Coverage Report

Created: 2026-06-30 06:53

next uncovered line (L), next uncovered region (R), next uncovered branch (B)
/src/aom/av1/common/reconintra.c
Line
Count
Source
1
/*
2
 * Copyright (c) 2016, Alliance for Open Media. All rights reserved.
3
 *
4
 * This source code is subject to the terms of the BSD 2 Clause License and
5
 * the Alliance for Open Media Patent License 1.0. If the BSD 2 Clause License
6
 * was not distributed with this source code in the LICENSE file, you can
7
 * obtain it at www.aomedia.org/license/software. If the Alliance for Open
8
 * Media Patent License 1.0 was not distributed with this source code in the
9
 * PATENTS file, you can obtain it at www.aomedia.org/license/patent.
10
 */
11
12
#include <assert.h>
13
#include <math.h>
14
15
#include "config/aom_config.h"
16
#include "config/aom_dsp_rtcd.h"
17
#include "config/av1_rtcd.h"
18
19
#include "aom_dsp/aom_dsp_common.h"
20
#include "aom_mem/aom_mem.h"
21
#include "aom_ports/aom_once.h"
22
#include "aom_ports/mem.h"
23
#include "av1/common/av1_common_int.h"
24
#include "av1/common/cfl.h"
25
#include "av1/common/reconintra.h"
26
27
enum {
28
  NEED_LEFT = 1 << 1,
29
  NEED_ABOVE = 1 << 2,
30
  NEED_ABOVERIGHT = 1 << 3,
31
  NEED_ABOVELEFT = 1 << 4,
32
  NEED_BOTTOMLEFT = 1 << 5,
33
};
34
35
#define INTRA_EDGE_FILT 3
36
0
#define INTRA_EDGE_TAPS 5
37
#define MAX_UPSAMPLE_SZ 16
38
177M
#define NUM_INTRA_NEIGHBOUR_PIXELS (MAX_TX_SIZE * 2 + 32)
39
40
static const uint8_t extend_modes[INTRA_MODES] = {
41
  NEED_ABOVE | NEED_LEFT,                   // DC
42
  NEED_ABOVE,                               // V
43
  NEED_LEFT,                                // H
44
  NEED_ABOVE | NEED_ABOVERIGHT,             // D45
45
  NEED_LEFT | NEED_ABOVE | NEED_ABOVELEFT,  // D135
46
  NEED_LEFT | NEED_ABOVE | NEED_ABOVELEFT,  // D113
47
  NEED_LEFT | NEED_ABOVE | NEED_ABOVELEFT,  // D157
48
  NEED_LEFT | NEED_BOTTOMLEFT,              // D203
49
  NEED_ABOVE | NEED_ABOVERIGHT,             // D67
50
  NEED_LEFT | NEED_ABOVE,                   // SMOOTH
51
  NEED_LEFT | NEED_ABOVE,                   // SMOOTH_V
52
  NEED_LEFT | NEED_ABOVE,                   // SMOOTH_H
53
  NEED_LEFT | NEED_ABOVE | NEED_ABOVELEFT,  // PAETH
54
};
55
56
// Tables to store if the top-right reference pixels are available. The flags
57
// are represented with bits, packed into 8-bit integers. E.g., for the 32x32
58
// blocks in a 128x128 superblock, the index of the "o" block is 10 (in raster
59
// order), so its flag is stored at the 3rd bit of the 2nd entry in the table,
60
// i.e. (table[10 / 8] >> (10 % 8)) & 1.
61
//       . . . .
62
//       . . . .
63
//       . . o .
64
//       . . . .
65
static uint8_t has_tr_4x4[128] = {
66
  255, 255, 255, 255, 85, 85, 85, 85, 119, 119, 119, 119, 85, 85, 85, 85,
67
  127, 127, 127, 127, 85, 85, 85, 85, 119, 119, 119, 119, 85, 85, 85, 85,
68
  255, 127, 255, 127, 85, 85, 85, 85, 119, 119, 119, 119, 85, 85, 85, 85,
69
  127, 127, 127, 127, 85, 85, 85, 85, 119, 119, 119, 119, 85, 85, 85, 85,
70
  255, 255, 255, 127, 85, 85, 85, 85, 119, 119, 119, 119, 85, 85, 85, 85,
71
  127, 127, 127, 127, 85, 85, 85, 85, 119, 119, 119, 119, 85, 85, 85, 85,
72
  255, 127, 255, 127, 85, 85, 85, 85, 119, 119, 119, 119, 85, 85, 85, 85,
73
  127, 127, 127, 127, 85, 85, 85, 85, 119, 119, 119, 119, 85, 85, 85, 85,
74
};
75
static uint8_t has_tr_4x8[64] = {
76
  255, 255, 255, 255, 119, 119, 119, 119, 127, 127, 127, 127, 119,
77
  119, 119, 119, 255, 127, 255, 127, 119, 119, 119, 119, 127, 127,
78
  127, 127, 119, 119, 119, 119, 255, 255, 255, 127, 119, 119, 119,
79
  119, 127, 127, 127, 127, 119, 119, 119, 119, 255, 127, 255, 127,
80
  119, 119, 119, 119, 127, 127, 127, 127, 119, 119, 119, 119,
81
};
82
static uint8_t has_tr_8x4[64] = {
83
  255, 255, 0, 0, 85, 85, 0, 0, 119, 119, 0, 0, 85, 85, 0, 0,
84
  127, 127, 0, 0, 85, 85, 0, 0, 119, 119, 0, 0, 85, 85, 0, 0,
85
  255, 127, 0, 0, 85, 85, 0, 0, 119, 119, 0, 0, 85, 85, 0, 0,
86
  127, 127, 0, 0, 85, 85, 0, 0, 119, 119, 0, 0, 85, 85, 0, 0,
87
};
88
static uint8_t has_tr_8x8[32] = {
89
  255, 255, 85, 85, 119, 119, 85, 85, 127, 127, 85, 85, 119, 119, 85, 85,
90
  255, 127, 85, 85, 119, 119, 85, 85, 127, 127, 85, 85, 119, 119, 85, 85,
91
};
92
static uint8_t has_tr_8x16[16] = {
93
  255, 255, 119, 119, 127, 127, 119, 119,
94
  255, 127, 119, 119, 127, 127, 119, 119,
95
};
96
static uint8_t has_tr_16x8[16] = {
97
  255, 0, 85, 0, 119, 0, 85, 0, 127, 0, 85, 0, 119, 0, 85, 0,
98
};
99
static uint8_t has_tr_16x16[8] = {
100
  255, 85, 119, 85, 127, 85, 119, 85,
101
};
102
static uint8_t has_tr_16x32[4] = { 255, 119, 127, 119 };
103
static uint8_t has_tr_32x16[4] = { 15, 5, 7, 5 };
104
static uint8_t has_tr_32x32[2] = { 95, 87 };
105
static uint8_t has_tr_32x64[1] = { 127 };
106
static uint8_t has_tr_64x32[1] = { 19 };
107
static uint8_t has_tr_64x64[1] = { 7 };
108
static uint8_t has_tr_64x128[1] = { 3 };
109
static uint8_t has_tr_128x64[1] = { 1 };
110
static uint8_t has_tr_128x128[1] = { 1 };
111
static uint8_t has_tr_4x16[32] = {
112
  255, 255, 255, 255, 127, 127, 127, 127, 255, 127, 255,
113
  127, 127, 127, 127, 127, 255, 255, 255, 127, 127, 127,
114
  127, 127, 255, 127, 255, 127, 127, 127, 127, 127,
115
};
116
static uint8_t has_tr_16x4[32] = {
117
  255, 0, 0, 0, 85, 0, 0, 0, 119, 0, 0, 0, 85, 0, 0, 0,
118
  127, 0, 0, 0, 85, 0, 0, 0, 119, 0, 0, 0, 85, 0, 0, 0,
119
};
120
static uint8_t has_tr_8x32[8] = {
121
  255, 255, 127, 127, 255, 127, 127, 127,
122
};
123
static uint8_t has_tr_32x8[8] = {
124
  15, 0, 5, 0, 7, 0, 5, 0,
125
};
126
static uint8_t has_tr_16x64[2] = { 255, 127 };
127
static uint8_t has_tr_64x16[2] = { 3, 1 };
128
129
static const uint8_t *const has_tr_tables[BLOCK_SIZES_ALL] = {
130
  // 4X4
131
  has_tr_4x4,
132
  // 4X8,       8X4,            8X8
133
  has_tr_4x8, has_tr_8x4, has_tr_8x8,
134
  // 8X16,      16X8,           16X16
135
  has_tr_8x16, has_tr_16x8, has_tr_16x16,
136
  // 16X32,     32X16,          32X32
137
  has_tr_16x32, has_tr_32x16, has_tr_32x32,
138
  // 32X64,     64X32,          64X64
139
  has_tr_32x64, has_tr_64x32, has_tr_64x64,
140
  // 64x128,    128x64,         128x128
141
  has_tr_64x128, has_tr_128x64, has_tr_128x128,
142
  // 4x16,      16x4,            8x32
143
  has_tr_4x16, has_tr_16x4, has_tr_8x32,
144
  // 32x8,      16x64,           64x16
145
  has_tr_32x8, has_tr_16x64, has_tr_64x16
146
};
147
148
static uint8_t has_tr_vert_8x8[32] = {
149
  255, 255, 0, 0, 119, 119, 0, 0, 127, 127, 0, 0, 119, 119, 0, 0,
150
  255, 127, 0, 0, 119, 119, 0, 0, 127, 127, 0, 0, 119, 119, 0, 0,
151
};
152
static uint8_t has_tr_vert_16x16[8] = {
153
  255, 0, 119, 0, 127, 0, 119, 0,
154
};
155
static uint8_t has_tr_vert_32x32[2] = { 15, 7 };
156
static uint8_t has_tr_vert_64x64[1] = { 3 };
157
158
// The _vert_* tables are like the ordinary tables above, but describe the
159
// order we visit square blocks when doing a PARTITION_VERT_A or
160
// PARTITION_VERT_B. This is the same order as normal except for on the last
161
// split where we go vertically (TL, BL, TR, BR). We treat the rectangular block
162
// as a pair of squares, which means that these tables work correctly for both
163
// mixed vertical partition types.
164
//
165
// There are tables for each of the square sizes. Vertical rectangles (like
166
// BLOCK_16X32) use their respective "non-vert" table
167
static const uint8_t *const has_tr_vert_tables[BLOCK_SIZES] = {
168
  // 4X4
169
  NULL,
170
  // 4X8,      8X4,         8X8
171
  has_tr_4x8, NULL, has_tr_vert_8x8,
172
  // 8X16,     16X8,        16X16
173
  has_tr_8x16, NULL, has_tr_vert_16x16,
174
  // 16X32,    32X16,       32X32
175
  has_tr_16x32, NULL, has_tr_vert_32x32,
176
  // 32X64,    64X32,       64X64
177
  has_tr_32x64, NULL, has_tr_vert_64x64,
178
  // 64x128,   128x64,      128x128
179
  has_tr_64x128, NULL, has_tr_128x128
180
};
181
182
static const uint8_t *get_has_tr_table(PARTITION_TYPE partition,
183
576k
                                       BLOCK_SIZE bsize) {
184
576k
  const uint8_t *ret = NULL;
185
  // If this is a mixed vertical partition, look up bsize in orders_vert.
186
576k
  if (partition == PARTITION_VERT_A || partition == PARTITION_VERT_B) {
187
55.3k
    assert(bsize < BLOCK_SIZES);
188
55.3k
    ret = has_tr_vert_tables[bsize];
189
521k
  } else {
190
521k
    ret = has_tr_tables[bsize];
191
521k
  }
192
576k
  assert(ret);
193
576k
  return ret;
194
576k
}
195
196
static int has_top_right(BLOCK_SIZE sb_size, BLOCK_SIZE bsize, int mi_row,
197
                         int mi_col, int top_available, int right_available,
198
                         PARTITION_TYPE partition, TX_SIZE txsz, int row_off,
199
1.04M
                         int col_off, int ss_x, int ss_y) {
200
1.04M
  if (!top_available || !right_available) return 0;
201
202
987k
  const int bw_unit = mi_size_wide[bsize];
203
987k
  const int plane_bw_unit = AOMMAX(bw_unit >> ss_x, 1);
204
987k
  const int top_right_count_unit = tx_size_wide_unit[txsz];
205
206
987k
  if (row_off > 0) {  // Just need to check if enough pixels on the right.
207
179k
    if (block_size_wide[bsize] > block_size_wide[BLOCK_64X64]) {
208
      // Special case: For 128x128 blocks, the transform unit whose
209
      // top-right corner is at the center of the block does in fact have
210
      // pixels available at its top-right corner.
211
121k
      if (row_off == mi_size_high[BLOCK_64X64] >> ss_y &&
212
28.5k
          col_off + top_right_count_unit == mi_size_wide[BLOCK_64X64] >> ss_x) {
213
12.0k
        return 1;
214
12.0k
      }
215
109k
      const int plane_bw_unit_64 = mi_size_wide[BLOCK_64X64] >> ss_x;
216
109k
      const int col_off_64 = col_off % plane_bw_unit_64;
217
109k
      return col_off_64 + top_right_count_unit < plane_bw_unit_64;
218
121k
    }
219
58.2k
    return col_off + top_right_count_unit < plane_bw_unit;
220
807k
  } else {
221
    // All top-right pixels are in the block above, which is already available.
222
807k
    if (col_off + top_right_count_unit < plane_bw_unit) return 1;
223
224
775k
    const int bw_in_mi_log2 = mi_size_wide_log2[bsize];
225
775k
    const int bh_in_mi_log2 = mi_size_high_log2[bsize];
226
775k
    const int sb_mi_size = mi_size_high[sb_size];
227
775k
    const int blk_row_in_sb = (mi_row & (sb_mi_size - 1)) >> bh_in_mi_log2;
228
775k
    const int blk_col_in_sb = (mi_col & (sb_mi_size - 1)) >> bw_in_mi_log2;
229
230
    // Top row of superblock: so top-right pixels are in the top and/or
231
    // top-right superblocks, both of which are already available.
232
775k
    if (blk_row_in_sb == 0) return 1;
233
234
    // Rightmost column of superblock (and not the top row): so top-right pixels
235
    // fall in the right superblock, which is not available yet.
236
675k
    if (((blk_col_in_sb + 1) << bw_in_mi_log2) >= sb_mi_size) {
237
98.8k
      return 0;
238
98.8k
    }
239
240
    // General case (neither top row nor rightmost column): check if the
241
    // top-right block is coded before the current block.
242
576k
    const int this_blk_index =
243
576k
        ((blk_row_in_sb + 0) << (MAX_MIB_SIZE_LOG2 - bw_in_mi_log2)) +
244
576k
        blk_col_in_sb + 0;
245
576k
    const int idx1 = this_blk_index / 8;
246
576k
    const int idx2 = this_blk_index % 8;
247
576k
    const uint8_t *has_tr_table = get_has_tr_table(partition, bsize);
248
576k
    return (has_tr_table[idx1] >> idx2) & 1;
249
675k
  }
250
987k
}
251
252
// Similar to the has_tr_* tables, but store if the bottom-left reference
253
// pixels are available.
254
static uint8_t has_bl_4x4[128] = {
255
  84, 85, 85, 85, 16, 17, 17, 17, 84, 85, 85, 85, 0,  1,  1,  1,  84, 85, 85,
256
  85, 16, 17, 17, 17, 84, 85, 85, 85, 0,  0,  1,  0,  84, 85, 85, 85, 16, 17,
257
  17, 17, 84, 85, 85, 85, 0,  1,  1,  1,  84, 85, 85, 85, 16, 17, 17, 17, 84,
258
  85, 85, 85, 0,  0,  0,  0,  84, 85, 85, 85, 16, 17, 17, 17, 84, 85, 85, 85,
259
  0,  1,  1,  1,  84, 85, 85, 85, 16, 17, 17, 17, 84, 85, 85, 85, 0,  0,  1,
260
  0,  84, 85, 85, 85, 16, 17, 17, 17, 84, 85, 85, 85, 0,  1,  1,  1,  84, 85,
261
  85, 85, 16, 17, 17, 17, 84, 85, 85, 85, 0,  0,  0,  0,
262
};
263
static uint8_t has_bl_4x8[64] = {
264
  16, 17, 17, 17, 0, 1, 1, 1, 16, 17, 17, 17, 0, 0, 1, 0,
265
  16, 17, 17, 17, 0, 1, 1, 1, 16, 17, 17, 17, 0, 0, 0, 0,
266
  16, 17, 17, 17, 0, 1, 1, 1, 16, 17, 17, 17, 0, 0, 1, 0,
267
  16, 17, 17, 17, 0, 1, 1, 1, 16, 17, 17, 17, 0, 0, 0, 0,
268
};
269
static uint8_t has_bl_8x4[64] = {
270
  254, 255, 84, 85, 254, 255, 16, 17, 254, 255, 84, 85, 254, 255, 0, 1,
271
  254, 255, 84, 85, 254, 255, 16, 17, 254, 255, 84, 85, 254, 255, 0, 0,
272
  254, 255, 84, 85, 254, 255, 16, 17, 254, 255, 84, 85, 254, 255, 0, 1,
273
  254, 255, 84, 85, 254, 255, 16, 17, 254, 255, 84, 85, 254, 255, 0, 0,
274
};
275
static uint8_t has_bl_8x8[32] = {
276
  84, 85, 16, 17, 84, 85, 0, 1, 84, 85, 16, 17, 84, 85, 0, 0,
277
  84, 85, 16, 17, 84, 85, 0, 1, 84, 85, 16, 17, 84, 85, 0, 0,
278
};
279
static uint8_t has_bl_8x16[16] = {
280
  16, 17, 0, 1, 16, 17, 0, 0, 16, 17, 0, 1, 16, 17, 0, 0,
281
};
282
static uint8_t has_bl_16x8[16] = {
283
  254, 84, 254, 16, 254, 84, 254, 0, 254, 84, 254, 16, 254, 84, 254, 0,
284
};
285
static uint8_t has_bl_16x16[8] = {
286
  84, 16, 84, 0, 84, 16, 84, 0,
287
};
288
static uint8_t has_bl_16x32[4] = { 16, 0, 16, 0 };
289
static uint8_t has_bl_32x16[4] = { 78, 14, 78, 14 };
290
static uint8_t has_bl_32x32[2] = { 4, 4 };
291
static uint8_t has_bl_32x64[1] = { 0 };
292
static uint8_t has_bl_64x32[1] = { 34 };
293
static uint8_t has_bl_64x64[1] = { 0 };
294
static uint8_t has_bl_64x128[1] = { 0 };
295
static uint8_t has_bl_128x64[1] = { 0 };
296
static uint8_t has_bl_128x128[1] = { 0 };
297
static uint8_t has_bl_4x16[32] = {
298
  0, 1, 1, 1, 0, 0, 1, 0, 0, 1, 1, 1, 0, 0, 0, 0,
299
  0, 1, 1, 1, 0, 0, 1, 0, 0, 1, 1, 1, 0, 0, 0, 0,
300
};
301
static uint8_t has_bl_16x4[32] = {
302
  254, 254, 254, 84, 254, 254, 254, 16, 254, 254, 254, 84, 254, 254, 254, 0,
303
  254, 254, 254, 84, 254, 254, 254, 16, 254, 254, 254, 84, 254, 254, 254, 0,
304
};
305
static uint8_t has_bl_8x32[8] = {
306
  0, 1, 0, 0, 0, 1, 0, 0,
307
};
308
static uint8_t has_bl_32x8[8] = {
309
  238, 78, 238, 14, 238, 78, 238, 14,
310
};
311
static uint8_t has_bl_16x64[2] = { 0, 0 };
312
static uint8_t has_bl_64x16[2] = { 42, 42 };
313
314
static const uint8_t *const has_bl_tables[BLOCK_SIZES_ALL] = {
315
  // 4X4
316
  has_bl_4x4,
317
  // 4X8,         8X4,         8X8
318
  has_bl_4x8, has_bl_8x4, has_bl_8x8,
319
  // 8X16,        16X8,        16X16
320
  has_bl_8x16, has_bl_16x8, has_bl_16x16,
321
  // 16X32,       32X16,       32X32
322
  has_bl_16x32, has_bl_32x16, has_bl_32x32,
323
  // 32X64,       64X32,       64X64
324
  has_bl_32x64, has_bl_64x32, has_bl_64x64,
325
  // 64x128,      128x64,      128x128
326
  has_bl_64x128, has_bl_128x64, has_bl_128x128,
327
  // 4x16,        16x4,        8x32
328
  has_bl_4x16, has_bl_16x4, has_bl_8x32,
329
  // 32x8,        16x64,       64x16
330
  has_bl_32x8, has_bl_16x64, has_bl_64x16
331
};
332
333
static uint8_t has_bl_vert_8x8[32] = {
334
  254, 255, 16, 17, 254, 255, 0, 1, 254, 255, 16, 17, 254, 255, 0, 0,
335
  254, 255, 16, 17, 254, 255, 0, 1, 254, 255, 16, 17, 254, 255, 0, 0,
336
};
337
static uint8_t has_bl_vert_16x16[8] = {
338
  254, 16, 254, 0, 254, 16, 254, 0,
339
};
340
static uint8_t has_bl_vert_32x32[2] = { 14, 14 };
341
static uint8_t has_bl_vert_64x64[1] = { 2 };
342
343
// The _vert_* tables are like the ordinary tables above, but describe the
344
// order we visit square blocks when doing a PARTITION_VERT_A or
345
// PARTITION_VERT_B. This is the same order as normal except for on the last
346
// split where we go vertically (TL, BL, TR, BR). We treat the rectangular block
347
// as a pair of squares, which means that these tables work correctly for both
348
// mixed vertical partition types.
349
//
350
// There are tables for each of the square sizes. Vertical rectangles (like
351
// BLOCK_16X32) use their respective "non-vert" table
352
static const uint8_t *const has_bl_vert_tables[BLOCK_SIZES] = {
353
  // 4X4
354
  NULL,
355
  // 4X8,     8X4,         8X8
356
  has_bl_4x8, NULL, has_bl_vert_8x8,
357
  // 8X16,    16X8,        16X16
358
  has_bl_8x16, NULL, has_bl_vert_16x16,
359
  // 16X32,   32X16,       32X32
360
  has_bl_16x32, NULL, has_bl_vert_32x32,
361
  // 32X64,   64X32,       64X64
362
  has_bl_32x64, NULL, has_bl_vert_64x64,
363
  // 64x128,  128x64,      128x128
364
  has_bl_64x128, NULL, has_bl_128x128
365
};
366
367
static const uint8_t *get_has_bl_table(PARTITION_TYPE partition,
368
890k
                                       BLOCK_SIZE bsize) {
369
890k
  const uint8_t *ret = NULL;
370
  // If this is a mixed vertical partition, look up bsize in orders_vert.
371
890k
  if (partition == PARTITION_VERT_A || partition == PARTITION_VERT_B) {
372
76.2k
    assert(bsize < BLOCK_SIZES);
373
76.2k
    ret = has_bl_vert_tables[bsize];
374
814k
  } else {
375
814k
    ret = has_bl_tables[bsize];
376
814k
  }
377
890k
  assert(ret);
378
890k
  return ret;
379
890k
}
380
381
static int has_bottom_left(BLOCK_SIZE sb_size, BLOCK_SIZE bsize, int mi_row,
382
                           int mi_col, int bottom_available, int left_available,
383
                           PARTITION_TYPE partition, TX_SIZE txsz, int row_off,
384
1.67M
                           int col_off, int ss_x, int ss_y) {
385
1.67M
  if (!bottom_available || !left_available) return 0;
386
387
  // Special case for 128x* blocks, when col_off is half the block width.
388
  // This is needed because 128x* superblocks are divided into 64x* blocks in
389
  // raster order
390
1.52M
  if (block_size_wide[bsize] > block_size_wide[BLOCK_64X64] && col_off > 0) {
391
102k
    const int plane_bw_unit_64 = mi_size_wide[BLOCK_64X64] >> ss_x;
392
102k
    const int col_off_64 = col_off % plane_bw_unit_64;
393
102k
    if (col_off_64 == 0) {
394
      // We are at the left edge of top-right or bottom-right 64x* block.
395
46.0k
      const int plane_bh_unit_64 = mi_size_high[BLOCK_64X64] >> ss_y;
396
46.0k
      const int row_off_64 = row_off % plane_bh_unit_64;
397
46.0k
      const int plane_bh_unit =
398
46.0k
          AOMMIN(mi_size_high[bsize] >> ss_y, plane_bh_unit_64);
399
      // Check if all bottom-left pixels are in the left 64x* block (which is
400
      // already coded).
401
46.0k
      return row_off_64 + tx_size_high_unit[txsz] < plane_bh_unit;
402
46.0k
    }
403
102k
  }
404
405
1.48M
  if (col_off > 0) {
406
    // Bottom-left pixels are in the bottom-left block, which is not available.
407
203k
    return 0;
408
1.28M
  } else {
409
1.28M
    const int bh_unit = mi_size_high[bsize];
410
1.28M
    const int plane_bh_unit = AOMMAX(bh_unit >> ss_y, 1);
411
1.28M
    const int bottom_left_count_unit = tx_size_high_unit[txsz];
412
413
    // All bottom-left pixels are in the left block, which is already available.
414
1.28M
    if (row_off + bottom_left_count_unit < plane_bh_unit) return 1;
415
416
1.22M
    const int bw_in_mi_log2 = mi_size_wide_log2[bsize];
417
1.22M
    const int bh_in_mi_log2 = mi_size_high_log2[bsize];
418
1.22M
    const int sb_mi_size = mi_size_high[sb_size];
419
1.22M
    const int blk_row_in_sb = (mi_row & (sb_mi_size - 1)) >> bh_in_mi_log2;
420
1.22M
    const int blk_col_in_sb = (mi_col & (sb_mi_size - 1)) >> bw_in_mi_log2;
421
422
    // Leftmost column of superblock: so bottom-left pixels maybe in the left
423
    // and/or bottom-left superblocks. But only the left superblock is
424
    // available, so check if all required pixels fall in that superblock.
425
1.22M
    if (blk_col_in_sb == 0) {
426
196k
      const int blk_start_row_off =
427
196k
          blk_row_in_sb << (bh_in_mi_log2 + MI_SIZE_LOG2 - MI_SIZE_LOG2) >>
428
196k
          ss_y;
429
196k
      const int row_off_in_sb = blk_start_row_off + row_off;
430
196k
      const int sb_height_unit = sb_mi_size >> ss_y;
431
196k
      return row_off_in_sb + bottom_left_count_unit < sb_height_unit;
432
196k
    }
433
434
    // Bottom row of superblock (and not the leftmost column): so bottom-left
435
    // pixels fall in the bottom superblock, which is not available yet.
436
1.02M
    if (((blk_row_in_sb + 1) << bh_in_mi_log2) >= sb_mi_size) return 0;
437
438
    // General case (neither leftmost column nor bottom row): check if the
439
    // bottom-left block is coded before the current block.
440
890k
    const int this_blk_index =
441
890k
        ((blk_row_in_sb + 0) << (MAX_MIB_SIZE_LOG2 - bw_in_mi_log2)) +
442
890k
        blk_col_in_sb + 0;
443
890k
    const int idx1 = this_blk_index / 8;
444
890k
    const int idx2 = this_blk_index % 8;
445
890k
    const uint8_t *has_bl_table = get_has_bl_table(partition, bsize);
446
890k
    return (has_bl_table[idx1] >> idx2) & 1;
447
1.02M
  }
448
1.48M
}
449
450
typedef void (*intra_pred_fn)(uint8_t *dst, ptrdiff_t stride,
451
                              const uint8_t *above, const uint8_t *left);
452
453
static intra_pred_fn pred[INTRA_MODES][TX_SIZES_ALL];
454
static intra_pred_fn dc_pred[2][2][TX_SIZES_ALL];
455
456
#if CONFIG_AV1_HIGHBITDEPTH
457
typedef void (*intra_high_pred_fn)(uint16_t *dst, ptrdiff_t stride,
458
                                   const uint16_t *above, const uint16_t *left,
459
                                   int bd);
460
static intra_high_pred_fn pred_high[INTRA_MODES][TX_SIZES_ALL];
461
static intra_high_pred_fn dc_pred_high[2][2][TX_SIZES_ALL];
462
#endif
463
464
1
static void init_intra_predictors_internal(void) {
465
1
  assert(NELEMENTS(mode_to_angle_map) == INTRA_MODES);
466
467
#if CONFIG_REALTIME_ONLY && !CONFIG_AV1_DECODER
468
#define INIT_RECTANGULAR(p, type)             \
469
  p[TX_4X8] = aom_##type##_predictor_4x8;     \
470
  p[TX_8X4] = aom_##type##_predictor_8x4;     \
471
  p[TX_8X16] = aom_##type##_predictor_8x16;   \
472
  p[TX_16X8] = aom_##type##_predictor_16x8;   \
473
  p[TX_16X32] = aom_##type##_predictor_16x32; \
474
  p[TX_32X16] = aom_##type##_predictor_32x16; \
475
  p[TX_32X64] = aom_##type##_predictor_32x64; \
476
  p[TX_64X32] = aom_##type##_predictor_64x32;
477
#else
478
1
#define INIT_RECTANGULAR(p, type)             \
479
20
  p[TX_4X8] = aom_##type##_predictor_4x8;     \
480
20
  p[TX_8X4] = aom_##type##_predictor_8x4;     \
481
20
  p[TX_8X16] = aom_##type##_predictor_8x16;   \
482
20
  p[TX_16X8] = aom_##type##_predictor_16x8;   \
483
20
  p[TX_16X32] = aom_##type##_predictor_16x32; \
484
20
  p[TX_32X16] = aom_##type##_predictor_32x16; \
485
20
  p[TX_32X64] = aom_##type##_predictor_32x64; \
486
20
  p[TX_64X32] = aom_##type##_predictor_64x32; \
487
20
  p[TX_4X16] = aom_##type##_predictor_4x16;   \
488
20
  p[TX_16X4] = aom_##type##_predictor_16x4;   \
489
20
  p[TX_8X32] = aom_##type##_predictor_8x32;   \
490
20
  p[TX_32X8] = aom_##type##_predictor_32x8;   \
491
20
  p[TX_16X64] = aom_##type##_predictor_16x64; \
492
20
  p[TX_64X16] = aom_##type##_predictor_64x16;
493
1
#endif  // CONFIG_REALTIME_ONLY && !CONFIG_AV1_DECODER
494
495
1
#define INIT_NO_4X4(p, type)                  \
496
20
  p[TX_8X8] = aom_##type##_predictor_8x8;     \
497
20
  p[TX_16X16] = aom_##type##_predictor_16x16; \
498
20
  p[TX_32X32] = aom_##type##_predictor_32x32; \
499
20
  p[TX_64X64] = aom_##type##_predictor_64x64; \
500
20
  INIT_RECTANGULAR(p, type)
501
502
1
#define INIT_ALL_SIZES(p, type)           \
503
20
  p[TX_4X4] = aom_##type##_predictor_4x4; \
504
20
  INIT_NO_4X4(p, type)
505
506
1
  INIT_ALL_SIZES(pred[V_PRED], v)
507
1
  INIT_ALL_SIZES(pred[H_PRED], h)
508
1
  INIT_ALL_SIZES(pred[PAETH_PRED], paeth)
509
1
  INIT_ALL_SIZES(pred[SMOOTH_PRED], smooth)
510
1
  INIT_ALL_SIZES(pred[SMOOTH_V_PRED], smooth_v)
511
1
  INIT_ALL_SIZES(pred[SMOOTH_H_PRED], smooth_h)
512
1
  INIT_ALL_SIZES(dc_pred[0][0], dc_128)
513
1
  INIT_ALL_SIZES(dc_pred[0][1], dc_top)
514
1
  INIT_ALL_SIZES(dc_pred[1][0], dc_left)
515
1
  INIT_ALL_SIZES(dc_pred[1][1], dc)
516
1
#if CONFIG_AV1_HIGHBITDEPTH
517
1
  INIT_ALL_SIZES(pred_high[V_PRED], highbd_v)
518
1
  INIT_ALL_SIZES(pred_high[H_PRED], highbd_h)
519
1
  INIT_ALL_SIZES(pred_high[PAETH_PRED], highbd_paeth)
520
1
  INIT_ALL_SIZES(pred_high[SMOOTH_PRED], highbd_smooth)
521
1
  INIT_ALL_SIZES(pred_high[SMOOTH_V_PRED], highbd_smooth_v)
522
1
  INIT_ALL_SIZES(pred_high[SMOOTH_H_PRED], highbd_smooth_h)
523
1
  INIT_ALL_SIZES(dc_pred_high[0][0], highbd_dc_128)
524
1
  INIT_ALL_SIZES(dc_pred_high[0][1], highbd_dc_top)
525
1
  INIT_ALL_SIZES(dc_pred_high[1][0], highbd_dc_left)
526
1
  INIT_ALL_SIZES(dc_pred_high[1][1], highbd_dc)
527
1
#endif
528
1
#undef intra_pred_allsizes
529
1
}
530
531
// Directional prediction, zone 1: 0 < angle < 90
532
void av1_dr_prediction_z1_c(uint8_t *dst, ptrdiff_t stride, int bw, int bh,
533
                            const uint8_t *above, const uint8_t *left,
534
0
                            int upsample_above, int dx, int dy) {
535
0
  int r, c, x, base, shift, val;
536
537
0
  (void)left;
538
0
  (void)dy;
539
0
  assert(dy == 1);
540
0
  assert(dx > 0);
541
542
0
  const int max_base_x = ((bw + bh) - 1) << upsample_above;
543
0
  const int frac_bits = 6 - upsample_above;
544
0
  const int base_inc = 1 << upsample_above;
545
0
  x = dx;
546
0
  for (r = 0; r < bh; ++r, dst += stride, x += dx) {
547
0
    base = x >> frac_bits;
548
0
    shift = ((x << upsample_above) & 0x3F) >> 1;
549
550
0
    if (base >= max_base_x) {
551
0
      for (int i = r; i < bh; ++i) {
552
0
        memset(dst, above[max_base_x], bw * sizeof(dst[0]));
553
0
        dst += stride;
554
0
      }
555
0
      return;
556
0
    }
557
558
0
    for (c = 0; c < bw; ++c, base += base_inc) {
559
0
      if (base < max_base_x) {
560
0
        val = above[base] * (32 - shift) + above[base + 1] * shift;
561
0
        dst[c] = ROUND_POWER_OF_TWO(val, 5);
562
0
      } else {
563
0
        dst[c] = above[max_base_x];
564
0
      }
565
0
    }
566
0
  }
567
0
}
568
569
// Directional prediction, zone 2: 90 < angle < 180
570
void av1_dr_prediction_z2_c(uint8_t *dst, ptrdiff_t stride, int bw, int bh,
571
                            const uint8_t *above, const uint8_t *left,
572
                            int upsample_above, int upsample_left, int dx,
573
0
                            int dy) {
574
0
  assert(dx > 0);
575
0
  assert(dy > 0);
576
577
0
  const int min_base_x = -(1 << upsample_above);
578
0
  const int min_base_y = -(1 << upsample_left);
579
0
  (void)min_base_y;
580
0
  const int frac_bits_x = 6 - upsample_above;
581
0
  const int frac_bits_y = 6 - upsample_left;
582
583
0
  for (int r = 0; r < bh; ++r) {
584
0
    for (int c = 0; c < bw; ++c) {
585
0
      int val;
586
0
      int y = r + 1;
587
0
      int x = (c << 6) - y * dx;
588
0
      const int base_x = x >> frac_bits_x;
589
0
      if (base_x >= min_base_x) {
590
0
        const int shift = ((x * (1 << upsample_above)) & 0x3F) >> 1;
591
0
        val = above[base_x] * (32 - shift) + above[base_x + 1] * shift;
592
0
        val = ROUND_POWER_OF_TWO(val, 5);
593
0
      } else {
594
0
        x = c + 1;
595
0
        y = (r << 6) - x * dy;
596
0
        const int base_y = y >> frac_bits_y;
597
0
        assert(base_y >= min_base_y);
598
0
        const int shift = ((y * (1 << upsample_left)) & 0x3F) >> 1;
599
0
        val = left[base_y] * (32 - shift) + left[base_y + 1] * shift;
600
0
        val = ROUND_POWER_OF_TWO(val, 5);
601
0
      }
602
0
      dst[c] = val;
603
0
    }
604
0
    dst += stride;
605
0
  }
606
0
}
607
608
// Directional prediction, zone 3: 180 < angle < 270
609
void av1_dr_prediction_z3_c(uint8_t *dst, ptrdiff_t stride, int bw, int bh,
610
                            const uint8_t *above, const uint8_t *left,
611
0
                            int upsample_left, int dx, int dy) {
612
0
  int r, c, y, base, shift, val;
613
614
0
  (void)above;
615
0
  (void)dx;
616
617
0
  assert(dx == 1);
618
0
  assert(dy > 0);
619
620
0
  const int max_base_y = (bw + bh - 1) << upsample_left;
621
0
  const int frac_bits = 6 - upsample_left;
622
0
  const int base_inc = 1 << upsample_left;
623
0
  y = dy;
624
0
  for (c = 0; c < bw; ++c, y += dy) {
625
0
    base = y >> frac_bits;
626
0
    shift = ((y << upsample_left) & 0x3F) >> 1;
627
628
0
    for (r = 0; r < bh; ++r, base += base_inc) {
629
0
      if (base < max_base_y) {
630
0
        val = left[base] * (32 - shift) + left[base + 1] * shift;
631
0
        dst[r * stride + c] = ROUND_POWER_OF_TWO(val, 5);
632
0
      } else {
633
0
        for (; r < bh; ++r) dst[r * stride + c] = left[max_base_y];
634
0
        break;
635
0
      }
636
0
    }
637
0
  }
638
0
}
639
640
static void dr_predictor(uint8_t *dst, ptrdiff_t stride, TX_SIZE tx_size,
641
                         const uint8_t *above, const uint8_t *left,
642
3.48M
                         int upsample_above, int upsample_left, int angle) {
643
3.48M
  const int dx = av1_get_dx(angle);
644
3.48M
  const int dy = av1_get_dy(angle);
645
3.48M
  const int bw = tx_size_wide[tx_size];
646
3.48M
  const int bh = tx_size_high[tx_size];
647
3.48M
  assert(angle > 0 && angle < 270);
648
649
3.48M
  if (angle > 0 && angle < 90) {
650
393k
    av1_dr_prediction_z1(dst, stride, bw, bh, above, left, upsample_above, dx,
651
393k
                         dy);
652
3.09M
  } else if (angle > 90 && angle < 180) {
653
870k
    av1_dr_prediction_z2(dst, stride, bw, bh, above, left, upsample_above,
654
870k
                         upsample_left, dx, dy);
655
2.22M
  } else if (angle > 180 && angle < 270) {
656
617k
    av1_dr_prediction_z3(dst, stride, bw, bh, above, left, upsample_left, dx,
657
617k
                         dy);
658
1.60M
  } else if (angle == 90) {
659
361k
    pred[V_PRED][tx_size](dst, stride, above, left);
660
1.24M
  } else if (angle == 180) {
661
1.24M
    pred[H_PRED][tx_size](dst, stride, above, left);
662
1.24M
  }
663
3.48M
}
664
665
#if CONFIG_AV1_HIGHBITDEPTH
666
// Directional prediction, zone 1: 0 < angle < 90
667
void av1_highbd_dr_prediction_z1_c(uint16_t *dst, ptrdiff_t stride, int bw,
668
                                   int bh, const uint16_t *above,
669
                                   const uint16_t *left, int upsample_above,
670
0
                                   int dx, int dy, int bd) {
671
0
  int r, c, x, base, shift, val;
672
673
0
  (void)left;
674
0
  (void)dy;
675
0
  (void)bd;
676
0
  assert(dy == 1);
677
0
  assert(dx > 0);
678
679
0
  const int max_base_x = ((bw + bh) - 1) << upsample_above;
680
0
  const int frac_bits = 6 - upsample_above;
681
0
  const int base_inc = 1 << upsample_above;
682
0
  x = dx;
683
0
  for (r = 0; r < bh; ++r, dst += stride, x += dx) {
684
0
    base = x >> frac_bits;
685
0
    shift = ((x << upsample_above) & 0x3F) >> 1;
686
687
0
    if (base >= max_base_x) {
688
0
      for (int i = r; i < bh; ++i) {
689
0
        aom_memset16(dst, above[max_base_x], bw);
690
0
        dst += stride;
691
0
      }
692
0
      return;
693
0
    }
694
695
0
    for (c = 0; c < bw; ++c, base += base_inc) {
696
0
      if (base < max_base_x) {
697
0
        val = above[base] * (32 - shift) + above[base + 1] * shift;
698
0
        dst[c] = ROUND_POWER_OF_TWO(val, 5);
699
0
      } else {
700
0
        dst[c] = above[max_base_x];
701
0
      }
702
0
    }
703
0
  }
704
0
}
705
706
// Directional prediction, zone 2: 90 < angle < 180
707
void av1_highbd_dr_prediction_z2_c(uint16_t *dst, ptrdiff_t stride, int bw,
708
                                   int bh, const uint16_t *above,
709
                                   const uint16_t *left, int upsample_above,
710
0
                                   int upsample_left, int dx, int dy, int bd) {
711
0
  (void)bd;
712
0
  assert(dx > 0);
713
0
  assert(dy > 0);
714
715
0
  const int min_base_x = -(1 << upsample_above);
716
0
  const int min_base_y = -(1 << upsample_left);
717
0
  (void)min_base_y;
718
0
  const int frac_bits_x = 6 - upsample_above;
719
0
  const int frac_bits_y = 6 - upsample_left;
720
721
0
  for (int r = 0; r < bh; ++r) {
722
0
    for (int c = 0; c < bw; ++c) {
723
0
      int val;
724
0
      int y = r + 1;
725
0
      int x = (c << 6) - y * dx;
726
0
      const int base_x = x >> frac_bits_x;
727
0
      if (base_x >= min_base_x) {
728
0
        const int shift = ((x * (1 << upsample_above)) & 0x3F) >> 1;
729
0
        val = above[base_x] * (32 - shift) + above[base_x + 1] * shift;
730
0
        val = ROUND_POWER_OF_TWO(val, 5);
731
0
      } else {
732
0
        x = c + 1;
733
0
        y = (r << 6) - x * dy;
734
0
        const int base_y = y >> frac_bits_y;
735
0
        assert(base_y >= min_base_y);
736
0
        const int shift = ((y * (1 << upsample_left)) & 0x3F) >> 1;
737
0
        val = left[base_y] * (32 - shift) + left[base_y + 1] * shift;
738
0
        val = ROUND_POWER_OF_TWO(val, 5);
739
0
      }
740
0
      dst[c] = val;
741
0
    }
742
0
    dst += stride;
743
0
  }
744
0
}
745
746
// Directional prediction, zone 3: 180 < angle < 270
747
void av1_highbd_dr_prediction_z3_c(uint16_t *dst, ptrdiff_t stride, int bw,
748
                                   int bh, const uint16_t *above,
749
                                   const uint16_t *left, int upsample_left,
750
0
                                   int dx, int dy, int bd) {
751
0
  int r, c, y, base, shift, val;
752
753
0
  (void)above;
754
0
  (void)dx;
755
0
  (void)bd;
756
0
  assert(dx == 1);
757
0
  assert(dy > 0);
758
759
0
  const int max_base_y = (bw + bh - 1) << upsample_left;
760
0
  const int frac_bits = 6 - upsample_left;
761
0
  const int base_inc = 1 << upsample_left;
762
0
  y = dy;
763
0
  for (c = 0; c < bw; ++c, y += dy) {
764
0
    base = y >> frac_bits;
765
0
    shift = ((y << upsample_left) & 0x3F) >> 1;
766
767
0
    for (r = 0; r < bh; ++r, base += base_inc) {
768
0
      if (base < max_base_y) {
769
0
        val = left[base] * (32 - shift) + left[base + 1] * shift;
770
0
        dst[r * stride + c] = ROUND_POWER_OF_TWO(val, 5);
771
0
      } else {
772
0
        for (; r < bh; ++r) dst[r * stride + c] = left[max_base_y];
773
0
        break;
774
0
      }
775
0
    }
776
0
  }
777
0
}
778
779
static void highbd_dr_predictor(uint16_t *dst, ptrdiff_t stride,
780
                                TX_SIZE tx_size, const uint16_t *above,
781
                                const uint16_t *left, int upsample_above,
782
5.20M
                                int upsample_left, int angle, int bd) {
783
5.20M
  const int dx = av1_get_dx(angle);
784
5.20M
  const int dy = av1_get_dy(angle);
785
5.20M
  const int bw = tx_size_wide[tx_size];
786
5.20M
  const int bh = tx_size_high[tx_size];
787
5.20M
  assert(angle > 0 && angle < 270);
788
789
5.20M
  if (angle > 0 && angle < 90) {
790
619k
    av1_highbd_dr_prediction_z1(dst, stride, bw, bh, above, left,
791
619k
                                upsample_above, dx, dy, bd);
792
4.58M
  } else if (angle > 90 && angle < 180) {
793
1.17M
    av1_highbd_dr_prediction_z2(dst, stride, bw, bh, above, left,
794
1.17M
                                upsample_above, upsample_left, dx, dy, bd);
795
3.41M
  } else if (angle > 180 && angle < 270) {
796
939k
    av1_highbd_dr_prediction_z3(dst, stride, bw, bh, above, left, upsample_left,
797
939k
                                dx, dy, bd);
798
2.47M
  } else if (angle == 90) {
799
528k
    pred_high[V_PRED][tx_size](dst, stride, above, left, bd);
800
1.95M
  } else if (angle == 180) {
801
1.95M
    pred_high[H_PRED][tx_size](dst, stride, above, left, bd);
802
1.95M
  }
803
5.20M
}
804
#endif  // CONFIG_AV1_HIGHBITDEPTH
805
806
DECLARE_ALIGNED(16, const int8_t,
807
                av1_filter_intra_taps[FILTER_INTRA_MODES][8][8]) = {
808
  {
809
      { -6, 10, 0, 0, 0, 12, 0, 0 },
810
      { -5, 2, 10, 0, 0, 9, 0, 0 },
811
      { -3, 1, 1, 10, 0, 7, 0, 0 },
812
      { -3, 1, 1, 2, 10, 5, 0, 0 },
813
      { -4, 6, 0, 0, 0, 2, 12, 0 },
814
      { -3, 2, 6, 0, 0, 2, 9, 0 },
815
      { -3, 2, 2, 6, 0, 2, 7, 0 },
816
      { -3, 1, 2, 2, 6, 3, 5, 0 },
817
  },
818
  {
819
      { -10, 16, 0, 0, 0, 10, 0, 0 },
820
      { -6, 0, 16, 0, 0, 6, 0, 0 },
821
      { -4, 0, 0, 16, 0, 4, 0, 0 },
822
      { -2, 0, 0, 0, 16, 2, 0, 0 },
823
      { -10, 16, 0, 0, 0, 0, 10, 0 },
824
      { -6, 0, 16, 0, 0, 0, 6, 0 },
825
      { -4, 0, 0, 16, 0, 0, 4, 0 },
826
      { -2, 0, 0, 0, 16, 0, 2, 0 },
827
  },
828
  {
829
      { -8, 8, 0, 0, 0, 16, 0, 0 },
830
      { -8, 0, 8, 0, 0, 16, 0, 0 },
831
      { -8, 0, 0, 8, 0, 16, 0, 0 },
832
      { -8, 0, 0, 0, 8, 16, 0, 0 },
833
      { -4, 4, 0, 0, 0, 0, 16, 0 },
834
      { -4, 0, 4, 0, 0, 0, 16, 0 },
835
      { -4, 0, 0, 4, 0, 0, 16, 0 },
836
      { -4, 0, 0, 0, 4, 0, 16, 0 },
837
  },
838
  {
839
      { -2, 8, 0, 0, 0, 10, 0, 0 },
840
      { -1, 3, 8, 0, 0, 6, 0, 0 },
841
      { -1, 2, 3, 8, 0, 4, 0, 0 },
842
      { 0, 1, 2, 3, 8, 2, 0, 0 },
843
      { -1, 4, 0, 0, 0, 3, 10, 0 },
844
      { -1, 3, 4, 0, 0, 4, 6, 0 },
845
      { -1, 2, 3, 4, 0, 4, 4, 0 },
846
      { -1, 2, 2, 3, 4, 3, 3, 0 },
847
  },
848
  {
849
      { -12, 14, 0, 0, 0, 14, 0, 0 },
850
      { -10, 0, 14, 0, 0, 12, 0, 0 },
851
      { -9, 0, 0, 14, 0, 11, 0, 0 },
852
      { -8, 0, 0, 0, 14, 10, 0, 0 },
853
      { -10, 12, 0, 0, 0, 0, 14, 0 },
854
      { -9, 1, 12, 0, 0, 0, 12, 0 },
855
      { -8, 0, 0, 12, 0, 1, 11, 0 },
856
      { -7, 0, 0, 1, 12, 1, 9, 0 },
857
  },
858
};
859
860
void av1_filter_intra_predictor_c(uint8_t *dst, ptrdiff_t stride,
861
                                  TX_SIZE tx_size, const uint8_t *above,
862
0
                                  const uint8_t *left, int mode) {
863
0
  int r, c;
864
0
  uint8_t buffer[33][33];
865
0
  const int bw = tx_size_wide[tx_size];
866
0
  const int bh = tx_size_high[tx_size];
867
868
0
  assert(bw <= 32 && bh <= 32);
869
870
0
  for (r = 0; r < bh; ++r) buffer[r + 1][0] = left[r];
871
0
  memcpy(buffer[0], &above[-1], (bw + 1) * sizeof(uint8_t));
872
873
0
  for (r = 1; r < bh + 1; r += 2)
874
0
    for (c = 1; c < bw + 1; c += 4) {
875
0
      const uint8_t p0 = buffer[r - 1][c - 1];
876
0
      const uint8_t p1 = buffer[r - 1][c];
877
0
      const uint8_t p2 = buffer[r - 1][c + 1];
878
0
      const uint8_t p3 = buffer[r - 1][c + 2];
879
0
      const uint8_t p4 = buffer[r - 1][c + 3];
880
0
      const uint8_t p5 = buffer[r][c - 1];
881
0
      const uint8_t p6 = buffer[r + 1][c - 1];
882
0
      for (int k = 0; k < 8; ++k) {
883
0
        int r_offset = k >> 2;
884
0
        int c_offset = k & 0x03;
885
0
        int pr = av1_filter_intra_taps[mode][k][0] * p0 +
886
0
                 av1_filter_intra_taps[mode][k][1] * p1 +
887
0
                 av1_filter_intra_taps[mode][k][2] * p2 +
888
0
                 av1_filter_intra_taps[mode][k][3] * p3 +
889
0
                 av1_filter_intra_taps[mode][k][4] * p4 +
890
0
                 av1_filter_intra_taps[mode][k][5] * p5 +
891
0
                 av1_filter_intra_taps[mode][k][6] * p6;
892
        // Section 7.11.2.3 specifies the right-hand side of the assignment as
893
        //   Clip1( Round2Signed( pr, INTRA_FILTER_SCALE_BITS ) ).
894
        // Since Clip1() clips a negative value to 0, it is safe to replace
895
        // Round2Signed() with Round2().
896
0
        buffer[r + r_offset][c + c_offset] =
897
0
            clip_pixel(ROUND_POWER_OF_TWO(pr, FILTER_INTRA_SCALE_BITS));
898
0
      }
899
0
    }
900
901
0
  for (r = 0; r < bh; ++r) {
902
0
    memcpy(dst, &buffer[r + 1][1], bw * sizeof(uint8_t));
903
0
    dst += stride;
904
0
  }
905
0
}
906
907
#if CONFIG_AV1_HIGHBITDEPTH
908
static void highbd_filter_intra_predictor(uint16_t *dst, ptrdiff_t stride,
909
                                          TX_SIZE tx_size,
910
                                          const uint16_t *above,
911
                                          const uint16_t *left, int mode,
912
746k
                                          int bd) {
913
746k
  int r, c;
914
746k
  uint16_t buffer[33][33];
915
746k
  const int bw = tx_size_wide[tx_size];
916
746k
  const int bh = tx_size_high[tx_size];
917
918
746k
  assert(bw <= 32 && bh <= 32);
919
920
8.18M
  for (r = 0; r < bh; ++r) buffer[r + 1][0] = left[r];
921
746k
  memcpy(buffer[0], &above[-1], (bw + 1) * sizeof(buffer[0][0]));
922
923
4.44M
  for (r = 1; r < bh + 1; r += 2)
924
17.1M
    for (c = 1; c < bw + 1; c += 4) {
925
13.4M
      const uint16_t p0 = buffer[r - 1][c - 1];
926
13.4M
      const uint16_t p1 = buffer[r - 1][c];
927
13.4M
      const uint16_t p2 = buffer[r - 1][c + 1];
928
13.4M
      const uint16_t p3 = buffer[r - 1][c + 2];
929
13.4M
      const uint16_t p4 = buffer[r - 1][c + 3];
930
13.4M
      const uint16_t p5 = buffer[r][c - 1];
931
13.4M
      const uint16_t p6 = buffer[r + 1][c - 1];
932
121M
      for (int k = 0; k < 8; ++k) {
933
107M
        int r_offset = k >> 2;
934
107M
        int c_offset = k & 0x03;
935
107M
        int pr = av1_filter_intra_taps[mode][k][0] * p0 +
936
107M
                 av1_filter_intra_taps[mode][k][1] * p1 +
937
107M
                 av1_filter_intra_taps[mode][k][2] * p2 +
938
107M
                 av1_filter_intra_taps[mode][k][3] * p3 +
939
107M
                 av1_filter_intra_taps[mode][k][4] * p4 +
940
107M
                 av1_filter_intra_taps[mode][k][5] * p5 +
941
107M
                 av1_filter_intra_taps[mode][k][6] * p6;
942
        // Section 7.11.2.3 specifies the right-hand side of the assignment as
943
        //   Clip1( Round2Signed( pr, INTRA_FILTER_SCALE_BITS ) ).
944
        // Since Clip1() clips a negative value to 0, it is safe to replace
945
        // Round2Signed() with Round2().
946
107M
        buffer[r + r_offset][c + c_offset] = clip_pixel_highbd(
947
107M
            ROUND_POWER_OF_TWO(pr, FILTER_INTRA_SCALE_BITS), bd);
948
107M
      }
949
13.4M
    }
950
951
8.18M
  for (r = 0; r < bh; ++r) {
952
7.43M
    memcpy(dst, &buffer[r + 1][1], bw * sizeof(dst[0]));
953
7.43M
    dst += stride;
954
7.43M
  }
955
746k
}
956
#endif  // CONFIG_AV1_HIGHBITDEPTH
957
958
17.9M
static int is_smooth(const MB_MODE_INFO *mbmi, int plane) {
959
17.9M
  if (plane == 0) {
960
8.82M
    const PREDICTION_MODE mode = mbmi->mode;
961
8.82M
    return (mode == SMOOTH_PRED || mode == SMOOTH_V_PRED ||
962
7.96M
            mode == SMOOTH_H_PRED);
963
9.08M
  } else {
964
    // uv_mode is not set for inter blocks, so need to explicitly
965
    // detect that case.
966
9.08M
    if (is_inter_block(mbmi)) return 0;
967
968
8.16M
    const UV_PREDICTION_MODE uv_mode = mbmi->uv_mode;
969
8.16M
    return (uv_mode == UV_SMOOTH_PRED || uv_mode == UV_SMOOTH_V_PRED ||
970
7.62M
            uv_mode == UV_SMOOTH_H_PRED);
971
9.08M
  }
972
17.9M
}
973
974
10.1M
static int get_intra_edge_filter_type(const MACROBLOCKD *xd, int plane) {
975
10.1M
  const MB_MODE_INFO *above;
976
10.1M
  const MB_MODE_INFO *left;
977
978
10.1M
  if (plane == 0) {
979
5.14M
    above = xd->above_mbmi;
980
5.14M
    left = xd->left_mbmi;
981
5.14M
  } else {
982
5.02M
    above = xd->chroma_above_mbmi;
983
5.02M
    left = xd->chroma_left_mbmi;
984
5.02M
  }
985
986
10.1M
  return (above && is_smooth(above, plane)) || (left && is_smooth(left, plane));
987
10.1M
}
988
989
5.60M
static int intra_edge_filter_strength(int bs0, int bs1, int delta, int type) {
990
5.60M
  const int d = abs(delta);
991
5.60M
  int strength = 0;
992
993
5.60M
  const int blk_wh = bs0 + bs1;
994
5.60M
  if (type == 0) {
995
4.39M
    if (blk_wh <= 8) {
996
802k
      if (d >= 56) strength = 1;
997
3.59M
    } else if (blk_wh <= 12) {
998
482k
      if (d >= 40) strength = 1;
999
3.11M
    } else if (blk_wh <= 16) {
1000
686k
      if (d >= 40) strength = 1;
1001
2.42M
    } else if (blk_wh <= 24) {
1002
913k
      if (d >= 8) strength = 1;
1003
913k
      if (d >= 16) strength = 2;
1004
913k
      if (d >= 32) strength = 3;
1005
1.51M
    } else if (blk_wh <= 32) {
1006
496k
      if (d >= 1) strength = 1;
1007
496k
      if (d >= 4) strength = 2;
1008
496k
      if (d >= 32) strength = 3;
1009
1.01M
    } else {
1010
1.01M
      if (d >= 1) strength = 3;
1011
1.01M
    }
1012
4.39M
  } else {
1013
1.21M
    if (blk_wh <= 8) {
1014
156k
      if (d >= 40) strength = 1;
1015
156k
      if (d >= 64) strength = 2;
1016
1.05M
    } else if (blk_wh <= 16) {
1017
342k
      if (d >= 20) strength = 1;
1018
342k
      if (d >= 48) strength = 2;
1019
712k
    } else if (blk_wh <= 24) {
1020
272k
      if (d >= 4) strength = 3;
1021
440k
    } else {
1022
440k
      if (d >= 1) strength = 3;
1023
440k
    }
1024
1.21M
  }
1025
5.60M
  return strength;
1026
5.60M
}
1027
1028
0
void av1_filter_intra_edge_c(uint8_t *p, int sz, int strength) {
1029
0
  if (!strength) return;
1030
1031
0
  const int kernel[INTRA_EDGE_FILT][INTRA_EDGE_TAPS] = { { 0, 4, 8, 4, 0 },
1032
0
                                                         { 0, 5, 6, 5, 0 },
1033
0
                                                         { 2, 4, 4, 4, 2 } };
1034
0
  const int filt = strength - 1;
1035
0
  uint8_t edge[129];
1036
1037
0
  memcpy(edge, p, sz * sizeof(*p));
1038
0
  for (int i = 1; i < sz; i++) {
1039
0
    int s = 0;
1040
0
    for (int j = 0; j < INTRA_EDGE_TAPS; j++) {
1041
0
      int k = i - 2 + j;
1042
0
      k = (k < 0) ? 0 : k;
1043
0
      k = (k > sz - 1) ? sz - 1 : k;
1044
0
      s += edge[k] * kernel[filt][j];
1045
0
    }
1046
0
    s = (s + 8) >> 4;
1047
0
    p[i] = s;
1048
0
  }
1049
0
}
1050
1051
353k
static void filter_intra_edge_corner(uint8_t *p_above, uint8_t *p_left) {
1052
353k
  const int kernel[3] = { 5, 6, 5 };
1053
1054
353k
  int s = (p_left[0] * kernel[0]) + (p_above[-1] * kernel[1]) +
1055
353k
          (p_above[0] * kernel[2]);
1056
353k
  s = (s + 8) >> 4;
1057
353k
  p_above[-1] = s;
1058
353k
  p_left[-1] = s;
1059
353k
}
1060
1061
0
void av1_upsample_intra_edge_c(uint8_t *p, int sz) {
1062
  // interpolate half-sample positions
1063
0
  assert(sz <= MAX_UPSAMPLE_SZ);
1064
1065
0
  uint8_t in[MAX_UPSAMPLE_SZ + 3];
1066
  // copy p[-1..(sz-1)] and extend first and last samples
1067
0
  in[0] = p[-1];
1068
0
  in[1] = p[-1];
1069
0
  for (int i = 0; i < sz; i++) {
1070
0
    in[i + 2] = p[i];
1071
0
  }
1072
0
  in[sz + 2] = p[sz - 1];
1073
1074
  // interpolate half-sample edge positions
1075
0
  p[-2] = in[0];
1076
0
  for (int i = 0; i < sz; i++) {
1077
0
    int s = -in[i] + (9 * in[i + 1]) + (9 * in[i + 2]) - in[i + 3];
1078
0
    s = clip_pixel((s + 8) >> 4);
1079
0
    p[2 * i - 1] = s;
1080
0
    p[2 * i] = in[i + 2];
1081
0
  }
1082
0
}
1083
1084
static void build_directional_and_filter_intra_predictors(
1085
    const uint8_t *ref, int ref_stride, uint8_t *dst, int dst_stride,
1086
    PREDICTION_MODE mode, int p_angle, FILTER_INTRA_MODE filter_intra_mode,
1087
    TX_SIZE tx_size, int disable_edge_filter, int n_top_px, int n_topright_px,
1088
4.07M
    int n_left_px, int n_bottomleft_px, int intra_edge_filter_type) {
1089
4.07M
  int i;
1090
4.07M
  const uint8_t *above_ref = ref - ref_stride;
1091
4.07M
  const uint8_t *left_ref = ref - 1;
1092
4.07M
  DECLARE_ALIGNED(16, uint8_t, left_data[NUM_INTRA_NEIGHBOUR_PIXELS]);
1093
4.07M
  DECLARE_ALIGNED(16, uint8_t, above_data[NUM_INTRA_NEIGHBOUR_PIXELS]);
1094
4.07M
  uint8_t *const above_row = above_data + 16;
1095
4.07M
  uint8_t *const left_col = left_data + 16;
1096
4.07M
  const int txwpx = tx_size_wide[tx_size];
1097
4.07M
  const int txhpx = tx_size_high[tx_size];
1098
4.07M
  int need_left = extend_modes[mode] & NEED_LEFT;
1099
4.07M
  int need_above = extend_modes[mode] & NEED_ABOVE;
1100
4.07M
  int need_above_left = extend_modes[mode] & NEED_ABOVELEFT;
1101
4.07M
  const int is_dr_mode = av1_is_directional_mode(mode);
1102
4.07M
  const int use_filter_intra = filter_intra_mode != FILTER_INTRA_MODES;
1103
4.07M
  assert(use_filter_intra || is_dr_mode);
1104
  // The left_data, above_data buffers must be zeroed to fix some intermittent
1105
  // valgrind errors. Uninitialized reads in intra pred modules (e.g. width = 4
1106
  // path in av1_dr_prediction_z1_avx2()) from left_data, above_data are seen to
1107
  // be the potential reason for this issue.
1108
4.07M
  memset(left_data, 129, NUM_INTRA_NEIGHBOUR_PIXELS);
1109
4.07M
  memset(above_data, 127, NUM_INTRA_NEIGHBOUR_PIXELS);
1110
1111
  // The default values if ref pixels are not available:
1112
  // 128 127 127 .. 127 127 127 127 127 127
1113
  // 129  A   B  ..  Y   Z
1114
  // 129  C   D  ..  W   X
1115
  // 129  E   F  ..  U   V
1116
  // 129  G   H  ..  S   T   T   T   T   T
1117
  // ..
1118
1119
4.07M
  if (is_dr_mode) {
1120
3.53M
    if (p_angle <= 90)
1121
780k
      need_above = 1, need_left = 0, need_above_left = 1;
1122
2.75M
    else if (p_angle < 180)
1123
870k
      need_above = 1, need_left = 1, need_above_left = 1;
1124
1.88M
    else
1125
1.88M
      need_above = 0, need_left = 1, need_above_left = 1;
1126
3.53M
  }
1127
4.07M
  if (use_filter_intra) need_left = need_above = need_above_left = 1;
1128
1129
4.07M
  assert(n_top_px >= 0);
1130
4.07M
  assert(n_topright_px >= -1);
1131
4.07M
  assert(n_left_px >= 0);
1132
4.07M
  assert(n_bottomleft_px >= -1);
1133
1134
4.07M
  if ((!need_above && n_left_px == 0) || (!need_left && n_top_px == 0)) {
1135
53.4k
    int val;
1136
53.4k
    if (need_left) {
1137
28.7k
      val = (n_top_px > 0) ? above_ref[0] : 129;
1138
28.7k
    } else {
1139
24.6k
      val = (n_left_px > 0) ? left_ref[0] : 127;
1140
24.6k
    }
1141
1.61M
    for (i = 0; i < txhpx; ++i) {
1142
1.56M
      memset(dst, val, txwpx);
1143
1.56M
      dst += dst_stride;
1144
1.56M
    }
1145
53.4k
    return;
1146
53.4k
  }
1147
1148
  // NEED_LEFT
1149
4.02M
  if (need_left) {
1150
3.27M
    const int num_left_pixels_needed =
1151
3.27M
        txhpx + (n_bottomleft_px >= 0 ? txwpx : 0);
1152
3.27M
    i = 0;
1153
3.27M
    if (n_left_px > 0) {
1154
44.2M
      for (; i < n_left_px; i++) left_col[i] = left_ref[i * ref_stride];
1155
3.23M
      if (n_bottomleft_px > 0) {
1156
253k
        assert(i == txhpx);
1157
3.00M
        for (; i < txhpx + n_bottomleft_px; i++)
1158
2.75M
          left_col[i] = left_ref[i * ref_stride];
1159
253k
      }
1160
3.23M
      if (i < num_left_pixels_needed)
1161
523k
        memset(&left_col[i], left_col[i - 1], num_left_pixels_needed - i);
1162
3.23M
    } else if (n_top_px > 0) {
1163
24.1k
      memset(left_col, above_ref[0], num_left_pixels_needed);
1164
24.1k
    }
1165
3.27M
  }
1166
1167
  // NEED_ABOVE
1168
4.02M
  if (need_above) {
1169
2.16M
    const int num_top_pixels_needed = txwpx + (n_topright_px >= 0 ? txhpx : 0);
1170
2.16M
    if (n_top_px > 0) {
1171
2.11M
      memcpy(above_row, above_ref, n_top_px);
1172
2.11M
      i = n_top_px;
1173
2.11M
      if (n_topright_px > 0) {
1174
236k
        assert(n_top_px == txwpx);
1175
236k
        memcpy(above_row + txwpx, above_ref + txwpx, n_topright_px);
1176
236k
        i += n_topright_px;
1177
236k
      }
1178
2.11M
      if (i < num_top_pixels_needed)
1179
219k
        memset(&above_row[i], above_row[i - 1], num_top_pixels_needed - i);
1180
2.11M
    } else if (n_left_px > 0) {
1181
36.8k
      memset(above_row, left_ref[0], num_top_pixels_needed);
1182
36.8k
    }
1183
2.16M
  }
1184
1185
4.02M
  if (need_above_left) {
1186
4.02M
    if (n_top_px > 0 && n_left_px > 0) {
1187
3.87M
      above_row[-1] = above_ref[-1];
1188
3.87M
    } else if (n_top_px > 0) {
1189
54.5k
      above_row[-1] = above_ref[0];
1190
101k
    } else if (n_left_px > 0) {
1191
89.1k
      above_row[-1] = left_ref[0];
1192
89.1k
    } else {
1193
12.0k
      above_row[-1] = 128;
1194
12.0k
    }
1195
4.02M
    left_col[-1] = above_row[-1];
1196
4.02M
  }
1197
1198
4.02M
  if (use_filter_intra) {
1199
543k
    av1_filter_intra_predictor(dst, dst_stride, tx_size, above_row, left_col,
1200
543k
                               filter_intra_mode);
1201
543k
    return;
1202
543k
  }
1203
1204
4.02M
  assert(is_dr_mode);
1205
3.48M
  int upsample_above = 0;
1206
3.48M
  int upsample_left = 0;
1207
3.48M
  if (!disable_edge_filter) {
1208
3.31M
    const int need_right = p_angle < 90;
1209
3.31M
    const int need_bottom = p_angle > 180;
1210
3.31M
    if (p_angle != 90 && p_angle != 180) {
1211
1.77M
      assert(need_above_left);
1212
1.77M
      const int ab_le = 1;
1213
1.77M
      if (need_above && need_left && (txwpx + txhpx >= 24)) {
1214
353k
        filter_intra_edge_corner(above_row, left_col);
1215
353k
      }
1216
1.77M
      if (need_above && n_top_px > 0) {
1217
1.16M
        const int strength = intra_edge_filter_strength(
1218
1.16M
            txwpx, txhpx, p_angle - 90, intra_edge_filter_type);
1219
1.16M
        const int n_px = n_top_px + ab_le + (need_right ? txhpx : 0);
1220
1.16M
        av1_filter_intra_edge(above_row - ab_le, n_px, strength);
1221
1.16M
      }
1222
1.77M
      if (need_left && n_left_px > 0) {
1223
1.40M
        const int strength = intra_edge_filter_strength(
1224
1.40M
            txhpx, txwpx, p_angle - 180, intra_edge_filter_type);
1225
1.40M
        const int n_px = n_left_px + ab_le + (need_bottom ? txwpx : 0);
1226
1.40M
        av1_filter_intra_edge(left_col - ab_le, n_px, strength);
1227
1.40M
      }
1228
1.77M
    }
1229
3.31M
    upsample_above = av1_use_intra_edge_upsample(txwpx, txhpx, p_angle - 90,
1230
3.31M
                                                 intra_edge_filter_type);
1231
3.31M
    if (need_above && upsample_above) {
1232
189k
      const int n_px = txwpx + (need_right ? txhpx : 0);
1233
189k
      av1_upsample_intra_edge(above_row, n_px);
1234
189k
    }
1235
3.31M
    upsample_left = av1_use_intra_edge_upsample(txhpx, txwpx, p_angle - 180,
1236
3.31M
                                                intra_edge_filter_type);
1237
3.31M
    if (need_left && upsample_left) {
1238
392k
      const int n_px = txhpx + (need_bottom ? txwpx : 0);
1239
392k
      av1_upsample_intra_edge(left_col, n_px);
1240
392k
    }
1241
3.31M
  }
1242
3.48M
  dr_predictor(dst, dst_stride, tx_size, above_row, left_col, upsample_above,
1243
3.48M
               upsample_left, p_angle);
1244
3.48M
}
1245
1246
// This function generates the pred data of a given block for non-directional
1247
// intra prediction modes (i.e., DC, SMOOTH, SMOOTH_H, SMOOTH_V and PAETH).
1248
static void build_non_directional_intra_predictors(
1249
    const uint8_t *ref, int ref_stride, uint8_t *dst, int dst_stride,
1250
9.79M
    PREDICTION_MODE mode, TX_SIZE tx_size, int n_top_px, int n_left_px) {
1251
9.79M
  const uint8_t *above_ref = ref - ref_stride;
1252
9.79M
  const uint8_t *left_ref = ref - 1;
1253
9.79M
  const int txwpx = tx_size_wide[tx_size];
1254
9.79M
  const int txhpx = tx_size_high[tx_size];
1255
9.79M
  const int need_left = extend_modes[mode] & NEED_LEFT;
1256
9.79M
  const int need_above = extend_modes[mode] & NEED_ABOVE;
1257
9.79M
  const int need_above_left = extend_modes[mode] & NEED_ABOVELEFT;
1258
9.79M
  int i = 0;
1259
9.79M
  assert(n_top_px >= 0);
1260
9.79M
  assert(n_left_px >= 0);
1261
9.79M
  assert(mode == DC_PRED || mode == SMOOTH_PRED || mode == SMOOTH_V_PRED ||
1262
9.79M
         mode == SMOOTH_H_PRED || mode == PAETH_PRED);
1263
1264
9.79M
  if ((!need_above && n_left_px == 0) || (!need_left && n_top_px == 0)) {
1265
0
    int val = 0;
1266
0
    if (need_left) {
1267
0
      val = (n_top_px > 0) ? above_ref[0] : 129;
1268
0
    } else {
1269
0
      val = (n_left_px > 0) ? left_ref[0] : 127;
1270
0
    }
1271
0
    for (i = 0; i < txhpx; ++i) {
1272
0
      memset(dst, val, txwpx);
1273
0
      dst += dst_stride;
1274
0
    }
1275
0
    return;
1276
0
  }
1277
1278
9.79M
  DECLARE_ALIGNED(16, uint8_t, left_data[NUM_INTRA_NEIGHBOUR_PIXELS]);
1279
9.79M
  DECLARE_ALIGNED(16, uint8_t, above_data[NUM_INTRA_NEIGHBOUR_PIXELS]);
1280
9.79M
  uint8_t *const above_row = above_data + 16;
1281
9.79M
  uint8_t *const left_col = left_data + 16;
1282
1283
9.79M
  if (need_left) {
1284
9.79M
    memset(left_data, 129, NUM_INTRA_NEIGHBOUR_PIXELS);
1285
9.79M
    if (n_left_px > 0) {
1286
166M
      for (i = 0; i < n_left_px; i++) left_col[i] = left_ref[i * ref_stride];
1287
9.36M
      if (i < txhpx) memset(&left_col[i], left_col[i - 1], txhpx - i);
1288
9.36M
    } else if (n_top_px > 0) {
1289
346k
      memset(left_col, above_ref[0], txhpx);
1290
346k
    }
1291
9.79M
  }
1292
1293
9.79M
  if (need_above) {
1294
9.79M
    memset(above_data, 127, NUM_INTRA_NEIGHBOUR_PIXELS);
1295
9.79M
    if (n_top_px > 0) {
1296
9.34M
      memcpy(above_row, above_ref, n_top_px);
1297
9.34M
      i = n_top_px;
1298
9.34M
      if (i < txwpx) memset(&above_row[i], above_row[i - 1], txwpx - i);
1299
9.34M
    } else if (n_left_px > 0) {
1300
372k
      memset(above_row, left_ref[0], txwpx);
1301
372k
    }
1302
9.79M
  }
1303
1304
9.79M
  if (need_above_left) {
1305
2.15M
    if (n_top_px > 0 && n_left_px > 0) {
1306
1.98M
      above_row[-1] = above_ref[-1];
1307
1.98M
    } else if (n_top_px > 0) {
1308
119k
      above_row[-1] = above_ref[0];
1309
119k
    } else if (n_left_px > 0) {
1310
49.9k
      above_row[-1] = left_ref[0];
1311
49.9k
    } else {
1312
2.16k
      above_row[-1] = 128;
1313
2.16k
    }
1314
2.15M
    left_col[-1] = above_row[-1];
1315
2.15M
  }
1316
1317
9.79M
  if (mode == DC_PRED) {
1318
6.20M
    dc_pred[n_left_px > 0][n_top_px > 0][tx_size](dst, dst_stride, above_row,
1319
6.20M
                                                  left_col);
1320
6.20M
  } else {
1321
3.58M
    pred[mode][tx_size](dst, dst_stride, above_row, left_col);
1322
3.58M
  }
1323
9.79M
}
1324
1325
#if CONFIG_AV1_HIGHBITDEPTH
1326
0
void av1_highbd_filter_intra_edge_c(uint16_t *p, int sz, int strength) {
1327
0
  if (!strength) return;
1328
1329
0
  const int kernel[INTRA_EDGE_FILT][INTRA_EDGE_TAPS] = { { 0, 4, 8, 4, 0 },
1330
0
                                                         { 0, 5, 6, 5, 0 },
1331
0
                                                         { 2, 4, 4, 4, 2 } };
1332
0
  const int filt = strength - 1;
1333
0
  uint16_t edge[129];
1334
1335
0
  memcpy(edge, p, sz * sizeof(*p));
1336
0
  for (int i = 1; i < sz; i++) {
1337
0
    int s = 0;
1338
0
    for (int j = 0; j < INTRA_EDGE_TAPS; j++) {
1339
0
      int k = i - 2 + j;
1340
0
      k = (k < 0) ? 0 : k;
1341
0
      k = (k > sz - 1) ? sz - 1 : k;
1342
0
      s += edge[k] * kernel[filt][j];
1343
0
    }
1344
0
    s = (s + 8) >> 4;
1345
0
    p[i] = s;
1346
0
  }
1347
0
}
1348
1349
static void highbd_filter_intra_edge_corner(uint16_t *p_above,
1350
416k
                                            uint16_t *p_left) {
1351
416k
  const int kernel[3] = { 5, 6, 5 };
1352
1353
416k
  int s = (p_left[0] * kernel[0]) + (p_above[-1] * kernel[1]) +
1354
416k
          (p_above[0] * kernel[2]);
1355
416k
  s = (s + 8) >> 4;
1356
416k
  p_above[-1] = s;
1357
416k
  p_left[-1] = s;
1358
416k
}
1359
1360
0
void av1_highbd_upsample_intra_edge_c(uint16_t *p, int sz, int bd) {
1361
  // interpolate half-sample positions
1362
0
  assert(sz <= MAX_UPSAMPLE_SZ);
1363
1364
0
  uint16_t in[MAX_UPSAMPLE_SZ + 3];
1365
  // copy p[-1..(sz-1)] and extend first and last samples
1366
0
  in[0] = p[-1];
1367
0
  in[1] = p[-1];
1368
0
  for (int i = 0; i < sz; i++) {
1369
0
    in[i + 2] = p[i];
1370
0
  }
1371
0
  in[sz + 2] = p[sz - 1];
1372
1373
  // interpolate half-sample edge positions
1374
0
  p[-2] = in[0];
1375
0
  for (int i = 0; i < sz; i++) {
1376
0
    int s = -in[i] + (9 * in[i + 1]) + (9 * in[i + 2]) - in[i + 3];
1377
0
    s = (s + 8) >> 4;
1378
0
    s = clip_pixel_highbd(s, bd);
1379
0
    p[2 * i - 1] = s;
1380
0
    p[2 * i] = in[i + 2];
1381
0
  }
1382
0
}
1383
1384
static void highbd_build_directional_and_filter_intra_predictors(
1385
    const uint8_t *ref8, int ref_stride, uint8_t *dst8, int dst_stride,
1386
    PREDICTION_MODE mode, int p_angle, FILTER_INTRA_MODE filter_intra_mode,
1387
    TX_SIZE tx_size, int disable_edge_filter, int n_top_px, int n_topright_px,
1388
    int n_left_px, int n_bottomleft_px, int intra_edge_filter_type,
1389
6.08M
    int bit_depth) {
1390
6.08M
  int i;
1391
6.08M
  uint16_t *dst = CONVERT_TO_SHORTPTR(dst8);
1392
6.08M
  const uint16_t *const ref = CONVERT_TO_SHORTPTR(ref8);
1393
6.08M
  DECLARE_ALIGNED(16, uint16_t, left_data[NUM_INTRA_NEIGHBOUR_PIXELS]);
1394
6.08M
  DECLARE_ALIGNED(16, uint16_t, above_data[NUM_INTRA_NEIGHBOUR_PIXELS]);
1395
6.08M
  uint16_t *const above_row = above_data + 16;
1396
6.08M
  uint16_t *const left_col = left_data + 16;
1397
6.08M
  const int txwpx = tx_size_wide[tx_size];
1398
6.08M
  const int txhpx = tx_size_high[tx_size];
1399
6.08M
  int need_left = extend_modes[mode] & NEED_LEFT;
1400
6.08M
  int need_above = extend_modes[mode] & NEED_ABOVE;
1401
6.08M
  int need_above_left = extend_modes[mode] & NEED_ABOVELEFT;
1402
6.08M
  const uint16_t *above_ref = ref - ref_stride;
1403
6.08M
  const uint16_t *left_ref = ref - 1;
1404
6.08M
  const int is_dr_mode = av1_is_directional_mode(mode);
1405
6.08M
  const int use_filter_intra = filter_intra_mode != FILTER_INTRA_MODES;
1406
6.08M
  assert(use_filter_intra || is_dr_mode);
1407
6.08M
  const int base = 128 << (bit_depth - 8);
1408
  // The left_data, above_data buffers must be zeroed to fix some intermittent
1409
  // valgrind errors. Uninitialized reads in intra pred modules (e.g. width = 4
1410
  // path in av1_highbd_dr_prediction_z2_avx2()) from left_data, above_data are
1411
  // seen to be the potential reason for this issue.
1412
6.08M
  aom_memset16(left_data, base + 1, NUM_INTRA_NEIGHBOUR_PIXELS);
1413
6.08M
  aom_memset16(above_data, base - 1, NUM_INTRA_NEIGHBOUR_PIXELS);
1414
1415
  // The default values if ref pixels are not available:
1416
  // base   base-1 base-1 .. base-1 base-1 base-1 base-1 base-1 base-1
1417
  // base+1   A      B  ..     Y      Z
1418
  // base+1   C      D  ..     W      X
1419
  // base+1   E      F  ..     U      V
1420
  // base+1   G      H  ..     S      T      T      T      T      T
1421
1422
6.08M
  if (is_dr_mode) {
1423
5.35M
    if (p_angle <= 90)
1424
1.18M
      need_above = 1, need_left = 0, need_above_left = 1;
1425
4.16M
    else if (p_angle < 180)
1426
1.17M
      need_above = 1, need_left = 1, need_above_left = 1;
1427
2.99M
    else
1428
2.99M
      need_above = 0, need_left = 1, need_above_left = 1;
1429
5.35M
  }
1430
6.08M
  if (use_filter_intra) need_left = need_above = need_above_left = 1;
1431
1432
6.08M
  assert(n_top_px >= 0);
1433
6.09M
  assert(n_topright_px >= -1);
1434
6.09M
  assert(n_left_px >= 0);
1435
6.09M
  assert(n_bottomleft_px >= -1);
1436
1437
6.10M
  if ((!need_above && n_left_px == 0) || (!need_left && n_top_px == 0)) {
1438
150k
    int val;
1439
150k
    if (need_left) {
1440
117k
      val = (n_top_px > 0) ? above_ref[0] : base + 1;
1441
117k
    } else {
1442
33.1k
      val = (n_left_px > 0) ? left_ref[0] : base - 1;
1443
33.1k
    }
1444
3.13M
    for (i = 0; i < txhpx; ++i) {
1445
2.98M
      aom_memset16(dst, val, txwpx);
1446
2.98M
      dst += dst_stride;
1447
2.98M
    }
1448
150k
    return;
1449
150k
  }
1450
1451
  // NEED_LEFT
1452
5.94M
  if (need_left) {
1453
4.80M
    const int num_left_pixels_needed =
1454
4.80M
        txhpx + (n_bottomleft_px >= 0 ? txwpx : 0);
1455
4.80M
    i = 0;
1456
4.80M
    if (n_left_px > 0) {
1457
64.1M
      for (; i < n_left_px; i++) left_col[i] = left_ref[i * ref_stride];
1458
4.76M
      if (n_bottomleft_px > 0) {
1459
367k
        assert(i == txhpx);
1460
4.27M
        for (; i < txhpx + n_bottomleft_px; i++)
1461
3.91M
          left_col[i] = left_ref[i * ref_stride];
1462
367k
      }
1463
4.76M
      if (i < num_left_pixels_needed)
1464
807k
        aom_memset16(&left_col[i], left_col[i - 1], num_left_pixels_needed - i);
1465
4.76M
    } else if (n_top_px > 0) {
1466
31.5k
      aom_memset16(left_col, above_ref[0], num_left_pixels_needed);
1467
31.5k
    }
1468
4.80M
  }
1469
1470
  // NEED_ABOVE
1471
5.94M
  if (need_above) {
1472
3.06M
    const int num_top_pixels_needed = txwpx + (n_topright_px >= 0 ? txhpx : 0);
1473
3.06M
    if (n_top_px > 0) {
1474
3.02M
      memcpy(above_row, above_ref, n_top_px * sizeof(above_ref[0]));
1475
3.02M
      i = n_top_px;
1476
3.02M
      if (n_topright_px > 0) {
1477
356k
        assert(n_top_px == txwpx);
1478
356k
        memcpy(above_row + txwpx, above_ref + txwpx,
1479
356k
               n_topright_px * sizeof(above_ref[0]));
1480
356k
        i += n_topright_px;
1481
356k
      }
1482
3.02M
      if (i < num_top_pixels_needed)
1483
362k
        aom_memset16(&above_row[i], above_row[i - 1],
1484
362k
                     num_top_pixels_needed - i);
1485
3.02M
    } else if (n_left_px > 0) {
1486
36.9k
      aom_memset16(above_row, left_ref[0], num_top_pixels_needed);
1487
36.9k
    }
1488
3.06M
  }
1489
1490
5.94M
  if (need_above_left) {
1491
5.94M
    if (n_top_px > 0 && n_left_px > 0) {
1492
5.75M
      above_row[-1] = above_ref[-1];
1493
5.75M
    } else if (n_top_px > 0) {
1494
58.5k
      above_row[-1] = above_ref[0];
1495
131k
    } else if (n_left_px > 0) {
1496
125k
      above_row[-1] = left_ref[0];
1497
125k
    } else {
1498
5.36k
      above_row[-1] = base;
1499
5.36k
    }
1500
5.94M
    left_col[-1] = above_row[-1];
1501
5.94M
  }
1502
1503
5.94M
  if (use_filter_intra) {
1504
746k
    highbd_filter_intra_predictor(dst, dst_stride, tx_size, above_row, left_col,
1505
746k
                                  filter_intra_mode, bit_depth);
1506
746k
    return;
1507
746k
  }
1508
1509
5.94M
  assert(is_dr_mode);
1510
5.20M
  int upsample_above = 0;
1511
5.20M
  int upsample_left = 0;
1512
5.20M
  if (!disable_edge_filter) {
1513
4.44M
    const int need_right = p_angle < 90;
1514
4.44M
    const int need_bottom = p_angle > 180;
1515
4.44M
    if (p_angle != 90 && p_angle != 180) {
1516
2.16M
      assert(need_above_left);
1517
2.16M
      const int ab_le = 1;
1518
2.16M
      if (need_above && need_left && (txwpx + txhpx >= 24)) {
1519
416k
        highbd_filter_intra_edge_corner(above_row, left_col);
1520
416k
      }
1521
2.16M
      if (need_above && n_top_px > 0) {
1522
1.35M
        const int strength = intra_edge_filter_strength(
1523
1.35M
            txwpx, txhpx, p_angle - 90, intra_edge_filter_type);
1524
1.35M
        const int n_px = n_top_px + ab_le + (need_right ? txhpx : 0);
1525
1.35M
        av1_highbd_filter_intra_edge(above_row - ab_le, n_px, strength);
1526
1.35M
      }
1527
2.16M
      if (need_left && n_left_px > 0) {
1528
1.68M
        const int strength = intra_edge_filter_strength(
1529
1.68M
            txhpx, txwpx, p_angle - 180, intra_edge_filter_type);
1530
1.68M
        const int n_px = n_left_px + ab_le + (need_bottom ? txwpx : 0);
1531
1.68M
        av1_highbd_filter_intra_edge(left_col - ab_le, n_px, strength);
1532
1.68M
      }
1533
2.16M
    }
1534
4.44M
    upsample_above = av1_use_intra_edge_upsample(txwpx, txhpx, p_angle - 90,
1535
4.44M
                                                 intra_edge_filter_type);
1536
4.44M
    if (need_above && upsample_above) {
1537
260k
      const int n_px = txwpx + (need_right ? txhpx : 0);
1538
260k
      av1_highbd_upsample_intra_edge(above_row, n_px, bit_depth);
1539
260k
    }
1540
4.44M
    upsample_left = av1_use_intra_edge_upsample(txhpx, txwpx, p_angle - 180,
1541
4.44M
                                                intra_edge_filter_type);
1542
4.44M
    if (need_left && upsample_left) {
1543
433k
      const int n_px = txhpx + (need_bottom ? txwpx : 0);
1544
433k
      av1_highbd_upsample_intra_edge(left_col, n_px, bit_depth);
1545
433k
    }
1546
4.44M
  }
1547
5.20M
  highbd_dr_predictor(dst, dst_stride, tx_size, above_row, left_col,
1548
5.20M
                      upsample_above, upsample_left, p_angle, bit_depth);
1549
5.20M
}
1550
1551
// For HBD encode/decode, this function generates the pred data of a given
1552
// block for non-directional intra prediction modes (i.e., DC, SMOOTH, SMOOTH_H,
1553
// SMOOTH_V and PAETH).
1554
static void highbd_build_non_directional_intra_predictors(
1555
    const uint8_t *ref8, int ref_stride, uint8_t *dst8, int dst_stride,
1556
    PREDICTION_MODE mode, TX_SIZE tx_size, int n_top_px, int n_left_px,
1557
68.7M
    int bit_depth) {
1558
68.7M
  int i = 0;
1559
68.7M
  uint16_t *dst = CONVERT_TO_SHORTPTR(dst8);
1560
68.7M
  const uint16_t *const ref = CONVERT_TO_SHORTPTR(ref8);
1561
68.7M
  const int txwpx = tx_size_wide[tx_size];
1562
68.7M
  const int txhpx = tx_size_high[tx_size];
1563
68.7M
  int need_left = extend_modes[mode] & NEED_LEFT;
1564
68.7M
  int need_above = extend_modes[mode] & NEED_ABOVE;
1565
68.7M
  int need_above_left = extend_modes[mode] & NEED_ABOVELEFT;
1566
68.7M
  const uint16_t *above_ref = ref - ref_stride;
1567
68.7M
  const uint16_t *left_ref = ref - 1;
1568
68.7M
  const int base = 128 << (bit_depth - 8);
1569
1570
68.7M
  assert(n_top_px >= 0);
1571
68.7M
  assert(n_left_px >= 0);
1572
68.7M
  assert(mode == DC_PRED || mode == SMOOTH_PRED || mode == SMOOTH_V_PRED ||
1573
68.7M
         mode == SMOOTH_H_PRED || mode == PAETH_PRED);
1574
1575
68.7M
  if ((!need_above && n_left_px == 0) || (!need_left && n_top_px == 0)) {
1576
0
    int val = 0;
1577
0
    if (need_left) {
1578
0
      val = (n_top_px > 0) ? above_ref[0] : base + 1;
1579
0
    } else {
1580
0
      val = (n_left_px > 0) ? left_ref[0] : base - 1;
1581
0
    }
1582
0
    for (i = 0; i < txhpx; ++i) {
1583
0
      aom_memset16(dst, val, txwpx);
1584
0
      dst += dst_stride;
1585
0
    }
1586
0
    return;
1587
0
  }
1588
1589
68.7M
  DECLARE_ALIGNED(16, uint16_t, left_data[NUM_INTRA_NEIGHBOUR_PIXELS]);
1590
68.7M
  DECLARE_ALIGNED(16, uint16_t, above_data[NUM_INTRA_NEIGHBOUR_PIXELS]);
1591
68.7M
  uint16_t *const above_row = above_data + 16;
1592
68.7M
  uint16_t *const left_col = left_data + 16;
1593
1594
68.7M
  if (need_left) {
1595
68.7M
    aom_memset16(left_data, base + 1, NUM_INTRA_NEIGHBOUR_PIXELS);
1596
68.7M
    if (n_left_px > 0) {
1597
471M
      for (i = 0; i < n_left_px; i++) left_col[i] = left_ref[i * ref_stride];
1598
67.3M
      if (i < txhpx) aom_memset16(&left_col[i], left_col[i - 1], txhpx - i);
1599
67.3M
    } else if (n_top_px > 0) {
1600
1.31M
      aom_memset16(left_col, above_ref[0], txhpx);
1601
1.31M
    }
1602
68.7M
  }
1603
1604
68.7M
  if (need_above) {
1605
68.7M
    aom_memset16(above_data, base - 1, NUM_INTRA_NEIGHBOUR_PIXELS);
1606
68.7M
    if (n_top_px > 0) {
1607
68.3M
      memcpy(above_row, above_ref, n_top_px * sizeof(above_ref[0]));
1608
68.3M
      i = n_top_px;
1609
68.3M
      if (i < txwpx) aom_memset16(&above_row[i], above_row[i - 1], (txwpx - i));
1610
68.3M
    } else if (n_left_px > 0) {
1611
407k
      aom_memset16(above_row, left_ref[0], txwpx);
1612
407k
    }
1613
68.7M
  }
1614
1615
68.7M
  if (need_above_left) {
1616
2.47M
    if (n_top_px > 0 && n_left_px > 0) {
1617
2.34M
      above_row[-1] = above_ref[-1];
1618
2.34M
    } else if (n_top_px > 0) {
1619
55.1k
      above_row[-1] = above_ref[0];
1620
74.6k
    } else if (n_left_px > 0) {
1621
71.9k
      above_row[-1] = left_ref[0];
1622
71.9k
    } else {
1623
2.70k
      above_row[-1] = base;
1624
2.70k
    }
1625
2.47M
    left_col[-1] = above_row[-1];
1626
2.47M
  }
1627
1628
68.7M
  if (mode == DC_PRED) {
1629
64.2M
    dc_pred_high[n_left_px > 0][n_top_px > 0][tx_size](
1630
64.2M
        dst, dst_stride, above_row, left_col, bit_depth);
1631
64.2M
  } else {
1632
4.55M
    pred_high[mode][tx_size](dst, dst_stride, above_row, left_col, bit_depth);
1633
4.55M
  }
1634
68.7M
}
1635
#endif  // CONFIG_AV1_HIGHBITDEPTH
1636
1637
static inline BLOCK_SIZE scale_chroma_bsize(BLOCK_SIZE bsize, int subsampling_x,
1638
3.23M
                                            int subsampling_y) {
1639
3.23M
  assert(subsampling_x >= 0 && subsampling_x < 2);
1640
3.23M
  assert(subsampling_y >= 0 && subsampling_y < 2);
1641
3.23M
  BLOCK_SIZE bs = bsize;
1642
3.23M
  switch (bsize) {
1643
15.2k
    case BLOCK_4X4:
1644
15.2k
      if (subsampling_x == 1 && subsampling_y == 1)
1645
14.8k
        bs = BLOCK_8X8;
1646
402
      else if (subsampling_x == 1)
1647
402
        bs = BLOCK_8X4;
1648
0
      else if (subsampling_y == 1)
1649
0
        bs = BLOCK_4X8;
1650
15.2k
      break;
1651
31.6k
    case BLOCK_4X8:
1652
31.6k
      if (subsampling_x == 1 && subsampling_y == 1)
1653
31.6k
        bs = BLOCK_8X8;
1654
0
      else if (subsampling_x == 1)
1655
0
        bs = BLOCK_8X8;
1656
0
      else if (subsampling_y == 1)
1657
0
        bs = BLOCK_4X8;
1658
31.6k
      break;
1659
45.5k
    case BLOCK_8X4:
1660
45.5k
      if (subsampling_x == 1 && subsampling_y == 1)
1661
42.1k
        bs = BLOCK_8X8;
1662
3.42k
      else if (subsampling_x == 1)
1663
3.42k
        bs = BLOCK_8X4;
1664
0
      else if (subsampling_y == 1)
1665
0
        bs = BLOCK_8X8;
1666
45.5k
      break;
1667
37.3k
    case BLOCK_4X16:
1668
37.3k
      if (subsampling_x == 1 && subsampling_y == 1)
1669
37.3k
        bs = BLOCK_8X16;
1670
0
      else if (subsampling_x == 1)
1671
0
        bs = BLOCK_8X16;
1672
0
      else if (subsampling_y == 1)
1673
0
        bs = BLOCK_4X16;
1674
37.3k
      break;
1675
66.1k
    case BLOCK_16X4:
1676
66.1k
      if (subsampling_x == 1 && subsampling_y == 1)
1677
64.9k
        bs = BLOCK_16X8;
1678
1.22k
      else if (subsampling_x == 1)
1679
1.22k
        bs = BLOCK_16X4;
1680
0
      else if (subsampling_y == 1)
1681
0
        bs = BLOCK_16X8;
1682
66.1k
      break;
1683
3.03M
    default: break;
1684
3.23M
  }
1685
3.23M
  return bs;
1686
3.23M
}
1687
1688
void av1_predict_intra_block(const MACROBLOCKD *xd, BLOCK_SIZE sb_size,
1689
                             int enable_intra_edge_filter, int wpx, int hpx,
1690
                             TX_SIZE tx_size, PREDICTION_MODE mode,
1691
                             int angle_delta, int use_palette,
1692
                             FILTER_INTRA_MODE filter_intra_mode,
1693
                             const uint8_t *ref, int ref_stride, uint8_t *dst,
1694
                             int dst_stride, int col_off, int row_off,
1695
88.7M
                             int plane) {
1696
88.7M
  const MB_MODE_INFO *const mbmi = xd->mi[0];
1697
88.7M
  const int txwpx = tx_size_wide[tx_size];
1698
88.7M
  const int txhpx = tx_size_high[tx_size];
1699
88.7M
  const int x = col_off << MI_SIZE_LOG2;
1700
88.7M
  const int y = row_off << MI_SIZE_LOG2;
1701
88.7M
  const int is_hbd = is_cur_buf_hbd(xd);
1702
1703
88.7M
  assert(mode < INTRA_MODES);
1704
1705
88.7M
  if (use_palette) {
1706
113k
    int r, c;
1707
113k
    const uint8_t *const map = xd->plane[plane != 0].color_index_map +
1708
113k
                               xd->color_index_map_offset[plane != 0];
1709
113k
    const uint16_t *const palette =
1710
113k
        mbmi->palette_mode_info.palette_colors + plane * PALETTE_MAX_SIZE;
1711
113k
    if (is_hbd) {
1712
44.1k
      uint16_t *dst16 = CONVERT_TO_SHORTPTR(dst);
1713
466k
      for (r = 0; r < txhpx; ++r) {
1714
5.89M
        for (c = 0; c < txwpx; ++c) {
1715
5.47M
          dst16[r * dst_stride + c] = palette[map[(r + y) * wpx + c + x]];
1716
5.47M
        }
1717
422k
      }
1718
69.4k
    } else {
1719
760k
      for (r = 0; r < txhpx; ++r) {
1720
12.4M
        for (c = 0; c < txwpx; ++c) {
1721
11.7M
          dst[r * dst_stride + c] =
1722
11.7M
              (uint8_t)palette[map[(r + y) * wpx + c + x]];
1723
11.7M
        }
1724
690k
      }
1725
69.4k
    }
1726
113k
    return;
1727
113k
  }
1728
1729
88.6M
  const struct macroblockd_plane *const pd = &xd->plane[plane];
1730
88.6M
  const int ss_x = pd->subsampling_x;
1731
88.6M
  const int ss_y = pd->subsampling_y;
1732
88.6M
  const int have_top =
1733
88.6M
      row_off || (ss_y ? xd->chroma_up_available : xd->up_available);
1734
88.6M
  const int have_left =
1735
88.6M
      col_off || (ss_x ? xd->chroma_left_available : xd->left_available);
1736
1737
  // Distance between the right edge of this prediction block to
1738
  // the frame right edge
1739
88.6M
  const int xr = (xd->mb_to_right_edge >> (3 + ss_x)) + wpx - x - txwpx;
1740
  // Distance between the bottom edge of this prediction block to
1741
  // the frame bottom edge
1742
88.6M
  const int yd = (xd->mb_to_bottom_edge >> (3 + ss_y)) + hpx - y - txhpx;
1743
88.6M
  const int use_filter_intra = filter_intra_mode != FILTER_INTRA_MODES;
1744
88.6M
  const int is_dr_mode = av1_is_directional_mode(mode);
1745
1746
  // The computations in this function, as well as in build_intra_predictors(),
1747
  // are generalized for all intra modes. Some of these operations are not
1748
  // required since non-directional intra modes (i.e., DC, SMOOTH, SMOOTH_H,
1749
  // SMOOTH_V, and PAETH) specifically require left and top neighbors. Hence, a
1750
  // separate function build_non_directional_intra_predictors() is introduced
1751
  // for these modes to avoid redundant computations while generating pred data.
1752
1753
88.6M
  const int n_top_px = have_top ? AOMMIN(txwpx, xr + txwpx) : 0;
1754
88.6M
  const int n_left_px = have_left ? AOMMIN(txhpx, yd + txhpx) : 0;
1755
88.6M
  if (!use_filter_intra && !is_dr_mode) {
1756
78.5M
#if CONFIG_AV1_HIGHBITDEPTH
1757
78.5M
    if (is_hbd) {
1758
68.7M
      highbd_build_non_directional_intra_predictors(
1759
68.7M
          ref, ref_stride, dst, dst_stride, mode, tx_size, n_top_px, n_left_px,
1760
68.7M
          xd->bd);
1761
68.7M
      return;
1762
68.7M
    }
1763
9.79M
#endif  // CONFIG_AV1_HIGHBITDEPTH
1764
9.79M
    build_non_directional_intra_predictors(ref, ref_stride, dst, dst_stride,
1765
9.79M
                                           mode, tx_size, n_top_px, n_left_px);
1766
9.79M
    return;
1767
78.5M
  }
1768
1769
10.1M
  const int txw = tx_size_wide_unit[tx_size];
1770
10.1M
  const int txh = tx_size_high_unit[tx_size];
1771
10.1M
  const int mi_row = -xd->mb_to_top_edge >> (3 + MI_SIZE_LOG2);
1772
10.1M
  const int mi_col = -xd->mb_to_left_edge >> (3 + MI_SIZE_LOG2);
1773
10.1M
  const int right_available =
1774
10.1M
      mi_col + ((col_off + txw) << ss_x) < xd->tile.mi_col_end;
1775
10.1M
  const int bottom_available =
1776
10.1M
      (yd > 0) && (mi_row + ((row_off + txh) << ss_y) < xd->tile.mi_row_end);
1777
1778
10.1M
  const PARTITION_TYPE partition = mbmi->partition;
1779
1780
10.1M
  BLOCK_SIZE bsize = mbmi->bsize;
1781
  // force 4x4 chroma component block size.
1782
10.1M
  if (ss_x || ss_y) {
1783
3.23M
    bsize = scale_chroma_bsize(bsize, ss_x, ss_y);
1784
3.23M
  }
1785
1786
10.1M
  int p_angle = 0;
1787
10.1M
  int need_top_right = extend_modes[mode] & NEED_ABOVERIGHT;
1788
10.1M
  int need_bottom_left = extend_modes[mode] & NEED_BOTTOMLEFT;
1789
1790
10.1M
  if (use_filter_intra) {
1791
1.29M
    need_top_right = 0;
1792
1.29M
    need_bottom_left = 0;
1793
1.29M
  }
1794
10.1M
  if (is_dr_mode) {
1795
8.88M
    p_angle = mode_to_angle_map[mode] + angle_delta;
1796
8.88M
    need_top_right = p_angle < 90;
1797
8.88M
    need_bottom_left = p_angle > 180;
1798
8.88M
  }
1799
1800
  // Possible states for have_top_right(TR) and have_bottom_left(BL)
1801
  // -1 : TR and BL are not needed
1802
  //  0 : TR and BL are needed but not available
1803
  // > 0 : TR and BL are needed and pixels are available
1804
10.1M
  const int have_top_right =
1805
10.1M
      need_top_right ? has_top_right(sb_size, bsize, mi_row, mi_col, have_top,
1806
1.04M
                                     right_available, partition, tx_size,
1807
1.04M
                                     row_off, col_off, ss_x, ss_y)
1808
10.1M
                     : -1;
1809
10.1M
  const int have_bottom_left =
1810
10.1M
      need_bottom_left ? has_bottom_left(sb_size, bsize, mi_row, mi_col,
1811
1.67M
                                         bottom_available, have_left, partition,
1812
1.67M
                                         tx_size, row_off, col_off, ss_x, ss_y)
1813
10.1M
                       : -1;
1814
1815
10.1M
  const int disable_edge_filter = !enable_intra_edge_filter;
1816
10.1M
  const int intra_edge_filter_type = get_intra_edge_filter_type(xd, plane);
1817
10.1M
  const int n_topright_px =
1818
10.1M
      have_top_right > 0 ? AOMMIN(txwpx, xr) : have_top_right;
1819
10.1M
  const int n_bottomleft_px =
1820
10.1M
      have_bottom_left > 0 ? AOMMIN(txhpx, yd) : have_bottom_left;
1821
10.1M
#if CONFIG_AV1_HIGHBITDEPTH
1822
10.1M
  if (is_hbd) {
1823
6.08M
    highbd_build_directional_and_filter_intra_predictors(
1824
6.08M
        ref, ref_stride, dst, dst_stride, mode, p_angle, filter_intra_mode,
1825
6.08M
        tx_size, disable_edge_filter, n_top_px, n_topright_px, n_left_px,
1826
6.08M
        n_bottomleft_px, intra_edge_filter_type, xd->bd);
1827
6.08M
    return;
1828
6.08M
  }
1829
4.01M
#endif
1830
4.01M
  build_directional_and_filter_intra_predictors(
1831
4.01M
      ref, ref_stride, dst, dst_stride, mode, p_angle, filter_intra_mode,
1832
4.01M
      tx_size, disable_edge_filter, n_top_px, n_topright_px, n_left_px,
1833
4.01M
      n_bottomleft_px, intra_edge_filter_type);
1834
4.01M
}
1835
1836
void av1_predict_intra_block_facade(const AV1_COMMON *cm, MACROBLOCKD *xd,
1837
                                    int plane, int blk_col, int blk_row,
1838
88.0M
                                    TX_SIZE tx_size) {
1839
88.0M
  const MB_MODE_INFO *const mbmi = xd->mi[0];
1840
88.0M
  struct macroblockd_plane *const pd = &xd->plane[plane];
1841
88.0M
  const int dst_stride = pd->dst.stride;
1842
88.0M
  uint8_t *dst = &pd->dst.buf[(blk_row * dst_stride + blk_col) << MI_SIZE_LOG2];
1843
88.0M
  const PREDICTION_MODE mode =
1844
88.0M
      (plane == AOM_PLANE_Y) ? mbmi->mode : get_uv_mode(mbmi->uv_mode);
1845
88.0M
  const int use_palette = mbmi->palette_mode_info.palette_size[plane != 0] > 0;
1846
88.0M
  const FILTER_INTRA_MODE filter_intra_mode =
1847
88.0M
      (plane == AOM_PLANE_Y && mbmi->filter_intra_mode_info.use_filter_intra)
1848
88.0M
          ? mbmi->filter_intra_mode_info.filter_intra_mode
1849
88.0M
          : FILTER_INTRA_MODES;
1850
88.0M
  const int angle_delta = mbmi->angle_delta[plane != AOM_PLANE_Y] * ANGLE_STEP;
1851
88.0M
  const SequenceHeader *seq_params = cm->seq_params;
1852
1853
88.0M
#if !CONFIG_REALTIME_ONLY || CONFIG_AV1_DECODER
1854
88.0M
  if (plane != AOM_PLANE_Y && mbmi->uv_mode == UV_CFL_PRED) {
1855
#if CONFIG_DEBUG
1856
    assert(is_cfl_allowed(xd));
1857
    const BLOCK_SIZE plane_bsize =
1858
        get_plane_block_size(mbmi->bsize, pd->subsampling_x, pd->subsampling_y);
1859
    (void)plane_bsize;
1860
    assert(plane_bsize < BLOCK_SIZES_ALL);
1861
    if (!xd->lossless[mbmi->segment_id]) {
1862
      assert(blk_col == 0);
1863
      assert(blk_row == 0);
1864
      assert(block_size_wide[plane_bsize] == tx_size_wide[tx_size]);
1865
      assert(block_size_high[plane_bsize] == tx_size_high[tx_size]);
1866
    }
1867
#endif
1868
2.65M
    CFL_CTX *const cfl = &xd->cfl;
1869
2.65M
    CFL_PRED_TYPE pred_plane = get_cfl_pred_type(plane);
1870
2.65M
    if (!cfl->dc_pred_is_cached[pred_plane]) {
1871
2.65M
      av1_predict_intra_block(xd, seq_params->sb_size,
1872
2.65M
                              seq_params->enable_intra_edge_filter, pd->width,
1873
2.65M
                              pd->height, tx_size, mode, angle_delta,
1874
2.65M
                              use_palette, filter_intra_mode, dst, dst_stride,
1875
2.65M
                              dst, dst_stride, blk_col, blk_row, plane);
1876
2.65M
      if (cfl->use_dc_pred_cache) {
1877
0
        cfl_store_dc_pred(xd, dst, pred_plane, tx_size_wide[tx_size]);
1878
0
        cfl->dc_pred_is_cached[pred_plane] = true;
1879
0
      }
1880
2.65M
    } else {
1881
0
      cfl_load_dc_pred(xd, dst, dst_stride, tx_size, pred_plane);
1882
0
    }
1883
2.65M
    av1_cfl_predict_block(xd, dst, dst_stride, tx_size, plane);
1884
2.65M
    return;
1885
2.65M
  }
1886
85.3M
#endif  // !CONFIG_REALTIME_ONLY || CONFIG_AV1_DECODER
1887
85.3M
  av1_predict_intra_block(
1888
85.3M
      xd, seq_params->sb_size, seq_params->enable_intra_edge_filter, pd->width,
1889
85.3M
      pd->height, tx_size, mode, angle_delta, use_palette, filter_intra_mode,
1890
85.3M
      dst, dst_stride, dst, dst_stride, blk_col, blk_row, plane);
1891
85.3M
}
1892
1893
10.8k
void av1_init_intra_predictors(void) {
1894
10.8k
  aom_once(init_intra_predictors_internal);
1895
10.8k
}