/* -*- 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 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #include "nsError.h" #include "nsBuiltinDecoder.h" #include "MediaResource.h" #include "nsWaveReader.h" #include "nsTimeRanges.h" #include "VideoUtils.h" #include "mozilla/StandardInteger.h" using namespace mozilla; // Un-comment to enable logging of seek bisections. //#define SEEK_LOGGING #ifdef PR_LOGGING extern PRLogModuleInfo* gBuiltinDecoderLog; #define LOG(type, msg) PR_LOG(gBuiltinDecoderLog, type, msg) #ifdef SEEK_LOGGING #define SEEK_LOG(type, msg) PR_LOG(gBuiltinDecoderLog, type, msg) #else #define SEEK_LOG(type, msg) #endif #else #define LOG(type, msg) #define SEEK_LOG(type, msg) #endif // Magic values that identify RIFF chunks we're interested in. static const PRUint32 RIFF_CHUNK_MAGIC = 0x52494646; static const PRUint32 WAVE_CHUNK_MAGIC = 0x57415645; static const PRUint32 FRMT_CHUNK_MAGIC = 0x666d7420; static const PRUint32 DATA_CHUNK_MAGIC = 0x64617461; // Size of RIFF chunk header. 4 byte chunk header type and 4 byte size field. static const PRUint16 RIFF_CHUNK_HEADER_SIZE = 8; // Size of RIFF header. RIFF chunk and 4 byte RIFF type. static const PRUint16 RIFF_INITIAL_SIZE = RIFF_CHUNK_HEADER_SIZE + 4; // Size of required part of format chunk. Actual format chunks may be // extended (for non-PCM encodings), but we skip any extended data. static const PRUint16 WAVE_FORMAT_CHUNK_SIZE = 16; // PCM encoding type from format chunk. Linear PCM is the only encoding // supported by nsAudioStream. static const PRUint16 WAVE_FORMAT_ENCODING_PCM = 1; // Maximum number of channels supported static const PRUint8 MAX_CHANNELS = 2; namespace { PRUint32 ReadUint32BE(const char** aBuffer) { PRUint32 result = PRUint8((*aBuffer)[0]) << 24 | PRUint8((*aBuffer)[1]) << 16 | PRUint8((*aBuffer)[2]) << 8 | PRUint8((*aBuffer)[3]); *aBuffer += sizeof(PRUint32); return result; } PRUint32 ReadUint32LE(const char** aBuffer) { PRUint32 result = PRUint8((*aBuffer)[3]) << 24 | PRUint8((*aBuffer)[2]) << 16 | PRUint8((*aBuffer)[1]) << 8 | PRUint8((*aBuffer)[0]); *aBuffer += sizeof(PRUint32); return result; } PRUint16 ReadUint16LE(const char** aBuffer) { PRUint16 result = PRUint8((*aBuffer)[1]) << 8 | PRUint8((*aBuffer)[0]) << 0; *aBuffer += sizeof(PRUint16); return result; } PRInt16 ReadInt16LE(const char** aBuffer) { return static_cast(ReadUint16LE(aBuffer)); } PRUint8 ReadUint8(const char** aBuffer) { PRUint8 result = PRUint8((*aBuffer)[0]); *aBuffer += sizeof(PRUint8); return result; } } nsWaveReader::nsWaveReader(nsBuiltinDecoder* aDecoder) : nsBuiltinDecoderReader(aDecoder) { MOZ_COUNT_CTOR(nsWaveReader); } nsWaveReader::~nsWaveReader() { MOZ_COUNT_DTOR(nsWaveReader); } nsresult nsWaveReader::Init(nsBuiltinDecoderReader* aCloneDonor) { return NS_OK; } nsresult nsWaveReader::ReadMetadata(nsVideoInfo* aInfo, nsHTMLMediaElement::MetadataTags** aTags) { NS_ASSERTION(mDecoder->OnDecodeThread(), "Should be on decode thread."); bool loaded = LoadRIFFChunk() && LoadFormatChunk() && FindDataOffset(); if (!loaded) { return NS_ERROR_FAILURE; } mInfo.mHasAudio = true; mInfo.mHasVideo = false; mInfo.mAudioRate = mSampleRate; mInfo.mAudioChannels = mChannels; *aInfo = mInfo; *aTags = nullptr; ReentrantMonitorAutoEnter mon(mDecoder->GetReentrantMonitor()); mDecoder->GetStateMachine()->SetDuration( static_cast(BytesToTime(GetDataLength()) * USECS_PER_S)); return NS_OK; } bool nsWaveReader::DecodeAudioData() { NS_ASSERTION(mDecoder->OnDecodeThread(), "Should be on decode thread."); PRInt64 pos = GetPosition() - mWavePCMOffset; PRInt64 len = GetDataLength(); PRInt64 remaining = len - pos; NS_ASSERTION(remaining >= 0, "Current wave position is greater than wave file length"); static const PRInt64 BLOCK_SIZE = 4096; PRInt64 readSize = NS_MIN(BLOCK_SIZE, remaining); PRInt64 frames = readSize / mFrameSize; PR_STATIC_ASSERT(PRUint64(BLOCK_SIZE) < UINT_MAX / sizeof(AudioDataValue) / MAX_CHANNELS); const size_t bufferSize = static_cast(frames * mChannels); nsAutoArrayPtr sampleBuffer(new AudioDataValue[bufferSize]); PR_STATIC_ASSERT(PRUint64(BLOCK_SIZE) < UINT_MAX / sizeof(char)); nsAutoArrayPtr dataBuffer(new char[static_cast(readSize)]); if (!ReadAll(dataBuffer, readSize)) { mAudioQueue.Finish(); return false; } // convert data to samples const char* d = dataBuffer.get(); AudioDataValue* s = sampleBuffer.get(); for (int i = 0; i < frames; ++i) { for (unsigned int j = 0; j < mChannels; ++j) { if (mSampleFormat == nsAudioStream::FORMAT_U8) { PRUint8 v = ReadUint8(&d); #if defined(MOZ_SAMPLE_TYPE_S16LE) *s++ = (v * (1.F/PR_UINT8_MAX)) * PR_UINT16_MAX + PR_INT16_MIN; #elif defined(MOZ_SAMPLE_TYPE_FLOAT32) *s++ = (v * (1.F/PR_UINT8_MAX)) * 2.F - 1.F; #endif } else if (mSampleFormat == nsAudioStream::FORMAT_S16_LE) { PRInt16 v = ReadInt16LE(&d); #if defined(MOZ_SAMPLE_TYPE_S16LE) *s++ = v; #elif defined(MOZ_SAMPLE_TYPE_FLOAT32) *s++ = (PRInt32(v) - PR_INT16_MIN) / float(PR_UINT16_MAX) * 2.F - 1.F; #endif } } } double posTime = BytesToTime(pos); double readSizeTime = BytesToTime(readSize); NS_ASSERTION(posTime <= INT64_MAX / USECS_PER_S, "posTime overflow"); NS_ASSERTION(readSizeTime <= INT64_MAX / USECS_PER_S, "readSizeTime overflow"); NS_ASSERTION(frames < PR_INT32_MAX, "frames overflow"); mAudioQueue.Push(new AudioData(pos, static_cast(posTime * USECS_PER_S), static_cast(readSizeTime * USECS_PER_S), static_cast(frames), sampleBuffer.forget(), mChannels)); return true; } bool nsWaveReader::DecodeVideoFrame(bool &aKeyframeSkip, PRInt64 aTimeThreshold) { NS_ASSERTION(mDecoder->OnDecodeThread(), "Should be on decode thread."); return false; } nsresult nsWaveReader::Seek(PRInt64 aTarget, PRInt64 aStartTime, PRInt64 aEndTime, PRInt64 aCurrentTime) { NS_ASSERTION(mDecoder->OnDecodeThread(), "Should be on decode thread."); LOG(PR_LOG_DEBUG, ("%p About to seek to %lld", mDecoder, aTarget)); if (NS_FAILED(ResetDecode())) { return NS_ERROR_FAILURE; } double d = BytesToTime(GetDataLength()); NS_ASSERTION(d < INT64_MAX / USECS_PER_S, "Duration overflow"); PRInt64 duration = static_cast(d * USECS_PER_S); double seekTime = NS_MIN(aTarget, duration) / static_cast(USECS_PER_S); PRInt64 position = RoundDownToFrame(static_cast(TimeToBytes(seekTime))); NS_ASSERTION(INT64_MAX - mWavePCMOffset > position, "Integer overflow during wave seek"); position += mWavePCMOffset; return mDecoder->GetResource()->Seek(nsISeekableStream::NS_SEEK_SET, position); } static double RoundToUsecs(double aSeconds) { return floor(aSeconds * USECS_PER_S) / USECS_PER_S; } nsresult nsWaveReader::GetBuffered(nsTimeRanges* aBuffered, PRInt64 aStartTime) { if (!mInfo.mHasAudio) { return NS_OK; } PRInt64 startOffset = mDecoder->GetResource()->GetNextCachedData(mWavePCMOffset); while (startOffset >= 0) { PRInt64 endOffset = mDecoder->GetResource()->GetCachedDataEnd(startOffset); // Bytes [startOffset..endOffset] are cached. NS_ASSERTION(startOffset >= mWavePCMOffset, "Integer underflow in GetBuffered"); NS_ASSERTION(endOffset >= mWavePCMOffset, "Integer underflow in GetBuffered"); // We need to round the buffered ranges' times to microseconds so that they // have the same precision as the currentTime and duration attribute on // the media element. aBuffered->Add(RoundToUsecs(BytesToTime(startOffset - mWavePCMOffset)), RoundToUsecs(BytesToTime(endOffset - mWavePCMOffset))); startOffset = mDecoder->GetResource()->GetNextCachedData(endOffset); } return NS_OK; } bool nsWaveReader::ReadAll(char* aBuf, PRInt64 aSize, PRInt64* aBytesRead) { PRUint32 got = 0; if (aBytesRead) { *aBytesRead = 0; } do { PRUint32 read = 0; if (NS_FAILED(mDecoder->GetResource()->Read(aBuf + got, PRUint32(aSize - got), &read))) { NS_WARNING("Resource read failed"); return false; } if (read == 0) { return false; } mDecoder->NotifyBytesConsumed(read); got += read; if (aBytesRead) { *aBytesRead = got; } } while (got != aSize); return true; } bool nsWaveReader::LoadRIFFChunk() { char riffHeader[RIFF_INITIAL_SIZE]; const char* p = riffHeader; NS_ABORT_IF_FALSE(mDecoder->GetResource()->Tell() == 0, "LoadRIFFChunk called when resource in invalid state"); if (!ReadAll(riffHeader, sizeof(riffHeader))) { return false; } PR_STATIC_ASSERT(sizeof(PRUint32) * 2 <= RIFF_INITIAL_SIZE); if (ReadUint32BE(&p) != RIFF_CHUNK_MAGIC) { NS_WARNING("resource data not in RIFF format"); return false; } // Skip over RIFF size field. p += 4; if (ReadUint32BE(&p) != WAVE_CHUNK_MAGIC) { NS_WARNING("Expected WAVE chunk"); return false; } return true; } bool nsWaveReader::ScanForwardUntil(PRUint32 aWantedChunk, PRUint32* aChunkSize) { NS_ABORT_IF_FALSE(aChunkSize, "Require aChunkSize argument"); *aChunkSize = 0; for (;;) { static const unsigned int CHUNK_HEADER_SIZE = 8; char chunkHeader[CHUNK_HEADER_SIZE]; const char* p = chunkHeader; if (!ReadAll(chunkHeader, sizeof(chunkHeader))) { return false; } PR_STATIC_ASSERT(sizeof(PRUint32) * 2 <= CHUNK_HEADER_SIZE); PRUint32 magic = ReadUint32BE(&p); PRUint32 chunkSize = ReadUint32LE(&p); if (magic == aWantedChunk) { *aChunkSize = chunkSize; return true; } // RIFF chunks are two-byte aligned, so round up if necessary. chunkSize += chunkSize % 2; static const unsigned int MAX_CHUNK_SIZE = 1 << 16; PR_STATIC_ASSERT(MAX_CHUNK_SIZE < UINT_MAX / sizeof(char)); nsAutoArrayPtr chunk(new char[MAX_CHUNK_SIZE]); while (chunkSize > 0) { PRUint32 size = NS_MIN(chunkSize, MAX_CHUNK_SIZE); if (!ReadAll(chunk.get(), size)) { return false; } chunkSize -= size; } } } bool nsWaveReader::LoadFormatChunk() { PRUint32 fmtSize, rate, channels, frameSize, sampleFormat; char waveFormat[WAVE_FORMAT_CHUNK_SIZE]; const char* p = waveFormat; // RIFF chunks are always word (two byte) aligned. NS_ABORT_IF_FALSE(mDecoder->GetResource()->Tell() % 2 == 0, "LoadFormatChunk called with unaligned resource"); // The "format" chunk may not directly follow the "riff" chunk, so skip // over any intermediate chunks. if (!ScanForwardUntil(FRMT_CHUNK_MAGIC, &fmtSize)) { return false; } if (!ReadAll(waveFormat, sizeof(waveFormat))) { return false; } PR_STATIC_ASSERT(sizeof(PRUint16) + sizeof(PRUint16) + sizeof(PRUint32) + 4 + sizeof(PRUint16) + sizeof(PRUint16) <= sizeof(waveFormat)); if (ReadUint16LE(&p) != WAVE_FORMAT_ENCODING_PCM) { NS_WARNING("WAVE is not uncompressed PCM, compressed encodings are not supported"); return false; } channels = ReadUint16LE(&p); rate = ReadUint32LE(&p); // Skip over average bytes per second field. p += 4; frameSize = ReadUint16LE(&p); sampleFormat = ReadUint16LE(&p); // PCM encoded WAVEs are not expected to have an extended "format" chunk, // but I have found WAVEs that have a extended "format" chunk with an // extension size of 0 bytes. Be polite and handle this rather than // considering the file invalid. This code skips any extension of the // "format" chunk. if (fmtSize > WAVE_FORMAT_CHUNK_SIZE) { char extLength[2]; const char* p = extLength; if (!ReadAll(extLength, sizeof(extLength))) { return false; } PR_STATIC_ASSERT(sizeof(PRUint16) <= sizeof(extLength)); PRUint16 extra = ReadUint16LE(&p); if (fmtSize - (WAVE_FORMAT_CHUNK_SIZE + 2) != extra) { NS_WARNING("Invalid extended format chunk size"); return false; } extra += extra % 2; if (extra > 0) { PR_STATIC_ASSERT(PR_UINT16_MAX + (PR_UINT16_MAX % 2) < UINT_MAX / sizeof(char)); nsAutoArrayPtr chunkExtension(new char[extra]); if (!ReadAll(chunkExtension.get(), extra)) { return false; } } } // RIFF chunks are always word (two byte) aligned. NS_ABORT_IF_FALSE(mDecoder->GetResource()->Tell() % 2 == 0, "LoadFormatChunk left resource unaligned"); // Make sure metadata is fairly sane. The rate check is fairly arbitrary, // but the channels check is intentionally limited to mono or stereo // because that's what the audio backend currently supports. if (rate < 100 || rate > 96000 || channels < 1 || channels > MAX_CHANNELS || (frameSize != 1 && frameSize != 2 && frameSize != 4) || (sampleFormat != 8 && sampleFormat != 16)) { NS_WARNING("Invalid WAVE metadata"); return false; } ReentrantMonitorAutoEnter monitor(mDecoder->GetReentrantMonitor()); mSampleRate = rate; mChannels = channels; mFrameSize = frameSize; if (sampleFormat == 8) { mSampleFormat = nsAudioStream::FORMAT_U8; } else { mSampleFormat = nsAudioStream::FORMAT_S16_LE; } return true; } bool nsWaveReader::FindDataOffset() { // RIFF chunks are always word (two byte) aligned. NS_ABORT_IF_FALSE(mDecoder->GetResource()->Tell() % 2 == 0, "FindDataOffset called with unaligned resource"); // The "data" chunk may not directly follow the "format" chunk, so skip // over any intermediate chunks. PRUint32 length; if (!ScanForwardUntil(DATA_CHUNK_MAGIC, &length)) { return false; } PRInt64 offset = mDecoder->GetResource()->Tell(); if (offset <= 0 || offset > PR_UINT32_MAX) { NS_WARNING("PCM data offset out of range"); return false; } ReentrantMonitorAutoEnter monitor(mDecoder->GetReentrantMonitor()); mWaveLength = length; mWavePCMOffset = PRUint32(offset); return true; } double nsWaveReader::BytesToTime(PRInt64 aBytes) const { NS_ABORT_IF_FALSE(aBytes >= 0, "Must be >= 0"); return float(aBytes) / mSampleRate / mFrameSize; } PRInt64 nsWaveReader::TimeToBytes(double aTime) const { NS_ABORT_IF_FALSE(aTime >= 0.0f, "Must be >= 0"); return RoundDownToFrame(PRInt64(aTime * mSampleRate * mFrameSize)); } PRInt64 nsWaveReader::RoundDownToFrame(PRInt64 aBytes) const { NS_ABORT_IF_FALSE(aBytes >= 0, "Must be >= 0"); return aBytes - (aBytes % mFrameSize); } PRInt64 nsWaveReader::GetDataLength() { PRInt64 length = mWaveLength; // If the decoder has a valid content length, and it's shorter than the // expected length of the PCM data, calculate the playback duration from // the content length rather than the expected PCM data length. PRInt64 streamLength = mDecoder->GetResource()->GetLength(); if (streamLength >= 0) { PRInt64 dataLength = NS_MAX(0, streamLength - mWavePCMOffset); length = NS_MIN(dataLength, length); } return length; } PRInt64 nsWaveReader::GetPosition() { return mDecoder->GetResource()->Tell(); }