gnss/1.0-legacy/GnssBatching.cpp - hardware/lineage/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.
  */

 #define LOG_TAG "GnssHAL_GnssBatchingInterface"

 #include "GnssBatching.h"
 #include <Gnss.h> // for wakelock consolidation
 #include <GnssUtils.h>

 #include <android/log.h>  // for ALOGE
 #include <vector>

 namespace android {
 namespace hardware {
 namespace gnss {
 namespace V1_0 {
 namespace implementation {

 sp<IGnssBatchingCallback> GnssBatching::sGnssBatchingCbIface = nullptr;
 bool GnssBatching::sFlpSupportsBatching = false;

 FlpCallbacks GnssBatching::sFlpCb = {
     .size = sizeof(FlpCallbacks),
     .location_cb = locationCb,
     .acquire_wakelock_cb = acquireWakelockCb,
     .release_wakelock_cb = releaseWakelockCb,
     .set_thread_event_cb = setThreadEventCb,
     .flp_capabilities_cb = flpCapabilitiesCb,
     .flp_status_cb = flpStatusCb,
 };

 GnssBatching::GnssBatching(const FlpLocationInterface* flpLocationIface) :
     mFlpLocationIface(flpLocationIface) {
 }

 /*
  * This enum is used locally by various methods below. It is only used by the default
  * implementation and is not part of the GNSS interface.
  */
 enum BatchingValues : uint16_t {
     // Numbers 0-3 were used in earlier implementations - using 4 to be distinct to the HAL
     FLP_GNSS_BATCHING_CLIENT_ID = 4,
     // Tech. mask of GNSS, and sensor aiding, for legacy HAL to fit with GnssBatching API
     FLP_TECH_MASK_GNSS_AND_SENSORS = FLP_TECH_MASK_GNSS | FLP_TECH_MASK_SENSORS,
     // Putting a cap to avoid possible memory issues.  Unlikely values this high are supported.
     MAX_LOCATIONS_PER_BATCH = 1000
 };

 void GnssBatching::locationCb(int32_t locationsCount, FlpLocation** locations) {
     if (sGnssBatchingCbIface == nullptr) {
         ALOGE("%s: GNSS Batching Callback Interface configured incorrectly", __func__);
         return;
     }

     if (locations == nullptr) {
         ALOGE("%s: Invalid locations from GNSS HAL", __func__);
         return;
     }

     if (locationsCount < 0) {
         ALOGE("%s: Negative location count: %d set to 0", __func__, locationsCount);
         locationsCount = 0;
     } else if (locationsCount > MAX_LOCATIONS_PER_BATCH) {
         ALOGW("%s: Unexpected high location count: %d set to %d", __func__, locationsCount,
                 MAX_LOCATIONS_PER_BATCH);
         locationsCount = MAX_LOCATIONS_PER_BATCH;
     }

     /**
      * Note:
      * Some existing implementations may drop duplicate locations.  These could be expanded here
      * but as there's ambiguity between no-GPS-fix vs. dropped duplicates in that implementation,
      * and that's not specified by the fused_location.h, that isn't safe to do here.
      * Fortunately, this shouldn't be a major issue in cases where GNSS batching is typically
      * used (e.g. when user is likely in vehicle/bicycle.)
      */
     std::vector<android::hardware::gnss::V1_0::GnssLocation> gnssLocations;
     for (int iLocation = 0; iLocation < locationsCount; iLocation++) {
         if (locations[iLocation] == nullptr) {
             ALOGE("%s: Null location at slot: %d of %d, skipping", __func__, iLocation,
                     locationsCount);
             continue;
         }
         if ((locations[iLocation]->sources_used & ~FLP_TECH_MASK_GNSS_AND_SENSORS) != 0)
         {
             ALOGE("%s: Unrequested location type %d at slot: %d of %d, skipping", __func__,
                     locations[iLocation]->sources_used, iLocation, locationsCount);
             continue;
         }
         gnssLocations.push_back(convertToGnssLocation(locations[iLocation]));
     }

     auto ret = sGnssBatchingCbIface->gnssLocationBatchCb(gnssLocations);
     if (!ret.isOk()) {
         ALOGE("%s: Unable to invoke callback", __func__);
     }
 }

 void GnssBatching::acquireWakelockCb() {
     Gnss::acquireWakelockFused();
 }

 void GnssBatching::releaseWakelockCb() {
     Gnss::releaseWakelockFused();
 }

 // this can just return success, because threads are now set up on demand in the jni layer
 int32_t GnssBatching::setThreadEventCb(ThreadEvent /*event*/) {
     return FLP_RESULT_SUCCESS;
 }

 void GnssBatching::flpCapabilitiesCb(int32_t capabilities) {
     ALOGD("%s capabilities %d", __func__, capabilities);

     if (capabilities & CAPABILITY_GNSS) {
         // once callback is received and capabilities high enough, we know version is
         // high enough for flush()
         sFlpSupportsBatching = true;
     }
 }

 void GnssBatching::flpStatusCb(int32_t status) {
     ALOGD("%s (default implementation) not forwarding status: %d", __func__, status);
 }

 // Methods from ::android::hardware::gnss::V1_0::IGnssBatching follow.
 Return<bool> GnssBatching::init(const sp<IGnssBatchingCallback>& callback) {
     if (mFlpLocationIface == nullptr) {
         ALOGE("%s: Flp batching is unavailable", __func__);
         return false;
     }

     sGnssBatchingCbIface = callback;

     return (mFlpLocationIface->init(&sFlpCb) == 0);
 }

 Return<uint16_t> GnssBatching::getBatchSize() {
     if (mFlpLocationIface == nullptr) {
         ALOGE("%s: Flp batching interface is unavailable", __func__);
         return 0;
     }

     return mFlpLocationIface->get_batch_size();
 }

 Return<bool> GnssBatching::start(const IGnssBatching::Options& options) {
     if (mFlpLocationIface == nullptr) {
         ALOGE("%s: Flp batching interface is unavailable", __func__);
         return false;
     }

     if (!sFlpSupportsBatching) {
         ALOGE("%s: Flp batching interface not supported, no capabilities callback received",
                 __func__);
         return false;
     }

     FlpBatchOptions optionsHw;
     // Legacy code used 9999 mW for High accuracy, and 21 mW for balanced.
     // New GNSS API just expects reasonable GNSS chipset behavior - do something efficient
     // given the interval.  This 100 mW limit should be quite sufficient (esp. given legacy code
     // implementations may not even use this value.)
     optionsHw.max_power_allocation_mW = 100;
     optionsHw.sources_to_use = FLP_TECH_MASK_GNSS_AND_SENSORS;
     optionsHw.flags = 0;
     if (options.flags & Flag::WAKEUP_ON_FIFO_FULL) {
         optionsHw.flags |= FLP_BATCH_WAKEUP_ON_FIFO_FULL;
     }
     optionsHw.period_ns = options.periodNanos;
     optionsHw.smallest_displacement_meters = 0; // Zero offset - just use time interval

     return (mFlpLocationIface->start_batching(FLP_GNSS_BATCHING_CLIENT_ID, &optionsHw)
             == FLP_RESULT_SUCCESS);
 }

 Return<void> GnssBatching::flush() {
     if (mFlpLocationIface == nullptr) {
         ALOGE("%s: Flp batching interface is unavailable", __func__);
         return Void();
     }

     mFlpLocationIface->flush_batched_locations();

     return Void();
 }

 Return<bool> GnssBatching::stop() {
     if (mFlpLocationIface == nullptr) {
         ALOGE("%s: Flp batching interface is unavailable", __func__);
         return false;
     }

     return (mFlpLocationIface->stop_batching(FLP_GNSS_BATCHING_CLIENT_ID) == FLP_RESULT_SUCCESS);
 }

 Return<void> GnssBatching::cleanup() {
     if (mFlpLocationIface == nullptr) {
         ALOGE("%s: Flp batching interface is unavailable", __func__);
         return Void();
     }

     mFlpLocationIface->cleanup();

     return Void();
 }

 }  // namespace implementation
 }  // namespace V1_0
 }  // namespace gnss
 }  // namespace hardware
 }  // namespace android
	/*
	* 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.
	*/

	#define LOG_TAG "GnssHAL_GnssBatchingInterface"

	#include "GnssBatching.h"
	#include <Gnss.h> // for wakelock consolidation
	#include <GnssUtils.h>

	#include <android/log.h> // for ALOGE
	#include <vector>

	namespace android {
	namespace hardware {
	namespace gnss {
	namespace V1_0 {
	namespace implementation {

	sp<IGnssBatchingCallback> GnssBatching::sGnssBatchingCbIface = nullptr;
	bool GnssBatching::sFlpSupportsBatching = false;

	FlpCallbacks GnssBatching::sFlpCb = {
	.size = sizeof(FlpCallbacks),
	.location_cb = locationCb,
	.acquire_wakelock_cb = acquireWakelockCb,
	.release_wakelock_cb = releaseWakelockCb,
	.set_thread_event_cb = setThreadEventCb,
	.flp_capabilities_cb = flpCapabilitiesCb,
	.flp_status_cb = flpStatusCb,
	};

	GnssBatching::GnssBatching(const FlpLocationInterface* flpLocationIface) :
	mFlpLocationIface(flpLocationIface) {
	}

	/*
	* This enum is used locally by various methods below. It is only used by the default
	* implementation and is not part of the GNSS interface.
	*/
	enum BatchingValues : uint16_t {
	// Numbers 0-3 were used in earlier implementations - using 4 to be distinct to the HAL
	FLP_GNSS_BATCHING_CLIENT_ID = 4,
	// Tech. mask of GNSS, and sensor aiding, for legacy HAL to fit with GnssBatching API
	FLP_TECH_MASK_GNSS_AND_SENSORS = FLP_TECH_MASK_GNSS \| FLP_TECH_MASK_SENSORS,
	// Putting a cap to avoid possible memory issues. Unlikely values this high are supported.
	MAX_LOCATIONS_PER_BATCH = 1000
	};

	void GnssBatching::locationCb(int32_t locationsCount, FlpLocation** locations) {
	if (sGnssBatchingCbIface == nullptr) {
	ALOGE("%s: GNSS Batching Callback Interface configured incorrectly", __func__);
	return;
	}

	if (locations == nullptr) {
	ALOGE("%s: Invalid locations from GNSS HAL", __func__);
	return;
	}

	if (locationsCount < 0) {
	ALOGE("%s: Negative location count: %d set to 0", __func__, locationsCount);
	locationsCount = 0;
	} else if (locationsCount > MAX_LOCATIONS_PER_BATCH) {
	ALOGW("%s: Unexpected high location count: %d set to %d", __func__, locationsCount,
	MAX_LOCATIONS_PER_BATCH);
	locationsCount = MAX_LOCATIONS_PER_BATCH;
	}

	/**
	* Note:
	* Some existing implementations may drop duplicate locations. These could be expanded here
	* but as there's ambiguity between no-GPS-fix vs. dropped duplicates in that implementation,
	* and that's not specified by the fused_location.h, that isn't safe to do here.
	* Fortunately, this shouldn't be a major issue in cases where GNSS batching is typically
	* used (e.g. when user is likely in vehicle/bicycle.)
	*/
	std::vector<android::hardware::gnss::V1_0::GnssLocation> gnssLocations;
	for (int iLocation = 0; iLocation < locationsCount; iLocation++) {
	if (locations[iLocation] == nullptr) {
	ALOGE("%s: Null location at slot: %d of %d, skipping", __func__, iLocation,
	locationsCount);
	continue;
	}
	if ((locations[iLocation]->sources_used & ~FLP_TECH_MASK_GNSS_AND_SENSORS) != 0)
	{
	ALOGE("%s: Unrequested location type %d at slot: %d of %d, skipping", __func__,
	locations[iLocation]->sources_used, iLocation, locationsCount);
	continue;
	}
	gnssLocations.push_back(convertToGnssLocation(locations[iLocation]));
	}

	auto ret = sGnssBatchingCbIface->gnssLocationBatchCb(gnssLocations);
	if (!ret.isOk()) {
	ALOGE("%s: Unable to invoke callback", __func__);
	}
	}

	void GnssBatching::acquireWakelockCb() {
	Gnss::acquireWakelockFused();
	}

	void GnssBatching::releaseWakelockCb() {
	Gnss::releaseWakelockFused();
	}

	// this can just return success, because threads are now set up on demand in the jni layer
	int32_t GnssBatching::setThreadEventCb(ThreadEvent /event/) {
	return FLP_RESULT_SUCCESS;
	}

	void GnssBatching::flpCapabilitiesCb(int32_t capabilities) {
	ALOGD("%s capabilities %d", __func__, capabilities);

	if (capabilities & CAPABILITY_GNSS) {
	// once callback is received and capabilities high enough, we know version is
	// high enough for flush()
	sFlpSupportsBatching = true;
	}
	}

	void GnssBatching::flpStatusCb(int32_t status) {
	ALOGD("%s (default implementation) not forwarding status: %d", __func__, status);
	}

	// Methods from ::android::hardware::gnss::V1_0::IGnssBatching follow.
	Return<bool> GnssBatching::init(const sp<IGnssBatchingCallback>& callback) {
	if (mFlpLocationIface == nullptr) {
	ALOGE("%s: Flp batching is unavailable", __func__);
	return false;
	}

	sGnssBatchingCbIface = callback;

	return (mFlpLocationIface->init(&sFlpCb) == 0);
	}

	Return<uint16_t> GnssBatching::getBatchSize() {
	if (mFlpLocationIface == nullptr) {
	ALOGE("%s: Flp batching interface is unavailable", __func__);
	return 0;
	}

	return mFlpLocationIface->get_batch_size();
	}

	Return<bool> GnssBatching::start(const IGnssBatching::Options& options) {
	if (mFlpLocationIface == nullptr) {
	ALOGE("%s: Flp batching interface is unavailable", __func__);
	return false;
	}

	if (!sFlpSupportsBatching) {
	ALOGE("%s: Flp batching interface not supported, no capabilities callback received",
	__func__);
	return false;
	}

	FlpBatchOptions optionsHw;
	// Legacy code used 9999 mW for High accuracy, and 21 mW for balanced.
	// New GNSS API just expects reasonable GNSS chipset behavior - do something efficient
	// given the interval. This 100 mW limit should be quite sufficient (esp. given legacy code
	// implementations may not even use this value.)
	optionsHw.max_power_allocation_mW = 100;
	optionsHw.sources_to_use = FLP_TECH_MASK_GNSS_AND_SENSORS;
	optionsHw.flags = 0;
	if (options.flags & Flag::WAKEUP_ON_FIFO_FULL) {
	optionsHw.flags \|= FLP_BATCH_WAKEUP_ON_FIFO_FULL;
	}
	optionsHw.period_ns = options.periodNanos;
	optionsHw.smallest_displacement_meters = 0; // Zero offset - just use time interval

	return (mFlpLocationIface->start_batching(FLP_GNSS_BATCHING_CLIENT_ID, &optionsHw)
	== FLP_RESULT_SUCCESS);
	}

	Return<void> GnssBatching::flush() {
	if (mFlpLocationIface == nullptr) {
	ALOGE("%s: Flp batching interface is unavailable", __func__);
	return Void();
	}

	mFlpLocationIface->flush_batched_locations();

	return Void();
	}

	Return<bool> GnssBatching::stop() {
	if (mFlpLocationIface == nullptr) {
	ALOGE("%s: Flp batching interface is unavailable", __func__);
	return false;
	}

	return (mFlpLocationIface->stop_batching(FLP_GNSS_BATCHING_CLIENT_ID) == FLP_RESULT_SUCCESS);
	}

	Return<void> GnssBatching::cleanup() {
	if (mFlpLocationIface == nullptr) {
	ALOGE("%s: Flp batching interface is unavailable", __func__);
	return Void();
	}

	mFlpLocationIface->cleanup();

	return Void();
	}

	} // namespace implementation
	} // namespace V1_0
	} // namespace gnss
	} // namespace hardware
	} // namespace android