services/camera/libcameraservice/device1/CameraHardwareInterface.h - third_party/android/platform/frameworks/av - Git at Google

 /*
  * Copyright (C) 2008 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_HARDWARE_CAMERA_HARDWARE_INTERFACE_H
 #define ANDROID_HARDWARE_CAMERA_HARDWARE_INTERFACE_H

 #include <unordered_map>
 #include <binder/IMemory.h>
 #include <binder/MemoryBase.h>
 #include <binder/MemoryHeapBase.h>
 #include <utils/RefBase.h>
 #include <ui/GraphicBuffer.h>
 #include <camera/Camera.h>
 #include <camera/CameraParameters.h>
 #include <system/window.h>
 #include <hardware/camera.h>

 #include <common/CameraProviderManager.h>

 namespace android {

 typedef void (*notify_callback)(int32_t msgType,
                             int32_t ext1,
                             int32_t ext2,
                             void* user);

 typedef void (*data_callback)(int32_t msgType,
                             const sp<IMemory> &dataPtr,
                             camera_frame_metadata_t *metadata,
                             void* user);

 typedef void (*data_callback_timestamp)(nsecs_t timestamp,
                             int32_t msgType,
                             const sp<IMemory> &dataPtr,
                             void *user);

 struct HandleTimestampMessage {
     nsecs_t timestamp;
     const sp<IMemory> dataPtr;
 };

 typedef void (*data_callback_timestamp_batch)(
         int32_t msgType,
         const std::vector<HandleTimestampMessage>&, void* user);

 /**
  * CameraHardwareInterface.h defines the interface to the
  * camera hardware abstraction layer, used for setting and getting
  * parameters, live previewing, and taking pictures. It is used for
  * HAL devices with version CAMERA_DEVICE_API_VERSION_1_0 only.
  *
  * It is a referenced counted interface with RefBase as its base class.
  * CameraService calls openCameraHardware() to retrieve a strong pointer to the
  * instance of this interface and may be called multiple times. The
  * following steps describe a typical sequence:
  *
  *   -# After CameraService calls openCameraHardware(), getParameters() and
  *      setParameters() are used to initialize the camera instance.
  *   -# startPreview() is called.
  *
  * Prior to taking a picture, CameraService often calls autofocus(). When auto
  * focusing has completed, the camera instance sends a CAMERA_MSG_FOCUS notification,
  * which informs the application whether focusing was successful. The camera instance
  * only sends this message once and it is up  to the application to call autoFocus()
  * again if refocusing is desired.
  *
  * CameraService calls takePicture() to request the camera instance take a
  * picture. At this point, if a shutter, postview, raw, and/or compressed
  * callback is desired, the corresponding message must be enabled. Any memory
  * provided in a data callback must be copied if it's needed after returning.
  */

 class CameraHardwareInterface :
         public virtual RefBase,
         public virtual hardware::camera::device::V1_0::ICameraDeviceCallback,
         public virtual hardware::camera::device::V1_0::ICameraDevicePreviewCallback {

 public:
     explicit CameraHardwareInterface(const char *name):
             mDevice(nullptr),
             mHidlDevice(nullptr),
             mName(name),
             mPreviewScalingMode(NOT_SET),
             mPreviewTransform(NOT_SET),
             mPreviewWidth(NOT_SET),
             mPreviewHeight(NOT_SET),
             mPreviewFormat(NOT_SET),
             mPreviewUsage(0),
             mPreviewSwapInterval(NOT_SET),
             mPreviewCrop{NOT_SET,NOT_SET,NOT_SET,NOT_SET}
     {
     }

     ~CameraHardwareInterface();

     status_t initialize(sp<CameraProviderManager> manager);

     /** Set the ANativeWindow to which preview frames are sent */
     status_t setPreviewWindow(const sp<ANativeWindow>& buf);

     status_t setPreviewScalingMode(int scalingMode);

     status_t setPreviewTransform(int transform);

     /** Set the notification and data callbacks */
     void setCallbacks(notify_callback notify_cb,
                       data_callback data_cb,
                       data_callback_timestamp data_cb_timestamp,
                       data_callback_timestamp_batch data_cb_timestamp_batch,
                       void* user);

     /**
      * The following three functions all take a msgtype,
      * which is a bitmask of the messages defined in
      * include/ui/Camera.h
      */

     /**
      * Enable a message, or set of messages.
      */
     void enableMsgType(int32_t msgType);

     /**
      * Disable a message, or a set of messages.
      *
      * Once received a call to disableMsgType(CAMERA_MSG_VIDEO_FRAME), camera hal
      * should not rely on its client to call releaseRecordingFrame() to release
      * video recording frames sent out by the cameral hal before and after the
      * disableMsgType(CAMERA_MSG_VIDEO_FRAME) call. Camera hal clients must not
      * modify/access any video recording frame after calling
      * disableMsgType(CAMERA_MSG_VIDEO_FRAME).
      */
     void disableMsgType(int32_t msgType);

     /**
      * Query whether a message, or a set of messages, is enabled.
      * Note that this is operates as an AND, if any of the messages
      * queried are off, this will return false.
      */
     int msgTypeEnabled(int32_t msgType);

     /**
      * Start preview mode.
      */
     status_t startPreview();

     /**
      * Stop a previously started preview.
      */
     void stopPreview();

     /**
      * Returns true if preview is enabled.
      */
     int previewEnabled();

     /**
      * Request the camera hal to store meta data or real YUV data in
      * the video buffers send out via CAMERA_MSG_VIDEO_FRRAME for a
      * recording session. If it is not called, the default camera
      * hal behavior is to store real YUV data in the video buffers.
      *
      * This method should be called before startRecording() in order
      * to be effective.
      *
      * If meta data is stored in the video buffers, it is up to the
      * receiver of the video buffers to interpret the contents and
      * to find the actual frame data with the help of the meta data
      * in the buffer. How this is done is outside of the scope of
      * this method.
      *
      * Some camera hal may not support storing meta data in the video
      * buffers, but all camera hal should support storing real YUV data
      * in the video buffers. If the camera hal does not support storing
      * the meta data in the video buffers when it is requested to do
      * do, INVALID_OPERATION must be returned. It is very useful for
      * the camera hal to pass meta data rather than the actual frame
      * data directly to the video encoder, since the amount of the
      * uncompressed frame data can be very large if video size is large.
      *
      * @param enable if true to instruct the camera hal to store
      *      meta data in the video buffers; false to instruct
      *      the camera hal to store real YUV data in the video
      *      buffers.
      *
      * @return OK on success.
      */

     status_t storeMetaDataInBuffers(int enable);

     /**
      * Start record mode. When a record image is available a CAMERA_MSG_VIDEO_FRAME
      * message is sent with the corresponding frame. Every record frame must be released
      * by a cameral hal client via releaseRecordingFrame() before the client calls
      * disableMsgType(CAMERA_MSG_VIDEO_FRAME). After the client calls
      * disableMsgType(CAMERA_MSG_VIDEO_FRAME), it is camera hal's responsibility
      * to manage the life-cycle of the video recording frames, and the client must
      * not modify/access any video recording frames.
      */
     status_t startRecording();

     /**
      * Stop a previously started recording.
      */
     void stopRecording();

     /**
      * Returns true if recording is enabled.
      */
     int recordingEnabled();

     /**
      * Release a record frame previously returned by CAMERA_MSG_VIDEO_FRAME.
      *
      * It is camera hal client's responsibility to release video recording
      * frames sent out by the camera hal before the camera hal receives
      * a call to disableMsgType(CAMERA_MSG_VIDEO_FRAME). After it receives
      * the call to disableMsgType(CAMERA_MSG_VIDEO_FRAME), it is camera hal's
      * responsibility of managing the life-cycle of the video recording
      * frames.
      */
     void releaseRecordingFrame(const sp<IMemory>& mem);

     /**
      * Release a batch of recording frames previously returned by
      * CAMERA_MSG_VIDEO_FRAME. This method only supports frames that are
      * stored as VideoNativeHandleMetadata.
      *
      * It is camera hal client's responsibility to release video recording
      * frames sent out by the camera hal before the camera hal receives
      * a call to disableMsgType(CAMERA_MSG_VIDEO_FRAME). After it receives
      * the call to disableMsgType(CAMERA_MSG_VIDEO_FRAME), it is camera hal's
      * responsibility of managing the life-cycle of the video recording
      * frames.
      */
     void releaseRecordingFrameBatch(const std::vector<sp<IMemory>>& frames);

     /**
      * Start auto focus, the notification callback routine is called
      * with CAMERA_MSG_FOCUS once when focusing is complete. autoFocus()
      * will be called again if another auto focus is needed.
      */
     status_t autoFocus();

     /**
      * Cancels auto-focus function. If the auto-focus is still in progress,
      * this function will cancel it. Whether the auto-focus is in progress
      * or not, this function will return the focus position to the default.
      * If the camera does not support auto-focus, this is a no-op.
      */
     status_t cancelAutoFocus();

     /**
      * Take a picture.
      */
     status_t takePicture();

     /**
      * Cancel a picture that was started with takePicture.  Calling this
      * method when no picture is being taken is a no-op.
      */
     status_t cancelPicture();

     /**
      * Set the camera parameters. This returns BAD_VALUE if any parameter is
      * invalid or not supported. */
     status_t setParameters(const CameraParameters &params);

     /** Return the camera parameters. */
     CameraParameters getParameters() const;

     /**
      * Send command to camera driver.
      */
     status_t sendCommand(int32_t cmd, int32_t arg1, int32_t arg2);

     /**
      * Release the hardware resources owned by this object.  Note that this is
      * *not* done in the destructor.
      */
     void release();

     /**
      * Dump state of the camera hardware
      */
     status_t dump(int fd, const Vector<String16>& /*args*/) const;

 private:
     camera_device_t *mDevice;
     sp<hardware::camera::device::V1_0::ICameraDevice> mHidlDevice;
     String8 mName;

     static void sNotifyCb(int32_t msg_type, int32_t ext1,
                             int32_t ext2, void *user);

     static void sDataCb(int32_t msg_type,
                           const camera_memory_t *data, unsigned int index,
                           camera_frame_metadata_t *metadata,
                           void *user);

     static void sDataCbTimestamp(nsecs_t timestamp, int32_t msg_type,
                              const camera_memory_t *data, unsigned index,
                              void *user);

     // This is a utility class that combines a MemoryHeapBase and a MemoryBase
     // in one.  Since we tend to use them in a one-to-one relationship, this is
     // handy.
     class CameraHeapMemory : public RefBase {
     public:
         CameraHeapMemory(int fd, size_t buf_size, uint_t num_buffers = 1) :
                          mBufSize(buf_size),
                          mNumBufs(num_buffers)
         {
             mHeap = new MemoryHeapBase(fd, buf_size * num_buffers);
             commonInitialization();
         }

         explicit CameraHeapMemory(size_t buf_size, uint_t num_buffers = 1) :
                                   mBufSize(buf_size),
                                   mNumBufs(num_buffers)
         {
             mHeap = new MemoryHeapBase(buf_size * num_buffers);
             commonInitialization();
         }

         void commonInitialization()
         {
             handle.data = mHeap->base();
             handle.size = mBufSize * mNumBufs;
             handle.handle = this;

             mBuffers = new sp<MemoryBase>[mNumBufs];
             for (uint_t i = 0; i < mNumBufs; i++)
                 mBuffers[i] = new MemoryBase(mHeap,
                                              i * mBufSize,
                                              mBufSize);

             handle.release = sPutMemory;
         }

         virtual ~CameraHeapMemory()
         {
             delete [] mBuffers;
         }

         size_t mBufSize;
         uint_t mNumBufs;
         sp<MemoryHeapBase> mHeap;
         sp<MemoryBase> *mBuffers;

         camera_memory_t handle;
     };

     static camera_memory_t* sGetMemory(int fd, size_t buf_size, uint_t num_bufs,
                                          void *user __attribute__((unused)));

     static void sPutMemory(camera_memory_t *data);

     static ANativeWindow *sToAnw(void *user);

     static int sDequeueBuffer(struct preview_stream_ops* w,
                                 buffer_handle_t** buffer, int *stride);

     static int sLockBuffer(struct preview_stream_ops* w,
                       buffer_handle_t* /*buffer*/);

     static int sEnqueueBuffer(struct preview_stream_ops* w,
                       buffer_handle_t* buffer);

     static int sCancelBuffer(struct preview_stream_ops* w,
                       buffer_handle_t* buffer);

     static int sSetBufferCount(struct preview_stream_ops* w, int count);

     static int sSetBuffersGeometry(struct preview_stream_ops* w,
                       int width, int height, int format);

     static int sSetCrop(struct preview_stream_ops *w,
                       int left, int top, int right, int bottom);

     static int sSetTimestamp(struct preview_stream_ops *w,
                                int64_t timestamp);

     static int sSetUsage(struct preview_stream_ops* w, int usage);

     static int sSetSwapInterval(struct preview_stream_ops *w, int interval);

     static int sGetMinUndequeuedBufferCount(
                       const struct preview_stream_ops *w,
                       int *count);

     void initHalPreviewWindow();

     std::pair<bool, uint64_t> getBufferId(ANativeWindowBuffer* anb);
     void cleanupCirculatingBuffers();

     /**
      * Implementation of android::hardware::camera::device::V1_0::ICameraDeviceCallback
      */
     hardware::Return<void> notifyCallback(
             hardware::camera::device::V1_0::NotifyCallbackMsg msgType,
             int32_t ext1, int32_t ext2) override;
     hardware::Return<uint32_t> registerMemory(
             const hardware::hidl_handle& descriptor,
             uint32_t bufferSize, uint32_t bufferCount) override;
     hardware::Return<void> unregisterMemory(uint32_t memId) override;
     hardware::Return<void> dataCallback(
             hardware::camera::device::V1_0::DataCallbackMsg msgType,
             uint32_t data, uint32_t bufferIndex,
             const hardware::camera::device::V1_0::CameraFrameMetadata& metadata) override;
     hardware::Return<void> dataCallbackTimestamp(
             hardware::camera::device::V1_0::DataCallbackMsg msgType,
             uint32_t data, uint32_t bufferIndex, int64_t timestamp) override;
     hardware::Return<void> handleCallbackTimestamp(
             hardware::camera::device::V1_0::DataCallbackMsg msgType,
             const hardware::hidl_handle& frameData, uint32_t data,
             uint32_t bufferIndex, int64_t timestamp) override;
     hardware::Return<void> handleCallbackTimestampBatch(
             hardware::camera::device::V1_0::DataCallbackMsg msgType,
             const hardware::hidl_vec<
                     hardware::camera::device::V1_0::HandleTimestampMessage>&) override;

     /**
      * Implementation of android::hardware::camera::device::V1_0::ICameraDevicePreviewCallback
      */
     hardware::Return<void> dequeueBuffer(dequeueBuffer_cb _hidl_cb) override;
     hardware::Return<hardware::camera::common::V1_0::Status>
             enqueueBuffer(uint64_t bufferId) override;
     hardware::Return<hardware::camera::common::V1_0::Status>
             cancelBuffer(uint64_t bufferId) override;
     hardware::Return<hardware::camera::common::V1_0::Status>
             setBufferCount(uint32_t count) override;
     hardware::Return<hardware::camera::common::V1_0::Status>
             setBuffersGeometry(uint32_t w, uint32_t h,
                     hardware::graphics::common::V1_0::PixelFormat format) override;
     hardware::Return<hardware::camera::common::V1_0::Status>
             setCrop(int32_t left, int32_t top, int32_t right, int32_t bottom) override;
     hardware::Return<hardware::camera::common::V1_0::Status>
             setUsage(hardware::graphics::common::V1_0::BufferUsage usage) override;
     hardware::Return<hardware::camera::common::V1_0::Status>
             setSwapInterval(int32_t interval) override;
     hardware::Return<void> getMinUndequeuedBufferCount(
         getMinUndequeuedBufferCount_cb _hidl_cb) override;
     hardware::Return<hardware::camera::common::V1_0::Status>
             setTimestamp(int64_t timestamp) override;

     sp<ANativeWindow>        mPreviewWindow;

     struct camera_preview_window {
         struct preview_stream_ops nw;
         void *user;
     };

     struct camera_preview_window mHalPreviewWindow;

     notify_callback               mNotifyCb;
     data_callback                 mDataCb;
     data_callback_timestamp       mDataCbTimestamp;
     data_callback_timestamp_batch mDataCbTimestampBatch;
     void *mCbUser;

     // Cached values for preview stream parameters
     static const int NOT_SET = -1;
     int mPreviewScalingMode;
     int mPreviewTransform;
     int mPreviewWidth;
     int mPreviewHeight;
     int mPreviewFormat;
     int mPreviewUsage;
     int mPreviewSwapInterval;
     android_native_rect_t mPreviewCrop;

     struct BufferHasher {
         size_t operator()(const buffer_handle_t& buf) const {
             if (buf == nullptr)
                 return 0;

             size_t result = 1;
             result = 31 * result + buf->numFds;
             result = 31 * result + buf->numInts;
             int length = buf->numFds + buf->numInts;
             for (int i = 0; i < length; i++) {
                 result = 31 * result + buf->data[i];
             }
             return result;
         }
     };

     struct BufferComparator {
         bool operator()(const buffer_handle_t& buf1, const buffer_handle_t& buf2) const {
             if (buf1->numFds == buf2->numFds && buf1->numInts == buf2->numInts) {
                 int length = buf1->numFds + buf1->numInts;
                 for (int i = 0; i < length; i++) {
                     if (buf1->data[i] != buf2->data[i]) {
                         return false;
                     }
                 }
                 return true;
             }
             return false;
         }
     };

     std::mutex mBufferIdMapLock; // protecting mBufferIdMap and mNextBufferId
     typedef std::unordered_map<const buffer_handle_t, uint64_t,
             BufferHasher, BufferComparator> BufferIdMap;
     // stream ID -> per stream buffer ID map
     BufferIdMap mBufferIdMap;
     std::unordered_map<uint64_t, ANativeWindowBuffer*> mReversedBufMap;
     uint64_t mNextBufferId = 1;
     static const uint64_t BUFFER_ID_NO_BUFFER = 0;

     std::unordered_map<int, camera_memory_t*> mHidlMemPoolMap;
 };

 };  // namespace android

 #endif
	/*
	* Copyright (C) 2008 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_HARDWARE_CAMERA_HARDWARE_INTERFACE_H
	#define ANDROID_HARDWARE_CAMERA_HARDWARE_INTERFACE_H

	#include <unordered_map>
	#include <binder/IMemory.h>
	#include <binder/MemoryBase.h>
	#include <binder/MemoryHeapBase.h>
	#include <utils/RefBase.h>
	#include <ui/GraphicBuffer.h>
	#include <camera/Camera.h>
	#include <camera/CameraParameters.h>
	#include <system/window.h>
	#include <hardware/camera.h>

	#include <common/CameraProviderManager.h>

	namespace android {

	typedef void (*notify_callback)(int32_t msgType,
	int32_t ext1,
	int32_t ext2,
	void* user);

	typedef void (*data_callback)(int32_t msgType,
	const sp<IMemory> &dataPtr,
	camera_frame_metadata_t *metadata,
	void* user);

	typedef void (*data_callback_timestamp)(nsecs_t timestamp,
	int32_t msgType,
	const sp<IMemory> &dataPtr,
	void *user);

	struct HandleTimestampMessage {
	nsecs_t timestamp;
	const sp<IMemory> dataPtr;
	};

	typedef void (*data_callback_timestamp_batch)(
	int32_t msgType,
	const std::vector<HandleTimestampMessage>&, void* user);

	/**
	* CameraHardwareInterface.h defines the interface to the
	* camera hardware abstraction layer, used for setting and getting
	* parameters, live previewing, and taking pictures. It is used for
	* HAL devices with version CAMERA_DEVICE_API_VERSION_1_0 only.
	*
	* It is a referenced counted interface with RefBase as its base class.
	* CameraService calls openCameraHardware() to retrieve a strong pointer to the
	* instance of this interface and may be called multiple times. The
	* following steps describe a typical sequence:
	*
	* -# After CameraService calls openCameraHardware(), getParameters() and
	* setParameters() are used to initialize the camera instance.
	* -# startPreview() is called.
	*
	* Prior to taking a picture, CameraService often calls autofocus(). When auto
	* focusing has completed, the camera instance sends a CAMERA_MSG_FOCUS notification,
	* which informs the application whether focusing was successful. The camera instance
	* only sends this message once and it is up to the application to call autoFocus()
	* again if refocusing is desired.
	*
	* CameraService calls takePicture() to request the camera instance take a
	* picture. At this point, if a shutter, postview, raw, and/or compressed
	* callback is desired, the corresponding message must be enabled. Any memory
	* provided in a data callback must be copied if it's needed after returning.
	*/

	class CameraHardwareInterface :
	public virtual RefBase,
	public virtual hardware::camera::device::V1_0::ICameraDeviceCallback,
	public virtual hardware::camera::device::V1_0::ICameraDevicePreviewCallback {

	public:
	explicit CameraHardwareInterface(const char *name):
	mDevice(nullptr),
	mHidlDevice(nullptr),
	mName(name),
	mPreviewScalingMode(NOT_SET),
	mPreviewTransform(NOT_SET),
	mPreviewWidth(NOT_SET),
	mPreviewHeight(NOT_SET),
	mPreviewFormat(NOT_SET),
	mPreviewUsage(0),
	mPreviewSwapInterval(NOT_SET),
	mPreviewCrop{NOT_SET,NOT_SET,NOT_SET,NOT_SET}
	{
	}

	~CameraHardwareInterface();

	status_t initialize(sp<CameraProviderManager> manager);

	/** Set the ANativeWindow to which preview frames are sent */
	status_t setPreviewWindow(const sp<ANativeWindow>& buf);

	status_t setPreviewScalingMode(int scalingMode);

	status_t setPreviewTransform(int transform);

	/** Set the notification and data callbacks */
	void setCallbacks(notify_callback notify_cb,
	data_callback data_cb,
	data_callback_timestamp data_cb_timestamp,
	data_callback_timestamp_batch data_cb_timestamp_batch,
	void* user);

	/**
	* The following three functions all take a msgtype,
	* which is a bitmask of the messages defined in
	* include/ui/Camera.h
	*/

	/**
	* Enable a message, or set of messages.
	*/
	void enableMsgType(int32_t msgType);

	/**
	* Disable a message, or a set of messages.
	*
	* Once received a call to disableMsgType(CAMERA_MSG_VIDEO_FRAME), camera hal
	* should not rely on its client to call releaseRecordingFrame() to release
	* video recording frames sent out by the cameral hal before and after the
	* disableMsgType(CAMERA_MSG_VIDEO_FRAME) call. Camera hal clients must not
	* modify/access any video recording frame after calling
	* disableMsgType(CAMERA_MSG_VIDEO_FRAME).
	*/
	void disableMsgType(int32_t msgType);

	/**
	* Query whether a message, or a set of messages, is enabled.
	* Note that this is operates as an AND, if any of the messages
	* queried are off, this will return false.
	*/
	int msgTypeEnabled(int32_t msgType);

	/**
	* Start preview mode.
	*/
	status_t startPreview();

	/**
	* Stop a previously started preview.
	*/
	void stopPreview();

	/**
	* Returns true if preview is enabled.
	*/
	int previewEnabled();

	/**
	* Request the camera hal to store meta data or real YUV data in
	* the video buffers send out via CAMERA_MSG_VIDEO_FRRAME for a
	* recording session. If it is not called, the default camera
	* hal behavior is to store real YUV data in the video buffers.
	*
	* This method should be called before startRecording() in order
	* to be effective.
	*
	* If meta data is stored in the video buffers, it is up to the
	* receiver of the video buffers to interpret the contents and
	* to find the actual frame data with the help of the meta data
	* in the buffer. How this is done is outside of the scope of
	* this method.
	*
	* Some camera hal may not support storing meta data in the video
	* buffers, but all camera hal should support storing real YUV data
	* in the video buffers. If the camera hal does not support storing
	* the meta data in the video buffers when it is requested to do
	* do, INVALID_OPERATION must be returned. It is very useful for
	* the camera hal to pass meta data rather than the actual frame
	* data directly to the video encoder, since the amount of the
	* uncompressed frame data can be very large if video size is large.
	*
	* @param enable if true to instruct the camera hal to store
	* meta data in the video buffers; false to instruct
	* the camera hal to store real YUV data in the video
	* buffers.
	*
	* @return OK on success.
	*/

	status_t storeMetaDataInBuffers(int enable);

	/**
	* Start record mode. When a record image is available a CAMERA_MSG_VIDEO_FRAME
	* message is sent with the corresponding frame. Every record frame must be released
	* by a cameral hal client via releaseRecordingFrame() before the client calls
	* disableMsgType(CAMERA_MSG_VIDEO_FRAME). After the client calls
	* disableMsgType(CAMERA_MSG_VIDEO_FRAME), it is camera hal's responsibility
	* to manage the life-cycle of the video recording frames, and the client must
	* not modify/access any video recording frames.
	*/
	status_t startRecording();

	/**
	* Stop a previously started recording.
	*/
	void stopRecording();

	/**
	* Returns true if recording is enabled.
	*/
	int recordingEnabled();

	/**
	* Release a record frame previously returned by CAMERA_MSG_VIDEO_FRAME.
	*
	* It is camera hal client's responsibility to release video recording
	* frames sent out by the camera hal before the camera hal receives
	* a call to disableMsgType(CAMERA_MSG_VIDEO_FRAME). After it receives
	* the call to disableMsgType(CAMERA_MSG_VIDEO_FRAME), it is camera hal's
	* responsibility of managing the life-cycle of the video recording
	* frames.
	*/
	void releaseRecordingFrame(const sp<IMemory>& mem);

	/**
	* Release a batch of recording frames previously returned by
	* CAMERA_MSG_VIDEO_FRAME. This method only supports frames that are
	* stored as VideoNativeHandleMetadata.
	*
	* It is camera hal client's responsibility to release video recording
	* frames sent out by the camera hal before the camera hal receives
	* a call to disableMsgType(CAMERA_MSG_VIDEO_FRAME). After it receives
	* the call to disableMsgType(CAMERA_MSG_VIDEO_FRAME), it is camera hal's
	* responsibility of managing the life-cycle of the video recording
	* frames.
	*/
	void releaseRecordingFrameBatch(const std::vector<sp<IMemory>>& frames);

	/**
	* Start auto focus, the notification callback routine is called
	* with CAMERA_MSG_FOCUS once when focusing is complete. autoFocus()
	* will be called again if another auto focus is needed.
	*/
	status_t autoFocus();

	/**
	* Cancels auto-focus function. If the auto-focus is still in progress,
	* this function will cancel it. Whether the auto-focus is in progress
	* or not, this function will return the focus position to the default.
	* If the camera does not support auto-focus, this is a no-op.
	*/
	status_t cancelAutoFocus();

	/**
	* Take a picture.
	*/
	status_t takePicture();

	/**
	* Cancel a picture that was started with takePicture. Calling this
	* method when no picture is being taken is a no-op.
	*/
	status_t cancelPicture();

	/**
	* Set the camera parameters. This returns BAD_VALUE if any parameter is
	* invalid or not supported. */
	status_t setParameters(const CameraParameters &params);

	/** Return the camera parameters. */
	CameraParameters getParameters() const;

	/**
	* Send command to camera driver.
	*/
	status_t sendCommand(int32_t cmd, int32_t arg1, int32_t arg2);

	/**
	* Release the hardware resources owned by this object. Note that this is
	* not done in the destructor.
	*/
	void release();

	/**
	* Dump state of the camera hardware
	*/
	status_t dump(int fd, const Vector<String16>& /args/) const;

	private:
	camera_device_t *mDevice;
	sp<hardware::camera::device::V1_0::ICameraDevice> mHidlDevice;
	String8 mName;

	static void sNotifyCb(int32_t msg_type, int32_t ext1,
	int32_t ext2, void *user);

	static void sDataCb(int32_t msg_type,
	const camera_memory_t *data, unsigned int index,
	camera_frame_metadata_t *metadata,
	void *user);

	static void sDataCbTimestamp(nsecs_t timestamp, int32_t msg_type,
	const camera_memory_t *data, unsigned index,
	void *user);

	// This is a utility class that combines a MemoryHeapBase and a MemoryBase
	// in one. Since we tend to use them in a one-to-one relationship, this is
	// handy.
	class CameraHeapMemory : public RefBase {
	public:
	CameraHeapMemory(int fd, size_t buf_size, uint_t num_buffers = 1) :
	mBufSize(buf_size),
	mNumBufs(num_buffers)
	{
	mHeap = new MemoryHeapBase(fd, buf_size * num_buffers);
	commonInitialization();
	}

	explicit CameraHeapMemory(size_t buf_size, uint_t num_buffers = 1) :
	mBufSize(buf_size),
	mNumBufs(num_buffers)
	{
	mHeap = new MemoryHeapBase(buf_size * num_buffers);
	commonInitialization();
	}

	void commonInitialization()
	{
	handle.data = mHeap->base();
	handle.size = mBufSize * mNumBufs;
	handle.handle = this;

	mBuffers = new sp<MemoryBase>[mNumBufs];
	for (uint_t i = 0; i < mNumBufs; i++)
	mBuffers[i] = new MemoryBase(mHeap,
	i * mBufSize,
	mBufSize);

	handle.release = sPutMemory;
	}

	virtual ~CameraHeapMemory()
	{
	delete [] mBuffers;
	}

	size_t mBufSize;
	uint_t mNumBufs;
	sp<MemoryHeapBase> mHeap;
	sp<MemoryBase> *mBuffers;

	camera_memory_t handle;
	};

	static camera_memory_t* sGetMemory(int fd, size_t buf_size, uint_t num_bufs,
	void *user __attribute__((unused)));

	static void sPutMemory(camera_memory_t *data);

	static ANativeWindow sToAnw(void user);

	static int sDequeueBuffer(struct preview_stream_ops* w,
	buffer_handle_t** buffer, int *stride);

	static int sLockBuffer(struct preview_stream_ops* w,
	buffer_handle_t* /buffer/);

	static int sEnqueueBuffer(struct preview_stream_ops* w,
	buffer_handle_t* buffer);

	static int sCancelBuffer(struct preview_stream_ops* w,
	buffer_handle_t* buffer);

	static int sSetBufferCount(struct preview_stream_ops* w, int count);

	static int sSetBuffersGeometry(struct preview_stream_ops* w,
	int width, int height, int format);

	static int sSetCrop(struct preview_stream_ops *w,
	int left, int top, int right, int bottom);

	static int sSetTimestamp(struct preview_stream_ops *w,
	int64_t timestamp);

	static int sSetUsage(struct preview_stream_ops* w, int usage);

	static int sSetSwapInterval(struct preview_stream_ops *w, int interval);

	static int sGetMinUndequeuedBufferCount(
	const struct preview_stream_ops *w,
	int *count);

	void initHalPreviewWindow();

	std::pair<bool, uint64_t> getBufferId(ANativeWindowBuffer* anb);
	void cleanupCirculatingBuffers();

	/**
	* Implementation of android::hardware::camera::device::V1_0::ICameraDeviceCallback
	*/
	hardware::Return<void> notifyCallback(
	hardware::camera::device::V1_0::NotifyCallbackMsg msgType,
	int32_t ext1, int32_t ext2) override;
	hardware::Return<uint32_t> registerMemory(
	const hardware::hidl_handle& descriptor,
	uint32_t bufferSize, uint32_t bufferCount) override;
	hardware::Return<void> unregisterMemory(uint32_t memId) override;
	hardware::Return<void> dataCallback(
	hardware::camera::device::V1_0::DataCallbackMsg msgType,
	uint32_t data, uint32_t bufferIndex,
	const hardware::camera::device::V1_0::CameraFrameMetadata& metadata) override;
	hardware::Return<void> dataCallbackTimestamp(
	hardware::camera::device::V1_0::DataCallbackMsg msgType,
	uint32_t data, uint32_t bufferIndex, int64_t timestamp) override;
	hardware::Return<void> handleCallbackTimestamp(
	hardware::camera::device::V1_0::DataCallbackMsg msgType,
	const hardware::hidl_handle& frameData, uint32_t data,
	uint32_t bufferIndex, int64_t timestamp) override;
	hardware::Return<void> handleCallbackTimestampBatch(
	hardware::camera::device::V1_0::DataCallbackMsg msgType,
	const hardware::hidl_vec<
	hardware::camera::device::V1_0::HandleTimestampMessage>&) override;

	/**
	* Implementation of android::hardware::camera::device::V1_0::ICameraDevicePreviewCallback
	*/
	hardware::Return<void> dequeueBuffer(dequeueBuffer_cb _hidl_cb) override;
	hardware::Return<hardware::camera::common::V1_0::Status>
	enqueueBuffer(uint64_t bufferId) override;
	hardware::Return<hardware::camera::common::V1_0::Status>
	cancelBuffer(uint64_t bufferId) override;
	hardware::Return<hardware::camera::common::V1_0::Status>
	setBufferCount(uint32_t count) override;
	hardware::Return<hardware::camera::common::V1_0::Status>
	setBuffersGeometry(uint32_t w, uint32_t h,
	hardware::graphics::common::V1_0::PixelFormat format) override;
	hardware::Return<hardware::camera::common::V1_0::Status>
	setCrop(int32_t left, int32_t top, int32_t right, int32_t bottom) override;
	hardware::Return<hardware::camera::common::V1_0::Status>
	setUsage(hardware::graphics::common::V1_0::BufferUsage usage) override;
	hardware::Return<hardware::camera::common::V1_0::Status>
	setSwapInterval(int32_t interval) override;
	hardware::Return<void> getMinUndequeuedBufferCount(
	getMinUndequeuedBufferCount_cb _hidl_cb) override;
	hardware::Return<hardware::camera::common::V1_0::Status>
	setTimestamp(int64_t timestamp) override;

	sp<ANativeWindow> mPreviewWindow;

	struct camera_preview_window {
	struct preview_stream_ops nw;
	void *user;
	};

	struct camera_preview_window mHalPreviewWindow;

	notify_callback mNotifyCb;
	data_callback mDataCb;
	data_callback_timestamp mDataCbTimestamp;
	data_callback_timestamp_batch mDataCbTimestampBatch;
	void *mCbUser;

	// Cached values for preview stream parameters
	static const int NOT_SET = -1;
	int mPreviewScalingMode;
	int mPreviewTransform;
	int mPreviewWidth;
	int mPreviewHeight;
	int mPreviewFormat;
	int mPreviewUsage;
	int mPreviewSwapInterval;
	android_native_rect_t mPreviewCrop;

	struct BufferHasher {
	size_t operator()(const buffer_handle_t& buf) const {
	if (buf == nullptr)
	return 0;

	size_t result = 1;
	result = 31 * result + buf->numFds;
	result = 31 * result + buf->numInts;
	int length = buf->numFds + buf->numInts;
	for (int i = 0; i < length; i++) {
	result = 31 * result + buf->data[i];
	}
	return result;
	}
	};

	struct BufferComparator {
	bool operator()(const buffer_handle_t& buf1, const buffer_handle_t& buf2) const {
	if (buf1->numFds == buf2->numFds && buf1->numInts == buf2->numInts) {
	int length = buf1->numFds + buf1->numInts;
	for (int i = 0; i < length; i++) {
	if (buf1->data[i] != buf2->data[i]) {
	return false;
	}
	}
	return true;
	}
	return false;
	}
	};

	std::mutex mBufferIdMapLock; // protecting mBufferIdMap and mNextBufferId
	typedef std::unordered_map<const buffer_handle_t, uint64_t,
	BufferHasher, BufferComparator> BufferIdMap;
	// stream ID -> per stream buffer ID map
	BufferIdMap mBufferIdMap;
	std::unordered_map<uint64_t, ANativeWindowBuffer*> mReversedBufMap;
	uint64_t mNextBufferId = 1;
	static const uint64_t BUFFER_ID_NO_BUFFER = 0;

	std::unordered_map<int, camera_memory_t*> mHidlMemPoolMap;
	};

	}; // namespace android

	#endif