 1.1 mrg * are met: 10 1.1 mrg * 1. Redistributions of source code must retain the above copyright 11 1.1 mrg * notice, this list of conditions and the following disclaimer. 12 1.1 mrg * 2. Redistributions in binary form must reproduce the above copyright 13 1.1 mrg * notice, this list of conditions and the following disclaimer in the 14 1.1 mrg * documentation and/or other materials provided with the distribution. 15 1.1 mrg * 16 1.1 mrg * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR 17 1.1 mrg * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES 18 1.1 mrg * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. 19 1.1 mrg * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, 20 1.1 mrg * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, 21 1.1 mrg * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; 22 1.1 mrg * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED 23 1.1 mrg * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, 24 1.1 mrg * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY 25 1.1 mrg * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF 26 1.1 mrg * SUCH DAMAGE. 27 1.1 mrg */ 28 1.1 mrg 29 1.1 mrg /* 30 1.1 mrg * WAV support for the audio tools; thanks go to the sox utility for 31 1.1 mrg * clearing up issues with WAV files. 32 1.1 mrg */ 33 1.6 agc #include <sys/cdefs.h> 34 1.6 agc 35 1.6 agc #ifndef lint 36 1.15 mrg __RCSID("$NetBSD: wav.c,v 1.15 2019/11/09 12:46:44 mrg Exp $"); 37 1.6 agc #endif 38 1.6 agc 39 1.1 mrg 40 1.1 mrg #include <sys/types.h> 41 1.1 mrg #include <sys/audioio.h> 42 1.1 mrg #include <sys/ioctl.h> 43 1.1 mrg #include <sys/time.h> 44 1.1 mrg 45 1.1 mrg #include <ctype.h> 46 1.1 mrg #include <err.h> 47 1.1 mrg #include <stdio.h> 48 1.1 mrg #include <stdlib.h> 49 1.1 mrg #include <string.h> 50 1.9 mrg #include <stdint.h> 51 1.11 mrg #include <unistd.h> 52 1.1 mrg 53 1.1 mrg #include "libaudio.h" 54 1.11 mrg #include "auconv.h" 55 1.1 mrg 56 1.10 joerg static const struct { 57 1.1 mrg int wenc; 58 1.2 mrg const char *wname; 59 1.1 mrg } wavencs[] = { 60 1.1 mrg { WAVE_FORMAT_UNKNOWN, "Microsoft Official Unknown" }, 61 1.1 mrg { WAVE_FORMAT_PCM, "Microsoft PCM" }, 62 1.1 mrg { WAVE_FORMAT_ADPCM, "Microsoft ADPCM" }, 63 1.15 mrg { WAVE_FORMAT_IEEE_FLOAT,"Microsoft IEEE Floating-Point" }, 64 1.1 mrg { WAVE_FORMAT_ALAW, "Microsoft A-law" }, 65 1.5 wiz { WAVE_FORMAT_MULAW, "Microsoft mu-law" }, 66 1.1 mrg { WAVE_FORMAT_OKI_ADPCM,"OKI ADPCM" }, 67 1.1 mrg { WAVE_FORMAT_DIGISTD, "Digistd format" }, 68 1.1 mrg { WAVE_FORMAT_DIGIFIX, "Digifix format" }, 69 1.1 mrg { -1, "?Unknown?" }, 70 1.1 mrg }; 71 1.1 mrg 72 1.2 mrg const char * 73 1.2 mrg wav_enc_from_val(int encoding) 74 1.1 mrg { 75 1.1 mrg int i; 76 1.1 mrg 77 1.1 mrg for (i = 0; wavencs[i].wenc != -1; i++) 78 1.1 mrg if (wavencs[i].wenc == encoding) 79 1.1 mrg break; 80 1.1 mrg return (wavencs[i].wname); 81 1.1 mrg } 82 1.1 mrg 83 1.1 mrg /* 84 1.1 mrg * sample header is: 85 1.1 mrg * 86 1.1 mrg * RIFF\^@^C^@WAVEfmt ^P^@^@^@^A^@^B^@D<AC>^@^@^P<B1>^B^@^D^@^P^@data^@^@^C^@^@^@^@^@^@^@^@^@^@ 87 1.1 mrg * 88 1.1 mrg */ 89 1.1 mrg /* 90 1.1 mrg * WAV format helpers 91 1.1 mrg */ 92 1.1 mrg /* 93 1.1 mrg * find a .wav header, etc. returns header length on success 94 1.1 mrg */ 95 1.1 mrg ssize_t 96 1.10 joerg audio_wav_parse_hdr(void *hdr, size_t sz, u_int *enc, u_int *prec, 97 1.13 mrg u_int *sample, u_int *channels, off_t *datasize) 98 1.1 mrg { 99 1.1 mrg char *where = hdr, *owhere; 100 1.1 mrg wav_audioheaderpart part; 101 1.1 mrg wav_audioheaderfmt fmt; 102 1.9 mrg wav_audiohdrextensible ext; 103 1.1 mrg char *end = (((char *)hdr) + sz); 104 1.7 mrg u_int newenc, newprec; 105 1.9 mrg u_int16_t fmttag; 106 1.2 mrg static const char 107 1.2 mrg strfmt[4] = "fmt ", 108 1.2 mrg strRIFF[4] = "RIFF", 109 1.2 mrg strWAVE[4] = "WAVE", 110 1.2 mrg strdata[4] = "data"; 111 1.2 mrg 112 1.1 mrg if (sz < 32) 113 1.1 mrg return (AUDIO_ENOENT); 114 1.1 mrg 115 1.2 mrg if (strncmp(where, strRIFF, sizeof strRIFF)) 116 1.1 mrg return (AUDIO_ENOENT); 117 1.1 mrg where += 8; 118 1.2 mrg if (strncmp(where, strWAVE, sizeof strWAVE)) 119 1.1 mrg return (AUDIO_ENOENT); 120 1.1 mrg where += 4; 121 1.1 mrg 122 1.1 mrg do { 123 1.1 mrg memcpy(&part, where, sizeof part); 124 1.1 mrg owhere = where; 125 1.1 mrg where += getle32(part.len) + 8; 126 1.2 mrg } while (where < end && strncmp(part.name, strfmt, sizeof strfmt)); 127 1.1 mrg 128 1.1 mrg /* too short ? */ 129 1.1 mrg if (where + sizeof fmt > end) 130 1.1 mrg return (AUDIO_ESHORTHDR); 131 1.1 mrg 132 1.1 mrg memcpy(&fmt, (owhere + 8), sizeof fmt); 133 1.1 mrg 134 1.9 mrg fmttag = getle16(fmt.tag); 135 1.9 mrg if (verbose) 136 1.9 mrg printf("WAVE format tag: %x\n", fmttag); 137 1.9 mrg 138 1.9 mrg if (fmttag == WAVE_FORMAT_EXTENSIBLE) { 139 1.9 mrg if ((uintptr_t)(where - owhere) < sizeof(fmt) + sizeof(ext)) 140 1.9 mrg return (AUDIO_ESHORTHDR); 141 1.9 mrg memcpy(&ext, owhere + sizeof fmt, sizeof ext); 142 1.9 mrg if (getle16(ext.len) < sizeof(ext) - sizeof(ext.len)) 143 1.9 mrg return (AUDIO_ESHORTHDR); 144 1.14 jdolecek fmttag = getle16(ext.sub_tag); 145 1.9 mrg if (verbose) 146 1.9 mrg printf("WAVE extensible sub tag: %x\n", fmttag); 147 1.9 mrg } 148 1.9 mrg 149 1.9 mrg switch (fmttag) { 150 1.1 mrg case WAVE_FORMAT_UNKNOWN: 151 1.1 mrg case IBM_FORMAT_MULAW: 152 1.1 mrg case IBM_FORMAT_ALAW: 153 1.1 mrg case IBM_FORMAT_ADPCM: 154 1.1 mrg default: 155 1.1 mrg return (AUDIO_EWAVUNSUPP); 156 1.1 mrg 157 1.1 mrg case WAVE_FORMAT_PCM: 158 1.9 mrg case WAVE_FORMAT_ADPCM: 159 1.9 mrg case WAVE_FORMAT_OKI_ADPCM: 160 1.9 mrg case WAVE_FORMAT_IMA_ADPCM: 161 1.9 mrg case WAVE_FORMAT_DIGIFIX: 162 1.9 mrg case WAVE_FORMAT_DIGISTD: 163 1.1 mrg switch (getle16(fmt.bits_per_sample)) { 164 1.1 mrg case 8: 165 1.1 mrg newprec = 8; 166 1.1 mrg break; 167 1.1 mrg case 16: 168 1.1 mrg newprec = 16; 169 1.1 mrg break; 170 1.1 mrg case 24: 171 1.1 mrg newprec = 24; 172 1.1 mrg break; 173 1.1 mrg case 32: 174 1.1 mrg newprec = 32; 175 1.1 mrg break; 176 1.1 mrg default: 177 1.1 mrg return (AUDIO_EWAVBADPCM); 178 1.1 mrg } 179 1.1 mrg if (newprec == 8) 180 1.1 mrg newenc = AUDIO_ENCODING_ULINEAR_LE; 181 1.1 mrg else 182 1.1 mrg newenc = AUDIO_ENCODING_SLINEAR_LE; 183 1.1 mrg break; 184 1.1 mrg case WAVE_FORMAT_ALAW: 185 1.1 mrg newenc = AUDIO_ENCODING_ALAW; 186 1.1 mrg newprec = 8; 187 1.1 mrg break; 188 1.1 mrg case WAVE_FORMAT_MULAW: 189 1.1 mrg newenc = AUDIO_ENCODING_ULAW; 190 1.1 mrg newprec = 8; 191 1.1 mrg break; 192 1.15 mrg case WAVE_FORMAT_IEEE_FLOAT: 193 1.15 mrg switch (getle16(fmt.bits_per_sample)) { 194 1.15 mrg case 32: 195 1.15 mrg newenc = AUDIO_ENCODING_LIBAUDIO_FLOAT32; 196 1.15 mrg newprec = 32; 197 1.15 mrg break; 198 1.15 mrg case 64: 199 1.15 mrg newenc = AUDIO_ENCODING_LIBAUDIO_FLOAT64; 200 1.15 mrg newprec = 32; 201 1.15 mrg break; 202 1.15 mrg default: 203 1.15 mrg return (AUDIO_EWAVBADPCM); 204 1.15 mrg } 205 1.15 mrg break; 206 1.1 mrg } 207 1.1 mrg 208 1.1 mrg do { 209 1.1 mrg memcpy(&part, where, sizeof part); 210 1.1 mrg owhere = where; 211 1.1 mrg where += (getle32(part.len) + 8); 212 1.2 mrg } while (where < end && strncmp(part.name, strdata, sizeof strdata)); 213 1.1 mrg 214 1.1 mrg if ((where - getle32(part.len)) <= end) { 215 1.1 mrg if (channels) 216 1.7 mrg *channels = (u_int)getle16(fmt.channels); 217 1.1 mrg if (sample) 218 1.1 mrg *sample = getle32(fmt.sample_rate); 219 1.1 mrg if (enc) 220 1.1 mrg *enc = newenc; 221 1.1 mrg if (prec) 222 1.1 mrg *prec = newprec; 223 1.1 mrg if (datasize) 224 1.13 mrg *datasize = (off_t)getle32(part.len); 225 1.1 mrg return (owhere - (char *)hdr + 8); 226 1.1 mrg } 227 1.1 mrg return (AUDIO_EWAVNODATA); 228 1.1 mrg } 229 1.11 mrg 230 1.11 mrg 231 1.11 mrg /* 232 1.11 mrg * prepare a WAV header for writing; we fill in hdrp, lenp and leftp, 233 1.11 mrg * and expect our caller (wav_write_header()) to use them. 234 1.11 mrg */ 235 1.11 mrg int 236 1.13 mrg wav_prepare_header(struct track_info *ti, void **hdrp, size_t *lenp, int *leftp) 237 1.11 mrg { 238 1.11 mrg /* 239 1.11 mrg * WAV header we write looks like this: 240 1.11 mrg * 241 1.11 mrg * bytes purpose 242 1.11 mrg * 0-3 "RIFF" 243 1.11 mrg * 4-7 file length (minus 8) 244 1.11 mrg * 8-15 "WAVEfmt " 245 1.11 mrg * 16-19 format size 246 1.11 mrg * 20-21 format tag 247 1.11 mrg * 22-23 number of channels 248 1.11 mrg * 24-27 sample rate 249 1.11 mrg * 28-31 average bytes per second 250 1.11 mrg * 32-33 block alignment 251 1.11 mrg * 34-35 bits per sample 252 1.11 mrg * 253 1.11 mrg * then for ULAW and ALAW outputs, we have an extended chunk size 254 1.11 mrg * and a WAV "fact" to add: 255 1.11 mrg * 256 1.11 mrg * 36-37 length of extension (== 0) 257 1.11 mrg * 38-41 "fact" 258 1.11 mrg * 42-45 fact size 259 1.11 mrg * 46-49 number of samples written 260 1.11 mrg * 50-53 "data" 261 1.11 mrg * 54-57 data length 262 1.11 mrg * 58- raw audio data 263 1.11 mrg * 264 1.11 mrg * for PCM outputs we have just the data remaining: 265 1.11 mrg * 266 1.11 mrg * 36-39 "data" 267 1.11 mrg * 40-43 data length 268 1.11 mrg * 44- raw audio data 269 1.11 mrg * 270 1.11 mrg * RIFF\^@^C^@WAVEfmt ^P^@^@^@^A^@^B^@D<AC>^@^@^P<B1>^B^@^D^@^P^@data^@^@^C^@^@^@^@^@^@^@^@^@^@ 271 1.11 mrg */ 272 1.11 mrg static char wavheaderbuf[64]; 273 1.11 mrg char *p = wavheaderbuf; 274 1.11 mrg const char *riff = "RIFF", 275 1.11 mrg *wavefmt = "WAVEfmt ", 276 1.11 mrg *fact = "fact", 277 1.11 mrg *data = "data"; 278 1.11 mrg u_int32_t filelen, fmtsz, sps, abps, factsz = 4, nsample, datalen; 279 1.12 christos u_int16_t fmttag, nchan, align, extln = 0; 280 1.11 mrg 281 1.13 mrg if (ti->header_info) 282 1.11 mrg warnx("header information not supported for WAV"); 283 1.11 mrg *leftp = 0; 284 1.11 mrg 285 1.13 mrg switch (ti->precision) { 286 1.11 mrg case 8: 287 1.11 mrg break; 288 1.11 mrg case 16: 289 1.11 mrg break; 290 1.11 mrg case 32: 291 1.11 mrg break; 292 1.11 mrg default: 293 1.11 mrg { 294 1.11 mrg static int warned = 0; 295 1.11 mrg 296 1.11 mrg if (warned == 0) { 297 1.13 mrg warnx("can not support precision of %d", ti->precision); 298 1.11 mrg warned = 1; 299 1.11 mrg } 300 1.11 mrg } 301 1.11 mrg return (-1); 302 1.11 mrg } 303 1.11 mrg 304 1.13 mrg switch (ti->encoding) { 305 1.11 mrg case AUDIO_ENCODING_ULAW: 306 1.11 mrg fmttag = WAVE_FORMAT_MULAW; 307 1.11 mrg fmtsz = 18; 308 1.13 mrg align = ti->channels; 309 1.11 mrg break; 310 1.11 mrg 311 1.11 mrg case AUDIO_ENCODING_ALAW: 312 1.11 mrg fmttag = WAVE_FORMAT_ALAW; 313 1.11 mrg fmtsz = 18; 314 1.13 mrg align = ti->channels; 315 1.11 mrg break; 316 1.11 mrg 317 1.11 mrg /* 318 1.11 mrg * we could try to support RIFX but it seems to be more portable 319 1.11 mrg * to output little-endian data for WAV files. 320 1.11 mrg */ 321 1.11 mrg case AUDIO_ENCODING_ULINEAR_BE: 322 1.11 mrg case AUDIO_ENCODING_SLINEAR_BE: 323 1.11 mrg case AUDIO_ENCODING_ULINEAR_LE: 324 1.11 mrg case AUDIO_ENCODING_SLINEAR_LE: 325 1.11 mrg case AUDIO_ENCODING_PCM16: 326 1.11 mrg 327 1.11 mrg #if BYTE_ORDER == LITTLE_ENDIAN 328 1.11 mrg case AUDIO_ENCODING_ULINEAR: 329 1.11 mrg case AUDIO_ENCODING_SLINEAR: 330 1.11 mrg #endif 331 1.11 mrg fmttag = WAVE_FORMAT_PCM; 332 1.11 mrg fmtsz = 16; 333 1.13 mrg align = ti->channels * (ti->precision / 8); 334 1.11 mrg break; 335 1.11 mrg 336 1.11 mrg default: 337 1.11 mrg #if 0 // move into record.c, and maybe merge.c 338 1.11 mrg { 339 1.11 mrg static int warned = 0; 340 1.11 mrg 341 1.11 mrg if (warned == 0) { 342 1.13 mrg const char *s = wav_enc_from_val(ti->encoding); 343 1.11 mrg 344 1.11 mrg if (s == NULL) 345 1.11 mrg warnx("can not support encoding of %s", s); 346 1.11 mrg else 347 1.13 mrg warnx("can not support encoding of %d", ti->encoding); 348 1.11 mrg warned = 1; 349 1.11 mrg } 350 1.11 mrg } 351 1.11 mrg #endif 352 1.13 mrg ti->format = AUDIO_FORMAT_NONE; 353 1.11 mrg return (-1); 354 1.11 mrg } 355 1.11 mrg 356 1.13 mrg nchan = ti->channels; 357 1.13 mrg sps = ti->sample_rate; 358 1.11 mrg 359 1.11 mrg /* data length */ 360 1.13 mrg if (ti->outfd == STDOUT_FILENO) 361 1.11 mrg datalen = 0; 362 1.13 mrg else if (ti->total_size != -1) 363 1.13 mrg datalen = ti->total_size; 364 1.11 mrg else 365 1.11 mrg datalen = 0; 366 1.11 mrg 367 1.11 mrg /* file length */ 368 1.11 mrg filelen = 4 + (8 + fmtsz) + (8 + datalen); 369 1.11 mrg if (fmttag != WAVE_FORMAT_PCM) 370 1.11 mrg filelen += 8 + factsz; 371 1.11 mrg 372 1.13 mrg abps = (double)align*ti->sample_rate / (double)1 + 0.5; 373 1.11 mrg 374 1.13 mrg nsample = (datalen / ti->precision) / ti->sample_rate; 375 1.11 mrg 376 1.11 mrg /* 377 1.11 mrg * now we've calculated the info, write it out! 378 1.11 mrg */ 379 1.11 mrg #define put32(x) do { \ 380 1.11 mrg u_int32_t _f; \ 381 1.11 mrg putle32(_f, (x)); \ 382 1.11 mrg memcpy(p, &_f, 4); \ 383 1.11 mrg } while (0) 384 1.11 mrg #define put16(x) do { \ 385 1.11 mrg u_int16_t _f; \ 386 1.11 mrg putle16(_f, (x)); \ 387 1.11 mrg memcpy(p, &_f, 2); \ 388 1.11 mrg } while (0) 389 1.11 mrg memcpy(p, riff, 4); 390 1.11 mrg p += 4; /* 4 */ 391 1.11 mrg put32(filelen); 392 1.11 mrg p += 4; /* 8 */ 393 1.11 mrg memcpy(p, wavefmt, 8); 394 1.11 mrg p += 8; /* 16 */ 395 1.11 mrg put32(fmtsz); 396 1.11 mrg p += 4; /* 20 */ 397 1.11 mrg put16(fmttag); 398 1.11 mrg p += 2; /* 22 */ 399 1.11 mrg put16(nchan); 400 1.11 mrg p += 2; /* 24 */ 401 1.11 mrg put32(sps); 402 1.11 mrg p += 4; /* 28 */ 403 1.11 mrg put32(abps); 404 1.11 mrg p += 4; /* 32 */ 405 1.11 mrg put16(align); 406 1.11 mrg p += 2; /* 34 */ 407 1.13 mrg put16(ti->precision); 408 1.11 mrg p += 2; /* 36 */ 409 1.11 mrg /* NON PCM formats have an extended chunk; write it */ 410 1.11 mrg if (fmttag != WAVE_FORMAT_PCM) { 411 1.11 mrg put16(extln); 412 1.11 mrg p += 2; /* 38 */ 413 1.11 mrg memcpy(p, fact, 4); 414 1.11 mrg p += 4; /* 42 */ 415 1.11 mrg put32(factsz); 416 1.11 mrg p += 4; /* 46 */ 417 1.11 mrg put32(nsample); 418 1.11 mrg p += 4; /* 50 */ 419 1.11 mrg } 420 1.11 mrg memcpy(p, data, 4); 421 1.11 mrg p += 4; /* 40/54 */ 422 1.11 mrg put32(datalen); 423 1.11 mrg p += 4; /* 44/58 */ 424 1.11 mrg #undef put32 425 1.11 mrg #undef put16 426 1.11 mrg 427 1.11 mrg *hdrp = wavheaderbuf; 428 1.11 mrg *lenp = (p - wavheaderbuf); 429 1.11 mrg 430 1.11 mrg return 0; 431 1.11 mrg } 432 1.11 mrg 433 1.11 mrg write_conv_func 434 1.13 mrg wav_write_get_conv_func(struct track_info *ti) 435 1.11 mrg { 436 1.11 mrg write_conv_func conv_func = NULL; 437 1.11 mrg 438 1.13 mrg switch (ti->encoding) { 439 1.11 mrg 440 1.11 mrg /* 441 1.11 mrg * we could try to support RIFX but it seems to be more portable 442 1.11 mrg * to output little-endian data for WAV files. 443 1.11 mrg */ 444 1.11 mrg case AUDIO_ENCODING_ULINEAR_BE: 445 1.11 mrg #if BYTE_ORDER == BIG_ENDIAN 446 1.11 mrg case AUDIO_ENCODING_ULINEAR: 447 1.11 mrg #endif 448 1.13 mrg if (ti->precision == 16) 449 1.11 mrg conv_func = change_sign16_swap_bytes_be; 450 1.13 mrg else if (ti->precision == 32) 451 1.11 mrg conv_func = change_sign32_swap_bytes_be; 452 1.11 mrg break; 453 1.11 mrg 454 1.11 mrg case AUDIO_ENCODING_SLINEAR_BE: 455 1.11 mrg #if BYTE_ORDER == BIG_ENDIAN 456 1.11 mrg case AUDIO_ENCODING_SLINEAR: 457 1.11 mrg #endif 458 1.13 mrg if (ti->precision == 8) 459 1.11 mrg conv_func = change_sign8; 460 1.13 mrg else if (ti->precision == 16) 461 1.11 mrg conv_func = swap_bytes; 462 1.13 mrg else if (ti->precision == 32) 463 1.11 mrg conv_func = swap_bytes32; 464 1.11 mrg break; 465 1.11 mrg 466 1.11 mrg case AUDIO_ENCODING_ULINEAR_LE: 467 1.11 mrg #if BYTE_ORDER == LITTLE_ENDIAN 468 1.11 mrg case AUDIO_ENCODING_ULINEAR: 469 1.11 mrg #endif 470 1.13 mrg if (ti->precision == 16) 471 1.11 mrg conv_func = change_sign16_le; 472 1.13 mrg else if (ti->precision == 32) 473 1.11 mrg conv_func = change_sign32_le; 474 1.11 mrg break; 475 1.11 mrg 476 1.11 mrg case AUDIO_ENCODING_SLINEAR_LE: 477 1.11 mrg case AUDIO_ENCODING_PCM16: 478 1.11 mrg #if BYTE_ORDER == LITTLE_ENDIAN 479 1.11 mrg case AUDIO_ENCODING_SLINEAR: 480 1.11 mrg #endif 481 1.13 mrg if (ti->precision == 8) 482 1.11 mrg conv_func = change_sign8; 483 1.11 mrg break; 484 1.11 mrg 485 1.11 mrg default: 486 1.13 mrg ti->format = AUDIO_FORMAT_NONE; 487 1.11 mrg } 488 1.11 mrg 489 1.11 mrg return conv_func; 490 1.11 mrg } 491
Indexes created Wed Sep 24 22:09:59 GMT 2025