| /* Copyright (c) 2017-2020, The Linux Foundation. All rights reserved. |
| * |
| * Redistribution and use in source and binary forms, with or without |
| * modification, are permitted provided that the following conditions are |
| * met: |
| * * Redistributions of source code must retain the above copyright |
| * notice, this list of conditions and the following disclaimer. |
| * * Redistributions in binary form must reproduce the above |
| * copyright notice, this list of conditions and the following |
| * disclaimer in the documentation and/or other materials provided |
| * with the distribution. |
| * * Neither the name of The Linux Foundation, nor the names of its |
| * contributors may be used to endorse or promote products derived |
| * from this software without specific prior written permission. |
| * |
| * THIS SOFTWARE IS PROVIDED "AS IS" AND ANY EXPRESS OR IMPLIED |
| * WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF |
| * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT |
| * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS |
| * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR |
| * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF |
| * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR |
| * BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, |
| * WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE |
| * OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN |
| * IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. |
| * |
| */ |
| |
| #define LOG_NDEBUG 0 |
| #define LOG_TAG "LocSvc_MeasurementAPIClient" |
| |
| #include <log_util.h> |
| #include <loc_cfg.h> |
| #include <inttypes.h> |
| |
| #include "LocationUtil.h" |
| #include "MeasurementAPIClient.h" |
| |
| namespace android { |
| namespace hardware { |
| namespace gnss { |
| namespace V2_1 { |
| namespace implementation { |
| |
| using ::android::hardware::gnss::V1_0::IGnssMeasurement; |
| using ::android::hardware::gnss::V2_0::IGnssMeasurementCallback; |
| |
| static void convertGnssData(GnssMeasurementsNotification& in, |
| V1_0::IGnssMeasurementCallback::GnssData& out); |
| static void convertGnssData_1_1(GnssMeasurementsNotification& in, |
| V1_1::IGnssMeasurementCallback::GnssData& out); |
| static void convertGnssData_2_0(GnssMeasurementsNotification& in, |
| V2_0::IGnssMeasurementCallback::GnssData& out); |
| static void convertGnssData_2_1(GnssMeasurementsNotification& in, |
| V2_1::IGnssMeasurementCallback::GnssData& out); |
| static void convertGnssMeasurement(GnssMeasurementsData& in, |
| V1_0::IGnssMeasurementCallback::GnssMeasurement& out); |
| static void convertGnssClock(GnssMeasurementsClock& in, IGnssMeasurementCallback::GnssClock& out); |
| static void convertGnssClock_2_1(GnssMeasurementsClock& in, |
| V2_1::IGnssMeasurementCallback::GnssClock& out); |
| static void convertGnssMeasurementsCodeType(GnssMeasurementsCodeType& inCodeType, |
| char* inOtherCodeTypeName, |
| ::android::hardware::hidl_string& out); |
| static void convertGnssMeasurementsAccumulatedDeltaRangeState(GnssMeasurementsAdrStateMask& in, |
| ::android::hardware::hidl_bitfield |
| <V1_1::IGnssMeasurementCallback::GnssAccumulatedDeltaRangeState>& out); |
| static void convertGnssMeasurementsState(GnssMeasurementsStateMask& in, |
| ::android::hardware::hidl_bitfield |
| <V2_0::IGnssMeasurementCallback::GnssMeasurementState>& out); |
| |
| MeasurementAPIClient::MeasurementAPIClient() : |
| mGnssMeasurementCbIface(nullptr), |
| mGnssMeasurementCbIface_1_1(nullptr), |
| mGnssMeasurementCbIface_2_0(nullptr), |
| mGnssMeasurementCbIface_2_1(nullptr), |
| mTracking(false) |
| { |
| LOC_LOGD("%s]: ()", __FUNCTION__); |
| } |
| |
| MeasurementAPIClient::~MeasurementAPIClient() |
| { |
| LOC_LOGD("%s]: ()", __FUNCTION__); |
| } |
| |
| // for GpsInterface |
| Return<IGnssMeasurement::GnssMeasurementStatus> |
| MeasurementAPIClient::measurementSetCallback(const sp<V1_0::IGnssMeasurementCallback>& callback) |
| { |
| LOC_LOGD("%s]: (%p)", __FUNCTION__, &callback); |
| |
| mMutex.lock(); |
| mGnssMeasurementCbIface = callback; |
| mMutex.unlock(); |
| |
| return startTracking(); |
| } |
| |
| Return<IGnssMeasurement::GnssMeasurementStatus> |
| MeasurementAPIClient::measurementSetCallback_1_1( |
| const sp<V1_1::IGnssMeasurementCallback>& callback, |
| GnssPowerMode powerMode, uint32_t timeBetweenMeasurement) |
| { |
| LOC_LOGD("%s]: (%p) (powermode: %d) (tbm: %d)", |
| __FUNCTION__, &callback, (int)powerMode, timeBetweenMeasurement); |
| |
| mMutex.lock(); |
| mGnssMeasurementCbIface_1_1 = callback; |
| mMutex.unlock(); |
| |
| return startTracking(powerMode, timeBetweenMeasurement); |
| } |
| |
| Return<IGnssMeasurement::GnssMeasurementStatus> |
| MeasurementAPIClient::measurementSetCallback_2_0( |
| const sp<V2_0::IGnssMeasurementCallback>& callback, |
| GnssPowerMode powerMode, uint32_t timeBetweenMeasurement) |
| { |
| LOC_LOGD("%s]: (%p) (powermode: %d) (tbm: %d)", |
| __FUNCTION__, &callback, (int)powerMode, timeBetweenMeasurement); |
| |
| mMutex.lock(); |
| mGnssMeasurementCbIface_2_0 = callback; |
| mMutex.unlock(); |
| |
| return startTracking(powerMode, timeBetweenMeasurement); |
| } |
| |
| Return<IGnssMeasurement::GnssMeasurementStatus> MeasurementAPIClient::measurementSetCallback_2_1( |
| const sp<V2_1::IGnssMeasurementCallback>& callback, |
| GnssPowerMode powerMode, uint32_t timeBetweenMeasurement) { |
| LOC_LOGD("%s]: (%p) (powermode: %d) (tbm: %d)", |
| __FUNCTION__, &callback, (int)powerMode, timeBetweenMeasurement); |
| |
| mMutex.lock(); |
| mGnssMeasurementCbIface_2_1 = callback; |
| mMutex.unlock(); |
| |
| return startTracking(powerMode, timeBetweenMeasurement); |
| } |
| Return<IGnssMeasurement::GnssMeasurementStatus> |
| MeasurementAPIClient::startTracking( |
| GnssPowerMode powerMode, uint32_t timeBetweenMeasurement) |
| { |
| LocationCallbacks locationCallbacks; |
| memset(&locationCallbacks, 0, sizeof(LocationCallbacks)); |
| locationCallbacks.size = sizeof(LocationCallbacks); |
| |
| locationCallbacks.trackingCb = nullptr; |
| locationCallbacks.batchingCb = nullptr; |
| locationCallbacks.geofenceBreachCb = nullptr; |
| locationCallbacks.geofenceStatusCb = nullptr; |
| locationCallbacks.gnssLocationInfoCb = nullptr; |
| locationCallbacks.gnssNiCb = nullptr; |
| locationCallbacks.gnssSvCb = nullptr; |
| locationCallbacks.gnssNmeaCb = nullptr; |
| |
| locationCallbacks.gnssMeasurementsCb = nullptr; |
| if (mGnssMeasurementCbIface_2_1 != nullptr || |
| mGnssMeasurementCbIface_2_0 != nullptr || |
| mGnssMeasurementCbIface_1_1 != nullptr || |
| mGnssMeasurementCbIface != nullptr) { |
| locationCallbacks.gnssMeasurementsCb = |
| [this](GnssMeasurementsNotification gnssMeasurementsNotification) { |
| onGnssMeasurementsCb(gnssMeasurementsNotification); |
| }; |
| } |
| |
| locAPISetCallbacks(locationCallbacks); |
| |
| TrackingOptions options = {}; |
| memset(&options, 0, sizeof(TrackingOptions)); |
| options.size = sizeof(TrackingOptions); |
| options.minInterval = 1000; |
| options.mode = GNSS_SUPL_MODE_STANDALONE; |
| if (GNSS_POWER_MODE_INVALID != powerMode) { |
| options.powerMode = powerMode; |
| options.tbm = timeBetweenMeasurement; |
| } |
| |
| mTracking = true; |
| LOC_LOGD("%s]: start tracking session", __FUNCTION__); |
| locAPIStartTracking(options); |
| return IGnssMeasurement::GnssMeasurementStatus::SUCCESS; |
| } |
| |
| // for GpsMeasurementInterface |
| void MeasurementAPIClient::measurementClose() { |
| LOC_LOGD("%s]: ()", __FUNCTION__); |
| mTracking = false; |
| locAPIStopTracking(); |
| } |
| |
| // callbacks |
| void MeasurementAPIClient::onGnssMeasurementsCb( |
| GnssMeasurementsNotification gnssMeasurementsNotification) |
| { |
| LOC_LOGD("%s]: (count: %u active: %d)", |
| __FUNCTION__, gnssMeasurementsNotification.count, mTracking); |
| if (mTracking) { |
| mMutex.lock(); |
| sp<V1_0::IGnssMeasurementCallback> gnssMeasurementCbIface = nullptr; |
| sp<V1_1::IGnssMeasurementCallback> gnssMeasurementCbIface_1_1 = nullptr; |
| sp<V2_0::IGnssMeasurementCallback> gnssMeasurementCbIface_2_0 = nullptr; |
| sp<V2_1::IGnssMeasurementCallback> gnssMeasurementCbIface_2_1 = nullptr; |
| if (mGnssMeasurementCbIface_2_1 != nullptr) { |
| gnssMeasurementCbIface_2_1 = mGnssMeasurementCbIface_2_1; |
| } else if (mGnssMeasurementCbIface_2_0 != nullptr) { |
| gnssMeasurementCbIface_2_0 = mGnssMeasurementCbIface_2_0; |
| } else if (mGnssMeasurementCbIface_1_1 != nullptr) { |
| gnssMeasurementCbIface_1_1 = mGnssMeasurementCbIface_1_1; |
| } else if (mGnssMeasurementCbIface != nullptr) { |
| gnssMeasurementCbIface = mGnssMeasurementCbIface; |
| } |
| mMutex.unlock(); |
| |
| if (gnssMeasurementCbIface_2_1 != nullptr) { |
| V2_1::IGnssMeasurementCallback::GnssData gnssData; |
| convertGnssData_2_1(gnssMeasurementsNotification, gnssData); |
| auto r = gnssMeasurementCbIface_2_1->gnssMeasurementCb_2_1(gnssData); |
| if (!r.isOk()) { |
| LOC_LOGE("%s] Error from gnssMeasurementCb description=%s", |
| __func__, r.description().c_str()); |
| } |
| } else if (gnssMeasurementCbIface_2_0 != nullptr) { |
| V2_0::IGnssMeasurementCallback::GnssData gnssData; |
| convertGnssData_2_0(gnssMeasurementsNotification, gnssData); |
| auto r = gnssMeasurementCbIface_2_0->gnssMeasurementCb_2_0(gnssData); |
| if (!r.isOk()) { |
| LOC_LOGE("%s] Error from gnssMeasurementCb description=%s", |
| __func__, r.description().c_str()); |
| } |
| } else if (gnssMeasurementCbIface_1_1 != nullptr) { |
| V1_1::IGnssMeasurementCallback::GnssData gnssData; |
| convertGnssData_1_1(gnssMeasurementsNotification, gnssData); |
| auto r = gnssMeasurementCbIface_1_1->gnssMeasurementCb(gnssData); |
| if (!r.isOk()) { |
| LOC_LOGE("%s] Error from gnssMeasurementCb description=%s", |
| __func__, r.description().c_str()); |
| } |
| } else if (gnssMeasurementCbIface != nullptr) { |
| V1_0::IGnssMeasurementCallback::GnssData gnssData; |
| convertGnssData(gnssMeasurementsNotification, gnssData); |
| auto r = gnssMeasurementCbIface->GnssMeasurementCb(gnssData); |
| if (!r.isOk()) { |
| LOC_LOGE("%s] Error from GnssMeasurementCb description=%s", |
| __func__, r.description().c_str()); |
| } |
| } |
| } |
| } |
| |
| static void convertGnssMeasurement(GnssMeasurementsData& in, |
| V1_0::IGnssMeasurementCallback::GnssMeasurement& out) |
| { |
| memset(&out, 0, sizeof(out)); |
| if (in.flags & GNSS_MEASUREMENTS_DATA_SIGNAL_TO_NOISE_RATIO_BIT) |
| out.flags |= IGnssMeasurementCallback::GnssMeasurementFlags::HAS_SNR; |
| if (in.flags & GNSS_MEASUREMENTS_DATA_CARRIER_FREQUENCY_BIT) |
| out.flags |= IGnssMeasurementCallback::GnssMeasurementFlags::HAS_CARRIER_FREQUENCY; |
| if (in.flags & GNSS_MEASUREMENTS_DATA_CARRIER_CYCLES_BIT) |
| out.flags |= IGnssMeasurementCallback::GnssMeasurementFlags::HAS_CARRIER_CYCLES; |
| if (in.flags & GNSS_MEASUREMENTS_DATA_CARRIER_PHASE_BIT) |
| out.flags |= IGnssMeasurementCallback::GnssMeasurementFlags::HAS_CARRIER_PHASE; |
| if (in.flags & GNSS_MEASUREMENTS_DATA_CARRIER_PHASE_UNCERTAINTY_BIT) |
| out.flags |= IGnssMeasurementCallback::GnssMeasurementFlags::HAS_CARRIER_PHASE_UNCERTAINTY; |
| if (in.flags & GNSS_MEASUREMENTS_DATA_AUTOMATIC_GAIN_CONTROL_BIT) |
| out.flags |= IGnssMeasurementCallback::GnssMeasurementFlags::HAS_AUTOMATIC_GAIN_CONTROL; |
| out.svid = in.svId; |
| convertGnssConstellationType(in.svType, out.constellation); |
| out.timeOffsetNs = in.timeOffsetNs; |
| if (in.stateMask & GNSS_MEASUREMENTS_STATE_CODE_LOCK_BIT) |
| out.state |= IGnssMeasurementCallback::GnssMeasurementState::STATE_CODE_LOCK; |
| if (in.stateMask & GNSS_MEASUREMENTS_STATE_BIT_SYNC_BIT) |
| out.state |= IGnssMeasurementCallback::GnssMeasurementState::STATE_BIT_SYNC; |
| if (in.stateMask & GNSS_MEASUREMENTS_STATE_SUBFRAME_SYNC_BIT) |
| out.state |= IGnssMeasurementCallback::GnssMeasurementState::STATE_SUBFRAME_SYNC; |
| if (in.stateMask & GNSS_MEASUREMENTS_STATE_TOW_DECODED_BIT) |
| out.state |= IGnssMeasurementCallback::GnssMeasurementState::STATE_TOW_DECODED; |
| if (in.stateMask & GNSS_MEASUREMENTS_STATE_MSEC_AMBIGUOUS_BIT) |
| out.state |= IGnssMeasurementCallback::GnssMeasurementState::STATE_MSEC_AMBIGUOUS; |
| if (in.stateMask & GNSS_MEASUREMENTS_STATE_SYMBOL_SYNC_BIT) |
| out.state |= IGnssMeasurementCallback::GnssMeasurementState::STATE_SYMBOL_SYNC; |
| if (in.stateMask & GNSS_MEASUREMENTS_STATE_GLO_STRING_SYNC_BIT) |
| out.state |= IGnssMeasurementCallback::GnssMeasurementState::STATE_GLO_STRING_SYNC; |
| if (in.stateMask & GNSS_MEASUREMENTS_STATE_GLO_TOD_DECODED_BIT) |
| out.state |= IGnssMeasurementCallback::GnssMeasurementState::STATE_GLO_TOD_DECODED; |
| if (in.stateMask & GNSS_MEASUREMENTS_STATE_BDS_D2_BIT_SYNC_BIT) |
| out.state |= IGnssMeasurementCallback::GnssMeasurementState::STATE_BDS_D2_BIT_SYNC; |
| if (in.stateMask & GNSS_MEASUREMENTS_STATE_BDS_D2_SUBFRAME_SYNC_BIT) |
| out.state |= IGnssMeasurementCallback::GnssMeasurementState::STATE_BDS_D2_SUBFRAME_SYNC; |
| if (in.stateMask & GNSS_MEASUREMENTS_STATE_GAL_E1BC_CODE_LOCK_BIT) |
| out.state |= IGnssMeasurementCallback::GnssMeasurementState::STATE_GAL_E1BC_CODE_LOCK; |
| if (in.stateMask & GNSS_MEASUREMENTS_STATE_GAL_E1C_2ND_CODE_LOCK_BIT) |
| out.state |= IGnssMeasurementCallback::GnssMeasurementState::STATE_GAL_E1C_2ND_CODE_LOCK; |
| if (in.stateMask & GNSS_MEASUREMENTS_STATE_GAL_E1B_PAGE_SYNC_BIT) |
| out.state |= IGnssMeasurementCallback::GnssMeasurementState::STATE_GAL_E1B_PAGE_SYNC; |
| if (in.stateMask & GNSS_MEASUREMENTS_STATE_SBAS_SYNC_BIT) |
| out.state |= IGnssMeasurementCallback::GnssMeasurementState::STATE_SBAS_SYNC; |
| out.receivedSvTimeInNs = in.receivedSvTimeNs; |
| out.receivedSvTimeUncertaintyInNs = in.receivedSvTimeUncertaintyNs; |
| out.cN0DbHz = in.carrierToNoiseDbHz; |
| out.pseudorangeRateMps = in.pseudorangeRateMps; |
| out.pseudorangeRateUncertaintyMps = in.pseudorangeRateUncertaintyMps; |
| if (in.adrStateMask & GNSS_MEASUREMENTS_ACCUMULATED_DELTA_RANGE_STATE_VALID_BIT) |
| out.accumulatedDeltaRangeState |= |
| IGnssMeasurementCallback::GnssAccumulatedDeltaRangeState::ADR_STATE_VALID; |
| if (in.adrStateMask & GNSS_MEASUREMENTS_ACCUMULATED_DELTA_RANGE_STATE_RESET_BIT) |
| out.accumulatedDeltaRangeState |= |
| IGnssMeasurementCallback::GnssAccumulatedDeltaRangeState::ADR_STATE_RESET; |
| if (in.adrStateMask & GNSS_MEASUREMENTS_ACCUMULATED_DELTA_RANGE_STATE_CYCLE_SLIP_BIT) |
| out.accumulatedDeltaRangeState |= |
| IGnssMeasurementCallback::GnssAccumulatedDeltaRangeState::ADR_STATE_CYCLE_SLIP; |
| out.accumulatedDeltaRangeM = in.adrMeters; |
| out.accumulatedDeltaRangeUncertaintyM = in.adrUncertaintyMeters; |
| out.carrierFrequencyHz = in.carrierFrequencyHz; |
| out.carrierCycles = in.carrierCycles; |
| out.carrierPhase = in.carrierPhase; |
| out.carrierPhaseUncertainty = in.carrierPhaseUncertainty; |
| uint8_t indicator = |
| static_cast<uint8_t>(IGnssMeasurementCallback::GnssMultipathIndicator::INDICATOR_UNKNOWN); |
| if (in.multipathIndicator & GNSS_MEASUREMENTS_MULTIPATH_INDICATOR_PRESENT) |
| indicator |= IGnssMeasurementCallback::GnssMultipathIndicator::INDICATOR_PRESENT; |
| if (in.multipathIndicator & GNSS_MEASUREMENTS_MULTIPATH_INDICATOR_NOT_PRESENT) |
| indicator |= IGnssMeasurementCallback::GnssMultipathIndicator::INDICATIOR_NOT_PRESENT; |
| out.multipathIndicator = |
| static_cast<IGnssMeasurementCallback::GnssMultipathIndicator>(indicator); |
| out.snrDb = in.signalToNoiseRatioDb; |
| out.agcLevelDb = in.agcLevelDb; |
| } |
| |
| static void convertGnssClock(GnssMeasurementsClock& in, IGnssMeasurementCallback::GnssClock& out) |
| { |
| memset(&out, 0, sizeof(IGnssMeasurementCallback::GnssClock)); |
| if (in.flags & GNSS_MEASUREMENTS_CLOCK_FLAGS_LEAP_SECOND_BIT) |
| out.gnssClockFlags |= IGnssMeasurementCallback::GnssClockFlags::HAS_LEAP_SECOND; |
| if (in.flags & GNSS_MEASUREMENTS_CLOCK_FLAGS_TIME_UNCERTAINTY_BIT) |
| out.gnssClockFlags |= IGnssMeasurementCallback::GnssClockFlags::HAS_TIME_UNCERTAINTY; |
| if (in.flags & GNSS_MEASUREMENTS_CLOCK_FLAGS_FULL_BIAS_BIT) |
| out.gnssClockFlags |= IGnssMeasurementCallback::GnssClockFlags::HAS_FULL_BIAS; |
| if (in.flags & GNSS_MEASUREMENTS_CLOCK_FLAGS_BIAS_BIT) |
| out.gnssClockFlags |= IGnssMeasurementCallback::GnssClockFlags::HAS_BIAS; |
| if (in.flags & GNSS_MEASUREMENTS_CLOCK_FLAGS_BIAS_UNCERTAINTY_BIT) |
| out.gnssClockFlags |= IGnssMeasurementCallback::GnssClockFlags::HAS_BIAS_UNCERTAINTY; |
| if (in.flags & GNSS_MEASUREMENTS_CLOCK_FLAGS_DRIFT_BIT) |
| out.gnssClockFlags |= IGnssMeasurementCallback::GnssClockFlags::HAS_DRIFT; |
| if (in.flags & GNSS_MEASUREMENTS_CLOCK_FLAGS_DRIFT_UNCERTAINTY_BIT) |
| out.gnssClockFlags |= IGnssMeasurementCallback::GnssClockFlags::HAS_DRIFT_UNCERTAINTY; |
| out.leapSecond = in.leapSecond; |
| out.timeNs = in.timeNs; |
| out.timeUncertaintyNs = in.timeUncertaintyNs; |
| out.fullBiasNs = in.fullBiasNs; |
| out.biasNs = in.biasNs; |
| out.biasUncertaintyNs = in.biasUncertaintyNs; |
| out.driftNsps = in.driftNsps; |
| out.driftUncertaintyNsps = in.driftUncertaintyNsps; |
| out.hwClockDiscontinuityCount = in.hwClockDiscontinuityCount; |
| } |
| |
| static void convertGnssClock_2_1(GnssMeasurementsClock& in, |
| V2_1::IGnssMeasurementCallback::GnssClock& out) |
| { |
| convertGnssClock(in, out.v1_0); |
| convertGnssConstellationType(in.referenceSignalTypeForIsb.svType, |
| out.referenceSignalTypeForIsb.constellation); |
| out.referenceSignalTypeForIsb.carrierFrequencyHz = |
| in.referenceSignalTypeForIsb.carrierFrequencyHz; |
| convertGnssMeasurementsCodeType(in.referenceSignalTypeForIsb.codeType, |
| in.referenceSignalTypeForIsb.otherCodeTypeName, |
| out.referenceSignalTypeForIsb.codeType); |
| } |
| |
| static void convertGnssData(GnssMeasurementsNotification& in, |
| V1_0::IGnssMeasurementCallback::GnssData& out) |
| { |
| out.measurementCount = in.count; |
| if (out.measurementCount > static_cast<uint32_t>(V1_0::GnssMax::SVS_COUNT)) { |
| LOC_LOGW("%s]: Too many measurement %u. Clamps to %d.", |
| __FUNCTION__, out.measurementCount, V1_0::GnssMax::SVS_COUNT); |
| out.measurementCount = static_cast<uint32_t>(V1_0::GnssMax::SVS_COUNT); |
| } |
| for (size_t i = 0; i < out.measurementCount; i++) { |
| convertGnssMeasurement(in.measurements[i], out.measurements[i]); |
| } |
| convertGnssClock(in.clock, out.clock); |
| } |
| |
| static void convertGnssData_1_1(GnssMeasurementsNotification& in, |
| V1_1::IGnssMeasurementCallback::GnssData& out) |
| { |
| out.measurements.resize(in.count); |
| for (size_t i = 0; i < in.count; i++) { |
| convertGnssMeasurement(in.measurements[i], out.measurements[i].v1_0); |
| convertGnssMeasurementsAccumulatedDeltaRangeState(in.measurements[i].adrStateMask, |
| out.measurements[i].accumulatedDeltaRangeState); |
| } |
| convertGnssClock(in.clock, out.clock); |
| } |
| |
| static void convertGnssData_2_0(GnssMeasurementsNotification& in, |
| V2_0::IGnssMeasurementCallback::GnssData& out) |
| { |
| out.measurements.resize(in.count); |
| for (size_t i = 0; i < in.count; i++) { |
| convertGnssMeasurement(in.measurements[i], out.measurements[i].v1_1.v1_0); |
| convertGnssConstellationType(in.measurements[i].svType, out.measurements[i].constellation); |
| convertGnssMeasurementsCodeType(in.measurements[i].codeType, |
| in.measurements[i].otherCodeTypeName, |
| out.measurements[i].codeType); |
| convertGnssMeasurementsAccumulatedDeltaRangeState(in.measurements[i].adrStateMask, |
| out.measurements[i].v1_1.accumulatedDeltaRangeState); |
| convertGnssMeasurementsState(in.measurements[i].stateMask, out.measurements[i].state); |
| } |
| convertGnssClock(in.clock, out.clock); |
| |
| const uint32_t UTC_TO_GPS_SECONDS = 315964800; |
| struct timespec currentTime; |
| int64_t sinceBootTimeNanos; |
| |
| if (getCurrentTime(currentTime, sinceBootTimeNanos) && |
| in.clock.flags & GNSS_MEASUREMENTS_CLOCK_FLAGS_LEAP_SECOND_BIT && |
| in.clock.flags & GNSS_MEASUREMENTS_CLOCK_FLAGS_FULL_BIAS_BIT && |
| in.clock.flags & GNSS_MEASUREMENTS_CLOCK_FLAGS_BIAS_BIT && |
| in.clock.flags & GNSS_MEASUREMENTS_CLOCK_FLAGS_BIAS_UNCERTAINTY_BIT) { |
| int64_t currentTimeNanos = currentTime.tv_sec * 1000000000 + currentTime.tv_nsec; |
| int64_t measTimeNanos = (int64_t)in.clock.timeNs - (int64_t)in.clock.fullBiasNs |
| - (int64_t)in.clock.biasNs - (int64_t)in.clock.leapSecond * 1000000000 |
| + (int64_t)UTC_TO_GPS_SECONDS * 1000000000; |
| |
| LOC_LOGd("sinceBootTimeNanos:%" PRIi64 " currentTimeNanos:%" PRIi64 "" |
| " measTimeNanos:%" PRIi64 "", |
| sinceBootTimeNanos, currentTimeNanos, measTimeNanos); |
| if (currentTimeNanos >= measTimeNanos) { |
| int64_t ageTimeNanos = currentTimeNanos - measTimeNanos; |
| LOC_LOGD("%s]: ageTimeNanos:%" PRIi64 ")", __FUNCTION__, ageTimeNanos); |
| if (ageTimeNanos >= 0 && ageTimeNanos <= sinceBootTimeNanos) { |
| out.elapsedRealtime.flags |= V2_0::ElapsedRealtimeFlags::HAS_TIMESTAMP_NS; |
| out.elapsedRealtime.timestampNs = sinceBootTimeNanos - ageTimeNanos; |
| out.elapsedRealtime.flags |= V2_0::ElapsedRealtimeFlags::HAS_TIME_UNCERTAINTY_NS; |
| // time uncertainty is 1 ms since it is calculated from utc time that is in ms |
| out.elapsedRealtime.timeUncertaintyNs = 1000000; |
| LOC_LOGd("timestampNs:%" PRIi64 ") timeUncertaintyNs:%" PRIi64 ")", |
| out.elapsedRealtime.timestampNs, |
| out.elapsedRealtime.timeUncertaintyNs); |
| } |
| } |
| } else { |
| LOC_LOGe("Failed to calculate elapsedRealtimeNanos timestamp"); |
| } |
| } |
| |
| static void convertGnssMeasurementsCodeType(GnssMeasurementsCodeType& inCodeType, |
| char* inOtherCodeTypeName, ::android::hardware::hidl_string& out) |
| { |
| switch(inCodeType) { |
| case GNSS_MEASUREMENTS_CODE_TYPE_A: |
| out = "A"; |
| break; |
| case GNSS_MEASUREMENTS_CODE_TYPE_B: |
| out = "B"; |
| break; |
| case GNSS_MEASUREMENTS_CODE_TYPE_C: |
| out = "C"; |
| break; |
| case GNSS_MEASUREMENTS_CODE_TYPE_I: |
| out = "I"; |
| break; |
| case GNSS_MEASUREMENTS_CODE_TYPE_L: |
| out = "L"; |
| break; |
| case GNSS_MEASUREMENTS_CODE_TYPE_M: |
| out = "M"; |
| break; |
| case GNSS_MEASUREMENTS_CODE_TYPE_P: |
| out = "P"; |
| break; |
| case GNSS_MEASUREMENTS_CODE_TYPE_Q: |
| out = "Q"; |
| break; |
| case GNSS_MEASUREMENTS_CODE_TYPE_S: |
| out = "S"; |
| break; |
| case GNSS_MEASUREMENTS_CODE_TYPE_W: |
| out = "W"; |
| break; |
| case GNSS_MEASUREMENTS_CODE_TYPE_X: |
| out = "X"; |
| break; |
| case GNSS_MEASUREMENTS_CODE_TYPE_Y: |
| out = "Y"; |
| break; |
| case GNSS_MEASUREMENTS_CODE_TYPE_Z: |
| out = "Z"; |
| break; |
| case GNSS_MEASUREMENTS_CODE_TYPE_N: |
| out = "N"; |
| break; |
| case GNSS_MEASUREMENTS_CODE_TYPE_OTHER: |
| default: |
| out = inOtherCodeTypeName; |
| break; |
| } |
| } |
| |
| static void convertGnssMeasurementsAccumulatedDeltaRangeState(GnssMeasurementsAdrStateMask& in, |
| ::android::hardware::hidl_bitfield |
| <V1_1::IGnssMeasurementCallback::GnssAccumulatedDeltaRangeState>& out) |
| { |
| if (in & GNSS_MEASUREMENTS_ACCUMULATED_DELTA_RANGE_STATE_VALID_BIT) |
| out |= IGnssMeasurementCallback::GnssAccumulatedDeltaRangeState::ADR_STATE_VALID; |
| if (in & GNSS_MEASUREMENTS_ACCUMULATED_DELTA_RANGE_STATE_RESET_BIT) |
| out |= IGnssMeasurementCallback::GnssAccumulatedDeltaRangeState::ADR_STATE_RESET; |
| if (in & GNSS_MEASUREMENTS_ACCUMULATED_DELTA_RANGE_STATE_CYCLE_SLIP_BIT) |
| out |= IGnssMeasurementCallback::GnssAccumulatedDeltaRangeState::ADR_STATE_CYCLE_SLIP; |
| if (in & GNSS_MEASUREMENTS_ACCUMULATED_DELTA_RANGE_STATE_HALF_CYCLE_RESOLVED_BIT) |
| out |= IGnssMeasurementCallback:: |
| GnssAccumulatedDeltaRangeState::ADR_STATE_HALF_CYCLE_RESOLVED; |
| } |
| |
| static void convertGnssMeasurementsState(GnssMeasurementsStateMask& in, |
| ::android::hardware::hidl_bitfield |
| <V2_0::IGnssMeasurementCallback::GnssMeasurementState>& out) |
| { |
| if (in & GNSS_MEASUREMENTS_STATE_CODE_LOCK_BIT) |
| out |= IGnssMeasurementCallback::GnssMeasurementState::STATE_CODE_LOCK; |
| if (in & GNSS_MEASUREMENTS_STATE_BIT_SYNC_BIT) |
| out |= IGnssMeasurementCallback::GnssMeasurementState::STATE_BIT_SYNC; |
| if (in & GNSS_MEASUREMENTS_STATE_SUBFRAME_SYNC_BIT) |
| out |= IGnssMeasurementCallback::GnssMeasurementState::STATE_SUBFRAME_SYNC; |
| if (in & GNSS_MEASUREMENTS_STATE_TOW_DECODED_BIT) |
| out |= IGnssMeasurementCallback::GnssMeasurementState::STATE_TOW_DECODED; |
| if (in & GNSS_MEASUREMENTS_STATE_MSEC_AMBIGUOUS_BIT) |
| out |= IGnssMeasurementCallback::GnssMeasurementState::STATE_MSEC_AMBIGUOUS; |
| if (in & GNSS_MEASUREMENTS_STATE_SYMBOL_SYNC_BIT) |
| out |= IGnssMeasurementCallback::GnssMeasurementState::STATE_SYMBOL_SYNC; |
| if (in & GNSS_MEASUREMENTS_STATE_GLO_STRING_SYNC_BIT) |
| out |= IGnssMeasurementCallback::GnssMeasurementState::STATE_GLO_STRING_SYNC; |
| if (in & GNSS_MEASUREMENTS_STATE_GLO_TOD_DECODED_BIT) |
| out |= IGnssMeasurementCallback::GnssMeasurementState::STATE_GLO_TOD_DECODED; |
| if (in & GNSS_MEASUREMENTS_STATE_BDS_D2_BIT_SYNC_BIT) |
| out |= IGnssMeasurementCallback::GnssMeasurementState::STATE_BDS_D2_BIT_SYNC; |
| if (in & GNSS_MEASUREMENTS_STATE_BDS_D2_SUBFRAME_SYNC_BIT) |
| out |= IGnssMeasurementCallback::GnssMeasurementState::STATE_BDS_D2_SUBFRAME_SYNC; |
| if (in & GNSS_MEASUREMENTS_STATE_GAL_E1BC_CODE_LOCK_BIT) |
| out |= IGnssMeasurementCallback::GnssMeasurementState::STATE_GAL_E1BC_CODE_LOCK; |
| if (in & GNSS_MEASUREMENTS_STATE_GAL_E1C_2ND_CODE_LOCK_BIT) |
| out |= IGnssMeasurementCallback::GnssMeasurementState::STATE_GAL_E1C_2ND_CODE_LOCK; |
| if (in & GNSS_MEASUREMENTS_STATE_GAL_E1B_PAGE_SYNC_BIT) |
| out |= IGnssMeasurementCallback::GnssMeasurementState::STATE_GAL_E1B_PAGE_SYNC; |
| if (in & GNSS_MEASUREMENTS_STATE_SBAS_SYNC_BIT) |
| out |= IGnssMeasurementCallback::GnssMeasurementState::STATE_SBAS_SYNC; |
| if (in & GNSS_MEASUREMENTS_STATE_TOW_KNOWN_BIT) |
| out |= IGnssMeasurementCallback::GnssMeasurementState::STATE_TOW_KNOWN; |
| if (in & GNSS_MEASUREMENTS_STATE_GLO_TOD_KNOWN_BIT) |
| out |= IGnssMeasurementCallback::GnssMeasurementState::STATE_GLO_TOD_KNOWN; |
| if (in & GNSS_MEASUREMENTS_STATE_2ND_CODE_LOCK_BIT) |
| out |= IGnssMeasurementCallback::GnssMeasurementState::STATE_2ND_CODE_LOCK; |
| } |
| |
| static void convertGnssData_2_1(GnssMeasurementsNotification& in, |
| V2_1::IGnssMeasurementCallback::GnssData& out) |
| { |
| out.measurements.resize(in.count); |
| for (size_t i = 0; i < in.count; i++) { |
| out.measurements[i].flags = 0; |
| convertGnssMeasurement(in.measurements[i], out.measurements[i].v2_0.v1_1.v1_0); |
| convertGnssConstellationType(in.measurements[i].svType, |
| out.measurements[i].v2_0.constellation); |
| convertGnssMeasurementsCodeType(in.measurements[i].codeType, |
| in.measurements[i].otherCodeTypeName, |
| out.measurements[i].v2_0.codeType); |
| convertGnssMeasurementsAccumulatedDeltaRangeState(in.measurements[i].adrStateMask, |
| out.measurements[i].v2_0.v1_1.accumulatedDeltaRangeState); |
| convertGnssMeasurementsState(in.measurements[i].stateMask, |
| out.measurements[i].v2_0.state); |
| out.measurements[i].basebandCN0DbHz = in.measurements[i].basebandCarrierToNoiseDbHz; |
| |
| if (in.measurements[i].flags & GNSS_MEASUREMENTS_DATA_SIGNAL_TO_NOISE_RATIO_BIT) { |
| out.measurements[i].flags |= |
| V2_1::IGnssMeasurementCallback::GnssMeasurementFlags::HAS_SNR; |
| } |
| if (in.measurements[i].flags & GNSS_MEASUREMENTS_DATA_CARRIER_FREQUENCY_BIT) { |
| out.measurements[i].flags |= |
| V2_1::IGnssMeasurementCallback::GnssMeasurementFlags::HAS_CARRIER_FREQUENCY; |
| } |
| if (in.measurements[i].flags & GNSS_MEASUREMENTS_DATA_CARRIER_CYCLES_BIT) { |
| out.measurements[i].flags |= |
| V2_1::IGnssMeasurementCallback::GnssMeasurementFlags::HAS_CARRIER_CYCLES; |
| } |
| if (in.measurements[i].flags & GNSS_MEASUREMENTS_DATA_CARRIER_PHASE_BIT) { |
| out.measurements[i].flags |= |
| V2_1::IGnssMeasurementCallback::GnssMeasurementFlags::HAS_CARRIER_PHASE; |
| } |
| if (in.measurements[i].flags & GNSS_MEASUREMENTS_DATA_CARRIER_PHASE_UNCERTAINTY_BIT) { |
| out.measurements[i].flags |= |
| V2_1::IGnssMeasurementCallback:: |
| GnssMeasurementFlags::HAS_CARRIER_PHASE_UNCERTAINTY; |
| } |
| if (in.measurements[i].flags & GNSS_MEASUREMENTS_DATA_AUTOMATIC_GAIN_CONTROL_BIT) { |
| out.measurements[i].flags |= |
| V2_1::IGnssMeasurementCallback::GnssMeasurementFlags::HAS_AUTOMATIC_GAIN_CONTROL; |
| } |
| if (in.measurements[i].flags & GNSS_MEASUREMENTS_DATA_FULL_ISB_BIT) { |
| out.measurements[i].fullInterSignalBiasNs = in.measurements[i].fullInterSignalBiasNs; |
| out.measurements[i].flags |= |
| V2_1::IGnssMeasurementCallback::GnssMeasurementFlags::HAS_FULL_ISB; |
| } |
| if (in.measurements[i].flags & GNSS_MEASUREMENTS_DATA_FULL_ISB_UNCERTAINTY_BIT) { |
| out.measurements[i].fullInterSignalBiasUncertaintyNs = |
| in.measurements[i].fullInterSignalBiasUncertaintyNs; |
| out.measurements[i].flags |= |
| V2_1::IGnssMeasurementCallback:: |
| GnssMeasurementFlags::HAS_FULL_ISB_UNCERTAINTY; |
| } |
| if (in.measurements[i].flags & GNSS_MEASUREMENTS_DATA_SATELLITE_ISB_BIT) { |
| out.measurements[i].satelliteInterSignalBiasNs = |
| in.measurements[i].satelliteInterSignalBiasNs; |
| out.measurements[i].flags |= |
| V2_1::IGnssMeasurementCallback::GnssMeasurementFlags::HAS_SATELLITE_ISB; |
| } |
| if (in.measurements[i].flags & GNSS_MEASUREMENTS_DATA_SATELLITE_ISB_UNCERTAINTY_BIT) { |
| out.measurements[i].satelliteInterSignalBiasUncertaintyNs = |
| in.measurements[i].satelliteInterSignalBiasUncertaintyNs; |
| out.measurements[i].flags |= |
| V2_1::IGnssMeasurementCallback:: |
| GnssMeasurementFlags::HAS_SATELLITE_ISB_UNCERTAINTY; |
| } |
| } |
| convertGnssClock_2_1(in.clock, out.clock); |
| } |
| |
| } // namespace implementation |
| } // namespace V2_1 |
| } // namespace gnss |
| } // namespace hardware |
| } // namespace android |