/* * 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. */ package com.android.server.wifi; import static java.lang.StrictMath.toIntExact; import android.content.Context; import android.hardware.wifi.supplicant.V1_0.ISupplicantStaIfaceCallback; import android.net.NetworkAgent; import android.net.wifi.EAPConstants; import android.net.wifi.IOnWifiUsabilityStatsListener; import android.net.wifi.ScanResult; import android.net.wifi.SupplicantState; import android.net.wifi.WifiConfiguration; import android.net.wifi.WifiInfo; import android.net.wifi.WifiManager; import android.net.wifi.WifiManager.DeviceMobilityState; import android.net.wifi.WifiUsabilityStatsEntry.ProbeStatus; import android.net.wifi.hotspot2.PasspointConfiguration; import android.net.wifi.hotspot2.ProvisioningCallback; import android.os.Handler; import android.os.IBinder; import android.os.Looper; import android.os.Message; import android.os.RemoteException; import android.os.SystemProperties; import android.provider.Settings; import android.telephony.TelephonyManager; import android.util.ArrayMap; import android.util.Base64; import android.util.Log; import android.util.Pair; import android.util.SparseArray; import android.util.SparseIntArray; import com.android.internal.annotations.VisibleForTesting; import com.android.server.wifi.aware.WifiAwareMetrics; import com.android.server.wifi.hotspot2.ANQPNetworkKey; import com.android.server.wifi.hotspot2.NetworkDetail; import com.android.server.wifi.hotspot2.PasspointManager; import com.android.server.wifi.hotspot2.PasspointMatch; import com.android.server.wifi.hotspot2.PasspointProvider; import com.android.server.wifi.hotspot2.Utils; import com.android.server.wifi.nano.WifiMetricsProto; import com.android.server.wifi.nano.WifiMetricsProto.ConnectToNetworkNotificationAndActionCount; import com.android.server.wifi.nano.WifiMetricsProto.DeviceMobilityStatePnoScanStats; import com.android.server.wifi.nano.WifiMetricsProto.ExperimentValues; import com.android.server.wifi.nano.WifiMetricsProto.LinkProbeStats; import com.android.server.wifi.nano.WifiMetricsProto.LinkProbeStats.ExperimentProbeCounts; import com.android.server.wifi.nano.WifiMetricsProto.LinkProbeStats.LinkProbeFailureReasonCount; import com.android.server.wifi.nano.WifiMetricsProto.LinkSpeedCount; import com.android.server.wifi.nano.WifiMetricsProto.NetworkSelectionExperimentDecisions; import com.android.server.wifi.nano.WifiMetricsProto.PasspointProfileTypeCount; import com.android.server.wifi.nano.WifiMetricsProto.PasspointProvisionStats; import com.android.server.wifi.nano.WifiMetricsProto.PasspointProvisionStats.ProvisionFailureCount; import com.android.server.wifi.nano.WifiMetricsProto.PnoScanMetrics; import com.android.server.wifi.nano.WifiMetricsProto.SoftApConnectedClientsEvent; import com.android.server.wifi.nano.WifiMetricsProto.StaEvent; import com.android.server.wifi.nano.WifiMetricsProto.StaEvent.ConfigInfo; import com.android.server.wifi.nano.WifiMetricsProto.WifiIsUnusableEvent; import com.android.server.wifi.nano.WifiMetricsProto.WifiLinkLayerUsageStats; import com.android.server.wifi.nano.WifiMetricsProto.WifiLockStats; import com.android.server.wifi.nano.WifiMetricsProto.WifiNetworkRequestApiLog; import com.android.server.wifi.nano.WifiMetricsProto.WifiNetworkSuggestionApiLog; import com.android.server.wifi.nano.WifiMetricsProto.WifiToggleStats; import com.android.server.wifi.nano.WifiMetricsProto.WifiUsabilityStats; import com.android.server.wifi.nano.WifiMetricsProto.WifiUsabilityStatsEntry; import com.android.server.wifi.nano.WifiMetricsProto.WpsMetrics; import com.android.server.wifi.p2p.WifiP2pMetrics; import com.android.server.wifi.rtt.RttMetrics; import com.android.server.wifi.util.ExternalCallbackTracker; import com.android.server.wifi.util.InformationElementUtil; import com.android.server.wifi.util.IntCounter; import com.android.server.wifi.util.IntHistogram; import com.android.server.wifi.util.MetricsUtils; import com.android.server.wifi.util.ObjectCounter; import com.android.server.wifi.util.ScanResultUtil; import org.json.JSONArray; import org.json.JSONException; import org.json.JSONObject; import java.io.FileDescriptor; import java.io.PrintWriter; import java.util.ArrayList; import java.util.BitSet; import java.util.Calendar; import java.util.HashMap; import java.util.HashSet; import java.util.LinkedList; import java.util.List; import java.util.Map; import java.util.Random; import java.util.Set; /** * Provides storage for wireless connectivity metrics, as they are generated. * Metrics logged by this class include: * Aggregated connection stats (num of connections, num of failures, ...) * Discrete connection event stats (time, duration, failure codes, ...) * Router details (technology type, authentication type, ...) * Scan stats */ public class WifiMetrics { private static final String TAG = "WifiMetrics"; private static final boolean DBG = false; /** * Clamp the RSSI poll counts to values between [MIN,MAX]_RSSI_POLL */ private static final int MAX_RSSI_POLL = 0; private static final int MIN_RSSI_POLL = -127; public static final int MAX_RSSI_DELTA = 127; public static final int MIN_RSSI_DELTA = -127; /** Minimum link speed (Mbps) to count for link_speed_counts */ public static final int MIN_LINK_SPEED_MBPS = 0; /** Maximum time period between ScanResult and RSSI poll to generate rssi delta datapoint */ public static final long TIMEOUT_RSSI_DELTA_MILLIS = 3000; private static final int MIN_WIFI_SCORE = 0; private static final int MAX_WIFI_SCORE = NetworkAgent.WIFI_BASE_SCORE; private static final int MIN_WIFI_USABILITY_SCORE = 0; // inclusive private static final int MAX_WIFI_USABILITY_SCORE = 100; // inclusive @VisibleForTesting static final int LOW_WIFI_SCORE = 50; // Mobile data score @VisibleForTesting static final int LOW_WIFI_USABILITY_SCORE = 50; // Mobile data score private final Object mLock = new Object(); private static final int MAX_CONNECTION_EVENTS = 256; // Largest bucket in the NumConnectableNetworkCount histogram, // anything large will be stored in this bucket public static final int MAX_CONNECTABLE_SSID_NETWORK_BUCKET = 20; public static final int MAX_CONNECTABLE_BSSID_NETWORK_BUCKET = 50; public static final int MAX_TOTAL_SCAN_RESULT_SSIDS_BUCKET = 100; public static final int MAX_TOTAL_SCAN_RESULTS_BUCKET = 250; public static final int MAX_TOTAL_PASSPOINT_APS_BUCKET = 50; public static final int MAX_TOTAL_PASSPOINT_UNIQUE_ESS_BUCKET = 20; public static final int MAX_PASSPOINT_APS_PER_UNIQUE_ESS_BUCKET = 50; public static final int MAX_TOTAL_80211MC_APS_BUCKET = 20; private static final int CONNECT_TO_NETWORK_NOTIFICATION_ACTION_KEY_MULTIPLIER = 1000; // Max limit for number of soft AP related events, extra events will be dropped. private static final int MAX_NUM_SOFT_AP_EVENTS = 256; // Maximum number of WifiIsUnusableEvent public static final int MAX_UNUSABLE_EVENTS = 20; // Minimum time wait before generating next WifiIsUnusableEvent from data stall public static final int MIN_DATA_STALL_WAIT_MS = 120 * 1000; // 2 minutes private static final int WIFI_IS_UNUSABLE_EVENT_METRICS_ENABLED_DEFAULT = 1; // 1 = true private static final int WIFI_LINK_SPEED_METRICS_ENABLED_DEFAULT = 1; // 1 = true // Max number of WifiUsabilityStatsEntry elements to store in the ringbuffer. public static final int MAX_WIFI_USABILITY_STATS_ENTRIES_LIST_SIZE = 40; // Max number of WifiUsabilityStats elements to store for each type. public static final int MAX_WIFI_USABILITY_STATS_LIST_SIZE_PER_TYPE = 10; // Max number of WifiUsabilityStats per labeled type to upload to server public static final int MAX_WIFI_USABILITY_STATS_PER_TYPE_TO_UPLOAD = 2; public static final int NUM_WIFI_USABILITY_STATS_ENTRIES_PER_WIFI_GOOD = 100; public static final int MIN_WIFI_GOOD_USABILITY_STATS_PERIOD_MS = 1000 * 3600; // 1 hour // Histogram for WifiConfigStore IO duration times. Indicates the following 5 buckets (in ms): // < 50 // [50, 100) // [100, 150) // [150, 200) // [200, 300) // >= 300 private static final int[] WIFI_CONFIG_STORE_IO_DURATION_BUCKET_RANGES_MS = {50, 100, 150, 200, 300}; // Minimum time wait before generating a LABEL_GOOD stats after score breaching low. public static final int MIN_SCORE_BREACH_TO_GOOD_STATS_WAIT_TIME_MS = 60 * 1000; // 1 minute // Maximum time that a score breaching low event stays valid. public static final int VALIDITY_PERIOD_OF_SCORE_BREACH_LOW_MS = 90 * 1000; // 1.5 minutes public static final int BAND_2G_MAX_FREQ_MHZ = 2484; public static final int BAND_5G_LOW_MAX_FREQ_MHZ = 5240; public static final int BAND_5G_MID_MAX_FREQ_MHZ = 5720; public static final int BAND_5G_HIGH_MAX_FREQ_MHZ = 5865; private Clock mClock; private boolean mScreenOn; private int mWifiState; private WifiAwareMetrics mWifiAwareMetrics; private RttMetrics mRttMetrics; private final PnoScanMetrics mPnoScanMetrics = new PnoScanMetrics(); private final WifiLinkLayerUsageStats mWifiLinkLayerUsageStats = new WifiLinkLayerUsageStats(); private final WpsMetrics mWpsMetrics = new WpsMetrics(); private final ExperimentValues mExperimentValues = new ExperimentValues(); private Handler mHandler; private ScoringParams mScoringParams; private WifiConfigManager mWifiConfigManager; private WifiNetworkSelector mWifiNetworkSelector; private PasspointManager mPasspointManager; private Context mContext; private FrameworkFacade mFacade; private WifiDataStall mWifiDataStall; private WifiLinkLayerStats mLastLinkLayerStats; private String mLastBssid; private int mLastFrequency = -1; private int mSeqNumInsideFramework = 0; private int mLastWifiUsabilityScore = -1; private int mLastWifiUsabilityScoreNoReset = -1; private int mLastPredictionHorizonSec = -1; private int mLastPredictionHorizonSecNoReset = -1; private int mSeqNumToFramework = -1; @ProbeStatus private int mProbeStatusSinceLastUpdate = android.net.wifi.WifiUsabilityStatsEntry.PROBE_STATUS_NO_PROBE; private int mProbeElapsedTimeSinceLastUpdateMs = -1; private int mProbeMcsRateSinceLastUpdate = -1; private long mScoreBreachLowTimeMillis = -1; public static final int MAX_STA_EVENTS = 768; private LinkedList mStaEventList = new LinkedList<>(); private int mLastPollRssi = -127; private int mLastPollLinkSpeed = -1; private int mLastPollRxLinkSpeed = -1; private int mLastPollFreq = -1; private int mLastScore = -1; /** Tracks if we should be logging WifiIsUnusableEvent */ private boolean mUnusableEventLogging = false; /** Tracks if we should be logging LinkSpeedCounts */ private boolean mLinkSpeedCountsLogging = true; /** * Metrics are stored within an instance of the WifiLog proto during runtime, * The ConnectionEvent, SystemStateEntries & ScanReturnEntries metrics are stored during * runtime in member lists of this WifiMetrics class, with the final WifiLog proto being pieced * together at dump-time */ private final WifiMetricsProto.WifiLog mWifiLogProto = new WifiMetricsProto.WifiLog(); /** * Session information that gets logged for every Wifi connection attempt. */ private final List mConnectionEventList = new ArrayList<>(); /** * The latest started (but un-ended) connection attempt */ private ConnectionEvent mCurrentConnectionEvent; /** * Count of number of times each scan return code, indexed by WifiLog.ScanReturnCode */ private final SparseIntArray mScanReturnEntries = new SparseIntArray(); /** * Mapping of system state to the counts of scans requested in that wifi state * screenOn * combination. Indexed by WifiLog.WifiState * (1 + screenOn) */ private final SparseIntArray mWifiSystemStateEntries = new SparseIntArray(); /** Mapping of channel frequency to its RSSI distribution histogram **/ private final Map mRssiPollCountsMap = new HashMap<>(); /** Mapping of RSSI scan-poll delta values to counts. */ private final SparseIntArray mRssiDeltaCounts = new SparseIntArray(); /** Mapping of link speed values to LinkSpeedCount objects. */ private final SparseArray mLinkSpeedCounts = new SparseArray<>(); private final IntCounter mTxLinkSpeedCount2g = new IntCounter(); private final IntCounter mTxLinkSpeedCount5gLow = new IntCounter(); private final IntCounter mTxLinkSpeedCount5gMid = new IntCounter(); private final IntCounter mTxLinkSpeedCount5gHigh = new IntCounter(); private final IntCounter mRxLinkSpeedCount2g = new IntCounter(); private final IntCounter mRxLinkSpeedCount5gLow = new IntCounter(); private final IntCounter mRxLinkSpeedCount5gMid = new IntCounter(); private final IntCounter mRxLinkSpeedCount5gHigh = new IntCounter(); /** RSSI of the scan result for the last connection event*/ private int mScanResultRssi = 0; /** Boot-relative timestamp when the last candidate scanresult was received, used to calculate RSSI deltas. -1 designates no candidate scanResult being tracked */ private long mScanResultRssiTimestampMillis = -1; /** Mapping of alert reason to the respective alert count. */ private final SparseIntArray mWifiAlertReasonCounts = new SparseIntArray(); /** * Records the getElapsedSinceBootMillis (in seconds) that represents the beginning of data * capture for for this WifiMetricsProto */ private long mRecordStartTimeSec; /** Mapping of Wifi Scores to counts */ private final SparseIntArray mWifiScoreCounts = new SparseIntArray(); /** Mapping of Wifi Usability Scores to counts */ private final SparseIntArray mWifiUsabilityScoreCounts = new SparseIntArray(); /** Mapping of SoftApManager start SoftAp return codes to counts */ private final SparseIntArray mSoftApManagerReturnCodeCounts = new SparseIntArray(); private final SparseIntArray mTotalSsidsInScanHistogram = new SparseIntArray(); private final SparseIntArray mTotalBssidsInScanHistogram = new SparseIntArray(); private final SparseIntArray mAvailableOpenSsidsInScanHistogram = new SparseIntArray(); private final SparseIntArray mAvailableOpenBssidsInScanHistogram = new SparseIntArray(); private final SparseIntArray mAvailableSavedSsidsInScanHistogram = new SparseIntArray(); private final SparseIntArray mAvailableSavedBssidsInScanHistogram = new SparseIntArray(); private final SparseIntArray mAvailableOpenOrSavedSsidsInScanHistogram = new SparseIntArray(); private final SparseIntArray mAvailableOpenOrSavedBssidsInScanHistogram = new SparseIntArray(); private final SparseIntArray mAvailableSavedPasspointProviderProfilesInScanHistogram = new SparseIntArray(); private final SparseIntArray mAvailableSavedPasspointProviderBssidsInScanHistogram = new SparseIntArray(); private final IntCounter mInstalledPasspointProfileTypeForR1 = new IntCounter(); private final IntCounter mInstalledPasspointProfileTypeForR2 = new IntCounter(); /** Mapping of "Connect to Network" notifications to counts. */ private final SparseIntArray mConnectToNetworkNotificationCount = new SparseIntArray(); /** Mapping of "Connect to Network" notification user actions to counts. */ private final SparseIntArray mConnectToNetworkNotificationActionCount = new SparseIntArray(); private int mOpenNetworkRecommenderBlacklistSize = 0; private boolean mIsWifiNetworksAvailableNotificationOn = false; private int mNumOpenNetworkConnectMessageFailedToSend = 0; private int mNumOpenNetworkRecommendationUpdates = 0; /** List of soft AP events related to number of connected clients in tethered mode */ private final List mSoftApEventListTethered = new ArrayList<>(); /** List of soft AP events related to number of connected clients in local only mode */ private final List mSoftApEventListLocalOnly = new ArrayList<>(); private final SparseIntArray mObservedHotspotR1ApInScanHistogram = new SparseIntArray(); private final SparseIntArray mObservedHotspotR2ApInScanHistogram = new SparseIntArray(); private final SparseIntArray mObservedHotspotR1EssInScanHistogram = new SparseIntArray(); private final SparseIntArray mObservedHotspotR2EssInScanHistogram = new SparseIntArray(); private final SparseIntArray mObservedHotspotR1ApsPerEssInScanHistogram = new SparseIntArray(); private final SparseIntArray mObservedHotspotR2ApsPerEssInScanHistogram = new SparseIntArray(); private final SparseIntArray mObserved80211mcApInScanHistogram = new SparseIntArray(); // link probing stats private final IntCounter mLinkProbeSuccessRssiCounts = new IntCounter(-85, -65); private final IntCounter mLinkProbeFailureRssiCounts = new IntCounter(-85, -65); private final IntCounter mLinkProbeSuccessLinkSpeedCounts = new IntCounter(); private final IntCounter mLinkProbeFailureLinkSpeedCounts = new IntCounter(); private static final int[] LINK_PROBE_TIME_SINCE_LAST_TX_SUCCESS_SECONDS_HISTOGRAM_BUCKETS = {5, 15, 45, 135}; private final IntHistogram mLinkProbeSuccessSecondsSinceLastTxSuccessHistogram = new IntHistogram(LINK_PROBE_TIME_SINCE_LAST_TX_SUCCESS_SECONDS_HISTOGRAM_BUCKETS); private final IntHistogram mLinkProbeFailureSecondsSinceLastTxSuccessHistogram = new IntHistogram(LINK_PROBE_TIME_SINCE_LAST_TX_SUCCESS_SECONDS_HISTOGRAM_BUCKETS); private static final int[] LINK_PROBE_ELAPSED_TIME_MS_HISTOGRAM_BUCKETS = {5, 10, 15, 20, 25, 50, 100, 200, 400, 800}; private final IntHistogram mLinkProbeSuccessElapsedTimeMsHistogram = new IntHistogram( LINK_PROBE_ELAPSED_TIME_MS_HISTOGRAM_BUCKETS); private final IntCounter mLinkProbeFailureReasonCounts = new IntCounter(); /** * Maps a String link probe experiment ID to the number of link probes that were sent for this * experiment. */ private final ObjectCounter mLinkProbeExperimentProbeCounts = new ObjectCounter<>(); private int mLinkProbeStaEventCount = 0; @VisibleForTesting static final int MAX_LINK_PROBE_STA_EVENTS = MAX_STA_EVENTS / 4; private final LinkedList mWifiUsabilityStatsEntriesList = new LinkedList<>(); private final LinkedList mWifiUsabilityStatsListBad = new LinkedList<>(); private final LinkedList mWifiUsabilityStatsListGood = new LinkedList<>(); private int mWifiUsabilityStatsCounter = 0; private final Random mRand = new Random(); private final ExternalCallbackTracker mOnWifiUsabilityListeners; private final SparseArray mMobilityStatePnoStatsMap = new SparseArray<>(); private int mCurrentDeviceMobilityState; /** * The timestamp of the start of the current device mobility state. */ private long mCurrentDeviceMobilityStateStartMs; /** * The timestamp of when the PNO scan started in the current device mobility state. */ private long mCurrentDeviceMobilityStatePnoScanStartMs; /** Wifi power metrics*/ private WifiPowerMetrics mWifiPowerMetrics; /** Wifi Wake metrics */ private final WifiWakeMetrics mWifiWakeMetrics = new WifiWakeMetrics(); /** Wifi P2p metrics */ private final WifiP2pMetrics mWifiP2pMetrics; private boolean mIsMacRandomizationOn = false; /** DPP */ private final DppMetrics mDppMetrics; /** WifiConfigStore read duration histogram. */ private SparseIntArray mWifiConfigStoreReadDurationHistogram = new SparseIntArray(); /** WifiConfigStore write duration histogram. */ private SparseIntArray mWifiConfigStoreWriteDurationHistogram = new SparseIntArray(); /** New API surface metrics */ private final WifiNetworkRequestApiLog mWifiNetworkRequestApiLog = new WifiNetworkRequestApiLog(); private static final int[] NETWORK_REQUEST_API_MATCH_SIZE_HISTOGRAM_BUCKETS = {0, 1, 5, 10}; private final IntHistogram mWifiNetworkRequestApiMatchSizeHistogram = new IntHistogram(NETWORK_REQUEST_API_MATCH_SIZE_HISTOGRAM_BUCKETS); private final WifiNetworkSuggestionApiLog mWifiNetworkSuggestionApiLog = new WifiNetworkSuggestionApiLog(); private static final int[] NETWORK_SUGGESTION_API_LIST_SIZE_HISTOGRAM_BUCKETS = {5, 20, 50, 100, 500}; private final IntHistogram mWifiNetworkSuggestionApiListSizeHistogram = new IntHistogram(NETWORK_SUGGESTION_API_LIST_SIZE_HISTOGRAM_BUCKETS); private final WifiLockStats mWifiLockStats = new WifiLockStats(); private static final int[] WIFI_LOCK_SESSION_DURATION_HISTOGRAM_BUCKETS = {1, 10, 60, 600, 3600}; private final WifiToggleStats mWifiToggleStats = new WifiToggleStats(); private final IntHistogram mWifiLockHighPerfAcqDurationSecHistogram = new IntHistogram(WIFI_LOCK_SESSION_DURATION_HISTOGRAM_BUCKETS); private final IntHistogram mWifiLockLowLatencyAcqDurationSecHistogram = new IntHistogram(WIFI_LOCK_SESSION_DURATION_HISTOGRAM_BUCKETS); private final IntHistogram mWifiLockHighPerfActiveSessionDurationSecHistogram = new IntHistogram(WIFI_LOCK_SESSION_DURATION_HISTOGRAM_BUCKETS); private final IntHistogram mWifiLockLowLatencyActiveSessionDurationSecHistogram = new IntHistogram(WIFI_LOCK_SESSION_DURATION_HISTOGRAM_BUCKETS); /** * (experiment1Id, experiment2Id) => * (sameSelectionNumChoicesCounter, differentSelectionNumChoicesCounter) */ private Map, NetworkSelectionExperimentResults> mNetworkSelectionExperimentPairNumChoicesCounts = new ArrayMap<>(); private int mNetworkSelectorExperimentId; private final CellularLinkLayerStatsCollector mCellularLinkLayerStatsCollector; /** * Tracks the nominator for each network (i.e. which entity made the suggestion to connect). * This object should not be cleared. */ private final SparseIntArray mNetworkIdToNominatorId = new SparseIntArray(); /** passpoint provision success count */ private int mNumProvisionSuccess = 0; /** Mapping of failure code to the respective passpoint provision failure count. */ private final IntCounter mPasspointProvisionFailureCounts = new IntCounter(); @VisibleForTesting static class NetworkSelectionExperimentResults { public static final int MAX_CHOICES = 10; public IntCounter sameSelectionNumChoicesCounter = new IntCounter(0, MAX_CHOICES); public IntCounter differentSelectionNumChoicesCounter = new IntCounter(0, MAX_CHOICES); @Override public String toString() { return "NetworkSelectionExperimentResults{" + "sameSelectionNumChoicesCounter=" + sameSelectionNumChoicesCounter + ", differentSelectionNumChoicesCounter=" + differentSelectionNumChoicesCounter + '}'; } } class RouterFingerPrint { private WifiMetricsProto.RouterFingerPrint mRouterFingerPrintProto; RouterFingerPrint() { mRouterFingerPrintProto = new WifiMetricsProto.RouterFingerPrint(); } public String toString() { StringBuilder sb = new StringBuilder(); synchronized (mLock) { sb.append("mConnectionEvent.roamType=" + mRouterFingerPrintProto.roamType); sb.append(", mChannelInfo=" + mRouterFingerPrintProto.channelInfo); sb.append(", mDtim=" + mRouterFingerPrintProto.dtim); sb.append(", mAuthentication=" + mRouterFingerPrintProto.authentication); sb.append(", mHidden=" + mRouterFingerPrintProto.hidden); sb.append(", mRouterTechnology=" + mRouterFingerPrintProto.routerTechnology); sb.append(", mSupportsIpv6=" + mRouterFingerPrintProto.supportsIpv6); } return sb.toString(); } public void updateFromWifiConfiguration(WifiConfiguration config) { synchronized (mLock) { if (config != null) { // Is this a hidden network mRouterFingerPrintProto.hidden = config.hiddenSSID; // Config may not have a valid dtimInterval set yet, in which case dtim will be zero // (These are only populated from beacon frame scan results, which are returned as // scan results from the chip far less frequently than Probe-responses) if (config.dtimInterval > 0) { mRouterFingerPrintProto.dtim = config.dtimInterval; } mCurrentConnectionEvent.mConfigSsid = config.SSID; // Get AuthType information from config (We do this again from ScanResult after // associating with BSSID) if (config.allowedKeyManagement != null && config.allowedKeyManagement.get(WifiConfiguration.KeyMgmt.NONE)) { mCurrentConnectionEvent.mRouterFingerPrint.mRouterFingerPrintProto .authentication = WifiMetricsProto.RouterFingerPrint.AUTH_OPEN; } else if (config.isEnterprise()) { mCurrentConnectionEvent.mRouterFingerPrint.mRouterFingerPrintProto .authentication = WifiMetricsProto.RouterFingerPrint.AUTH_ENTERPRISE; } else { mCurrentConnectionEvent.mRouterFingerPrint.mRouterFingerPrintProto .authentication = WifiMetricsProto.RouterFingerPrint.AUTH_PERSONAL; } mCurrentConnectionEvent.mRouterFingerPrint.mRouterFingerPrintProto .passpoint = config.isPasspoint(); // If there's a ScanResult candidate associated with this config already, get it and // log (more accurate) metrics from it ScanResult candidate = config.getNetworkSelectionStatus().getCandidate(); if (candidate != null) { updateMetricsFromScanResult(candidate); } } } } } /** * Log event, tracking the start time, end time and result of a wireless connection attempt. */ class ConnectionEvent { WifiMetricsProto.ConnectionEvent mConnectionEvent; // Move these constants into a wifi.proto Enum, and create a new Failure Type field //covering more than just l2 failures. see b/27652362 /** * Failure codes, used for the 'level_2_failure_code' Connection event field (covers a lot * more failures than just l2 though, since the proto does not have a place to log * framework failures) */ // Failure is unknown public static final int FAILURE_UNKNOWN = 0; // NONE public static final int FAILURE_NONE = 1; // ASSOCIATION_REJECTION_EVENT public static final int FAILURE_ASSOCIATION_REJECTION = 2; // AUTHENTICATION_FAILURE_EVENT public static final int FAILURE_AUTHENTICATION_FAILURE = 3; // SSID_TEMP_DISABLED (Also Auth failure) public static final int FAILURE_SSID_TEMP_DISABLED = 4; // reconnect() or reassociate() call to WifiNative failed public static final int FAILURE_CONNECT_NETWORK_FAILED = 5; // NETWORK_DISCONNECTION_EVENT public static final int FAILURE_NETWORK_DISCONNECTION = 6; // NEW_CONNECTION_ATTEMPT before previous finished public static final int FAILURE_NEW_CONNECTION_ATTEMPT = 7; // New connection attempt to the same network & bssid public static final int FAILURE_REDUNDANT_CONNECTION_ATTEMPT = 8; // Roam Watchdog timer triggered (Roaming timed out) public static final int FAILURE_ROAM_TIMEOUT = 9; // DHCP failure public static final int FAILURE_DHCP = 10; // ASSOCIATION_TIMED_OUT public static final int FAILURE_ASSOCIATION_TIMED_OUT = 11; RouterFingerPrint mRouterFingerPrint; private long mRealStartTime; private long mRealEndTime; private String mConfigSsid; private String mConfigBssid; private int mWifiState; private boolean mScreenOn; private ConnectionEvent() { mConnectionEvent = new WifiMetricsProto.ConnectionEvent(); mRealEndTime = 0; mRealStartTime = 0; mRouterFingerPrint = new RouterFingerPrint(); mConnectionEvent.routerFingerprint = mRouterFingerPrint.mRouterFingerPrintProto; mConfigSsid = ""; mConfigBssid = ""; mWifiState = WifiMetricsProto.WifiLog.WIFI_UNKNOWN; mScreenOn = false; } public String toString() { StringBuilder sb = new StringBuilder(); sb.append("startTime="); Calendar c = Calendar.getInstance(); synchronized (mLock) { c.setTimeInMillis(mConnectionEvent.startTimeMillis); sb.append(mConnectionEvent.startTimeMillis == 0 ? " " : String.format("%tm-%td %tH:%tM:%tS.%tL", c, c, c, c, c, c)); sb.append(", SSID="); sb.append(mConfigSsid); sb.append(", BSSID="); sb.append(mConfigBssid); sb.append(", durationMillis="); sb.append(mConnectionEvent.durationTakenToConnectMillis); sb.append(", roamType="); switch(mConnectionEvent.roamType) { case 1: sb.append("ROAM_NONE"); break; case 2: sb.append("ROAM_DBDC"); break; case 3: sb.append("ROAM_ENTERPRISE"); break; case 4: sb.append("ROAM_USER_SELECTED"); break; case 5: sb.append("ROAM_UNRELATED"); break; default: sb.append("ROAM_UNKNOWN"); } sb.append(", connectionResult="); sb.append(mConnectionEvent.connectionResult); sb.append(", level2FailureCode="); switch(mConnectionEvent.level2FailureCode) { case FAILURE_NONE: sb.append("NONE"); break; case FAILURE_ASSOCIATION_REJECTION: sb.append("ASSOCIATION_REJECTION"); break; case FAILURE_AUTHENTICATION_FAILURE: sb.append("AUTHENTICATION_FAILURE"); break; case FAILURE_SSID_TEMP_DISABLED: sb.append("SSID_TEMP_DISABLED"); break; case FAILURE_CONNECT_NETWORK_FAILED: sb.append("CONNECT_NETWORK_FAILED"); break; case FAILURE_NETWORK_DISCONNECTION: sb.append("NETWORK_DISCONNECTION"); break; case FAILURE_NEW_CONNECTION_ATTEMPT: sb.append("NEW_CONNECTION_ATTEMPT"); break; case FAILURE_REDUNDANT_CONNECTION_ATTEMPT: sb.append("REDUNDANT_CONNECTION_ATTEMPT"); break; case FAILURE_ROAM_TIMEOUT: sb.append("ROAM_TIMEOUT"); break; case FAILURE_DHCP: sb.append("DHCP"); break; case FAILURE_ASSOCIATION_TIMED_OUT: sb.append("ASSOCIATION_TIMED_OUT"); break; default: sb.append("UNKNOWN"); break; } sb.append(", connectivityLevelFailureCode="); switch(mConnectionEvent.connectivityLevelFailureCode) { case WifiMetricsProto.ConnectionEvent.HLF_NONE: sb.append("NONE"); break; case WifiMetricsProto.ConnectionEvent.HLF_DHCP: sb.append("DHCP"); break; case WifiMetricsProto.ConnectionEvent.HLF_NO_INTERNET: sb.append("NO_INTERNET"); break; case WifiMetricsProto.ConnectionEvent.HLF_UNWANTED: sb.append("UNWANTED"); break; default: sb.append("UNKNOWN"); break; } sb.append(", signalStrength="); sb.append(mConnectionEvent.signalStrength); sb.append(", wifiState="); switch(mWifiState) { case WifiMetricsProto.WifiLog.WIFI_DISABLED: sb.append("WIFI_DISABLED"); break; case WifiMetricsProto.WifiLog.WIFI_DISCONNECTED: sb.append("WIFI_DISCONNECTED"); break; case WifiMetricsProto.WifiLog.WIFI_ASSOCIATED: sb.append("WIFI_ASSOCIATED"); break; default: sb.append("WIFI_UNKNOWN"); break; } sb.append(", screenOn="); sb.append(mScreenOn); sb.append(", mRouterFingerprint="); sb.append(mRouterFingerPrint.toString()); sb.append(", useRandomizedMac="); sb.append(mConnectionEvent.useRandomizedMac); sb.append(", connectionNominator="); switch (mConnectionEvent.connectionNominator) { case WifiMetricsProto.ConnectionEvent.NOMINATOR_UNKNOWN: sb.append("NOMINATOR_UNKNOWN"); break; case WifiMetricsProto.ConnectionEvent.NOMINATOR_MANUAL: sb.append("NOMINATOR_MANUAL"); break; case WifiMetricsProto.ConnectionEvent.NOMINATOR_SAVED: sb.append("NOMINATOR_SAVED"); break; case WifiMetricsProto.ConnectionEvent.NOMINATOR_SUGGESTION: sb.append("NOMINATOR_SUGGESTION"); break; case WifiMetricsProto.ConnectionEvent.NOMINATOR_PASSPOINT: sb.append("NOMINATOR_PASSPOINT"); break; case WifiMetricsProto.ConnectionEvent.NOMINATOR_CARRIER: sb.append("NOMINATOR_CARRIER"); break; case WifiMetricsProto.ConnectionEvent.NOMINATOR_EXTERNAL_SCORED: sb.append("NOMINATOR_EXTERNAL_SCORED"); break; case WifiMetricsProto.ConnectionEvent.NOMINATOR_SPECIFIER: sb.append("NOMINATOR_SPECIFIER"); break; case WifiMetricsProto.ConnectionEvent.NOMINATOR_SAVED_USER_CONNECT_CHOICE: sb.append("NOMINATOR_SAVED_USER_CONNECT_CHOICE"); break; case WifiMetricsProto.ConnectionEvent.NOMINATOR_OPEN_NETWORK_AVAILABLE: sb.append("NOMINATOR_OPEN_NETWORK_AVAILABLE"); break; default: sb.append(String.format("UnrecognizedNominator(%d)", mConnectionEvent.connectionNominator)); } sb.append(", networkSelectorExperimentId="); sb.append(mConnectionEvent.networkSelectorExperimentId); sb.append(", level2FailureReason="); switch(mConnectionEvent.level2FailureReason) { case WifiMetricsProto.ConnectionEvent.AUTH_FAILURE_NONE: sb.append("AUTH_FAILURE_NONE"); break; case WifiMetricsProto.ConnectionEvent.AUTH_FAILURE_TIMEOUT: sb.append("AUTH_FAILURE_TIMEOUT"); break; case WifiMetricsProto.ConnectionEvent.AUTH_FAILURE_WRONG_PSWD: sb.append("AUTH_FAILURE_WRONG_PSWD"); break; case WifiMetricsProto.ConnectionEvent.AUTH_FAILURE_EAP_FAILURE: sb.append("AUTH_FAILURE_EAP_FAILURE"); break; default: sb.append("FAILURE_REASON_UNKNOWN"); break; } } return sb.toString(); } } public WifiMetrics(Context context, FrameworkFacade facade, Clock clock, Looper looper, WifiAwareMetrics awareMetrics, RttMetrics rttMetrics, WifiPowerMetrics wifiPowerMetrics, WifiP2pMetrics wifiP2pMetrics, DppMetrics dppMetrics, CellularLinkLayerStatsCollector cellularLinkLayerStatsCollector) { mContext = context; mFacade = facade; mClock = clock; mCurrentConnectionEvent = null; mScreenOn = true; mWifiState = WifiMetricsProto.WifiLog.WIFI_DISABLED; mRecordStartTimeSec = mClock.getElapsedSinceBootMillis() / 1000; mWifiAwareMetrics = awareMetrics; mRttMetrics = rttMetrics; mWifiPowerMetrics = wifiPowerMetrics; mWifiP2pMetrics = wifiP2pMetrics; mDppMetrics = dppMetrics; mCellularLinkLayerStatsCollector = cellularLinkLayerStatsCollector; loadSettings(); mHandler = new Handler(looper) { public void handleMessage(Message msg) { synchronized (mLock) { processMessage(msg); } } }; mCurrentDeviceMobilityState = WifiManager.DEVICE_MOBILITY_STATE_UNKNOWN; DeviceMobilityStatePnoScanStats unknownStateStats = getOrCreateDeviceMobilityStatePnoScanStats(mCurrentDeviceMobilityState); unknownStateStats.numTimesEnteredState++; mCurrentDeviceMobilityStateStartMs = mClock.getElapsedSinceBootMillis(); mCurrentDeviceMobilityStatePnoScanStartMs = -1; mOnWifiUsabilityListeners = new ExternalCallbackTracker(mHandler); } /** * Load setting values related to metrics logging. */ @VisibleForTesting public void loadSettings() { int unusableEventFlag = mFacade.getIntegerSetting( mContext, Settings.Global.WIFI_IS_UNUSABLE_EVENT_METRICS_ENABLED, WIFI_IS_UNUSABLE_EVENT_METRICS_ENABLED_DEFAULT); mUnusableEventLogging = (unusableEventFlag == 1); setWifiIsUnusableLoggingEnabled(mUnusableEventLogging); int linkSpeedCountsFlag = mFacade.getIntegerSetting( mContext, Settings.Global.WIFI_LINK_SPEED_METRICS_ENABLED, WIFI_LINK_SPEED_METRICS_ENABLED_DEFAULT); mLinkSpeedCountsLogging = (linkSpeedCountsFlag == 1); setLinkSpeedCountsLoggingEnabled(mLinkSpeedCountsLogging); if (mWifiDataStall != null) { mWifiDataStall.loadSettings(); } } /** Sets internal ScoringParams member */ public void setScoringParams(ScoringParams scoringParams) { mScoringParams = scoringParams; } /** Sets internal WifiConfigManager member */ public void setWifiConfigManager(WifiConfigManager wifiConfigManager) { mWifiConfigManager = wifiConfigManager; } /** Sets internal WifiNetworkSelector member */ public void setWifiNetworkSelector(WifiNetworkSelector wifiNetworkSelector) { mWifiNetworkSelector = wifiNetworkSelector; } /** Sets internal PasspointManager member */ public void setPasspointManager(PasspointManager passpointManager) { mPasspointManager = passpointManager; } /** Sets internal WifiDataStall member */ public void setWifiDataStall(WifiDataStall wifiDataStall) { mWifiDataStall = wifiDataStall; } /** * Increment cumulative counters for link layer stats. * @param newStats */ public void incrementWifiLinkLayerUsageStats(WifiLinkLayerStats newStats) { if (newStats == null) { return; } if (mLastLinkLayerStats == null) { mLastLinkLayerStats = newStats; return; } if (!newLinkLayerStatsIsValid(mLastLinkLayerStats, newStats)) { // This could mean the radio chip is reset or the data is incorrectly reported. // Don't increment any counts and discard the possibly corrupt |newStats| completely. mLastLinkLayerStats = null; return; } mWifiLinkLayerUsageStats.loggingDurationMs += (newStats.timeStampInMs - mLastLinkLayerStats.timeStampInMs); mWifiLinkLayerUsageStats.radioOnTimeMs += (newStats.on_time - mLastLinkLayerStats.on_time); mWifiLinkLayerUsageStats.radioTxTimeMs += (newStats.tx_time - mLastLinkLayerStats.tx_time); mWifiLinkLayerUsageStats.radioRxTimeMs += (newStats.rx_time - mLastLinkLayerStats.rx_time); mWifiLinkLayerUsageStats.radioScanTimeMs += (newStats.on_time_scan - mLastLinkLayerStats.on_time_scan); mWifiLinkLayerUsageStats.radioNanScanTimeMs += (newStats.on_time_nan_scan - mLastLinkLayerStats.on_time_nan_scan); mWifiLinkLayerUsageStats.radioBackgroundScanTimeMs += (newStats.on_time_background_scan - mLastLinkLayerStats.on_time_background_scan); mWifiLinkLayerUsageStats.radioRoamScanTimeMs += (newStats.on_time_roam_scan - mLastLinkLayerStats.on_time_roam_scan); mWifiLinkLayerUsageStats.radioPnoScanTimeMs += (newStats.on_time_pno_scan - mLastLinkLayerStats.on_time_pno_scan); mWifiLinkLayerUsageStats.radioHs20ScanTimeMs += (newStats.on_time_hs20_scan - mLastLinkLayerStats.on_time_hs20_scan); mLastLinkLayerStats = newStats; } private boolean newLinkLayerStatsIsValid(WifiLinkLayerStats oldStats, WifiLinkLayerStats newStats) { if (newStats.on_time < oldStats.on_time || newStats.tx_time < oldStats.tx_time || newStats.rx_time < oldStats.rx_time || newStats.on_time_scan < oldStats.on_time_scan) { return false; } return true; } /** * Increment total number of attempts to start a pno scan */ public void incrementPnoScanStartAttempCount() { synchronized (mLock) { mPnoScanMetrics.numPnoScanAttempts++; } } /** * Increment total number of attempts with pno scan failed */ public void incrementPnoScanFailedCount() { synchronized (mLock) { mPnoScanMetrics.numPnoScanFailed++; } } /** * Increment number of pno scans started successfully over offload */ public void incrementPnoScanStartedOverOffloadCount() { synchronized (mLock) { mPnoScanMetrics.numPnoScanStartedOverOffload++; } } /** * Increment number of pno scans failed over offload */ public void incrementPnoScanFailedOverOffloadCount() { synchronized (mLock) { mPnoScanMetrics.numPnoScanFailedOverOffload++; } } /** * Increment number of times pno scan found a result */ public void incrementPnoFoundNetworkEventCount() { synchronized (mLock) { mPnoScanMetrics.numPnoFoundNetworkEvents++; } } /** * Increment total number of wps connection attempts */ public void incrementWpsAttemptCount() { synchronized (mLock) { mWpsMetrics.numWpsAttempts++; } } /** * Increment total number of wps connection success */ public void incrementWpsSuccessCount() { synchronized (mLock) { mWpsMetrics.numWpsSuccess++; } } /** * Increment total number of wps failure on start */ public void incrementWpsStartFailureCount() { synchronized (mLock) { mWpsMetrics.numWpsStartFailure++; } } /** * Increment total number of wps overlap failure */ public void incrementWpsOverlapFailureCount() { synchronized (mLock) { mWpsMetrics.numWpsOverlapFailure++; } } /** * Increment total number of wps timeout failure */ public void incrementWpsTimeoutFailureCount() { synchronized (mLock) { mWpsMetrics.numWpsTimeoutFailure++; } } /** * Increment total number of other wps failure during connection */ public void incrementWpsOtherConnectionFailureCount() { synchronized (mLock) { mWpsMetrics.numWpsOtherConnectionFailure++; } } /** * Increment total number of supplicant failure after wps */ public void incrementWpsSupplicantFailureCount() { synchronized (mLock) { mWpsMetrics.numWpsSupplicantFailure++; } } /** * Increment total number of wps cancellation */ public void incrementWpsCancellationCount() { synchronized (mLock) { mWpsMetrics.numWpsCancellation++; } } // Values used for indexing SystemStateEntries private static final int SCREEN_ON = 1; private static final int SCREEN_OFF = 0; /** * Create a new connection event. Call when wifi attempts to make a new network connection * If there is a current 'un-ended' connection event, it will be ended with UNKNOWN connectivity * failure code. * Gathers and sets the RouterFingerPrint data as well * * @param config WifiConfiguration of the config used for the current connection attempt * @param roamType Roam type that caused connection attempt, see WifiMetricsProto.WifiLog.ROAM_X */ public void startConnectionEvent(WifiConfiguration config, String targetBSSID, int roamType) { synchronized (mLock) { // Check if this is overlapping another current connection event if (mCurrentConnectionEvent != null) { //Is this new Connection Event the same as the current one if (mCurrentConnectionEvent.mConfigSsid != null && mCurrentConnectionEvent.mConfigBssid != null && config != null && mCurrentConnectionEvent.mConfigSsid.equals(config.SSID) && (mCurrentConnectionEvent.mConfigBssid.equals("any") || mCurrentConnectionEvent.mConfigBssid.equals(targetBSSID))) { mCurrentConnectionEvent.mConfigBssid = targetBSSID; // End Connection Event due to new connection attempt to the same network endConnectionEvent(ConnectionEvent.FAILURE_REDUNDANT_CONNECTION_ATTEMPT, WifiMetricsProto.ConnectionEvent.HLF_NONE, WifiMetricsProto.ConnectionEvent.FAILURE_REASON_UNKNOWN); } else { // End Connection Event due to new connection attempt to different network endConnectionEvent(ConnectionEvent.FAILURE_NEW_CONNECTION_ATTEMPT, WifiMetricsProto.ConnectionEvent.HLF_NONE, WifiMetricsProto.ConnectionEvent.FAILURE_REASON_UNKNOWN); } } //If past maximum connection events, start removing the oldest while(mConnectionEventList.size() >= MAX_CONNECTION_EVENTS) { mConnectionEventList.remove(0); } mCurrentConnectionEvent = new ConnectionEvent(); mCurrentConnectionEvent.mConnectionEvent.startTimeMillis = mClock.getWallClockMillis(); mCurrentConnectionEvent.mConfigBssid = targetBSSID; mCurrentConnectionEvent.mConnectionEvent.roamType = roamType; mCurrentConnectionEvent.mConnectionEvent.networkSelectorExperimentId = mNetworkSelectorExperimentId; mCurrentConnectionEvent.mRouterFingerPrint.updateFromWifiConfiguration(config); mCurrentConnectionEvent.mConfigBssid = "any"; mCurrentConnectionEvent.mRealStartTime = mClock.getElapsedSinceBootMillis(); mCurrentConnectionEvent.mWifiState = mWifiState; mCurrentConnectionEvent.mScreenOn = mScreenOn; mConnectionEventList.add(mCurrentConnectionEvent); mScanResultRssiTimestampMillis = -1; if (config != null) { mCurrentConnectionEvent.mConnectionEvent.useRandomizedMac = config.macRandomizationSetting == WifiConfiguration.RANDOMIZATION_PERSISTENT; mCurrentConnectionEvent.mConnectionEvent.connectionNominator = mNetworkIdToNominatorId.get(config.networkId, WifiMetricsProto.ConnectionEvent.NOMINATOR_UNKNOWN); ScanResult candidate = config.getNetworkSelectionStatus().getCandidate(); if (candidate != null) { // Cache the RSSI of the candidate, as the connection event level is updated // from other sources (polls, bssid_associations) and delta requires the // scanResult rssi mScanResultRssi = candidate.level; mScanResultRssiTimestampMillis = mClock.getElapsedSinceBootMillis(); } } } } /** * set the RoamType of the current ConnectionEvent (if any) */ public void setConnectionEventRoamType(int roamType) { synchronized (mLock) { if (mCurrentConnectionEvent != null) { mCurrentConnectionEvent.mConnectionEvent.roamType = roamType; } } } /** * Set AP related metrics from ScanDetail */ public void setConnectionScanDetail(ScanDetail scanDetail) { synchronized (mLock) { if (mCurrentConnectionEvent != null && scanDetail != null) { NetworkDetail networkDetail = scanDetail.getNetworkDetail(); ScanResult scanResult = scanDetail.getScanResult(); //Ensure that we have a networkDetail, and that it corresponds to the currently //tracked connection attempt if (networkDetail != null && scanResult != null && mCurrentConnectionEvent.mConfigSsid != null && mCurrentConnectionEvent.mConfigSsid .equals("\"" + networkDetail.getSSID() + "\"")) { updateMetricsFromNetworkDetail(networkDetail); updateMetricsFromScanResult(scanResult); } } } } /** * End a Connection event record. Call when wifi connection attempt succeeds or fails. * If a Connection event has not been started and is active when .end is called, a new one is * created with zero duration. * * @param level2FailureCode Level 2 failure code returned by supplicant * @param connectivityFailureCode WifiMetricsProto.ConnectionEvent.HLF_X * @param level2FailureReason Breakdown of level2FailureCode with more detailed reason */ public void endConnectionEvent(int level2FailureCode, int connectivityFailureCode, int level2FailureReason) { synchronized (mLock) { if (mCurrentConnectionEvent != null) { boolean result = (level2FailureCode == 1) && (connectivityFailureCode == WifiMetricsProto.ConnectionEvent.HLF_NONE); mCurrentConnectionEvent.mConnectionEvent.connectionResult = result ? 1 : 0; mCurrentConnectionEvent.mRealEndTime = mClock.getElapsedSinceBootMillis(); mCurrentConnectionEvent.mConnectionEvent.durationTakenToConnectMillis = (int) (mCurrentConnectionEvent.mRealEndTime - mCurrentConnectionEvent.mRealStartTime); mCurrentConnectionEvent.mConnectionEvent.level2FailureCode = level2FailureCode; mCurrentConnectionEvent.mConnectionEvent.connectivityLevelFailureCode = connectivityFailureCode; mCurrentConnectionEvent.mConnectionEvent.level2FailureReason = level2FailureReason; // ConnectionEvent already added to ConnectionEvents List. Safe to null current here mCurrentConnectionEvent = null; if (!result) { mScanResultRssiTimestampMillis = -1; } } } } /** * Set ConnectionEvent DTIM Interval (if set), and 802.11 Connection mode, from NetworkDetail */ private void updateMetricsFromNetworkDetail(NetworkDetail networkDetail) { int dtimInterval = networkDetail.getDtimInterval(); if (dtimInterval > 0) { mCurrentConnectionEvent.mRouterFingerPrint.mRouterFingerPrintProto.dtim = dtimInterval; } int connectionWifiMode; switch (networkDetail.getWifiMode()) { case InformationElementUtil.WifiMode.MODE_UNDEFINED: connectionWifiMode = WifiMetricsProto.RouterFingerPrint.ROUTER_TECH_UNKNOWN; break; case InformationElementUtil.WifiMode.MODE_11A: connectionWifiMode = WifiMetricsProto.RouterFingerPrint.ROUTER_TECH_A; break; case InformationElementUtil.WifiMode.MODE_11B: connectionWifiMode = WifiMetricsProto.RouterFingerPrint.ROUTER_TECH_B; break; case InformationElementUtil.WifiMode.MODE_11G: connectionWifiMode = WifiMetricsProto.RouterFingerPrint.ROUTER_TECH_G; break; case InformationElementUtil.WifiMode.MODE_11N: connectionWifiMode = WifiMetricsProto.RouterFingerPrint.ROUTER_TECH_N; break; case InformationElementUtil.WifiMode.MODE_11AC : connectionWifiMode = WifiMetricsProto.RouterFingerPrint.ROUTER_TECH_AC; break; default: connectionWifiMode = WifiMetricsProto.RouterFingerPrint.ROUTER_TECH_OTHER; break; } mCurrentConnectionEvent.mRouterFingerPrint.mRouterFingerPrintProto .routerTechnology = connectionWifiMode; } /** * Set ConnectionEvent RSSI and authentication type from ScanResult */ private void updateMetricsFromScanResult(ScanResult scanResult) { mCurrentConnectionEvent.mConnectionEvent.signalStrength = scanResult.level; mCurrentConnectionEvent.mRouterFingerPrint.mRouterFingerPrintProto.authentication = WifiMetricsProto.RouterFingerPrint.AUTH_OPEN; mCurrentConnectionEvent.mConfigBssid = scanResult.BSSID; if (scanResult.capabilities != null) { if (ScanResultUtil.isScanResultForWepNetwork(scanResult)) { mCurrentConnectionEvent.mRouterFingerPrint.mRouterFingerPrintProto.authentication = WifiMetricsProto.RouterFingerPrint.AUTH_PERSONAL; } else if (ScanResultUtil.isScanResultForPskNetwork(scanResult) || ScanResultUtil.isScanResultForSaeNetwork(scanResult)) { mCurrentConnectionEvent.mRouterFingerPrint.mRouterFingerPrintProto.authentication = WifiMetricsProto.RouterFingerPrint.AUTH_PERSONAL; } else if (ScanResultUtil.isScanResultForEapNetwork(scanResult) || ScanResultUtil.isScanResultForEapSuiteBNetwork(scanResult)) { mCurrentConnectionEvent.mRouterFingerPrint.mRouterFingerPrintProto.authentication = WifiMetricsProto.RouterFingerPrint.AUTH_ENTERPRISE; } } mCurrentConnectionEvent.mRouterFingerPrint.mRouterFingerPrintProto.channelInfo = scanResult.frequency; } void setIsLocationEnabled(boolean enabled) { synchronized (mLock) { mWifiLogProto.isLocationEnabled = enabled; } } void setIsScanningAlwaysEnabled(boolean enabled) { synchronized (mLock) { mWifiLogProto.isScanningAlwaysEnabled = enabled; } } /** * Increment Non Empty Scan Results count */ public void incrementNonEmptyScanResultCount() { if (DBG) Log.v(TAG, "incrementNonEmptyScanResultCount"); synchronized (mLock) { mWifiLogProto.numNonEmptyScanResults++; } } /** * Increment Empty Scan Results count */ public void incrementEmptyScanResultCount() { if (DBG) Log.v(TAG, "incrementEmptyScanResultCount"); synchronized (mLock) { mWifiLogProto.numEmptyScanResults++; } } /** * Increment background scan count */ public void incrementBackgroundScanCount() { if (DBG) Log.v(TAG, "incrementBackgroundScanCount"); synchronized (mLock) { mWifiLogProto.numBackgroundScans++; } } /** * Get Background scan count */ public int getBackgroundScanCount() { synchronized (mLock) { return mWifiLogProto.numBackgroundScans; } } /** * Increment oneshot scan count, and the associated WifiSystemScanStateCount entry */ public void incrementOneshotScanCount() { synchronized (mLock) { mWifiLogProto.numOneshotScans++; } incrementWifiSystemScanStateCount(mWifiState, mScreenOn); } /** * Increment the count of oneshot scans that include DFS channels. */ public void incrementOneshotScanWithDfsCount() { synchronized (mLock) { mWifiLogProto.numOneshotHasDfsChannelScans++; } } /** * Increment connectivity oneshot scan count. */ public void incrementConnectivityOneshotScanCount() { synchronized (mLock) { mWifiLogProto.numConnectivityOneshotScans++; } } /** * Get oneshot scan count */ public int getOneshotScanCount() { synchronized (mLock) { return mWifiLogProto.numOneshotScans; } } /** * Get connectivity oneshot scan count */ public int getConnectivityOneshotScanCount() { synchronized (mLock) { return mWifiLogProto.numConnectivityOneshotScans; } } /** * Get the count of oneshot scan requests that included DFS channels. */ public int getOneshotScanWithDfsCount() { synchronized (mLock) { return mWifiLogProto.numOneshotHasDfsChannelScans; } } /** * Increment oneshot scan count for external apps. */ public void incrementExternalAppOneshotScanRequestsCount() { synchronized (mLock) { mWifiLogProto.numExternalAppOneshotScanRequests++; } } /** * Increment oneshot scan throttle count for external foreground apps. */ public void incrementExternalForegroundAppOneshotScanRequestsThrottledCount() { synchronized (mLock) { mWifiLogProto.numExternalForegroundAppOneshotScanRequestsThrottled++; } } /** * Increment oneshot scan throttle count for external background apps. */ public void incrementExternalBackgroundAppOneshotScanRequestsThrottledCount() { synchronized (mLock) { mWifiLogProto.numExternalBackgroundAppOneshotScanRequestsThrottled++; } } private String returnCodeToString(int scanReturnCode) { switch(scanReturnCode){ case WifiMetricsProto.WifiLog.SCAN_UNKNOWN: return "SCAN_UNKNOWN"; case WifiMetricsProto.WifiLog.SCAN_SUCCESS: return "SCAN_SUCCESS"; case WifiMetricsProto.WifiLog.SCAN_FAILURE_INTERRUPTED: return "SCAN_FAILURE_INTERRUPTED"; case WifiMetricsProto.WifiLog.SCAN_FAILURE_INVALID_CONFIGURATION: return "SCAN_FAILURE_INVALID_CONFIGURATION"; case WifiMetricsProto.WifiLog.FAILURE_WIFI_DISABLED: return "FAILURE_WIFI_DISABLED"; default: return ""; } } /** * Increment count of scan return code occurrence * * @param scanReturnCode Return code from scan attempt WifiMetricsProto.WifiLog.SCAN_X */ public void incrementScanReturnEntry(int scanReturnCode, int countToAdd) { synchronized (mLock) { if (DBG) Log.v(TAG, "incrementScanReturnEntry " + returnCodeToString(scanReturnCode)); int entry = mScanReturnEntries.get(scanReturnCode); entry += countToAdd; mScanReturnEntries.put(scanReturnCode, entry); } } /** * Get the count of this scanReturnCode * @param scanReturnCode that we are getting the count for */ public int getScanReturnEntry(int scanReturnCode) { synchronized (mLock) { return mScanReturnEntries.get(scanReturnCode); } } private String wifiSystemStateToString(int state) { switch(state){ case WifiMetricsProto.WifiLog.WIFI_UNKNOWN: return "WIFI_UNKNOWN"; case WifiMetricsProto.WifiLog.WIFI_DISABLED: return "WIFI_DISABLED"; case WifiMetricsProto.WifiLog.WIFI_DISCONNECTED: return "WIFI_DISCONNECTED"; case WifiMetricsProto.WifiLog.WIFI_ASSOCIATED: return "WIFI_ASSOCIATED"; default: return "default"; } } /** * Increments the count of scans initiated by each wifi state, accounts for screenOn/Off * * @param state State of the system when scan was initiated, see WifiMetricsProto.WifiLog.WIFI_X * @param screenOn Is the screen on */ public void incrementWifiSystemScanStateCount(int state, boolean screenOn) { synchronized (mLock) { if (DBG) { Log.v(TAG, "incrementWifiSystemScanStateCount " + wifiSystemStateToString(state) + " " + screenOn); } int index = (state * 2) + (screenOn ? SCREEN_ON : SCREEN_OFF); int entry = mWifiSystemStateEntries.get(index); entry++; mWifiSystemStateEntries.put(index, entry); } } /** * Get the count of this system State Entry */ public int getSystemStateCount(int state, boolean screenOn) { synchronized (mLock) { int index = state * 2 + (screenOn ? SCREEN_ON : SCREEN_OFF); return mWifiSystemStateEntries.get(index); } } /** * Increment number of times the Watchdog of Last Resort triggered, resetting the wifi stack */ public void incrementNumLastResortWatchdogTriggers() { synchronized (mLock) { mWifiLogProto.numLastResortWatchdogTriggers++; } } /** * @param count number of networks over bad association threshold when watchdog triggered */ public void addCountToNumLastResortWatchdogBadAssociationNetworksTotal(int count) { synchronized (mLock) { mWifiLogProto.numLastResortWatchdogBadAssociationNetworksTotal += count; } } /** * @param count number of networks over bad authentication threshold when watchdog triggered */ public void addCountToNumLastResortWatchdogBadAuthenticationNetworksTotal(int count) { synchronized (mLock) { mWifiLogProto.numLastResortWatchdogBadAuthenticationNetworksTotal += count; } } /** * @param count number of networks over bad dhcp threshold when watchdog triggered */ public void addCountToNumLastResortWatchdogBadDhcpNetworksTotal(int count) { synchronized (mLock) { mWifiLogProto.numLastResortWatchdogBadDhcpNetworksTotal += count; } } /** * @param count number of networks over bad other threshold when watchdog triggered */ public void addCountToNumLastResortWatchdogBadOtherNetworksTotal(int count) { synchronized (mLock) { mWifiLogProto.numLastResortWatchdogBadOtherNetworksTotal += count; } } /** * @param count number of networks seen when watchdog triggered */ public void addCountToNumLastResortWatchdogAvailableNetworksTotal(int count) { synchronized (mLock) { mWifiLogProto.numLastResortWatchdogAvailableNetworksTotal += count; } } /** * Increment count of triggers with atleast one bad association network */ public void incrementNumLastResortWatchdogTriggersWithBadAssociation() { synchronized (mLock) { mWifiLogProto.numLastResortWatchdogTriggersWithBadAssociation++; } } /** * Increment count of triggers with atleast one bad authentication network */ public void incrementNumLastResortWatchdogTriggersWithBadAuthentication() { synchronized (mLock) { mWifiLogProto.numLastResortWatchdogTriggersWithBadAuthentication++; } } /** * Increment count of triggers with atleast one bad dhcp network */ public void incrementNumLastResortWatchdogTriggersWithBadDhcp() { synchronized (mLock) { mWifiLogProto.numLastResortWatchdogTriggersWithBadDhcp++; } } /** * Increment count of triggers with atleast one bad other network */ public void incrementNumLastResortWatchdogTriggersWithBadOther() { synchronized (mLock) { mWifiLogProto.numLastResortWatchdogTriggersWithBadOther++; } } /** * Increment number of times connectivity watchdog confirmed pno is working */ public void incrementNumConnectivityWatchdogPnoGood() { synchronized (mLock) { mWifiLogProto.numConnectivityWatchdogPnoGood++; } } /** * Increment number of times connectivity watchdog found pno not working */ public void incrementNumConnectivityWatchdogPnoBad() { synchronized (mLock) { mWifiLogProto.numConnectivityWatchdogPnoBad++; } } /** * Increment number of times connectivity watchdog confirmed background scan is working */ public void incrementNumConnectivityWatchdogBackgroundGood() { synchronized (mLock) { mWifiLogProto.numConnectivityWatchdogBackgroundGood++; } } /** * Increment number of times connectivity watchdog found background scan not working */ public void incrementNumConnectivityWatchdogBackgroundBad() { synchronized (mLock) { mWifiLogProto.numConnectivityWatchdogBackgroundBad++; } } /** * Increment various poll related metrics, and cache performance data for StaEvent logging */ public void handlePollResult(WifiInfo wifiInfo) { mLastPollRssi = wifiInfo.getRssi(); mLastPollLinkSpeed = wifiInfo.getLinkSpeed(); mLastPollFreq = wifiInfo.getFrequency(); incrementRssiPollRssiCount(mLastPollFreq, mLastPollRssi); incrementLinkSpeedCount(mLastPollLinkSpeed, mLastPollRssi); mLastPollRxLinkSpeed = wifiInfo.getRxLinkSpeedMbps(); incrementTxLinkSpeedBandCount(mLastPollLinkSpeed, mLastPollFreq); incrementRxLinkSpeedBandCount(mLastPollRxLinkSpeed, mLastPollFreq); } /** * Increment occurence count of RSSI level from RSSI poll for the given frequency. * @param frequency (MHz) * @param rssi */ @VisibleForTesting public void incrementRssiPollRssiCount(int frequency, int rssi) { if (!(rssi >= MIN_RSSI_POLL && rssi <= MAX_RSSI_POLL)) { return; } synchronized (mLock) { if (!mRssiPollCountsMap.containsKey(frequency)) { mRssiPollCountsMap.put(frequency, new SparseIntArray()); } SparseIntArray sparseIntArray = mRssiPollCountsMap.get(frequency); int count = sparseIntArray.get(rssi); sparseIntArray.put(rssi, count + 1); maybeIncrementRssiDeltaCount(rssi - mScanResultRssi); } } /** * Increment occurence count of difference between scan result RSSI and the first RSSI poll. * Ignores rssi values outside the bounds of [MIN_RSSI_DELTA, MAX_RSSI_DELTA] * mLock must be held when calling this method. */ private void maybeIncrementRssiDeltaCount(int rssi) { // Check if this RSSI poll is close enough to a scan result RSSI to log a delta value if (mScanResultRssiTimestampMillis >= 0) { long timeDelta = mClock.getElapsedSinceBootMillis() - mScanResultRssiTimestampMillis; if (timeDelta <= TIMEOUT_RSSI_DELTA_MILLIS) { if (rssi >= MIN_RSSI_DELTA && rssi <= MAX_RSSI_DELTA) { int count = mRssiDeltaCounts.get(rssi); mRssiDeltaCounts.put(rssi, count + 1); } } mScanResultRssiTimestampMillis = -1; } } /** * Increment occurrence count of link speed. * Ignores link speed values that are lower than MIN_LINK_SPEED_MBPS * and rssi values outside the bounds of [MIN_RSSI_POLL, MAX_RSSI_POLL] */ @VisibleForTesting public void incrementLinkSpeedCount(int linkSpeed, int rssi) { if (!(mLinkSpeedCountsLogging && linkSpeed >= MIN_LINK_SPEED_MBPS && rssi >= MIN_RSSI_POLL && rssi <= MAX_RSSI_POLL)) { return; } synchronized (mLock) { LinkSpeedCount linkSpeedCount = mLinkSpeedCounts.get(linkSpeed); if (linkSpeedCount == null) { linkSpeedCount = new LinkSpeedCount(); linkSpeedCount.linkSpeedMbps = linkSpeed; mLinkSpeedCounts.put(linkSpeed, linkSpeedCount); } linkSpeedCount.count++; linkSpeedCount.rssiSumDbm += Math.abs(rssi); linkSpeedCount.rssiSumOfSquaresDbmSq += rssi * rssi; } } /** * Increment occurrence count of Tx link speed for operating sub-band * Ignores link speed values that are lower than MIN_LINK_SPEED_MBPS * @param txLinkSpeed PHY layer Tx link speed in Mbps * @param frequency Channel frequency of beacon frames in MHz */ @VisibleForTesting public void incrementTxLinkSpeedBandCount(int txLinkSpeed, int frequency) { if (!(mLinkSpeedCountsLogging && txLinkSpeed >= MIN_LINK_SPEED_MBPS)) { return; } synchronized (mLock) { if (frequency <= BAND_2G_MAX_FREQ_MHZ) { mTxLinkSpeedCount2g.increment(txLinkSpeed); } else if (frequency <= BAND_5G_LOW_MAX_FREQ_MHZ) { mTxLinkSpeedCount5gLow.increment(txLinkSpeed); } else if (frequency <= BAND_5G_MID_MAX_FREQ_MHZ) { mTxLinkSpeedCount5gMid.increment(txLinkSpeed); } else { mTxLinkSpeedCount5gHigh.increment(txLinkSpeed); } } } /** * Increment occurrence count of Rx link speed for operating sub-band * Ignores link speed values that are lower than MIN_LINK_SPEED_MBPS * @param rxLinkSpeed PHY layer Tx link speed in Mbps * @param frequency Channel frequency of beacon frames in MHz */ @VisibleForTesting public void incrementRxLinkSpeedBandCount(int rxLinkSpeed, int frequency) { if (!(mLinkSpeedCountsLogging && rxLinkSpeed >= MIN_LINK_SPEED_MBPS)) { return; } synchronized (mLock) { if (frequency <= BAND_2G_MAX_FREQ_MHZ) { mRxLinkSpeedCount2g.increment(rxLinkSpeed); } else if (frequency <= BAND_5G_LOW_MAX_FREQ_MHZ) { mRxLinkSpeedCount5gLow.increment(rxLinkSpeed); } else if (frequency <= BAND_5G_MID_MAX_FREQ_MHZ) { mRxLinkSpeedCount5gMid.increment(rxLinkSpeed); } else { mRxLinkSpeedCount5gHigh.increment(rxLinkSpeed); } } } /** * Increment count of Watchdog successes. */ public void incrementNumLastResortWatchdogSuccesses() { synchronized (mLock) { mWifiLogProto.numLastResortWatchdogSuccesses++; } } /** * Increment the count of network connection failures that happened after watchdog has been * triggered. */ public void incrementWatchdogTotalConnectionFailureCountAfterTrigger() { synchronized (mLock) { mWifiLogProto.watchdogTotalConnectionFailureCountAfterTrigger++; } } /** * Sets the time taken for wifi to connect after a watchdog triggers a restart. * @param milliseconds */ public void setWatchdogSuccessTimeDurationMs(long ms) { synchronized (mLock) { mWifiLogProto.watchdogTriggerToConnectionSuccessDurationMs = ms; } } /** * Increments the count of alerts by alert reason. * * @param reason The cause of the alert. The reason values are driver-specific. */ private void incrementAlertReasonCount(int reason) { if (reason > WifiLoggerHal.WIFI_ALERT_REASON_MAX || reason < WifiLoggerHal.WIFI_ALERT_REASON_MIN) { reason = WifiLoggerHal.WIFI_ALERT_REASON_RESERVED; } synchronized (mLock) { int alertCount = mWifiAlertReasonCounts.get(reason); mWifiAlertReasonCounts.put(reason, alertCount + 1); } } /** * Counts all the different types of networks seen in a set of scan results */ public void countScanResults(List scanDetails) { if (scanDetails == null) { return; } int totalResults = 0; int openNetworks = 0; int personalNetworks = 0; int enterpriseNetworks = 0; int hiddenNetworks = 0; int hotspot2r1Networks = 0; int hotspot2r2Networks = 0; int enhacedOpenNetworks = 0; int wpa3PersonalNetworks = 0; int wpa3EnterpriseNetworks = 0; for (ScanDetail scanDetail : scanDetails) { NetworkDetail networkDetail = scanDetail.getNetworkDetail(); ScanResult scanResult = scanDetail.getScanResult(); totalResults++; if (networkDetail != null) { if (networkDetail.isHiddenBeaconFrame()) { hiddenNetworks++; } if (networkDetail.getHSRelease() != null) { if (networkDetail.getHSRelease() == NetworkDetail.HSRelease.R1) { hotspot2r1Networks++; } else if (networkDetail.getHSRelease() == NetworkDetail.HSRelease.R2) { hotspot2r2Networks++; } } } if (scanResult != null && scanResult.capabilities != null) { if (ScanResultUtil.isScanResultForEapSuiteBNetwork(scanResult)) { wpa3EnterpriseNetworks++; } else if (ScanResultUtil.isScanResultForEapNetwork(scanResult)) { enterpriseNetworks++; } else if (ScanResultUtil.isScanResultForSaeNetwork(scanResult)) { wpa3PersonalNetworks++; } else if (ScanResultUtil.isScanResultForPskNetwork(scanResult) || ScanResultUtil.isScanResultForWepNetwork(scanResult)) { personalNetworks++; } else if (ScanResultUtil.isScanResultForOweNetwork(scanResult)) { enhacedOpenNetworks++; } else { openNetworks++; } } } synchronized (mLock) { mWifiLogProto.numTotalScanResults += totalResults; mWifiLogProto.numOpenNetworkScanResults += openNetworks; mWifiLogProto.numLegacyPersonalNetworkScanResults += personalNetworks; mWifiLogProto.numLegacyEnterpriseNetworkScanResults += enterpriseNetworks; mWifiLogProto.numEnhancedOpenNetworkScanResults += enhacedOpenNetworks; mWifiLogProto.numWpa3PersonalNetworkScanResults += wpa3PersonalNetworks; mWifiLogProto.numWpa3EnterpriseNetworkScanResults += wpa3EnterpriseNetworks; mWifiLogProto.numHiddenNetworkScanResults += hiddenNetworks; mWifiLogProto.numHotspot2R1NetworkScanResults += hotspot2r1Networks; mWifiLogProto.numHotspot2R2NetworkScanResults += hotspot2r2Networks; mWifiLogProto.numScans++; } } private boolean mWifiWins = false; // Based on scores, use wifi instead of mobile data? // Based on Wifi usability scores. use wifi instead of mobile data? private boolean mWifiWinsUsabilityScore = false; /** * Increments occurence of a particular wifi score calculated * in WifiScoreReport by current connected network. Scores are bounded * within [MIN_WIFI_SCORE, MAX_WIFI_SCORE] to limit size of SparseArray. * * Also records events when the current score breaches significant thresholds. */ public void incrementWifiScoreCount(int score) { if (score < MIN_WIFI_SCORE || score > MAX_WIFI_SCORE) { return; } synchronized (mLock) { int count = mWifiScoreCounts.get(score); mWifiScoreCounts.put(score, count + 1); boolean wifiWins = mWifiWins; if (mWifiWins && score < LOW_WIFI_SCORE) { wifiWins = false; } else if (!mWifiWins && score > LOW_WIFI_SCORE) { wifiWins = true; } mLastScore = score; mLastScoreNoReset = score; if (wifiWins != mWifiWins) { mWifiWins = wifiWins; StaEvent event = new StaEvent(); event.type = StaEvent.TYPE_SCORE_BREACH; addStaEvent(event); // Only record the first score breach by checking whether mScoreBreachLowTimeMillis // has been set to -1 if (!wifiWins && mScoreBreachLowTimeMillis == -1) { mScoreBreachLowTimeMillis = mClock.getElapsedSinceBootMillis(); } } } } /** * Increments occurence of the results from attempting to start SoftAp. * Maps the |result| and WifiManager |failureCode| constant to proto defined SoftApStartResult * codes. */ public void incrementSoftApStartResult(boolean result, int failureCode) { synchronized (mLock) { if (result) { int count = mSoftApManagerReturnCodeCounts.get( WifiMetricsProto.SoftApReturnCodeCount.SOFT_AP_STARTED_SUCCESSFULLY); mSoftApManagerReturnCodeCounts.put( WifiMetricsProto.SoftApReturnCodeCount.SOFT_AP_STARTED_SUCCESSFULLY, count + 1); return; } // now increment failure modes - if not explicitly handled, dump into the general // error bucket. if (failureCode == WifiManager.SAP_START_FAILURE_NO_CHANNEL) { int count = mSoftApManagerReturnCodeCounts.get( WifiMetricsProto.SoftApReturnCodeCount.SOFT_AP_FAILED_NO_CHANNEL); mSoftApManagerReturnCodeCounts.put( WifiMetricsProto.SoftApReturnCodeCount.SOFT_AP_FAILED_NO_CHANNEL, count + 1); } else { // failure mode not tracked at this time... count as a general error for now. int count = mSoftApManagerReturnCodeCounts.get( WifiMetricsProto.SoftApReturnCodeCount.SOFT_AP_FAILED_GENERAL_ERROR); mSoftApManagerReturnCodeCounts.put( WifiMetricsProto.SoftApReturnCodeCount.SOFT_AP_FAILED_GENERAL_ERROR, count + 1); } } } /** * Adds a record indicating the current up state of soft AP */ public void addSoftApUpChangedEvent(boolean isUp, int mode) { SoftApConnectedClientsEvent event = new SoftApConnectedClientsEvent(); event.eventType = isUp ? SoftApConnectedClientsEvent.SOFT_AP_UP : SoftApConnectedClientsEvent.SOFT_AP_DOWN; event.numConnectedClients = 0; addSoftApConnectedClientsEvent(event, mode); } /** * Adds a record for current number of associated stations to soft AP */ public void addSoftApNumAssociatedStationsChangedEvent(int numStations, int mode) { SoftApConnectedClientsEvent event = new SoftApConnectedClientsEvent(); event.eventType = SoftApConnectedClientsEvent.NUM_CLIENTS_CHANGED; event.numConnectedClients = numStations; addSoftApConnectedClientsEvent(event, mode); } /** * Adds a record to the corresponding event list based on mode param */ private void addSoftApConnectedClientsEvent(SoftApConnectedClientsEvent event, int mode) { synchronized (mLock) { List softApEventList; switch (mode) { case WifiManager.IFACE_IP_MODE_TETHERED: softApEventList = mSoftApEventListTethered; break; case WifiManager.IFACE_IP_MODE_LOCAL_ONLY: softApEventList = mSoftApEventListLocalOnly; break; default: return; } if (softApEventList.size() > MAX_NUM_SOFT_AP_EVENTS) { return; } event.timeStampMillis = mClock.getElapsedSinceBootMillis(); softApEventList.add(event); } } /** * Updates current soft AP events with channel info */ public void addSoftApChannelSwitchedEvent(int frequency, int bandwidth, int mode) { synchronized (mLock) { List softApEventList; switch (mode) { case WifiManager.IFACE_IP_MODE_TETHERED: softApEventList = mSoftApEventListTethered; break; case WifiManager.IFACE_IP_MODE_LOCAL_ONLY: softApEventList = mSoftApEventListLocalOnly; break; default: return; } for (int index = softApEventList.size() - 1; index >= 0; index--) { SoftApConnectedClientsEvent event = softApEventList.get(index); if (event != null && event.eventType == SoftApConnectedClientsEvent.SOFT_AP_UP) { event.channelFrequency = frequency; event.channelBandwidth = bandwidth; break; } } } } /** * Increment number of times the HAL crashed. */ public void incrementNumHalCrashes() { synchronized (mLock) { mWifiLogProto.numHalCrashes++; } } /** * Increment number of times the Wificond crashed. */ public void incrementNumWificondCrashes() { synchronized (mLock) { mWifiLogProto.numWificondCrashes++; } } /** * Increment number of times the supplicant crashed. */ public void incrementNumSupplicantCrashes() { synchronized (mLock) { mWifiLogProto.numSupplicantCrashes++; } } /** * Increment number of times the hostapd crashed. */ public void incrementNumHostapdCrashes() { synchronized (mLock) { mWifiLogProto.numHostapdCrashes++; } } /** * Increment number of times the wifi on failed due to an error in HAL. */ public void incrementNumSetupClientInterfaceFailureDueToHal() { synchronized (mLock) { mWifiLogProto.numSetupClientInterfaceFailureDueToHal++; } } /** * Increment number of times the wifi on failed due to an error in wificond. */ public void incrementNumSetupClientInterfaceFailureDueToWificond() { synchronized (mLock) { mWifiLogProto.numSetupClientInterfaceFailureDueToWificond++; } } /** * Increment number of times the wifi on failed due to an error in supplicant. */ public void incrementNumSetupClientInterfaceFailureDueToSupplicant() { synchronized (mLock) { mWifiLogProto.numSetupClientInterfaceFailureDueToSupplicant++; } } /** * Increment number of times the SoftAp on failed due to an error in HAL. */ public void incrementNumSetupSoftApInterfaceFailureDueToHal() { synchronized (mLock) { mWifiLogProto.numSetupSoftApInterfaceFailureDueToHal++; } } /** * Increment number of times the SoftAp on failed due to an error in wificond. */ public void incrementNumSetupSoftApInterfaceFailureDueToWificond() { synchronized (mLock) { mWifiLogProto.numSetupSoftApInterfaceFailureDueToWificond++; } } /** * Increment number of times the SoftAp on failed due to an error in hostapd. */ public void incrementNumSetupSoftApInterfaceFailureDueToHostapd() { synchronized (mLock) { mWifiLogProto.numSetupSoftApInterfaceFailureDueToHostapd++; } } /** * Increment number of times we got client interface down. */ public void incrementNumClientInterfaceDown() { synchronized (mLock) { mWifiLogProto.numClientInterfaceDown++; } } /** * Increment number of times we got client interface down. */ public void incrementNumSoftApInterfaceDown() { synchronized (mLock) { mWifiLogProto.numSoftApInterfaceDown++; } } /** * Increment number of times Passpoint provider being installed. */ public void incrementNumPasspointProviderInstallation() { synchronized (mLock) { mWifiLogProto.numPasspointProviderInstallation++; } } /** * Increment number of times Passpoint provider is installed successfully. */ public void incrementNumPasspointProviderInstallSuccess() { synchronized (mLock) { mWifiLogProto.numPasspointProviderInstallSuccess++; } } /** * Increment number of times Passpoint provider being uninstalled. */ public void incrementNumPasspointProviderUninstallation() { synchronized (mLock) { mWifiLogProto.numPasspointProviderUninstallation++; } } /** * Increment number of times Passpoint provider is uninstalled successfully. */ public void incrementNumPasspointProviderUninstallSuccess() { synchronized (mLock) { mWifiLogProto.numPasspointProviderUninstallSuccess++; } } /** * Increment number of times we detected a radio mode change to MCC. */ public void incrementNumRadioModeChangeToMcc() { synchronized (mLock) { mWifiLogProto.numRadioModeChangeToMcc++; } } /** * Increment number of times we detected a radio mode change to SCC. */ public void incrementNumRadioModeChangeToScc() { synchronized (mLock) { mWifiLogProto.numRadioModeChangeToScc++; } } /** * Increment number of times we detected a radio mode change to SBS. */ public void incrementNumRadioModeChangeToSbs() { synchronized (mLock) { mWifiLogProto.numRadioModeChangeToSbs++; } } /** * Increment number of times we detected a radio mode change to DBS. */ public void incrementNumRadioModeChangeToDbs() { synchronized (mLock) { mWifiLogProto.numRadioModeChangeToDbs++; } } /** * Increment number of times we detected a channel did not satisfy user band preference. */ public void incrementNumSoftApUserBandPreferenceUnsatisfied() { synchronized (mLock) { mWifiLogProto.numSoftApUserBandPreferenceUnsatisfied++; } } /** Increment the failure count of SAR sensor listener registration */ public void incrementNumSarSensorRegistrationFailures() { synchronized (mLock) { mWifiLogProto.numSarSensorRegistrationFailures++; } } /** * Increment N-Way network selection decision histograms: * Counts the size of various sets of scanDetails within a scan, and increment the occurrence * of that size for the associated histogram. There are ten histograms generated for each * combination of: {SSID, BSSID} *{Total, Saved, Open, Saved_or_Open, Passpoint} * Only performs this count if isFullBand is true, otherwise, increments the partial scan count */ public void incrementAvailableNetworksHistograms(List scanDetails, boolean isFullBand) { synchronized (mLock) { if (mWifiConfigManager == null || mWifiNetworkSelector == null || mPasspointManager == null) { return; } if (!isFullBand) { mWifiLogProto.partialAllSingleScanListenerResults++; return; } Set ssids = new HashSet(); int bssids = 0; Set openSsids = new HashSet(); int openBssids = 0; Set savedSsids = new HashSet(); int savedBssids = 0; // openOrSavedSsids calculated from union of savedSsids & openSsids int openOrSavedBssids = 0; Set savedPasspointProviderProfiles = new HashSet(); int savedPasspointProviderBssids = 0; int passpointR1Aps = 0; int passpointR2Aps = 0; Map passpointR1UniqueEss = new HashMap<>(); Map passpointR2UniqueEss = new HashMap<>(); int supporting80211mcAps = 0; for (ScanDetail scanDetail : scanDetails) { NetworkDetail networkDetail = scanDetail.getNetworkDetail(); ScanResult scanResult = scanDetail.getScanResult(); // statistics to be collected for ALL APs (irrespective of signal power) if (networkDetail.is80211McResponderSupport()) { supporting80211mcAps++; } ScanResultMatchInfo matchInfo = ScanResultMatchInfo.fromScanResult(scanResult); Pair providerMatch = null; PasspointProvider passpointProvider = null; if (networkDetail.isInterworking()) { providerMatch = mPasspointManager.matchProvider(scanResult); passpointProvider = providerMatch != null ? providerMatch.first : null; if (networkDetail.getHSRelease() == NetworkDetail.HSRelease.R1) { passpointR1Aps++; } else if (networkDetail.getHSRelease() == NetworkDetail.HSRelease.R2) { passpointR2Aps++; } long bssid = 0; boolean validBssid = false; try { bssid = Utils.parseMac(scanResult.BSSID); validBssid = true; } catch (IllegalArgumentException e) { Log.e(TAG, "Invalid BSSID provided in the scan result: " + scanResult.BSSID); } if (validBssid) { ANQPNetworkKey uniqueEss = ANQPNetworkKey.buildKey(scanResult.SSID, bssid, scanResult.hessid, networkDetail.getAnqpDomainID()); if (networkDetail.getHSRelease() == NetworkDetail.HSRelease.R1) { Integer countObj = passpointR1UniqueEss.get(uniqueEss); int count = countObj == null ? 0 : countObj; passpointR1UniqueEss.put(uniqueEss, count + 1); } else if (networkDetail.getHSRelease() == NetworkDetail.HSRelease.R2) { Integer countObj = passpointR2UniqueEss.get(uniqueEss); int count = countObj == null ? 0 : countObj; passpointR2UniqueEss.put(uniqueEss, count + 1); } } } if (mWifiNetworkSelector.isSignalTooWeak(scanResult)) { continue; } // statistics to be collected ONLY for those APs with sufficient signal power ssids.add(matchInfo); bssids++; boolean isOpen = matchInfo.networkType == WifiConfiguration.SECURITY_TYPE_OPEN; WifiConfiguration config = mWifiConfigManager.getConfiguredNetworkForScanDetail(scanDetail); boolean isSaved = (config != null) && !config.isEphemeral() && !config.isPasspoint(); boolean isSavedPasspoint = passpointProvider != null; if (isOpen) { openSsids.add(matchInfo); openBssids++; } if (isSaved) { savedSsids.add(matchInfo); savedBssids++; } if (isOpen || isSaved) { openOrSavedBssids++; // Calculate openOrSavedSsids union later } if (isSavedPasspoint) { savedPasspointProviderProfiles.add(passpointProvider); savedPasspointProviderBssids++; } } mWifiLogProto.fullBandAllSingleScanListenerResults++; incrementTotalScanSsids(mTotalSsidsInScanHistogram, ssids.size()); incrementTotalScanResults(mTotalBssidsInScanHistogram, bssids); incrementSsid(mAvailableOpenSsidsInScanHistogram, openSsids.size()); incrementBssid(mAvailableOpenBssidsInScanHistogram, openBssids); incrementSsid(mAvailableSavedSsidsInScanHistogram, savedSsids.size()); incrementBssid(mAvailableSavedBssidsInScanHistogram, savedBssids); openSsids.addAll(savedSsids); // openSsids = Union(openSsids, savedSsids) incrementSsid(mAvailableOpenOrSavedSsidsInScanHistogram, openSsids.size()); incrementBssid(mAvailableOpenOrSavedBssidsInScanHistogram, openOrSavedBssids); incrementSsid(mAvailableSavedPasspointProviderProfilesInScanHistogram, savedPasspointProviderProfiles.size()); incrementBssid(mAvailableSavedPasspointProviderBssidsInScanHistogram, savedPasspointProviderBssids); incrementTotalPasspointAps(mObservedHotspotR1ApInScanHistogram, passpointR1Aps); incrementTotalPasspointAps(mObservedHotspotR2ApInScanHistogram, passpointR2Aps); incrementTotalUniquePasspointEss(mObservedHotspotR1EssInScanHistogram, passpointR1UniqueEss.size()); incrementTotalUniquePasspointEss(mObservedHotspotR2EssInScanHistogram, passpointR2UniqueEss.size()); for (Integer count : passpointR1UniqueEss.values()) { incrementPasspointPerUniqueEss(mObservedHotspotR1ApsPerEssInScanHistogram, count); } for (Integer count : passpointR2UniqueEss.values()) { incrementPasspointPerUniqueEss(mObservedHotspotR2ApsPerEssInScanHistogram, count); } increment80211mcAps(mObserved80211mcApInScanHistogram, supporting80211mcAps); } } /** * TODO: (b/72443859) Use notifierTag param to separate metrics for OpenNetworkNotifier and * CarrierNetworkNotifier, for this method and all other related metrics. */ /** Increments the occurence of a "Connect to Network" notification. */ public void incrementConnectToNetworkNotification(String notifierTag, int notificationType) { synchronized (mLock) { int count = mConnectToNetworkNotificationCount.get(notificationType); mConnectToNetworkNotificationCount.put(notificationType, count + 1); } } /** Increments the occurence of an "Connect to Network" notification user action. */ public void incrementConnectToNetworkNotificationAction(String notifierTag, int notificationType, int actionType) { synchronized (mLock) { int key = notificationType * CONNECT_TO_NETWORK_NOTIFICATION_ACTION_KEY_MULTIPLIER + actionType; int count = mConnectToNetworkNotificationActionCount.get(key); mConnectToNetworkNotificationActionCount.put(key, count + 1); } } /** * Sets the number of SSIDs blacklisted from recommendation by the open network notification * recommender. */ public void setNetworkRecommenderBlacklistSize(String notifierTag, int size) { synchronized (mLock) { mOpenNetworkRecommenderBlacklistSize = size; } } /** Sets if the available network notification feature is enabled. */ public void setIsWifiNetworksAvailableNotificationEnabled(String notifierTag, boolean enabled) { synchronized (mLock) { mIsWifiNetworksAvailableNotificationOn = enabled; } } /** Increments the occurence of connection attempts that were initiated unsuccessfully */ public void incrementNumNetworkRecommendationUpdates(String notifierTag) { synchronized (mLock) { mNumOpenNetworkRecommendationUpdates++; } } /** Increments the occurence of connection attempts that were initiated unsuccessfully */ public void incrementNumNetworkConnectMessageFailedToSend(String notifierTag) { synchronized (mLock) { mNumOpenNetworkConnectMessageFailedToSend++; } } /** Sets if Connected MAC Randomization feature is enabled */ public void setIsMacRandomizationOn(boolean enabled) { synchronized (mLock) { mIsMacRandomizationOn = enabled; } } /** Log firmware alert related metrics */ public void logFirmwareAlert(int errorCode) { incrementAlertReasonCount(errorCode); logWifiIsUnusableEvent(WifiIsUnusableEvent.TYPE_FIRMWARE_ALERT, errorCode); addToWifiUsabilityStatsList(WifiUsabilityStats.LABEL_BAD, WifiUsabilityStats.TYPE_FIRMWARE_ALERT, errorCode); } public static final String PROTO_DUMP_ARG = "wifiMetricsProto"; public static final String CLEAN_DUMP_ARG = "clean"; /** * Dump all WifiMetrics. Collects some metrics from ConfigStore, Settings and WifiManager * at this time. * * @param fd unused * @param pw PrintWriter for writing dump to * @param args [wifiMetricsProto [clean]] */ public void dump(FileDescriptor fd, PrintWriter pw, String[] args) { synchronized (mLock) { consolidateScoringParams(); if (args != null && args.length > 0 && PROTO_DUMP_ARG.equals(args[0])) { // Dump serialized WifiLog proto consolidateProto(); byte[] wifiMetricsProto = WifiMetricsProto.WifiLog.toByteArray(mWifiLogProto); String metricsProtoDump = Base64.encodeToString(wifiMetricsProto, Base64.DEFAULT); if (args.length > 1 && CLEAN_DUMP_ARG.equals(args[1])) { // Output metrics proto bytes (base64) and nothing else pw.print(metricsProtoDump); } else { // Tag the start and end of the metrics proto bytes pw.println("WifiMetrics:"); pw.println(metricsProtoDump); pw.println("EndWifiMetrics"); } clear(); } else { pw.println("WifiMetrics:"); pw.println("mConnectionEvents:"); for (ConnectionEvent event : mConnectionEventList) { String eventLine = event.toString(); if (event == mCurrentConnectionEvent) { eventLine += "CURRENTLY OPEN EVENT"; } pw.println(eventLine); } pw.println("mWifiLogProto.numSavedNetworks=" + mWifiLogProto.numSavedNetworks); pw.println("mWifiLogProto.numSavedNetworksWithMacRandomization=" + mWifiLogProto.numSavedNetworksWithMacRandomization); pw.println("mWifiLogProto.numOpenNetworks=" + mWifiLogProto.numOpenNetworks); pw.println("mWifiLogProto.numLegacyPersonalNetworks=" + mWifiLogProto.numLegacyPersonalNetworks); pw.println("mWifiLogProto.numLegacyEnterpriseNetworks=" + mWifiLogProto.numLegacyEnterpriseNetworks); pw.println("mWifiLogProto.numEnhancedOpenNetworks=" + mWifiLogProto.numEnhancedOpenNetworks); pw.println("mWifiLogProto.numWpa3PersonalNetworks=" + mWifiLogProto.numWpa3PersonalNetworks); pw.println("mWifiLogProto.numWpa3EnterpriseNetworks=" + mWifiLogProto.numWpa3EnterpriseNetworks); pw.println("mWifiLogProto.numHiddenNetworks=" + mWifiLogProto.numHiddenNetworks); pw.println("mWifiLogProto.numPasspointNetworks=" + mWifiLogProto.numPasspointNetworks); pw.println("mWifiLogProto.isLocationEnabled=" + mWifiLogProto.isLocationEnabled); pw.println("mWifiLogProto.isScanningAlwaysEnabled=" + mWifiLogProto.isScanningAlwaysEnabled); pw.println("mWifiLogProto.numNetworksAddedByUser=" + mWifiLogProto.numNetworksAddedByUser); pw.println("mWifiLogProto.numNetworksAddedByApps=" + mWifiLogProto.numNetworksAddedByApps); pw.println("mWifiLogProto.numNonEmptyScanResults=" + mWifiLogProto.numNonEmptyScanResults); pw.println("mWifiLogProto.numEmptyScanResults=" + mWifiLogProto.numEmptyScanResults); pw.println("mWifiLogProto.numConnecitvityOneshotScans=" + mWifiLogProto.numConnectivityOneshotScans); pw.println("mWifiLogProto.numOneshotScans=" + mWifiLogProto.numOneshotScans); pw.println("mWifiLogProto.numOneshotHasDfsChannelScans=" + mWifiLogProto.numOneshotHasDfsChannelScans); pw.println("mWifiLogProto.numBackgroundScans=" + mWifiLogProto.numBackgroundScans); pw.println("mWifiLogProto.numExternalAppOneshotScanRequests=" + mWifiLogProto.numExternalAppOneshotScanRequests); pw.println("mWifiLogProto.numExternalForegroundAppOneshotScanRequestsThrottled=" + mWifiLogProto.numExternalForegroundAppOneshotScanRequestsThrottled); pw.println("mWifiLogProto.numExternalBackgroundAppOneshotScanRequestsThrottled=" + mWifiLogProto.numExternalBackgroundAppOneshotScanRequestsThrottled); pw.println("mScanReturnEntries:"); pw.println(" SCAN_UNKNOWN: " + getScanReturnEntry( WifiMetricsProto.WifiLog.SCAN_UNKNOWN)); pw.println(" SCAN_SUCCESS: " + getScanReturnEntry( WifiMetricsProto.WifiLog.SCAN_SUCCESS)); pw.println(" SCAN_FAILURE_INTERRUPTED: " + getScanReturnEntry( WifiMetricsProto.WifiLog.SCAN_FAILURE_INTERRUPTED)); pw.println(" SCAN_FAILURE_INVALID_CONFIGURATION: " + getScanReturnEntry( WifiMetricsProto.WifiLog.SCAN_FAILURE_INVALID_CONFIGURATION)); pw.println(" FAILURE_WIFI_DISABLED: " + getScanReturnEntry( WifiMetricsProto.WifiLog.FAILURE_WIFI_DISABLED)); pw.println("mSystemStateEntries: : "); pw.println(" WIFI_UNKNOWN ON: " + getSystemStateCount(WifiMetricsProto.WifiLog.WIFI_UNKNOWN, true)); pw.println(" WIFI_DISABLED ON: " + getSystemStateCount(WifiMetricsProto.WifiLog.WIFI_DISABLED, true)); pw.println(" WIFI_DISCONNECTED ON: " + getSystemStateCount(WifiMetricsProto.WifiLog.WIFI_DISCONNECTED, true)); pw.println(" WIFI_ASSOCIATED ON: " + getSystemStateCount(WifiMetricsProto.WifiLog.WIFI_ASSOCIATED, true)); pw.println(" WIFI_UNKNOWN OFF: " + getSystemStateCount(WifiMetricsProto.WifiLog.WIFI_UNKNOWN, false)); pw.println(" WIFI_DISABLED OFF: " + getSystemStateCount(WifiMetricsProto.WifiLog.WIFI_DISABLED, false)); pw.println(" WIFI_DISCONNECTED OFF: " + getSystemStateCount(WifiMetricsProto.WifiLog.WIFI_DISCONNECTED, false)); pw.println(" WIFI_ASSOCIATED OFF: " + getSystemStateCount(WifiMetricsProto.WifiLog.WIFI_ASSOCIATED, false)); pw.println("mWifiLogProto.numConnectivityWatchdogPnoGood=" + mWifiLogProto.numConnectivityWatchdogPnoGood); pw.println("mWifiLogProto.numConnectivityWatchdogPnoBad=" + mWifiLogProto.numConnectivityWatchdogPnoBad); pw.println("mWifiLogProto.numConnectivityWatchdogBackgroundGood=" + mWifiLogProto.numConnectivityWatchdogBackgroundGood); pw.println("mWifiLogProto.numConnectivityWatchdogBackgroundBad=" + mWifiLogProto.numConnectivityWatchdogBackgroundBad); pw.println("mWifiLogProto.numLastResortWatchdogTriggers=" + mWifiLogProto.numLastResortWatchdogTriggers); pw.println("mWifiLogProto.numLastResortWatchdogBadAssociationNetworksTotal=" + mWifiLogProto.numLastResortWatchdogBadAssociationNetworksTotal); pw.println("mWifiLogProto.numLastResortWatchdogBadAuthenticationNetworksTotal=" + mWifiLogProto.numLastResortWatchdogBadAuthenticationNetworksTotal); pw.println("mWifiLogProto.numLastResortWatchdogBadDhcpNetworksTotal=" + mWifiLogProto.numLastResortWatchdogBadDhcpNetworksTotal); pw.println("mWifiLogProto.numLastResortWatchdogBadOtherNetworksTotal=" + mWifiLogProto.numLastResortWatchdogBadOtherNetworksTotal); pw.println("mWifiLogProto.numLastResortWatchdogAvailableNetworksTotal=" + mWifiLogProto.numLastResortWatchdogAvailableNetworksTotal); pw.println("mWifiLogProto.numLastResortWatchdogTriggersWithBadAssociation=" + mWifiLogProto.numLastResortWatchdogTriggersWithBadAssociation); pw.println("mWifiLogProto.numLastResortWatchdogTriggersWithBadAuthentication=" + mWifiLogProto.numLastResortWatchdogTriggersWithBadAuthentication); pw.println("mWifiLogProto.numLastResortWatchdogTriggersWithBadDhcp=" + mWifiLogProto.numLastResortWatchdogTriggersWithBadDhcp); pw.println("mWifiLogProto.numLastResortWatchdogTriggersWithBadOther=" + mWifiLogProto.numLastResortWatchdogTriggersWithBadOther); pw.println("mWifiLogProto.numLastResortWatchdogSuccesses=" + mWifiLogProto.numLastResortWatchdogSuccesses); pw.println("mWifiLogProto.watchdogTotalConnectionFailureCountAfterTrigger=" + mWifiLogProto.watchdogTotalConnectionFailureCountAfterTrigger); pw.println("mWifiLogProto.watchdogTriggerToConnectionSuccessDurationMs=" + mWifiLogProto.watchdogTriggerToConnectionSuccessDurationMs); pw.println("mWifiLogProto.recordDurationSec=" + ((mClock.getElapsedSinceBootMillis() / 1000) - mRecordStartTimeSec)); try { JSONObject rssiMap = new JSONObject(); for (Map.Entry entry : mRssiPollCountsMap.entrySet()) { int frequency = entry.getKey(); final SparseIntArray histogram = entry.getValue(); JSONArray histogramElements = new JSONArray(); for (int i = MIN_RSSI_POLL; i <= MAX_RSSI_POLL; i++) { int count = histogram.get(i); if (count == 0) { continue; } JSONObject histogramElement = new JSONObject(); histogramElement.put(Integer.toString(i), count); histogramElements.put(histogramElement); } rssiMap.put(Integer.toString(frequency), histogramElements); } pw.println("mWifiLogProto.rssiPollCount: " + rssiMap.toString()); } catch (JSONException e) { pw.println("JSONException occurred: " + e.getMessage()); } pw.println("mWifiLogProto.rssiPollDeltaCount: Printing counts for [" + MIN_RSSI_DELTA + ", " + MAX_RSSI_DELTA + "]"); StringBuilder sb = new StringBuilder(); for (int i = MIN_RSSI_DELTA; i <= MAX_RSSI_DELTA; i++) { sb.append(mRssiDeltaCounts.get(i) + " "); } pw.println(" " + sb.toString()); pw.println("mWifiLogProto.linkSpeedCounts: "); sb.setLength(0); for (int i = 0; i < mLinkSpeedCounts.size(); i++) { LinkSpeedCount linkSpeedCount = mLinkSpeedCounts.valueAt(i); sb.append(linkSpeedCount.linkSpeedMbps).append(":{") .append(linkSpeedCount.count).append(", ") .append(linkSpeedCount.rssiSumDbm).append(", ") .append(linkSpeedCount.rssiSumOfSquaresDbmSq).append("} "); } if (sb.length() > 0) { pw.println(sb.toString()); } pw.print("mWifiLogProto.alertReasonCounts="); sb.setLength(0); for (int i = WifiLoggerHal.WIFI_ALERT_REASON_MIN; i <= WifiLoggerHal.WIFI_ALERT_REASON_MAX; i++) { int count = mWifiAlertReasonCounts.get(i); if (count > 0) { sb.append("(" + i + "," + count + "),"); } } if (sb.length() > 1) { sb.setLength(sb.length() - 1); // strip trailing comma pw.println(sb.toString()); } else { pw.println("()"); } pw.println("mWifiLogProto.numTotalScanResults=" + mWifiLogProto.numTotalScanResults); pw.println("mWifiLogProto.numOpenNetworkScanResults=" + mWifiLogProto.numOpenNetworkScanResults); pw.println("mWifiLogProto.numLegacyPersonalNetworkScanResults=" + mWifiLogProto.numLegacyPersonalNetworkScanResults); pw.println("mWifiLogProto.numLegacyEnterpriseNetworkScanResults=" + mWifiLogProto.numLegacyEnterpriseNetworkScanResults); pw.println("mWifiLogProto.numEnhancedOpenNetworkScanResults=" + mWifiLogProto.numEnhancedOpenNetworkScanResults); pw.println("mWifiLogProto.numWpa3PersonalNetworkScanResults=" + mWifiLogProto.numWpa3PersonalNetworkScanResults); pw.println("mWifiLogProto.numWpa3EnterpriseNetworkScanResults=" + mWifiLogProto.numWpa3EnterpriseNetworkScanResults); pw.println("mWifiLogProto.numHiddenNetworkScanResults=" + mWifiLogProto.numHiddenNetworkScanResults); pw.println("mWifiLogProto.numHotspot2R1NetworkScanResults=" + mWifiLogProto.numHotspot2R1NetworkScanResults); pw.println("mWifiLogProto.numHotspot2R2NetworkScanResults=" + mWifiLogProto.numHotspot2R2NetworkScanResults); pw.println("mWifiLogProto.numScans=" + mWifiLogProto.numScans); pw.println("mWifiLogProto.WifiScoreCount: [" + MIN_WIFI_SCORE + ", " + MAX_WIFI_SCORE + "]"); for (int i = 0; i <= MAX_WIFI_SCORE; i++) { pw.print(mWifiScoreCounts.get(i) + " "); } pw.println(); // add a line after wifi scores pw.println("mWifiLogProto.WifiUsabilityScoreCount: [" + MIN_WIFI_USABILITY_SCORE + ", " + MAX_WIFI_USABILITY_SCORE + "]"); for (int i = MIN_WIFI_USABILITY_SCORE; i <= MAX_WIFI_USABILITY_SCORE; i++) { pw.print(mWifiUsabilityScoreCounts.get(i) + " "); } pw.println(); // add a line after wifi usability scores pw.println("mWifiLogProto.SoftApManagerReturnCodeCounts:"); pw.println(" SUCCESS: " + mSoftApManagerReturnCodeCounts.get( WifiMetricsProto.SoftApReturnCodeCount.SOFT_AP_STARTED_SUCCESSFULLY)); pw.println(" FAILED_GENERAL_ERROR: " + mSoftApManagerReturnCodeCounts.get( WifiMetricsProto.SoftApReturnCodeCount.SOFT_AP_FAILED_GENERAL_ERROR)); pw.println(" FAILED_NO_CHANNEL: " + mSoftApManagerReturnCodeCounts.get( WifiMetricsProto.SoftApReturnCodeCount.SOFT_AP_FAILED_NO_CHANNEL)); pw.print("\n"); pw.println("mWifiLogProto.numHalCrashes=" + mWifiLogProto.numHalCrashes); pw.println("mWifiLogProto.numWificondCrashes=" + mWifiLogProto.numWificondCrashes); pw.println("mWifiLogProto.numSupplicantCrashes=" + mWifiLogProto.numSupplicantCrashes); pw.println("mWifiLogProto.numHostapdCrashes=" + mWifiLogProto.numHostapdCrashes); pw.println("mWifiLogProto.numSetupClientInterfaceFailureDueToHal=" + mWifiLogProto.numSetupClientInterfaceFailureDueToHal); pw.println("mWifiLogProto.numSetupClientInterfaceFailureDueToWificond=" + mWifiLogProto.numSetupClientInterfaceFailureDueToWificond); pw.println("mWifiLogProto.numSetupClientInterfaceFailureDueToSupplicant=" + mWifiLogProto.numSetupClientInterfaceFailureDueToSupplicant); pw.println("mWifiLogProto.numSetupSoftApInterfaceFailureDueToHal=" + mWifiLogProto.numSetupSoftApInterfaceFailureDueToHal); pw.println("mWifiLogProto.numSetupSoftApInterfaceFailureDueToWificond=" + mWifiLogProto.numSetupSoftApInterfaceFailureDueToWificond); pw.println("mWifiLogProto.numSetupSoftApInterfaceFailureDueToHostapd=" + mWifiLogProto.numSetupSoftApInterfaceFailureDueToHostapd); pw.println("mWifiLogProto.numSarSensorRegistrationFailures=" + mWifiLogProto.numSarSensorRegistrationFailures); pw.println("StaEventList:"); for (StaEventWithTime event : mStaEventList) { pw.println(event); } pw.println("mWifiLogProto.numPasspointProviders=" + mWifiLogProto.numPasspointProviders); pw.println("mWifiLogProto.numPasspointProviderInstallation=" + mWifiLogProto.numPasspointProviderInstallation); pw.println("mWifiLogProto.numPasspointProviderInstallSuccess=" + mWifiLogProto.numPasspointProviderInstallSuccess); pw.println("mWifiLogProto.numPasspointProviderUninstallation=" + mWifiLogProto.numPasspointProviderUninstallation); pw.println("mWifiLogProto.numPasspointProviderUninstallSuccess=" + mWifiLogProto.numPasspointProviderUninstallSuccess); pw.println("mWifiLogProto.numPasspointProvidersSuccessfullyConnected=" + mWifiLogProto.numPasspointProvidersSuccessfullyConnected); pw.println("mWifiLogProto.installedPasspointProfileTypeForR1:" + mInstalledPasspointProfileTypeForR1); pw.println("mWifiLogProto.installedPasspointProfileTypeForR2:" + mInstalledPasspointProfileTypeForR2); pw.println("mWifiLogProto.passpointProvisionStats.numProvisionSuccess=" + mNumProvisionSuccess); pw.println("mWifiLogProto.passpointProvisionStats.provisionFailureCount:" + mPasspointProvisionFailureCounts); pw.println("mWifiLogProto.numRadioModeChangeToMcc=" + mWifiLogProto.numRadioModeChangeToMcc); pw.println("mWifiLogProto.numRadioModeChangeToScc=" + mWifiLogProto.numRadioModeChangeToScc); pw.println("mWifiLogProto.numRadioModeChangeToSbs=" + mWifiLogProto.numRadioModeChangeToSbs); pw.println("mWifiLogProto.numRadioModeChangeToDbs=" + mWifiLogProto.numRadioModeChangeToDbs); pw.println("mWifiLogProto.numSoftApUserBandPreferenceUnsatisfied=" + mWifiLogProto.numSoftApUserBandPreferenceUnsatisfied); pw.println("mTotalSsidsInScanHistogram:" + mTotalSsidsInScanHistogram.toString()); pw.println("mTotalBssidsInScanHistogram:" + mTotalBssidsInScanHistogram.toString()); pw.println("mAvailableOpenSsidsInScanHistogram:" + mAvailableOpenSsidsInScanHistogram.toString()); pw.println("mAvailableOpenBssidsInScanHistogram:" + mAvailableOpenBssidsInScanHistogram.toString()); pw.println("mAvailableSavedSsidsInScanHistogram:" + mAvailableSavedSsidsInScanHistogram.toString()); pw.println("mAvailableSavedBssidsInScanHistogram:" + mAvailableSavedBssidsInScanHistogram.toString()); pw.println("mAvailableOpenOrSavedSsidsInScanHistogram:" + mAvailableOpenOrSavedSsidsInScanHistogram.toString()); pw.println("mAvailableOpenOrSavedBssidsInScanHistogram:" + mAvailableOpenOrSavedBssidsInScanHistogram.toString()); pw.println("mAvailableSavedPasspointProviderProfilesInScanHistogram:" + mAvailableSavedPasspointProviderProfilesInScanHistogram.toString()); pw.println("mAvailableSavedPasspointProviderBssidsInScanHistogram:" + mAvailableSavedPasspointProviderBssidsInScanHistogram.toString()); pw.println("mWifiLogProto.partialAllSingleScanListenerResults=" + mWifiLogProto.partialAllSingleScanListenerResults); pw.println("mWifiLogProto.fullBandAllSingleScanListenerResults=" + mWifiLogProto.fullBandAllSingleScanListenerResults); pw.println("mWifiAwareMetrics:"); mWifiAwareMetrics.dump(fd, pw, args); pw.println("mRttMetrics:"); mRttMetrics.dump(fd, pw, args); pw.println("mPnoScanMetrics.numPnoScanAttempts=" + mPnoScanMetrics.numPnoScanAttempts); pw.println("mPnoScanMetrics.numPnoScanFailed=" + mPnoScanMetrics.numPnoScanFailed); pw.println("mPnoScanMetrics.numPnoScanStartedOverOffload=" + mPnoScanMetrics.numPnoScanStartedOverOffload); pw.println("mPnoScanMetrics.numPnoScanFailedOverOffload=" + mPnoScanMetrics.numPnoScanFailedOverOffload); pw.println("mPnoScanMetrics.numPnoFoundNetworkEvents=" + mPnoScanMetrics.numPnoFoundNetworkEvents); pw.println("mWifiLinkLayerUsageStats.loggingDurationMs=" + mWifiLinkLayerUsageStats.loggingDurationMs); pw.println("mWifiLinkLayerUsageStats.radioOnTimeMs=" + mWifiLinkLayerUsageStats.radioOnTimeMs); pw.println("mWifiLinkLayerUsageStats.radioTxTimeMs=" + mWifiLinkLayerUsageStats.radioTxTimeMs); pw.println("mWifiLinkLayerUsageStats.radioRxTimeMs=" + mWifiLinkLayerUsageStats.radioRxTimeMs); pw.println("mWifiLinkLayerUsageStats.radioScanTimeMs=" + mWifiLinkLayerUsageStats.radioScanTimeMs); pw.println("mWifiLinkLayerUsageStats.radioNanScanTimeMs=" + mWifiLinkLayerUsageStats.radioNanScanTimeMs); pw.println("mWifiLinkLayerUsageStats.radioBackgroundScanTimeMs=" + mWifiLinkLayerUsageStats.radioBackgroundScanTimeMs); pw.println("mWifiLinkLayerUsageStats.radioRoamScanTimeMs=" + mWifiLinkLayerUsageStats.radioRoamScanTimeMs); pw.println("mWifiLinkLayerUsageStats.radioPnoScanTimeMs=" + mWifiLinkLayerUsageStats.radioPnoScanTimeMs); pw.println("mWifiLinkLayerUsageStats.radioHs20ScanTimeMs=" + mWifiLinkLayerUsageStats.radioHs20ScanTimeMs); pw.println("mWifiLogProto.connectToNetworkNotificationCount=" + mConnectToNetworkNotificationCount.toString()); pw.println("mWifiLogProto.connectToNetworkNotificationActionCount=" + mConnectToNetworkNotificationActionCount.toString()); pw.println("mWifiLogProto.openNetworkRecommenderBlacklistSize=" + mOpenNetworkRecommenderBlacklistSize); pw.println("mWifiLogProto.isWifiNetworksAvailableNotificationOn=" + mIsWifiNetworksAvailableNotificationOn); pw.println("mWifiLogProto.numOpenNetworkRecommendationUpdates=" + mNumOpenNetworkRecommendationUpdates); pw.println("mWifiLogProto.numOpenNetworkConnectMessageFailedToSend=" + mNumOpenNetworkConnectMessageFailedToSend); pw.println("mWifiLogProto.observedHotspotR1ApInScanHistogram=" + mObservedHotspotR1ApInScanHistogram); pw.println("mWifiLogProto.observedHotspotR2ApInScanHistogram=" + mObservedHotspotR2ApInScanHistogram); pw.println("mWifiLogProto.observedHotspotR1EssInScanHistogram=" + mObservedHotspotR1EssInScanHistogram); pw.println("mWifiLogProto.observedHotspotR2EssInScanHistogram=" + mObservedHotspotR2EssInScanHistogram); pw.println("mWifiLogProto.observedHotspotR1ApsPerEssInScanHistogram=" + mObservedHotspotR1ApsPerEssInScanHistogram); pw.println("mWifiLogProto.observedHotspotR2ApsPerEssInScanHistogram=" + mObservedHotspotR2ApsPerEssInScanHistogram); pw.println("mWifiLogProto.observed80211mcSupportingApsInScanHistogram" + mObserved80211mcApInScanHistogram); pw.println("mSoftApTetheredEvents:"); for (SoftApConnectedClientsEvent event : mSoftApEventListTethered) { StringBuilder eventLine = new StringBuilder(); eventLine.append("event_type=" + event.eventType); eventLine.append(",time_stamp_millis=" + event.timeStampMillis); eventLine.append(",num_connected_clients=" + event.numConnectedClients); eventLine.append(",channel_frequency=" + event.channelFrequency); eventLine.append(",channel_bandwidth=" + event.channelBandwidth); pw.println(eventLine.toString()); } pw.println("mSoftApLocalOnlyEvents:"); for (SoftApConnectedClientsEvent event : mSoftApEventListLocalOnly) { StringBuilder eventLine = new StringBuilder(); eventLine.append("event_type=" + event.eventType); eventLine.append(",time_stamp_millis=" + event.timeStampMillis); eventLine.append(",num_connected_clients=" + event.numConnectedClients); eventLine.append(",channel_frequency=" + event.channelFrequency); eventLine.append(",channel_bandwidth=" + event.channelBandwidth); pw.println(eventLine.toString()); } pw.println("mWpsMetrics.numWpsAttempts=" + mWpsMetrics.numWpsAttempts); pw.println("mWpsMetrics.numWpsSuccess=" + mWpsMetrics.numWpsSuccess); pw.println("mWpsMetrics.numWpsStartFailure=" + mWpsMetrics.numWpsStartFailure); pw.println("mWpsMetrics.numWpsOverlapFailure=" + mWpsMetrics.numWpsOverlapFailure); pw.println("mWpsMetrics.numWpsTimeoutFailure=" + mWpsMetrics.numWpsTimeoutFailure); pw.println("mWpsMetrics.numWpsOtherConnectionFailure=" + mWpsMetrics.numWpsOtherConnectionFailure); pw.println("mWpsMetrics.numWpsSupplicantFailure=" + mWpsMetrics.numWpsSupplicantFailure); pw.println("mWpsMetrics.numWpsCancellation=" + mWpsMetrics.numWpsCancellation); mWifiPowerMetrics.dump(pw); mWifiWakeMetrics.dump(pw); pw.println("mWifiLogProto.isMacRandomizationOn=" + mIsMacRandomizationOn); pw.println("mWifiLogProto.scoreExperimentId=" + mWifiLogProto.scoreExperimentId); pw.println("mExperimentValues.wifiIsUnusableLoggingEnabled=" + mExperimentValues.wifiIsUnusableLoggingEnabled); pw.println("mExperimentValues.wifiDataStallMinTxBad=" + mExperimentValues.wifiDataStallMinTxBad); pw.println("mExperimentValues.wifiDataStallMinTxSuccessWithoutRx=" + mExperimentValues.wifiDataStallMinTxSuccessWithoutRx); pw.println("mExperimentValues.linkSpeedCountsLoggingEnabled=" + mExperimentValues.linkSpeedCountsLoggingEnabled); pw.println("WifiIsUnusableEventList: "); for (WifiIsUnusableWithTime event : mWifiIsUnusableList) { pw.println(event); } pw.println("Hardware Version: " + SystemProperties.get("ro.boot.revision", "")); pw.println("mWifiUsabilityStatsEntriesList:"); for (WifiUsabilityStatsEntry stats : mWifiUsabilityStatsEntriesList) { printWifiUsabilityStatsEntry(pw, stats); } pw.println("mWifiUsabilityStatsList:"); for (WifiUsabilityStats stats : mWifiUsabilityStatsListGood) { pw.println("\nlabel=" + stats.label); pw.println("\ntrigger_type=" + stats.triggerType); pw.println("\ntime_stamp_ms=" + stats.timeStampMs); for (WifiUsabilityStatsEntry entry : stats.stats) { printWifiUsabilityStatsEntry(pw, entry); } } for (WifiUsabilityStats stats : mWifiUsabilityStatsListBad) { pw.println("\nlabel=" + stats.label); pw.println("\ntrigger_type=" + stats.triggerType); pw.println("\ntime_stamp_ms=" + stats.timeStampMs); for (WifiUsabilityStatsEntry entry : stats.stats) { printWifiUsabilityStatsEntry(pw, entry); } } pw.println("mMobilityStatePnoStatsMap:"); for (int i = 0; i < mMobilityStatePnoStatsMap.size(); i++) { printDeviceMobilityStatePnoScanStats(pw, mMobilityStatePnoStatsMap.valueAt(i)); } mWifiP2pMetrics.dump(pw); pw.println("mDppMetrics:"); mDppMetrics.dump(pw); pw.println("mWifiConfigStoreReadDurationHistogram:" + mWifiConfigStoreReadDurationHistogram.toString()); pw.println("mWifiConfigStoreWriteDurationHistogram:" + mWifiConfigStoreWriteDurationHistogram.toString()); pw.println("mLinkProbeSuccessRssiCounts:" + mLinkProbeSuccessRssiCounts); pw.println("mLinkProbeFailureRssiCounts:" + mLinkProbeFailureRssiCounts); pw.println("mLinkProbeSuccessLinkSpeedCounts:" + mLinkProbeSuccessLinkSpeedCounts); pw.println("mLinkProbeFailureLinkSpeedCounts:" + mLinkProbeFailureLinkSpeedCounts); pw.println("mLinkProbeSuccessSecondsSinceLastTxSuccessHistogram:" + mLinkProbeSuccessSecondsSinceLastTxSuccessHistogram); pw.println("mLinkProbeFailureSecondsSinceLastTxSuccessHistogram:" + mLinkProbeFailureSecondsSinceLastTxSuccessHistogram); pw.println("mLinkProbeSuccessElapsedTimeMsHistogram:" + mLinkProbeSuccessElapsedTimeMsHistogram); pw.println("mLinkProbeFailureReasonCounts:" + mLinkProbeFailureReasonCounts); pw.println("mLinkProbeExperimentProbeCounts:" + mLinkProbeExperimentProbeCounts); pw.println("mNetworkSelectionExperimentPairNumChoicesCounts:" + mNetworkSelectionExperimentPairNumChoicesCounts); pw.println("mLinkProbeStaEventCount:" + mLinkProbeStaEventCount); pw.println("mWifiNetworkRequestApiLog:\n" + mWifiNetworkRequestApiLog); pw.println("mWifiNetworkRequestApiMatchSizeHistogram:\n" + mWifiNetworkRequestApiMatchSizeHistogram); pw.println("mWifiNetworkSuggestionApiLog:\n" + mWifiNetworkSuggestionApiLog); pw.println("mWifiNetworkSuggestionApiMatchSizeHistogram:\n" + mWifiNetworkRequestApiMatchSizeHistogram); pw.println("mNetworkIdToNominatorId:\n" + mNetworkIdToNominatorId); pw.println("mWifiLockStats:\n" + mWifiLockStats); pw.println("mWifiLockHighPerfAcqDurationSecHistogram:\n" + mWifiLockHighPerfAcqDurationSecHistogram); pw.println("mWifiLockLowLatencyAcqDurationSecHistogram:\n" + mWifiLockLowLatencyAcqDurationSecHistogram); pw.println("mWifiLockHighPerfActiveSessionDurationSecHistogram:\n" + mWifiLockHighPerfActiveSessionDurationSecHistogram); pw.println("mWifiLockLowLatencyActiveSessionDurationSecHistogram:\n" + mWifiLockLowLatencyActiveSessionDurationSecHistogram); pw.println("mWifiToggleStats:\n" + mWifiToggleStats); pw.println("mWifiLogProto.numAddOrUpdateNetworkCalls=" + mWifiLogProto.numAddOrUpdateNetworkCalls); pw.println("mWifiLogProto.numEnableNetworkCalls=" + mWifiLogProto.numEnableNetworkCalls); pw.println("mWifiLogProto.txLinkSpeedCount2g=" + mTxLinkSpeedCount2g); pw.println("mWifiLogProto.txLinkSpeedCount5gLow=" + mTxLinkSpeedCount5gLow); pw.println("mWifiLogProto.txLinkSpeedCount5gMid=" + mTxLinkSpeedCount5gMid); pw.println("mWifiLogProto.txLinkSpeedCount5gHigh=" + mTxLinkSpeedCount5gHigh); pw.println("mWifiLogProto.rxLinkSpeedCount2g=" + mRxLinkSpeedCount2g); pw.println("mWifiLogProto.rxLinkSpeedCount5gLow=" + mRxLinkSpeedCount5gLow); pw.println("mWifiLogProto.rxLinkSpeedCount5gMid=" + mRxLinkSpeedCount5gMid); pw.println("mWifiLogProto.rxLinkSpeedCount5gHigh=" + mRxLinkSpeedCount5gHigh); } } } private void printWifiUsabilityStatsEntry(PrintWriter pw, WifiUsabilityStatsEntry entry) { StringBuilder line = new StringBuilder(); line.append("timestamp_ms=" + entry.timeStampMs); line.append(",rssi=" + entry.rssi); line.append(",link_speed_mbps=" + entry.linkSpeedMbps); line.append(",total_tx_success=" + entry.totalTxSuccess); line.append(",total_tx_retries=" + entry.totalTxRetries); line.append(",total_tx_bad=" + entry.totalTxBad); line.append(",total_rx_success=" + entry.totalRxSuccess); line.append(",total_radio_on_time_ms=" + entry.totalRadioOnTimeMs); line.append(",total_radio_tx_time_ms=" + entry.totalRadioTxTimeMs); line.append(",total_radio_rx_time_ms=" + entry.totalRadioRxTimeMs); line.append(",total_scan_time_ms=" + entry.totalScanTimeMs); line.append(",total_nan_scan_time_ms=" + entry.totalNanScanTimeMs); line.append(",total_background_scan_time_ms=" + entry.totalBackgroundScanTimeMs); line.append(",total_roam_scan_time_ms=" + entry.totalRoamScanTimeMs); line.append(",total_pno_scan_time_ms=" + entry.totalPnoScanTimeMs); line.append(",total_hotspot_2_scan_time_ms=" + entry.totalHotspot2ScanTimeMs); line.append(",wifi_score=" + entry.wifiScore); line.append(",wifi_usability_score=" + entry.wifiUsabilityScore); line.append(",seq_num_to_framework=" + entry.seqNumToFramework); line.append(",prediction_horizon_sec=" + entry.predictionHorizonSec); line.append(",total_cca_busy_freq_time_ms=" + entry.totalCcaBusyFreqTimeMs); line.append(",total_radio_on_freq_time_ms=" + entry.totalRadioOnFreqTimeMs); line.append(",total_beacon_rx=" + entry.totalBeaconRx); line.append(",probe_status_since_last_update=" + entry.probeStatusSinceLastUpdate); line.append(",probe_elapsed_time_ms_since_last_update=" + entry.probeElapsedTimeSinceLastUpdateMs); line.append(",probe_mcs_rate_since_last_update=" + entry.probeMcsRateSinceLastUpdate); line.append(",rx_link_speed_mbps=" + entry.rxLinkSpeedMbps); line.append(",seq_num_inside_framework=" + entry.seqNumInsideFramework); line.append(",is_same_bssid_and_freq=" + entry.isSameBssidAndFreq); line.append(",cellular_data_network_type=" + entry.cellularDataNetworkType); line.append(",cellular_signal_strength_dbm=" + entry.cellularSignalStrengthDbm); line.append(",cellular_signal_strength_db=" + entry.cellularSignalStrengthDb); line.append(",is_same_registered_cell=" + entry.isSameRegisteredCell); line.append(",device_mobility_state=" + entry.deviceMobilityState); pw.println(line.toString()); } private void printDeviceMobilityStatePnoScanStats(PrintWriter pw, DeviceMobilityStatePnoScanStats stats) { StringBuilder line = new StringBuilder(); line.append("device_mobility_state=" + stats.deviceMobilityState); line.append(",num_times_entered_state=" + stats.numTimesEnteredState); line.append(",total_duration_ms=" + stats.totalDurationMs); line.append(",pno_duration_ms=" + stats.pnoDurationMs); pw.println(line.toString()); } /** * Update various counts of saved network types * @param networks List of WifiConfigurations representing all saved networks, must not be null */ public void updateSavedNetworks(List networks) { synchronized (mLock) { mWifiLogProto.numSavedNetworks = networks.size(); mWifiLogProto.numOpenNetworks = 0; mWifiLogProto.numLegacyPersonalNetworks = 0; mWifiLogProto.numLegacyEnterpriseNetworks = 0; mWifiLogProto.numEnhancedOpenNetworks = 0; mWifiLogProto.numWpa3PersonalNetworks = 0; mWifiLogProto.numWpa3EnterpriseNetworks = 0; mWifiLogProto.numNetworksAddedByUser = 0; mWifiLogProto.numNetworksAddedByApps = 0; mWifiLogProto.numHiddenNetworks = 0; mWifiLogProto.numPasspointNetworks = 0; for (WifiConfiguration config : networks) { if (config.allowedKeyManagement.get(WifiConfiguration.KeyMgmt.NONE)) { mWifiLogProto.numOpenNetworks++; } else if (config.allowedKeyManagement.get(WifiConfiguration.KeyMgmt.OWE)) { mWifiLogProto.numEnhancedOpenNetworks++; } else if (config.isEnterprise()) { if (config.allowedKeyManagement.get(WifiConfiguration.KeyMgmt.SUITE_B_192)) { mWifiLogProto.numWpa3EnterpriseNetworks++; } else { mWifiLogProto.numLegacyEnterpriseNetworks++; } } else { if (config.allowedKeyManagement.get(WifiConfiguration.KeyMgmt.SAE)) { mWifiLogProto.numWpa3PersonalNetworks++; } else { mWifiLogProto.numLegacyPersonalNetworks++; } } if (config.selfAdded) { mWifiLogProto.numNetworksAddedByUser++; } else { mWifiLogProto.numNetworksAddedByApps++; } if (config.hiddenSSID) { mWifiLogProto.numHiddenNetworks++; } if (config.isPasspoint()) { mWifiLogProto.numPasspointNetworks++; } if (config.macRandomizationSetting == WifiConfiguration.RANDOMIZATION_PERSISTENT) { mWifiLogProto.numSavedNetworksWithMacRandomization++; } } } } /** * Update metrics for saved Passpoint profiles. * * @param numSavedProfiles The number of saved Passpoint profiles * @param numConnectedProfiles The number of saved Passpoint profiles that have ever resulted * in a successful network connection */ public void updateSavedPasspointProfiles(int numSavedProfiles, int numConnectedProfiles) { synchronized (mLock) { mWifiLogProto.numPasspointProviders = numSavedProfiles; mWifiLogProto.numPasspointProvidersSuccessfullyConnected = numConnectedProfiles; } } /** * Update number of times for type of saved Passpoint profile. * * @param providers Passpoint providers installed on the device. */ public void updateSavedPasspointProfilesInfo( Map providers) { int passpointType; int eapType; PasspointConfiguration config; synchronized (mLock) { mInstalledPasspointProfileTypeForR1.clear(); mInstalledPasspointProfileTypeForR2.clear(); for (Map.Entry entry : providers.entrySet()) { config = entry.getValue().getConfig(); if (config.getCredential().getUserCredential() != null) { eapType = EAPConstants.EAP_TTLS; } else if (config.getCredential().getCertCredential() != null) { eapType = EAPConstants.EAP_TLS; } else if (config.getCredential().getSimCredential() != null) { eapType = config.getCredential().getSimCredential().getEapType(); } else { eapType = -1; } switch (eapType) { case EAPConstants.EAP_TLS: passpointType = WifiMetricsProto.PasspointProfileTypeCount.TYPE_EAP_TLS; break; case EAPConstants.EAP_TTLS: passpointType = WifiMetricsProto.PasspointProfileTypeCount.TYPE_EAP_TTLS; break; case EAPConstants.EAP_SIM: passpointType = WifiMetricsProto.PasspointProfileTypeCount.TYPE_EAP_SIM; break; case EAPConstants.EAP_AKA: passpointType = WifiMetricsProto.PasspointProfileTypeCount.TYPE_EAP_AKA; break; case EAPConstants.EAP_AKA_PRIME: passpointType = WifiMetricsProto.PasspointProfileTypeCount.TYPE_EAP_AKA_PRIME; break; default: passpointType = WifiMetricsProto.PasspointProfileTypeCount.TYPE_UNKNOWN; } if (config.validateForR2()) { mInstalledPasspointProfileTypeForR2.increment(passpointType); } else { mInstalledPasspointProfileTypeForR1.increment(passpointType); } } } } /** * Put all metrics that were being tracked separately into mWifiLogProto */ private void consolidateProto() { List rssis = new ArrayList<>(); synchronized (mLock) { int connectionEventCount = mConnectionEventList.size(); // Exclude the current active un-ended connection event if (mCurrentConnectionEvent != null) { connectionEventCount--; } mWifiLogProto.connectionEvent = new WifiMetricsProto.ConnectionEvent[connectionEventCount]; for (int i = 0; i < connectionEventCount; i++) { mWifiLogProto.connectionEvent[i] = mConnectionEventList.get(i).mConnectionEvent; } //Convert the SparseIntArray of scanReturnEntry integers into ScanReturnEntry proto list mWifiLogProto.scanReturnEntries = new WifiMetricsProto.WifiLog.ScanReturnEntry[mScanReturnEntries.size()]; for (int i = 0; i < mScanReturnEntries.size(); i++) { mWifiLogProto.scanReturnEntries[i] = new WifiMetricsProto.WifiLog.ScanReturnEntry(); mWifiLogProto.scanReturnEntries[i].scanReturnCode = mScanReturnEntries.keyAt(i); mWifiLogProto.scanReturnEntries[i].scanResultsCount = mScanReturnEntries.valueAt(i); } // Convert the SparseIntArray of systemStateEntry into WifiSystemStateEntry proto list // This one is slightly more complex, as the Sparse are indexed with: // key: wifiState * 2 + isScreenOn, value: wifiStateCount mWifiLogProto.wifiSystemStateEntries = new WifiMetricsProto.WifiLog .WifiSystemStateEntry[mWifiSystemStateEntries.size()]; for (int i = 0; i < mWifiSystemStateEntries.size(); i++) { mWifiLogProto.wifiSystemStateEntries[i] = new WifiMetricsProto.WifiLog.WifiSystemStateEntry(); mWifiLogProto.wifiSystemStateEntries[i].wifiState = mWifiSystemStateEntries.keyAt(i) / 2; mWifiLogProto.wifiSystemStateEntries[i].wifiStateCount = mWifiSystemStateEntries.valueAt(i); mWifiLogProto.wifiSystemStateEntries[i].isScreenOn = (mWifiSystemStateEntries.keyAt(i) % 2) > 0; } mWifiLogProto.recordDurationSec = (int) ((mClock.getElapsedSinceBootMillis() / 1000) - mRecordStartTimeSec); /** * Convert the SparseIntArrays of RSSI poll rssi, counts, and frequency to the * proto's repeated IntKeyVal array. */ for (Map.Entry entry : mRssiPollCountsMap.entrySet()) { int frequency = entry.getKey(); SparseIntArray histogram = entry.getValue(); for (int i = 0; i < histogram.size(); i++) { WifiMetricsProto.RssiPollCount keyVal = new WifiMetricsProto.RssiPollCount(); keyVal.rssi = histogram.keyAt(i); keyVal.count = histogram.valueAt(i); keyVal.frequency = frequency; rssis.add(keyVal); } } mWifiLogProto.rssiPollRssiCount = rssis.toArray(mWifiLogProto.rssiPollRssiCount); /** * Convert the SparseIntArray of RSSI delta rssi's and counts to the proto's repeated * IntKeyVal array. */ mWifiLogProto.rssiPollDeltaCount = new WifiMetricsProto.RssiPollCount[mRssiDeltaCounts.size()]; for (int i = 0; i < mRssiDeltaCounts.size(); i++) { mWifiLogProto.rssiPollDeltaCount[i] = new WifiMetricsProto.RssiPollCount(); mWifiLogProto.rssiPollDeltaCount[i].rssi = mRssiDeltaCounts.keyAt(i); mWifiLogProto.rssiPollDeltaCount[i].count = mRssiDeltaCounts.valueAt(i); } /** * Add LinkSpeedCount objects from mLinkSpeedCounts to proto. */ mWifiLogProto.linkSpeedCounts = new WifiMetricsProto.LinkSpeedCount[mLinkSpeedCounts.size()]; for (int i = 0; i < mLinkSpeedCounts.size(); i++) { mWifiLogProto.linkSpeedCounts[i] = mLinkSpeedCounts.valueAt(i); } /** * Convert the SparseIntArray of alert reasons and counts to the proto's repeated * IntKeyVal array. */ mWifiLogProto.alertReasonCount = new WifiMetricsProto.AlertReasonCount[mWifiAlertReasonCounts.size()]; for (int i = 0; i < mWifiAlertReasonCounts.size(); i++) { mWifiLogProto.alertReasonCount[i] = new WifiMetricsProto.AlertReasonCount(); mWifiLogProto.alertReasonCount[i].reason = mWifiAlertReasonCounts.keyAt(i); mWifiLogProto.alertReasonCount[i].count = mWifiAlertReasonCounts.valueAt(i); } /** * Convert the SparseIntArray of Wifi Score and counts to proto's repeated * IntKeyVal array. */ mWifiLogProto.wifiScoreCount = new WifiMetricsProto.WifiScoreCount[mWifiScoreCounts.size()]; for (int score = 0; score < mWifiScoreCounts.size(); score++) { mWifiLogProto.wifiScoreCount[score] = new WifiMetricsProto.WifiScoreCount(); mWifiLogProto.wifiScoreCount[score].score = mWifiScoreCounts.keyAt(score); mWifiLogProto.wifiScoreCount[score].count = mWifiScoreCounts.valueAt(score); } /** * Convert the SparseIntArray of Wifi Usability Score and counts to proto's repeated * IntKeyVal array. */ mWifiLogProto.wifiUsabilityScoreCount = new WifiMetricsProto.WifiUsabilityScoreCount[mWifiUsabilityScoreCounts.size()]; for (int scoreIdx = 0; scoreIdx < mWifiUsabilityScoreCounts.size(); scoreIdx++) { mWifiLogProto.wifiUsabilityScoreCount[scoreIdx] = new WifiMetricsProto.WifiUsabilityScoreCount(); mWifiLogProto.wifiUsabilityScoreCount[scoreIdx].score = mWifiUsabilityScoreCounts.keyAt(scoreIdx); mWifiLogProto.wifiUsabilityScoreCount[scoreIdx].count = mWifiUsabilityScoreCounts.valueAt(scoreIdx); } /** * Convert the SparseIntArray of SoftAp Return codes and counts to proto's repeated * IntKeyVal array. */ int codeCounts = mSoftApManagerReturnCodeCounts.size(); mWifiLogProto.softApReturnCode = new WifiMetricsProto.SoftApReturnCodeCount[codeCounts]; for (int sapCode = 0; sapCode < codeCounts; sapCode++) { mWifiLogProto.softApReturnCode[sapCode] = new WifiMetricsProto.SoftApReturnCodeCount(); mWifiLogProto.softApReturnCode[sapCode].startResult = mSoftApManagerReturnCodeCounts.keyAt(sapCode); mWifiLogProto.softApReturnCode[sapCode].count = mSoftApManagerReturnCodeCounts.valueAt(sapCode); } /** * Convert StaEventList to array of StaEvents */ mWifiLogProto.staEventList = new StaEvent[mStaEventList.size()]; for (int i = 0; i < mStaEventList.size(); i++) { mWifiLogProto.staEventList[i] = mStaEventList.get(i).staEvent; } mWifiLogProto.totalSsidsInScanHistogram = makeNumConnectableNetworksBucketArray(mTotalSsidsInScanHistogram); mWifiLogProto.totalBssidsInScanHistogram = makeNumConnectableNetworksBucketArray(mTotalBssidsInScanHistogram); mWifiLogProto.availableOpenSsidsInScanHistogram = makeNumConnectableNetworksBucketArray(mAvailableOpenSsidsInScanHistogram); mWifiLogProto.availableOpenBssidsInScanHistogram = makeNumConnectableNetworksBucketArray(mAvailableOpenBssidsInScanHistogram); mWifiLogProto.availableSavedSsidsInScanHistogram = makeNumConnectableNetworksBucketArray(mAvailableSavedSsidsInScanHistogram); mWifiLogProto.availableSavedBssidsInScanHistogram = makeNumConnectableNetworksBucketArray(mAvailableSavedBssidsInScanHistogram); mWifiLogProto.availableOpenOrSavedSsidsInScanHistogram = makeNumConnectableNetworksBucketArray( mAvailableOpenOrSavedSsidsInScanHistogram); mWifiLogProto.availableOpenOrSavedBssidsInScanHistogram = makeNumConnectableNetworksBucketArray( mAvailableOpenOrSavedBssidsInScanHistogram); mWifiLogProto.availableSavedPasspointProviderProfilesInScanHistogram = makeNumConnectableNetworksBucketArray( mAvailableSavedPasspointProviderProfilesInScanHistogram); mWifiLogProto.availableSavedPasspointProviderBssidsInScanHistogram = makeNumConnectableNetworksBucketArray( mAvailableSavedPasspointProviderBssidsInScanHistogram); mWifiLogProto.wifiAwareLog = mWifiAwareMetrics.consolidateProto(); mWifiLogProto.wifiRttLog = mRttMetrics.consolidateProto(); mWifiLogProto.pnoScanMetrics = mPnoScanMetrics; mWifiLogProto.wifiLinkLayerUsageStats = mWifiLinkLayerUsageStats; /** * Convert the SparseIntArray of "Connect to Network" notification types and counts to * proto's repeated IntKeyVal array. */ ConnectToNetworkNotificationAndActionCount[] notificationCountArray = new ConnectToNetworkNotificationAndActionCount[ mConnectToNetworkNotificationCount.size()]; for (int i = 0; i < mConnectToNetworkNotificationCount.size(); i++) { ConnectToNetworkNotificationAndActionCount keyVal = new ConnectToNetworkNotificationAndActionCount(); keyVal.notification = mConnectToNetworkNotificationCount.keyAt(i); keyVal.recommender = ConnectToNetworkNotificationAndActionCount.RECOMMENDER_OPEN; keyVal.count = mConnectToNetworkNotificationCount.valueAt(i); notificationCountArray[i] = keyVal; } mWifiLogProto.connectToNetworkNotificationCount = notificationCountArray; /** * Convert the SparseIntArray of "Connect to Network" notification types and counts to * proto's repeated IntKeyVal array. */ ConnectToNetworkNotificationAndActionCount[] notificationActionCountArray = new ConnectToNetworkNotificationAndActionCount[ mConnectToNetworkNotificationActionCount.size()]; for (int i = 0; i < mConnectToNetworkNotificationActionCount.size(); i++) { ConnectToNetworkNotificationAndActionCount keyVal = new ConnectToNetworkNotificationAndActionCount(); int key = mConnectToNetworkNotificationActionCount.keyAt(i); keyVal.notification = key / CONNECT_TO_NETWORK_NOTIFICATION_ACTION_KEY_MULTIPLIER; keyVal.action = key % CONNECT_TO_NETWORK_NOTIFICATION_ACTION_KEY_MULTIPLIER; keyVal.recommender = ConnectToNetworkNotificationAndActionCount.RECOMMENDER_OPEN; keyVal.count = mConnectToNetworkNotificationActionCount.valueAt(i); notificationActionCountArray[i] = keyVal; } mWifiLogProto.installedPasspointProfileTypeForR1 = convertPasspointProfilesToProto(mInstalledPasspointProfileTypeForR1); mWifiLogProto.installedPasspointProfileTypeForR2 = convertPasspointProfilesToProto(mInstalledPasspointProfileTypeForR2); mWifiLogProto.connectToNetworkNotificationActionCount = notificationActionCountArray; mWifiLogProto.openNetworkRecommenderBlacklistSize = mOpenNetworkRecommenderBlacklistSize; mWifiLogProto.isWifiNetworksAvailableNotificationOn = mIsWifiNetworksAvailableNotificationOn; mWifiLogProto.numOpenNetworkRecommendationUpdates = mNumOpenNetworkRecommendationUpdates; mWifiLogProto.numOpenNetworkConnectMessageFailedToSend = mNumOpenNetworkConnectMessageFailedToSend; mWifiLogProto.observedHotspotR1ApsInScanHistogram = makeNumConnectableNetworksBucketArray(mObservedHotspotR1ApInScanHistogram); mWifiLogProto.observedHotspotR2ApsInScanHistogram = makeNumConnectableNetworksBucketArray(mObservedHotspotR2ApInScanHistogram); mWifiLogProto.observedHotspotR1EssInScanHistogram = makeNumConnectableNetworksBucketArray(mObservedHotspotR1EssInScanHistogram); mWifiLogProto.observedHotspotR2EssInScanHistogram = makeNumConnectableNetworksBucketArray(mObservedHotspotR2EssInScanHistogram); mWifiLogProto.observedHotspotR1ApsPerEssInScanHistogram = makeNumConnectableNetworksBucketArray( mObservedHotspotR1ApsPerEssInScanHistogram); mWifiLogProto.observedHotspotR2ApsPerEssInScanHistogram = makeNumConnectableNetworksBucketArray( mObservedHotspotR2ApsPerEssInScanHistogram); mWifiLogProto.observed80211McSupportingApsInScanHistogram = makeNumConnectableNetworksBucketArray(mObserved80211mcApInScanHistogram); if (mSoftApEventListTethered.size() > 0) { mWifiLogProto.softApConnectedClientsEventsTethered = mSoftApEventListTethered.toArray( mWifiLogProto.softApConnectedClientsEventsTethered); } if (mSoftApEventListLocalOnly.size() > 0) { mWifiLogProto.softApConnectedClientsEventsLocalOnly = mSoftApEventListLocalOnly.toArray( mWifiLogProto.softApConnectedClientsEventsLocalOnly); } mWifiLogProto.wpsMetrics = mWpsMetrics; mWifiLogProto.wifiPowerStats = mWifiPowerMetrics.buildProto(); mWifiLogProto.wifiRadioUsage = mWifiPowerMetrics.buildWifiRadioUsageProto(); mWifiLogProto.wifiWakeStats = mWifiWakeMetrics.buildProto(); mWifiLogProto.isMacRandomizationOn = mIsMacRandomizationOn; mWifiLogProto.experimentValues = mExperimentValues; mWifiLogProto.wifiIsUnusableEventList = new WifiIsUnusableEvent[mWifiIsUnusableList.size()]; for (int i = 0; i < mWifiIsUnusableList.size(); i++) { mWifiLogProto.wifiIsUnusableEventList[i] = mWifiIsUnusableList.get(i).event; } mWifiLogProto.hardwareRevision = SystemProperties.get("ro.boot.revision", ""); // Postprocessing on WifiUsabilityStats to upload an equal number of LABEL_GOOD and // LABEL_BAD WifiUsabilityStats final int numUsabilityStats = Math.min( Math.min(mWifiUsabilityStatsListBad.size(), mWifiUsabilityStatsListGood.size()), MAX_WIFI_USABILITY_STATS_PER_TYPE_TO_UPLOAD); LinkedList usabilityStatsGoodCopy = new LinkedList<>(mWifiUsabilityStatsListGood); LinkedList usabilityStatsBadCopy = new LinkedList<>(mWifiUsabilityStatsListBad); mWifiLogProto.wifiUsabilityStatsList = new WifiUsabilityStats[numUsabilityStats * 2]; for (int i = 0; i < numUsabilityStats; i++) { mWifiLogProto.wifiUsabilityStatsList[2 * i] = usabilityStatsGoodCopy.remove( mRand.nextInt(usabilityStatsGoodCopy.size())); mWifiLogProto.wifiUsabilityStatsList[2 * i + 1] = usabilityStatsBadCopy.remove( mRand.nextInt(usabilityStatsBadCopy.size())); } mWifiLogProto.mobilityStatePnoStatsList = new DeviceMobilityStatePnoScanStats[mMobilityStatePnoStatsMap.size()]; for (int i = 0; i < mMobilityStatePnoStatsMap.size(); i++) { mWifiLogProto.mobilityStatePnoStatsList[i] = mMobilityStatePnoStatsMap.valueAt(i); } mWifiLogProto.wifiP2PStats = mWifiP2pMetrics.consolidateProto(); mWifiLogProto.wifiDppLog = mDppMetrics.consolidateProto(); mWifiLogProto.wifiConfigStoreIo = new WifiMetricsProto.WifiConfigStoreIO(); mWifiLogProto.wifiConfigStoreIo.readDurations = makeWifiConfigStoreIODurationBucketArray(mWifiConfigStoreReadDurationHistogram); mWifiLogProto.wifiConfigStoreIo.writeDurations = makeWifiConfigStoreIODurationBucketArray( mWifiConfigStoreWriteDurationHistogram); LinkProbeStats linkProbeStats = new LinkProbeStats(); linkProbeStats.successRssiCounts = mLinkProbeSuccessRssiCounts.toProto(); linkProbeStats.failureRssiCounts = mLinkProbeFailureRssiCounts.toProto(); linkProbeStats.successLinkSpeedCounts = mLinkProbeSuccessLinkSpeedCounts.toProto(); linkProbeStats.failureLinkSpeedCounts = mLinkProbeFailureLinkSpeedCounts.toProto(); linkProbeStats.successSecondsSinceLastTxSuccessHistogram = mLinkProbeSuccessSecondsSinceLastTxSuccessHistogram.toProto(); linkProbeStats.failureSecondsSinceLastTxSuccessHistogram = mLinkProbeFailureSecondsSinceLastTxSuccessHistogram.toProto(); linkProbeStats.successElapsedTimeMsHistogram = mLinkProbeSuccessElapsedTimeMsHistogram.toProto(); linkProbeStats.failureReasonCounts = mLinkProbeFailureReasonCounts.toProto( LinkProbeFailureReasonCount.class, (reason, count) -> { LinkProbeFailureReasonCount c = new LinkProbeFailureReasonCount(); c.failureReason = linkProbeFailureReasonToProto(reason); c.count = count; return c; }); linkProbeStats.experimentProbeCounts = mLinkProbeExperimentProbeCounts.toProto( ExperimentProbeCounts.class, (experimentId, probeCount) -> { ExperimentProbeCounts c = new ExperimentProbeCounts(); c.experimentId = experimentId; c.probeCount = probeCount; return c; }); mWifiLogProto.linkProbeStats = linkProbeStats; mWifiLogProto.networkSelectionExperimentDecisionsList = makeNetworkSelectionExperimentDecisionsList(); mWifiNetworkRequestApiLog.networkMatchSizeHistogram = mWifiNetworkRequestApiMatchSizeHistogram.toProto(); mWifiLogProto.wifiNetworkRequestApiLog = mWifiNetworkRequestApiLog; mWifiNetworkSuggestionApiLog.networkListSizeHistogram = mWifiNetworkSuggestionApiListSizeHistogram.toProto(); mWifiLogProto.wifiNetworkSuggestionApiLog = mWifiNetworkSuggestionApiLog; mWifiLockStats.highPerfLockAcqDurationSecHistogram = mWifiLockHighPerfAcqDurationSecHistogram.toProto(); mWifiLockStats.lowLatencyLockAcqDurationSecHistogram = mWifiLockLowLatencyAcqDurationSecHistogram.toProto(); mWifiLockStats.highPerfActiveSessionDurationSecHistogram = mWifiLockHighPerfActiveSessionDurationSecHistogram.toProto(); mWifiLockStats.lowLatencyActiveSessionDurationSecHistogram = mWifiLockLowLatencyActiveSessionDurationSecHistogram.toProto(); mWifiLogProto.wifiLockStats = mWifiLockStats; mWifiLogProto.wifiToggleStats = mWifiToggleStats; /** * Convert the SparseIntArray of passpoint provision failure code * and counts to the proto's repeated IntKeyVal array. */ mWifiLogProto.passpointProvisionStats = new PasspointProvisionStats(); mWifiLogProto.passpointProvisionStats.numProvisionSuccess = mNumProvisionSuccess; mWifiLogProto.passpointProvisionStats.provisionFailureCount = mPasspointProvisionFailureCounts.toProto(ProvisionFailureCount.class, (key, count) -> { ProvisionFailureCount entry = new ProvisionFailureCount(); entry.failureCode = key; entry.count = count; return entry; }); // 'G' is due to that 1st Letter after _ becomes capital during protobuff compilation mWifiLogProto.txLinkSpeedCount2G = mTxLinkSpeedCount2g.toProto(); mWifiLogProto.txLinkSpeedCount5GLow = mTxLinkSpeedCount5gLow.toProto(); mWifiLogProto.txLinkSpeedCount5GMid = mTxLinkSpeedCount5gMid.toProto(); mWifiLogProto.txLinkSpeedCount5GHigh = mTxLinkSpeedCount5gHigh.toProto(); mWifiLogProto.rxLinkSpeedCount2G = mRxLinkSpeedCount2g.toProto(); mWifiLogProto.rxLinkSpeedCount5GLow = mRxLinkSpeedCount5gLow.toProto(); mWifiLogProto.rxLinkSpeedCount5GMid = mRxLinkSpeedCount5gMid.toProto(); mWifiLogProto.rxLinkSpeedCount5GHigh = mRxLinkSpeedCount5gHigh.toProto(); } } private static int linkProbeFailureReasonToProto(@WifiNative.SendMgmtFrameError int reason) { switch (reason) { case WifiNative.SEND_MGMT_FRAME_ERROR_MCS_UNSUPPORTED: return LinkProbeStats.LINK_PROBE_FAILURE_REASON_MCS_UNSUPPORTED; case WifiNative.SEND_MGMT_FRAME_ERROR_NO_ACK: return LinkProbeStats.LINK_PROBE_FAILURE_REASON_NO_ACK; case WifiNative.SEND_MGMT_FRAME_ERROR_TIMEOUT: return LinkProbeStats.LINK_PROBE_FAILURE_REASON_TIMEOUT; case WifiNative.SEND_MGMT_FRAME_ERROR_ALREADY_STARTED: return LinkProbeStats.LINK_PROBE_FAILURE_REASON_ALREADY_STARTED; default: return LinkProbeStats.LINK_PROBE_FAILURE_REASON_UNKNOWN; } } private NetworkSelectionExperimentDecisions[] makeNetworkSelectionExperimentDecisionsList() { NetworkSelectionExperimentDecisions[] results = new NetworkSelectionExperimentDecisions[ mNetworkSelectionExperimentPairNumChoicesCounts.size()]; int i = 0; for (Map.Entry, NetworkSelectionExperimentResults> entry : mNetworkSelectionExperimentPairNumChoicesCounts.entrySet()) { NetworkSelectionExperimentDecisions result = new NetworkSelectionExperimentDecisions(); result.experiment1Id = entry.getKey().first; result.experiment2Id = entry.getKey().second; result.sameSelectionNumChoicesCounter = entry.getValue().sameSelectionNumChoicesCounter.toProto(); result.differentSelectionNumChoicesCounter = entry.getValue().differentSelectionNumChoicesCounter.toProto(); results[i] = result; i++; } return results; } /** Sets the scoring experiment id to current value */ private void consolidateScoringParams() { synchronized (mLock) { if (mScoringParams != null) { int experimentIdentifier = mScoringParams.getExperimentIdentifier(); if (experimentIdentifier == 0) { mWifiLogProto.scoreExperimentId = ""; } else { mWifiLogProto.scoreExperimentId = "x" + experimentIdentifier; } } } } private WifiMetricsProto.NumConnectableNetworksBucket[] makeNumConnectableNetworksBucketArray( SparseIntArray sia) { WifiMetricsProto.NumConnectableNetworksBucket[] array = new WifiMetricsProto.NumConnectableNetworksBucket[sia.size()]; for (int i = 0; i < sia.size(); i++) { WifiMetricsProto.NumConnectableNetworksBucket keyVal = new WifiMetricsProto.NumConnectableNetworksBucket(); keyVal.numConnectableNetworks = sia.keyAt(i); keyVal.count = sia.valueAt(i); array[i] = keyVal; } return array; } private WifiMetricsProto.WifiConfigStoreIO.DurationBucket[] makeWifiConfigStoreIODurationBucketArray(SparseIntArray sia) { MetricsUtils.GenericBucket[] genericBuckets = MetricsUtils.linearHistogramToGenericBuckets(sia, WIFI_CONFIG_STORE_IO_DURATION_BUCKET_RANGES_MS); WifiMetricsProto.WifiConfigStoreIO.DurationBucket[] array = new WifiMetricsProto.WifiConfigStoreIO.DurationBucket[genericBuckets.length]; try { for (int i = 0; i < genericBuckets.length; i++) { array[i] = new WifiMetricsProto.WifiConfigStoreIO.DurationBucket(); array[i].rangeStartMs = toIntExact(genericBuckets[i].start); array[i].rangeEndMs = toIntExact(genericBuckets[i].end); array[i].count = genericBuckets[i].count; } } catch (ArithmeticException e) { // Return empty array on any overflow errors. array = new WifiMetricsProto.WifiConfigStoreIO.DurationBucket[0]; } return array; } /** * Clear all WifiMetrics, except for currentConnectionEvent and Open Network Notification * feature enabled state, blacklist size. */ private void clear() { synchronized (mLock) { loadSettings(); mConnectionEventList.clear(); if (mCurrentConnectionEvent != null) { mConnectionEventList.add(mCurrentConnectionEvent); } mScanReturnEntries.clear(); mWifiSystemStateEntries.clear(); mRecordStartTimeSec = mClock.getElapsedSinceBootMillis() / 1000; mRssiPollCountsMap.clear(); mRssiDeltaCounts.clear(); mLinkSpeedCounts.clear(); mTxLinkSpeedCount2g.clear(); mTxLinkSpeedCount5gLow.clear(); mTxLinkSpeedCount5gMid.clear(); mTxLinkSpeedCount5gHigh.clear(); mRxLinkSpeedCount2g.clear(); mRxLinkSpeedCount5gLow.clear(); mRxLinkSpeedCount5gMid.clear(); mRxLinkSpeedCount5gHigh.clear(); mWifiAlertReasonCounts.clear(); mWifiScoreCounts.clear(); mWifiUsabilityScoreCounts.clear(); mWifiLogProto.clear(); mScanResultRssiTimestampMillis = -1; mSoftApManagerReturnCodeCounts.clear(); mStaEventList.clear(); mWifiAwareMetrics.clear(); mRttMetrics.clear(); mTotalSsidsInScanHistogram.clear(); mTotalBssidsInScanHistogram.clear(); mAvailableOpenSsidsInScanHistogram.clear(); mAvailableOpenBssidsInScanHistogram.clear(); mAvailableSavedSsidsInScanHistogram.clear(); mAvailableSavedBssidsInScanHistogram.clear(); mAvailableOpenOrSavedSsidsInScanHistogram.clear(); mAvailableOpenOrSavedBssidsInScanHistogram.clear(); mAvailableSavedPasspointProviderProfilesInScanHistogram.clear(); mAvailableSavedPasspointProviderBssidsInScanHistogram.clear(); mPnoScanMetrics.clear(); mWifiLinkLayerUsageStats.clear(); mConnectToNetworkNotificationCount.clear(); mConnectToNetworkNotificationActionCount.clear(); mNumOpenNetworkRecommendationUpdates = 0; mNumOpenNetworkConnectMessageFailedToSend = 0; mObservedHotspotR1ApInScanHistogram.clear(); mObservedHotspotR2ApInScanHistogram.clear(); mObservedHotspotR1EssInScanHistogram.clear(); mObservedHotspotR2EssInScanHistogram.clear(); mObservedHotspotR1ApsPerEssInScanHistogram.clear(); mObservedHotspotR2ApsPerEssInScanHistogram.clear(); mSoftApEventListTethered.clear(); mSoftApEventListLocalOnly.clear(); mWpsMetrics.clear(); mWifiWakeMetrics.clear(); mObserved80211mcApInScanHistogram.clear(); mWifiIsUnusableList.clear(); mInstalledPasspointProfileTypeForR1.clear(); mInstalledPasspointProfileTypeForR2.clear(); mWifiUsabilityStatsListGood.clear(); mWifiUsabilityStatsListBad.clear(); mWifiUsabilityStatsEntriesList.clear(); mMobilityStatePnoStatsMap.clear(); mWifiP2pMetrics.clear(); mDppMetrics.clear(); mWifiUsabilityStatsCounter = 0; mLastBssid = null; mLastFrequency = -1; mSeqNumInsideFramework = 0; mLastWifiUsabilityScore = -1; mLastWifiUsabilityScoreNoReset = -1; mLastPredictionHorizonSec = -1; mLastPredictionHorizonSecNoReset = -1; mSeqNumToFramework = -1; mProbeStatusSinceLastUpdate = android.net.wifi.WifiUsabilityStatsEntry.PROBE_STATUS_NO_PROBE; mProbeElapsedTimeSinceLastUpdateMs = -1; mProbeMcsRateSinceLastUpdate = -1; mScoreBreachLowTimeMillis = -1; mWifiConfigStoreReadDurationHistogram.clear(); mWifiConfigStoreWriteDurationHistogram.clear(); mLinkProbeSuccessRssiCounts.clear(); mLinkProbeFailureRssiCounts.clear(); mLinkProbeSuccessLinkSpeedCounts.clear(); mLinkProbeFailureLinkSpeedCounts.clear(); mLinkProbeSuccessSecondsSinceLastTxSuccessHistogram.clear(); mLinkProbeFailureSecondsSinceLastTxSuccessHistogram.clear(); mLinkProbeSuccessElapsedTimeMsHistogram.clear(); mLinkProbeFailureReasonCounts.clear(); mLinkProbeExperimentProbeCounts.clear(); mLinkProbeStaEventCount = 0; mNetworkSelectionExperimentPairNumChoicesCounts.clear(); mWifiNetworkSuggestionApiLog.clear(); mWifiNetworkSuggestionApiLog.clear(); mWifiNetworkRequestApiMatchSizeHistogram.clear(); mWifiNetworkSuggestionApiListSizeHistogram.clear(); mWifiLockHighPerfAcqDurationSecHistogram.clear(); mWifiLockLowLatencyAcqDurationSecHistogram.clear(); mWifiLockHighPerfActiveSessionDurationSecHistogram.clear(); mWifiLockLowLatencyActiveSessionDurationSecHistogram.clear(); mWifiLockStats.clear(); mWifiToggleStats.clear(); mPasspointProvisionFailureCounts.clear(); mNumProvisionSuccess = 0; } } /** * Set screen state (On/Off) */ public void setScreenState(boolean screenOn) { synchronized (mLock) { mScreenOn = screenOn; } } /** * Set wifi state (WIFI_UNKNOWN, WIFI_DISABLED, WIFI_DISCONNECTED, WIFI_ASSOCIATED) */ public void setWifiState(int wifiState) { synchronized (mLock) { mWifiState = wifiState; mWifiWins = (wifiState == WifiMetricsProto.WifiLog.WIFI_ASSOCIATED); mWifiWinsUsabilityScore = (wifiState == WifiMetricsProto.WifiLog.WIFI_ASSOCIATED); } } /** * Message handler for interesting WifiMonitor messages. Generates StaEvents */ private void processMessage(Message msg) { StaEvent event = new StaEvent(); boolean logEvent = true; switch (msg.what) { case WifiMonitor.ASSOCIATION_REJECTION_EVENT: event.type = StaEvent.TYPE_ASSOCIATION_REJECTION_EVENT; event.associationTimedOut = msg.arg1 > 0 ? true : false; event.status = msg.arg2; break; case WifiMonitor.AUTHENTICATION_FAILURE_EVENT: event.type = StaEvent.TYPE_AUTHENTICATION_FAILURE_EVENT; switch (msg.arg1) { case WifiManager.ERROR_AUTH_FAILURE_NONE: event.authFailureReason = StaEvent.AUTH_FAILURE_NONE; break; case WifiManager.ERROR_AUTH_FAILURE_TIMEOUT: event.authFailureReason = StaEvent.AUTH_FAILURE_TIMEOUT; break; case WifiManager.ERROR_AUTH_FAILURE_WRONG_PSWD: event.authFailureReason = StaEvent.AUTH_FAILURE_WRONG_PSWD; break; case WifiManager.ERROR_AUTH_FAILURE_EAP_FAILURE: event.authFailureReason = StaEvent.AUTH_FAILURE_EAP_FAILURE; break; default: break; } break; case WifiMonitor.NETWORK_CONNECTION_EVENT: event.type = StaEvent.TYPE_NETWORK_CONNECTION_EVENT; break; case WifiMonitor.NETWORK_DISCONNECTION_EVENT: event.type = StaEvent.TYPE_NETWORK_DISCONNECTION_EVENT; event.reason = msg.arg2; event.localGen = msg.arg1 == 0 ? false : true; break; case WifiMonitor.SUPPLICANT_STATE_CHANGE_EVENT: logEvent = false; StateChangeResult stateChangeResult = (StateChangeResult) msg.obj; mSupplicantStateChangeBitmask |= supplicantStateToBit(stateChangeResult.state); break; case ClientModeImpl.CMD_ASSOCIATED_BSSID: event.type = StaEvent.TYPE_CMD_ASSOCIATED_BSSID; break; case ClientModeImpl.CMD_TARGET_BSSID: event.type = StaEvent.TYPE_CMD_TARGET_BSSID; break; default: return; } if (logEvent) { addStaEvent(event); } } /** * Log a StaEvent from ClientModeImpl. The StaEvent must not be one of the supplicant * generated event types, which are logged through 'sendMessage' * @param type StaEvent.EventType describing the event */ public void logStaEvent(int type) { logStaEvent(type, StaEvent.DISCONNECT_UNKNOWN, null); } /** * Log a StaEvent from ClientModeImpl. The StaEvent must not be one of the supplicant * generated event types, which are logged through 'sendMessage' * @param type StaEvent.EventType describing the event * @param config WifiConfiguration for a framework initiated connection attempt */ public void logStaEvent(int type, WifiConfiguration config) { logStaEvent(type, StaEvent.DISCONNECT_UNKNOWN, config); } /** * Log a StaEvent from ClientModeImpl. The StaEvent must not be one of the supplicant * generated event types, which are logged through 'sendMessage' * @param type StaEvent.EventType describing the event * @param frameworkDisconnectReason StaEvent.FrameworkDisconnectReason explaining why framework * initiated a FRAMEWORK_DISCONNECT */ public void logStaEvent(int type, int frameworkDisconnectReason) { logStaEvent(type, frameworkDisconnectReason, null); } /** * Log a StaEvent from ClientModeImpl. The StaEvent must not be one of the supplicant * generated event types, which are logged through 'sendMessage' * @param type StaEvent.EventType describing the event * @param frameworkDisconnectReason StaEvent.FrameworkDisconnectReason explaining why framework * initiated a FRAMEWORK_DISCONNECT * @param config WifiConfiguration for a framework initiated connection attempt */ public void logStaEvent(int type, int frameworkDisconnectReason, WifiConfiguration config) { switch (type) { case StaEvent.TYPE_CMD_IP_CONFIGURATION_SUCCESSFUL: case StaEvent.TYPE_CMD_IP_CONFIGURATION_LOST: case StaEvent.TYPE_CMD_IP_REACHABILITY_LOST: case StaEvent.TYPE_CMD_START_CONNECT: case StaEvent.TYPE_CMD_START_ROAM: case StaEvent.TYPE_CONNECT_NETWORK: case StaEvent.TYPE_NETWORK_AGENT_VALID_NETWORK: case StaEvent.TYPE_FRAMEWORK_DISCONNECT: case StaEvent.TYPE_SCORE_BREACH: case StaEvent.TYPE_MAC_CHANGE: case StaEvent.TYPE_WIFI_ENABLED: case StaEvent.TYPE_WIFI_DISABLED: case StaEvent.TYPE_WIFI_USABILITY_SCORE_BREACH: break; default: Log.e(TAG, "Unknown StaEvent:" + type); return; } StaEvent event = new StaEvent(); event.type = type; if (frameworkDisconnectReason != StaEvent.DISCONNECT_UNKNOWN) { event.frameworkDisconnectReason = frameworkDisconnectReason; } event.configInfo = createConfigInfo(config); addStaEvent(event); } private void addStaEvent(StaEvent staEvent) { staEvent.startTimeMillis = mClock.getElapsedSinceBootMillis(); staEvent.lastRssi = mLastPollRssi; staEvent.lastFreq = mLastPollFreq; staEvent.lastLinkSpeed = mLastPollLinkSpeed; staEvent.supplicantStateChangesBitmask = mSupplicantStateChangeBitmask; staEvent.lastScore = mLastScore; staEvent.lastWifiUsabilityScore = mLastWifiUsabilityScore; staEvent.lastPredictionHorizonSec = mLastPredictionHorizonSec; mSupplicantStateChangeBitmask = 0; mLastPollRssi = -127; mLastPollFreq = -1; mLastPollLinkSpeed = -1; mLastPollRxLinkSpeed = -1; mLastScore = -1; mLastWifiUsabilityScore = -1; mLastPredictionHorizonSec = -1; mStaEventList.add(new StaEventWithTime(staEvent, mClock.getWallClockMillis())); // Prune StaEventList if it gets too long if (mStaEventList.size() > MAX_STA_EVENTS) mStaEventList.remove(); } private ConfigInfo createConfigInfo(WifiConfiguration config) { if (config == null) return null; ConfigInfo info = new ConfigInfo(); info.allowedKeyManagement = bitSetToInt(config.allowedKeyManagement); info.allowedProtocols = bitSetToInt(config.allowedProtocols); info.allowedAuthAlgorithms = bitSetToInt(config.allowedAuthAlgorithms); info.allowedPairwiseCiphers = bitSetToInt(config.allowedPairwiseCiphers); info.allowedGroupCiphers = bitSetToInt(config.allowedGroupCiphers); info.hiddenSsid = config.hiddenSSID; info.isPasspoint = config.isPasspoint(); info.isEphemeral = config.isEphemeral(); info.hasEverConnected = config.getNetworkSelectionStatus().getHasEverConnected(); ScanResult candidate = config.getNetworkSelectionStatus().getCandidate(); if (candidate != null) { info.scanRssi = candidate.level; info.scanFreq = candidate.frequency; } return info; } public Handler getHandler() { return mHandler; } public WifiAwareMetrics getWifiAwareMetrics() { return mWifiAwareMetrics; } public WifiWakeMetrics getWakeupMetrics() { return mWifiWakeMetrics; } public RttMetrics getRttMetrics() { return mRttMetrics; } // Rather than generate a StaEvent for each SUPPLICANT_STATE_CHANGE, cache these in a bitmask // and attach it to the next event which is generated. private int mSupplicantStateChangeBitmask = 0; /** * Converts a SupplicantState value to a single bit, with position defined by * {@code StaEvent.SupplicantState} */ public static int supplicantStateToBit(SupplicantState state) { switch(state) { case DISCONNECTED: return 1 << StaEvent.STATE_DISCONNECTED; case INTERFACE_DISABLED: return 1 << StaEvent.STATE_INTERFACE_DISABLED; case INACTIVE: return 1 << StaEvent.STATE_INACTIVE; case SCANNING: return 1 << StaEvent.STATE_SCANNING; case AUTHENTICATING: return 1 << StaEvent.STATE_AUTHENTICATING; case ASSOCIATING: return 1 << StaEvent.STATE_ASSOCIATING; case ASSOCIATED: return 1 << StaEvent.STATE_ASSOCIATED; case FOUR_WAY_HANDSHAKE: return 1 << StaEvent.STATE_FOUR_WAY_HANDSHAKE; case GROUP_HANDSHAKE: return 1 << StaEvent.STATE_GROUP_HANDSHAKE; case COMPLETED: return 1 << StaEvent.STATE_COMPLETED; case DORMANT: return 1 << StaEvent.STATE_DORMANT; case UNINITIALIZED: return 1 << StaEvent.STATE_UNINITIALIZED; case INVALID: return 1 << StaEvent.STATE_INVALID; default: Log.wtf(TAG, "Got unknown supplicant state: " + state.ordinal()); return 0; } } private static String supplicantStateChangesBitmaskToString(int mask) { StringBuilder sb = new StringBuilder(); sb.append("supplicantStateChangeEvents: {"); if ((mask & (1 << StaEvent.STATE_DISCONNECTED)) > 0) sb.append(" DISCONNECTED"); if ((mask & (1 << StaEvent.STATE_INTERFACE_DISABLED)) > 0) sb.append(" INTERFACE_DISABLED"); if ((mask & (1 << StaEvent.STATE_INACTIVE)) > 0) sb.append(" INACTIVE"); if ((mask & (1 << StaEvent.STATE_SCANNING)) > 0) sb.append(" SCANNING"); if ((mask & (1 << StaEvent.STATE_AUTHENTICATING)) > 0) sb.append(" AUTHENTICATING"); if ((mask & (1 << StaEvent.STATE_ASSOCIATING)) > 0) sb.append(" ASSOCIATING"); if ((mask & (1 << StaEvent.STATE_ASSOCIATED)) > 0) sb.append(" ASSOCIATED"); if ((mask & (1 << StaEvent.STATE_FOUR_WAY_HANDSHAKE)) > 0) sb.append(" FOUR_WAY_HANDSHAKE"); if ((mask & (1 << StaEvent.STATE_GROUP_HANDSHAKE)) > 0) sb.append(" GROUP_HANDSHAKE"); if ((mask & (1 << StaEvent.STATE_COMPLETED)) > 0) sb.append(" COMPLETED"); if ((mask & (1 << StaEvent.STATE_DORMANT)) > 0) sb.append(" DORMANT"); if ((mask & (1 << StaEvent.STATE_UNINITIALIZED)) > 0) sb.append(" UNINITIALIZED"); if ((mask & (1 << StaEvent.STATE_INVALID)) > 0) sb.append(" INVALID"); sb.append(" }"); return sb.toString(); } /** * Returns a human readable string from a Sta Event. Only adds information relevant to the event * type. */ public static String staEventToString(StaEvent event) { if (event == null) return ""; StringBuilder sb = new StringBuilder(); switch (event.type) { case StaEvent.TYPE_ASSOCIATION_REJECTION_EVENT: sb.append("ASSOCIATION_REJECTION_EVENT") .append(" timedOut=").append(event.associationTimedOut) .append(" status=").append(event.status).append(":") .append(ISupplicantStaIfaceCallback.StatusCode.toString(event.status)); break; case StaEvent.TYPE_AUTHENTICATION_FAILURE_EVENT: sb.append("AUTHENTICATION_FAILURE_EVENT reason=").append(event.authFailureReason) .append(":").append(authFailureReasonToString(event.authFailureReason)); break; case StaEvent.TYPE_NETWORK_CONNECTION_EVENT: sb.append("NETWORK_CONNECTION_EVENT"); break; case StaEvent.TYPE_NETWORK_DISCONNECTION_EVENT: sb.append("NETWORK_DISCONNECTION_EVENT") .append(" local_gen=").append(event.localGen) .append(" reason=").append(event.reason).append(":") .append(ISupplicantStaIfaceCallback.ReasonCode.toString( (event.reason >= 0 ? event.reason : -1 * event.reason))); break; case StaEvent.TYPE_CMD_ASSOCIATED_BSSID: sb.append("CMD_ASSOCIATED_BSSID"); break; case StaEvent.TYPE_CMD_IP_CONFIGURATION_SUCCESSFUL: sb.append("CMD_IP_CONFIGURATION_SUCCESSFUL"); break; case StaEvent.TYPE_CMD_IP_CONFIGURATION_LOST: sb.append("CMD_IP_CONFIGURATION_LOST"); break; case StaEvent.TYPE_CMD_IP_REACHABILITY_LOST: sb.append("CMD_IP_REACHABILITY_LOST"); break; case StaEvent.TYPE_CMD_TARGET_BSSID: sb.append("CMD_TARGET_BSSID"); break; case StaEvent.TYPE_CMD_START_CONNECT: sb.append("CMD_START_CONNECT"); break; case StaEvent.TYPE_CMD_START_ROAM: sb.append("CMD_START_ROAM"); break; case StaEvent.TYPE_CONNECT_NETWORK: sb.append("CONNECT_NETWORK"); break; case StaEvent.TYPE_NETWORK_AGENT_VALID_NETWORK: sb.append("NETWORK_AGENT_VALID_NETWORK"); break; case StaEvent.TYPE_FRAMEWORK_DISCONNECT: sb.append("FRAMEWORK_DISCONNECT") .append(" reason=") .append(frameworkDisconnectReasonToString(event.frameworkDisconnectReason)); break; case StaEvent.TYPE_SCORE_BREACH: sb.append("SCORE_BREACH"); break; case StaEvent.TYPE_MAC_CHANGE: sb.append("MAC_CHANGE"); break; case StaEvent.TYPE_WIFI_ENABLED: sb.append("WIFI_ENABLED"); break; case StaEvent.TYPE_WIFI_DISABLED: sb.append("WIFI_DISABLED"); break; case StaEvent.TYPE_WIFI_USABILITY_SCORE_BREACH: sb.append("WIFI_USABILITY_SCORE_BREACH"); break; case StaEvent.TYPE_LINK_PROBE: sb.append("LINK_PROBE"); sb.append(" linkProbeWasSuccess=").append(event.linkProbeWasSuccess); if (event.linkProbeWasSuccess) { sb.append(" linkProbeSuccessElapsedTimeMs=") .append(event.linkProbeSuccessElapsedTimeMs); } else { sb.append(" linkProbeFailureReason=").append(event.linkProbeFailureReason); } break; default: sb.append("UNKNOWN " + event.type + ":"); break; } if (event.lastRssi != -127) sb.append(" lastRssi=").append(event.lastRssi); if (event.lastFreq != -1) sb.append(" lastFreq=").append(event.lastFreq); if (event.lastLinkSpeed != -1) sb.append(" lastLinkSpeed=").append(event.lastLinkSpeed); if (event.lastScore != -1) sb.append(" lastScore=").append(event.lastScore); if (event.lastWifiUsabilityScore != -1) { sb.append(" lastWifiUsabilityScore=").append(event.lastWifiUsabilityScore); sb.append(" lastPredictionHorizonSec=").append(event.lastPredictionHorizonSec); } if (event.supplicantStateChangesBitmask != 0) { sb.append(", ").append(supplicantStateChangesBitmaskToString( event.supplicantStateChangesBitmask)); } if (event.configInfo != null) { sb.append(", ").append(configInfoToString(event.configInfo)); } return sb.toString(); } private static String authFailureReasonToString(int authFailureReason) { switch (authFailureReason) { case StaEvent.AUTH_FAILURE_NONE: return "ERROR_AUTH_FAILURE_NONE"; case StaEvent.AUTH_FAILURE_TIMEOUT: return "ERROR_AUTH_FAILURE_TIMEOUT"; case StaEvent.AUTH_FAILURE_WRONG_PSWD: return "ERROR_AUTH_FAILURE_WRONG_PSWD"; case StaEvent.AUTH_FAILURE_EAP_FAILURE: return "ERROR_AUTH_FAILURE_EAP_FAILURE"; default: return ""; } } private static String frameworkDisconnectReasonToString(int frameworkDisconnectReason) { switch (frameworkDisconnectReason) { case StaEvent.DISCONNECT_API: return "DISCONNECT_API"; case StaEvent.DISCONNECT_GENERIC: return "DISCONNECT_GENERIC"; case StaEvent.DISCONNECT_UNWANTED: return "DISCONNECT_UNWANTED"; case StaEvent.DISCONNECT_ROAM_WATCHDOG_TIMER: return "DISCONNECT_ROAM_WATCHDOG_TIMER"; case StaEvent.DISCONNECT_P2P_DISCONNECT_WIFI_REQUEST: return "DISCONNECT_P2P_DISCONNECT_WIFI_REQUEST"; case StaEvent.DISCONNECT_RESET_SIM_NETWORKS: return "DISCONNECT_RESET_SIM_NETWORKS"; default: return "DISCONNECT_UNKNOWN=" + frameworkDisconnectReason; } } private static String configInfoToString(ConfigInfo info) { StringBuilder sb = new StringBuilder(); sb.append("ConfigInfo:") .append(" allowed_key_management=").append(info.allowedKeyManagement) .append(" allowed_protocols=").append(info.allowedProtocols) .append(" allowed_auth_algorithms=").append(info.allowedAuthAlgorithms) .append(" allowed_pairwise_ciphers=").append(info.allowedPairwiseCiphers) .append(" allowed_group_ciphers=").append(info.allowedGroupCiphers) .append(" hidden_ssid=").append(info.hiddenSsid) .append(" is_passpoint=").append(info.isPasspoint) .append(" is_ephemeral=").append(info.isEphemeral) .append(" has_ever_connected=").append(info.hasEverConnected) .append(" scan_rssi=").append(info.scanRssi) .append(" scan_freq=").append(info.scanFreq); return sb.toString(); } /** * Converts the first 31 bits of a BitSet to a little endian int */ private static int bitSetToInt(BitSet bits) { int value = 0; int nBits = bits.length() < 31 ? bits.length() : 31; for (int i = 0; i < nBits; i++) { value += bits.get(i) ? (1 << i) : 0; } return value; } private void incrementSsid(SparseIntArray sia, int element) { increment(sia, Math.min(element, MAX_CONNECTABLE_SSID_NETWORK_BUCKET)); } private void incrementBssid(SparseIntArray sia, int element) { increment(sia, Math.min(element, MAX_CONNECTABLE_BSSID_NETWORK_BUCKET)); } private void incrementTotalScanResults(SparseIntArray sia, int element) { increment(sia, Math.min(element, MAX_TOTAL_SCAN_RESULTS_BUCKET)); } private void incrementTotalScanSsids(SparseIntArray sia, int element) { increment(sia, Math.min(element, MAX_TOTAL_SCAN_RESULT_SSIDS_BUCKET)); } private void incrementTotalPasspointAps(SparseIntArray sia, int element) { increment(sia, Math.min(element, MAX_TOTAL_PASSPOINT_APS_BUCKET)); } private void incrementTotalUniquePasspointEss(SparseIntArray sia, int element) { increment(sia, Math.min(element, MAX_TOTAL_PASSPOINT_UNIQUE_ESS_BUCKET)); } private void incrementPasspointPerUniqueEss(SparseIntArray sia, int element) { increment(sia, Math.min(element, MAX_PASSPOINT_APS_PER_UNIQUE_ESS_BUCKET)); } private void increment80211mcAps(SparseIntArray sia, int element) { increment(sia, Math.min(element, MAX_TOTAL_80211MC_APS_BUCKET)); } private void increment(SparseIntArray sia, int element) { int count = sia.get(element); sia.put(element, count + 1); } private static class StaEventWithTime { public StaEvent staEvent; public long wallClockMillis; StaEventWithTime(StaEvent event, long wallClockMillis) { staEvent = event; this.wallClockMillis = wallClockMillis; } public String toString() { StringBuilder sb = new StringBuilder(); Calendar c = Calendar.getInstance(); c.setTimeInMillis(wallClockMillis); if (wallClockMillis != 0) { sb.append(String.format("%tm-%td %tH:%tM:%tS.%tL", c, c, c, c, c, c)); } else { sb.append(" "); } sb.append(" ").append(staEventToString(staEvent)); return sb.toString(); } } private LinkedList mWifiIsUnusableList = new LinkedList(); private long mTxScucessDelta = 0; private long mTxRetriesDelta = 0; private long mTxBadDelta = 0; private long mRxSuccessDelta = 0; private long mLlStatsUpdateTimeDelta = 0; private long mLlStatsLastUpdateTime = 0; private int mLastScoreNoReset = -1; private long mLastDataStallTime = Long.MIN_VALUE; private static class WifiIsUnusableWithTime { public WifiIsUnusableEvent event; public long wallClockMillis; WifiIsUnusableWithTime(WifiIsUnusableEvent event, long wallClockMillis) { this.event = event; this.wallClockMillis = wallClockMillis; } public String toString() { if (event == null) return ""; StringBuilder sb = new StringBuilder(); if (wallClockMillis != 0) { Calendar c = Calendar.getInstance(); c.setTimeInMillis(wallClockMillis); sb.append(String.format("%tm-%td %tH:%tM:%tS.%tL", c, c, c, c, c, c)); } else { sb.append(" "); } sb.append(" "); switch(event.type) { case WifiIsUnusableEvent.TYPE_DATA_STALL_BAD_TX: sb.append("DATA_STALL_BAD_TX"); break; case WifiIsUnusableEvent.TYPE_DATA_STALL_TX_WITHOUT_RX: sb.append("DATA_STALL_TX_WITHOUT_RX"); break; case WifiIsUnusableEvent.TYPE_DATA_STALL_BOTH: sb.append("DATA_STALL_BOTH"); break; case WifiIsUnusableEvent.TYPE_FIRMWARE_ALERT: sb.append("FIRMWARE_ALERT"); break; default: sb.append("UNKNOWN " + event.type); break; } sb.append(" lastScore=").append(event.lastScore); sb.append(" txSuccessDelta=").append(event.txSuccessDelta); sb.append(" txRetriesDelta=").append(event.txRetriesDelta); sb.append(" txBadDelta=").append(event.txBadDelta); sb.append(" rxSuccessDelta=").append(event.rxSuccessDelta); sb.append(" packetUpdateTimeDelta=").append(event.packetUpdateTimeDelta) .append("ms"); if (event.firmwareAlertCode != -1) { sb.append(" firmwareAlertCode=").append(event.firmwareAlertCode); } sb.append(" lastWifiUsabilityScore=").append(event.lastWifiUsabilityScore); sb.append(" lastPredictionHorizonSec=").append(event.lastPredictionHorizonSec); return sb.toString(); } } /** * Update the difference between the last two WifiLinkLayerStats for WifiIsUnusableEvent */ public void updateWifiIsUnusableLinkLayerStats(long txSuccessDelta, long txRetriesDelta, long txBadDelta, long rxSuccessDelta, long updateTimeDelta) { mTxScucessDelta = txSuccessDelta; mTxRetriesDelta = txRetriesDelta; mTxBadDelta = txBadDelta; mRxSuccessDelta = rxSuccessDelta; mLlStatsUpdateTimeDelta = updateTimeDelta; mLlStatsLastUpdateTime = mClock.getElapsedSinceBootMillis(); } /** * Clear the saved difference between the last two WifiLinkLayerStats */ public void resetWifiIsUnusableLinkLayerStats() { mTxScucessDelta = 0; mTxRetriesDelta = 0; mTxBadDelta = 0; mRxSuccessDelta = 0; mLlStatsUpdateTimeDelta = 0; mLlStatsLastUpdateTime = 0; mLastDataStallTime = Long.MIN_VALUE; } /** * Log a WifiIsUnusableEvent * @param triggerType WifiIsUnusableEvent.type describing the event */ public void logWifiIsUnusableEvent(int triggerType) { logWifiIsUnusableEvent(triggerType, -1); } /** * Log a WifiIsUnusableEvent * @param triggerType WifiIsUnusableEvent.type describing the event * @param firmwareAlertCode WifiIsUnusableEvent.firmwareAlertCode for firmware alert code */ public void logWifiIsUnusableEvent(int triggerType, int firmwareAlertCode) { mScoreBreachLowTimeMillis = -1; if (!mUnusableEventLogging) { return; } long currentBootTime = mClock.getElapsedSinceBootMillis(); switch (triggerType) { case WifiIsUnusableEvent.TYPE_DATA_STALL_BAD_TX: case WifiIsUnusableEvent.TYPE_DATA_STALL_TX_WITHOUT_RX: case WifiIsUnusableEvent.TYPE_DATA_STALL_BOTH: // Have a time-based throttle for generating WifiIsUnusableEvent from data stalls if (currentBootTime < mLastDataStallTime + MIN_DATA_STALL_WAIT_MS) { return; } mLastDataStallTime = currentBootTime; break; case WifiIsUnusableEvent.TYPE_FIRMWARE_ALERT: break; case WifiIsUnusableEvent.TYPE_IP_REACHABILITY_LOST: break; default: Log.e(TAG, "Unknown WifiIsUnusableEvent: " + triggerType); return; } WifiIsUnusableEvent event = new WifiIsUnusableEvent(); event.type = triggerType; if (triggerType == WifiIsUnusableEvent.TYPE_FIRMWARE_ALERT) { event.firmwareAlertCode = firmwareAlertCode; } event.startTimeMillis = currentBootTime; event.lastScore = mLastScoreNoReset; event.lastWifiUsabilityScore = mLastWifiUsabilityScoreNoReset; event.lastPredictionHorizonSec = mLastPredictionHorizonSecNoReset; event.txSuccessDelta = mTxScucessDelta; event.txRetriesDelta = mTxRetriesDelta; event.txBadDelta = mTxBadDelta; event.rxSuccessDelta = mRxSuccessDelta; event.packetUpdateTimeDelta = mLlStatsUpdateTimeDelta; event.lastLinkLayerStatsUpdateTime = mLlStatsLastUpdateTime; event.screenOn = mScreenOn; mWifiIsUnusableList.add(new WifiIsUnusableWithTime(event, mClock.getWallClockMillis())); if (mWifiIsUnusableList.size() > MAX_UNUSABLE_EVENTS) { mWifiIsUnusableList.removeFirst(); } } /** * Sets whether or not WifiIsUnusableEvent is logged in metrics */ @VisibleForTesting public void setWifiIsUnusableLoggingEnabled(boolean enabled) { synchronized (mLock) { mExperimentValues.wifiIsUnusableLoggingEnabled = enabled; } } /** * Sets whether or not LinkSpeedCounts is logged in metrics */ @VisibleForTesting public void setLinkSpeedCountsLoggingEnabled(boolean enabled) { synchronized (mLock) { mExperimentValues.linkSpeedCountsLoggingEnabled = enabled; } } /** * Sets the minimum number of txBad to trigger a data stall */ public void setWifiDataStallMinTxBad(int minTxBad) { synchronized (mLock) { mExperimentValues.wifiDataStallMinTxBad = minTxBad; } } /** * Sets the minimum number of txSuccess to trigger a data stall * when rxSuccess is 0 */ public void setWifiDataStallMinRxWithoutTx(int minTxSuccessWithoutRx) { synchronized (mLock) { mExperimentValues.wifiDataStallMinTxSuccessWithoutRx = minTxSuccessWithoutRx; } } /** * Extract data from |info| and |stats| to build a WifiUsabilityStatsEntry and then adds it * into an internal ring buffer. * @param info * @param stats */ public void updateWifiUsabilityStatsEntries(WifiInfo info, WifiLinkLayerStats stats) { synchronized (mLock) { if (info == null || stats == null) { return; } WifiUsabilityStatsEntry wifiUsabilityStatsEntry = mWifiUsabilityStatsEntriesList.size() < MAX_WIFI_USABILITY_STATS_ENTRIES_LIST_SIZE ? new WifiUsabilityStatsEntry() : mWifiUsabilityStatsEntriesList.remove(); wifiUsabilityStatsEntry.timeStampMs = stats.timeStampInMs; wifiUsabilityStatsEntry.totalTxSuccess = stats.txmpdu_be + stats.txmpdu_bk + stats.txmpdu_vi + stats.txmpdu_vo; wifiUsabilityStatsEntry.totalTxRetries = stats.retries_be + stats.retries_bk + stats.retries_vi + stats.retries_vo; wifiUsabilityStatsEntry.totalTxBad = stats.lostmpdu_be + stats.lostmpdu_bk + stats.lostmpdu_vi + stats.lostmpdu_vo; wifiUsabilityStatsEntry.totalRxSuccess = stats.rxmpdu_be + stats.rxmpdu_bk + stats.rxmpdu_vi + stats.rxmpdu_vo; wifiUsabilityStatsEntry.totalRadioOnTimeMs = stats.on_time; wifiUsabilityStatsEntry.totalRadioTxTimeMs = stats.tx_time; wifiUsabilityStatsEntry.totalRadioRxTimeMs = stats.rx_time; wifiUsabilityStatsEntry.totalScanTimeMs = stats.on_time_scan; wifiUsabilityStatsEntry.totalNanScanTimeMs = stats.on_time_nan_scan; wifiUsabilityStatsEntry.totalBackgroundScanTimeMs = stats.on_time_background_scan; wifiUsabilityStatsEntry.totalRoamScanTimeMs = stats.on_time_roam_scan; wifiUsabilityStatsEntry.totalPnoScanTimeMs = stats.on_time_pno_scan; wifiUsabilityStatsEntry.totalHotspot2ScanTimeMs = stats.on_time_hs20_scan; wifiUsabilityStatsEntry.rssi = info.getRssi(); wifiUsabilityStatsEntry.linkSpeedMbps = info.getLinkSpeed(); WifiLinkLayerStats.ChannelStats statsMap = stats.channelStatsMap.get(info.getFrequency()); if (statsMap != null) { wifiUsabilityStatsEntry.totalRadioOnFreqTimeMs = statsMap.radioOnTimeMs; wifiUsabilityStatsEntry.totalCcaBusyFreqTimeMs = statsMap.ccaBusyTimeMs; } wifiUsabilityStatsEntry.totalBeaconRx = stats.beacon_rx; boolean isSameBssidAndFreq = mLastBssid == null || mLastFrequency == -1 || (mLastBssid.equals(info.getBSSID()) && mLastFrequency == info.getFrequency()); mLastBssid = info.getBSSID(); mLastFrequency = info.getFrequency(); wifiUsabilityStatsEntry.wifiScore = mLastScoreNoReset; wifiUsabilityStatsEntry.wifiUsabilityScore = mLastWifiUsabilityScoreNoReset; wifiUsabilityStatsEntry.seqNumToFramework = mSeqNumToFramework; wifiUsabilityStatsEntry.predictionHorizonSec = mLastPredictionHorizonSecNoReset; switch (mProbeStatusSinceLastUpdate) { case android.net.wifi.WifiUsabilityStatsEntry.PROBE_STATUS_NO_PROBE: wifiUsabilityStatsEntry.probeStatusSinceLastUpdate = WifiUsabilityStatsEntry.PROBE_STATUS_NO_PROBE; break; case android.net.wifi.WifiUsabilityStatsEntry.PROBE_STATUS_SUCCESS: wifiUsabilityStatsEntry.probeStatusSinceLastUpdate = WifiUsabilityStatsEntry.PROBE_STATUS_SUCCESS; break; case android.net.wifi.WifiUsabilityStatsEntry.PROBE_STATUS_FAILURE: wifiUsabilityStatsEntry.probeStatusSinceLastUpdate = WifiUsabilityStatsEntry.PROBE_STATUS_FAILURE; break; default: wifiUsabilityStatsEntry.probeStatusSinceLastUpdate = WifiUsabilityStatsEntry.PROBE_STATUS_UNKNOWN; Log.e(TAG, "Unknown link probe status: " + mProbeStatusSinceLastUpdate); } wifiUsabilityStatsEntry.probeElapsedTimeSinceLastUpdateMs = mProbeElapsedTimeSinceLastUpdateMs; wifiUsabilityStatsEntry.probeMcsRateSinceLastUpdate = mProbeMcsRateSinceLastUpdate; wifiUsabilityStatsEntry.rxLinkSpeedMbps = info.getRxLinkSpeedMbps(); wifiUsabilityStatsEntry.isSameBssidAndFreq = isSameBssidAndFreq; wifiUsabilityStatsEntry.seqNumInsideFramework = mSeqNumInsideFramework; wifiUsabilityStatsEntry.deviceMobilityState = mCurrentDeviceMobilityState; CellularLinkLayerStats cls = mCellularLinkLayerStatsCollector.update(); if (DBG) Log.v(TAG, "Latest Cellular Link Layer Stats: " + cls); wifiUsabilityStatsEntry.cellularDataNetworkType = parseDataNetworkTypeToProto(cls.getDataNetworkType()); wifiUsabilityStatsEntry.cellularSignalStrengthDbm = cls.getSignalStrengthDbm(); wifiUsabilityStatsEntry.cellularSignalStrengthDb = cls.getSignalStrengthDb(); wifiUsabilityStatsEntry.isSameRegisteredCell = cls.getIsSameRegisteredCell(); mWifiUsabilityStatsEntriesList.add(wifiUsabilityStatsEntry); mWifiUsabilityStatsCounter++; if (mWifiUsabilityStatsCounter >= NUM_WIFI_USABILITY_STATS_ENTRIES_PER_WIFI_GOOD) { addToWifiUsabilityStatsList(WifiUsabilityStats.LABEL_GOOD, WifiUsabilityStats.TYPE_UNKNOWN, -1); } if (mScoreBreachLowTimeMillis != -1) { long elapsedTime = mClock.getElapsedSinceBootMillis() - mScoreBreachLowTimeMillis; if (elapsedTime >= MIN_SCORE_BREACH_TO_GOOD_STATS_WAIT_TIME_MS) { mScoreBreachLowTimeMillis = -1; if (elapsedTime <= VALIDITY_PERIOD_OF_SCORE_BREACH_LOW_MS) { addToWifiUsabilityStatsList(WifiUsabilityStats.LABEL_GOOD, WifiUsabilityStats.TYPE_UNKNOWN, -1); } } } // Invoke Wifi usability stats listener. sendWifiUsabilityStats(mSeqNumInsideFramework, isSameBssidAndFreq, createNewWifiUsabilityStatsEntryParcelable(wifiUsabilityStatsEntry)); mSeqNumInsideFramework++; mProbeStatusSinceLastUpdate = android.net.wifi.WifiUsabilityStatsEntry.PROBE_STATUS_NO_PROBE; mProbeElapsedTimeSinceLastUpdateMs = -1; mProbeMcsRateSinceLastUpdate = -1; } } private int parseDataNetworkTypeToProto(int cellularDataNetworkType) { switch (cellularDataNetworkType) { case TelephonyManager.NETWORK_TYPE_UNKNOWN: return WifiUsabilityStatsEntry.NETWORK_TYPE_UNKNOWN; case TelephonyManager.NETWORK_TYPE_GSM: return WifiUsabilityStatsEntry.NETWORK_TYPE_GSM; case TelephonyManager.NETWORK_TYPE_CDMA: return WifiUsabilityStatsEntry.NETWORK_TYPE_CDMA; case TelephonyManager.NETWORK_TYPE_EVDO_0: return WifiUsabilityStatsEntry.NETWORK_TYPE_EVDO_0; case TelephonyManager.NETWORK_TYPE_UMTS: return WifiUsabilityStatsEntry.NETWORK_TYPE_UMTS; case TelephonyManager.NETWORK_TYPE_TD_SCDMA: return WifiUsabilityStatsEntry.NETWORK_TYPE_TD_SCDMA; case TelephonyManager.NETWORK_TYPE_LTE: return WifiUsabilityStatsEntry.NETWORK_TYPE_LTE; case TelephonyManager.NETWORK_TYPE_NR: return WifiUsabilityStatsEntry.NETWORK_TYPE_NR; default: Log.e(TAG, "Unknown data network type : " + cellularDataNetworkType); return WifiUsabilityStatsEntry.NETWORK_TYPE_UNKNOWN; } } private int parseDataNetworkTypeFromProto(int cellularDataNetworkType) { switch (cellularDataNetworkType) { case WifiUsabilityStatsEntry.NETWORK_TYPE_UNKNOWN: return TelephonyManager.NETWORK_TYPE_UNKNOWN; case WifiUsabilityStatsEntry.NETWORK_TYPE_GSM: return TelephonyManager.NETWORK_TYPE_GSM; case WifiUsabilityStatsEntry.NETWORK_TYPE_CDMA: return TelephonyManager.NETWORK_TYPE_CDMA; case WifiUsabilityStatsEntry.NETWORK_TYPE_EVDO_0: return TelephonyManager.NETWORK_TYPE_EVDO_0; case WifiUsabilityStatsEntry.NETWORK_TYPE_UMTS: return TelephonyManager.NETWORK_TYPE_UMTS; case WifiUsabilityStatsEntry.NETWORK_TYPE_TD_SCDMA: return TelephonyManager.NETWORK_TYPE_TD_SCDMA; case WifiUsabilityStatsEntry.NETWORK_TYPE_LTE: return TelephonyManager.NETWORK_TYPE_LTE; case WifiUsabilityStatsEntry.NETWORK_TYPE_NR: return TelephonyManager.NETWORK_TYPE_NR; default: Log.e(TAG, "Unknown data network type : " + cellularDataNetworkType); return TelephonyManager.NETWORK_TYPE_UNKNOWN; } } /** * Send Wifi usability stats. * @param seqNum * @param isSameBssidAndFreq * @param statsEntry */ private void sendWifiUsabilityStats(int seqNum, boolean isSameBssidAndFreq, android.net.wifi.WifiUsabilityStatsEntry statsEntry) { for (IOnWifiUsabilityStatsListener listener : mOnWifiUsabilityListeners.getCallbacks()) { try { listener.onWifiUsabilityStats(seqNum, isSameBssidAndFreq, statsEntry); } catch (RemoteException e) { Log.e(TAG, "Unable to invoke Wifi usability stats entry listener " + listener, e); } } } private android.net.wifi.WifiUsabilityStatsEntry createNewWifiUsabilityStatsEntryParcelable( WifiUsabilityStatsEntry s) { int probeStatus; switch (s.probeStatusSinceLastUpdate) { case WifiUsabilityStatsEntry.PROBE_STATUS_NO_PROBE: probeStatus = android.net.wifi.WifiUsabilityStatsEntry.PROBE_STATUS_NO_PROBE; break; case WifiUsabilityStatsEntry.PROBE_STATUS_SUCCESS: probeStatus = android.net.wifi.WifiUsabilityStatsEntry.PROBE_STATUS_SUCCESS; break; case WifiUsabilityStatsEntry.PROBE_STATUS_FAILURE: probeStatus = android.net.wifi.WifiUsabilityStatsEntry.PROBE_STATUS_FAILURE; break; default: probeStatus = android.net.wifi.WifiUsabilityStatsEntry.PROBE_STATUS_UNKNOWN; Log.e(TAG, "Unknown link probe status: " + s.probeStatusSinceLastUpdate); } int cellularDataNetworkType = parseDataNetworkTypeFromProto(s.cellularDataNetworkType); return new android.net.wifi.WifiUsabilityStatsEntry(s.timeStampMs, s.rssi, s.linkSpeedMbps, s.totalTxSuccess, s.totalTxRetries, s.totalTxBad, s.totalRxSuccess, s.totalRadioOnTimeMs, s.totalRadioTxTimeMs, s.totalRadioRxTimeMs, s.totalScanTimeMs, s.totalNanScanTimeMs, s.totalBackgroundScanTimeMs, s.totalRoamScanTimeMs, s.totalPnoScanTimeMs, s.totalHotspot2ScanTimeMs, s.totalCcaBusyFreqTimeMs, s.totalRadioOnFreqTimeMs, s.totalBeaconRx, probeStatus, s.probeElapsedTimeSinceLastUpdateMs, s.probeMcsRateSinceLastUpdate, s.rxLinkSpeedMbps, cellularDataNetworkType, s.cellularSignalStrengthDbm, s.cellularSignalStrengthDb, s.isSameRegisteredCell ); } private WifiUsabilityStatsEntry createNewWifiUsabilityStatsEntry(WifiUsabilityStatsEntry s) { WifiUsabilityStatsEntry out = new WifiUsabilityStatsEntry(); out.timeStampMs = s.timeStampMs; out.totalTxSuccess = s.totalTxSuccess; out.totalTxRetries = s.totalTxRetries; out.totalTxBad = s.totalTxBad; out.totalRxSuccess = s.totalRxSuccess; out.totalRadioOnTimeMs = s.totalRadioOnTimeMs; out.totalRadioTxTimeMs = s.totalRadioTxTimeMs; out.totalRadioRxTimeMs = s.totalRadioRxTimeMs; out.totalScanTimeMs = s.totalScanTimeMs; out.totalNanScanTimeMs = s.totalNanScanTimeMs; out.totalBackgroundScanTimeMs = s.totalBackgroundScanTimeMs; out.totalRoamScanTimeMs = s.totalRoamScanTimeMs; out.totalPnoScanTimeMs = s.totalPnoScanTimeMs; out.totalHotspot2ScanTimeMs = s.totalHotspot2ScanTimeMs; out.rssi = s.rssi; out.linkSpeedMbps = s.linkSpeedMbps; out.totalCcaBusyFreqTimeMs = s.totalCcaBusyFreqTimeMs; out.totalRadioOnFreqTimeMs = s.totalRadioOnFreqTimeMs; out.totalBeaconRx = s.totalBeaconRx; out.wifiScore = s.wifiScore; out.wifiUsabilityScore = s.wifiUsabilityScore; out.seqNumToFramework = s.seqNumToFramework; out.predictionHorizonSec = s.predictionHorizonSec; out.probeStatusSinceLastUpdate = s.probeStatusSinceLastUpdate; out.probeElapsedTimeSinceLastUpdateMs = s.probeElapsedTimeSinceLastUpdateMs; out.probeMcsRateSinceLastUpdate = s.probeMcsRateSinceLastUpdate; out.rxLinkSpeedMbps = s.rxLinkSpeedMbps; out.isSameBssidAndFreq = s.isSameBssidAndFreq; out.seqNumInsideFramework = s.seqNumInsideFramework; out.cellularDataNetworkType = s.cellularDataNetworkType; out.cellularSignalStrengthDbm = s.cellularSignalStrengthDbm; out.cellularSignalStrengthDb = s.cellularSignalStrengthDb; out.isSameRegisteredCell = s.isSameRegisteredCell; out.deviceMobilityState = s.deviceMobilityState; return out; } private WifiUsabilityStats createWifiUsabilityStatsWithLabel(int label, int triggerType, int firmwareAlertCode) { WifiUsabilityStats wifiUsabilityStats = new WifiUsabilityStats(); wifiUsabilityStats.label = label; wifiUsabilityStats.triggerType = triggerType; wifiUsabilityStats.firmwareAlertCode = firmwareAlertCode; wifiUsabilityStats.timeStampMs = mClock.getElapsedSinceBootMillis(); wifiUsabilityStats.stats = new WifiUsabilityStatsEntry[mWifiUsabilityStatsEntriesList.size()]; for (int i = 0; i < mWifiUsabilityStatsEntriesList.size(); i++) { wifiUsabilityStats.stats[i] = createNewWifiUsabilityStatsEntry(mWifiUsabilityStatsEntriesList.get(i)); } return wifiUsabilityStats; } /** * Label the current snapshot of WifiUsabilityStatsEntrys and save the labeled data in memory. * @param label WifiUsabilityStats.LABEL_GOOD or WifiUsabilityStats.LABEL_BAD * @param triggerType what event triggers WifiUsabilityStats * @param firmwareAlertCode the firmware alert code when the stats was triggered by a * firmware alert */ public void addToWifiUsabilityStatsList(int label, int triggerType, int firmwareAlertCode) { synchronized (mLock) { if (mWifiUsabilityStatsEntriesList.isEmpty() || !mScreenOn) { return; } if (label == WifiUsabilityStats.LABEL_GOOD) { // Only add a good event if at least |MIN_WIFI_GOOD_USABILITY_STATS_PERIOD_MS| // has passed. if (mWifiUsabilityStatsListGood.isEmpty() || mWifiUsabilityStatsListGood.getLast().stats[mWifiUsabilityStatsListGood .getLast().stats.length - 1].timeStampMs + MIN_WIFI_GOOD_USABILITY_STATS_PERIOD_MS < mWifiUsabilityStatsEntriesList.getLast().timeStampMs) { while (mWifiUsabilityStatsListGood.size() >= MAX_WIFI_USABILITY_STATS_LIST_SIZE_PER_TYPE) { mWifiUsabilityStatsListGood.remove( mRand.nextInt(mWifiUsabilityStatsListGood.size())); } mWifiUsabilityStatsListGood.add( createWifiUsabilityStatsWithLabel(label, triggerType, firmwareAlertCode)); } } else { // Only add a bad event if at least |MIN_DATA_STALL_WAIT_MS| // has passed. mScoreBreachLowTimeMillis = -1; if (mWifiUsabilityStatsListBad.isEmpty() || (mWifiUsabilityStatsListBad.getLast().stats[mWifiUsabilityStatsListBad .getLast().stats.length - 1].timeStampMs + MIN_DATA_STALL_WAIT_MS < mWifiUsabilityStatsEntriesList.getLast().timeStampMs)) { while (mWifiUsabilityStatsListBad.size() >= MAX_WIFI_USABILITY_STATS_LIST_SIZE_PER_TYPE) { mWifiUsabilityStatsListBad.remove( mRand.nextInt(mWifiUsabilityStatsListBad.size())); } mWifiUsabilityStatsListBad.add( createWifiUsabilityStatsWithLabel(label, triggerType, firmwareAlertCode)); } } mWifiUsabilityStatsCounter = 0; } } private DeviceMobilityStatePnoScanStats getOrCreateDeviceMobilityStatePnoScanStats( @DeviceMobilityState int deviceMobilityState) { DeviceMobilityStatePnoScanStats stats = mMobilityStatePnoStatsMap.get(deviceMobilityState); if (stats == null) { stats = new DeviceMobilityStatePnoScanStats(); stats.deviceMobilityState = deviceMobilityState; stats.numTimesEnteredState = 0; stats.totalDurationMs = 0; stats.pnoDurationMs = 0; mMobilityStatePnoStatsMap.put(deviceMobilityState, stats); } return stats; } /** * Updates the current device mobility state's total duration. This method should be called * before entering a new device mobility state. */ private void updateCurrentMobilityStateTotalDuration(long now) { DeviceMobilityStatePnoScanStats stats = getOrCreateDeviceMobilityStatePnoScanStats(mCurrentDeviceMobilityState); stats.totalDurationMs += now - mCurrentDeviceMobilityStateStartMs; mCurrentDeviceMobilityStateStartMs = now; } /** * Convert the IntCounter of passpoint profile types and counts to proto's * repeated IntKeyVal array. * * @param passpointProfileTypes passpoint profile types and counts. */ private PasspointProfileTypeCount[] convertPasspointProfilesToProto( IntCounter passpointProfileTypes) { return passpointProfileTypes.toProto(PasspointProfileTypeCount.class, (key, count) -> { PasspointProfileTypeCount entry = new PasspointProfileTypeCount(); entry.eapMethodType = key; entry.count = count; return entry; }); } /** * Reports that the device entered a new mobility state. * * @param newState the new device mobility state. */ public void enterDeviceMobilityState(@DeviceMobilityState int newState) { synchronized (mLock) { long now = mClock.getElapsedSinceBootMillis(); updateCurrentMobilityStateTotalDuration(now); if (newState == mCurrentDeviceMobilityState) return; mCurrentDeviceMobilityState = newState; DeviceMobilityStatePnoScanStats stats = getOrCreateDeviceMobilityStatePnoScanStats(mCurrentDeviceMobilityState); stats.numTimesEnteredState++; } } /** * Logs the start of a PNO scan. */ public void logPnoScanStart() { synchronized (mLock) { long now = mClock.getElapsedSinceBootMillis(); mCurrentDeviceMobilityStatePnoScanStartMs = now; updateCurrentMobilityStateTotalDuration(now); } } /** * Logs the end of a PNO scan. This is attributed to the current device mobility state, as * logged by {@link #enterDeviceMobilityState(int)}. Thus, if the mobility state changes during * a PNO scan, one should call {@link #logPnoScanStop()}, {@link #enterDeviceMobilityState(int)} * , then {@link #logPnoScanStart()} so that the portion of PNO scan before the mobility state * change can be correctly attributed to the previous mobility state. */ public void logPnoScanStop() { synchronized (mLock) { if (mCurrentDeviceMobilityStatePnoScanStartMs < 0) { Log.e(TAG, "Called WifiMetrics#logPNoScanStop() without calling " + "WifiMetrics#logPnoScanStart() first!"); return; } DeviceMobilityStatePnoScanStats stats = getOrCreateDeviceMobilityStatePnoScanStats(mCurrentDeviceMobilityState); long now = mClock.getElapsedSinceBootMillis(); stats.pnoDurationMs += now - mCurrentDeviceMobilityStatePnoScanStartMs; mCurrentDeviceMobilityStatePnoScanStartMs = -1; updateCurrentMobilityStateTotalDuration(now); } } /** * Add a new listener for Wi-Fi usability stats handling. */ public void addOnWifiUsabilityListener(IBinder binder, IOnWifiUsabilityStatsListener listener, int listenerIdentifier) { if (!mOnWifiUsabilityListeners.add(binder, listener, listenerIdentifier)) { Log.e(TAG, "Failed to add listener"); return; } if (DBG) { Log.v(TAG, "Adding listener. Num listeners: " + mOnWifiUsabilityListeners.getNumCallbacks()); } } /** * Remove an existing listener for Wi-Fi usability stats handling. */ public void removeOnWifiUsabilityListener(int listenerIdentifier) { mOnWifiUsabilityListeners.remove(listenerIdentifier); if (DBG) { Log.v(TAG, "Removing listener. Num listeners: " + mOnWifiUsabilityListeners.getNumCallbacks()); } } /** * Updates the Wi-Fi usability score and increments occurence of a particular Wifi usability * score passed in from outside framework. Scores are bounded within * [MIN_WIFI_USABILITY_SCORE, MAX_WIFI_USABILITY_SCORE]. * * Also records events when the Wifi usability score breaches significant thresholds. * * @param seqNum Sequence number of the Wi-Fi usability score. * @param score The Wi-Fi usability score. * @param predictionHorizonSec Prediction horizon of the Wi-Fi usability score. */ public void incrementWifiUsabilityScoreCount(int seqNum, int score, int predictionHorizonSec) { if (score < MIN_WIFI_USABILITY_SCORE || score > MAX_WIFI_USABILITY_SCORE) { return; } synchronized (mLock) { mSeqNumToFramework = seqNum; mLastWifiUsabilityScore = score; mLastWifiUsabilityScoreNoReset = score; mWifiUsabilityScoreCounts.put(score, mWifiUsabilityScoreCounts.get(score) + 1); mLastPredictionHorizonSec = predictionHorizonSec; mLastPredictionHorizonSecNoReset = predictionHorizonSec; boolean wifiWins = mWifiWinsUsabilityScore; if (score > LOW_WIFI_USABILITY_SCORE) { wifiWins = true; } else if (score < LOW_WIFI_USABILITY_SCORE) { wifiWins = false; } if (wifiWins != mWifiWinsUsabilityScore) { mWifiWinsUsabilityScore = wifiWins; StaEvent event = new StaEvent(); event.type = StaEvent.TYPE_WIFI_USABILITY_SCORE_BREACH; addStaEvent(event); // Only record the first score breach by checking whether mScoreBreachLowTimeMillis // has been set to -1 if (!wifiWins && mScoreBreachLowTimeMillis == -1) { mScoreBreachLowTimeMillis = mClock.getElapsedSinceBootMillis(); } } } } /** * Reports stats for a successful link probe. * * @param timeSinceLastTxSuccessMs At {@code startTimestampMs}, the number of milliseconds since * the last Tx success (according to * {@link WifiInfo#txSuccess}). * @param rssi The Rx RSSI at {@code startTimestampMs}. * @param linkSpeed The Tx link speed in Mbps at {@code startTimestampMs}. * @param elapsedTimeMs The number of milliseconds between when the command to transmit the * probe was sent to the driver and when the driver responded that the * probe was ACKed. Note: this number should be correlated with the number * of retries that the driver attempted before the probe was ACKed. */ public void logLinkProbeSuccess(long timeSinceLastTxSuccessMs, int rssi, int linkSpeed, int elapsedTimeMs) { synchronized (mLock) { mProbeStatusSinceLastUpdate = android.net.wifi.WifiUsabilityStatsEntry.PROBE_STATUS_SUCCESS; mProbeElapsedTimeSinceLastUpdateMs = elapsedTimeMs; mLinkProbeSuccessSecondsSinceLastTxSuccessHistogram.increment( (int) (timeSinceLastTxSuccessMs / 1000)); mLinkProbeSuccessRssiCounts.increment(rssi); mLinkProbeSuccessLinkSpeedCounts.increment(linkSpeed); mLinkProbeSuccessElapsedTimeMsHistogram.increment(elapsedTimeMs); if (mLinkProbeStaEventCount < MAX_LINK_PROBE_STA_EVENTS) { StaEvent event = new StaEvent(); event.type = StaEvent.TYPE_LINK_PROBE; event.linkProbeWasSuccess = true; event.linkProbeSuccessElapsedTimeMs = elapsedTimeMs; addStaEvent(event); } mLinkProbeStaEventCount++; } } /** * Reports stats for an unsuccessful link probe. * * @param timeSinceLastTxSuccessMs At {@code startTimestampMs}, the number of milliseconds since * the last Tx success (according to * {@link WifiInfo#txSuccess}). * @param rssi The Rx RSSI at {@code startTimestampMs}. * @param linkSpeed The Tx link speed in Mbps at {@code startTimestampMs}. * @param reason The error code for the failure. See {@link WifiNative.SendMgmtFrameError}. */ public void logLinkProbeFailure(long timeSinceLastTxSuccessMs, int rssi, int linkSpeed, @WifiNative.SendMgmtFrameError int reason) { synchronized (mLock) { mProbeStatusSinceLastUpdate = android.net.wifi.WifiUsabilityStatsEntry.PROBE_STATUS_FAILURE; mProbeElapsedTimeSinceLastUpdateMs = Integer.MAX_VALUE; mLinkProbeFailureSecondsSinceLastTxSuccessHistogram.increment( (int) (timeSinceLastTxSuccessMs / 1000)); mLinkProbeFailureRssiCounts.increment(rssi); mLinkProbeFailureLinkSpeedCounts.increment(linkSpeed); mLinkProbeFailureReasonCounts.increment(reason); if (mLinkProbeStaEventCount < MAX_LINK_PROBE_STA_EVENTS) { StaEvent event = new StaEvent(); event.type = StaEvent.TYPE_LINK_PROBE; event.linkProbeWasSuccess = false; event.linkProbeFailureReason = linkProbeFailureReasonToProto(reason); addStaEvent(event); } mLinkProbeStaEventCount++; } } /** * Increments the number of probes triggered by the experiment `experimentId`. */ public void incrementLinkProbeExperimentProbeCount(String experimentId) { synchronized (mLock) { mLinkProbeExperimentProbeCounts.increment(experimentId); } } /** * Update wifi config store read duration. * * @param timeMs Time it took to complete the operation, in milliseconds */ public void noteWifiConfigStoreReadDuration(int timeMs) { synchronized (mLock) { MetricsUtils.addValueToLinearHistogram(timeMs, mWifiConfigStoreReadDurationHistogram, WIFI_CONFIG_STORE_IO_DURATION_BUCKET_RANGES_MS); } } /** * Update wifi config store write duration. * * @param timeMs Time it took to complete the operation, in milliseconds */ public void noteWifiConfigStoreWriteDuration(int timeMs) { synchronized (mLock) { MetricsUtils.addValueToLinearHistogram(timeMs, mWifiConfigStoreWriteDurationHistogram, WIFI_CONFIG_STORE_IO_DURATION_BUCKET_RANGES_MS); } } /** * Logs the decision of a network selection algorithm when compared against another network * selection algorithm. * * @param experiment1Id ID of one experiment * @param experiment2Id ID of the other experiment * @param isSameDecision did the 2 experiments make the same decision? * @param numNetworkChoices the number of non-null network choices there were, where the null * choice is not selecting any network */ public void logNetworkSelectionDecision(int experiment1Id, int experiment2Id, boolean isSameDecision, int numNetworkChoices) { if (numNetworkChoices < 0) { Log.e(TAG, "numNetworkChoices cannot be negative!"); return; } if (experiment1Id == experiment2Id) { Log.e(TAG, "comparing the same experiment id: " + experiment1Id); return; } Pair key = new Pair<>(experiment1Id, experiment2Id); synchronized (mLock) { NetworkSelectionExperimentResults results = mNetworkSelectionExperimentPairNumChoicesCounts .computeIfAbsent(key, k -> new NetworkSelectionExperimentResults()); IntCounter counter = isSameDecision ? results.sameSelectionNumChoicesCounter : results.differentSelectionNumChoicesCounter; counter.increment(numNetworkChoices); } } /** Increment number of network request API usage stats */ public void incrementNetworkRequestApiNumRequest() { synchronized (mLock) { mWifiNetworkRequestApiLog.numRequest++; } } /** Add to the network request API match size histogram */ public void incrementNetworkRequestApiMatchSizeHistogram(int matchSize) { synchronized (mLock) { mWifiNetworkRequestApiMatchSizeHistogram.increment(matchSize); } } /** Increment number of connection success via network request API */ public void incrementNetworkRequestApiNumConnectSuccess() { synchronized (mLock) { mWifiNetworkRequestApiLog.numConnectSuccess++; } } /** Increment number of requests that bypassed user approval via network request API */ public void incrementNetworkRequestApiNumUserApprovalBypass() { synchronized (mLock) { mWifiNetworkRequestApiLog.numUserApprovalBypass++; } } /** Increment number of requests that user rejected via network request API */ public void incrementNetworkRequestApiNumUserReject() { synchronized (mLock) { mWifiNetworkRequestApiLog.numUserReject++; } } /** Increment number of requests from unique apps via network request API */ public void incrementNetworkRequestApiNumApps() { synchronized (mLock) { mWifiNetworkRequestApiLog.numApps++; } } /** Increment number of network suggestion API modification by app stats */ public void incrementNetworkSuggestionApiNumModification() { synchronized (mLock) { mWifiNetworkSuggestionApiLog.numModification++; } } /** Increment number of connection success via network suggestion API */ public void incrementNetworkSuggestionApiNumConnectSuccess() { synchronized (mLock) { mWifiNetworkSuggestionApiLog.numConnectSuccess++; } } /** Increment number of connection failure via network suggestion API */ public void incrementNetworkSuggestionApiNumConnectFailure() { synchronized (mLock) { mWifiNetworkSuggestionApiLog.numConnectFailure++; } } /** Clear and set the latest network suggestion API max list size histogram */ public void noteNetworkSuggestionApiListSizeHistogram(List listSizes) { synchronized (mLock) { mWifiNetworkSuggestionApiListSizeHistogram.clear(); for (Integer listSize : listSizes) { mWifiNetworkSuggestionApiListSizeHistogram.increment(listSize); } } } /** * Sets the nominator for a network (i.e. which entity made the suggestion to connect) * @param networkId the ID of the network, from its {@link WifiConfiguration} * @param nominatorId the entity that made the suggestion to connect to this network, * from {@link WifiMetricsProto.ConnectionEvent.ConnectionNominator} */ public void setNominatorForNetwork(int networkId, int nominatorId) { synchronized (mLock) { if (networkId == WifiConfiguration.INVALID_NETWORK_ID) return; mNetworkIdToNominatorId.put(networkId, nominatorId); } } /** * Sets the numeric CandidateScorer id. */ public void setNetworkSelectorExperimentId(int expId) { synchronized (mLock) { mNetworkSelectorExperimentId = expId; } } /** Add a WifiLock acqusition session */ public void addWifiLockAcqSession(int lockType, long duration) { switch (lockType) { case WifiManager.WIFI_MODE_FULL_HIGH_PERF: mWifiLockHighPerfAcqDurationSecHistogram.increment((int) (duration / 1000)); break; case WifiManager.WIFI_MODE_FULL_LOW_LATENCY: mWifiLockLowLatencyAcqDurationSecHistogram.increment((int) (duration / 1000)); break; default: Log.e(TAG, "addWifiLockAcqSession: Invalid lock type: " + lockType); break; } } /** Add a WifiLock active session */ public void addWifiLockActiveSession(int lockType, long duration) { switch (lockType) { case WifiManager.WIFI_MODE_FULL_HIGH_PERF: mWifiLockStats.highPerfActiveTimeMs += duration; mWifiLockHighPerfActiveSessionDurationSecHistogram.increment( (int) (duration / 1000)); break; case WifiManager.WIFI_MODE_FULL_LOW_LATENCY: mWifiLockStats.lowLatencyActiveTimeMs += duration; mWifiLockLowLatencyActiveSessionDurationSecHistogram.increment( (int) (duration / 1000)); break; default: Log.e(TAG, "addWifiLockActiveSession: Invalid lock type: " + lockType); break; } } /** Increments metrics counting number of addOrUpdateNetwork calls. **/ public void incrementNumAddOrUpdateNetworkCalls() { synchronized (mLock) { mWifiLogProto.numAddOrUpdateNetworkCalls++; } } /** Increments metrics counting number of enableNetwork calls. **/ public void incrementNumEnableNetworkCalls() { synchronized (mLock) { mWifiLogProto.numEnableNetworkCalls++; } } /** Add to WifiToggleStats **/ public void incrementNumWifiToggles(boolean isPrivileged, boolean enable) { synchronized (mLock) { if (isPrivileged && enable) { mWifiToggleStats.numToggleOnPrivileged++; } else if (isPrivileged && !enable) { mWifiToggleStats.numToggleOffPrivileged++; } else if (!isPrivileged && enable) { mWifiToggleStats.numToggleOnNormal++; } else { mWifiToggleStats.numToggleOffNormal++; } } } /** * Increment number of passpoint provision failure * @param failureCode indicates error condition */ public void incrementPasspointProvisionFailure(int failureCode) { int provisionFailureCode; synchronized (mLock) { switch (failureCode) { case ProvisioningCallback.OSU_FAILURE_AP_CONNECTION: provisionFailureCode = PasspointProvisionStats.OSU_FAILURE_AP_CONNECTION; break; case ProvisioningCallback.OSU_FAILURE_SERVER_URL_INVALID: provisionFailureCode = PasspointProvisionStats.OSU_FAILURE_SERVER_URL_INVALID; break; case ProvisioningCallback.OSU_FAILURE_SERVER_CONNECTION: provisionFailureCode = PasspointProvisionStats.OSU_FAILURE_SERVER_CONNECTION; break; case ProvisioningCallback.OSU_FAILURE_SERVER_VALIDATION: provisionFailureCode = PasspointProvisionStats.OSU_FAILURE_SERVER_VALIDATION; break; case ProvisioningCallback.OSU_FAILURE_SERVICE_PROVIDER_VERIFICATION: provisionFailureCode = PasspointProvisionStats .OSU_FAILURE_SERVICE_PROVIDER_VERIFICATION; break; case ProvisioningCallback.OSU_FAILURE_PROVISIONING_ABORTED: provisionFailureCode = PasspointProvisionStats.OSU_FAILURE_PROVISIONING_ABORTED; break; case ProvisioningCallback.OSU_FAILURE_PROVISIONING_NOT_AVAILABLE: provisionFailureCode = PasspointProvisionStats .OSU_FAILURE_PROVISIONING_NOT_AVAILABLE; break; case ProvisioningCallback.OSU_FAILURE_INVALID_URL_FORMAT_FOR_OSU: provisionFailureCode = PasspointProvisionStats .OSU_FAILURE_INVALID_URL_FORMAT_FOR_OSU; break; case ProvisioningCallback.OSU_FAILURE_UNEXPECTED_COMMAND_TYPE: provisionFailureCode = PasspointProvisionStats .OSU_FAILURE_UNEXPECTED_COMMAND_TYPE; break; case ProvisioningCallback.OSU_FAILURE_UNEXPECTED_SOAP_MESSAGE_TYPE: provisionFailureCode = PasspointProvisionStats .OSU_FAILURE_UNEXPECTED_SOAP_MESSAGE_TYPE; break; case ProvisioningCallback.OSU_FAILURE_SOAP_MESSAGE_EXCHANGE: provisionFailureCode = PasspointProvisionStats .OSU_FAILURE_SOAP_MESSAGE_EXCHANGE; break; case ProvisioningCallback.OSU_FAILURE_START_REDIRECT_LISTENER: provisionFailureCode = PasspointProvisionStats .OSU_FAILURE_START_REDIRECT_LISTENER; break; case ProvisioningCallback.OSU_FAILURE_TIMED_OUT_REDIRECT_LISTENER: provisionFailureCode = PasspointProvisionStats .OSU_FAILURE_TIMED_OUT_REDIRECT_LISTENER; break; case ProvisioningCallback.OSU_FAILURE_NO_OSU_ACTIVITY_FOUND: provisionFailureCode = PasspointProvisionStats .OSU_FAILURE_NO_OSU_ACTIVITY_FOUND; break; case ProvisioningCallback.OSU_FAILURE_UNEXPECTED_SOAP_MESSAGE_STATUS: provisionFailureCode = PasspointProvisionStats .OSU_FAILURE_UNEXPECTED_SOAP_MESSAGE_STATUS; break; case ProvisioningCallback.OSU_FAILURE_NO_PPS_MO: provisionFailureCode = PasspointProvisionStats.OSU_FAILURE_NO_PPS_MO; break; case ProvisioningCallback.OSU_FAILURE_NO_AAA_SERVER_TRUST_ROOT_NODE: provisionFailureCode = PasspointProvisionStats .OSU_FAILURE_NO_AAA_SERVER_TRUST_ROOT_NODE; break; case ProvisioningCallback.OSU_FAILURE_NO_REMEDIATION_SERVER_TRUST_ROOT_NODE: provisionFailureCode = PasspointProvisionStats .OSU_FAILURE_NO_REMEDIATION_SERVER_TRUST_ROOT_NODE; break; case ProvisioningCallback.OSU_FAILURE_NO_POLICY_SERVER_TRUST_ROOT_NODE: provisionFailureCode = PasspointProvisionStats .OSU_FAILURE_NO_POLICY_SERVER_TRUST_ROOT_NODE; break; case ProvisioningCallback.OSU_FAILURE_RETRIEVE_TRUST_ROOT_CERTIFICATES: provisionFailureCode = PasspointProvisionStats .OSU_FAILURE_RETRIEVE_TRUST_ROOT_CERTIFICATES; break; case ProvisioningCallback.OSU_FAILURE_NO_AAA_TRUST_ROOT_CERTIFICATE: provisionFailureCode = PasspointProvisionStats .OSU_FAILURE_NO_AAA_TRUST_ROOT_CERTIFICATE; break; case ProvisioningCallback.OSU_FAILURE_ADD_PASSPOINT_CONFIGURATION: provisionFailureCode = PasspointProvisionStats .OSU_FAILURE_ADD_PASSPOINT_CONFIGURATION; break; case ProvisioningCallback.OSU_FAILURE_OSU_PROVIDER_NOT_FOUND: provisionFailureCode = PasspointProvisionStats .OSU_FAILURE_OSU_PROVIDER_NOT_FOUND; break; default: provisionFailureCode = PasspointProvisionStats.OSU_FAILURE_UNKNOWN; } mPasspointProvisionFailureCounts.increment(provisionFailureCode); } } /** * Increment number of passpoint provision success */ public void incrementPasspointProvisionSuccess() { synchronized (mLock) { mNumProvisionSuccess++; } } }