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FFmpeg/libavcodec/bink.c

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  1. /*

  2.  * Bink video decoder

  3.  * Copyright (c) 2009 Konstantin Shishkov

  4.  * Copyright (C) 2011 Peter Ross <pross@xvid.org>

  5.  *

  6.  * This file is part of Libav.

  7.  *

  8.  * Libav is free software; you can redistribute it and/or

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

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

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

  12.  *

  13.  * Libav is distributed in the hope that it will be useful,

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

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

  16.  * Lesser General Public License for more details.

  17.  *

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

  19.  * License along with Libav; if not, write to the Free Software

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

  21.  */

  22. 

  23. #include "libavutil/imgutils.h"

  24. #include "avcodec.h"

  25. #include "dsputil.h"

  26. #include "binkdata.h"

  27. #include "binkdsp.h"

  28. #include "mathops.h"

  29. 

  30. #define ALT_BITSTREAM_READER_LE

  31. #include "get_bits.h"

  32. 

  33. #define BINK_FLAG_ALPHA 0x00100000

  34. #define BINK_FLAG_GRAY  0x00020000

  35. 

  36. static VLC bink_trees[16];

  37. 

  38. /**

  39.  * IDs for different data types used in old version of Bink video codec

  40.  */

  41. enum OldSources {

  42.     BINKB_SRC_BLOCK_TYPES = 0, ///< 8x8 block types

  43.     BINKB_SRC_COLORS,          ///< pixel values used for different block types

  44.     BINKB_SRC_PATTERN,         ///< 8-bit values for 2-colour pattern fill

  45.     BINKB_SRC_X_OFF,           ///< X components of motion value

  46.     BINKB_SRC_Y_OFF,           ///< Y components of motion value

  47.     BINKB_SRC_INTRA_DC,        ///< DC values for intrablocks with DCT

  48.     BINKB_SRC_INTER_DC,        ///< DC values for interblocks with DCT

  49.     BINKB_SRC_INTRA_Q,         ///< quantizer values for intrablocks with DCT

  50.     BINKB_SRC_INTER_Q,         ///< quantizer values for interblocks with DCT

  51.     BINKB_SRC_INTER_COEFS,     ///< number of coefficients for residue blocks

  52. 

  53.     BINKB_NB_SRC

  54. };

  55. 

  56. static const int binkb_bundle_sizes[BINKB_NB_SRC] = {

  57.     4, 8, 8, 5, 5, 11, 11, 4, 4, 7

  58. };

  59. 

  60. static const int binkb_bundle_signed[BINKB_NB_SRC] = {

  61.     0, 0, 0, 1, 1, 0, 1, 0, 0, 0

  62. };

  63. 

  64. static int32_t binkb_intra_quant[16][64];

  65. static int32_t binkb_inter_quant[16][64];

  66. 

  67. /**

  68.  * IDs for different data types used in Bink video codec

  69.  */

  70. enum Sources {

  71.     BINK_SRC_BLOCK_TYPES = 0, ///< 8x8 block types

  72.     BINK_SRC_SUB_BLOCK_TYPES, ///< 16x16 block types (a subset of 8x8 block types)

  73.     BINK_SRC_COLORS,          ///< pixel values used for different block types

  74.     BINK_SRC_PATTERN,         ///< 8-bit values for 2-colour pattern fill

  75.     BINK_SRC_X_OFF,           ///< X components of motion value

  76.     BINK_SRC_Y_OFF,           ///< Y components of motion value

  77.     BINK_SRC_INTRA_DC,        ///< DC values for intrablocks with DCT

  78.     BINK_SRC_INTER_DC,        ///< DC values for interblocks with DCT

  79.     BINK_SRC_RUN,             ///< run lengths for special fill block

  80. 

  81.     BINK_NB_SRC

  82. };

  83. 

  84. /**

  85.  * data needed to decode 4-bit Huffman-coded value

  86.  */

  87. typedef struct Tree {

  88.     int     vlc_num;  ///< tree number (in bink_trees[])

  89.     uint8_t syms[16]; ///< leaf value to symbol mapping

  90. } Tree;

  91. 

  92. #define GET_HUFF(gb, tree)  (tree).syms[get_vlc2(gb, bink_trees[(tree).vlc_num].table,\

  93.                                                  bink_trees[(tree).vlc_num].bits, 1)]

  94. 

  95. /**

  96.  * data structure used for decoding single Bink data type

  97.  */

  98. typedef struct Bundle {

  99.     int     len;       ///< length of number of entries to decode (in bits)

  100.     Tree    tree;      ///< Huffman tree-related data

  101.     uint8_t *data;     ///< buffer for decoded symbols

  102.     uint8_t *data_end; ///< buffer end

  103.     uint8_t *cur_dec;  ///< pointer to the not yet decoded part of the buffer

  104.     uint8_t *cur_ptr;  ///< pointer to the data that is not read from buffer yet

  105. } Bundle;

  106. 

  107. /*

  108.  * Decoder context

  109.  */

  110. typedef struct BinkContext {

  111.     AVCodecContext *avctx;

  112.     DSPContext     dsp;

  113.     BinkDSPContext bdsp;

  114.     AVFrame        pic, last;

  115.     int            version;              ///< internal Bink file version

  116.     int            has_alpha;

  117.     int            swap_planes;

  118. 

  119.     Bundle         bundle[BINKB_NB_SRC]; ///< bundles for decoding all data types

  120.     Tree           col_high[16];         ///< trees for decoding high nibble in "colours" data type

  121.     int            col_lastval;          ///< value of last decoded high nibble in "colours" data type

  122. } BinkContext;

  123. 

  124. /**

  125.  * Bink video block types

  126.  */

  127. enum BlockTypes {

  128.     SKIP_BLOCK = 0, ///< skipped block

  129.     SCALED_BLOCK,   ///< block has size 16x16

  130.     MOTION_BLOCK,   ///< block is copied from previous frame with some offset

  131.     RUN_BLOCK,      ///< block is composed from runs of colours with custom scan order

  132.     RESIDUE_BLOCK,  ///< motion block with some difference added

  133.     INTRA_BLOCK,    ///< intra DCT block

  134.     FILL_BLOCK,     ///< block is filled with single colour

  135.     INTER_BLOCK,    ///< motion block with DCT applied to the difference

  136.     PATTERN_BLOCK,  ///< block is filled with two colours following custom pattern

  137.     RAW_BLOCK,      ///< uncoded 8x8 block

  138. };

  139. 

  140. /**

  141.  * Initialize length length in all bundles.

  142.  *

  143.  * @param c     decoder context

  144.  * @param width plane width

  145.  * @param bw    plane width in 8x8 blocks

  146.  */

  147. static void init_lengths(BinkContext *c, int width, int bw)

  148. {

  149.     c->bundle[BINK_SRC_BLOCK_TYPES].len = av_log2((width >> 3) + 511) + 1;

  150. 

  151.     c->bundle[BINK_SRC_SUB_BLOCK_TYPES].len = av_log2((width >> 4) + 511) + 1;

  152. 

  153.     c->bundle[BINK_SRC_COLORS].len = av_log2(bw*64 + 511) + 1;

  154. 

  155.     c->bundle[BINK_SRC_INTRA_DC].len =

  156.     c->bundle[BINK_SRC_INTER_DC].len =

  157.     c->bundle[BINK_SRC_X_OFF].len =

  158.     c->bundle[BINK_SRC_Y_OFF].len = av_log2((width >> 3) + 511) + 1;

  159. 

  160.     c->bundle[BINK_SRC_PATTERN].len = av_log2((bw << 3) + 511) + 1;

  161. 

  162.     c->bundle[BINK_SRC_RUN].len = av_log2(bw*48 + 511) + 1;

  163. }

  164. 

  165. /**

  166.  * Allocate memory for bundles.

  167.  *

  168.  * @param c decoder context

  169.  */

  170. static av_cold void init_bundles(BinkContext *c)

  171. {

  172.     int bw, bh, blocks;

  173.     int i;

  174. 

  175.     bw = (c->avctx->width  + 7) >> 3;

  176.     bh = (c->avctx->height + 7) >> 3;

  177.     blocks = bw * bh;

  178. 

  179.     for (i = 0; i < BINKB_NB_SRC; i++) {

  180.         c->bundle[i].data = av_malloc(blocks * 64);

  181.         c->bundle[i].data_end = c->bundle[i].data + blocks * 64;

  182.     }

  183. }

  184. 

  185. /**

  186.  * Free memory used by bundles.

  187.  *

  188.  * @param c decoder context

  189.  */

  190. static av_cold void free_bundles(BinkContext *c)

  191. {

  192.     int i;

  193.     for (i = 0; i < BINKB_NB_SRC; i++)

  194.         av_freep(&c->bundle[i].data);

  195. }

  196. 

  197. /**

  198.  * Merge two consequent lists of equal size depending on bits read.

  199.  *

  200.  * @param gb   context for reading bits

  201.  * @param dst  buffer where merged list will be written to

  202.  * @param src  pointer to the head of the first list (the second lists starts at src+size)

  203.  * @param size input lists size

  204.  */

  205. static void merge(GetBitContext *gb, uint8_t *dst, uint8_t *src, int size)

  206. {

  207.     uint8_t *src2 = src + size;

  208.     int size2 = size;

  209. 

  210.     do {

  211.         if (!get_bits1(gb)) {

  212.             *dst++ = *src++;

  213.             size--;

  214.         } else {

  215.             *dst++ = *src2++;

  216.             size2--;

  217.         }

  218.     } while (size && size2);

  219. 

  220.     while (size--)

  221.         *dst++ = *src++;

  222.     while (size2--)

  223.         *dst++ = *src2++;

  224. }

  225. 

  226. /**

  227.  * Read information about Huffman tree used to decode data.

  228.  *

  229.  * @param gb   context for reading bits

  230.  * @param tree pointer for storing tree data

  231.  */

  232. static void read_tree(GetBitContext *gb, Tree *tree)

  233. {

  234.     uint8_t tmp1[16], tmp2[16], *in = tmp1, *out = tmp2;

  235.     int i, t, len;

  236. 

  237.     tree->vlc_num = get_bits(gb, 4);

  238.     if (!tree->vlc_num) {

  239.         for (i = 0; i < 16; i++)

  240.             tree->syms[i] = i;

  241.         return;

  242.     }

  243.     if (get_bits1(gb)) {

  244.         len = get_bits(gb, 3);

  245.         memset(tmp1, 0, sizeof(tmp1));

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

  247.             tree->syms[i] = get_bits(gb, 4);

  248.             tmp1[tree->syms[i]] = 1;

  249.         }

  250.         for (i = 0; i < 16; i++)

  251.             if (!tmp1[i])

  252.                 tree->syms[++len] = i;

  253.     } else {

  254.         len = get_bits(gb, 2);

  255.         for (i = 0; i < 16; i++)

  256.             in[i] = i;

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

  258.             int size = 1 << i;

  259.             for (t = 0; t < 16; t += size << 1)

  260.                 merge(gb, out + t, in + t, size);

  261.             FFSWAP(uint8_t*, in, out);

  262.         }

  263.         memcpy(tree->syms, in, 16);

  264.     }

  265. }

  266. 

  267. /**

  268.  * Prepare bundle for decoding data.

  269.  *

  270.  * @param gb          context for reading bits

  271.  * @param c           decoder context

  272.  * @param bundle_num  number of the bundle to initialize

  273.  */

  274. static void read_bundle(GetBitContext *gb, BinkContext *c, int bundle_num)

  275. {

  276.     int i;

  277. 

  278.     if (bundle_num == BINK_SRC_COLORS) {

  279.         for (i = 0; i < 16; i++)

  280.             read_tree(gb, &c->col_high[i]);

  281.         c->col_lastval = 0;

  282.     }

  283.     if (bundle_num != BINK_SRC_INTRA_DC && bundle_num != BINK_SRC_INTER_DC)

  284.         read_tree(gb, &c->bundle[bundle_num].tree);

  285.     c->bundle[bundle_num].cur_dec =

  286.     c->bundle[bundle_num].cur_ptr = c->bundle[bundle_num].data;

  287. }

  288. 

  289. /**

  290.  * common check before starting decoding bundle data

  291.  *

  292.  * @param gb context for reading bits

  293.  * @param b  bundle

  294.  * @param t  variable where number of elements to decode will be stored

  295.  */

  296. #define CHECK_READ_VAL(gb, b, t) \

  297.     if (!b->cur_dec || (b->cur_dec > b->cur_ptr)) \

  298.         return 0; \

  299.     t = get_bits(gb, b->len); \

  300.     if (!t) { \

  301.         b->cur_dec = NULL; \

  302.         return 0; \

  303.     } \

  304. 

  305. static int read_runs(AVCodecContext *avctx, GetBitContext *gb, Bundle *b)

  306. {

  307.     int t, v;

  308.     const uint8_t *dec_end;

  309. 

  310.     CHECK_READ_VAL(gb, b, t);

  311.     dec_end = b->cur_dec + t;

  312.     if (dec_end > b->data_end) {

  313.         av_log(avctx, AV_LOG_ERROR, "Run value went out of bounds\n");

  314.         return -1;

  315.     }

  316.     if (get_bits1(gb)) {

  317.         v = get_bits(gb, 4);

  318.         memset(b->cur_dec, v, t);

  319.         b->cur_dec += t;

  320.     } else {

  321.         while (b->cur_dec < dec_end)

  322.             *b->cur_dec++ = GET_HUFF(gb, b->tree);

  323.     }

  324.     return 0;

  325. }

  326. 

  327. static int read_motion_values(AVCodecContext *avctx, GetBitContext *gb, Bundle *b)

  328. {

  329.     int t, sign, v;

  330.     const uint8_t *dec_end;

  331. 

  332.     CHECK_READ_VAL(gb, b, t);

  333.     dec_end = b->cur_dec + t;

  334.     if (dec_end > b->data_end) {

  335.         av_log(avctx, AV_LOG_ERROR, "Too many motion values\n");

  336.         return -1;

  337.     }

  338.     if (get_bits1(gb)) {

  339.         v = get_bits(gb, 4);

  340.         if (v) {

  341.             sign = -get_bits1(gb);

  342.             v = (v ^ sign) - sign;

  343.         }

  344.         memset(b->cur_dec, v, t);

  345.         b->cur_dec += t;

  346.     } else {

  347.         do {

  348.             v = GET_HUFF(gb, b->tree);

  349.             if (v) {

  350.                 sign = -get_bits1(gb);

  351.                 v = (v ^ sign) - sign;

  352.             }

  353.             *b->cur_dec++ = v;

  354.         } while (b->cur_dec < dec_end);

  355.     }

  356.     return 0;

  357. }

  358. 

  359. static const uint8_t bink_rlelens[4] = { 4, 8, 12, 32 };

  360. 

  361. static int read_block_types(AVCodecContext *avctx, GetBitContext *gb, Bundle *b)

  362. {

  363.     int t, v;

  364.     int last = 0;

  365.     const uint8_t *dec_end;

  366. 

  367.     CHECK_READ_VAL(gb, b, t);

  368.     dec_end = b->cur_dec + t;

  369.     if (dec_end > b->data_end) {

  370.         av_log(avctx, AV_LOG_ERROR, "Too many block type values\n");

  371.         return -1;

  372.     }

  373.     if (get_bits1(gb)) {

  374.         v = get_bits(gb, 4);

  375.         memset(b->cur_dec, v, t);

  376.         b->cur_dec += t;

  377.     } else {

  378.         do {

  379.             v = GET_HUFF(gb, b->tree);

  380.             if (v < 12) {

  381.                 last = v;

  382.                 *b->cur_dec++ = v;

  383.             } else {

  384.                 int run = bink_rlelens[v - 12];

  385. 

  386.                 memset(b->cur_dec, last, run);

  387.                 b->cur_dec += run;

  388.             }

  389.         } while (b->cur_dec < dec_end);

  390.     }

  391.     return 0;

  392. }

  393. 

  394. static int read_patterns(AVCodecContext *avctx, GetBitContext *gb, Bundle *b)

  395. {

  396.     int t, v;

  397.     const uint8_t *dec_end;

  398. 

  399.     CHECK_READ_VAL(gb, b, t);

  400.     dec_end = b->cur_dec + t;

  401.     if (dec_end > b->data_end) {

  402.         av_log(avctx, AV_LOG_ERROR, "Too many pattern values\n");

  403.         return -1;

  404.     }

  405.     while (b->cur_dec < dec_end) {

  406.         v  = GET_HUFF(gb, b->tree);

  407.         v |= GET_HUFF(gb, b->tree) << 4;

  408.         *b->cur_dec++ = v;

  409.     }

  410. 

  411.     return 0;

  412. }

  413. 

  414. static int read_colors(GetBitContext *gb, Bundle *b, BinkContext *c)

  415. {

  416.     int t, sign, v;

  417.     const uint8_t *dec_end;

  418. 

  419.     CHECK_READ_VAL(gb, b, t);

  420.     dec_end = b->cur_dec + t;

  421.     if (dec_end > b->data_end) {

  422.         av_log(c->avctx, AV_LOG_ERROR, "Too many color values\n");

  423.         return -1;

  424.     }

  425.     if (get_bits1(gb)) {

  426.         c->col_lastval = GET_HUFF(gb, c->col_high[c->col_lastval]);

  427.         v = GET_HUFF(gb, b->tree);

  428.         v = (c->col_lastval << 4) | v;

  429.         if (c->version < 'i') {

  430.             sign = ((int8_t) v) >> 7;

  431.             v = ((v & 0x7F) ^ sign) - sign;

  432.             v += 0x80;

  433.         }

  434.         memset(b->cur_dec, v, t);

  435.         b->cur_dec += t;

  436.     } else {

  437.         while (b->cur_dec < dec_end) {

  438.             c->col_lastval = GET_HUFF(gb, c->col_high[c->col_lastval]);

  439.             v = GET_HUFF(gb, b->tree);

  440.             v = (c->col_lastval << 4) | v;

  441.             if (c->version < 'i') {

  442.                 sign = ((int8_t) v) >> 7;

  443.                 v = ((v & 0x7F) ^ sign) - sign;

  444.                 v += 0x80;

  445.             }

  446.             *b->cur_dec++ = v;

  447.         }

  448.     }

  449.     return 0;

  450. }

  451. 

  452. /** number of bits used to store first DC value in bundle */

  453. #define DC_START_BITS 11

  454. 

  455. static int read_dcs(AVCodecContext *avctx, GetBitContext *gb, Bundle *b,

  456.                     int start_bits, int has_sign)

  457. {

  458.     int i, j, len, len2, bsize, sign, v, v2;

  459.     int16_t *dst = (int16_t*)b->cur_dec;

  460. 

  461.     CHECK_READ_VAL(gb, b, len);

  462.     v = get_bits(gb, start_bits - has_sign);

  463.     if (v && has_sign) {

  464.         sign = -get_bits1(gb);

  465.         v = (v ^ sign) - sign;

  466.     }

  467.     *dst++ = v;

  468.     len--;

  469.     for (i = 0; i < len; i += 8) {

  470.         len2 = FFMIN(len - i, 8);

  471.         bsize = get_bits(gb, 4);

  472.         if (bsize) {

  473.             for (j = 0; j < len2; j++) {

  474.                 v2 = get_bits(gb, bsize);

  475.                 if (v2) {

  476.                     sign = -get_bits1(gb);

  477.                     v2 = (v2 ^ sign) - sign;

  478.                 }

  479.                 v += v2;

  480.                 *dst++ = v;

  481.                 if (v < -32768 || v > 32767) {

  482.                     av_log(avctx, AV_LOG_ERROR, "DC value went out of bounds: %d\n", v);

  483.                     return -1;

  484.                 }

  485.             }

  486.         } else {

  487.             for (j = 0; j < len2; j++)

  488.                 *dst++ = v;

  489.         }

  490.     }

  491. 

  492.     b->cur_dec = (uint8_t*)dst;

  493.     return 0;

  494. }

  495. 

  496. /**

  497.  * Retrieve next value from bundle.

  498.  *

  499.  * @param c      decoder context

  500.  * @param bundle bundle number

  501.  */

  502. static inline int get_value(BinkContext *c, int bundle)

  503. {

  504.     int ret;

  505. 

  506.     if (bundle < BINK_SRC_X_OFF || bundle == BINK_SRC_RUN)

  507.         return *c->bundle[bundle].cur_ptr++;

  508.     if (bundle == BINK_SRC_X_OFF || bundle == BINK_SRC_Y_OFF)

  509.         return (int8_t)*c->bundle[bundle].cur_ptr++;

  510.     ret = *(int16_t*)c->bundle[bundle].cur_ptr;

  511.     c->bundle[bundle].cur_ptr += 2;

  512.     return ret;

  513. }

  514. 

  515. static void binkb_init_bundle(BinkContext *c, int bundle_num)

  516. {

  517.     c->bundle[bundle_num].cur_dec =

  518.     c->bundle[bundle_num].cur_ptr = c->bundle[bundle_num].data;

  519.     c->bundle[bundle_num].len = 13;

  520. }

  521. 

  522. static void binkb_init_bundles(BinkContext *c)

  523. {

  524.     int i;

  525.     for (i = 0; i < BINKB_NB_SRC; i++)

  526.         binkb_init_bundle(c, i);

  527. }

  528. 

  529. static int binkb_read_bundle(BinkContext *c, GetBitContext *gb, int bundle_num)

  530. {

  531.     const int bits = binkb_bundle_sizes[bundle_num];

  532.     const int mask = 1 << (bits - 1);

  533.     const int issigned = binkb_bundle_signed[bundle_num];

  534.     Bundle *b = &c->bundle[bundle_num];

  535.     int i, len;

  536. 

  537.     CHECK_READ_VAL(gb, b, len);

  538.     if (bits <= 8) {

  539.         if (!issigned) {

  540.             for (i = 0; i < len; i++)

  541.                 *b->cur_dec++ = get_bits(gb, bits);

  542.         } else {

  543.             for (i = 0; i < len; i++)

  544.                 *b->cur_dec++ = get_bits(gb, bits) - mask;

  545.         }

  546.     } else {

  547.         int16_t *dst = (int16_t*)b->cur_dec;

  548. 

  549.         if (!issigned) {

  550.             for (i = 0; i < len; i++)

  551.                 *dst++ = get_bits(gb, bits);

  552.         } else {

  553.             for (i = 0; i < len; i++)

  554.                 *dst++ = get_bits(gb, bits) - mask;

  555.         }

  556.         b->cur_dec = (uint8_t*)dst;

  557.     }

  558.     return 0;

  559. }

  560. 

  561. static inline int binkb_get_value(BinkContext *c, int bundle_num)

  562. {

  563.     int16_t ret;

  564.     const int bits = binkb_bundle_sizes[bundle_num];

  565. 

  566.     if (bits <= 8) {

  567.         int val = *c->bundle[bundle_num].cur_ptr++;

  568.         return binkb_bundle_signed[bundle_num] ? (int8_t)val : val;

  569.     }

  570.     ret = *(int16_t*)c->bundle[bundle_num].cur_ptr;

  571.     c->bundle[bundle_num].cur_ptr += 2;

  572.     return ret;

  573. }

  574. 

  575. /**

  576.  * Read 8x8 block of DCT coefficients.

  577.  *

  578.  * @param gb       context for reading bits

  579.  * @param block    place for storing coefficients

  580.  * @param scan     scan order table

  581.  * @param quant_matrices quantization matrices

  582.  * @return 0 for success, negative value in other cases

  583.  */

  584. static int read_dct_coeffs(GetBitContext *gb, int32_t block[64], const uint8_t *scan,

  585.                            const int32_t quant_matrices[16][64], int q)

  586. {

  587.     int coef_list[128];

  588.     int mode_list[128];

  589.     int i, t, mask, bits, ccoef, mode, sign;

  590.     int list_start = 64, list_end = 64, list_pos;

  591.     int coef_count = 0;

  592.     int coef_idx[64];

  593.     int quant_idx;

  594.     const int32_t *quant;

  595. 

  596.     coef_list[list_end] = 4;  mode_list[list_end++] = 0;

  597.     coef_list[list_end] = 24; mode_list[list_end++] = 0;

  598.     coef_list[list_end] = 44; mode_list[list_end++] = 0;

  599.     coef_list[list_end] = 1;  mode_list[list_end++] = 3;

  600.     coef_list[list_end] = 2;  mode_list[list_end++] = 3;

  601.     coef_list[list_end] = 3;  mode_list[list_end++] = 3;

  602. 

  603.     bits = get_bits(gb, 4) - 1;

  604.     for (mask = 1 << bits; bits >= 0; mask >>= 1, bits--) {

  605.         list_pos = list_start;

  606.         while (list_pos < list_end) {

  607.             if (!(mode_list[list_pos] | coef_list[list_pos]) || !get_bits1(gb)) {

  608.                 list_pos++;

  609.                 continue;

  610.             }

  611.             ccoef = coef_list[list_pos];

  612.             mode  = mode_list[list_pos];

  613.             switch (mode) {

  614.             case 0:

  615.                 coef_list[list_pos] = ccoef + 4;

  616.                 mode_list[list_pos] = 1;

  617.             case 2:

  618.                 if (mode == 2) {

  619.                     coef_list[list_pos]   = 0;

  620.                     mode_list[list_pos++] = 0;

  621.                 }

  622.                 for (i = 0; i < 4; i++, ccoef++) {

  623.                     if (get_bits1(gb)) {

  624.                         coef_list[--list_start] = ccoef;

  625.                         mode_list[  list_start] = 3;

  626.                     } else {

  627.                         if (!bits) {

  628.                             t = 1 - (get_bits1(gb) << 1);

  629.                         } else {

  630.                             t = get_bits(gb, bits) | mask;

  631.                             sign = -get_bits1(gb);

  632.                             t = (t ^ sign) - sign;

  633.                         }

  634.                         block[scan[ccoef]] = t;

  635.                         coef_idx[coef_count++] = ccoef;

  636.                     }

  637.                 }

  638.                 break;

  639.             case 1:

  640.                 mode_list[list_pos] = 2;

  641.                 for (i = 0; i < 3; i++) {

  642.                     ccoef += 4;

  643.                     coef_list[list_end]   = ccoef;

  644.                     mode_list[list_end++] = 2;

  645.                 }

  646.                 break;

  647.             case 3:

  648.                 if (!bits) {

  649.                     t = 1 - (get_bits1(gb) << 1);

  650.                 } else {

  651.                     t = get_bits(gb, bits) | mask;

  652.                     sign = -get_bits1(gb);

  653.                     t = (t ^ sign) - sign;

  654.                 }

  655.                 block[scan[ccoef]] = t;

  656.                 coef_idx[coef_count++] = ccoef;

  657.                 coef_list[list_pos]   = 0;

  658.                 mode_list[list_pos++] = 0;

  659.                 break;

  660.             }

  661.         }

  662.     }

  663. 

  664.     if (q == -1) {

  665.         quant_idx = get_bits(gb, 4);

  666.     } else {

  667.         quant_idx = q;

  668.     }

  669. 

  670.     quant = quant_matrices[quant_idx];

  671. 

  672.     block[0] = (block[0] * quant[0]) >> 11;

  673.     for (i = 0; i < coef_count; i++) {

  674.         int idx = coef_idx[i];

  675.         block[scan[idx]] = (block[scan[idx]] * quant[idx]) >> 11;

  676.     }

  677. 

  678.     return 0;

  679. }

  680. 

  681. /**

  682.  * Read 8x8 block with residue after motion compensation.

  683.  *

  684.  * @param gb          context for reading bits

  685.  * @param block       place to store read data

  686.  * @param masks_count number of masks to decode

  687.  * @return 0 on success, negative value in other cases

  688.  */

  689. static int read_residue(GetBitContext *gb, DCTELEM block[64], int masks_count)

  690. {

  691.     int coef_list[128];

  692.     int mode_list[128];

  693.     int i, sign, mask, ccoef, mode;

  694.     int list_start = 64, list_end = 64, list_pos;

  695.     int nz_coeff[64];

  696.     int nz_coeff_count = 0;

  697. 

  698.     coef_list[list_end] =  4; mode_list[list_end++] = 0;

  699.     coef_list[list_end] = 24; mode_list[list_end++] = 0;

  700.     coef_list[list_end] = 44; mode_list[list_end++] = 0;

  701.     coef_list[list_end] =  0; mode_list[list_end++] = 2;

  702. 

  703.     for (mask = 1 << get_bits(gb, 3); mask; mask >>= 1) {

  704.         for (i = 0; i < nz_coeff_count; i++) {

  705.             if (!get_bits1(gb))

  706.                 continue;

  707.             if (block[nz_coeff[i]] < 0)

  708.                 block[nz_coeff[i]] -= mask;

  709.             else

  710.                 block[nz_coeff[i]] += mask;

  711.             masks_count--;

  712.             if (masks_count < 0)

  713.                 return 0;

  714.         }

  715.         list_pos = list_start;

  716.         while (list_pos < list_end) {

  717.             if (!(coef_list[list_pos] | mode_list[list_pos]) || !get_bits1(gb)) {

  718.                 list_pos++;

  719.                 continue;

  720.             }

  721.             ccoef = coef_list[list_pos];

  722.             mode  = mode_list[list_pos];

  723.             switch (mode) {

  724.             case 0:

  725.                 coef_list[list_pos] = ccoef + 4;

  726.                 mode_list[list_pos] = 1;

  727.             case 2:

  728.                 if (mode == 2) {

  729.                     coef_list[list_pos]   = 0;

  730.                     mode_list[list_pos++] = 0;

  731.                 }

  732.                 for (i = 0; i < 4; i++, ccoef++) {

  733.                     if (get_bits1(gb)) {

  734.                         coef_list[--list_start] = ccoef;

  735.                         mode_list[  list_start] = 3;

  736.                     } else {

  737.                         nz_coeff[nz_coeff_count++] = bink_scan[ccoef];

  738.                         sign = -get_bits1(gb);

  739.                         block[bink_scan[ccoef]] = (mask ^ sign) - sign;

  740.                         masks_count--;

  741.                         if (masks_count < 0)

  742.                             return 0;

  743.                     }

  744.                 }

  745.                 break;

  746.             case 1:

  747.                 mode_list[list_pos] = 2;

  748.                 for (i = 0; i < 3; i++) {

  749.                     ccoef += 4;

  750.                     coef_list[list_end]   = ccoef;

  751.                     mode_list[list_end++] = 2;

  752.                 }

  753.                 break;

  754.             case 3:

  755.                 nz_coeff[nz_coeff_count++] = bink_scan[ccoef];

  756.                 sign = -get_bits1(gb);

  757.                 block[bink_scan[ccoef]] = (mask ^ sign) - sign;

  758.                 coef_list[list_pos]   = 0;

  759.                 mode_list[list_pos++] = 0;

  760.                 masks_count--;

  761.                 if (masks_count < 0)

  762.                     return 0;

  763.                 break;

  764.             }

  765.         }

  766.     }

  767. 

  768.     return 0;

  769. }

  770. 

  771. /**

  772.  * Copy 8x8 block from source to destination, where src and dst may be overlapped

  773.  */

  774. static inline void put_pixels8x8_overlapped(uint8_t *dst, uint8_t *src, int stride)

  775. {

  776.     uint8_t tmp[64];

  777.     int i;

  778.     for (i = 0; i < 8; i++)

  779.         memcpy(tmp + i*8, src + i*stride, 8);

  780.     for (i = 0; i < 8; i++)

  781.         memcpy(dst + i*stride, tmp + i*8, 8);

  782. }

  783. 

  784. static int binkb_decode_plane(BinkContext *c, GetBitContext *gb, int plane_idx,

  785.                               int is_key, int is_chroma)

  786. {

  787.     int blk;

  788.     int i, j, bx, by;

  789.     uint8_t *dst, *ref, *ref_start, *ref_end;

  790.     int v, col[2];

  791.     const uint8_t *scan;

  792.     int xoff, yoff;

  793.     LOCAL_ALIGNED_16(DCTELEM, block, [64]);

  794.     LOCAL_ALIGNED_16(int32_t, dctblock, [64]);

  795.     int coordmap[64];

  796.     int ybias = is_key ? -15 : 0;

  797.     int qp;

  798. 

  799.     const int stride = c->pic.linesize[plane_idx];

  800.     int bw = is_chroma ? (c->avctx->width  + 15) >> 4 : (c->avctx->width  + 7) >> 3;

  801.     int bh = is_chroma ? (c->avctx->height + 15) >> 4 : (c->avctx->height + 7) >> 3;

  802. 

  803.     binkb_init_bundles(c);

  804.     ref_start = c->pic.data[plane_idx];

  805.     ref_end   = c->pic.data[plane_idx] + (bh * c->pic.linesize[plane_idx] + bw) * 8;

  806. 

  807.     for (i = 0; i < 64; i++)

  808.         coordmap[i] = (i & 7) + (i >> 3) * stride;

  809. 

  810.     for (by = 0; by < bh; by++) {

  811.         for (i = 0; i < BINKB_NB_SRC; i++) {

  812.             if (binkb_read_bundle(c, gb, i) < 0)

  813.                 return -1;

  814.         }

  815. 

  816.         dst  = c->pic.data[plane_idx]  + 8*by*stride;

  817.         for (bx = 0; bx < bw; bx++, dst += 8) {

  818.             blk = binkb_get_value(c, BINKB_SRC_BLOCK_TYPES);

  819.             switch (blk) {

  820.             case 0:

  821.                 break;

  822.             case 1:

  823.                 scan = bink_patterns[get_bits(gb, 4)];

  824.                 i = 0;

  825.                 do {

  826.                     int mode, run;

  827. 

  828.                     mode = get_bits1(gb);

  829.                     run = get_bits(gb, binkb_runbits[i]) + 1;

  830. 

  831.                     i += run;

  832.                     if (i > 64) {

  833.                         av_log(c->avctx, AV_LOG_ERROR, "Run went out of bounds\n");

  834.                         return -1;

  835.                     }

  836.                     if (mode) {

  837.                         v = binkb_get_value(c, BINKB_SRC_COLORS);

  838.                         for (j = 0; j < run; j++)

  839.                             dst[coordmap[*scan++]] = v;

  840.                     } else {

  841.                         for (j = 0; j < run; j++)

  842.                             dst[coordmap[*scan++]] = binkb_get_value(c, BINKB_SRC_COLORS);

  843.                     }

  844.                 } while (i < 63);

  845.                 if (i == 63)

  846.                     dst[coordmap[*scan++]] = binkb_get_value(c, BINKB_SRC_COLORS);

  847.                 break;

  848.             case 2:

  849.                 memset(dctblock, 0, sizeof(*dctblock) * 64);

  850.                 dctblock[0] = binkb_get_value(c, BINKB_SRC_INTRA_DC);

  851.                 qp = binkb_get_value(c, BINKB_SRC_INTRA_Q);

  852.                 read_dct_coeffs(gb, dctblock, bink_scan, binkb_intra_quant, qp);

  853.                 c->bdsp.idct_put(dst, stride, dctblock);

  854.                 break;

  855.             case 3:

  856.                 xoff = binkb_get_value(c, BINKB_SRC_X_OFF);

  857.                 yoff = binkb_get_value(c, BINKB_SRC_Y_OFF) + ybias;

  858.                 ref = dst + xoff + yoff * stride;

  859.                 if (ref < ref_start || ref + 8*stride > ref_end) {

  860.                     av_log(c->avctx, AV_LOG_WARNING, "Reference block is out of bounds\n");

  861.                 } else if (ref + 8*stride < dst || ref >= dst + 8*stride) {

  862.                     c->dsp.put_pixels_tab[1][0](dst, ref, stride, 8);

  863.                 } else {

  864.                     put_pixels8x8_overlapped(dst, ref, stride);

  865.                 }

  866.                 c->dsp.clear_block(block);

  867.                 v = binkb_get_value(c, BINKB_SRC_INTER_COEFS);

  868.                 read_residue(gb, block, v);

  869.                 c->dsp.add_pixels8(dst, block, stride);

  870.                 break;

  871.             case 4:

  872.                 xoff = binkb_get_value(c, BINKB_SRC_X_OFF);

  873.                 yoff = binkb_get_value(c, BINKB_SRC_Y_OFF) + ybias;

  874.                 ref = dst + xoff + yoff * stride;

  875.                 if (ref < ref_start || ref + 8 * stride > ref_end) {

  876.                     av_log(c->avctx, AV_LOG_WARNING, "Reference block is out of bounds\n");

  877.                 } else if (ref + 8*stride < dst || ref >= dst + 8*stride) {

  878.                     c->dsp.put_pixels_tab[1][0](dst, ref, stride, 8);

  879.                 } else {

  880.                     put_pixels8x8_overlapped(dst, ref, stride);

  881.                 }

  882.                 memset(dctblock, 0, sizeof(*dctblock) * 64);

  883.                 dctblock[0] = binkb_get_value(c, BINKB_SRC_INTER_DC);

  884.                 qp = binkb_get_value(c, BINKB_SRC_INTER_Q);

  885.                 read_dct_coeffs(gb, dctblock, bink_scan, binkb_inter_quant, qp);

  886.                 c->bdsp.idct_add(dst, stride, dctblock);

  887.                 break;

  888.             case 5:

  889.                 v = binkb_get_value(c, BINKB_SRC_COLORS);

  890.                 c->dsp.fill_block_tab[1](dst, v, stride, 8);

  891.                 break;

  892.             case 6:

  893.                 for (i = 0; i < 2; i++)

  894.                     col[i] = binkb_get_value(c, BINKB_SRC_COLORS);

  895.                 for (i = 0; i < 8; i++) {

  896.                     v = binkb_get_value(c, BINKB_SRC_PATTERN);

  897.                     for (j = 0; j < 8; j++, v >>= 1)

  898.                         dst[i*stride + j] = col[v & 1];

  899.                 }

  900.                 break;

  901.             case 7:

  902.                 xoff = binkb_get_value(c, BINKB_SRC_X_OFF);

  903.                 yoff = binkb_get_value(c, BINKB_SRC_Y_OFF) + ybias;

  904.                 ref = dst + xoff + yoff * stride;

  905.                 if (ref < ref_start || ref + 8 * stride > ref_end) {

  906.                     av_log(c->avctx, AV_LOG_WARNING, "Reference block is out of bounds\n");

  907.                 } else if (ref + 8*stride < dst || ref >= dst + 8*stride) {

  908.                     c->dsp.put_pixels_tab[1][0](dst, ref, stride, 8);

  909.                 } else {

  910.                     put_pixels8x8_overlapped(dst, ref, stride);

  911.                 }

  912.                 break;

  913.             case 8:

  914.                 for (i = 0; i < 8; i++)

  915.                     memcpy(dst + i*stride, c->bundle[BINKB_SRC_COLORS].cur_ptr + i*8, 8);

  916.                 c->bundle[BINKB_SRC_COLORS].cur_ptr += 64;

  917.                 break;

  918.             default:

  919.                 av_log(c->avctx, AV_LOG_ERROR, "Unknown block type %d\n", blk);

  920.                 return -1;

  921.             }

  922.         }

  923.     }

  924.     if (get_bits_count(gb) & 0x1F) //next plane data starts at 32-bit boundary

  925.         skip_bits_long(gb, 32 - (get_bits_count(gb) & 0x1F));

  926. 

  927.     return 0;

  928. }

  929. 

  930. static int bink_decode_plane(BinkContext *c, GetBitContext *gb, int plane_idx,

  931.                              int is_chroma)

  932. {

  933.     int blk;

  934.     int i, j, bx, by;

  935.     uint8_t *dst, *prev, *ref, *ref_start, *ref_end;

  936.     int v, col[2];

  937.     const uint8_t *scan;

  938.     int xoff, yoff;

  939.     LOCAL_ALIGNED_16(DCTELEM, block, [64]);

  940.     LOCAL_ALIGNED_16(uint8_t, ublock, [64]);

  941.     LOCAL_ALIGNED_16(int32_t, dctblock, [64]);

  942.     int coordmap[64];

  943. 

  944.     const int stride = c->pic.linesize[plane_idx];

  945.     int bw = is_chroma ? (c->avctx->width  + 15) >> 4 : (c->avctx->width  + 7) >> 3;

  946.     int bh = is_chroma ? (c->avctx->height + 15) >> 4 : (c->avctx->height + 7) >> 3;

  947.     int width = c->avctx->width >> is_chroma;

  948. 

  949.     init_lengths(c, FFMAX(width, 8), bw);

  950.     for (i = 0; i < BINK_NB_SRC; i++)

  951.         read_bundle(gb, c, i);

  952. 

  953.     ref_start = c->last.data[plane_idx] ? c->last.data[plane_idx]

  954.                                         : c->pic.data[plane_idx];

  955.     ref_end   = ref_start

  956.                 + (bw - 1 + c->last.linesize[plane_idx] * (bh - 1)) * 8;

  957. 

  958.     for (i = 0; i < 64; i++)

  959.         coordmap[i] = (i & 7) + (i >> 3) * stride;

  960. 

  961.     for (by = 0; by < bh; by++) {

  962.         if (read_block_types(c->avctx, gb, &c->bundle[BINK_SRC_BLOCK_TYPES]) < 0)

  963.             return -1;

  964.         if (read_block_types(c->avctx, gb, &c->bundle[BINK_SRC_SUB_BLOCK_TYPES]) < 0)

  965.             return -1;

  966.         if (read_colors(gb, &c->bundle[BINK_SRC_COLORS], c) < 0)

  967.             return -1;

  968.         if (read_patterns(c->avctx, gb, &c->bundle[BINK_SRC_PATTERN]) < 0)

  969.             return -1;

  970.         if (read_motion_values(c->avctx, gb, &c->bundle[BINK_SRC_X_OFF]) < 0)

  971.             return -1;

  972.         if (read_motion_values(c->avctx, gb, &c->bundle[BINK_SRC_Y_OFF]) < 0)

  973.             return -1;

  974.         if (read_dcs(c->avctx, gb, &c->bundle[BINK_SRC_INTRA_DC], DC_START_BITS, 0) < 0)

  975.             return -1;

  976.         if (read_dcs(c->avctx, gb, &c->bundle[BINK_SRC_INTER_DC], DC_START_BITS, 1) < 0)

  977.             return -1;

  978.         if (read_runs(c->avctx, gb, &c->bundle[BINK_SRC_RUN]) < 0)

  979.             return -1;

  980. 

  981.         if (by == bh)

  982.             break;

  983.         dst  = c->pic.data[plane_idx]  + 8*by*stride;

  984.         prev = (c->last.data[plane_idx] ? c->last.data[plane_idx]

  985.                                         : c->pic.data[plane_idx]) + 8*by*stride;

  986.         for (bx = 0; bx < bw; bx++, dst += 8, prev += 8) {

  987.             blk = get_value(c, BINK_SRC_BLOCK_TYPES);

  988.             // 16x16 block type on odd line means part of the already decoded block, so skip it

  989.             if ((by & 1) && blk == SCALED_BLOCK) {

  990.                 bx++;

  991.                 dst  += 8;

  992.                 prev += 8;

  993.                 continue;

  994.             }

  995.             switch (blk) {

  996.             case SKIP_BLOCK:

  997.                 c->dsp.put_pixels_tab[1][0](dst, prev, stride, 8);

  998.                 break;

  999.             case SCALED_BLOCK:

  1000.                 blk = get_value(c, BINK_SRC_SUB_BLOCK_TYPES);

  1001.                 switch (blk) {

  1002.                 case RUN_BLOCK:

  1003.                     scan = bink_patterns[get_bits(gb, 4)];

  1004.                     i = 0;

  1005.                     do {

  1006.                         int run = get_value(c, BINK_SRC_RUN) + 1;

  1007. 

  1008.                         i += run;

  1009.                         if (i > 64) {

  1010.                             av_log(c->avctx, AV_LOG_ERROR, "Run went out of bounds\n");

  1011.                             return -1;

  1012.                         }

  1013.                         if (get_bits1(gb)) {

  1014.                             v = get_value(c, BINK_SRC_COLORS);

  1015.                             for (j = 0; j < run; j++)

  1016.                                 ublock[*scan++] = v;

  1017.                         } else {

  1018.                             for (j = 0; j < run; j++)

  1019.                                 ublock[*scan++] = get_value(c, BINK_SRC_COLORS);

  1020.                         }

  1021.                     } while (i < 63);

  1022.                     if (i == 63)

  1023.                         ublock[*scan++] = get_value(c, BINK_SRC_COLORS);

  1024.                     break;

  1025.                 case INTRA_BLOCK:

  1026.                     memset(dctblock, 0, sizeof(*dctblock) * 64);

  1027.                     dctblock[0] = get_value(c, BINK_SRC_INTRA_DC);

  1028.                     read_dct_coeffs(gb, dctblock, bink_scan, bink_intra_quant, -1);

  1029.                     c->bdsp.idct_put(ublock, 8, dctblock);

  1030.                     break;

  1031.                 case FILL_BLOCK:

  1032.                     v = get_value(c, BINK_SRC_COLORS);

  1033.                     c->dsp.fill_block_tab[0](dst, v, stride, 16);

  1034.                     break;

  1035.                 case PATTERN_BLOCK:

  1036.                     for (i = 0; i < 2; i++)

  1037.                         col[i] = get_value(c, BINK_SRC_COLORS);

  1038.                     for (j = 0; j < 8; j++) {

  1039.                         v = get_value(c, BINK_SRC_PATTERN);

  1040.                         for (i = 0; i < 8; i++, v >>= 1)

  1041.                             ublock[i + j*8] = col[v & 1];

  1042.                     }

  1043.                     break;

  1044.                 case RAW_BLOCK:

  1045.                     for (j = 0; j < 8; j++)

  1046.                         for (i = 0; i < 8; i++)

  1047.                             ublock[i + j*8] = get_value(c, BINK_SRC_COLORS);

  1048.                     break;

  1049.                 default:

  1050.                     av_log(c->avctx, AV_LOG_ERROR, "Incorrect 16x16 block type %d\n", blk);

  1051.                     return -1;

  1052.                 }

  1053.                 if (blk != FILL_BLOCK)

  1054.                 c->bdsp.scale_block(ublock, dst, stride);

  1055.                 bx++;

  1056.                 dst  += 8;

  1057.                 prev += 8;

  1058.                 break;

  1059.             case MOTION_BLOCK:

  1060.                 xoff = get_value(c, BINK_SRC_X_OFF);

  1061.                 yoff = get_value(c, BINK_SRC_Y_OFF);

  1062.                 ref = prev + xoff + yoff * stride;

  1063.                 if (ref < ref_start || ref > ref_end) {

  1064.                     av_log(c->avctx, AV_LOG_ERROR, "Copy out of bounds @%d, %d\n",

  1065.                            bx*8 + xoff, by*8 + yoff);

  1066.                     return -1;

  1067.                 }

  1068.                 c->dsp.put_pixels_tab[1][0](dst, ref, stride, 8);

  1069.                 break;

  1070.             case RUN_BLOCK:

  1071.                 scan = bink_patterns[get_bits(gb, 4)];

  1072.                 i = 0;

  1073.                 do {

  1074.                     int run = get_value(c, BINK_SRC_RUN) + 1;

  1075. 

  1076.                     i += run;

  1077.                     if (i > 64) {

  1078.                         av_log(c->avctx, AV_LOG_ERROR, "Run went out of bounds\n");

  1079.                         return -1;

  1080.                     }

  1081.                     if (get_bits1(gb)) {

  1082.                         v = get_value(c, BINK_SRC_COLORS);

  1083.                         for (j = 0; j < run; j++)

  1084.                             dst[coordmap[*scan++]] = v;

  1085.                     } else {

  1086.                         for (j = 0; j < run; j++)

  1087.                             dst[coordmap[*scan++]] = get_value(c, BINK_SRC_COLORS);

  1088.                     }

  1089.                 } while (i < 63);

  1090.                 if (i == 63)

  1091.                     dst[coordmap[*scan++]] = get_value(c, BINK_SRC_COLORS);

  1092.                 break;

  1093.             case RESIDUE_BLOCK:

  1094.                 xoff = get_value(c, BINK_SRC_X_OFF);

  1095.                 yoff = get_value(c, BINK_SRC_Y_OFF);

  1096.                 ref = prev + xoff + yoff * stride;

  1097.                 if (ref < ref_start || ref > ref_end) {

  1098.                     av_log(c->avctx, AV_LOG_ERROR, "Copy out of bounds @%d, %d\n",

  1099.                            bx*8 + xoff, by*8 + yoff);

  1100.                     return -1;

  1101.                 }

  1102.                 c->dsp.put_pixels_tab[1][0](dst, ref, stride, 8);

  1103.                 c->dsp.clear_block(block);

  1104.                 v = get_bits(gb, 7);

  1105.                 read_residue(gb, block, v);

  1106.                 c->dsp.add_pixels8(dst, block, stride);

  1107.                 break;

  1108.             case INTRA_BLOCK:

  1109.                 memset(dctblock, 0, sizeof(*dctblock) * 64);

  1110.                 dctblock[0] = get_value(c, BINK_SRC_INTRA_DC);

  1111.                 read_dct_coeffs(gb, dctblock, bink_scan, bink_intra_quant, -1);

  1112.                 c->bdsp.idct_put(dst, stride, dctblock);

  1113.                 break;

  1114.             case FILL_BLOCK:

  1115.                 v = get_value(c, BINK_SRC_COLORS);

  1116.                 c->dsp.fill_block_tab[1](dst, v, stride, 8);

  1117.                 break;

  1118.             case INTER_BLOCK:

  1119.                 xoff = get_value(c, BINK_SRC_X_OFF);

  1120.                 yoff = get_value(c, BINK_SRC_Y_OFF);

  1121.                 ref = prev + xoff + yoff * stride;

  1122.                 c->dsp.put_pixels_tab[1][0](dst, ref, stride, 8);

  1123.                 memset(dctblock, 0, sizeof(*dctblock) * 64);

  1124.                 dctblock[0] = get_value(c, BINK_SRC_INTER_DC);

  1125.                 read_dct_coeffs(gb, dctblock, bink_scan, bink_inter_quant, -1);

  1126.                 c->bdsp.idct_add(dst, stride, dctblock);

  1127.                 break;

  1128.             case PATTERN_BLOCK:

  1129.                 for (i = 0; i < 2; i++)

  1130.                     col[i] = get_value(c, BINK_SRC_COLORS);

  1131.                 for (i = 0; i < 8; i++) {

  1132.                     v = get_value(c, BINK_SRC_PATTERN);

  1133.                     for (j = 0; j < 8; j++, v >>= 1)

  1134.                         dst[i*stride + j] = col[v & 1];

  1135.                 }

  1136.                 break;

  1137.             case RAW_BLOCK:

  1138.                 for (i = 0; i < 8; i++)

  1139.                     memcpy(dst + i*stride, c->bundle[BINK_SRC_COLORS].cur_ptr + i*8, 8);

  1140.                 c->bundle[BINK_SRC_COLORS].cur_ptr += 64;

  1141.                 break;

  1142.             default:

  1143.                 av_log(c->avctx, AV_LOG_ERROR, "Unknown block type %d\n", blk);

  1144.                 return -1;

  1145.             }

  1146.         }

  1147.     }

  1148.     if (get_bits_count(gb) & 0x1F) //next plane data starts at 32-bit boundary

  1149.         skip_bits_long(gb, 32 - (get_bits_count(gb) & 0x1F));

  1150. 

  1151.     return 0;

  1152. }

  1153. 

  1154. static int decode_frame(AVCodecContext *avctx, void *data, int *data_size, AVPacket *pkt)

  1155. {

  1156.     BinkContext * const c = avctx->priv_data;

  1157.     GetBitContext gb;

  1158.     int plane, plane_idx;

  1159.     int bits_count = pkt->size << 3;

  1160. 

  1161.     if (c->version > 'b') {

  1162.         if(c->pic.data[0])

  1163.             avctx->release_buffer(avctx, &c->pic);

  1164. 

  1165.         if(avctx->get_buffer(avctx, &c->pic) < 0){

  1166.             av_log(avctx, AV_LOG_ERROR, "get_buffer() failed\n");

  1167.             return -1;

  1168.         }

  1169.     } else {

  1170.         if(avctx->reget_buffer(avctx, &c->pic) < 0){

  1171.             av_log(avctx, AV_LOG_ERROR, "reget_buffer() failed\n");

  1172.             return -1;

  1173.         }

  1174.     }

  1175. 

  1176.     init_get_bits(&gb, pkt->data, bits_count);

  1177.     if (c->has_alpha) {

  1178.         if (c->version >= 'i')

  1179.             skip_bits_long(&gb, 32);

  1180.         if (bink_decode_plane(c, &gb, 3, 0) < 0)

  1181.             return -1;

  1182.     }

  1183.     if (c->version >= 'i')

  1184.         skip_bits_long(&gb, 32);

  1185. 

  1186.     for (plane = 0; plane < 3; plane++) {

  1187.         plane_idx = (!plane || !c->swap_planes) ? plane : (plane ^ 3);

  1188. 

  1189.         if (c->version > 'b') {

  1190.             if (bink_decode_plane(c, &gb, plane_idx, !!plane) < 0)

  1191.                 return -1;

  1192.         } else {

  1193.             if (binkb_decode_plane(c, &gb, plane_idx, !pkt->pts, !!plane) < 0)

  1194.                 return -1;

  1195.         }

  1196.         if (get_bits_count(&gb) >= bits_count)

  1197.             break;

  1198.     }

  1199.     emms_c();

  1200. 

  1201.     *data_size = sizeof(AVFrame);

  1202.     *(AVFrame*)data = c->pic;

  1203. 

  1204.     if (c->version > 'b')

  1205.         FFSWAP(AVFrame, c->pic, c->last);

  1206. 

  1207.     /* always report that the buffer was completely consumed */

  1208.     return pkt->size;

  1209. }

  1210. 

  1211. /**

  1212.  * Caclulate quantization tables for version b

  1213.  */

  1214. static av_cold void binkb_calc_quant(void)

  1215. {

  1216.     uint8_t inv_bink_scan[64];

  1217.     double s[64];

  1218.     int i, j;

  1219. 

  1220.     for (j = 0; j < 8; j++) {

  1221.         for (i = 0; i < 8; i++) {

  1222.             if (j && j != 4)

  1223.                if (i && i != 4)

  1224.                    s[j*8 + i] = cos(j * M_PI/16.0) * cos(i * M_PI/16.0) * 2.0;

  1225.                else

  1226.                    s[j*8 + i] = cos(j * M_PI/16.0) * sqrt(2.0);

  1227.             else

  1228.                if (i && i != 4)

  1229.                    s[j*8 + i] = cos(i * M_PI/16.0) * sqrt(2.0);

  1230.                else

  1231.                    s[j*8 + i] = 1.0;

  1232.         }

  1233.     }

  1234. 

  1235.     for (i = 0; i < 64; i++)

  1236.         inv_bink_scan[bink_scan[i]] = i;

  1237. 

  1238.     for (j = 0; j < 16; j++) {

  1239.         for (i = 0; i < 64; i++) {

  1240.             int k = inv_bink_scan[i];

  1241.             if (s[i] == 1.0) {

  1242.                 binkb_intra_quant[j][k] = (1L << 12) * binkb_intra_seed[i] *

  1243.                                           binkb_num[j]/binkb_den[j];

  1244.                 binkb_inter_quant[j][k] = (1L << 12) * binkb_inter_seed[i] *

  1245.                                           binkb_num[j]/binkb_den[j];

  1246.             } else {

  1247.                 binkb_intra_quant[j][k] = (1L << 12) * binkb_intra_seed[i] * s[i] *

  1248.                                           binkb_num[j]/(double)binkb_den[j];

  1249.                 binkb_inter_quant[j][k] = (1L << 12) * binkb_inter_seed[i] * s[i] *

  1250.                                           binkb_num[j]/(double)binkb_den[j];

  1251.             }

  1252.         }

  1253.     }

  1254. }

  1255. 

  1256. static av_cold int decode_init(AVCodecContext *avctx)

  1257. {

  1258.     BinkContext * const c = avctx->priv_data;

  1259.     static VLC_TYPE table[16 * 128][2];

  1260.     static int binkb_initialised = 0;

  1261.     int i;

  1262.     int flags;

  1263. 

  1264.     c->version = avctx->codec_tag >> 24;

  1265.     if (avctx->extradata_size < 4) {

  1266.         av_log(avctx, AV_LOG_ERROR, "Extradata missing or too short\n");

  1267.         return -1;

  1268.     }

  1269.     flags = AV_RL32(avctx->extradata);

  1270.     c->has_alpha = flags & BINK_FLAG_ALPHA;

  1271.     c->swap_planes = c->version >= 'h';

  1272.     if (!bink_trees[15].table) {

  1273.         for (i = 0; i < 16; i++) {

  1274.             const int maxbits = bink_tree_lens[i][15];

  1275.             bink_trees[i].table = table + i*128;

  1276.             bink_trees[i].table_allocated = 1 << maxbits;

  1277.             init_vlc(&bink_trees[i], maxbits, 16,

  1278.                      bink_tree_lens[i], 1, 1,

  1279.                      bink_tree_bits[i], 1, 1, INIT_VLC_USE_NEW_STATIC | INIT_VLC_LE);

  1280.         }

  1281.     }

  1282.     c->avctx = avctx;

  1283. 

  1284.     c->pic.data[0] = NULL;

  1285. 

  1286.     if (av_image_check_size(avctx->width, avctx->height, 0, avctx) < 0) {

  1287.         return 1;

  1288.     }

  1289. 

  1290.     avctx->pix_fmt = c->has_alpha ? PIX_FMT_YUVA420P : PIX_FMT_YUV420P;

  1291. 

  1292.     avctx->idct_algo = FF_IDCT_BINK;

  1293.     dsputil_init(&c->dsp, avctx);

  1294.     ff_binkdsp_init(&c->bdsp);

  1295. 

  1296.     init_bundles(c);

  1297. 

  1298.     if (c->version == 'b') {

  1299.         if (!binkb_initialised) {

  1300.             binkb_calc_quant();

  1301.             binkb_initialised = 1;

  1302.         }

  1303.     }

  1304. 

  1305.     return 0;

  1306. }

  1307. 

  1308. static av_cold int decode_end(AVCodecContext *avctx)

  1309. {

  1310.     BinkContext * const c = avctx->priv_data;

  1311. 

  1312.     if (c->pic.data[0])

  1313.         avctx->release_buffer(avctx, &c->pic);

  1314.     if (c->last.data[0])

  1315.         avctx->release_buffer(avctx, &c->last);

  1316. 

  1317.     free_bundles(c);

  1318.     return 0;

  1319. }

  1320. 

  1321. AVCodec ff_bink_decoder = {

  1322.     .name           = "binkvideo",

  1323.     .type           = AVMEDIA_TYPE_VIDEO,

  1324.     .id             = CODEC_ID_BINKVIDEO,

  1325.     .priv_data_size = sizeof(BinkContext),

  1326.     .init           = decode_init,

  1327.     .close          = decode_end,

  1328.     .decode         = decode_frame,

  1329.     .long_name = NULL_IF_CONFIG_SMALL("Bink video"),

  1330. };