/* * Copyright (C) 2020 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 "GnssAidl" #include "Gnss.h" #include #include #include #include "AGnss.h" #include "AGnssRil.h" #include "DeviceFileReader.h" #include "FixLocationParser.h" #include "GnssAntennaInfo.h" #include "GnssBatching.h" #include "GnssConfiguration.h" #include "GnssDebug.h" #include "GnssGeofence.h" #include "GnssNavigationMessageInterface.h" #include "GnssPsds.h" #include "GnssVisibilityControl.h" #include "MeasurementCorrectionsInterface.h" #include "Utils.h" #include namespace aidl::android::hardware::gnss { using ::android::hardware::gnss::common::Utils; using ndk::ScopedAStatus; using GnssSvInfo = IGnssCallback::GnssSvInfo; std::vector> Gnss::sThreadFuncArgsList; std::shared_ptr Gnss::sGnssCallback = nullptr; const GpsInterface* mGnssIface = nullptr; GpsCallbacks Gnss::sGnssCb = { .size = sizeof(GpsCallbacks), .location_cb = locationCb, .status_cb = statusCb, .sv_status_cb = gpsSvStatusCb, .nmea_cb = nmeaCb, .set_capabilities_cb = setCapabilitiesCb, .acquire_wakelock_cb = acquireWakelockCb, .release_wakelock_cb = releaseWakelockCb, .create_thread_cb = createThreadCb, .request_utc_time_cb = requestUtcTimeCb, .set_system_info_cb = setSystemInfoCb, .gnss_sv_status_cb = gnssSvStatusCb, }; bool Gnss::sWakelockHeldGnss = false; bool Gnss::sWakelockHeldFused = false; uint32_t Gnss::sCapabilitiesCached = 0; uint16_t Gnss::sYearOfHwCached = 0; GnssLocation convertToGnssLocation(GpsLocation* location) { GnssLocation gnssLocation ; if (location != nullptr) { // Bit operation AND with 1f below is needed to clear vertical accuracy, // speed accuracy and bearing accuracy flags as some vendors are found // to be setting these bits in pre-Android-O devices gnssLocation.gnssLocationFlags = static_cast(location->flags & 0x1f); gnssLocation.latitudeDegrees = location->latitude; gnssLocation.longitudeDegrees = location->longitude; gnssLocation.altitudeMeters = location->altitude; gnssLocation.speedMetersPerSec = location->speed; gnssLocation.bearingDegrees = location->bearing; gnssLocation.horizontalAccuracyMeters = location->accuracy; // Older chipsets do not provide the following 3 fields, hence the flags // HAS_VERTICAL_ACCURACY, HAS_SPEED_ACCURACY and HAS_BEARING_ACCURACY are // not set and the field are set to zeros. gnssLocation.verticalAccuracyMeters = 0; gnssLocation.speedAccuracyMetersPerSecond = 0; gnssLocation.bearingAccuracyDegrees = 0; gnssLocation.timestampMillis = location->timestamp; } return gnssLocation; } Gnss::Gnss() : mMinIntervalMs(1000), mFirstFixReceived(false) { ALOGD("make Gnss"); hw_module_t* module; int err = hw_get_module(GPS_HARDWARE_MODULE_ID, (hw_module_t const**)&module); if (err == 0) { hw_device_t* device; gps_device_t* gnssDevice; err = module->methods->open(module, GPS_HARDWARE_MODULE_ID, &device); if (err == 0) { ALOGD("gnss hw_get_module ok"); gnssDevice =(gps_device_t *)device; mGnssIface = gnssDevice->get_gps_interface(gnssDevice); } else { ALOGE("gnssDevice open %s failed: %d", GPS_HARDWARE_MODULE_ID, err); } } else { ALOGE("gnss hw_get_module %s failed: %d", GPS_HARDWARE_MODULE_ID, err); } } void Gnss::locationCb(GpsLocation* location) { if (sGnssCallback == nullptr) { ALOGE("%s: GNSS Callback Interface configured incorrectly", __func__); return; } if (location == nullptr) { ALOGE("%s: Invalid location from GNSS HAL", __func__); return; } GnssLocation gnssLocation = convertToGnssLocation(location); if (sGnssCallback == nullptr) { ALOGE("%s: GnssCallback is null.", __func__); return; } auto status = sGnssCallback->gnssLocationCb(gnssLocation); if (!status.isOk()) { ALOGE("%s: Unable to invoke gnssLocationCb", __func__); } } void Gnss::statusCb(GpsStatus* gnssStatus) { if (sGnssCallback == nullptr) { ALOGE("%s: GNSS Callback Interface configured incorrectly", __func__); return; } if (gnssStatus == nullptr) { ALOGE("%s: Invalid GpsStatus from GNSS HAL", __func__); return; } IGnssCallback::GnssStatusValue status = static_cast(gnssStatus->status); if (sGnssCallback == nullptr) { ALOGE("%s: sGnssCallback is null.", __func__); return; } auto status1 = sGnssCallback->gnssStatusCb(status); if (!status1.isOk()) { ALOGE("%s: Unable to invoke gnssStatusCb", __func__); } } void Gnss::gnssSvStatusCb(GnssSvStatus* status) { if (sGnssCallback == nullptr) { ALOGE("%s: GNSS Callback Interface configured incorrectly", __func__); return; } if (status == nullptr) { ALOGE("Invalid status from GNSS HAL %s", __func__); return; } int numSvs = status->num_svs; std::vector gnssSvInfoList; if (numSvs > 64) { ALOGW("Too many satellites %u. Clamps to 64.", numSvs); numSvs = 64; } for (int i = 0; i < numSvs; i++) { auto svInfo = status->gnss_sv_list[i]; GnssSvInfo gnssSvInfo = { .svid = svInfo.svid, .constellation = static_cast< GnssConstellationType>( svInfo.constellation), .cN0Dbhz = svInfo.c_n0_dbhz, .elevationDegrees = svInfo.elevation, .azimuthDegrees = svInfo.azimuth, // Older chipsets do not provide carrier frequency, hence // HAS_CARRIER_FREQUENCY flag and the carrierFrequencyHz fields // are not set. So we are resetting both fields here. //.svFlag = static_cast( // svInfo.flags &= ~(static_cast( // V1_0::IGnssCallback::GnssSvFlags::HAS_CARRIER_FREQUENCY))), .svFlag = svInfo.flags, .carrierFrequencyHz = 1575420000}; gnssSvInfoList.push_back(gnssSvInfo); } if (sGnssCallback == nullptr) { ALOGE("%s: sGnssCallback is null.", __func__); return; } auto res = sGnssCallback->gnssSvStatusCb(gnssSvInfoList); if (!res.isOk()) { ALOGE("%s: Unable to invoke callback", __func__); } } /* * This enum is used by gpsSvStatusCb() method below to convert GpsSvStatus * to GnssSvStatus for backward compatibility. It is only used by the default * implementation and is not part of the GNSS interface. */ enum SvidValues : uint16_t { GLONASS_SVID_OFFSET = 64, GLONASS_SVID_COUNT = 24, BEIDOU_SVID_OFFSET = 200, BEIDOU_SVID_COUNT = 35, SBAS_SVID_MIN = 33, SBAS_SVID_MAX = 64, SBAS_SVID_ADD = 87, QZSS_SVID_MIN = 193, QZSS_SVID_MAX = 200 }; /* * The following code that converts GpsSvStatus to GnssSvStatus is moved here from * GnssLocationProvider. GnssLocationProvider does not require it anymore since GpsSvStatus is * being deprecated and is no longer part of the GNSS interface. */ void Gnss::gpsSvStatusCb(GpsSvStatus* svInfo) { if (sGnssCallback == nullptr) { ALOGE("%s: GNSS Callback Interface configured incorrectly", __func__); return; } if (svInfo == nullptr) { ALOGE("Invalid status from GNSS HAL %s", __func__); return; } int numSvs = svInfo->num_svs; std::vector gnssSvInfoList; /* * Clamp the list size since GnssSvStatus can support a maximum of * GnssMax::SVS_COUNT entries. */ if (numSvs > 64) { ALOGW("Too many satellites %u. Clamps to 64.", numSvs); numSvs = 64; } uint32_t ephemerisMask = svInfo->ephemeris_mask; uint32_t almanacMask = svInfo->almanac_mask; uint32_t usedInFixMask = svInfo->used_in_fix_mask; /* * Conversion from GpsSvInfo to IGnssCallback::GnssSvInfo happens below. */ for (int i = 0; i < numSvs; i++) { GnssSvInfo info; info.svid = svInfo->sv_list[i].prn; if (info.svid >= 1 && info.svid <= 32) { info.constellation = GnssConstellationType::GPS; } else if (info.svid > GLONASS_SVID_OFFSET && info.svid <= GLONASS_SVID_OFFSET + GLONASS_SVID_COUNT) { info.constellation = GnssConstellationType::GLONASS; info.svid -= GLONASS_SVID_OFFSET; } else if (info.svid > BEIDOU_SVID_OFFSET && info.svid <= BEIDOU_SVID_OFFSET + BEIDOU_SVID_COUNT) { info.constellation = GnssConstellationType::BEIDOU; info.svid -= BEIDOU_SVID_OFFSET; } else if (info.svid >= SBAS_SVID_MIN && info.svid <= SBAS_SVID_MAX) { info.constellation = GnssConstellationType::SBAS; info.svid += SBAS_SVID_ADD; } else if (info.svid >= QZSS_SVID_MIN && info.svid <= QZSS_SVID_MAX) { info.constellation = GnssConstellationType::QZSS; } else { ALOGD("Unknown constellation type with Svid = %d.", info.svid); info.constellation = GnssConstellationType::UNKNOWN; } info.cN0Dbhz = svInfo->sv_list[i].snr; info.elevationDegrees = svInfo->sv_list[i].elevation; info.azimuthDegrees = svInfo->sv_list[i].azimuth; // TODO: b/31702236 info.svFlag = static_cast(IGnssCallback::GnssSvFlags::NONE); /* * Only GPS info is valid for these fields, as these masks are just 32 * bits, by GPS prn. */ if (info.constellation == GnssConstellationType::GPS) { int32_t svidMask = (1 << (info.svid - 1)); if ((ephemerisMask & svidMask) != 0) { info.svFlag |= (int)IGnssCallback::GnssSvFlags::HAS_EPHEMERIS_DATA; } if ((almanacMask & svidMask) != 0) { info.svFlag |= (int)IGnssCallback::GnssSvFlags::HAS_ALMANAC_DATA; } if ((usedInFixMask & svidMask) != 0) { info.svFlag |= (int)IGnssCallback::GnssSvFlags::USED_IN_FIX; } } gnssSvInfoList.push_back(info); } if (sGnssCallback == nullptr) { ALOGE("%s: sGnssCallback is null.", __func__); return; } auto status = sGnssCallback->gnssSvStatusCb(gnssSvInfoList); if (!status.isOk()) { ALOGE("%s: Unable to invoke callback", __func__); } } void Gnss::nmeaCb(GpsUtcTime timestamp, const char* nmea, int length) { if (sGnssCallback == nullptr) { ALOGE("%s: GNSS Callback Interface configured incorrectly", __func__); return; } char nmeaString[300]={0}; memcpy(nmeaString,nmea,length); if(sGnssCallback != nullptr) { auto ret = sGnssCallback->gnssNmeaCb(timestamp, nmeaString); if (!ret.isOk()) { ALOGE("%s: Unable to invoke callback", __func__); } } } void Gnss::setCapabilitiesCb(uint32_t capabilities) { if (sGnssCallback == nullptr) { ALOGE("%s: GNSS Callback Interface configured incorrectly", __func__); return; } if(sGnssCallback != nullptr) { auto ret = sGnssCallback->gnssSetCapabilitiesCb(capabilities); if (!ret.isOk()) { ALOGE("%s: Unable to invoke callback", __func__); } } // Save for reconnection when some legacy hal's don't resend this info sCapabilitiesCached = capabilities; } void Gnss::acquireWakelockCb() { acquireWakelockGnss(); } void Gnss::releaseWakelockCb() { releaseWakelockGnss(); } void Gnss::acquireWakelockGnss() { sWakelockHeldGnss = true; updateWakelock(); } void Gnss::releaseWakelockGnss() { sWakelockHeldGnss = false; updateWakelock(); } void Gnss::acquireWakelockFused() { sWakelockHeldFused = true; updateWakelock(); } void Gnss::releaseWakelockFused() { sWakelockHeldFused = false; updateWakelock(); } void Gnss::updateWakelock() { // Track the state of the last request - in case the wake lock in the layer above is reference // counted. static bool sWakelockHeld = false; if (sGnssCallback == nullptr) { ALOGE("%s: GNSS Callback Interface configured incorrectly", __func__); return; } if (sWakelockHeldGnss || sWakelockHeldFused) { if (!sWakelockHeld) { ALOGI("%s: GNSS HAL Wakelock acquired due to gps: %d, fused: %d", __func__, sWakelockHeldGnss, sWakelockHeldFused); sWakelockHeld = true; if(sGnssCallback != nullptr) { auto ret = sGnssCallback->gnssAcquireWakelockCb(); if (!ret.isOk()) { ALOGE("%s: Unable to invoke callback", __func__); } } } } else { if (sWakelockHeld) { ALOGI("%s: GNSS HAL Wakelock released", __func__); } else { // To avoid burning power, always release, even if logic got here with sWakelock false // which it shouldn't, unless underlying *.h implementation makes duplicate requests. ALOGW("%s: GNSS HAL Wakelock released, duplicate request", __func__); } sWakelockHeld = false; if(sGnssCallback != nullptr) { auto ret = sGnssCallback->gnssReleaseWakelockCb(); if (!ret.isOk()) { ALOGE("%s: Unable to invoke callback", __func__); } } } } void Gnss::requestUtcTimeCb() { if (sGnssCallback == nullptr ) { ALOGE("%s: GNSS Callback Interface configured incorrectly", __func__); return; } if(sGnssCallback != nullptr) { auto ret = sGnssCallback->gnssRequestTimeCb(); if (!ret.isOk()) { ALOGE("%s: Unable to invoke callback", __func__); } } } pthread_t Gnss::createThreadCb(const char* name, void (*start)(void*), void* arg) { return createPthread(name, start, arg, &sThreadFuncArgsList); } void Gnss::setSystemInfoCb(const LegacyGnssSystemInfo* info) { if (sGnssCallback == nullptr ) { ALOGE("%s: GNSS Callback Interface configured incorrectly", __func__); return; } if (info == nullptr) { ALOGE("Invalid GnssSystemInfo from GNSS HAL %s", __func__); return; } IGnssCallback::GnssSystemInfo gnssInfo = { .yearOfHw = info->year_of_hw }; if(sGnssCallback != nullptr) { auto ret = sGnssCallback->gnssSetSystemInfoCb(gnssInfo); if (!ret.isOk()) { ALOGE("%s: Unable to invoke callback", __func__); } } // Save for reconnection when some legacy hal's don't resend this info sYearOfHwCached = info->year_of_hw; } ScopedAStatus Gnss::setCallback(const std::shared_ptr& callback) { ALOGD("setCallback"); if (mGnssIface == nullptr) { ALOGE("%s: Gnss interface is unavailable", __func__); return ScopedAStatus::fromExceptionCode(STATUS_INVALID_OPERATION); } if (callback == nullptr) { ALOGE("%s: Null callback ignored", __func__); return ScopedAStatus::fromExceptionCode(STATUS_INVALID_OPERATION); } sGnssCallback = callback; int capabilities = (int)(IGnssCallback::CAPABILITY_MEASUREMENTS | IGnssCallback::CAPABILITY_SCHEDULING | IGnssCallback::CAPABILITY_SATELLITE_BLOCKLIST | IGnssCallback::CAPABILITY_SATELLITE_PVT | IGnssCallback::CAPABILITY_CORRELATION_VECTOR | IGnssCallback::CAPABILITY_ANTENNA_INFO | IGnssCallback::CAPABILITY_ACCUMULATED_DELTA_RANGE); auto status = sGnssCallback->gnssSetCapabilitiesCb(capabilities); if (!status.isOk()) { ALOGE("%s: Unable to invoke callback.gnssSetCapabilitiesCb", __func__); } IGnssCallback::GnssSystemInfo systemInfo = { .yearOfHw = 2022, .name = "Google, Cuttlefish, AIDL v3", }; status = sGnssCallback->gnssSetSystemInfoCb(systemInfo); if (!status.isOk()) { ALOGE("%s: Unable to invoke callback.gnssSetSystemInfoCb", __func__); } GnssSignalType signalType1 = { .constellation = GnssConstellationType::GPS, .carrierFrequencyHz = 1.57542e+09, .codeType = GnssSignalType::CODE_TYPE_C, }; GnssSignalType signalType2 = { .constellation = GnssConstellationType::GLONASS, .carrierFrequencyHz = 1.5980625e+09, .codeType = GnssSignalType::CODE_TYPE_C, }; status = sGnssCallback->gnssSetSignalTypeCapabilitiesCb( std::vector({signalType1, signalType2})); if (!status.isOk()) { ALOGE("%s: Unable to invoke callback.gnssSetSignalTypeCapabilitiesCb", __func__); } if (sCapabilitiesCached != 0) { setCapabilitiesCb(sCapabilitiesCached); } if (sYearOfHwCached != 0) { LegacyGnssSystemInfo info; info.year_of_hw = sYearOfHwCached; setSystemInfoCb(&info); } if(mGnssIface->init(&sGnssCb)){ ALOGE("%s: Unable to init gps module", __func__); } return ScopedAStatus::ok(); } std::unique_ptr Gnss::getLocationFromHW() { if (!::android::hardware::gnss::common::ReplayUtils::hasFixedLocationDeviceFile()) { return nullptr; } std::string inputStr = ::android::hardware::gnss::common::DeviceFileReader::Instance().getLocationData(); return ::android::hardware::gnss::common::FixLocationParser::getLocationFromInputStr(inputStr); } ScopedAStatus Gnss::start() { ALOGD("start()"); if (mIsActive) { ALOGW("Gnss has started. Restarting..."); stop(); } mIsActive = true; mThreadBlocker.reset(); // notify measurement engine to update measurement interval //mGnssMeasurementInterface->setLocationEnabled(true); this->reportGnssStatusValue(IGnssCallback::GnssStatusValue::SESSION_BEGIN); if (mGnssIface == nullptr) { ALOGE("%s: Gnss interface is unavailable", __func__); return ScopedAStatus::fromExceptionCode(STATUS_INVALID_OPERATION); } mGnssIface->start() ; return ScopedAStatus::ok(); } ScopedAStatus Gnss::stop() { ALOGD("stop"); mIsActive = false; mGnssMeasurementInterface->setLocationEnabled(false); this->reportGnssStatusValue(IGnssCallback::GnssStatusValue::SESSION_END); if (mGnssIface == nullptr) { ALOGE("%s: Gnss interface is unavailable", __func__); return ScopedAStatus::fromExceptionCode(STATUS_INVALID_OPERATION); } mGnssIface->stop(); return ScopedAStatus::ok(); } ScopedAStatus Gnss::close() { ALOGD("close"); sGnssCallback = nullptr; return ScopedAStatus::ok(); } void Gnss::reportLocation(const GnssLocation& location) const { std::unique_lock lock(mMutex); if (sGnssCallback == nullptr) { ALOGE("%s: GnssCallback is null.", __func__); return; } auto status = sGnssCallback->gnssLocationCb(location); if (!status.isOk()) { ALOGE("%s: Unable to invoke gnssLocationCb", __func__); } return; } void Gnss::reportSvStatus() const { if (mIsSvStatusActive) { auto svStatus = filterBlocklistedSatellites(Utils::getMockSvInfoList()); reportSvStatus(svStatus); } } void Gnss::reportSvStatus(const std::vector& svInfoList) const { std::unique_lock lock(mMutex); if (sGnssCallback == nullptr) { ALOGE("%s: sGnssCallback is null.", __func__); return; } auto status = sGnssCallback->gnssSvStatusCb(svInfoList); if (!status.isOk()) { ALOGE("%s: Unable to invoke callback", __func__); } } std::vector Gnss::filterBlocklistedSatellites( std::vector gnssSvInfoList) const { for (uint32_t i = 0; i < gnssSvInfoList.size(); i++) { if (mGnssConfiguration->isBlocklisted(gnssSvInfoList[i])) { gnssSvInfoList[i].svFlag &= ~(uint32_t)IGnssCallback::GnssSvFlags::USED_IN_FIX; } } return gnssSvInfoList; } void Gnss::reportGnssStatusValue(const IGnssCallback::GnssStatusValue gnssStatusValue) const { std::unique_lock lock(mMutex); if (sGnssCallback == nullptr) { ALOGE("%s: sGnssCallback is null.", __func__); return; } auto status = sGnssCallback->gnssStatusCb(gnssStatusValue); if (!status.isOk()) { ALOGE("%s: Unable to invoke gnssStatusCb", __func__); } } void Gnss::reportNmea() const { if (mIsNmeaActive) { std::unique_lock lock(mMutex); if (sGnssCallback == nullptr) { ALOGE("%s: sGnssCallback is null.", __func__); return; } nsecs_t now = systemTime(SYSTEM_TIME_MONOTONIC); auto status = sGnssCallback->gnssNmeaCb(now, "$TEST,0,1,2,3,4,5"); if (!status.isOk()) { ALOGE("%s: Unable to invoke callback", __func__); } } } ScopedAStatus Gnss::startSvStatus() { ALOGD("startSvStatus"); mIsSvStatusActive = true; return ScopedAStatus::ok(); } ScopedAStatus Gnss::stopSvStatus() { ALOGD("stopSvStatus"); mIsSvStatusActive = false; return ScopedAStatus::ok(); } ScopedAStatus Gnss::startNmea() { ALOGD("startNmea"); mIsNmeaActive = true; return ScopedAStatus::ok(); } ScopedAStatus Gnss::stopNmea() { ALOGD("stopNmea"); mIsNmeaActive = false; return ScopedAStatus::ok(); } ScopedAStatus Gnss::getExtensionAGnss(std::shared_ptr* iAGnss) { ALOGD("Gnss::getExtensionAGnss"); *iAGnss = SharedRefBase::make(); return ndk::ScopedAStatus::ok(); } ScopedAStatus Gnss::injectTime(int64_t timeMs, int64_t timeReferenceMs, int uncertaintyMs) { ALOGD("injectTime. timeMs:%" PRId64 ", timeReferenceMs:%" PRId64 ", uncertaintyMs:%d", timeMs, timeReferenceMs, uncertaintyMs); return ScopedAStatus::ok(); } ScopedAStatus Gnss::getExtensionAGnssRil(std::shared_ptr* iAGnssRil) { ALOGD("Gnss::getExtensionAGnssRil"); *iAGnssRil = SharedRefBase::make(); return ndk::ScopedAStatus::ok(); } ScopedAStatus Gnss::injectLocation(const GnssLocation& location) { ALOGD("injectLocation. lat:%lf, lng:%lf, acc:%f", location.latitudeDegrees, location.longitudeDegrees, location.horizontalAccuracyMeters); return ScopedAStatus::ok(); } ScopedAStatus Gnss::injectBestLocation(const GnssLocation& location) { ALOGD("injectBestLocation. lat:%lf, lng:%lf, acc:%f", location.latitudeDegrees, location.longitudeDegrees, location.horizontalAccuracyMeters); return ScopedAStatus::ok(); } ScopedAStatus Gnss::deleteAidingData(GnssAidingData aidingDataFlags) { ALOGD("deleteAidingData. flags:%d", (int)aidingDataFlags); mFirstFixReceived = false; return ScopedAStatus::ok(); } ScopedAStatus Gnss::setPositionMode(const PositionModeOptions& options) { ALOGD("setPositionMode. minIntervalMs:%d, lowPowerMode:%d", options.minIntervalMs, (int)options.lowPowerMode); mMinIntervalMs = std::max(1000, options.minIntervalMs); mGnssMeasurementInterface->setLocationInterval(mMinIntervalMs); return ScopedAStatus::ok(); } ScopedAStatus Gnss::getExtensionPsds(std::shared_ptr* iGnssPsds) { ALOGD("getExtensionPsds"); *iGnssPsds = SharedRefBase::make(); return ScopedAStatus::ok(); } ScopedAStatus Gnss::getExtensionGnssConfiguration( std::shared_ptr* iGnssConfiguration) { ALOGD("getExtensionGnssConfiguration"); if (mGnssConfiguration == nullptr) { mGnssConfiguration = SharedRefBase::make(); } *iGnssConfiguration = mGnssConfiguration; return ScopedAStatus::ok(); } ScopedAStatus Gnss::getExtensionGnssPowerIndication( std::shared_ptr* iGnssPowerIndication) { ALOGD("getExtensionGnssPowerIndication"); if (mGnssPowerIndication == nullptr) { mGnssPowerIndication = SharedRefBase::make(); } *iGnssPowerIndication = mGnssPowerIndication; return ScopedAStatus::ok(); } ScopedAStatus Gnss::getExtensionGnssMeasurement( std::shared_ptr* iGnssMeasurement) { ALOGD("getExtensionGnssMeasurement"); if (mGnssMeasurementInterface == nullptr) { mGnssMeasurementInterface = SharedRefBase::make(); mGnssMeasurementInterface->setGnssInterface(static_cast>(this)); } *iGnssMeasurement = mGnssMeasurementInterface; return ScopedAStatus::ok(); } ScopedAStatus Gnss::getExtensionGnssBatching(std::shared_ptr* iGnssBatching) { ALOGD("getExtensionGnssBatching"); *iGnssBatching = SharedRefBase::make(); return ScopedAStatus::ok(); } ScopedAStatus Gnss::getExtensionGnssGeofence(std::shared_ptr* iGnssGeofence) { ALOGD("getExtensionGnssGeofence"); *iGnssGeofence = SharedRefBase::make(); return ScopedAStatus::ok(); } ScopedAStatus Gnss::getExtensionGnssNavigationMessage( std::shared_ptr* iGnssNavigationMessage) { ALOGD("getExtensionGnssNavigationMessage"); *iGnssNavigationMessage = SharedRefBase::make(); return ScopedAStatus::ok(); } ndk::ScopedAStatus Gnss::getExtensionGnssDebug(std::shared_ptr* iGnssDebug) { ALOGD("Gnss::getExtensionGnssDebug"); *iGnssDebug = SharedRefBase::make(); return ndk::ScopedAStatus::ok(); } ndk::ScopedAStatus Gnss::getExtensionGnssVisibilityControl( std::shared_ptr* iGnssVisibilityControl) { ALOGD("Gnss::getExtensionGnssVisibilityControl"); *iGnssVisibilityControl = SharedRefBase::make(); return ndk::ScopedAStatus::ok(); } ndk::ScopedAStatus Gnss::getExtensionGnssAntennaInfo( std::shared_ptr* iGnssAntennaInfo) { ALOGD("Gnss::getExtensionGnssAntennaInfo"); *iGnssAntennaInfo = SharedRefBase::make(); return ndk::ScopedAStatus::ok(); } ndk::ScopedAStatus Gnss::getExtensionMeasurementCorrections( std::shared_ptr* iMeasurementCorrections) { ALOGD("Gnss::getExtensionMeasurementCorrections"); *iMeasurementCorrections = SharedRefBase::make(); return ndk::ScopedAStatus::ok(); } } // namespace aidl::android::hardware::gnss