camera/device/3.2/ICameraDeviceSession.hal - LeafOS-Project/android_hardware_interfaces - Gitiles

 /*
  * Copyright (C) 2016 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.
  */

 package android.hardware.camera.device@3.2;

 import android.hardware.camera.common@1.0::types;

 /**
  * Camera device active session interface.
  *
  * Obtained via ICameraDevice::open(), this interface contains the methods to
  * configure and request captures from an active camera device.
  *
  */
 interface ICameraDeviceSession {

     /**
      * constructDefaultRequestSettings:
      *
      * Create capture settings for standard camera use cases.
      *
      * The device must return a settings buffer that is configured to meet the
      * requested use case, which must be one of the CAMERA3_TEMPLATE_*
      * enums. All request control fields must be included.
      *
      * Performance requirements:
      *
      * This must be a non-blocking call. The HAL should return from this call
      * in 1ms, and must return from this call in 5ms.
      *
      * Return values:
      * @return status Status code for the operation, one of:
      *     OK:
      *         On a successful construction of default settings.
      *     INTERNAL_ERROR:
      *         An unexpected internal error occurred, and the default settings
      *         are not available.
      *     ILLEGAL_ARGUMENT:
      *         The camera HAL does not support the input template type
      *     CAMERA_DISCONNECTED:
      *         An external camera device has been disconnected, and is no longer
      *         available. This camera device interface is now stale, and a new
      *         instance must be acquired if the device is reconnected. All
      *         subsequent calls on this interface must return
      *         CAMERA_DISCONNECTED.
      * @return template The default capture request settings for the requested
      *     use case, or an empty metadata structure if status is not OK.
      *
      */
     constructDefaultRequestSettings(RequestTemplate type) generates
             (Status status, CameraMetadata requestTemplate);

     /**
      * configureStreams:
      *
      * Reset the HAL camera device processing pipeline and set up new input and
      * output streams. This call replaces any existing stream configuration with
      * the streams defined in the streamList. This method must be called at
      * least once before a request is submitted with processCaptureRequest().
      *
      * The streamList must contain at least one output-capable stream, and may
      * not contain more than one input-capable stream.
      *
      * The streamList may contain streams that are also in the currently-active
      * set of streams (from the previous call to configureStreams()). These
      * streams must already have valid values for usage, maxBuffers, and the
      * private pointer.
      *
      * If the HAL needs to change the stream configuration for an existing
      * stream due to the new configuration, it may rewrite the values of usage
      * and/or maxBuffers during the configure call.
      *
      * The framework must detect such a change, and may then reallocate the
      * stream buffers before using buffers from that stream in a request.
      *
      * If a currently-active stream is not included in streamList, the HAL may
      * safely remove any references to that stream. It must not be reused in a
      * later configureStreams() call by the framework, and all the gralloc
      * buffers for it must be freed after the configureStreams() call returns.
      *
      * If the stream is new, the client must set the consumer usage flags in
      * requestedConfiguration. Upon return, the HAL device must set producerUsage,
      * maxBuffers, and other fields in the configureStreams() return values. These
      * fields are then used by the framework and the platform gralloc module to
      * allocate the gralloc buffers for each stream.
      *
      * Newly allocated buffers may be included in a capture request at any time
      * by the framework. Once a gralloc buffer is returned to the framework
      * with processCaptureResult (and its respective releaseFence has been
      * signaled) the framework may free or reuse it at any time.
      *
      * ------------------------------------------------------------------------
      *
      * Preconditions:
      *
      * The framework must only call this method when no captures are being
      * processed. That is, all results have been returned to the framework, and
      * all in-flight input and output buffers have been returned and their
      * release sync fences have been signaled by the HAL. The framework must not
      * submit new requests for capture while the configureStreams() call is
      * underway.
      *
      * Postconditions:
      *
      * The HAL device must configure itself to provide maximum possible output
      * frame rate given the sizes and formats of the output streams, as
      * documented in the camera device's static metadata.
      *
      * Performance requirements:
      *
      * This call is expected to be heavyweight and possibly take several hundred
      * milliseconds to complete, since it may require resetting and
      * reconfiguring the image sensor and the camera processing pipeline.
      * Nevertheless, the HAL device should attempt to minimize the
      * reconfiguration delay to minimize the user-visible pauses during
      * application operational mode changes (such as switching from still
      * capture to video recording).
      *
      * The HAL should return from this call in 500ms, and must return from this
      * call in 1000ms.
      *
      * @return Status Status code for the operation, one of:
      *     OK:
      *          On successful stream configuration.
      *     INTERNAL_ERROR:
      *         If there has been a fatal error and the device is no longer
      *         operational. Only close() can be called successfully by the
      *         framework after this error is returned.
      *     ILLEGAL_ARGUMENT:
      *         If the requested stream configuration is invalid. Some examples
      *         of invalid stream configurations include:
      *           - Including more than 1 INPUT stream
      *           - Not including any OUTPUT streams
      *           - Including streams with unsupported formats, or an unsupported
      *             size for that format.
      *           - Including too many output streams of a certain format.
      *           - Unsupported rotation configuration
      *           - Stream sizes/formats don't satisfy the
      *             StreamConfigurationMode requirements for non-NORMAL mode, or
      *             the requested operation_mode is not supported by the HAL.
      *           - Unsupported usage flag
      *         The camera service cannot filter out all possible illegal stream
      *         configurations, since some devices may support more simultaneous
      *         streams or larger stream resolutions than the minimum required
      *         for a given camera device hardware level. The HAL must return an
      *         ILLEGAL_ARGUMENT for any unsupported stream set, and then be
      *         ready to accept a future valid stream configuration in a later
      *         configureStreams call.
      * @return finalConfiguration The stream parameters desired by the HAL for
      *     each stream, including maximum buffers, the usage flags, and the
      *     override format.
      *
      */
     configureStreams(StreamConfiguration requestedConfiguration)
             generates (Status status,
                     HalStreamConfiguration halConfiguration);

     /**
      * processCaptureRequest:
      *
      * Send a list of capture requests to the HAL. The HAL must not return from
      * this call until it is ready to accept the next set of requests to
      * process. Only one call to processCaptureRequest() must be made at a time
      * by the framework, and the calls must all be from the same thread. The
      * next call to processCaptureRequest() must be made as soon as a new
      * request and its associated buffers are available. In a normal preview
      * scenario, this means the function is generally called again by the
      * framework almost instantly. If more than one request is provided by the
      * client, the HAL must process the requests in order of lowest index to
      * highest index.
      *
      * The cachesToRemove argument contains a list of buffer caches (see
      * StreamBuffer document for more information on buffer cache) to be removed
      * by camera HAL. Camera HAL must remove these cache entries whether or not
      * this method returns OK.
      *
      * The actual request processing is asynchronous, with the results of
      * capture being returned by the HAL through the processCaptureResult()
      * call. This call requires the result metadata to be available, but output
      * buffers may simply provide sync fences to wait on. Multiple requests are
      * expected to be in flight at once, to maintain full output frame rate.
      *
      * The framework retains ownership of the request structure. It is only
      * guaranteed to be valid during this call. The HAL device must make copies
      * of the information it needs to retain for the capture processing. The HAL
      * is responsible for waiting on and closing the buffers' fences and
      * returning the buffer handles to the framework.
      *
      * The HAL must write the file descriptor for the input buffer's release
      * sync fence into input_buffer->release_fence, if input_buffer is not
      * valid. If the HAL returns -1 for the input buffer release sync fence, the
      * framework is free to immediately reuse the input buffer. Otherwise, the
      * framework must wait on the sync fence before refilling and reusing the
      * input buffer.
      *
      * The input/output buffers provided by the framework in each request
      * may be brand new (having never before seen by the HAL).
      *
      * ------------------------------------------------------------------------
      * Performance considerations:
      *
      * Handling a new buffer should be extremely lightweight and there must be
      * no frame rate degradation or frame jitter introduced.
      *
      * This call must return fast enough to ensure that the requested frame
      * rate can be sustained, especially for streaming cases (post-processing
      * quality settings set to FAST). The HAL should return this call in 1
      * frame interval, and must return from this call in 4 frame intervals.
      *
      * @return status Status code for the operation, one of:
      *     OK:
      *         On a successful start to processing the capture request
      *     ILLEGAL_ARGUMENT:
      *         If the input is malformed (the settings are empty when not
      *         allowed, there are 0 output buffers, etc) and capture processing
      *         cannot start. Failures during request processing must be
      *         handled by calling ICameraDeviceCallback::notify(). In case of
      *         this error, the framework retains responsibility for the
      *         stream buffers' fences and the buffer handles; the HAL must not
      *         close the fences or return these buffers with
      *         ICameraDeviceCallback::processCaptureResult().
      *     INTERNAL_ERROR:
      *         If the camera device has encountered a serious error. After this
      *         error is returned, only the close() method can be successfully
      *         called by the framework.
      * @return numRequestProcessed Number of requests successfully processed by
      *     camera HAL. When status is OK, this must be equal to the size of
      *     requests. When the call fails, this number is the number of requests
      *     that HAL processed successfully before HAL runs into an error.
      *
      */
     processCaptureRequest(vec<CaptureRequest> requests,
             vec<BufferCache> cachesToRemove)
             generates (Status status, uint32_t numRequestProcessed);

     /**
      * getCaptureRequestMetadataQueue:
      *
      * Retrieves the queue used along with processCaptureRequest. If
      * client decides to use fast message queue to pass request metadata,
      * it must:
      * - Call getCaptureRequestMetadataQueue to retrieve the fast message queue;
      * - In each of the requests sent in processCaptureRequest, set
      *   fmqSettingsSize field of CaptureRequest to be the size to read from the
      *   fast message queue; leave settings field of CaptureRequest empty.
      *
      * @return queue the queue that client writes request metadata to.
      */
     getCaptureRequestMetadataQueue() generates (fmq_sync<uint8_t> queue);

     /**
      * getCaptureResultMetadataQueue:
      *
      * Retrieves the queue used along with
      * ICameraDeviceCallback.processCaptureResult.
      *
      * Clients to ICameraDeviceSession must:
      * - Call getCaptureRequestMetadataQueue to retrieve the fast message queue;
      * - In implementation of ICameraDeviceCallback, test whether
      *   .fmqResultSize field is zero.
      *     - If .fmqResultSize != 0, read result metadata from the fast message
      *       queue;
      *     - otherwise, read result metadata in CaptureResult.result.
      *
      * @return queue the queue that implementation writes result metadata to.
      */
     getCaptureResultMetadataQueue() generates (fmq_sync<uint8_t> queue);

     /**
      * flush:
      *
      * Flush all currently in-process captures and all buffers in the pipeline
      * on the given device. Generally, this method is used to dump all state as
      * quickly as possible in order to prepare for a configure_streams() call.
      *
      * No buffers are required to be successfully returned, so every buffer
      * held at the time of flush() (whether successfully filled or not) may be
      * returned with CAMERA3_BUFFER_STATUS_ERROR. Note the HAL is still allowed
      * to return valid (CAMERA3_BUFFER_STATUS_OK) buffers during this call,
      * provided they are successfully filled.
      *
      * All requests currently in the HAL are expected to be returned as soon as
      * possible. Not-in-process requests must return errors immediately. Any
      * interruptible hardware blocks must be stopped, and any uninterruptible
      * blocks must be waited on.
      *
      * flush() may be called concurrently to processCaptureRequest(), with the
      * expectation that processCaptureRequest returns quickly and the
      * request submitted in that processCaptureRequest call is treated like
      * all other in-flight requests. Due to concurrency issues, it is possible
      * that from the HAL's point of view, a processCaptureRequest() call may
      * be started after flush has been invoked but has not returned yet. If such
      * a call happens before flush() returns, the HAL must treat the new
      * capture request like other in-flight pending requests (see #4 below).
      *
      * More specifically, the HAL must follow below requirements for various
      * cases:
      *
      * 1. For captures that are too late for the HAL to cancel/stop, and must be
      *    completed normally by the HAL; i.e. the HAL can send shutter/notify
      *    and processCaptureResult and buffers as normal.
      *
      * 2. For pending requests that have not done any processing, the HAL must
      *    call notify CAMERA3_MSG_ERROR_REQUEST, and return all the output
      *    buffers with processCaptureResult in the error state
      *    (CAMERA3_BUFFER_STATUS_ERROR). The HAL must not place the release
      *    fence into an error state, instead, the release fences must be set to
      *    the acquire fences passed by the framework, or -1 if they have been
      *    waited on by the HAL already. This is also the path to follow for any
      *    captures for which the HAL already called notify() with
      *    CAMERA3_MSG_SHUTTER but won't be producing any metadata/valid buffers
      *    for. After CAMERA3_MSG_ERROR_REQUEST, for a given frame, only
      *    processCaptureResults with buffers in CAMERA3_BUFFER_STATUS_ERROR
      *    are allowed. No further notifys or processCaptureResult with
      *    non-empty metadata is allowed.
      *
      * 3. For partially completed pending requests that do not have all the
      *    output buffers or perhaps missing metadata, the HAL must follow
      *    below:
      *
      *    3.1. Call notify with CAMERA3_MSG_ERROR_RESULT if some of the expected
      *         result metadata (i.e. one or more partial metadata) won't be
      *         available for the capture.
      *
      *    3.2. Call notify with CAMERA3_MSG_ERROR_BUFFER for every buffer that
      *         won't be produced for the capture.
      *
      *    3.3. Call notify with CAMERA3_MSG_SHUTTER with the capture timestamp
      *         before any buffers/metadata are returned with
      *         processCaptureResult.
      *
      *    3.4. For captures that will produce some results, the HAL must not
      *         call CAMERA3_MSG_ERROR_REQUEST, since that indicates complete
      *         failure.
      *
      *    3.5. Valid buffers/metadata must be passed to the framework as
      *         normal.
      *
      *    3.6. Failed buffers must be returned to the framework as described
      *         for case 2. But failed buffers do not have to follow the strict
      *         ordering valid buffers do, and may be out-of-order with respect
      *         to valid buffers. For example, if buffers A, B, C, D, E are sent,
      *         D and E are failed, then A, E, B, D, C is an acceptable return
      *         order.
      *
      *    3.7. For fully-missing metadata, calling CAMERA3_MSG_ERROR_RESULT is
      *         sufficient, no need to call processCaptureResult with empty
      *         metadata or equivalent.
      *
      * 4. If a flush() is invoked while a processCaptureRequest() invocation
      *    is active, that process call must return as soon as possible. In
      *    addition, if a processCaptureRequest() call is made after flush()
      *    has been invoked but before flush() has returned, the capture request
      *    provided by the late processCaptureRequest call must be treated
      *    like a pending request in case #2 above.
      *
      * flush() must only return when there are no more outstanding buffers or
      * requests left in the HAL. The framework may call configure_streams (as
      * the HAL state is now quiesced) or may issue new requests.
      *
      * Note that it's sufficient to only support fully-succeeded and
      * fully-failed result cases. However, it is highly desirable to support
      * the partial failure cases as well, as it could help improve the flush
      * call overall performance.
      *
      * Performance requirements:
      *
      * The HAL should return from this call in 100ms, and must return from this
      * call in 1000ms. And this call must not be blocked longer than pipeline
      * latency (see S7 for definition).
      *
      * @return status Status code for the operation, one of:
      *     OK:
      *         On a successful flush of the camera HAL.
      *     INTERNAL_ERROR:
      *         If the camera device has encountered a serious error. After this
      *         error is returned, only the close() method can be successfully
      *         called by the framework.
      */
     flush() generates (Status status);

     /**
      * close:
      *
      * Shut down the camera device.
      *
      * After this call, all calls to this session instance must return
      * INTERNAL_ERROR.
      *
      * This method must always succeed, even if the device has encountered a
      * serious error.
      */
     close();
 };
	/*
	* Copyright (C) 2016 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.
	*/

	package android.hardware.camera.device@3.2;

	import android.hardware.camera.common@1.0::types;

	/**
	* Camera device active session interface.
	*
	* Obtained via ICameraDevice::open(), this interface contains the methods to
	* configure and request captures from an active camera device.
	*
	*/
	interface ICameraDeviceSession {

	/**
	* constructDefaultRequestSettings:
	*
	* Create capture settings for standard camera use cases.
	*
	* The device must return a settings buffer that is configured to meet the
	* requested use case, which must be one of the CAMERA3_TEMPLATE_*
	* enums. All request control fields must be included.
	*
	* Performance requirements:
	*
	* This must be a non-blocking call. The HAL should return from this call
	* in 1ms, and must return from this call in 5ms.
	*
	* Return values:
	* @return status Status code for the operation, one of:
	* OK:
	* On a successful construction of default settings.
	* INTERNAL_ERROR:
	* An unexpected internal error occurred, and the default settings
	* are not available.
	* ILLEGAL_ARGUMENT:
	* The camera HAL does not support the input template type
	* CAMERA_DISCONNECTED:
	* An external camera device has been disconnected, and is no longer
	* available. This camera device interface is now stale, and a new
	* instance must be acquired if the device is reconnected. All
	* subsequent calls on this interface must return
	* CAMERA_DISCONNECTED.
	* @return template The default capture request settings for the requested
	* use case, or an empty metadata structure if status is not OK.
	*
	*/
	constructDefaultRequestSettings(RequestTemplate type) generates
	(Status status, CameraMetadata requestTemplate);

	/**
	* configureStreams:
	*
	* Reset the HAL camera device processing pipeline and set up new input and
	* output streams. This call replaces any existing stream configuration with
	* the streams defined in the streamList. This method must be called at
	* least once before a request is submitted with processCaptureRequest().
	*
	* The streamList must contain at least one output-capable stream, and may
	* not contain more than one input-capable stream.
	*
	* The streamList may contain streams that are also in the currently-active
	* set of streams (from the previous call to configureStreams()). These
	* streams must already have valid values for usage, maxBuffers, and the
	* private pointer.
	*
	* If the HAL needs to change the stream configuration for an existing
	* stream due to the new configuration, it may rewrite the values of usage
	* and/or maxBuffers during the configure call.
	*
	* The framework must detect such a change, and may then reallocate the
	* stream buffers before using buffers from that stream in a request.
	*
	* If a currently-active stream is not included in streamList, the HAL may
	* safely remove any references to that stream. It must not be reused in a
	* later configureStreams() call by the framework, and all the gralloc
	* buffers for it must be freed after the configureStreams() call returns.
	*
	* If the stream is new, the client must set the consumer usage flags in
	* requestedConfiguration. Upon return, the HAL device must set producerUsage,
	* maxBuffers, and other fields in the configureStreams() return values. These
	* fields are then used by the framework and the platform gralloc module to
	* allocate the gralloc buffers for each stream.
	*
	* Newly allocated buffers may be included in a capture request at any time
	* by the framework. Once a gralloc buffer is returned to the framework
	* with processCaptureResult (and its respective releaseFence has been
	* signaled) the framework may free or reuse it at any time.
	*
	* ------------------------------------------------------------------------
	*
	* Preconditions:
	*
	* The framework must only call this method when no captures are being
	* processed. That is, all results have been returned to the framework, and
	* all in-flight input and output buffers have been returned and their
	* release sync fences have been signaled by the HAL. The framework must not
	* submit new requests for capture while the configureStreams() call is
	* underway.
	*
	* Postconditions:
	*
	* The HAL device must configure itself to provide maximum possible output
	* frame rate given the sizes and formats of the output streams, as
	* documented in the camera device's static metadata.
	*
	* Performance requirements:
	*
	* This call is expected to be heavyweight and possibly take several hundred
	* milliseconds to complete, since it may require resetting and
	* reconfiguring the image sensor and the camera processing pipeline.
	* Nevertheless, the HAL device should attempt to minimize the
	* reconfiguration delay to minimize the user-visible pauses during
	* application operational mode changes (such as switching from still
	* capture to video recording).
	*
	* The HAL should return from this call in 500ms, and must return from this
	* call in 1000ms.
	*
	* @return Status Status code for the operation, one of:
	* OK:
	* On successful stream configuration.
	* INTERNAL_ERROR:
	* If there has been a fatal error and the device is no longer
	* operational. Only close() can be called successfully by the
	* framework after this error is returned.
	* ILLEGAL_ARGUMENT:
	* If the requested stream configuration is invalid. Some examples
	* of invalid stream configurations include:
	* - Including more than 1 INPUT stream
	* - Not including any OUTPUT streams
	* - Including streams with unsupported formats, or an unsupported
	* size for that format.
	* - Including too many output streams of a certain format.
	* - Unsupported rotation configuration
	* - Stream sizes/formats don't satisfy the
	* StreamConfigurationMode requirements for non-NORMAL mode, or
	* the requested operation_mode is not supported by the HAL.
	* - Unsupported usage flag
	* The camera service cannot filter out all possible illegal stream
	* configurations, since some devices may support more simultaneous
	* streams or larger stream resolutions than the minimum required
	* for a given camera device hardware level. The HAL must return an
	* ILLEGAL_ARGUMENT for any unsupported stream set, and then be
	* ready to accept a future valid stream configuration in a later
	* configureStreams call.
	* @return finalConfiguration The stream parameters desired by the HAL for
	* each stream, including maximum buffers, the usage flags, and the
	* override format.
	*
	*/
	configureStreams(StreamConfiguration requestedConfiguration)
	generates (Status status,
	HalStreamConfiguration halConfiguration);

	/**
	* processCaptureRequest:
	*
	* Send a list of capture requests to the HAL. The HAL must not return from
	* this call until it is ready to accept the next set of requests to
	* process. Only one call to processCaptureRequest() must be made at a time
	* by the framework, and the calls must all be from the same thread. The
	* next call to processCaptureRequest() must be made as soon as a new
	* request and its associated buffers are available. In a normal preview
	* scenario, this means the function is generally called again by the
	* framework almost instantly. If more than one request is provided by the
	* client, the HAL must process the requests in order of lowest index to
	* highest index.
	*
	* The cachesToRemove argument contains a list of buffer caches (see
	* StreamBuffer document for more information on buffer cache) to be removed
	* by camera HAL. Camera HAL must remove these cache entries whether or not
	* this method returns OK.
	*
	* The actual request processing is asynchronous, with the results of
	* capture being returned by the HAL through the processCaptureResult()
	* call. This call requires the result metadata to be available, but output
	* buffers may simply provide sync fences to wait on. Multiple requests are
	* expected to be in flight at once, to maintain full output frame rate.
	*
	* The framework retains ownership of the request structure. It is only
	* guaranteed to be valid during this call. The HAL device must make copies
	* of the information it needs to retain for the capture processing. The HAL
	* is responsible for waiting on and closing the buffers' fences and
	* returning the buffer handles to the framework.
	*
	* The HAL must write the file descriptor for the input buffer's release
	* sync fence into input_buffer->release_fence, if input_buffer is not
	* valid. If the HAL returns -1 for the input buffer release sync fence, the
	* framework is free to immediately reuse the input buffer. Otherwise, the
	* framework must wait on the sync fence before refilling and reusing the
	* input buffer.
	*
	* The input/output buffers provided by the framework in each request
	* may be brand new (having never before seen by the HAL).
	*
	* ------------------------------------------------------------------------
	* Performance considerations:
	*
	* Handling a new buffer should be extremely lightweight and there must be
	* no frame rate degradation or frame jitter introduced.
	*
	* This call must return fast enough to ensure that the requested frame
	* rate can be sustained, especially for streaming cases (post-processing
	* quality settings set to FAST). The HAL should return this call in 1
	* frame interval, and must return from this call in 4 frame intervals.
	*
	* @return status Status code for the operation, one of:
	* OK:
	* On a successful start to processing the capture request
	* ILLEGAL_ARGUMENT:
	* If the input is malformed (the settings are empty when not
	* allowed, there are 0 output buffers, etc) and capture processing
	* cannot start. Failures during request processing must be
	* handled by calling ICameraDeviceCallback::notify(). In case of
	* this error, the framework retains responsibility for the
	* stream buffers' fences and the buffer handles; the HAL must not
	* close the fences or return these buffers with
	* ICameraDeviceCallback::processCaptureResult().
	* INTERNAL_ERROR:
	* If the camera device has encountered a serious error. After this
	* error is returned, only the close() method can be successfully
	* called by the framework.
	* @return numRequestProcessed Number of requests successfully processed by
	* camera HAL. When status is OK, this must be equal to the size of
	* requests. When the call fails, this number is the number of requests
	* that HAL processed successfully before HAL runs into an error.
	*
	*/
	processCaptureRequest(vec<CaptureRequest> requests,
	vec<BufferCache> cachesToRemove)
	generates (Status status, uint32_t numRequestProcessed);

	/**
	* getCaptureRequestMetadataQueue:
	*
	* Retrieves the queue used along with processCaptureRequest. If
	* client decides to use fast message queue to pass request metadata,
	* it must:
	* - Call getCaptureRequestMetadataQueue to retrieve the fast message queue;
	* - In each of the requests sent in processCaptureRequest, set
	* fmqSettingsSize field of CaptureRequest to be the size to read from the
	* fast message queue; leave settings field of CaptureRequest empty.
	*
	* @return queue the queue that client writes request metadata to.
	*/
	getCaptureRequestMetadataQueue() generates (fmq_sync<uint8_t> queue);

	/**
	* getCaptureResultMetadataQueue:
	*
	* Retrieves the queue used along with
	* ICameraDeviceCallback.processCaptureResult.
	*
	* Clients to ICameraDeviceSession must:
	* - Call getCaptureRequestMetadataQueue to retrieve the fast message queue;
	* - In implementation of ICameraDeviceCallback, test whether
	* .fmqResultSize field is zero.
	* - If .fmqResultSize != 0, read result metadata from the fast message
	* queue;
	* - otherwise, read result metadata in CaptureResult.result.
	*
	* @return queue the queue that implementation writes result metadata to.
	*/
	getCaptureResultMetadataQueue() generates (fmq_sync<uint8_t> queue);

	/**
	* flush:
	*
	* Flush all currently in-process captures and all buffers in the pipeline
	* on the given device. Generally, this method is used to dump all state as
	* quickly as possible in order to prepare for a configure_streams() call.
	*
	* No buffers are required to be successfully returned, so every buffer
	* held at the time of flush() (whether successfully filled or not) may be
	* returned with CAMERA3_BUFFER_STATUS_ERROR. Note the HAL is still allowed
	* to return valid (CAMERA3_BUFFER_STATUS_OK) buffers during this call,
	* provided they are successfully filled.
	*
	* All requests currently in the HAL are expected to be returned as soon as
	* possible. Not-in-process requests must return errors immediately. Any
	* interruptible hardware blocks must be stopped, and any uninterruptible
	* blocks must be waited on.
	*
	* flush() may be called concurrently to processCaptureRequest(), with the
	* expectation that processCaptureRequest returns quickly and the
	* request submitted in that processCaptureRequest call is treated like
	* all other in-flight requests. Due to concurrency issues, it is possible
	* that from the HAL's point of view, a processCaptureRequest() call may
	* be started after flush has been invoked but has not returned yet. If such
	* a call happens before flush() returns, the HAL must treat the new
	* capture request like other in-flight pending requests (see #4 below).
	*
	* More specifically, the HAL must follow below requirements for various
	* cases:
	*
	* 1. For captures that are too late for the HAL to cancel/stop, and must be
	* completed normally by the HAL; i.e. the HAL can send shutter/notify
	* and processCaptureResult and buffers as normal.
	*
	* 2. For pending requests that have not done any processing, the HAL must
	* call notify CAMERA3_MSG_ERROR_REQUEST, and return all the output
	* buffers with processCaptureResult in the error state
	* (CAMERA3_BUFFER_STATUS_ERROR). The HAL must not place the release
	* fence into an error state, instead, the release fences must be set to
	* the acquire fences passed by the framework, or -1 if they have been
	* waited on by the HAL already. This is also the path to follow for any
	* captures for which the HAL already called notify() with
	* CAMERA3_MSG_SHUTTER but won't be producing any metadata/valid buffers
	* for. After CAMERA3_MSG_ERROR_REQUEST, for a given frame, only
	* processCaptureResults with buffers in CAMERA3_BUFFER_STATUS_ERROR
	* are allowed. No further notifys or processCaptureResult with
	* non-empty metadata is allowed.
	*
	* 3. For partially completed pending requests that do not have all the
	* output buffers or perhaps missing metadata, the HAL must follow
	* below:
	*
	* 3.1. Call notify with CAMERA3_MSG_ERROR_RESULT if some of the expected
	* result metadata (i.e. one or more partial metadata) won't be
	* available for the capture.
	*
	* 3.2. Call notify with CAMERA3_MSG_ERROR_BUFFER for every buffer that
	* won't be produced for the capture.
	*
	* 3.3. Call notify with CAMERA3_MSG_SHUTTER with the capture timestamp
	* before any buffers/metadata are returned with
	* processCaptureResult.
	*
	* 3.4. For captures that will produce some results, the HAL must not
	* call CAMERA3_MSG_ERROR_REQUEST, since that indicates complete
	* failure.
	*
	* 3.5. Valid buffers/metadata must be passed to the framework as
	* normal.
	*
	* 3.6. Failed buffers must be returned to the framework as described
	* for case 2. But failed buffers do not have to follow the strict
	* ordering valid buffers do, and may be out-of-order with respect
	* to valid buffers. For example, if buffers A, B, C, D, E are sent,
	* D and E are failed, then A, E, B, D, C is an acceptable return
	* order.
	*
	* 3.7. For fully-missing metadata, calling CAMERA3_MSG_ERROR_RESULT is
	* sufficient, no need to call processCaptureResult with empty
	* metadata or equivalent.
	*
	* 4. If a flush() is invoked while a processCaptureRequest() invocation
	* is active, that process call must return as soon as possible. In
	* addition, if a processCaptureRequest() call is made after flush()
	* has been invoked but before flush() has returned, the capture request
	* provided by the late processCaptureRequest call must be treated
	* like a pending request in case #2 above.
	*
	* flush() must only return when there are no more outstanding buffers or
	* requests left in the HAL. The framework may call configure_streams (as
	* the HAL state is now quiesced) or may issue new requests.
	*
	* Note that it's sufficient to only support fully-succeeded and
	* fully-failed result cases. However, it is highly desirable to support
	* the partial failure cases as well, as it could help improve the flush
	* call overall performance.
	*
	* Performance requirements:
	*
	* The HAL should return from this call in 100ms, and must return from this
	* call in 1000ms. And this call must not be blocked longer than pipeline
	* latency (see S7 for definition).
	*
	* @return status Status code for the operation, one of:
	* OK:
	* On a successful flush of the camera HAL.
	* INTERNAL_ERROR:
	* If the camera device has encountered a serious error. After this
	* error is returned, only the close() method can be successfully
	* called by the framework.
	*/
	flush() generates (Status status);

	/**
	* close:
	*
	* Shut down the camera device.
	*
	* After this call, all calls to this session instance must return
	* INTERNAL_ERROR.
	*
	* This method must always succeed, even if the device has encountered a
	* serious error.
	*/
	close();
	};