gecko-dev/dom/media/MediaData.h

/* -*- 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/. */
#if !defined(MediaData_h)
#define MediaData_h

#include "AudioConfig.h"
#include "AudioSampleFormat.h"
#include "ImageTypes.h"
#include "SharedBuffer.h"
#include "TimeUnits.h"
#include "mozilla/CheckedInt.h"
#include "mozilla/PodOperations.h"
#include "mozilla/RefPtr.h"
#include "mozilla/Span.h"
#include "mozilla/UniquePtr.h"
#include "mozilla/UniquePtrExtensions.h"
#include "mozilla/gfx/Rect.h"
#include "nsString.h"
#include "nsTArray.h"

namespace mozilla {

namespace layers {
class Image;
class ImageContainer;
class KnowsCompositor;
} // namespace layers

class MediaByteBuffer;
class TrackInfoSharedPtr;

// AlignedBuffer:
// Memory allocations are fallibles. Methods return a boolean indicating if
// memory allocations were successful. Return values should always be checked.
// AlignedBuffer::mData will be nullptr if no memory has been allocated or if
// an error occurred during construction.
// Existing data is only ever modified if new memory allocation has succeeded
// and preserved if not.
//
// The memory referenced by mData will always be Alignment bytes aligned and the
// underlying buffer will always have a size such that Alignment bytes blocks
// can be used to read the content, regardless of the mSize value. Buffer is
// zeroed on creation, elements are not individually constructed.
// An Alignment value of 0 means that the data isn't aligned.
//
// Type must be trivially copyable.
//
// AlignedBuffer can typically be used in place of UniquePtr<Type[]> however
// care must be taken as all memory allocations are fallible.
// Example:
// auto buffer = MakeUniqueFallible<float[]>(samples)
// becomes: AlignedFloatBuffer buffer(samples)
//
// auto buffer = MakeUnique<float[]>(samples)
// becomes:
// AlignedFloatBuffer buffer(samples);
// if (!buffer) { return NS_ERROR_OUT_OF_MEMORY; }

template <typename Type, int Alignment = 32>
class AlignedBuffer
{
public:
  AlignedBuffer()
    : mData(nullptr)
    , mLength(0)
    , mBuffer(nullptr)
    , mCapacity(0)
  {
  }

  explicit AlignedBuffer(size_t aLength)
    : mData(nullptr)
    , mLength(0)
    , mBuffer(nullptr)
    , mCapacity(0)
  {
    if (EnsureCapacity(aLength)) {
      mLength = aLength;
    }
  }

  AlignedBuffer(const Type* aData, size_t aLength)
    : AlignedBuffer(aLength)
  {
    if (!mData) {
      return;
    }
    PodCopy(mData, aData, aLength);
  }

  AlignedBuffer(const AlignedBuffer& aOther)
    : AlignedBuffer(aOther.Data(), aOther.Length())
  {
  }

  AlignedBuffer(AlignedBuffer&& aOther)
    : mData(aOther.mData)
    , mLength(aOther.mLength)
    , mBuffer(std::move(aOther.mBuffer))
    , mCapacity(aOther.mCapacity)
  {
    aOther.mData = nullptr;
    aOther.mLength = 0;
    aOther.mCapacity = 0;
  }

  AlignedBuffer& operator=(AlignedBuffer&& aOther)
  {
    this->~AlignedBuffer();
    new (this) AlignedBuffer(std::move(aOther));
    return *this;
  }

  Type* Data() const { return mData; }
  size_t Length() const { return mLength; }
  size_t Size() const { return mLength * sizeof(Type); }
  Type& operator[](size_t aIndex)
  {
    MOZ_ASSERT(aIndex < mLength);
    return mData[aIndex];
  }
  const Type& operator[](size_t aIndex) const
  {
    MOZ_ASSERT(aIndex < mLength);
    return mData[aIndex];
  }
  // Set length of buffer, allocating memory as required.
  // If length is increased, new buffer area is filled with 0.
  bool SetLength(size_t aLength)
  {
    if (aLength > mLength && !EnsureCapacity(aLength)) {
      return false;
    }
    mLength = aLength;
    return true;
  }
  // Add aData at the beginning of buffer.
  bool Prepend(const Type* aData, size_t aLength)
  {
    if (!EnsureCapacity(aLength + mLength)) {
      return false;
    }

    // Shift the data to the right by aLength to leave room for the new data.
    PodMove(mData + aLength, mData, mLength);
    PodCopy(mData, aData, aLength);

    mLength += aLength;
    return true;
  }
  // Add aData at the end of buffer.
  bool Append(const Type* aData, size_t aLength)
  {
    if (!EnsureCapacity(aLength + mLength)) {
      return false;
    }

    PodCopy(mData + mLength, aData, aLength);

    mLength += aLength;
    return true;
  }
  // Replace current content with aData.
  bool Replace(const Type* aData, size_t aLength)
  {
    // If aLength is smaller than our current length, we leave the buffer as is,
    // only adjusting the reported length.
    if (!EnsureCapacity(aLength)) {
      return false;
    }

    PodCopy(mData, aData, aLength);
    mLength = aLength;
    return true;
  }
  // Clear the memory buffer. Will set target mData and mLength to 0.
  void Clear()
  {
    mLength = 0;
    mData = nullptr;
  }

  // Methods for reporting memory.
  size_t SizeOfIncludingThis(MallocSizeOf aMallocSizeOf) const
  {
    size_t size = aMallocSizeOf(this);
    size += aMallocSizeOf(mBuffer.get());
    return size;
  }
  // AlignedBuffer is typically allocated on the stack. As such, you likely
  // want to use SizeOfExcludingThis
  size_t SizeOfExcludingThis(MallocSizeOf aMallocSizeOf) const
  {
    return aMallocSizeOf(mBuffer.get());
  }
  size_t ComputedSizeOfExcludingThis() const
  {
    return mCapacity;
  }

  // For backward compatibility with UniquePtr<Type[]>
  Type* get() const { return mData; }
  explicit operator bool() const { return mData != nullptr; }

  // Size in bytes of extra space allocated for padding.
  static size_t AlignmentPaddingSize()
  {
    return AlignmentOffset() * 2;
  }

  void PopFront(size_t aSize)
  {
    MOZ_ASSERT(mLength >= aSize);
    PodMove(mData, mData + aSize, mLength - aSize);
    mLength -= aSize;
  }

private:
  static size_t AlignmentOffset()
  {
    return Alignment ? Alignment - 1 : 0;
  }

  // Ensure that the backend buffer can hold aLength data. Will update mData.
  // Will enforce that the start of allocated data is always Alignment bytes
  // aligned and that it has sufficient end padding to allow for Alignment bytes
  // block read as required by some data decoders.
  // Returns false if memory couldn't be allocated.
  bool EnsureCapacity(size_t aLength)
  {
    if (!aLength) {
      // No need to allocate a buffer yet.
      return true;
    }
    const CheckedInt<size_t> sizeNeeded =
      CheckedInt<size_t>(aLength) * sizeof(Type) + AlignmentPaddingSize();

    if (!sizeNeeded.isValid() || sizeNeeded.value() >= INT32_MAX) {
      // overflow or over an acceptable size.
      return false;
    }
    if (mData && mCapacity >= sizeNeeded.value()) {
      return true;
    }
    auto newBuffer = MakeUniqueFallible<uint8_t[]>(sizeNeeded.value());
    if (!newBuffer) {
      return false;
    }

    // Find alignment address.
    const uintptr_t alignmask = AlignmentOffset();
    Type* newData = reinterpret_cast<Type*>(
      (reinterpret_cast<uintptr_t>(newBuffer.get()) + alignmask) & ~alignmask);
    MOZ_ASSERT(uintptr_t(newData) % (AlignmentOffset()+1) == 0);

    MOZ_ASSERT(!mLength || mData);

    PodZero(newData + mLength, aLength - mLength);
    if (mLength) {
      PodCopy(newData, mData, mLength);
    }

    mBuffer = std::move(newBuffer);
    mCapacity = sizeNeeded.value();
    mData = newData;

    return true;
  }
  Type* mData;
  size_t mLength;
  UniquePtr<uint8_t[]> mBuffer;
  size_t mCapacity;
};

typedef AlignedBuffer<uint8_t> AlignedByteBuffer;
typedef AlignedBuffer<float> AlignedFloatBuffer;
typedef AlignedBuffer<int16_t> AlignedShortBuffer;
typedef AlignedBuffer<AudioDataValue> AlignedAudioBuffer;

// Container that holds media samples.
class MediaData
{
public:

  NS_INLINE_DECL_THREADSAFE_REFCOUNTING(MediaData)

  enum Type
  {
    AUDIO_DATA = 0,
    VIDEO_DATA,
    RAW_DATA,
    NULL_DATA
  };

  MediaData(Type aType,
            int64_t aOffset,
            const media::TimeUnit& aTimestamp,
            const media::TimeUnit& aDuration,
            uint32_t aFrames)
    : mType(aType)
    , mOffset(aOffset)
    , mTime(aTimestamp)
    , mTimecode(aTimestamp)
    , mDuration(aDuration)
    , mFrames(aFrames)
    , mKeyframe(false)
  {
  }

  // Type of contained data.
  const Type mType;

  // Approximate byte offset where this data was demuxed from its media.
  int64_t mOffset;

  // Start time of sample.
  media::TimeUnit mTime;

  // Codec specific internal time code. For Ogg based codecs this is the
  // granulepos.
  media::TimeUnit mTimecode;

  // Duration of sample, in microseconds.
  media::TimeUnit mDuration;

  // Amount of frames for contained data.
  const uint32_t mFrames;

  bool mKeyframe;

  media::TimeUnit GetEndTime() const
  {
    return mTime + mDuration;
  }

  bool AdjustForStartTime(int64_t aStartTime)
  {
    mTime = mTime - media::TimeUnit::FromMicroseconds(aStartTime);
    return !mTime.IsNegative();
  }

  template <typename ReturnType>
  const ReturnType* As() const
  {
    MOZ_ASSERT(this->mType == ReturnType::sType);
    return static_cast<const ReturnType*>(this);
  }

  template <typename ReturnType>
  ReturnType* As()
  {
    MOZ_ASSERT(this->mType == ReturnType::sType);
    return static_cast<ReturnType*>(this);
  }

protected:
  MediaData(Type aType, uint32_t aFrames)
    : mType(aType)
    , mOffset(0)
    , mFrames(aFrames)
    , mKeyframe(false)
  {
  }

  virtual ~MediaData() { }

};

// NullData is for decoder generating a sample which doesn't need to be
// rendered.
class NullData : public MediaData
{
public:
  NullData(int64_t aOffset,
           const media::TimeUnit& aTime,
           const media::TimeUnit& aDuration)
    : MediaData(NULL_DATA, aOffset, aTime, aDuration, 0)
  {
  }

  static const Type sType = NULL_DATA;
};

// Holds chunk a decoded audio frames.
class AudioData : public MediaData
{
public:

  AudioData(int64_t aOffset,
            const media::TimeUnit& aTime,
            const media::TimeUnit& aDuration,
            uint32_t aFrames,
            AlignedAudioBuffer&& aData,
            uint32_t aChannels,
            uint32_t aRate,
            uint32_t aChannelMap = AudioConfig::ChannelLayout::UNKNOWN_MAP)
    : MediaData(sType, aOffset, aTime, aDuration, aFrames)
    , mChannels(aChannels)
    , mChannelMap(aChannelMap)
    , mRate(aRate)
    , mAudioData(std::move(aData))
  {
  }

  static const Type sType = AUDIO_DATA;
  static const char* sTypeName;

  // Creates a new AudioData identical to aOther, but with a different
  // specified timestamp and duration. All data from aOther is copied
  // into the new AudioData but the audio data which is transferred.
  // After such call, the original aOther is unusable.
  static already_AddRefed<AudioData>
  TransferAndUpdateTimestampAndDuration(AudioData* aOther,
                                        const media::TimeUnit& aTimestamp,
                                        const media::TimeUnit& aDuration);

  size_t SizeOfIncludingThis(MallocSizeOf aMallocSizeOf) const;

  // If mAudioBuffer is null, creates it from mAudioData.
  void EnsureAudioBuffer();

  // To check whether mAudioData has audible signal, it's used to distinguish
  // the audiable data and silent data.
  bool IsAudible() const;

  const uint32_t mChannels;
  // The AudioConfig::ChannelLayout map. Channels are ordered as per SMPTE
  // definition. A value of UNKNOWN_MAP indicates unknown layout.
  // ChannelMap is an unsigned bitmap compatible with Windows' WAVE and FFmpeg
  // channel map.
  const AudioConfig::ChannelLayout::ChannelMap mChannelMap;
  const uint32_t mRate;
  // At least one of mAudioBuffer/mAudioData must be non-null.
  // mChannels channels, each with mFrames frames
  RefPtr<SharedBuffer> mAudioBuffer;
  // mFrames frames, each with mChannels values
  AlignedAudioBuffer mAudioData;

protected:
  ~AudioData() { }
};

namespace layers {
class TextureClient;
class PlanarYCbCrImage;
} // namespace layers

class VideoInfo;

// Holds a decoded video frame, in YCbCr format. These are queued in the reader.
class VideoData : public MediaData
{
public:
  typedef gfx::IntRect IntRect;
  typedef gfx::IntSize IntSize;
  typedef layers::ImageContainer ImageContainer;
  typedef layers::Image Image;
  typedef layers::PlanarYCbCrImage PlanarYCbCrImage;

  static const Type sType = VIDEO_DATA;
  static const char* sTypeName;

  // YCbCr data obtained from decoding the video. The index's are:
  //   0 = Y
  //   1 = Cb
  //   2 = Cr
  struct YCbCrBuffer
  {
    struct Plane
    {
      uint8_t* mData;
      uint32_t mWidth;
      uint32_t mHeight;
      uint32_t mStride;
      uint32_t mOffset;
      uint32_t mSkip;
    };

    Plane mPlanes[3];
    YUVColorSpace mYUVColorSpace = YUVColorSpace::BT601;
    uint32_t mBitDepth = 8;
  };

  class Listener
  {
  public:
    virtual void OnSentToCompositor() = 0;
    virtual ~Listener() { }
  };

  // Constructs a VideoData object. If aImage is nullptr, creates a new Image
  // holding a copy of the YCbCr data passed in aBuffer. If aImage is not
  // nullptr, it's stored as the underlying video image and aBuffer is assumed
  // to point to memory within aImage so no copy is made. aTimecode is a codec
  // specific number representing the timestamp of the frame of video data.
  // Returns nsnull 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).


  // Creates a new VideoData containing a deep copy of aBuffer. May use
  // aContainer to allocate an Image to hold the copied data.
  static already_AddRefed<VideoData> CreateAndCopyData(
    const VideoInfo& aInfo,
    ImageContainer* aContainer,
    int64_t aOffset,
    const media::TimeUnit& aTime,
    const media::TimeUnit& aDuration,
    const YCbCrBuffer& aBuffer,
    bool aKeyframe,
    const media::TimeUnit& aTimecode,
    const IntRect& aPicture,
    layers::KnowsCompositor* aAllocator = nullptr);

  static already_AddRefed<VideoData> CreateAndCopyData(
    const VideoInfo& aInfo,
    ImageContainer* aContainer,
    int64_t aOffset,
    const media::TimeUnit& aTime,
    const media::TimeUnit& aDuration,
    const YCbCrBuffer& aBuffer,
    const YCbCrBuffer::Plane& aAlphaPlane,
    bool aKeyframe,
    const media::TimeUnit& aTimecode,
    const IntRect& aPicture);

  static already_AddRefed<VideoData> CreateFromImage(
    const IntSize& aDisplay,
    int64_t aOffset,
    const media::TimeUnit& aTime,
    const media::TimeUnit& aDuration,
    const RefPtr<Image>& aImage,
    bool aKeyframe,
    const media::TimeUnit& aTimecode);

  // Initialize PlanarYCbCrImage. Only When aCopyData is true,
  // video data is copied to PlanarYCbCrImage.
  static bool SetVideoDataToImage(PlanarYCbCrImage* aVideoImage,
                                  const VideoInfo& aInfo,
                                  const YCbCrBuffer& aBuffer,
                                  const IntRect& aPicture,
                                  bool aCopyData);

  size_t SizeOfIncludingThis(MallocSizeOf aMallocSizeOf) const;

  // 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.
  const IntSize mDisplay;

  // This frame's image.
  RefPtr<Image> mImage;

  int32_t mFrameID;

  VideoData(int64_t aOffset,
            const media::TimeUnit& aTime,
            const media::TimeUnit& aDuration,
            bool aKeyframe,
            const media::TimeUnit& aTimecode,
            IntSize aDisplay,
            uint32_t aFrameID);

  void SetListener(UniquePtr<Listener> aListener);
  void MarkSentToCompositor();
  bool IsSentToCompositor() { return mSentToCompositor; }

  void UpdateDuration(const media::TimeUnit& aDuration);
  void UpdateTimestamp(const media::TimeUnit& aTimestamp);

  void SetNextKeyFrameTime(const media::TimeUnit& aTime)
  {
    mNextKeyFrameTime = aTime;
  }

  const media::TimeUnit& NextKeyFrameTime() const
  {
    return mNextKeyFrameTime;
  }

protected:
  ~VideoData();

  bool mSentToCompositor;
  UniquePtr<Listener> mListener;
  media::TimeUnit mNextKeyFrameTime;
};

class CryptoTrack
{
public:
  CryptoTrack() : mValid(false), mMode(0), mIVSize(0) { }
  bool mValid;
  int32_t mMode;
  int32_t mIVSize;
  nsTArray<uint8_t> mKeyId;
};

class CryptoSample : public CryptoTrack
{
public:
  nsTArray<uint16_t> mPlainSizes;
  nsTArray<uint32_t> mEncryptedSizes;
  nsTArray<uint8_t> mIV;
  nsTArray<nsTArray<uint8_t>> mInitDatas;
  nsString mInitDataType;
};

// MediaRawData is a MediaData container used to store demuxed, still compressed
// samples.
// Use MediaRawData::CreateWriter() to obtain a MediaRawDataWriter object that
// provides methods to modify and manipulate the data.
// Memory allocations are fallible. Methods return a boolean indicating if
// memory allocations were successful. Return values should always be checked.
// MediaRawData::mData will be nullptr if no memory has been allocated or if
// an error occurred during construction.
// Existing data is only ever modified if new memory allocation has succeeded
// and preserved if not.
//
// The memory referenced by mData will always be 32 bytes aligned and the
// underlying buffer will always have a size such that 32 bytes blocks can be
// used to read the content, regardless of the mSize value. Buffer is zeroed
// on creation.
//
// Typical usage: create new MediaRawData; create the associated
// MediaRawDataWriter, call SetSize() to allocate memory, write to mData,
// up to mSize bytes.

class MediaRawData;

class MediaRawDataWriter
{
public:
  // Pointer to data or null if not-yet allocated
  uint8_t* Data();
  // Writeable size of buffer.
  size_t Size();
  // Writeable reference to MediaRawData::mCryptoInternal
  CryptoSample& mCrypto;

  // Data manipulation methods. mData and mSize may be updated accordingly.

  // Set size of buffer, allocating memory as required.
  // If size is increased, new buffer area is filled with 0.
  MOZ_MUST_USE bool SetSize(size_t aSize);
  // Add aData at the beginning of buffer.
  MOZ_MUST_USE bool Prepend(const uint8_t* aData, size_t aSize);
  // Replace current content with aData.
  MOZ_MUST_USE bool Replace(const uint8_t* aData, size_t aSize);
  // Clear the memory buffer. Will set target mData and mSize to 0.
  void Clear();
  // Remove aSize bytes from the front of the sample.
  void PopFront(size_t aSize);

private:
  friend class MediaRawData;
  explicit MediaRawDataWriter(MediaRawData* aMediaRawData);
  MOZ_MUST_USE bool EnsureSize(size_t aSize);
  MediaRawData* mTarget;
};

class MediaRawData final : public MediaData
{
public:
  MediaRawData();
  MediaRawData(const uint8_t* aData, size_t aSize);
  MediaRawData(const uint8_t* aData, size_t aSize,
               const uint8_t* aAlphaData, size_t aAlphaSize);

  // Pointer to data or null if not-yet allocated
  const uint8_t* Data() const { return mBuffer.Data(); }
  // Pointer to alpha data or null if not-yet allocated
  const uint8_t* AlphaData() const { return mAlphaBuffer.Data(); }
  // Size of buffer.
  size_t Size() const { return mBuffer.Length(); }
  size_t AlphaSize() const { return mAlphaBuffer.Length(); }
  size_t ComputedSizeOfIncludingThis() const
  {
    return sizeof(*this)
           + mBuffer.ComputedSizeOfExcludingThis()
           + mAlphaBuffer.ComputedSizeOfExcludingThis();
  }
  // Access the buffer as a Span.
  operator Span<const uint8_t>() { return MakeSpan(Data(), Size()); }

  const CryptoSample& mCrypto;
  RefPtr<MediaByteBuffer> mExtraData;

  // Used by the Vorbis decoder and Ogg demuxer.
  // Indicates that this is the last packet of the stream.
  bool mEOS = false;

  // Indicate to the audio decoder that mDiscardPadding frames should be
  // trimmed.
  uint32_t mDiscardPadding = 0;

  RefPtr<TrackInfoSharedPtr> mTrackInfo;

  // Return a deep copy or nullptr if out of memory.
  already_AddRefed<MediaRawData> Clone() const;
  // Create a MediaRawDataWriter for this MediaRawData. The writer is not
  // thread-safe.
  UniquePtr<MediaRawDataWriter> CreateWriter();
  size_t SizeOfIncludingThis(MallocSizeOf aMallocSizeOf) const;

protected:
  ~MediaRawData();

private:
  friend class MediaRawDataWriter;
  AlignedByteBuffer mBuffer;
  AlignedByteBuffer mAlphaBuffer;
  CryptoSample mCryptoInternal;
  MediaRawData(const MediaRawData&); // Not implemented
};

  // MediaByteBuffer is a ref counted infallible TArray.
class MediaByteBuffer : public nsTArray<uint8_t>
{
  NS_INLINE_DECL_THREADSAFE_REFCOUNTING(MediaByteBuffer);
  MediaByteBuffer() = default;
  explicit MediaByteBuffer(size_t aCapacity) : nsTArray<uint8_t>(aCapacity) { }

private:
  ~MediaByteBuffer() { }
};

} // namespace mozilla

#endif // MediaData_h