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chromium / chromium / src.git / b437ed5efaa9bc059b12464769aa3fc0d44b33ee / . / media / base / video_frame.h
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// Copyright (c) 2012 The Chromium Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#ifndef MEDIA_BASE_VIDEO_FRAME_H_
#define MEDIA_BASE_VIDEO_FRAME_H_
#include <stddef.h>
#include <stdint.h>
#include <memory>
#include <string>
#include <utility>
#include <vector>
#include "base/callback.h"
#include "base/hash/md5.h"
#include "base/logging.h"
#include "base/macros.h"
#include "base/memory/aligned_memory.h"
#include "base/memory/ref_counted.h"
#include "base/memory/unsafe_shared_memory_region.h"
#include "base/optional.h"
#include "base/synchronization/lock.h"
#include "base/thread_annotations.h"
#include "base/unguessable_token.h"
#include "build/build_config.h"
#include "gpu/command_buffer/common/mailbox_holder.h"
#include "gpu/ipc/common/vulkan_ycbcr_info.h"
#include "media/base/video_frame_layout.h"
#include "media/base/video_frame_metadata.h"
#include "media/base/video_types.h"
#include "ui/gfx/color_space.h"
#include "ui/gfx/geometry/rect.h"
#include "ui/gfx/geometry/size.h"
#if defined(OS_MACOSX)
#include <CoreVideo/CVPixelBuffer.h>
#include "base/mac/scoped_cftyperef.h"
#endif // defined(OS_MACOSX)
#if defined(OS_LINUX)
#include "base/files/scoped_file.h"
#endif // defined(OS_LINUX)
namespace gfx {
class GpuMemoryBuffer;
}
namespace media {
class MEDIA_EXPORT VideoFrame : public base::RefCountedThreadSafe<VideoFrame> {
public:
enum {
kFrameSizeAlignment = 16,
kFrameSizePadding = 16,
kFrameAddressAlignment = VideoFrameLayout::kBufferAddressAlignment
};
enum {
kMaxPlanes = 4,
kYPlane = 0,
kARGBPlane = kYPlane,
kUPlane = 1,
kUVPlane = kUPlane,
kVPlane = 2,
kAPlane = 3,
};
// Defines the pixel storage type. Differentiates between directly accessible
// |data_| and pixels that are only indirectly accessible and not via mappable
// memory.
// Note that VideoFrames of any StorageType can also have Texture backing,
// with "classical" GPU Driver-only textures identified as STORAGE_OPAQUE.
enum StorageType {
STORAGE_UNKNOWN = 0,
STORAGE_OPAQUE = 1, // We don't know how VideoFrame's pixels are stored.
STORAGE_UNOWNED_MEMORY = 2, // External, non owned data pointers.
STORAGE_OWNED_MEMORY = 3, // VideoFrame has allocated its own data buffer.
STORAGE_SHMEM = 4, // Backed by unsafe (writable) shared memory.
#if defined(OS_LINUX)
// TODO(mcasas): Consider turning this type into STORAGE_NATIVE
// based on the idea of using this same enum value for both DMA
// buffers on Linux and CVPixelBuffers on Mac (which currently use
// STORAGE_UNOWNED_MEMORY) and handle it appropriately in all cases.
STORAGE_DMABUFS = 5, // Each plane is stored into a DmaBuf.
#endif
// Backed by a mojo shared buffer. This should only be used by the
// MojoSharedBufferVideoFrame subclass.
STORAGE_MOJO_SHARED_BUFFER = 6,
STORAGE_GPU_MEMORY_BUFFER = 7,
STORAGE_LAST = STORAGE_GPU_MEMORY_BUFFER,
};
// CB to be called on the mailbox backing this frame when the frame is
// destroyed.
typedef base::OnceCallback<void(const gpu::SyncToken&)> ReleaseMailboxCB;
// Interface representing client operations on a SyncToken, i.e. insert one in
// the GPU Command Buffer and wait for it.
class SyncTokenClient {
public:
SyncTokenClient() {}
virtual void GenerateSyncToken(gpu::SyncToken* sync_token) = 0;
virtual void WaitSyncToken(const gpu::SyncToken& sync_token) = 0;
protected:
virtual ~SyncTokenClient() {}
DISALLOW_COPY_AND_ASSIGN(SyncTokenClient);
};
// Call prior to CreateFrame to ensure validity of frame configuration. Called
// automatically by VideoDecoderConfig::IsValidConfig().
static bool IsValidConfig(VideoPixelFormat format,
StorageType storage_type,
const gfx::Size& coded_size,
const gfx::Rect& visible_rect,
const gfx::Size& natural_size);
// Creates a new frame in system memory with given parameters. Buffers for the
// frame are allocated but not initialized. The caller must not make
// assumptions about the actual underlying size(s), but check the returned
// VideoFrame instead.
static scoped_refptr<VideoFrame> CreateFrame(VideoPixelFormat format,
const gfx::Size& coded_size,
const gfx::Rect& visible_rect,
const gfx::Size& natural_size,
base::TimeDelta timestamp);
// Used by Chromecast only.
// Create a new frame that doesn't contain any valid video content. This frame
// is meant to be sent to compositor to inform that the compositor should
// punch a transparent hole so the video underlay will be visible.
static scoped_refptr<VideoFrame> CreateVideoHoleFrame(
const base::UnguessableToken& overlay_plane_id,
const gfx::Size& natural_size,
base::TimeDelta timestamp);
// Offers the same functionality as CreateFrame, and additionally zeroes out
// the initial allocated buffers.
static scoped_refptr<VideoFrame> CreateZeroInitializedFrame(
VideoPixelFormat format,
const gfx::Size& coded_size,
const gfx::Rect& visible_rect,
const gfx::Size& natural_size,
base::TimeDelta timestamp);
// Creates a new frame in system memory with given parameters. Buffers for the
// frame are allocated but not initialized. The caller should specify the
// physical buffer size and strides if needed in |layout| parameter.
static scoped_refptr<VideoFrame> CreateFrameWithLayout(
const VideoFrameLayout& layout,
const gfx::Rect& visible_rect,
const gfx::Size& natural_size,
base::TimeDelta timestamp,
bool zero_initialize_memory);
// Wraps a set of native textures with a VideoFrame.
// |mailbox_holders_release_cb| will be called with a sync token as the
// argument when the VideoFrame is to be destroyed.
static scoped_refptr<VideoFrame> WrapNativeTextures(
VideoPixelFormat format,
const gpu::MailboxHolder (&mailbox_holder)[kMaxPlanes],
ReleaseMailboxCB mailbox_holders_release_cb,
const gfx::Size& coded_size,
const gfx::Rect& visible_rect,
const gfx::Size& natural_size,
base::TimeDelta timestamp);
// Wraps packed image data residing in a memory buffer with a VideoFrame.
// The image data resides in |data| and is assumed to be packed tightly in a
// buffer of logical dimensions |coded_size| with the appropriate bit depth
// and plane count as given by |format|. Returns NULL on failure.
static scoped_refptr<VideoFrame> WrapExternalData(
VideoPixelFormat format,
const gfx::Size& coded_size,
const gfx::Rect& visible_rect,
const gfx::Size& natural_size,
uint8_t* data,
size_t data_size,
base::TimeDelta timestamp);
static scoped_refptr<VideoFrame> WrapExternalDataWithLayout(
const VideoFrameLayout& layout,
const gfx::Rect& visible_rect,
const gfx::Size& natural_size,
uint8_t* data,
size_t data_size,
base::TimeDelta timestamp);
// Wraps external YUV data of the given parameters with a VideoFrame.
// The returned VideoFrame does not own the data passed in.
static scoped_refptr<VideoFrame> WrapExternalYuvData(
VideoPixelFormat format,
const gfx::Size& coded_size,
const gfx::Rect& visible_rect,
const gfx::Size& natural_size,
int32_t y_stride,
int32_t u_stride,
int32_t v_stride,
uint8_t* y_data,
uint8_t* u_data,
uint8_t* v_data,
base::TimeDelta timestamp);
// Wraps external YUV data with VideoFrameLayout. The returned VideoFrame does
// not own the data passed in.
static scoped_refptr<VideoFrame> WrapExternalYuvDataWithLayout(
const VideoFrameLayout& layout,
const gfx::Rect& visible_rect,
const gfx::Size& natural_size,
uint8_t* y_data,
uint8_t* u_data,
uint8_t* v_data,
base::TimeDelta timestamp);
// Wraps external YUVA data of the given parameters with a VideoFrame.
// The returned VideoFrame does not own the data passed in.
static scoped_refptr<VideoFrame> WrapExternalYuvaData(
VideoPixelFormat format,
const gfx::Size& coded_size,
const gfx::Rect& visible_rect,
const gfx::Size& natural_size,
int32_t y_stride,
int32_t u_stride,
int32_t v_stride,
int32_t a_stride,
uint8_t* y_data,
uint8_t* u_data,
uint8_t* v_data,
uint8_t* a_data,
base::TimeDelta timestamp);
// Wraps |gpu_memory_buffer| along with the mailboxes created from
// |gpu_memory_buffer|. |mailbox_holders_release_cb| will be called with a
// sync token as the argument when the VideoFrame is to be destroyed.
static scoped_refptr<VideoFrame> WrapExternalGpuMemoryBuffer(
const gfx::Rect& visible_rect,
const gfx::Size& natural_size,
std::unique_ptr<gfx::GpuMemoryBuffer> gpu_memory_buffer,
const gpu::MailboxHolder (&mailbox_holders)[kMaxPlanes],
ReleaseMailboxCB mailbox_holder_release_cb,
base::TimeDelta timestamp);
#if defined(OS_LINUX)
// Wraps provided dmabufs
// (https://www.kernel.org/doc/html/latest/driver-api/dma-buf.html) with a
// VideoFrame. The frame will take ownership of |dmabuf_fds|, and will
// automatically close() them on destruction. Callers can call
// media::DuplicateFDs() if they need to retain a copy of the FDs for
// themselves. Note that the FDs are consumed even in case of failure.
// The image data is only accessible via dmabuf fds, which are usually passed
// directly to a hardware device and/or to another process, or can also be
// mapped via mmap() for CPU access.
// Returns NULL on failure.
static scoped_refptr<VideoFrame> WrapExternalDmabufs(
const VideoFrameLayout& layout,
const gfx::Rect& visible_rect,
const gfx::Size& natural_size,
std::vector<base::ScopedFD> dmabuf_fds,
base::TimeDelta timestamp);
#endif
#if defined(OS_MACOSX)
// Wraps a provided CVPixelBuffer with a VideoFrame. The pixel buffer is
// retained for the lifetime of the VideoFrame and released upon destruction.
// The image data is only accessible via the pixel buffer, which could be
// backed by an IOSurface from another process. All the attributes of the
// VideoFrame are derived from the pixel buffer, with the exception of the
// timestamp. If information is missing or is incompatible (for example, a
// pixel format that has no VideoFrame match), NULL is returned.
// http://crbug.com/401308
static scoped_refptr<VideoFrame> WrapCVPixelBuffer(
CVPixelBufferRef cv_pixel_buffer,
base::TimeDelta timestamp);
#endif
// Wraps |frame|. |visible_rect| must be a sub rect within
// frame->visible_rect().
static scoped_refptr<VideoFrame> WrapVideoFrame(
scoped_refptr<VideoFrame> frame,
VideoPixelFormat format,
const gfx::Rect& visible_rect,
const gfx::Size& natural_size);
// Creates a frame which indicates end-of-stream.
static scoped_refptr<VideoFrame> CreateEOSFrame();
// Allocates YV12 frame based on |size|, and sets its data to the YUV(y,u,v).
static scoped_refptr<VideoFrame> CreateColorFrame(const gfx::Size& size,
uint8_t y,
uint8_t u,
uint8_t v,
base::TimeDelta timestamp);
// Allocates YV12 frame based on |size|, and sets its data to the YUV
// equivalent of RGB(0,0,0).
static scoped_refptr<VideoFrame> CreateBlackFrame(const gfx::Size& size);
// Allocates YV12A frame based on |size|, and sets its data to the YUVA
// equivalent of RGBA(0,0,0,0).
static scoped_refptr<VideoFrame> CreateTransparentFrame(
const gfx::Size& size);
static size_t NumPlanes(VideoPixelFormat format);
// Returns the required allocation size for a (tightly packed) frame of the
// given coded size and format.
static size_t AllocationSize(VideoPixelFormat format,
const gfx::Size& coded_size);
// Returns the plane gfx::Size (in bytes) for a plane of the given coded size
// and format.
static gfx::Size PlaneSize(VideoPixelFormat format,
size_t plane,
const gfx::Size& coded_size);
// Returns horizontal bits per pixel for given |plane| and |format|.
static int PlaneHorizontalBitsPerPixel(VideoPixelFormat format, size_t plane);
// Returns bits per pixel for given |plane| and |format|.
static int PlaneBitsPerPixel(VideoPixelFormat format, size_t plane);
// Returns the number of bytes per row for the given plane, format, and width.
// The width may be aligned to format requirements.
static size_t RowBytes(size_t plane, VideoPixelFormat format, int width);
// Returns the number of bytes per element for given |plane| and |format|.
static int BytesPerElement(VideoPixelFormat format, size_t plane);
// Calculates strides for each plane based on |format| and |coded_size|.
static std::vector<int32_t> ComputeStrides(VideoPixelFormat format,
const gfx::Size& coded_size);
// Returns the number of rows for the given plane, format, and height.
// The height may be aligned to format requirements.
static size_t Rows(size_t plane, VideoPixelFormat format, int height);
// Returns the number of columns for the given plane, format, and width.
// The width may be aligned to format requirements.
static size_t Columns(size_t plane, VideoPixelFormat format, int width);
// Used to keep a running hash of seen frames. Expects an initialized MD5
// context. Calls MD5Update with the context and the contents of the frame.
static void HashFrameForTesting(base::MD5Context* context,
const VideoFrame& frame);
// Returns true if |frame| is accesible mapped in the VideoFrame memory space.
// static
static bool IsStorageTypeMappable(VideoFrame::StorageType storage_type);
// Returns true if |plane| is a valid plane index for the given |format|.
static bool IsValidPlane(VideoPixelFormat format, size_t plane);
// Returns the pixel size of each subsample for a given |plane| and |format|.
// E.g. 2x2 for the U-plane in PIXEL_FORMAT_I420.
static gfx::Size SampleSize(VideoPixelFormat format, size_t plane);
// Returns a human readable string of StorageType.
static std::string StorageTypeToString(VideoFrame::StorageType storage_type);
// A video frame wrapping external data may be backed by an unsafe shared
// memory region. These methods are used to appropriately transform a
// VideoFrame created with WrapExternalData, WrapExternalYuvaData, etc. The
// storage type of the Video Frame will be changed to STORAGE_SHM. Once the
// backing of a VideoFrame is set, it cannot be changed.
//
// The region is NOT owned by the video frame. Both the region and its
// associated mapping must outlive this instance.
void BackWithSharedMemory(base::UnsafeSharedMemoryRegion* region,
size_t offset = 0);
// As above, but the VideoFrame owns the shared memory region as well as the
// mapping. They will be destroyed with their VideoFrame.
void BackWithOwnedSharedMemory(base::UnsafeSharedMemoryRegion region,
base::WritableSharedMemoryMapping mapping,
size_t offset = 0);
// Returns the offset into the shared memory where the frame data begins. Only
// valid if the frame is backed by shared memory.
size_t shared_memory_offset() const {
DCHECK(IsValidSharedMemoryFrame());
return shared_memory_offset_;
}
// Valid for shared memory backed VideoFrames.
base::UnsafeSharedMemoryRegion* shm_region() {
DCHECK(IsValidSharedMemoryFrame());
DCHECK(storage_type_ == STORAGE_SHMEM);
return shm_region_;
}
// Returns true if |frame| is accessible and mapped in the VideoFrame memory
// space. If false, clients should refrain from accessing data(),
// visible_data() etc.
bool IsMappable() const;
// Returns true if |frame| has textures with any StorageType and should not be
// accessed via data(), visible_data() etc.
bool HasTextures() const;
// Returns the number of native textures.
size_t NumTextures() const;
// Returns true if the video frame is backed with GpuMemoryBuffer.
bool HasGpuMemoryBuffer() const;
// Gets the GpuMemoryBuffer backing the VideoFrame.
gfx::GpuMemoryBuffer* GetGpuMemoryBuffer() const;
// Returns the color space of this frame's content.
gfx::ColorSpace ColorSpace() const;
void set_color_space(const gfx::ColorSpace& color_space) {
color_space_ = color_space;
}
const VideoFrameLayout& layout() const { return layout_; }
VideoPixelFormat format() const { return layout_.format(); }
StorageType storage_type() const { return storage_type_; }
// The full dimensions of the video frame data.
const gfx::Size& coded_size() const { return layout_.coded_size(); }
// A subsection of [0, 0, coded_size().width(), coded_size.height()]. This
// can be set to "soft-apply" a cropping. It determines the pointers into
// the data returned by visible_data().
const gfx::Rect& visible_rect() const { return visible_rect_; }
// Specifies that the |visible_rect| section of the frame is supposed to be
// scaled to this size when being presented. This can be used to represent
// anamorphic frames, or to "soft-apply" any custom scaling.
const gfx::Size& natural_size() const { return natural_size_; }
int stride(size_t plane) const {
DCHECK(IsValidPlane(format(), plane));
DCHECK_LT(plane, layout_.num_planes());
return layout_.planes()[plane].stride;
}
// Returns the number of bytes per row and number of rows for a given plane.
//
// As opposed to stride(), row_bytes() refers to the bytes representing
// frame data scanlines (coded_size.width() pixels, without stride padding).
int row_bytes(size_t plane) const;
int rows(size_t plane) const;
// Returns pointer to the buffer for a given plane, if this is an
// IsMappable() frame type. The memory is owned by VideoFrame object and must
// not be freed by the caller.
const uint8_t* data(size_t plane) const {
DCHECK(IsValidPlane(format(), plane));
DCHECK(IsMappable());
return data_[plane];
}
uint8_t* data(size_t plane) {
DCHECK(IsValidPlane(format(), plane));
DCHECK(IsMappable());
return data_[plane];
}
const base::Optional<gpu::VulkanYCbCrInfo>& ycbcr_info() const {
return ycbcr_info_;
}
// Returns pointer to the data in the visible region of the frame, for
// IsMappable() storage types. The returned pointer is offsetted into the
// plane buffer specified by visible_rect().origin(). Memory is owned by
// VideoFrame object and must not be freed by the caller.
const uint8_t* visible_data(size_t plane) const;
uint8_t* visible_data(size_t plane);
// Returns a mailbox holder for a given texture.
// Only valid to call if this is a NATIVE_TEXTURE frame. Before using the
// mailbox, the caller must wait for the included sync point.
const gpu::MailboxHolder& mailbox_holder(size_t texture_index) const;
#if defined(OS_LINUX)
// Returns a vector containing the backing DmaBufs for this frame. The number
// of returned DmaBufs will be equal or less than the number of planes of
// the frame. If there are less, this means that the last FD contains the
// remaining planes.
// Note that the returned FDs are still owned by the VideoFrame. This means
// that the caller shall not close them, or use them after the VideoFrame is
// destroyed. For such use cases, use media::DuplicateFDs() to obtain your
// own copy of the FDs.
const std::vector<base::ScopedFD>& DmabufFds() const;
// Returns true if |frame| has DmaBufs.
bool HasDmaBufs() const;
// Returns true if both VideoFrames are backed by DMABUF memory and point
// to the same set of DMABUFs, meaning that both frames use the same memory.
bool IsSameDmaBufsAs(const VideoFrame& frame) const;
#endif
#if defined(OS_MACOSX)
// Returns the backing CVPixelBuffer, if present.
CVPixelBufferRef CvPixelBuffer() const;
#endif
// Sets the mailbox release callback.
//
// The callback may be run from ANY THREAD, and so it is up to the client to
// ensure thread safety.
//
// WARNING: This method is not thread safe; it should only be called if you
// are still the only owner of this VideoFrame.
void SetReleaseMailboxCB(ReleaseMailboxCB release_mailbox_cb);
// Tests whether a mailbox release callback is configured.
bool HasReleaseMailboxCB() const;
// Adds a callback to be run when the VideoFrame is about to be destroyed.
// The callback may be run from ANY THREAD, and so it is up to the client to
// ensure thread safety. Although read-only access to the members of this
// VideoFrame is permitted while the callback executes (including
// VideoFrameMetadata), clients should not assume the data pointers are
// valid.
void AddDestructionObserver(base::OnceClosure callback);
// Returns a dictionary of optional metadata. This contains information
// associated with the frame that downstream clients might use for frame-level
// logging, quality/performance optimizations, signaling, etc.
//
// TODO(miu): Move some of the "extra" members of VideoFrame (below) into
// here as a later clean-up step.
const VideoFrameMetadata* metadata() const { return &metadata_; }
VideoFrameMetadata* metadata() { return &metadata_; }
// The time span between the current frame and the first frame of the stream.
// This is the media timestamp, and not the reference time.
// See VideoFrameMetadata::REFERENCE_TIME for details.
base::TimeDelta timestamp() const { return timestamp_; }
void set_timestamp(base::TimeDelta timestamp) {
timestamp_ = timestamp;
}
// It uses |client| to insert a new sync token and potentially waits on an
// older sync token. The final sync point will be used to release this
// VideoFrame. Also returns the new sync token.
// This method is thread safe. Both blink and compositor threads can call it.
gpu::SyncToken UpdateReleaseSyncToken(SyncTokenClient* client);
// Returns a human-readable string describing |*this|.
std::string AsHumanReadableString();
// Unique identifier for this video frame; generated at construction time and
// guaranteed to be unique within a single process.
int unique_id() const { return unique_id_; }
// Returns the number of bits per channel.
size_t BitDepth() const;
// Provide the sampler conversion information for the frame.
void set_ycbcr_info(const base::Optional<gpu::VulkanYCbCrInfo>& ycbcr_info) {
ycbcr_info_ = ycbcr_info;
}
protected:
friend class base::RefCountedThreadSafe<VideoFrame>;
// Clients must use the static factory/wrapping methods to create a new frame.
// Derived classes should create their own factory/wrapping methods, and use
// this constructor to do basic initialization.
VideoFrame(const VideoFrameLayout& layout,
StorageType storage_type,
const gfx::Rect& visible_rect,
const gfx::Size& natural_size,
base::TimeDelta timestamp);
virtual ~VideoFrame();
// Creates a summary of the configuration settings provided as parameters.
static std::string ConfigToString(const VideoPixelFormat format,
const VideoFrame::StorageType storage_type,
const gfx::Size& coded_size,
const gfx::Rect& visible_rect,
const gfx::Size& natural_size);
// Returns |dimensions| adjusted to appropriate boundaries based on |format|.
static gfx::Size DetermineAlignedSize(VideoPixelFormat format,
const gfx::Size& dimensions);
void set_data(size_t plane, uint8_t* ptr) {
DCHECK(IsValidPlane(format(), plane));
DCHECK(ptr);
data_[plane] = ptr;
}
private:
static scoped_refptr<VideoFrame> CreateFrameInternal(
VideoPixelFormat format,
const gfx::Size& coded_size,
const gfx::Rect& visible_rect,
const gfx::Size& natural_size,
base::TimeDelta timestamp,
bool zero_initialize_memory);
// Return the alignment for the whole frame, calculated as the max of the
// alignment for each individual plane.
static gfx::Size CommonAlignment(VideoPixelFormat format);
void AllocateMemory(bool zero_initialize_memory);
// Calculates plane size.
// It first considers buffer size layout_ object provides. If layout's
// number of buffers equals to number of planes, and buffer size is assigned
// (non-zero), it returns buffers' size.
// Otherwise, it uses the first (num_buffers - 1) assigned buffers' size as
// plane size. Then for the rest unassigned planes, calculates their size
// based on format, coded size and stride for the plane.
std::vector<size_t> CalculatePlaneSize() const;
// Returns true iff the frame has a shared memory storage type, and the
// associated regions are valid.
bool IsValidSharedMemoryFrame() const;
// VideFrameLayout (includes format, coded_size, and strides).
const VideoFrameLayout layout_;
// Set by WrapVideoFrame to soft-apply a new set of format, visible rectangle,
// and natural size on |wrapped_frame_|
scoped_refptr<VideoFrame> wrapped_frame_;
// Storage type for the different planes.
StorageType storage_type_; // TODO(mcasas): make const
// Width, height, and offsets of the visible portion of the video frame. Must
// be a subrect of |coded_size_|. Can be odd with respect to the sample
// boundaries, e.g. for formats with subsampled chroma.
const gfx::Rect visible_rect_;
// Width and height of the visible portion of the video frame
// (|visible_rect_.size()|) with aspect ratio taken into account.
const gfx::Size natural_size_;
// Array of data pointers to each plane.
// TODO(mcasas): we don't know on ctor if we own |data_| or not. Change
// to std::unique_ptr<uint8_t, AlignedFreeDeleter> after refactoring
// VideoFrame.
uint8_t* data_[kMaxPlanes];
// Native texture mailboxes, if this is a IsTexture() frame.
gpu::MailboxHolder mailbox_holders_[kMaxPlanes];
ReleaseMailboxCB mailbox_holders_release_cb_;
// Shared memory handle, if this frame is STORAGE_SHMEM. The region pointed
// to is unowned.
base::UnsafeSharedMemoryRegion* shm_region_ = nullptr;
// If this is a STORAGE_SHMEM frame, the offset of the data within the shared
// memory.
size_t shared_memory_offset_ = 0;
// Used if this is a STORAGE_SHMEM frame with owned shared memory. In that
// case, shm_region_ will refer to this region.
base::UnsafeSharedMemoryRegion owned_shm_region_;
base::WritableSharedMemoryMapping owned_shm_mapping_;
// GPU memory buffer, if this frame is STORAGE_GPU_MEMORY_BUFFER.
std::unique_ptr<gfx::GpuMemoryBuffer> gpu_memory_buffer_;
#if defined(OS_LINUX)
class DmabufHolder;
// Dmabufs for the frame, used when storage is STORAGE_DMABUFS. Size is either
// equal or less than the number of planes of the frame. If it is less, then
// the memory area represented by the last FD contains the remaining planes.
// If a STORAGE_DMABUFS frame is wrapped into another, the wrapping frame
// will get an extra reference to the FDs (i.e. no duplication is involved).
// This makes it possible to test whether two VideoFrame instances point to
// the same DMABUF memory by testing for
// (&vf1->DmabufFds() == &vf2->DmabufFds()).
scoped_refptr<DmabufHolder> dmabuf_fds_;
#endif
#if defined(OS_MACOSX)
// CVPixelBuffer, if this frame is wrapping one.
base::ScopedCFTypeRef<CVPixelBufferRef> cv_pixel_buffer_;
#endif
std::vector<base::OnceClosure> done_callbacks_;
base::TimeDelta timestamp_;
base::Lock release_sync_token_lock_;
gpu::SyncToken release_sync_token_ GUARDED_BY(release_sync_token_lock_);
VideoFrameMetadata metadata_;
// Generated at construction time.
const int unique_id_;
gfx::ColorSpace color_space_;
// Sampler conversion information which is used in vulkan context for android.
base::Optional<gpu::VulkanYCbCrInfo> ycbcr_info_;
DISALLOW_IMPLICIT_CONSTRUCTORS(VideoFrame);
};
} // namespace media
#endif // MEDIA_BASE_VIDEO_FRAME_H_