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FFmpeg/tests/audiogen.c

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  1. /*

  2.  * Generate a synthetic stereo sound.

  3.  * NOTE: No floats are used to guarantee bitexact output.

  4.  *

  5.  * Copyright (c) 2002 Fabrice Bellard

  6.  *

  7.  * This file is part of FFmpeg.

  8.  *

  9.  * FFmpeg is free software; you can redistribute it and/or

  10.  * modify it under the terms of the GNU Lesser General Public

  11.  * License as published by the Free Software Foundation; either

  12.  * version 2.1 of the License, or (at your option) any later version.

  13.  *

  14.  * FFmpeg is distributed in the hope that it will be useful,

  15.  * but WITHOUT ANY WARRANTY; without even the implied warranty of

  16.  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU

  17.  * Lesser General Public License for more details.

  18.  *

  19.  * You should have received a copy of the GNU Lesser General Public

  20.  * License along with FFmpeg; if not, write to the Free Software

  21.  * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA

  22.  */

  23. 

  24. #include <stdlib.h>

  25. #include <stdint.h>

  26. #include <stdio.h>

  27. #include <string.h>

  28. 

  29. #define MAX_CHANNELS 12

  30. 

  31. static unsigned int myrnd(unsigned int *seed_ptr, int n)

  32. {

  33.     unsigned int seed, val;

  34. 

  35.     seed = *seed_ptr;

  36.     seed = (seed * 314159) + 1;

  37.     if (n == 256) {

  38.         val = seed >> 24;

  39.     } else {

  40.         val = seed % n;

  41.     }

  42.     *seed_ptr = seed;

  43.     return val;

  44. }

  45. 

  46. #define FRAC_BITS 16

  47. #define FRAC_ONE (1 << FRAC_BITS)

  48. 

  49. #define COS_TABLE_BITS 7

  50. 

  51. /* integer cosine */

  52. static const unsigned short cos_table[(1 << COS_TABLE_BITS) + 2] = {

  53.     0x8000, 0x7ffe, 0x7ff6, 0x7fea, 0x7fd9, 0x7fc2, 0x7fa7, 0x7f87,

  54.     0x7f62, 0x7f38, 0x7f0a, 0x7ed6, 0x7e9d, 0x7e60, 0x7e1e, 0x7dd6,

  55.     0x7d8a, 0x7d3a, 0x7ce4, 0x7c89, 0x7c2a, 0x7bc6, 0x7b5d, 0x7aef,

  56.     0x7a7d, 0x7a06, 0x798a, 0x790a, 0x7885, 0x77fb, 0x776c, 0x76d9,

  57.     0x7642, 0x75a6, 0x7505, 0x7460, 0x73b6, 0x7308, 0x7255, 0x719e,

  58.     0x70e3, 0x7023, 0x6f5f, 0x6e97, 0x6dca, 0x6cf9, 0x6c24, 0x6b4b,

  59.     0x6a6e, 0x698c, 0x68a7, 0x67bd, 0x66d0, 0x65de, 0x64e9, 0x63ef,

  60.     0x62f2, 0x61f1, 0x60ec, 0x5fe4, 0x5ed7, 0x5dc8, 0x5cb4, 0x5b9d,

  61.     0x5a82, 0x5964, 0x5843, 0x571e, 0x55f6, 0x54ca, 0x539b, 0x5269,

  62.     0x5134, 0x4ffb, 0x4ec0, 0x4d81, 0x4c40, 0x4afb, 0x49b4, 0x486a,

  63.     0x471d, 0x45cd, 0x447b, 0x4326, 0x41ce, 0x4074, 0x3f17, 0x3db8,

  64.     0x3c57, 0x3af3, 0x398d, 0x3825, 0x36ba, 0x354e, 0x33df, 0x326e,

  65.     0x30fc, 0x2f87, 0x2e11, 0x2c99, 0x2b1f, 0x29a4, 0x2827, 0x26a8,

  66.     0x2528, 0x23a7, 0x2224, 0x209f, 0x1f1a, 0x1d93, 0x1c0c, 0x1a83,

  67.     0x18f9, 0x176e, 0x15e2, 0x1455, 0x12c8, 0x113a, 0x0fab, 0x0e1c,

  68.     0x0c8c, 0x0afb, 0x096b, 0x07d9, 0x0648, 0x04b6, 0x0324, 0x0192,

  69.     0x0000, 0x0000,

  70. };

  71. 

  72. #define CSHIFT (FRAC_BITS - COS_TABLE_BITS - 2)

  73. 

  74. static int int_cos(int a)

  75. {

  76.     int neg, v, f;

  77.     const unsigned short *p;

  78. 

  79.     a = a & (FRAC_ONE - 1); /* modulo 2 * pi */

  80.     if (a >= (FRAC_ONE / 2))

  81.         a = FRAC_ONE - a;

  82.     neg = 0;

  83.     if (a > (FRAC_ONE / 4)) {

  84.         neg = -1;

  85.         a   = (FRAC_ONE / 2) - a;

  86.     }

  87.     p = cos_table + (a >> CSHIFT);

  88.     /* linear interpolation */

  89.     f = a & ((1 << CSHIFT) - 1);

  90.     v = p[0] + (((p[1] - p[0]) * f + (1 << (CSHIFT - 1))) >> CSHIFT);

  91.     v = (v ^ neg) - neg;

  92.     v = v << (FRAC_BITS - 15);

  93.     return v;

  94. }

  95. 

  96. FILE *outfile;

  97. 

  98. static void put16(int16_t v)

  99. {

  100.     fputc( v       & 0xff, outfile);

  101.     fputc((v >> 8) & 0xff, outfile);

  102. }

  103. 

  104. static void put32(uint32_t v)

  105. {

  106.     fputc( v        & 0xff, outfile);

  107.     fputc((v >>  8) & 0xff, outfile);

  108.     fputc((v >> 16) & 0xff, outfile);

  109.     fputc((v >> 24) & 0xff, outfile);

  110. }

  111. 

  112. #define HEADER_SIZE      46

  113. #define FMT_SIZE         18

  114. #define SAMPLE_SIZE       2

  115. #define WFORMAT_PCM  0x0001

  116. 

  117. static void put_wav_header(int sample_rate, int channels, int nb_samples)

  118. {

  119.     int block_align = SAMPLE_SIZE * channels;

  120.     int data_size   = block_align * nb_samples;

  121. 

  122.     fputs("RIFF", outfile);

  123.     put32(HEADER_SIZE + data_size);

  124.     fputs("WAVEfmt ", outfile);

  125.     put32(FMT_SIZE);

  126.     put16(WFORMAT_PCM);

  127.     put16(channels);

  128.     put32(sample_rate);

  129.     put32(block_align * sample_rate);

  130.     put16(block_align);

  131.     put16(SAMPLE_SIZE * 8);

  132.     put16(0);

  133.     fputs("data", outfile);

  134.     put32(data_size);

  135. }

  136. 

  137. int main(int argc, char **argv)

  138. {

  139.     int i, a, v, j, f, amp, ampa;

  140.     unsigned int seed = 1;

  141.     int tabf1[MAX_CHANNELS], tabf2[MAX_CHANNELS];

  142.     int taba[MAX_CHANNELS];

  143.     int sample_rate = 44100;

  144.     int nb_channels = 2;

  145.     char *ext;

  146. 

  147.     if (argc < 2 || argc > 5) {

  148.         printf("usage: %s file [<sample rate> [<channels>] [<random seed>]]\n"

  149.                "generate a test raw 16 bit audio stream\n"

  150.                "If the file extension is .wav a WAVE header will be added.\n"

  151.                "default: 44100 Hz stereo\n", argv[0]);

  152.         exit(1);

  153.     }

  154. 

  155.     if (argc > 2) {

  156.         sample_rate = atoi(argv[2]);

  157.         if (sample_rate <= 0) {

  158.             fprintf(stderr, "invalid sample rate: %d\n", sample_rate);

  159.             return 1;

  160.         }

  161.     }

  162. 

  163.     if (argc > 3) {

  164.         nb_channels = atoi(argv[3]);

  165.         if (nb_channels < 1 || nb_channels > MAX_CHANNELS) {

  166.             fprintf(stderr, "invalid number of channels: %d\n", nb_channels);

  167.             return 1;

  168.         }

  169.     }

  170. 

  171.     if (argc > 4)

  172.         seed = atoi(argv[4]);

  173. 

  174.     outfile = fopen(argv[1], "wb");

  175.     if (!outfile) {

  176.         perror(argv[1]);

  177.         return 1;

  178.     }

  179. 

  180.     if ((ext = strrchr(argv[1], '.')) && !strcmp(ext, ".wav"))

  181.         put_wav_header(sample_rate, nb_channels, 6 * sample_rate);

  182. 

  183.     /* 1 second of single freq sine at 1000 Hz */

  184.     a = 0;

  185.     for (i = 0; i < 1 * sample_rate; i++) {

  186.         v = (int_cos(a) * 10000) >> FRAC_BITS;

  187.         for (j = 0; j < nb_channels; j++)

  188.             put16(v);

  189.         a += (1000 * FRAC_ONE) / sample_rate;

  190.     }

  191. 

  192.     /* 1 second of varying frequency between 100 and 10000 Hz */

  193.     a = 0;

  194.     for (i = 0; i < 1 * sample_rate; i++) {

  195.         v = (int_cos(a) * 10000) >> FRAC_BITS;

  196.         for (j = 0; j < nb_channels; j++)

  197.             put16(v);

  198.         f  = 100 + (((10000 - 100) * i) / sample_rate);

  199.         a += (f * FRAC_ONE) / sample_rate;

  200.     }

  201. 

  202.     /* 0.5 second of low amplitude white noise */

  203.     for (i = 0; i < sample_rate / 2; i++) {

  204.         v = myrnd(&seed, 20000) - 10000;

  205.         for (j = 0; j < nb_channels; j++)

  206.             put16(v);

  207.     }

  208. 

  209.     /* 0.5 second of high amplitude white noise */

  210.     for (i = 0; i < sample_rate / 2; i++) {

  211.         v = myrnd(&seed, 65535) - 32768;

  212.         for (j = 0; j < nb_channels; j++)

  213.             put16(v);

  214.     }

  215. 

  216.     /* 1 second of unrelated ramps for each channel */

  217.     for (j = 0; j < nb_channels; j++) {

  218.         taba[j]  = 0;

  219.         tabf1[j] = 100 + myrnd(&seed, 5000);

  220.         tabf2[j] = 100 + myrnd(&seed, 5000);

  221.     }

  222.     for (i = 0; i < 1 * sample_rate; i++) {

  223.         for (j = 0; j < nb_channels; j++) {

  224.             v = (int_cos(taba[j]) * 10000) >> FRAC_BITS;

  225.             put16(v);

  226.             f        = tabf1[j] + (((tabf2[j] - tabf1[j]) * i) / sample_rate);

  227.             taba[j] += (f * FRAC_ONE) / sample_rate;

  228.         }

  229.     }

  230. 

  231.     /* 2 seconds of 500 Hz with varying volume */

  232.     a    = 0;

  233.     ampa = 0;

  234.     for (i = 0; i < 2 * sample_rate; i++) {

  235.         for (j = 0; j < nb_channels; j++) {

  236.             amp = ((FRAC_ONE + int_cos(ampa)) * 5000) >> FRAC_BITS;

  237.             if (j & 1)

  238.                 amp = 10000 - amp;

  239.             v = (int_cos(a) * amp) >> FRAC_BITS;

  240.             put16(v);

  241.             a    += (500 * FRAC_ONE) / sample_rate;

  242.             ampa += (2 * FRAC_ONE) / sample_rate;

  243.         }

  244.     }

  245. 

  246.     fclose(outfile);

  247.     return 0;

  248. }