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Issue 1040513003: VAVDA: Use the new, generic video decoder and accelerator infrastructure. (Closed) Base URL: https://chromium.googlesource.com/chromium/src.git@master
Patch Set: rebase Created 5 years, 8 months ago
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1 // Copyright (c) 2012 The Chromium Authors. All rights reserved.
2 // Use of this source code is governed by a BSD-style license that can be
3 // found in the LICENSE file.
4
5 #include <algorithm>
6 #include <limits>
7
8 #include "base/bind.h"
9 #include "base/bind_helpers.h"
10 #include "base/numerics/safe_conversions.h"
11 #include "base/stl_util.h"
12 #include "content/common/gpu/media/vaapi_h264_decoder.h"
13
14 namespace content {
15
16 // Decode surface, used for decoding and reference. input_id comes from client
17 // and is associated with the surface that was produced as the result
18 // of decoding a bitstream buffer with that id.
19 class VaapiH264Decoder::DecodeSurface {
20 public:
21 DecodeSurface(int poc,
22 int32 input_id,
23 const scoped_refptr<VASurface>& va_surface);
24 DecodeSurface(int poc, const scoped_refptr<DecodeSurface>& dec_surface);
25 ~DecodeSurface();
26
27 int poc() {
28 return poc_;
29 }
30
31 scoped_refptr<VASurface> va_surface() {
32 return va_surface_;
33 }
34
35 int32 input_id() {
36 return input_id_;
37 }
38
39 private:
40 int poc_;
41 int32 input_id_;
42 scoped_refptr<VASurface> va_surface_;
43 };
44
45 VaapiH264Decoder::DecodeSurface::DecodeSurface(
46 int poc,
47 int32 input_id,
48 const scoped_refptr<VASurface>& va_surface)
49 : poc_(poc),
50 input_id_(input_id),
51 va_surface_(va_surface) {
52 DCHECK(va_surface_.get());
53 }
54
55 VaapiH264Decoder::DecodeSurface::~DecodeSurface() {
56 }
57
58 VaapiH264Decoder::VaapiH264Decoder(
59 VaapiWrapper* vaapi_wrapper,
60 const OutputPicCB& output_pic_cb,
61 const ReportErrorToUmaCB& report_error_to_uma_cb)
62 : max_pic_order_cnt_lsb_(0),
63 max_frame_num_(0),
64 max_pic_num_(0),
65 max_long_term_frame_idx_(0),
66 max_num_reorder_frames_(0),
67 curr_sps_id_(-1),
68 curr_pps_id_(-1),
69 vaapi_wrapper_(vaapi_wrapper),
70 output_pic_cb_(output_pic_cb),
71 report_error_to_uma_cb_(report_error_to_uma_cb) {
72 Reset();
73 state_ = kNeedStreamMetadata;
74 }
75
76 VaapiH264Decoder::~VaapiH264Decoder() {
77 }
78
79 void VaapiH264Decoder::Reset() {
80 curr_pic_.reset();
81
82 curr_input_id_ = -1;
83 frame_num_ = 0;
84 prev_frame_num_ = -1;
85 prev_frame_num_offset_ = -1;
86
87 prev_ref_has_memmgmnt5_ = false;
88 prev_ref_top_field_order_cnt_ = -1;
89 prev_ref_pic_order_cnt_msb_ = -1;
90 prev_ref_pic_order_cnt_lsb_ = -1;
91 prev_ref_field_ = VaapiH264Picture::FIELD_NONE;
92
93 vaapi_wrapper_->DestroyPendingBuffers();
94
95 ref_pic_list0_.clear();
96 ref_pic_list1_.clear();
97
98 for (DecSurfacesInUse::iterator it = decode_surfaces_in_use_.begin();
99 it != decode_surfaces_in_use_.end(); ) {
100 int poc = it->second->poc();
101 // Must be incremented before UnassignSurfaceFromPoC as this call
102 // invalidates |it|.
103 ++it;
104 UnassignSurfaceFromPoC(poc);
105 }
106 DCHECK(decode_surfaces_in_use_.empty());
107
108 dpb_.Clear();
109 parser_.Reset();
110 last_output_poc_ = std::numeric_limits<int>::min();
111
112 // If we are in kDecoding, we can resume without processing an SPS.
113 if (state_ == kDecoding)
114 state_ = kAfterReset;
115 }
116
117 void VaapiH264Decoder::ReuseSurface(
118 const scoped_refptr<VASurface>& va_surface) {
119 available_va_surfaces_.push_back(va_surface);
120 }
121
122 // Fill |va_pic| with default/neutral values.
123 static void InitVAPicture(VAPictureH264* va_pic) {
124 memset(va_pic, 0, sizeof(*va_pic));
125 va_pic->picture_id = VA_INVALID_ID;
126 va_pic->flags = VA_PICTURE_H264_INVALID;
127 }
128
129 void VaapiH264Decoder::FillVAPicture(VAPictureH264* va_pic,
130 VaapiH264Picture* pic) {
131 DCHECK(pic);
132
133 DecodeSurface* dec_surface = DecodeSurfaceByPoC(pic->pic_order_cnt);
134 if (!dec_surface) {
135 // Cannot provide a ref picture, will corrupt output, but may be able
136 // to recover.
137 InitVAPicture(va_pic);
138 return;
139 }
140
141 va_pic->picture_id = dec_surface->va_surface()->id();
142 va_pic->frame_idx = pic->frame_num;
143 va_pic->flags = 0;
144
145 switch (pic->field) {
146 case VaapiH264Picture::FIELD_NONE:
147 break;
148 case VaapiH264Picture::FIELD_TOP:
149 va_pic->flags |= VA_PICTURE_H264_TOP_FIELD;
150 break;
151 case VaapiH264Picture::FIELD_BOTTOM:
152 va_pic->flags |= VA_PICTURE_H264_BOTTOM_FIELD;
153 break;
154 }
155
156 if (pic->ref) {
157 va_pic->flags |= pic->long_term ? VA_PICTURE_H264_LONG_TERM_REFERENCE
158 : VA_PICTURE_H264_SHORT_TERM_REFERENCE;
159 }
160
161 va_pic->TopFieldOrderCnt = pic->top_field_order_cnt;
162 va_pic->BottomFieldOrderCnt = pic->bottom_field_order_cnt;
163 }
164
165 int VaapiH264Decoder::FillVARefFramesFromDPB(VAPictureH264 *va_pics,
166 int num_pics) {
167 VaapiH264DPB::Pictures::reverse_iterator rit;
168 int i;
169
170 // Return reference frames in reverse order of insertion.
171 // Libva does not document this, but other implementations (e.g. mplayer)
172 // do it this way as well.
173 for (rit = dpb_.rbegin(), i = 0; rit != dpb_.rend() && i < num_pics; ++rit) {
174 if ((*rit)->ref)
175 FillVAPicture(&va_pics[i++], *rit);
176 }
177
178 return i;
179 }
180
181 VaapiH264Decoder::DecodeSurface* VaapiH264Decoder::DecodeSurfaceByPoC(int poc) {
182 DecSurfacesInUse::iterator iter = decode_surfaces_in_use_.find(poc);
183 if (iter == decode_surfaces_in_use_.end()) {
184 DVLOG(1) << "Could not find surface assigned to POC: " << poc;
185 return NULL;
186 }
187
188 return iter->second.get();
189 }
190
191 bool VaapiH264Decoder::AssignSurfaceToPoC(int32 input_id, int poc) {
192 if (available_va_surfaces_.empty()) {
193 DVLOG(1) << "No VA Surfaces available";
194 return false;
195 }
196
197 linked_ptr<DecodeSurface> dec_surface(new DecodeSurface(
198 poc, input_id, available_va_surfaces_.back()));
199 available_va_surfaces_.pop_back();
200
201 DVLOG(4) << "POC " << poc
202 << " will use surface " << dec_surface->va_surface()->id();
203
204 bool inserted = decode_surfaces_in_use_.insert(
205 std::make_pair(poc, dec_surface)).second;
206 DCHECK(inserted);
207
208 return true;
209 }
210
211 void VaapiH264Decoder::UnassignSurfaceFromPoC(int poc) {
212 DecSurfacesInUse::iterator it = decode_surfaces_in_use_.find(poc);
213 if (it == decode_surfaces_in_use_.end()) {
214 DVLOG(1) << "Asked to unassign an unassigned POC " << poc;
215 return;
216 }
217
218 DVLOG(4) << "POC " << poc << " no longer using VA surface "
219 << it->second->va_surface()->id();
220
221 decode_surfaces_in_use_.erase(it);
222 }
223
224 bool VaapiH264Decoder::SendPPS() {
225 const media::H264PPS* pps = parser_.GetPPS(curr_pps_id_);
226 DCHECK(pps);
227
228 const media::H264SPS* sps = parser_.GetSPS(pps->seq_parameter_set_id);
229 DCHECK(sps);
230
231 DCHECK(curr_pic_.get());
232
233 VAPictureParameterBufferH264 pic_param;
234 memset(&pic_param, 0, sizeof(VAPictureParameterBufferH264));
235
236 #define FROM_SPS_TO_PP(a) pic_param.a = sps->a;
237 #define FROM_SPS_TO_PP2(a, b) pic_param.b = sps->a;
238 FROM_SPS_TO_PP2(pic_width_in_mbs_minus1, picture_width_in_mbs_minus1);
239 // This assumes non-interlaced video
240 FROM_SPS_TO_PP2(pic_height_in_map_units_minus1,
241 picture_height_in_mbs_minus1);
242 FROM_SPS_TO_PP(bit_depth_luma_minus8);
243 FROM_SPS_TO_PP(bit_depth_chroma_minus8);
244 #undef FROM_SPS_TO_PP
245 #undef FROM_SPS_TO_PP2
246
247 #define FROM_SPS_TO_PP_SF(a) pic_param.seq_fields.bits.a = sps->a;
248 #define FROM_SPS_TO_PP_SF2(a, b) pic_param.seq_fields.bits.b = sps->a;
249 FROM_SPS_TO_PP_SF(chroma_format_idc);
250 FROM_SPS_TO_PP_SF2(separate_colour_plane_flag,
251 residual_colour_transform_flag);
252 FROM_SPS_TO_PP_SF(gaps_in_frame_num_value_allowed_flag);
253 FROM_SPS_TO_PP_SF(frame_mbs_only_flag);
254 FROM_SPS_TO_PP_SF(mb_adaptive_frame_field_flag);
255 FROM_SPS_TO_PP_SF(direct_8x8_inference_flag);
256 pic_param.seq_fields.bits.MinLumaBiPredSize8x8 = (sps->level_idc >= 31);
257 FROM_SPS_TO_PP_SF(log2_max_frame_num_minus4);
258 FROM_SPS_TO_PP_SF(pic_order_cnt_type);
259 FROM_SPS_TO_PP_SF(log2_max_pic_order_cnt_lsb_minus4);
260 FROM_SPS_TO_PP_SF(delta_pic_order_always_zero_flag);
261 #undef FROM_SPS_TO_PP_SF
262 #undef FROM_SPS_TO_PP_SF2
263
264 #define FROM_PPS_TO_PP(a) pic_param.a = pps->a;
265 FROM_PPS_TO_PP(num_slice_groups_minus1);
266 pic_param.slice_group_map_type = 0;
267 pic_param.slice_group_change_rate_minus1 = 0;
268 FROM_PPS_TO_PP(pic_init_qp_minus26);
269 FROM_PPS_TO_PP(pic_init_qs_minus26);
270 FROM_PPS_TO_PP(chroma_qp_index_offset);
271 FROM_PPS_TO_PP(second_chroma_qp_index_offset);
272 #undef FROM_PPS_TO_PP
273
274 #define FROM_PPS_TO_PP_PF(a) pic_param.pic_fields.bits.a = pps->a;
275 #define FROM_PPS_TO_PP_PF2(a, b) pic_param.pic_fields.bits.b = pps->a;
276 FROM_PPS_TO_PP_PF(entropy_coding_mode_flag);
277 FROM_PPS_TO_PP_PF(weighted_pred_flag);
278 FROM_PPS_TO_PP_PF(weighted_bipred_idc);
279 FROM_PPS_TO_PP_PF(transform_8x8_mode_flag);
280
281 pic_param.pic_fields.bits.field_pic_flag = 0;
282 FROM_PPS_TO_PP_PF(constrained_intra_pred_flag);
283 FROM_PPS_TO_PP_PF2(bottom_field_pic_order_in_frame_present_flag,
284 pic_order_present_flag);
285 FROM_PPS_TO_PP_PF(deblocking_filter_control_present_flag);
286 FROM_PPS_TO_PP_PF(redundant_pic_cnt_present_flag);
287 pic_param.pic_fields.bits.reference_pic_flag = curr_pic_->ref;
288 #undef FROM_PPS_TO_PP_PF
289 #undef FROM_PPS_TO_PP_PF2
290
291 pic_param.frame_num = curr_pic_->frame_num;
292
293 InitVAPicture(&pic_param.CurrPic);
294 FillVAPicture(&pic_param.CurrPic, curr_pic_.get());
295
296 // Init reference pictures' array.
297 for (int i = 0; i < 16; ++i)
298 InitVAPicture(&pic_param.ReferenceFrames[i]);
299
300 // And fill it with picture info from DPB.
301 FillVARefFramesFromDPB(pic_param.ReferenceFrames,
302 arraysize(pic_param.ReferenceFrames));
303
304 pic_param.num_ref_frames = sps->max_num_ref_frames;
305
306 return vaapi_wrapper_->SubmitBuffer(VAPictureParameterBufferType,
307 sizeof(VAPictureParameterBufferH264),
308 &pic_param);
309 }
310
311 bool VaapiH264Decoder::SendIQMatrix() {
312 const media::H264PPS* pps = parser_.GetPPS(curr_pps_id_);
313 DCHECK(pps);
314
315 VAIQMatrixBufferH264 iq_matrix_buf;
316 memset(&iq_matrix_buf, 0, sizeof(VAIQMatrixBufferH264));
317
318 if (pps->pic_scaling_matrix_present_flag) {
319 for (int i = 0; i < 6; ++i) {
320 for (int j = 0; j < 16; ++j)
321 iq_matrix_buf.ScalingList4x4[i][j] = pps->scaling_list4x4[i][j];
322 }
323
324 for (int i = 0; i < 2; ++i) {
325 for (int j = 0; j < 64; ++j)
326 iq_matrix_buf.ScalingList8x8[i][j] = pps->scaling_list8x8[i][j];
327 }
328 } else {
329 const media::H264SPS* sps = parser_.GetSPS(pps->seq_parameter_set_id);
330 DCHECK(sps);
331 for (int i = 0; i < 6; ++i) {
332 for (int j = 0; j < 16; ++j)
333 iq_matrix_buf.ScalingList4x4[i][j] = sps->scaling_list4x4[i][j];
334 }
335
336 for (int i = 0; i < 2; ++i) {
337 for (int j = 0; j < 64; ++j)
338 iq_matrix_buf.ScalingList8x8[i][j] = sps->scaling_list8x8[i][j];
339 }
340 }
341
342 return vaapi_wrapper_->SubmitBuffer(VAIQMatrixBufferType,
343 sizeof(VAIQMatrixBufferH264),
344 &iq_matrix_buf);
345 }
346
347 bool VaapiH264Decoder::SendVASliceParam(media::H264SliceHeader* slice_hdr) {
348 const media::H264PPS* pps = parser_.GetPPS(slice_hdr->pic_parameter_set_id);
349 DCHECK(pps);
350
351 const media::H264SPS* sps = parser_.GetSPS(pps->seq_parameter_set_id);
352 DCHECK(sps);
353
354 VASliceParameterBufferH264 slice_param;
355 memset(&slice_param, 0, sizeof(VASliceParameterBufferH264));
356
357 slice_param.slice_data_size = slice_hdr->nalu_size;
358 slice_param.slice_data_offset = 0;
359 slice_param.slice_data_flag = VA_SLICE_DATA_FLAG_ALL;
360 slice_param.slice_data_bit_offset = slice_hdr->header_bit_size;
361
362 #define SHDRToSP(a) slice_param.a = slice_hdr->a;
363 SHDRToSP(first_mb_in_slice);
364 slice_param.slice_type = slice_hdr->slice_type % 5;
365 SHDRToSP(direct_spatial_mv_pred_flag);
366
367 // TODO posciak: make sure parser sets those even when override flags
368 // in slice header is off.
369 SHDRToSP(num_ref_idx_l0_active_minus1);
370 SHDRToSP(num_ref_idx_l1_active_minus1);
371 SHDRToSP(cabac_init_idc);
372 SHDRToSP(slice_qp_delta);
373 SHDRToSP(disable_deblocking_filter_idc);
374 SHDRToSP(slice_alpha_c0_offset_div2);
375 SHDRToSP(slice_beta_offset_div2);
376
377 if (((slice_hdr->IsPSlice() || slice_hdr->IsSPSlice()) &&
378 pps->weighted_pred_flag) ||
379 (slice_hdr->IsBSlice() && pps->weighted_bipred_idc == 1)) {
380 SHDRToSP(luma_log2_weight_denom);
381 SHDRToSP(chroma_log2_weight_denom);
382
383 SHDRToSP(luma_weight_l0_flag);
384 SHDRToSP(luma_weight_l1_flag);
385
386 SHDRToSP(chroma_weight_l0_flag);
387 SHDRToSP(chroma_weight_l1_flag);
388
389 for (int i = 0; i <= slice_param.num_ref_idx_l0_active_minus1; ++i) {
390 slice_param.luma_weight_l0[i] =
391 slice_hdr->pred_weight_table_l0.luma_weight[i];
392 slice_param.luma_offset_l0[i] =
393 slice_hdr->pred_weight_table_l0.luma_offset[i];
394
395 for (int j = 0; j < 2; ++j) {
396 slice_param.chroma_weight_l0[i][j] =
397 slice_hdr->pred_weight_table_l0.chroma_weight[i][j];
398 slice_param.chroma_offset_l0[i][j] =
399 slice_hdr->pred_weight_table_l0.chroma_offset[i][j];
400 }
401 }
402
403 if (slice_hdr->IsBSlice()) {
404 for (int i = 0; i <= slice_param.num_ref_idx_l1_active_minus1; ++i) {
405 slice_param.luma_weight_l1[i] =
406 slice_hdr->pred_weight_table_l1.luma_weight[i];
407 slice_param.luma_offset_l1[i] =
408 slice_hdr->pred_weight_table_l1.luma_offset[i];
409
410 for (int j = 0; j < 2; ++j) {
411 slice_param.chroma_weight_l1[i][j] =
412 slice_hdr->pred_weight_table_l1.chroma_weight[i][j];
413 slice_param.chroma_offset_l1[i][j] =
414 slice_hdr->pred_weight_table_l1.chroma_offset[i][j];
415 }
416 }
417 }
418 }
419
420 for (int i = 0; i < 32; ++i) {
421 InitVAPicture(&slice_param.RefPicList0[i]);
422 InitVAPicture(&slice_param.RefPicList1[i]);
423 }
424
425 int i;
426 VaapiH264Picture::PtrVector::iterator it;
427 for (it = ref_pic_list0_.begin(), i = 0; it != ref_pic_list0_.end() && *it;
428 ++it, ++i)
429 FillVAPicture(&slice_param.RefPicList0[i], *it);
430 for (it = ref_pic_list1_.begin(), i = 0; it != ref_pic_list1_.end() && *it;
431 ++it, ++i)
432 FillVAPicture(&slice_param.RefPicList1[i], *it);
433
434 return vaapi_wrapper_->SubmitBuffer(VASliceParameterBufferType,
435 sizeof(VASliceParameterBufferH264),
436 &slice_param);
437 }
438
439 bool VaapiH264Decoder::SendSliceData(const uint8* ptr, size_t size) {
440 // Can't help it, blame libva...
441 void* non_const_ptr = const_cast<uint8*>(ptr);
442 return vaapi_wrapper_->SubmitBuffer(VASliceDataBufferType, size,
443 non_const_ptr);
444 }
445
446 bool VaapiH264Decoder::PrepareRefPicLists(media::H264SliceHeader* slice_hdr) {
447 ref_pic_list0_.clear();
448 ref_pic_list1_.clear();
449
450 // Fill reference picture lists for B and S/SP slices.
451 if (slice_hdr->IsPSlice() || slice_hdr->IsSPSlice()) {
452 ConstructReferencePicListsP(slice_hdr);
453 return ModifyReferencePicList(slice_hdr, 0);
454 }
455
456 if (slice_hdr->IsBSlice()) {
457 ConstructReferencePicListsB(slice_hdr);
458 return ModifyReferencePicList(slice_hdr, 0) &&
459 ModifyReferencePicList(slice_hdr, 1);
460 }
461
462 return true;
463 }
464
465 bool VaapiH264Decoder::QueueSlice(media::H264SliceHeader* slice_hdr) {
466 DCHECK(curr_pic_.get());
467
468 if (!PrepareRefPicLists(slice_hdr))
469 return false;
470
471 if (!SendVASliceParam(slice_hdr))
472 return false;
473
474 if (!SendSliceData(slice_hdr->nalu_data, slice_hdr->nalu_size))
475 return false;
476
477 return true;
478 }
479
480 // TODO(posciak) start using vaMapBuffer instead of vaCreateBuffer wherever
481 // possible.
482 bool VaapiH264Decoder::DecodePicture() {
483 DCHECK(curr_pic_.get());
484
485 DVLOG(4) << "Decoding POC " << curr_pic_->pic_order_cnt;
486 DecodeSurface* dec_surface = DecodeSurfaceByPoC(curr_pic_->pic_order_cnt);
487 if (!dec_surface) {
488 DVLOG(1) << "Asked to decode an invalid POC " << curr_pic_->pic_order_cnt;
489 return false;
490 }
491
492 if (!vaapi_wrapper_->ExecuteAndDestroyPendingBuffers(
493 dec_surface->va_surface()->id())) {
494 DVLOG(1) << "Failed decoding picture";
495 return false;
496 }
497
498 return true;
499 }
500
501 bool VaapiH264Decoder::InitCurrPicture(media::H264SliceHeader* slice_hdr) {
502 DCHECK(curr_pic_.get());
503
504 memset(curr_pic_.get(), 0, sizeof(VaapiH264Picture));
505
506 curr_pic_->idr = slice_hdr->idr_pic_flag;
507
508 if (slice_hdr->field_pic_flag) {
509 curr_pic_->field = slice_hdr->bottom_field_flag
510 ? VaapiH264Picture::FIELD_BOTTOM
511 : VaapiH264Picture::FIELD_TOP;
512 } else {
513 curr_pic_->field = VaapiH264Picture::FIELD_NONE;
514 }
515
516 curr_pic_->ref = slice_hdr->nal_ref_idc != 0;
517 // This assumes non-interlaced stream.
518 curr_pic_->frame_num = curr_pic_->pic_num = slice_hdr->frame_num;
519
520 if (!CalculatePicOrderCounts(slice_hdr))
521 return false;
522
523 // Try to get an empty surface to decode this picture to.
524 if (!AssignSurfaceToPoC(curr_input_id_, curr_pic_->pic_order_cnt)) {
525 DVLOG(1) << "Failed getting a free surface for a picture";
526 return false;
527 }
528
529 curr_pic_->long_term_reference_flag = slice_hdr->long_term_reference_flag;
530 curr_pic_->adaptive_ref_pic_marking_mode_flag =
531 slice_hdr->adaptive_ref_pic_marking_mode_flag;
532
533 // If the slice header indicates we will have to perform reference marking
534 // process after this picture is decoded, store required data for that
535 // purpose.
536 if (slice_hdr->adaptive_ref_pic_marking_mode_flag) {
537 static_assert(sizeof(curr_pic_->ref_pic_marking) ==
538 sizeof(slice_hdr->ref_pic_marking),
539 "ref_pic_marking array sizes do not match");
540 memcpy(curr_pic_->ref_pic_marking, slice_hdr->ref_pic_marking,
541 sizeof(curr_pic_->ref_pic_marking));
542 }
543
544 return true;
545 }
546
547 bool VaapiH264Decoder::CalculatePicOrderCounts(
548 media::H264SliceHeader* slice_hdr) {
549 DCHECK_NE(curr_sps_id_, -1);
550 const media::H264SPS* sps = parser_.GetSPS(curr_sps_id_);
551
552 int pic_order_cnt_lsb = slice_hdr->pic_order_cnt_lsb;
553 curr_pic_->pic_order_cnt_lsb = pic_order_cnt_lsb;
554
555 switch (sps->pic_order_cnt_type) {
556 case 0:
557 // See spec 8.2.1.1.
558 int prev_pic_order_cnt_msb, prev_pic_order_cnt_lsb;
559 if (slice_hdr->idr_pic_flag) {
560 prev_pic_order_cnt_msb = prev_pic_order_cnt_lsb = 0;
561 } else {
562 if (prev_ref_has_memmgmnt5_) {
563 if (prev_ref_field_ != VaapiH264Picture::FIELD_BOTTOM) {
564 prev_pic_order_cnt_msb = 0;
565 prev_pic_order_cnt_lsb = prev_ref_top_field_order_cnt_;
566 } else {
567 prev_pic_order_cnt_msb = 0;
568 prev_pic_order_cnt_lsb = 0;
569 }
570 } else {
571 prev_pic_order_cnt_msb = prev_ref_pic_order_cnt_msb_;
572 prev_pic_order_cnt_lsb = prev_ref_pic_order_cnt_lsb_;
573 }
574 }
575
576 DCHECK_NE(max_pic_order_cnt_lsb_, 0);
577 if ((pic_order_cnt_lsb < prev_pic_order_cnt_lsb) &&
578 (prev_pic_order_cnt_lsb - pic_order_cnt_lsb >=
579 max_pic_order_cnt_lsb_ / 2)) {
580 curr_pic_->pic_order_cnt_msb = prev_pic_order_cnt_msb +
581 max_pic_order_cnt_lsb_;
582 } else if ((pic_order_cnt_lsb > prev_pic_order_cnt_lsb) &&
583 (pic_order_cnt_lsb - prev_pic_order_cnt_lsb >
584 max_pic_order_cnt_lsb_ / 2)) {
585 curr_pic_->pic_order_cnt_msb = prev_pic_order_cnt_msb -
586 max_pic_order_cnt_lsb_;
587 } else {
588 curr_pic_->pic_order_cnt_msb = prev_pic_order_cnt_msb;
589 }
590
591 if (curr_pic_->field != VaapiH264Picture::FIELD_BOTTOM) {
592 curr_pic_->top_field_order_cnt = curr_pic_->pic_order_cnt_msb +
593 pic_order_cnt_lsb;
594 }
595
596 if (curr_pic_->field != VaapiH264Picture::FIELD_TOP) {
597 // TODO posciak: perhaps replace with pic->field?
598 if (!slice_hdr->field_pic_flag) {
599 curr_pic_->bottom_field_order_cnt = curr_pic_->top_field_order_cnt +
600 slice_hdr->delta_pic_order_cnt_bottom;
601 } else {
602 curr_pic_->bottom_field_order_cnt = curr_pic_->pic_order_cnt_msb +
603 pic_order_cnt_lsb;
604 }
605 }
606 break;
607
608 case 1: {
609 // See spec 8.2.1.2.
610 if (prev_has_memmgmnt5_)
611 prev_frame_num_offset_ = 0;
612
613 if (slice_hdr->idr_pic_flag)
614 curr_pic_->frame_num_offset = 0;
615 else if (prev_frame_num_ > slice_hdr->frame_num)
616 curr_pic_->frame_num_offset = prev_frame_num_offset_ + max_frame_num_;
617 else
618 curr_pic_->frame_num_offset = prev_frame_num_offset_;
619
620 int abs_frame_num = 0;
621 if (sps->num_ref_frames_in_pic_order_cnt_cycle != 0)
622 abs_frame_num = curr_pic_->frame_num_offset + slice_hdr->frame_num;
623 else
624 abs_frame_num = 0;
625
626 if (slice_hdr->nal_ref_idc == 0 && abs_frame_num > 0)
627 --abs_frame_num;
628
629 int expected_pic_order_cnt = 0;
630 if (abs_frame_num > 0) {
631 if (sps->num_ref_frames_in_pic_order_cnt_cycle == 0) {
632 DVLOG(1) << "Invalid num_ref_frames_in_pic_order_cnt_cycle "
633 << "in stream";
634 return false;
635 }
636
637 int pic_order_cnt_cycle_cnt = (abs_frame_num - 1) /
638 sps->num_ref_frames_in_pic_order_cnt_cycle;
639 int frame_num_in_pic_order_cnt_cycle = (abs_frame_num - 1) %
640 sps->num_ref_frames_in_pic_order_cnt_cycle;
641
642 expected_pic_order_cnt = pic_order_cnt_cycle_cnt *
643 sps->expected_delta_per_pic_order_cnt_cycle;
644 // frame_num_in_pic_order_cnt_cycle is verified < 255 in parser
645 for (int i = 0; i <= frame_num_in_pic_order_cnt_cycle; ++i)
646 expected_pic_order_cnt += sps->offset_for_ref_frame[i];
647 }
648
649 if (!slice_hdr->nal_ref_idc)
650 expected_pic_order_cnt += sps->offset_for_non_ref_pic;
651
652 if (!slice_hdr->field_pic_flag) {
653 curr_pic_->top_field_order_cnt = expected_pic_order_cnt +
654 slice_hdr->delta_pic_order_cnt0;
655 curr_pic_->bottom_field_order_cnt = curr_pic_->top_field_order_cnt +
656 sps->offset_for_top_to_bottom_field +
657 slice_hdr->delta_pic_order_cnt1;
658 } else if (!slice_hdr->bottom_field_flag) {
659 curr_pic_->top_field_order_cnt = expected_pic_order_cnt +
660 slice_hdr->delta_pic_order_cnt0;
661 } else {
662 curr_pic_->bottom_field_order_cnt = expected_pic_order_cnt +
663 sps->offset_for_top_to_bottom_field +
664 slice_hdr->delta_pic_order_cnt0;
665 }
666 break;
667 }
668
669 case 2:
670 // See spec 8.2.1.3.
671 if (prev_has_memmgmnt5_)
672 prev_frame_num_offset_ = 0;
673
674 if (slice_hdr->idr_pic_flag)
675 curr_pic_->frame_num_offset = 0;
676 else if (prev_frame_num_ > slice_hdr->frame_num)
677 curr_pic_->frame_num_offset = prev_frame_num_offset_ + max_frame_num_;
678 else
679 curr_pic_->frame_num_offset = prev_frame_num_offset_;
680
681 int temp_pic_order_cnt;
682 if (slice_hdr->idr_pic_flag) {
683 temp_pic_order_cnt = 0;
684 } else if (!slice_hdr->nal_ref_idc) {
685 temp_pic_order_cnt =
686 2 * (curr_pic_->frame_num_offset + slice_hdr->frame_num) - 1;
687 } else {
688 temp_pic_order_cnt = 2 * (curr_pic_->frame_num_offset +
689 slice_hdr->frame_num);
690 }
691
692 if (!slice_hdr->field_pic_flag) {
693 curr_pic_->top_field_order_cnt = temp_pic_order_cnt;
694 curr_pic_->bottom_field_order_cnt = temp_pic_order_cnt;
695 } else if (slice_hdr->bottom_field_flag) {
696 curr_pic_->bottom_field_order_cnt = temp_pic_order_cnt;
697 } else {
698 curr_pic_->top_field_order_cnt = temp_pic_order_cnt;
699 }
700 break;
701
702 default:
703 DVLOG(1) << "Invalid pic_order_cnt_type: " << sps->pic_order_cnt_type;
704 return false;
705 }
706
707 switch (curr_pic_->field) {
708 case VaapiH264Picture::FIELD_NONE:
709 curr_pic_->pic_order_cnt = std::min(curr_pic_->top_field_order_cnt,
710 curr_pic_->bottom_field_order_cnt);
711 break;
712 case VaapiH264Picture::FIELD_TOP:
713 curr_pic_->pic_order_cnt = curr_pic_->top_field_order_cnt;
714 break;
715 case VaapiH264Picture::FIELD_BOTTOM:
716 curr_pic_->pic_order_cnt = curr_pic_->bottom_field_order_cnt;
717 break;
718 }
719
720 return true;
721 }
722
723 void VaapiH264Decoder::UpdatePicNums() {
724 for (VaapiH264DPB::Pictures::iterator it = dpb_.begin(); it != dpb_.end();
725 ++it) {
726 VaapiH264Picture* pic = *it;
727 DCHECK(pic);
728 if (!pic->ref)
729 continue;
730
731 // Below assumes non-interlaced stream.
732 DCHECK_EQ(pic->field, VaapiH264Picture::FIELD_NONE);
733 if (pic->long_term) {
734 pic->long_term_pic_num = pic->long_term_frame_idx;
735 } else {
736 if (pic->frame_num > frame_num_)
737 pic->frame_num_wrap = pic->frame_num - max_frame_num_;
738 else
739 pic->frame_num_wrap = pic->frame_num;
740
741 pic->pic_num = pic->frame_num_wrap;
742 }
743 }
744 }
745
746 struct PicNumDescCompare {
747 bool operator()(const VaapiH264Picture* a, const VaapiH264Picture* b) const {
748 return a->pic_num > b->pic_num;
749 }
750 };
751
752 struct LongTermPicNumAscCompare {
753 bool operator()(const VaapiH264Picture* a, const VaapiH264Picture* b) const {
754 return a->long_term_pic_num < b->long_term_pic_num;
755 }
756 };
757
758 void VaapiH264Decoder::ConstructReferencePicListsP(
759 media::H264SliceHeader* slice_hdr) {
760 // RefPicList0 (8.2.4.2.1) [[1] [2]], where:
761 // [1] shortterm ref pics sorted by descending pic_num,
762 // [2] longterm ref pics by ascending long_term_pic_num.
763 DCHECK(ref_pic_list0_.empty() && ref_pic_list1_.empty());
764 // First get the short ref pics...
765 dpb_.GetShortTermRefPicsAppending(ref_pic_list0_);
766 size_t num_short_refs = ref_pic_list0_.size();
767
768 // and sort them to get [1].
769 std::sort(ref_pic_list0_.begin(), ref_pic_list0_.end(), PicNumDescCompare());
770
771 // Now get long term pics and sort them by long_term_pic_num to get [2].
772 dpb_.GetLongTermRefPicsAppending(ref_pic_list0_);
773 std::sort(ref_pic_list0_.begin() + num_short_refs, ref_pic_list0_.end(),
774 LongTermPicNumAscCompare());
775
776 // Cut off if we have more than requested in slice header.
777 ref_pic_list0_.resize(slice_hdr->num_ref_idx_l0_active_minus1 + 1);
778 }
779
780 struct POCAscCompare {
781 bool operator()(const VaapiH264Picture* a, const VaapiH264Picture* b) const {
782 return a->pic_order_cnt < b->pic_order_cnt;
783 }
784 };
785
786 struct POCDescCompare {
787 bool operator()(const VaapiH264Picture* a, const VaapiH264Picture* b) const {
788 return a->pic_order_cnt > b->pic_order_cnt;
789 }
790 };
791
792 void VaapiH264Decoder::ConstructReferencePicListsB(
793 media::H264SliceHeader* slice_hdr) {
794 // RefPicList0 (8.2.4.2.3) [[1] [2] [3]], where:
795 // [1] shortterm ref pics with POC < curr_pic's POC sorted by descending POC,
796 // [2] shortterm ref pics with POC > curr_pic's POC by ascending POC,
797 // [3] longterm ref pics by ascending long_term_pic_num.
798 DCHECK(ref_pic_list0_.empty() && ref_pic_list1_.empty());
799 dpb_.GetShortTermRefPicsAppending(ref_pic_list0_);
800 size_t num_short_refs = ref_pic_list0_.size();
801
802 // First sort ascending, this will put [1] in right place and finish [2].
803 std::sort(ref_pic_list0_.begin(), ref_pic_list0_.end(), POCAscCompare());
804
805 // Find first with POC > curr_pic's POC to get first element in [2]...
806 VaapiH264Picture::PtrVector::iterator iter;
807 iter = std::upper_bound(ref_pic_list0_.begin(), ref_pic_list0_.end(),
808 curr_pic_.get(), POCAscCompare());
809
810 // and sort [1] descending, thus finishing sequence [1] [2].
811 std::sort(ref_pic_list0_.begin(), iter, POCDescCompare());
812
813 // Now add [3] and sort by ascending long_term_pic_num.
814 dpb_.GetLongTermRefPicsAppending(ref_pic_list0_);
815 std::sort(ref_pic_list0_.begin() + num_short_refs, ref_pic_list0_.end(),
816 LongTermPicNumAscCompare());
817
818 // RefPicList1 (8.2.4.2.4) [[1] [2] [3]], where:
819 // [1] shortterm ref pics with POC > curr_pic's POC sorted by ascending POC,
820 // [2] shortterm ref pics with POC < curr_pic's POC by descending POC,
821 // [3] longterm ref pics by ascending long_term_pic_num.
822
823 dpb_.GetShortTermRefPicsAppending(ref_pic_list1_);
824 num_short_refs = ref_pic_list1_.size();
825
826 // First sort by descending POC.
827 std::sort(ref_pic_list1_.begin(), ref_pic_list1_.end(), POCDescCompare());
828
829 // Find first with POC < curr_pic's POC to get first element in [2]...
830 iter = std::upper_bound(ref_pic_list1_.begin(), ref_pic_list1_.end(),
831 curr_pic_.get(), POCDescCompare());
832
833 // and sort [1] ascending.
834 std::sort(ref_pic_list1_.begin(), iter, POCAscCompare());
835
836 // Now add [3] and sort by ascending long_term_pic_num
837 dpb_.GetShortTermRefPicsAppending(ref_pic_list1_);
838 std::sort(ref_pic_list1_.begin() + num_short_refs, ref_pic_list1_.end(),
839 LongTermPicNumAscCompare());
840
841 // If lists identical, swap first two entries in RefPicList1 (spec 8.2.4.2.3)
842 if (ref_pic_list1_.size() > 1 &&
843 std::equal(ref_pic_list0_.begin(), ref_pic_list0_.end(),
844 ref_pic_list1_.begin()))
845 std::swap(ref_pic_list1_[0], ref_pic_list1_[1]);
846
847 // Per 8.2.4.2 it's possible for num_ref_idx_lX_active_minus1 to indicate
848 // there should be more ref pics on list than we constructed.
849 // Those superfluous ones should be treated as non-reference.
850 ref_pic_list0_.resize(slice_hdr->num_ref_idx_l0_active_minus1 + 1);
851 ref_pic_list1_.resize(slice_hdr->num_ref_idx_l1_active_minus1 + 1);
852 }
853
854 // See 8.2.4
855 int VaapiH264Decoder::PicNumF(VaapiH264Picture* pic) {
856 if (!pic)
857 return -1;
858
859 if (!pic->long_term)
860 return pic->pic_num;
861 else
862 return max_pic_num_;
863 }
864
865 // See 8.2.4
866 int VaapiH264Decoder::LongTermPicNumF(VaapiH264Picture* pic) {
867 if (pic->ref && pic->long_term)
868 return pic->long_term_pic_num;
869 else
870 return 2 * (max_long_term_frame_idx_ + 1);
871 }
872
873 // Shift elements on the |v| starting from |from| to |to|, inclusive,
874 // one position to the right and insert pic at |from|.
875 static void ShiftRightAndInsert(VaapiH264Picture::PtrVector* v,
876 int from,
877 int to,
878 VaapiH264Picture* pic) {
879 // Security checks, do not disable in Debug mode.
880 CHECK(from <= to);
881 CHECK(to <= std::numeric_limits<int>::max() - 2);
882 // Additional checks. Debug mode ok.
883 DCHECK(v);
884 DCHECK(pic);
885 DCHECK((to + 1 == static_cast<int>(v->size())) ||
886 (to + 2 == static_cast<int>(v->size())));
887
888 v->resize(to + 2);
889
890 for (int i = to + 1; i > from; --i)
891 (*v)[i] = (*v)[i - 1];
892
893 (*v)[from] = pic;
894 }
895
896 bool VaapiH264Decoder::ModifyReferencePicList(media::H264SliceHeader* slice_hdr,
897 int list) {
898 int num_ref_idx_lX_active_minus1;
899 VaapiH264Picture::PtrVector* ref_pic_listx;
900 media::H264ModificationOfPicNum* list_mod;
901
902 // This can process either ref_pic_list0 or ref_pic_list1, depending on
903 // the list argument. Set up pointers to proper list to be processed here.
904 if (list == 0) {
905 if (!slice_hdr->ref_pic_list_modification_flag_l0)
906 return true;
907
908 list_mod = slice_hdr->ref_list_l0_modifications;
909 num_ref_idx_lX_active_minus1 = ref_pic_list0_.size() - 1;
910
911 ref_pic_listx = &ref_pic_list0_;
912 } else {
913 if (!slice_hdr->ref_pic_list_modification_flag_l1)
914 return true;
915
916 list_mod = slice_hdr->ref_list_l1_modifications;
917 num_ref_idx_lX_active_minus1 = ref_pic_list1_.size() - 1;
918
919 ref_pic_listx = &ref_pic_list1_;
920 }
921
922 DCHECK_GE(num_ref_idx_lX_active_minus1, 0);
923
924 // Spec 8.2.4.3:
925 // Reorder pictures on the list in a way specified in the stream.
926 int pic_num_lx_pred = curr_pic_->pic_num;
927 int ref_idx_lx = 0;
928 int pic_num_lx_no_wrap;
929 int pic_num_lx;
930 bool done = false;
931 VaapiH264Picture* pic;
932 for (int i = 0; i < media::H264SliceHeader::kRefListModSize && !done; ++i) {
933 switch (list_mod->modification_of_pic_nums_idc) {
934 case 0:
935 case 1:
936 // Modify short reference picture position.
937 if (list_mod->modification_of_pic_nums_idc == 0) {
938 // Subtract given value from predicted PicNum.
939 pic_num_lx_no_wrap = pic_num_lx_pred -
940 (static_cast<int>(list_mod->abs_diff_pic_num_minus1) + 1);
941 // Wrap around max_pic_num_ if it becomes < 0 as result
942 // of subtraction.
943 if (pic_num_lx_no_wrap < 0)
944 pic_num_lx_no_wrap += max_pic_num_;
945 } else {
946 // Add given value to predicted PicNum.
947 pic_num_lx_no_wrap = pic_num_lx_pred +
948 (static_cast<int>(list_mod->abs_diff_pic_num_minus1) + 1);
949 // Wrap around max_pic_num_ if it becomes >= max_pic_num_ as result
950 // of the addition.
951 if (pic_num_lx_no_wrap >= max_pic_num_)
952 pic_num_lx_no_wrap -= max_pic_num_;
953 }
954
955 // For use in next iteration.
956 pic_num_lx_pred = pic_num_lx_no_wrap;
957
958 if (pic_num_lx_no_wrap > curr_pic_->pic_num)
959 pic_num_lx = pic_num_lx_no_wrap - max_pic_num_;
960 else
961 pic_num_lx = pic_num_lx_no_wrap;
962
963 DCHECK_LT(num_ref_idx_lX_active_minus1 + 1,
964 media::H264SliceHeader::kRefListModSize);
965 pic = dpb_.GetShortRefPicByPicNum(pic_num_lx);
966 if (!pic) {
967 DVLOG(1) << "Malformed stream, no pic num " << pic_num_lx;
968 return false;
969 }
970 ShiftRightAndInsert(ref_pic_listx, ref_idx_lx,
971 num_ref_idx_lX_active_minus1, pic);
972 ref_idx_lx++;
973
974 for (int src = ref_idx_lx, dst = ref_idx_lx;
975 src <= num_ref_idx_lX_active_minus1 + 1; ++src) {
976 if (PicNumF((*ref_pic_listx)[src]) != pic_num_lx)
977 (*ref_pic_listx)[dst++] = (*ref_pic_listx)[src];
978 }
979 break;
980
981 case 2:
982 // Modify long term reference picture position.
983 DCHECK_LT(num_ref_idx_lX_active_minus1 + 1,
984 media::H264SliceHeader::kRefListModSize);
985 pic = dpb_.GetLongRefPicByLongTermPicNum(list_mod->long_term_pic_num);
986 if (!pic) {
987 DVLOG(1) << "Malformed stream, no pic num "
988 << list_mod->long_term_pic_num;
989 return false;
990 }
991 ShiftRightAndInsert(ref_pic_listx, ref_idx_lx,
992 num_ref_idx_lX_active_minus1, pic);
993 ref_idx_lx++;
994
995 for (int src = ref_idx_lx, dst = ref_idx_lx;
996 src <= num_ref_idx_lX_active_minus1 + 1; ++src) {
997 if (LongTermPicNumF((*ref_pic_listx)[src])
998 != static_cast<int>(list_mod->long_term_pic_num))
999 (*ref_pic_listx)[dst++] = (*ref_pic_listx)[src];
1000 }
1001 break;
1002
1003 case 3:
1004 // End of modification list.
1005 done = true;
1006 break;
1007
1008 default:
1009 // May be recoverable.
1010 DVLOG(1) << "Invalid modification_of_pic_nums_idc="
1011 << list_mod->modification_of_pic_nums_idc
1012 << " in position " << i;
1013 break;
1014 }
1015
1016 ++list_mod;
1017 }
1018
1019 // Per NOTE 2 in 8.2.4.3.2, the ref_pic_listx size in the above loop is
1020 // temporarily made one element longer than the required final list.
1021 // Resize the list back to its required size.
1022 ref_pic_listx->resize(num_ref_idx_lX_active_minus1 + 1);
1023
1024 return true;
1025 }
1026
1027 bool VaapiH264Decoder::OutputPic(VaapiH264Picture* pic) {
1028 DCHECK(!pic->outputted);
1029 pic->outputted = true;
1030 last_output_poc_ = pic->pic_order_cnt;
1031
1032 DecodeSurface* dec_surface = DecodeSurfaceByPoC(pic->pic_order_cnt);
1033 if (!dec_surface)
1034 return false;
1035
1036 DCHECK_GE(dec_surface->input_id(), 0);
1037 DVLOG(4) << "Posting output task for POC: " << pic->pic_order_cnt
1038 << " input_id: " << dec_surface->input_id();
1039 output_pic_cb_.Run(dec_surface->input_id(), dec_surface->va_surface());
1040
1041 return true;
1042 }
1043
1044 void VaapiH264Decoder::ClearDPB() {
1045 // Clear DPB contents, marking the pictures as unused first.
1046 for (VaapiH264DPB::Pictures::iterator it = dpb_.begin(); it != dpb_.end();
1047 ++it)
1048 UnassignSurfaceFromPoC((*it)->pic_order_cnt);
1049
1050 dpb_.Clear();
1051 last_output_poc_ = std::numeric_limits<int>::min();
1052 }
1053
1054 bool VaapiH264Decoder::OutputAllRemainingPics() {
1055 // Output all pictures that are waiting to be outputted.
1056 FinishPrevFrameIfPresent();
1057 VaapiH264Picture::PtrVector to_output;
1058 dpb_.GetNotOutputtedPicsAppending(to_output);
1059 // Sort them by ascending POC to output in order.
1060 std::sort(to_output.begin(), to_output.end(), POCAscCompare());
1061
1062 VaapiH264Picture::PtrVector::iterator it;
1063 for (it = to_output.begin(); it != to_output.end(); ++it) {
1064 if (!OutputPic(*it)) {
1065 DVLOG(1) << "Failed to output pic POC: " << (*it)->pic_order_cnt;
1066 return false;
1067 }
1068 }
1069
1070 return true;
1071 }
1072
1073 bool VaapiH264Decoder::Flush() {
1074 DVLOG(2) << "Decoder flush";
1075
1076 if (!OutputAllRemainingPics())
1077 return false;
1078
1079 ClearDPB();
1080
1081 DCHECK(decode_surfaces_in_use_.empty());
1082 return true;
1083 }
1084
1085 bool VaapiH264Decoder::StartNewFrame(media::H264SliceHeader* slice_hdr) {
1086 // TODO posciak: add handling of max_num_ref_frames per spec.
1087
1088 // If the new frame is an IDR, output what's left to output and clear DPB
1089 if (slice_hdr->idr_pic_flag) {
1090 // (unless we are explicitly instructed not to do so).
1091 if (!slice_hdr->no_output_of_prior_pics_flag) {
1092 // Output DPB contents.
1093 if (!Flush())
1094 return false;
1095 }
1096 dpb_.Clear();
1097 last_output_poc_ = std::numeric_limits<int>::min();
1098 }
1099
1100 // curr_pic_ should have either been added to DPB or discarded when finishing
1101 // the last frame. DPB is responsible for releasing that memory once it's
1102 // not needed anymore.
1103 DCHECK(!curr_pic_.get());
1104 curr_pic_.reset(new VaapiH264Picture);
1105 CHECK(curr_pic_.get());
1106
1107 if (!InitCurrPicture(slice_hdr))
1108 return false;
1109
1110 DCHECK_GT(max_frame_num_, 0);
1111
1112 UpdatePicNums();
1113
1114 // Send parameter buffers before each new picture, before the first slice.
1115 if (!SendPPS())
1116 return false;
1117
1118 if (!SendIQMatrix())
1119 return false;
1120
1121 if (!QueueSlice(slice_hdr))
1122 return false;
1123
1124 return true;
1125 }
1126
1127 bool VaapiH264Decoder::HandleMemoryManagementOps() {
1128 // 8.2.5.4
1129 for (unsigned int i = 0; i < arraysize(curr_pic_->ref_pic_marking); ++i) {
1130 // Code below does not support interlaced stream (per-field pictures).
1131 media::H264DecRefPicMarking* ref_pic_marking =
1132 &curr_pic_->ref_pic_marking[i];
1133 VaapiH264Picture* to_mark;
1134 int pic_num_x;
1135
1136 switch (ref_pic_marking->memory_mgmnt_control_operation) {
1137 case 0:
1138 // Normal end of operations' specification.
1139 return true;
1140
1141 case 1:
1142 // Mark a short term reference picture as unused so it can be removed
1143 // if outputted.
1144 pic_num_x = curr_pic_->pic_num -
1145 (ref_pic_marking->difference_of_pic_nums_minus1 + 1);
1146 to_mark = dpb_.GetShortRefPicByPicNum(pic_num_x);
1147 if (to_mark) {
1148 to_mark->ref = false;
1149 } else {
1150 DVLOG(1) << "Invalid short ref pic num to unmark";
1151 return false;
1152 }
1153 break;
1154
1155 case 2:
1156 // Mark a long term reference picture as unused so it can be removed
1157 // if outputted.
1158 to_mark = dpb_.GetLongRefPicByLongTermPicNum(
1159 ref_pic_marking->long_term_pic_num);
1160 if (to_mark) {
1161 to_mark->ref = false;
1162 } else {
1163 DVLOG(1) << "Invalid long term ref pic num to unmark";
1164 return false;
1165 }
1166 break;
1167
1168 case 3:
1169 // Mark a short term reference picture as long term reference.
1170 pic_num_x = curr_pic_->pic_num -
1171 (ref_pic_marking->difference_of_pic_nums_minus1 + 1);
1172 to_mark = dpb_.GetShortRefPicByPicNum(pic_num_x);
1173 if (to_mark) {
1174 DCHECK(to_mark->ref && !to_mark->long_term);
1175 to_mark->long_term = true;
1176 to_mark->long_term_frame_idx = ref_pic_marking->long_term_frame_idx;
1177 } else {
1178 DVLOG(1) << "Invalid short term ref pic num to mark as long ref";
1179 return false;
1180 }
1181 break;
1182
1183 case 4: {
1184 // Unmark all reference pictures with long_term_frame_idx over new max.
1185 max_long_term_frame_idx_
1186 = ref_pic_marking->max_long_term_frame_idx_plus1 - 1;
1187 VaapiH264Picture::PtrVector long_terms;
1188 dpb_.GetLongTermRefPicsAppending(long_terms);
1189 for (size_t i = 0; i < long_terms.size(); ++i) {
1190 VaapiH264Picture* pic = long_terms[i];
1191 DCHECK(pic->ref && pic->long_term);
1192 // Ok to cast, max_long_term_frame_idx is much smaller than 16bit.
1193 if (pic->long_term_frame_idx >
1194 static_cast<int>(max_long_term_frame_idx_))
1195 pic->ref = false;
1196 }
1197 break;
1198 }
1199
1200 case 5:
1201 // Unmark all reference pictures.
1202 dpb_.MarkAllUnusedForRef();
1203 max_long_term_frame_idx_ = -1;
1204 curr_pic_->mem_mgmt_5 = true;
1205 break;
1206
1207 case 6: {
1208 // Replace long term reference pictures with current picture.
1209 // First unmark if any existing with this long_term_frame_idx...
1210 VaapiH264Picture::PtrVector long_terms;
1211 dpb_.GetLongTermRefPicsAppending(long_terms);
1212 for (size_t i = 0; i < long_terms.size(); ++i) {
1213 VaapiH264Picture* pic = long_terms[i];
1214 DCHECK(pic->ref && pic->long_term);
1215 // Ok to cast, long_term_frame_idx is much smaller than 16bit.
1216 if (pic->long_term_frame_idx ==
1217 static_cast<int>(ref_pic_marking->long_term_frame_idx))
1218 pic->ref = false;
1219 }
1220
1221 // and mark the current one instead.
1222 curr_pic_->ref = true;
1223 curr_pic_->long_term = true;
1224 curr_pic_->long_term_frame_idx = ref_pic_marking->long_term_frame_idx;
1225 break;
1226 }
1227
1228 default:
1229 // Would indicate a bug in parser.
1230 NOTREACHED();
1231 }
1232 }
1233
1234 return true;
1235 }
1236
1237 // This method ensures that DPB does not overflow, either by removing
1238 // reference pictures as specified in the stream, or using a sliding window
1239 // procedure to remove the oldest one.
1240 // It also performs marking and unmarking pictures as reference.
1241 // See spac 8.2.5.1.
1242 void VaapiH264Decoder::ReferencePictureMarking() {
1243 if (curr_pic_->idr) {
1244 // If current picture is an IDR, all reference pictures are unmarked.
1245 dpb_.MarkAllUnusedForRef();
1246
1247 if (curr_pic_->long_term_reference_flag) {
1248 curr_pic_->long_term = true;
1249 curr_pic_->long_term_frame_idx = 0;
1250 max_long_term_frame_idx_ = 0;
1251 } else {
1252 curr_pic_->long_term = false;
1253 max_long_term_frame_idx_ = -1;
1254 }
1255 } else {
1256 if (!curr_pic_->adaptive_ref_pic_marking_mode_flag) {
1257 // If non-IDR, and the stream does not indicate what we should do to
1258 // ensure DPB doesn't overflow, discard oldest picture.
1259 // See spec 8.2.5.3.
1260 if (curr_pic_->field == VaapiH264Picture::FIELD_NONE) {
1261 DCHECK_LE(dpb_.CountRefPics(),
1262 std::max<int>(parser_.GetSPS(curr_sps_id_)->max_num_ref_frames,
1263 1));
1264 if (dpb_.CountRefPics() ==
1265 std::max<int>(parser_.GetSPS(curr_sps_id_)->max_num_ref_frames,
1266 1)) {
1267 // Max number of reference pics reached,
1268 // need to remove one of the short term ones.
1269 // Find smallest frame_num_wrap short reference picture and mark
1270 // it as unused.
1271 VaapiH264Picture* to_unmark = dpb_.GetLowestFrameNumWrapShortRefPic();
1272 if (to_unmark == NULL) {
1273 DVLOG(1) << "Couldn't find a short ref picture to unmark";
1274 return;
1275 }
1276 to_unmark->ref = false;
1277 }
1278 } else {
1279 // Shouldn't get here.
1280 DVLOG(1) << "Interlaced video not supported.";
1281 report_error_to_uma_cb_.Run(INTERLACED_STREAM);
1282 }
1283 } else {
1284 // Stream has instructions how to discard pictures from DPB and how
1285 // to mark/unmark existing reference pictures. Do it.
1286 // Spec 8.2.5.4.
1287 if (curr_pic_->field == VaapiH264Picture::FIELD_NONE) {
1288 HandleMemoryManagementOps();
1289 } else {
1290 // Shouldn't get here.
1291 DVLOG(1) << "Interlaced video not supported.";
1292 report_error_to_uma_cb_.Run(INTERLACED_STREAM);
1293 }
1294 }
1295 }
1296 }
1297
1298 bool VaapiH264Decoder::FinishPicture() {
1299 DCHECK(curr_pic_.get());
1300
1301 // Finish processing previous picture.
1302 // Start by storing previous reference picture data for later use,
1303 // if picture being finished is a reference picture.
1304 if (curr_pic_->ref) {
1305 ReferencePictureMarking();
1306 prev_ref_has_memmgmnt5_ = curr_pic_->mem_mgmt_5;
1307 prev_ref_top_field_order_cnt_ = curr_pic_->top_field_order_cnt;
1308 prev_ref_pic_order_cnt_msb_ = curr_pic_->pic_order_cnt_msb;
1309 prev_ref_pic_order_cnt_lsb_ = curr_pic_->pic_order_cnt_lsb;
1310 prev_ref_field_ = curr_pic_->field;
1311 }
1312 prev_has_memmgmnt5_ = curr_pic_->mem_mgmt_5;
1313 prev_frame_num_offset_ = curr_pic_->frame_num_offset;
1314
1315 // Remove unused (for reference or later output) pictures from DPB, marking
1316 // them as such.
1317 for (VaapiH264DPB::Pictures::iterator it = dpb_.begin(); it != dpb_.end();
1318 ++it) {
1319 if ((*it)->outputted && !(*it)->ref)
1320 UnassignSurfaceFromPoC((*it)->pic_order_cnt);
1321 }
1322 dpb_.DeleteUnused();
1323
1324 DVLOG(4) << "Finishing picture, entries in DPB: " << dpb_.size();
1325
1326 // Whatever happens below, curr_pic_ will stop managing the pointer to the
1327 // picture after this function returns. The ownership will either be
1328 // transferred to DPB, if the image is still needed (for output and/or
1329 // reference), or the memory will be released if we manage to output it here
1330 // without having to store it for future reference.
1331 scoped_ptr<VaapiH264Picture> pic(curr_pic_.release());
1332
1333 // Get all pictures that haven't been outputted yet.
1334 VaapiH264Picture::PtrVector not_outputted;
1335 // TODO(posciak): pass as pointer, not reference (violates coding style).
1336 dpb_.GetNotOutputtedPicsAppending(not_outputted);
1337 // Include the one we've just decoded.
1338 not_outputted.push_back(pic.get());
1339
1340 // Sort in output order.
1341 std::sort(not_outputted.begin(), not_outputted.end(), POCAscCompare());
1342
1343 // Try to output as many pictures as we can. A picture can be output,
1344 // if the number of decoded and not yet outputted pictures that would remain
1345 // in DPB afterwards would at least be equal to max_num_reorder_frames.
1346 // If the outputted picture is not a reference picture, it doesn't have
1347 // to remain in the DPB and can be removed.
1348 VaapiH264Picture::PtrVector::iterator output_candidate =
1349 not_outputted.begin();
1350 size_t num_remaining = not_outputted.size();
1351 while (num_remaining > max_num_reorder_frames_) {
1352 int poc = (*output_candidate)->pic_order_cnt;
1353 DCHECK_GE(poc, last_output_poc_);
1354 if (!OutputPic(*output_candidate))
1355 return false;
1356
1357 if (!(*output_candidate)->ref) {
1358 // Current picture hasn't been inserted into DPB yet, so don't remove it
1359 // if we managed to output it immediately.
1360 if (*output_candidate != pic)
1361 dpb_.DeleteByPOC(poc);
1362 // Mark as unused.
1363 UnassignSurfaceFromPoC(poc);
1364 }
1365
1366 ++output_candidate;
1367 --num_remaining;
1368 }
1369
1370 // If we haven't managed to output the picture that we just decoded, or if
1371 // it's a reference picture, we have to store it in DPB.
1372 if (!pic->outputted || pic->ref) {
1373 if (dpb_.IsFull()) {
1374 // If we haven't managed to output anything to free up space in DPB
1375 // to store this picture, it's an error in the stream.
1376 DVLOG(1) << "Could not free up space in DPB!";
1377 return false;
1378 }
1379
1380 dpb_.StorePic(pic.release());
1381 }
1382
1383 return true;
1384 }
1385
1386 static int LevelToMaxDpbMbs(int level) {
1387 // See table A-1 in spec.
1388 switch (level) {
1389 case 10: return 396;
1390 case 11: return 900;
1391 case 12: // fallthrough
1392 case 13: // fallthrough
1393 case 20: return 2376;
1394 case 21: return 4752;
1395 case 22: // fallthrough
1396 case 30: return 8100;
1397 case 31: return 18000;
1398 case 32: return 20480;
1399 case 40: // fallthrough
1400 case 41: return 32768;
1401 case 42: return 34816;
1402 case 50: return 110400;
1403 case 51: // fallthrough
1404 case 52: return 184320;
1405 default:
1406 DVLOG(1) << "Invalid codec level (" << level << ")";
1407 return 0;
1408 }
1409 }
1410
1411 bool VaapiH264Decoder::UpdateMaxNumReorderFrames(const media::H264SPS* sps) {
1412 if (sps->vui_parameters_present_flag && sps->bitstream_restriction_flag) {
1413 max_num_reorder_frames_ =
1414 base::checked_cast<size_t>(sps->max_num_reorder_frames);
1415 if (max_num_reorder_frames_ > dpb_.max_num_pics()) {
1416 DVLOG(1)
1417 << "max_num_reorder_frames present, but larger than MaxDpbFrames ("
1418 << max_num_reorder_frames_ << " > " << dpb_.max_num_pics() << ")";
1419 max_num_reorder_frames_ = 0;
1420 return false;
1421 }
1422 return true;
1423 }
1424
1425 // max_num_reorder_frames not present, infer from profile/constraints
1426 // (see VUI semantics in spec).
1427 if (sps->constraint_set3_flag) {
1428 switch (sps->profile_idc) {
1429 case 44:
1430 case 86:
1431 case 100:
1432 case 110:
1433 case 122:
1434 case 244:
1435 max_num_reorder_frames_ = 0;
1436 break;
1437 default:
1438 max_num_reorder_frames_ = dpb_.max_num_pics();
1439 break;
1440 }
1441 } else {
1442 max_num_reorder_frames_ = dpb_.max_num_pics();
1443 }
1444
1445 return true;
1446 }
1447
1448 bool VaapiH264Decoder::ProcessSPS(int sps_id, bool* need_new_buffers) {
1449 const media::H264SPS* sps = parser_.GetSPS(sps_id);
1450 DCHECK(sps);
1451 DVLOG(4) << "Processing SPS";
1452
1453 *need_new_buffers = false;
1454
1455 if (sps->frame_mbs_only_flag == 0) {
1456 DVLOG(1) << "frame_mbs_only_flag != 1 not supported";
1457 report_error_to_uma_cb_.Run(FRAME_MBS_ONLY_FLAG_NOT_ONE);
1458 return false;
1459 }
1460
1461 if (sps->gaps_in_frame_num_value_allowed_flag) {
1462 DVLOG(1) << "Gaps in frame numbers not supported";
1463 report_error_to_uma_cb_.Run(GAPS_IN_FRAME_NUM);
1464 return false;
1465 }
1466
1467 curr_sps_id_ = sps->seq_parameter_set_id;
1468
1469 // Calculate picture height/width in macroblocks and pixels
1470 // (spec 7.4.2.1.1, 7.4.3).
1471 int width_mb = sps->pic_width_in_mbs_minus1 + 1;
1472 int height_mb = (2 - sps->frame_mbs_only_flag) *
1473 (sps->pic_height_in_map_units_minus1 + 1);
1474
1475 gfx::Size new_pic_size(16 * width_mb, 16 * height_mb);
1476 if (new_pic_size.IsEmpty()) {
1477 DVLOG(1) << "Invalid picture size: " << new_pic_size.ToString();
1478 return false;
1479 }
1480
1481 if (!pic_size_.IsEmpty() && new_pic_size == pic_size_) {
1482 // Already have surfaces and this SPS keeps the same resolution,
1483 // no need to request a new set.
1484 return true;
1485 }
1486
1487 pic_size_ = new_pic_size;
1488 DVLOG(1) << "New picture size: " << pic_size_.ToString();
1489
1490 max_pic_order_cnt_lsb_ = 1 << (sps->log2_max_pic_order_cnt_lsb_minus4 + 4);
1491 max_frame_num_ = 1 << (sps->log2_max_frame_num_minus4 + 4);
1492
1493 int level = sps->level_idc;
1494 int max_dpb_mbs = LevelToMaxDpbMbs(level);
1495 if (max_dpb_mbs == 0)
1496 return false;
1497
1498 size_t max_dpb_size = std::min(max_dpb_mbs / (width_mb * height_mb),
1499 static_cast<int>(VaapiH264DPB::kDPBMaxSize));
1500 DVLOG(1) << "Codec level: " << level << ", DPB size: " << max_dpb_size;
1501 if (max_dpb_size == 0) {
1502 DVLOG(1) << "Invalid DPB Size";
1503 return false;
1504 }
1505
1506 dpb_.set_max_num_pics(max_dpb_size);
1507
1508 if (!UpdateMaxNumReorderFrames(sps))
1509 return false;
1510 DVLOG(1) << "max_num_reorder_frames: " << max_num_reorder_frames_;
1511
1512 *need_new_buffers = true;
1513 return true;
1514 }
1515
1516 bool VaapiH264Decoder::ProcessPPS(int pps_id) {
1517 const media::H264PPS* pps = parser_.GetPPS(pps_id);
1518 DCHECK(pps);
1519
1520 curr_pps_id_ = pps->pic_parameter_set_id;
1521
1522 return true;
1523 }
1524
1525 bool VaapiH264Decoder::FinishPrevFrameIfPresent() {
1526 // If we already have a frame waiting to be decoded, decode it and finish.
1527 if (curr_pic_ != NULL) {
1528 if (!DecodePicture())
1529 return false;
1530 return FinishPicture();
1531 }
1532
1533 return true;
1534 }
1535
1536 bool VaapiH264Decoder::ProcessSlice(media::H264SliceHeader* slice_hdr) {
1537 prev_frame_num_ = frame_num_;
1538 frame_num_ = slice_hdr->frame_num;
1539
1540 if (prev_frame_num_ > 0 && prev_frame_num_ < frame_num_ - 1) {
1541 DVLOG(1) << "Gap in frame_num!";
1542 report_error_to_uma_cb_.Run(GAPS_IN_FRAME_NUM);
1543 return false;
1544 }
1545
1546 if (slice_hdr->field_pic_flag == 0)
1547 max_pic_num_ = max_frame_num_;
1548 else
1549 max_pic_num_ = 2 * max_frame_num_;
1550
1551 // TODO posciak: switch to new picture detection per 7.4.1.2.4.
1552 if (curr_pic_ != NULL && slice_hdr->first_mb_in_slice != 0) {
1553 // This is just some more slice data of the current picture, so
1554 // just queue it and return.
1555 QueueSlice(slice_hdr);
1556 return true;
1557 } else {
1558 // A new frame, so first finish the previous one before processing it...
1559 if (!FinishPrevFrameIfPresent())
1560 return false;
1561
1562 // and then start a new one.
1563 return StartNewFrame(slice_hdr);
1564 }
1565 }
1566
1567 #define SET_ERROR_AND_RETURN() \
1568 do { \
1569 DVLOG(1) << "Error during decode"; \
1570 state_ = kError; \
1571 return VaapiH264Decoder::kDecodeError; \
1572 } while (0)
1573
1574 void VaapiH264Decoder::SetStream(const uint8* ptr,
1575 size_t size,
1576 int32 input_id) {
1577 DCHECK(ptr);
1578 DCHECK(size);
1579
1580 // Got new input stream data from the client.
1581 DVLOG(4) << "New input stream id: " << input_id << " at: " << (void*) ptr
1582 << " size: " << size;
1583 parser_.SetStream(ptr, size);
1584 curr_input_id_ = input_id;
1585 }
1586
1587 VaapiH264Decoder::DecResult VaapiH264Decoder::Decode() {
1588 media::H264Parser::Result par_res;
1589 media::H264NALU nalu;
1590 DCHECK_NE(state_, kError);
1591
1592 while (1) {
1593 // If we've already decoded some of the stream (after reset, i.e. we are
1594 // not in kNeedStreamMetadata state), we may be able to go back into
1595 // decoding state not only starting at/resuming from an SPS, but also from
1596 // other resume points, such as IDRs. In the latter case we need an output
1597 // surface, because we will end up decoding that IDR in the process.
1598 // Otherwise we just look for an SPS and don't produce any output frames.
1599 if (state_ != kNeedStreamMetadata && available_va_surfaces_.empty()) {
1600 DVLOG(4) << "No output surfaces available";
1601 return kRanOutOfSurfaces;
1602 }
1603
1604 par_res = parser_.AdvanceToNextNALU(&nalu);
1605 if (par_res == media::H264Parser::kEOStream)
1606 return kRanOutOfStreamData;
1607 else if (par_res != media::H264Parser::kOk)
1608 SET_ERROR_AND_RETURN();
1609
1610 DVLOG(4) << "NALU found: " << static_cast<int>(nalu.nal_unit_type);
1611
1612 switch (nalu.nal_unit_type) {
1613 case media::H264NALU::kNonIDRSlice:
1614 // We can't resume from a non-IDR slice.
1615 if (state_ != kDecoding)
1616 break;
1617 // else fallthrough
1618 case media::H264NALU::kIDRSlice: {
1619 // TODO(posciak): the IDR may require an SPS that we don't have
1620 // available. For now we'd fail if that happens, but ideally we'd like
1621 // to keep going until the next SPS in the stream.
1622 if (state_ == kNeedStreamMetadata) {
1623 // We need an SPS, skip this IDR and keep looking.
1624 break;
1625 }
1626
1627 // If after reset, we should be able to recover from an IDR.
1628 media::H264SliceHeader slice_hdr;
1629
1630 par_res = parser_.ParseSliceHeader(nalu, &slice_hdr);
1631 if (par_res != media::H264Parser::kOk)
1632 SET_ERROR_AND_RETURN();
1633
1634 if (!ProcessSlice(&slice_hdr))
1635 SET_ERROR_AND_RETURN();
1636
1637 state_ = kDecoding;
1638 break;
1639 }
1640
1641 case media::H264NALU::kSPS: {
1642 int sps_id;
1643
1644 if (!FinishPrevFrameIfPresent())
1645 SET_ERROR_AND_RETURN();
1646
1647 par_res = parser_.ParseSPS(&sps_id);
1648 if (par_res != media::H264Parser::kOk)
1649 SET_ERROR_AND_RETURN();
1650
1651 bool need_new_buffers = false;
1652 if (!ProcessSPS(sps_id, &need_new_buffers))
1653 SET_ERROR_AND_RETURN();
1654
1655 state_ = kDecoding;
1656
1657 if (need_new_buffers) {
1658 if (!Flush())
1659 return kDecodeError;
1660
1661 available_va_surfaces_.clear();
1662 return kAllocateNewSurfaces;
1663 }
1664 break;
1665 }
1666
1667 case media::H264NALU::kPPS: {
1668 if (state_ != kDecoding)
1669 break;
1670
1671 int pps_id;
1672
1673 if (!FinishPrevFrameIfPresent())
1674 SET_ERROR_AND_RETURN();
1675
1676 par_res = parser_.ParsePPS(&pps_id);
1677 if (par_res != media::H264Parser::kOk)
1678 SET_ERROR_AND_RETURN();
1679
1680 if (!ProcessPPS(pps_id))
1681 SET_ERROR_AND_RETURN();
1682 break;
1683 }
1684
1685 case media::H264NALU::kAUD:
1686 case media::H264NALU::kEOSeq:
1687 case media::H264NALU::kEOStream:
1688 if (state_ != kDecoding)
1689 break;
1690 if (!FinishPrevFrameIfPresent())
1691 SET_ERROR_AND_RETURN();
1692
1693 break;
1694
1695 default:
1696 DVLOG(4) << "Skipping NALU type: " << nalu.nal_unit_type;
1697 break;
1698 }
1699 }
1700 }
1701
1702 size_t VaapiH264Decoder::GetRequiredNumOfPictures() {
1703 return dpb_.max_num_pics() + kPicsInPipeline;
1704 }
1705
1706 } // namespace content
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