553 lines
18 KiB
C++
553 lines
18 KiB
C++
// Copyright (c) 2012 The Chromium Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style license that can be
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// found in the LICENSE file.
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#include "media/formats/mp4/track_run_iterator.h"
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#include <algorithm>
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#include "media/base/buffer_reader.h"
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#include "media/formats/mp4/chunk_info_iterator.h"
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#include "media/formats/mp4/composition_offset_iterator.h"
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#include "media/formats/mp4/decoding_time_iterator.h"
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#include "media/formats/mp4/rcheck.h"
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#include "media/formats/mp4/sync_sample_iterator.h"
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namespace media {
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namespace mp4 {
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struct SampleInfo {
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int size;
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int duration;
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int cts_offset;
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bool is_keyframe;
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};
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struct TrackRunInfo {
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uint32 track_id;
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std::vector<SampleInfo> samples;
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int64 timescale;
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int64 start_dts;
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int64 sample_start_offset;
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TrackType track_type;
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const AudioSampleEntry* audio_description;
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const VideoSampleEntry* video_description;
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int64 aux_info_start_offset; // Only valid if aux_info_total_size > 0.
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int aux_info_default_size;
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std::vector<uint8> aux_info_sizes; // Populated if default_size == 0.
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int aux_info_total_size;
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TrackRunInfo();
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~TrackRunInfo();
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};
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TrackRunInfo::TrackRunInfo()
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: track_id(0),
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timescale(-1),
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start_dts(-1),
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sample_start_offset(-1),
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track_type(kInvalid),
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audio_description(NULL),
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video_description(NULL),
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aux_info_start_offset(-1),
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aux_info_default_size(0),
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aux_info_total_size(0) {}
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TrackRunInfo::~TrackRunInfo() {}
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TrackRunIterator::TrackRunIterator(const Movie* moov)
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: moov_(moov), sample_dts_(0), sample_offset_(0) {
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CHECK(moov);
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}
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TrackRunIterator::~TrackRunIterator() {}
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static void PopulateSampleInfo(const TrackExtends& trex,
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const TrackFragmentHeader& tfhd,
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const TrackFragmentRun& trun,
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const uint32 i,
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SampleInfo* sample_info) {
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if (i < trun.sample_sizes.size()) {
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sample_info->size = trun.sample_sizes[i];
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} else if (tfhd.default_sample_size > 0) {
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sample_info->size = tfhd.default_sample_size;
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} else {
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sample_info->size = trex.default_sample_size;
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}
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if (i < trun.sample_durations.size()) {
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sample_info->duration = trun.sample_durations[i];
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} else if (tfhd.default_sample_duration > 0) {
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sample_info->duration = tfhd.default_sample_duration;
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} else {
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sample_info->duration = trex.default_sample_duration;
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}
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if (i < trun.sample_composition_time_offsets.size()) {
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sample_info->cts_offset = trun.sample_composition_time_offsets[i];
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} else {
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sample_info->cts_offset = 0;
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}
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uint32 flags;
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if (i < trun.sample_flags.size()) {
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flags = trun.sample_flags[i];
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} else if (tfhd.flags & TrackFragmentHeader::kDefaultSampleFlagsPresentMask) {
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flags = tfhd.default_sample_flags;
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} else {
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flags = trex.default_sample_flags;
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}
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sample_info->is_keyframe = !(flags & TrackFragmentHeader::kNonKeySampleMask);
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}
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// In well-structured encrypted media, each track run will be immediately
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// preceded by its auxiliary information; this is the only optimal storage
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// pattern in terms of minimum number of bytes from a serial stream needed to
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// begin playback. It also allows us to optimize caching on memory-constrained
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// architectures, because we can cache the relatively small auxiliary
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// information for an entire run and then discard data from the input stream,
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// instead of retaining the entire 'mdat' box.
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//
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// We optimize for this situation (with no loss of generality) by sorting track
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// runs during iteration in order of their first data offset (either sample data
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// or auxiliary data).
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class CompareMinTrackRunDataOffset {
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public:
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bool operator()(const TrackRunInfo& a, const TrackRunInfo& b) {
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int64 a_aux = a.aux_info_total_size ? a.aux_info_start_offset : kint64max;
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int64 b_aux = b.aux_info_total_size ? b.aux_info_start_offset : kint64max;
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int64 a_lesser = std::min(a_aux, a.sample_start_offset);
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int64 a_greater = std::max(a_aux, a.sample_start_offset);
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int64 b_lesser = std::min(b_aux, b.sample_start_offset);
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int64 b_greater = std::max(b_aux, b.sample_start_offset);
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if (a_lesser == b_lesser)
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return a_greater < b_greater;
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return a_lesser < b_lesser;
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}
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};
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bool TrackRunIterator::Init() {
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runs_.clear();
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for (std::vector<Track>::const_iterator trak = moov_->tracks.begin();
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trak != moov_->tracks.end(); ++trak) {
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const SampleDescription& stsd =
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trak->media.information.sample_table.description;
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if (stsd.type != kAudio && stsd.type != kVideo) {
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DVLOG(1) << "Skipping unhandled track type";
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continue;
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}
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// Edit list is ignored.
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// We may consider supporting the single edit with a nonnegative media time
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// if it is required. Just need to pass the media_time to Muxer and
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// generate the edit list.
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const std::vector<EditListEntry>& edits = trak->edit.list.edits;
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if (!edits.empty()) {
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if (edits.size() > 1)
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DVLOG(1) << "Multi-entry edit box detected.";
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DLOG(INFO) << "Edit list with media time " << edits[0].media_time
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<< " ignored.";
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}
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DecodingTimeIterator decoding_time(
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trak->media.information.sample_table.decoding_time_to_sample);
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CompositionOffsetIterator composition_offset(
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trak->media.information.sample_table.composition_time_to_sample);
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bool has_composition_offset = composition_offset.IsValid();
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ChunkInfoIterator chunk_info(
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trak->media.information.sample_table.sample_to_chunk);
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SyncSampleIterator sync_sample(
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trak->media.information.sample_table.sync_sample);
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// Skip processing saiz and saio boxes for non-fragmented mp4 as we
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// don't support encrypted non-fragmented mp4.
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const SampleSize& sample_size =
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trak->media.information.sample_table.sample_size;
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const std::vector<uint64>& chunk_offset_vector =
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trak->media.information.sample_table.chunk_large_offset.offsets;
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int64 run_start_dts = 0;
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uint32 num_samples = sample_size.sample_count;
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uint32 num_chunks = chunk_offset_vector.size();
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// Check that total number of samples match.
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DCHECK_EQ(num_samples, decoding_time.NumSamples());
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if (has_composition_offset)
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DCHECK_EQ(num_samples, composition_offset.NumSamples());
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if (num_chunks > 0)
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DCHECK_EQ(num_samples, chunk_info.NumSamples(1, num_chunks));
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DCHECK_GE(num_chunks, chunk_info.LastFirstChunk());
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if (num_samples > 0) {
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// Verify relevant tables are not empty.
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RCHECK(decoding_time.IsValid());
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RCHECK(chunk_info.IsValid());
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}
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uint32 sample_index = 0;
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for (uint32 chunk_index = 0; chunk_index < num_chunks; ++chunk_index) {
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RCHECK(chunk_info.current_chunk() == chunk_index + 1);
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TrackRunInfo tri;
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tri.track_id = trak->header.track_id;
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tri.timescale = trak->media.header.timescale;
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tri.start_dts = run_start_dts;
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tri.sample_start_offset = chunk_offset_vector[chunk_index];
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uint32 desc_idx = chunk_info.sample_description_index();
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RCHECK(desc_idx > 0); // Descriptions are one-indexed in the file.
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desc_idx -= 1;
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tri.track_type = stsd.type;
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if (tri.track_type == kAudio) {
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RCHECK(!stsd.audio_entries.empty());
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if (desc_idx > stsd.audio_entries.size())
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desc_idx = 0;
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tri.audio_description = &stsd.audio_entries[desc_idx];
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// We don't support encrypted non-fragmented mp4 for now.
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RCHECK(!tri.audio_description->sinf.info.track_encryption.is_encrypted);
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} else if (tri.track_type == kVideo) {
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RCHECK(!stsd.video_entries.empty());
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if (desc_idx > stsd.video_entries.size())
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desc_idx = 0;
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tri.video_description = &stsd.video_entries[desc_idx];
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// We don't support encrypted non-fragmented mp4 for now.
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RCHECK(!tri.video_description->sinf.info.track_encryption.is_encrypted);
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}
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uint32 samples_per_chunk = chunk_info.samples_per_chunk();
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tri.samples.resize(samples_per_chunk);
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for (uint32 k = 0; k < samples_per_chunk; ++k) {
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SampleInfo& sample = tri.samples[k];
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sample.size = sample_size.sample_size != 0
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? sample_size.sample_size
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: sample_size.sizes[sample_index];
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sample.duration = decoding_time.sample_delta();
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sample.cts_offset =
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has_composition_offset ? composition_offset.sample_offset() : 0;
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sample.is_keyframe = sync_sample.IsSyncSample();
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run_start_dts += sample.duration;
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// Advance to next sample. Should success except for last sample.
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++sample_index;
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RCHECK(chunk_info.AdvanceSample() && sync_sample.AdvanceSample());
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if (sample_index == num_samples) {
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// We should hit end of tables for decoding time and composition
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// offset.
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RCHECK(!decoding_time.AdvanceSample());
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if (has_composition_offset)
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RCHECK(!composition_offset.AdvanceSample());
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} else {
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RCHECK(decoding_time.AdvanceSample());
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if (has_composition_offset)
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RCHECK(composition_offset.AdvanceSample());
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}
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}
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runs_.push_back(tri);
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}
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}
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std::sort(runs_.begin(), runs_.end(), CompareMinTrackRunDataOffset());
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run_itr_ = runs_.begin();
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ResetRun();
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return true;
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}
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bool TrackRunIterator::Init(const MovieFragment& moof) {
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runs_.clear();
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for (size_t i = 0; i < moof.tracks.size(); i++) {
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const TrackFragment& traf = moof.tracks[i];
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const Track* trak = NULL;
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for (size_t t = 0; t < moov_->tracks.size(); t++) {
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if (moov_->tracks[t].header.track_id == traf.header.track_id)
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trak = &moov_->tracks[t];
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}
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RCHECK(trak);
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const TrackExtends* trex = NULL;
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for (size_t t = 0; t < moov_->extends.tracks.size(); t++) {
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if (moov_->extends.tracks[t].track_id == traf.header.track_id)
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trex = &moov_->extends.tracks[t];
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}
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RCHECK(trex);
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const SampleDescription& stsd =
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trak->media.information.sample_table.description;
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if (stsd.type != kAudio && stsd.type != kVideo) {
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DVLOG(1) << "Skipping unhandled track type";
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continue;
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}
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size_t desc_idx = traf.header.sample_description_index;
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if (!desc_idx)
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desc_idx = trex->default_sample_description_index;
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RCHECK(desc_idx > 0); // Descriptions are one-indexed in the file
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desc_idx -= 1;
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int64 run_start_dts = traf.decode_time.decode_time;
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int sample_count_sum = 0;
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for (size_t j = 0; j < traf.runs.size(); j++) {
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const TrackFragmentRun& trun = traf.runs[j];
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TrackRunInfo tri;
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tri.track_id = traf.header.track_id;
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tri.timescale = trak->media.header.timescale;
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tri.start_dts = run_start_dts;
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tri.sample_start_offset = trun.data_offset;
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tri.track_type = stsd.type;
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if (tri.track_type == kAudio) {
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RCHECK(!stsd.audio_entries.empty());
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if (desc_idx > stsd.audio_entries.size())
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desc_idx = 0;
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tri.audio_description = &stsd.audio_entries[desc_idx];
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} else if (tri.track_type == kVideo) {
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RCHECK(!stsd.video_entries.empty());
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if (desc_idx > stsd.video_entries.size())
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desc_idx = 0;
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tri.video_description = &stsd.video_entries[desc_idx];
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}
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// Collect information from the auxiliary_offset entry with the same index
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// in the 'saiz' container as the current run's index in the 'trun'
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// container, if it is present.
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if (traf.auxiliary_offset.offsets.size() > j) {
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// There should be an auxiliary info entry corresponding to each sample
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// in the auxiliary offset entry's corresponding track run.
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RCHECK(traf.auxiliary_size.sample_count >=
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sample_count_sum + trun.sample_count);
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tri.aux_info_start_offset = traf.auxiliary_offset.offsets[j];
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tri.aux_info_default_size =
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traf.auxiliary_size.default_sample_info_size;
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if (tri.aux_info_default_size == 0) {
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const std::vector<uint8>& sizes =
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traf.auxiliary_size.sample_info_sizes;
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tri.aux_info_sizes.insert(
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tri.aux_info_sizes.begin(),
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sizes.begin() + sample_count_sum,
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sizes.begin() + sample_count_sum + trun.sample_count);
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}
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// If the default info size is positive, find the total size of the aux
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// info block from it, otherwise sum over the individual sizes of each
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// aux info entry in the aux_offset entry.
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if (tri.aux_info_default_size) {
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tri.aux_info_total_size =
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tri.aux_info_default_size * trun.sample_count;
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} else {
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tri.aux_info_total_size = 0;
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for (size_t k = 0; k < trun.sample_count; k++) {
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tri.aux_info_total_size += tri.aux_info_sizes[k];
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}
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}
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} else {
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tri.aux_info_start_offset = -1;
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tri.aux_info_total_size = 0;
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}
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tri.samples.resize(trun.sample_count);
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for (size_t k = 0; k < trun.sample_count; k++) {
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PopulateSampleInfo(*trex, traf.header, trun, k, &tri.samples[k]);
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run_start_dts += tri.samples[k].duration;
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}
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runs_.push_back(tri);
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sample_count_sum += trun.sample_count;
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}
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}
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std::sort(runs_.begin(), runs_.end(), CompareMinTrackRunDataOffset());
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run_itr_ = runs_.begin();
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ResetRun();
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return true;
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}
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void TrackRunIterator::AdvanceRun() {
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++run_itr_;
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ResetRun();
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}
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void TrackRunIterator::ResetRun() {
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if (!IsRunValid())
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return;
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sample_dts_ = run_itr_->start_dts;
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sample_offset_ = run_itr_->sample_start_offset;
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sample_itr_ = run_itr_->samples.begin();
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cenc_info_.clear();
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}
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void TrackRunIterator::AdvanceSample() {
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DCHECK(IsSampleValid());
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sample_dts_ += sample_itr_->duration;
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sample_offset_ += sample_itr_->size;
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++sample_itr_;
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}
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// This implementation only indicates a need for caching if CENC auxiliary
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// info is available in the stream.
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bool TrackRunIterator::AuxInfoNeedsToBeCached() {
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DCHECK(IsRunValid());
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return is_encrypted() && aux_info_size() > 0 && cenc_info_.size() == 0;
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}
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// This implementation currently only caches CENC auxiliary info.
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bool TrackRunIterator::CacheAuxInfo(const uint8* buf, int buf_size) {
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RCHECK(AuxInfoNeedsToBeCached() && buf_size >= aux_info_size());
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cenc_info_.resize(run_itr_->samples.size());
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int64 pos = 0;
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for (size_t i = 0; i < run_itr_->samples.size(); i++) {
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int info_size = run_itr_->aux_info_default_size;
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if (!info_size)
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info_size = run_itr_->aux_info_sizes[i];
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BufferReader reader(buf + pos, info_size);
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RCHECK(cenc_info_[i].Parse(track_encryption().default_iv_size, &reader));
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pos += info_size;
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}
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return true;
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}
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bool TrackRunIterator::IsRunValid() const { return run_itr_ != runs_.end(); }
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bool TrackRunIterator::IsSampleValid() const {
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return IsRunValid() && (sample_itr_ != run_itr_->samples.end());
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}
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// Because tracks are in sorted order and auxiliary information is cached when
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// returning samples, it is guaranteed that no data will be required before the
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// lesser of the minimum data offset of this track and the next in sequence.
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// (The stronger condition - that no data is required before the minimum data
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// offset of this track alone - is not guaranteed, because the BMFF spec does
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// not have any inter-run ordering restrictions.)
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int64 TrackRunIterator::GetMaxClearOffset() {
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int64 offset = kint64max;
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if (IsSampleValid()) {
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offset = std::min(offset, sample_offset_);
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if (AuxInfoNeedsToBeCached())
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offset = std::min(offset, aux_info_offset());
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}
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if (run_itr_ != runs_.end()) {
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std::vector<TrackRunInfo>::const_iterator next_run = run_itr_ + 1;
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if (next_run != runs_.end()) {
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offset = std::min(offset, next_run->sample_start_offset);
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if (next_run->aux_info_total_size)
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offset = std::min(offset, next_run->aux_info_start_offset);
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}
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}
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if (offset == kint64max)
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return runs_.empty() ? 0 : runs_[0].sample_start_offset;
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return offset;
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}
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uint32 TrackRunIterator::track_id() const {
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DCHECK(IsRunValid());
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return run_itr_->track_id;
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}
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bool TrackRunIterator::is_encrypted() const {
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DCHECK(IsRunValid());
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return track_encryption().is_encrypted;
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}
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int64 TrackRunIterator::aux_info_offset() const {
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return run_itr_->aux_info_start_offset;
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}
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int TrackRunIterator::aux_info_size() const {
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return run_itr_->aux_info_total_size;
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}
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|
|
|
bool TrackRunIterator::is_audio() const {
|
|
DCHECK(IsRunValid());
|
|
return run_itr_->track_type == kAudio;
|
|
}
|
|
|
|
bool TrackRunIterator::is_video() const {
|
|
DCHECK(IsRunValid());
|
|
return run_itr_->track_type == kVideo;
|
|
}
|
|
|
|
const AudioSampleEntry& TrackRunIterator::audio_description() const {
|
|
DCHECK(is_audio());
|
|
DCHECK(run_itr_->audio_description);
|
|
return *run_itr_->audio_description;
|
|
}
|
|
|
|
const VideoSampleEntry& TrackRunIterator::video_description() const {
|
|
DCHECK(is_video());
|
|
DCHECK(run_itr_->video_description);
|
|
return *run_itr_->video_description;
|
|
}
|
|
|
|
int64 TrackRunIterator::sample_offset() const {
|
|
DCHECK(IsSampleValid());
|
|
return sample_offset_;
|
|
}
|
|
|
|
int TrackRunIterator::sample_size() const {
|
|
DCHECK(IsSampleValid());
|
|
return sample_itr_->size;
|
|
}
|
|
|
|
int64 TrackRunIterator::dts() const {
|
|
DCHECK(IsSampleValid());
|
|
return sample_dts_;
|
|
}
|
|
|
|
int64 TrackRunIterator::cts() const {
|
|
DCHECK(IsSampleValid());
|
|
return sample_dts_ + sample_itr_->cts_offset;
|
|
}
|
|
|
|
int64 TrackRunIterator::duration() const {
|
|
DCHECK(IsSampleValid());
|
|
return sample_itr_->duration;
|
|
}
|
|
|
|
bool TrackRunIterator::is_keyframe() const {
|
|
DCHECK(IsSampleValid());
|
|
return sample_itr_->is_keyframe;
|
|
}
|
|
|
|
const TrackEncryption& TrackRunIterator::track_encryption() const {
|
|
if (is_audio())
|
|
return audio_description().sinf.info.track_encryption;
|
|
DCHECK(is_video());
|
|
return video_description().sinf.info.track_encryption;
|
|
}
|
|
|
|
scoped_ptr<DecryptConfig> TrackRunIterator::GetDecryptConfig() {
|
|
size_t sample_idx = sample_itr_ - run_itr_->samples.begin();
|
|
DCHECK_LT(sample_idx, cenc_info_.size());
|
|
const FrameCENCInfo& cenc_info = cenc_info_[sample_idx];
|
|
DCHECK(is_encrypted());
|
|
DCHECK(!AuxInfoNeedsToBeCached());
|
|
|
|
const size_t total_size_of_subsamples = cenc_info.GetTotalSizeOfSubsamples();
|
|
if (total_size_of_subsamples != 0 &&
|
|
total_size_of_subsamples != static_cast<size_t>(sample_size())) {
|
|
LOG(ERROR) << "Incorrect CENC subsample size.";
|
|
return scoped_ptr<DecryptConfig>();
|
|
}
|
|
|
|
return scoped_ptr<DecryptConfig>(new DecryptConfig(
|
|
track_encryption().default_kid,
|
|
cenc_info.iv(),
|
|
0, // No offset to start of media data in MP4 using CENC.
|
|
cenc_info.subsamples()));
|
|
}
|
|
|
|
} // namespace mp4
|
|
} // namespace media
|