gecko/content/media/nsBuiltinDecoderReader.h
Ralph Giles f63a794f44 Bug 763010 - Expose media element metadata. r=cpearce
Implements a media.mozGetMetadata() method returning a new javascript object whose properties are key value pairs respresenting metadata tags from the media resource. This data is available after readystate enters METADATA_LOADED.

Currently this is only implemented for Ogg Vorbis streams.

Media format metadata is parsed out by the media decoders. In the nsCodecStateMachine::ReadMetadata subclasses we fill in an nsDataHashtable pointer using the format-specifc api.

The hash pointer is passed up to the media element as part of the MetadataLoaded event.

The hash is deleted if the load is aborted. The audio metadata is also reset to zero (as in the constructor), resolving a todo comment.
2012-07-30 20:14:29 -04:00

536 lines
16 KiB
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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
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
#if !defined(nsBuiltinDecoderReader_h_)
#define nsBuiltinDecoderReader_h_
#include <nsDeque.h>
#include "nsSize.h"
#include "mozilla/ReentrantMonitor.h"
#include "MediaStreamGraph.h"
#include "SharedBuffer.h"
// Stores info relevant to presenting media frames.
class nsVideoInfo {
public:
nsVideoInfo()
: mAudioRate(44100),
mAudioChannels(2),
mDisplay(0,0),
mStereoMode(mozilla::layers::STEREO_MODE_MONO),
mHasAudio(false),
mHasVideo(false)
{}
// Returns true if it's safe to use aPicture as the picture to be
// extracted inside a frame of size aFrame, and scaled up to and displayed
// at a size of aDisplay. You should validate the frame, picture, and
// display regions before using them to display video frames.
static bool ValidateVideoRegion(const nsIntSize& aFrame,
const nsIntRect& aPicture,
const nsIntSize& aDisplay);
// Sample rate.
PRUint32 mAudioRate;
// Number of audio channels.
PRUint32 mAudioChannels;
// Size in pixels at which the video is rendered. This is after it has
// been scaled by its aspect ratio.
nsIntSize mDisplay;
// Indicates the frame layout for single track stereo videos.
mozilla::layers::StereoMode mStereoMode;
// True if we have an active audio bitstream.
bool mHasAudio;
// True if we have an active video bitstream.
bool mHasVideo;
};
#ifdef MOZ_TREMOR
#include <ogg/os_types.h>
typedef ogg_int32_t VorbisPCMValue;
typedef short AudioDataValue;
#define MOZ_AUDIO_DATA_FORMAT (nsAudioStream::FORMAT_S16_LE)
#define MOZ_CLIP_TO_15(x) ((x)<-32768?-32768:(x)<=32767?(x):32767)
// Convert the output of vorbis_synthesis_pcmout to a AudioDataValue
#define MOZ_CONVERT_VORBIS_SAMPLE(x) \
(static_cast<AudioDataValue>(MOZ_CLIP_TO_15((x)>>9)))
// Convert a AudioDataValue to a float for the Audio API
#define MOZ_CONVERT_AUDIO_SAMPLE(x) ((x)*(1.F/32768))
#define MOZ_SAMPLE_TYPE_S16LE 1
#else /*MOZ_VORBIS*/
typedef float VorbisPCMValue;
typedef float AudioDataValue;
#define MOZ_AUDIO_DATA_FORMAT (nsAudioStream::FORMAT_FLOAT32)
#define MOZ_CONVERT_VORBIS_SAMPLE(x) (x)
#define MOZ_CONVERT_AUDIO_SAMPLE(x) (x)
#define MOZ_SAMPLE_TYPE_FLOAT32 1
#endif
// Holds chunk a decoded audio frames.
class AudioData {
public:
typedef mozilla::SharedBuffer SharedBuffer;
AudioData(PRInt64 aOffset,
PRInt64 aTime,
PRInt64 aDuration,
PRUint32 aFrames,
AudioDataValue* aData,
PRUint32 aChannels)
: mOffset(aOffset),
mTime(aTime),
mDuration(aDuration),
mFrames(aFrames),
mChannels(aChannels),
mAudioData(aData)
{
MOZ_COUNT_CTOR(AudioData);
}
~AudioData()
{
MOZ_COUNT_DTOR(AudioData);
}
// If mAudioBuffer is null, creates it from mAudioData.
void EnsureAudioBuffer();
PRInt64 GetEnd() { return mTime + mDuration; }
// Approximate byte offset of the end of the page on which this chunk
// ends.
const PRInt64 mOffset;
PRInt64 mTime; // Start time of data in usecs.
const PRInt64 mDuration; // In usecs.
const PRUint32 mFrames;
const PRUint32 mChannels;
// At least one of mAudioBuffer/mAudioData must be non-null.
// mChannels channels, each with mFrames frames
nsRefPtr<SharedBuffer> mAudioBuffer;
// mFrames frames, each with mChannels values
nsAutoArrayPtr<AudioDataValue> mAudioData;
};
// Holds a decoded video frame, in YCbCr format. These are queued in the reader.
class VideoData {
public:
typedef mozilla::layers::ImageContainer ImageContainer;
typedef mozilla::layers::Image Image;
// YCbCr data obtained from decoding the video. The index's are:
// 0 = Y
// 1 = Cb
// 2 = Cr
struct YCbCrBuffer {
struct Plane {
PRUint8* mData;
PRUint32 mWidth;
PRUint32 mHeight;
PRUint32 mStride;
PRUint32 mOffset;
PRUint32 mSkip;
};
Plane mPlanes[3];
};
// Constructs a VideoData object. Makes a copy of YCbCr data in aBuffer.
// aTimecode is a codec specific number representing the timestamp of
// the frame of video data. Returns nullptr if an error occurs. This may
// indicate that memory couldn't be allocated to create the VideoData
// object, or it may indicate some problem with the input data (e.g.
// negative stride).
static VideoData* Create(nsVideoInfo& aInfo,
ImageContainer* aContainer,
PRInt64 aOffset,
PRInt64 aTime,
PRInt64 aEndTime,
const YCbCrBuffer &aBuffer,
bool aKeyframe,
PRInt64 aTimecode,
nsIntRect aPicture);
// Constructs a duplicate VideoData object. This intrinsically tells the
// player that it does not need to update the displayed frame when this
// frame is played; this frame is identical to the previous.
static VideoData* CreateDuplicate(PRInt64 aOffset,
PRInt64 aTime,
PRInt64 aEndTime,
PRInt64 aTimecode)
{
return new VideoData(aOffset, aTime, aEndTime, aTimecode);
}
~VideoData()
{
MOZ_COUNT_DTOR(VideoData);
}
PRInt64 GetEnd() { return mEndTime; }
// Dimensions at which to display the video frame. The picture region
// will be scaled to this size. This is should be the picture region's
// dimensions scaled with respect to its aspect ratio.
nsIntSize mDisplay;
// Approximate byte offset of the end of the frame in the media.
PRInt64 mOffset;
// Start time of frame in microseconds.
PRInt64 mTime;
// End time of frame in microseconds.
PRInt64 mEndTime;
// Codec specific internal time code. For Ogg based codecs this is the
// granulepos.
PRInt64 mTimecode;
// This frame's image.
nsRefPtr<Image> mImage;
// When true, denotes that this frame is identical to the frame that
// came before; it's a duplicate. mBuffer will be empty.
bool mDuplicate;
bool mKeyframe;
public:
VideoData(PRInt64 aOffset, PRInt64 aTime, PRInt64 aEndTime, PRInt64 aTimecode)
: mOffset(aOffset),
mTime(aTime),
mEndTime(aEndTime),
mTimecode(aTimecode),
mDuplicate(true),
mKeyframe(false)
{
MOZ_COUNT_CTOR(VideoData);
NS_ASSERTION(aEndTime >= aTime, "Frame must start before it ends.");
}
VideoData(PRInt64 aOffset,
PRInt64 aTime,
PRInt64 aEndTime,
bool aKeyframe,
PRInt64 aTimecode,
nsIntSize aDisplay)
: mDisplay(aDisplay),
mOffset(aOffset),
mTime(aTime),
mEndTime(aEndTime),
mTimecode(aTimecode),
mDuplicate(false),
mKeyframe(aKeyframe)
{
MOZ_COUNT_CTOR(VideoData);
NS_ASSERTION(aEndTime >= aTime, "Frame must start before it ends.");
}
};
// Thread and type safe wrapper around nsDeque.
template <class T>
class MediaQueueDeallocator : public nsDequeFunctor {
virtual void* operator() (void* anObject) {
delete static_cast<T*>(anObject);
return nullptr;
}
};
template <class T> class MediaQueue : private nsDeque {
public:
typedef mozilla::ReentrantMonitorAutoEnter ReentrantMonitorAutoEnter;
typedef mozilla::ReentrantMonitor ReentrantMonitor;
MediaQueue()
: nsDeque(new MediaQueueDeallocator<T>()),
mReentrantMonitor("mediaqueue"),
mEndOfStream(0)
{}
~MediaQueue() {
Reset();
}
inline PRInt32 GetSize() {
ReentrantMonitorAutoEnter mon(mReentrantMonitor);
return nsDeque::GetSize();
}
inline void Push(T* aItem) {
ReentrantMonitorAutoEnter mon(mReentrantMonitor);
nsDeque::Push(aItem);
}
inline void PushFront(T* aItem) {
ReentrantMonitorAutoEnter mon(mReentrantMonitor);
nsDeque::PushFront(aItem);
}
inline T* Pop() {
ReentrantMonitorAutoEnter mon(mReentrantMonitor);
return static_cast<T*>(nsDeque::Pop());
}
inline T* PopFront() {
ReentrantMonitorAutoEnter mon(mReentrantMonitor);
return static_cast<T*>(nsDeque::PopFront());
}
inline T* Peek() {
ReentrantMonitorAutoEnter mon(mReentrantMonitor);
return static_cast<T*>(nsDeque::Peek());
}
inline T* PeekFront() {
ReentrantMonitorAutoEnter mon(mReentrantMonitor);
return static_cast<T*>(nsDeque::PeekFront());
}
inline void Empty() {
ReentrantMonitorAutoEnter mon(mReentrantMonitor);
nsDeque::Empty();
}
inline void Erase() {
ReentrantMonitorAutoEnter mon(mReentrantMonitor);
nsDeque::Erase();
}
void Reset() {
ReentrantMonitorAutoEnter mon(mReentrantMonitor);
while (GetSize() > 0) {
T* x = PopFront();
delete x;
}
mEndOfStream = false;
}
bool AtEndOfStream() {
ReentrantMonitorAutoEnter mon(mReentrantMonitor);
return GetSize() == 0 && mEndOfStream;
}
// Returns true if the media queue has had it last item added to it.
// This happens when the media stream has been completely decoded. Note this
// does not mean that the corresponding stream has finished playback.
bool IsFinished() {
ReentrantMonitorAutoEnter mon(mReentrantMonitor);
return mEndOfStream;
}
// Informs the media queue that it won't be receiving any more items.
void Finish() {
ReentrantMonitorAutoEnter mon(mReentrantMonitor);
mEndOfStream = true;
}
// Returns the approximate number of microseconds of items in the queue.
PRInt64 Duration() {
ReentrantMonitorAutoEnter mon(mReentrantMonitor);
if (GetSize() < 2) {
return 0;
}
T* last = Peek();
T* first = PeekFront();
return last->mTime - first->mTime;
}
void LockedForEach(nsDequeFunctor& aFunctor) const {
ReentrantMonitorAutoEnter mon(mReentrantMonitor);
ForEach(aFunctor);
}
// Extracts elements from the queue into aResult, in order.
// Elements whose start time is before aTime are ignored.
void GetElementsAfter(PRInt64 aTime, nsTArray<T*>* aResult) {
ReentrantMonitorAutoEnter mon(mReentrantMonitor);
if (!GetSize())
return;
PRInt32 i;
for (i = GetSize() - 1; i > 0; --i) {
T* v = static_cast<T*>(ObjectAt(i));
if (v->GetEnd() < aTime)
break;
}
// Elements less than i have a end time before aTime. It's also possible
// that the element at i has a end time before aTime, but that's OK.
for (; i < GetSize(); ++i) {
aResult->AppendElement(static_cast<T*>(ObjectAt(i)));
}
}
private:
mutable ReentrantMonitor mReentrantMonitor;
// True when we've decoded the last frame of data in the
// bitstream for which we're queueing frame data.
bool mEndOfStream;
};
// Encapsulates the decoding and reading of media data. Reading can only be
// done on the decode thread. Never hold the decoder monitor when
// calling into this class. Unless otherwise specified, methods and fields of
// this class can only be accessed on the decode thread.
class nsBuiltinDecoderReader : public nsRunnable {
public:
typedef mozilla::ReentrantMonitor ReentrantMonitor;
typedef mozilla::ReentrantMonitorAutoEnter ReentrantMonitorAutoEnter;
typedef mozilla::VideoFrameContainer VideoFrameContainer;
nsBuiltinDecoderReader(nsBuiltinDecoder* aDecoder);
virtual ~nsBuiltinDecoderReader();
// Initializes the reader, returns NS_OK on success, or NS_ERROR_FAILURE
// on failure.
virtual nsresult Init(nsBuiltinDecoderReader* aCloneDonor) = 0;
// Resets all state related to decoding, emptying all buffers etc.
virtual nsresult ResetDecode();
// Decodes an unspecified amount of audio data, enqueuing the audio data
// in mAudioQueue. Returns true when there's more audio to decode,
// false if the audio is finished, end of file has been reached,
// or an un-recoverable read error has occured.
virtual bool DecodeAudioData() = 0;
// Reads and decodes one video frame. Packets with a timestamp less
// than aTimeThreshold will be decoded (unless they're not keyframes
// and aKeyframeSkip is true), but will not be added to the queue.
virtual bool DecodeVideoFrame(bool &aKeyframeSkip,
PRInt64 aTimeThreshold) = 0;
virtual bool HasAudio() = 0;
virtual bool HasVideo() = 0;
// Read header data for all bitstreams in the file. Fills aInfo with
// the data required to present the media, and optionally fills *aTags
// with tag metadata from the file.
// Returns NS_OK on success, or NS_ERROR_FAILURE on failure.
virtual nsresult ReadMetadata(nsVideoInfo* aInfo,
nsHTMLMediaElement::MetadataTags** aTags) = 0;
// Stores the presentation time of the first frame we'd be able to play if
// we started playback at the current position. Returns the first video
// frame, if we have video.
VideoData* FindStartTime(PRInt64& aOutStartTime);
// Moves the decode head to aTime microseconds. aStartTime and aEndTime
// denote the start and end times of the media in usecs, and aCurrentTime
// is the current playback position in microseconds.
virtual nsresult Seek(PRInt64 aTime,
PRInt64 aStartTime,
PRInt64 aEndTime,
PRInt64 aCurrentTime) = 0;
// Queue of audio frames. This queue is threadsafe, and is accessed from
// the audio, decoder, state machine, and main threads.
MediaQueue<AudioData> mAudioQueue;
// Queue of video frames. This queue is threadsafe, and is accessed from
// the decoder, state machine, and main threads.
MediaQueue<VideoData> mVideoQueue;
// Populates aBuffered with the time ranges which are buffered. aStartTime
// must be the presentation time of the first frame in the media, e.g.
// the media time corresponding to playback time/position 0. This function
// should only be called on the main thread.
virtual nsresult GetBuffered(nsTimeRanges* aBuffered,
PRInt64 aStartTime) = 0;
// True if we can seek using only buffered ranges. This is backend dependant.
virtual bool IsSeekableInBufferedRanges() = 0;
class VideoQueueMemoryFunctor : public nsDequeFunctor {
public:
VideoQueueMemoryFunctor() : mResult(0) {}
virtual void* operator()(void* anObject) {
const VideoData* v = static_cast<const VideoData*>(anObject);
if (!v->mImage) {
return nullptr;
}
NS_ASSERTION(v->mImage->GetFormat() == mozilla::layers::Image::PLANAR_YCBCR,
"Wrong format?");
mozilla::layers::PlanarYCbCrImage* vi = static_cast<mozilla::layers::PlanarYCbCrImage*>(v->mImage.get());
mResult += vi->GetDataSize();
return nullptr;
}
PRInt64 mResult;
};
PRInt64 VideoQueueMemoryInUse() {
VideoQueueMemoryFunctor functor;
mVideoQueue.LockedForEach(functor);
return functor.mResult;
}
class AudioQueueMemoryFunctor : public nsDequeFunctor {
public:
AudioQueueMemoryFunctor() : mResult(0) {}
virtual void* operator()(void* anObject) {
const AudioData* audioData = static_cast<const AudioData*>(anObject);
mResult += audioData->mFrames * audioData->mChannels * sizeof(AudioDataValue);
return nullptr;
}
PRInt64 mResult;
};
PRInt64 AudioQueueMemoryInUse() {
AudioQueueMemoryFunctor functor;
mAudioQueue.LockedForEach(functor);
return functor.mResult;
}
// Only used by nsWebMReader for now, so stub here rather than in every
// reader than inherits from nsBuiltinDecoderReader.
virtual void NotifyDataArrived(const char* aBuffer, PRUint32 aLength, PRInt64 aOffset) {}
protected:
// Pumps the decode until we reach frames required to play at time aTarget
// (usecs).
nsresult DecodeToTarget(PRInt64 aTarget);
// Reader decode function. Matches DecodeVideoFrame() and
// DecodeAudioData().
typedef bool (nsBuiltinDecoderReader::*DecodeFn)();
// Calls aDecodeFn on *this until aQueue has an item, whereupon
// we return the first item.
template<class Data>
Data* DecodeToFirstData(DecodeFn aDecodeFn,
MediaQueue<Data>& aQueue);
// Wrapper so that DecodeVideoFrame(bool&,PRInt64) can be called from
// DecodeToFirstData().
bool DecodeVideoFrame() {
bool f = false;
return DecodeVideoFrame(f, 0);
}
// Reference to the owning decoder object.
nsBuiltinDecoder* mDecoder;
// Stores presentation info required for playback.
nsVideoInfo mInfo;
};
#endif