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FFmpeg/libavcodec/ra144.c

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  1. /*

  2.  * Real Audio 1.0 (14.4K)

  3.  * Copyright (c) 2003 the ffmpeg project

  4.  *

  5.  * This file is part of FFmpeg.

  6.  *

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

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

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

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

  11.  *

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

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

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

  15.  * Lesser General Public License for more details.

  16.  *

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

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

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

  20.  */

  21. 

  22. #include "avcodec.h"

  23. #include "bitstream.h"

  24. #include "ra144.h"

  25. 

  26. #define NBLOCKS         4       /* number of segments within a block */

  27. #define BLOCKSIZE       40      /* (quarter) block size in 16-bit words (80 bytes) */

  28. #define HALFBLOCK       20      /* BLOCKSIZE/2 */

  29. #define BUFFERSIZE      146     /* for do_output */

  30. 

  31. 

  32. /* internal globals */

  33. typedef struct {

  34.     unsigned int     old_energy;        ///< previous frame energy

  35. 

  36.     /* the swapped buffers */

  37.     unsigned int     lpc_tables[2][10];

  38.     unsigned int    *lpc_coef;          ///< LPC coefficients

  39.     unsigned int    *lpc_coef_old;      ///< previous frame LPC coefficients

  40.     unsigned int     lpc_refl_rms;

  41.     unsigned int     lpc_refl_rms_old;

  42. 

  43.     unsigned int buffer[5];

  44.     uint16_t adapt_cb[148];             ///< adaptive codebook

  45. } RA144Context;

  46. 

  47. static int ra144_decode_init(AVCodecContext * avctx)

  48. {

  49.     RA144Context *ractx = avctx->priv_data;

  50. 

  51.     ractx->lpc_coef     = ractx->lpc_tables[0];

  52.     ractx->lpc_coef_old = ractx->lpc_tables[1];

  53. 

  54.     return 0;

  55. }

  56. 

  57. /**

  58.  * Evaluate sqrt(x << 24). x must fit in 20 bits. This value is evaluated in an

  59.  * odd way to make the output identical to the binary decoder.

  60.  */

  61. static int t_sqrt(unsigned int x)

  62. {

  63.     int s = 0;

  64.     while (x > 0xfff) {

  65.         s++;

  66.         x = x >> 2;

  67.     }

  68. 

  69.     return (ff_sqrt(x << 20) << s) << 2;

  70. }

  71. 

  72. /**

  73.  * Evaluate the LPC filter coefficients from the reflection coefficients.

  74.  * Does the inverse of the eval_refl() function.

  75.  */

  76. static void eval_coefs(const int *refl, int *coefs)

  77. {

  78.     int buffer[10];

  79.     int *b1 = buffer;

  80.     int *b2 = coefs;

  81.     int x, y;

  82. 

  83.     for (x=0; x < 10; x++) {

  84.         b1[x] = refl[x] << 4;

  85. 

  86.         for (y=0; y < x; y++)

  87.             b1[y] = ((refl[x] * b2[x-y-1]) >> 12) + b2[y];

  88. 

  89.         FFSWAP(int *, b1, b2);

  90.     }

  91. 

  92.     for (x=0; x < 10; x++)

  93.         coefs[x] >>= 4;

  94. }

  95. 

  96. /* rotate block */

  97. static void rotate_block(const int16_t *source, int16_t *target, int offset)

  98. {

  99.     int i=0, k=0;

  100.     source += BUFFERSIZE - offset;

  101. 

  102.     while (i<BLOCKSIZE) {

  103.         target[i++] = source[k++];

  104. 

  105.         if (k == offset)

  106.             k = 0;

  107.     }

  108. }

  109. 

  110. /* inverse root mean square */

  111. static int irms(const int16_t *data, int factor)

  112. {

  113.     unsigned int i, sum = 0;

  114. 

  115.     for (i=0; i < BLOCKSIZE; i++)

  116.         sum += data[i] * data[i];

  117. 

  118.     if (sum == 0)

  119.         return 0; /* OOPS - division by zero */

  120. 

  121.     return (0x20000000 / (t_sqrt(sum) >> 8)) * factor;

  122. }

  123. 

  124. /* multiply/add wavetable */

  125. static void add_wav(int n, int skip_first, int *m, const int16_t *s1,

  126.                     const int8_t *s2, const int8_t *s3, int16_t *dest)

  127. {

  128.     int i;

  129.     int v[3];

  130. 

  131.     v[0] = 0;

  132.     for (i=!skip_first; i<3; i++)

  133.         v[i] = (wavtable1[n][i] * m[i]) >> (wavtable2[n][i] + 1);

  134. 

  135.     for (i=0; i < BLOCKSIZE; i++)

  136.         dest[i] = ((*(s1++))*v[0] + (*(s2++))*v[1] + (*(s3++))*v[2]) >> 12;

  137. }

  138. 

  139. 

  140. static void final(const int16_t *i1, const int16_t *i2,

  141.                   void *out, int *statbuf, int len)

  142. {

  143.     int x, i;

  144.     uint16_t work[50];

  145.     int16_t *ptr = work;

  146. 

  147.     memcpy(work, statbuf,20);

  148.     memcpy(work + 10, i2, len * 2);

  149. 

  150.     for (i=0; i<len; i++) {

  151.         int sum = 0;

  152.         int new_val;

  153. 

  154.         for(x=0; x<10; x++)

  155.             sum += i1[9-x] * ptr[x];

  156. 

  157.         sum >>= 12;

  158. 

  159.         new_val = ptr[10] - sum;

  160. 

  161.         if (new_val < -32768 || new_val > 32767) {

  162.             memset(out, 0, len * 2);

  163.             memset(statbuf, 0, 20);

  164.             return;

  165.         }

  166. 

  167.         ptr[10] = new_val;

  168.         ptr++;

  169.     }

  170. 

  171.     memcpy(out, work+10, len * 2);

  172.     memcpy(statbuf, work + 40, 20);

  173. }

  174. 

  175. static unsigned int rescale_rms(int rms, int energy)

  176. {

  177.     return (rms * energy) >> 10;

  178. }

  179. 

  180. static unsigned int rms(const int *data)

  181. {

  182.     int x;

  183.     unsigned int res = 0x10000;

  184.     int b = 0;

  185. 

  186.     for (x=0; x<10; x++) {

  187.         res = (((0x1000000 - (*data) * (*data)) >> 12) * res) >> 12;

  188. 

  189.         if (res == 0)

  190.             return 0;

  191. 

  192.         while (res <= 0x3fff) {

  193.             b++;

  194.             res <<= 2;

  195.         }

  196.         data++;

  197.     }

  198. 

  199.     if (res > 0)

  200.         res = t_sqrt(res);

  201. 

  202.     res >>= (b + 10);

  203.     return res;

  204. }

  205. 

  206. /* do quarter-block output */

  207. static void do_output_subblock(RA144Context *ractx,

  208.                                const uint16_t  *lpc_coefs, unsigned int gval,

  209.                                int16_t *output_buffer, GetBitContext *gb)

  210. {

  211.     uint16_t buffer_a[40];

  212.     uint16_t *block;

  213.     int cba_idx = get_bits(gb, 7); // index of the adaptive CB, 0 if none

  214.     int gain    = get_bits(gb, 8);

  215.     int cb1_idx = get_bits(gb, 7);

  216.     int cb2_idx = get_bits(gb, 7);

  217.     int m[3];

  218. 

  219.     if (cba_idx) {

  220.         cba_idx += HALFBLOCK - 1;

  221.         rotate_block(ractx->adapt_cb, buffer_a, cba_idx);

  222.         m[0] = irms(buffer_a, gval) >> 12;

  223.     } else {

  224.         m[0] = 0;

  225.     }

  226. 

  227.     m[1] = ((ftable1[cb1_idx] >> 4) * gval) >> 8;

  228.     m[2] = ((ftable2[cb2_idx] >> 4) * gval) >> 8;

  229. 

  230.     memmove(ractx->adapt_cb, ractx->adapt_cb + BLOCKSIZE,

  231.             (BUFFERSIZE - BLOCKSIZE) * 2);

  232. 

  233.     block = ractx->adapt_cb + BUFFERSIZE - BLOCKSIZE;

  234. 

  235.     add_wav(gain, cba_idx, m, buffer_a, etable1[cb1_idx], etable2[cb2_idx],

  236.             block);

  237. 

  238.     final(lpc_coefs, block, output_buffer, ractx->buffer, BLOCKSIZE);

  239. }

  240. 

  241. static void int_to_int16(int16_t *decsp, const int *inp)

  242. {

  243.     int i;

  244. 

  245.     for (i=0; i<30; i++)

  246.         *(decsp++) = *(inp++);

  247. }

  248. 

  249. /**

  250.  * Evaluate the reflection coefficients from the filter coefficients.

  251.  * Does the inverse of the eval_coefs() function.

  252.  *

  253.  * @return 1 if one of the reflection coefficients is of magnitude greater than

  254.  *         4095, 0 if not.

  255.  */

  256. static int eval_refl(const int16_t *coefs, int *refl, RA144Context *ractx)

  257. {

  258.     int retval = 0;

  259.     int b, c, i;

  260.     unsigned int u;

  261.     int buffer1[10];

  262.     int buffer2[10];

  263.     int *bp1 = buffer1;

  264.     int *bp2 = buffer2;

  265. 

  266.     for (i=0; i < 10; i++)

  267.         buffer2[i] = coefs[i];

  268. 

  269.     u = refl[9] = bp2[9];

  270. 

  271.     if (u + 0x1000 > 0x1fff) {

  272.         av_log(ractx, AV_LOG_ERROR, "Overflow. Broken sample?\n");

  273.         return 0;

  274.     }

  275. 

  276.     for (c=8; c >= 0; c--) {

  277.         if (u == 0x1000)

  278.             u++;

  279. 

  280.         if (u == 0xfffff000)

  281.             u--;

  282. 

  283.         b = 0x1000-((u * u) >> 12);

  284. 

  285.         if (b == 0)

  286.             b++;

  287. 

  288.         for (u=0; u<=c; u++)

  289.             bp1[u] = ((bp2[u] - ((refl[c+1] * bp2[c-u]) >> 12)) * (0x1000000 / b)) >> 12;

  290. 

  291.         refl[c] = u = bp1[c];

  292. 

  293.         if ((u + 0x1000) > 0x1fff)

  294.             retval = 1;

  295. 

  296.         FFSWAP(int *, bp1, bp2);

  297.     }

  298.     return retval;

  299. }

  300. 

  301. static int interp(RA144Context *ractx, int16_t *decsp, int block_num,

  302.                   int copynew, int energy)

  303. {

  304.     int work[10];

  305.     int a = block_num + 1;

  306.     int b = NBLOCKS - a;

  307.     int x;

  308. 

  309.     // Interpolate block coefficients from the this frame forth block and

  310.     // last frame forth block

  311.     for (x=0; x<30; x++)

  312.         decsp[x] = (a * ractx->lpc_coef[x] + b * ractx->lpc_coef_old[x])>> 2;

  313. 

  314.     if (eval_refl(decsp, work, ractx)) {

  315.         // The interpolated coefficients are unstable, copy either new or old

  316.         // coefficients

  317.         if (copynew) {

  318.             int_to_int16(decsp, ractx->lpc_coef);

  319.             return rescale_rms(ractx->lpc_refl_rms, energy);

  320.         } else {

  321.             int_to_int16(decsp, ractx->lpc_coef_old);

  322.             return rescale_rms(ractx->lpc_refl_rms_old, energy);

  323.         }

  324.     } else {

  325.         return rescale_rms(rms(work), energy);

  326.     }

  327. }

  328. 

  329. /* Uncompress one block (20 bytes -> 160*2 bytes) */

  330. static int ra144_decode_frame(AVCodecContext * avctx,

  331.                               void *vdata, int *data_size,

  332.                               const uint8_t * buf, int buf_size)

  333. {

  334.     static const uint8_t sizes[10] = {6, 5, 5, 4, 4, 3, 3, 3, 3, 2};

  335.     unsigned int refl_rms[4];  // RMS of the reflection coefficients

  336.     uint16_t block_coefs[4][30]; // LPC coefficients of each sub-block

  337.     unsigned int lpc_refl[10];   // LPC reflection coefficients of the frame

  338.     int i, c;

  339.     int16_t *data = vdata;

  340.     unsigned int energy;

  341. 

  342.     RA144Context *ractx = avctx->priv_data;

  343.     GetBitContext gb;

  344. 

  345.     if(buf_size < 20) {

  346.         av_log(avctx, AV_LOG_ERROR,

  347.                "Frame too small (%d bytes). Truncated file?\n", buf_size);

  348.         return buf_size;

  349.     }

  350.     init_get_bits(&gb, buf, 20 * 8);

  351. 

  352.     for (i=0; i<10; i++)

  353.         // "<< 1"? Doesn't this make one value out of two of the table useless?

  354.         lpc_refl[i] = decodetable[i][get_bits(&gb, sizes[i]) << 1];

  355. 

  356.     eval_coefs(lpc_refl, ractx->lpc_coef);

  357.     ractx->lpc_refl_rms = rms(lpc_refl);

  358. 

  359.     energy = decodeval[get_bits(&gb, 5) << 1]; // Useless table entries?

  360. 

  361.     refl_rms[0] = interp(ractx, block_coefs[0], 0, 0, ractx->old_energy);

  362.     refl_rms[1] = interp(ractx, block_coefs[1], 1, energy > ractx->old_energy,

  363.                     t_sqrt(energy*ractx->old_energy) >> 12);

  364.     refl_rms[2] = interp(ractx, block_coefs[2], 2, 1, energy);

  365.     refl_rms[3] = rescale_rms(ractx->lpc_refl_rms, energy);

  366. 

  367.     int_to_int16(block_coefs[3], ractx->lpc_coef);

  368. 

  369.     /* do output */

  370.     for (c=0; c<4; c++) {

  371.         do_output_subblock(ractx, block_coefs[c], refl_rms[c], data, &gb);

  372. 

  373.         for (i=0; i<BLOCKSIZE; i++) {

  374.             *data = av_clip_int16(*data << 2);

  375.             data++;

  376.         }

  377.     }

  378. 

  379.     ractx->old_energy = energy;

  380.     ractx->lpc_refl_rms_old = ractx->lpc_refl_rms;

  381. 

  382.     FFSWAP(unsigned int *, ractx->lpc_coef_old, ractx->lpc_coef);

  383. 

  384.     *data_size = 2*160;

  385.     return 20;

  386. }

  387. 

  388. 

  389. AVCodec ra_144_decoder =

  390. {

  391.     "real_144",

  392.     CODEC_TYPE_AUDIO,

  393.     CODEC_ID_RA_144,

  394.     sizeof(RA144Context),

  395.     ra144_decode_init,

  396.     NULL,

  397.     NULL,

  398.     ra144_decode_frame,

  399.     .long_name = NULL_IF_CONFIG_SMALL("RealAudio 1.0 (14.4K)"),

  400. };