/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* vim: set ts=8 sts=2 et sw=2 tw=80: */ /* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #include "ContainerParser.h" #include "WebMBufferedParser.h" #include "mozilla/EndianUtils.h" #include "mozilla/IntegerPrintfMacros.h" #include "mozilla/ErrorResult.h" #include "MoofParser.h" #include "mozilla/Logging.h" #include "mozilla/Maybe.h" #include "mozilla/Result.h" #include "MediaData.h" #include "nsMimeTypes.h" #ifdef MOZ_FMP4 # include "AtomType.h" # include "BufferReader.h" # include "ByteStream.h" # include "MP4Interval.h" # include "SampleIterator.h" #endif #include "SourceBufferResource.h" #include extern mozilla::LogModule* GetMediaSourceSamplesLog(); #define MSE_DEBUG(arg, ...) \ DDMOZ_LOG(GetMediaSourceSamplesLog(), mozilla::LogLevel::Debug, \ "(%s)::%s: " arg, mType.OriginalString().Data(), __func__, \ ##__VA_ARGS__) #define MSE_DEBUGV(arg, ...) \ DDMOZ_LOG(GetMediaSourceSamplesLog(), mozilla::LogLevel::Verbose, \ "(%s)::%s: " arg, mType.OriginalString().Data(), __func__, \ ##__VA_ARGS__) #define MSE_DEBUGVEX(_this, arg, ...) \ DDMOZ_LOGEX(_this, GetMediaSourceSamplesLog(), mozilla::LogLevel::Verbose, \ "(%s)::%s: " arg, mType.OriginalString().Data(), __func__, \ ##__VA_ARGS__) namespace mozilla { ContainerParser::ContainerParser(const MediaContainerType& aType) : mHasInitData(false), mTotalParsed(0), mGlobalOffset(0), mType(aType) {} ContainerParser::~ContainerParser() = default; MediaResult ContainerParser::IsInitSegmentPresent(const MediaSpan& aData) { MSE_DEBUG( "aLength=%zu [%x%x%x%x]", aData.Length(), aData.Length() > 0 ? aData[0] : 0, aData.Length() > 1 ? aData[1] : 0, aData.Length() > 2 ? aData[2] : 0, aData.Length() > 3 ? aData[3] : 0); return NS_ERROR_NOT_AVAILABLE; } MediaResult ContainerParser::IsMediaSegmentPresent(const MediaSpan& aData) { MSE_DEBUG( "aLength=%zu [%x%x%x%x]", aData.Length(), aData.Length() > 0 ? aData[0] : 0, aData.Length() > 1 ? aData[1] : 0, aData.Length() > 2 ? aData[2] : 0, aData.Length() > 3 ? aData[3] : 0); return NS_ERROR_NOT_AVAILABLE; } MediaResult ContainerParser::ParseStartAndEndTimestamps(const MediaSpan& aData, media::TimeUnit& aStart, media::TimeUnit& aEnd) { return NS_ERROR_NOT_AVAILABLE; } bool ContainerParser::TimestampsFuzzyEqual(int64_t aLhs, int64_t aRhs) { return llabs(aLhs - aRhs) <= GetRoundingError(); } int64_t ContainerParser::GetRoundingError() { NS_WARNING("Using default ContainerParser::GetRoundingError implementation"); return 0; } bool ContainerParser::HasCompleteInitData() { return mHasInitData && !!mInitData->Length(); } MediaByteBuffer* ContainerParser::InitData() { return mInitData; } MediaByteRange ContainerParser::InitSegmentRange() { return mCompleteInitSegmentRange; } MediaByteRange ContainerParser::MediaHeaderRange() { return mCompleteMediaHeaderRange; } MediaByteRange ContainerParser::MediaSegmentRange() { return mCompleteMediaSegmentRange; } DDLoggedTypeDeclNameAndBase(WebMContainerParser, ContainerParser); class WebMContainerParser : public ContainerParser, public DecoderDoctorLifeLogger { public: explicit WebMContainerParser(const MediaContainerType& aType) : ContainerParser(aType), mParser(0), mOffset(0) {} static const unsigned NS_PER_USEC = 1000; MediaResult IsInitSegmentPresent(const MediaSpan& aData) override { ContainerParser::IsInitSegmentPresent(aData); if (aData.Length() < 4) { return NS_ERROR_NOT_AVAILABLE; } WebMBufferedParser parser(0); nsTArray mapping; if (auto result = parser.Append(aData.Elements(), aData.Length(), mapping); NS_FAILED(result)) { return result; } return parser.mInitEndOffset > 0 ? NS_OK : NS_ERROR_NOT_AVAILABLE; } MediaResult IsMediaSegmentPresent(const MediaSpan& aData) override { ContainerParser::IsMediaSegmentPresent(aData); if (aData.Length() < 4) { return NS_ERROR_NOT_AVAILABLE; } WebMBufferedParser parser(0); nsTArray mapping; parser.AppendMediaSegmentOnly(); if (auto result = parser.Append(aData.Elements(), aData.Length(), mapping); NS_FAILED(result)) { return result; } return parser.GetClusterOffset() >= 0 ? NS_OK : NS_ERROR_NOT_AVAILABLE; } MediaResult ParseStartAndEndTimestamps(const MediaSpan& aData, media::TimeUnit& aStart, media::TimeUnit& aEnd) override { bool initSegment = NS_SUCCEEDED(IsInitSegmentPresent(aData)); if (mLastMapping && (initSegment || NS_SUCCEEDED(IsMediaSegmentPresent(aData)))) { // The last data contained a complete cluster but we can only detect it // now that a new one is starting. // We use mOffset as end position to ensure that any blocks not reported // by WebMBufferParser are properly skipped. mCompleteMediaSegmentRange = MediaByteRange(mLastMapping.ref().mSyncOffset, mOffset) + mGlobalOffset; mLastMapping.reset(); MSE_DEBUG("New cluster found at start, ending previous one"); return NS_ERROR_NOT_AVAILABLE; } if (initSegment) { mOffset = 0; mParser = WebMBufferedParser(0); mOverlappedMapping.Clear(); mInitData = new MediaByteBuffer(); mResource = new SourceBufferResource(); DDLINKCHILD("resource", mResource.get()); mCompleteInitSegmentRange = MediaByteRange(); mCompleteMediaHeaderRange = MediaByteRange(); mCompleteMediaSegmentRange = MediaByteRange(); mGlobalOffset = mTotalParsed; } // XXX if it only adds new mappings, overlapped but not available // (e.g. overlap < 0) frames are "lost" from the reported mappings here. nsTArray mapping; mapping.AppendElements(mOverlappedMapping); mOverlappedMapping.Clear(); if (auto result = mParser.Append(aData.Elements(), aData.Length(), mapping); NS_FAILED(result)) { return result; } if (mResource) { mResource->AppendData(aData); } // XXX This is a bit of a hack. Assume if there are no timecodes // present and it's an init segment that it's _just_ an init segment. // We should be more precise. if (initSegment || !HasCompleteInitData()) { if (mParser.mInitEndOffset > 0) { MOZ_DIAGNOSTIC_ASSERT(mInitData && mResource && mParser.mInitEndOffset <= mResource->GetLength()); if (!mInitData->SetLength(mParser.mInitEndOffset, fallible)) { // Super unlikely OOM return NS_ERROR_OUT_OF_MEMORY; } mCompleteInitSegmentRange = MediaByteRange(0, mParser.mInitEndOffset) + mGlobalOffset; char* buffer = reinterpret_cast(mInitData->Elements()); mResource->ReadFromCache(buffer, 0, mParser.mInitEndOffset); MSE_DEBUG("Stashed init of %" PRId64 " bytes.", mParser.mInitEndOffset); mResource = nullptr; } else { MSE_DEBUG("Incomplete init found."); } mHasInitData = true; } mOffset += aData.Length(); mTotalParsed += aData.Length(); if (mapping.IsEmpty()) { return NS_ERROR_NOT_AVAILABLE; } // Calculate media range for first media segment. // Check if we have a cluster finishing in the current data. uint32_t endIdx = mapping.Length() - 1; bool foundNewCluster = false; while (mapping[0].mSyncOffset != mapping[endIdx].mSyncOffset) { endIdx -= 1; foundNewCluster = true; } int32_t completeIdx = endIdx; while (completeIdx >= 0 && mOffset < mapping[completeIdx].mEndOffset) { MSE_DEBUG("block is incomplete, missing: %" PRId64, mapping[completeIdx].mEndOffset - mOffset); completeIdx -= 1; } // Save parsed blocks for which we do not have all data yet. mOverlappedMapping.AppendElements(mapping.Elements() + completeIdx + 1, mapping.Length() - completeIdx - 1); if (completeIdx < 0) { mLastMapping.reset(); return NS_ERROR_NOT_AVAILABLE; } if (mCompleteMediaHeaderRange.IsEmpty()) { mCompleteMediaHeaderRange = MediaByteRange(mapping[0].mSyncOffset, mapping[0].mEndOffset) + mGlobalOffset; } if (foundNewCluster && mOffset >= mapping[endIdx].mEndOffset) { // We now have all information required to delimit a complete cluster. int64_t endOffset = mapping[endIdx + 1].mSyncOffset; if (mapping[endIdx + 1].mInitOffset > mapping[endIdx].mInitOffset) { // We have a new init segment before this cluster. endOffset = mapping[endIdx + 1].mInitOffset; } mCompleteMediaSegmentRange = MediaByteRange(mapping[endIdx].mSyncOffset, endOffset) + mGlobalOffset; } else if (mapping[endIdx].mClusterEndOffset >= 0 && mOffset >= mapping[endIdx].mClusterEndOffset) { mCompleteMediaSegmentRange = MediaByteRange( mapping[endIdx].mSyncOffset, mParser.EndSegmentOffset(mapping[endIdx].mClusterEndOffset)) + mGlobalOffset; } Maybe previousMapping; if (completeIdx) { previousMapping = Some(mapping[completeIdx - 1]); } else { previousMapping = mLastMapping; } mLastMapping = Some(mapping[completeIdx]); if (!previousMapping && completeIdx + 1u >= mapping.Length()) { // We have no previous nor next block available, // so we can't estimate this block's duration. return NS_ERROR_NOT_AVAILABLE; } uint64_t frameDuration = (completeIdx + 1u < mapping.Length()) ? mapping[completeIdx + 1].mTimecode - mapping[completeIdx].mTimecode : mapping[completeIdx].mTimecode - previousMapping.ref().mTimecode; aStart = media::TimeUnit::FromNanoseconds( AssertedCast(mapping[0].mTimecode)); aEnd = media::TimeUnit::FromNanoseconds( AssertedCast(mapping[completeIdx].mTimecode + frameDuration)); MSE_DEBUG("[%" PRId64 ", %" PRId64 "] [fso=%" PRId64 ", leo=%" PRId64 ", l=%zu processedIdx=%u fs=%" PRId64 "]", aStart.ToMicroseconds(), aEnd.ToMicroseconds(), mapping[0].mSyncOffset, mapping[completeIdx].mEndOffset, mapping.Length(), completeIdx, mCompleteMediaSegmentRange.mEnd); return NS_OK; } int64_t GetRoundingError() override { int64_t error = mParser.GetTimecodeScale() / NS_PER_USEC; return error * 2; } private: WebMBufferedParser mParser; nsTArray mOverlappedMapping; int64_t mOffset; Maybe mLastMapping; }; #ifdef MOZ_FMP4 DDLoggedTypeDeclNameAndBase(MP4Stream, ByteStream); class MP4Stream : public ByteStream, public DecoderDoctorLifeLogger { public: explicit MP4Stream(SourceBufferResource* aResource); virtual ~MP4Stream(); bool ReadAt(int64_t aOffset, void* aBuffer, size_t aCount, size_t* aBytesRead) override; bool CachedReadAt(int64_t aOffset, void* aBuffer, size_t aCount, size_t* aBytesRead) override; bool Length(int64_t* aSize) override; const uint8_t* GetContiguousAccess(int64_t aOffset, size_t aSize) override; private: RefPtr mResource; }; MP4Stream::MP4Stream(SourceBufferResource* aResource) : mResource(aResource) { MOZ_COUNT_CTOR(MP4Stream); MOZ_ASSERT(aResource); DDLINKCHILD("resource", aResource); } MP4Stream::~MP4Stream() { MOZ_COUNT_DTOR(MP4Stream); } bool MP4Stream::ReadAt(int64_t aOffset, void* aBuffer, size_t aCount, size_t* aBytesRead) { return CachedReadAt(aOffset, aBuffer, aCount, aBytesRead); } bool MP4Stream::CachedReadAt(int64_t aOffset, void* aBuffer, size_t aCount, size_t* aBytesRead) { nsresult rv = mResource->ReadFromCache(reinterpret_cast(aBuffer), aOffset, aCount); if (NS_FAILED(rv)) { *aBytesRead = 0; return false; } *aBytesRead = aCount; return true; } const uint8_t* MP4Stream::GetContiguousAccess(int64_t aOffset, size_t aSize) { return mResource->GetContiguousAccess(aOffset, aSize); } bool MP4Stream::Length(int64_t* aSize) { if (mResource->GetLength() < 0) return false; *aSize = mResource->GetLength(); return true; } DDLoggedTypeDeclNameAndBase(MP4ContainerParser, ContainerParser); class MP4ContainerParser : public ContainerParser, public DecoderDoctorLifeLogger { public: explicit MP4ContainerParser(const MediaContainerType& aType) : ContainerParser(aType) {} MediaResult IsInitSegmentPresent(const MediaSpan& aData) override { ContainerParser::IsInitSegmentPresent(aData); // Each MP4 atom has a chunk size and chunk type. The root chunk in an MP4 // file is the 'ftyp' atom followed by a file type. We just check for a // vaguely valid 'ftyp' atom. if (aData.Length() < 8) { return NS_ERROR_NOT_AVAILABLE; } AtomParser parser(*this, aData, AtomParser::StopAt::eInitSegment); if (!parser.IsValid()) { return MediaResult( NS_ERROR_FAILURE, RESULT_DETAIL("Invalid Top-Level Box:%s", parser.LastInvalidBox())); } return parser.StartWithInitSegment() ? NS_OK : NS_ERROR_NOT_AVAILABLE; } MediaResult IsMediaSegmentPresent(const MediaSpan& aData) override { if (aData.Length() < 8) { return NS_ERROR_NOT_AVAILABLE; } AtomParser parser(*this, aData, AtomParser::StopAt::eMediaSegment); if (!parser.IsValid()) { return MediaResult( NS_ERROR_FAILURE, RESULT_DETAIL("Invalid Box:%s", parser.LastInvalidBox())); } return parser.StartWithMediaSegment() ? NS_OK : NS_ERROR_NOT_AVAILABLE; } private: class AtomParser { public: enum class StopAt { eInitSegment, eMediaSegment, eEnd }; AtomParser(const MP4ContainerParser& aParser, const MediaSpan& aData, StopAt aStop = StopAt::eEnd) { mValid = Init(aParser, aData, aStop).isOk(); } Result Init(const MP4ContainerParser& aParser, const MediaSpan& aData, StopAt aStop) { const MediaContainerType mType( aParser.ContainerType()); // for logging macro. BufferReader reader(aData); AtomType initAtom("moov"); AtomType mediaAtom("moof"); AtomType dataAtom("mdat"); // Valid top-level boxes defined in ISO/IEC 14496-12 (Table 1) static const AtomType validBoxes[] = { "ftyp", "moov", // init segment "pdin", "free", "sidx", // optional prior moov box "styp", "moof", "mdat", // media segment "mfra", "skip", "meta", "meco", "ssix", "prft", // others. "pssh", // optional with encrypted EME, though ignored. "emsg", // ISO23009-1:2014 Section 5.10.3.3 "bloc", "uuid" // boxes accepted by chrome. }; while (reader.Remaining() >= 8) { uint32_t tmp; MOZ_TRY_VAR(tmp, reader.ReadU32()); uint64_t size = tmp; const uint8_t* typec = reader.Peek(4); MOZ_TRY_VAR(tmp, reader.ReadU32()); AtomType type(tmp); MSE_DEBUGVEX(&aParser, "Checking atom:'%c%c%c%c' @ %u", typec[0], typec[1], typec[2], typec[3], (uint32_t)reader.Offset() - 8); if (std::find(std::begin(validBoxes), std::end(validBoxes), type) == std::end(validBoxes)) { // No valid box found, no point continuing. mLastInvalidBox[0] = typec[0]; mLastInvalidBox[1] = typec[1]; mLastInvalidBox[2] = typec[2]; mLastInvalidBox[3] = typec[3]; mLastInvalidBox[4] = '\0'; return Err(NS_ERROR_FAILURE); } if (mInitOffset.isNothing() && AtomType(type) == initAtom) { mInitOffset = Some(reader.Offset()); } if (mMediaOffset.isNothing() && AtomType(type) == mediaAtom) { mMediaOffset = Some(reader.Offset()); } if (mDataOffset.isNothing() && AtomType(type) == dataAtom) { mDataOffset = Some(reader.Offset()); } if (size == 1) { // 64 bits size. MOZ_TRY_VAR(size, reader.ReadU64()); } else if (size == 0) { // Atom extends to the end of the buffer, it can't have what we're // looking for. break; } if (reader.Remaining() < size - 8) { // Incomplete atom. break; } reader.Read(size - 8); if (aStop == StopAt::eInitSegment && (mInitOffset || mMediaOffset)) { // When we're looking for an init segment, if we encountered a media // segment, it we will need to be processed first. So we can stop // right away if we have found a media segment. break; } if (aStop == StopAt::eMediaSegment && (mInitOffset || (mMediaOffset && mDataOffset))) { // When we're looking for a media segment, if we encountered an init // segment, it we will need to be processed first. So we can stop // right away if we have found an init segment. break; } } return Ok(); } bool StartWithInitSegment() const { return mInitOffset.isSome() && (mMediaOffset.isNothing() || mInitOffset.ref() < mMediaOffset.ref()); } bool StartWithMediaSegment() const { return mMediaOffset.isSome() && (mInitOffset.isNothing() || mMediaOffset.ref() < mInitOffset.ref()); } bool IsValid() const { return mValid; } const char* LastInvalidBox() const { return mLastInvalidBox; } private: Maybe mInitOffset; Maybe mMediaOffset; Maybe mDataOffset; bool mValid; char mLastInvalidBox[5]; }; public: MediaResult ParseStartAndEndTimestamps(const MediaSpan& aData, media::TimeUnit& aStart, media::TimeUnit& aEnd) override { bool initSegment = NS_SUCCEEDED(IsInitSegmentPresent(aData)); if (initSegment) { mResource = new SourceBufferResource(); DDLINKCHILD("resource", mResource.get()); mStream = new MP4Stream(mResource); // We use a timestampOffset of 0 for ContainerParser, and require // consumers of ParseStartAndEndTimestamps to add their timestamp offset // manually. This allows the ContainerParser to be shared across different // timestampOffsets. mParser = MakeUnique(mStream, AsVariant(ParseAllTracks{}), /* aIsAudio = */ false); DDLINKCHILD("parser", mParser.get()); mInitData = new MediaByteBuffer(); mCompleteInitSegmentRange = MediaByteRange(); mCompleteMediaHeaderRange = MediaByteRange(); mCompleteMediaSegmentRange = MediaByteRange(); mGlobalOffset = mTotalParsed; } else if (!mStream || !mParser) { mTotalParsed += aData.Length(); return NS_ERROR_NOT_AVAILABLE; } MOZ_DIAGNOSTIC_ASSERT(mResource && mParser && mInitData, "Should have received an init segment first"); mResource->AppendData(aData); MediaByteRangeSet byteRanges; byteRanges += MediaByteRange(int64_t(mParser->mOffset), mResource->GetLength()); mParser->RebuildFragmentedIndex(byteRanges); if (initSegment || !HasCompleteInitData()) { MediaByteRange& range = mParser->mInitRange; if (range.Length()) { mCompleteInitSegmentRange = range + mGlobalOffset; if (!mInitData->SetLength(range.Length(), fallible)) { // Super unlikely OOM return NS_ERROR_OUT_OF_MEMORY; } char* buffer = reinterpret_cast(mInitData->Elements()); mResource->ReadFromCache(buffer, range.mStart, range.Length()); MSE_DEBUG("Stashed init of %" PRIu64 " bytes.", range.Length()); } else { MSE_DEBUG("Incomplete init found."); } mHasInitData = true; } mTotalParsed += aData.Length(); MP4Interval compositionRange = mParser->GetCompositionRange(byteRanges); mCompleteMediaHeaderRange = mParser->FirstCompleteMediaHeader() + mGlobalOffset; mCompleteMediaSegmentRange = mParser->FirstCompleteMediaSegment() + mGlobalOffset; if (HasCompleteInitData()) { mResource->EvictData(mParser->mOffset, mParser->mOffset); } if (compositionRange.IsNull()) { return NS_ERROR_NOT_AVAILABLE; } aStart = compositionRange.start; aEnd = compositionRange.end; MSE_DEBUG("[%" PRId64 ", %" PRId64 "]", aStart.ToMicroseconds(), aEnd.ToMicroseconds()); return NS_OK; } // Gaps of up to 35ms (marginally longer than a single frame at 30fps) are // considered to be sequential frames. int64_t GetRoundingError() override { return 35000; } private: RefPtr mStream; UniquePtr mParser; }; #endif // MOZ_FMP4 #ifdef MOZ_FMP4 DDLoggedTypeDeclNameAndBase(ADTSContainerParser, ContainerParser); class ADTSContainerParser : public ContainerParser, public DecoderDoctorLifeLogger { public: explicit ADTSContainerParser(const MediaContainerType& aType) : ContainerParser(aType) {} typedef struct { size_t header_length; // Length of just the initialization data. size_t frame_length; // Includes header_length; uint8_t aac_frames; // Number of AAC frames in the ADTS frame. bool have_crc; } Header; /// Helper to parse the ADTS header, returning data we care about. /// Returns true if the header is parsed successfully. /// Returns false if the header is invalid or incomplete, /// without modifying the passed-in Header object. bool Parse(const MediaSpan& aData, Header& header) { // ADTS initialization segments are just the packet header. if (aData.Length() < 7) { MSE_DEBUG("buffer too short for header."); return false; } // Check 0xfffx sync word plus layer 0. if ((aData[0] != 0xff) || ((aData[1] & 0xf6) != 0xf0)) { MSE_DEBUG("no syncword."); return false; } bool have_crc = !(aData[1] & 0x01); if (have_crc && aData.Length() < 9) { MSE_DEBUG("buffer too short for header with crc."); return false; } uint8_t frequency_index = (aData[2] & 0x3c) >> 2; MOZ_ASSERT(frequency_index < 16); if (frequency_index == 15) { MSE_DEBUG("explicit frequency disallowed."); return false; } size_t header_length = have_crc ? 9 : 7; size_t data_length = ((aData[3] & 0x03) << 11) | ((aData[4] & 0xff) << 3) | ((aData[5] & 0xe0) >> 5); uint8_t frames = (aData[6] & 0x03) + 1; MOZ_ASSERT(frames > 0); MOZ_ASSERT(frames < 4); // Return successfully parsed data. header.header_length = header_length; header.frame_length = header_length + data_length; header.aac_frames = frames; header.have_crc = have_crc; return true; } MediaResult IsInitSegmentPresent(const MediaSpan& aData) override { // Call superclass for logging. ContainerParser::IsInitSegmentPresent(aData); Header header; if (!Parse(aData, header)) { return NS_ERROR_NOT_AVAILABLE; } MSE_DEBUGV("%llu byte frame %d aac frames%s", (unsigned long long)header.frame_length, (int)header.aac_frames, header.have_crc ? " crc" : ""); return NS_OK; } MediaResult IsMediaSegmentPresent(const MediaSpan& aData) override { // Call superclass for logging. ContainerParser::IsMediaSegmentPresent(aData); // Make sure we have a header so we know how long the frame is. // NB this assumes the media segment buffer starts with an // initialization segment. Since every frame has an ADTS header // this is a normal place to divide packets, but we can re-parse // mInitData if we need to handle separate media segments. Header header; if (!Parse(aData, header)) { return NS_ERROR_NOT_AVAILABLE; } // We're supposed to return true as long as aData contains the // start of a media segment, whether or not it's complete. So // return true if we have any data beyond the header. if (aData.Length() <= header.header_length) { return NS_ERROR_NOT_AVAILABLE; } // We should have at least a partial frame. return NS_OK; } MediaResult ParseStartAndEndTimestamps(const MediaSpan& aData, media::TimeUnit& aStart, media::TimeUnit& aEnd) override { // ADTS header. Header header; if (!Parse(aData, header)) { return NS_ERROR_NOT_AVAILABLE; } mHasInitData = true; mCompleteInitSegmentRange = MediaByteRange(0, int64_t(header.header_length)); // Cache raw header in case the caller wants a copy. mInitData = new MediaByteBuffer(header.header_length); mInitData->AppendElements(aData.Elements(), header.header_length); // Check that we have enough data for the frame body. if (aData.Length() < header.frame_length) { MSE_DEBUGV( "Not enough data for %llu byte frame" " in %llu byte buffer.", (unsigned long long)header.frame_length, (unsigned long long)(aData.Length())); return NS_ERROR_NOT_AVAILABLE; } mCompleteMediaSegmentRange = MediaByteRange(header.header_length, header.frame_length); // The ADTS MediaSource Byte Stream Format document doesn't // define media header. Just treat it the same as the whole // media segment. mCompleteMediaHeaderRange = mCompleteMediaSegmentRange; MSE_DEBUG("[%" PRId64 ", %" PRId64 "]", aStart.ToMicroseconds(), aEnd.ToMicroseconds()); // We don't update timestamps, regardless. return NS_ERROR_NOT_AVAILABLE; } // Audio shouldn't have gaps. // Especially when we generate the timestamps ourselves. int64_t GetRoundingError() override { return 0; } }; #endif // MOZ_FMP4 /*static*/ UniquePtr ContainerParser::CreateForMIMEType( const MediaContainerType& aType) { if (aType.Type() == MEDIAMIMETYPE(VIDEO_WEBM) || aType.Type() == MEDIAMIMETYPE(AUDIO_WEBM)) { return MakeUnique(aType); } #ifdef MOZ_FMP4 if (aType.Type() == MEDIAMIMETYPE(VIDEO_MP4) || aType.Type() == MEDIAMIMETYPE(AUDIO_MP4)) { return MakeUnique(aType); } if (aType.Type() == MEDIAMIMETYPE("audio/aac")) { return MakeUnique(aType); } #endif return MakeUnique(aType); } #undef MSE_DEBUG #undef MSE_DEBUGV #undef MSE_DEBUGVEX } // namespace mozilla