/* * 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_GUI_SURFACE_H #define ANDROID_GUI_SURFACE_H #include <gui/BufferQueueDefs.h> #include <gui/HdrMetadata.h> #include <gui/IGraphicBufferProducer.h> #include <ui/ANativeObjectBase.h> #include <ui/GraphicTypes.h> #include <ui/Region.h> #include <utils/Condition.h> #include <utils/Mutex.h> #include <utils/RefBase.h> #include <system/window.h> namespace android { class ISurfaceComposer; /* * An implementation of ANativeWindow that feeds graphics buffers into a * BufferQueue. * * This is typically used by programs that want to render frames through * some means (maybe OpenGL, a software renderer, or a hardware decoder) * and have the frames they create forwarded to SurfaceFlinger for * compositing. For example, a video decoder could render a frame and call * eglSwapBuffers(), which invokes ANativeWindow callbacks defined by * Surface. Surface then forwards the buffers through Binder IPC * to the BufferQueue's producer interface, providing the new frame to a * consumer such as GLConsumer. */ class Surface : public ANativeObjectBase<ANativeWindow, Surface, RefBase> { public: /* * creates a Surface from the given IGraphicBufferProducer (which concrete * implementation is a BufferQueue). * * Surface is mainly state-less while it's disconnected, it can be * viewed as a glorified IGraphicBufferProducer holder. It's therefore * safe to create other Surfaces from the same IGraphicBufferProducer. * * However, once a Surface is connected, it'll prevent other Surfaces * referring to the same IGraphicBufferProducer to become connected and * therefore prevent them to be used as actual producers of buffers. * * the controlledByApp flag indicates that this Surface (producer) is * controlled by the application. This flag is used at connect time. */ explicit Surface(const sp<IGraphicBufferProducer>& bufferProducer, bool controlledByApp = false); /* getIGraphicBufferProducer() returns the IGraphicBufferProducer this * Surface was created with. Usually it's an error to use the * IGraphicBufferProducer while the Surface is connected. */ sp<IGraphicBufferProducer> getIGraphicBufferProducer() const; /* convenience function to check that the given surface is non NULL as * well as its IGraphicBufferProducer */ static bool isValid(const sp<Surface>& surface) { return surface != NULL && surface->getIGraphicBufferProducer() != NULL; } /* Attaches a sideband buffer stream to the Surface's IGraphicBufferProducer. * * A sideband stream is a device-specific mechanism for passing buffers * from the producer to the consumer without using dequeueBuffer/ * queueBuffer. If a sideband stream is present, the consumer can choose * whether to acquire buffers from the sideband stream or from the queued * buffers. * * Passing NULL or a different stream handle will detach the previous * handle if any. */ void setSidebandStream(const sp<NativeHandle>& stream); /* Allocates buffers based on the current dimensions/format. * * This function will allocate up to the maximum number of buffers * permitted by the current BufferQueue configuration. It will use the * default format and dimensions. This is most useful to avoid an allocation * delay during dequeueBuffer. If there are already the maximum number of * buffers allocated, this function has no effect. */ void allocateBuffers(); /* Sets the generation number on the IGraphicBufferProducer and updates the * generation number on any buffers attached to the Surface after this call. * See IGBP::setGenerationNumber for more information. */ status_t setGenerationNumber(uint32_t generationNumber); // See IGraphicBufferProducer::getConsumerName String8 getConsumerName() const; // See IGraphicBufferProducer::getNextFrameNumber uint64_t getNextFrameNumber() const; /* Set the scaling mode to be used with a Surface. * See NATIVE_WINDOW_SET_SCALING_MODE and its parameters * in <system/window.h>. */ int setScalingMode(int mode); // See IGraphicBufferProducer::setDequeueTimeout status_t setDequeueTimeout(nsecs_t timeout); /* * Wait for frame number to increase past lastFrame for at most * timeoutNs. Useful for one thread to wait for another unknown * thread to queue a buffer. */ bool waitForNextFrame(uint64_t lastFrame, nsecs_t timeout); // See IGraphicBufferProducer::getLastQueuedBuffer // See GLConsumer::getTransformMatrix for outTransformMatrix format status_t getLastQueuedBuffer(sp<GraphicBuffer>* outBuffer, sp<Fence>* outFence, float outTransformMatrix[16]); status_t getDisplayRefreshCycleDuration(nsecs_t* outRefreshDuration); /* Enables or disables frame timestamp tracking. It is disabled by default * to avoid overhead during queue and dequeue for applications that don't * need the feature. If disabled, calls to getFrameTimestamps will fail. */ void enableFrameTimestamps(bool enable); status_t getCompositorTiming( nsecs_t* compositeDeadline, nsecs_t* compositeInterval, nsecs_t* compositeToPresentLatency); // See IGraphicBufferProducer::getFrameTimestamps status_t getFrameTimestamps(uint64_t frameNumber, nsecs_t* outRequestedPresentTime, nsecs_t* outAcquireTime, nsecs_t* outLatchTime, nsecs_t* outFirstRefreshStartTime, nsecs_t* outLastRefreshStartTime, nsecs_t* outGlCompositionDoneTime, nsecs_t* outDisplayPresentTime, nsecs_t* outDequeueReadyTime, nsecs_t* outReleaseTime); status_t getWideColorSupport(bool* supported); status_t getHdrSupport(bool* supported); status_t getUniqueId(uint64_t* outId) const; status_t getConsumerUsage(uint64_t* outUsage) const; // Returns the CLOCK_MONOTONIC start time of the last dequeueBuffer call nsecs_t getLastDequeueStartTime() const; protected: virtual ~Surface(); // Virtual for testing. virtual sp<ISurfaceComposer> composerService() const; virtual nsecs_t now() const; private: // can't be copied Surface& operator = (const Surface& rhs); Surface(const Surface& rhs); // ANativeWindow hooks static int hook_cancelBuffer(ANativeWindow* window, ANativeWindowBuffer* buffer, int fenceFd); static int hook_dequeueBuffer(ANativeWindow* window, ANativeWindowBuffer** buffer, int* fenceFd); static int hook_perform(ANativeWindow* window, int operation, ...); static int hook_query(const ANativeWindow* window, int what, int* value); static int hook_queueBuffer(ANativeWindow* window, ANativeWindowBuffer* buffer, int fenceFd); static int hook_setSwapInterval(ANativeWindow* window, int interval); static int hook_cancelBuffer_DEPRECATED(ANativeWindow* window, ANativeWindowBuffer* buffer); static int hook_dequeueBuffer_DEPRECATED(ANativeWindow* window, ANativeWindowBuffer** buffer); static int hook_lockBuffer_DEPRECATED(ANativeWindow* window, ANativeWindowBuffer* buffer); static int hook_queueBuffer_DEPRECATED(ANativeWindow* window, ANativeWindowBuffer* buffer); int dispatchConnect(va_list args); int dispatchDisconnect(va_list args); int dispatchSetBufferCount(va_list args); int dispatchSetBuffersGeometry(va_list args); int dispatchSetBuffersDimensions(va_list args); int dispatchSetBuffersUserDimensions(va_list args); int dispatchSetBuffersFormat(va_list args); int dispatchSetScalingMode(va_list args); int dispatchSetBuffersTransform(va_list args); int dispatchSetBuffersStickyTransform(va_list args); int dispatchSetBuffersTimestamp(va_list args); int dispatchSetCrop(va_list args); int dispatchSetUsage(va_list args); int dispatchSetUsage64(va_list args); int dispatchLock(va_list args); int dispatchUnlockAndPost(va_list args); int dispatchSetSidebandStream(va_list args); int dispatchSetBuffersDataSpace(va_list args); int dispatchSetBuffersSmpte2086Metadata(va_list args); int dispatchSetBuffersCta8613Metadata(va_list args); int dispatchSetSurfaceDamage(va_list args); int dispatchSetSharedBufferMode(va_list args); int dispatchSetAutoRefresh(va_list args); int dispatchGetDisplayRefreshCycleDuration(va_list args); int dispatchGetNextFrameId(va_list args); int dispatchEnableFrameTimestamps(va_list args); int dispatchGetCompositorTiming(va_list args); int dispatchGetFrameTimestamps(va_list args); int dispatchGetWideColorSupport(va_list args); int dispatchGetHdrSupport(va_list args); int dispatchGetConsumerUsage64(va_list args); protected: virtual int dequeueBuffer(ANativeWindowBuffer** buffer, int* fenceFd); virtual int cancelBuffer(ANativeWindowBuffer* buffer, int fenceFd); virtual int queueBuffer(ANativeWindowBuffer* buffer, int fenceFd); virtual int perform(int operation, va_list args); virtual int setSwapInterval(int interval); virtual int lockBuffer_DEPRECATED(ANativeWindowBuffer* buffer); virtual int connect(int api); virtual int setBufferCount(int bufferCount); virtual int setBuffersUserDimensions(uint32_t width, uint32_t height); virtual int setBuffersFormat(PixelFormat format); virtual int setBuffersTransform(uint32_t transform); virtual int setBuffersStickyTransform(uint32_t transform); virtual int setBuffersTimestamp(int64_t timestamp); virtual int setBuffersDataSpace(ui::Dataspace dataSpace); virtual int setBuffersSmpte2086Metadata(const android_smpte2086_metadata* metadata); virtual int setBuffersCta8613Metadata(const android_cta861_3_metadata* metadata); virtual int setCrop(Rect const* rect); virtual int setUsage(uint64_t reqUsage); virtual void setSurfaceDamage(android_native_rect_t* rects, size_t numRects); public: virtual int disconnect(int api, IGraphicBufferProducer::DisconnectMode mode = IGraphicBufferProducer::DisconnectMode::Api); virtual int setMaxDequeuedBufferCount(int maxDequeuedBuffers); virtual int setAsyncMode(bool async); virtual int setSharedBufferMode(bool sharedBufferMode); virtual int setAutoRefresh(bool autoRefresh); virtual int setBuffersDimensions(uint32_t width, uint32_t height); virtual int lock(ANativeWindow_Buffer* outBuffer, ARect* inOutDirtyBounds); virtual int unlockAndPost(); virtual int query(int what, int* value) const; virtual int connect(int api, const sp<IProducerListener>& listener); // When reportBufferRemoval is true, clients must call getAndFlushRemovedBuffers to fetch // GraphicBuffers removed from this surface after a dequeueBuffer, detachNextBuffer or // attachBuffer call. This allows clients with their own buffer caches to free up buffers no // longer in use by this surface. virtual int connect( int api, const sp<IProducerListener>& listener, bool reportBufferRemoval); virtual int detachNextBuffer(sp<GraphicBuffer>* outBuffer, sp<Fence>* outFence); virtual int attachBuffer(ANativeWindowBuffer*); // When client connects to Surface with reportBufferRemoval set to true, any buffers removed // from this Surface will be collected and returned here. Once this method returns, these // buffers will no longer be referenced by this Surface unless they are attached to this // Surface later. The list of removed buffers will only be stored until the next dequeueBuffer, // detachNextBuffer, or attachBuffer call. status_t getAndFlushRemovedBuffers(std::vector<sp<GraphicBuffer>>* out); ui::Dataspace getBuffersDataSpace(); static status_t attachAndQueueBuffer(Surface* surface, sp<GraphicBuffer> buffer); protected: enum { NUM_BUFFER_SLOTS = BufferQueueDefs::NUM_BUFFER_SLOTS }; enum { DEFAULT_FORMAT = PIXEL_FORMAT_RGBA_8888 }; void querySupportedTimestampsLocked() const; void freeAllBuffers(); int getSlotFromBufferLocked(android_native_buffer_t* buffer) const; struct BufferSlot { sp<GraphicBuffer> buffer; Region dirtyRegion; }; // mSurfaceTexture is the interface to the surface texture server. All // operations on the surface texture client ultimately translate into // interactions with the server using this interface. // TODO: rename to mBufferProducer sp<IGraphicBufferProducer> mGraphicBufferProducer; // mSlots stores the buffers that have been allocated for each buffer slot. // It is initialized to null pointers, and gets filled in with the result of // IGraphicBufferProducer::requestBuffer when the client dequeues a buffer from a // slot that has not yet been used. The buffer allocated to a slot will also // be replaced if the requested buffer usage or geometry differs from that // of the buffer allocated to a slot. BufferSlot mSlots[NUM_BUFFER_SLOTS]; // mReqWidth is the buffer width that will be requested at the next dequeue // operation. It is initialized to 1. uint32_t mReqWidth; // mReqHeight is the buffer height that will be requested at the next // dequeue operation. It is initialized to 1. uint32_t mReqHeight; // mReqFormat is the buffer pixel format that will be requested at the next // deuque operation. It is initialized to PIXEL_FORMAT_RGBA_8888. PixelFormat mReqFormat; // mReqUsage is the set of buffer usage flags that will be requested // at the next deuque operation. It is initialized to 0. uint64_t mReqUsage; // mTimestamp is the timestamp that will be used for the next buffer queue // operation. It defaults to NATIVE_WINDOW_TIMESTAMP_AUTO, which means that // a timestamp is auto-generated when queueBuffer is called. int64_t mTimestamp; // mDataSpace is the buffer dataSpace that will be used for the next buffer // queue operation. It defaults to Dataspace::UNKNOWN, which // means that the buffer contains some type of color data. ui::Dataspace mDataSpace; // mHdrMetadata is the HDR metadata that will be used for the next buffer // queue operation. There is no HDR metadata by default. HdrMetadata mHdrMetadata; // mCrop is the crop rectangle that will be used for the next buffer // that gets queued. It is set by calling setCrop. Rect mCrop; // mScalingMode is the scaling mode that will be used for the next // buffers that get queued. It is set by calling setScalingMode. int mScalingMode; // mTransform is the transform identifier that will be used for the next // buffer that gets queued. It is set by calling setTransform. uint32_t mTransform; // mStickyTransform is a transform that is applied on top of mTransform // in each buffer that is queued. This is typically used to force the // compositor to apply a transform, and will prevent the transform hint // from being set by the compositor. uint32_t mStickyTransform; // mDefaultWidth is default width of the buffers, regardless of the // native_window_set_buffers_dimensions call. uint32_t mDefaultWidth; // mDefaultHeight is default height of the buffers, regardless of the // native_window_set_buffers_dimensions call. uint32_t mDefaultHeight; // mUserWidth, if non-zero, is an application-specified override // of mDefaultWidth. This is lower priority than the width set by // native_window_set_buffers_dimensions. uint32_t mUserWidth; // mUserHeight, if non-zero, is an application-specified override // of mDefaultHeight. This is lower priority than the height set // by native_window_set_buffers_dimensions. uint32_t mUserHeight; // mTransformHint is the transform probably applied to buffers of this // window. this is only a hint, actual transform may differ. uint32_t mTransformHint; // mProducerControlledByApp whether this buffer producer is controlled // by the application bool mProducerControlledByApp; // mSwapIntervalZero set if we should drop buffers at queue() time to // achieve an asynchronous swap interval bool mSwapIntervalZero; // mConsumerRunningBehind whether the consumer is running more than // one buffer behind the producer. mutable bool mConsumerRunningBehind; // mMutex is the mutex used to prevent concurrent access to the member // variables of Surface objects. It must be locked whenever the // member variables are accessed. mutable Mutex mMutex; // must be used from the lock/unlock thread sp<GraphicBuffer> mLockedBuffer; sp<GraphicBuffer> mPostedBuffer; bool mConnectedToCpu; // When a CPU producer is attached, this reflects the region that the // producer wished to update as well as whether the Surface was able to copy // the previous buffer back to allow a partial update. // // When a non-CPU producer is attached, this reflects the surface damage // (the change since the previous frame) passed in by the producer. Region mDirtyRegion; // mBufferAge tracks the age of the contents of the most recently dequeued // buffer as the number of frames that have elapsed since it was last queued uint64_t mBufferAge; // Stores the current generation number. See setGenerationNumber and // IGraphicBufferProducer::setGenerationNumber for more information. uint32_t mGenerationNumber; // Caches the values that have been passed to the producer. bool mSharedBufferMode; bool mAutoRefresh; // If in shared buffer mode and auto refresh is enabled, store the shared // buffer slot and return it for all calls to queue/dequeue without going // over Binder. int mSharedBufferSlot; // This is true if the shared buffer has already been queued/canceled. It's // used to prevent a mismatch between the number of queue/dequeue calls. bool mSharedBufferHasBeenQueued; // These are used to satisfy the NATIVE_WINDOW_LAST_*_DURATION queries nsecs_t mLastDequeueDuration = 0; nsecs_t mLastQueueDuration = 0; // Stores the time right before we call IGBP::dequeueBuffer nsecs_t mLastDequeueStartTime = 0; Condition mQueueBufferCondition; uint64_t mNextFrameNumber = 1; uint64_t mLastFrameNumber = 0; // Mutable because ANativeWindow::query needs this class const. mutable bool mQueriedSupportedTimestamps; mutable bool mFrameTimestampsSupportsPresent; // A cached copy of the FrameEventHistory maintained by the consumer. bool mEnableFrameTimestamps = false; std::unique_ptr<ProducerFrameEventHistory> mFrameEventHistory; bool mReportRemovedBuffers = false; std::vector<sp<GraphicBuffer>> mRemovedBuffers; }; } // namespace android #endif // ANDROID_GUI_SURFACE_H