sensors/2.0/ISensors.hal - platform/hardware/interfaces - Git at Google

 /*
  * Copyright (C) 2018 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.sensors@2.0;

 import @1.0::Event;
 import @1.0::OperationMode;
 import @1.0::RateLevel;
 import @1.0::Result;
 import @1.0::SensorInfo;
 import @1.0::SharedMemInfo;
 import @2.0::ISensorsCallback;

 interface ISensors {
     /**
      * Enumerate all available (static) sensors.
      *
      * The SensorInfo for each sensor returned by getSensorsList must be stable
      * from the initial call to getSensorsList after a device boot until the
      * entire system restarts. The SensorInfo for each sensor must not change
      * between subsequent calls to getSensorsList, even across restarts of the
      * HAL and its dependencies (for example, the sensor handle for a given
      * sensor must not change across HAL restarts).
      */
     getSensorsList() generates (vec<SensorInfo> list);

     /**
      * Place the module in a specific mode. The following modes are defined
      *
      *  SENSOR_HAL_NORMAL_MODE - Normal operation. Default state of the module.
      *
      *  SENSOR_HAL_DATA_INJECTION_MODE - Loopback mode.
      *    Data is injected for the supported sensors by the sensor service in
      *    this mode.
      *
      * @return OK on success
      *     BAD_VALUE if requested mode is not supported
      *     PERMISSION_DENIED if operation is not allowed
      */
     setOperationMode(OperationMode mode) generates (Result result);

     /**
      * Activate/de-activate one sensor.
      *
      * After sensor de-activation, existing sensor events that have not
      * been written to the event queue must be abandoned immediately so that
      * subsequent activations do not get stale sensor events (events
      * that are generated prior to the latter activation).
      *
      * @param sensorHandle is the handle of the sensor to change.
      * @param enabled set to true to enable, or false to disable the sensor.
      * @return result OK on success, BAD_VALUE if sensorHandle is invalid.
      */
     activate(int32_t sensorHandle, bool enabled) generates (Result result);

     /**
      * Initialize the Sensors HAL's Fast Message Queues (FMQ) and callback.
      *
      * The Fast Message Queues (FMQ) that are used to send data between the
      * framework and the HAL. The callback is used by the HAL to notify the
      * framework of asynchronous events, such as a dynamic sensor connection.
      *
      * The Event FMQ is used to transport sensor events from the HAL to the
      * framework. The Event FMQ is created using the eventQueueDescriptor.
      * Data may only be written to the Event FMQ. Data must not be read from
      * the Event FMQ since the framework is the only reader. Upon receiving
      * sensor events, the HAL writes the sensor events to the Event FMQ.
      *
      * Once the HAL is finished writing sensor events to the Event FMQ, the HAL
      * must notify the framework that sensor events are available to be read and
      * processed. This is accomplished by either:
      *     1) Calling the Event FMQ’s EventFlag::wake() function with
               EventQueueFlagBits::READ_AND_PROCESS
      *     2) Setting the write notification in the Event FMQ’s writeBlocking()
      *        function to EventQueueFlagBits::READ_AND_PROCESS.
      *
      * If the Event FMQ’s writeBlocking() function is used, the read
      * notification must be set to EventQueueFlagBits::EVENTS_READ in order to
      * be notified and unblocked when the framework has successfully read events
      * from the Event FMQ.
      *
      * The Wake Lock FMQ is used by the framework to notify the HAL when it is
      * safe to release its wake_lock. When the framework receives WAKE_UP events
      * from the Event FMQ and the framework has acquired a wake_lock, the
      * framework must write the number of WAKE_UP events processed to the Wake
      * Lock FMQ. When the HAL reads the data from the Wake Lock FMQ, the HAL
      * decrements its current count of unprocessed WAKE_UP events and releases
      * its wake_lock if the current count of unprocessed WAKE_UP events is
      * zero. It is important to note that the HAL must acquire the wake lock and
      * update its internal state regarding the number of outstanding WAKE_UP
      * events _before_ posting the event to the Wake Lock FMQ, in order to avoid
      * a race condition that can lead to loss of wake lock synchronization with
      * the framework.
      *
      * The framework must use the WakeLockQueueFlagBits::DATA_WRITTEN value to
      * notify the HAL that data has been written to the Wake Lock FMQ and must
      * be read by HAL.
      *
      * The ISensorsCallback is used by the HAL to notify the framework of
      * asynchronous events, such as a dynamic sensor connection.
      *
      * The name of any wake_lock acquired by the Sensors HAL for WAKE_UP events
      * must begin with "SensorsHAL_WAKEUP".
      *
      * If WAKE_LOCK_TIMEOUT_SECONDS has elapsed since the most recent WAKE_UP
      * event was written to the Event FMQ without receiving a message on the
      * Wake Lock FMQ, then any held wake_lock for WAKE_UP events must be
      * released.
      *
      * If either the Event FMQ or the Wake Lock FMQ is already initialized when
      * initialize is invoked, then both existing FMQs must be discarded and the
      * new descriptors must be used to create new FMQs within the HAL. The
      * number of outstanding WAKE_UP events should also be reset to zero, and
      * any outstanding wake_locks held as a result of WAKE_UP events should be
      * released.
      *
      * All active sensor requests and direct channels must be closed and
      * properly cleaned up when initialize is called in order to ensure that the
      * HAL and framework's state is consistent (e.g. after a runtime restart).
      *
      * initialize must be thread safe and prevent concurrent calls
      * to initialize from simultaneously modifying state.
      *
      * @param eventQueueDescriptor Fast Message Queue descriptor that is used to
      *     create the Event FMQ which is where sensor events are written. The
      *     descriptor is obtained from the framework's FMQ that is used to read
      *     sensor events.
      * @param wakeLockDescriptor Fast Message Queue descriptor that is used to
      *     create the Wake Lock FMQ which is where wake_lock events are read
      *     from. The descriptor is obtained from the framework's FMQ that is
      *     used to write wake_lock events.
      * @param sensorsCallback sensors callback that receives asynchronous data
      *     from the Sensors HAL.
      * @return result OK on success; BAD_VALUE if descriptor is invalid (such
      *     as null)
      */
     @entry
     @callflow(next = {"getSensorsList"})
     initialize(fmq_sync<Event> eventQueueDescriptor,
                fmq_sync<uint32_t> wakeLockDescriptor,
                ISensorsCallback sensorsCallback)
         generates
               (Result result);

     /**
      * Sets a sensor’s parameters, including sampling frequency and maximum
      * report latency. This function can be called while the sensor is
      * activated, in which case it must not cause any sensor measurements to
      * be lost: transitioning from one sampling rate to the other cannot cause
      * lost events, nor can transitioning from a high maximum report latency to
      * a low maximum report latency.
      *
      * @param sensorHandle handle of sensor to be changed.
      * @param samplingPeriodNs specifies sensor sample period in nanoseconds.
      * @param maxReportLatencyNs allowed delay time before an event is sampled
      *     to time of report.
      * @return result OK on success, BAD_VALUE if any parameters are invalid.
      */
     batch(int32_t sensorHandle,
           int64_t samplingPeriodNs,
           int64_t maxReportLatencyNs)
         generates (
           Result result);

     /**
      * Trigger a flush of internal FIFO.
      *
      * Flush adds a FLUSH_COMPLETE metadata event to the end of the "batch mode"
      * FIFO for the specified sensor and flushes the FIFO.  If the FIFO is empty
      * or if the sensor doesn't support batching (FIFO size zero), return
      * SUCCESS and add a trivial FLUSH_COMPLETE event added to the event stream.
      * This applies to all sensors other than one-shot sensors. If the sensor
      * is a one-shot sensor, flush must return BAD_VALUE and not generate any
      * flush complete metadata.  If the sensor is not active at the time flush()
      * is called, flush() return BAD_VALUE.
      *
      * @param sensorHandle handle of sensor to be flushed.
      * @return result OK on success and BAD_VALUE if sensorHandle is invalid.
      */
     flush(int32_t sensorHandle) generates (Result result);

     /**
      * Inject a single sensor event or push operation environment parameters to
      * device.
      *
      * When device is in NORMAL mode, this function is called to push operation
      * environment data to device. In this operation, Event is always of
      * SensorType::AdditionalInfo type. See operation evironment parameters
      * section in AdditionalInfoType.
      *
      * When device is in DATA_INJECTION mode, this function is also used for
      * injecting sensor events.
      *
      * Regardless of OperationMode, injected SensorType::ADDITIONAL_INFO
      * type events should not be routed back to the sensor event queue.
      *
      * @see AdditionalInfoType
      * @see OperationMode
      * @param event sensor event to be injected
      * @return result OK on success; PERMISSION_DENIED if operation is not
      *     allowed; INVALID_OPERATION, if this functionality is unsupported;
      *     BAD_VALUE if sensor event cannot be injected.
      */
     injectSensorData(Event event) generates (Result result);

     /**
      * Register direct report channel.
      *
      * Register a direct channel with supplied shared memory information. Upon
      * return, the sensor hardware is responsible for resetting the memory
      * content to initial value (depending on memory format settings).
      *
      * @param mem shared memory info data structure.
      * @return result OK on success; BAD_VALUE if shared memory information is
      *     not consistent; NO_MEMORY if shared memory cannot be used by sensor
      *     system; INVALID_OPERATION if functionality is not supported.
      * @return channelHandle a positive integer used for referencing registered
      *     direct channel (>0) in configureDirectReport and
      *     unregisterDirectChannel if result is OK, -1 otherwise.
      */
     registerDirectChannel(SharedMemInfo mem)
                generates (Result result,
                           int32_t channelHandle);

     /**
      * Unregister direct report channel.
      *
      * Unregister a direct channel previously registered using
      * registerDirectChannel, and remove all active sensor report configured in
      * still active sensor report configured in the direct channel.
      *
      * @param channelHandle handle of direct channel to be unregistered.
      * @return result OK if direct report is supported; INVALID_OPERATION
      *     otherwise.
      */
     unregisterDirectChannel(int32_t channelHandle) generates (Result result);

     /**
      * Configure direct sensor event report in direct channel.
      *
      * This function start, modify rate or stop direct report of a sensor in a
      * certain direct channel.
      *
      * @param sensorHandle handle of sensor to be configured. When combined
      *     with STOP rate, sensorHandle can be -1 to denote all active sensors
      *     in the direct channel specified by channel Handle.
      * @param channelHandle handle of direct channel to be configured.
      * @param rate rate level, see RateLevel enum.
      * @return result OK on success; BAD_VALUE if parameter is invalid (such as
      *     rate level is not supported by sensor, channelHandle does not exist,
      *     etc); INVALID_OPERATION if functionality is not supported.
      * @return reportToken positive integer to identify multiple sensors of
      *     the same type in a single direct channel. Ignored if rate is STOP.
      *     See SharedMemFormat.
      */
     configDirectReport(
             int32_t sensorHandle,
             int32_t channelHandle,
             RateLevel rate
         ) generates (
             Result result,
             int32_t reportToken);
 };
	/*
	* Copyright (C) 2018 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.sensors@2.0;

	import @1.0::Event;
	import @1.0::OperationMode;
	import @1.0::RateLevel;
	import @1.0::Result;
	import @1.0::SensorInfo;
	import @1.0::SharedMemInfo;
	import @2.0::ISensorsCallback;

	interface ISensors {
	/**
	* Enumerate all available (static) sensors.
	*
	* The SensorInfo for each sensor returned by getSensorsList must be stable
	* from the initial call to getSensorsList after a device boot until the
	* entire system restarts. The SensorInfo for each sensor must not change
	* between subsequent calls to getSensorsList, even across restarts of the
	* HAL and its dependencies (for example, the sensor handle for a given
	* sensor must not change across HAL restarts).
	*/
	getSensorsList() generates (vec<SensorInfo> list);

	/**
	* Place the module in a specific mode. The following modes are defined
	*
	* SENSOR_HAL_NORMAL_MODE - Normal operation. Default state of the module.
	*
	* SENSOR_HAL_DATA_INJECTION_MODE - Loopback mode.
	* Data is injected for the supported sensors by the sensor service in
	* this mode.
	*
	* @return OK on success
	* BAD_VALUE if requested mode is not supported
	* PERMISSION_DENIED if operation is not allowed
	*/
	setOperationMode(OperationMode mode) generates (Result result);

	/**
	* Activate/de-activate one sensor.
	*
	* After sensor de-activation, existing sensor events that have not
	* been written to the event queue must be abandoned immediately so that
	* subsequent activations do not get stale sensor events (events
	* that are generated prior to the latter activation).
	*
	* @param sensorHandle is the handle of the sensor to change.
	* @param enabled set to true to enable, or false to disable the sensor.
	* @return result OK on success, BAD_VALUE if sensorHandle is invalid.
	*/
	activate(int32_t sensorHandle, bool enabled) generates (Result result);

	/**
	* Initialize the Sensors HAL's Fast Message Queues (FMQ) and callback.
	*
	* The Fast Message Queues (FMQ) that are used to send data between the
	* framework and the HAL. The callback is used by the HAL to notify the
	* framework of asynchronous events, such as a dynamic sensor connection.
	*
	* The Event FMQ is used to transport sensor events from the HAL to the
	* framework. The Event FMQ is created using the eventQueueDescriptor.
	* Data may only be written to the Event FMQ. Data must not be read from
	* the Event FMQ since the framework is the only reader. Upon receiving
	* sensor events, the HAL writes the sensor events to the Event FMQ.
	*
	* Once the HAL is finished writing sensor events to the Event FMQ, the HAL
	* must notify the framework that sensor events are available to be read and
	* processed. This is accomplished by either:
	* 1) Calling the Event FMQ’s EventFlag::wake() function with
	EventQueueFlagBits::READ_AND_PROCESS
	* 2) Setting the write notification in the Event FMQ’s writeBlocking()
	* function to EventQueueFlagBits::READ_AND_PROCESS.
	*
	* If the Event FMQ’s writeBlocking() function is used, the read
	* notification must be set to EventQueueFlagBits::EVENTS_READ in order to
	* be notified and unblocked when the framework has successfully read events
	* from the Event FMQ.
	*
	* The Wake Lock FMQ is used by the framework to notify the HAL when it is
	* safe to release its wake_lock. When the framework receives WAKE_UP events
	* from the Event FMQ and the framework has acquired a wake_lock, the
	* framework must write the number of WAKE_UP events processed to the Wake
	* Lock FMQ. When the HAL reads the data from the Wake Lock FMQ, the HAL
	* decrements its current count of unprocessed WAKE_UP events and releases
	* its wake_lock if the current count of unprocessed WAKE_UP events is
	* zero. It is important to note that the HAL must acquire the wake lock and
	* update its internal state regarding the number of outstanding WAKE_UP
	* events _before_ posting the event to the Wake Lock FMQ, in order to avoid
	* a race condition that can lead to loss of wake lock synchronization with
	* the framework.
	*
	* The framework must use the WakeLockQueueFlagBits::DATA_WRITTEN value to
	* notify the HAL that data has been written to the Wake Lock FMQ and must
	* be read by HAL.
	*
	* The ISensorsCallback is used by the HAL to notify the framework of
	* asynchronous events, such as a dynamic sensor connection.
	*
	* The name of any wake_lock acquired by the Sensors HAL for WAKE_UP events
	* must begin with "SensorsHAL_WAKEUP".
	*
	* If WAKE_LOCK_TIMEOUT_SECONDS has elapsed since the most recent WAKE_UP
	* event was written to the Event FMQ without receiving a message on the
	* Wake Lock FMQ, then any held wake_lock for WAKE_UP events must be
	* released.
	*
	* If either the Event FMQ or the Wake Lock FMQ is already initialized when
	* initialize is invoked, then both existing FMQs must be discarded and the
	* new descriptors must be used to create new FMQs within the HAL. The
	* number of outstanding WAKE_UP events should also be reset to zero, and
	* any outstanding wake_locks held as a result of WAKE_UP events should be
	* released.
	*
	* All active sensor requests and direct channels must be closed and
	* properly cleaned up when initialize is called in order to ensure that the
	* HAL and framework's state is consistent (e.g. after a runtime restart).
	*
	* initialize must be thread safe and prevent concurrent calls
	* to initialize from simultaneously modifying state.
	*
	* @param eventQueueDescriptor Fast Message Queue descriptor that is used to
	* create the Event FMQ which is where sensor events are written. The
	* descriptor is obtained from the framework's FMQ that is used to read
	* sensor events.
	* @param wakeLockDescriptor Fast Message Queue descriptor that is used to
	* create the Wake Lock FMQ which is where wake_lock events are read
	* from. The descriptor is obtained from the framework's FMQ that is
	* used to write wake_lock events.
	* @param sensorsCallback sensors callback that receives asynchronous data
	* from the Sensors HAL.
	* @return result OK on success; BAD_VALUE if descriptor is invalid (such
	* as null)
	*/
	@entry
	@callflow(next = {"getSensorsList"})
	initialize(fmq_sync<Event> eventQueueDescriptor,
	fmq_sync<uint32_t> wakeLockDescriptor,
	ISensorsCallback sensorsCallback)
	generates
	(Result result);

	/**
	* Sets a sensor’s parameters, including sampling frequency and maximum
	* report latency. This function can be called while the sensor is
	* activated, in which case it must not cause any sensor measurements to
	* be lost: transitioning from one sampling rate to the other cannot cause
	* lost events, nor can transitioning from a high maximum report latency to
	* a low maximum report latency.
	*
	* @param sensorHandle handle of sensor to be changed.
	* @param samplingPeriodNs specifies sensor sample period in nanoseconds.
	* @param maxReportLatencyNs allowed delay time before an event is sampled
	* to time of report.
	* @return result OK on success, BAD_VALUE if any parameters are invalid.
	*/
	batch(int32_t sensorHandle,
	int64_t samplingPeriodNs,
	int64_t maxReportLatencyNs)
	generates (
	Result result);

	/**
	* Trigger a flush of internal FIFO.
	*
	* Flush adds a FLUSH_COMPLETE metadata event to the end of the "batch mode"
	* FIFO for the specified sensor and flushes the FIFO. If the FIFO is empty
	* or if the sensor doesn't support batching (FIFO size zero), return
	* SUCCESS and add a trivial FLUSH_COMPLETE event added to the event stream.
	* This applies to all sensors other than one-shot sensors. If the sensor
	* is a one-shot sensor, flush must return BAD_VALUE and not generate any
	* flush complete metadata. If the sensor is not active at the time flush()
	* is called, flush() return BAD_VALUE.
	*
	* @param sensorHandle handle of sensor to be flushed.
	* @return result OK on success and BAD_VALUE if sensorHandle is invalid.
	*/
	flush(int32_t sensorHandle) generates (Result result);

	/**
	* Inject a single sensor event or push operation environment parameters to
	* device.
	*
	* When device is in NORMAL mode, this function is called to push operation
	* environment data to device. In this operation, Event is always of
	* SensorType::AdditionalInfo type. See operation evironment parameters
	* section in AdditionalInfoType.
	*
	* When device is in DATA_INJECTION mode, this function is also used for
	* injecting sensor events.
	*
	* Regardless of OperationMode, injected SensorType::ADDITIONAL_INFO
	* type events should not be routed back to the sensor event queue.
	*
	* @see AdditionalInfoType
	* @see OperationMode
	* @param event sensor event to be injected
	* @return result OK on success; PERMISSION_DENIED if operation is not
	* allowed; INVALID_OPERATION, if this functionality is unsupported;
	* BAD_VALUE if sensor event cannot be injected.
	*/
	injectSensorData(Event event) generates (Result result);

	/**
	* Register direct report channel.
	*
	* Register a direct channel with supplied shared memory information. Upon
	* return, the sensor hardware is responsible for resetting the memory
	* content to initial value (depending on memory format settings).
	*
	* @param mem shared memory info data structure.
	* @return result OK on success; BAD_VALUE if shared memory information is
	* not consistent; NO_MEMORY if shared memory cannot be used by sensor
	* system; INVALID_OPERATION if functionality is not supported.
	* @return channelHandle a positive integer used for referencing registered
	* direct channel (>0) in configureDirectReport and
	* unregisterDirectChannel if result is OK, -1 otherwise.
	*/
	registerDirectChannel(SharedMemInfo mem)
	generates (Result result,
	int32_t channelHandle);

	/**
	* Unregister direct report channel.
	*
	* Unregister a direct channel previously registered using
	* registerDirectChannel, and remove all active sensor report configured in
	* still active sensor report configured in the direct channel.
	*
	* @param channelHandle handle of direct channel to be unregistered.
	* @return result OK if direct report is supported; INVALID_OPERATION
	* otherwise.
	*/
	unregisterDirectChannel(int32_t channelHandle) generates (Result result);

	/**
	* Configure direct sensor event report in direct channel.
	*
	* This function start, modify rate or stop direct report of a sensor in a
	* certain direct channel.
	*
	* @param sensorHandle handle of sensor to be configured. When combined
	* with STOP rate, sensorHandle can be -1 to denote all active sensors
	* in the direct channel specified by channel Handle.
	* @param channelHandle handle of direct channel to be configured.
	* @param rate rate level, see RateLevel enum.
	* @return result OK on success; BAD_VALUE if parameter is invalid (such as
	* rate level is not supported by sensor, channelHandle does not exist,
	* etc); INVALID_OPERATION if functionality is not supported.
	* @return reportToken positive integer to identify multiple sensors of
	* the same type in a single direct channel. Ignored if rate is STOP.
	* See SharedMemFormat.
	*/
	configDirectReport(
	int32_t sensorHandle,
	int32_t channelHandle,
	RateLevel rate
	) generates (
	Result result,
	int32_t reportToken);
	};