/* * Copyright (C) 2017 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 "GnssHalTestCases" #include #include #include #include using android::hardware::hidl_vec; using IGnssMeasurement_1_0 = android::hardware::gnss::V1_0::IGnssMeasurement; using IGnssMeasurement_1_1 = android::hardware::gnss::V1_1::IGnssMeasurement; using android::hardware::gnss::V1_0::GnssConstellationType; using android::hardware::gnss::V1_0::GnssLocation; using android::hardware::gnss::V1_0::IGnssDebug; using android::hardware::gnss::V1_1::IGnssConfiguration; using android::hardware::gnss::V1_1::IGnssMeasurement; static bool IsAutomotiveDevice() { char buffer[PROPERTY_VALUE_MAX] = {0}; property_get("ro.hardware.type", buffer, ""); return strncmp(buffer, "automotive", PROPERTY_VALUE_MAX) == 0; } /* * SetupTeardownCreateCleanup: * Requests the gnss HAL then calls cleanup * * Empty test fixture to verify basic Setup & Teardown */ TEST_P(GnssHalTest, SetupTeardownCreateCleanup) {} /* * TestGnssMeasurementCallback: * Gets the GnssMeasurementExtension and verify that it returns an actual extension. */ TEST_P(GnssHalTest, TestGnssMeasurementCallback) { auto gnssMeasurement_1_1 = gnss_hal_->getExtensionGnssMeasurement_1_1(); ASSERT_TRUE(gnssMeasurement_1_1.isOk()); auto gnssMeasurement_1_0 = gnss_hal_->getExtensionGnssMeasurement(); ASSERT_TRUE(gnssMeasurement_1_0.isOk()); if (gnss_cb_->last_capabilities_ & IGnssCallback::Capabilities::MEASUREMENTS) { sp iGnssMeas_1_1 = gnssMeasurement_1_1; sp iGnssMeas_1_0 = gnssMeasurement_1_0; // At least one interface must be non-null. ASSERT_TRUE(iGnssMeas_1_1 != nullptr || iGnssMeas_1_0 != nullptr); } } /* * GetLocationLowPower: * Turns on location, waits for at least 5 locations allowing max of LOCATION_TIMEOUT_SUBSEQUENT_SEC * between one location and the next. Also ensure that MIN_INTERVAL_MSEC is respected by waiting * NO_LOCATION_PERIOD_SEC and verfiy that no location is received. Also perform validity checks on * each received location. */ TEST_P(GnssHalTest, GetLocationLowPower) { if (!IsGnssHalVersion_1_1()) { ALOGI("Test GetLocationLowPower skipped. GNSS HAL version is greater than 1.1."); return; } const int kMinIntervalMsec = 5000; const int kLocationTimeoutSubsequentSec = (kMinIntervalMsec / 1000) * 2; const int kNoLocationPeriodSec = (kMinIntervalMsec / 1000) / 2; const int kLocationsToCheck = 5; const bool kLowPowerMode = true; // Warmup period - VTS doesn't have AGPS access via GnssLocationProvider gnss_cb_->location_cbq_.reset(); StartAndCheckLocations(kLocationsToCheck); StopAndClearLocations(); gnss_cb_->location_cbq_.reset(); // Start of Low Power Mode test // Don't expect true - as without AGPS access if (!StartAndCheckFirstLocation(/* strict= */ false, kMinIntervalMsec, kLowPowerMode)) { ALOGW("GetLocationLowPower test - no first low power location received."); } for (int i = 1; i < kLocationsToCheck; i++) { // Verify that kMinIntervalMsec is respected by waiting kNoLocationPeriodSec and // ensure that no location is received yet gnss_cb_->location_cbq_.retrieve(gnss_cb_->last_location_, kNoLocationPeriodSec); const int location_called_count = gnss_cb_->location_cbq_.calledCount(); // Tolerate (ignore) one extra location right after the first one // to handle startup edge case scheduling limitations in some implementations if ((i == 1) && (location_called_count == 2)) { CheckLocation(gnss_cb_->last_location_, true); continue; // restart the quiet wait period after this too-fast location } EXPECT_LE(location_called_count, i); if (location_called_count != i) { ALOGW("GetLocationLowPower test - not enough locations received. %d vs. %d expected ", location_called_count, i); } if (!gnss_cb_->location_cbq_.retrieve( gnss_cb_->last_location_, kLocationTimeoutSubsequentSec - kNoLocationPeriodSec)) { ALOGW("GetLocationLowPower test - timeout awaiting location %d", i); } else { CheckLocation(gnss_cb_->last_location_, true); } } StopAndClearLocations(); } /* * FindStrongFrequentNonGpsSource: * * Search through a GnssSvStatus list for the strongest non-GPS satellite observed enough times * * returns the strongest source, * or a source with constellation == UNKNOWN if none are found sufficient times */ IGnssConfiguration::BlacklistedSource FindStrongFrequentNonGpsSource( const std::list list_gnss_sv_status, const int min_observations) { struct ComparableBlacklistedSource { IGnssConfiguration::BlacklistedSource id; ComparableBlacklistedSource() { id.constellation = GnssConstellationType::UNKNOWN; id.svid = 0; } bool operator<(const ComparableBlacklistedSource& compare) const { return ((id.svid < compare.id.svid) || ((id.svid == compare.id.svid) && (id.constellation < compare.id.constellation))); } }; struct SignalCounts { int observations; float max_cn0_dbhz; }; std::map mapSignals; for (const auto& gnss_sv_status : list_gnss_sv_status) { for (uint32_t iSv = 0; iSv < gnss_sv_status.numSvs; iSv++) { const auto& gnss_sv = gnss_sv_status.gnssSvList[iSv]; if ((gnss_sv.svFlag & IGnssCallback::GnssSvFlags::USED_IN_FIX) && (gnss_sv.constellation != GnssConstellationType::GPS)) { ComparableBlacklistedSource source; source.id.svid = gnss_sv.svid; source.id.constellation = gnss_sv.constellation; const auto& itSignal = mapSignals.find(source); if (itSignal == mapSignals.end()) { SignalCounts counts; counts.observations = 1; counts.max_cn0_dbhz = gnss_sv.cN0Dbhz; mapSignals.insert( std::pair(source, counts)); } else { itSignal->second.observations++; if (itSignal->second.max_cn0_dbhz < gnss_sv.cN0Dbhz) { itSignal->second.max_cn0_dbhz = gnss_sv.cN0Dbhz; } } } } } float max_cn0_dbhz_with_sufficient_count = 0.; int total_observation_count = 0; int blacklisted_source_count_observation = 0; ComparableBlacklistedSource source_to_blacklist; // initializes to zero = UNKNOWN constellation for (auto const& pairSignal : mapSignals) { total_observation_count += pairSignal.second.observations; if ((pairSignal.second.observations >= min_observations) && (pairSignal.second.max_cn0_dbhz > max_cn0_dbhz_with_sufficient_count)) { source_to_blacklist = pairSignal.first; blacklisted_source_count_observation = pairSignal.second.observations; max_cn0_dbhz_with_sufficient_count = pairSignal.second.max_cn0_dbhz; } } ALOGD( "Among %d observations, chose svid %d, constellation %d, " "with %d observations at %.1f max CNo", total_observation_count, source_to_blacklist.id.svid, (int)source_to_blacklist.id.constellation, blacklisted_source_count_observation, max_cn0_dbhz_with_sufficient_count); return source_to_blacklist.id; } /* * BlacklistIndividualSatellites: * * 1) Turns on location, waits for 3 locations, ensuring they are valid, and checks corresponding * GnssStatus for common satellites (strongest and one other.) * 2a & b) Turns off location, and blacklists common satellites. * 3) Restart location, wait for 3 locations, ensuring they are valid, and checks corresponding * GnssStatus does not use those satellites. * 4a & b) Turns off location, and send in empty blacklist. * 5a) Restart location, wait for 3 locations, ensuring they are valid, and checks corresponding * GnssStatus does re-use at least the previously strongest satellite * 5b) Retry a few times, in case GNSS search strategy takes a while to reacquire even the * formerly strongest satellite */ TEST_P(GnssHalTest, BlacklistIndividualSatellites) { if (!IsGnssHalVersion_1_1()) { ALOGI("Test BlacklistIndividualSatellites skipped. GNSS HAL version is greater than 1.1."); return; } const int kLocationsToAwait = 3; const int kRetriesToUnBlacklist = 10; gnss_cb_->location_cbq_.reset(); StartAndCheckLocations(kLocationsToAwait); int location_called_count = gnss_cb_->location_cbq_.calledCount(); // Tolerate 1 less sv status to handle edge cases in reporting. int sv_status_cbq_size = gnss_cb_->sv_status_cbq_.size(); EXPECT_GE(sv_status_cbq_size + 1, kLocationsToAwait); ALOGD("Observed %d GnssSvStatus, while awaiting %d Locations (%d received)", sv_status_cbq_size, kLocationsToAwait, location_called_count); /* * Identify strongest SV seen at least kLocationsToAwait -1 times * Why -1? To avoid test flakiness in case of (plausible) slight flakiness in strongest signal * observability (one epoch RF null) */ const int kGnssSvStatusTimeout = 2; std::list sv_status_list; int count = gnss_cb_->sv_status_cbq_.retrieve(sv_status_list, sv_status_cbq_size, kGnssSvStatusTimeout); ASSERT_EQ(count, sv_status_cbq_size); IGnssConfiguration::BlacklistedSource source_to_blacklist = FindStrongFrequentNonGpsSource(sv_status_list, kLocationsToAwait - 1); if (source_to_blacklist.constellation == GnssConstellationType::UNKNOWN) { // Cannot find a non-GPS satellite. Let the test pass. return; } // Stop locations, blacklist the common SV StopAndClearLocations(); auto gnss_configuration_hal_return = gnss_hal_->getExtensionGnssConfiguration_1_1(); ASSERT_TRUE(gnss_configuration_hal_return.isOk()); sp gnss_configuration_hal = gnss_configuration_hal_return; ASSERT_NE(gnss_configuration_hal, nullptr); hidl_vec sources; sources.resize(1); sources[0] = source_to_blacklist; auto result = gnss_configuration_hal->setBlacklist(sources); ASSERT_TRUE(result.isOk()); EXPECT_TRUE(result); // retry and ensure satellite not used gnss_cb_->sv_status_cbq_.reset(); gnss_cb_->location_cbq_.reset(); StartAndCheckLocations(kLocationsToAwait); // early exit if test is being run with insufficient signal location_called_count = gnss_cb_->location_cbq_.calledCount(); if (location_called_count == 0) { ALOGE("0 Gnss locations received - ensure sufficient signal and retry"); } ASSERT_TRUE(location_called_count > 0); // Tolerate 1 less sv status to handle edge cases in reporting. sv_status_cbq_size = gnss_cb_->sv_status_cbq_.size(); EXPECT_GE(sv_status_cbq_size + 1, kLocationsToAwait); ALOGD("Observed %d GnssSvStatus, while awaiting %d Locations (%d received)", sv_status_cbq_size, kLocationsToAwait, location_called_count); for (int i = 0; i < sv_status_cbq_size; ++i) { IGnssCallback::GnssSvStatus gnss_sv_status; gnss_cb_->sv_status_cbq_.retrieve(gnss_sv_status, kGnssSvStatusTimeout); for (uint32_t iSv = 0; iSv < gnss_sv_status.numSvs; iSv++) { const auto& gnss_sv = gnss_sv_status.gnssSvList[iSv]; EXPECT_FALSE((gnss_sv.svid == source_to_blacklist.svid) && (gnss_sv.constellation == source_to_blacklist.constellation) && (gnss_sv.svFlag & IGnssCallback::GnssSvFlags::USED_IN_FIX)); } } // clear blacklist and restart - this time updating the blacklist while location is still on sources.resize(0); result = gnss_configuration_hal->setBlacklist(sources); ASSERT_TRUE(result.isOk()); EXPECT_TRUE(result); bool strongest_sv_is_reobserved = false; // do several loops awaiting a few locations, allowing non-immediate reacquisition strategies int unblacklist_loops_remaining = kRetriesToUnBlacklist; while (!strongest_sv_is_reobserved && (unblacklist_loops_remaining-- > 0)) { StopAndClearLocations(); gnss_cb_->sv_status_cbq_.reset(); gnss_cb_->location_cbq_.reset(); StartAndCheckLocations(kLocationsToAwait); // early exit loop if test is being run with insufficient signal location_called_count = gnss_cb_->location_cbq_.calledCount(); if (location_called_count == 0) { ALOGE("0 Gnss locations received - ensure sufficient signal and retry"); } ASSERT_TRUE(location_called_count > 0); // Tolerate 1 less sv status to handle edge cases in reporting. sv_status_cbq_size = gnss_cb_->sv_status_cbq_.size(); EXPECT_GE(sv_status_cbq_size + 1, kLocationsToAwait); ALOGD("Clear blacklist, observed %d GnssSvStatus, while awaiting %d Locations" ", tries remaining %d", sv_status_cbq_size, kLocationsToAwait, unblacklist_loops_remaining); for (int i = 0; i < sv_status_cbq_size; ++i) { IGnssCallback::GnssSvStatus gnss_sv_status; gnss_cb_->sv_status_cbq_.retrieve(gnss_sv_status, kGnssSvStatusTimeout); for (uint32_t iSv = 0; iSv < gnss_sv_status.numSvs; iSv++) { const auto& gnss_sv = gnss_sv_status.gnssSvList[iSv]; if ((gnss_sv.svid == source_to_blacklist.svid) && (gnss_sv.constellation == source_to_blacklist.constellation) && (gnss_sv.svFlag & IGnssCallback::GnssSvFlags::USED_IN_FIX)) { strongest_sv_is_reobserved = true; break; } } if (strongest_sv_is_reobserved) break; } } EXPECT_TRUE(strongest_sv_is_reobserved); StopAndClearLocations(); } /* * BlacklistConstellationWithLocationOff: * * 1) Turns on location, waits for 3 locations, ensuring they are valid, and checks corresponding * GnssStatus for any non-GPS constellations. * 2a & b) Turns off location, and blacklist first non-GPS constellations. * 3) Restart location, wait for 3 locations, ensuring they are valid, and checks corresponding * GnssStatus does not use any constellation but GPS. * 4a & b) Clean up by turning off location, and send in empty blacklist. */ TEST_P(GnssHalTest, BlacklistConstellationWithLocationOff) { if (!IsGnssHalVersion_1_1()) { ALOGI("Test BlacklistConstellation skipped. GNSS HAL version is greater than 1.1."); return; } const int kLocationsToAwait = 3; const int kGnssSvStatusTimeout = 2; // Find first non-GPS constellation to blacklist GnssConstellationType constellation_to_blacklist = startLocationAndGetNonGpsConstellation(kLocationsToAwait, kGnssSvStatusTimeout); // Turns off location StopAndClearLocations(); IGnssConfiguration::BlacklistedSource source_to_blacklist; source_to_blacklist.constellation = constellation_to_blacklist; source_to_blacklist.svid = 0; // documented wildcard for all satellites in this constellation auto gnss_configuration_hal_return = gnss_hal_->getExtensionGnssConfiguration_1_1(); ASSERT_TRUE(gnss_configuration_hal_return.isOk()); sp gnss_configuration_hal = gnss_configuration_hal_return; ASSERT_NE(gnss_configuration_hal, nullptr); hidl_vec sources; sources.resize(1); sources[0] = source_to_blacklist; // setBlacklist when location is off. auto result = gnss_configuration_hal->setBlacklist(sources); ASSERT_TRUE(result.isOk()); EXPECT_TRUE(result); // retry and ensure constellation not used gnss_cb_->sv_status_cbq_.reset(); gnss_cb_->location_cbq_.reset(); StartAndCheckLocations(kLocationsToAwait); // Tolerate 1 less sv status to handle edge cases in reporting. int sv_status_cbq_size = gnss_cb_->sv_status_cbq_.size(); EXPECT_GE(sv_status_cbq_size + 1, kLocationsToAwait); ALOGD("Observed %d GnssSvStatus, while awaiting %d Locations", sv_status_cbq_size, kLocationsToAwait); for (int i = 0; i < sv_status_cbq_size; ++i) { IGnssCallback::GnssSvStatus gnss_sv_status; gnss_cb_->sv_status_cbq_.retrieve(gnss_sv_status, kGnssSvStatusTimeout); for (uint32_t iSv = 0; iSv < gnss_sv_status.numSvs; iSv++) { const auto& gnss_sv = gnss_sv_status.gnssSvList[iSv]; EXPECT_FALSE((gnss_sv.constellation == source_to_blacklist.constellation) && (gnss_sv.svFlag & IGnssCallback::GnssSvFlags::USED_IN_FIX)); } } // clean up StopAndClearLocations(); sources.resize(0); result = gnss_configuration_hal->setBlacklist(sources); ASSERT_TRUE(result.isOk()); EXPECT_TRUE(result); } /* * BlacklistConstellationWithLocationOn: * * 1) Turns on location, waits for 3 locations, ensuring they are valid, and checks corresponding * GnssStatus for any non-GPS constellations. * 2a & b) Blacklist first non-GPS constellation, and turn off location. * 3) Restart location, wait for 3 locations, ensuring they are valid, and checks corresponding * GnssStatus does not use any constellation but GPS. * 4a & b) Clean up by turning off location, and send in empty blacklist. */ TEST_P(GnssHalTest, BlacklistConstellationWithLocationOn) { if (!IsGnssHalVersion_1_1()) { ALOGI("Test BlacklistConstellation skipped. GNSS HAL version is greater than 1.1."); return; } const int kLocationsToAwait = 3; const int kGnssSvStatusTimeout = 2; // Find first non-GPS constellation to blacklist GnssConstellationType constellation_to_blacklist = startLocationAndGetNonGpsConstellation(kLocationsToAwait, kGnssSvStatusTimeout); IGnssConfiguration::BlacklistedSource source_to_blacklist; source_to_blacklist.constellation = constellation_to_blacklist; source_to_blacklist.svid = 0; // documented wildcard for all satellites in this constellation auto gnss_configuration_hal_return = gnss_hal_->getExtensionGnssConfiguration_1_1(); ASSERT_TRUE(gnss_configuration_hal_return.isOk()); sp gnss_configuration_hal = gnss_configuration_hal_return; ASSERT_NE(gnss_configuration_hal, nullptr); hidl_vec sources; sources.resize(1); sources[0] = source_to_blacklist; // setBlacklist when location is still on auto result = gnss_configuration_hal->setBlacklist(sources); ASSERT_TRUE(result.isOk()); EXPECT_TRUE(result); // Turns off location StopAndClearLocations(); // retry and ensure constellation not used gnss_cb_->sv_status_cbq_.reset(); gnss_cb_->location_cbq_.reset(); StartAndCheckLocations(kLocationsToAwait); // Tolerate 1 less sv status to handle edge cases in reporting. int sv_status_cbq_size = gnss_cb_->sv_status_cbq_.size(); EXPECT_GE(sv_status_cbq_size + 1, kLocationsToAwait); ALOGD("Observed %d GnssSvStatus, while awaiting %d Locations", sv_status_cbq_size, kLocationsToAwait); for (int i = 0; i < sv_status_cbq_size; ++i) { IGnssCallback::GnssSvStatus gnss_sv_status; gnss_cb_->sv_status_cbq_.retrieve(gnss_sv_status, kGnssSvStatusTimeout); for (uint32_t iSv = 0; iSv < gnss_sv_status.numSvs; iSv++) { const auto& gnss_sv = gnss_sv_status.gnssSvList[iSv]; EXPECT_FALSE((gnss_sv.constellation == source_to_blacklist.constellation) && (gnss_sv.svFlag & IGnssCallback::GnssSvFlags::USED_IN_FIX)); } } // clean up StopAndClearLocations(); sources.resize(0); result = gnss_configuration_hal->setBlacklist(sources); ASSERT_TRUE(result.isOk()); EXPECT_TRUE(result); } /* * InjectBestLocation * * Ensure successfully injecting a location. */ TEST_P(GnssHalTest, InjectBestLocation) { StartAndCheckLocations(1); GnssLocation gnssLocation = gnss_cb_->last_location_; CheckLocation(gnssLocation, true); auto result = gnss_hal_->injectBestLocation(gnssLocation); ASSERT_TRUE(result.isOk()); EXPECT_TRUE(result); auto resultVoid = gnss_hal_->deleteAidingData(IGnss::GnssAidingData::DELETE_POSITION); ASSERT_TRUE(resultVoid.isOk()); } /* * GnssDebugValuesSanityTest: * Ensures that GnssDebug values make sense. */ TEST_P(GnssHalTest, GnssDebugValuesSanityTest) { auto gnssDebug = gnss_hal_->getExtensionGnssDebug(); ASSERT_TRUE(gnssDebug.isOk()); if (!IsAutomotiveDevice() && gnss_cb_->info_cbq_.calledCount() > 0 && gnss_cb_->last_info_.yearOfHw >= 2017) { sp iGnssDebug = gnssDebug; EXPECT_NE(iGnssDebug, nullptr); IGnssDebug::DebugData data; iGnssDebug->getDebugData( [&data](const IGnssDebug::DebugData& debugData) { data = debugData; }); if (data.position.valid) { EXPECT_GE(data.position.latitudeDegrees, -90); EXPECT_LE(data.position.latitudeDegrees, 90); EXPECT_GE(data.position.longitudeDegrees, -180); EXPECT_LE(data.position.longitudeDegrees, 180); EXPECT_GE(data.position.altitudeMeters, -1000); // Dead Sea: -414m EXPECT_LE(data.position.altitudeMeters, 20000); // Mount Everest: 8850m EXPECT_GE(data.position.speedMetersPerSec, 0); EXPECT_LE(data.position.speedMetersPerSec, 600); EXPECT_GE(data.position.bearingDegrees, -360); EXPECT_LE(data.position.bearingDegrees, 360); EXPECT_GT(data.position.horizontalAccuracyMeters, 0); EXPECT_LE(data.position.horizontalAccuracyMeters, 20000000); EXPECT_GT(data.position.verticalAccuracyMeters, 0); EXPECT_LE(data.position.verticalAccuracyMeters, 20000); EXPECT_GT(data.position.speedAccuracyMetersPerSecond, 0); EXPECT_LE(data.position.speedAccuracyMetersPerSecond, 500); EXPECT_GT(data.position.bearingAccuracyDegrees, 0); EXPECT_LE(data.position.bearingAccuracyDegrees, 180); EXPECT_GE(data.position.ageSeconds, 0); } EXPECT_GE(data.time.timeEstimate, 1483228800000); // Jan 01 2017 00:00:00 GMT. EXPECT_GT(data.time.timeUncertaintyNs, 0); EXPECT_GT(data.time.frequencyUncertaintyNsPerSec, 0); EXPECT_LE(data.time.frequencyUncertaintyNsPerSec, 2.0e5); // 200 ppm } }