platform_hardware_libhardware/include/hardware/fused_location.h

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/*
* Copyright (C) 2013 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#ifndef ANDROID_INCLUDE_HARDWARE_FUSED_LOCATION_H
#define ANDROID_INCLUDE_HARDWARE_FUSED_LOCATION_H
#include <hardware/hardware.h>
/**
* This header file defines the interface of the Fused Location Provider.
* Fused Location Provider is designed to fuse data from various sources
* like GPS, Wifi, Cell, Sensors, Bluetooth etc to provide a fused location to the
* upper layers. The advantage of doing fusion in hardware is power savings.
* The goal is to do this without waking up the AP to get additional data.
* The software implementation of FLP will decide when to use
* the hardware fused location. Other location features like geofencing will
* also be implemented using fusion in hardware.
*/
__BEGIN_DECLS
#define FLP_HEADER_VERSION 1
#define FLP_MODULE_API_VERSION_0_1 HARDWARE_MODULE_API_VERSION(0, 1)
#define FLP_DEVICE_API_VERSION_0_1 HARDWARE_DEVICE_API_VERSION_2(0, 1, FLP_HEADER_VERSION)
/**
* The id of this module
*/
#define FUSED_LOCATION_HARDWARE_MODULE_ID "flp"
/**
* Name for the FLP location interface
*/
#define FLP_LOCATION_INTERFACE "flp_location"
/**
* Name for the FLP location interface
*/
#define FLP_DIAGNOSTIC_INTERFACE "flp_diagnostic"
/**
* Name for the FLP_Geofencing interface.
*/
#define FLP_GEOFENCING_INTERFACE "flp_geofencing"
/**
* Name for the FLP_device context interface.
*/
#define FLP_DEVICE_CONTEXT_INTERFACE "flp_device_context"
/**
* Constants to indicate the various subsystems
* that will be used.
*/
#define FLP_TECH_MASK_GNSS (1U<<0)
#define FLP_TECH_MASK_WIFI (1U<<1)
#define FLP_TECH_MASK_SENSORS (1U<<2)
#define FLP_TECH_MASK_CELL (1U<<3)
#define FLP_TECH_MASK_BLUETOOTH (1U<<4)
/**
* This constant is used with the batched locations
* APIs. Batching is mandatory when FLP implementation
* is supported. If the flag is set, the hardware implementation
* will wake up the application processor when the FIFO is full,
* If the flag is not set, the hardware implementation will drop
* the oldest data when the FIFO is full.
*/
#define FLP_BATCH_WAKEUP_ON_FIFO_FULL 0x0000001
/**
* While batching, the implementation should not call the
* flp_location_callback on every location fix. However,
* sometimes in high power mode, the system might need
* a location callback every single time the location
* fix has been obtained. This flag controls that option.
* Its the responsibility of the upper layers (caller) to switch
* it off, if it knows that the AP might go to sleep.
* When this bit is on amidst a batching session, batching should
* continue while location fixes are reported in real time.
*/
#define FLP_BATCH_CALLBACK_ON_LOCATION_FIX 0x0000002
/** Flags to indicate which values are valid in a FlpLocation. */
typedef uint16_t FlpLocationFlags;
// IMPORTANT: Note that the following values must match
// constants in the corresponding java file.
/** FlpLocation has valid latitude and longitude. */
#define FLP_LOCATION_HAS_LAT_LONG (1U<<0)
/** FlpLocation has valid altitude. */
#define FLP_LOCATION_HAS_ALTITUDE (1U<<1)
/** FlpLocation has valid speed. */
#define FLP_LOCATION_HAS_SPEED (1U<<2)
/** FlpLocation has valid bearing. */
#define FLP_LOCATION_HAS_BEARING (1U<<4)
/** FlpLocation has valid accuracy. */
#define FLP_LOCATION_HAS_ACCURACY (1U<<8)
typedef int64_t FlpUtcTime;
/** Represents a location. */
typedef struct {
/** set to sizeof(FlpLocation) */
size_t size;
/** Flags associated with the location object. */
FlpLocationFlags flags;
/** Represents latitude in degrees. */
double latitude;
/** Represents longitude in degrees. */
double longitude;
/**
* Represents altitude in meters above the WGS 84 reference
* ellipsoid. */
double altitude;
/** Represents speed in meters per second. */
float speed;
/** Represents heading in degrees. */
float bearing;
/** Represents expected accuracy in meters. */
float accuracy;
/** Timestamp for the location fix. */
FlpUtcTime timestamp;
/** Sources used, will be Bitwise OR of the FLP_TECH_MASK bits. */
uint32_t sources_used;
} FlpLocation;
typedef enum {
ASSOCIATE_JVM,
DISASSOCIATE_JVM,
} ThreadEvent;
/**
* Callback with location information.
* Can only be called from a thread associated to JVM using set_thread_event_cb.
* Parameters:
* num_locations is the number of batched locations available.
* location is the pointer to an array of pointers to location objects.
*/
typedef void (*flp_location_callback)(int32_t num_locations, FlpLocation** location);
/**
* Callback utility for acquiring a wakelock.
* This can be used to prevent the CPU from suspending while handling FLP events.
*/
typedef void (*flp_acquire_wakelock)();
/**
* Callback utility for releasing the FLP wakelock.
*/
typedef void (*flp_release_wakelock)();
/**
* Callback for associating a thread that can call into the Java framework code.
* This must be used to initialize any threads that report events up to the framework.
* Return value:
* FLP_RESULT_SUCCESS on success.
* FLP_RESULT_ERROR if the association failed in the current thread.
*/
typedef int (*flp_set_thread_event)(ThreadEvent event);
/** FLP callback structure. */
typedef struct {
/** set to sizeof(FlpCallbacks) */
size_t size;
flp_location_callback location_cb;
flp_acquire_wakelock acquire_wakelock_cb;
flp_release_wakelock release_wakelock_cb;
flp_set_thread_event set_thread_event_cb;
} FlpCallbacks;
/** Options with the batching FLP APIs */
typedef struct {
/**
* Maximum power in mW that the underlying implementation
* can use for this batching call.
* If max_power_allocation_mW is 0, only fixes that are generated
* at no additional cost of power shall be reported.
*/
double max_power_allocation_mW;
/** Bitwise OR of the FLP_TECH_MASKS to use */
uint32_t sources_to_use;
/**
* FLP_BATCH_WAKEUP_ON_FIFO_FULL - If set the hardware
* will wake up the AP when the buffer is full. If not set, the
* hardware will drop the oldest location object.
*
* FLP_BATCH_CALLBACK_ON_LOCATION_FIX - If set the location
* callback will be called every time there is a location fix.
* Its the responsibility of the upper layers (caller) to switch
* it off, if it knows that the AP might go to sleep. When this
* bit is on amidst a batching session, batching should continue
* while location fixes are reported in real time.
*
* Other flags to be bitwised ORed in the future.
*/
uint32_t flags;
/**
* Frequency with which location needs to be batched in nano
* seconds.
*/
int64_t period_ns;
} FlpBatchOptions;
#define FLP_RESULT_SUCCESS 0
#define FLP_RESULT_ERROR -1
#define FLP_RESULT_INSUFFICIENT_MEMORY -2
#define FLP_RESULT_TOO_MANY_GEOFENCES -3
#define FLP_RESULT_ID_EXISTS -4
#define FLP_RESULT_ID_UNKNOWN -5
#define FLP_RESULT_INVALID_GEOFENCE_TRANSITION -6
/**
* Represents the standard FLP interface.
*/
typedef struct {
/**
* set to sizeof(FlpLocationInterface)
*/
size_t size;
/**
* Opens the interface and provides the callback routines
* to the implemenation of this interface.
*/
int (*init)(FlpCallbacks* callbacks );
/**
* Return the batch size (in number of FlpLocation objects)
* available in the hardware. Note, different HW implementations
* may have different sample sizes. This shall return number
* of samples defined in the format of FlpLocation.
* This will be used by the upper layer, to decide on the batching
* interval and whether the AP should be woken up or not.
*/
int (*get_batch_size)();
/**
* Start batching locations. This API is primarily used when the AP is
* asleep and the device can batch locations in the hardware.
* flp_location_callback is used to return the locations. When the buffer
* is full and FLP_BATCH_WAKEUP_ON_FIFO_FULL is used, the AP is woken up.
* When the buffer is full and FLP_BATCH_WAKEUP_ON_FIFO_FULL is not set,
* the oldest location object is dropped. In this case the AP will not be
* woken up. The upper layer will use get_batched_location
* API to explicitly ask for the location.
* If FLP_BATCH_CALLBACK_ON_LOCATION_FIX is set, the implementation
* will call the flp_location_callback every single time there is a location
* fix. This overrides FLP_BATCH_WAKEUP_ON_FIFO_FULL flag setting.
* It's the responsibility of the upper layers (caller) to switch
* it off, if it knows that the AP might go to sleep. This is useful
* for nagivational applications when the system is in high power mode.
* Parameters:
* id - Id for the request.
* options - See FlpBatchOptions struct definition.
* Return value:
* FLP_RESULT_SUCCESS on success, FLP_RESULT_INSUFFICIENT_MEMORY,
* FLP_RESULT_ID_EXISTS, FLP_RESULT_ERROR on failure.
*/
int (*start_batching)(int id, FlpBatchOptions* options);
/**
* Update FlpBatchOptions associated with a batching request.
* When a batching operation is in progress and a batching option
* such as FLP_BATCH_WAKEUP_ON_FIFO_FULL needs to be updated, this API
* will be used. For instance, this can happen when the AP is awake and
* the maps application is being used.
* Parameters:
* id - Id of an existing batch request.
* new_options - Updated FlpBatchOptions
* Return value:
* FLP_RESULT_SUCCESS on success, FLP_RESULT_ID_UNKNOWN,
* FLP_RESULT_ERROR on error.
*/
int (*update_batching_options)(int id, FlpBatchOptions* new_options);
/**
* Stop batching.
* Parameters:
* id - Id for the request.
* Return Value:
* FLP_RESULT_SUCCESS on success, FLP_RESULT_ID_UNKNOWN or
* FLP_RESULT_ERROR on failure.
*/
int (*stop_batching)(int id);
/**
* Closes the interface. If any batch operations are in progress,
* they should be stopped.
*/
void (*cleanup)();
/**
* Get the fused location that was batched.
* flp_location_callback is used to return the location. The location object
* is dropped from the buffer only when the buffer is full. Do not remove it
* from the buffer just because it has been returned using the callback.
* In other words, when there is no new location object, two calls to
* get_batched_location(1) should return the same location object.
* Parameters:
* last_n_locations - Number of locations to get. This can be one or many.
* If the last_n_locations is 1, you get the latest location known to the
* hardware.
*/
void (*get_batched_location)(int last_n_locations);
/**
* Injects current location from another location provider
* latitude and longitude are measured in degrees
* expected accuracy is measured in meters
* Parameters:
* location - The location object being injected.
* Return value: FLP_RESULT_SUCCESS or FLP_RESULT_ERROR.
*/
int (*inject_location)(FlpLocation* location);
/**
* Get a pointer to extension information.
*/
const void* (*get_extension)(const char* name);
} FlpLocationInterface;
struct flp_device_t {
struct hw_device_t common;
/**
* Get a handle to the FLP Interface.
*/
const FlpLocationInterface* (*get_flp_interface)(struct flp_device_t* dev);
};
/**
* Callback for reports diagnostic data into the Java framework code.
*/
typedef void (*report_data)(char* data, int length);
/**
* FLP diagnostic callback structure.
* Currently, not used - but this for future extension.
*/
typedef struct {
/** set to sizeof(FlpDiagnosticCallbacks) */
size_t size;
flp_set_thread_event set_thread_event_cb;
/** reports diagnostic data into the Java framework code */
report_data data_cb;
} FlpDiagnosticCallbacks;
/** Extended interface for diagnostic support. */
typedef struct {
/** set to sizeof(FlpDiagnosticInterface) */
size_t size;
/**
* Opens the diagnostic interface and provides the callback routines
* to the implemenation of this interface.
*/
void (*init)(FlpDiagnosticCallbacks* callbacks);
/**
* Injects diagnostic data into the FLP subsystem.
* Return 0 on success, -1 on error.
**/
int (*inject_data)(char* data, int length );
} FlpDiagnosticInterface;
/**
* Context setting information.
* All these settings shall be injected to FLP HAL at FLP init time.
* Following that, only the changed setting need to be re-injected
* upon changes.
*/
#define FLP_DEVICE_CONTEXT_GPS_ENABLED (1U<<0)
#define FLP_DEVICE_CONTEXT_AGPS_ENABLED (1U<<1)
#define FLP_DEVICE_CONTEXT_NETWORK_POSITIONING_ENABLED (1U<<2)
#define FLP_DEVICE_CONTEXT_WIFI_CONNECTIVITY_ENABLED (1U<<3)
#define FLP_DEVICE_CONTEXT_WIFI_POSITIONING_ENABLED (1U<<4)
#define FIP_DEVICE_CONTEXT_HW_NETWORK_POSITIONING ENABLED (1U<<5)
#define FLP_DEVICE_CONTEXT_AIRPLANE_MODE_ON (1U<<6)
#define FLP_DEVICE_CONTEXT_DATA_ENABLED (1U<<7)
#define FLP_DEVICE_CONTEXT_ROAMING_ENABLED (1U<<8)
#define FLP_DEVICE_CONTEXT_CURRENTLY_ROAMING (1U<<9)
#define FLP_DEVICE_CONTEXT_SENSOR_ENABLED (1U<<10)
#define FLP_DEVICE_CONTEXT_BLUETOOTH_ENABLED (1U<<11)
#define FLP_DEVICE_CONTEXT_CHARGER_ON (1U<<12)
/** Extended interface for device context support. */
typedef struct {
/** set to sizeof(FlpDeviceContextInterface) */
size_t size;
/**
* Injects debug data into the FLP subsystem.
* Return 0 on success, -1 on error.
**/
int (*inject_device_context)(uint32_t enabledMask);
} FlpDeviceContextInterface;
/**
* There are 3 states associated with a Geofence: Inside, Outside, Unknown.
* There are 3 transitions: ENTERED, EXITED, UNCERTAIN.
*
* An example state diagram with confidence level: 95% and Unknown time limit
* set as 30 secs is shown below. (confidence level and Unknown time limit are
* explained latter)
* ____________________________
* | Unknown (30 secs) |
* """"""""""""""""""""""""""""
* ^ | | ^
* UNCERTAIN| |ENTERED EXITED| |UNCERTAIN
* | v v |
* ________ EXITED _________
* | Inside | -----------> | Outside |
* | | <----------- | |
* """""""" ENTERED """""""""
*
* Inside state: We are 95% confident that the user is inside the geofence.
* Outside state: We are 95% confident that the user is outside the geofence
* Unknown state: Rest of the time.
*
* The Unknown state is better explained with an example:
*
* __________
* | c|
* | ___ | _______
* | |a| | | b |
* | """ | """""""
* | |
* """"""""""
* In the diagram above, "a" and "b" are 2 geofences and "c" is the accuracy
* circle reported by the FLP subsystem. Now with regard to "b", the system is
* confident that the user is outside. But with regard to "a" is not confident
* whether it is inside or outside the geofence. If the accuracy remains the
* same for a sufficient period of time, the UNCERTAIN transition would be
* triggered with the state set to Unknown. If the accuracy improves later, an
* appropriate transition should be triggered. This "sufficient period of time"
* is defined by the parameter in the add_geofence_area API.
* In other words, Unknown state can be interpreted as a state in which the
* FLP subsystem isn't confident enough that the user is either inside or
* outside the Geofence. It moves to Unknown state only after the expiry of the
* timeout.
*
* The geofence callback needs to be triggered for the ENTERED and EXITED
* transitions, when the FLP system is confident that the user has entered
* (Inside state) or exited (Outside state) the Geofence. An implementation
* which uses a value of 95% as the confidence is recommended. The callback
* should be triggered only for the transitions requested by the
* add_geofence_area call.
*
* Even though the diagram and explanation talks about states and transitions,
* the callee is only interested in the transistions. The states are mentioned
* here for illustrative purposes.
*
* Startup Scenario: When the device boots up, if an application adds geofences,
* and then we get an accurate FLP location fix, it needs to trigger the
* appropriate (ENTERED or EXITED) transition for every Geofence it knows about.
* By default, all the Geofences will be in the Unknown state.
*
* When the FLP system is unavailable, flp_geofence_status_callback should be
* called to inform the upper layers of the same. Similarly, when it becomes
* available the callback should be called. This is a global state while the
* UNKNOWN transition described above is per geofence.
*
*/
#define FLP_GEOFENCE_TRANSITION_ENTERED (1L<<0)
#define FLP_GEOFENCE_TRANSITION_EXITED (1L<<1)
#define FLP_GEOFENCE_TRANSITION_UNCERTAIN (1L<<2)
#define FLP_GEOFENCE_MONITOR_STATUS_UNAVAILABLE (1L<<0)
#define FLP_GEOFENCE_MONITOR_STATUS_AVAILABLE (1L<<1)
/**
* The callback associated with the geofence.
* Parameters:
* geofence_id - The id associated with the add_geofence_area.
* location - The current location as determined by the FLP subsystem.
* transition - Can be one of FLP_GEOFENCE_TRANSITION_ENTERED, FLP_GEOFENCE_TRANSITION_EXITED,
* FLP_GEOFENCE_TRANSITION_UNCERTAIN.
* timestamp - Timestamp when the transition was detected; -1 if not available.
* sources_used - Bitwise OR of FLP_TECH_MASK flags indicating which
* subsystems were used.
*
* The callback should only be called when the caller is interested in that
* particular transition. For instance, if the caller is interested only in
* ENTERED transition, then the callback should NOT be called with the EXITED
* transition.
*
* IMPORTANT: If a transition is triggered resulting in this callback, the
* subsystem will wake up the application processor, if its in suspend state.
*/
typedef void (*flp_geofence_transition_callback) (int32_t geofence_id, FlpLocation* location,
int32_t transition, FlpUtcTime timestamp, uint32_t sources_used);
/**
* The callback associated with the availablity of one the sources used for geofence
* monitoring by the FLP sub-system For example, if the GPS system determines that it cannot
* monitor geofences because of lack of reliability or unavailability of the GPS signals,
* it will call this callback with FLP_GEOFENCE_MONITOR_STATUS_UNAVAILABLE parameter and the
* source set to FLP_TECH_MASK_GNSS.
*
* Parameters:
* status - FLP_GEOFENCE_MONITOR_STATUS_UNAVAILABLE or FLP_GEOFENCE_MONITOR_STATUS_AVAILABLE.
* source - One of the FLP_TECH_MASKS
* last_location - Last known location.
*/
typedef void (*flp_geofence_monitor_status_callback) (int32_t status, uint32_t source,
FlpLocation* last_location);
/**
* The callback associated with the add_geofence call.
*
* Parameter:
* geofence_id - Id of the geofence.
* result - FLP_RESULT_SUCCESS
* FLP_RESULT_ERROR_TOO_MANY_GEOFENCES - geofence limit has been reached.
* FLP_RESULT_ID_EXISTS - geofence with id already exists
* FLP_RESULT_INVALID_GEOFENCE_TRANSITION - the monitorTransition contains an
* invalid transition
* FLP_RESULT_ERROR - for other errors.
*/
typedef void (*flp_geofence_add_callback) (int32_t geofence_id, int32_t result);
/**
* The callback associated with the remove_geofence call.
*
* Parameter:
* geofence_id - Id of the geofence.
* result - FLP_RESULT_SUCCESS
* FLP_RESULT_ID_UNKNOWN - for invalid id
* FLP_RESULT_ERROR for others.
*/
typedef void (*flp_geofence_remove_callback) (int32_t geofence_id, int32_t result);
/**
* The callback associated with the pause_geofence call.
*
* Parameter:
* geofence_id - Id of the geofence.
* result - FLP_RESULT_SUCCESS
* FLP_RESULT__ID_UNKNOWN - for invalid id
* FLP_RESULT_INVALID_TRANSITION -
* when monitor_transitions is invalid
* FLP_RESULT_ERROR for others.
*/
typedef void (*flp_geofence_pause_callback) (int32_t geofence_id, int32_t result);
/**
* The callback associated with the resume_geofence call.
*
* Parameter:
* geofence_id - Id of the geofence.
* result - FLP_RESULT_SUCCESS
* FLP_RESULT_ID_UNKNOWN - for invalid id
* FLP_RESULT_ERROR for others.
*/
typedef void (*flp_geofence_resume_callback) (int32_t geofence_id, int32_t result);
typedef struct {
/** set to sizeof(FlpGeofenceCallbacks) */
size_t size;
flp_geofence_transition_callback geofence_transition_callback;
flp_geofence_monitor_status_callback geofence_status_callback;
flp_geofence_add_callback geofence_add_callback;
flp_geofence_remove_callback geofence_remove_callback;
flp_geofence_pause_callback geofence_pause_callback;
flp_geofence_resume_callback geofence_resume_callback;
flp_set_thread_event set_thread_event_cb;
} FlpGeofenceCallbacks;
/** Type of geofence */
typedef enum {
TYPE_CIRCLE = 0,
} GeofenceType;
/** Circular geofence is represented by lat / long / radius */
typedef struct {
double latitude;
double longitude;
double radius_m;
} GeofenceCircle;
/** Represents the type of geofence and data */
typedef struct {
GeofenceType type;
union {
GeofenceCircle circle;
} geofence;
} GeofenceData;
/** Geofence Options */
typedef struct {
/**
* The current state of the geofence. For example, if
* the system already knows that the user is inside the geofence,
* this will be set to FLP_GEOFENCE_TRANSITION_ENTERED. In most cases, it
* will be FLP_GEOFENCE_TRANSITION_UNCERTAIN. */
int last_transition;
/**
* Transitions to monitor. Bitwise OR of
* FLP_GEOFENCE_TRANSITION_ENTERED, FLP_GEOFENCE_TRANSITION_EXITED and
* FLP_GEOFENCE_TRANSITION_UNCERTAIN.
*/
int monitor_transitions;
/**
* Defines the best-effort description
* of how soon should the callback be called when the transition
* associated with the Geofence is triggered. For instance, if set
* to 1000 millseconds with FLP_GEOFENCE_TRANSITION_ENTERED, the callback
* should be called 1000 milliseconds within entering the geofence.
* This parameter is defined in milliseconds.
* NOTE: This is not to be confused with the rate that the GPS is
* polled at. It is acceptable to dynamically vary the rate of
* sampling the GPS for power-saving reasons; thus the rate of
* sampling may be faster or slower than this.
*/
int notification_responsivenes_ms;
/**
* The time limit after which the UNCERTAIN transition
* should be triggered. This paramter is defined in milliseconds.
*/
int unknown_timer_ms;
/**
* The sources to use for monitoring geofences. Its a BITWISE-OR
* of FLP_TECH_MASK flags.
*/
uint32_t sources_to_use;
} GeofenceOptions;
/** Geofence struct */
typedef struct {
int32_t geofence_id;
GeofenceData* data;
GeofenceOptions* options;
} Geofence;
/** Extended interface for FLP_Geofencing support */
typedef struct {
/** set to sizeof(FlpGeofencingInterface) */
size_t size;
/**
* Opens the geofence interface and provides the callback routines
* to the implemenation of this interface.
*/
void (*init)( FlpGeofenceCallbacks* callbacks );
/**
* Add a list of geofences.
* Parameters:
* number_of_geofences - The number of geofences that needed to be added.
* geofences - Pointer to array of pointers to Geofence structure.
*/
void (*add_geofences) (int32_t number_of_geofences, Geofence** geofences);
/**
* Pause monitoring a particular geofence.
* Parameters:
* geofence_id - The id for the geofence.
*/
void (*pause_geofence) (int32_t geofence_id);
/**
* Resume monitoring a particular geofence.
* Parameters:
* geofence_id - The id for the geofence.
* monitor_transitions - Which transitions to monitor. Bitwise OR of
* FLP_GEOFENCE_TRANSITION_ENTERED, FLP_GEOFENCE_TRANSITION_EXITED and
* FLP_GEOFENCE_TRANSITION_UNCERTAIN.
* This supersedes the value associated provided in the
* add_geofence_area call.
*/
void (*resume_geofence) (int32_t geofence_id, int monitor_transitions);
/**
* Modify a particular geofence option.
* Parameters:
* geofence_id - The id for the geofence.
* options - Various options associated with the geofence. See
* GeofenceOptions structure for details.
*/
void (*modify_geofence_option) (int32_t geofence_id, GeofenceOptions* options);
/**
* Remove a list of geofences. After the function returns, no notifications
* should be sent.
* Parameter:
* number_of_geofences - The number of geofences that needed to be added.
* geofence_id - Pointer to array of geofence_ids to be removed.
*/
void (*remove_geofences) (int32_t number_of_geofences, int32_t* geofence_id);
} FlpGeofencingInterface;
__END_DECLS
#endif /* ANDROID_INCLUDE_HARDWARE_FLP_H */