// Copyright (c) 2012 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "media/mp4/mp4_media_parser.h" #include "base/callback.h" #include "base/callback_helpers.h" #include "base/logging.h" #include "base/memory/ref_counted.h" #include "media/base/audio_stream_info.h" #include "media/base/media_sample.h" #include "media/base/video_stream_info.h" #include "media/mp4/box_definitions.h" #include "media/mp4/box_reader.h" #include "media/mp4/es_descriptor.h" #include "media/mp4/rcheck.h" #include "media/mp4/track_run_iterator.h" namespace { uint64 Rescale(uint64 time_in_old_scale, uint32 old_scale, uint32 new_scale) { return (static_cast(time_in_old_scale) / old_scale) * new_scale; } } // namespace namespace media { namespace mp4 { MP4MediaParser::MP4MediaParser() : state_(kWaitingForInit), moof_head_(0), mdat_tail_(0) {} MP4MediaParser::~MP4MediaParser() {} void MP4MediaParser::Init(const InitCB& init_cb, const NewSampleCB& new_sample_cb, const NeedKeyCB& need_key_cb) { DCHECK_EQ(state_, kWaitingForInit); DCHECK(init_cb_.is_null()); DCHECK(!init_cb.is_null()); DCHECK(!new_sample_cb.is_null()); DCHECK(!need_key_cb.is_null()); ChangeState(kParsingBoxes); init_cb_ = init_cb; new_sample_cb_ = new_sample_cb; need_key_cb_ = need_key_cb; } void MP4MediaParser::Reset() { queue_.Reset(); runs_.reset(); moof_head_ = 0; mdat_tail_ = 0; } bool MP4MediaParser::Parse(const uint8* buf, int size) { DCHECK_NE(state_, kWaitingForInit); if (state_ == kError) return false; queue_.Push(buf, size); bool result, err = false; do { if (state_ == kParsingBoxes) { result = ParseBox(&err); } else { DCHECK_EQ(kEmittingSamples, state_); result = EnqueueSample(&err); if (result) { int64 max_clear = runs_->GetMaxClearOffset() + moof_head_; err = !ReadAndDiscardMDATsUntil(max_clear); } } } while (result && !err); if (err) { DLOG(ERROR) << "Error while parsing MP4"; moov_.reset(); Reset(); ChangeState(kError); return false; } return true; } bool MP4MediaParser::ParseBox(bool* err) { const uint8* buf; int size; queue_.Peek(&buf, &size); if (!size) return false; scoped_ptr reader(BoxReader::ReadTopLevelBox(buf, size, err)); if (reader.get() == NULL) return false; if (reader->type() == FOURCC_MDAT) { // The code ends up here only if a MOOV box is not yet seen. DCHECK(!moov_); NOTIMPLEMENTED() << " Files with MDAT before MOOV is not supported yet."; *err = true; return false; } // Set up mdat offset for ReadMDATsUntil(). mdat_tail_ = queue_.head() + reader->size(); if (reader->type() == FOURCC_MOOV) { *err = !ParseMoov(reader.get()); } else if (reader->type() == FOURCC_MOOF) { moof_head_ = queue_.head(); *err = !ParseMoof(reader.get()); // Return early to avoid evicting 'moof' data from queue. Auxiliary info may // be located anywhere in the file, including inside the 'moof' itself. // (Since 'default-base-is-moof' is mandated, no data references can come // before the head of the 'moof', so keeping this box around is sufficient.) return !(*err); } else { DLOG(WARNING) << "Skipping unrecognized top-level box: " << FourCCToString(reader->type()); } queue_.Pop(reader->size()); return !(*err); } bool MP4MediaParser::ParseMoov(BoxReader* reader) { moov_.reset(new Movie); RCHECK(moov_->Parse(reader)); runs_.reset(); std::vector > streams; for (std::vector::const_iterator track = moov_->tracks.begin(); track != moov_->tracks.end(); ++track) { const uint32 timescale = track->media.header.timescale; // Calculate duration (based on timescale). uint64 duration = 0; if (track->media.header.duration > 0) { duration = track->media.header.duration; } else if (moov_->extends.header.fragment_duration > 0) { DCHECK(moov_->header.timescale != 0); duration = Rescale(moov_->extends.header.fragment_duration, moov_->header.timescale, timescale); } else if (moov_->header.duration > 0 && moov_->header.duration != kuint64max) { DCHECK(moov_->header.timescale != 0); duration = Rescale(moov_->header.duration, moov_->header.timescale, timescale); } const SampleDescription& samp_descr = track->media.information.sample_table.description; size_t desc_idx = 0; // Read sample description index from mvex if it exists otherwise read // from the first entry in Sample To Chunk box. if (moov_->extends.tracks.size() > 0) { for (size_t t = 0; t < moov_->extends.tracks.size(); t++) { const TrackExtends& trex = moov_->extends.tracks[t]; if (trex.track_id == track->header.track_id) { desc_idx = trex.default_sample_description_index; break; } } } else { const std::vector& chunk_info = track->media.information.sample_table.sample_to_chunk.chunk_info; RCHECK(chunk_info.size() > 0); desc_idx = chunk_info[0].sample_description_index; } RCHECK(desc_idx > 0); desc_idx -= 1; // BMFF descriptor index is one-based if (track->media.handler.type == kAudio) { RCHECK(!samp_descr.audio_entries.empty()); // It is not uncommon to find otherwise-valid files with incorrect sample // description indices, so we fail gracefully in that case. if (desc_idx >= samp_descr.audio_entries.size()) desc_idx = 0; const AudioSampleEntry& entry = samp_descr.audio_entries[desc_idx]; if (!(entry.format == FOURCC_MP4A || entry.format == FOURCC_EAC3 || (entry.format == FOURCC_ENCA && entry.sinf.format.format == FOURCC_MP4A))) { LOG(ERROR) << "Unsupported audio format 0x" << std::hex << entry.format << " in stsd box."; return false; } ObjectType audio_type = entry.esds.es_descriptor.object_type(); DVLOG(1) << "audio_type " << std::hex << audio_type; if (audio_type == kForbidden && entry.format == FOURCC_EAC3) { audio_type = kEAC3; } AudioCodec codec = kUnknownAudioCodec; uint8 num_channels = 0; uint32 sampling_frequency = 0; uint8 audio_object_type = 0; std::vector extra_data; // Check if it is MPEG4 AAC defined in ISO 14496 Part 3 or // supported MPEG2 AAC variants. if (entry.esds.es_descriptor.IsAAC()) { codec = kCodecAAC; const AACAudioSpecificConfig& aac_audio_specific_config = entry.esds.aac_audio_specific_config; num_channels = aac_audio_specific_config.num_channels(); sampling_frequency = aac_audio_specific_config.frequency(); audio_object_type = aac_audio_specific_config.audio_object_type(); extra_data = entry.esds.es_descriptor.decoder_specific_info(); } else if (audio_type == kEAC3) { codec = kCodecEAC3; num_channels = entry.channelcount; sampling_frequency = entry.samplerate; } else { LOG(ERROR) << "Unsupported audio object type 0x" << std::hex << audio_type << " in esds."; return false; } bool is_encrypted = entry.sinf.info.track_encryption.is_encrypted; DVLOG(1) << "is_audio_track_encrypted_: " << is_encrypted; streams.push_back(new AudioStreamInfo( track->header.track_id, timescale, duration, codec, AudioStreamInfo::GetCodecString(codec, audio_object_type), track->media.header.language, entry.samplesize, num_channels, sampling_frequency, extra_data.size() ? &extra_data[0] : NULL, extra_data.size(), is_encrypted)); } if (track->media.handler.type == kVideo) { RCHECK(!samp_descr.video_entries.empty()); if (desc_idx >= samp_descr.video_entries.size()) desc_idx = 0; const VideoSampleEntry& entry = samp_descr.video_entries[desc_idx]; if (!(entry.format == FOURCC_AVC1 || (entry.format == FOURCC_ENCV && entry.sinf.format.format == FOURCC_AVC1))) { LOG(ERROR) << "Unsupported video format 0x" << std::hex << entry.format << " in stsd box."; return false; } const std::string codec_string = VideoStreamInfo::GetCodecString(kCodecH264, entry.avcc.profile_indication, entry.avcc.profile_compatibility, entry.avcc.avc_level); bool is_encrypted = entry.sinf.info.track_encryption.is_encrypted; DVLOG(1) << "is_video_track_encrypted_: " << is_encrypted; streams.push_back(new VideoStreamInfo(track->header.track_id, timescale, duration, kCodecH264, codec_string, track->media.header.language, entry.width, entry.height, entry.avcc.length_size, &entry.avcc.data[0], entry.avcc.data.size(), is_encrypted)); } } init_cb_.Run(streams); EmitNeedKeyIfNecessary(moov_->pssh); runs_.reset(new TrackRunIterator(moov_.get())); RCHECK(runs_->Init()); ChangeState(kEmittingSamples); return true; } bool MP4MediaParser::ParseMoof(BoxReader* reader) { // Must already have initialization segment. RCHECK(moov_.get() && runs_.get()); MovieFragment moof; RCHECK(moof.Parse(reader)); RCHECK(runs_->Init(moof)); EmitNeedKeyIfNecessary(moof.pssh); ChangeState(kEmittingSamples); return true; } void MP4MediaParser::EmitNeedKeyIfNecessary( const std::vector& headers) { if (headers.empty()) return; size_t total_size = 0; for (size_t i = 0; i < headers.size(); i++) total_size += headers[i].raw_box.size(); scoped_ptr init_data(new uint8[total_size]); size_t pos = 0; for (size_t i = 0; i < headers.size(); i++) { memcpy(&init_data.get()[pos], &headers[i].raw_box[0], headers[i].raw_box.size()); pos += headers[i].raw_box.size(); } need_key_cb_.Run(CONTAINER_MOV, init_data.Pass(), total_size); } bool MP4MediaParser::EnqueueSample(bool* err) { if (!runs_->IsRunValid()) { // Remain in kEnqueueingSamples state, discarding data, until the end of // the current 'mdat' box has been appended to the queue. if (!queue_.Trim(mdat_tail_)) return false; ChangeState(kParsingBoxes); return true; } if (!runs_->IsSampleValid()) { runs_->AdvanceRun(); return true; } DCHECK(!(*err)); const uint8* buf; int buf_size; queue_.Peek(&buf, &buf_size); if (!buf_size) return false; // Skip this entire track if it is not audio nor video. if (!runs_->is_audio() && !runs_->is_video()) runs_->AdvanceRun(); // Attempt to cache the auxiliary information first. Aux info is usually // placed in a contiguous block before the sample data, rather than being // interleaved. If we didn't cache it, this would require that we retain the // start of the segment buffer while reading samples. Aux info is typically // quite small compared to sample data, so this pattern is useful on // memory-constrained devices where the source buffer consumes a substantial // portion of the total system memory. if (runs_->AuxInfoNeedsToBeCached()) { queue_.PeekAt(runs_->aux_info_offset() + moof_head_, &buf, &buf_size); if (buf_size < runs_->aux_info_size()) return false; *err = !runs_->CacheAuxInfo(buf, buf_size); return !*err; } queue_.PeekAt(runs_->sample_offset() + moof_head_, &buf, &buf_size); if (buf_size < runs_->sample_size()) return false; scoped_ptr decrypt_config; std::vector subsamples; if (runs_->is_encrypted()) { decrypt_config = runs_->GetDecryptConfig(); if (!decrypt_config) { *err = true; return false; } subsamples = decrypt_config->subsamples(); } if (decrypt_config) { if (!subsamples.empty()) { // Create a new config with the updated subsamples. decrypt_config.reset(new DecryptConfig(decrypt_config->key_id(), decrypt_config->iv(), decrypt_config->data_offset(), subsamples)); } // else, use the existing config. } std::vector frame_buf(buf, buf + runs_->sample_size()); scoped_refptr stream_sample = MediaSample::CopyFrom( &frame_buf[0], frame_buf.size(), runs_->is_keyframe()); if (decrypt_config) stream_sample->set_decrypt_config(decrypt_config.Pass()); stream_sample->set_dts(runs_->dts()); stream_sample->set_pts(runs_->cts()); stream_sample->set_duration(runs_->duration()); DVLOG(3) << "Pushing frame: " << ", key=" << runs_->is_keyframe() << ", dur=" << runs_->duration() << ", dts=" << runs_->dts() << ", cts=" << runs_->cts() << ", size=" << runs_->sample_size(); new_sample_cb_.Run(runs_->track_id(), stream_sample); runs_->AdvanceSample(); return true; } bool MP4MediaParser::ReadAndDiscardMDATsUntil(const int64 offset) { bool err = false; while (mdat_tail_ < offset) { const uint8* buf; int size; queue_.PeekAt(mdat_tail_, &buf, &size); FourCC type; int box_sz; if (!BoxReader::StartTopLevelBox(buf, size, &type, &box_sz, &err)) break; if (type != FOURCC_MDAT) { LOG(ERROR) << "Unexpected box type while parsing MDATs: " << FourCCToString(type); } mdat_tail_ += box_sz; } queue_.Trim(std::min(mdat_tail_, offset)); return !err; } void MP4MediaParser::ChangeState(State new_state) { DVLOG(2) << "Changing state: " << new_state; state_ = new_state; } } // namespace mp4 } // namespace media