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FFmpeg/libavcodec/cavs.c

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  1. /*

  2.  * Chinese AVS video (AVS1-P2, JiZhun profile) decoder.

  3.  * Copyright (c) 2006  Stefan Gehrer <stefan.gehrer@gmx.de>

  4.  *

  5.  * This file is part of Libav.

  6.  *

  7.  * Libav 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.  * Libav 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 Libav; if not, write to the Free Software

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

  20.  */

  21. 

  22. /**

  23.  * @file

  24.  * Chinese AVS video (AVS1-P2, JiZhun profile) decoder

  25.  * @author Stefan Gehrer <stefan.gehrer@gmx.de>

  26.  */

  27. 

  28. #include "avcodec.h"

  29. #include "get_bits.h"

  30. #include "golomb.h"

  31. #include "h264chroma.h"

  32. #include "mathops.h"

  33. #include "qpeldsp.h"

  34. #include "cavs.h"

  35. 

  36. static const uint8_t alpha_tab[64] = {

  37.      0,  0,  0,  0,  0,  0,  1,  1,  1,  1,  1,  2,  2,  2,  3,  3,

  38.      4,  4,  5,  5,  6,  7,  8,  9, 10, 11, 12, 13, 15, 16, 18, 20,

  39.     22, 24, 26, 28, 30, 33, 33, 35, 35, 36, 37, 37, 39, 39, 42, 44,

  40.     46, 48, 50, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64

  41. };

  42. 

  43. static const uint8_t beta_tab[64] = {

  44.      0,  0,  0,  0,  0,  0,  1,  1,  1,  1,  1,  1,  1,  2,  2,  2,

  45.      2,  2,  3,  3,  3,  3,  4,  4,  4,  4,  5,  5,  5,  5,  6,  6,

  46.      6,  7,  7,  7,  8,  8,  8,  9,  9, 10, 10, 11, 11, 12, 13, 14,

  47.     15, 16, 17, 18, 19, 20, 21, 22, 23, 23, 24, 24, 25, 25, 26, 27

  48. };

  49. 

  50. static const uint8_t tc_tab[64] = {

  51.     0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,

  52.     1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 2, 2,

  53.     2, 2, 2, 2, 2, 2, 3, 3, 3, 3, 3, 3, 3, 4, 4, 4,

  54.     5, 5, 5, 6, 6, 6, 7, 7, 7, 7, 8, 8, 8, 9, 9, 9

  55. };

  56. 

  57. /** mark block as unavailable, i.e. out of picture

  58.  *  or not yet decoded */

  59. static const cavs_vector un_mv = { 0, 0, 1, NOT_AVAIL };

  60. 

  61. static const int8_t left_modifier_l[8] = {  0, -1,  6, -1, -1, 7, 6, 7 };

  62. static const int8_t top_modifier_l[8]  = { -1,  1,  5, -1, -1, 5, 7, 7 };

  63. static const int8_t left_modifier_c[7] = {  5, -1,  2, -1,  6, 5, 6 };

  64. static const int8_t top_modifier_c[7]  = {  4,  1, -1, -1,  4, 6, 6 };

  65. 

  66. /*****************************************************************************

  67.  *

  68.  * in-loop deblocking filter

  69.  *

  70.  ****************************************************************************/

  71. 

  72. static inline int get_bs(cavs_vector *mvP, cavs_vector *mvQ, int b)

  73. {

  74.     if ((mvP->ref == REF_INTRA) || (mvQ->ref == REF_INTRA))

  75.         return 2;

  76.     if ((abs(mvP->x - mvQ->x) >= 4) || (abs(mvP->y - mvQ->y) >= 4))

  77.         return 1;

  78.     if (b) {

  79.         mvP += MV_BWD_OFFS;

  80.         mvQ += MV_BWD_OFFS;

  81.         if ((abs(mvP->x - mvQ->x) >= 4) || (abs(mvP->y - mvQ->y) >= 4))

  82.             return 1;

  83.     } else {

  84.         if (mvP->ref != mvQ->ref)

  85.             return 1;

  86.     }

  87.     return 0;

  88. }

  89. 

  90. #define SET_PARAMS                                                \

  91.     alpha = alpha_tab[av_clip(qp_avg + h->alpha_offset, 0, 63)];  \

  92.     beta  =  beta_tab[av_clip(qp_avg + h->beta_offset,  0, 63)];  \

  93.     tc    =    tc_tab[av_clip(qp_avg + h->alpha_offset, 0, 63)];

  94. 

  95. /**

  96.  * in-loop deblocking filter for a single macroblock

  97.  *

  98.  * boundary strength (bs) mapping:

  99.  *

  100.  * --4---5--

  101.  * 0   2   |

  102.  * | 6 | 7 |

  103.  * 1   3   |

  104.  * ---------

  105.  *

  106.  */

  107. void ff_cavs_filter(AVSContext *h, enum cavs_mb mb_type)

  108. {

  109.     uint8_t bs[8];

  110.     int qp_avg, alpha, beta, tc;

  111.     int i;

  112. 

  113.     /* save un-deblocked lines */

  114.     h->topleft_border_y = h->top_border_y[h->mbx * 16 + 15];

  115.     h->topleft_border_u = h->top_border_u[h->mbx * 10 + 8];

  116.     h->topleft_border_v = h->top_border_v[h->mbx * 10 + 8];

  117.     memcpy(&h->top_border_y[h->mbx * 16],     h->cy + 15 * h->l_stride, 16);

  118.     memcpy(&h->top_border_u[h->mbx * 10 + 1], h->cu +  7 * h->c_stride, 8);

  119.     memcpy(&h->top_border_v[h->mbx * 10 + 1], h->cv +  7 * h->c_stride, 8);

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

  121.         h->left_border_y[i * 2 + 1] = *(h->cy + 15 + (i * 2 + 0) * h->l_stride);

  122.         h->left_border_y[i * 2 + 2] = *(h->cy + 15 + (i * 2 + 1) * h->l_stride);

  123.         h->left_border_u[i + 1]     = *(h->cu + 7  +  i          * h->c_stride);

  124.         h->left_border_v[i + 1]     = *(h->cv + 7  +  i          * h->c_stride);

  125.     }

  126.     if (!h->loop_filter_disable) {

  127.         /* determine bs */

  128.         if (mb_type == I_8X8)

  129.             memset(bs, 2, 8);

  130.         else {

  131.             memset(bs, 0, 8);

  132.             if (ff_cavs_partition_flags[mb_type] & SPLITV) {

  133.                 bs[2] = get_bs(&h->mv[MV_FWD_X0], &h->mv[MV_FWD_X1], mb_type > P_8X8);

  134.                 bs[3] = get_bs(&h->mv[MV_FWD_X2], &h->mv[MV_FWD_X3], mb_type > P_8X8);

  135.             }

  136.             if (ff_cavs_partition_flags[mb_type] & SPLITH) {

  137.                 bs[6] = get_bs(&h->mv[MV_FWD_X0], &h->mv[MV_FWD_X2], mb_type > P_8X8);

  138.                 bs[7] = get_bs(&h->mv[MV_FWD_X1], &h->mv[MV_FWD_X3], mb_type > P_8X8);

  139.             }

  140.             bs[0] = get_bs(&h->mv[MV_FWD_A1], &h->mv[MV_FWD_X0], mb_type > P_8X8);

  141.             bs[1] = get_bs(&h->mv[MV_FWD_A3], &h->mv[MV_FWD_X2], mb_type > P_8X8);

  142.             bs[4] = get_bs(&h->mv[MV_FWD_B2], &h->mv[MV_FWD_X0], mb_type > P_8X8);

  143.             bs[5] = get_bs(&h->mv[MV_FWD_B3], &h->mv[MV_FWD_X1], mb_type > P_8X8);

  144.         }

  145.         if (AV_RN64(bs)) {

  146.             if (h->flags & A_AVAIL) {

  147.                 qp_avg = (h->qp + h->left_qp + 1) >> 1;

  148.                 SET_PARAMS;

  149.                 h->cdsp.cavs_filter_lv(h->cy, h->l_stride, alpha, beta, tc, bs[0], bs[1]);

  150.                 h->cdsp.cavs_filter_cv(h->cu, h->c_stride, alpha, beta, tc, bs[0], bs[1]);

  151.                 h->cdsp.cavs_filter_cv(h->cv, h->c_stride, alpha, beta, tc, bs[0], bs[1]);

  152.             }

  153.             qp_avg = h->qp;

  154.             SET_PARAMS;

  155.             h->cdsp.cavs_filter_lv(h->cy + 8,               h->l_stride, alpha, beta, tc, bs[2], bs[3]);

  156.             h->cdsp.cavs_filter_lh(h->cy + 8 * h->l_stride, h->l_stride, alpha, beta, tc, bs[6], bs[7]);

  157. 

  158.             if (h->flags & B_AVAIL) {

  159.                 qp_avg = (h->qp + h->top_qp[h->mbx] + 1) >> 1;

  160.                 SET_PARAMS;

  161.                 h->cdsp.cavs_filter_lh(h->cy, h->l_stride, alpha, beta, tc, bs[4], bs[5]);

  162.                 h->cdsp.cavs_filter_ch(h->cu, h->c_stride, alpha, beta, tc, bs[4], bs[5]);

  163.                 h->cdsp.cavs_filter_ch(h->cv, h->c_stride, alpha, beta, tc, bs[4], bs[5]);

  164.             }

  165.         }

  166.     }

  167.     h->left_qp        = h->qp;

  168.     h->top_qp[h->mbx] = h->qp;

  169. }

  170. 

  171. #undef SET_PARAMS

  172. 

  173. /*****************************************************************************

  174.  *

  175.  * spatial intra prediction

  176.  *

  177.  ****************************************************************************/

  178. 

  179. void ff_cavs_load_intra_pred_luma(AVSContext *h, uint8_t *top,

  180.                                   uint8_t **left, int block)

  181. {

  182.     int i;

  183. 

  184.     switch (block) {

  185.     case 0:

  186.         *left               = h->left_border_y;

  187.         h->left_border_y[0] = h->left_border_y[1];

  188.         memset(&h->left_border_y[17], h->left_border_y[16], 9);

  189.         memcpy(&top[1], &h->top_border_y[h->mbx * 16], 16);

  190.         top[17] = top[16];

  191.         top[0]  = top[1];

  192.         if ((h->flags & A_AVAIL) && (h->flags & B_AVAIL))

  193.             h->left_border_y[0] = top[0] = h->topleft_border_y;

  194.         break;

  195.     case 1:

  196.         *left = h->intern_border_y;

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

  198.             h->intern_border_y[i + 1] = *(h->cy + 7 + i * h->l_stride);

  199.         memset(&h->intern_border_y[9], h->intern_border_y[8], 9);

  200.         h->intern_border_y[0] = h->intern_border_y[1];

  201.         memcpy(&top[1], &h->top_border_y[h->mbx * 16 + 8], 8);

  202.         if (h->flags & C_AVAIL)

  203.             memcpy(&top[9], &h->top_border_y[(h->mbx + 1) * 16], 8);

  204.         else

  205.             memset(&top[9], top[8], 9);

  206.         top[17] = top[16];

  207.         top[0]  = top[1];

  208.         if (h->flags & B_AVAIL)

  209.             h->intern_border_y[0] = top[0] = h->top_border_y[h->mbx * 16 + 7];

  210.         break;

  211.     case 2:

  212.         *left = &h->left_border_y[8];

  213.         memcpy(&top[1], h->cy + 7 * h->l_stride, 16);

  214.         top[17] = top[16];

  215.         top[0]  = top[1];

  216.         if (h->flags & A_AVAIL)

  217.             top[0] = h->left_border_y[8];

  218.         break;

  219.     case 3:

  220.         *left = &h->intern_border_y[8];

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

  222.             h->intern_border_y[i + 9] = *(h->cy + 7 + (i + 8) * h->l_stride);

  223.         memset(&h->intern_border_y[17], h->intern_border_y[16], 9);

  224.         memcpy(&top[0], h->cy + 7 + 7 * h->l_stride, 9);

  225.         memset(&top[9], top[8], 9);

  226.         break;

  227.     }

  228. }

  229. 

  230. void ff_cavs_load_intra_pred_chroma(AVSContext *h)

  231. {

  232.     /* extend borders by one pixel */

  233.     h->left_border_u[9]              = h->left_border_u[8];

  234.     h->left_border_v[9]              = h->left_border_v[8];

  235.     h->top_border_u[h->mbx * 10 + 9] = h->top_border_u[h->mbx * 10 + 8];

  236.     h->top_border_v[h->mbx * 10 + 9] = h->top_border_v[h->mbx * 10 + 8];

  237.     if (h->mbx && h->mby) {

  238.         h->top_border_u[h->mbx * 10] = h->left_border_u[0] = h->topleft_border_u;

  239.         h->top_border_v[h->mbx * 10] = h->left_border_v[0] = h->topleft_border_v;

  240.     } else {

  241.         h->left_border_u[0]          = h->left_border_u[1];

  242.         h->left_border_v[0]          = h->left_border_v[1];

  243.         h->top_border_u[h->mbx * 10] = h->top_border_u[h->mbx * 10 + 1];

  244.         h->top_border_v[h->mbx * 10] = h->top_border_v[h->mbx * 10 + 1];

  245.     }

  246. }

  247. 

  248. static void intra_pred_vert(uint8_t *d, uint8_t *top, uint8_t *left, int stride)

  249. {

  250.     int y;

  251.     uint64_t a = AV_RN64(&top[1]);

  252.     for (y = 0; y < 8; y++)

  253.         *((uint64_t *)(d + y * stride)) = a;

  254. }

  255. 

  256. static void intra_pred_horiz(uint8_t *d, uint8_t *top, uint8_t *left, int stride)

  257. {

  258.     int y;

  259.     uint64_t a;

  260.     for (y = 0; y < 8; y++) {

  261.         a = left[y + 1] * 0x0101010101010101ULL;

  262.         *((uint64_t *)(d + y * stride)) = a;

  263.     }

  264. }

  265. 

  266. static void intra_pred_dc_128(uint8_t *d, uint8_t *top, uint8_t *left, int stride)

  267. {

  268.     int y;

  269.     uint64_t a = 0x8080808080808080ULL;

  270.     for (y = 0; y < 8; y++)

  271.         *((uint64_t *)(d + y * stride)) = a;

  272. }

  273. 

  274. static void intra_pred_plane(uint8_t *d, uint8_t *top, uint8_t *left, int stride)

  275. {

  276.     int x, y, ia;

  277.     int ih = 0;

  278.     int iv = 0;

  279.     const uint8_t *cm = ff_crop_tab + MAX_NEG_CROP;

  280. 

  281.     for (x = 0; x < 4; x++) {

  282.         ih += (x + 1) *  (top[5 + x] -  top[3 - x]);

  283.         iv += (x + 1) * (left[5 + x] - left[3 - x]);

  284.     }

  285.     ia = (top[8] + left[8]) << 4;

  286.     ih = (17 * ih + 16) >> 5;

  287.     iv = (17 * iv + 16) >> 5;

  288.     for (y = 0; y < 8; y++)

  289.         for (x = 0; x < 8; x++)

  290.             d[y * stride + x] = cm[(ia + (x - 3) * ih + (y - 3) * iv + 16) >> 5];

  291. }

  292. 

  293. #define LOWPASS(ARRAY, INDEX)                                           \

  294.     ((ARRAY[(INDEX) - 1] + 2 * ARRAY[(INDEX)] + ARRAY[(INDEX) + 1] + 2) >> 2)

  295. 

  296. static void intra_pred_lp(uint8_t *d, uint8_t *top, uint8_t *left, int stride)

  297. {

  298.     int x, y;

  299.     for (y = 0; y < 8; y++)

  300.         for (x = 0; x < 8; x++)

  301.             d[y * stride + x] = (LOWPASS(top, x + 1) + LOWPASS(left, y + 1)) >> 1;

  302. }

  303. 

  304. static void intra_pred_down_left(uint8_t *d, uint8_t *top, uint8_t *left, int stride)

  305. {

  306.     int x, y;

  307.     for (y = 0; y < 8; y++)

  308.         for (x = 0; x < 8; x++)

  309.             d[y * stride + x] = (LOWPASS(top, x + y + 2) + LOWPASS(left, x + y + 2)) >> 1;

  310. }

  311. 

  312. static void intra_pred_down_right(uint8_t *d, uint8_t *top, uint8_t *left, int stride)

  313. {

  314.     int x, y;

  315.     for (y = 0; y < 8; y++)

  316.         for (x = 0; x < 8; x++)

  317.             if (x == y)

  318.                 d[y * stride + x] = (left[1] + 2 * top[0] + top[1] + 2) >> 2;

  319.             else if (x > y)

  320.                 d[y * stride + x] = LOWPASS(top, x - y);

  321.             else

  322.                 d[y * stride + x] = LOWPASS(left, y - x);

  323. }

  324. 

  325. static void intra_pred_lp_left(uint8_t *d, uint8_t *top, uint8_t *left, int stride)

  326. {

  327.     int x, y;

  328.     for (y = 0; y < 8; y++)

  329.         for (x = 0; x < 8; x++)

  330.             d[y * stride + x] = LOWPASS(left, y + 1);

  331. }

  332. 

  333. static void intra_pred_lp_top(uint8_t *d, uint8_t *top, uint8_t *left, int stride)

  334. {

  335.     int x, y;

  336.     for (y = 0; y < 8; y++)

  337.         for (x = 0; x < 8; x++)

  338.             d[y * stride + x] = LOWPASS(top, x + 1);

  339. }

  340. 

  341. #undef LOWPASS

  342. 

  343. static inline void modify_pred(const int8_t *mod_table, int *mode)

  344. {

  345.     *mode = mod_table[*mode];

  346.     if (*mode < 0) {

  347.         av_log(NULL, AV_LOG_ERROR, "Illegal intra prediction mode\n");

  348.         *mode = 0;

  349.     }

  350. }

  351. 

  352. void ff_cavs_modify_mb_i(AVSContext *h, int *pred_mode_uv)

  353. {

  354.     /* save pred modes before they get modified */

  355.     h->pred_mode_Y[3]             = h->pred_mode_Y[5];

  356.     h->pred_mode_Y[6]             = h->pred_mode_Y[8];

  357.     h->top_pred_Y[h->mbx * 2 + 0] = h->pred_mode_Y[7];

  358.     h->top_pred_Y[h->mbx * 2 + 1] = h->pred_mode_Y[8];

  359. 

  360.     /* modify pred modes according to availability of neighbour samples */

  361.     if (!(h->flags & A_AVAIL)) {

  362.         modify_pred(left_modifier_l, &h->pred_mode_Y[4]);

  363.         modify_pred(left_modifier_l, &h->pred_mode_Y[7]);

  364.         modify_pred(left_modifier_c, pred_mode_uv);

  365.     }

  366.     if (!(h->flags & B_AVAIL)) {

  367.         modify_pred(top_modifier_l, &h->pred_mode_Y[4]);

  368.         modify_pred(top_modifier_l, &h->pred_mode_Y[5]);

  369.         modify_pred(top_modifier_c, pred_mode_uv);

  370.     }

  371. }

  372. 

  373. /*****************************************************************************

  374.  *

  375.  * motion compensation

  376.  *

  377.  ****************************************************************************/

  378. 

  379. static inline void mc_dir_part(AVSContext *h, AVFrame *pic, int chroma_height,

  380.                                int delta, int list, uint8_t *dest_y,

  381.                                uint8_t *dest_cb, uint8_t *dest_cr,

  382.                                int src_x_offset, int src_y_offset,

  383.                                qpel_mc_func *qpix_op,

  384.                                h264_chroma_mc_func chroma_op, cavs_vector *mv)

  385. {

  386.     const int mx         = mv->x + src_x_offset * 8;

  387.     const int my         = mv->y + src_y_offset * 8;

  388.     const int luma_xy    = (mx & 3) + ((my & 3) << 2);

  389.     uint8_t *src_y       = pic->data[0] + (mx >> 2) + (my >> 2) * h->l_stride;

  390.     uint8_t *src_cb      = pic->data[1] + (mx >> 3) + (my >> 3) * h->c_stride;

  391.     uint8_t *src_cr      = pic->data[2] + (mx >> 3) + (my >> 3) * h->c_stride;

  392.     int extra_width      = 0;

  393.     int extra_height     = extra_width;

  394.     const int full_mx    = mx >> 2;

  395.     const int full_my    = my >> 2;

  396.     const int pic_width  = 16 * h->mb_width;

  397.     const int pic_height = 16 * h->mb_height;

  398.     int emu = 0;

  399. 

  400.     if (!pic->data[0])

  401.         return;

  402.     if (mx & 7)

  403.         extra_width  -= 3;

  404.     if (my & 7)

  405.         extra_height -= 3;

  406. 

  407.     if (full_mx < 0 - extra_width ||

  408.         full_my < 0 - extra_height ||

  409.         full_mx + 16 /* FIXME */ > pic_width + extra_width ||

  410.         full_my + 16 /* FIXME */ > pic_height + extra_height) {

  411.         h->vdsp.emulated_edge_mc(h->edge_emu_buffer,

  412.                                  src_y - 2 - 2 * h->l_stride,

  413.                                  h->l_stride, h->l_stride,

  414.                                  16 + 5, 16 + 5 /* FIXME */,

  415.                                  full_mx - 2, full_my - 2,

  416.                                  pic_width, pic_height);

  417.         src_y = h->edge_emu_buffer + 2 + 2 * h->l_stride;

  418.         emu   = 1;

  419.     }

  420. 

  421.     // FIXME try variable height perhaps?

  422.     qpix_op[luma_xy](dest_y, src_y, h->l_stride);

  423. 

  424.     if (emu) {

  425.         h->vdsp.emulated_edge_mc(h->edge_emu_buffer, src_cb,

  426.                                  h->c_stride, h->c_stride,

  427.                                  9, 9 /* FIXME */,

  428.                                  mx >> 3, my >> 3,

  429.                                  pic_width >> 1, pic_height >> 1);

  430.         src_cb = h->edge_emu_buffer;

  431.     }

  432.     chroma_op(dest_cb, src_cb, h->c_stride, chroma_height, mx & 7, my & 7);

  433. 

  434.     if (emu) {

  435.         h->vdsp.emulated_edge_mc(h->edge_emu_buffer, src_cr,

  436.                                  h->c_stride, h->c_stride,

  437.                                  9, 9 /* FIXME */,

  438.                                  mx >> 3, my >> 3,

  439.                                  pic_width >> 1, pic_height >> 1);

  440.         src_cr = h->edge_emu_buffer;

  441.     }

  442.     chroma_op(dest_cr, src_cr, h->c_stride, chroma_height, mx & 7, my & 7);

  443. }

  444. 

  445. static inline void mc_part_std(AVSContext *h, int chroma_height, int delta,

  446.                                uint8_t *dest_y,

  447.                                uint8_t *dest_cb,

  448.                                uint8_t *dest_cr,

  449.                                int x_offset, int y_offset,

  450.                                qpel_mc_func *qpix_put,

  451.                                h264_chroma_mc_func chroma_put,

  452.                                qpel_mc_func *qpix_avg,

  453.                                h264_chroma_mc_func chroma_avg,

  454.                                cavs_vector *mv)

  455. {

  456.     qpel_mc_func *qpix_op =  qpix_put;

  457.     h264_chroma_mc_func chroma_op = chroma_put;

  458. 

  459.     dest_y   += x_offset * 2 + y_offset * h->l_stride * 2;

  460.     dest_cb  += x_offset     + y_offset * h->c_stride;

  461.     dest_cr  += x_offset     + y_offset * h->c_stride;

  462.     x_offset += 8 * h->mbx;

  463.     y_offset += 8 * h->mby;

  464. 

  465.     if (mv->ref >= 0) {

  466.         AVFrame *ref = h->DPB[mv->ref].f;

  467.         mc_dir_part(h, ref, chroma_height, delta, 0,

  468.                     dest_y, dest_cb, dest_cr, x_offset, y_offset,

  469.                     qpix_op, chroma_op, mv);

  470. 

  471.         qpix_op   = qpix_avg;

  472.         chroma_op = chroma_avg;

  473.     }

  474. 

  475.     if ((mv + MV_BWD_OFFS)->ref >= 0) {

  476.         AVFrame *ref = h->DPB[0].f;

  477.         mc_dir_part(h, ref, chroma_height, delta, 1,

  478.                     dest_y, dest_cb, dest_cr, x_offset, y_offset,

  479.                     qpix_op, chroma_op, mv + MV_BWD_OFFS);

  480.     }

  481. }

  482. 

  483. void ff_cavs_inter(AVSContext *h, enum cavs_mb mb_type)

  484. {

  485.     if (ff_cavs_partition_flags[mb_type] == 0) { // 16x16

  486.         mc_part_std(h, 8, 0, h->cy, h->cu, h->cv, 0, 0,

  487.                     h->cdsp.put_cavs_qpel_pixels_tab[0],

  488.                     h->h264chroma.put_h264_chroma_pixels_tab[0],

  489.                     h->cdsp.avg_cavs_qpel_pixels_tab[0],

  490.                     h->h264chroma.avg_h264_chroma_pixels_tab[0],

  491.                     &h->mv[MV_FWD_X0]);

  492.     } else {

  493.         mc_part_std(h, 4, 0, h->cy, h->cu, h->cv, 0, 0,

  494.                     h->cdsp.put_cavs_qpel_pixels_tab[1],

  495.                     h->h264chroma.put_h264_chroma_pixels_tab[1],

  496.                     h->cdsp.avg_cavs_qpel_pixels_tab[1],

  497.                     h->h264chroma.avg_h264_chroma_pixels_tab[1],

  498.                     &h->mv[MV_FWD_X0]);

  499.         mc_part_std(h, 4, 0, h->cy, h->cu, h->cv, 4, 0,

  500.                     h->cdsp.put_cavs_qpel_pixels_tab[1],

  501.                     h->h264chroma.put_h264_chroma_pixels_tab[1],

  502.                     h->cdsp.avg_cavs_qpel_pixels_tab[1],

  503.                     h->h264chroma.avg_h264_chroma_pixels_tab[1],

  504.                     &h->mv[MV_FWD_X1]);

  505.         mc_part_std(h, 4, 0, h->cy, h->cu, h->cv, 0, 4,

  506.                     h->cdsp.put_cavs_qpel_pixels_tab[1],

  507.                     h->h264chroma.put_h264_chroma_pixels_tab[1],

  508.                     h->cdsp.avg_cavs_qpel_pixels_tab[1],

  509.                     h->h264chroma.avg_h264_chroma_pixels_tab[1],

  510.                     &h->mv[MV_FWD_X2]);

  511.         mc_part_std(h, 4, 0, h->cy, h->cu, h->cv, 4, 4,

  512.                     h->cdsp.put_cavs_qpel_pixels_tab[1],

  513.                     h->h264chroma.put_h264_chroma_pixels_tab[1],

  514.                     h->cdsp.avg_cavs_qpel_pixels_tab[1],

  515.                     h->h264chroma.avg_h264_chroma_pixels_tab[1],

  516.                     &h->mv[MV_FWD_X3]);

  517.     }

  518. }

  519. 

  520. /*****************************************************************************

  521.  *

  522.  * motion vector prediction

  523.  *

  524.  ****************************************************************************/

  525. 

  526. static inline void scale_mv(AVSContext *h, int *d_x, int *d_y,

  527.                             cavs_vector *src, int distp)

  528. {

  529.     int den = h->scale_den[src->ref];

  530. 

  531.     *d_x = (src->x * distp * den + 256 + (src->x >> 31)) >> 9;

  532.     *d_y = (src->y * distp * den + 256 + (src->y >> 31)) >> 9;

  533. }

  534. 

  535. static inline void mv_pred_median(AVSContext *h,

  536.                                   cavs_vector *mvP,

  537.                                   cavs_vector *mvA,

  538.                                   cavs_vector *mvB,

  539.                                   cavs_vector *mvC)

  540. {

  541.     int ax, ay, bx, by, cx, cy;

  542.     int len_ab, len_bc, len_ca, len_mid;

  543. 

  544.     /* scale candidates according to their temporal span */

  545.     scale_mv(h, &ax, &ay, mvA, mvP->dist);

  546.     scale_mv(h, &bx, &by, mvB, mvP->dist);

  547.     scale_mv(h, &cx, &cy, mvC, mvP->dist);

  548.     /* find the geometrical median of the three candidates */

  549.     len_ab  = abs(ax - bx) + abs(ay - by);

  550.     len_bc  = abs(bx - cx) + abs(by - cy);

  551.     len_ca  = abs(cx - ax) + abs(cy - ay);

  552.     len_mid = mid_pred(len_ab, len_bc, len_ca);

  553.     if (len_mid == len_ab) {

  554.         mvP->x = cx;

  555.         mvP->y = cy;

  556.     } else if (len_mid == len_bc) {

  557.         mvP->x = ax;

  558.         mvP->y = ay;

  559.     } else {

  560.         mvP->x = bx;

  561.         mvP->y = by;

  562.     }

  563. }

  564. 

  565. void ff_cavs_mv(AVSContext *h, enum cavs_mv_loc nP, enum cavs_mv_loc nC,

  566.                 enum cavs_mv_pred mode, enum cavs_block size, int ref)

  567. {

  568.     cavs_vector *mvP = &h->mv[nP];

  569.     cavs_vector *mvA = &h->mv[nP-1];

  570.     cavs_vector *mvB = &h->mv[nP-4];

  571.     cavs_vector *mvC = &h->mv[nC];

  572.     const cavs_vector *mvP2 = NULL;

  573. 

  574.     mvP->ref  = ref;

  575.     mvP->dist = h->dist[mvP->ref];

  576.     if (mvC->ref == NOT_AVAIL)

  577.         mvC = &h->mv[nP - 5];  // set to top-left (mvD)

  578.     if (mode == MV_PRED_PSKIP &&

  579.         (mvA->ref == NOT_AVAIL ||

  580.          mvB->ref == NOT_AVAIL ||

  581.          (mvA->x | mvA->y | mvA->ref) == 0 ||

  582.          (mvB->x | mvB->y | mvB->ref) == 0)) {

  583.         mvP2 = &un_mv;

  584.     /* if there is only one suitable candidate, take it */

  585.     } else if (mvA->ref >= 0 && mvB->ref < 0  && mvC->ref < 0) {

  586.         mvP2 = mvA;

  587.     } else if (mvA->ref < 0  && mvB->ref >= 0 && mvC->ref < 0) {

  588.         mvP2 = mvB;

  589.     } else if (mvA->ref < 0  && mvB->ref < 0  && mvC->ref >= 0) {

  590.         mvP2 = mvC;

  591.     } else if (mode == MV_PRED_LEFT     && mvA->ref == ref) {

  592.         mvP2 = mvA;

  593.     } else if (mode == MV_PRED_TOP      && mvB->ref == ref) {

  594.         mvP2 = mvB;

  595.     } else if (mode == MV_PRED_TOPRIGHT && mvC->ref == ref) {

  596.         mvP2 = mvC;

  597.     }

  598.     if (mvP2) {

  599.         mvP->x = mvP2->x;

  600.         mvP->y = mvP2->y;

  601.     } else

  602.         mv_pred_median(h, mvP, mvA, mvB, mvC);

  603. 

  604.     if (mode < MV_PRED_PSKIP) {

  605.         mvP->x += get_se_golomb(&h->gb);

  606.         mvP->y += get_se_golomb(&h->gb);

  607.     }

  608.     set_mvs(mvP, size);

  609. }

  610. 

  611. /*****************************************************************************

  612.  *

  613.  * macroblock level

  614.  *

  615.  ****************************************************************************/

  616. 

  617. /**

  618.  * initialise predictors for motion vectors and intra prediction

  619.  */

  620. void ff_cavs_init_mb(AVSContext *h)

  621. {

  622.     int i;

  623. 

  624.     /* copy predictors from top line (MB B and C) into cache */

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

  626.         h->mv[MV_FWD_B2 + i] = h->top_mv[0][h->mbx * 2 + i];

  627.         h->mv[MV_BWD_B2 + i] = h->top_mv[1][h->mbx * 2 + i];

  628.     }

  629.     h->pred_mode_Y[1] = h->top_pred_Y[h->mbx * 2 + 0];

  630.     h->pred_mode_Y[2] = h->top_pred_Y[h->mbx * 2 + 1];

  631.     /* clear top predictors if MB B is not available */

  632.     if (!(h->flags & B_AVAIL)) {

  633.         h->mv[MV_FWD_B2]  = un_mv;

  634.         h->mv[MV_FWD_B3]  = un_mv;

  635.         h->mv[MV_BWD_B2]  = un_mv;

  636.         h->mv[MV_BWD_B3]  = un_mv;

  637.         h->pred_mode_Y[1] = h->pred_mode_Y[2] = NOT_AVAIL;

  638.         h->flags         &= ~(C_AVAIL | D_AVAIL);

  639.     } else if (h->mbx) {

  640.         h->flags |= D_AVAIL;

  641.     }

  642.     if (h->mbx == h->mb_width - 1) // MB C not available

  643.         h->flags &= ~C_AVAIL;

  644.     /* clear top-right predictors if MB C is not available */

  645.     if (!(h->flags & C_AVAIL)) {

  646.         h->mv[MV_FWD_C2] = un_mv;

  647.         h->mv[MV_BWD_C2] = un_mv;

  648.     }

  649.     /* clear top-left predictors if MB D is not available */

  650.     if (!(h->flags & D_AVAIL)) {

  651.         h->mv[MV_FWD_D3] = un_mv;

  652.         h->mv[MV_BWD_D3] = un_mv;

  653.     }

  654. }

  655. 

  656. /**

  657.  * save predictors for later macroblocks and increase

  658.  * macroblock address

  659.  * @return 0 if end of frame is reached, 1 otherwise

  660.  */

  661. int ff_cavs_next_mb(AVSContext *h)

  662. {

  663.     int i;

  664. 

  665.     h->flags |= A_AVAIL;

  666.     h->cy    += 16;

  667.     h->cu    += 8;

  668.     h->cv    += 8;

  669.     /* copy mvs as predictors to the left */

  670.     for (i = 0; i <= 20; i += 4)

  671.         h->mv[i] = h->mv[i + 2];

  672.     /* copy bottom mvs from cache to top line */

  673.     h->top_mv[0][h->mbx * 2 + 0] = h->mv[MV_FWD_X2];

  674.     h->top_mv[0][h->mbx * 2 + 1] = h->mv[MV_FWD_X3];

  675.     h->top_mv[1][h->mbx * 2 + 0] = h->mv[MV_BWD_X2];

  676.     h->top_mv[1][h->mbx * 2 + 1] = h->mv[MV_BWD_X3];

  677.     /* next MB address */

  678.     h->mbidx++;

  679.     h->mbx++;

  680.     if (h->mbx == h->mb_width) { // New mb line

  681.         h->flags = B_AVAIL | C_AVAIL;

  682.         /* clear left pred_modes */

  683.         h->pred_mode_Y[3] = h->pred_mode_Y[6] = NOT_AVAIL;

  684.         /* clear left mv predictors */

  685.         for (i = 0; i <= 20; i += 4)

  686.             h->mv[i] = un_mv;

  687.         h->mbx = 0;

  688.         h->mby++;

  689.         /* re-calculate sample pointers */

  690.         h->cy = h->cur.f->data[0] + h->mby * 16 * h->l_stride;

  691.         h->cu = h->cur.f->data[1] + h->mby * 8 * h->c_stride;

  692.         h->cv = h->cur.f->data[2] + h->mby * 8 * h->c_stride;

  693.         if (h->mby == h->mb_height) { // Frame end

  694.             return 0;

  695.         }

  696.     }

  697.     return 1;

  698. }

  699. 

  700. /*****************************************************************************

  701.  *

  702.  * frame level

  703.  *

  704.  ****************************************************************************/

  705. 

  706. void ff_cavs_init_pic(AVSContext *h)

  707. {

  708.     int i;

  709. 

  710.     /* clear some predictors */

  711.     for (i = 0; i <= 20; i += 4)

  712.         h->mv[i] = un_mv;

  713.     h->mv[MV_BWD_X0] = ff_cavs_dir_mv;

  714.     set_mvs(&h->mv[MV_BWD_X0], BLK_16X16);

  715.     h->mv[MV_FWD_X0] = ff_cavs_dir_mv;

  716.     set_mvs(&h->mv[MV_FWD_X0], BLK_16X16);

  717.     h->pred_mode_Y[3] = h->pred_mode_Y[6] = NOT_AVAIL;

  718.     h->cy             = h->cur.f->data[0];

  719.     h->cu             = h->cur.f->data[1];

  720.     h->cv             = h->cur.f->data[2];

  721.     h->l_stride       = h->cur.f->linesize[0];

  722.     h->c_stride       = h->cur.f->linesize[1];

  723.     h->luma_scan[2]   = 8 * h->l_stride;

  724.     h->luma_scan[3]   = 8 * h->l_stride + 8;

  725.     h->mbx            = h->mby = h->mbidx = 0;

  726.     h->flags          = 0;

  727. }

  728. 

  729. /*****************************************************************************

  730.  *

  731.  * headers and interface

  732.  *

  733.  ****************************************************************************/

  734. 

  735. /**

  736.  * some predictions require data from the top-neighbouring macroblock.

  737.  * this data has to be stored for one complete row of macroblocks

  738.  * and this storage space is allocated here

  739.  */

  740. void ff_cavs_init_top_lines(AVSContext *h)

  741. {

  742.     /* alloc top line of predictors */

  743.     h->top_qp       = av_mallocz(h->mb_width);

  744.     h->top_mv[0]    = av_mallocz((h->mb_width * 2 + 1) * sizeof(cavs_vector));

  745.     h->top_mv[1]    = av_mallocz((h->mb_width * 2 + 1) * sizeof(cavs_vector));

  746.     h->top_pred_Y   = av_mallocz(h->mb_width * 2 * sizeof(*h->top_pred_Y));

  747.     h->top_border_y = av_mallocz((h->mb_width + 1) * 16);

  748.     h->top_border_u = av_mallocz(h->mb_width * 10);

  749.     h->top_border_v = av_mallocz(h->mb_width * 10);

  750. 

  751.     /* alloc space for co-located MVs and types */

  752.     h->col_mv        = av_mallocz(h->mb_width * h->mb_height * 4 *

  753.                                   sizeof(cavs_vector));

  754.     h->col_type_base = av_mallocz(h->mb_width * h->mb_height);

  755.     h->block         = av_mallocz(64 * sizeof(int16_t));

  756. }

  757. 

  758. av_cold int ff_cavs_init(AVCodecContext *avctx)

  759. {

  760.     AVSContext *h = avctx->priv_data;

  761. 

  762.     ff_dsputil_init(&h->dsp, avctx);

  763.     ff_h264chroma_init(&h->h264chroma, 8);

  764.     ff_videodsp_init(&h->vdsp, 8);

  765.     ff_cavsdsp_init(&h->cdsp, avctx);

  766.     ff_init_scantable_permutation(h->dsp.idct_permutation,

  767.                                   h->cdsp.idct_perm);

  768.     ff_init_scantable(h->dsp.idct_permutation, &h->scantable, ff_zigzag_direct);

  769. 

  770.     h->avctx       = avctx;

  771.     avctx->pix_fmt = AV_PIX_FMT_YUV420P;

  772. 

  773.     h->cur.f    = av_frame_alloc();

  774.     h->DPB[0].f = av_frame_alloc();

  775.     h->DPB[1].f = av_frame_alloc();

  776.     if (!h->cur.f || !h->DPB[0].f || !h->DPB[1].f) {

  777.         ff_cavs_end(avctx);

  778.         return AVERROR(ENOMEM);

  779.     }

  780. 

  781.     h->luma_scan[0]                     = 0;

  782.     h->luma_scan[1]                     = 8;

  783.     h->intra_pred_l[INTRA_L_VERT]       = intra_pred_vert;

  784.     h->intra_pred_l[INTRA_L_HORIZ]      = intra_pred_horiz;

  785.     h->intra_pred_l[INTRA_L_LP]         = intra_pred_lp;

  786.     h->intra_pred_l[INTRA_L_DOWN_LEFT]  = intra_pred_down_left;

  787.     h->intra_pred_l[INTRA_L_DOWN_RIGHT] = intra_pred_down_right;

  788.     h->intra_pred_l[INTRA_L_LP_LEFT]    = intra_pred_lp_left;

  789.     h->intra_pred_l[INTRA_L_LP_TOP]     = intra_pred_lp_top;

  790.     h->intra_pred_l[INTRA_L_DC_128]     = intra_pred_dc_128;

  791.     h->intra_pred_c[INTRA_C_LP]         = intra_pred_lp;

  792.     h->intra_pred_c[INTRA_C_HORIZ]      = intra_pred_horiz;

  793.     h->intra_pred_c[INTRA_C_VERT]       = intra_pred_vert;

  794.     h->intra_pred_c[INTRA_C_PLANE]      = intra_pred_plane;

  795.     h->intra_pred_c[INTRA_C_LP_LEFT]    = intra_pred_lp_left;

  796.     h->intra_pred_c[INTRA_C_LP_TOP]     = intra_pred_lp_top;

  797.     h->intra_pred_c[INTRA_C_DC_128]     = intra_pred_dc_128;

  798.     h->mv[7]                            = un_mv;

  799.     h->mv[19]                           = un_mv;

  800.     return 0;

  801. }

  802. 

  803. av_cold int ff_cavs_end(AVCodecContext *avctx)

  804. {

  805.     AVSContext *h = avctx->priv_data;

  806. 

  807.     av_frame_free(&h->cur.f);

  808.     av_frame_free(&h->DPB[0].f);

  809.     av_frame_free(&h->DPB[1].f);

  810. 

  811.     av_free(h->top_qp);

  812.     av_free(h->top_mv[0]);

  813.     av_free(h->top_mv[1]);

  814.     av_free(h->top_pred_Y);

  815.     av_free(h->top_border_y);

  816.     av_free(h->top_border_u);

  817.     av_free(h->top_border_v);

  818.     av_free(h->col_mv);

  819.     av_free(h->col_type_base);

  820.     av_free(h->block);

  821.     av_freep(&h->edge_emu_buffer);

  822.     return 0;

  823. }