Coverage Report

Created: 2026-06-30 06:53

next uncovered line (L), next uncovered region (R), next uncovered branch (B)
/src/aom/av1/common/restoration.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
13
#include <math.h>
14
#include <stddef.h>
15
16
#include "config/aom_config.h"
17
#include "config/aom_scale_rtcd.h"
18
19
#include "aom/internal/aom_codec_internal.h"
20
#include "aom_mem/aom_mem.h"
21
#include "aom_dsp/aom_dsp_common.h"
22
#include "aom_mem/aom_mem.h"
23
#include "aom_ports/mem.h"
24
#include "aom_util/aom_pthread.h"
25
26
#include "av1/common/av1_common_int.h"
27
#include "av1/common/convolve.h"
28
#include "av1/common/enums.h"
29
#include "av1/common/resize.h"
30
#include "av1/common/restoration.h"
31
#include "av1/common/thread_common.h"
32
33
// The 's' values are calculated based on original 'r' and 'e' values in the
34
// spec using GenSgrprojVtable().
35
// Note: Setting r = 0 skips the filter; with corresponding s = -1 (invalid).
36
const sgr_params_type av1_sgr_params[SGRPROJ_PARAMS] = {
37
  { { 2, 1 }, { 140, 3236 } }, { { 2, 1 }, { 112, 2158 } },
38
  { { 2, 1 }, { 93, 1618 } },  { { 2, 1 }, { 80, 1438 } },
39
  { { 2, 1 }, { 70, 1295 } },  { { 2, 1 }, { 58, 1177 } },
40
  { { 2, 1 }, { 47, 1079 } },  { { 2, 1 }, { 37, 996 } },
41
  { { 2, 1 }, { 30, 925 } },   { { 2, 1 }, { 25, 863 } },
42
  { { 0, 1 }, { -1, 2589 } },  { { 0, 1 }, { -1, 1618 } },
43
  { { 0, 1 }, { -1, 1177 } },  { { 0, 1 }, { -1, 925 } },
44
  { { 2, 0 }, { 56, -1 } },    { { 2, 0 }, { 22, -1 } },
45
};
46
47
void av1_get_upsampled_plane_size(const AV1_COMMON *cm, int is_uv, int *plane_w,
48
178k
                                  int *plane_h) {
49
178k
  int ss_x = is_uv && cm->seq_params->subsampling_x;
50
178k
  int ss_y = is_uv && cm->seq_params->subsampling_y;
51
178k
  *plane_w = ROUND_POWER_OF_TWO(cm->superres_upscaled_width, ss_x);
52
178k
  *plane_h = ROUND_POWER_OF_TWO(cm->height, ss_y);
53
178k
}
54
55
// Count horizontal or vertical units in a plane (use a width or height for
56
// plane_size, respectively). We basically want to divide the plane size by the
57
// size of a restoration unit. Rather than rounding up unconditionally as you
58
// might expect, we round to nearest, which models the way a right or bottom
59
// restoration unit can extend to up to 150% its normal width or height.
60
//
61
// The max with 1 is to deal with small frames, which may be smaller than
62
// half of an LR unit in size.
63
172k
int av1_lr_count_units(int unit_size, int plane_size) {
64
172k
  return AOMMAX((plane_size + (unit_size >> 1)) / unit_size, 1);
65
172k
}
66
67
void av1_alloc_restoration_struct(AV1_COMMON *cm, RestorationInfo *rsi,
68
66.3k
                                  int is_uv) {
69
66.3k
  int plane_w, plane_h;
70
66.3k
  av1_get_upsampled_plane_size(cm, is_uv, &plane_w, &plane_h);
71
72
66.3k
  const int unit_size = rsi->restoration_unit_size;
73
66.3k
  const int horz_units = av1_lr_count_units(unit_size, plane_w);
74
66.3k
  const int vert_units = av1_lr_count_units(unit_size, plane_h);
75
76
66.3k
  rsi->num_rest_units = horz_units * vert_units;
77
66.3k
  rsi->horz_units = horz_units;
78
66.3k
  rsi->vert_units = vert_units;
79
80
66.3k
  aom_free(rsi->unit_info);
81
66.3k
  CHECK_MEM_ERROR(cm, rsi->unit_info,
82
66.3k
                  (RestorationUnitInfo *)aom_memalign(
83
66.3k
                      16, sizeof(*rsi->unit_info) * rsi->num_rest_units));
84
66.3k
}
85
86
32.6k
void av1_free_restoration_struct(RestorationInfo *rst_info) {
87
32.6k
  aom_free(rst_info->unit_info);
88
32.6k
  rst_info->unit_info = NULL;
89
32.6k
}
90
91
#if 0
92
// Pair of values for each sgrproj parameter:
93
// Index 0 corresponds to r[0], e[0]
94
// Index 1 corresponds to r[1], e[1]
95
int sgrproj_mtable[SGRPROJ_PARAMS][2];
96
97
static void GenSgrprojVtable(void) {
98
  for (int i = 0; i < SGRPROJ_PARAMS; ++i) {
99
    const sgr_params_type *const params = &av1_sgr_params[i];
100
    for (int j = 0; j < 2; ++j) {
101
      const int e = params->e[j];
102
      const int r = params->r[j];
103
      if (r == 0) {                 // filter is disabled
104
        sgrproj_mtable[i][j] = -1;  // mark invalid
105
      } else {                      // filter is enabled
106
        const int n = (2 * r + 1) * (2 * r + 1);
107
        const int n2e = n * n * e;
108
        assert(n2e != 0);
109
        sgrproj_mtable[i][j] = (((1 << SGRPROJ_MTABLE_BITS) + n2e / 2) / n2e);
110
      }
111
    }
112
  }
113
}
114
#endif
115
116
10.8k
void av1_loop_restoration_precal(void) {
117
#if 0
118
  GenSgrprojVtable();
119
#endif
120
10.8k
}
121
122
static void extend_frame_lowbd(uint8_t *data, int width, int height,
123
                               ptrdiff_t stride, int border_horz,
124
15.5k
                               int border_vert) {
125
15.5k
  uint8_t *data_p;
126
15.5k
  int i;
127
1.94M
  for (i = 0; i < height; ++i) {
128
1.93M
    data_p = data + i * stride;
129
1.93M
    memset(data_p - border_horz, data_p[0], border_horz);
130
1.93M
    memset(data_p + width, data_p[width - 1], border_horz);
131
1.93M
  }
132
15.5k
  data_p = data - border_horz;
133
62.1k
  for (i = -border_vert; i < 0; ++i) {
134
46.5k
    memcpy(data_p + i * stride, data_p, width + 2 * border_horz);
135
46.5k
  }
136
62.1k
  for (i = height; i < height + border_vert; ++i) {
137
46.5k
    memcpy(data_p + i * stride, data_p + (height - 1) * stride,
138
46.5k
           width + 2 * border_horz);
139
46.5k
  }
140
15.5k
}
141
142
#if CONFIG_AV1_HIGHBITDEPTH
143
static void extend_frame_highbd(uint16_t *data, int width, int height,
144
                                ptrdiff_t stride, int border_horz,
145
17.4k
                                int border_vert) {
146
17.4k
  uint16_t *data_p;
147
17.4k
  int i, j;
148
2.36M
  for (i = 0; i < height; ++i) {
149
2.34M
    data_p = data + i * stride;
150
9.39M
    for (j = -border_horz; j < 0; ++j) data_p[j] = data_p[0];
151
9.39M
    for (j = width; j < width + border_horz; ++j) data_p[j] = data_p[width - 1];
152
2.34M
  }
153
17.4k
  data_p = data - border_horz;
154
69.9k
  for (i = -border_vert; i < 0; ++i) {
155
52.4k
    memcpy(data_p + i * stride, data_p,
156
52.4k
           (width + 2 * border_horz) * sizeof(uint16_t));
157
52.4k
  }
158
69.9k
  for (i = height; i < height + border_vert; ++i) {
159
52.4k
    memcpy(data_p + i * stride, data_p + (height - 1) * stride,
160
52.4k
           (width + 2 * border_horz) * sizeof(uint16_t));
161
52.4k
  }
162
17.4k
}
163
164
static void copy_rest_unit_highbd(int width, int height, const uint16_t *src,
165
                                  int src_stride, uint16_t *dst,
166
14.7k
                                  int dst_stride) {
167
1.62M
  for (int i = 0; i < height; ++i)
168
1.61M
    memcpy(dst + i * dst_stride, src + i * src_stride, width * sizeof(*dst));
169
14.7k
}
170
#endif
171
172
void av1_extend_frame(uint8_t *data, int width, int height, int stride,
173
33.0k
                      int border_horz, int border_vert, int highbd) {
174
33.0k
#if CONFIG_AV1_HIGHBITDEPTH
175
33.0k
  if (highbd) {
176
17.4k
    extend_frame_highbd(CONVERT_TO_SHORTPTR(data), width, height, stride,
177
17.4k
                        border_horz, border_vert);
178
17.4k
    return;
179
17.4k
  }
180
15.5k
#endif
181
15.5k
  (void)highbd;
182
15.5k
  extend_frame_lowbd(data, width, height, stride, border_horz, border_vert);
183
15.5k
}
184
185
static void copy_rest_unit_lowbd(int width, int height, const uint8_t *src,
186
19.4k
                                 int src_stride, uint8_t *dst, int dst_stride) {
187
1.66M
  for (int i = 0; i < height; ++i)
188
1.64M
    memcpy(dst + i * dst_stride, src + i * src_stride, width);
189
19.4k
}
190
191
static void copy_rest_unit(int width, int height, const uint8_t *src,
192
                           int src_stride, uint8_t *dst, int dst_stride,
193
34.3k
                           int highbd) {
194
34.3k
#if CONFIG_AV1_HIGHBITDEPTH
195
34.3k
  if (highbd) {
196
14.7k
    copy_rest_unit_highbd(width, height, CONVERT_TO_SHORTPTR(src), src_stride,
197
14.7k
                          CONVERT_TO_SHORTPTR(dst), dst_stride);
198
14.7k
    return;
199
14.7k
  }
200
19.5k
#endif
201
19.5k
  (void)highbd;
202
19.5k
  copy_rest_unit_lowbd(width, height, src, src_stride, dst, dst_stride);
203
19.5k
}
204
205
3.74M
#define REAL_PTR(hbd, d) ((hbd) ? (uint8_t *)CONVERT_TO_SHORTPTR(d) : (d))
206
207
// With striped loop restoration, the filtering for each 64-pixel stripe gets
208
// most of its input from the output of CDEF (stored in data8), but we need to
209
// fill out a border of 3 pixels above/below the stripe according to the
210
// following rules:
211
//
212
// * At the top and bottom of the frame, we copy the outermost row of CDEF
213
//   pixels three times. This extension is done by a call to av1_extend_frame()
214
//   at the start of the loop restoration process, so the value of
215
//   copy_above/copy_below doesn't strictly matter.
216
//
217
// * All other boundaries are stripe boundaries within the frame. In that case,
218
//   we take 2 rows of deblocked pixels and extend them to 3 rows of context.
219
static void get_stripe_boundary_info(const RestorationTileLimits *limits,
220
                                     int plane_w, int plane_h, int ss_y,
221
232k
                                     int *copy_above, int *copy_below) {
222
232k
  (void)plane_w;
223
224
232k
  *copy_above = 1;
225
232k
  *copy_below = 1;
226
227
232k
  const int full_stripe_height = RESTORATION_PROC_UNIT_SIZE >> ss_y;
228
232k
  const int runit_offset = RESTORATION_UNIT_OFFSET >> ss_y;
229
230
232k
  const int first_stripe_in_plane = (limits->v_start == 0);
231
232k
  const int this_stripe_height =
232
232k
      full_stripe_height - (first_stripe_in_plane ? runit_offset : 0);
233
232k
  const int last_stripe_in_plane =
234
232k
      (limits->v_start + this_stripe_height >= plane_h);
235
236
232k
  if (first_stripe_in_plane) *copy_above = 0;
237
232k
  if (last_stripe_in_plane) *copy_below = 0;
238
232k
}
239
240
// Overwrite the border pixels around a processing stripe so that the conditions
241
// listed above get_stripe_boundary_info() are preserved.
242
// We save the pixels which get overwritten into a temporary buffer, so that
243
// they can be restored by restore_processing_stripe_boundary() after we've
244
// processed the stripe.
245
//
246
// limits gives the rectangular limits of the remaining stripes for the current
247
// restoration unit. rsb is the stored stripe boundaries (taken from either
248
// deblock or CDEF output as necessary).
249
static void setup_processing_stripe_boundary(
250
    const RestorationTileLimits *limits, const RestorationStripeBoundaries *rsb,
251
    int rsb_row, int use_highbd, int h, uint8_t *data8, int data_stride,
252
232k
    RestorationLineBuffers *rlbs, int copy_above, int copy_below, int opt) {
253
  // Offsets within the line buffers. The buffer logically starts at column
254
  // -RESTORATION_EXTRA_HORZ so the 1st column (at x0 - RESTORATION_EXTRA_HORZ)
255
  // has column x0 in the buffer.
256
232k
  const int buf_stride = rsb->stripe_boundary_stride;
257
232k
  const int buf_x0_off = limits->h_start;
258
232k
  const int line_width =
259
232k
      (limits->h_end - limits->h_start) + 2 * RESTORATION_EXTRA_HORZ;
260
232k
  const int line_size = line_width << use_highbd;
261
262
232k
  const int data_x0 = limits->h_start - RESTORATION_EXTRA_HORZ;
263
264
  // Replace RESTORATION_BORDER pixels above the top of the stripe
265
  // We expand RESTORATION_CTX_VERT=2 lines from rsb->stripe_boundary_above
266
  // to fill RESTORATION_BORDER=3 lines of above pixels. This is done by
267
  // duplicating the topmost of the 2 lines (see the AOMMAX call when
268
  // calculating src_row, which gets the values 0, 0, 1 for i = -3, -2, -1).
269
232k
  if (!opt) {
270
207k
    if (copy_above) {
271
187k
      uint8_t *data8_tl = data8 + data_x0 + limits->v_start * data_stride;
272
273
750k
      for (int i = -RESTORATION_BORDER; i < 0; ++i) {
274
563k
        const int buf_row = rsb_row + AOMMAX(i + RESTORATION_CTX_VERT, 0);
275
563k
        const int buf_off = buf_x0_off + buf_row * buf_stride;
276
563k
        const uint8_t *buf =
277
563k
            rsb->stripe_boundary_above + (buf_off << use_highbd);
278
563k
        uint8_t *dst8 = data8_tl + i * data_stride;
279
        // Save old pixels, then replace with data from stripe_boundary_above
280
563k
        memcpy(rlbs->tmp_save_above[i + RESTORATION_BORDER],
281
563k
               REAL_PTR(use_highbd, dst8), line_size);
282
563k
        memcpy(REAL_PTR(use_highbd, dst8), buf, line_size);
283
563k
      }
284
187k
    }
285
286
    // Replace RESTORATION_BORDER pixels below the bottom of the stripe.
287
    // The second buffer row is repeated, so src_row gets the values 0, 1, 1
288
    // for i = 0, 1, 2.
289
207k
    if (copy_below) {
290
186k
      const int stripe_end = limits->v_start + h;
291
186k
      uint8_t *data8_bl = data8 + data_x0 + stripe_end * data_stride;
292
293
745k
      for (int i = 0; i < RESTORATION_BORDER; ++i) {
294
558k
        const int buf_row = rsb_row + AOMMIN(i, RESTORATION_CTX_VERT - 1);
295
558k
        const int buf_off = buf_x0_off + buf_row * buf_stride;
296
558k
        const uint8_t *src =
297
558k
            rsb->stripe_boundary_below + (buf_off << use_highbd);
298
299
558k
        uint8_t *dst8 = data8_bl + i * data_stride;
300
        // Save old pixels, then replace with data from stripe_boundary_below
301
558k
        memcpy(rlbs->tmp_save_below[i], REAL_PTR(use_highbd, dst8), line_size);
302
558k
        memcpy(REAL_PTR(use_highbd, dst8), src, line_size);
303
558k
      }
304
186k
    }
305
207k
  } else {
306
24.8k
    if (copy_above) {
307
15.9k
      uint8_t *data8_tl = data8 + data_x0 + limits->v_start * data_stride;
308
309
      // Only save and overwrite i=-RESTORATION_BORDER line.
310
15.9k
      uint8_t *dst8 = data8_tl + (-RESTORATION_BORDER) * data_stride;
311
      // Save old pixels, then replace with data from stripe_boundary_above
312
15.9k
      memcpy(rlbs->tmp_save_above[0], REAL_PTR(use_highbd, dst8), line_size);
313
15.9k
      memcpy(REAL_PTR(use_highbd, dst8),
314
15.9k
             REAL_PTR(use_highbd,
315
15.9k
                      data8_tl + (-RESTORATION_BORDER + 1) * data_stride),
316
15.9k
             line_size);
317
15.9k
    }
318
319
24.8k
    if (copy_below) {
320
15.9k
      const int stripe_end = limits->v_start + h;
321
15.9k
      uint8_t *data8_bl = data8 + data_x0 + stripe_end * data_stride;
322
323
      // Only save and overwrite i=2 line.
324
15.9k
      uint8_t *dst8 = data8_bl + 2 * data_stride;
325
      // Save old pixels, then replace with data from stripe_boundary_below
326
15.9k
      memcpy(rlbs->tmp_save_below[2], REAL_PTR(use_highbd, dst8), line_size);
327
15.9k
      memcpy(REAL_PTR(use_highbd, dst8),
328
15.9k
             REAL_PTR(use_highbd, data8_bl + (2 - 1) * data_stride), line_size);
329
15.9k
    }
330
24.8k
  }
331
232k
}
332
333
// Once a processing stripe is finished, this function sets the boundary
334
// pixels which were overwritten by setup_processing_stripe_boundary()
335
// back to their original values
336
static void restore_processing_stripe_boundary(
337
    const RestorationTileLimits *limits, const RestorationLineBuffers *rlbs,
338
    int use_highbd, int h, uint8_t *data8, int data_stride, int copy_above,
339
230k
    int copy_below, int opt) {
340
230k
  const int line_width =
341
230k
      (limits->h_end - limits->h_start) + 2 * RESTORATION_EXTRA_HORZ;
342
230k
  const int line_size = line_width << use_highbd;
343
344
230k
  const int data_x0 = limits->h_start - RESTORATION_EXTRA_HORZ;
345
346
230k
  if (!opt) {
347
205k
    if (copy_above) {
348
185k
      uint8_t *data8_tl = data8 + data_x0 + limits->v_start * data_stride;
349
743k
      for (int i = -RESTORATION_BORDER; i < 0; ++i) {
350
557k
        uint8_t *dst8 = data8_tl + i * data_stride;
351
557k
        memcpy(REAL_PTR(use_highbd, dst8),
352
557k
               rlbs->tmp_save_above[i + RESTORATION_BORDER], line_size);
353
557k
      }
354
185k
    }
355
356
205k
    if (copy_below) {
357
186k
      const int stripe_bottom = limits->v_start + h;
358
186k
      uint8_t *data8_bl = data8 + data_x0 + stripe_bottom * data_stride;
359
360
745k
      for (int i = 0; i < RESTORATION_BORDER; ++i) {
361
558k
        if (stripe_bottom + i >= limits->v_end + RESTORATION_BORDER) break;
362
363
558k
        uint8_t *dst8 = data8_bl + i * data_stride;
364
558k
        memcpy(REAL_PTR(use_highbd, dst8), rlbs->tmp_save_below[i], line_size);
365
558k
      }
366
186k
    }
367
205k
  } else {
368
24.7k
    if (copy_above) {
369
15.8k
      uint8_t *data8_tl = data8 + data_x0 + limits->v_start * data_stride;
370
371
      // Only restore i=-RESTORATION_BORDER line.
372
15.8k
      uint8_t *dst8 = data8_tl + (-RESTORATION_BORDER) * data_stride;
373
15.8k
      memcpy(REAL_PTR(use_highbd, dst8), rlbs->tmp_save_above[0], line_size);
374
15.8k
    }
375
376
24.7k
    if (copy_below) {
377
15.8k
      const int stripe_bottom = limits->v_start + h;
378
15.8k
      uint8_t *data8_bl = data8 + data_x0 + stripe_bottom * data_stride;
379
380
      // Only restore i=2 line.
381
15.8k
      if (stripe_bottom + 2 < limits->v_end + RESTORATION_BORDER) {
382
15.8k
        uint8_t *dst8 = data8_bl + 2 * data_stride;
383
15.8k
        memcpy(REAL_PTR(use_highbd, dst8), rlbs->tmp_save_below[2], line_size);
384
15.8k
      }
385
15.8k
    }
386
24.7k
  }
387
230k
}
388
389
static void wiener_filter_stripe(const RestorationUnitInfo *rui,
390
                                 int stripe_width, int stripe_height,
391
                                 int procunit_width, const uint8_t *src,
392
                                 int src_stride, uint8_t *dst, int dst_stride,
393
                                 int32_t *tmpbuf, int bit_depth,
394
36.0k
                                 struct aom_internal_error_info *error_info) {
395
36.0k
  (void)tmpbuf;
396
36.0k
  (void)bit_depth;
397
36.0k
  (void)error_info;
398
36.0k
  assert(bit_depth == 8);
399
36.0k
  const WienerConvolveParams conv_params = get_conv_params_wiener(8);
400
401
269k
  for (int j = 0; j < stripe_width; j += procunit_width) {
402
233k
    int w = AOMMIN(procunit_width, (stripe_width - j + 15) & ~15);
403
233k
    const uint8_t *src_p = src + j;
404
233k
    uint8_t *dst_p = dst + j;
405
233k
    av1_wiener_convolve_add_src(
406
233k
        src_p, src_stride, dst_p, dst_stride, rui->wiener_info.hfilter, 16,
407
233k
        rui->wiener_info.vfilter, 16, w, stripe_height, &conv_params);
408
233k
  }
409
36.0k
}
410
411
/* Calculate windowed sums (if sqr=0) or sums of squares (if sqr=1)
412
   over the input. The window is of size (2r + 1)x(2r + 1), and we
413
   specialize to r = 1, 2, 3. A default function is used for r > 3.
414
415
   Each loop follows the same format: We keep a window's worth of input
416
   in individual variables and select data out of that as appropriate.
417
*/
418
static void boxsum1(int32_t *src, int width, int height, int src_stride,
419
0
                    int sqr, int32_t *dst, int dst_stride) {
420
0
  int i, j, a, b, c;
421
0
  assert(width > 2 * SGRPROJ_BORDER_HORZ);
422
0
  assert(height > 2 * SGRPROJ_BORDER_VERT);
423
424
  // Vertical sum over 3-pixel regions, from src into dst.
425
0
  if (!sqr) {
426
0
    for (j = 0; j < width; ++j) {
427
0
      a = src[j];
428
0
      b = src[src_stride + j];
429
0
      c = src[2 * src_stride + j];
430
431
0
      dst[j] = a + b;
432
0
      for (i = 1; i < height - 2; ++i) {
433
        // Loop invariant: At the start of each iteration,
434
        // a = src[(i - 1) * src_stride + j]
435
        // b = src[(i    ) * src_stride + j]
436
        // c = src[(i + 1) * src_stride + j]
437
0
        dst[i * dst_stride + j] = a + b + c;
438
0
        a = b;
439
0
        b = c;
440
0
        c = src[(i + 2) * src_stride + j];
441
0
      }
442
0
      dst[i * dst_stride + j] = a + b + c;
443
0
      dst[(i + 1) * dst_stride + j] = b + c;
444
0
    }
445
0
  } else {
446
0
    for (j = 0; j < width; ++j) {
447
0
      a = src[j] * src[j];
448
0
      b = src[src_stride + j] * src[src_stride + j];
449
0
      c = src[2 * src_stride + j] * src[2 * src_stride + j];
450
451
0
      dst[j] = a + b;
452
0
      for (i = 1; i < height - 2; ++i) {
453
0
        dst[i * dst_stride + j] = a + b + c;
454
0
        a = b;
455
0
        b = c;
456
0
        c = src[(i + 2) * src_stride + j] * src[(i + 2) * src_stride + j];
457
0
      }
458
0
      dst[i * dst_stride + j] = a + b + c;
459
0
      dst[(i + 1) * dst_stride + j] = b + c;
460
0
    }
461
0
  }
462
463
  // Horizontal sum over 3-pixel regions of dst
464
0
  for (i = 0; i < height; ++i) {
465
0
    a = dst[i * dst_stride];
466
0
    b = dst[i * dst_stride + 1];
467
0
    c = dst[i * dst_stride + 2];
468
469
0
    dst[i * dst_stride] = a + b;
470
0
    for (j = 1; j < width - 2; ++j) {
471
      // Loop invariant: At the start of each iteration,
472
      // a = src[i * src_stride + (j - 1)]
473
      // b = src[i * src_stride + (j    )]
474
      // c = src[i * src_stride + (j + 1)]
475
0
      dst[i * dst_stride + j] = a + b + c;
476
0
      a = b;
477
0
      b = c;
478
0
      c = dst[i * dst_stride + (j + 2)];
479
0
    }
480
0
    dst[i * dst_stride + j] = a + b + c;
481
0
    dst[i * dst_stride + (j + 1)] = b + c;
482
0
  }
483
0
}
484
485
static void boxsum2(int32_t *src, int width, int height, int src_stride,
486
0
                    int sqr, int32_t *dst, int dst_stride) {
487
0
  int i, j, a, b, c, d, e;
488
0
  assert(width > 2 * SGRPROJ_BORDER_HORZ);
489
0
  assert(height > 2 * SGRPROJ_BORDER_VERT);
490
491
  // Vertical sum over 5-pixel regions, from src into dst.
492
0
  if (!sqr) {
493
0
    for (j = 0; j < width; ++j) {
494
0
      a = src[j];
495
0
      b = src[src_stride + j];
496
0
      c = src[2 * src_stride + j];
497
0
      d = src[3 * src_stride + j];
498
0
      e = src[4 * src_stride + j];
499
500
0
      dst[j] = a + b + c;
501
0
      dst[dst_stride + j] = a + b + c + d;
502
0
      for (i = 2; i < height - 3; ++i) {
503
        // Loop invariant: At the start of each iteration,
504
        // a = src[(i - 2) * src_stride + j]
505
        // b = src[(i - 1) * src_stride + j]
506
        // c = src[(i    ) * src_stride + j]
507
        // d = src[(i + 1) * src_stride + j]
508
        // e = src[(i + 2) * src_stride + j]
509
0
        dst[i * dst_stride + j] = a + b + c + d + e;
510
0
        a = b;
511
0
        b = c;
512
0
        c = d;
513
0
        d = e;
514
0
        e = src[(i + 3) * src_stride + j];
515
0
      }
516
0
      dst[i * dst_stride + j] = a + b + c + d + e;
517
0
      dst[(i + 1) * dst_stride + j] = b + c + d + e;
518
0
      dst[(i + 2) * dst_stride + j] = c + d + e;
519
0
    }
520
0
  } else {
521
0
    for (j = 0; j < width; ++j) {
522
0
      a = src[j] * src[j];
523
0
      b = src[src_stride + j] * src[src_stride + j];
524
0
      c = src[2 * src_stride + j] * src[2 * src_stride + j];
525
0
      d = src[3 * src_stride + j] * src[3 * src_stride + j];
526
0
      e = src[4 * src_stride + j] * src[4 * src_stride + j];
527
528
0
      dst[j] = a + b + c;
529
0
      dst[dst_stride + j] = a + b + c + d;
530
0
      for (i = 2; i < height - 3; ++i) {
531
0
        dst[i * dst_stride + j] = a + b + c + d + e;
532
0
        a = b;
533
0
        b = c;
534
0
        c = d;
535
0
        d = e;
536
0
        e = src[(i + 3) * src_stride + j] * src[(i + 3) * src_stride + j];
537
0
      }
538
0
      dst[i * dst_stride + j] = a + b + c + d + e;
539
0
      dst[(i + 1) * dst_stride + j] = b + c + d + e;
540
0
      dst[(i + 2) * dst_stride + j] = c + d + e;
541
0
    }
542
0
  }
543
544
  // Horizontal sum over 5-pixel regions of dst
545
0
  for (i = 0; i < height; ++i) {
546
0
    a = dst[i * dst_stride];
547
0
    b = dst[i * dst_stride + 1];
548
0
    c = dst[i * dst_stride + 2];
549
0
    d = dst[i * dst_stride + 3];
550
0
    e = dst[i * dst_stride + 4];
551
552
0
    dst[i * dst_stride] = a + b + c;
553
0
    dst[i * dst_stride + 1] = a + b + c + d;
554
0
    for (j = 2; j < width - 3; ++j) {
555
      // Loop invariant: At the start of each iteration,
556
      // a = src[i * src_stride + (j - 2)]
557
      // b = src[i * src_stride + (j - 1)]
558
      // c = src[i * src_stride + (j    )]
559
      // d = src[i * src_stride + (j + 1)]
560
      // e = src[i * src_stride + (j + 2)]
561
0
      dst[i * dst_stride + j] = a + b + c + d + e;
562
0
      a = b;
563
0
      b = c;
564
0
      c = d;
565
0
      d = e;
566
0
      e = dst[i * dst_stride + (j + 3)];
567
0
    }
568
0
    dst[i * dst_stride + j] = a + b + c + d + e;
569
0
    dst[i * dst_stride + (j + 1)] = b + c + d + e;
570
0
    dst[i * dst_stride + (j + 2)] = c + d + e;
571
0
  }
572
0
}
573
574
static void boxsum(int32_t *src, int width, int height, int src_stride, int r,
575
0
                   int sqr, int32_t *dst, int dst_stride) {
576
0
  if (r == 1)
577
0
    boxsum1(src, width, height, src_stride, sqr, dst, dst_stride);
578
0
  else if (r == 2)
579
0
    boxsum2(src, width, height, src_stride, sqr, dst, dst_stride);
580
0
  else
581
0
    assert(0 && "Invalid value of r in self-guided filter");
582
0
}
583
584
467k
void av1_decode_xq(const int *xqd, int *xq, const sgr_params_type *params) {
585
467k
  if (params->r[0] == 0) {
586
62.0k
    xq[0] = 0;
587
62.0k
    xq[1] = (1 << SGRPROJ_PRJ_BITS) - xqd[1];
588
405k
  } else if (params->r[1] == 0) {
589
18.6k
    xq[0] = xqd[0];
590
18.6k
    xq[1] = 0;
591
387k
  } else {
592
387k
    xq[0] = xqd[0];
593
387k
    xq[1] = (1 << SGRPROJ_PRJ_BITS) - xq[0] - xqd[1];
594
387k
  }
595
467k
}
596
597
const int32_t av1_x_by_xplus1[256] = {
598
  // Special case: Map 0 -> 1 (corresponding to a value of 1/256)
599
  // instead of 0. See comments in selfguided_restoration_internal() for why
600
  1,   128, 171, 192, 205, 213, 219, 224, 228, 230, 233, 235, 236, 238, 239,
601
  240, 241, 242, 243, 243, 244, 244, 245, 245, 246, 246, 247, 247, 247, 247,
602
  248, 248, 248, 248, 249, 249, 249, 249, 249, 250, 250, 250, 250, 250, 250,
603
  250, 251, 251, 251, 251, 251, 251, 251, 251, 251, 251, 252, 252, 252, 252,
604
  252, 252, 252, 252, 252, 252, 252, 252, 252, 252, 252, 252, 252, 253, 253,
605
  253, 253, 253, 253, 253, 253, 253, 253, 253, 253, 253, 253, 253, 253, 253,
606
  253, 253, 253, 253, 253, 253, 253, 253, 253, 253, 253, 253, 254, 254, 254,
607
  254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254,
608
  254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254,
609
  254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254,
610
  254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254,
611
  254, 254, 254, 254, 254, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255,
612
  255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255,
613
  255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255,
614
  255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255,
615
  255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255,
616
  255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255,
617
  256,
618
};
619
620
const int32_t av1_one_by_x[MAX_NELEM] = {
621
  4096, 2048, 1365, 1024, 819, 683, 585, 512, 455, 410, 372, 341, 315,
622
  293,  273,  256,  241,  228, 216, 205, 195, 186, 178, 171, 164,
623
};
624
625
static void calculate_intermediate_result(int32_t *dgd, int width, int height,
626
                                          int dgd_stride, int bit_depth,
627
                                          int sgr_params_idx, int radius_idx,
628
0
                                          int pass, int32_t *A, int32_t *B) {
629
0
  const sgr_params_type *const params = &av1_sgr_params[sgr_params_idx];
630
0
  const int r = params->r[radius_idx];
631
0
  const int width_ext = width + 2 * SGRPROJ_BORDER_HORZ;
632
0
  const int height_ext = height + 2 * SGRPROJ_BORDER_VERT;
633
  // Adjusting the stride of A and B here appears to avoid bad cache effects,
634
  // leading to a significant speed improvement.
635
  // We also align the stride to a multiple of 16 bytes, for consistency
636
  // with the SIMD version of this function.
637
0
  int buf_stride = ((width_ext + 3) & ~3) + 16;
638
0
  const int step = pass == 0 ? 1 : 2;
639
0
  int i, j;
640
641
0
  assert(r <= MAX_RADIUS && "Need MAX_RADIUS >= r");
642
0
  assert(r <= SGRPROJ_BORDER_VERT - 1 && r <= SGRPROJ_BORDER_HORZ - 1 &&
643
0
         "Need SGRPROJ_BORDER_* >= r+1");
644
645
0
  boxsum(dgd - dgd_stride * SGRPROJ_BORDER_VERT - SGRPROJ_BORDER_HORZ,
646
0
         width_ext, height_ext, dgd_stride, r, 0, B, buf_stride);
647
0
  boxsum(dgd - dgd_stride * SGRPROJ_BORDER_VERT - SGRPROJ_BORDER_HORZ,
648
0
         width_ext, height_ext, dgd_stride, r, 1, A, buf_stride);
649
0
  A += SGRPROJ_BORDER_VERT * buf_stride + SGRPROJ_BORDER_HORZ;
650
0
  B += SGRPROJ_BORDER_VERT * buf_stride + SGRPROJ_BORDER_HORZ;
651
  // Calculate the eventual A[] and B[] arrays. Include a 1-pixel border - ie,
652
  // for a 64x64 processing unit, we calculate 66x66 pixels of A[] and B[].
653
0
  for (i = -1; i < height + 1; i += step) {
654
0
    for (j = -1; j < width + 1; ++j) {
655
0
      const int k = i * buf_stride + j;
656
0
      const int n = (2 * r + 1) * (2 * r + 1);
657
658
      // a < 2^16 * n < 2^22 regardless of bit depth
659
0
      uint32_t a = ROUND_POWER_OF_TWO(A[k], 2 * (bit_depth - 8));
660
      // b < 2^8 * n < 2^14 regardless of bit depth
661
0
      uint32_t b = ROUND_POWER_OF_TWO(B[k], bit_depth - 8);
662
663
      // Each term in calculating p = a * n - b * b is < 2^16 * n^2 < 2^28,
664
      // and p itself satisfies p < 2^14 * n^2 < 2^26.
665
      // This bound on p is due to:
666
      // https://en.wikipedia.org/wiki/Popoviciu's_inequality_on_variances
667
      //
668
      // Note: Sometimes, in high bit depth, we can end up with a*n < b*b.
669
      // This is an artefact of rounding, and can only happen if all pixels
670
      // are (almost) identical, so in this case we saturate to p=0.
671
0
      uint32_t p = (a * n < b * b) ? 0 : a * n - b * b;
672
673
0
      const uint32_t s = params->s[radius_idx];
674
675
      // p * s < (2^14 * n^2) * round(2^20 / n^2 eps) < 2^34 / eps < 2^32
676
      // as long as eps >= 4. So p * s fits into a uint32_t, and z < 2^12
677
      // (this holds even after accounting for the rounding in s)
678
0
      const uint32_t z = ROUND_POWER_OF_TWO(p * s, SGRPROJ_MTABLE_BITS);
679
680
      // Note: We have to be quite careful about the value of A[k].
681
      // This is used as a blend factor between individual pixel values and the
682
      // local mean. So it logically has a range of [0, 256], including both
683
      // endpoints.
684
      //
685
      // This is a pain for hardware, as we'd like something which can be stored
686
      // in exactly 8 bits.
687
      // Further, in the calculation of B[k] below, if z == 0 and r == 2,
688
      // then A[k] "should be" 0. But then we can end up setting B[k] to a value
689
      // slightly above 2^(8 + bit depth), due to rounding in the value of
690
      // av1_one_by_x[25-1].
691
      //
692
      // Thus we saturate so that, when z == 0, A[k] is set to 1 instead of 0.
693
      // This fixes the above issues (256 - A[k] fits in a uint8, and we can't
694
      // overflow), without significantly affecting the final result: z == 0
695
      // implies that the image is essentially "flat", so the local mean and
696
      // individual pixel values are very similar.
697
      //
698
      // Note that saturating on the other side, ie. requring A[k] <= 255,
699
      // would be a bad idea, as that corresponds to the case where the image
700
      // is very variable, when we want to preserve the local pixel value as
701
      // much as possible.
702
0
      A[k] = av1_x_by_xplus1[AOMMIN(z, 255)];  // in range [1, 256]
703
704
      // SGRPROJ_SGR - A[k] < 2^8 (from above), B[k] < 2^(bit_depth) * n,
705
      // av1_one_by_x[n - 1] = round(2^12 / n)
706
      // => the product here is < 2^(20 + bit_depth) <= 2^32,
707
      // and B[k] is set to a value < 2^(8 + bit depth)
708
      // This holds even with the rounding in av1_one_by_x and in the overall
709
      // result, as long as SGRPROJ_SGR - A[k] is strictly less than 2^8.
710
0
      B[k] = (int32_t)ROUND_POWER_OF_TWO((uint32_t)(SGRPROJ_SGR - A[k]) *
711
0
                                             (uint32_t)B[k] *
712
0
                                             (uint32_t)av1_one_by_x[n - 1],
713
0
                                         SGRPROJ_RECIP_BITS);
714
0
    }
715
0
  }
716
0
}
717
718
static void selfguided_restoration_fast_internal(
719
    int32_t *dgd, int width, int height, int dgd_stride, int32_t *dst,
720
0
    int dst_stride, int bit_depth, int sgr_params_idx, int radius_idx) {
721
0
  const sgr_params_type *const params = &av1_sgr_params[sgr_params_idx];
722
0
  const int r = params->r[radius_idx];
723
0
  const int width_ext = width + 2 * SGRPROJ_BORDER_HORZ;
724
  // Adjusting the stride of A and B here appears to avoid bad cache effects,
725
  // leading to a significant speed improvement.
726
  // We also align the stride to a multiple of 16 bytes, for consistency
727
  // with the SIMD version of this function.
728
0
  int buf_stride = ((width_ext + 3) & ~3) + 16;
729
0
  int32_t A_[RESTORATION_PROC_UNIT_PELS];
730
0
  int32_t B_[RESTORATION_PROC_UNIT_PELS];
731
0
  int32_t *A = A_;
732
0
  int32_t *B = B_;
733
0
  int i, j;
734
0
  calculate_intermediate_result(dgd, width, height, dgd_stride, bit_depth,
735
0
                                sgr_params_idx, radius_idx, 1, A, B);
736
0
  A += SGRPROJ_BORDER_VERT * buf_stride + SGRPROJ_BORDER_HORZ;
737
0
  B += SGRPROJ_BORDER_VERT * buf_stride + SGRPROJ_BORDER_HORZ;
738
739
  // Use the A[] and B[] arrays to calculate the filtered image
740
0
  (void)r;
741
0
  assert(r == 2);
742
0
  for (i = 0; i < height; ++i) {
743
0
    if (!(i & 1)) {  // even row
744
0
      for (j = 0; j < width; ++j) {
745
0
        const int k = i * buf_stride + j;
746
0
        const int l = i * dgd_stride + j;
747
0
        const int m = i * dst_stride + j;
748
0
        const int nb = 5;
749
0
        const int32_t a = (A[k - buf_stride] + A[k + buf_stride]) * 6 +
750
0
                          (A[k - 1 - buf_stride] + A[k - 1 + buf_stride] +
751
0
                           A[k + 1 - buf_stride] + A[k + 1 + buf_stride]) *
752
0
                              5;
753
0
        const int32_t b = (B[k - buf_stride] + B[k + buf_stride]) * 6 +
754
0
                          (B[k - 1 - buf_stride] + B[k - 1 + buf_stride] +
755
0
                           B[k + 1 - buf_stride] + B[k + 1 + buf_stride]) *
756
0
                              5;
757
0
        const int32_t v = a * dgd[l] + b;
758
0
        dst[m] =
759
0
            ROUND_POWER_OF_TWO(v, SGRPROJ_SGR_BITS + nb - SGRPROJ_RST_BITS);
760
0
      }
761
0
    } else {  // odd row
762
0
      for (j = 0; j < width; ++j) {
763
0
        const int k = i * buf_stride + j;
764
0
        const int l = i * dgd_stride + j;
765
0
        const int m = i * dst_stride + j;
766
0
        const int nb = 4;
767
0
        const int32_t a = A[k] * 6 + (A[k - 1] + A[k + 1]) * 5;
768
0
        const int32_t b = B[k] * 6 + (B[k - 1] + B[k + 1]) * 5;
769
0
        const int32_t v = a * dgd[l] + b;
770
0
        dst[m] =
771
0
            ROUND_POWER_OF_TWO(v, SGRPROJ_SGR_BITS + nb - SGRPROJ_RST_BITS);
772
0
      }
773
0
    }
774
0
  }
775
0
}
776
777
static void selfguided_restoration_internal(int32_t *dgd, int width, int height,
778
                                            int dgd_stride, int32_t *dst,
779
                                            int dst_stride, int bit_depth,
780
                                            int sgr_params_idx,
781
0
                                            int radius_idx) {
782
0
  const int width_ext = width + 2 * SGRPROJ_BORDER_HORZ;
783
  // Adjusting the stride of A and B here appears to avoid bad cache effects,
784
  // leading to a significant speed improvement.
785
  // We also align the stride to a multiple of 16 bytes, for consistency
786
  // with the SIMD version of this function.
787
0
  int buf_stride = ((width_ext + 3) & ~3) + 16;
788
0
  int32_t A_[RESTORATION_PROC_UNIT_PELS];
789
0
  int32_t B_[RESTORATION_PROC_UNIT_PELS];
790
0
  int32_t *A = A_;
791
0
  int32_t *B = B_;
792
0
  int i, j;
793
0
  calculate_intermediate_result(dgd, width, height, dgd_stride, bit_depth,
794
0
                                sgr_params_idx, radius_idx, 0, A, B);
795
0
  A += SGRPROJ_BORDER_VERT * buf_stride + SGRPROJ_BORDER_HORZ;
796
0
  B += SGRPROJ_BORDER_VERT * buf_stride + SGRPROJ_BORDER_HORZ;
797
798
  // Use the A[] and B[] arrays to calculate the filtered image
799
0
  for (i = 0; i < height; ++i) {
800
0
    for (j = 0; j < width; ++j) {
801
0
      const int k = i * buf_stride + j;
802
0
      const int l = i * dgd_stride + j;
803
0
      const int m = i * dst_stride + j;
804
0
      const int nb = 5;
805
0
      const int32_t a =
806
0
          (A[k] + A[k - 1] + A[k + 1] + A[k - buf_stride] + A[k + buf_stride]) *
807
0
              4 +
808
0
          (A[k - 1 - buf_stride] + A[k - 1 + buf_stride] +
809
0
           A[k + 1 - buf_stride] + A[k + 1 + buf_stride]) *
810
0
              3;
811
0
      const int32_t b =
812
0
          (B[k] + B[k - 1] + B[k + 1] + B[k - buf_stride] + B[k + buf_stride]) *
813
0
              4 +
814
0
          (B[k - 1 - buf_stride] + B[k - 1 + buf_stride] +
815
0
           B[k + 1 - buf_stride] + B[k + 1 + buf_stride]) *
816
0
              3;
817
0
      const int32_t v = a * dgd[l] + b;
818
0
      dst[m] = ROUND_POWER_OF_TWO(v, SGRPROJ_SGR_BITS + nb - SGRPROJ_RST_BITS);
819
0
    }
820
0
  }
821
0
}
822
823
int av1_selfguided_restoration_c(const uint8_t *dgd8, int width, int height,
824
                                 int dgd_stride, int32_t *flt0, int32_t *flt1,
825
                                 int flt_stride, int sgr_params_idx,
826
0
                                 int bit_depth, int highbd) {
827
0
  int32_t dgd32_[RESTORATION_PROC_UNIT_PELS];
828
0
  const int dgd32_stride = width + 2 * SGRPROJ_BORDER_HORZ;
829
0
  int32_t *dgd32 =
830
0
      dgd32_ + dgd32_stride * SGRPROJ_BORDER_VERT + SGRPROJ_BORDER_HORZ;
831
832
0
  if (highbd) {
833
0
    const uint16_t *dgd16 = CONVERT_TO_SHORTPTR(dgd8);
834
0
    for (int i = -SGRPROJ_BORDER_VERT; i < height + SGRPROJ_BORDER_VERT; ++i) {
835
0
      for (int j = -SGRPROJ_BORDER_HORZ; j < width + SGRPROJ_BORDER_HORZ; ++j) {
836
0
        dgd32[i * dgd32_stride + j] = dgd16[i * dgd_stride + j];
837
0
      }
838
0
    }
839
0
  } else {
840
0
    for (int i = -SGRPROJ_BORDER_VERT; i < height + SGRPROJ_BORDER_VERT; ++i) {
841
0
      for (int j = -SGRPROJ_BORDER_HORZ; j < width + SGRPROJ_BORDER_HORZ; ++j) {
842
0
        dgd32[i * dgd32_stride + j] = dgd8[i * dgd_stride + j];
843
0
      }
844
0
    }
845
0
  }
846
847
0
  const sgr_params_type *const params = &av1_sgr_params[sgr_params_idx];
848
  // If params->r == 0 we skip the corresponding filter. We only allow one of
849
  // the radii to be 0, as having both equal to 0 would be equivalent to
850
  // skipping SGR entirely.
851
0
  assert(!(params->r[0] == 0 && params->r[1] == 0));
852
853
0
  if (params->r[0] > 0)
854
0
    selfguided_restoration_fast_internal(dgd32, width, height, dgd32_stride,
855
0
                                         flt0, flt_stride, bit_depth,
856
0
                                         sgr_params_idx, 0);
857
0
  if (params->r[1] > 0)
858
0
    selfguided_restoration_internal(dgd32, width, height, dgd32_stride, flt1,
859
0
                                    flt_stride, bit_depth, sgr_params_idx, 1);
860
0
  return 0;
861
0
}
862
863
int av1_apply_selfguided_restoration_c(const uint8_t *dat8, int width,
864
                                       int height, int stride, int eps,
865
                                       const int *xqd, uint8_t *dst8,
866
                                       int dst_stride, int32_t *tmpbuf,
867
0
                                       int bit_depth, int highbd) {
868
0
  int32_t *flt0 = tmpbuf;
869
0
  int32_t *flt1 = flt0 + RESTORATION_UNITPELS_MAX;
870
0
  assert(width * height <= RESTORATION_UNITPELS_MAX);
871
872
0
  const int ret = av1_selfguided_restoration_c(
873
0
      dat8, width, height, stride, flt0, flt1, width, eps, bit_depth, highbd);
874
0
  if (ret != 0) return ret;
875
0
  const sgr_params_type *const params = &av1_sgr_params[eps];
876
0
  int xq[2];
877
0
  av1_decode_xq(xqd, xq, params);
878
0
  for (int i = 0; i < height; ++i) {
879
0
    for (int j = 0; j < width; ++j) {
880
0
      const int k = i * width + j;
881
0
      uint8_t *dst8ij = dst8 + i * dst_stride + j;
882
0
      const uint8_t *dat8ij = dat8 + i * stride + j;
883
884
0
      const uint16_t pre_u = highbd ? *CONVERT_TO_SHORTPTR(dat8ij) : *dat8ij;
885
0
      const int32_t u = (int32_t)pre_u << SGRPROJ_RST_BITS;
886
0
      int32_t v = u << SGRPROJ_PRJ_BITS;
887
      // If params->r == 0 then we skipped the filtering in
888
      // av1_selfguided_restoration_c, i.e. flt[k] == u
889
0
      if (params->r[0] > 0) v += xq[0] * (flt0[k] - u);
890
0
      if (params->r[1] > 0) v += xq[1] * (flt1[k] - u);
891
0
      const int16_t w =
892
0
          (int16_t)ROUND_POWER_OF_TWO(v, SGRPROJ_PRJ_BITS + SGRPROJ_RST_BITS);
893
894
0
      const uint16_t out = clip_pixel_highbd(w, bit_depth);
895
0
      if (highbd)
896
0
        *CONVERT_TO_SHORTPTR(dst8ij) = out;
897
0
      else
898
0
        *dst8ij = (uint8_t)out;
899
0
    }
900
0
  }
901
0
  return 0;
902
0
}
903
904
static void sgrproj_filter_stripe(const RestorationUnitInfo *rui,
905
                                  int stripe_width, int stripe_height,
906
                                  int procunit_width, const uint8_t *src,
907
                                  int src_stride, uint8_t *dst, int dst_stride,
908
                                  int32_t *tmpbuf, int bit_depth,
909
57.7k
                                  struct aom_internal_error_info *error_info) {
910
57.7k
  (void)bit_depth;
911
57.7k
  assert(bit_depth == 8);
912
913
264k
  for (int j = 0; j < stripe_width; j += procunit_width) {
914
206k
    int w = AOMMIN(procunit_width, stripe_width - j);
915
206k
    if (av1_apply_selfguided_restoration(
916
206k
            src + j, w, stripe_height, src_stride, rui->sgrproj_info.ep,
917
206k
            rui->sgrproj_info.xqd, dst + j, dst_stride, tmpbuf, bit_depth,
918
206k
            0) != 0) {
919
0
      aom_internal_error(
920
0
          error_info, AOM_CODEC_MEM_ERROR,
921
0
          "Error allocating buffer in av1_apply_selfguided_restoration");
922
0
    }
923
206k
  }
924
57.7k
}
925
926
#if CONFIG_AV1_HIGHBITDEPTH
927
static void wiener_filter_stripe_highbd(
928
    const RestorationUnitInfo *rui, int stripe_width, int stripe_height,
929
    int procunit_width, const uint8_t *src8, int src_stride, uint8_t *dst8,
930
    int dst_stride, int32_t *tmpbuf, int bit_depth,
931
62.7k
    struct aom_internal_error_info *error_info) {
932
62.7k
  (void)tmpbuf;
933
62.7k
  (void)error_info;
934
62.7k
  const WienerConvolveParams conv_params = get_conv_params_wiener(bit_depth);
935
936
429k
  for (int j = 0; j < stripe_width; j += procunit_width) {
937
366k
    int w = AOMMIN(procunit_width, (stripe_width - j + 15) & ~15);
938
366k
    const uint8_t *src8_p = src8 + j;
939
366k
    uint8_t *dst8_p = dst8 + j;
940
366k
    av1_highbd_wiener_convolve_add_src(src8_p, src_stride, dst8_p, dst_stride,
941
366k
                                       rui->wiener_info.hfilter, 16,
942
366k
                                       rui->wiener_info.vfilter, 16, w,
943
366k
                                       stripe_height, &conv_params, bit_depth);
944
366k
  }
945
62.7k
}
946
947
static void sgrproj_filter_stripe_highbd(
948
    const RestorationUnitInfo *rui, int stripe_width, int stripe_height,
949
    int procunit_width, const uint8_t *src8, int src_stride, uint8_t *dst8,
950
    int dst_stride, int32_t *tmpbuf, int bit_depth,
951
76.1k
    struct aom_internal_error_info *error_info) {
952
333k
  for (int j = 0; j < stripe_width; j += procunit_width) {
953
257k
    int w = AOMMIN(procunit_width, stripe_width - j);
954
257k
    if (av1_apply_selfguided_restoration(
955
257k
            src8 + j, w, stripe_height, src_stride, rui->sgrproj_info.ep,
956
257k
            rui->sgrproj_info.xqd, dst8 + j, dst_stride, tmpbuf, bit_depth,
957
257k
            1) != 0) {
958
0
      aom_internal_error(
959
0
          error_info, AOM_CODEC_MEM_ERROR,
960
0
          "Error allocating buffer in av1_apply_selfguided_restoration");
961
0
    }
962
257k
  }
963
76.1k
}
964
#endif  // CONFIG_AV1_HIGHBITDEPTH
965
966
typedef void (*stripe_filter_fun)(const RestorationUnitInfo *rui,
967
                                  int stripe_width, int stripe_height,
968
                                  int procunit_width, const uint8_t *src,
969
                                  int src_stride, uint8_t *dst, int dst_stride,
970
                                  int32_t *tmpbuf, int bit_depth,
971
                                  struct aom_internal_error_info *error_info);
972
973
#if CONFIG_AV1_HIGHBITDEPTH
974
#define NUM_STRIPE_FILTERS 4
975
static const stripe_filter_fun stripe_filters[NUM_STRIPE_FILTERS] = {
976
  wiener_filter_stripe, sgrproj_filter_stripe, wiener_filter_stripe_highbd,
977
  sgrproj_filter_stripe_highbd
978
};
979
#else
980
#define NUM_STRIPE_FILTERS 2
981
static const stripe_filter_fun stripe_filters[NUM_STRIPE_FILTERS] = {
982
  wiener_filter_stripe, sgrproj_filter_stripe
983
};
984
#endif  // CONFIG_AV1_HIGHBITDEPTH
985
986
// Filter one restoration unit
987
void av1_loop_restoration_filter_unit(
988
    const RestorationTileLimits *limits, const RestorationUnitInfo *rui,
989
    const RestorationStripeBoundaries *rsb, RestorationLineBuffers *rlbs,
990
    int plane_w, int plane_h, int ss_x, int ss_y, int highbd, int bit_depth,
991
    uint8_t *data8, int stride, uint8_t *dst8, int dst_stride, int32_t *tmpbuf,
992
94.7k
    int optimized_lr, struct aom_internal_error_info *error_info) {
993
94.7k
  RestorationType unit_rtype = rui->restoration_type;
994
995
94.7k
  int unit_h = limits->v_end - limits->v_start;
996
94.7k
  int unit_w = limits->h_end - limits->h_start;
997
94.7k
  uint8_t *data8_tl =
998
94.7k
      data8 + limits->v_start * (ptrdiff_t)stride + limits->h_start;
999
94.7k
  uint8_t *dst8_tl =
1000
94.7k
      dst8 + limits->v_start * (ptrdiff_t)dst_stride + limits->h_start;
1001
1002
94.7k
  if (unit_rtype == RESTORE_NONE) {
1003
34.3k
    copy_rest_unit(unit_w, unit_h, data8_tl, stride, dst8_tl, dst_stride,
1004
34.3k
                   highbd);
1005
34.3k
    return;
1006
34.3k
  }
1007
1008
60.3k
  const int filter_idx = 2 * highbd + (unit_rtype == RESTORE_SGRPROJ);
1009
60.3k
  assert(filter_idx < NUM_STRIPE_FILTERS);
1010
60.4k
  const stripe_filter_fun stripe_filter = stripe_filters[filter_idx];
1011
1012
60.4k
  const int procunit_width = RESTORATION_PROC_UNIT_SIZE >> ss_x;
1013
1014
  // Filter the whole image one stripe at a time
1015
60.4k
  RestorationTileLimits remaining_stripes = *limits;
1016
60.4k
  int i = 0;
1017
293k
  while (i < unit_h) {
1018
232k
    int copy_above, copy_below;
1019
232k
    remaining_stripes.v_start = limits->v_start + i;
1020
1021
232k
    get_stripe_boundary_info(&remaining_stripes, plane_w, plane_h, ss_y,
1022
232k
                             &copy_above, &copy_below);
1023
1024
232k
    const int full_stripe_height = RESTORATION_PROC_UNIT_SIZE >> ss_y;
1025
232k
    const int runit_offset = RESTORATION_UNIT_OFFSET >> ss_y;
1026
1027
    // Work out where this stripe's boundaries are within
1028
    // rsb->stripe_boundary_{above,below}
1029
232k
    const int frame_stripe =
1030
232k
        (remaining_stripes.v_start + runit_offset) / full_stripe_height;
1031
232k
    const int rsb_row = RESTORATION_CTX_VERT * frame_stripe;
1032
1033
    // Calculate this stripe's height, based on two rules:
1034
    // * The topmost stripe in the frame is 8 luma pixels shorter than usual.
1035
    // * We can't extend past the end of the current restoration unit
1036
232k
    const int nominal_stripe_height =
1037
232k
        full_stripe_height - ((frame_stripe == 0) ? runit_offset : 0);
1038
232k
    const int h = AOMMIN(nominal_stripe_height,
1039
232k
                         remaining_stripes.v_end - remaining_stripes.v_start);
1040
1041
232k
    setup_processing_stripe_boundary(&remaining_stripes, rsb, rsb_row, highbd,
1042
232k
                                     h, data8, stride, rlbs, copy_above,
1043
232k
                                     copy_below, optimized_lr);
1044
1045
232k
    stripe_filter(rui, unit_w, h, procunit_width, data8_tl + i * stride, stride,
1046
232k
                  dst8_tl + i * dst_stride, dst_stride, tmpbuf, bit_depth,
1047
232k
                  error_info);
1048
1049
232k
    restore_processing_stripe_boundary(&remaining_stripes, rlbs, highbd, h,
1050
232k
                                       data8, stride, copy_above, copy_below,
1051
232k
                                       optimized_lr);
1052
1053
232k
    i += h;
1054
232k
  }
1055
60.4k
}
1056
1057
static void filter_frame_on_unit(const RestorationTileLimits *limits,
1058
                                 int rest_unit_idx, void *priv, int32_t *tmpbuf,
1059
                                 RestorationLineBuffers *rlbs,
1060
94.8k
                                 struct aom_internal_error_info *error_info) {
1061
94.8k
  FilterFrameCtxt *ctxt = (FilterFrameCtxt *)priv;
1062
94.8k
  const RestorationInfo *rsi = ctxt->rsi;
1063
1064
94.8k
  av1_loop_restoration_filter_unit(
1065
94.8k
      limits, &rsi->unit_info[rest_unit_idx], &rsi->boundaries, rlbs,
1066
94.8k
      ctxt->plane_w, ctxt->plane_h, ctxt->ss_x, ctxt->ss_y, ctxt->highbd,
1067
94.8k
      ctxt->bit_depth, ctxt->data8, ctxt->data_stride, ctxt->dst8,
1068
94.8k
      ctxt->dst_stride, tmpbuf, rsi->optimized_lr, error_info);
1069
94.8k
}
1070
1071
void av1_loop_restoration_filter_frame_init(AV1LrStruct *lr_ctxt,
1072
                                            YV12_BUFFER_CONFIG *frame,
1073
                                            AV1_COMMON *cm, int optimized_lr,
1074
15.5k
                                            int num_planes) {
1075
15.5k
  const SequenceHeader *const seq_params = cm->seq_params;
1076
15.5k
  const int bit_depth = seq_params->bit_depth;
1077
15.5k
  const int highbd = seq_params->use_highbitdepth;
1078
15.5k
  lr_ctxt->dst = &cm->rst_frame;
1079
1080
15.5k
  const int frame_width = frame->crop_widths[0];
1081
15.5k
  const int frame_height = frame->crop_heights[0];
1082
15.5k
  if (aom_realloc_frame_buffer(
1083
15.5k
          lr_ctxt->dst, frame_width, frame_height, seq_params->subsampling_x,
1084
15.5k
          seq_params->subsampling_y, highbd, AOM_RESTORATION_FRAME_BORDER,
1085
15.5k
          cm->features.byte_alignment, NULL, NULL, NULL, false,
1086
15.5k
          0) != AOM_CODEC_OK)
1087
0
    aom_internal_error(cm->error, AOM_CODEC_MEM_ERROR,
1088
0
                       "Failed to allocate restoration dst buffer");
1089
1090
15.5k
  lr_ctxt->on_rest_unit = filter_frame_on_unit;
1091
15.5k
  lr_ctxt->frame = frame;
1092
56.8k
  for (int plane = 0; plane < num_planes; ++plane) {
1093
41.3k
    RestorationInfo *rsi = &cm->rst_info[plane];
1094
41.3k
    RestorationType rtype = rsi->frame_restoration_type;
1095
41.3k
    rsi->optimized_lr = optimized_lr;
1096
41.3k
    lr_ctxt->ctxt[plane].rsi = rsi;
1097
1098
41.3k
    if (rtype == RESTORE_NONE) {
1099
8.30k
      continue;
1100
8.30k
    }
1101
1102
33.0k
    const int is_uv = plane > 0;
1103
33.0k
    int plane_w, plane_h;
1104
33.0k
    av1_get_upsampled_plane_size(cm, is_uv, &plane_w, &plane_h);
1105
33.0k
    assert(plane_w == frame->crop_widths[is_uv]);
1106
33.0k
    assert(plane_h == frame->crop_heights[is_uv]);
1107
1108
33.0k
    av1_extend_frame(frame->buffers[plane], plane_w, plane_h,
1109
33.0k
                     frame->strides[is_uv], RESTORATION_BORDER,
1110
33.0k
                     RESTORATION_BORDER, highbd);
1111
1112
33.0k
    FilterFrameCtxt *lr_plane_ctxt = &lr_ctxt->ctxt[plane];
1113
33.0k
    lr_plane_ctxt->ss_x = is_uv && seq_params->subsampling_x;
1114
33.0k
    lr_plane_ctxt->ss_y = is_uv && seq_params->subsampling_y;
1115
33.0k
    lr_plane_ctxt->plane_w = plane_w;
1116
33.0k
    lr_plane_ctxt->plane_h = plane_h;
1117
33.0k
    lr_plane_ctxt->highbd = highbd;
1118
33.0k
    lr_plane_ctxt->bit_depth = bit_depth;
1119
33.0k
    lr_plane_ctxt->data8 = frame->buffers[plane];
1120
33.0k
    lr_plane_ctxt->dst8 = lr_ctxt->dst->buffers[plane];
1121
33.0k
    lr_plane_ctxt->data_stride = frame->strides[is_uv];
1122
33.0k
    lr_plane_ctxt->dst_stride = lr_ctxt->dst->strides[is_uv];
1123
33.0k
  }
1124
15.5k
}
1125
1126
static void loop_restoration_copy_planes(AV1LrStruct *loop_rest_ctxt,
1127
6.37k
                                         AV1_COMMON *cm, int num_planes) {
1128
6.37k
  typedef void (*copy_fun)(const YV12_BUFFER_CONFIG *src_ybc,
1129
6.37k
                           YV12_BUFFER_CONFIG *dst_ybc, int hstart, int hend,
1130
6.37k
                           int vstart, int vend);
1131
6.37k
  static const copy_fun copy_funs[3] = { aom_yv12_partial_coloc_copy_y,
1132
6.37k
                                         aom_yv12_partial_coloc_copy_u,
1133
6.37k
                                         aom_yv12_partial_coloc_copy_v };
1134
6.37k
  assert(num_planes <= 3);
1135
21.1k
  for (int plane = 0; plane < num_planes; ++plane) {
1136
14.8k
    if (cm->rst_info[plane].frame_restoration_type == RESTORE_NONE) continue;
1137
11.9k
    FilterFrameCtxt *lr_plane_ctxt = &loop_rest_ctxt->ctxt[plane];
1138
11.9k
    copy_funs[plane](loop_rest_ctxt->dst, loop_rest_ctxt->frame, 0,
1139
11.9k
                     lr_plane_ctxt->plane_w, 0, lr_plane_ctxt->plane_h);
1140
11.9k
  }
1141
6.37k
}
1142
1143
// Call on_rest_unit for each loop restoration unit in the plane.
1144
static void foreach_rest_unit_in_plane(const struct AV1Common *cm, int plane,
1145
                                       rest_unit_visitor_t on_rest_unit,
1146
                                       void *priv, int32_t *tmpbuf,
1147
11.9k
                                       RestorationLineBuffers *rlbs) {
1148
11.9k
  const RestorationInfo *rsi = &cm->rst_info[plane];
1149
11.9k
  const int hnum_rest_units = rsi->horz_units;
1150
11.9k
  const int vnum_rest_units = rsi->vert_units;
1151
11.9k
  const int unit_size = rsi->restoration_unit_size;
1152
1153
11.9k
  const int is_uv = plane > 0;
1154
11.9k
  const int ss_y = is_uv && cm->seq_params->subsampling_y;
1155
11.9k
  const int ext_size = unit_size * 3 / 2;
1156
11.9k
  int plane_w, plane_h;
1157
11.9k
  av1_get_upsampled_plane_size(cm, is_uv, &plane_w, &plane_h);
1158
1159
11.9k
  int y0 = 0, i = 0;
1160
25.1k
  while (y0 < plane_h) {
1161
13.1k
    int remaining_h = plane_h - y0;
1162
13.1k
    int h = (remaining_h < ext_size) ? remaining_h : unit_size;
1163
1164
13.1k
    RestorationTileLimits limits;
1165
13.1k
    limits.v_start = y0;
1166
13.1k
    limits.v_end = y0 + h;
1167
13.1k
    assert(limits.v_end <= plane_h);
1168
    // Offset upwards to align with the restoration processing stripe
1169
13.1k
    const int voffset = RESTORATION_UNIT_OFFSET >> ss_y;
1170
13.1k
    limits.v_start = AOMMAX(0, limits.v_start - voffset);
1171
13.1k
    if (limits.v_end < plane_h) limits.v_end -= voffset;
1172
1173
13.1k
    av1_foreach_rest_unit_in_row(&limits, plane_w, on_rest_unit, i, unit_size,
1174
13.1k
                                 hnum_rest_units, vnum_rest_units, plane, priv,
1175
13.1k
                                 tmpbuf, rlbs, av1_lr_sync_read_dummy,
1176
13.1k
                                 av1_lr_sync_write_dummy, NULL, cm->error);
1177
1178
13.1k
    y0 += h;
1179
13.1k
    ++i;
1180
13.1k
  }
1181
11.9k
}
1182
1183
static void foreach_rest_unit_in_planes(AV1LrStruct *lr_ctxt, AV1_COMMON *cm,
1184
6.37k
                                        int num_planes) {
1185
6.37k
  FilterFrameCtxt *ctxt = lr_ctxt->ctxt;
1186
1187
21.1k
  for (int plane = 0; plane < num_planes; ++plane) {
1188
14.8k
    if (cm->rst_info[plane].frame_restoration_type == RESTORE_NONE) {
1189
2.81k
      continue;
1190
2.81k
    }
1191
1192
11.9k
    foreach_rest_unit_in_plane(cm, plane, lr_ctxt->on_rest_unit, &ctxt[plane],
1193
11.9k
                               cm->rst_tmpbuf, cm->rlbs);
1194
11.9k
  }
1195
6.37k
}
1196
1197
void av1_loop_restoration_filter_frame(YV12_BUFFER_CONFIG *frame,
1198
                                       AV1_COMMON *cm, int optimized_lr,
1199
6.37k
                                       void *lr_ctxt) {
1200
6.37k
  assert(!cm->features.all_lossless);
1201
6.37k
  const int num_planes = av1_num_planes(cm);
1202
1203
6.37k
  AV1LrStruct *loop_rest_ctxt = (AV1LrStruct *)lr_ctxt;
1204
1205
6.37k
  av1_loop_restoration_filter_frame_init(loop_rest_ctxt, frame, cm,
1206
6.37k
                                         optimized_lr, num_planes);
1207
1208
6.37k
  foreach_rest_unit_in_planes(loop_rest_ctxt, cm, num_planes);
1209
1210
6.37k
  loop_restoration_copy_planes(loop_rest_ctxt, cm, num_planes);
1211
6.37k
}
1212
1213
void av1_foreach_rest_unit_in_row(
1214
    RestorationTileLimits *limits, int plane_w,
1215
    rest_unit_visitor_t on_rest_unit, int row_number, int unit_size,
1216
    int hnum_rest_units, int vnum_rest_units, int plane, void *priv,
1217
    int32_t *tmpbuf, RestorationLineBuffers *rlbs, sync_read_fn_t on_sync_read,
1218
    sync_write_fn_t on_sync_write, struct AV1LrSyncData *const lr_sync,
1219
44.0k
    struct aom_internal_error_info *error_info) {
1220
44.0k
  const int ext_size = unit_size * 3 / 2;
1221
44.0k
  int x0 = 0, j = 0;
1222
138k
  while (x0 < plane_w) {
1223
94.8k
    int remaining_w = plane_w - x0;
1224
94.8k
    int w = (remaining_w < ext_size) ? remaining_w : unit_size;
1225
1226
94.8k
    limits->h_start = x0;
1227
94.8k
    limits->h_end = x0 + w;
1228
94.8k
    assert(limits->h_end <= plane_w);
1229
1230
94.7k
    const int unit_idx = row_number * hnum_rest_units + j;
1231
1232
    // No sync for even numbered rows
1233
    // For odd numbered rows, Loop Restoration of current block requires the LR
1234
    // of top-right and bottom-right blocks to be completed
1235
1236
    // top-right sync
1237
94.7k
    on_sync_read(lr_sync, row_number, j, plane);
1238
94.7k
    if ((row_number + 1) < vnum_rest_units)
1239
      // bottom-right sync
1240
40.8k
      on_sync_read(lr_sync, row_number + 2, j, plane);
1241
1242
94.7k
#if CONFIG_MULTITHREAD
1243
94.7k
    if (lr_sync && lr_sync->num_workers > 1) {
1244
76.5k
      pthread_mutex_lock(lr_sync->job_mutex);
1245
76.5k
      const bool lr_mt_exit = lr_sync->lr_mt_exit;
1246
76.5k
      pthread_mutex_unlock(lr_sync->job_mutex);
1247
      // Exit in case any worker has encountered an error.
1248
76.5k
      if (lr_mt_exit) return;
1249
76.5k
    }
1250
94.7k
#endif
1251
1252
94.7k
    on_rest_unit(limits, unit_idx, priv, tmpbuf, rlbs, error_info);
1253
1254
94.7k
    on_sync_write(lr_sync, row_number, j, hnum_rest_units, plane);
1255
1256
94.7k
    x0 += w;
1257
94.7k
    ++j;
1258
94.7k
  }
1259
44.0k
}
1260
1261
98.3k
void av1_lr_sync_read_dummy(void *const lr_sync, int r, int c, int plane) {
1262
98.3k
  (void)lr_sync;
1263
98.3k
  (void)r;
1264
98.3k
  (void)c;
1265
98.3k
  (void)plane;
1266
98.3k
}
1267
1268
void av1_lr_sync_write_dummy(void *const lr_sync, int r, int c,
1269
44.2k
                             const int sb_cols, int plane) {
1270
44.2k
  (void)lr_sync;
1271
44.2k
  (void)r;
1272
44.2k
  (void)c;
1273
44.2k
  (void)sb_cols;
1274
44.2k
  (void)plane;
1275
44.2k
}
1276
1277
int av1_loop_restoration_corners_in_sb(const struct AV1Common *cm, int plane,
1278
                                       int mi_row, int mi_col, BLOCK_SIZE bsize,
1279
                                       int *rcol0, int *rcol1, int *rrow0,
1280
16.3M
                                       int *rrow1) {
1281
16.3M
  assert(rcol0 && rcol1 && rrow0 && rrow1);
1282
1283
16.3M
  if (bsize != cm->seq_params->sb_size) return 0;
1284
1285
16.3M
  assert(!cm->features.all_lossless);
1286
1287
820k
  const int is_uv = plane > 0;
1288
1289
  // Compute the mi-unit corners of the superblock
1290
820k
  const int mi_row0 = mi_row;
1291
820k
  const int mi_col0 = mi_col;
1292
820k
  const int mi_row1 = mi_row0 + mi_size_high[bsize];
1293
820k
  const int mi_col1 = mi_col0 + mi_size_wide[bsize];
1294
1295
820k
  const RestorationInfo *rsi = &cm->rst_info[plane];
1296
820k
  const int size = rsi->restoration_unit_size;
1297
820k
  const int horz_units = rsi->horz_units;
1298
820k
  const int vert_units = rsi->vert_units;
1299
1300
  // The size of an MI-unit on this plane of the image
1301
820k
  const int ss_x = is_uv && cm->seq_params->subsampling_x;
1302
820k
  const int ss_y = is_uv && cm->seq_params->subsampling_y;
1303
820k
  const int mi_size_x = MI_SIZE >> ss_x;
1304
820k
  const int mi_size_y = MI_SIZE >> ss_y;
1305
1306
  // Write m for the relative mi column or row, D for the superres denominator
1307
  // and N for the superres numerator. If u is the upscaled pixel offset then
1308
  // we can write the downscaled pixel offset in two ways as:
1309
  //
1310
  //   MI_SIZE * m = N / D u
1311
  //
1312
  // from which we get u = D * MI_SIZE * m / N
1313
820k
  const int mi_to_num_x = av1_superres_scaled(cm)
1314
820k
                              ? mi_size_x * cm->superres_scale_denominator
1315
820k
                              : mi_size_x;
1316
820k
  const int mi_to_num_y = mi_size_y;
1317
820k
  const int denom_x = av1_superres_scaled(cm) ? size * SCALE_NUMERATOR : size;
1318
820k
  const int denom_y = size;
1319
1320
820k
  const int rnd_x = denom_x - 1;
1321
820k
  const int rnd_y = denom_y - 1;
1322
1323
  // rcol0/rrow0 should be the first column/row of restoration units that
1324
  // doesn't start left/below of mi_col/mi_row. For this calculation, we need
1325
  // to round up the division (if the sb starts at runit column 10.1, the first
1326
  // matching runit has column index 11)
1327
820k
  *rcol0 = (mi_col0 * mi_to_num_x + rnd_x) / denom_x;
1328
820k
  *rrow0 = (mi_row0 * mi_to_num_y + rnd_y) / denom_y;
1329
1330
  // rel_col1/rel_row1 is the equivalent calculation, but for the superblock
1331
  // below-right. If we're at the bottom or right of the frame, this restoration
1332
  // unit might not exist, in which case we'll clamp accordingly.
1333
820k
  *rcol1 = AOMMIN((mi_col1 * mi_to_num_x + rnd_x) / denom_x, horz_units);
1334
820k
  *rrow1 = AOMMIN((mi_row1 * mi_to_num_y + rnd_y) / denom_y, vert_units);
1335
1336
820k
  return *rcol0 < *rcol1 && *rrow0 < *rrow1;
1337
815k
}
1338
1339
// Extend to left and right
1340
static void extend_lines(uint8_t *buf, int width, int height, int stride,
1341
261k
                         int extend, int use_highbitdepth) {
1342
784k
  for (int i = 0; i < height; ++i) {
1343
522k
    if (use_highbitdepth) {
1344
269k
      uint16_t *buf16 = (uint16_t *)buf;
1345
269k
      aom_memset16(buf16 - extend, buf16[0], extend);
1346
269k
      aom_memset16(buf16 + width, buf16[width - 1], extend);
1347
269k
    } else {
1348
252k
      memset(buf - extend, buf[0], extend);
1349
252k
      memset(buf + width, buf[width - 1], extend);
1350
252k
    }
1351
522k
    buf += stride;
1352
522k
  }
1353
261k
}
1354
1355
static void save_deblock_boundary_lines(
1356
    const YV12_BUFFER_CONFIG *frame, const AV1_COMMON *cm, int plane, int row,
1357
    int stripe, int use_highbd, int is_above,
1358
193k
    RestorationStripeBoundaries *boundaries) {
1359
193k
  const int is_uv = plane > 0;
1360
193k
  const uint8_t *src_buf = REAL_PTR(use_highbd, frame->buffers[plane]);
1361
193k
  const int src_stride = frame->strides[is_uv] << use_highbd;
1362
193k
  const uint8_t *src_rows = src_buf + row * (ptrdiff_t)src_stride;
1363
1364
193k
  uint8_t *bdry_buf = is_above ? boundaries->stripe_boundary_above
1365
193k
                               : boundaries->stripe_boundary_below;
1366
193k
  uint8_t *bdry_start = bdry_buf + (RESTORATION_EXTRA_HORZ << use_highbd);
1367
193k
  const int bdry_stride = boundaries->stripe_boundary_stride << use_highbd;
1368
193k
  uint8_t *bdry_rows = bdry_start + RESTORATION_CTX_VERT * stripe * bdry_stride;
1369
1370
  // There is a rare case in which a processing stripe can end 1px above the
1371
  // crop border. In this case, we do want to use deblocked pixels from below
1372
  // the stripe (hence why we ended up in this function), but instead of
1373
  // fetching 2 "below" rows we need to fetch one and duplicate it.
1374
  // This is equivalent to clamping the sample locations against the crop border
1375
193k
  const int lines_to_save =
1376
193k
      AOMMIN(RESTORATION_CTX_VERT, frame->crop_heights[is_uv] - row);
1377
193k
  assert(lines_to_save == 1 || lines_to_save == 2);
1378
1379
193k
  int upscaled_width;
1380
193k
  int line_bytes;
1381
193k
  if (av1_superres_scaled(cm)) {
1382
25.8k
    const int ss_x = is_uv && cm->seq_params->subsampling_x;
1383
25.8k
    upscaled_width = (cm->superres_upscaled_width + ss_x) >> ss_x;
1384
25.8k
    line_bytes = upscaled_width << use_highbd;
1385
25.8k
    if (use_highbd)
1386
7.67k
      av1_upscale_normative_rows(
1387
7.67k
          cm, CONVERT_TO_BYTEPTR(src_rows), frame->strides[is_uv],
1388
7.67k
          CONVERT_TO_BYTEPTR(bdry_rows), boundaries->stripe_boundary_stride,
1389
7.67k
          plane, lines_to_save);
1390
18.2k
    else
1391
18.2k
      av1_upscale_normative_rows(cm, src_rows, frame->strides[is_uv], bdry_rows,
1392
18.2k
                                 boundaries->stripe_boundary_stride, plane,
1393
18.2k
                                 lines_to_save);
1394
167k
  } else {
1395
167k
    upscaled_width = frame->crop_widths[is_uv];
1396
167k
    line_bytes = upscaled_width << use_highbd;
1397
499k
    for (int i = 0; i < lines_to_save; i++) {
1398
332k
      memcpy(bdry_rows + i * bdry_stride, src_rows + i * src_stride,
1399
332k
             line_bytes);
1400
332k
    }
1401
167k
  }
1402
  // If we only saved one line, then copy it into the second line buffer
1403
193k
  if (lines_to_save == 1)
1404
4.81k
    memcpy(bdry_rows + bdry_stride, bdry_rows, line_bytes);
1405
1406
193k
  extend_lines(bdry_rows, upscaled_width, RESTORATION_CTX_VERT, bdry_stride,
1407
193k
               RESTORATION_EXTRA_HORZ, use_highbd);
1408
193k
}
1409
1410
static void save_cdef_boundary_lines(const YV12_BUFFER_CONFIG *frame,
1411
                                     const AV1_COMMON *cm, int plane, int row,
1412
                                     int stripe, int use_highbd, int is_above,
1413
67.5k
                                     RestorationStripeBoundaries *boundaries) {
1414
67.5k
  const int is_uv = plane > 0;
1415
67.5k
  const uint8_t *src_buf = REAL_PTR(use_highbd, frame->buffers[plane]);
1416
67.5k
  const int src_stride = frame->strides[is_uv] << use_highbd;
1417
67.5k
  const uint8_t *src_rows = src_buf + row * (ptrdiff_t)src_stride;
1418
1419
67.5k
  uint8_t *bdry_buf = is_above ? boundaries->stripe_boundary_above
1420
67.5k
                               : boundaries->stripe_boundary_below;
1421
67.5k
  uint8_t *bdry_start = bdry_buf + (RESTORATION_EXTRA_HORZ << use_highbd);
1422
67.5k
  const int bdry_stride = boundaries->stripe_boundary_stride << use_highbd;
1423
67.5k
  uint8_t *bdry_rows = bdry_start + RESTORATION_CTX_VERT * stripe * bdry_stride;
1424
67.5k
  const int src_width = frame->crop_widths[is_uv];
1425
1426
  // At the point where this function is called, we've already applied
1427
  // superres. So we don't need to extend the lines here, we can just
1428
  // pull directly from the topmost row of the upscaled frame.
1429
67.5k
  const int ss_x = is_uv && cm->seq_params->subsampling_x;
1430
67.5k
  const int upscaled_width = av1_superres_scaled(cm)
1431
67.5k
                                 ? (cm->superres_upscaled_width + ss_x) >> ss_x
1432
67.5k
                                 : src_width;
1433
67.5k
  const int line_bytes = upscaled_width << use_highbd;
1434
202k
  for (int i = 0; i < RESTORATION_CTX_VERT; i++) {
1435
    // Copy the line at 'src_rows' into both context lines
1436
135k
    memcpy(bdry_rows + i * bdry_stride, src_rows, line_bytes);
1437
135k
  }
1438
67.5k
  extend_lines(bdry_rows, upscaled_width, RESTORATION_CTX_VERT, bdry_stride,
1439
67.5k
               RESTORATION_EXTRA_HORZ, use_highbd);
1440
67.5k
}
1441
1442
static void save_boundary_lines(const YV12_BUFFER_CONFIG *frame, int use_highbd,
1443
67.5k
                                int plane, AV1_COMMON *cm, int after_cdef) {
1444
67.5k
  const int is_uv = plane > 0;
1445
67.5k
  const int ss_y = is_uv && cm->seq_params->subsampling_y;
1446
67.5k
  const int stripe_height = RESTORATION_PROC_UNIT_SIZE >> ss_y;
1447
67.5k
  const int stripe_off = RESTORATION_UNIT_OFFSET >> ss_y;
1448
1449
67.5k
  int plane_w, plane_h;
1450
67.5k
  av1_get_upsampled_plane_size(cm, is_uv, &plane_w, &plane_h);
1451
1452
67.5k
  RestorationStripeBoundaries *boundaries = &cm->rst_info[plane].boundaries;
1453
1454
67.5k
  const int plane_height = ROUND_POWER_OF_TWO(cm->height, ss_y);
1455
1456
67.5k
  int stripe_idx;
1457
328k
  for (stripe_idx = 0;; ++stripe_idx) {
1458
328k
    const int rel_y0 = AOMMAX(0, stripe_idx * stripe_height - stripe_off);
1459
328k
    const int y0 = rel_y0;
1460
328k
    if (y0 >= plane_h) break;
1461
1462
261k
    const int rel_y1 = (stripe_idx + 1) * stripe_height - stripe_off;
1463
261k
    const int y1 = AOMMIN(rel_y1, plane_h);
1464
1465
    // Extend using CDEF pixels at the top and bottom of the frame,
1466
    // and deblocked pixels at internal stripe boundaries
1467
261k
    const int use_deblock_above = (stripe_idx > 0);
1468
261k
    const int use_deblock_below = (y1 < plane_height);
1469
1470
261k
    if (!after_cdef) {
1471
      // Save deblocked context at internal stripe boundaries
1472
130k
      if (use_deblock_above) {
1473
96.9k
        save_deblock_boundary_lines(frame, cm, plane, y0 - RESTORATION_CTX_VERT,
1474
96.9k
                                    stripe_idx, use_highbd, 1, boundaries);
1475
96.9k
      }
1476
130k
      if (use_deblock_below) {
1477
96.9k
        save_deblock_boundary_lines(frame, cm, plane, y1, stripe_idx,
1478
96.9k
                                    use_highbd, 0, boundaries);
1479
96.9k
      }
1480
130k
    } else {
1481
      // Save CDEF context at frame boundaries
1482
130k
      if (!use_deblock_above) {
1483
33.7k
        save_cdef_boundary_lines(frame, cm, plane, y0, stripe_idx, use_highbd,
1484
33.7k
                                 1, boundaries);
1485
33.7k
      }
1486
130k
      if (!use_deblock_below) {
1487
33.7k
        save_cdef_boundary_lines(frame, cm, plane, y1 - 1, stripe_idx,
1488
33.7k
                                 use_highbd, 0, boundaries);
1489
33.7k
      }
1490
130k
    }
1491
261k
  }
1492
67.5k
}
1493
1494
// For each RESTORATION_PROC_UNIT_SIZE pixel high stripe, save 4 scan
1495
// lines to be used as boundary in the loop restoration process. The
1496
// lines are saved in rst_internal.stripe_boundary_lines
1497
void av1_loop_restoration_save_boundary_lines(const YV12_BUFFER_CONFIG *frame,
1498
25.9k
                                              AV1_COMMON *cm, int after_cdef) {
1499
25.9k
  const int num_planes = av1_num_planes(cm);
1500
25.9k
  const int use_highbd = cm->seq_params->use_highbitdepth;
1501
93.5k
  for (int p = 0; p < num_planes; ++p) {
1502
67.5k
    save_boundary_lines(frame, use_highbd, p, cm, after_cdef);
1503
67.5k
  }
1504
25.9k
}