summaryrefslogtreecommitdiff
path: root/thirdparty/libwebp/src/enc/analysis_enc.c
blob: 08f471f5f84881509e6b95ba5c18c161795684d0 (plain)
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341
342
343
344
345
346
347
348
349
350
351
352
353
354
355
356
357
358
359
360
361
362
363
364
365
366
367
368
369
370
371
372
373
374
375
376
377
378
379
380
381
382
383
384
385
386
387
388
389
390
391
392
393
394
395
396
397
398
399
400
401
402
403
404
405
406
407
408
409
410
411
412
413
414
415
416
417
418
419
420
421
422
423
424
425
426
427
428
429
430
431
432
433
434
435
436
437
438
439
440
441
442
443
444
445
446
447
448
449
450
451
452
453
454
455
456
457
458
459
460
461
462
463
464
465
466
467
468
469
470
471
472
473
474
475
476
477
478
479
480
481
482
483
484
485
486
487
488
489
490
491
492
493
494
495
496
497
498
499
500
501
502
503
504
505
506
507
508
509
510
511
512
513
514
515
516
517
518
519
520
521
522
523
524
525
526
527
528
529
530
531
532
533
// Copyright 2011 Google Inc. All Rights Reserved.
//
// Use of this source code is governed by a BSD-style license
// that can be found in the COPYING file in the root of the source
// tree. An additional intellectual property rights grant can be found
// in the file PATENTS. All contributing project authors may
// be found in the AUTHORS file in the root of the source tree.
// -----------------------------------------------------------------------------
//
// Macroblock analysis
//
// Author: Skal (pascal.massimino@gmail.com)

#include <stdlib.h>
#include <string.h>
#include <assert.h>

#include "src/enc/vp8i_enc.h"
#include "src/enc/cost_enc.h"
#include "src/utils/utils.h"

#define MAX_ITERS_K_MEANS  6

//------------------------------------------------------------------------------
// Smooth the segment map by replacing isolated block by the majority of its
// neighbours.

static void SmoothSegmentMap(VP8Encoder* const enc) {
  int n, x, y;
  const int w = enc->mb_w_;
  const int h = enc->mb_h_;
  const int majority_cnt_3_x_3_grid = 5;
  uint8_t* const tmp = (uint8_t*)WebPSafeMalloc(w * h, sizeof(*tmp));
  assert((uint64_t)(w * h) == (uint64_t)w * h);   // no overflow, as per spec

  if (tmp == NULL) return;
  for (y = 1; y < h - 1; ++y) {
    for (x = 1; x < w - 1; ++x) {
      int cnt[NUM_MB_SEGMENTS] = { 0 };
      const VP8MBInfo* const mb = &enc->mb_info_[x + w * y];
      int majority_seg = mb->segment_;
      // Check the 8 neighbouring segment values.
      cnt[mb[-w - 1].segment_]++;  // top-left
      cnt[mb[-w + 0].segment_]++;  // top
      cnt[mb[-w + 1].segment_]++;  // top-right
      cnt[mb[   - 1].segment_]++;  // left
      cnt[mb[   + 1].segment_]++;  // right
      cnt[mb[ w - 1].segment_]++;  // bottom-left
      cnt[mb[ w + 0].segment_]++;  // bottom
      cnt[mb[ w + 1].segment_]++;  // bottom-right
      for (n = 0; n < NUM_MB_SEGMENTS; ++n) {
        if (cnt[n] >= majority_cnt_3_x_3_grid) {
          majority_seg = n;
          break;
        }
      }
      tmp[x + y * w] = majority_seg;
    }
  }
  for (y = 1; y < h - 1; ++y) {
    for (x = 1; x < w - 1; ++x) {
      VP8MBInfo* const mb = &enc->mb_info_[x + w * y];
      mb->segment_ = tmp[x + y * w];
    }
  }
  WebPSafeFree(tmp);
}

//------------------------------------------------------------------------------
// set segment susceptibility alpha_ / beta_

static WEBP_INLINE int clip(int v, int m, int M) {
  return (v < m) ? m : (v > M) ? M : v;
}

static void SetSegmentAlphas(VP8Encoder* const enc,
                             const int centers[NUM_MB_SEGMENTS],
                             int mid) {
  const int nb = enc->segment_hdr_.num_segments_;
  int min = centers[0], max = centers[0];
  int n;

  if (nb > 1) {
    for (n = 0; n < nb; ++n) {
      if (min > centers[n]) min = centers[n];
      if (max < centers[n]) max = centers[n];
    }
  }
  if (max == min) max = min + 1;
  assert(mid <= max && mid >= min);
  for (n = 0; n < nb; ++n) {
    const int alpha = 255 * (centers[n] - mid) / (max - min);
    const int beta = 255 * (centers[n] - min) / (max - min);
    enc->dqm_[n].alpha_ = clip(alpha, -127, 127);
    enc->dqm_[n].beta_ = clip(beta, 0, 255);
  }
}

//------------------------------------------------------------------------------
// Compute susceptibility based on DCT-coeff histograms:
// the higher, the "easier" the macroblock is to compress.

#define MAX_ALPHA 255                // 8b of precision for susceptibilities.
#define ALPHA_SCALE (2 * MAX_ALPHA)  // scaling factor for alpha.
#define DEFAULT_ALPHA (-1)
#define IS_BETTER_ALPHA(alpha, best_alpha) ((alpha) > (best_alpha))

static int FinalAlphaValue(int alpha) {
  alpha = MAX_ALPHA - alpha;
  return clip(alpha, 0, MAX_ALPHA);
}

static int GetAlpha(const VP8Histogram* const histo) {
  // 'alpha' will later be clipped to [0..MAX_ALPHA] range, clamping outer
  // values which happen to be mostly noise. This leaves the maximum precision
  // for handling the useful small values which contribute most.
  const int max_value = histo->max_value;
  const int last_non_zero = histo->last_non_zero;
  const int alpha =
      (max_value > 1) ? ALPHA_SCALE * last_non_zero / max_value : 0;
  return alpha;
}

static void InitHistogram(VP8Histogram* const histo) {
  histo->max_value = 0;
  histo->last_non_zero = 1;
}

static void MergeHistograms(const VP8Histogram* const in,
                            VP8Histogram* const out) {
  if (in->max_value > out->max_value) {
    out->max_value = in->max_value;
  }
  if (in->last_non_zero > out->last_non_zero) {
    out->last_non_zero = in->last_non_zero;
  }
}

//------------------------------------------------------------------------------
// Simplified k-Means, to assign Nb segments based on alpha-histogram

static void AssignSegments(VP8Encoder* const enc,
                           const int alphas[MAX_ALPHA + 1]) {
  // 'num_segments_' is previously validated and <= NUM_MB_SEGMENTS, but an
  // explicit check is needed to avoid spurious warning about 'n + 1' exceeding
  // array bounds of 'centers' with some compilers (noticed with gcc-4.9).
  const int nb = (enc->segment_hdr_.num_segments_ < NUM_MB_SEGMENTS) ?
                 enc->segment_hdr_.num_segments_ : NUM_MB_SEGMENTS;
  int centers[NUM_MB_SEGMENTS];
  int weighted_average = 0;
  int map[MAX_ALPHA + 1];
  int a, n, k;
  int min_a = 0, max_a = MAX_ALPHA, range_a;
  // 'int' type is ok for histo, and won't overflow
  int accum[NUM_MB_SEGMENTS], dist_accum[NUM_MB_SEGMENTS];

  assert(nb >= 1);
  assert(nb <= NUM_MB_SEGMENTS);

  // bracket the input
  for (n = 0; n <= MAX_ALPHA && alphas[n] == 0; ++n) {}
  min_a = n;
  for (n = MAX_ALPHA; n > min_a && alphas[n] == 0; --n) {}
  max_a = n;
  range_a = max_a - min_a;

  // Spread initial centers evenly
  for (k = 0, n = 1; k < nb; ++k, n += 2) {
    assert(n < 2 * nb);
    centers[k] = min_a + (n * range_a) / (2 * nb);
  }

  for (k = 0; k < MAX_ITERS_K_MEANS; ++k) {     // few iters are enough
    int total_weight;
    int displaced;
    // Reset stats
    for (n = 0; n < nb; ++n) {
      accum[n] = 0;
      dist_accum[n] = 0;
    }
    // Assign nearest center for each 'a'
    n = 0;    // track the nearest center for current 'a'
    for (a = min_a; a <= max_a; ++a) {
      if (alphas[a]) {
        while (n + 1 < nb && abs(a - centers[n + 1]) < abs(a - centers[n])) {
          n++;
        }
        map[a] = n;
        // accumulate contribution into best centroid
        dist_accum[n] += a * alphas[a];
        accum[n] += alphas[a];
      }
    }
    // All point are classified. Move the centroids to the
    // center of their respective cloud.
    displaced = 0;
    weighted_average = 0;
    total_weight = 0;
    for (n = 0; n < nb; ++n) {
      if (accum[n]) {
        const int new_center = (dist_accum[n] + accum[n] / 2) / accum[n];
        displaced += abs(centers[n] - new_center);
        centers[n] = new_center;
        weighted_average += new_center * accum[n];
        total_weight += accum[n];
      }
    }
    weighted_average = (weighted_average + total_weight / 2) / total_weight;
    if (displaced < 5) break;   // no need to keep on looping...
  }

  // Map each original value to the closest centroid
  for (n = 0; n < enc->mb_w_ * enc->mb_h_; ++n) {
    VP8MBInfo* const mb = &enc->mb_info_[n];
    const int alpha = mb->alpha_;
    mb->segment_ = map[alpha];
    mb->alpha_ = centers[map[alpha]];  // for the record.
  }

  if (nb > 1) {
    const int smooth = (enc->config_->preprocessing & 1);
    if (smooth) SmoothSegmentMap(enc);
  }

  SetSegmentAlphas(enc, centers, weighted_average);  // pick some alphas.
}

//------------------------------------------------------------------------------
// Macroblock analysis: collect histogram for each mode, deduce the maximal
// susceptibility and set best modes for this macroblock.
// Segment assignment is done later.

// Number of modes to inspect for alpha_ evaluation. We don't need to test all
// the possible modes during the analysis phase: we risk falling into a local
// optimum, or be subject to boundary effect
#define MAX_INTRA16_MODE 2
#define MAX_INTRA4_MODE  2
#define MAX_UV_MODE      2

static int MBAnalyzeBestIntra16Mode(VP8EncIterator* const it) {
  const int max_mode = MAX_INTRA16_MODE;
  int mode;
  int best_alpha = DEFAULT_ALPHA;
  int best_mode = 0;

  VP8MakeLuma16Preds(it);
  for (mode = 0; mode < max_mode; ++mode) {
    VP8Histogram histo;
    int alpha;

    InitHistogram(&histo);
    VP8CollectHistogram(it->yuv_in_ + Y_OFF_ENC,
                        it->yuv_p_ + VP8I16ModeOffsets[mode],
                        0, 16, &histo);
    alpha = GetAlpha(&histo);
    if (IS_BETTER_ALPHA(alpha, best_alpha)) {
      best_alpha = alpha;
      best_mode = mode;
    }
  }
  VP8SetIntra16Mode(it, best_mode);
  return best_alpha;
}

static int FastMBAnalyze(VP8EncIterator* const it) {
  // Empirical cut-off value, should be around 16 (~=block size). We use the
  // [8-17] range and favor intra4 at high quality, intra16 for low quality.
  const int q = (int)it->enc_->config_->quality;
  const uint32_t kThreshold = 8 + (17 - 8) * q / 100;
  int k;
  uint32_t dc[16], m, m2;
  for (k = 0; k < 16; k += 4) {
    VP8Mean16x4(it->yuv_in_ + Y_OFF_ENC + k * BPS, &dc[k]);
  }
  for (m = 0, m2 = 0, k = 0; k < 16; ++k) {
    m += dc[k];
    m2 += dc[k] * dc[k];
  }
  if (kThreshold * m2 < m * m) {
    VP8SetIntra16Mode(it, 0);   // DC16
  } else {
    const uint8_t modes[16] = { 0 };  // DC4
    VP8SetIntra4Mode(it, modes);
  }
  return 0;
}

static int MBAnalyzeBestIntra4Mode(VP8EncIterator* const it,
                                   int best_alpha) {
  uint8_t modes[16];
  const int max_mode = MAX_INTRA4_MODE;
  int i4_alpha;
  VP8Histogram total_histo;
  int cur_histo = 0;
  InitHistogram(&total_histo);

  VP8IteratorStartI4(it);
  do {
    int mode;
    int best_mode_alpha = DEFAULT_ALPHA;
    VP8Histogram histos[2];
    const uint8_t* const src = it->yuv_in_ + Y_OFF_ENC + VP8Scan[it->i4_];

    VP8MakeIntra4Preds(it);
    for (mode = 0; mode < max_mode; ++mode) {
      int alpha;

      InitHistogram(&histos[cur_histo]);
      VP8CollectHistogram(src, it->yuv_p_ + VP8I4ModeOffsets[mode],
                          0, 1, &histos[cur_histo]);
      alpha = GetAlpha(&histos[cur_histo]);
      if (IS_BETTER_ALPHA(alpha, best_mode_alpha)) {
        best_mode_alpha = alpha;
        modes[it->i4_] = mode;
        cur_histo ^= 1;   // keep track of best histo so far.
      }
    }
    // accumulate best histogram
    MergeHistograms(&histos[cur_histo ^ 1], &total_histo);
    // Note: we reuse the original samples for predictors
  } while (VP8IteratorRotateI4(it, it->yuv_in_ + Y_OFF_ENC));

  i4_alpha = GetAlpha(&total_histo);
  if (IS_BETTER_ALPHA(i4_alpha, best_alpha)) {
    VP8SetIntra4Mode(it, modes);
    best_alpha = i4_alpha;
  }
  return best_alpha;
}

static int MBAnalyzeBestUVMode(VP8EncIterator* const it) {
  int best_alpha = DEFAULT_ALPHA;
  int smallest_alpha = 0;
  int best_mode = 0;
  const int max_mode = MAX_UV_MODE;
  int mode;

  VP8MakeChroma8Preds(it);
  for (mode = 0; mode < max_mode; ++mode) {
    VP8Histogram histo;
    int alpha;
    InitHistogram(&histo);
    VP8CollectHistogram(it->yuv_in_ + U_OFF_ENC,
                        it->yuv_p_ + VP8UVModeOffsets[mode],
                        16, 16 + 4 + 4, &histo);
    alpha = GetAlpha(&histo);
    if (IS_BETTER_ALPHA(alpha, best_alpha)) {
      best_alpha = alpha;
    }
    // The best prediction mode tends to be the one with the smallest alpha.
    if (mode == 0 || alpha < smallest_alpha) {
      smallest_alpha = alpha;
      best_mode = mode;
    }
  }
  VP8SetIntraUVMode(it, best_mode);
  return best_alpha;
}

static void MBAnalyze(VP8EncIterator* const it,
                      int alphas[MAX_ALPHA + 1],
                      int* const alpha, int* const uv_alpha) {
  const VP8Encoder* const enc = it->enc_;
  int best_alpha, best_uv_alpha;

  VP8SetIntra16Mode(it, 0);  // default: Intra16, DC_PRED
  VP8SetSkip(it, 0);         // not skipped
  VP8SetSegment(it, 0);      // default segment, spec-wise.

  if (enc->method_ <= 1) {
    best_alpha = FastMBAnalyze(it);
  } else {
    best_alpha = MBAnalyzeBestIntra16Mode(it);
    if (enc->method_ >= 5) {
      // We go and make a fast decision for intra4/intra16.
      // It's usually not a good and definitive pick, but helps seeding the
      // stats about level bit-cost.
      // TODO(skal): improve criterion.
      best_alpha = MBAnalyzeBestIntra4Mode(it, best_alpha);
    }
  }
  best_uv_alpha = MBAnalyzeBestUVMode(it);

  // Final susceptibility mix
  best_alpha = (3 * best_alpha + best_uv_alpha + 2) >> 2;
  best_alpha = FinalAlphaValue(best_alpha);
  alphas[best_alpha]++;
  it->mb_->alpha_ = best_alpha;   // for later remapping.

  // Accumulate for later complexity analysis.
  *alpha += best_alpha;   // mixed susceptibility (not just luma)
  *uv_alpha += best_uv_alpha;
}

static void DefaultMBInfo(VP8MBInfo* const mb) {
  mb->type_ = 1;     // I16x16
  mb->uv_mode_ = 0;
  mb->skip_ = 0;     // not skipped
  mb->segment_ = 0;  // default segment
  mb->alpha_ = 0;
}

//------------------------------------------------------------------------------
// Main analysis loop:
// Collect all susceptibilities for each macroblock and record their
// distribution in alphas[]. Segments is assigned a-posteriori, based on
// this histogram.
// We also pick an intra16 prediction mode, which shouldn't be considered
// final except for fast-encode settings. We can also pick some intra4 modes
// and decide intra4/intra16, but that's usually almost always a bad choice at
// this stage.

static void ResetAllMBInfo(VP8Encoder* const enc) {
  int n;
  for (n = 0; n < enc->mb_w_ * enc->mb_h_; ++n) {
    DefaultMBInfo(&enc->mb_info_[n]);
  }
  // Default susceptibilities.
  enc->dqm_[0].alpha_ = 0;
  enc->dqm_[0].beta_ = 0;
  // Note: we can't compute this alpha_ / uv_alpha_ -> set to default value.
  enc->alpha_ = 0;
  enc->uv_alpha_ = 0;
  WebPReportProgress(enc->pic_, enc->percent_ + 20, &enc->percent_);
}

// struct used to collect job result
typedef struct {
  WebPWorker worker;
  int alphas[MAX_ALPHA + 1];
  int alpha, uv_alpha;
  VP8EncIterator it;
  int delta_progress;
} SegmentJob;

// main work call
static int DoSegmentsJob(SegmentJob* const job, VP8EncIterator* const it) {
  int ok = 1;
  if (!VP8IteratorIsDone(it)) {
    uint8_t tmp[32 + WEBP_ALIGN_CST];
    uint8_t* const scratch = (uint8_t*)WEBP_ALIGN(tmp);
    do {
      // Let's pretend we have perfect lossless reconstruction.
      VP8IteratorImport(it, scratch);
      MBAnalyze(it, job->alphas, &job->alpha, &job->uv_alpha);
      ok = VP8IteratorProgress(it, job->delta_progress);
    } while (ok && VP8IteratorNext(it));
  }
  return ok;
}

static void MergeJobs(const SegmentJob* const src, SegmentJob* const dst) {
  int i;
  for (i = 0; i <= MAX_ALPHA; ++i) dst->alphas[i] += src->alphas[i];
  dst->alpha += src->alpha;
  dst->uv_alpha += src->uv_alpha;
}

// initialize the job struct with some TODOs
static void InitSegmentJob(VP8Encoder* const enc, SegmentJob* const job,
                           int start_row, int end_row) {
  WebPGetWorkerInterface()->Init(&job->worker);
  job->worker.data1 = job;
  job->worker.data2 = &job->it;
  job->worker.hook = (WebPWorkerHook)DoSegmentsJob;
  VP8IteratorInit(enc, &job->it);
  VP8IteratorSetRow(&job->it, start_row);
  VP8IteratorSetCountDown(&job->it, (end_row - start_row) * enc->mb_w_);
  memset(job->alphas, 0, sizeof(job->alphas));
  job->alpha = 0;
  job->uv_alpha = 0;
  // only one of both jobs can record the progress, since we don't
  // expect the user's hook to be multi-thread safe
  job->delta_progress = (start_row == 0) ? 20 : 0;
}

// main entry point
int VP8EncAnalyze(VP8Encoder* const enc) {
  int ok = 1;
  const int do_segments =
      enc->config_->emulate_jpeg_size ||   // We need the complexity evaluation.
      (enc->segment_hdr_.num_segments_ > 1) ||
      (enc->method_ <= 1);  // for method 0 - 1, we need preds_[] to be filled.
  if (do_segments) {
    const int last_row = enc->mb_h_;
    // We give a little more than a half work to the main thread.
    const int split_row = (9 * last_row + 15) >> 4;
    const int total_mb = last_row * enc->mb_w_;
#ifdef WEBP_USE_THREAD
    const int kMinSplitRow = 2;  // minimal rows needed for mt to be worth it
    const int do_mt = (enc->thread_level_ > 0) && (split_row >= kMinSplitRow);
#else
    const int do_mt = 0;
#endif
    const WebPWorkerInterface* const worker_interface =
        WebPGetWorkerInterface();
    SegmentJob main_job;
    if (do_mt) {
      SegmentJob side_job;
      // Note the use of '&' instead of '&&' because we must call the functions
      // no matter what.
      InitSegmentJob(enc, &main_job, 0, split_row);
      InitSegmentJob(enc, &side_job, split_row, last_row);
      // we don't need to call Reset() on main_job.worker, since we're calling
      // WebPWorkerExecute() on it
      ok &= worker_interface->Reset(&side_job.worker);
      // launch the two jobs in parallel
      if (ok) {
        worker_interface->Launch(&side_job.worker);
        worker_interface->Execute(&main_job.worker);
        ok &= worker_interface->Sync(&side_job.worker);
        ok &= worker_interface->Sync(&main_job.worker);
      }
      worker_interface->End(&side_job.worker);
      if (ok) MergeJobs(&side_job, &main_job);  // merge results together
    } else {
      // Even for single-thread case, we use the generic Worker tools.
      InitSegmentJob(enc, &main_job, 0, last_row);
      worker_interface->Execute(&main_job.worker);
      ok &= worker_interface->Sync(&main_job.worker);
    }
    worker_interface->End(&main_job.worker);
    if (ok) {
      enc->alpha_ = main_job.alpha / total_mb;
      enc->uv_alpha_ = main_job.uv_alpha / total_mb;
      AssignSegments(enc, main_job.alphas);
    }
  } else {   // Use only one default segment.
    ResetAllMBInfo(enc);
  }
  return ok;
}