include/gui/IGraphicBufferConsumer.h - third_party/android/platform/frameworks/native - Git at Google

 /*
  * Copyright (C) 2013 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_IGRAPHICBUFFERCONSUMER_H
 #define ANDROID_GUI_IGRAPHICBUFFERCONSUMER_H

 #include <stdint.h>
 #include <sys/types.h>

 #include <utils/Errors.h>
 #include <utils/RefBase.h>
 #include <utils/Timers.h>

 #include <binder/IInterface.h>
 #include <ui/Rect.h>

 #include <EGL/egl.h>
 #include <EGL/eglext.h>

 namespace android {
 // ----------------------------------------------------------------------------

 class Fence;
 class GraphicBuffer;
 class IConsumerListener;
 class NativeHandle;

 class IGraphicBufferConsumer : public IInterface {

 public:

     // public facing structure for BufferSlot
     class BufferItem : public Flattenable<BufferItem> {
         friend class Flattenable<BufferItem>;
         size_t getPodSize() const;
         size_t getFlattenedSize() const;
         size_t getFdCount() const;
         status_t flatten(void*& buffer, size_t& size, int*& fds, size_t& count) const;
         status_t unflatten(void const*& buffer, size_t& size, int const*& fds, size_t& count);

     public:
         // The default value of mBuf, used to indicate this doesn't correspond to a slot.
         enum { INVALID_BUFFER_SLOT = -1 };
         BufferItem();

         // mGraphicBuffer points to the buffer allocated for this slot, or is NULL
         // if the buffer in this slot has been acquired in the past (see
         // BufferSlot.mAcquireCalled).
         sp<GraphicBuffer> mGraphicBuffer;

         // mFence is a fence that will signal when the buffer is idle.
         sp<Fence> mFence;

         // mCrop is the current crop rectangle for this buffer slot.
         Rect mCrop;

         // mTransform is the current transform flags for this buffer slot.
         // refer to NATIVE_WINDOW_TRANSFORM_* in <window.h>
         uint32_t mTransform;

         // mScalingMode is the current scaling mode for this buffer slot.
         // refer to NATIVE_WINDOW_SCALING_* in <window.h>
         uint32_t mScalingMode;

         // mTimestamp is the current timestamp for this buffer slot. This gets
         // to set by queueBuffer each time this slot is queued. This value
         // is guaranteed to be monotonically increasing for each newly
         // acquired buffer.
         int64_t mTimestamp;

         // mIsAutoTimestamp indicates whether mTimestamp was generated
         // automatically when the buffer was queued.
         bool mIsAutoTimestamp;

         // mFrameNumber is the number of the queued frame for this slot.
         uint64_t mFrameNumber;

         // mBuf is the slot index of this buffer (default INVALID_BUFFER_SLOT).
         int mBuf;

         // mIsDroppable whether this buffer was queued with the
         // property that it can be replaced by a new buffer for the purpose of
         // making sure dequeueBuffer() won't block.
         // i.e.: was the BufferQueue in "mDequeueBufferCannotBlock" when this buffer
         // was queued.
         bool mIsDroppable;

         // Indicates whether this buffer has been seen by a consumer yet
         bool mAcquireCalled;

         // Indicates this buffer must be transformed by the inverse transform of the screen
         // it is displayed onto. This is applied after mTransform.
         bool mTransformToDisplayInverse;
     };

     enum {
         // Returned by releaseBuffer, after which the consumer must
         // free any references to the just-released buffer that it might have.
         STALE_BUFFER_SLOT = 1,
         // Returned by dequeueBuffer if there are no pending buffers available.
         NO_BUFFER_AVAILABLE,
         // Returned by dequeueBuffer if it's too early for the buffer to be acquired.
         PRESENT_LATER,
     };

     // acquireBuffer attempts to acquire ownership of the next pending buffer in
     // the BufferQueue.  If no buffer is pending then it returns
     // NO_BUFFER_AVAILABLE.  If a buffer is successfully acquired, the
     // information about the buffer is returned in BufferItem.
     //
     // If the buffer returned had previously been
     // acquired then the BufferItem::mGraphicBuffer field of buffer is set to
     // NULL and it is assumed that the consumer still holds a reference to the
     // buffer.
     //
     // If presentWhen is non-zero, it indicates the time when the buffer will
     // be displayed on screen.  If the buffer's timestamp is farther in the
     // future, the buffer won't be acquired, and PRESENT_LATER will be
     // returned.  The presentation time is in nanoseconds, and the time base
     // is CLOCK_MONOTONIC.
     //
     // Return of NO_ERROR means the operation completed as normal.
     //
     // Return of a positive value means the operation could not be completed
     //    at this time, but the user should try again later:
     // * NO_BUFFER_AVAILABLE - no buffer is pending (nothing queued by producer)
     // * PRESENT_LATER - the buffer's timestamp is farther in the future
     //
     // Return of a negative value means an error has occurred:
     // * INVALID_OPERATION - too many buffers have been acquired
     virtual status_t acquireBuffer(BufferItem* buffer, nsecs_t presentWhen) = 0;

     // detachBuffer attempts to remove all ownership of the buffer in the given
     // slot from the buffer queue. If this call succeeds, the slot will be
     // freed, and there will be no way to obtain the buffer from this interface.
     // The freed slot will remain unallocated until either it is selected to
     // hold a freshly allocated buffer in dequeueBuffer or a buffer is attached
     // to the slot. The buffer must have already been acquired.
     //
     // Return of a value other than NO_ERROR means an error has occurred:
     // * BAD_VALUE - the given slot number is invalid, either because it is
     //               out of the range [0, NUM_BUFFER_SLOTS) or because the slot
     //               it refers to is not currently acquired.
     virtual status_t detachBuffer(int slot) = 0;

     // attachBuffer attempts to transfer ownership of a buffer to the buffer
     // queue. If this call succeeds, it will be as if this buffer was acquired
     // from the returned slot number. As such, this call will fail if attaching
     // this buffer would cause too many buffers to be simultaneously acquired.
     //
     // If the buffer is successfully attached, its frameNumber is initialized
     // to 0. This must be passed into the releaseBuffer call or else the buffer
     // will be deallocated as stale.
     //
     // Return of a value other than NO_ERROR means an error has occurred:
     // * BAD_VALUE - outSlot or buffer were NULL
     // * INVALID_OPERATION - cannot attach the buffer because it would cause too
     //                       many buffers to be acquired.
     // * NO_MEMORY - no free slots available
     virtual status_t attachBuffer(int *outSlot,
             const sp<GraphicBuffer>& buffer) = 0;

     // releaseBuffer releases a buffer slot from the consumer back to the
     // BufferQueue.  This may be done while the buffer's contents are still
     // being accessed.  The fence will signal when the buffer is no longer
     // in use. frameNumber is used to indentify the exact buffer returned.
     //
     // If releaseBuffer returns STALE_BUFFER_SLOT, then the consumer must free
     // any references to the just-released buffer that it might have, as if it
     // had received a onBuffersReleased() call with a mask set for the released
     // buffer.
     //
     // Note that the dependencies on EGL will be removed once we switch to using
     // the Android HW Sync HAL.
     //
     // Return of NO_ERROR means the operation completed as normal.
     //
     // Return of a positive value means the operation could not be completed
     //    at this time, but the user should try again later:
     // * STALE_BUFFER_SLOT - see above (second paragraph)
     //
     // Return of a negative value means an error has occurred:
     // * BAD_VALUE - one of the following could've happened:
     //               * the buffer slot was invalid
     //               * the fence was NULL
     //               * the buffer slot specified is not in the acquired state
     virtual status_t releaseBuffer(int buf, uint64_t frameNumber,
             EGLDisplay display, EGLSyncKHR fence,
             const sp<Fence>& releaseFence) = 0;

     // consumerConnect connects a consumer to the BufferQueue.  Only one
     // consumer may be connected, and when that consumer disconnects the
     // BufferQueue is placed into the "abandoned" state, causing most
     // interactions with the BufferQueue by the producer to fail.
     // controlledByApp indicates whether the consumer is controlled by
     // the application.
     //
     // consumer may not be NULL.
     //
     // Return of a value other than NO_ERROR means an error has occurred:
     // * NO_INIT - the buffer queue has been abandoned
     // * BAD_VALUE - a NULL consumer was provided
     virtual status_t consumerConnect(const sp<IConsumerListener>& consumer, bool controlledByApp) = 0;

     // consumerDisconnect disconnects a consumer from the BufferQueue. All
     // buffers will be freed and the BufferQueue is placed in the "abandoned"
     // state, causing most interactions with the BufferQueue by the producer to
     // fail.
     //
     // Return of a value other than NO_ERROR means an error has occurred:
     // * BAD_VALUE - no consumer is currently connected
     virtual status_t consumerDisconnect() = 0;

     // getReleasedBuffers sets the value pointed to by slotMask to a bit set.
     // Each bit index with a 1 corresponds to a released buffer slot with that
     // index value.  In particular, a released buffer is one that has
     // been released by the BufferQueue but have not yet been released by the consumer.
     //
     // This should be called from the onBuffersReleased() callback.
     //
     // Return of a value other than NO_ERROR means an error has occurred:
     // * NO_INIT - the buffer queue has been abandoned.
     virtual status_t getReleasedBuffers(uint64_t* slotMask) = 0;

     // setDefaultBufferSize is used to set the size of buffers returned by
     // dequeueBuffer when a width and height of zero is requested.  Default
     // is 1x1.
     //
     // Return of a value other than NO_ERROR means an error has occurred:
     // * BAD_VALUE - either w or h was zero
     virtual status_t setDefaultBufferSize(uint32_t w, uint32_t h) = 0;

     // setDefaultMaxBufferCount sets the default value for the maximum buffer
     // count (the initial default is 2). If the producer has requested a
     // buffer count using setBufferCount, the default buffer count will only
     // take effect if the producer sets the count back to zero.
     //
     // The count must be between 2 and NUM_BUFFER_SLOTS, inclusive.
     //
     // Return of a value other than NO_ERROR means an error has occurred:
     // * BAD_VALUE - bufferCount was out of range (see above).
     virtual status_t setDefaultMaxBufferCount(int bufferCount) = 0;

     // disableAsyncBuffer disables the extra buffer used in async mode
     // (when both producer and consumer have set their "isControlledByApp"
     // flag) and has dequeueBuffer() return WOULD_BLOCK instead.
     //
     // This can only be called before consumerConnect().
     //
     // Return of a value other than NO_ERROR means an error has occurred:
     // * INVALID_OPERATION - attempting to call this after consumerConnect.
     virtual status_t disableAsyncBuffer() = 0;

     // setMaxAcquiredBufferCount sets the maximum number of buffers that can
     // be acquired by the consumer at one time (default 1).  This call will
     // fail if a producer is connected to the BufferQueue.
     //
     // maxAcquiredBuffers must be (inclusive) between 1 and MAX_MAX_ACQUIRED_BUFFERS.
     //
     // Return of a value other than NO_ERROR means an error has occurred:
     // * BAD_VALUE - maxAcquiredBuffers was out of range (see above).
     // * INVALID_OPERATION - attempting to call this after a producer connected.
     virtual status_t setMaxAcquiredBufferCount(int maxAcquiredBuffers) = 0;

     // setConsumerName sets the name used in logging
     virtual void setConsumerName(const String8& name) = 0;

     // setDefaultBufferFormat allows the BufferQueue to create
     // GraphicBuffers of a defaultFormat if no format is specified
     // in dequeueBuffer.  Formats are enumerated in graphics.h; the
     // initial default is HAL_PIXEL_FORMAT_RGBA_8888.
     //
     // Return of a value other than NO_ERROR means an unknown error has occurred.
     virtual status_t setDefaultBufferFormat(uint32_t defaultFormat) = 0;

     // setConsumerUsageBits will turn on additional usage bits for dequeueBuffer.
     // These are merged with the bits passed to dequeueBuffer.  The values are
     // enumerated in gralloc.h, e.g. GRALLOC_USAGE_HW_RENDER; the default is 0.
     //
     // Return of a value other than NO_ERROR means an unknown error has occurred.
     virtual status_t setConsumerUsageBits(uint32_t usage) = 0;

     // setTransformHint bakes in rotation to buffers so overlays can be used.
     // The values are enumerated in window.h, e.g.
     // NATIVE_WINDOW_TRANSFORM_ROT_90.  The default is 0 (no transform).
     //
     // Return of a value other than NO_ERROR means an unknown error has occurred.
     virtual status_t setTransformHint(uint32_t hint) = 0;

     // Retrieve the sideband buffer stream, if any.
     virtual sp<NativeHandle> getSidebandStream() const = 0;

     // dump state into a string
     virtual void dump(String8& result, const char* prefix) const = 0;

 public:
     DECLARE_META_INTERFACE(GraphicBufferConsumer);
 };

 // ----------------------------------------------------------------------------

 class BnGraphicBufferConsumer : public BnInterface<IGraphicBufferConsumer>
 {
 public:
     virtual status_t    onTransact( uint32_t code,
                                     const Parcel& data,
                                     Parcel* reply,
                                     uint32_t flags = 0);
 };

 // ----------------------------------------------------------------------------
 }; // namespace android

 #endif // ANDROID_GUI_IGRAPHICBUFFERCONSUMER_H
	/*
	* Copyright (C) 2013 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_IGRAPHICBUFFERCONSUMER_H
	#define ANDROID_GUI_IGRAPHICBUFFERCONSUMER_H

	#include <stdint.h>
	#include <sys/types.h>

	#include <utils/Errors.h>
	#include <utils/RefBase.h>
	#include <utils/Timers.h>

	#include <binder/IInterface.h>
	#include <ui/Rect.h>

	#include <EGL/egl.h>
	#include <EGL/eglext.h>

	namespace android {
	// ----------------------------------------------------------------------------

	class Fence;
	class GraphicBuffer;
	class IConsumerListener;
	class NativeHandle;

	class IGraphicBufferConsumer : public IInterface {

	public:

	// public facing structure for BufferSlot
	class BufferItem : public Flattenable<BufferItem> {
	friend class Flattenable<BufferItem>;
	size_t getPodSize() const;
	size_t getFlattenedSize() const;
	size_t getFdCount() const;
	status_t flatten(void& buffer, size_t& size, int& fds, size_t& count) const;
	status_t unflatten(void const& buffer, size_t& size, int const& fds, size_t& count);

	public:
	// The default value of mBuf, used to indicate this doesn't correspond to a slot.
	enum { INVALID_BUFFER_SLOT = -1 };
	BufferItem();

	// mGraphicBuffer points to the buffer allocated for this slot, or is NULL
	// if the buffer in this slot has been acquired in the past (see
	// BufferSlot.mAcquireCalled).
	sp<GraphicBuffer> mGraphicBuffer;

	// mFence is a fence that will signal when the buffer is idle.
	sp<Fence> mFence;

	// mCrop is the current crop rectangle for this buffer slot.
	Rect mCrop;

	// mTransform is the current transform flags for this buffer slot.
	// refer to NATIVE_WINDOW_TRANSFORM_* in <window.h>
	uint32_t mTransform;

	// mScalingMode is the current scaling mode for this buffer slot.
	// refer to NATIVE_WINDOW_SCALING_* in <window.h>
	uint32_t mScalingMode;

	// mTimestamp is the current timestamp for this buffer slot. This gets
	// to set by queueBuffer each time this slot is queued. This value
	// is guaranteed to be monotonically increasing for each newly
	// acquired buffer.
	int64_t mTimestamp;

	// mIsAutoTimestamp indicates whether mTimestamp was generated
	// automatically when the buffer was queued.
	bool mIsAutoTimestamp;

	// mFrameNumber is the number of the queued frame for this slot.
	uint64_t mFrameNumber;

	// mBuf is the slot index of this buffer (default INVALID_BUFFER_SLOT).
	int mBuf;

	// mIsDroppable whether this buffer was queued with the
	// property that it can be replaced by a new buffer for the purpose of
	// making sure dequeueBuffer() won't block.
	// i.e.: was the BufferQueue in "mDequeueBufferCannotBlock" when this buffer
	// was queued.
	bool mIsDroppable;

	// Indicates whether this buffer has been seen by a consumer yet
	bool mAcquireCalled;

	// Indicates this buffer must be transformed by the inverse transform of the screen
	// it is displayed onto. This is applied after mTransform.
	bool mTransformToDisplayInverse;
	};

	enum {
	// Returned by releaseBuffer, after which the consumer must
	// free any references to the just-released buffer that it might have.
	STALE_BUFFER_SLOT = 1,
	// Returned by dequeueBuffer if there are no pending buffers available.
	NO_BUFFER_AVAILABLE,
	// Returned by dequeueBuffer if it's too early for the buffer to be acquired.
	PRESENT_LATER,
	};

	// acquireBuffer attempts to acquire ownership of the next pending buffer in
	// the BufferQueue. If no buffer is pending then it returns
	// NO_BUFFER_AVAILABLE. If a buffer is successfully acquired, the
	// information about the buffer is returned in BufferItem.
	//
	// If the buffer returned had previously been
	// acquired then the BufferItem::mGraphicBuffer field of buffer is set to
	// NULL and it is assumed that the consumer still holds a reference to the
	// buffer.
	//
	// If presentWhen is non-zero, it indicates the time when the buffer will
	// be displayed on screen. If the buffer's timestamp is farther in the
	// future, the buffer won't be acquired, and PRESENT_LATER will be
	// returned. The presentation time is in nanoseconds, and the time base
	// is CLOCK_MONOTONIC.
	//
	// Return of NO_ERROR means the operation completed as normal.
	//
	// Return of a positive value means the operation could not be completed
	// at this time, but the user should try again later:
	// * NO_BUFFER_AVAILABLE - no buffer is pending (nothing queued by producer)
	// * PRESENT_LATER - the buffer's timestamp is farther in the future
	//
	// Return of a negative value means an error has occurred:
	// * INVALID_OPERATION - too many buffers have been acquired
	virtual status_t acquireBuffer(BufferItem* buffer, nsecs_t presentWhen) = 0;

	// detachBuffer attempts to remove all ownership of the buffer in the given
	// slot from the buffer queue. If this call succeeds, the slot will be
	// freed, and there will be no way to obtain the buffer from this interface.
	// The freed slot will remain unallocated until either it is selected to
	// hold a freshly allocated buffer in dequeueBuffer or a buffer is attached
	// to the slot. The buffer must have already been acquired.
	//
	// Return of a value other than NO_ERROR means an error has occurred:
	// * BAD_VALUE - the given slot number is invalid, either because it is
	// out of the range [0, NUM_BUFFER_SLOTS) or because the slot
	// it refers to is not currently acquired.
	virtual status_t detachBuffer(int slot) = 0;

	// attachBuffer attempts to transfer ownership of a buffer to the buffer
	// queue. If this call succeeds, it will be as if this buffer was acquired
	// from the returned slot number. As such, this call will fail if attaching
	// this buffer would cause too many buffers to be simultaneously acquired.
	//
	// If the buffer is successfully attached, its frameNumber is initialized
	// to 0. This must be passed into the releaseBuffer call or else the buffer
	// will be deallocated as stale.
	//
	// Return of a value other than NO_ERROR means an error has occurred:
	// * BAD_VALUE - outSlot or buffer were NULL
	// * INVALID_OPERATION - cannot attach the buffer because it would cause too
	// many buffers to be acquired.
	// * NO_MEMORY - no free slots available
	virtual status_t attachBuffer(int *outSlot,
	const sp<GraphicBuffer>& buffer) = 0;

	// releaseBuffer releases a buffer slot from the consumer back to the
	// BufferQueue. This may be done while the buffer's contents are still
	// being accessed. The fence will signal when the buffer is no longer
	// in use. frameNumber is used to indentify the exact buffer returned.
	//
	// If releaseBuffer returns STALE_BUFFER_SLOT, then the consumer must free
	// any references to the just-released buffer that it might have, as if it
	// had received a onBuffersReleased() call with a mask set for the released
	// buffer.
	//
	// Note that the dependencies on EGL will be removed once we switch to using
	// the Android HW Sync HAL.
	//
	// Return of NO_ERROR means the operation completed as normal.
	//
	// Return of a positive value means the operation could not be completed
	// at this time, but the user should try again later:
	// * STALE_BUFFER_SLOT - see above (second paragraph)
	//
	// Return of a negative value means an error has occurred:
	// * BAD_VALUE - one of the following could've happened:
	// * the buffer slot was invalid
	// * the fence was NULL
	// * the buffer slot specified is not in the acquired state
	virtual status_t releaseBuffer(int buf, uint64_t frameNumber,
	EGLDisplay display, EGLSyncKHR fence,
	const sp<Fence>& releaseFence) = 0;

	// consumerConnect connects a consumer to the BufferQueue. Only one
	// consumer may be connected, and when that consumer disconnects the
	// BufferQueue is placed into the "abandoned" state, causing most
	// interactions with the BufferQueue by the producer to fail.
	// controlledByApp indicates whether the consumer is controlled by
	// the application.
	//
	// consumer may not be NULL.
	//
	// Return of a value other than NO_ERROR means an error has occurred:
	// * NO_INIT - the buffer queue has been abandoned
	// * BAD_VALUE - a NULL consumer was provided
	virtual status_t consumerConnect(const sp<IConsumerListener>& consumer, bool controlledByApp) = 0;

	// consumerDisconnect disconnects a consumer from the BufferQueue. All
	// buffers will be freed and the BufferQueue is placed in the "abandoned"
	// state, causing most interactions with the BufferQueue by the producer to
	// fail.
	//
	// Return of a value other than NO_ERROR means an error has occurred:
	// * BAD_VALUE - no consumer is currently connected
	virtual status_t consumerDisconnect() = 0;

	// getReleasedBuffers sets the value pointed to by slotMask to a bit set.
	// Each bit index with a 1 corresponds to a released buffer slot with that
	// index value. In particular, a released buffer is one that has
	// been released by the BufferQueue but have not yet been released by the consumer.
	//
	// This should be called from the onBuffersReleased() callback.
	//
	// Return of a value other than NO_ERROR means an error has occurred:
	// * NO_INIT - the buffer queue has been abandoned.
	virtual status_t getReleasedBuffers(uint64_t* slotMask) = 0;

	// setDefaultBufferSize is used to set the size of buffers returned by
	// dequeueBuffer when a width and height of zero is requested. Default
	// is 1x1.
	//
	// Return of a value other than NO_ERROR means an error has occurred:
	// * BAD_VALUE - either w or h was zero
	virtual status_t setDefaultBufferSize(uint32_t w, uint32_t h) = 0;

	// setDefaultMaxBufferCount sets the default value for the maximum buffer
	// count (the initial default is 2). If the producer has requested a
	// buffer count using setBufferCount, the default buffer count will only
	// take effect if the producer sets the count back to zero.
	//
	// The count must be between 2 and NUM_BUFFER_SLOTS, inclusive.
	//
	// Return of a value other than NO_ERROR means an error has occurred:
	// * BAD_VALUE - bufferCount was out of range (see above).
	virtual status_t setDefaultMaxBufferCount(int bufferCount) = 0;

	// disableAsyncBuffer disables the extra buffer used in async mode
	// (when both producer and consumer have set their "isControlledByApp"
	// flag) and has dequeueBuffer() return WOULD_BLOCK instead.
	//
	// This can only be called before consumerConnect().
	//
	// Return of a value other than NO_ERROR means an error has occurred:
	// * INVALID_OPERATION - attempting to call this after consumerConnect.
	virtual status_t disableAsyncBuffer() = 0;

	// setMaxAcquiredBufferCount sets the maximum number of buffers that can
	// be acquired by the consumer at one time (default 1). This call will
	// fail if a producer is connected to the BufferQueue.
	//
	// maxAcquiredBuffers must be (inclusive) between 1 and MAX_MAX_ACQUIRED_BUFFERS.
	//
	// Return of a value other than NO_ERROR means an error has occurred:
	// * BAD_VALUE - maxAcquiredBuffers was out of range (see above).
	// * INVALID_OPERATION - attempting to call this after a producer connected.
	virtual status_t setMaxAcquiredBufferCount(int maxAcquiredBuffers) = 0;

	// setConsumerName sets the name used in logging
	virtual void setConsumerName(const String8& name) = 0;

	// setDefaultBufferFormat allows the BufferQueue to create
	// GraphicBuffers of a defaultFormat if no format is specified
	// in dequeueBuffer. Formats are enumerated in graphics.h; the
	// initial default is HAL_PIXEL_FORMAT_RGBA_8888.
	//
	// Return of a value other than NO_ERROR means an unknown error has occurred.
	virtual status_t setDefaultBufferFormat(uint32_t defaultFormat) = 0;

	// setConsumerUsageBits will turn on additional usage bits for dequeueBuffer.
	// These are merged with the bits passed to dequeueBuffer. The values are
	// enumerated in gralloc.h, e.g. GRALLOC_USAGE_HW_RENDER; the default is 0.
	//
	// Return of a value other than NO_ERROR means an unknown error has occurred.
	virtual status_t setConsumerUsageBits(uint32_t usage) = 0;

	// setTransformHint bakes in rotation to buffers so overlays can be used.
	// The values are enumerated in window.h, e.g.
	// NATIVE_WINDOW_TRANSFORM_ROT_90. The default is 0 (no transform).
	//
	// Return of a value other than NO_ERROR means an unknown error has occurred.
	virtual status_t setTransformHint(uint32_t hint) = 0;

	// Retrieve the sideband buffer stream, if any.
	virtual sp<NativeHandle> getSidebandStream() const = 0;

	// dump state into a string
	virtual void dump(String8& result, const char* prefix) const = 0;

	public:
	DECLARE_META_INTERFACE(GraphicBufferConsumer);
	};

	// ----------------------------------------------------------------------------

	class BnGraphicBufferConsumer : public BnInterface<IGraphicBufferConsumer>
	{
	public:
	virtual status_t onTransact( uint32_t code,
	const Parcel& data,
	Parcel* reply,
	uint32_t flags = 0);
	};

	// ----------------------------------------------------------------------------
	}; // namespace android

	#endif // ANDROID_GUI_IGRAPHICBUFFERCONSUMER_H