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/* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
/* vim:set ts=2 sw=2 sts=2 et cindent: */
/* 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
#include "WaveDemuxer.h"
#include <inttypes.h>
#include <algorithm>
#include "mozilla/Assertions.h"
#include "mozilla/Utf8.h"
#include "BufferReader.h"
#include "mozilla/EndianUtils.h"
#include "VideoUtils.h"
#include "TimeUnits.h"
#include "mozilla/Logging.h"
using mozilla::media::TimeIntervals;
using mozilla::media::TimeUnit;
extern mozilla::LazyLogModule gMediaDemuxerLog;
namespace mozilla {
#define LOG(msg, ...) \
MOZ_LOG(gMediaDemuxerLog, LogLevel::Debug, msg, ##__VA_ARGS__)
WAVDemuxer::WAVDemuxer(MediaResource* aSource) : mSource(aSource) {
DDLINKCHILD("source", aSource);
}
bool WAVDemuxer::InitInternal() {
if (!mTrackDemuxer) {
mTrackDemuxer = new WAVTrackDemuxer(mSource.GetResource());
DDLINKCHILD("track demuxer", mTrackDemuxer.get());
}
return mTrackDemuxer->Init();
}
RefPtr<WAVDemuxer::InitPromise> WAVDemuxer::Init() {
if (!InitInternal()) {
return InitPromise::CreateAndReject(NS_ERROR_DOM_MEDIA_METADATA_ERR,
__func__);
}
return InitPromise::CreateAndResolve(NS_OK, __func__);
}
uint32_t WAVDemuxer::GetNumberTracks(TrackInfo::TrackType aType) const {
return aType == TrackInfo::kAudioTrack ? 1u : 0u;
}
already_AddRefed<MediaTrackDemuxer> WAVDemuxer::GetTrackDemuxer(
TrackInfo::TrackType aType, uint32_t aTrackNumber) {
if (!mTrackDemuxer) {
return nullptr;
}
return RefPtr<WAVTrackDemuxer>(mTrackDemuxer).forget();
}
bool WAVDemuxer::IsSeekable() const { return true; }
// WAVTrackDemuxer
WAVTrackDemuxer::WAVTrackDemuxer(MediaResource* aSource)
: mSource(aSource),
mOffset(0),
mFirstChunkOffset(0),
mNumParsedChunks(0),
mChunkIndex(0),
mDataLength(0),
mTotalChunkLen(0),
mSamplesPerChunk(0),
mSamplesPerSecond(0),
mChannels(0),
mSampleFormat(0) {
DDLINKCHILD("source", aSource);
Reset();
}
bool WAVTrackDemuxer::Init() {
Reset();
FastSeek(TimeUnit());
if (!mInfo) {
mInfo = MakeUnique<AudioInfo>();
mInfo->mCodecSpecificConfig =
AudioCodecSpecificVariant{WaveCodecSpecificData{}};
}
if (!RIFFParserInit()) {
return false;
}
bool hasValidFmt = false;
while (true) {
if (!HeaderParserInit()) {
return false;
}
uint32_t chunkName = mHeaderParser.GiveHeader().ChunkName();
uint32_t chunkSize = mHeaderParser.GiveHeader().ChunkSize();
if (chunkName == FRMT_CODE) {
hasValidFmt = FmtChunkParserInit();
} else if (chunkName == LIST_CODE) {
mHeaderParser.Reset();
uint64_t endOfListChunk = static_cast<uint64_t>(mOffset) + chunkSize;
if (endOfListChunk > UINT32_MAX) {
return false;
}
if (!ListChunkParserInit(chunkSize)) {
mOffset = endOfListChunk;
}
} else if (chunkName == DATA_CODE) {
mDataLength = chunkSize;
if (mFirstChunkOffset != mOffset) {
mFirstChunkOffset = mOffset;
}
break;
} else {
mOffset += chunkSize; // Skip other irrelevant chunks.
}
if (mOffset & 1) {
// Wave files are 2-byte aligned so we need to round up
mOffset += 1;
}
mHeaderParser.Reset();
}
if (!hasValidFmt) {
return false;
}
int64_t streamLength = StreamLength();
// If the chunk length and the resource length are not equal, use the
// resource length as the "real" data chunk length, if it's longer than the
// chunk size.
if (streamLength != -1) {
uint64_t streamLengthPositive = static_cast<uint64_t>(streamLength);
if (streamLengthPositive > mFirstChunkOffset &&
mDataLength > streamLengthPositive - mFirstChunkOffset) {
mDataLength = streamLengthPositive - mFirstChunkOffset;
}
}
mSamplesPerSecond = mFmtChunk.SampleRate();
mChannels = mFmtChunk.Channels();
if (!mSamplesPerSecond || !mChannels || !mFmtChunk.ValidBitsPerSamples()) {
return false;
}
mSamplesPerChunk =
DATA_CHUNK_SIZE * 8 / mChannels / mFmtChunk.ValidBitsPerSamples();
mSampleFormat = mFmtChunk.ValidBitsPerSamples();
mInfo->mRate = mSamplesPerSecond;
mInfo->mChannels = mChannels;
mInfo->mBitDepth = mFmtChunk.ValidBitsPerSamples();
mInfo->mProfile = AssertedCast<uint8_t>(mFmtChunk.WaveFormat() & 0x00FF);
mInfo->mExtendedProfile =
AssertedCast<uint8_t>(mFmtChunk.WaveFormat() & 0xFF00 >> 8);
mInfo->mMimeType = "audio/wave; codecs=";
// 1: linear integer pcm
// 3: float
// 6: alaw
// 7: ulaw
mInfo->mMimeType.AppendInt(mInfo->mProfile);
mInfo->mDuration = Duration();
mInfo->mChannelMap = mFmtChunk.ChannelMap();
if (AudioConfig::ChannelLayout::Channels(mInfo->mChannelMap) !=
mInfo->mChannels) {
AudioConfig::ChannelLayout::ChannelMap defaultForChannelCount =
AudioConfig::ChannelLayout(mInfo->mChannels).Map();
LOG(("Channel count of %" PRIu32
" and channel layout disagree, overriding channel map from %s to %s",
mInfo->mChannels,
AudioConfig::ChannelLayout::ChannelMapToString(mInfo->mChannelMap)
.get(),
AudioConfig::ChannelLayout::ChannelMapToString(defaultForChannelCount)
.get()));
mInfo->mChannelMap = defaultForChannelCount;
}
LOG(("WavDemuxer initialized: %s", mInfo->ToString().get()));
return mInfo->mDuration.IsPositive();
}
bool WAVTrackDemuxer::RIFFParserInit() {
RefPtr<MediaRawData> riffHeader = GetFileHeader(FindRIFFHeader());
if (!riffHeader) {
return false;
}
BufferReader RIFFReader(riffHeader->Data(), 12);
Unused << mRIFFParser.Parse(RIFFReader);
return mRIFFParser.RiffHeader().IsValid(11);
}
bool WAVTrackDemuxer::HeaderParserInit() {
RefPtr<MediaRawData> header = GetFileHeader(FindChunkHeader());
if (!header) {
return false;
}
BufferReader headerReader(header->Data(), 8);
Unused << mHeaderParser.Parse(headerReader);
return true;
}
bool WAVTrackDemuxer::FmtChunkParserInit() {
RefPtr<MediaRawData> fmtChunk = GetFileHeader(FindFmtChunk());
if (!fmtChunk || fmtChunk->Size() < 16) {
return false;
}
nsTArray<uint8_t> fmtChunkData(fmtChunk->Data(), fmtChunk->Size());
mFmtChunk.Init(std::move(fmtChunkData));
return true;
}
bool WAVTrackDemuxer::ListChunkParserInit(uint32_t aChunkSize) {
uint32_t bytesRead = 0;
RefPtr<MediaRawData> infoTag = GetFileHeader(FindInfoTag());
if (!infoTag) {
return false;
}
BufferReader infoTagReader(infoTag->Data(), 4);
auto res = infoTagReader.ReadU32();
if (res.isErr() || (res.isOk() && res.unwrap() != INFO_CODE)) {
return false;
}
bytesRead += 4;
while (bytesRead < aChunkSize) {
if (!HeaderParserInit()) {
return false;
}
bytesRead += 8;
uint32_t id = mHeaderParser.GiveHeader().ChunkName();
uint32_t length = mHeaderParser.GiveHeader().ChunkSize();
// SubChunk Length Cannot Exceed List Chunk length.
if (length > aChunkSize - bytesRead) {
length = aChunkSize - bytesRead;
}
MediaByteRange mRange = {mOffset, mOffset + length};
RefPtr<MediaRawData> mChunkData = GetFileHeader(mRange);
if (!mChunkData) {
return false;
}
const char* rawData = reinterpret_cast<const char*>(mChunkData->Data());
nsCString val(rawData, length);
if (length > 0 && val[length - 1] == '\0') {
val.SetLength(length - 1);
}
if (length % 2) {
mOffset += 1;
length += length % 2;
}
bytesRead += length;
if (!IsUtf8(val)) {
mHeaderParser.Reset();
continue;
}
switch (id) {
case 0x49415254: // IART
mInfo->mTags.AppendElement(MetadataTag("artist"_ns, val));
break;
case 0x49434d54: // ICMT
mInfo->mTags.AppendElement(MetadataTag("comments"_ns, val));
break;
case 0x49474e52: // IGNR
mInfo->mTags.AppendElement(MetadataTag("genre"_ns, val));
break;
case 0x494e414d: // INAM
mInfo->mTags.AppendElement(MetadataTag("name"_ns, val));
break;
default:
LOG(("Metadata key %08x not handled", id));
}
mHeaderParser.Reset();
}
return true;
}
media::TimeUnit WAVTrackDemuxer::SeekPosition() const {
TimeUnit pos = Duration(mChunkIndex);
if (Duration() > TimeUnit()) {
pos = std::min(Duration(), pos);
}
return pos;
}
RefPtr<MediaRawData> WAVTrackDemuxer::DemuxSample() {
return GetNextChunk(FindNextChunk());
}
UniquePtr<TrackInfo> WAVTrackDemuxer::GetInfo() const { return mInfo->Clone(); }
RefPtr<WAVTrackDemuxer::SeekPromise> WAVTrackDemuxer::Seek(
const TimeUnit& aTime) {
FastSeek(aTime);
const TimeUnit seekTime = ScanUntil(aTime);
return SeekPromise::CreateAndResolve(seekTime, __func__);
}
TimeUnit WAVTrackDemuxer::FastSeek(const TimeUnit& aTime) {
if (aTime.ToMicroseconds()) {
mChunkIndex = ChunkIndexFromTime(aTime);
} else {
mChunkIndex = 0;
}
mOffset = OffsetFromChunkIndex(mChunkIndex);
if (mOffset > mFirstChunkOffset && StreamLength() > 0) {
mOffset = std::min(static_cast<uint64_t>(StreamLength() - 1), mOffset);
}
return Duration(mChunkIndex);
}
TimeUnit WAVTrackDemuxer::ScanUntil(const TimeUnit& aTime) {
if (!aTime.ToMicroseconds()) {
return FastSeek(aTime);
}
if (Duration(mChunkIndex) > aTime) {
FastSeek(aTime);
}
return SeekPosition();
}
RefPtr<WAVTrackDemuxer::SamplesPromise> WAVTrackDemuxer::GetSamples(
int32_t aNumSamples) {
MOZ_ASSERT(aNumSamples);
RefPtr<SamplesHolder> datachunks = new SamplesHolder();
while (aNumSamples--) {
RefPtr<MediaRawData> datachunk = GetNextChunk(FindNextChunk());
if (!datachunk) {
break;
}
if (!datachunk->HasValidTime()) {
return SamplesPromise::CreateAndReject(NS_ERROR_DOM_MEDIA_DEMUXER_ERR,
__func__);
}
datachunks->AppendSample(datachunk);
}
if (datachunks->GetSamples().IsEmpty()) {
return SamplesPromise::CreateAndReject(NS_ERROR_DOM_MEDIA_END_OF_STREAM,
__func__);
}
return SamplesPromise::CreateAndResolve(datachunks, __func__);
}
void WAVTrackDemuxer::Reset() {
FastSeek(TimeUnit());
mParser.Reset();
mHeaderParser.Reset();
mRIFFParser.Reset();
}
RefPtr<WAVTrackDemuxer::SkipAccessPointPromise>
WAVTrackDemuxer::SkipToNextRandomAccessPoint(const TimeUnit& aTimeThreshold) {
return SkipAccessPointPromise::CreateAndReject(
SkipFailureHolder(NS_ERROR_DOM_MEDIA_DEMUXER_ERR, 0), __func__);
}
int64_t WAVTrackDemuxer::GetResourceOffset() const {
return AssertedCast<int64_t>(mOffset);
}
TimeIntervals WAVTrackDemuxer::GetBuffered() {
TimeUnit duration = Duration();
if (duration <= TimeUnit()) {
return TimeIntervals();
}
AutoPinned<MediaResource> stream(mSource.GetResource());
return GetEstimatedBufferedTimeRanges(stream, duration.ToMicroseconds());
}
int64_t WAVTrackDemuxer::StreamLength() const { return mSource.GetLength(); }
TimeUnit WAVTrackDemuxer::Duration() const {
if (!mDataLength || !mChannels || !mSampleFormat) {
return TimeUnit();
}
int64_t numSamples =
static_cast<int64_t>(mDataLength) * 8 / mChannels / mSampleFormat;
int64_t numUSeconds = USECS_PER_S * numSamples / mSamplesPerSecond;
if (USECS_PER_S * numSamples % mSamplesPerSecond > mSamplesPerSecond / 2) {
numUSeconds++;
}
return TimeUnit::FromMicroseconds(numUSeconds);
}
TimeUnit WAVTrackDemuxer::Duration(int64_t aNumDataChunks) const {
if (!mSamplesPerSecond || !mSamplesPerChunk) {
return TimeUnit();
}
const int64_t frames = mSamplesPerChunk * aNumDataChunks;
return TimeUnit(frames, mSamplesPerSecond);
}
TimeUnit WAVTrackDemuxer::DurationFromBytes(uint32_t aNumBytes) const {
if (!mSamplesPerSecond || !mChannels || !mSampleFormat) {
return TimeUnit();
}
uint64_t numSamples = aNumBytes * 8 / mChannels / mSampleFormat;
return TimeUnit(numSamples, mSamplesPerSecond);
}
MediaByteRange WAVTrackDemuxer::FindNextChunk() {
if (mOffset + DATA_CHUNK_SIZE < mFirstChunkOffset + mDataLength) {
return {mOffset, mOffset + DATA_CHUNK_SIZE};
}
return {mOffset, mFirstChunkOffset + mDataLength};
}
MediaByteRange WAVTrackDemuxer::FindChunkHeader() {
return {mOffset, mOffset + CHUNK_HEAD_SIZE};
}
MediaByteRange WAVTrackDemuxer::FindRIFFHeader() {
return {mOffset, mOffset + RIFF_CHUNK_SIZE};
}
MediaByteRange WAVTrackDemuxer::FindFmtChunk() {
return {mOffset, mOffset + mHeaderParser.GiveHeader().ChunkSize()};
}
MediaByteRange WAVTrackDemuxer::FindListChunk() {
return {mOffset, mOffset + mHeaderParser.GiveHeader().ChunkSize()};
}
MediaByteRange WAVTrackDemuxer::FindInfoTag() { return {mOffset, mOffset + 4}; }
bool WAVTrackDemuxer::SkipNextChunk(const MediaByteRange& aRange) {
UpdateState(aRange);
return true;
}
already_AddRefed<MediaRawData> WAVTrackDemuxer::GetNextChunk(
const MediaByteRange& aRange) {
if (!aRange.Length()) {
return nullptr;
}
RefPtr<MediaRawData> datachunk = new MediaRawData();
datachunk->mOffset = aRange.mStart;
UniquePtr<MediaRawDataWriter> chunkWriter(datachunk->CreateWriter());
if (!chunkWriter->SetSize(static_cast<uint32_t>(aRange.Length()))) {
return nullptr;
}
const uint32_t read = Read(chunkWriter->Data(), datachunk->mOffset,
AssertedCast<int64_t>(datachunk->Size()));
if (read != aRange.Length()) {
return nullptr;
}
UpdateState(aRange);
++mNumParsedChunks;
++mChunkIndex;
datachunk->mTime = Duration(mChunkIndex - 1);
if (static_cast<uint32_t>(mChunkIndex) * DATA_CHUNK_SIZE < mDataLength) {
datachunk->mDuration = Duration(1);
} else {
uint32_t mBytesRemaining = mDataLength - mChunkIndex * DATA_CHUNK_SIZE;
datachunk->mDuration = DurationFromBytes(mBytesRemaining);
}
datachunk->mTimecode = datachunk->mTime;
datachunk->mKeyframe = true;
MOZ_ASSERT(!datachunk->mTime.IsNegative());
MOZ_ASSERT(!datachunk->mDuration.IsNegative());
return datachunk.forget();
}
already_AddRefed<MediaRawData> WAVTrackDemuxer::GetFileHeader(
const MediaByteRange& aRange) {
if (!aRange.Length()) {
return nullptr;
}
RefPtr<MediaRawData> fileHeader = new MediaRawData();
fileHeader->mOffset = aRange.mStart;
UniquePtr<MediaRawDataWriter> headerWriter(fileHeader->CreateWriter());
if (!headerWriter->SetSize(static_cast<uint32_t>(aRange.Length()))) {
return nullptr;
}
const uint32_t read = Read(headerWriter->Data(), fileHeader->mOffset,
AssertedCast<int64_t>(fileHeader->Size()));
if (read != aRange.Length()) {
return nullptr;
}
UpdateState(aRange);
return fileHeader.forget();
}
uint64_t WAVTrackDemuxer::OffsetFromChunkIndex(uint32_t aChunkIndex) const {
return mFirstChunkOffset + aChunkIndex * DATA_CHUNK_SIZE;
}
uint64_t WAVTrackDemuxer::ChunkIndexFromTime(
const media::TimeUnit& aTime) const {
if (!mSamplesPerChunk || !mSamplesPerSecond) {
return 0;
}
double chunkDurationS =
mSamplesPerChunk / static_cast<double>(mSamplesPerSecond);
int64_t chunkIndex = std::floor(aTime.ToSeconds() / chunkDurationS);
return chunkIndex;
}
void WAVTrackDemuxer::UpdateState(const MediaByteRange& aRange) {
// Full chunk parsed, move offset to its end.
mOffset = static_cast<uint32_t>(aRange.mEnd);
mTotalChunkLen += static_cast<uint64_t>(aRange.Length());
}
int64_t WAVTrackDemuxer::Read(uint8_t* aBuffer, int64_t aOffset,
int64_t aSize) {
const int64_t streamLen = StreamLength();
if (mInfo && streamLen > 0) {
int64_t max = streamLen > aOffset ? streamLen - aOffset : 0;
aSize = std::min(aSize, max);
}
uint32_t read = 0;
const nsresult rv = mSource.ReadAt(aOffset, reinterpret_cast<char*>(aBuffer),
static_cast<uint32_t>(aSize), &read);
NS_ENSURE_SUCCESS(rv, 0);
return read;
}
// RIFFParser
Result<uint32_t, nsresult> RIFFParser::Parse(BufferReader& aReader) {
for (auto res = aReader.ReadU8();
res.isOk() && !mRiffHeader.ParseNext(res.unwrap());
res = aReader.ReadU8()) {
}
if (mRiffHeader.IsValid()) {
return RIFF_CHUNK_SIZE;
}
return 0;
}
void RIFFParser::Reset() { mRiffHeader.Reset(); }
const RIFFParser::RIFFHeader& RIFFParser::RiffHeader() const {
return mRiffHeader;
}
// RIFFParser::RIFFHeader
RIFFParser::RIFFHeader::RIFFHeader() { Reset(); }
void RIFFParser::RIFFHeader::Reset() {
memset(mRaw, 0, sizeof(mRaw));
mPos = 0;
}
bool RIFFParser::RIFFHeader::ParseNext(uint8_t c) {
if (!Update(c)) {
Reset();
if (!Update(c)) {
Reset();
}
}
return IsValid();
}
bool RIFFParser::RIFFHeader::IsValid(int aPos) const {
if (aPos > -1 && aPos < 4) {
return RIFF[aPos] == mRaw[aPos];
}
if (aPos > 7 && aPos < 12) {
return WAVE[aPos - 8] == mRaw[aPos];
}
return true;
}
bool RIFFParser::RIFFHeader::IsValid() const { return mPos >= RIFF_CHUNK_SIZE; }
bool RIFFParser::RIFFHeader::Update(uint8_t c) {
if (mPos < RIFF_CHUNK_SIZE) {
mRaw[mPos] = c;
}
return IsValid(mPos++);
}
// HeaderParser
Result<uint32_t, nsresult> HeaderParser::Parse(BufferReader& aReader) {
for (auto res = aReader.ReadU8();
res.isOk() && !mHeader.ParseNext(res.unwrap()); res = aReader.ReadU8()) {
}
if (mHeader.IsValid()) {
return CHUNK_HEAD_SIZE;
}
return 0;
}
void HeaderParser::Reset() { mHeader.Reset(); }
const HeaderParser::ChunkHeader& HeaderParser::GiveHeader() const {
return mHeader;
}
// HeaderParser::ChunkHeader
HeaderParser::ChunkHeader::ChunkHeader() { Reset(); }
void HeaderParser::ChunkHeader::Reset() {
memset(mRaw, 0, sizeof(mRaw));
mPos = 0;
}
bool HeaderParser::ChunkHeader::ParseNext(uint8_t c) {
Update(c);
return IsValid();
}
bool HeaderParser::ChunkHeader::IsValid() const {
return mPos >= CHUNK_HEAD_SIZE;
}
uint32_t HeaderParser::ChunkHeader::ChunkName() const {
return static_cast<uint32_t>(
((mRaw[0] << 24) | (mRaw[1] << 16) | (mRaw[2] << 8) | (mRaw[3])));
}
uint32_t HeaderParser::ChunkHeader::ChunkSize() const {
return static_cast<uint32_t>(
((mRaw[7] << 24) | (mRaw[6] << 16) | (mRaw[5] << 8) | (mRaw[4])));
}
void HeaderParser::ChunkHeader::Update(uint8_t c) {
if (mPos < CHUNK_HEAD_SIZE) {
mRaw[mPos++] = c;
}
}
// FormatChunk
void FormatChunk::Init(nsTArray<uint8_t>&& aData) { mRaw = std::move(aData); }
uint16_t FormatChunk::Channels() const { return (mRaw[3] << 8) | (mRaw[2]); }
uint32_t FormatChunk::SampleRate() const {
return static_cast<uint32_t>((mRaw[7] << 24) | (mRaw[6] << 16) |
(mRaw[5] << 8) | (mRaw[4]));
}
uint16_t FormatChunk::AverageBytesPerSec() const {
return static_cast<uint16_t>((mRaw[11] << 24) | (mRaw[10] << 16) |
(mRaw[9] << 8) | (mRaw[8]));
}
uint16_t FormatChunk::BlockAlign() const {
return static_cast<uint16_t>(mRaw[13] << 8) | (mRaw[12]);
}
uint16_t FormatChunk::ValidBitsPerSamples() const {
return (mRaw[15] << 8) | (mRaw[14]);
}
// Constants to deal with WAVEFORMATEXTENSIBLE struct
constexpr size_t MIN_SIZE_WAVEFORMATEXTENSIBLE = 22;
constexpr size_t OFFSET_CHANNEL_MAP = 20;
constexpr size_t OFFSET_FORMAT = 24;
constexpr size_t SIZE_WAVEFORMATEX = 18;
template <typename T>
Result<T, nsresult> GetFromExtradata(const nsTArray<uint8_t>& aRawData,
size_t aOffset) {
// Check there is extradata
MOZ_ASSERT(((aRawData[1] << 8) | aRawData[0]) == 0xFFFE,
"GetFromExtradata called without a tag of 0xFFFE");
if (aRawData.Length() <= SIZE_WAVEFORMATEX) {
return Err(NS_ERROR_UNEXPECTED);
}
uint16_t extradataSize =
static_cast<uint16_t>(aRawData[17] << 8) | (aRawData[16]);
// The length of this chunk is at least 18, check if it's long enough to
// hold the WAVE_FORMAT_EXTENSIBLE struct, that is 22 more than the
// WAVEFORMATEX.
if (extradataSize < MIN_SIZE_WAVEFORMATEXTENSIBLE ||
aRawData.Length() < SIZE_WAVEFORMATEX + MIN_SIZE_WAVEFORMATEXTENSIBLE) {
return Err(NS_ERROR_UNEXPECTED);
}
BufferReader reader(aRawData.Elements() + aOffset, sizeof(T));
T value = reader.ReadType<T>();
T swapped = mozilla::NativeEndian::swapFromLittleEndian(value);
return swapped;
}
uint16_t FormatChunk::WaveFormat() const {
uint16_t format = (mRaw[1] << 8) | mRaw[0];
if (format != 0xFFFE) {
return format;
}
auto formatResult = GetFromExtradata<uint16_t>(mRaw, OFFSET_FORMAT);
if (formatResult.isErr()) {
LOG(("Error getting the Wave format, returning PCM"));
return 1;
}
return formatResult.unwrap();
}
AudioConfig::ChannelLayout::ChannelMap FormatChunk::ChannelMap() const {
uint16_t format = (mRaw[1] << 8) | mRaw[0];
if (format != 0xFFFE) {
return AudioConfig::ChannelLayout(Channels()).Map();
}
auto mapResult = GetFromExtradata<uint32_t>(mRaw, OFFSET_CHANNEL_MAP);
if (mapResult.isErr()) {
LOG(("Error getting channel map, falling back to default order"));
return AudioConfig::ChannelLayout(Channels()).Map();
}
// ChannelLayout::ChannelMap is by design bit-per-bit compatible with
// WAVEFORMATEXTENSIBLE's dwChannelMask attribute.
return mapResult.unwrap();
}
// DataParser
DataParser::DataParser() = default;
void DataParser::Reset() { mChunk.Reset(); }
const DataParser::DataChunk& DataParser::CurrentChunk() const { return mChunk; }
// DataParser::DataChunk
void DataParser::DataChunk::Reset() { mPos = 0; }
} // namespace mozilla