/* * 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_CONSUMER_H #define ANDROID_GUI_CONSUMER_H #include #include #include #include #include #include #include #include #include namespace android { // ---------------------------------------------------------------------------- class String8; /* * GLConsumer consumes buffers of graphics data from a BufferQueue, * and makes them available to OpenGL as a texture. * * A typical usage pattern is to set up the GLConsumer with the * desired options, and call updateTexImage() when a new frame is desired. * If a new frame is available, the texture will be updated. If not, * the previous contents are retained. * * By default, the texture is attached to the GL_TEXTURE_EXTERNAL_OES * texture target, in the EGL context of the first thread that calls * updateTexImage(). * * This class was previously called SurfaceTexture. */ class GLConsumer : public ConsumerBase { public: enum { TEXTURE_EXTERNAL = 0x8D65 }; // GL_TEXTURE_EXTERNAL_OES typedef ConsumerBase::FrameAvailableListener FrameAvailableListener; // GLConsumer constructs a new GLConsumer object. If the constructor with // the tex parameter is used, tex indicates the name of the OpenGL ES // texture to which images are to be streamed. texTarget specifies the // OpenGL ES texture target to which the texture will be bound in // updateTexImage. useFenceSync specifies whether fences should be used to // synchronize access to buffers if that behavior is enabled at // compile-time. // // A GLConsumer may be detached from one OpenGL ES context and then // attached to a different context using the detachFromContext and // attachToContext methods, respectively. The intention of these methods is // purely to allow a GLConsumer to be transferred from one consumer // context to another. If such a transfer is not needed there is no // requirement that either of these methods be called. // // If the constructor with the tex parameter is used, the GLConsumer is // created in a state where it is considered attached to an OpenGL ES // context for the purposes of the attachToContext and detachFromContext // methods. However, despite being considered "attached" to a context, the // specific OpenGL ES context doesn't get latched until the first call to // updateTexImage. After that point, all calls to updateTexImage must be // made with the same OpenGL ES context current. // // If the constructor without the tex parameter is used, the GLConsumer is // created in a detached state, and attachToContext must be called before // calls to updateTexImage. GLConsumer(const sp& bq, uint32_t tex, uint32_t texureTarget, bool useFenceSync, bool isControlledByApp); GLConsumer(const sp& bq, uint32_t texureTarget, bool useFenceSync, bool isControlledByApp); // 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 the OpenGL ES context to which the // target texture belongs is bound to the calling thread. // // This calls doGLFenceWait to ensure proper synchronization. status_t updateTexImage(); // releaseTexImage releases the texture acquired in updateTexImage(). // This is intended to be used in single buffer mode. // // This call may only be made while the OpenGL ES context to which the // target texture belongs is bound to the calling thread. status_t releaseTexImage(); // 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); // setDefaultMaxBufferCount sets the default limit on the maximum number // of buffers that will be allocated at one time. The image producer may // override the limit. status_t setDefaultMaxBufferCount(int bufferCount); // getTransformMatrix retrieves the 4x4 texture coordinate transform matrix // associated with the texture image set by the most recent call to // updateTexImage. // // This transform matrix maps 2D homogeneous texture coordinates of the form // (s, t, 0, 1) with s and t in the inclusive range [0, 1] to the texture // coordinate that should be used to sample that location from the texture. // Sampling the texture outside of the range of this transform is undefined. // // This transform is necessary to compensate for transforms that the stream // content producer may implicitly apply to the content. By forcing users of // a GLConsumer to apply this transform we avoid performing an extra // copy of the data that would be needed to hide the transform from the // user. // // The matrix is stored in column-major order so that it may be passed // directly to OpenGL ES via the glLoadMatrixf or glUniformMatrix4fv // functions. 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(); // 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(); // setDefaultBufferSize is used to set the size of buffers returned by // requestBuffers when a with and height of zero is requested. // A call to setDefaultBufferSize() may trigger requestBuffers() to // be called from the client. // The width and height parameters must be no greater than the minimum of // GL_MAX_VIEWPORT_DIMS and GL_MAX_TEXTURE_SIZE (see: glGetIntegerv). // An error due to invalid dimensions might not be reported until // updateTexImage() is called. 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. sp getCurrentBuffer() const; // getCurrentTextureTarget returns the texture target of the current // texture as returned by updateTexImage(). uint32_t getCurrentTextureTarget() 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 getCurrentFence() const; // doGLFenceWait inserts a wait command into the OpenGL ES command stream // to ensure that it is safe for future OpenGL ES commands to access the // current texture buffer. status_t doGLFenceWait() const; // set the name of the GLConsumer that will be used to identify it in // log messages. void setName(const String8& name); // These functions call the corresponding BufferQueue implementation // so the refactoring can proceed smoothly status_t setDefaultBufferFormat(PixelFormat defaultFormat); status_t setDefaultBufferDataSpace(android_dataspace defaultDataSpace); status_t setConsumerUsageBits(uint32_t usage); status_t setTransformHint(uint32_t hint); // detachFromContext detaches the GLConsumer from the calling thread's // current OpenGL ES context. This context must be the same as the context // that was current for previous calls to updateTexImage. // // Detaching a GLConsumer from an OpenGL ES context will result in the // deletion of the OpenGL ES texture object into which the images were being // streamed. After a GLConsumer has been detached from the OpenGL ES // context calls to updateTexImage will fail returning INVALID_OPERATION // until the GLConsumer is attached to a new OpenGL ES context using the // attachToContext method. status_t detachFromContext(); // attachToContext attaches a GLConsumer that is currently in the // 'detached' state to the current OpenGL ES context. A GLConsumer is // in the 'detached' state iff detachFromContext has successfully been // called and no calls to attachToContext have succeeded since the last // detachFromContext call. Calls to attachToContext made on a // GLConsumer that is not in the 'detached' state will result in an // INVALID_OPERATION error. // // The tex argument specifies the OpenGL ES texture object name in the // new context into which the image contents will be streamed. A successful // call to attachToContext will result in this texture object being bound to // the texture target and populated with the image contents that were // current at the time of the last call to detachFromContext. status_t attachToContext(uint32_t tex); protected: // abandonLocked overrides the ConsumerBase method to clear // mCurrentTextureImage in addition to the ConsumerBase behavior. virtual void abandonLocked(); // dumpLocked overrides the ConsumerBase method to dump GLConsumer- // specific info in addition to the ConsumerBase behavior. virtual void dumpLocked(String8& result, const char* prefix) const; // acquireBufferLocked overrides the ConsumerBase method to update the // mEglSlots array in addition to the ConsumerBase behavior. virtual status_t acquireBufferLocked(BufferItem *item, nsecs_t presentWhen, uint64_t maxFrameNumber = 0) override; // releaseBufferLocked overrides the ConsumerBase method to update the // mEglSlots array in addition to the ConsumerBase. virtual status_t releaseBufferLocked(int slot, const sp graphicBuffer, EGLDisplay display, EGLSyncKHR eglFence); status_t releaseBufferLocked(int slot, const sp graphicBuffer, EGLSyncKHR eglFence) { return releaseBufferLocked(slot, graphicBuffer, mEglDisplay, eglFence); } static bool isExternalFormat(PixelFormat format); // 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. status_t updateAndReleaseLocked(const BufferItem& item); // Binds mTexName and the current buffer to mTexTarget. Uses // mCurrentTexture if it's set, mCurrentTextureImage if not. If the // bind succeeds, this calls doGLFenceWait. status_t bindTextureImageLocked(); // Gets the current EGLDisplay and EGLContext values, and compares them // to mEglDisplay and mEglContext. If the fields have been previously // set, the values must match; if not, the fields are set to the current // values. // The contextCheck argument is used to ensure that a GL context is // properly set; when set to false, the check is not performed. status_t checkAndUpdateEglStateLocked(bool contextCheck = false); private: // EglImage is a utility class for tracking and creating EGLImageKHRs. There // is primarily just one image per slot, but there is also special cases: // - For releaseTexImage, we use a debug image (mReleasedTexImage) // - After freeBuffer, we must still keep the current image/buffer // Reference counting EGLImages lets us handle all these cases easily while // also only creating new EGLImages from buffers when required. class EglImage : public LightRefBase { public: EglImage(sp graphicBuffer); // createIfNeeded creates an EGLImage if required (we haven't created // one yet, or the EGLDisplay or crop-rect has changed). status_t createIfNeeded(EGLDisplay display, const Rect& cropRect, bool forceCreate = false); // This calls glEGLImageTargetTexture2DOES to bind the image to the // texture in the specified texture target. void bindToTextureTarget(uint32_t texTarget); const sp& graphicBuffer() { return mGraphicBuffer; } const native_handle* graphicBufferHandle() { return mGraphicBuffer == NULL ? NULL : mGraphicBuffer->handle; } private: // Only allow instantiation using ref counting. friend class LightRefBase; virtual ~EglImage(); // createImage creates a new EGLImage from a GraphicBuffer. EGLImageKHR createImage(EGLDisplay dpy, const sp& graphicBuffer, const Rect& crop); // Disallow copying EglImage(const EglImage& rhs); void operator = (const EglImage& rhs); // mGraphicBuffer is the buffer that was used to create this image. sp mGraphicBuffer; // mEglImage is the EGLImage created from mGraphicBuffer. EGLImageKHR mEglImage; // mEGLDisplay is the EGLDisplay that was used to create mEglImage. EGLDisplay mEglDisplay; // mCropRect is the crop rectangle passed to EGL when mEglImage // was created. Rect mCropRect; }; // freeBufferLocked frees up the given buffer slot. If the slot has been // initialized this will release the reference to the GraphicBuffer in that // slot and destroy the EGLImage in that slot. Otherwise it has no effect. // // This method must be called with mMutex locked. virtual void freeBufferLocked(int slotIndex); // 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 NULL. void computeCurrentTransformMatrixLocked(); // doGLFenceWaitLocked inserts a wait command into the OpenGL ES command // stream to ensure that it is safe for future OpenGL ES commands to // access the current texture buffer. status_t doGLFenceWaitLocked() const; // syncForReleaseLocked performs the synchronization needed to release the // current slot from an OpenGL ES context. If needed it will set the // current slot's fence to guard against a producer accessing the buffer // before the outstanding accesses have completed. status_t syncForReleaseLocked(EGLDisplay dpy); // returns a graphic buffer used when the texture image has been released static sp getDebugTexImageBuffer(); // The default consumer usage flags that GLConsumer always sets on its // BufferQueue instance; these will be OR:d with any additional flags passed // from the GLConsumer user. In particular, GLConsumer will always // consume buffers as hardware textures. static const uint32_t DEFAULT_USAGE_FLAGS = GraphicBuffer::USAGE_HW_TEXTURE; // mCurrentTextureImage is the EglImage/buffer of 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. sp mCurrentTextureImage; // 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 mCurrentFence; // 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; // mCurrentFrameNumber is the frame counter for the current texture. // It gets set each time updateTexImage is called. uint64_t mCurrentFrameNumber; 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; // mTexName is the name of the OpenGL texture to which streamed images will // be bound when updateTexImage is called. It is set at construction time // and can be changed with a call to attachToContext. uint32_t mTexName; // mUseFenceSync indicates whether creation of the EGL_KHR_fence_sync // extension should be used to prevent buffers from being dequeued before // it's safe for them to be written. It gets set at construction time and // never changes. const bool mUseFenceSync; // mTexTarget is the GL texture target with which the GL texture object is // associated. It is set in the constructor and never changed. It is // almost always GL_TEXTURE_EXTERNAL_OES except for one use case in Android // Browser. In that case it is set to GL_TEXTURE_2D to allow // glCopyTexSubImage to read from the texture. This is a hack to work // around a GL driver limitation on the number of FBO attachments, which the // browser's tile cache exceeds. const uint32_t mTexTarget; // EGLSlot contains the information and object references that // GLConsumer maintains about a BufferQueue buffer slot. struct EglSlot { EglSlot() : mEglFence(EGL_NO_SYNC_KHR) {} // mEglImage is the EGLImage created from mGraphicBuffer. sp mEglImage; // mFence is the EGL sync object that must signal before the buffer // associated with this buffer slot may be dequeued. It is initialized // to EGL_NO_SYNC_KHR when the buffer is created and (optionally, based // on a compile-time option) set to a new sync object in updateTexImage. EGLSyncKHR mEglFence; }; // mEglDisplay is the EGLDisplay with which this GLConsumer is currently // associated. It is intialized to EGL_NO_DISPLAY and gets set to the // current display when updateTexImage is called for the first time and when // attachToContext is called. EGLDisplay mEglDisplay; // mEglContext is the OpenGL ES context with which this GLConsumer is // currently associated. It is initialized to EGL_NO_CONTEXT and gets set // to the current GL context when updateTexImage is called for the first // time and when attachToContext is called. EGLContext mEglContext; // mEGLSlots stores the buffers that have been allocated by the BufferQueue // for each buffer slot. It is initialized to null pointers, and gets // filled in with the result of BufferQueue::acquire 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. EglSlot mEglSlots[BufferQueue::NUM_BUFFER_SLOTS]; // mCurrentTexture is the buffer slot index of the buffer that is currently // bound to the OpenGL 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; // mAttached indicates whether the ConsumerBase is currently attached to // an OpenGL ES context. For legacy reasons, this is initialized to true, // indicating that the ConsumerBase is considered to be attached to // whatever context is current at the time of the first updateTexImage call. // It is set to false by detachFromContext, and then set to true again by // attachToContext. bool mAttached; // protects static initialization static Mutex sStaticInitLock; // mReleasedTexImageBuffer is a dummy buffer used when in single buffer // mode and releaseTexImage() has been called static sp sReleasedTexImageBuffer; sp mReleasedTexImage; }; // ---------------------------------------------------------------------------- }; // namespace android #endif // ANDROID_GUI_CONSUMER_H