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/*
* Copyright (C) 2010 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#ifndef ANDROID_BUFFERLAYERCONSUMER_H
#define ANDROID_BUFFERLAYERCONSUMER_H
#include <android-base/thread_annotations.h>
#include <gui/BufferQueueDefs.h>
#include <gui/ConsumerBase.h>
#include <gui/HdrMetadata.h>
#include <ui/FenceTime.h>
#include <ui/GraphicBuffer.h>
#include <ui/GraphicTypes.h>
#include <ui/Region.h>
#include <utils/String8.h>
#include <utils/Vector.h>
#include <utils/threads.h>
namespace android {
// ----------------------------------------------------------------------------
class DispSync;
class Layer;
class String8;
namespace renderengine {
class RenderEngine;
class Image;
} // namespace renderengine
/*
* BufferLayerConsumer consumes buffers of graphics data from a BufferQueue,
* and makes them available to RenderEngine as a texture.
*
* A typical usage pattern is to call updateTexImage() when a new frame is
* desired. If a new frame is available, the frame is latched. If not, the
* previous contents are retained. The texture is attached and updated after
* bindTextureImage() is called.
*
* All calls to updateTexImage must be made with RenderEngine being current.
* The texture is attached to the TEXTURE_EXTERNAL texture target.
*/
class BufferLayerConsumer : public ConsumerBase {
public:
static const status_t BUFFER_REJECTED = UNKNOWN_ERROR + 8;
class BufferRejecter {
friend class BufferLayerConsumer;
virtual bool reject(const sp<GraphicBuffer>& buf, const BufferItem& item) = 0;
protected:
virtual ~BufferRejecter() {}
};
struct ContentsChangedListener : public FrameAvailableListener {
virtual void onSidebandStreamChanged() = 0;
};
// BufferLayerConsumer constructs a new BufferLayerConsumer object. The
// tex parameter indicates the name of the RenderEngine texture to which
// images are to be streamed.
BufferLayerConsumer(const sp<IGraphicBufferConsumer>& bq, renderengine::RenderEngine& engine,
uint32_t tex, Layer* layer);
// Sets the contents changed listener. This should be used instead of
// ConsumerBase::setFrameAvailableListener().
void setContentsChangedListener(const wp<ContentsChangedListener>& listener);
// updateTexImage acquires the most recently queued buffer, and sets the
// image contents of the target texture to it.
//
// This call may only be made while RenderEngine is current.
//
// This calls doFenceWait to ensure proper synchronization unless native
// fence is supported.
//
// Unlike the GLConsumer version, this version takes a functor that may be
// used to reject the newly acquired buffer. It also does not bind the
// RenderEngine texture until bindTextureImage is called.
status_t updateTexImage(BufferRejecter* rejecter, nsecs_t expectedPresentTime,
bool* autoRefresh, bool* queuedBuffer, uint64_t maxFrameNumber);
// See BufferLayerConsumer::bindTextureImageLocked().
status_t bindTextureImage();
// setReleaseFence stores a fence that will signal when the current buffer
// is no longer being read. This fence will be returned to the producer
// when the current buffer is released by updateTexImage(). Multiple
// fences can be set for a given buffer; they will be merged into a single
// union fence.
void setReleaseFence(const sp<Fence>& fence);
bool releasePendingBuffer();
sp<Fence> getPrevFinalReleaseFence() const;
// See GLConsumer::getTransformMatrix.
void getTransformMatrix(float mtx[16]);
// getTimestamp retrieves the timestamp associated with the texture image
// set by the most recent call to updateTexImage.
//
// The timestamp is in nanoseconds, and is monotonically increasing. Its
// other semantics (zero point, etc) are source-dependent and should be
// documented by the source.
int64_t getTimestamp();
// getDataSpace retrieves the DataSpace associated with the texture image
// set by the most recent call to updateTexImage.
ui::Dataspace getCurrentDataSpace();
// getCurrentHdrMetadata retrieves the HDR metadata associated with the
// texture image set by the most recent call to updateTexImage.
const HdrMetadata& getCurrentHdrMetadata() const;
// getFrameNumber retrieves the frame number associated with the texture
// image set by the most recent call to updateTexImage.
//
// The frame number is an incrementing counter set to 0 at the creation of
// the BufferQueue associated with this consumer.
uint64_t getFrameNumber();
bool getTransformToDisplayInverse() const;
// must be called from SF main thread
const Region& getSurfaceDamage() const;
// Merge the given damage region into the current damage region value.
void mergeSurfaceDamage(const Region& damage);
// getCurrentApi retrieves the API which queues the current buffer.
int getCurrentApi() const;
// See GLConsumer::setDefaultBufferSize.
status_t setDefaultBufferSize(uint32_t width, uint32_t height);
// setFilteringEnabled sets whether the transform matrix should be computed
// for use with bilinear filtering.
void setFilteringEnabled(bool enabled);
// getCurrentBuffer returns the buffer associated with the current image.
// When outSlot is not nullptr, the current buffer slot index is also
// returned. Simiarly, when outFence is not nullptr, the current output
// fence is returned.
sp<GraphicBuffer> getCurrentBuffer(int* outSlot = nullptr, sp<Fence>* outFence = nullptr) const;
// getCurrentCrop returns the cropping rectangle of the current buffer.
Rect getCurrentCrop() const;
// getCurrentTransform returns the transform of the current buffer.
uint32_t getCurrentTransform() const;
// getCurrentScalingMode returns the scaling mode of the current buffer.
uint32_t getCurrentScalingMode() const;
// getCurrentFence returns the fence indicating when the current buffer is
// ready to be read from.
sp<Fence> getCurrentFence() const;
// getCurrentFence returns the FenceTime indicating when the current
// buffer is ready to be read from.
std::shared_ptr<FenceTime> getCurrentFenceTime() const;
// setConsumerUsageBits overrides the ConsumerBase method to OR
// DEFAULT_USAGE_FLAGS to usage.
status_t setConsumerUsageBits(uint64_t usage);
void onBufferAvailable(const BufferItem& item) EXCLUDES(mImagesMutex);
protected:
// abandonLocked overrides the ConsumerBase method to clear
// mCurrentTextureImage in addition to the ConsumerBase behavior.
virtual void abandonLocked() EXCLUDES(mImagesMutex);
// dumpLocked overrides the ConsumerBase method to dump BufferLayerConsumer-
// specific info in addition to the ConsumerBase behavior.
virtual void dumpLocked(String8& result, const char* prefix) const;
// See ConsumerBase::acquireBufferLocked
virtual status_t acquireBufferLocked(BufferItem* item, nsecs_t presentWhen,
uint64_t maxFrameNumber = 0) override
EXCLUDES(mImagesMutex);
bool canUseImageCrop(const Rect& crop) const;
struct PendingRelease {
PendingRelease() : isPending(false), currentTexture(-1), graphicBuffer() {}
bool isPending;
int currentTexture;
sp<GraphicBuffer> graphicBuffer;
};
// This releases the buffer in the slot referenced by mCurrentTexture,
// then updates state to refer to the BufferItem, which must be a
// newly-acquired buffer. If pendingRelease is not null, the parameters
// which would have been passed to releaseBufferLocked upon the successful
// completion of the method will instead be returned to the caller, so that
// it may call releaseBufferLocked itself later.
status_t updateAndReleaseLocked(const BufferItem& item,
PendingRelease* pendingRelease = nullptr)
EXCLUDES(mImagesMutex);
// Binds mTexName and the current buffer to TEXTURE_EXTERNAL target.
// If the bind succeeds, this calls doFenceWait.
status_t bindTextureImageLocked();
private:
// Utility class for managing GraphicBuffer references into renderengine
class Image {
public:
Image(const sp<GraphicBuffer>& graphicBuffer, renderengine::RenderEngine& engine);
virtual ~Image();
const sp<GraphicBuffer>& graphicBuffer() { return mGraphicBuffer; }
private:
// mGraphicBuffer is the buffer that was used to create this image.
sp<GraphicBuffer> mGraphicBuffer;
// Back-reference into renderengine to initiate cleanup.
renderengine::RenderEngine& mRE;
DISALLOW_COPY_AND_ASSIGN(Image);
};
// freeBufferLocked frees up the given buffer slot. If the slot has been
// initialized this will release the reference to the GraphicBuffer in
// that slot. Otherwise it has no effect.
//
// This method must be called with mMutex locked.
virtual void freeBufferLocked(int slotIndex) EXCLUDES(mImagesMutex);
// IConsumerListener interface
void onDisconnect() override;
void onSidebandStreamChanged() override;
void addAndGetFrameTimestamps(const NewFrameEventsEntry* newTimestamps,
FrameEventHistoryDelta* outDelta) override;
// computeCurrentTransformMatrixLocked computes the transform matrix for the
// current texture. It uses mCurrentTransform and the current GraphicBuffer
// to compute this matrix and stores it in mCurrentTransformMatrix.
// mCurrentTextureImage must not be nullptr.
void computeCurrentTransformMatrixLocked();
// doFenceWaitLocked inserts a wait command into the RenderEngine command
// stream to ensure that it is safe for future RenderEngine commands to
// access the current texture buffer.
status_t doFenceWaitLocked() const;
// getCurrentCropLocked returns the cropping rectangle of the current buffer.
Rect getCurrentCropLocked() const;
// The default consumer usage flags that BufferLayerConsumer always sets on its
// BufferQueue instance; these will be OR:d with any additional flags passed
// from the BufferLayerConsumer user. In particular, BufferLayerConsumer will always
// consume buffers as hardware textures.
static const uint64_t DEFAULT_USAGE_FLAGS = GraphicBuffer::USAGE_HW_TEXTURE;
// mCurrentTextureBuffer is the buffer containing the current texture. It's
// possible that this buffer is not associated with any buffer slot, so we
// must track it separately in order to support the getCurrentBuffer method.
std::shared_ptr<Image> mCurrentTextureBuffer;
// mCurrentCrop is the crop rectangle that applies to the current texture.
// It gets set each time updateTexImage is called.
Rect mCurrentCrop;
// mCurrentTransform is the transform identifier for the current texture. It
// gets set each time updateTexImage is called.
uint32_t mCurrentTransform;
// mCurrentScalingMode is the scaling mode for the current texture. It gets
// set each time updateTexImage is called.
uint32_t mCurrentScalingMode;
// mCurrentFence is the fence received from BufferQueue in updateTexImage.
sp<Fence> mCurrentFence;
// The FenceTime wrapper around mCurrentFence.
std::shared_ptr<FenceTime> mCurrentFenceTime{FenceTime::NO_FENCE};
// mCurrentTransformMatrix is the transform matrix for the current texture.
// It gets computed by computeTransformMatrix each time updateTexImage is
// called.
float mCurrentTransformMatrix[16];
// mCurrentTimestamp is the timestamp for the current texture. It
// gets set each time updateTexImage is called.
int64_t mCurrentTimestamp;
// mCurrentDataSpace is the dataspace for the current texture. It
// gets set each time updateTexImage is called.
ui::Dataspace mCurrentDataSpace;
// mCurrentHdrMetadata is the HDR metadata for the current texture. It
// gets set each time updateTexImage is called.
HdrMetadata mCurrentHdrMetadata;
// mCurrentFrameNumber is the frame counter for the current texture.
// It gets set each time updateTexImage is called.
uint64_t mCurrentFrameNumber;
// Indicates this buffer must be transformed by the inverse transform of the screen
// it is displayed onto. This is applied after BufferLayerConsumer::mCurrentTransform.
// This must be set/read from SurfaceFlinger's main thread.
bool mCurrentTransformToDisplayInverse;
// The portion of this surface that has changed since the previous frame
Region mCurrentSurfaceDamage;
int mCurrentApi;
uint32_t mDefaultWidth, mDefaultHeight;
// mFilteringEnabled indicates whether the transform matrix is computed for
// use with bilinear filtering. It defaults to true and is changed by
// setFilteringEnabled().
bool mFilteringEnabled;
renderengine::RenderEngine& mRE;
// mTexName is the name of the RenderEngine texture to which streamed
// images will be bound when bindTexImage is called. It is set at
// construction time.
const uint32_t mTexName;
// The layer for this BufferLayerConsumer
const wp<Layer> mLayer;
wp<ContentsChangedListener> mContentsChangedListener;
// mCurrentTexture is the buffer slot index of the buffer that is currently
// bound to the RenderEngine texture. It is initialized to INVALID_BUFFER_SLOT,
// indicating that no buffer slot is currently bound to the texture. Note,
// however, that a value of INVALID_BUFFER_SLOT does not necessarily mean
// that no buffer is bound to the texture. A call to setBufferCount will
// reset mCurrentTexture to INVALID_BUFFER_SLOT.
int mCurrentTexture;
// Shadow buffer cache for cleaning up renderengine references.
std::shared_ptr<Image> mImages[BufferQueueDefs::NUM_BUFFER_SLOTS] GUARDED_BY(mImagesMutex);
// Separate mutex guarding the shadow buffer cache.
// mImagesMutex can be manipulated with binder threads (e.g. onBuffersAllocated)
// which is contentious enough that we can't just use mMutex.
mutable std::mutex mImagesMutex;
// A release that is pending on the receipt of a new release fence from
// presentDisplay
PendingRelease mPendingRelease;
};
// ----------------------------------------------------------------------------
}; // namespace android
#endif // ANDROID_BUFFERLAYERCONSUMER_H