/* * Copyright (C) 2021 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. */ #include "GnssRawMeasurementParser.h" namespace android { namespace hardware { namespace gnss { namespace common { using aidl::android::hardware::gnss::ElapsedRealtime; using aidl::android::hardware::gnss::GnssClock; using aidl::android::hardware::gnss::GnssConstellationType; using aidl::android::hardware::gnss::GnssData; using aidl::android::hardware::gnss::GnssMeasurement; using aidl::android::hardware::gnss::GnssMultipathIndicator; using aidl::android::hardware::gnss::GnssSignalType; using ParseUtils = ::android::hardware::gnss::common::ParseUtils; std::unordered_map GnssRawMeasurementParser::getColumnIdNameMappingFromHeader( const std::string& header) { std::vector columnNames; std::unordered_map columnNameIdMapping; std::string s = header; // Trim left spaces s.erase(s.begin(), std::find_if(s.begin(), s.end(), [](unsigned char ch) { return !std::isspace(ch); })); // Trim right spaces s.erase(std::find_if(s.rbegin(), s.rend(), [](unsigned char ch) { return !std::isspace(ch); }) .base(), s.end()); // Remove comment symbol, start from `Raw`. s = s.substr(s.find("Raw")); ParseUtils::splitStr(s, COMMA_SEPARATOR, columnNames); int columnId = 0; for (auto& name : columnNames) { columnNameIdMapping[name] = columnId++; } return columnNameIdMapping; } int GnssRawMeasurementParser::getClockFlags( const std::vector& rawMeasurementRecordValues, const std::unordered_map& columnNameIdMapping) { int clockFlags = 0; if (!rawMeasurementRecordValues[columnNameIdMapping.at("LeapSecond")].empty()) { clockFlags |= GnssClock::HAS_LEAP_SECOND; } if (!rawMeasurementRecordValues[columnNameIdMapping.at("FullBiasNanos")].empty()) { clockFlags |= GnssClock::HAS_FULL_BIAS; } if (!rawMeasurementRecordValues[columnNameIdMapping.at("BiasNanos")].empty()) { clockFlags |= GnssClock::HAS_BIAS; } if (!rawMeasurementRecordValues[columnNameIdMapping.at("BiasUncertaintyNanos")].empty()) { clockFlags |= GnssClock::HAS_BIAS_UNCERTAINTY; } if (!rawMeasurementRecordValues[columnNameIdMapping.at("DriftNanosPerSecond")].empty()) { clockFlags |= GnssClock::HAS_DRIFT; } if (!rawMeasurementRecordValues[columnNameIdMapping.at("DriftUncertaintyNanosPerSecond")] .empty()) { clockFlags |= GnssClock::HAS_DRIFT_UNCERTAINTY; } return clockFlags; } int GnssRawMeasurementParser::getElapsedRealtimeFlags( const std::vector& rawMeasurementRecordValues, const std::unordered_map& columnNameIdMapping) { int elapsedRealtimeFlags = ElapsedRealtime::HAS_TIMESTAMP_NS; if (!rawMeasurementRecordValues[columnNameIdMapping.at("TimeUncertaintyNanos")].empty()) { elapsedRealtimeFlags |= ElapsedRealtime::HAS_TIME_UNCERTAINTY_NS; } return elapsedRealtimeFlags; } int GnssRawMeasurementParser::getRawMeasurementFlags( const std::vector& rawMeasurementRecordValues, const std::unordered_map& columnNameIdMapping) { int rawMeasurementFlags = 0; if (!rawMeasurementRecordValues[columnNameIdMapping.at("SnrInDb")].empty()) { rawMeasurementFlags |= GnssMeasurement::HAS_SNR; } if (!rawMeasurementRecordValues[columnNameIdMapping.at("CarrierFrequencyHz")].empty()) { rawMeasurementFlags |= GnssMeasurement::HAS_CARRIER_FREQUENCY; } if (!rawMeasurementRecordValues[columnNameIdMapping.at("CarrierCycles")].empty()) { rawMeasurementFlags |= GnssMeasurement::HAS_CARRIER_CYCLES; } if (!rawMeasurementRecordValues[columnNameIdMapping.at("CarrierPhase")].empty()) { rawMeasurementFlags |= GnssMeasurement::HAS_CARRIER_PHASE; } if (!rawMeasurementRecordValues[columnNameIdMapping.at("CarrierPhaseUncertainty")].empty()) { rawMeasurementFlags |= GnssMeasurement::HAS_CARRIER_PHASE_UNCERTAINTY; } if (!rawMeasurementRecordValues[columnNameIdMapping.at("AgcDb")].empty()) { rawMeasurementFlags |= GnssMeasurement::HAS_AUTOMATIC_GAIN_CONTROL; } if (!rawMeasurementRecordValues[columnNameIdMapping.at("FullInterSignalBiasNanos")].empty()) { rawMeasurementFlags |= GnssMeasurement::HAS_FULL_ISB; } if (!rawMeasurementRecordValues[columnNameIdMapping.at("FullInterSignalBiasUncertaintyNanos")] .empty()) { rawMeasurementFlags |= GnssMeasurement::HAS_FULL_ISB_UNCERTAINTY; } if (!rawMeasurementRecordValues[columnNameIdMapping.at("SatelliteInterSignalBiasNanos")] .empty()) { rawMeasurementFlags |= GnssMeasurement::HAS_SATELLITE_ISB; } if (!rawMeasurementRecordValues[columnNameIdMapping.at( "SatelliteInterSignalBiasUncertaintyNanos")] .empty()) { rawMeasurementFlags |= GnssMeasurement::HAS_SATELLITE_ISB_UNCERTAINTY; } // HAS_SATELLITE_PVT and HAS_CORRELATION_VECTOR fields currently not in rawmeasurement // output, need add them later. return rawMeasurementFlags; } GnssConstellationType GnssRawMeasurementParser::getGnssConstellationType(int constellationType) { GnssConstellationType gnssConstellationType = aidl::android::hardware::gnss::GnssConstellationType::UNKNOWN; switch (constellationType) { case 1: gnssConstellationType = aidl::android::hardware::gnss::GnssConstellationType::GPS; break; case 2: gnssConstellationType = aidl::android::hardware::gnss::GnssConstellationType::SBAS; break; case 3: gnssConstellationType = aidl::android::hardware::gnss::GnssConstellationType::GLONASS; break; case 4: gnssConstellationType = aidl::android::hardware::gnss::GnssConstellationType::QZSS; break; case 5: gnssConstellationType = aidl::android::hardware::gnss::GnssConstellationType::BEIDOU; break; case 6: gnssConstellationType = aidl::android::hardware::gnss::GnssConstellationType::GALILEO; break; default: gnssConstellationType = aidl::android::hardware::gnss::GnssConstellationType::UNKNOWN; } return gnssConstellationType; } std::unique_ptr GnssRawMeasurementParser::getMeasurementFromStrs( std::string& rawMeasurementStr) { /* * Raw,utcTimeMillis,TimeNanos,LeapSecond,TimeUncertaintyNanos,FullBiasNanos,BiasNanos, * BiasUncertaintyNanos,DriftNanosPerSecond,DriftUncertaintyNanosPerSecond, * HardwareClockDiscontinuityCount,Svid,TimeOffsetNanos,State,ReceivedSvTimeNanos, * ReceivedSvTimeUncertaintyNanos,Cn0DbHz,PseudorangeRateMetersPerSecond, * PseudorangeRateUncertaintyMetersPerSecond,AccumulatedDeltaRangeState, * AccumulatedDeltaRangeMeters,AccumulatedDeltaRangeUncertaintyMeters,CarrierFrequencyHz, * CarrierCycles,CarrierPhase,CarrierPhaseUncertainty,MultipathIndicator,SnrInDb, * ConstellationType,AgcDb,BasebandCn0DbHz,FullInterSignalBiasNanos, * FullInterSignalBiasUncertaintyNanos,SatelliteInterSignalBiasNanos, * SatelliteInterSignalBiasUncertaintyNanos,CodeType,ChipsetElapsedRealtimeNanos */ ALOGD("Parsing %zu bytes rawMeasurementStr.", rawMeasurementStr.size()); if (rawMeasurementStr.empty()) { return nullptr; } std::vector rawMeasurementStrRecords; ParseUtils::splitStr(rawMeasurementStr, LINE_SEPARATOR, rawMeasurementStrRecords); if (rawMeasurementStrRecords.size() <= 1) { ALOGE("Raw GNSS Measurements parser failed. (No records) "); return nullptr; } // Get the column name mapping from the header. std::unordered_map columnNameIdMapping = getColumnIdNameMappingFromHeader(rawMeasurementStrRecords[0]); if (columnNameIdMapping.size() < 37 || !ParseUtils::isValidHeader(columnNameIdMapping)) { ALOGE("Raw GNSS Measurements parser failed. (No header or missing columns.) "); return nullptr; } // Set GnssClock from 1st record. std::size_t pointer = 1; std::vector firstRecordValues; ParseUtils::splitStr(rawMeasurementStrRecords[pointer], COMMA_SEPARATOR, firstRecordValues); GnssClock clock = { .gnssClockFlags = getClockFlags(firstRecordValues, columnNameIdMapping), .timeNs = ParseUtils::tryParseLongLong( firstRecordValues[columnNameIdMapping.at("TimeNanos")], 0), .fullBiasNs = ParseUtils::tryParseLongLong( firstRecordValues[columnNameIdMapping.at("FullBiasNanos")], 0), .biasNs = ParseUtils::tryParseDouble( firstRecordValues[columnNameIdMapping.at("BiasNanos")], 0), .biasUncertaintyNs = ParseUtils::tryParseDouble( firstRecordValues[columnNameIdMapping.at("BiasUncertaintyNanos")], 0), .driftNsps = ParseUtils::tryParseDouble( firstRecordValues[columnNameIdMapping.at("DriftNanosPerSecond")], 0), .driftUncertaintyNsps = ParseUtils::tryParseDouble( firstRecordValues[columnNameIdMapping.at("DriftNanosPerSecond")], 0), .hwClockDiscontinuityCount = ParseUtils::tryParseInt( firstRecordValues[columnNameIdMapping.at("HardwareClockDiscontinuityCount")], 0)}; ElapsedRealtime timestamp = { .flags = getElapsedRealtimeFlags(firstRecordValues, columnNameIdMapping), .timestampNs = ParseUtils::tryParseLongLong( firstRecordValues[columnNameIdMapping.at("ChipsetElapsedRealtimeNanos")]), .timeUncertaintyNs = ParseUtils::tryParseDouble( firstRecordValues[columnNameIdMapping.at("TimeUncertaintyNanos")], 0)}; std::vector measurementsVec; for (pointer = 1; pointer < rawMeasurementStrRecords.size(); pointer++) { std::vector rawMeasurementValues; std::string line = rawMeasurementStrRecords[pointer]; ParseUtils::splitStr(line, COMMA_SEPARATOR, rawMeasurementValues); GnssSignalType signalType = { .constellation = getGnssConstellationType(ParseUtils::tryParseInt( rawMeasurementValues[columnNameIdMapping.at("ConstellationType")], 0)), .carrierFrequencyHz = ParseUtils::tryParseDouble( rawMeasurementValues[columnNameIdMapping.at("CarrierFrequencyHz")], 0), .codeType = rawMeasurementValues[columnNameIdMapping.at("CodeType")], }; GnssMeasurement measurement = { .flags = getRawMeasurementFlags(rawMeasurementValues, columnNameIdMapping), .svid = ParseUtils::tryParseInt( rawMeasurementValues[columnNameIdMapping.at("Svid")], 0), .signalType = signalType, .receivedSvTimeInNs = ParseUtils::tryParseLongLong( rawMeasurementValues[columnNameIdMapping.at("ReceivedSvTimeNanos")], 0), .receivedSvTimeUncertaintyInNs = ParseUtils::tryParseLongLong(rawMeasurementValues[columnNameIdMapping.at( "ReceivedSvTimeUncertaintyNanos")], 0), .antennaCN0DbHz = ParseUtils::tryParseDouble( rawMeasurementValues[columnNameIdMapping.at("Cn0DbHz")], 0), .basebandCN0DbHz = ParseUtils::tryParseDouble( rawMeasurementValues[columnNameIdMapping.at("BasebandCn0DbHz")], 0), .agcLevelDb = ParseUtils::tryParseDouble( rawMeasurementValues[columnNameIdMapping.at("AgcDb")], 0), .pseudorangeRateMps = ParseUtils::tryParseDouble(rawMeasurementValues[columnNameIdMapping.at( "PseudorangeRateMetersPerSecond")], 0), .pseudorangeRateUncertaintyMps = ParseUtils::tryParseDouble( rawMeasurementValues[columnNameIdMapping.at( "PseudorangeRateUncertaintyMetersPerSecond")], 0), .accumulatedDeltaRangeState = ParseUtils::tryParseInt( rawMeasurementValues[columnNameIdMapping.at("AccumulatedDeltaRangeState")], 0), .accumulatedDeltaRangeM = ParseUtils::tryParseDouble( rawMeasurementValues[columnNameIdMapping.at("AccumulatedDeltaRangeMeters")], 0), .accumulatedDeltaRangeUncertaintyM = ParseUtils::tryParseDouble( rawMeasurementValues[columnNameIdMapping.at( "AccumulatedDeltaRangeUncertaintyMeters")], 0), .multipathIndicator = GnssMultipathIndicator::UNKNOWN, // Not in GnssLogger yet. .state = ParseUtils::tryParseInt( rawMeasurementValues[columnNameIdMapping.at("State")], 0), .fullInterSignalBiasNs = ParseUtils::tryParseDouble(rawMeasurementValues[31], 0), .fullInterSignalBiasUncertaintyNs = ParseUtils::tryParseDouble( rawMeasurementValues[columnNameIdMapping.at("FullInterSignalBiasNanos")], 0), .satelliteInterSignalBiasNs = ParseUtils::tryParseDouble(rawMeasurementValues[columnNameIdMapping.at( "SatelliteInterSignalBiasNanos")], 0), .satelliteInterSignalBiasUncertaintyNs = ParseUtils::tryParseDouble( rawMeasurementValues[columnNameIdMapping.at( "SatelliteInterSignalBiasUncertaintyNanos")], 0), .satellitePvt = {}, .correlationVectors = {}}; measurementsVec.push_back(measurement); } GnssData gnssData = { .measurements = measurementsVec, .clock = clock, .elapsedRealtime = timestamp}; return std::make_unique(gnssData); } } // namespace common } // namespace gnss } // namespace hardware } // namespace android