Gitiles
Code Review Sign In
LeafOS / LeafOS-Project / android_packages_modules_Connectivity / 5ea3c4df37b721f46e32593f54ef36be95baa698 / . / service / src / com / android / server / ConnectivityService.java
blob: 0ec0f13154e5e653b7daba90fb1bee75040ed8d1 [file] [log] [blame]
/*
* Copyright (C) 2008 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;
import static android.Manifest.permission.RECEIVE_DATA_ACTIVITY_CHANGE;
import static android.app.ActivityManager.UidFrozenStateChangedCallback.UID_FROZEN_STATE_FROZEN;
import static android.content.pm.PackageManager.FEATURE_BLUETOOTH;
import static android.content.pm.PackageManager.FEATURE_LEANBACK;
import static android.content.pm.PackageManager.FEATURE_WATCH;
import static android.content.pm.PackageManager.FEATURE_WIFI;
import static android.content.pm.PackageManager.FEATURE_WIFI_DIRECT;
import static android.content.pm.PackageManager.PERMISSION_GRANTED;
import static android.net.ConnectivityDiagnosticsManager.ConnectivityReport.KEY_NETWORK_PROBES_ATTEMPTED_BITMASK;
import static android.net.ConnectivityDiagnosticsManager.ConnectivityReport.KEY_NETWORK_PROBES_SUCCEEDED_BITMASK;
import static android.net.ConnectivityDiagnosticsManager.ConnectivityReport.KEY_NETWORK_VALIDATION_RESULT;
import static android.net.ConnectivityDiagnosticsManager.DataStallReport.DETECTION_METHOD_DNS_EVENTS;
import static android.net.ConnectivityDiagnosticsManager.DataStallReport.DETECTION_METHOD_TCP_METRICS;
import static android.net.ConnectivityDiagnosticsManager.DataStallReport.KEY_DNS_CONSECUTIVE_TIMEOUTS;
import static android.net.ConnectivityDiagnosticsManager.DataStallReport.KEY_TCP_METRICS_COLLECTION_PERIOD_MILLIS;
import static android.net.ConnectivityDiagnosticsManager.DataStallReport.KEY_TCP_PACKET_FAIL_RATE;
import static android.net.ConnectivityManager.ACTION_RESTRICT_BACKGROUND_CHANGED;
import static android.net.ConnectivityManager.BLOCKED_METERED_REASON_MASK;
import static android.net.ConnectivityManager.BLOCKED_REASON_LOCKDOWN_VPN;
import static android.net.ConnectivityManager.BLOCKED_REASON_NONE;
import static android.net.ConnectivityManager.CALLBACK_IP_CHANGED;
import static android.net.ConnectivityManager.CONNECTIVITY_ACTION;
import static android.net.ConnectivityManager.FIREWALL_RULE_ALLOW;
import static android.net.ConnectivityManager.FIREWALL_RULE_DEFAULT;
import static android.net.ConnectivityManager.FIREWALL_RULE_DENY;
import static android.net.ConnectivityManager.TYPE_BLUETOOTH;
import static android.net.ConnectivityManager.TYPE_ETHERNET;
import static android.net.ConnectivityManager.TYPE_MOBILE;
import static android.net.ConnectivityManager.TYPE_MOBILE_CBS;
import static android.net.ConnectivityManager.TYPE_MOBILE_DUN;
import static android.net.ConnectivityManager.TYPE_MOBILE_EMERGENCY;
import static android.net.ConnectivityManager.TYPE_MOBILE_FOTA;
import static android.net.ConnectivityManager.TYPE_MOBILE_HIPRI;
import static android.net.ConnectivityManager.TYPE_MOBILE_IA;
import static android.net.ConnectivityManager.TYPE_MOBILE_IMS;
import static android.net.ConnectivityManager.TYPE_MOBILE_MMS;
import static android.net.ConnectivityManager.TYPE_MOBILE_SUPL;
import static android.net.ConnectivityManager.TYPE_NONE;
import static android.net.ConnectivityManager.TYPE_PROXY;
import static android.net.ConnectivityManager.TYPE_VPN;
import static android.net.ConnectivityManager.TYPE_WIFI;
import static android.net.ConnectivityManager.TYPE_WIFI_P2P;
import static android.net.ConnectivityManager.getNetworkTypeName;
import static android.net.ConnectivityManager.isNetworkTypeValid;
import static android.net.ConnectivitySettingsManager.PRIVATE_DNS_MODE_OPPORTUNISTIC;
import static android.net.INetworkMonitor.NETWORK_VALIDATION_PROBE_PRIVDNS;
import static android.net.INetworkMonitor.NETWORK_VALIDATION_RESULT_PARTIAL;
import static android.net.INetworkMonitor.NETWORK_VALIDATION_RESULT_SKIPPED;
import static android.net.INetworkMonitor.NETWORK_VALIDATION_RESULT_VALID;
import static android.net.NetworkCapabilities.NET_CAPABILITY_CAPTIVE_PORTAL;
import static android.net.NetworkCapabilities.NET_CAPABILITY_ENTERPRISE;
import static android.net.NetworkCapabilities.NET_CAPABILITY_FOREGROUND;
import static android.net.NetworkCapabilities.NET_CAPABILITY_INTERNET;
import static android.net.NetworkCapabilities.NET_CAPABILITY_LOCAL_NETWORK;
import static android.net.NetworkCapabilities.NET_CAPABILITY_NOT_CONGESTED;
import static android.net.NetworkCapabilities.NET_CAPABILITY_NOT_METERED;
import static android.net.NetworkCapabilities.NET_CAPABILITY_NOT_RESTRICTED;
import static android.net.NetworkCapabilities.NET_CAPABILITY_NOT_ROAMING;
import static android.net.NetworkCapabilities.NET_CAPABILITY_NOT_SUSPENDED;
import static android.net.NetworkCapabilities.NET_CAPABILITY_NOT_VCN_MANAGED;
import static android.net.NetworkCapabilities.NET_CAPABILITY_NOT_VPN;
import static android.net.NetworkCapabilities.NET_CAPABILITY_OEM_PAID;
import static android.net.NetworkCapabilities.NET_CAPABILITY_OEM_PRIVATE;
import static android.net.NetworkCapabilities.NET_CAPABILITY_PARTIAL_CONNECTIVITY;
import static android.net.NetworkCapabilities.NET_CAPABILITY_TEMPORARILY_NOT_METERED;
import static android.net.NetworkCapabilities.NET_CAPABILITY_VALIDATED;
import static android.net.NetworkCapabilities.NET_ENTERPRISE_ID_1;
import static android.net.NetworkCapabilities.NET_ENTERPRISE_ID_5;
import static android.net.NetworkCapabilities.REDACT_FOR_ACCESS_FINE_LOCATION;
import static android.net.NetworkCapabilities.REDACT_FOR_LOCAL_MAC_ADDRESS;
import static android.net.NetworkCapabilities.REDACT_FOR_NETWORK_SETTINGS;
import static android.net.NetworkCapabilities.TRANSPORT_CELLULAR;
import static android.net.NetworkCapabilities.TRANSPORT_TEST;
import static android.net.NetworkCapabilities.TRANSPORT_VPN;
import static android.net.NetworkCapabilities.TRANSPORT_WIFI;
import static android.net.NetworkRequest.Type.LISTEN_FOR_BEST;
import static android.net.NetworkScore.POLICY_TRANSPORT_PRIMARY;
import static android.net.OemNetworkPreferences.OEM_NETWORK_PREFERENCE_TEST;
import static android.net.OemNetworkPreferences.OEM_NETWORK_PREFERENCE_TEST_ONLY;
import static android.os.Process.INVALID_UID;
import static android.os.Process.VPN_UID;
import static android.system.OsConstants.ETH_P_ALL;
import static android.system.OsConstants.IPPROTO_TCP;
import static android.system.OsConstants.IPPROTO_UDP;
import static com.android.net.module.util.BpfUtils.BPF_CGROUP_INET4_BIND;
import static com.android.net.module.util.BpfUtils.BPF_CGROUP_INET6_BIND;
import static com.android.net.module.util.BpfUtils.BPF_CGROUP_INET_EGRESS;
import static com.android.net.module.util.BpfUtils.BPF_CGROUP_INET_INGRESS;
import static com.android.net.module.util.BpfUtils.BPF_CGROUP_INET_SOCK_CREATE;
import static com.android.net.module.util.NetworkMonitorUtils.isPrivateDnsValidationRequired;
import static com.android.net.module.util.PermissionUtils.checkAnyPermissionOf;
import static com.android.net.module.util.PermissionUtils.enforceAnyPermissionOf;
import static com.android.net.module.util.PermissionUtils.enforceNetworkStackPermission;
import static com.android.net.module.util.PermissionUtils.enforceNetworkStackPermissionOr;
import static com.android.server.ConnectivityStatsLog.CONNECTIVITY_STATE_SAMPLE;
import static java.util.Map.Entry;
import android.Manifest;
import android.annotation.NonNull;
import android.annotation.Nullable;
import android.annotation.SuppressLint;
import android.annotation.TargetApi;
import android.app.ActivityManager;
import android.app.ActivityManager.UidFrozenStateChangedCallback;
import android.app.AppOpsManager;
import android.app.BroadcastOptions;
import android.app.PendingIntent;
import android.app.admin.DevicePolicyManager;
import android.app.compat.CompatChanges;
import android.app.usage.NetworkStatsManager;
import android.content.BroadcastReceiver;
import android.content.ComponentName;
import android.content.ContentResolver;
import android.content.Context;
import android.content.Intent;
import android.content.IntentFilter;
import android.content.pm.PackageManager;
import android.content.res.XmlResourceParser;
import android.database.ContentObserver;
import android.net.BpfNetMapsUtils;
import android.net.CaptivePortal;
import android.net.CaptivePortalData;
import android.net.ConnectionInfo;
import android.net.ConnectivityDiagnosticsManager.ConnectivityReport;
import android.net.ConnectivityDiagnosticsManager.DataStallReport;
import android.net.ConnectivityManager;
import android.net.ConnectivityManager.BlockedReason;
import android.net.ConnectivityManager.NetworkCallback;
import android.net.ConnectivityManager.RestrictBackgroundStatus;
import android.net.ConnectivitySettingsManager;
import android.net.DataStallReportParcelable;
import android.net.DnsResolverServiceManager;
import android.net.DscpPolicy;
import android.net.ICaptivePortal;
import android.net.IConnectivityDiagnosticsCallback;
import android.net.IConnectivityManager;
import android.net.IDnsResolver;
import android.net.INetd;
import android.net.INetworkActivityListener;
import android.net.INetworkAgent;
import android.net.INetworkMonitor;
import android.net.INetworkMonitorCallbacks;
import android.net.INetworkOfferCallback;
import android.net.IOnCompleteListener;
import android.net.IQosCallback;
import android.net.ISocketKeepaliveCallback;
import android.net.InetAddresses;
import android.net.IpMemoryStore;
import android.net.IpPrefix;
import android.net.LinkProperties;
import android.net.LocalNetworkConfig;
import android.net.LocalNetworkInfo;
import android.net.MatchAllNetworkSpecifier;
import android.net.NativeNetworkConfig;
import android.net.NativeNetworkType;
import android.net.NattSocketKeepalive;
import android.net.Network;
import android.net.NetworkAgent;
import android.net.NetworkAgentConfig;
import android.net.NetworkCapabilities;
import android.net.NetworkInfo;
import android.net.NetworkInfo.DetailedState;
import android.net.NetworkMonitorManager;
import android.net.NetworkPolicyManager;
import android.net.NetworkPolicyManager.NetworkPolicyCallback;
import android.net.NetworkProvider;
import android.net.NetworkRequest;
import android.net.NetworkScore;
import android.net.NetworkSpecifier;
import android.net.NetworkStack;
import android.net.NetworkState;
import android.net.NetworkStateSnapshot;
import android.net.NetworkTestResultParcelable;
import android.net.NetworkUtils;
import android.net.NetworkWatchlistManager;
import android.net.OemNetworkPreferences;
import android.net.PrivateDnsConfigParcel;
import android.net.ProfileNetworkPreference;
import android.net.ProxyInfo;
import android.net.QosCallbackException;
import android.net.QosFilter;
import android.net.QosSocketFilter;
import android.net.QosSocketInfo;
import android.net.RouteInfo;
import android.net.SocketKeepalive;
import android.net.TetheringManager;
import android.net.TransportInfo;
import android.net.UidRange;
import android.net.UidRangeParcel;
import android.net.UnderlyingNetworkInfo;
import android.net.Uri;
import android.net.VpnManager;
import android.net.VpnTransportInfo;
import android.net.connectivity.ConnectivityCompatChanges;
import android.net.metrics.IpConnectivityLog;
import android.net.metrics.NetworkEvent;
import android.net.netd.aidl.NativeUidRangeConfig;
import android.net.networkstack.ModuleNetworkStackClient;
import android.net.networkstack.NetworkStackClientBase;
import android.net.networkstack.aidl.NetworkMonitorParameters;
import android.net.resolv.aidl.DnsHealthEventParcel;
import android.net.resolv.aidl.IDnsResolverUnsolicitedEventListener;
import android.net.resolv.aidl.Nat64PrefixEventParcel;
import android.net.resolv.aidl.PrivateDnsValidationEventParcel;
import android.net.shared.PrivateDnsConfig;
import android.net.wifi.WifiInfo;
import android.os.BatteryStatsManager;
import android.os.Binder;
import android.os.Build;
import android.os.Bundle;
import android.os.ConditionVariable;
import android.os.Handler;
import android.os.HandlerThread;
import android.os.IBinder;
import android.os.Looper;
import android.os.Message;
import android.os.Messenger;
import android.os.ParcelFileDescriptor;
import android.os.Parcelable;
import android.os.PersistableBundle;
import android.os.PowerManager;
import android.os.Process;
import android.os.RemoteCallbackList;
import android.os.RemoteException;
import android.os.ServiceSpecificException;
import android.os.SystemClock;
import android.os.SystemProperties;
import android.os.UserHandle;
import android.os.UserManager;
import android.provider.Settings;
import android.stats.connectivity.MeteredState;
import android.stats.connectivity.RequestType;
import android.stats.connectivity.ValidatedState;
import android.sysprop.NetworkProperties;
import android.system.ErrnoException;
import android.telephony.TelephonyManager;
import android.text.TextUtils;
import android.util.ArrayMap;
import android.util.ArraySet;
import android.util.LocalLog;
import android.util.Log;
import android.util.Pair;
import android.util.Range;
import android.util.SparseArray;
import android.util.SparseIntArray;
import android.util.StatsEvent;
import androidx.annotation.RequiresApi;
import com.android.connectivity.resources.R;
import com.android.internal.annotations.GuardedBy;
import com.android.internal.annotations.VisibleForTesting;
import com.android.internal.util.IndentingPrintWriter;
import com.android.internal.util.MessageUtils;
import com.android.metrics.ConnectionDurationForTransports;
import com.android.metrics.ConnectionDurationPerTransports;
import com.android.metrics.ConnectivitySampleMetricsHelper;
import com.android.metrics.ConnectivityStateSample;
import com.android.metrics.NetworkCountForTransports;
import com.android.metrics.NetworkCountPerTransports;
import com.android.metrics.NetworkDescription;
import com.android.metrics.NetworkList;
import com.android.metrics.NetworkRequestCount;
import com.android.metrics.RequestCountForType;
import com.android.modules.utils.BasicShellCommandHandler;
import com.android.modules.utils.build.SdkLevel;
import com.android.net.module.util.BaseNetdUnsolicitedEventListener;
import com.android.net.module.util.BinderUtils;
import com.android.net.module.util.BitUtils;
import com.android.net.module.util.BpfUtils;
import com.android.net.module.util.CollectionUtils;
import com.android.net.module.util.DeviceConfigUtils;
import com.android.net.module.util.InterfaceParams;
import com.android.net.module.util.LinkPropertiesUtils.CompareOrUpdateResult;
import com.android.net.module.util.LinkPropertiesUtils.CompareResult;
import com.android.net.module.util.LocationPermissionChecker;
import com.android.net.module.util.PerUidCounter;
import com.android.net.module.util.PermissionUtils;
import com.android.net.module.util.TcUtils;
import com.android.net.module.util.netlink.InetDiagMessage;
import com.android.networkstack.apishim.BroadcastOptionsShimImpl;
import com.android.networkstack.apishim.ConstantsShim;
import com.android.networkstack.apishim.common.BroadcastOptionsShim;
import com.android.networkstack.apishim.common.UnsupportedApiLevelException;
import com.android.server.connectivity.ApplicationSelfCertifiedNetworkCapabilities;
import com.android.server.connectivity.AutodestructReference;
import com.android.server.connectivity.AutomaticOnOffKeepaliveTracker;
import com.android.server.connectivity.AutomaticOnOffKeepaliveTracker.AutomaticOnOffKeepalive;
import com.android.server.connectivity.CarrierPrivilegeAuthenticator;
import com.android.server.connectivity.ClatCoordinator;
import com.android.server.connectivity.ConnectivityFlags;
import com.android.server.connectivity.ConnectivityResources;
import com.android.server.connectivity.DnsManager;
import com.android.server.connectivity.DnsManager.PrivateDnsValidationUpdate;
import com.android.server.connectivity.DscpPolicyTracker;
import com.android.server.connectivity.FullScore;
import com.android.server.connectivity.HandlerUtils;
import com.android.server.connectivity.InvalidTagException;
import com.android.server.connectivity.KeepaliveResourceUtil;
import com.android.server.connectivity.KeepaliveTracker;
import com.android.server.connectivity.LingerMonitor;
import com.android.server.connectivity.MockableSystemProperties;
import com.android.server.connectivity.MultinetworkPolicyTracker;
import com.android.server.connectivity.NetworkAgentInfo;
import com.android.server.connectivity.NetworkDiagnostics;
import com.android.server.connectivity.NetworkNotificationManager;
import com.android.server.connectivity.NetworkNotificationManager.NotificationType;
import com.android.server.connectivity.NetworkOffer;
import com.android.server.connectivity.NetworkPreferenceList;
import com.android.server.connectivity.NetworkRanker;
import com.android.server.connectivity.PermissionMonitor;
import com.android.server.connectivity.ProfileNetworkPreferenceInfo;
import com.android.server.connectivity.ProxyTracker;
import com.android.server.connectivity.QosCallbackTracker;
import com.android.server.connectivity.RoutingCoordinatorService;
import com.android.server.connectivity.UidRangeUtils;
import com.android.server.connectivity.VpnNetworkPreferenceInfo;
import com.android.server.connectivity.wear.CompanionDeviceManagerProxyService;
import libcore.io.IoUtils;
import org.xmlpull.v1.XmlPullParserException;
import java.io.FileDescriptor;
import java.io.IOException;
import java.io.InterruptedIOException;
import java.io.PrintWriter;
import java.io.Writer;
import java.net.Inet4Address;
import java.net.InetAddress;
import java.net.InetSocketAddress;
import java.net.SocketException;
import java.net.UnknownHostException;
import java.util.ArrayList;
import java.util.Arrays;
import java.util.Collection;
import java.util.Collections;
import java.util.Comparator;
import java.util.ConcurrentModificationException;
import java.util.HashMap;
import java.util.HashSet;
import java.util.List;
import java.util.Map;
import java.util.NoSuchElementException;
import java.util.Objects;
import java.util.Set;
import java.util.SortedSet;
import java.util.StringJoiner;
import java.util.TreeSet;
import java.util.concurrent.TimeUnit;
import java.util.concurrent.atomic.AtomicInteger;
/**
* @hide
*/
public class ConnectivityService extends IConnectivityManager.Stub
implements PendingIntent.OnFinished {
private static final String TAG = ConnectivityService.class.getSimpleName();
private static final String DIAG_ARG = "--diag";
public static final String SHORT_ARG = "--short";
private static final String NETWORK_ARG = "networks";
private static final String REQUEST_ARG = "requests";
private static final String TRAFFICCONTROLLER_ARG = "trafficcontroller";
private static final boolean DBG = true;
private static final boolean DDBG = Log.isLoggable(TAG, Log.DEBUG);
private static final boolean VDBG = Log.isLoggable(TAG, Log.VERBOSE);
private static final boolean LOGD_BLOCKED_NETWORKINFO = true;
/**
* Default URL to use for {@link #getCaptivePortalServerUrl()}. This should not be changed
* by OEMs for configuration purposes, as this value is overridden by
* ConnectivitySettingsManager.CAPTIVE_PORTAL_HTTP_URL.
* R.string.config_networkCaptivePortalServerUrl should be overridden instead for this purpose
* (preferably via runtime resource overlays).
*/
private static final String DEFAULT_CAPTIVE_PORTAL_HTTP_URL =
"http://connectivitycheck.gstatic.com/generate_204";
// TODO: create better separation between radio types and network types
// how long to wait before switching back to a radio's default network
private static final int RESTORE_DEFAULT_NETWORK_DELAY = 1 * 60 * 1000;
// system property that can override the above value
private static final String NETWORK_RESTORE_DELAY_PROP_NAME =
"android.telephony.apn-restore";
// How long to wait before putting up a "This network doesn't have an Internet connection,
// connect anyway?" dialog after the user selects a network that doesn't validate.
private static final int PROMPT_UNVALIDATED_DELAY_MS = 8 * 1000;
// How long to wait before considering that a network is bad in the absence of any form
// of connectivity (valid, partial, captive portal). If none has been detected after this
// delay, the stack considers this network bad, which may affect how it's handled in ranking
// according to config_networkAvoidBadWifi.
// Timeout in case the "actively prefer bad wifi" feature is on
private static final int ACTIVELY_PREFER_BAD_WIFI_INITIAL_TIMEOUT_MS = 20 * 1000;
// Timeout in case the "actively prefer bad wifi" feature is off
private static final int DEFAULT_EVALUATION_TIMEOUT_MS = 8 * 1000;
// Default to 30s linger time-out, and 5s for nascent network. Modifiable only for testing.
private static final String LINGER_DELAY_PROPERTY = "persist.netmon.linger";
private static final int DEFAULT_LINGER_DELAY_MS = 30_000;
private static final int DEFAULT_NASCENT_DELAY_MS = 5_000;
// Delimiter used when creating the broadcast delivery group for sending
// CONNECTIVITY_ACTION broadcast.
private static final char DELIVERY_GROUP_KEY_DELIMITER = ';';
// The maximum value for the blocking validation result, in milliseconds.
public static final int MAX_VALIDATION_IGNORE_AFTER_ROAM_TIME_MS = 10000;
// The maximum number of network request allowed per uid before an exception is thrown.
@VisibleForTesting
static final int MAX_NETWORK_REQUESTS_PER_UID = 100;
// The maximum number of network request allowed for system UIDs before an exception is thrown.
@VisibleForTesting
static final int MAX_NETWORK_REQUESTS_PER_SYSTEM_UID = 250;
@VisibleForTesting
protected int mLingerDelayMs; // Can't be final, or test subclass constructors can't change it.
@VisibleForTesting
protected int mNascentDelayMs;
// True if the cell radio of the device is capable of time-sharing.
@VisibleForTesting
protected boolean mCellularRadioTimesharingCapable = true;
// How long to delay to removal of a pending intent based request.
// See ConnectivitySettingsManager.CONNECTIVITY_RELEASE_PENDING_INTENT_DELAY_MS
private final int mReleasePendingIntentDelayMs;
private final MockableSystemProperties mSystemProperties;
private final PermissionMonitor mPermissionMonitor;
@VisibleForTesting
final RequestInfoPerUidCounter mNetworkRequestCounter;
@VisibleForTesting
final RequestInfoPerUidCounter mSystemNetworkRequestCounter;
private volatile boolean mLockdownEnabled;
/**
* Stale copy of uid blocked reasons provided by NPMS. As long as they are accessed only in
* internal handler thread, they don't need a lock.
*/
private final SparseIntArray mUidBlockedReasons = new SparseIntArray();
private final Context mContext;
private final ConnectivityResources mResources;
private final int mWakeUpMark;
private final int mWakeUpMask;
// The Context is created for UserHandle.ALL.
private final Context mUserAllContext;
private final Dependencies mDeps;
private final ConnectivityFlags mFlags;
// 0 is full bad, 100 is full good
private int mDefaultInetConditionPublished = 0;
@VisibleForTesting
protected IDnsResolver mDnsResolver;
@VisibleForTesting
protected INetd mNetd;
private DscpPolicyTracker mDscpPolicyTracker = null;
private final NetworkStatsManager mStatsManager;
private final NetworkPolicyManager mPolicyManager;
private final BpfNetMaps mBpfNetMaps;
/**
* TestNetworkService (lazily) created upon first usage. Locked to prevent creation of multiple
* instances.
*/
@GuardedBy("mTNSLock")
private TestNetworkService mTNS;
private final CompanionDeviceManagerProxyService mCdmps;
private final RoutingCoordinatorService mRoutingCoordinatorService;
private final Object mTNSLock = new Object();
private String mCurrentTcpBufferSizes;
private static final SparseArray<String> sMagicDecoderRing = MessageUtils.findMessageNames(
new Class[] {
ConnectivityService.class,
NetworkAgent.class,
NetworkAgentInfo.class,
AutomaticOnOffKeepaliveTracker.class });
private enum ReapUnvalidatedNetworks {
// Tear down networks that have no chance (e.g. even if validated) of becoming
// the highest scoring network satisfying a NetworkRequest. This should be passed when
// all networks have been rematched against all NetworkRequests.
REAP,
// Don't reap networks. This should be passed when some networks have not yet been
// rematched against all NetworkRequests.
DONT_REAP
}
private enum UnneededFor {
LINGER, // Determine whether this network is unneeded and should be lingered.
TEARDOWN, // Determine whether this network is unneeded and should be torn down.
}
/**
* For per-app preferences, requests contain an int to signify which request
* should have priority. The order is passed to netd which will use it together
* with UID ranges to generate the corresponding IP rule. This serves to
* direct device-originated data traffic of the specific UIDs to the correct
* default network for each app.
* Order ints passed to netd must be in the 0~999 range. Larger values code for
* a lower priority, see {@link NativeUidRangeConfig}.
*
* Requests that don't code for a per-app preference use PREFERENCE_ORDER_INVALID.
* The default request uses PREFERENCE_ORDER_DEFAULT.
*/
// Used when sending to netd to code for "no order".
static final int PREFERENCE_ORDER_NONE = 0;
// Order for requests that don't code for a per-app preference. As it is
// out of the valid range, the corresponding order should be
// PREFERENCE_ORDER_NONE when sending to netd.
@VisibleForTesting
static final int PREFERENCE_ORDER_INVALID = Integer.MAX_VALUE;
// As a security feature, VPNs have the top priority.
static final int PREFERENCE_ORDER_VPN = 0; // Netd supports only 0 for VPN.
// Order of per-app OEM preference. See {@link #setOemNetworkPreference}.
@VisibleForTesting
static final int PREFERENCE_ORDER_OEM = 10;
// Order of per-profile preference, such as used by enterprise networks.
// See {@link #setProfileNetworkPreference}.
@VisibleForTesting
static final int PREFERENCE_ORDER_PROFILE = 20;
// Order of user setting to prefer mobile data even when networks with
// better scores are connected.
// See {@link ConnectivitySettingsManager#setMobileDataPreferredUids}
@VisibleForTesting
static final int PREFERENCE_ORDER_MOBILE_DATA_PREFERERRED = 30;
// Preference order that signifies the network shouldn't be set as a default network for
// the UIDs, only give them access to it. TODO : replace this with a boolean
// in NativeUidRangeConfig
@VisibleForTesting
static final int PREFERENCE_ORDER_IRRELEVANT_BECAUSE_NOT_DEFAULT = 999;
// Bound for the lowest valid preference order.
static final int PREFERENCE_ORDER_LOWEST = 999;
/**
* used internally to clear a wakelock when transitioning
* from one net to another. Clear happens when we get a new
* network - EVENT_EXPIRE_NET_TRANSITION_WAKELOCK happens
* after a timeout if no network is found (typically 1 min).
*/
private static final int EVENT_CLEAR_NET_TRANSITION_WAKELOCK = 8;
/**
* used internally to reload global proxy settings
*/
private static final int EVENT_APPLY_GLOBAL_HTTP_PROXY = 9;
/**
* PAC manager has received new port.
*/
private static final int EVENT_PAC_PROXY_HAS_CHANGED = 16;
/**
* used internally when registering NetworkProviders
* obj = NetworkProviderInfo
*/
private static final int EVENT_REGISTER_NETWORK_PROVIDER = 17;
/**
* used internally when registering NetworkAgents
* obj = Messenger
*/
private static final int EVENT_REGISTER_NETWORK_AGENT = 18;
/**
* used to add a network request
* includes a NetworkRequestInfo
*/
private static final int EVENT_REGISTER_NETWORK_REQUEST = 19;
/**
* indicates a timeout period is over - check if we had a network yet or not
* and if not, call the timeout callback (but leave the request live until they
* cancel it.
* includes a NetworkRequestInfo
*/
private static final int EVENT_TIMEOUT_NETWORK_REQUEST = 20;
/**
* used to add a network listener - no request
* includes a NetworkRequestInfo
*/
private static final int EVENT_REGISTER_NETWORK_LISTENER = 21;
/**
* used to remove a network request, either a listener or a real request
* arg1 = UID of caller
* obj = NetworkRequest
*/
private static final int EVENT_RELEASE_NETWORK_REQUEST = 22;
/**
* used internally when registering NetworkProviders
* obj = Messenger
*/
private static final int EVENT_UNREGISTER_NETWORK_PROVIDER = 23;
/**
* used internally to expire a wakelock when transitioning
* from one net to another. Expire happens when we fail to find
* a new network (typically after 1 minute) -
* EVENT_CLEAR_NET_TRANSITION_WAKELOCK happens if we had found
* a replacement network.
*/
private static final int EVENT_EXPIRE_NET_TRANSITION_WAKELOCK = 24;
/**
* used to add a network request with a pending intent
* obj = NetworkRequestInfo
*/
private static final int EVENT_REGISTER_NETWORK_REQUEST_WITH_INTENT = 26;
/**
* used to remove a pending intent and its associated network request.
* arg1 = UID of caller
* obj = PendingIntent
*/
private static final int EVENT_RELEASE_NETWORK_REQUEST_WITH_INTENT = 27;
/**
* used to specify whether a network should be used even if unvalidated.
* arg1 = whether to accept the network if it's unvalidated (1 or 0)
* arg2 = whether to remember this choice in the future (1 or 0)
* obj = network
*/
private static final int EVENT_SET_ACCEPT_UNVALIDATED = 28;
/**
* used internally to (re)configure always-on networks.
*/
private static final int EVENT_CONFIGURE_ALWAYS_ON_NETWORKS = 30;
/**
* used to add a network listener with a pending intent
* obj = NetworkRequestInfo
*/
private static final int EVENT_REGISTER_NETWORK_LISTENER_WITH_INTENT = 31;
/**
* used to specify whether a network should not be penalized when it becomes unvalidated.
*/
private static final int EVENT_SET_AVOID_UNVALIDATED = 35;
/**
* used to handle reported network connectivity. May trigger revalidation of a network.
*/
private static final int EVENT_REPORT_NETWORK_CONNECTIVITY = 36;
// Handle changes in Private DNS settings.
private static final int EVENT_PRIVATE_DNS_SETTINGS_CHANGED = 37;
// Handle private DNS validation status updates.
private static final int EVENT_PRIVATE_DNS_VALIDATION_UPDATE = 38;
/**
* Event for NetworkMonitor/NetworkAgentInfo to inform ConnectivityService that the network has
* been tested.
* obj = {@link NetworkTestedResults} representing information sent from NetworkMonitor.
* data = PersistableBundle of extras passed from NetworkMonitor. If {@link
* NetworkMonitorCallbacks#notifyNetworkTested} is called, this will be null.
*/
private static final int EVENT_NETWORK_TESTED = 41;
/**
* Event for NetworkMonitor/NetworkAgentInfo to inform ConnectivityService that the private DNS
* config was resolved.
* obj = PrivateDnsConfig
* arg2 = netid
*/
private static final int EVENT_PRIVATE_DNS_CONFIG_RESOLVED = 42;
/**
* Request ConnectivityService display provisioning notification.
* arg1 = Whether to make the notification visible.
* arg2 = NetID.
* obj = Intent to be launched when notification selected by user, null if !arg1.
*/
private static final int EVENT_PROVISIONING_NOTIFICATION = 43;
/**
* Used to specify whether a network should be used even if connectivity is partial.
* arg1 = whether to accept the network if its connectivity is partial (1 for true or 0 for
* false)
* arg2 = whether to remember this choice in the future (1 for true or 0 for false)
* obj = network
*/
private static final int EVENT_SET_ACCEPT_PARTIAL_CONNECTIVITY = 44;
/**
* Event for NetworkMonitor to inform ConnectivityService that the probe status has changed.
* Both of the arguments are bitmasks, and the value of bits come from
* INetworkMonitor.NETWORK_VALIDATION_PROBE_*.
* arg1 = unused
* arg2 = netId
* obj = A Pair of integers: the bitmasks of, respectively, completed and successful probes.
*/
public static final int EVENT_PROBE_STATUS_CHANGED = 45;
/**
* Event for NetworkMonitor to inform ConnectivityService that captive portal data has changed.
* arg1 = unused
* arg2 = netId
* obj = captive portal data
*/
private static final int EVENT_CAPPORT_DATA_CHANGED = 46;
/**
* Used by setRequireVpnForUids.
* arg1 = whether the specified UID ranges are required to use a VPN.
* obj = Array of UidRange objects.
*/
private static final int EVENT_SET_REQUIRE_VPN_FOR_UIDS = 47;
/**
* Used internally when setting the default networks for OemNetworkPreferences.
* obj = Pair<OemNetworkPreferences, listener>
*/
private static final int EVENT_SET_OEM_NETWORK_PREFERENCE = 48;
/**
* Used to indicate the system default network becomes active.
*/
private static final int EVENT_REPORT_NETWORK_ACTIVITY = 49;
/**
* Used internally when setting a network preference for a user profile.
* obj = Pair<ProfileNetworkPreference, Listener>
*/
private static final int EVENT_SET_PROFILE_NETWORK_PREFERENCE = 50;
/**
* Event to specify that reasons for why an uid is blocked changed.
* arg1 = uid
* arg2 = blockedReasons
*/
private static final int EVENT_UID_BLOCKED_REASON_CHANGED = 51;
/**
* Event to register a new network offer
* obj = NetworkOffer
*/
private static final int EVENT_REGISTER_NETWORK_OFFER = 52;
/**
* Event to unregister an existing network offer
* obj = INetworkOfferCallback
*/
private static final int EVENT_UNREGISTER_NETWORK_OFFER = 53;
/**
* Used internally when MOBILE_DATA_PREFERRED_UIDS setting changed.
*/
private static final int EVENT_MOBILE_DATA_PREFERRED_UIDS_CHANGED = 54;
/**
* Event to set temporary allow bad wifi within a limited time to override
* {@code config_networkAvoidBadWifi}.
*/
private static final int EVENT_SET_TEST_ALLOW_BAD_WIFI_UNTIL = 55;
/**
* Used internally when INGRESS_RATE_LIMIT_BYTES_PER_SECOND setting changes.
*/
private static final int EVENT_INGRESS_RATE_LIMIT_CHANGED = 56;
/**
* The initial evaluation period is over for this network.
*
* If no form of connectivity has been found on this network (valid, partial, captive portal)
* then the stack will now consider it to have been determined bad.
*/
private static final int EVENT_INITIAL_EVALUATION_TIMEOUT = 57;
/**
* Used internally when the user does not want the network from captive portal app.
* obj = Network
*/
private static final int EVENT_USER_DOES_NOT_WANT = 58;
/**
* Event to set VPN as preferred network for specific apps.
* obj = VpnNetworkPreferenceInfo
*/
private static final int EVENT_SET_VPN_NETWORK_PREFERENCE = 59;
/**
* Event to use low TCP polling timer used in automatic on/off keepalive temporarily.
*/
private static final int EVENT_SET_LOW_TCP_POLLING_UNTIL = 60;
/**
* Event to inform the ConnectivityService handler when a uid has been frozen or unfrozen.
*/
private static final int EVENT_UID_FROZEN_STATE_CHANGED = 61;
/**
* Argument for {@link #EVENT_PROVISIONING_NOTIFICATION} to indicate that the notification
* should be shown.
*/
private static final int PROVISIONING_NOTIFICATION_SHOW = 1;
/**
* Argument for {@link #EVENT_PROVISIONING_NOTIFICATION} to indicate that the notification
* should be hidden.
*/
private static final int PROVISIONING_NOTIFICATION_HIDE = 0;
/**
* The maximum alive time to allow bad wifi configuration for testing.
*/
private static final long MAX_TEST_ALLOW_BAD_WIFI_UNTIL_MS = 5 * 60 * 1000L;
/**
* The maximum alive time to decrease TCP polling timer in automatic on/off keepalive for
* testing.
*/
private static final long MAX_TEST_LOW_TCP_POLLING_UNTIL_MS = 5 * 60 * 1000L;
/**
* The priority of the tc police rate limiter -- smaller value is higher priority.
* This value needs to be coordinated with PRIO_CLAT, PRIO_TETHER4, and PRIO_TETHER6.
*/
private static final short TC_PRIO_POLICE = 1;
/**
* The BPF program attached to the tc-police hook to account for to-be-dropped traffic.
*/
private static final String TC_POLICE_BPF_PROG_PATH =
"/sys/fs/bpf/netd_shared/prog_netd_schedact_ingress_account";
private static String eventName(int what) {
return sMagicDecoderRing.get(what, Integer.toString(what));
}
private static IDnsResolver getDnsResolver(Context context) {
final DnsResolverServiceManager dsm = context.getSystemService(
DnsResolverServiceManager.class);
return IDnsResolver.Stub.asInterface(dsm.getService());
}
/** Handler thread used for all of the handlers below. */
@VisibleForTesting
protected final HandlerThread mHandlerThread;
/** Handler used for internal events. */
final private InternalHandler mHandler;
/** Handler used for incoming {@link NetworkStateTracker} events. */
final private NetworkStateTrackerHandler mTrackerHandler;
/** Handler used for processing {@link android.net.ConnectivityDiagnosticsManager} events */
@VisibleForTesting
final ConnectivityDiagnosticsHandler mConnectivityDiagnosticsHandler;
private final DnsManager mDnsManager;
@VisibleForTesting
final NetworkRanker mNetworkRanker;
private boolean mSystemReady;
private Intent mInitialBroadcast;
private final PowerManager.WakeLock mNetTransitionWakeLock;
private final PowerManager.WakeLock mPendingIntentWakeLock;
// A helper object to track the current default HTTP proxy. ConnectivityService needs to tell
// the world when it changes.
private final ProxyTracker mProxyTracker;
final private SettingsObserver mSettingsObserver;
private final UserManager mUserManager;
// the set of network types that can only be enabled by system/sig apps
private final List<Integer> mProtectedNetworks;
private Set<String> mWolSupportedInterfaces;
private final TelephonyManager mTelephonyManager;
private final CarrierPrivilegeAuthenticator mCarrierPrivilegeAuthenticator;
private final AppOpsManager mAppOpsManager;
private final LocationPermissionChecker mLocationPermissionChecker;
private final AutomaticOnOffKeepaliveTracker mKeepaliveTracker;
private final QosCallbackTracker mQosCallbackTracker;
private final NetworkNotificationManager mNotifier;
private final LingerMonitor mLingerMonitor;
// sequence number of NetworkRequests
private int mNextNetworkRequestId = NetworkRequest.FIRST_REQUEST_ID;
// Sequence number for NetworkProvider IDs.
private final AtomicInteger mNextNetworkProviderId = new AtomicInteger(
NetworkProvider.FIRST_PROVIDER_ID);
// NetworkRequest activity String log entries.
private static final int MAX_NETWORK_REQUEST_LOGS = 20;
private final LocalLog mNetworkRequestInfoLogs = new LocalLog(MAX_NETWORK_REQUEST_LOGS);
// NetworkInfo blocked and unblocked String log entries
private static final int MAX_NETWORK_INFO_LOGS = 40;
private final LocalLog mNetworkInfoBlockingLogs = new LocalLog(MAX_NETWORK_INFO_LOGS);
private static final int MAX_WAKELOCK_LOGS = 20;
private final LocalLog mWakelockLogs = new LocalLog(MAX_WAKELOCK_LOGS);
private int mTotalWakelockAcquisitions = 0;
private int mTotalWakelockReleases = 0;
private long mTotalWakelockDurationMs = 0;
private long mMaxWakelockDurationMs = 0;
private long mLastWakeLockAcquireTimestamp = 0;
private final IpConnectivityLog mMetricsLog;
@GuardedBy("mBandwidthRequests")
private final SparseArray<Integer> mBandwidthRequests = new SparseArray<>(10);
@VisibleForTesting
final MultinetworkPolicyTracker mMultinetworkPolicyTracker;
@VisibleForTesting
final Map<IBinder, ConnectivityDiagnosticsCallbackInfo> mConnectivityDiagnosticsCallbacks =
new HashMap<>();
// Rate limit applicable to all internet capable networks (-1 = disabled). This value is
// configured via {@link
// ConnectivitySettingsManager#INGRESS_RATE_LIMIT_BYTES_PER_SECOND}
// Only the handler thread is allowed to access this field.
private long mIngressRateLimit = -1;
// This is the cache for the packageName -> ApplicationSelfCertifiedNetworkCapabilities. This
// value can be accessed from both handler thread and any random binder thread. Therefore,
// accessing this value requires holding a lock. The cache is the same across all the users.
@GuardedBy("mSelfCertifiedCapabilityCache")
private final Map<String, ApplicationSelfCertifiedNetworkCapabilities>
mSelfCertifiedCapabilityCache = new HashMap<>();
// Flag to enable the feature of closing frozen app sockets.
private final boolean mDestroyFrozenSockets;
// Flag to optimize closing frozen app sockets by waiting for the cellular modem to wake up.
private final boolean mDelayDestroyFrozenSockets;
// Flag to allow SysUI to receive connectivity reports for wifi picker UI.
private final boolean mAllowSysUiConnectivityReports;
// Uids that ConnectivityService is pending to close sockets of.
private final Set<Integer> mPendingFrozenUids = new ArraySet<>();
/**
* Implements support for the legacy "one network per network type" model.
*
* We used to have a static array of NetworkStateTrackers, one for each
* network type, but that doesn't work any more now that we can have,
* for example, more that one wifi network. This class stores all the
* NetworkAgentInfo objects that support a given type, but the legacy
* API will only see the first one.
*
* It serves two main purposes:
*
* 1. Provide information about "the network for a given type" (since this
* API only supports one).
* 2. Send legacy connectivity change broadcasts. Broadcasts are sent if
* the first network for a given type changes, or if the default network
* changes.
*/
@VisibleForTesting
static class LegacyTypeTracker {
private static final boolean DBG = true;
private static final boolean VDBG = false;
/**
* Array of lists, one per legacy network type (e.g., TYPE_MOBILE_MMS).
* Each list holds references to all NetworkAgentInfos that are used to
* satisfy requests for that network type.
*
* This array is built out at startup such that an unsupported network
* doesn't get an ArrayList instance, making this a tristate:
* unsupported, supported but not active and active.
*
* The actual lists are populated when we scan the network types that
* are supported on this device.
*
* Threading model:
* - addSupportedType() is only called in the constructor
* - add(), update(), remove() are only called from the ConnectivityService handler thread.
* They are therefore not thread-safe with respect to each other.
* - getNetworkForType() can be called at any time on binder threads. It is synchronized
* on mTypeLists to be thread-safe with respect to a concurrent remove call.
* - getRestoreTimerForType(type) is also synchronized on mTypeLists.
* - dump is thread-safe with respect to concurrent add and remove calls.
*/
private final ArrayList<NetworkAgentInfo>[] mTypeLists;
@NonNull
private final ConnectivityService mService;
// Restore timers for requestNetworkForFeature (network type -> timer in ms). Types without
// an entry have no timer (equivalent to -1). Lazily loaded.
@NonNull
private ArrayMap<Integer, Integer> mRestoreTimers = new ArrayMap<>();
LegacyTypeTracker(@NonNull ConnectivityService service) {
mService = service;
mTypeLists = new ArrayList[ConnectivityManager.MAX_NETWORK_TYPE + 1];
}
// TODO: Set the mini sdk to 31 and remove @TargetApi annotation when b/205923322 is
// addressed.
@TargetApi(Build.VERSION_CODES.S)
public void loadSupportedTypes(@NonNull Context ctx, @NonNull TelephonyManager tm) {
final PackageManager pm = ctx.getPackageManager();
if (pm.hasSystemFeature(FEATURE_WIFI)) {
addSupportedType(TYPE_WIFI);
}
if (pm.hasSystemFeature(FEATURE_WIFI_DIRECT)) {
addSupportedType(TYPE_WIFI_P2P);
}
if (tm.isDataCapable()) {
// Telephony does not have granular support for these types: they are either all
// supported, or none is supported
addSupportedType(TYPE_MOBILE);
addSupportedType(TYPE_MOBILE_MMS);
addSupportedType(TYPE_MOBILE_SUPL);
addSupportedType(TYPE_MOBILE_DUN);
addSupportedType(TYPE_MOBILE_HIPRI);
addSupportedType(TYPE_MOBILE_FOTA);
addSupportedType(TYPE_MOBILE_IMS);
addSupportedType(TYPE_MOBILE_CBS);
addSupportedType(TYPE_MOBILE_IA);
addSupportedType(TYPE_MOBILE_EMERGENCY);
}
if (pm.hasSystemFeature(FEATURE_BLUETOOTH)) {
addSupportedType(TYPE_BLUETOOTH);
}
if (pm.hasSystemFeature(FEATURE_WATCH)) {
// TYPE_PROXY is only used on Wear
addSupportedType(TYPE_PROXY);
}
// Ethernet is often not specified in the configs, although many devices can use it via
// USB host adapters. Add it as long as the ethernet service is here.
if (deviceSupportsEthernet(ctx)) {
addSupportedType(TYPE_ETHERNET);
}
// Always add TYPE_VPN as a supported type
addSupportedType(TYPE_VPN);
}
private void addSupportedType(int type) {
if (mTypeLists[type] != null) {
throw new IllegalStateException(
"legacy list for type " + type + "already initialized");
}
mTypeLists[type] = new ArrayList<>();
}
public boolean isTypeSupported(int type) {
return isNetworkTypeValid(type) && mTypeLists[type] != null;
}
public NetworkAgentInfo getNetworkForType(int type) {
synchronized (mTypeLists) {
if (isTypeSupported(type) && !mTypeLists[type].isEmpty()) {
return mTypeLists[type].get(0);
}
}
return null;
}
public int getRestoreTimerForType(int type) {
synchronized (mTypeLists) {
if (mRestoreTimers == null) {
mRestoreTimers = loadRestoreTimers();
}
return mRestoreTimers.getOrDefault(type, -1);
}
}
private ArrayMap<Integer, Integer> loadRestoreTimers() {
final String[] configs = mService.mResources.get().getStringArray(
R.array.config_legacy_networktype_restore_timers);
final ArrayMap<Integer, Integer> ret = new ArrayMap<>(configs.length);
for (final String config : configs) {
final String[] splits = TextUtils.split(config, ",");
if (splits.length != 2) {
logwtf("Invalid restore timer token count: " + config);
continue;
}
try {
ret.put(Integer.parseInt(splits[0]), Integer.parseInt(splits[1]));
} catch (NumberFormatException e) {
logwtf("Invalid restore timer number format: " + config, e);
}
}
return ret;
}
private void maybeLogBroadcast(NetworkAgentInfo nai, DetailedState state, int type,
boolean isDefaultNetwork) {
if (DBG) {
log("Sending " + state
+ " broadcast for type " + type + " " + nai.toShortString()
+ " isDefaultNetwork=" + isDefaultNetwork);
}
}
// When a lockdown VPN connects, send another CONNECTED broadcast for the underlying
// network type, to preserve previous behaviour.
private void maybeSendLegacyLockdownBroadcast(@NonNull NetworkAgentInfo vpnNai) {
if (vpnNai != mService.getLegacyLockdownNai()) return;
if (vpnNai.declaredUnderlyingNetworks == null
|| vpnNai.declaredUnderlyingNetworks.length != 1) {
Log.wtf(TAG, "Legacy lockdown VPN must have exactly one underlying network: "
+ Arrays.toString(vpnNai.declaredUnderlyingNetworks));
return;
}
final NetworkAgentInfo underlyingNai = mService.getNetworkAgentInfoForNetwork(
vpnNai.declaredUnderlyingNetworks[0]);
if (underlyingNai == null) return;
final int type = underlyingNai.networkInfo.getType();
final DetailedState state = DetailedState.CONNECTED;
maybeLogBroadcast(underlyingNai, state, type, true /* isDefaultNetwork */);
mService.sendLegacyNetworkBroadcast(underlyingNai, state, type);
}
/** Adds the given network to the specified legacy type list. */
public void add(int type, NetworkAgentInfo nai) {
if (!isTypeSupported(type)) {
return; // Invalid network type.
}
if (VDBG) log("Adding agent " + nai + " for legacy network type " + type);
ArrayList<NetworkAgentInfo> list = mTypeLists[type];
if (list.contains(nai)) {
return;
}
synchronized (mTypeLists) {
list.add(nai);
}
// Send a broadcast if this is the first network of its type or if it's the default.
final boolean isDefaultNetwork = mService.isDefaultNetwork(nai);
// If a legacy lockdown VPN is active, override the NetworkInfo state in all broadcasts
// to preserve previous behaviour.
final DetailedState state = mService.getLegacyLockdownState(DetailedState.CONNECTED);
if ((list.size() == 1) || isDefaultNetwork) {
maybeLogBroadcast(nai, state, type, isDefaultNetwork);
mService.sendLegacyNetworkBroadcast(nai, state, type);
}
if (type == TYPE_VPN && state == DetailedState.CONNECTED) {
maybeSendLegacyLockdownBroadcast(nai);
}
}
/** Removes the given network from the specified legacy type list. */
public void remove(int type, NetworkAgentInfo nai, boolean wasDefault) {
ArrayList<NetworkAgentInfo> list = mTypeLists[type];
if (list == null || list.isEmpty()) {
return;
}
final boolean wasFirstNetwork = list.get(0).equals(nai);
synchronized (mTypeLists) {
if (!list.remove(nai)) {
return;
}
}
if (wasFirstNetwork || wasDefault) {
maybeLogBroadcast(nai, DetailedState.DISCONNECTED, type, wasDefault);
mService.sendLegacyNetworkBroadcast(nai, DetailedState.DISCONNECTED, type);
}
if (!list.isEmpty() && wasFirstNetwork) {
if (DBG) log("Other network available for type " + type +
", sending connected broadcast");
final NetworkAgentInfo replacement = list.get(0);
maybeLogBroadcast(replacement, DetailedState.CONNECTED, type,
mService.isDefaultNetwork(replacement));
mService.sendLegacyNetworkBroadcast(replacement, DetailedState.CONNECTED, type);
}
}
/** Removes the given network from all legacy type lists. */
public void remove(NetworkAgentInfo nai, boolean wasDefault) {
if (VDBG) log("Removing agent " + nai + " wasDefault=" + wasDefault);
for (int type = 0; type < mTypeLists.length; type++) {
remove(type, nai, wasDefault);
}
}
// send out another legacy broadcast - currently only used for suspend/unsuspend toggle
public void update(NetworkAgentInfo nai) {
final boolean isDefault = mService.isDefaultNetwork(nai);
final DetailedState state = nai.networkInfo.getDetailedState();
for (int type = 0; type < mTypeLists.length; type++) {
final ArrayList<NetworkAgentInfo> list = mTypeLists[type];
final boolean contains = (list != null && list.contains(nai));
final boolean isFirst = contains && (nai == list.get(0));
if (isFirst || contains && isDefault) {
maybeLogBroadcast(nai, state, type, isDefault);
mService.sendLegacyNetworkBroadcast(nai, state, type);
}
}
}
public void dump(IndentingPrintWriter pw) {
pw.println("mLegacyTypeTracker:");
pw.increaseIndent();
pw.print("Supported types:");
for (int type = 0; type < mTypeLists.length; type++) {
if (mTypeLists[type] != null) pw.print(" " + type);
}
pw.println();
pw.println("Current state:");
pw.increaseIndent();
synchronized (mTypeLists) {
for (int type = 0; type < mTypeLists.length; type++) {
if (mTypeLists[type] == null || mTypeLists[type].isEmpty()) continue;
for (NetworkAgentInfo nai : mTypeLists[type]) {
pw.println(type + " " + nai.toShortString());
}
}
}
pw.decreaseIndent();
pw.decreaseIndent();
pw.println();
}
}
private final LegacyTypeTracker mLegacyTypeTracker = new LegacyTypeTracker(this);
final LocalPriorityDump mPriorityDumper = new LocalPriorityDump();
/**
* Helper class which parses out priority arguments and dumps sections according to their
* priority. If priority arguments are omitted, function calls the legacy dump command.
*/
private class LocalPriorityDump {
private static final String PRIORITY_ARG = "--dump-priority";
private static final String PRIORITY_ARG_HIGH = "HIGH";
private static final String PRIORITY_ARG_NORMAL = "NORMAL";
private static final int DUMPSYS_DEFAULT_TIMEOUT_MS = 10_000;
LocalPriorityDump() {}
private void dumpHigh(FileDescriptor fd, PrintWriter pw) {
if (!HandlerUtils.runWithScissors(mHandler, () -> {
doDump(fd, pw, new String[]{DIAG_ARG});
doDump(fd, pw, new String[]{SHORT_ARG});
}, DUMPSYS_DEFAULT_TIMEOUT_MS)) {
pw.println("dumpHigh timeout");
}
}
private void dumpNormal(FileDescriptor fd, PrintWriter pw, String[] args) {
if (!HandlerUtils.runWithScissors(mHandler, () -> doDump(fd, pw, args),
DUMPSYS_DEFAULT_TIMEOUT_MS)) {
pw.println("dumpNormal timeout");
}
}
public void dump(FileDescriptor fd, PrintWriter pw, String[] args) {
if (args == null) {
dumpNormal(fd, pw, args);
return;
}
String priority = null;
for (int argIndex = 0; argIndex < args.length; argIndex++) {
if (args[argIndex].equals(PRIORITY_ARG) && argIndex + 1 < args.length) {
argIndex++;
priority = args[argIndex];
}
}
if (PRIORITY_ARG_HIGH.equals(priority)) {
dumpHigh(fd, pw);
} else if (PRIORITY_ARG_NORMAL.equals(priority)) {
dumpNormal(fd, pw, args);
} else {
// ConnectivityService publishes binder service using publishBinderService() with
// no priority assigned will be treated as NORMAL priority. Dumpsys does not send
// "--dump-priority" arguments to the service. Thus, dump NORMAL only to align the
// legacy output for dumpsys connectivity.
// TODO: Integrate into signal dump.
dumpNormal(fd, pw, args);
}
}
}
/**
* Dependencies of ConnectivityService, for injection in tests.
*/
@VisibleForTesting
public static class Dependencies {
public int getCallingUid() {
return Binder.getCallingUid();
}
public boolean isAtLeastS() {
return SdkLevel.isAtLeastS();
}
public boolean isAtLeastT() {
return SdkLevel.isAtLeastT();
}
public boolean isAtLeastU() {
return SdkLevel.isAtLeastU();
}
public boolean isAtLeastV() {
return SdkLevel.isAtLeastV();
}
/**
* Get system properties to use in ConnectivityService.
*/
public MockableSystemProperties getSystemProperties() {
return new MockableSystemProperties();
}
/**
* Get the {@link ConnectivityResources} to use in ConnectivityService.
*/
public ConnectivityResources getResources(@NonNull Context ctx) {
return new ConnectivityResources(ctx);
}
/**
* Create a HandlerThread to use in ConnectivityService.
*/
public HandlerThread makeHandlerThread(@NonNull final String tag) {
return new HandlerThread(tag);
}
/**
* Get a reference to the ModuleNetworkStackClient.
*/
public NetworkStackClientBase getNetworkStack() {
return ModuleNetworkStackClient.getInstance(null);
}
/**
* @see ProxyTracker
*/
public ProxyTracker makeProxyTracker(@NonNull Context context,
@NonNull Handler connServiceHandler) {
return new ProxyTracker(context, connServiceHandler, EVENT_PAC_PROXY_HAS_CHANGED);
}
/**
* @see NetIdManager
*/
public NetIdManager makeNetIdManager() {
return new NetIdManager();
}
/**
* @see NetworkUtils#queryUserAccess(int, int)
*/
public boolean queryUserAccess(int uid, Network network, ConnectivityService cs) {
return cs.queryUserAccess(uid, network);
}
/**
* Gets the UID that owns a socket connection. Needed because opening SOCK_DIAG sockets
* requires CAP_NET_ADMIN, which the unit tests do not have.
*/
public int getConnectionOwnerUid(int protocol, InetSocketAddress local,
InetSocketAddress remote) {
return InetDiagMessage.getConnectionOwnerUid(protocol, local, remote);
}
/**
* @see MultinetworkPolicyTracker
*/
public MultinetworkPolicyTracker makeMultinetworkPolicyTracker(
@NonNull Context c, @NonNull Handler h, @NonNull Runnable r) {
return new MultinetworkPolicyTracker(c, h, r);
}
/**
* @see AutomaticOnOffKeepaliveTracker
*/
public AutomaticOnOffKeepaliveTracker makeAutomaticOnOffKeepaliveTracker(
@NonNull Context c, @NonNull Handler h) {
return new AutomaticOnOffKeepaliveTracker(c, h);
}
/**
* @see BatteryStatsManager
*/
public void reportNetworkInterfaceForTransports(Context context, String iface,
int[] transportTypes) {
final BatteryStatsManager batteryStats =
context.getSystemService(BatteryStatsManager.class);
batteryStats.reportNetworkInterfaceForTransports(iface, transportTypes);
}
public boolean getCellular464XlatEnabled() {
return NetworkProperties.isCellular464XlatEnabled().orElse(true);
}
/**
* @see PendingIntent#intentFilterEquals
*/
public boolean intentFilterEquals(PendingIntent a, PendingIntent b) {
return a.intentFilterEquals(b);
}
/**
* @see LocationPermissionChecker
*/
public LocationPermissionChecker makeLocationPermissionChecker(Context context) {
return new LocationPermissionChecker(context);
}
/**
* @see CarrierPrivilegeAuthenticator
*
* This method returns null in versions before T, where carrier privilege
* authentication is not supported.
*/
@Nullable
public CarrierPrivilegeAuthenticator makeCarrierPrivilegeAuthenticator(
@NonNull final Context context, @NonNull final TelephonyManager tm) {
if (isAtLeastT()) {
return new CarrierPrivilegeAuthenticator(context, tm);
} else {
return null;
}
}
/**
* @see DeviceConfigUtils#isTetheringFeatureEnabled
*/
public boolean isFeatureEnabled(Context context, String name) {
return DeviceConfigUtils.isTetheringFeatureEnabled(context, name);
}
/**
* @see DeviceConfigUtils#isTetheringFeatureNotChickenedOut
*/
public boolean isFeatureNotChickenedOut(Context context, String name) {
return DeviceConfigUtils.isTetheringFeatureNotChickenedOut(context, name);
}
/**
* Get the BpfNetMaps implementation to use in ConnectivityService.
* @param netd a netd binder
* @return BpfNetMaps implementation.
*/
public BpfNetMaps getBpfNetMaps(Context context, INetd netd) {
return new BpfNetMaps(context, netd);
}
/**
* @see ClatCoordinator
*/
@RequiresApi(Build.VERSION_CODES.TIRAMISU)
public ClatCoordinator getClatCoordinator(INetd netd) {
return new ClatCoordinator(
new ClatCoordinator.Dependencies() {
@NonNull
public INetd getNetd() {
return netd;
}
});
}
/**
* Wraps {@link TcUtils#tcFilterAddDevIngressPolice}
*/
public void enableIngressRateLimit(String iface, long rateInBytesPerSecond) {
final InterfaceParams params = InterfaceParams.getByName(iface);
if (params == null) {
// the interface might have disappeared.
logw("Failed to get interface params for interface " + iface);
return;
}
try {
// converting rateInBytesPerSecond from long to int is safe here because the
// setting's range is limited to INT_MAX.
// TODO: add long/uint64 support to tcFilterAddDevIngressPolice.
Log.i(TAG,
"enableIngressRateLimit on " + iface + ": " + rateInBytesPerSecond + "B/s");
TcUtils.tcFilterAddDevIngressPolice(params.index, TC_PRIO_POLICE, (short) ETH_P_ALL,
(int) rateInBytesPerSecond, TC_POLICE_BPF_PROG_PATH);
} catch (IOException e) {
loge("TcUtils.tcFilterAddDevIngressPolice(ifaceIndex=" + params.index
+ ", PRIO_POLICE, ETH_P_ALL, rateInBytesPerSecond="
+ rateInBytesPerSecond + ", bpfProgPath=" + TC_POLICE_BPF_PROG_PATH
+ ") failure: ", e);
}
}
/**
* Wraps {@link TcUtils#tcFilterDelDev}
*/
public void disableIngressRateLimit(String iface) {
final InterfaceParams params = InterfaceParams.getByName(iface);
if (params == null) {
// the interface might have disappeared.
logw("Failed to get interface params for interface " + iface);
return;
}
try {
Log.i(TAG,
"disableIngressRateLimit on " + iface);
TcUtils.tcFilterDelDev(params.index, true, TC_PRIO_POLICE, (short) ETH_P_ALL);
} catch (IOException e) {
loge("TcUtils.tcFilterDelDev(ifaceIndex=" + params.index
+ ", ingress=true, PRIO_POLICE, ETH_P_ALL) failure: ", e);
}
}
/**
* Get BPF program Id from CGROUP. See {@link BpfUtils#getProgramId}.
*/
public int getBpfProgramId(final int attachType)
throws IOException {
return BpfUtils.getProgramId(attachType);
}
/**
* Wraps {@link BroadcastOptionsShimImpl#newInstance(BroadcastOptions)}
*/
// TODO: when available in all active branches:
// @RequiresApi(Build.VERSION_CODES.UPSIDE_DOWN_CAKE)
@RequiresApi(Build.VERSION_CODES.CUR_DEVELOPMENT)
public BroadcastOptionsShim makeBroadcastOptionsShim(BroadcastOptions options) {
return BroadcastOptionsShimImpl.newInstance(options);
}
/**
* Wrapper method for
* {@link android.app.compat.CompatChanges#isChangeEnabled(long, String, UserHandle)}.
*
* @param changeId The ID of the compatibility change in question.
* @param packageName The package name of the app in question.
* @param user The user that the operation is done for.
* @return {@code true} if the change is enabled for the specified package.
*/
public boolean isChangeEnabled(long changeId, @NonNull final String packageName,
@NonNull final UserHandle user) {
return CompatChanges.isChangeEnabled(changeId, packageName, user);
}
/**
* As above but with a UID.
* @see CompatChanges#isChangeEnabled(long, int)
*/
public boolean isChangeEnabled(final long changeId, final int uid) {
return CompatChanges.isChangeEnabled(changeId, uid);
}
/**
* Call {@link InetDiagMessage#destroyLiveTcpSockets(Set, Set)}
*
* @param ranges target uid ranges
* @param exemptUids uids to skip close socket
*/
public void destroyLiveTcpSockets(@NonNull final Set<Range<Integer>> ranges,
@NonNull final Set<Integer> exemptUids)
throws SocketException, InterruptedIOException, ErrnoException {
InetDiagMessage.destroyLiveTcpSockets(ranges, exemptUids);
}
/**
* Call {@link InetDiagMessage#destroyLiveTcpSocketsByOwnerUids(Set)}
*
* @param ownerUids target uids to close sockets
*/
public void destroyLiveTcpSocketsByOwnerUids(final Set<Integer> ownerUids)
throws SocketException, InterruptedIOException, ErrnoException {
InetDiagMessage.destroyLiveTcpSocketsByOwnerUids(ownerUids);
}
/**
* Schedule the evaluation timeout.
*
* When a network connects, it's "not evaluated" yet. Detection events cause the network
* to be "evaluated" (typically, validation or detection of a captive portal). If none
* of these events happen, this time will run out, after which the network is considered
* "evaluated" even if nothing happened to it. Notionally that means the system gave up
* on this network and considers it won't provide connectivity. In particular, that means
* it's when the system prefers it to cell if it's wifi and configuration says it should
* prefer bad wifi to cell.
*/
public void scheduleEvaluationTimeout(@NonNull Handler handler,
@NonNull final Network network, final long delayMs) {
handler.sendMessageDelayed(
handler.obtainMessage(EVENT_INITIAL_EVALUATION_TIMEOUT, network), delayMs);
}
}
public ConnectivityService(Context context) {
this(context, getDnsResolver(context), new IpConnectivityLog(),
INetd.Stub.asInterface((IBinder) context.getSystemService(Context.NETD_SERVICE)),
new Dependencies());
}
@VisibleForTesting
protected ConnectivityService(Context context, IDnsResolver dnsresolver,
IpConnectivityLog logger, INetd netd, Dependencies deps) {
if (DBG) log("ConnectivityService starting up");
mDeps = Objects.requireNonNull(deps, "missing Dependencies");
mFlags = new ConnectivityFlags();
mSystemProperties = mDeps.getSystemProperties();
mNetIdManager = mDeps.makeNetIdManager();
mContext = Objects.requireNonNull(context, "missing Context");
mResources = deps.getResources(mContext);
// The legacy PerUidCounter is buggy and throwing exception at count == limit.
// Pass limit - 1 to maintain backward compatibility.
// TODO: Remove the workaround.
mNetworkRequestCounter =
new RequestInfoPerUidCounter(MAX_NETWORK_REQUESTS_PER_UID - 1);
mSystemNetworkRequestCounter =
new RequestInfoPerUidCounter(MAX_NETWORK_REQUESTS_PER_SYSTEM_UID - 1);
mMetricsLog = logger;
final NetworkRequest defaultInternetRequest = createDefaultRequest();
mDefaultRequest = new NetworkRequestInfo(
Process.myUid(), defaultInternetRequest, null,
null /* binder */, NetworkCallback.FLAG_INCLUDE_LOCATION_INFO,
null /* attributionTags */);
mNetworkRequests.put(defaultInternetRequest, mDefaultRequest);
mDefaultNetworkRequests.add(mDefaultRequest);
mNetworkRequestInfoLogs.log("REGISTER " + mDefaultRequest);
mDefaultMobileDataRequest = createDefaultInternetRequestForTransport(
NetworkCapabilities.TRANSPORT_CELLULAR, NetworkRequest.Type.BACKGROUND_REQUEST);
// The default WiFi request is a background request so that apps using WiFi are
// migrated to a better network (typically ethernet) when one comes up, instead
// of staying on WiFi forever.
mDefaultWifiRequest = createDefaultInternetRequestForTransport(
NetworkCapabilities.TRANSPORT_WIFI, NetworkRequest.Type.BACKGROUND_REQUEST);
mDefaultVehicleRequest = createAlwaysOnRequestForCapability(
NetworkCapabilities.NET_CAPABILITY_VEHICLE_INTERNAL,
NetworkRequest.Type.BACKGROUND_REQUEST);
mLingerDelayMs = mSystemProperties.getInt(LINGER_DELAY_PROPERTY, DEFAULT_LINGER_DELAY_MS);
// TODO: Consider making the timer customizable.
mNascentDelayMs = DEFAULT_NASCENT_DELAY_MS;
mCellularRadioTimesharingCapable =
mResources.get().getBoolean(R.bool.config_cellular_radio_timesharing_capable);
int mark = mResources.get().getInteger(R.integer.config_networkWakeupPacketMark);
int mask = mResources.get().getInteger(R.integer.config_networkWakeupPacketMask);
if (SdkLevel.isAtLeastU()) {
// U+ default value of both mark & mask, this is the top bit of the skb->mark,
// see //system/netd/include/FwMark.h union Fwmark, field ingress_cpu_wakeup
final int defaultUMarkMask = 0x80000000; // u32
if ((mark == 0) || (mask == 0)) {
// simply treat unset/disabled as the default U value
mark = defaultUMarkMask;
mask = defaultUMarkMask;
}
if ((mark != defaultUMarkMask) || (mask != defaultUMarkMask)) {
// invalid device overlay settings
throw new IllegalArgumentException(
"Bad config_networkWakeupPacketMark/Mask " + mark + "/" + mask);
}
}
mWakeUpMark = mark;
mWakeUpMask = mask;
mNetd = netd;
mBpfNetMaps = mDeps.getBpfNetMaps(mContext, netd);
mHandlerThread = mDeps.makeHandlerThread("ConnectivityServiceThread");
mPermissionMonitor =
new PermissionMonitor(mContext, mNetd, mBpfNetMaps, mHandlerThread);
mHandlerThread.start();
mHandler = new InternalHandler(mHandlerThread.getLooper());
mTrackerHandler = new NetworkStateTrackerHandler(mHandlerThread.getLooper());
mConnectivityDiagnosticsHandler =
new ConnectivityDiagnosticsHandler(mHandlerThread.getLooper());
mReleasePendingIntentDelayMs = Settings.Secure.getInt(context.getContentResolver(),
ConnectivitySettingsManager.CONNECTIVITY_RELEASE_PENDING_INTENT_DELAY_MS, 5_000);
mStatsManager = mContext.getSystemService(NetworkStatsManager.class);
mPolicyManager = mContext.getSystemService(NetworkPolicyManager.class);
mDnsResolver = Objects.requireNonNull(dnsresolver, "missing IDnsResolver");
mProxyTracker = mDeps.makeProxyTracker(mContext, mHandler);
mTelephonyManager = (TelephonyManager) mContext.getSystemService(Context.TELEPHONY_SERVICE);
mAppOpsManager = (AppOpsManager) mContext.getSystemService(Context.APP_OPS_SERVICE);
mLocationPermissionChecker = mDeps.makeLocationPermissionChecker(mContext);
mCarrierPrivilegeAuthenticator =
mDeps.makeCarrierPrivilegeAuthenticator(mContext, mTelephonyManager);
// To ensure uid state is synchronized with Network Policy, register for
// NetworkPolicyManagerService events must happen prior to NetworkPolicyManagerService
// reading existing policy from disk.
mPolicyManager.registerNetworkPolicyCallback(null, mPolicyCallback);
final PowerManager powerManager = (PowerManager) context.getSystemService(
Context.POWER_SERVICE);
mNetTransitionWakeLock = powerManager.newWakeLock(PowerManager.PARTIAL_WAKE_LOCK, TAG);
mPendingIntentWakeLock = powerManager.newWakeLock(PowerManager.PARTIAL_WAKE_LOCK, TAG);
mLegacyTypeTracker.loadSupportedTypes(mContext, mTelephonyManager);
mProtectedNetworks = new ArrayList<>();
int[] protectedNetworks = mResources.get().getIntArray(R.array.config_protectedNetworks);
for (int p : protectedNetworks) {
if (mLegacyTypeTracker.isTypeSupported(p) && !mProtectedNetworks.contains(p)) {
mProtectedNetworks.add(p);
} else {
if (DBG) loge("Ignoring protectedNetwork " + p);
}
}
mUserManager = (UserManager) context.getSystemService(Context.USER_SERVICE);
mUserAllContext = mContext.createContextAsUser(UserHandle.ALL, 0 /* flags */);
// Listen for user add/removes to inform PermissionMonitor.
// Should run on mHandler to avoid any races.
final IntentFilter userIntentFilter = new IntentFilter();
userIntentFilter.addAction(Intent.ACTION_USER_ADDED);
userIntentFilter.addAction(Intent.ACTION_USER_REMOVED);
mUserAllContext.registerReceiver(mUserIntentReceiver, userIntentFilter,
null /* broadcastPermission */, mHandler);
// Listen to package add/removes for netd
final IntentFilter packageIntentFilter = new IntentFilter();
packageIntentFilter.addAction(Intent.ACTION_PACKAGE_ADDED);
packageIntentFilter.addAction(Intent.ACTION_PACKAGE_REMOVED);
packageIntentFilter.addAction(Intent.ACTION_PACKAGE_REPLACED);
packageIntentFilter.addDataScheme("package");
mUserAllContext.registerReceiver(mPackageIntentReceiver, packageIntentFilter,
null /* broadcastPermission */, mHandler);
// This is needed for pre-V devices to propagate the data saver status
// to the BPF map. This isn't supported before Android T because BPF maps are
// unsupported, and it's also unnecessary on Android V and later versions,
// as the platform code handles data saver bit updates. Additionally, checking
// the initial data saver status here is superfluous because the intent won't
// be sent until the system is ready.
if (mDeps.isAtLeastT() && !mDeps.isAtLeastV()) {
final IntentFilter dataSaverIntentFilter =
new IntentFilter(ACTION_RESTRICT_BACKGROUND_CHANGED);
mUserAllContext.registerReceiver(mDataSaverReceiver, dataSaverIntentFilter,
null /* broadcastPermission */, mHandler);
}
// TrackMultiNetworkActivities feature should be enabled by trunk stable flag.
// But reading the trunk stable flags from mainline modules is not supported yet.
// So enabling this feature on V+ release.
mTrackMultiNetworkActivities = mDeps.isAtLeastV();
mNetworkActivityTracker = new LegacyNetworkActivityTracker(mContext, mNetd, mHandler,
mTrackMultiNetworkActivities);
final NetdCallback netdCallback = new NetdCallback();
try {
mNetd.registerUnsolicitedEventListener(netdCallback);
} catch (RemoteException | ServiceSpecificException e) {
loge("Error registering event listener :" + e);
}
mSettingsObserver = new SettingsObserver(mContext, mHandler);
registerSettingsCallbacks();
mKeepaliveTracker = mDeps.makeAutomaticOnOffKeepaliveTracker(mContext, mHandler);
mNotifier = new NetworkNotificationManager(mContext, mTelephonyManager);
mQosCallbackTracker = new QosCallbackTracker(mHandler, mNetworkRequestCounter);
final int dailyLimit = Settings.Global.getInt(mContext.getContentResolver(),
ConnectivitySettingsManager.NETWORK_SWITCH_NOTIFICATION_DAILY_LIMIT,
LingerMonitor.DEFAULT_NOTIFICATION_DAILY_LIMIT);
final long rateLimit = Settings.Global.getLong(mContext.getContentResolver(),
ConnectivitySettingsManager.NETWORK_SWITCH_NOTIFICATION_RATE_LIMIT_MILLIS,
LingerMonitor.DEFAULT_NOTIFICATION_RATE_LIMIT_MILLIS);
mLingerMonitor = new LingerMonitor(mContext, mNotifier, dailyLimit, rateLimit);
mMultinetworkPolicyTracker = mDeps.makeMultinetworkPolicyTracker(
mContext, mHandler, () -> updateAvoidBadWifi());
mNetworkRanker =
new NetworkRanker(new NetworkRanker.Configuration(activelyPreferBadWifi()));
mMultinetworkPolicyTracker.start();
mDnsManager = new DnsManager(mContext, mDnsResolver);
registerPrivateDnsSettingsCallbacks();
// This NAI is a sentinel used to offer no service to apps that are on a multi-layer
// request that doesn't allow fallback to the default network. It should never be visible
// to apps. As such, it's not in the list of NAIs and doesn't need many of the normal
// arguments like the handler or the DnsResolver.
// TODO : remove this ; it is probably better handled with a sentinel request.
mNoServiceNetwork = new NetworkAgentInfo(null,
new Network(INetd.UNREACHABLE_NET_ID),
new NetworkInfo(TYPE_NONE, 0, "", ""),
new LinkProperties(), new NetworkCapabilities(), null /* localNetworkConfig */,
new NetworkScore.Builder().setLegacyInt(0).build(), mContext, null,
new NetworkAgentConfig(), this, null, null, 0, INVALID_UID,
mLingerDelayMs, mQosCallbackTracker, mDeps);
try {
// DscpPolicyTracker cannot run on S because on S the tethering module can only load
// BPF programs/maps into /sys/fs/tethering/bpf, which the system server cannot access.
// Even if it could, running on S would at least require mocking out the BPF map,
// otherwise the unit tests will fail on pre-T devices where the seccomp filter blocks
// the bpf syscall. http://aosp/1907693
if (mDeps.isAtLeastT()) {
mDscpPolicyTracker = new DscpPolicyTracker();
}
} catch (ErrnoException e) {
loge("Unable to create DscpPolicyTracker");
}
mIngressRateLimit = ConnectivitySettingsManager.getIngressRateLimitInBytesPerSecond(
mContext);
if (mDeps.isAtLeastT()) {
mCdmps = new CompanionDeviceManagerProxyService(context);
} else {
mCdmps = null;
}
mRoutingCoordinatorService = new RoutingCoordinatorService(netd);
mDestroyFrozenSockets = mDeps.isAtLeastU()
&& mDeps.isFeatureEnabled(context, KEY_DESTROY_FROZEN_SOCKETS_VERSION);
mDelayDestroyFrozenSockets = mDeps.isAtLeastU()
&& mDeps.isFeatureEnabled(context, DELAY_DESTROY_FROZEN_SOCKETS_VERSION);
mAllowSysUiConnectivityReports = mDeps.isFeatureNotChickenedOut(
mContext, ALLOW_SYSUI_CONNECTIVITY_REPORTS);
if (mDestroyFrozenSockets) {
final UidFrozenStateChangedCallback frozenStateChangedCallback =
new UidFrozenStateChangedCallback() {
@Override
public void onUidFrozenStateChanged(int[] uids, int[] frozenStates) {
if (uids.length != frozenStates.length) {
Log.wtf(TAG, "uids has length " + uids.length
+ " but frozenStates has length " + frozenStates.length);
return;
}
final UidFrozenStateChangedArgs args =
new UidFrozenStateChangedArgs(uids, frozenStates);
mHandler.sendMessage(
mHandler.obtainMessage(EVENT_UID_FROZEN_STATE_CHANGED, args));
}
};
final ActivityManager activityManager =
mContext.getSystemService(ActivityManager.class);
activityManager.registerUidFrozenStateChangedCallback(
(Runnable r) -> r.run(), frozenStateChangedCallback);
}
if (mDeps.isFeatureNotChickenedOut(mContext, LOG_BPF_RC)) {
mHandler.post(BpfLoaderRcUtils::checkBpfLoaderRc);
}
}
/**
* Check whether or not the device supports Ethernet transport.
*/
public static boolean deviceSupportsEthernet(final Context context) {
final PackageManager pm = context.getPackageManager();
return pm.hasSystemFeature(PackageManager.FEATURE_ETHERNET)
|| pm.hasSystemFeature(PackageManager.FEATURE_USB_HOST);
}
private static NetworkCapabilities createDefaultNetworkCapabilitiesForUid(int uid) {
return createDefaultNetworkCapabilitiesForUidRangeSet(Collections.singleton(
new UidRange(uid, uid)));
}
private static NetworkCapabilities createDefaultNetworkCapabilitiesForUidRangeSet(
@NonNull final Set<UidRange> uidRangeSet) {
final NetworkCapabilities netCap = new NetworkCapabilities();
netCap.addCapability(NET_CAPABILITY_INTERNET);
netCap.addCapability(NET_CAPABILITY_NOT_VCN_MANAGED);
netCap.removeCapability(NET_CAPABILITY_NOT_VPN);
netCap.setUids(UidRange.toIntRanges(uidRangeSet));
return netCap;
}
private NetworkRequest createDefaultRequest() {
return createDefaultInternetRequestForTransport(
TYPE_NONE, NetworkRequest.Type.REQUEST);
}
private NetworkRequest createVpnRequest() {
final NetworkCapabilities netCap = new NetworkCapabilities.Builder()
.withoutDefaultCapabilities()
.addTransportType(TRANSPORT_VPN)
.addCapability(NET_CAPABILITY_NOT_VCN_MANAGED)
.addCapability(NET_CAPABILITY_NOT_RESTRICTED)
.build();
netCap.setRequestorUidAndPackageName(Process.myUid(), mContext.getPackageName());
return createNetworkRequest(NetworkRequest.Type.REQUEST, netCap);
}
private NetworkRequest createDefaultInternetRequestForTransport(
int transportType, NetworkRequest.Type type) {
final NetworkCapabilities netCap = new NetworkCapabilities();
netCap.addCapability(NET_CAPABILITY_INTERNET);
netCap.addCapability(NET_CAPABILITY_NOT_VCN_MANAGED);
netCap.setRequestorUidAndPackageName(Process.myUid(), mContext.getPackageName());
if (transportType > TYPE_NONE) {
netCap.addTransportType(transportType);
}
return createNetworkRequest(type, netCap);
}
private NetworkRequest createNetworkRequest(
NetworkRequest.Type type, NetworkCapabilities netCap) {
return new NetworkRequest(netCap, TYPE_NONE, nextNetworkRequestId(), type);
}
private NetworkRequest createAlwaysOnRequestForCapability(int capability,
NetworkRequest.Type type) {
final NetworkCapabilities netCap = new NetworkCapabilities();
netCap.clearAll();
netCap.addCapability(capability);
netCap.setRequestorUidAndPackageName(Process.myUid(), mContext.getPackageName());
return new NetworkRequest(netCap, TYPE_NONE, nextNetworkRequestId(), type);
}
// Used only for testing.
// TODO: Delete this and either:
// 1. Give FakeSettingsProvider the ability to send settings change notifications (requires
// changing ContentResolver to make registerContentObserver non-final).
// 2. Give FakeSettingsProvider an alternative notification mechanism and have the test use it
// by subclassing SettingsObserver.
@VisibleForTesting
void updateAlwaysOnNetworks() {
mHandler.sendEmptyMessage(EVENT_CONFIGURE_ALWAYS_ON_NETWORKS);
}
// See FakeSettingsProvider comment above.
@VisibleForTesting
void updatePrivateDnsSettings() {
mHandler.sendEmptyMessage(EVENT_PRIVATE_DNS_SETTINGS_CHANGED);
}
@VisibleForTesting
void updateMobileDataPreferredUids() {
mHandler.sendEmptyMessage(EVENT_MOBILE_DATA_PREFERRED_UIDS_CHANGED);
}
@VisibleForTesting
void updateIngressRateLimit() {
mHandler.sendEmptyMessage(EVENT_INGRESS_RATE_LIMIT_CHANGED);
}
@VisibleForTesting
void simulateUpdateProxyInfo(@Nullable final Network network,
@NonNull final ProxyInfo proxyInfo) {
Message.obtain(mHandler, EVENT_PAC_PROXY_HAS_CHANGED,
new Pair<>(network, proxyInfo)).sendToTarget();
}
private void handleAlwaysOnNetworkRequest(
NetworkRequest networkRequest, String settingName, boolean defaultValue) {
final boolean enable = toBool(Settings.Global.getInt(
mContext.getContentResolver(), settingName, encodeBool(defaultValue)));
handleAlwaysOnNetworkRequest(networkRequest, enable);
}
private void handleAlwaysOnNetworkRequest(NetworkRequest networkRequest, boolean enable) {
final boolean isEnabled = (mNetworkRequests.get(networkRequest) != null);
if (enable == isEnabled) {
return; // Nothing to do.
}
if (enable) {
handleRegisterNetworkRequest(new NetworkRequestInfo(
Process.myUid(), networkRequest, null /* messenger */, null /* binder */,
NetworkCallback.FLAG_INCLUDE_LOCATION_INFO,
null /* attributionTags */));
} else {
handleReleaseNetworkRequest(networkRequest, Process.SYSTEM_UID,
/* callOnUnavailable */ false);
}
}
private void handleConfigureAlwaysOnNetworks() {
handleAlwaysOnNetworkRequest(mDefaultMobileDataRequest,
ConnectivitySettingsManager.MOBILE_DATA_ALWAYS_ON, true /* defaultValue */);
handleAlwaysOnNetworkRequest(mDefaultWifiRequest,
ConnectivitySettingsManager.WIFI_ALWAYS_REQUESTED, false /* defaultValue */);
final boolean vehicleAlwaysRequested = mResources.get().getBoolean(
R.bool.config_vehicleInternalNetworkAlwaysRequested);
handleAlwaysOnNetworkRequest(mDefaultVehicleRequest, vehicleAlwaysRequested);
}
// Note that registering observer for setting do not get initial callback when registering,
// callers must fetch the initial value of the setting themselves if needed.
private void registerSettingsCallbacks() {
// Watch for global HTTP proxy changes.
mSettingsObserver.observe(
Settings.Global.getUriFor(Settings.Global.HTTP_PROXY),
EVENT_APPLY_GLOBAL_HTTP_PROXY);
// Watch for whether to keep mobile data always on.
mSettingsObserver.observe(
Settings.Global.getUriFor(ConnectivitySettingsManager.MOBILE_DATA_ALWAYS_ON),
EVENT_CONFIGURE_ALWAYS_ON_NETWORKS);
// Watch for whether to keep wifi always on.
mSettingsObserver.observe(
Settings.Global.getUriFor(ConnectivitySettingsManager.WIFI_ALWAYS_REQUESTED),
EVENT_CONFIGURE_ALWAYS_ON_NETWORKS);
// Watch for mobile data preferred uids changes.
mSettingsObserver.observe(
Settings.Secure.getUriFor(ConnectivitySettingsManager.MOBILE_DATA_PREFERRED_UIDS),
EVENT_MOBILE_DATA_PREFERRED_UIDS_CHANGED);
// Watch for ingress rate limit changes.
mSettingsObserver.observe(
Settings.Global.getUriFor(
ConnectivitySettingsManager.INGRESS_RATE_LIMIT_BYTES_PER_SECOND),
EVENT_INGRESS_RATE_LIMIT_CHANGED);
}
private void registerPrivateDnsSettingsCallbacks() {
for (Uri uri : DnsManager.getPrivateDnsSettingsUris()) {
mSettingsObserver.observe(uri, EVENT_PRIVATE_DNS_SETTINGS_CHANGED);
}
}
private synchronized int nextNetworkRequestId() {
// TODO: Consider handle wrapping and exclude {@link NetworkRequest#REQUEST_ID_NONE} if
// doing that.
return mNextNetworkRequestId++;
}
@VisibleForTesting
@Nullable
protected NetworkAgentInfo getNetworkAgentInfoForNetwork(Network network) {
if (network == null) {
return null;
}
return getNetworkAgentInfoForNetId(network.getNetId());
}
private NetworkAgentInfo getNetworkAgentInfoForNetId(int netId) {
synchronized (mNetworkForNetId) {
return mNetworkForNetId.get(netId);
}
}
// TODO: determine what to do when more than one VPN applies to |uid|.
@Nullable
private NetworkAgentInfo getVpnForUid(int uid) {
synchronized (mNetworkForNetId) {
for (int i = 0; i < mNetworkForNetId.size(); i++) {
final NetworkAgentInfo nai = mNetworkForNetId.valueAt(i);
if (nai.isVPN() && nai.everConnected()
&& nai.networkCapabilities.appliesToUid(uid)) {
return nai;
}
}
}
return null;
}
@Nullable
private Network[] getVpnUnderlyingNetworks(int uid) {
if (mLockdownEnabled) return null;
final NetworkAgentInfo nai = getVpnForUid(uid);
if (nai != null) return nai.declaredUnderlyingNetworks;
return null;
}
private NetworkAgentInfo getNetworkAgentInfoForUid(int uid) {
NetworkAgentInfo nai = getDefaultNetworkForUid(uid);
final Network[] networks = getVpnUnderlyingNetworks(uid);
if (networks != null) {
// getUnderlyingNetworks() returns:
// null => there was no VPN, or the VPN didn't specify anything, so we use the default.
// empty array => the VPN explicitly said "no default network".
// non-empty array => the VPN specified one or more default networks; we use the
// first one.
if (networks.length > 0) {
nai = getNetworkAgentInfoForNetwork(networks[0]);
} else {
nai = null;
}
}
return nai;
}
/**
* Check if UID should be blocked from using the specified network.
*/
private boolean isNetworkWithCapabilitiesBlocked(@Nullable final NetworkCapabilities nc,
final int uid, final boolean ignoreBlocked) {
// Networks aren't blocked when ignoring blocked status
if (ignoreBlocked) {
return false;
}
if (isUidBlockedByVpn(uid, mVpnBlockedUidRanges)) return true;
final long ident = Binder.clearCallingIdentity();
try {
final boolean metered = nc == null ? true : nc.isMetered();
return mPolicyManager.isUidNetworkingBlocked(uid, metered);
} finally {
Binder.restoreCallingIdentity(ident);
}
}
private void maybeLogBlockedNetworkInfo(NetworkInfo ni, int uid) {
if (ni == null || !LOGD_BLOCKED_NETWORKINFO) {
return;
}
final boolean blocked;
synchronized (mBlockedAppUids) {
if (ni.getDetailedState() == DetailedState.BLOCKED && mBlockedAppUids.add(uid)) {
blocked = true;
} else if (ni.isConnected() && mBlockedAppUids.remove(uid)) {
blocked = false;
} else {
return;
}
}
String action = blocked ? "BLOCKED" : "UNBLOCKED";
log(String.format("Returning %s NetworkInfo to uid=%d", action, uid));
mNetworkInfoBlockingLogs.log(action + " " + uid);
}
private void maybeLogBlockedStatusChanged(NetworkRequestInfo nri, Network net, int blocked) {
if (nri == null || net == null || !LOGD_BLOCKED_NETWORKINFO) {
return;
}
final String action = (blocked != 0) ? "BLOCKED" : "UNBLOCKED";
final int requestId = nri.getActiveRequest() != null
? nri.getActiveRequest().requestId : nri.mRequests.get(0).requestId;
mNetworkInfoBlockingLogs.log(String.format(
"%s %d(%d) on netId %d: %s", action, nri.mAsUid, requestId, net.getNetId(),
Integer.toHexString(blocked)));
}
/**
* Apply any relevant filters to the specified {@link NetworkInfo} for the given UID. For
* example, this may mark the network as {@link DetailedState#BLOCKED} based
* on {@link #isNetworkWithCapabilitiesBlocked}.
*/
@NonNull
private NetworkInfo filterNetworkInfo(@NonNull NetworkInfo networkInfo, int type,
@NonNull NetworkCapabilities nc, int uid, boolean ignoreBlocked) {
final NetworkInfo filtered = new NetworkInfo(networkInfo);
// Many legacy types (e.g,. TYPE_MOBILE_HIPRI) are not actually a property of the network
// but only exists if an app asks about them or requests them. Ensure the requesting app
// gets the type it asks for.
filtered.setType(type);
if (isNetworkWithCapabilitiesBlocked(nc, uid, ignoreBlocked)) {
filtered.setDetailedState(DetailedState.BLOCKED, null /* reason */,
null /* extraInfo */);
}
filterForLegacyLockdown(filtered);
return filtered;
}
private NetworkInfo getFilteredNetworkInfo(NetworkAgentInfo nai, int uid,
boolean ignoreBlocked) {
return filterNetworkInfo(nai.networkInfo, nai.networkInfo.getType(),
nai.networkCapabilities, uid, ignoreBlocked);
}
/**
* Return NetworkInfo for the active (i.e., connected) network interface.
* It is assumed that at most one network is active at a time. If more
* than one is active, it is indeterminate which will be returned.
* @return the info for the active network, or {@code null} if none is
* active
*/
@Override
@Nullable
public NetworkInfo getActiveNetworkInfo() {
enforceAccessPermission();
final int uid = mDeps.getCallingUid();
final NetworkAgentInfo nai = getNetworkAgentInfoForUid(uid);
if (nai == null) return null;
final NetworkInfo networkInfo = getFilteredNetworkInfo(nai, uid, false);
maybeLogBlockedNetworkInfo(networkInfo, uid);
return networkInfo;
}
@Override
@Nullable
public Network getActiveNetwork() {
enforceAccessPermission();
return getActiveNetworkForUidInternal(mDeps.getCallingUid(), false);
}
@Override
@Nullable
public Network getActiveNetworkForUid(int uid, boolean ignoreBlocked) {
enforceNetworkStackPermission(mContext);
return getActiveNetworkForUidInternal(uid, ignoreBlocked);
}
@Nullable
private Network getActiveNetworkForUidInternal(final int uid, boolean ignoreBlocked) {
final NetworkAgentInfo vpnNai = getVpnForUid(uid);
if (vpnNai != null) {
final NetworkCapabilities requiredCaps = createDefaultNetworkCapabilitiesForUid(uid);
if (requiredCaps.satisfiedByNetworkCapabilities(vpnNai.networkCapabilities)) {
return vpnNai.network;
}
}
NetworkAgentInfo nai = getDefaultNetworkForUid(uid);
if (nai == null || isNetworkWithCapabilitiesBlocked(nai.networkCapabilities, uid,
ignoreBlocked)) {
return null;
}
return nai.network;
}
@Override
@Nullable
public NetworkInfo getActiveNetworkInfoForUid(int uid, boolean ignoreBlocked) {
enforceNetworkStackPermission(mContext);
final NetworkAgentInfo nai = getNetworkAgentInfoForUid(uid);
if (nai == null) return null;
return getFilteredNetworkInfo(nai, uid, ignoreBlocked);
}
/** Returns a NetworkInfo object for a network that doesn't exist. */
private NetworkInfo makeFakeNetworkInfo(int networkType, int uid) {
final NetworkInfo info = new NetworkInfo(networkType, 0 /* subtype */,
getNetworkTypeName(networkType), "" /* subtypeName */);
info.setIsAvailable(true);
// For compatibility with legacy code, return BLOCKED instead of DISCONNECTED when
// background data is restricted.
final NetworkCapabilities nc = new NetworkCapabilities(); // Metered.
final DetailedState state = isNetworkWithCapabilitiesBlocked(nc, uid, false)
? DetailedState.BLOCKED
: DetailedState.DISCONNECTED;
info.setDetailedState(state, null /* reason */, null /* extraInfo */);
filterForLegacyLockdown(info);
return info;
}
private NetworkInfo getFilteredNetworkInfoForType(int networkType, int uid) {
if (!mLegacyTypeTracker.isTypeSupported(networkType)) {
return null;
}
final NetworkAgentInfo nai = mLegacyTypeTracker.getNetworkForType(networkType);
if (nai == null) {
return makeFakeNetworkInfo(networkType, uid);
}
return filterNetworkInfo(nai.networkInfo, networkType, nai.networkCapabilities, uid,
false);
}
@Override
@Nullable
public NetworkInfo getNetworkInfo(int networkType) {
enforceAccessPermission();
final int uid = mDeps.getCallingUid();
if (getVpnUnderlyingNetworks(uid) != null) {
// A VPN is active, so we may need to return one of its underlying networks. This
// information is not available in LegacyTypeTracker, so we have to get it from
// getNetworkAgentInfoForUid.
final NetworkAgentInfo nai = getNetworkAgentInfoForUid(uid);
if (nai == null) return null;
final NetworkInfo networkInfo = getFilteredNetworkInfo(nai, uid, false);
if (networkInfo.getType() == networkType) {
return networkInfo;
}
}
return getFilteredNetworkInfoForType(networkType, uid);
}
@Override
@Nullable
public NetworkInfo getNetworkInfoForUid(Network network, int uid, boolean ignoreBlocked) {
enforceAccessPermission();
final NetworkAgentInfo nai = getNetworkAgentInfoForNetwork(network);
if (nai == null) return null;
return getFilteredNetworkInfo(nai, uid, ignoreBlocked);
}
@Override
public NetworkInfo[] getAllNetworkInfo() {
enforceAccessPermission();
final ArrayList<NetworkInfo> result = new ArrayList<>();
for (int networkType = 0; networkType <= ConnectivityManager.MAX_NETWORK_TYPE;
networkType++) {
NetworkInfo info = getNetworkInfo(networkType);
if (info != null) {
result.add(info);
}
}
return result.toArray(new NetworkInfo[result.size()]);
}
@Override
@Nullable
public Network getNetworkForType(int networkType) {
enforceAccessPermission();
if (!mLegacyTypeTracker.isTypeSupported(networkType)) {
return null;
}
final NetworkAgentInfo nai = mLegacyTypeTracker.getNetworkForType(networkType);
if (nai == null) {
return null;
}
final int uid = mDeps.getCallingUid();
if (isNetworkWithCapabilitiesBlocked(nai.networkCapabilities, uid, false)) {
return null;
}
return nai.network;
}
@Override
@NonNull
public Network[] getAllNetworks() {
enforceAccessPermission();
synchronized (mNetworkForNetId) {
final Network[] result = new Network[mNetworkForNetId.size()];
for (int i = 0; i < mNetworkForNetId.size(); i++) {
result[i] = mNetworkForNetId.valueAt(i).network;
}
return result;
}
}
@Override
public NetworkCapabilities[] getDefaultNetworkCapabilitiesForUser(
int userId, String callingPackageName, @Nullable String callingAttributionTag) {
// The basic principle is: if an app's traffic could possibly go over a
// network, without the app doing anything multinetwork-specific,
// (hence, by "default"), then include that network's capabilities in
// the array.
//
// In the normal case, app traffic only goes over the system's default
// network connection, so that's the only network returned.
//
// With a VPN in force, some app traffic may go into the VPN, and thus
// over whatever underlying networks the VPN specifies, while other app
// traffic may go over the system default network (e.g.: a split-tunnel
// VPN, or an app disallowed by the VPN), so the set of networks
// returned includes the VPN's underlying networks and the system
// default.
enforceAccessPermission();
HashMap<Network, NetworkCapabilities> result = new HashMap<>();
for (final NetworkRequestInfo nri : mDefaultNetworkRequests) {
if (!nri.isBeingSatisfied()) {
continue;
}
final NetworkAgentInfo nai = nri.getSatisfier();
final NetworkCapabilities nc = getNetworkCapabilitiesInternal(nai);
if (null != nc
&& nc.hasCapability(NET_CAPABILITY_NOT_RESTRICTED)
&& !result.containsKey(nai.network)) {
result.put(
nai.network,
createWithLocationInfoSanitizedIfNecessaryWhenParceled(
nc, false /* includeLocationSensitiveInfo */,
getCallingPid(), mDeps.getCallingUid(), callingPackageName,
callingAttributionTag));
}
}
// No need to check mLockdownEnabled. If it's true, getVpnUnderlyingNetworks returns null.
final Network[] networks = getVpnUnderlyingNetworks(mDeps.getCallingUid());
if (null != networks) {
for (final Network network : networks) {
final NetworkCapabilities nc = getNetworkCapabilitiesInternal(network);
if (null != nc) {
result.put(
network,
createWithLocationInfoSanitizedIfNecessaryWhenParceled(
nc,
false /* includeLocationSensitiveInfo */,
getCallingPid(), mDeps.getCallingUid(), callingPackageName,
callingAttributionTag));
}
}
}
NetworkCapabilities[] out = new NetworkCapabilities[result.size()];
out = result.values().toArray(out);
return out;
}
// Because StatsEvent is not usable in tests (everything inside it is hidden), this
// method is used to convert a ConnectivityStateSample into a StatsEvent, so that tests
// can call sampleConnectivityState and make the checks on it.
@NonNull
private StatsEvent sampleConnectivityStateToStatsEvent() {
final ConnectivityStateSample sample = sampleConnectivityState();
return ConnectivityStatsLog.buildStatsEvent(
ConnectivityStatsLog.CONNECTIVITY_STATE_SAMPLE,
sample.getNetworkCountPerTransports().toByteArray(),
sample.getConnectionDurationPerTransports().toByteArray(),
sample.getNetworkRequestCount().toByteArray(),
sample.getNetworks().toByteArray());
}
/**
* Gather and return a snapshot of the current connectivity state, to be used as a sample.
*
* This is used for metrics. These snapshots will be sampled and constitute a base for
* statistics about connectivity state of devices.
*/
@VisibleForTesting
@NonNull
public ConnectivityStateSample sampleConnectivityState() {
ensureRunningOnConnectivityServiceThread();
final ConnectivityStateSample.Builder builder = ConnectivityStateSample.newBuilder();
builder.setNetworkCountPerTransports(sampleNetworkCount(mNetworkAgentInfos));
builder.setConnectionDurationPerTransports(sampleConnectionDuration(mNetworkAgentInfos));
builder.setNetworkRequestCount(sampleNetworkRequestCount(mNetworkRequests.values()));
builder.setNetworks(sampleNetworks(mNetworkAgentInfos));
return builder.build();
}
private static NetworkCountPerTransports sampleNetworkCount(
@NonNull final ArraySet<NetworkAgentInfo> nais) {
final SparseIntArray countPerTransports = new SparseIntArray();
for (final NetworkAgentInfo nai : nais) {
int transports = (int) nai.networkCapabilities.getTransportTypesInternal();
countPerTransports.put(transports, 1 + countPerTransports.get(transports, 0));
}
final NetworkCountPerTransports.Builder builder = NetworkCountPerTransports.newBuilder();
for (int i = countPerTransports.size() - 1; i >= 0; --i) {
final NetworkCountForTransports.Builder c = NetworkCountForTransports.newBuilder();
c.setTransportTypes(countPerTransports.keyAt(i));
c.setNetworkCount(countPerTransports.valueAt(i));
builder.addNetworkCountForTransports(c);
}
return builder.build();
}
private static ConnectionDurationPerTransports sampleConnectionDuration(
@NonNull final ArraySet<NetworkAgentInfo> nais) {
final ConnectionDurationPerTransports.Builder builder =
ConnectionDurationPerTransports.newBuilder();
for (final NetworkAgentInfo nai : nais) {
final ConnectionDurationForTransports.Builder c =
ConnectionDurationForTransports.newBuilder();
c.setTransportTypes((int) nai.networkCapabilities.getTransportTypesInternal());
final long durationMillis = SystemClock.elapsedRealtime() - nai.getConnectedTime();
final long millisPerSecond = TimeUnit.SECONDS.toMillis(1);
// Add millisPerSecond/2 to round up or down to the nearest value
c.setDurationSec((int) ((durationMillis + millisPerSecond / 2) / millisPerSecond));
builder.addConnectionDurationForTransports(c);
}
return builder.build();
}
private static NetworkRequestCount sampleNetworkRequestCount(
@NonNull final Collection<NetworkRequestInfo> nris) {
final NetworkRequestCount.Builder builder = NetworkRequestCount.newBuilder();
final SparseIntArray countPerType = new SparseIntArray();
for (final NetworkRequestInfo nri : nris) {
final int type;
if (Process.SYSTEM_UID == nri.mAsUid) {
// The request is filed "as" the system, so it's the system on its own behalf.
type = RequestType.RT_SYSTEM.getNumber();
} else if (Process.SYSTEM_UID == nri.mUid) {
// The request is filed by the system as some other app, so it's the system on
// behalf of an app.
type = RequestType.RT_SYSTEM_ON_BEHALF_OF_APP.getNumber();
} else {
// Not the system, so it's an app requesting on its own behalf.
type = RequestType.RT_APP.getNumber();
}
countPerType.put(type, countPerType.get(type, 0));
}
for (int i = countPerType.size() - 1; i >= 0; --i) {
final RequestCountForType.Builder r = RequestCountForType.newBuilder();
r.setRequestType(RequestType.forNumber(countPerType.keyAt(i)));
r.setRequestCount(countPerType.valueAt(i));
builder.addRequestCountForType(r);
}
return builder.build();
}
private static NetworkList sampleNetworks(@NonNull final ArraySet<NetworkAgentInfo> nais) {
final NetworkList.Builder builder = NetworkList.newBuilder();
for (final NetworkAgentInfo nai : nais) {
final NetworkCapabilities nc = nai.networkCapabilities;
final NetworkDescription.Builder d = NetworkDescription.newBuilder();
d.setTransportTypes((int) nc.getTransportTypesInternal());
final MeteredState meteredState;
if (nc.hasCapability(NET_CAPABILITY_TEMPORARILY_NOT_METERED)) {
meteredState = MeteredState.METERED_TEMPORARILY_UNMETERED;
} else if (nc.hasCapability(NET_CAPABILITY_NOT_METERED)) {
meteredState = MeteredState.METERED_NO;
} else {
meteredState = MeteredState.METERED_YES;
}
d.setMeteredState(meteredState);
final ValidatedState validatedState;
if (nc.hasCapability(NET_CAPABILITY_CAPTIVE_PORTAL)) {
validatedState = ValidatedState.VS_PORTAL;
} else if (nc.hasCapability(NET_CAPABILITY_PARTIAL_CONNECTIVITY)) {
validatedState = ValidatedState.VS_PARTIAL;
} else if (nc.hasCapability(NET_CAPABILITY_VALIDATED)) {
validatedState = ValidatedState.VS_VALID;
} else {
validatedState = ValidatedState.VS_INVALID;
}
d.setValidatedState(validatedState);
d.setScorePolicies(nai.getScore().getPoliciesInternal());
d.setCapabilities(nc.getCapabilitiesInternal());
d.setEnterpriseId(nc.getEnterpriseIdsInternal());
builder.addNetworkDescription(d);
}
return builder.build();
}
@Override
public boolean isNetworkSupported(int networkType) {
enforceAccessPermission();
return mLegacyTypeTracker.isTypeSupported(networkType);
}
/**
* Return LinkProperties for the active (i.e., connected) default
* network interface for the calling uid.
* @return the ip properties for the active network, or {@code null} if
* none is active
*/
@Override
public LinkProperties getActiveLinkProperties() {
enforceAccessPermission();
final int uid = mDeps.getCallingUid();
NetworkAgentInfo nai = getNetworkAgentInfoForUid(uid);
if (nai == null) return null;
return linkPropertiesRestrictedForCallerPermissions(nai.linkProperties,
Binder.getCallingPid(), uid);
}
@Override
public LinkProperties getLinkPropertiesForType(int networkType) {
enforceAccessPermission();
NetworkAgentInfo nai = mLegacyTypeTracker.getNetworkForType(networkType);
final LinkProperties lp = getLinkProperties(nai);
if (lp == null) return null;
return linkPropertiesRestrictedForCallerPermissions(
lp, Binder.getCallingPid(), mDeps.getCallingUid());
}
// TODO - this should be ALL networks
@Override
public LinkProperties getLinkProperties(Network network) {
enforceAccessPermission();
final LinkProperties lp = getLinkProperties(getNetworkAgentInfoForNetwork(network));
if (lp == null) return null;
return linkPropertiesRestrictedForCallerPermissions(
lp, Binder.getCallingPid(), mDeps.getCallingUid());
}
@Nullable
private LinkProperties getLinkProperties(@Nullable NetworkAgentInfo nai) {
if (nai == null) {
return null;
}
synchronized (nai) {
return nai.linkProperties;
}
}
@Override
@Nullable
public LinkProperties getRedactedLinkPropertiesForPackage(@NonNull LinkProperties lp, int uid,
@NonNull String packageName, @Nullable String callingAttributionTag) {
Objects.requireNonNull(packageName);
Objects.requireNonNull(lp);
enforceNetworkStackOrSettingsPermission();
if (!checkAccessPermission(-1 /* pid */, uid)) {
return null;
}
return linkPropertiesRestrictedForCallerPermissions(lp, -1 /* callerPid */, uid);
}
private NetworkCapabilities getNetworkCapabilitiesInternal(Network network) {
return getNetworkCapabilitiesInternal(getNetworkAgentInfoForNetwork(network));
}
private NetworkCapabilities getNetworkCapabilitiesInternal(NetworkAgentInfo nai) {
if (nai == null) return null;
synchronized (nai) {
return networkCapabilitiesRestrictedForCallerPermissions(
nai.networkCapabilities, Binder.getCallingPid(), mDeps.getCallingUid());
}
}
@Override
public NetworkCapabilities getNetworkCapabilities(Network network, String callingPackageName,
@Nullable String callingAttributionTag) {
mAppOpsManager.checkPackage(mDeps.getCallingUid(), callingPackageName);
enforceAccessPermission();
return createWithLocationInfoSanitizedIfNecessaryWhenParceled(
getNetworkCapabilitiesInternal(network),
false /* includeLocationSensitiveInfo */,
getCallingPid(), mDeps.getCallingUid(), callingPackageName, callingAttributionTag);
}
@Override
public NetworkCapabilities getRedactedNetworkCapabilitiesForPackage(
@NonNull NetworkCapabilities nc, int uid, @NonNull String packageName,
@Nullable String callingAttributionTag) {
Objects.requireNonNull(nc);
Objects.requireNonNull(packageName);
enforceNetworkStackOrSettingsPermission();
if (!checkAccessPermission(-1 /* pid */, uid)) {
return null;
}
return createWithLocationInfoSanitizedIfNecessaryWhenParceled(
networkCapabilitiesRestrictedForCallerPermissions(nc, -1 /* callerPid */, uid),
true /* includeLocationSensitiveInfo */, -1 /* callingPid */, uid, packageName,
callingAttributionTag);
}
private void redactUnderlyingNetworksForCapabilities(NetworkCapabilities nc, int pid, int uid) {
if (nc.getUnderlyingNetworks() != null
&& !checkNetworkFactoryOrSettingsPermission(pid, uid)) {
nc.setUnderlyingNetworks(null);
}
}
private boolean canSeeAllowedUids(final int pid, final int uid, final int netOwnerUid) {
return Process.SYSTEM_UID == uid
|| checkAnyPermissionOf(mContext, pid, uid,
android.Manifest.permission.NETWORK_FACTORY);
}
@VisibleForTesting
NetworkCapabilities networkCapabilitiesRestrictedForCallerPermissions(
NetworkCapabilities nc, int callerPid, int callerUid) {
// Note : here it would be nice to check ACCESS_NETWORK_STATE and return null, but
// this would be expensive (one more permission check every time any NC callback is
// sent) and possibly dangerous : apps normally can't lose ACCESS_NETWORK_STATE, if
// it happens for some reason (e.g. the package is uninstalled while CS is trying to
// send the callback) it would crash the system server with NPE.
final NetworkCapabilities newNc = new NetworkCapabilities(nc);
if (!checkSettingsPermission(callerPid, callerUid)) {
newNc.setUids(null);
newNc.setSSID(null);
}
if (newNc.getNetworkSpecifier() != null) {
newNc.setNetworkSpecifier(newNc.getNetworkSpecifier().redact());
}
if (!checkAnyPermissionOf(mContext, callerPid, callerUid,
android.Manifest.permission.NETWORK_STACK,
NetworkStack.PERMISSION_MAINLINE_NETWORK_STACK)) {
newNc.setAdministratorUids(new int[0]);
}
if (!canSeeAllowedUids(callerPid, callerUid, newNc.getOwnerUid())) {
newNc.setAllowedUids(new ArraySet<>());
newNc.setSubscriptionIds(Collections.emptySet());
}
redactUnderlyingNetworksForCapabilities(newNc, callerPid, callerUid);
return newNc;
}
/**
* Wrapper used to cache the permission check results performed for the corresponding
* app. This avoids performing multiple permission checks for different fields in
* NetworkCapabilities.
* Note: This wrapper does not support any sort of invalidation and thus must not be
* persistent or long-lived. It may only be used for the time necessary to
* compute the redactions required by one particular NetworkCallback or
* synchronous call.
*/
private class RedactionPermissionChecker {
private final int mCallingPid;
private final int mCallingUid;
@NonNull private final String mCallingPackageName;
@Nullable private final String mCallingAttributionTag;
private Boolean mHasLocationPermission = null;
private Boolean mHasLocalMacAddressPermission = null;
private Boolean mHasSettingsPermission = null;
RedactionPermissionChecker(int callingPid, int callingUid,
@NonNull String callingPackageName, @Nullable String callingAttributionTag) {
mCallingPid = callingPid;
mCallingUid = callingUid;
mCallingPackageName = callingPackageName;
mCallingAttributionTag = callingAttributionTag;
}
private boolean hasLocationPermissionInternal() {
final long token = Binder.clearCallingIdentity();
try {
return mLocationPermissionChecker.checkLocationPermission(
mCallingPackageName, mCallingAttributionTag, mCallingUid,
null /* message */);
} finally {
Binder.restoreCallingIdentity(token);
}
}
/**
* Returns whether the app holds location permission or not (might return cached result
* if the permission was already checked before).
*/
public boolean hasLocationPermission() {
if (mHasLocationPermission == null) {
// If there is no cached result, perform the check now.
mHasLocationPermission = hasLocationPermissionInternal();
}
return mHasLocationPermission;
}
/**
* Returns whether the app holds local mac address permission or not (might return cached
* result if the permission was already checked before).
*/
public boolean hasLocalMacAddressPermission() {
if (mHasLocalMacAddressPermission == null) {
// If there is no cached result, perform the check now.
mHasLocalMacAddressPermission =
checkLocalMacAddressPermission(mCallingPid, mCallingUid);
}
return mHasLocalMacAddressPermission;
}
/**
* Returns whether the app holds settings permission or not (might return cached
* result if the permission was already checked before).
*/
public boolean hasSettingsPermission() {
if (mHasSettingsPermission == null) {
// If there is no cached result, perform the check now.
mHasSettingsPermission = checkSettingsPermission(mCallingPid, mCallingUid);
}
return mHasSettingsPermission;
}
}
private static boolean shouldRedact(@NetworkCapabilities.RedactionType long redactions,
@NetworkCapabilities.NetCapability long redaction) {
return (redactions & redaction) != 0;
}
/**
* Use the provided |applicableRedactions| to check the receiving app's
* permissions and clear/set the corresponding bit in the returned bitmask. The bitmask
* returned will be used to ensure the necessary redactions are performed by NetworkCapabilities
* before being sent to the corresponding app.
*/
private @NetworkCapabilities.RedactionType long retrieveRequiredRedactions(
@NetworkCapabilities.RedactionType long applicableRedactions,
@NonNull RedactionPermissionChecker redactionPermissionChecker,
boolean includeLocationSensitiveInfo) {
long redactions = applicableRedactions;
if (shouldRedact(redactions, REDACT_FOR_ACCESS_FINE_LOCATION)) {
if (includeLocationSensitiveInfo
&& redactionPermissionChecker.hasLocationPermission()) {
redactions &= ~REDACT_FOR_ACCESS_FINE_LOCATION;
}
}
if (shouldRedact(redactions, REDACT_FOR_LOCAL_MAC_ADDRESS)) {
if (redactionPermissionChecker.hasLocalMacAddressPermission()) {
redactions &= ~REDACT_FOR_LOCAL_MAC_ADDRESS;
}
}
if (shouldRedact(redactions, REDACT_FOR_NETWORK_SETTINGS)) {
if (redactionPermissionChecker.hasSettingsPermission()) {
redactions &= ~REDACT_FOR_NETWORK_SETTINGS;
}
}
return redactions;
}
@VisibleForTesting
@Nullable
NetworkCapabilities createWithLocationInfoSanitizedIfNecessaryWhenParceled(
@Nullable NetworkCapabilities nc, boolean includeLocationSensitiveInfo,
int callingPid, int callingUid, @NonNull String callingPkgName,
@Nullable String callingAttributionTag) {
if (nc == null) {
return null;
}
// Avoid doing location permission check if the transport info has no location sensitive
// data.
final RedactionPermissionChecker redactionPermissionChecker =
new RedactionPermissionChecker(callingPid, callingUid, callingPkgName,
callingAttributionTag);
final long redactions = retrieveRequiredRedactions(
nc.getApplicableRedactions(), redactionPermissionChecker,
includeLocationSensitiveInfo);
final NetworkCapabilities newNc = new NetworkCapabilities(nc, redactions);
// Reset owner uid if not destined for the owner app.
// TODO : calling UID is redacted because apps should generally not know what UID is
// bringing up the VPN, but this should not apply to some very privileged apps like settings
if (callingUid != nc.getOwnerUid()) {
newNc.setOwnerUid(INVALID_UID);
return newNc;
}
// Allow VPNs to see ownership of their own VPN networks - not location sensitive.
if (nc.hasTransport(TRANSPORT_VPN)) {
// Owner UIDs already checked above. No need to re-check.
return newNc;
}
// If the calling does not want location sensitive data & target SDK >= S, then mask info.
// Else include the owner UID iff the calling has location permission to provide backwards
// compatibility for older apps.
if (!includeLocationSensitiveInfo
&& isTargetSdkAtleast(
Build.VERSION_CODES.S, callingUid, callingPkgName)) {
newNc.setOwnerUid(INVALID_UID);
return newNc;
}
// Reset owner uid if the app has no location permission.
if (!redactionPermissionChecker.hasLocationPermission()) {
newNc.setOwnerUid(INVALID_UID);
}
return newNc;
}
@NonNull
private LinkProperties linkPropertiesRestrictedForCallerPermissions(
LinkProperties lp, int callerPid, int callerUid) {
if (lp == null) return new LinkProperties();
// Note : here it would be nice to check ACCESS_NETWORK_STATE and return null, but
// this would be expensive (one more permission check every time any LP callback is
// sent) and possibly dangerous : apps normally can't lose ACCESS_NETWORK_STATE, if
// it happens for some reason (e.g. the package is uninstalled while CS is trying to
// send the callback) it would crash the system server with NPE.
// Only do a permission check if sanitization is needed, to avoid unnecessary binder calls.
final boolean needsSanitization =
(lp.getCaptivePortalApiUrl() != null || lp.getCaptivePortalData() != null);
if (!needsSanitization) {
return new LinkProperties(lp);
}
if (checkSettingsPermission(callerPid, callerUid)) {
return new LinkProperties(lp, true /* parcelSensitiveFields */);
}
final LinkProperties newLp = new LinkProperties(lp);
// Sensitive fields would not be parceled anyway, but sanitize for consistency before the
// object gets parceled.
newLp.setCaptivePortalApiUrl(null);
newLp.setCaptivePortalData(null);
return newLp;
}
private void restrictRequestUidsForCallerAndSetRequestorInfo(NetworkCapabilities nc,
int callerUid, String callerPackageName) {
// There is no need to track the effective UID of the request here. If the caller
// lacks the settings permission, the effective UID is the same as the calling ID.
if (!checkSettingsPermission()) {
// Unprivileged apps can only pass in null or their own UID.
if (nc.getUids() == null) {
// If the caller passes in null, the callback will also match networks that do not
// apply to its UID, similarly to what it would see if it called getAllNetworks.
// In this case, redact everything in the request immediately. This ensures that the
// app is not able to get any redacted information by filing an unredacted request
// and observing whether the request matches something.
if (nc.getNetworkSpecifier() != null) {
nc.setNetworkSpecifier(nc.getNetworkSpecifier().redact());
}
} else {
nc.setSingleUid(callerUid);
}
}
nc.setRequestorUidAndPackageName(callerUid, callerPackageName);
nc.setAdministratorUids(new int[0]);
// Clear owner UID; this can never come from an app.
nc.setOwnerUid(INVALID_UID);
}
private void restrictBackgroundRequestForCaller(NetworkCapabilities nc) {
if (!mPermissionMonitor.hasUseBackgroundNetworksPermission(mDeps.getCallingUid())) {
nc.addCapability(NET_CAPABILITY_FOREGROUND);
}
}
@Override
public @RestrictBackgroundStatus int getRestrictBackgroundStatusByCaller() {
enforceAccessPermission();
final int callerUid = Binder.getCallingUid();
final long token = Binder.clearCallingIdentity();
try {
return mPolicyManager.getRestrictBackgroundStatus(callerUid);
} finally {
Binder.restoreCallingIdentity(token);
}
}
// TODO: Consider delete this function or turn it into a no-op method.
@Override
public NetworkState[] getAllNetworkState() {
// This contains IMSI details, so make sure the caller is privileged.
enforceNetworkStackPermission(mContext);
final ArrayList<NetworkState> result = new ArrayList<>();
for (NetworkStateSnapshot snapshot : getAllNetworkStateSnapshots()) {
// NetworkStateSnapshot doesn't contain NetworkInfo, so need to fetch it from the
// NetworkAgentInfo.
final NetworkAgentInfo nai = getNetworkAgentInfoForNetwork(snapshot.getNetwork());
if (nai != null && nai.networkInfo.isConnected()) {
result.add(new NetworkState(new NetworkInfo(nai.networkInfo),
snapshot.getLinkProperties(), snapshot.getNetworkCapabilities(),
snapshot.getNetwork(), snapshot.getSubscriberId()));
}
}
return result.toArray(new NetworkState[0]);
}
@Override
@NonNull
public List<NetworkStateSnapshot> getAllNetworkStateSnapshots() {
// This contains IMSI details, so make sure the caller is privileged.
enforceNetworkStackOrSettingsPermission();
final ArrayList<NetworkStateSnapshot> result = new ArrayList<>();
for (Network network : getAllNetworks()) {
final NetworkAgentInfo nai = getNetworkAgentInfoForNetwork(network);
final boolean includeNetwork = (nai != null) && nai.isCreated();
if (includeNetwork) {
// TODO (b/73321673) : NetworkStateSnapshot contains a copy of the
// NetworkCapabilities, which may contain UIDs of apps to which the
// network applies. Should the UIDs be cleared so as not to leak or
// interfere ?
result.add(nai.getNetworkStateSnapshot());
}
}
return result;
}
@Override
public boolean isActiveNetworkMetered() {
enforceAccessPermission();
final NetworkCapabilities caps = getNetworkCapabilitiesInternal(getActiveNetwork());
if (caps != null) {
return !caps.hasCapability(NetworkCapabilities.NET_CAPABILITY_NOT_METERED);
} else {
// Always return the most conservative value
return true;
}
}
/**
* Ensures that the system cannot call a particular method.
*/
private boolean disallowedBecauseSystemCaller() {
// TODO: start throwing a SecurityException when GnssLocationProvider stops calling
// requestRouteToHost. In Q, GnssLocationProvider is changed to not call requestRouteToHost
// for devices launched with Q and above. However, existing devices upgrading to Q and
// above must continued to be supported for few more releases.
if (isSystem(mDeps.getCallingUid()) && SystemProperties.getInt(
"ro.product.first_api_level", 0) > Build.VERSION_CODES.P) {
log("This method exists only for app backwards compatibility"
+ " and must not be called by system services.");
return true;
}
return false;
}
private int getAppUid(final String app, final UserHandle user) {
final PackageManager pm =
mContext.createContextAsUser(user, 0 /* flags */).getPackageManager();
final long token = Binder.clearCallingIdentity();
try {
return pm.getPackageUid(app, 0 /* flags */);
} catch (PackageManager.NameNotFoundException e) {
return -1;
} finally {
Binder.restoreCallingIdentity(token);
}
}
private void verifyCallingUidAndPackage(String packageName, int callingUid) {
final UserHandle user = UserHandle.getUserHandleForUid(callingUid);
if (getAppUid(packageName, user) != callingUid) {
throw new SecurityException(packageName + " does not belong to uid " + callingUid);
}
}
/**
* Ensure that a network route exists to deliver traffic to the specified
* host via the specified network interface.
* @param networkType the type of the network over which traffic to the
* specified host is to be routed
* @param hostAddress the IP address of the host to which the route is
* desired
* @return {@code true} on success, {@code false} on failure
*/
@Override
public boolean requestRouteToHostAddress(int networkType, byte[] hostAddress,
String callingPackageName, String callingAttributionTag) {
if (disallowedBecauseSystemCaller()) {
return false;
}
verifyCallingUidAndPackage(callingPackageName, mDeps.getCallingUid());
enforceChangePermission(callingPackageName, callingAttributionTag);
if (mProtectedNetworks.contains(networkType)) {
enforceConnectivityRestrictedNetworksPermission(true /* checkUidsAllowedList */);
}
InetAddress addr;
try {
addr = InetAddress.getByAddress(hostAddress);
} catch (UnknownHostException e) {
if (DBG) log("requestRouteToHostAddress got " + e);
return false;
}
if (!ConnectivityManager.isNetworkTypeValid(networkType)) {
if (DBG) log("requestRouteToHostAddress on invalid network: " + networkType);
return false;
}
NetworkAgentInfo nai = mLegacyTypeTracker.getNetworkForType(networkType);
if (nai == null) {
if (!mLegacyTypeTracker.isTypeSupported(networkType)) {
if (DBG) log("requestRouteToHostAddress on unsupported network: " + networkType);
} else {
if (DBG) log("requestRouteToHostAddress on down network: " + networkType);
}
return false;
}
DetailedState netState;
synchronized (nai) {
netState = nai.networkInfo.getDetailedState();
}
if (netState != DetailedState.CONNECTED && netState != DetailedState.CAPTIVE_PORTAL_CHECK) {
if (VDBG) {
log("requestRouteToHostAddress on down network "
+ "(" + networkType + ") - dropped"
+ " netState=" + netState);
}
return false;
}
final int uid = mDeps.getCallingUid();
final long token = Binder.clearCallingIdentity();
try {
LinkProperties lp;
int netId;
synchronized (nai) {
lp = nai.linkProperties;
netId = nai.network.getNetId();
}
boolean ok = addLegacyRouteToHost(lp, addr, netId, uid);
if (DBG) {
log("requestRouteToHostAddress " + addr + nai.toShortString() + " ok=" + ok);
}
return ok;
} finally {
Binder.restoreCallingIdentity(token);
}
}
private boolean addLegacyRouteToHost(LinkProperties lp, InetAddress addr, int netId, int uid) {
RouteInfo bestRoute = RouteInfo.selectBestRoute(lp.getAllRoutes(), addr);
if (bestRoute == null) {
bestRoute = RouteInfo.makeHostRoute(addr, lp.getInterfaceName());
} else {
String iface = bestRoute.getInterface();
if (bestRoute.getGateway().equals(addr)) {
// if there is no better route, add the implied hostroute for our gateway
bestRoute = RouteInfo.makeHostRoute(addr, iface);
} else {
// if we will connect to this through another route, add a direct route
// to it's gateway
bestRoute = RouteInfo.makeHostRoute(addr, bestRoute.getGateway(), iface);
}
}
if (DBG) log("Adding legacy route " + bestRoute +
" for UID/PID " + uid + "/" + Binder.getCallingPid());
final String dst = bestRoute.getDestinationLinkAddress().toString();
final String nextHop = bestRoute.hasGateway()
? bestRoute.getGateway().getHostAddress() : "";
try {
mNetd.networkAddLegacyRoute(netId, bestRoute.getInterface(), dst, nextHop , uid);
} catch (RemoteException | ServiceSpecificException e) {
if (DBG) loge("Exception trying to add a route: " + e);
return false;
}
return true;
}
class DnsResolverUnsolicitedEventCallback extends
IDnsResolverUnsolicitedEventListener.Stub {
@Override
public void onPrivateDnsValidationEvent(final PrivateDnsValidationEventParcel event) {
try {
mHandler.sendMessage(mHandler.obtainMessage(
EVENT_PRIVATE_DNS_VALIDATION_UPDATE,
new PrivateDnsValidationUpdate(event.netId,
InetAddresses.parseNumericAddress(event.ipAddress),
event.hostname, event.validation)));
} catch (IllegalArgumentException e) {
loge("Error parsing ip address in validation event");
}
}
@Override
public void onDnsHealthEvent(final DnsHealthEventParcel event) {
NetworkAgentInfo nai = getNetworkAgentInfoForNetId(event.netId);
// Netd event only allow registrants from system. Each NetworkMonitor thread is under
// the caller thread of registerNetworkAgent. Thus, it's not allowed to register netd
// event callback for certain nai. e.g. cellular. Register here to pass to
// NetworkMonitor instead.
// TODO: Move the Dns Event to NetworkMonitor. NetdEventListenerService only allows one
// callback from each caller type. Need to re-factor NetdEventListenerService to allow
// multiple NetworkMonitor registrants.
if (nai != null && nai.satisfies(mDefaultRequest.mRequests.get(0))) {
nai.networkMonitor().notifyDnsResponse(event.healthResult);
}
}
@Override
public void onNat64PrefixEvent(final Nat64PrefixEventParcel event) {
mHandler.post(() -> handleNat64PrefixEvent(event.netId, event.prefixOperation,
event.prefixAddress, event.prefixLength));
}
@Override
public int getInterfaceVersion() {
return this.VERSION;
}
@Override
public String getInterfaceHash() {
return this.HASH;
}
}
@VisibleForTesting
protected final DnsResolverUnsolicitedEventCallback mResolverUnsolEventCallback =
new DnsResolverUnsolicitedEventCallback();
private void registerDnsResolverUnsolicitedEventListener() {
try {
mDnsResolver.registerUnsolicitedEventListener(mResolverUnsolEventCallback);
} catch (Exception e) {
loge("Error registering DnsResolver unsolicited event callback: " + e);
}
}
private final NetworkPolicyCallback mPolicyCallback = new NetworkPolicyCallback() {
@Override
public void onUidBlockedReasonChanged(int uid, @BlockedReason int blockedReasons) {
mHandler.sendMessage(mHandler.obtainMessage(EVENT_UID_BLOCKED_REASON_CHANGED,
uid, blockedReasons));
}
};
private void handleUidBlockedReasonChanged(int uid, @BlockedReason int blockedReasons) {
maybeNotifyNetworkBlockedForNewState(uid, blockedReasons);
setUidBlockedReasons(uid, blockedReasons);
}
static final class UidFrozenStateChangedArgs {
final int[] mUids;
final int[] mFrozenStates;
UidFrozenStateChangedArgs(int[] uids, int[] frozenStates) {
mUids = uids;
mFrozenStates = frozenStates;
}
}
/**
* Check if the cell network is idle.
* @return true if the cell network state is idle
* false if the cell network state is active or unknown
*/
private boolean isCellNetworkIdle() {
final NetworkAgentInfo defaultNai = getDefaultNetwork();
if (defaultNai == null
|| !defaultNai.networkCapabilities.hasTransport(TRANSPORT_CELLULAR)) {
// mNetworkActivityTracker only tracks the activity of the default network. So if the
// cell network is not the default network, cell network state is unknown.
// TODO(b/279380356): Track cell network state when the cell is not the default network
return false;
}
return !mNetworkActivityTracker.isDefaultNetworkActive();
}
private void handleFrozenUids(int[] uids, int[] frozenStates) {
final ArraySet<Integer> ownerUids = new ArraySet<>();
for (int i = 0; i < uids.length; i++) {
if (frozenStates[i] == UID_FROZEN_STATE_FROZEN) {
ownerUids.add(uids[i]);
} else {
mPendingFrozenUids.remove(uids[i]);
}
}
if (ownerUids.isEmpty()) {
return;
}
if (mDelayDestroyFrozenSockets && isCellNetworkIdle()) {
// Delay closing sockets to avoid waking the cell modem up.
// Wi-Fi network state is not considered since waking Wi-Fi modem up is much cheaper
// than waking cell modem up.
mPendingFrozenUids.addAll(ownerUids);
} else {
try {
mDeps.destroyLiveTcpSocketsByOwnerUids(ownerUids);
} catch (SocketException | InterruptedIOException | ErrnoException e) {
loge("Exception in socket destroy: " + e);
}
}
}
private void closePendingFrozenSockets() {
ensureRunningOnConnectivityServiceThread();
try {
mDeps.destroyLiveTcpSocketsByOwnerUids(mPendingFrozenUids);
} catch (SocketException | InterruptedIOException | ErrnoException e) {
loge("Failed to close pending frozen app sockets: " + e);
}
mPendingFrozenUids.clear();
}
private void handleReportNetworkActivity(final NetworkActivityParams params) {
mNetworkActivityTracker.handleReportNetworkActivity(params);
final boolean isCellNetworkActivity;
if (mTrackMultiNetworkActivities) {
final NetworkAgentInfo nai = getNetworkAgentInfoForNetId(params.label);
// nai could be null if netd receives a netlink message and calls the network
// activity change callback after the network is unregistered from ConnectivityService.
isCellNetworkActivity = nai != null
&& nai.networkCapabilities.hasTransport(TRANSPORT_CELLULAR);
} else {
isCellNetworkActivity = params.label == TRANSPORT_CELLULAR;
}
if (mDelayDestroyFrozenSockets
&& params.isActive
&& isCellNetworkActivity
&& !mPendingFrozenUids.isEmpty()) {
closePendingFrozenSockets();
}
}
/**
* If the cellular network is no longer the default network, close pending frozen sockets.
*
* @param newNetwork new default network
* @param oldNetwork old default network
*/
private void maybeClosePendingFrozenSockets(NetworkAgentInfo newNetwork,
NetworkAgentInfo oldNetwork) {
final boolean isOldNetworkCellular = oldNetwork != null
&& oldNetwork.networkCapabilities.hasTransport(TRANSPORT_CELLULAR);
final boolean isNewNetworkCellular = newNetwork != null
&& newNetwork.networkCapabilities.hasTransport(TRANSPORT_CELLULAR);
if (isOldNetworkCellular
&& !isNewNetworkCellular
&& !mPendingFrozenUids.isEmpty()) {
closePendingFrozenSockets();
}
}
private void dumpCloseFrozenAppSockets(IndentingPrintWriter pw) {
pw.println("CloseFrozenAppSockets:");
pw.increaseIndent();
pw.print("mDestroyFrozenSockets="); pw.println(mDestroyFrozenSockets);
pw.print("mDelayDestroyFrozenSockets="); pw.println(mDelayDestroyFrozenSockets);
pw.print("mPendingFrozenUids="); pw.println(mPendingFrozenUids);
pw.decreaseIndent();
}
private void dumpBpfProgramStatus(IndentingPrintWriter pw) {
pw.println("Bpf Program Status:");
pw.increaseIndent();
try {
pw.print("CGROUP_INET_INGRESS: ");
pw.println(mDeps.getBpfProgramId(BPF_CGROUP_INET_INGRESS));
pw.print("CGROUP_INET_EGRESS: ");
pw.println(mDeps.getBpfProgramId(BPF_CGROUP_INET_EGRESS));
pw.print("CGROUP_INET_SOCK_CREATE: ");
pw.println(mDeps.getBpfProgramId(BPF_CGROUP_INET_SOCK_CREATE));
pw.print("CGROUP_INET4_BIND: ");
pw.println(mDeps.getBpfProgramId(BPF_CGROUP_INET4_BIND));
pw.print("CGROUP_INET6_BIND: ");
pw.println(mDeps.getBpfProgramId(BPF_CGROUP_INET6_BIND));
} catch (IOException e) {
pw.println(" IOException");
}
pw.decreaseIndent();
}
@VisibleForTesting
static final String KEY_DESTROY_FROZEN_SOCKETS_VERSION = "destroy_frozen_sockets_version";
@VisibleForTesting
static final String DELAY_DESTROY_FROZEN_SOCKETS_VERSION =
"delay_destroy_frozen_sockets_version";
@VisibleForTesting
public static final String ALLOW_SYSUI_CONNECTIVITY_REPORTS =
"allow_sysui_connectivity_reports";
public static final String LOG_BPF_RC = "log_bpf_rc_force_disable";
private void enforceInternetPermission() {
mContext.enforceCallingOrSelfPermission(
android.Manifest.permission.INTERNET,
"ConnectivityService");
}
private void enforceAccessPermission() {
mContext.enforceCallingOrSelfPermission(
android.Manifest.permission.ACCESS_NETWORK_STATE,
"ConnectivityService");
}
private boolean checkAccessPermission(int pid, int uid) {
return mContext.checkPermission(android.Manifest.permission.ACCESS_NETWORK_STATE, pid, uid)
== PERMISSION_GRANTED;
}
/**
* Performs a strict and comprehensive check of whether a calling package is allowed to
* change the state of network, as the condition differs for pre-M, M+, and
* privileged/preinstalled apps. The caller is expected to have either the
* CHANGE_NETWORK_STATE or the WRITE_SETTINGS permission declared. Either of these
* permissions allow changing network state; WRITE_SETTINGS is a runtime permission and
* can be revoked, but (except in M, excluding M MRs), CHANGE_NETWORK_STATE is a normal
* permission and cannot be revoked. See http://b/23597341
*
* Note: if the check succeeds because the application holds WRITE_SETTINGS, the operation
* of this app will be updated to the current time.
*/
private void enforceChangePermission(String callingPkg, String callingAttributionTag) {
if (mContext.checkCallingOrSelfPermission(android.Manifest.permission.CHANGE_NETWORK_STATE)
== PackageManager.PERMISSION_GRANTED) {
return;
}
if (callingPkg == null) {
throw new SecurityException("Calling package name is null.");
}
final AppOpsManager appOpsMgr = mContext.getSystemService(AppOpsManager.class);
final int uid = mDeps.getCallingUid();
final int mode = appOpsMgr.noteOpNoThrow(AppOpsManager.OPSTR_WRITE_SETTINGS, uid,
callingPkg, callingAttributionTag, null /* message */);
if (mode == AppOpsManager.MODE_ALLOWED) {
return;
}
if ((mode == AppOpsManager.MODE_DEFAULT) && (mContext.checkCallingOrSelfPermission(
android.Manifest.permission.WRITE_SETTINGS) == PackageManager.PERMISSION_GRANTED)) {
return;
}
throw new SecurityException(callingPkg + " was not granted either of these permissions:"
+ android.Manifest.permission.CHANGE_NETWORK_STATE + ","
+ android.Manifest.permission.WRITE_SETTINGS + ".");
}
private void enforceSettingsPermission() {
enforceAnyPermissionOf(mContext,
android.Manifest.permission.NETWORK_SETTINGS,
NetworkStack.PERMISSION_MAINLINE_NETWORK_STACK);
}
private void enforceSettingsOrSetupWizardOrUseRestrictedNetworksPermission() {
enforceAnyPermissionOf(mContext,
android.Manifest.permission.NETWORK_SETTINGS,
android.Manifest.permission.NETWORK_SETUP_WIZARD,
NetworkStack.PERMISSION_MAINLINE_NETWORK_STACK,
Manifest.permission.CONNECTIVITY_USE_RESTRICTED_NETWORKS);
}
private void enforceNetworkFactoryPermission() {
// TODO: Check for the BLUETOOTH_STACK permission once that is in the API surface.
if (UserHandle.getAppId(getCallingUid()) == Process.BLUETOOTH_UID) return;
enforceAnyPermissionOf(mContext,
android.Manifest.permission.NETWORK_FACTORY,
NetworkStack.PERMISSION_MAINLINE_NETWORK_STACK);
}
private void enforceNetworkFactoryOrSettingsPermission() {
// TODO: Check for the BLUETOOTH_STACK permission once that is in the API surface.
if (UserHandle.getAppId(getCallingUid()) == Process.BLUETOOTH_UID) return;
enforceAnyPermissionOf(mContext,
android.Manifest.permission.NETWORK_SETTINGS,
android.Manifest.permission.NETWORK_FACTORY,
NetworkStack.PERMISSION_MAINLINE_NETWORK_STACK);
}
private void enforceNetworkFactoryOrTestNetworksPermission() {
// TODO: Check for the BLUETOOTH_STACK permission once that is in the API surface.
if (UserHandle.getAppId(getCallingUid()) == Process.BLUETOOTH_UID) return;
enforceAnyPermissionOf(mContext,
android.Manifest.permission.MANAGE_TEST_NETWORKS,
android.Manifest.permission.NETWORK_FACTORY,
NetworkStack.PERMISSION_MAINLINE_NETWORK_STACK);
}
private boolean checkNetworkFactoryOrSettingsPermission(int pid, int uid) {
return PERMISSION_GRANTED == mContext.checkPermission(
android.Manifest.permission.NETWORK_FACTORY, pid, uid)
|| PERMISSION_GRANTED == mContext.checkPermission(
android.Manifest.permission.NETWORK_SETTINGS, pid, uid)
|| PERMISSION_GRANTED == mContext.checkPermission(
NetworkStack.PERMISSION_MAINLINE_NETWORK_STACK, pid, uid)
|| UserHandle.getAppId(uid) == Process.BLUETOOTH_UID;
}
private boolean checkSettingsPermission() {
return PermissionUtils.checkAnyPermissionOf(mContext,
android.Manifest.permission.NETWORK_SETTINGS,
NetworkStack.PERMISSION_MAINLINE_NETWORK_STACK);
}
private boolean checkSettingsPermission(int pid, int uid) {
return PERMISSION_GRANTED == mContext.checkPermission(
android.Manifest.permission.NETWORK_SETTINGS, pid, uid)
|| PERMISSION_GRANTED == mContext.checkPermission(
NetworkStack.PERMISSION_MAINLINE_NETWORK_STACK, pid, uid);
}
private void enforceNetworkStackOrSettingsPermission() {
enforceNetworkStackPermissionOr(mContext,
android.Manifest.permission.NETWORK_SETTINGS);
}
private void enforceNetworkStackSettingsOrSetup() {
enforceNetworkStackPermissionOr(mContext,
android.Manifest.permission.NETWORK_SETTINGS,
android.Manifest.permission.NETWORK_SETUP_WIZARD);
}
private void enforceAirplaneModePermission() {
enforceNetworkStackPermissionOr(mContext,
android.Manifest.permission.NETWORK_AIRPLANE_MODE,
android.Manifest.permission.NETWORK_SETTINGS,
android.Manifest.permission.NETWORK_SETUP_WIZARD);
}
private void enforceOemNetworkPreferencesPermission() {
mContext.enforceCallingOrSelfPermission(
android.Manifest.permission.CONTROL_OEM_PAID_NETWORK_PREFERENCE,
"ConnectivityService");
}
private void enforceManageTestNetworksPermission() {
mContext.enforceCallingOrSelfPermission(
android.Manifest.permission.MANAGE_TEST_NETWORKS,
"ConnectivityService");
}
private boolean checkNetworkStackPermission() {
return PermissionUtils.checkAnyPermissionOf(mContext,
android.Manifest.permission.NETWORK_STACK,
NetworkStack.PERMISSION_MAINLINE_NETWORK_STACK);
}
private boolean checkNetworkStackPermission(int pid, int uid) {
return checkAnyPermissionOf(mContext, pid, uid,
android.Manifest.permission.NETWORK_STACK,
NetworkStack.PERMISSION_MAINLINE_NETWORK_STACK);
}
private boolean checkSystemBarServicePermission(int pid, int uid) {
return checkAnyPermissionOf(mContext, pid, uid,
android.Manifest.permission.STATUS_BAR_SERVICE);
}
private boolean checkNetworkSignalStrengthWakeupPermission(int pid, int uid) {
return checkAnyPermissionOf(mContext, pid, uid,
android.Manifest.permission.NETWORK_SIGNAL_STRENGTH_WAKEUP,
NetworkStack.PERMISSION_MAINLINE_NETWORK_STACK,
android.Manifest.permission.NETWORK_SETTINGS);
}
private boolean checkConnectivityRestrictedNetworksPermission(int callingUid,
boolean checkUidsAllowedList) {
if (PermissionUtils.checkAnyPermissionOf(mContext,
android.Manifest.permission.CONNECTIVITY_USE_RESTRICTED_NETWORKS)) {
return true;
}
// fallback to ConnectivityInternalPermission
// TODO: Remove this fallback check after all apps have declared
// CONNECTIVITY_USE_RESTRICTED_NETWORKS.
if (PermissionUtils.checkAnyPermissionOf(mContext,
android.Manifest.permission.CONNECTIVITY_INTERNAL)) {
return true;
}
// Check whether uid is in allowed on restricted networks list.
if (checkUidsAllowedList
&& mPermissionMonitor.isUidAllowedOnRestrictedNetworks(callingUid)) {
return true;
}
return false;
}
private void enforceConnectivityRestrictedNetworksPermission(boolean checkUidsAllowedList) {
final int callingUid = mDeps.getCallingUid();
if (!checkConnectivityRestrictedNetworksPermission(callingUid, checkUidsAllowedList)) {
throw new SecurityException("ConnectivityService: user " + callingUid
+ " has no permission to access restricted network.");
}
}
private void enforceKeepalivePermission() {
mContext.enforceCallingOrSelfPermission(KeepaliveTracker.PERMISSION, "ConnectivityService");
}
private boolean checkLocalMacAddressPermission(int pid, int uid) {
return PERMISSION_GRANTED == mContext.checkPermission(
Manifest.permission.LOCAL_MAC_ADDRESS, pid, uid);
}
private void sendConnectedBroadcast(NetworkInfo info) {
sendGeneralBroadcast(info, CONNECTIVITY_ACTION);
}
private void sendInetConditionBroadcast(NetworkInfo info) {
sendGeneralBroadcast(info, ConnectivityManager.INET_CONDITION_ACTION);
}
private Intent makeGeneralIntent(NetworkInfo info, String bcastType) {
Intent intent = new Intent(bcastType);
intent.putExtra(ConnectivityManager.EXTRA_NETWORK_INFO, new NetworkInfo(info));
intent.putExtra(ConnectivityManager.EXTRA_NETWORK_TYPE, info.getType());
if (info.isFailover()) {
intent.putExtra(ConnectivityManager.EXTRA_IS_FAILOVER, true);
info.setFailover(false);
}
if (info.getReason() != null) {
intent.putExtra(ConnectivityManager.EXTRA_REASON, info.getReason());
}
if (info.getExtraInfo() != null) {
intent.putExtra(ConnectivityManager.EXTRA_EXTRA_INFO,
info.getExtraInfo());
}
intent.putExtra(ConnectivityManager.EXTRA_INET_CONDITION, mDefaultInetConditionPublished);
return intent;
}
private void sendGeneralBroadcast(NetworkInfo info, String bcastType) {
sendStickyBroadcast(makeGeneralIntent(info, bcastType));
}
// TODO(b/193460475): Remove when tooling supports SystemApi to public API.
@SuppressLint("NewApi")
// TODO: Set the mini sdk to 31 and remove @TargetApi annotation when b/205923322 is addressed.
@TargetApi(Build.VERSION_CODES.S)
private void sendStickyBroadcast(Intent intent) {
synchronized (this) {
if (!mSystemReady
&& intent.getAction().equals(ConnectivityManager.CONNECTIVITY_ACTION)) {
mInitialBroadcast = new Intent(intent);
}
intent.addFlags(Intent.FLAG_RECEIVER_REGISTERED_ONLY_BEFORE_BOOT);
if (VDBG) {
log("sendStickyBroadcast: action=" + intent.getAction());
}
Bundle options = null;
final long ident = Binder.clearCallingIdentity();
if (ConnectivityManager.CONNECTIVITY_ACTION.equals(intent.getAction())) {
final NetworkInfo ni = intent.getParcelableExtra(
ConnectivityManager.EXTRA_NETWORK_INFO);
final BroadcastOptions opts = BroadcastOptions.makeBasic();
opts.setMaxManifestReceiverApiLevel(Build.VERSION_CODES.M);
applyMostRecentPolicyForConnectivityAction(opts, ni);
options = opts.toBundle();
intent.addFlags(Intent.FLAG_RECEIVER_VISIBLE_TO_INSTANT_APPS);
}
try {
mUserAllContext.sendStickyBroadcast(intent, options);
} finally {
Binder.restoreCallingIdentity(ident);
}
}
}
private void applyMostRecentPolicyForConnectivityAction(BroadcastOptions options,
NetworkInfo info) {
// Delivery group policy APIs are only available on U+.
if (!mDeps.isAtLeastU()) return;
final BroadcastOptionsShim optsShim = mDeps.makeBroadcastOptionsShim(options);
try {
// This allows us to discard older broadcasts still waiting to be delivered
// which have the same namespace and key.
optsShim.setDeliveryGroupPolicy(ConstantsShim.DELIVERY_GROUP_POLICY_MOST_RECENT);
optsShim.setDeliveryGroupMatchingKey(ConnectivityManager.CONNECTIVITY_ACTION,
createDeliveryGroupKeyForConnectivityAction(info));
optsShim.setDeferralPolicy(ConstantsShim.DEFERRAL_POLICY_UNTIL_ACTIVE);
} catch (UnsupportedApiLevelException e) {
Log.wtf(TAG, "Using unsupported API" + e);
}
}
@VisibleForTesting
static String createDeliveryGroupKeyForConnectivityAction(NetworkInfo info) {
final StringBuilder sb = new StringBuilder();
sb.append(info.getType()).append(DELIVERY_GROUP_KEY_DELIMITER);
sb.append(info.getSubtype()).append(DELIVERY_GROUP_KEY_DELIMITER);
sb.append(info.getExtraInfo());
return sb.toString();
}
/**
* Called by SystemServer through ConnectivityManager when the system is ready.
*/
@Override
public void systemReady() {
if (mDeps.getCallingUid() != Process.SYSTEM_UID) {
throw new SecurityException("Calling Uid is not system uid.");
}
systemReadyInternal();
}
/**
* Called when ConnectivityService can initialize remaining components.
*/
@VisibleForTesting
public void systemReadyInternal() {
// Load flags after PackageManager is ready to query module version
mFlags.loadFlags(mDeps, mContext);
// Since mApps in PermissionMonitor needs to be populated first to ensure that
// listening network request which is sent by MultipathPolicyTracker won't be added
// NET_CAPABILITY_FOREGROUND capability. Thus, MultipathPolicyTracker.start() must
// be called after PermissionMonitor#startMonitoring().
// Calling PermissionMonitor#startMonitoring() in systemReadyInternal() and the
// MultipathPolicyTracker.start() is called in NetworkPolicyManagerService#systemReady()
// to ensure the tracking will be initialized correctly.
final ConditionVariable startMonitoringDone = new ConditionVariable();
mHandler.post(() -> {
mPermissionMonitor.startMonitoring();
startMonitoringDone.open();
});
mProxyTracker.loadGlobalProxy();
registerDnsResolverUnsolicitedEventListener();
synchronized (this) {
mSystemReady = true;
if (mInitialBroadcast != null) {
mContext.sendStickyBroadcastAsUser(mInitialBroadcast, UserHandle.ALL);
mInitialBroadcast = null;
}
}
// Create network requests for always-on networks.
mHandler.sendMessage(mHandler.obtainMessage(EVENT_CONFIGURE_ALWAYS_ON_NETWORKS));
// Update mobile data preference if necessary.
// Note that updating can be skipped here if the list is empty only because no uid
// rules are applied before system ready. Normally, the empty uid list means to clear
// the uids rules on netd.
if (!ConnectivitySettingsManager.getMobileDataPreferredUids(mContext).isEmpty()) {
updateMobileDataPreferredUids();
}
// On T+ devices, register callback for statsd to pull NETWORK_BPF_MAP_INFO atom
if (mDeps.isAtLeastT()) {
mBpfNetMaps.setPullAtomCallback(mContext);
}
ConnectivitySampleMetricsHelper.start(mContext, mHandler,
CONNECTIVITY_STATE_SAMPLE, this::sampleConnectivityStateToStatsEvent);
// Wait PermissionMonitor to finish the permission update. Then MultipathPolicyTracker won't
// have permission problem. While CV#block() is unbounded in time and can in principle block
// forever, this replaces a synchronous call to PermissionMonitor#startMonitoring, which
// could have blocked forever too.
startMonitoringDone.block();
}
/**
* Start listening for default data network activity state changes.
*/
@Override
public void registerNetworkActivityListener(@NonNull INetworkActivityListener l) {
mNetworkActivityTracker.registerNetworkActivityListener(l);
}
/**
* Stop listening for default data network activity state changes.
*/
@Override
public void unregisterNetworkActivityListener(@NonNull INetworkActivityListener l) {
mNetworkActivityTracker.unregisterNetworkActivityListener(l);
}
/**
* Check whether the default network radio is currently active.
*/
@Override
public boolean isDefaultNetworkActive() {
return mNetworkActivityTracker.isDefaultNetworkActive();
}
/**
* Reads the network specific MTU size from resources.
* and set it on it's iface.
*/
private void updateMtu(@NonNull LinkProperties newLp, @Nullable LinkProperties oldLp) {
final String iface = newLp.getInterfaceName();
final int mtu = newLp.getMtu();
if (mtu == 0) {
// Silently ignore unset MTU value.
return;
}
if (oldLp != null && newLp.isIdenticalMtu(oldLp)
&& TextUtils.equals(oldLp.getInterfaceName(), iface)) {
if (VDBG) log("identical MTU and iface - not setting");
return;
}
// Cannot set MTU without interface name
if (TextUtils.isEmpty(iface)) {
if (VDBG) log("Setting MTU size with null iface.");
return;
}
if (!LinkProperties.isValidMtu(mtu, newLp.hasGlobalIpv6Address())) {
loge("Unexpected mtu value: " + mtu + ", " + iface);
return;
}
try {
if (VDBG || DDBG) log("Setting MTU size: " + iface + ", " + mtu);
mNetd.interfaceSetMtu(iface, mtu);
} catch (RemoteException | ServiceSpecificException e) {
loge("exception in interfaceSetMtu()" + e);
}
}
@VisibleForTesting
protected static final String DEFAULT_TCP_BUFFER_SIZES = "4096,87380,110208,4096,16384,110208";
private void updateTcpBufferSizes(@Nullable String tcpBufferSizes) {
String[] values = null;
if (tcpBufferSizes != null) {
values = tcpBufferSizes.split(",");
}
if (values == null || values.length != 6) {
if (DBG) log("Invalid tcpBufferSizes string: " + tcpBufferSizes +", using defaults");
tcpBufferSizes = DEFAULT_TCP_BUFFER_SIZES;
values = tcpBufferSizes.split(",");
}
if (tcpBufferSizes.equals(mCurrentTcpBufferSizes)) return;
try {
if (VDBG || DDBG) log("Setting tx/rx TCP buffers to " + tcpBufferSizes);
String rmemValues = String.join(" ", values[0], values[1], values[2]);
String wmemValues = String.join(" ", values[3], values[4], values[5]);
mNetd.setTcpRWmemorySize(rmemValues, wmemValues);
mCurrentTcpBufferSizes = tcpBufferSizes;
} catch (RemoteException | ServiceSpecificException e) {
loge("Can't set TCP buffer sizes:" + e);
}
}
@Override
public int getRestoreDefaultNetworkDelay(int networkType) {
String restoreDefaultNetworkDelayStr = mSystemProperties.get(
NETWORK_RESTORE_DELAY_PROP_NAME);
if(restoreDefaultNetworkDelayStr != null &&
restoreDefaultNetworkDelayStr.length() != 0) {
try {
return Integer.parseInt(restoreDefaultNetworkDelayStr);
} catch (NumberFormatException e) {
}
}
// if the system property isn't set, use the value for the apn type
int ret = RESTORE_DEFAULT_NETWORK_DELAY;
if (mLegacyTypeTracker.isTypeSupported(networkType)) {
ret = mLegacyTypeTracker.getRestoreTimerForType(networkType);
}
return ret;
}
private void dumpNetworkDiagnostics(IndentingPrintWriter pw) {
final List<NetworkDiagnostics> netDiags = new ArrayList<>();
final long DIAG_TIME_MS = 5000;
for (NetworkAgentInfo nai : networksSortedById()) {
PrivateDnsConfig privateDnsCfg = mDnsManager.getPrivateDnsConfig(nai.network);
// Start gathering diagnostic information.
netDiags.add(new NetworkDiagnostics(
nai.network,
new LinkProperties(nai.linkProperties), // Must be a copy.
privateDnsCfg,
DIAG_TIME_MS));
}
for (NetworkDiagnostics netDiag : netDiags) {
pw.println();
netDiag.waitForMeasurements();
netDiag.dump(pw);
}
}
@Override
protected void dump(@NonNull FileDescriptor fd, @NonNull PrintWriter writer,
@Nullable String[] args) {
if (!checkDumpPermission(mContext, TAG, writer)) return;
mPriorityDumper.dump(fd, writer, args);
}
private boolean checkDumpPermission(Context context, String tag, PrintWriter pw) {
if (context.checkCallingOrSelfPermission(android.Manifest.permission.DUMP)
!= PackageManager.PERMISSION_GRANTED) {
pw.println("Permission Denial: can't dump " + tag + " from from pid="
+ Binder.getCallingPid() + ", uid=" + mDeps.getCallingUid()
+ " due to missing android.permission.DUMP permission");
return false;
} else {
return true;
}
}
private void doDump(FileDescriptor fd, PrintWriter writer, String[] args) {
final IndentingPrintWriter pw = new IndentingPrintWriter(writer, " ");
if (CollectionUtils.contains(args, DIAG_ARG)) {
dumpNetworkDiagnostics(pw);
return;
} else if (CollectionUtils.contains(args, NETWORK_ARG)) {
dumpNetworks(pw);
return;
} else if (CollectionUtils.contains(args, REQUEST_ARG)) {
dumpNetworkRequests(pw);
return;
} else if (CollectionUtils.contains(args, TRAFFICCONTROLLER_ARG)) {
boolean verbose = !CollectionUtils.contains(args, SHORT_ARG);
dumpTrafficController(pw, fd, verbose);
return;
}
pw.println("NetworkProviders for:");
pw.increaseIndent();
for (NetworkProviderInfo npi : mNetworkProviderInfos.values()) {
pw.println(npi.providerId + ": " + npi.name);
}
pw.decreaseIndent();
pw.println();
final NetworkAgentInfo defaultNai = getDefaultNetwork();
pw.print("Active default network: ");
if (defaultNai == null) {
pw.println("none");
} else {
pw.println(defaultNai.network.getNetId());
}
pw.println();
pw.println("Current network preferences: ");
pw.increaseIndent();
dumpNetworkPreferences(pw);
pw.decreaseIndent();
pw.println();
pw.println("Current Networks:");
pw.increaseIndent();
dumpNetworks(pw);
pw.decreaseIndent();
pw.println();
pw.println("Status for known UIDs:");
pw.increaseIndent();
final int size = mUidBlockedReasons.size();
for (int i = 0; i < size; i++) {
// Don't crash if the array is modified while dumping in bugreports.
try {
final int uid = mUidBlockedReasons.keyAt(i);
final int blockedReasons = mUidBlockedReasons.valueAt(i);
pw.println("UID=" + uid + " blockedReasons="
+ Integer.toHexString(blockedReasons));
} catch (ArrayIndexOutOfBoundsException e) {
pw.println(" ArrayIndexOutOfBoundsException");
} catch (ConcurrentModificationException e) {
pw.println(" ConcurrentModificationException");
}
}
pw.println();
pw.decreaseIndent();
pw.println("Network Requests:");
pw.increaseIndent();
dumpNetworkRequests(pw);
pw.decreaseIndent();
pw.println();
pw.println("Network Offers:");
pw.increaseIndent();
for (final NetworkOfferInfo offerInfo : mNetworkOffers) {
pw.println(offerInfo.offer);
}
pw.decreaseIndent();
pw.println();
mLegacyTypeTracker.dump(pw);
pw.println();
mKeepaliveTracker.dump(pw);
pw.println();
dumpAvoidBadWifiSettings(pw);
pw.println();
dumpCloseFrozenAppSockets(pw);
pw.println();
dumpBpfProgramStatus(pw);
if (null != mCarrierPrivilegeAuthenticator) {
pw.println();
mCarrierPrivilegeAuthenticator.dump(pw);
}
pw.println();
if (!CollectionUtils.contains(args, SHORT_ARG)) {
pw.println();
pw.println("mNetworkRequestInfoLogs (most recent first):");
pw.increaseIndent();
mNetworkRequestInfoLogs.reverseDump(pw);
pw.decreaseIndent();
pw.println();
pw.println("mNetworkInfoBlockingLogs (most recent first):");
pw.increaseIndent();
mNetworkInfoBlockingLogs.reverseDump(pw);
pw.decreaseIndent();
pw.println();
pw.println("NetTransition WakeLock activity (most recent first):");
pw.increaseIndent();
pw.println("total acquisitions: " + mTotalWakelockAcquisitions);
pw.println("total releases: " + mTotalWakelockReleases);
pw.println("cumulative duration: " + (mTotalWakelockDurationMs / 1000) + "s");
pw.println("longest duration: " + (mMaxWakelockDurationMs / 1000) + "s");
if (mTotalWakelockAcquisitions > mTotalWakelockReleases) {
long duration = SystemClock.elapsedRealtime() - mLastWakeLockAcquireTimestamp;
pw.println("currently holding WakeLock for: " + (duration / 1000) + "s");
}
mWakelockLogs.reverseDump(pw);
pw.println();
pw.println("bandwidth update requests (by uid):");
pw.increaseIndent();
synchronized (mBandwidthRequests) {
for (int i = 0; i < mBandwidthRequests.size(); i++) {
pw.println("[" + mBandwidthRequests.keyAt(i)
+ "]: " + mBandwidthRequests.valueAt(i));
}
}
pw.decreaseIndent();
pw.decreaseIndent();
pw.println();
pw.println("mOemNetworkPreferencesLogs (most recent first):");
pw.increaseIndent();
mOemNetworkPreferencesLogs.reverseDump(pw);
pw.decreaseIndent();
}
pw.println();
pw.println();
pw.println("Permission Monitor:");
pw.increaseIndent();
mPermissionMonitor.dump(pw);
pw.decreaseIndent();
pw.println();
pw.println("Legacy network activity:");
pw.increaseIndent();
mNetworkActivityTracker.dump(pw);
pw.decreaseIndent();
}
private void dumpNetworks(IndentingPrintWriter pw) {
for (NetworkAgentInfo nai : networksSortedById()) {
pw.println(nai.toString());
pw.increaseIndent();
pw.println("Nat464Xlat:");
pw.increaseIndent();
nai.dumpNat464Xlat(pw);
pw.decreaseIndent();
pw.println(String.format(
"Requests: REQUEST:%d LISTEN:%d BACKGROUND_REQUEST:%d total:%d",
nai.numForegroundNetworkRequests(),
nai.numNetworkRequests() - nai.numRequestNetworkRequests(),
nai.numBackgroundNetworkRequests(),
nai.numNetworkRequests()));
pw.increaseIndent();
for (int i = 0; i < nai.numNetworkRequests(); i++) {
pw.println(nai.requestAt(i).toString());
}
pw.decreaseIndent();
pw.println("Inactivity Timers:");
pw.increaseIndent();
nai.dumpInactivityTimers(pw);
pw.decreaseIndent();
pw.decreaseIndent();
}
}
private void dumpNetworkPreferences(IndentingPrintWriter pw) {
if (!mProfileNetworkPreferences.isEmpty()) {
pw.println("Profile preferences:");
pw.increaseIndent();
pw.println(mProfileNetworkPreferences);
pw.decreaseIndent();
}
if (!mOemNetworkPreferences.isEmpty()) {
pw.println("OEM preferences:");
pw.increaseIndent();
pw.println(mOemNetworkPreferences);
pw.decreaseIndent();
}
if (!mMobileDataPreferredUids.isEmpty()) {
pw.println("Mobile data preferred UIDs:");
pw.increaseIndent();
pw.println(mMobileDataPreferredUids);
pw.decreaseIndent();
}
pw.println("Default requests:");
pw.increaseIndent();
dumpPerAppDefaultRequests(pw);
pw.decreaseIndent();
}
private void dumpPerAppDefaultRequests(IndentingPrintWriter pw) {
for (final NetworkRequestInfo defaultRequest : mDefaultNetworkRequests) {
if (mDefaultRequest == defaultRequest) {
continue;
}
final NetworkAgentInfo satisfier = defaultRequest.getSatisfier();
final String networkOutput;
if (null == satisfier) {
networkOutput = "null";
} else if (mNoServiceNetwork.equals(satisfier)) {
networkOutput = "no service network";
} else {
networkOutput = String.valueOf(satisfier.network.netId);
}
final String asUidString = (defaultRequest.mAsUid == defaultRequest.mUid)
? "" : " asUid: " + defaultRequest.mAsUid;
final String requestInfo = "Request: [uid/pid:" + defaultRequest.mUid + "/"
+ defaultRequest.mPid + asUidString + "]";
final String satisfierOutput = "Satisfier: [" + networkOutput + "]"
+ " Preference order: " + defaultRequest.mPreferenceOrder
+ " Tracked UIDs: " + defaultRequest.getUids();
pw.println(requestInfo + " - " + satisfierOutput);
}
}
private void dumpNetworkRequests(IndentingPrintWriter pw) {
NetworkRequestInfo[] infos = null;
while (infos == null) {
try {
infos = requestsSortedById();
} catch (ConcurrentModificationException e) {
// mNetworkRequests should only be accessed from handler thread, except dump().
// As dump() is never called in normal usage, it would be needlessly expensive
// to lock the collection only for its benefit. Instead, retry getting the
// requests if ConcurrentModificationException is thrown during dump().
}
}
for (NetworkRequestInfo nri : infos) {
pw.println(nri.toString());
}
}
private void dumpTrafficController(IndentingPrintWriter pw, final FileDescriptor fd,
boolean verbose) {
try {
mBpfNetMaps.dump(pw, fd, verbose);
} catch (ServiceSpecificException e) {
pw.println(e.getMessage());
} catch (IOException e) {
loge("Dump BPF maps failed, " + e);
}
}
private void dumpAllRequestInfoLogsToLogcat() {
try (PrintWriter logPw = new PrintWriter(new Writer() {
@Override
public void write(final char[] cbuf, final int off, final int len) {
// This method is called with 0-length and 1-length arrays for empty strings
// or strings containing only the DEL character.
if (len <= 1) return;
Log.e(TAG, new String(cbuf, off, len));
}
@Override public void flush() {}
@Override public void close() {}
})) {
mNetworkRequestInfoLogs.dump(logPw);
}
}
/**
* Return an array of all current NetworkAgentInfos sorted by network id.
*/
private NetworkAgentInfo[] networksSortedById() {
NetworkAgentInfo[] networks = new NetworkAgentInfo[0];
networks = mNetworkAgentInfos.toArray(networks);
Arrays.sort(networks, Comparator.comparingInt(nai -> nai.network.getNetId()));
return networks;
}
/**
* Return an array of all current NetworkRequest sorted by request id.
*/
@VisibleForTesting
NetworkRequestInfo[] requestsSortedById() {
NetworkRequestInfo[] requests = new NetworkRequestInfo[0];
requests = getNrisFromGlobalRequests().toArray(requests);
// Sort the array based off the NRI containing the min requestId in its requests.
Arrays.sort(requests,
Comparator.comparingInt(nri -> Collections.min(nri.mRequests,
Comparator.comparingInt(req -> req.requestId)).requestId
)
);
return requests;
}
private boolean isLiveNetworkAgent(NetworkAgentInfo nai, int what) {
final NetworkAgentInfo officialNai = getNetworkAgentInfoForNetwork(nai.network);
if (officialNai != null && officialNai.equals(nai)) return true;
if (officialNai != null || VDBG) {
loge(eventName(what) + " - isLiveNetworkAgent found mismatched netId: " + officialNai +
" - " + nai);
}
return false;
}
private boolean isDisconnectRequest(Message msg) {
if (msg.what != NetworkAgent.EVENT_NETWORK_INFO_CHANGED) return false;
final NetworkInfo info = (NetworkInfo) ((Pair) msg.obj).second;
return info.getState() == NetworkInfo.State.DISCONNECTED;
}
// must be stateless - things change under us.
private class NetworkStateTrackerHandler extends Handler {
public NetworkStateTrackerHandler(Looper looper) {
super(looper);
}
private void maybeHandleNetworkAgentMessage(Message msg) {
final Pair<NetworkAgentInfo, Object> arg = (Pair<NetworkAgentInfo, Object>) msg.obj;
final NetworkAgentInfo nai = arg.first;
if (!mNetworkAgentInfos.contains(nai)) {
if (VDBG) {
log(String.format("%s from unknown NetworkAgent", eventName(msg.what)));
}
return;
}
// If the network has been destroyed, the only thing that it can do is disconnect.
if (nai.isDestroyed() && !isDisconnectRequest(msg)) {
return;
}
switch (msg.what) {
case NetworkAgent.EVENT_NETWORK_CAPABILITIES_CHANGED: {
final NetworkCapabilities proposed = (NetworkCapabilities) arg.second;
if (!nai.respectsNcStructuralConstraints(proposed)) {
Log.wtf(TAG, "Agent " + nai + " violates nc structural constraints : "
+ nai.networkCapabilities + " -> " + proposed);
disconnectAndDestroyNetwork(nai);
return;
}
nai.setDeclaredCapabilities(proposed);
final NetworkCapabilities sanitized =
nai.getDeclaredCapabilitiesSanitized(mCarrierPrivilegeAuthenticator);
maybeUpdateWifiRoamTimestamp(nai, sanitized);
updateCapabilities(nai.getScore(), nai, sanitized);
break;
}
case NetworkAgent.EVENT_NETWORK_PROPERTIES_CHANGED: {
LinkProperties newLp = (LinkProperties) arg.second;
processLinkPropertiesFromAgent(nai, newLp);
handleUpdateLinkProperties(nai, newLp);
break;
}
case NetworkAgent.EVENT_NETWORK_INFO_CHANGED: {
NetworkInfo info = (NetworkInfo) arg.second;
updateNetworkInfo(nai, info);
break;
}
case NetworkAgent.EVENT_LOCAL_NETWORK_CONFIG_CHANGED: {
final LocalNetworkConfig config = (LocalNetworkConfig) arg.second;
handleUpdateLocalNetworkConfig(nai, nai.localNetworkConfig, config);
break;
}
case NetworkAgent.EVENT_NETWORK_SCORE_CHANGED: {
updateNetworkScore(nai, (NetworkScore) arg.second);
break;
}
case NetworkAgent.EVENT_SET_EXPLICITLY_SELECTED: {
if (nai.everConnected()) {
loge("ERROR: cannot call explicitlySelected on already-connected network");
// Note that if the NAI had been connected, this would affect the
// score, and therefore would require re-mixing the score and performing
// a rematch.
}
nai.networkAgentConfig.explicitlySelected = toBool(msg.arg1);
nai.networkAgentConfig.acceptUnvalidated = toBool(msg.arg1) && toBool(msg.arg2);
// Mark the network as temporarily accepting partial connectivity so that it
// will be validated (and possibly become default) even if it only provides
// partial internet access. Note that if user connects to partial connectivity
// and choose "don't ask again", then wifi disconnected by some reasons(maybe
// out of wifi coverage) and if the same wifi is available again, the device
// will auto connect to this wifi even though the wifi has "no internet".
// TODO: Evaluate using a separate setting in IpMemoryStore.
nai.networkAgentConfig.acceptPartialConnectivity = toBool(msg.arg2);
break;
}
case NetworkAgent.EVENT_SOCKET_KEEPALIVE: {
mKeepaliveTracker.handleEventSocketKeepalive(nai, msg.arg1, msg.arg2);
break;
}
case NetworkAgent.EVENT_UNDERLYING_NETWORKS_CHANGED: {
// TODO: prevent loops, e.g., if a network declares itself as underlying.
final List<Network> underlying = (List<Network>) arg.second;
if (isLegacyLockdownNai(nai)
&& (underlying == null || underlying.size() != 1)) {
Log.wtf(TAG, "Legacy lockdown VPN " + nai.toShortString()
+ " must have exactly one underlying network: " + underlying);
}
final Network[] oldUnderlying = nai.declaredUnderlyingNetworks;
nai.declaredUnderlyingNetworks = (underlying != null)
? underlying.toArray(new Network[0]) : null;
if (!Arrays.equals(oldUnderlying, nai.declaredUnderlyingNetworks)) {
if (DBG) {
log(nai.toShortString() + " changed underlying networks to "
+ Arrays.toString(nai.declaredUnderlyingNetworks));
}
updateCapabilitiesForNetwork(nai);
notifyIfacesChangedForNetworkStats();
}
break;
}
case NetworkAgent.EVENT_TEARDOWN_DELAY_CHANGED: {
if (msg.arg1 >= 0 && msg.arg1 <= NetworkAgent.MAX_TEARDOWN_DELAY_MS) {
nai.teardownDelayMs = msg.arg1;
} else {
logwtf(nai.toShortString() + " set invalid teardown delay " + msg.arg1);
}
break;
}
case NetworkAgent.EVENT_LINGER_DURATION_CHANGED: {
nai.setLingerDuration((int) arg.second);
break;
}
case NetworkAgent.EVENT_ADD_DSCP_POLICY: {
DscpPolicy policy = (DscpPolicy) arg.second;
if (mDscpPolicyTracker != null) {
mDscpPolicyTracker.addDscpPolicy(nai, policy);
}
break;
}
case NetworkAgent.EVENT_REMOVE_DSCP_POLICY: {
if (mDscpPolicyTracker != null) {
mDscpPolicyTracker.removeDscpPolicy(nai, (int) arg.second);
}
break;
}
case NetworkAgent.EVENT_REMOVE_ALL_DSCP_POLICIES: {
if (mDscpPolicyTracker != null) {
mDscpPolicyTracker.removeAllDscpPolicies(nai, true);
}
break;
}
case NetworkAgent.EVENT_UNREGISTER_AFTER_REPLACEMENT: {
if (!nai.everConnected()) {
Log.d(TAG, "unregisterAfterReplacement on never-connected "
+ nai.toShortString() + ", tearing down instead");
teardownUnneededNetwork(nai);
break;
}
if (nai.isDestroyed()) {
Log.d(TAG, "unregisterAfterReplacement on destroyed " + nai.toShortString()
+ ", ignoring");
break;
}
final int timeoutMs = (int) arg.second;
if (timeoutMs < 0 || timeoutMs > NetworkAgent.MAX_TEARDOWN_DELAY_MS) {
Log.e(TAG, "Invalid network replacement timer " + timeoutMs
+ ", must be between 0 and " + NetworkAgent.MAX_TEARDOWN_DELAY_MS);
}
// Marking a network awaiting replacement is used to ensure that any requests
// satisfied by the network do not switch to another network until a
// replacement is available or the wait for a replacement times out.
// If the network is inactive (i.e., nascent or lingering), then there are no
// such requests, and there is no point keeping it. Just tear it down.
// Note that setLingerDuration(0) cannot be used to do this because the network
// could be nascent.
nai.clearInactivityState();
if (unneeded(nai, UnneededFor.TEARDOWN)) {
Log.d(TAG, nai.toShortString()
+ " marked awaiting replacement is unneeded, tearing down instead");
teardownUnneededNetwork(nai);
break;
}
Log.d(TAG, "Marking " + nai.toShortString()
+ " destroyed, awaiting replacement within " + timeoutMs + "ms");
destroyNativeNetwork(nai);
// TODO: deduplicate this call with the one in disconnectAndDestroyNetwork.
// This is not trivial because KeepaliveTracker#handleStartKeepalive does not
// consider the fact that the network could already have disconnected or been
// destroyed. Fix the code to send ERROR_INVALID_NETWORK when this happens
// (taking care to ensure no dup'd FD leaks), then remove the code duplication
// and move this code to a sensible location (destroyNativeNetwork perhaps?).
mKeepaliveTracker.handleStopAllKeepalives(nai,
SocketKeepalive.ERROR_INVALID_NETWORK);
nai.updateScoreForNetworkAgentUpdate();
// This rematch is almost certainly not going to result in any changes, because
// the destroyed flag is only just above the "current satisfier wins"
// tie-breaker. But technically anything that affects scoring should rematch.
rematchAllNetworksAndRequests();
mHandler.postDelayed(() -> nai.disconnect(), timeoutMs);
break;
}
}
}
private boolean maybeHandleNetworkMonitorMessage(Message msg) {
final int netId = msg.arg2;
final NetworkAgentInfo nai = getNetworkAgentInfoForNetId(netId);
// If a network has already been destroyed, all NetworkMonitor updates are ignored.
if (nai != null && nai.isDestroyed()) return true;
switch (msg.what) {
default:
return false;
case EVENT_PROBE_STATUS_CHANGED: {
if (nai == null) {
break;
}
final int probesCompleted = ((Pair<Integer, Integer>) msg.obj).first;
final int probesSucceeded = ((Pair<Integer, Integer>) msg.obj).second;
final boolean probePrivateDnsCompleted =
((probesCompleted & NETWORK_VALIDATION_PROBE_PRIVDNS) != 0);
final boolean privateDnsBroken =
((probesSucceeded & NETWORK_VALIDATION_PROBE_PRIVDNS) == 0);
if (probePrivateDnsCompleted) {
if (nai.networkCapabilities.isPrivateDnsBroken() != privateDnsBroken) {
nai.networkCapabilities.setPrivateDnsBroken(privateDnsBroken);
updateCapabilitiesForNetwork(nai);
}
// Only show the notification when the private DNS is broken and the
// PRIVATE_DNS_BROKEN notification hasn't shown since last valid.
if (privateDnsBroken && !nai.networkAgentConfig.hasShownBroken) {
showNetworkNotification(nai, NotificationType.PRIVATE_DNS_BROKEN);
}
nai.networkAgentConfig.hasShownBroken = privateDnsBroken;
} else if (nai.networkCapabilities.isPrivateDnsBroken()) {
// If probePrivateDnsCompleted is false but nai.networkCapabilities says
// private DNS is broken, it means this network is being reevaluated.
// Either probing private DNS is not necessary any more or it hasn't been
// done yet. In either case, the networkCapabilities should be updated to
// reflect the new status.
nai.networkCapabilities.setPrivateDnsBroken(false);
updateCapabilitiesForNetwork(nai);
nai.networkAgentConfig.hasShownBroken = false;
}
break;
}
case EVENT_NETWORK_TESTED: {
final NetworkTestedResults results = (NetworkTestedResults) msg.obj;
if (nai == null) break;
handleNetworkTested(nai, results.mTestResult,
(results.mRedirectUrl == null) ? "" : results.mRedirectUrl);
break;
}
case EVENT_PROVISIONING_NOTIFICATION: {
final boolean visible = toBool(msg.arg1);
// If captive portal status has changed, update capabilities or disconnect.
if (!visible) {
// Only clear SIGN_IN and NETWORK_SWITCH notifications here, or else other
// notifications belong to the same network may be cleared unexpectedly.
mNotifier.clearNotification(netId, NotificationType.SIGN_IN);
mNotifier.clearNotification(netId, NotificationType.NETWORK_SWITCH);
} else {
if (nai == null) {
loge("EVENT_PROVISIONING_NOTIFICATION from unknown NetworkMonitor");
break;
}
if (!nai.networkAgentConfig.provisioningNotificationDisabled) {
mNotifier.showNotification(netId, NotificationType.SIGN_IN, nai, null,
(PendingIntent) msg.obj,
nai.networkAgentConfig.explicitlySelected);
}
}
break;
}
case EVENT_PRIVATE_DNS_CONFIG_RESOLVED: {
if (nai == null) break;
updatePrivateDns(nai, (PrivateDnsConfig) msg.obj);
break;
}
case EVENT_CAPPORT_DATA_CHANGED: {
if (nai == null) break;
handleCapportApiDataUpdate(nai, (CaptivePortalData) msg.obj);
break;
}
}
return true;
}
private void handleNetworkTested(
@NonNull NetworkAgentInfo nai, int testResult, @NonNull String redirectUrl) {
final boolean valid = (testResult & NETWORK_VALIDATION_RESULT_VALID) != 0;
final boolean partial = (testResult & NETWORK_VALIDATION_RESULT_PARTIAL) != 0;
final boolean portal = !TextUtils.isEmpty(redirectUrl);
// If there is any kind of working networking, then the NAI has been evaluated
// once. {@see NetworkAgentInfo#setEvaluated}, which returns whether this is
// the first time this ever happened.
final boolean someConnectivity = (valid || partial || portal);
final boolean becameEvaluated = someConnectivity && nai.setEvaluated();
// Because of b/245893397, if the score is updated when updateCapabilities is called,
// any callback that receives onAvailable for that rematch receives an extra caps
// callback. To prevent that, update the score in the agent so the updates below won't
// see an update to both caps and score at the same time.
// TODO : fix b/245893397 and remove this.
if (becameEvaluated) nai.updateScoreForNetworkAgentUpdate();
if (!valid && shouldIgnoreValidationFailureAfterRoam(nai)) {
// Assume the validation failure is due to a temporary failure after roaming
// and ignore it. NetworkMonitor will continue to retry validation. If it
// continues to fail after the block timeout expires, the network will be
// marked unvalidated. If it succeeds, then validation state will not change.
return;
}
final boolean wasValidated = nai.isValidated();
final boolean wasPartial = nai.partialConnectivity();
final boolean wasPortal = nai.captivePortalDetected();
nai.setPartialConnectivity(partial);
nai.setCaptivePortalDetected(portal);
nai.updateScoreForNetworkAgentUpdate();
final boolean partialConnectivityChanged = (wasPartial != partial);
final boolean portalChanged = (wasPortal != portal);
if (DBG) {
final String logMsg = !TextUtils.isEmpty(redirectUrl)
? " with redirect to " + redirectUrl
: "";
log(nai.toShortString() + " validation " + (valid ? "passed" : "failed") + logMsg);
}
if (valid != wasValidated) {
final FullScore oldScore = nai.getScore();
nai.setValidated(valid);
updateCapabilities(oldScore, nai, nai.networkCapabilities);
if (valid) {
handleFreshlyValidatedNetwork(nai);
// Clear NO_INTERNET, PRIVATE_DNS_BROKEN, PARTIAL_CONNECTIVITY and
// LOST_INTERNET notifications if network becomes valid.
mNotifier.clearNotification(nai.network.getNetId(),
NotificationType.NO_INTERNET);
mNotifier.clearNotification(nai.network.getNetId(),
NotificationType.LOST_INTERNET);
mNotifier.clearNotification(nai.network.getNetId(),
NotificationType.PARTIAL_CONNECTIVITY);
mNotifier.clearNotification(nai.network.getNetId(),
NotificationType.PRIVATE_DNS_BROKEN);
// If network becomes valid, the hasShownBroken should be reset for
// that network so that the notification will be fired when the private
// DNS is broken again.
nai.networkAgentConfig.hasShownBroken = false;
}
} else if (partialConnectivityChanged) {
updateCapabilitiesForNetwork(nai);
} else if (portalChanged) {
if (portal && ConnectivitySettingsManager.CAPTIVE_PORTAL_MODE_AVOID
== getCaptivePortalMode(nai)) {
if (DBG) log("Avoiding captive portal network: " + nai.toShortString());
nai.onPreventAutomaticReconnect();
teardownUnneededNetwork(nai);
return;
} else {
updateCapabilitiesForNetwork(nai);
}
} else if (becameEvaluated) {
// If valid or partial connectivity changed, updateCapabilities* has
// done the rematch.
rematchAllNetworksAndRequests();
}
updateInetCondition(nai);
// Let the NetworkAgent know the state of its network
// TODO: Evaluate to update partial connectivity to status to NetworkAgent.
nai.onValidationStatusChanged(
valid ? NetworkAgent.VALID_NETWORK : NetworkAgent.INVALID_NETWORK,
redirectUrl);
// If NetworkMonitor detects partial connectivity before
// EVENT_INITIAL_EVALUATION_TIMEOUT arrives, show the partial connectivity notification
// immediately. Re-notify partial connectivity silently if no internet
// notification already there.
if (!wasPartial && nai.partialConnectivity()) {
// Remove delayed message if there is a pending message.
mHandler.removeMessages(EVENT_INITIAL_EVALUATION_TIMEOUT, nai.network);
handleInitialEvaluationTimeout(nai.network);
}
if (wasValidated && !nai.isValidated()) {
handleNetworkUnvalidated(nai);
}
}
private int getCaptivePortalMode(@NonNull NetworkAgentInfo nai) {
if (nai.networkCapabilities.hasTransport(NetworkCapabilities.TRANSPORT_BLUETOOTH) &&
mContext.getPackageManager().hasSystemFeature(FEATURE_WATCH)) {
// Do not avoid captive portal when network is wear proxy.
return ConnectivitySettingsManager.CAPTIVE_PORTAL_MODE_PROMPT;
}
return Settings.Global.getInt(mContext.getContentResolver(),
ConnectivitySettingsManager.CAPTIVE_PORTAL_MODE,
ConnectivitySettingsManager.CAPTIVE_PORTAL_MODE_PROMPT);
}
private boolean maybeHandleNetworkAgentInfoMessage(Message msg) {
switch (msg.what) {
default:
return false;
case NetworkAgentInfo.EVENT_NETWORK_LINGER_COMPLETE: {
NetworkAgentInfo nai = (NetworkAgentInfo) msg.obj;
if (nai != null && isLiveNetworkAgent(nai, msg.what)) {
handleLingerComplete(nai);
}
break;
}
case NetworkAgentInfo.EVENT_AGENT_REGISTERED: {
handleNetworkAgentRegistered(msg);
break;
}
case NetworkAgentInfo.EVENT_AGENT_DISCONNECTED: {
handleNetworkAgentDisconnected(msg);
break;
}
}
return true;
}
@Override
public void handleMessage(@NonNull Message msg) {
if (!maybeHandleNetworkMonitorMessage(msg)
&& !maybeHandleNetworkAgentInfoMessage(msg)) {
maybeHandleNetworkAgentMessage(msg);
}
}
}
private class NetworkMonitorCallbacks extends INetworkMonitorCallbacks.Stub {
private final int mNetId;
private final AutodestructReference<NetworkAgentInfo> mNai;
private NetworkMonitorCallbacks(NetworkAgentInfo nai) {
mNetId = nai.network.getNetId();
mNai = new AutodestructReference<>(nai);
}
@Override
public void onNetworkMonitorCreated(INetworkMonitor networkMonitor) {
mHandler.sendMessage(mHandler.obtainMessage(EVENT_REGISTER_NETWORK_AGENT,
new Pair<>(mNai.getAndDestroy(), networkMonitor)));
}
@Override
public void notifyNetworkTested(int testResult, @Nullable String redirectUrl) {
// Legacy version of notifyNetworkTestedWithExtras.
// Would only be called if the system has a NetworkStack module older than the
// framework, which does not happen in practice.
Log.wtf(TAG, "Deprecated notifyNetworkTested called: no action taken");
}
@Override
public void notifyNetworkTestedWithExtras(NetworkTestResultParcelable p) {
// Notify mTrackerHandler and mConnectivityDiagnosticsHandler of the event. Both use
// the same looper so messages will be processed in sequence.
final Message msg = mTrackerHandler.obtainMessage(
EVENT_NETWORK_TESTED,
0, mNetId,
new NetworkTestedResults(
mNetId, p.result, p.timestampMillis, p.redirectUrl));
mTrackerHandler.sendMessage(msg);
// Invoke ConnectivityReport generation for this Network test event.
final NetworkAgentInfo nai = getNetworkAgentInfoForNetId(mNetId);
if (nai == null) return;
// NetworkMonitor reports the network validation result as a bitmask while
// ConnectivityDiagnostics treats this value as an int. Convert the result to a single
// logical value for ConnectivityDiagnostics.
final int validationResult = networkMonitorValidationResultToConnDiagsValidationResult(
p.result);
final PersistableBundle extras = new PersistableBundle();
extras.putInt(KEY_NETWORK_VALIDATION_RESULT, validationResult);
extras.putInt(KEY_NETWORK_PROBES_SUCCEEDED_BITMASK, p.probesSucceeded);
extras.putInt(KEY_NETWORK_PROBES_ATTEMPTED_BITMASK, p.probesAttempted);
ConnectivityReportEvent reportEvent =
new ConnectivityReportEvent(p.timestampMillis, nai, extras);
final Message m = mConnectivityDiagnosticsHandler.obtainMessage(
ConnectivityDiagnosticsHandler.CMD_SEND_CONNECTIVITY_REPORT, reportEvent);
mConnectivityDiagnosticsHandler.sendMessage(m);
}
@Override
public void notifyPrivateDnsConfigResolved(PrivateDnsConfigParcel config) {
mTrackerHandler.sendMessage(mTrackerHandler.obtainMessage(
EVENT_PRIVATE_DNS_CONFIG_RESOLVED,
0, mNetId, PrivateDnsConfig.fromParcel(config)));
}
@Override
public void notifyProbeStatusChanged(int probesCompleted, int probesSucceeded) {
mTrackerHandler.sendMessage(mTrackerHandler.obtainMessage(
EVENT_PROBE_STATUS_CHANGED,
0, mNetId, new Pair<>(probesCompleted, probesSucceeded)));
}
@Override
public void notifyCaptivePortalDataChanged(CaptivePortalData data) {
mTrackerHandler.sendMessage(mTrackerHandler.obtainMessage(
EVENT_CAPPORT_DATA_CHANGED,
0, mNetId, data));
}
@Override
public void showProvisioningNotification(String action, String packageName) {
final Intent intent = new Intent(action);
intent.setPackage(packageName);
final PendingIntent pendingIntent;
// Only the system server can register notifications with package "android"
final long token = Binder.clearCallingIdentity();
try {
pendingIntent = PendingIntent.getBroadcast(
mContext,
0 /* requestCode */,
intent,
PendingIntent.FLAG_IMMUTABLE);
} finally {
Binder.restoreCallingIdentity(token);
}
mTrackerHandler.sendMessage(mTrackerHandler.obtainMessage(
EVENT_PROVISIONING_NOTIFICATION, PROVISIONING_NOTIFICATION_SHOW,
mNetId, pendingIntent));
}
@Override
public void hideProvisioningNotification() {
mTrackerHandler.sendMessage(mTrackerHandler.obtainMessage(
EVENT_PROVISIONING_NOTIFICATION, PROVISIONING_NOTIFICATION_HIDE, mNetId));
}
@Override
public void notifyDataStallSuspected(DataStallReportParcelable p) {
ConnectivityService.this.notifyDataStallSuspected(p, mNetId);
}
@Override
public int getInterfaceVersion() {
return this.VERSION;
}
@Override
public String getInterfaceHash() {
return this.HASH;
}
}
/**
* Converts the given NetworkMonitor-specific validation result bitmask to a
* ConnectivityDiagnostics-specific validation result int.
*/
private int networkMonitorValidationResultToConnDiagsValidationResult(int validationResult) {
if ((validationResult & NETWORK_VALIDATION_RESULT_SKIPPED) != 0) {
return ConnectivityReport.NETWORK_VALIDATION_RESULT_SKIPPED;
}
if ((validationResult & NETWORK_VALIDATION_RESULT_VALID) == 0) {
return ConnectivityReport.NETWORK_VALIDATION_RESULT_INVALID;
}
return (validationResult & NETWORK_VALIDATION_RESULT_PARTIAL) != 0
? ConnectivityReport.NETWORK_VALIDATION_RESULT_PARTIALLY_VALID
: ConnectivityReport.NETWORK_VALIDATION_RESULT_VALID;
}
private void notifyDataStallSuspected(DataStallReportParcelable p, int netId) {
log("Data stall detected with methods: " + p.detectionMethod);
final PersistableBundle extras = new PersistableBundle();
int detectionMethod = 0;
if (hasDataStallDetectionMethod(p, DETECTION_METHOD_DNS_EVENTS)) {
extras.putInt(KEY_DNS_CONSECUTIVE_TIMEOUTS, p.dnsConsecutiveTimeouts);
detectionMethod |= DETECTION_METHOD_DNS_EVENTS;
}
if (hasDataStallDetectionMethod(p, DETECTION_METHOD_TCP_METRICS)) {
extras.putInt(KEY_TCP_PACKET_FAIL_RATE, p.tcpPacketFailRate);
extras.putInt(KEY_TCP_METRICS_COLLECTION_PERIOD_MILLIS,
p.tcpMetricsCollectionPeriodMillis);
detectionMethod |= DETECTION_METHOD_TCP_METRICS;
}
final Message msg = mConnectivityDiagnosticsHandler.obtainMessage(
ConnectivityDiagnosticsHandler.EVENT_DATA_STALL_SUSPECTED, detectionMethod, netId,
new Pair<>(p.timestampMillis, extras));
// NetworkStateTrackerHandler currently doesn't take any actions based on data
// stalls so send the message directly to ConnectivityDiagnosticsHandler and avoid
// the cost of going through two handlers.
mConnectivityDiagnosticsHandler.sendMessage(msg);
}
private boolean hasDataStallDetectionMethod(DataStallReportParcelable p, int detectionMethod) {
return (p.detectionMethod & detectionMethod) != 0;
}
private boolean networkRequiresPrivateDnsValidation(NetworkAgentInfo nai) {
return isPrivateDnsValidationRequired(nai.networkCapabilities);
}
private void handleFreshlyValidatedNetwork(NetworkAgentInfo nai) {
if (nai == null) return;
// If the Private DNS mode is opportunistic, reprogram the DNS servers
// in order to restart a validation pass from within netd.
final PrivateDnsConfig cfg = mDnsManager.getPrivateDnsConfig();
if (cfg.inOpportunisticMode()) {
updateDnses(nai.linkProperties, null, nai.network.getNetId());
}
}
private void handlePrivateDnsSettingsChanged() {
final PrivateDnsConfig cfg = mDnsManager.getPrivateDnsConfig();
for (NetworkAgentInfo nai : mNetworkAgentInfos) {
handlePerNetworkPrivateDnsConfig(nai, cfg);
if (networkRequiresPrivateDnsValidation(nai)) {
handleUpdateLinkProperties(nai, new LinkProperties(nai.linkProperties));
}
}
}
private void handlePerNetworkPrivateDnsConfig(NetworkAgentInfo nai, PrivateDnsConfig cfg) {
// Private DNS only ever applies to networks that might provide
// Internet access and therefore also require validation.
if (!networkRequiresPrivateDnsValidation(nai)) return;
// Notify the NetworkAgentInfo/NetworkMonitor in case NetworkMonitor needs to cancel or
// schedule DNS resolutions. If a DNS resolution is required the
// result will be sent back to us.
nai.networkMonitor().notifyPrivateDnsChanged(cfg.toParcel());
// With Private DNS bypass support, we can proceed to update the
// Private DNS config immediately, even if we're in strict mode
// and have not yet resolved the provider name into a set of IPs.
updatePrivateDns(nai, cfg);
}
private void updatePrivateDns(NetworkAgentInfo nai, PrivateDnsConfig newCfg) {
mDnsManager.updatePrivateDns(nai.network, newCfg);
updateDnses(nai.linkProperties, null, nai.network.getNetId());
}
private void handlePrivateDnsValidationUpdate(PrivateDnsValidationUpdate update) {
NetworkAgentInfo nai = getNetworkAgentInfoForNetId(update.netId);
if (nai == null) {
return;
}
mDnsManager.updatePrivateDnsValidation(update);
handleUpdateLinkProperties(nai, new LinkProperties(nai.linkProperties));
}
private void handleNat64PrefixEvent(int netId, int operation, String prefixAddress,
int prefixLength) {
NetworkAgentInfo nai = mNetworkForNetId.get(netId);
if (nai == null) return;
log(String.format("NAT64 prefix changed on netId %d: operation=%d, %s/%d",
netId, operation, prefixAddress, prefixLength));
IpPrefix prefix = null;
if (operation == IDnsResolverUnsolicitedEventListener.PREFIX_OPERATION_ADDED) {
try {
prefix = new IpPrefix(InetAddresses.parseNumericAddress(prefixAddress),
prefixLength);
} catch (IllegalArgumentException e) {
loge("Invalid NAT64 prefix " + prefixAddress + "/" + prefixLength);
return;
}
}
nai.clatd.setNat64PrefixFromDns(prefix);
handleUpdateLinkProperties(nai, new LinkProperties(nai.linkProperties));
}
private void handleCapportApiDataUpdate(@NonNull final NetworkAgentInfo nai,
@Nullable final CaptivePortalData data) {
nai.capportApiData = data;
// CaptivePortalData will be merged into LinkProperties from NetworkAgentInfo
handleUpdateLinkProperties(nai, new LinkProperties(nai.linkProperties));
}
/**
* Updates the inactivity state from the network requests inside the NAI.
* @param nai the agent info to update
* @param now the timestamp of the event causing this update
* @return whether the network was inactive as a result of this update
*/
private boolean updateInactivityState(@NonNull final NetworkAgentInfo nai, final long now) {
// 1. Update the inactivity timer. If it's changed, reschedule or cancel the alarm.
// 2. If the network was inactive and there are now requests, unset inactive.
// 3. If this network is unneeded (which implies it is not lingering), and there is at least
// one lingered request, set inactive.
nai.updateInactivityTimer();
if (nai.isInactive() && nai.numForegroundNetworkRequests() > 0) {
if (DBG) log("Unsetting inactive " + nai.toShortString());
nai.unsetInactive();
logNetworkEvent(nai, NetworkEvent.NETWORK_UNLINGER);
} else if (unneeded(nai, UnneededFor.LINGER) && nai.getInactivityExpiry() > 0) {
if (DBG) {
final int lingerTime = (int) (nai.getInactivityExpiry() - now);
log("Setting inactive " + nai.toShortString() + " for " + lingerTime + "ms");
}
nai.setInactive();
logNetworkEvent(nai, NetworkEvent.NETWORK_LINGER);
return true;
}
return false;
}
private void handleNetworkAgentRegistered(Message msg) {
final NetworkAgentInfo nai = (NetworkAgentInfo) msg.obj;
if (!mNetworkAgentInfos.contains(nai)) {
return;
}
if (msg.arg1 == NetworkAgentInfo.ARG_AGENT_SUCCESS) {
if (VDBG) log("NetworkAgent registered");
} else {
loge("Error connecting NetworkAgent");
mNetworkAgentInfos.remove(nai);
if (nai != null) {
final boolean wasDefault = isDefaultNetwork(nai);
synchronized (mNetworkForNetId) {
mNetworkForNetId.remove(nai.network.getNetId());
}
mNetIdManager.releaseNetId(nai.network.getNetId());
// Just in case.
mLegacyTypeTracker.remove(nai, wasDefault);
}
}
}
@VisibleForTesting
protected static boolean shouldCreateNetworksImmediately() {
// The feature of creating the networks immediately was slated for U, but race conditions
// detected late required this was flagged off.
// TODO : enable this in a Mainline update or in V, and re-enable the test for this
// in NetworkAgentTest.
return false;
}
private static boolean shouldCreateNativeNetwork(@NonNull NetworkAgentInfo nai,
@NonNull NetworkInfo.State state) {
if (nai.isCreated()) return false;
if (state == NetworkInfo.State.CONNECTED) return true;
if (state != NetworkInfo.State.CONNECTING) {
// TODO: throw if no WTFs are observed in the field.
if (shouldCreateNetworksImmediately()) {
Log.wtf(TAG, "Uncreated network in invalid state: " + state);
}
return false;
}
return nai.isVPN() || shouldCreateNetworksImmediately();
}
private static boolean shouldDestroyNativeNetwork(@NonNull NetworkAgentInfo nai) {
return nai.isCreated() && !nai.isDestroyed();
}
@VisibleForTesting
boolean shouldIgnoreValidationFailureAfterRoam(NetworkAgentInfo nai) {
// T+ devices should use unregisterAfterReplacement.
if (mDeps.isAtLeastT()) return false;
// If the network never roamed, return false. The check below is not sufficient if time
// since boot is less than blockTimeOut, though that's extremely unlikely to happen.
if (nai.lastRoamTime == 0) return false;
final long blockTimeOut = Long.valueOf(mResources.get().getInteger(
R.integer.config_validationFailureAfterRoamIgnoreTimeMillis));
if (blockTimeOut <= MAX_VALIDATION_IGNORE_AFTER_ROAM_TIME_MS
&& blockTimeOut >= 0) {
final long currentTimeMs = SystemClock.elapsedRealtime();
long timeSinceLastRoam = currentTimeMs - nai.lastRoamTime;
if (timeSinceLastRoam <= blockTimeOut) {
log ("blocked because only " + timeSinceLastRoam + "ms after roam");
return true;
}
}
return false;
}
private void handleNetworkAgentDisconnected(Message msg) {
NetworkAgentInfo nai = (NetworkAgentInfo) msg.obj;
disconnectAndDestroyNetwork(nai);
}
// Destroys a network, remove references to it from the internal state managed by
// ConnectivityService, free its interfaces and clean up.
// Must be called on the Handler thread.
private void disconnectAndDestroyNetwork(NetworkAgentInfo nai) {
ensureRunningOnConnectivityServiceThread();
if (!mNetworkAgentInfos.contains(nai)) return;
if (DBG) {
log(nai.toShortString() + " disconnected, was satisfying " + nai.numNetworkRequests());
}
// Clear all notifications of this network.
mNotifier.clearNotification(nai.network.getNetId());
// A network agent has disconnected.
// TODO - if we move the logic to the network agent (have them disconnect
// because they lost all their requests or because their score isn't good)
// then they would disconnect organically, report their new state and then
// disconnect the channel.
if (nai.networkInfo.isConnected() || nai.networkInfo.isSuspended()) {
nai.networkInfo.setDetailedState(NetworkInfo.DetailedState.DISCONNECTED,
null, null);
}
final boolean wasDefault = isDefaultNetwork(nai);
if (wasDefault) {
mDefaultInetConditionPublished = 0;
}
if (mTrackMultiNetworkActivities) {
// If trackMultiNetworkActivities is disabled, ActivityTracker removes idleTimer when
// the network becomes no longer the default network.
mNetworkActivityTracker.removeDataActivityTracking(nai);
}
notifyIfacesChangedForNetworkStats();
// If this was a local network forwarded to some upstream, or if some local network was
// forwarded to this nai, then disable forwarding rules now.
maybeDisableForwardRulesForDisconnectingNai(nai, true /* sendCallbacks */);
// If this is a local network with an upstream selector, remove the associated network
// request.
if (nai.isLocalNetwork()) {
final NetworkRequest selector = nai.localNetworkConfig.getUpstreamSelector();
if (null != selector) {
handleRemoveNetworkRequest(mNetworkRequests.get(selector));
}
}
// TODO - we shouldn't send CALLBACK_LOST to requests that can be satisfied
// by other networks that are already connected. Perhaps that can be done by
// sending all CALLBACK_LOST messages (for requests, not listens) at the end
// of rematchAllNetworksAndRequests
notifyNetworkCallbacks(nai, ConnectivityManager.CALLBACK_LOST);
mKeepaliveTracker.handleStopAllKeepalives(nai, SocketKeepalive.ERROR_INVALID_NETWORK);
mQosCallbackTracker.handleNetworkReleased(nai.network);
for (String iface : nai.linkProperties.getAllInterfaceNames()) {
// Disable wakeup packet monitoring for each interface.
wakeupModifyInterface(iface, nai, false);
}
nai.networkMonitor().notifyNetworkDisconnected();
mNetworkAgentInfos.remove(nai);
nai.clatd.update();
synchronized (mNetworkForNetId) {
// Remove the NetworkAgent, but don't mark the netId as
// available until we've told netd to delete it below.
mNetworkForNetId.remove(nai.network.getNetId());
}
propagateUnderlyingNetworkCapabilities(nai.network);
// Update allowed network lists in netd. This should be called after removing nai
// from mNetworkAgentInfos.
updateProfileAllowedNetworks();
// Remove all previously satisfied requests.
for (int i = 0; i < nai.numNetworkRequests(); i++) {
final NetworkRequest request = nai.requestAt(i);
final NetworkRequestInfo nri = mNetworkRequests.get(request);
final NetworkAgentInfo currentNetwork = nri.getSatisfier();
if (currentNetwork != null
&& currentNetwork.network.getNetId() == nai.network.getNetId()) {
// uid rules for this network will be removed in destroyNativeNetwork(nai).
// TODO : setting the satisfier is in fact the job of the rematch. Teach the
// rematch not to keep disconnected agents instead of setting it here ; this
// will also allow removing updating the offers below.
nri.setSatisfier(null, null);
for (final NetworkOfferInfo noi : mNetworkOffers) {
informOffer(nri, noi.offer, mNetworkRanker);
}
if (mDefaultRequest == nri) {
mNetworkActivityTracker.updateDefaultNetwork(null /* newNetwork */, nai);
maybeClosePendingFrozenSockets(null /* newNetwork */, nai);
ensureNetworkTransitionWakelock(nai.toShortString());
}
}
}
nai.clearInactivityState();
// TODO: mLegacyTypeTracker.remove seems redundant given there's a full rematch right after.
// Currently, deleting it breaks tests that check for the default network disconnecting.
// Find out why, fix the rematch code, and delete this.
mLegacyTypeTracker.remove(nai, wasDefault);
rematchAllNetworksAndRequests();
mLingerMonitor.noteDisconnect(nai);
if (null == getDefaultNetwork() && nai.linkProperties.getHttpProxy() != null) {
// The obvious place to do this would be in makeDefault(), however makeDefault() is
// not called by the rematch in this case. This is because the code above unset
// this network from the default request's satisfier, and that is what the rematch
// is using as its source data to know what the old satisfier was. So as far as the
// rematch above is concerned, the old default network was null.
// Therefore if there is no new default, the default network was null and is still
// null, thus there was no change so makeDefault() is not called. So if the old
// network had a proxy and there is no new default, the proxy tracker should be told
// that there is no longer a default proxy.
// Strictly speaking this is not essential because having a proxy setting when
// there is no network is harmless, but it's still counter-intuitive so reset to null.
mProxyTracker.setDefaultProxy(null);
}
// Immediate teardown.
if (nai.teardownDelayMs == 0) {
destroyNetwork(nai);
return;
}
// Delayed teardown.
if (nai.isCreated()) {
try {
mNetd.networkSetPermissionForNetwork(nai.network.netId, INetd.PERMISSION_SYSTEM);
} catch (RemoteException e) {
Log.d(TAG, "Error marking network restricted during teardown: ", e);
}
}
mHandler.postDelayed(() -> destroyNetwork(nai), nai.teardownDelayMs);
}
private void destroyNetwork(NetworkAgentInfo nai) {
if (shouldDestroyNativeNetwork(nai)) {
// Tell netd to clean up the configuration for this network
// (routing rules, DNS, etc).
// This may be slow as it requires a lot of netd shelling out to ip and
// ip[6]tables to flush routes and remove the incoming packet mark rule, so do it
// after we've rematched networks with requests (which might change the default
// network or service a new request from an app), so network traffic isn't interrupted
// for an unnecessarily long time.
destroyNativeNetwork(nai);
}
if (!nai.isCreated() && !mDeps.isAtLeastT()) {
// Backwards compatibility: send onNetworkDestroyed even if network was never created.
// This can never run if the code above runs because shouldDestroyNativeNetwork is
// false if the network was never created.
// TODO: delete when S is no longer supported.
nai.onNetworkDestroyed();
}
mNetIdManager.releaseNetId(nai.network.getNetId());
}
private void maybeDisableForwardRulesForDisconnectingNai(
@NonNull final NetworkAgentInfo disconnecting, final boolean sendCallbacks) {
// Step 1 : maybe this network was the upstream for one or more local networks.
for (final NetworkAgentInfo local : mNetworkAgentInfos) {
if (!local.isLocalNetwork()) continue;
final NetworkRequest selector = local.localNetworkConfig.getUpstreamSelector();
if (null == selector) continue;
final NetworkRequestInfo nri = mNetworkRequests.get(selector);
// null == nri can happen while disconnecting a network, because destroyNetwork() is
// called after removing all associated NRIs from mNetworkRequests.
if (null == nri) continue;
final NetworkAgentInfo satisfier = nri.getSatisfier();
if (disconnecting != satisfier) continue;
removeLocalNetworkUpstream(local, disconnecting);
// Set the satisfier to null immediately so that the LOCAL_NETWORK_CHANGED callback
// correctly contains null as an upstream.
if (sendCallbacks) {
nri.setSatisfier(null, null);
notifyNetworkCallbacks(local,
ConnectivityManager.CALLBACK_LOCAL_NETWORK_INFO_CHANGED);
}
}
// Step 2 : maybe this is a local network that had an upstream.
if (!disconnecting.isLocalNetwork()) return;
final NetworkRequest selector = disconnecting.localNetworkConfig.getUpstreamSelector();
if (null == selector) return;
final NetworkRequestInfo nri = mNetworkRequests.get(selector);
// As above null == nri can happen while disconnecting a network, because destroyNetwork()
// is called after removing all associated NRIs from mNetworkRequests.
if (null == nri) return;
final NetworkAgentInfo satisfier = nri.getSatisfier();
if (null == satisfier) return;
removeLocalNetworkUpstream(disconnecting, satisfier);
}
private void removeLocalNetworkUpstream(@NonNull final NetworkAgentInfo localAgent,
@NonNull final NetworkAgentInfo upstream) {
try {
mRoutingCoordinatorService.removeInterfaceForward(
localAgent.linkProperties.getInterfaceName(),
upstream.linkProperties.getInterfaceName());
} catch (RemoteException e) {
loge("Couldn't remove interface forward for "
+ localAgent.linkProperties.getInterfaceName() + " to "
+ upstream.linkProperties.getInterfaceName() + " while disconnecting");
}
}
private boolean createNativeNetwork(@NonNull NetworkAgentInfo nai) {
try {
// This should never fail. Specifying an already in use NetID will cause failure.
final NativeNetworkConfig config;
if (nai.isVPN()) {
if (getVpnType(nai) == VpnManager.TYPE_VPN_NONE) {
Log.wtf(TAG, "Unable to get VPN type from network " + nai.toShortString());
return false;
}
config = new NativeNetworkConfig(nai.network.getNetId(), NativeNetworkType.VIRTUAL,
INetd.PERMISSION_NONE,
!nai.networkAgentConfig.allowBypass /* secure */,
getVpnType(nai), nai.networkAgentConfig.excludeLocalRouteVpn);
} else {
config = new NativeNetworkConfig(nai.network.getNetId(),
nai.isLocalNetwork() ? NativeNetworkType.PHYSICAL_LOCAL
: NativeNetworkType.PHYSICAL,
getNetworkPermission(nai.networkCapabilities),
false /* secure */,
VpnManager.TYPE_VPN_NONE,
false /* excludeLocalRoutes */);
}
mNetd.networkCreate(config);
mDnsResolver.createNetworkCache(nai.network.getNetId());
mDnsManager.updateCapabilitiesForNetwork(nai.network.getNetId(),
nai.networkCapabilities);
return true;
} catch (RemoteException | ServiceSpecificException e) {
loge("Error creating network " + nai.toShortString() + ": " + e.getMessage());
return false;
}
}
private void destroyNativeNetwork(@NonNull NetworkAgentInfo nai) {
if (mDscpPolicyTracker != null) {
mDscpPolicyTracker.removeAllDscpPolicies(nai, false);
}
// Remove any forwarding rules to and from the interface for this network, since
// the interface is going to go away. Don't send the callbacks however ; if the network
// was is being disconnected the callbacks have already been sent, and if it is being
// destroyed pending replacement they will be sent when it is disconnected.
maybeDisableForwardRulesForDisconnectingNai(nai, false /* sendCallbacks */);
try {
mNetd.networkDestroy(nai.network.getNetId());
} catch (RemoteException | ServiceSpecificException e) {
loge("Exception destroying network(networkDestroy): " + e);
}
try {
mDnsResolver.destroyNetworkCache(nai.network.getNetId());
} catch (RemoteException | ServiceSpecificException e) {
loge("Exception destroying network: " + e);
}
// TODO: defer calling this until the network is removed from mNetworkAgentInfos.
// Otherwise, a private DNS configuration update for a destroyed network, or one that never
// gets created, could add data to DnsManager data structures that will never get deleted.
mDnsManager.removeNetwork(nai.network);
// clean up tc police filters on interface.
if (nai.everConnected() && canNetworkBeRateLimited(nai) && mIngressRateLimit >= 0) {
mDeps.disableIngressRateLimit(nai.linkProperties.getInterfaceName());
}
nai.setDestroyed();
nai.onNetworkDestroyed();
}
// If this method proves to be too slow then we can maintain a separate
// pendingIntent => NetworkRequestInfo map.
// This method assumes that every non-null PendingIntent maps to exactly 1 NetworkRequestInfo.
private NetworkRequestInfo findExistingNetworkRequestInfo(PendingIntent pendingIntent) {
for (Map.Entry<NetworkRequest, NetworkRequestInfo> entry : mNetworkRequests.entrySet()) {
PendingIntent existingPendingIntent = entry.getValue().mPendingIntent;
if (existingPendingIntent != null &&
mDeps.intentFilterEquals(existingPendingIntent, pendingIntent)) {
return entry.getValue();
}
}
return null;
}
private void checkNrisConsistency(final NetworkRequestInfo nri) {
if (mDeps.isAtLeastT()) {
for (final NetworkRequestInfo n : mNetworkRequests.values()) {
if (n.mBinder != null && n.mBinder == nri.mBinder) {
// Temporary help to debug b/194394697 ; TODO : remove this function when the
// bug is fixed.
dumpAllRequestInfoLogsToLogcat();
throw new IllegalStateException("This NRI is already registered. New : " + nri
+ ", existing : " + n);
}
}
}
}
private boolean hasCarrierPrivilegeForNetworkCaps(final int callingUid,
@NonNull final NetworkCapabilities caps) {
if (mCarrierPrivilegeAuthenticator != null) {
return mCarrierPrivilegeAuthenticator.isCarrierServiceUidForNetworkCapabilities(
callingUid, caps);
}
return false;
}
private void handleRegisterNetworkRequestWithIntent(@NonNull final Message msg) {
final NetworkRequestInfo nri = (NetworkRequestInfo) (msg.obj);
// handleRegisterNetworkRequestWithIntent() doesn't apply to multilayer requests.
ensureNotMultilayerRequest(nri, "handleRegisterNetworkRequestWithIntent");
final NetworkRequestInfo existingRequest =
findExistingNetworkRequestInfo(nri.mPendingIntent);
if (existingRequest != null) { // remove the existing request.
if (DBG) {
log("Replacing " + existingRequest.mRequests.get(0) + " with "
+ nri.mRequests.get(0) + " because their intents matched.");
}
handleReleaseNetworkRequest(existingRequest.mRequests.get(0), mDeps.getCallingUid(),
/* callOnUnavailable */ false);
}
handleRegisterNetworkRequest(nri);
}
private void handleRegisterNetworkRequest(@NonNull final NetworkRequestInfo nri) {
handleRegisterNetworkRequests(Collections.singleton(nri));
}
private void handleRegisterNetworkRequests(@NonNull final Set<NetworkRequestInfo> nris) {
ensureRunningOnConnectivityServiceThread();
for (final NetworkRequestInfo nri : nris) {
mNetworkRequestInfoLogs.log("REGISTER " + nri);
checkNrisConsistency(nri);
for (final NetworkRequest req : nri.mRequests) {
mNetworkRequests.put(req, nri);
// TODO: Consider update signal strength for other types.
if (req.isListen()) {
for (final NetworkAgentInfo network : mNetworkAgentInfos) {
if (req.networkCapabilities.hasSignalStrength()
&& network.satisfiesImmutableCapabilitiesOf(req)) {
updateSignalStrengthThresholds(network, "REGISTER", req);
}
}
}
}
// If this NRI has a satisfier already, it is replacing an older request that
// has been removed. Track it.
final NetworkRequest activeRequest = nri.getActiveRequest();
if (null != activeRequest) {
// If there is an active request, then for sure there is a satisfier.
nri.getSatisfier().addRequest(activeRequest);
}
}
if (mFlags.noRematchAllRequestsOnRegister()) {
rematchNetworksAndRequests(nris);
} else {
rematchAllNetworksAndRequests();
}
// Requests that have not been matched to a network will not have been sent to the
// providers, because the old satisfier and the new satisfier are the same (null in this
// case). Send these requests to the providers.
for (final NetworkRequestInfo nri : nris) {
for (final NetworkOfferInfo noi : mNetworkOffers) {
informOffer(nri, noi.offer, mNetworkRanker);
}
}
}
private void handleReleaseNetworkRequestWithIntent(@NonNull final PendingIntent pendingIntent,
final int callingUid) {
final NetworkRequestInfo nri = findExistingNetworkRequestInfo(pendingIntent);
if (nri != null) {
// handleReleaseNetworkRequestWithIntent() paths don't apply to multilayer requests.
ensureNotMultilayerRequest(nri, "handleReleaseNetworkRequestWithIntent");
handleReleaseNetworkRequest(
nri.mRequests.get(0),
callingUid,
/* callOnUnavailable */ false);
}
}
// Determines whether the network is the best (or could become the best, if it validated), for
// none of a particular type of NetworkRequests. The type of NetworkRequests considered depends
// on the value of reason:
//
// - UnneededFor.TEARDOWN: non-listen NetworkRequests. If a network is unneeded for this reason,
// then it should be torn down.
// - UnneededFor.LINGER: foreground NetworkRequests. If a network is unneeded for this reason,
// then it should be lingered.
private boolean unneeded(NetworkAgentInfo nai, UnneededFor reason) {
ensureRunningOnConnectivityServiceThread();
if (!nai.everConnected() || nai.isVPN() || nai.isInactive()
|| nai.getScore().getKeepConnectedReason() != NetworkScore.KEEP_CONNECTED_NONE) {
return false;
}
final int numRequests;
switch (reason) {
case TEARDOWN:
numRequests = nai.numRequestNetworkRequests();
break;
case LINGER:
numRequests = nai.numForegroundNetworkRequests();
break;
default:
Log.wtf(TAG, "Invalid reason. Cannot happen.");
return true;
}
if (numRequests > 0) return false;
for (NetworkRequestInfo nri : mNetworkRequests.values()) {
if (reason == UnneededFor.LINGER
&& !nri.isMultilayerRequest()
&& nri.mRequests.get(0).isBackgroundRequest()) {
// Background requests don't affect lingering.
continue;
}
if (isNetworkPotentialSatisfier(nai, nri)) {
return false;
}
}
return true;
}
private boolean isNetworkPotentialSatisfier(
@NonNull final NetworkAgentInfo candidate, @NonNull final NetworkRequestInfo nri) {
// While destroyed network sometimes satisfy requests (including occasionally newly
// satisfying requests), *potential* satisfiers are networks that might beat a current
// champion if they validate. As such, a destroyed network is never a potential satisfier,
// because it's never a good idea to keep a destroyed network in case it validates.
// For example, declaring it a potential satisfier would keep an unvalidated destroyed
// candidate after it's been replaced by another unvalidated network.
if (candidate.isDestroyed()) return false;
// Listen requests won't keep up a network satisfying it. If this is not a multilayer
// request, return immediately. For multilayer requests, check to see if any of the
// multilayer requests may have a potential satisfier.
if (!nri.isMultilayerRequest() && (nri.mRequests.get(0).isListen()
|| nri.mRequests.get(0).isListenForBest())) {
return false;
}
for (final NetworkRequest req : nri.mRequests) {
// This multilayer listen request is satisfied therefore no further requests need to be
// evaluated deeming this network not a potential satisfier.
if ((req.isListen() || req.isListenForBest()) && nri.getActiveRequest() == req) {
return false;
}
// As non-multilayer listen requests have already returned, the below would only happen
// for a multilayer request therefore continue to the next request if available.
if (req.isListen() || req.isListenForBest()) {
continue;
}
// If there is hope for this network might validate and subsequently become the best
// network for that request, then it is needed. Note that this network can't already
// be the best for this request, or it would be the current satisfier, and therefore
// there would be no need to call this method to find out if it is a *potential*
// satisfier ("unneeded", the only caller, only calls this if this network currently
// satisfies no request).
if (candidate.satisfies(req)) {
// As soon as a network is found that satisfies a request, return. Specifically for
// multilayer requests, returning as soon as a NetworkAgentInfo satisfies a request
// is important so as to not evaluate lower priority requests further in
// nri.mRequests.
final NetworkAgentInfo champion = req.equals(nri.getActiveRequest())
? nri.getSatisfier() : null;
// Note that this catches two important cases:
// 1. Unvalidated cellular will not be reaped when unvalidated WiFi
// is currently satisfying the request. This is desirable when
// cellular ends up validating but WiFi does not.
// 2. Unvalidated WiFi will not be reaped when validated cellular
// is currently satisfying the request. This is desirable when
// WiFi ends up validating and out scoring cellular.
return mNetworkRanker.mightBeat(req, champion, candidate.getValidatedScoreable());
}
}
return false;
}
private NetworkRequestInfo getNriForAppRequest(
NetworkRequest request, int callingUid, String requestedOperation) {
// Looking up the app passed param request in mRequests isn't possible since it may return
// null for a request managed by a per-app default. Therefore use getNriForAppRequest() to
// do the lookup since that will also find per-app default managed requests.
// Additionally, this lookup needs to be relatively fast (hence the lookup optimization)
// to avoid potential race conditions when validating a package->uid mapping when sending
// the callback on the very low-chance that an application shuts down prior to the callback
// being sent.
final NetworkRequestInfo nri = mNetworkRequests.get(request) != null
? mNetworkRequests.get(request) : getNriForAppRequest(request);
if (nri != null) {
if (Process.SYSTEM_UID != callingUid && nri.mUid != callingUid) {
log(String.format("UID %d attempted to %s for unowned request %s",
callingUid, requestedOperation, nri));
return null;
}
}
return nri;
}
private void ensureNotMultilayerRequest(@NonNull final NetworkRequestInfo nri,
final String callingMethod) {
if (nri.isMultilayerRequest()) {
throw new IllegalStateException(
callingMethod + " does not support multilayer requests.");
}
}
private void handleTimedOutNetworkRequest(@NonNull final NetworkRequestInfo nri) {
ensureRunningOnConnectivityServiceThread();
// handleTimedOutNetworkRequest() is part of the requestNetwork() flow which works off of a
// single NetworkRequest and thus does not apply to multilayer requests.
ensureNotMultilayerRequest(nri, "handleTimedOutNetworkRequest");
if (mNetworkRequests.get(nri.mRequests.get(0)) == null) {
return;
}
if (nri.isBeingSatisfied()) {
return;
}
if (VDBG || (DBG && nri.mRequests.get(0).isRequest())) {
log("releasing " + nri.mRequests.get(0) + " (timeout)");
}
handleRemoveNetworkRequest(nri);
callCallbackForRequest(
nri, null, ConnectivityManager.CALLBACK_UNAVAIL, 0);
}
private void handleReleaseNetworkRequest(@NonNull final NetworkRequest request,
final int callingUid,
final boolean callOnUnavailable) {
final NetworkRequestInfo nri =
getNriForAppRequest(request, callingUid, "release NetworkRequest");
if (nri == null) {
return;
}
if (VDBG || (DBG && request.isRequest())) {
log("releasing " + request + " (release request)");
}
handleRemoveNetworkRequest(nri);
if (callOnUnavailable) {
callCallbackForRequest(nri, null, ConnectivityManager.CALLBACK_UNAVAIL, 0);
}
}
private void handleRemoveNetworkRequest(@NonNull final NetworkRequestInfo nri) {
ensureRunningOnConnectivityServiceThread();
for (final NetworkRequest req : nri.mRequests) {
if (null == mNetworkRequests.remove(req)) {
logw("Attempted removal of untracked request " + req + " for nri " + nri);
continue;
}
if (req.isListen()) {
removeListenRequestFromNetworks(req);
}
}
nri.unlinkDeathRecipient();
if (mDefaultNetworkRequests.remove(nri)) {
// If this request was one of the defaults, then the UID rules need to be updated
// WARNING : if the app(s) for which this network request is the default are doing
// traffic, this will kill their connected sockets, even if an equivalent request
// is going to be reinstated right away ; unconnected traffic will go on the default
// until the new default is set, which will happen very soon.
// TODO : The only way out of this is to diff old defaults and new defaults, and only
// remove ranges for those requests that won't have a replacement
final NetworkAgentInfo satisfier = nri.getSatisfier();
if (null != satisfier) {
try {
mNetd.networkRemoveUidRangesParcel(new NativeUidRangeConfig(
satisfier.network.getNetId(),
toUidRangeStableParcels(nri.getUids()),
nri.getPreferenceOrderForNetd()));
} catch (RemoteException e) {
loge("Exception setting network preference default network", e);
}
}
}
nri.mPerUidCounter.decrementCount(nri.mUid);
mNetworkRequestInfoLogs.log("RELEASE " + nri);
checkNrisConsistency(nri);
if (null != nri.getActiveRequest()) {
if (!nri.getActiveRequest().isListen()) {
removeSatisfiedNetworkRequestFromNetwork(nri);
}
}
// For all outstanding offers, cancel any of the layers of this NRI that used to be
// needed for this offer.
for (final NetworkOfferInfo noi : mNetworkOffers) {
for (final NetworkRequest req : nri.mRequests) {
if (req.isRequest() && noi.offer.neededFor(req)) {
noi.offer.onNetworkUnneeded(req);
}
}
}
}
private void handleRemoveNetworkRequests(@NonNull final Set<NetworkRequestInfo> nris) {
for (final NetworkRequestInfo nri : nris) {
if (mDefaultRequest == nri) {
// Make sure we never remove the default request.
continue;
}
handleRemoveNetworkRequest(nri);
}
}
private void removeListenRequestFromNetworks(@NonNull final NetworkRequest req) {
// listens don't have a singular affected Network. Check all networks to see
// if this listen request applies and remove it.
for (final NetworkAgentInfo nai : mNetworkAgentInfos) {
nai.removeRequest(req.requestId);
if (req.networkCapabilities.hasSignalStrength()
&& nai.satisfiesImmutableCapabilitiesOf(req)) {
updateSignalStrengthThresholds(nai, "RELEASE", req);
}
}
}
/**
* Remove a NetworkRequestInfo's satisfied request from its 'satisfier' (NetworkAgentInfo) and
* manage the necessary upkeep (linger, teardown networks, etc.) when doing so.
* @param nri the NetworkRequestInfo to disassociate from its current NetworkAgentInfo
*/
private void removeSatisfiedNetworkRequestFromNetwork(@NonNull final NetworkRequestInfo nri) {
boolean wasKept = false;
final NetworkAgentInfo nai = nri.getSatisfier();
if (nai != null) {
final int requestLegacyType = nri.getActiveRequest().legacyType;
final boolean wasBackgroundNetwork = nai.isBackgroundNetwork();
nai.removeRequest(nri.getActiveRequest().requestId);
if (VDBG || DDBG) {
log(" Removing from current network " + nai.toShortString()
+ ", leaving " + nai.numNetworkRequests() + " requests.");
}
// If there are still lingered requests on this network, don't tear it down,
// but resume lingering instead.
final long now = SystemClock.elapsedRealtime();
if (updateInactivityState(nai, now)) {
notifyNetworkLosing(nai, now);
}
if (unneeded(nai, UnneededFor.TEARDOWN)) {
if (DBG) log("no live requests for " + nai.toShortString() + "; disconnecting");
teardownUnneededNetwork(nai);
} else {
wasKept = true;
}
if (!wasBackgroundNetwork && nai.isBackgroundNetwork()) {
// Went from foreground to background.
updateCapabilitiesForNetwork(nai);
}
// Maintain the illusion. When this request arrived, we might have pretended
// that a network connected to serve it, even though the network was already
// connected. Now that this request has gone away, we might have to pretend
// that the network disconnected. LegacyTypeTracker will generate that
// phantom disconnect for this type.
if (requestLegacyType != TYPE_NONE) {
boolean doRemove = true;
if (wasKept) {
// check if any of the remaining requests for this network are for the
// same legacy type - if so, don't remove the nai
for (int i = 0; i < nai.numNetworkRequests(); i++) {
NetworkRequest otherRequest = nai.requestAt(i);
if (otherRequest.legacyType == requestLegacyType
&& otherRequest.isRequest()) {
if (DBG) log(" still have other legacy request - leaving");
doRemove = false;
}
}
}
if (doRemove) {
mLegacyTypeTracker.remove(requestLegacyType, nai, false);
}
}
}
}
private RequestInfoPerUidCounter getRequestCounter(NetworkRequestInfo nri) {
return checkAnyPermissionOf(mContext,
nri.mPid, nri.mUid, NetworkStack.PERMISSION_MAINLINE_NETWORK_STACK)
? mSystemNetworkRequestCounter : mNetworkRequestCounter;
}
@Override
public void setAcceptUnvalidated(Network network, boolean accept, boolean always) {
enforceNetworkStackSettingsOrSetup();
mHandler.sendMessage(mHandler.obtainMessage(EVENT_SET_ACCEPT_UNVALIDATED,
encodeBool(accept), encodeBool(always), network));
}
@Override
public void setAcceptPartialConnectivity(Network network, boolean accept, boolean always) {
enforceNetworkStackSettingsOrSetup();
mHandler.sendMessage(mHandler.obtainMessage(EVENT_SET_ACCEPT_PARTIAL_CONNECTIVITY,
encodeBool(accept), encodeBool(always), network));
}
@Override
public void setAvoidUnvalidated(Network network) {
enforceNetworkStackSettingsOrSetup();
mHandler.sendMessage(mHandler.obtainMessage(EVENT_SET_AVOID_UNVALIDATED, network));
}
@Override
public void setTestAllowBadWifiUntil(long timeMs) {
enforceSettingsPermission();
if (!Build.isDebuggable()) {
throw new IllegalStateException("Does not support in non-debuggable build");
}
if (timeMs > System.currentTimeMillis() + MAX_TEST_ALLOW_BAD_WIFI_UNTIL_MS) {
throw new IllegalArgumentException("It should not exceed "
+ MAX_TEST_ALLOW_BAD_WIFI_UNTIL_MS + "ms from now");
}
mHandler.sendMessage(
mHandler.obtainMessage(EVENT_SET_TEST_ALLOW_BAD_WIFI_UNTIL, timeMs));
}
@Override
public void setTestLowTcpPollingTimerForKeepalive(long timeMs) {
enforceSettingsPermission();
if (timeMs > System.currentTimeMillis() + MAX_TEST_LOW_TCP_POLLING_UNTIL_MS) {
throw new IllegalArgumentException("Argument should not exceed "
+ MAX_TEST_LOW_TCP_POLLING_UNTIL_MS + "ms from now");
}
mHandler.sendMessage(
mHandler.obtainMessage(EVENT_SET_LOW_TCP_POLLING_UNTIL, timeMs));
}
private void handleSetAcceptUnvalidated(Network network, boolean accept, boolean always) {
if (DBG) log("handleSetAcceptUnvalidated network=" + network +
" accept=" + accept + " always=" + always);
NetworkAgentInfo nai = getNetworkAgentInfoForNetwork(network);
if (nai == null) {
// Nothing to do.
return;
}
if (nai.everValidated()) {
// The network validated while the dialog box was up. Take no action.
return;
}
if (!nai.networkAgentConfig.explicitlySelected) {
Log.wtf(TAG, "BUG: setAcceptUnvalidated non non-explicitly selected network");
}
if (accept != nai.networkAgentConfig.acceptUnvalidated) {
nai.networkAgentConfig.acceptUnvalidated = accept;
// If network becomes partial connectivity and user already accepted to use this
// network, we should respect the user's option and don't need to popup the
// PARTIAL_CONNECTIVITY notification to user again.
nai.networkAgentConfig.acceptPartialConnectivity = accept;
nai.updateScoreForNetworkAgentUpdate();
rematchAllNetworksAndRequests();
}
if (always) {
nai.onSaveAcceptUnvalidated(accept);
}
if (!accept) {
// Tell the NetworkAgent to not automatically reconnect to the network.
nai.onPreventAutomaticReconnect();
// Teardown the network.
teardownUnneededNetwork(nai);
}
}
private void handleSetAcceptPartialConnectivity(Network network, boolean accept,
boolean always) {
if (DBG) {
log("handleSetAcceptPartialConnectivity network=" + network + " accept=" + accept
+ " always=" + always);
}
final NetworkAgentInfo nai = getNetworkAgentInfoForNetwork(network);
if (nai == null) {
// Nothing to do.
return;
}
if (nai.isValidated()) {
// The network validated while the dialog box was up. Take no action.
return;
}
if (accept != nai.networkAgentConfig.acceptPartialConnectivity) {
nai.networkAgentConfig.acceptPartialConnectivity = accept;
}
// TODO: Use the current design or save the user choice into IpMemoryStore.
if (always) {
nai.onSaveAcceptUnvalidated(accept);
}
if (!accept) {
// Tell the NetworkAgent to not automatically reconnect to the network.
nai.onPreventAutomaticReconnect();
// Tear down the network.
teardownUnneededNetwork(nai);
} else {
// Inform NetworkMonitor that partial connectivity is acceptable. This will likely
// result in a partial connectivity result which will be processed by
// maybeHandleNetworkMonitorMessage.
//
// TODO: NetworkMonitor does not refer to the "never ask again" bit. The bit is stored
// per network. Therefore, NetworkMonitor may still do https probe.
nai.networkMonitor().setAcceptPartialConnectivity();
}
}
private void handleSetAvoidUnvalidated(Network network) {
NetworkAgentInfo nai = getNetworkAgentInfoForNetwork(network);
if (nai == null || nai.isValidated()) {
// Nothing to do. The network either disconnected or revalidated.
return;
}
if (0L == nai.getAvoidUnvalidated()) {
nai.setAvoidUnvalidated();
nai.updateScoreForNetworkAgentUpdate();
rematchAllNetworksAndRequests();
}
}
/** Schedule evaluation timeout */
@VisibleForTesting
public void scheduleEvaluationTimeout(@NonNull final Network network, final long delayMs) {
mDeps.scheduleEvaluationTimeout(mHandler, network, delayMs);
}
@Override
public void startCaptivePortalApp(Network network) {
enforceNetworkStackOrSettingsPermission();
mHandler.post(() -> {
NetworkAgentInfo nai = getNetworkAgentInfoForNetwork(network);
if (nai == null) return;
if (!nai.networkCapabilities.hasCapability(NET_CAPABILITY_CAPTIVE_PORTAL)) return;
nai.networkMonitor().launchCaptivePortalApp();
});
}
/**
* NetworkStack endpoint to start the captive portal app. The NetworkStack needs to use this
* endpoint as it does not have INTERACT_ACROSS_USERS_FULL itself.
* @param network Network on which the captive portal was detected.
* @param appExtras Bundle to use as intent extras for the captive portal application.
* Must be treated as opaque to avoid preventing the captive portal app to
* update its arguments.
*/
@Override
public void startCaptivePortalAppInternal(Network network, Bundle appExtras) {
mContext.enforceCallingOrSelfPermission(NetworkStack.PERMISSION_MAINLINE_NETWORK_STACK,
"ConnectivityService");
final Intent appIntent = new Intent(ConnectivityManager.ACTION_CAPTIVE_PORTAL_SIGN_IN);
appIntent.putExtras(appExtras);
appIntent.putExtra(ConnectivityManager.EXTRA_CAPTIVE_PORTAL,
new CaptivePortal(new CaptivePortalImpl(network).asBinder()));
appIntent.setFlags(Intent.FLAG_ACTIVITY_BROUGHT_TO_FRONT | Intent.FLAG_ACTIVITY_NEW_TASK);
final long token = Binder.clearCallingIdentity();
try {
mContext.startActivityAsUser(appIntent, UserHandle.CURRENT);
} finally {
Binder.restoreCallingIdentity(token);
}
}
private class CaptivePortalImpl extends ICaptivePortal.Stub {
private final Network mNetwork;
private CaptivePortalImpl(Network network) {
mNetwork = network;
}
@Override
public void appResponse(final int response) {
if (response == CaptivePortal.APP_RETURN_WANTED_AS_IS) {
enforceSettingsPermission();
} else if (response == CaptivePortal.APP_RETURN_UNWANTED) {
mHandler.sendMessage(mHandler.obtainMessage(EVENT_USER_DOES_NOT_WANT, mNetwork));
// Since the network will be disconnected, skip notifying NetworkMonitor
return;
}
final NetworkMonitorManager nm = getNetworkMonitorManager(mNetwork);
if (nm == null) return;
nm.notifyCaptivePortalAppFinished(response);
}
@Override
public void appRequest(final int request) {
final NetworkMonitorManager nm = getNetworkMonitorManager(mNetwork);
if (nm == null) return;
if (request == CaptivePortal.APP_REQUEST_REEVALUATION_REQUIRED) {
checkNetworkStackPermission();
nm.forceReevaluation(mDeps.getCallingUid());
}
}
@Nullable
private NetworkMonitorManager getNetworkMonitorManager(final Network network) {
// getNetworkAgentInfoForNetwork is thread-safe
final NetworkAgentInfo nai = getNetworkAgentInfoForNetwork(network);
if (nai == null) return null;
// nai.networkMonitor() is thread-safe
return nai.networkMonitor();
}
}
public boolean avoidBadWifi() {
return mMultinetworkPolicyTracker.getAvoidBadWifi();
}
private boolean activelyPreferBadWifi() {
return mMultinetworkPolicyTracker.getActivelyPreferBadWifi();
}
/**
* Return whether the device should maintain continuous, working connectivity by switching away
* from WiFi networks having no connectivity.
* @see MultinetworkPolicyTracker#getAvoidBadWifi()
*/
public boolean shouldAvoidBadWifi() {
if (!checkNetworkStackPermission()) {
throw new SecurityException("avoidBadWifi requires NETWORK_STACK permission");
}
return avoidBadWifi();
}
private void updateAvoidBadWifi() {
ensureRunningOnConnectivityServiceThread();
// Agent info scores and offer scores depend on whether cells yields to bad wifi.
final boolean avoidBadWifi = avoidBadWifi();
for (final NetworkAgentInfo nai : mNetworkAgentInfos) {
nai.updateScoreForNetworkAgentUpdate();
if (avoidBadWifi) {
// If the device is now avoiding bad wifi, remove notifications that might have
// been put up when the device didn't.
mNotifier.clearNotification(nai.network.getNetId(), NotificationType.LOST_INTERNET);
}
}
// UpdateOfferScore will update mNetworkOffers inline, so make a copy first.
final ArrayList<NetworkOfferInfo> offersToUpdate = new ArrayList<>(mNetworkOffers);
for (final NetworkOfferInfo noi : offersToUpdate) {
updateOfferScore(noi.offer);
}
mNetworkRanker.setConfiguration(new NetworkRanker.Configuration(activelyPreferBadWifi()));
rematchAllNetworksAndRequests();
}
// TODO: Evaluate whether this is of interest to other consumers of
// MultinetworkPolicyTracker and worth moving out of here.
private void dumpAvoidBadWifiSettings(IndentingPrintWriter pw) {
final boolean configRestrict = mMultinetworkPolicyTracker.configRestrictsAvoidBadWifi();
if (!configRestrict) {
pw.println("Bad Wi-Fi avoidance: unrestricted");
return;
}
pw.println("Bad Wi-Fi avoidance: " + avoidBadWifi());
pw.increaseIndent();
pw.println("Config restrict: " + configRestrict);
pw.println("Actively prefer bad wifi: " + activelyPreferBadWifi());
final String settingValue = mMultinetworkPolicyTracker.getAvoidBadWifiSetting();
String description;
// Can't use a switch statement because strings are legal case labels, but null is not.
if ("0".equals(settingValue)) {
description = "get stuck";
} else if (settingValue == null) {
description = "prompt";
} else if ("1".equals(settingValue)) {
description = "avoid";
} else {
description = settingValue + " (?)";
}
pw.println("Avoid bad wifi setting: " + description);
final Boolean configValue = BinderUtils.withCleanCallingIdentity(
() -> mMultinetworkPolicyTracker.deviceConfigActivelyPreferBadWifi());
if (null == configValue) {
description = "unset";
} else if (configValue) {
description = "force true";
} else {
description = "force false";
}
pw.println("Actively prefer bad wifi conf: " + description);
pw.println();
pw.println("Network overrides:");
pw.increaseIndent();
for (NetworkAgentInfo nai : networksSortedById()) {
if (0L != nai.getAvoidUnvalidated()) {
pw.println(nai.toShortString());
}
}
pw.decreaseIndent();
pw.decreaseIndent();
}
// TODO: This method is copied from TetheringNotificationUpdater. Should have a utility class to
// unify the method.
private static @NonNull String getSettingsPackageName(@NonNull final PackageManager pm) {
final Intent settingsIntent = new Intent(Settings.ACTION_SETTINGS);
final ComponentName settingsComponent = settingsIntent.resolveActivity(pm);
return settingsComponent != null
? settingsComponent.getPackageName() : "com.android.settings";
}
private void showNetworkNotification(NetworkAgentInfo nai, NotificationType type) {
final String action;
final boolean highPriority;
switch (type) {
case NO_INTERNET:
action = ConnectivityManager.ACTION_PROMPT_UNVALIDATED;
// High priority because it is only displayed for explicitly selected networks.
highPriority = true;
break;
case PRIVATE_DNS_BROKEN:
action = Settings.ACTION_WIRELESS_SETTINGS;
// High priority because we should let user know why there is no internet.
highPriority = true;
break;
case LOST_INTERNET:
action = ConnectivityManager.ACTION_PROMPT_LOST_VALIDATION;
// High priority because it could help the user avoid unexpected data usage.
highPriority = true;
break;
case PARTIAL_CONNECTIVITY:
action = ConnectivityManager.ACTION_PROMPT_PARTIAL_CONNECTIVITY;
// Don't bother the user with a high-priority notification if the network was not
// explicitly selected by the user.
highPriority = nai.networkAgentConfig.explicitlySelected;
break;
default:
Log.wtf(TAG, "Unknown notification type " + type);
return;
}
Intent intent = new Intent(action);
if (type != NotificationType.PRIVATE_DNS_BROKEN) {
intent.putExtra(ConnectivityManager.EXTRA_NETWORK, nai.network);
intent.addFlags(Intent.FLAG_ACTIVITY_NEW_TASK);
// Some OEMs have their own Settings package. Thus, need to get the current using
// Settings package name instead of just use default name "com.android.settings".
final String settingsPkgName = getSettingsPackageName(mContext.getPackageManager());
intent.setClassName(settingsPkgName,
settingsPkgName + ".wifi.WifiNoInternetDialog");
}
PendingIntent pendingIntent = PendingIntent.getActivity(
mContext.createContextAsUser(UserHandle.CURRENT, 0 /* flags */),
0 /* requestCode */,
intent,
PendingIntent.FLAG_CANCEL_CURRENT | PendingIntent.FLAG_IMMUTABLE);
mNotifier.showNotification(
nai.network.getNetId(), type, nai, null, pendingIntent, highPriority);
}
private boolean shouldPromptUnvalidated(NetworkAgentInfo nai) {
// Don't prompt if the network is validated, and don't prompt on captive portals
// because we're already prompting the user to sign in.
if (nai.everValidated() || nai.everCaptivePortalDetected()) {
return false;
}
// If a network has partial connectivity, always prompt unless the user has already accepted
// partial connectivity and selected don't ask again. This ensures that if the device
// automatically connects to a network that has partial Internet access, the user will
// always be able to use it, either because they've already chosen "don't ask again" or
// because we have prompted them.
if (nai.partialConnectivity() && !nai.networkAgentConfig.acceptPartialConnectivity) {
return true;
}
// If a network has no Internet access, only prompt if the network was explicitly selected
// and if the user has not already told us to use the network regardless of whether it
// validated or not.
if (nai.networkAgentConfig.explicitlySelected
&& !nai.networkAgentConfig.acceptUnvalidated) {
return true;
}
return false;
}
private void handleInitialEvaluationTimeout(@NonNull final Network network) {
if (VDBG || DDBG) log("handleInitialEvaluationTimeout " + network);
NetworkAgentInfo nai = getNetworkAgentInfoForNetwork(network);
if (null == nai) return;
if (nai.setEvaluated()) {
// If setEvaluated() returned true, the network never had any form of connectivity.
// This may have an impact on request matching if bad WiFi avoidance is off and the
// network was found not to have Internet access.
nai.updateScoreForNetworkAgentUpdate();
rematchAllNetworksAndRequests();
// Also, if this is WiFi and it should be preferred actively, now is the time to
// prompt the user that they walked past and connected to a bad WiFi.
if (nai.networkCapabilities.hasTransport(TRANSPORT_WIFI)
&& !avoidBadWifi()
&& activelyPreferBadWifi()) {
// The notification will be removed if the network validates or disconnects.
showNetworkNotification(nai, NotificationType.LOST_INTERNET);
return;
}
}
if (!shouldPromptUnvalidated(nai)) return;
// Stop automatically reconnecting to this network in the future. Automatically connecting
// to a network that provides no or limited connectivity is not useful, because the user
// cannot use that network except through the notification shown by this method, and the
// notification is only shown if the network is explicitly selected by the user.
nai.onPreventAutomaticReconnect();
if (nai.partialConnectivity()) {
showNetworkNotification(nai, NotificationType.PARTIAL_CONNECTIVITY);
} else {
showNetworkNotification(nai, NotificationType.NO_INTERNET);
}
}
private void handleNetworkUnvalidated(NetworkAgentInfo nai) {
NetworkCapabilities nc = nai.networkCapabilities;
if (DBG) log("handleNetworkUnvalidated " + nai.toShortString() + " cap=" + nc);
if (!nc.hasTransport(NetworkCapabilities.TRANSPORT_WIFI)) {
return;
}
if (mMultinetworkPolicyTracker.shouldNotifyWifiUnvalidated()) {
showNetworkNotification(nai, NotificationType.LOST_INTERNET);
}
}
@Override
public int getMultipathPreference(Network network) {
enforceAccessPermission();
NetworkAgentInfo nai = getNetworkAgentInfoForNetwork(network);
if (nai != null && nai.networkCapabilities
.hasCapability(NetworkCapabilities.NET_CAPABILITY_NOT_METERED)) {
return ConnectivityManager.MULTIPATH_PREFERENCE_UNMETERED;
}
final NetworkPolicyManager netPolicyManager =
mContext.getSystemService(NetworkPolicyManager.class);
final long token = Binder.clearCallingIdentity();
final int networkPreference;
try {
networkPreference = netPolicyManager.getMultipathPreference(network);
} finally {
Binder.restoreCallingIdentity(token);
}
if (networkPreference != 0) {
return networkPreference;
}
return mMultinetworkPolicyTracker.getMeteredMultipathPreference();
}
@Override
public NetworkRequest getDefaultRequest() {
return mDefaultRequest.mRequests.get(0);
}
private class InternalHandler extends Handler {
public InternalHandler(Looper looper) {
super(looper);
}
@Override
public void handleMessage(Message msg) {
switch (msg.what) {
case EVENT_EXPIRE_NET_TRANSITION_WAKELOCK:
case EVENT_CLEAR_NET_TRANSITION_WAKELOCK: {
handleReleaseNetworkTransitionWakelock(msg.what);
break;
}
case EVENT_APPLY_GLOBAL_HTTP_PROXY: {
mProxyTracker.loadDeprecatedGlobalHttpProxy();
break;
}
case EVENT_PAC_PROXY_HAS_CHANGED: {
final Pair<Network, ProxyInfo> arg = (Pair<Network, ProxyInfo>) msg.obj;
handlePacProxyServiceStarted(arg.first, arg.second);
break;
}
case EVENT_REGISTER_NETWORK_PROVIDER: {
handleRegisterNetworkProvider((NetworkProviderInfo) msg.obj);
break;
}
case EVENT_UNREGISTER_NETWORK_PROVIDER: {
handleUnregisterNetworkProvider((Messenger) msg.obj);
break;
}
case EVENT_REGISTER_NETWORK_OFFER: {
handleRegisterNetworkOffer((NetworkOffer) msg.obj);
break;
}
case EVENT_UNREGISTER_NETWORK_OFFER: {
final NetworkOfferInfo offer =
findNetworkOfferInfoByCallback((INetworkOfferCallback) msg.obj);
if (null != offer) {
handleUnregisterNetworkOffer(offer);
}
break;
}
case EVENT_REGISTER_NETWORK_AGENT: {
final Pair<NetworkAgentInfo, INetworkMonitor> arg =
(Pair<NetworkAgentInfo, INetworkMonitor>) msg.obj;
handleRegisterNetworkAgent(arg.first, arg.second);
break;
}
case EVENT_REGISTER_NETWORK_REQUEST:
case EVENT_REGISTER_NETWORK_LISTENER: {
handleRegisterNetworkRequest((NetworkRequestInfo) msg.obj);
break;
}
case EVENT_REGISTER_NETWORK_REQUEST_WITH_INTENT:
case EVENT_REGISTER_NETWORK_LISTENER_WITH_INTENT: {
handleRegisterNetworkRequestWithIntent(msg);
break;
}
case EVENT_TIMEOUT_NETWORK_REQUEST: {
NetworkRequestInfo nri = (NetworkRequestInfo) msg.obj;
handleTimedOutNetworkRequest(nri);
break;
}
case EVENT_RELEASE_NETWORK_REQUEST_WITH_INTENT: {
handleReleaseNetworkRequestWithIntent((PendingIntent) msg.obj, msg.arg1);
break;
}
case EVENT_RELEASE_NETWORK_REQUEST: {
handleReleaseNetworkRequest((NetworkRequest) msg.obj, msg.arg1,
/* callOnUnavailable */ false);
break;
}
case EVENT_SET_ACCEPT_UNVALIDATED: {
Network network = (Network) msg.obj;
handleSetAcceptUnvalidated(network, toBool(msg.arg1), toBool(msg.arg2));
break;
}
case EVENT_SET_ACCEPT_PARTIAL_CONNECTIVITY: {
Network network = (Network) msg.obj;
handleSetAcceptPartialConnectivity(network, toBool(msg.arg1),
toBool(msg.arg2));
break;
}
case EVENT_SET_AVOID_UNVALIDATED: {
handleSetAvoidUnvalidated((Network) msg.obj);
break;
}
case EVENT_INITIAL_EVALUATION_TIMEOUT: {
handleInitialEvaluationTimeout((Network) msg.obj);
break;
}
case EVENT_CONFIGURE_ALWAYS_ON_NETWORKS: {
handleConfigureAlwaysOnNetworks();
break;
}
// Sent by AutomaticOnOffKeepaliveTracker to process an app request on the
// handler thread.
case AutomaticOnOffKeepaliveTracker.CMD_REQUEST_START_KEEPALIVE: {
mKeepaliveTracker.handleStartKeepalive(msg);
break;
}
case AutomaticOnOffKeepaliveTracker.CMD_MONITOR_AUTOMATIC_KEEPALIVE: {
final AutomaticOnOffKeepalive ki =
mKeepaliveTracker.getKeepaliveForBinder((IBinder) msg.obj);
if (null == ki) return; // The callback was unregistered before the alarm fired
final Network underpinnedNetwork = ki.getUnderpinnedNetwork();
final Network network = ki.getNetwork();
boolean networkFound = false;
boolean underpinnedNetworkFound = false;
for (NetworkAgentInfo n : mNetworkAgentInfos) {
if (n.network.equals(network)) networkFound = true;
if (n.everConnected() && n.network.equals(underpinnedNetwork)) {
underpinnedNetworkFound = true;
}
}
// If the network no longer exists, then the keepalive should have been
// cleaned up already. There is no point trying to resume keepalives.
if (!networkFound) return;
if (underpinnedNetworkFound) {
final NetworkCapabilities underpinnedNc =
getNetworkCapabilitiesInternal(underpinnedNetwork);
mKeepaliveTracker.handleMonitorAutomaticKeepalive(ki,
underpinnedNetwork.netId, underpinnedNc.getUids());
} else {
// If no underpinned network, then make sure the keepalive is running.
mKeepaliveTracker.handleMaybeResumeKeepalive(ki);
}
break;
}
// Sent by KeepaliveTracker to process an app request on the state machine thread.
case NetworkAgent.CMD_STOP_SOCKET_KEEPALIVE: {
final AutomaticOnOffKeepalive ki = mKeepaliveTracker.getKeepaliveForBinder(
(IBinder) msg.obj);
if (ki == null) {
Log.e(TAG, "Attempt to stop an already stopped keepalive");
return;
}
final int reason = msg.arg2;
mKeepaliveTracker.handleStopKeepalive(ki, reason);
break;
}
case EVENT_REPORT_NETWORK_CONNECTIVITY: {
handleReportNetworkConnectivity((NetworkAgentInfo) msg.obj, msg.arg1,
toBool(msg.arg2));
break;
}
case EVENT_PRIVATE_DNS_SETTINGS_CHANGED:
handlePrivateDnsSettingsChanged();
break;
case EVENT_PRIVATE_DNS_VALIDATION_UPDATE:
handlePrivateDnsValidationUpdate(
(PrivateDnsValidationUpdate) msg.obj);
break;
case EVENT_UID_BLOCKED_REASON_CHANGED:
handleUidBlockedReasonChanged(msg.arg1, msg.arg2);
break;
case EVENT_SET_REQUIRE_VPN_FOR_UIDS:
handleSetRequireVpnForUids(toBool(msg.arg1), (UidRange[]) msg.obj);
break;
case EVENT_SET_OEM_NETWORK_PREFERENCE: {
final Pair<OemNetworkPreferences, IOnCompleteListener> arg =
(Pair<OemNetworkPreferences, IOnCompleteListener>) msg.obj;
handleSetOemNetworkPreference(arg.first, arg.second);
break;
}
case EVENT_SET_PROFILE_NETWORK_PREFERENCE: {
final Pair<List<ProfileNetworkPreferenceInfo>, IOnCompleteListener> arg =
(Pair<List<ProfileNetworkPreferenceInfo>, IOnCompleteListener>) msg.obj;
handleSetProfileNetworkPreference(arg.first, arg.second);
break;
}
case EVENT_REPORT_NETWORK_ACTIVITY:
final NetworkActivityParams arg = (NetworkActivityParams) msg.obj;
handleReportNetworkActivity(arg);
break;
case EVENT_MOBILE_DATA_PREFERRED_UIDS_CHANGED:
handleMobileDataPreferredUidsChanged();
break;
case EVENT_SET_TEST_ALLOW_BAD_WIFI_UNTIL:
final long timeMs = ((Long) msg.obj).longValue();
mMultinetworkPolicyTracker.setTestAllowBadWifiUntil(timeMs);
break;
case EVENT_INGRESS_RATE_LIMIT_CHANGED:
handleIngressRateLimitChanged();
break;
case EVENT_USER_DOES_NOT_WANT:
final NetworkAgentInfo nai = getNetworkAgentInfoForNetwork((Network) msg.obj);
if (nai == null) break;
nai.onPreventAutomaticReconnect();
nai.disconnect();
break;
case EVENT_SET_VPN_NETWORK_PREFERENCE:
handleSetVpnNetworkPreference((VpnNetworkPreferenceInfo) msg.obj);
break;
case EVENT_SET_LOW_TCP_POLLING_UNTIL: {
final long time = ((Long) msg.obj).longValue();
mKeepaliveTracker.handleSetTestLowTcpPollingTimer(time);
break;
}
case EVENT_UID_FROZEN_STATE_CHANGED:
UidFrozenStateChangedArgs args = (UidFrozenStateChangedArgs) msg.obj;
handleFrozenUids(args.mUids, args.mFrozenStates);
break;
}
}
}
@Override
@Deprecated
public int getLastTetherError(String iface) {
enforceAccessPermission();
final TetheringManager tm = (TetheringManager) mContext.getSystemService(
Context.TETHERING_SERVICE);
return tm.getLastTetherError(iface);
}
@Override
@Deprecated
public String[] getTetherableIfaces() {
enforceAccessPermission();
final TetheringManager tm = (TetheringManager) mContext.getSystemService(
Context.TETHERING_SERVICE);
return tm.getTetherableIfaces();
}
@Override
@Deprecated
public String[] getTetheredIfaces() {
enforceAccessPermission();
final TetheringManager tm = (TetheringManager) mContext.getSystemService(
Context.TETHERING_SERVICE);
return tm.getTetheredIfaces();
}
@Override
@Deprecated
public String[] getTetheringErroredIfaces() {
enforceAccessPermission();
final TetheringManager tm = (TetheringManager) mContext.getSystemService(
Context.TETHERING_SERVICE);
return tm.getTetheringErroredIfaces();
}
@Override
@Deprecated
public String[] getTetherableUsbRegexs() {
enforceAccessPermission();
final TetheringManager tm = (TetheringManager) mContext.getSystemService(
Context.TETHERING_SERVICE);
return tm.getTetherableUsbRegexs();
}
@Override
@Deprecated
public String[] getTetherableWifiRegexs() {
enforceAccessPermission();
final TetheringManager tm = (TetheringManager) mContext.getSystemService(
Context.TETHERING_SERVICE);
return tm.getTetherableWifiRegexs();
}
// Called when we lose the default network and have no replacement yet.
// This will automatically be cleared after X seconds or a new default network
// becomes CONNECTED, whichever happens first. The timer is started by the
// first caller and not restarted by subsequent callers.
private void ensureNetworkTransitionWakelock(String forWhom) {
synchronized (this) {
if (mNetTransitionWakeLock.isHeld()) {
return;
}
mNetTransitionWakeLock.acquire();
mLastWakeLockAcquireTimestamp = SystemClock.elapsedRealtime();
mTotalWakelockAcquisitions++;
}
mWakelockLogs.log("ACQUIRE for " + forWhom);
Message msg = mHandler.obtainMessage(EVENT_EXPIRE_NET_TRANSITION_WAKELOCK);
final int lockTimeout = mResources.get().getInteger(
R.integer.config_networkTransitionTimeout);
mHandler.sendMessageDelayed(msg, lockTimeout);
}
// Called when we gain a new default network to release the network transition wakelock in a
// second, to allow a grace period for apps to reconnect over the new network. Pending expiry
// message is cancelled.
private void scheduleReleaseNetworkTransitionWakelock() {
synchronized (this) {
if (!mNetTransitionWakeLock.isHeld()) {
return; // expiry message released the lock first.
}
}
// Cancel self timeout on wakelock hold.
mHandler.removeMessages(EVENT_EXPIRE_NET_TRANSITION_WAKELOCK);
Message msg = mHandler.obtainMessage(EVENT_CLEAR_NET_TRANSITION_WAKELOCK);
mHandler.sendMessageDelayed(msg, 1000);
}
// Called when either message of ensureNetworkTransitionWakelock or
// scheduleReleaseNetworkTransitionWakelock is processed.
private void handleReleaseNetworkTransitionWakelock(int eventId) {
String event = eventName(eventId);
synchronized (this) {
if (!mNetTransitionWakeLock.isHeld()) {
mWakelockLogs.log(String.format("RELEASE: already released (%s)", event));
Log.w(TAG, "expected Net Transition WakeLock to be held");
return;
}
mNetTransitionWakeLock.release();
long lockDuration = SystemClock.elapsedRealtime() - mLastWakeLockAcquireTimestamp;
mTotalWakelockDurationMs += lockDuration;
mMaxWakelockDurationMs = Math.max(mMaxWakelockDurationMs, lockDuration);
mTotalWakelockReleases++;
}
mWakelockLogs.log(String.format("RELEASE (%s)", event));
}
// 100 percent is full good, 0 is full bad.
@Override
public void reportInetCondition(int networkType, int percentage) {
NetworkAgentInfo nai = mLegacyTypeTracker.getNetworkForType(networkType);
if (nai == null) return;
reportNetworkConnectivity(nai.network, percentage > 50);
}
@Override
public void reportNetworkConnectivity(Network network, boolean hasConnectivity) {
enforceAccessPermission();
enforceInternetPermission();
final int uid = mDeps.getCallingUid();
final int connectivityInfo = encodeBool(hasConnectivity);
final NetworkAgentInfo nai;
if (network == null) {
nai = getDefaultNetwork();
} else {
nai = getNetworkAgentInfoForNetwork(network);
}
mHandler.sendMessage(
mHandler.obtainMessage(
EVENT_REPORT_NETWORK_CONNECTIVITY, uid, connectivityInfo, nai));
}
private void handleReportNetworkConnectivity(
@Nullable NetworkAgentInfo nai, int uid, boolean hasConnectivity) {
if (nai == null
|| nai != getNetworkAgentInfoForNetwork(nai.network)
|| nai.networkInfo.getState() == NetworkInfo.State.DISCONNECTED) {
return;
}
// Revalidate if the app report does not match our current validated state.
if (hasConnectivity == nai.isValidated()) {
mConnectivityDiagnosticsHandler.sendMessage(
mConnectivityDiagnosticsHandler.obtainMessage(
ConnectivityDiagnosticsHandler.EVENT_NETWORK_CONNECTIVITY_REPORTED,
new ReportedNetworkConnectivityInfo(
hasConnectivity, false /* isNetworkRevalidating */, uid, nai)));
return;
}
if (DBG) {
int netid = nai.network.getNetId();
log("reportNetworkConnectivity(" + netid + ", " + hasConnectivity + ") by " + uid);
}
// Validating a network that has not yet connected could result in a call to
// rematchNetworkAndRequests() which is not meant to work on such networks.
if (!nai.everConnected()) {
return;
}
final NetworkCapabilities nc = getNetworkCapabilitiesInternal(nai);
if (isNetworkWithCapabilitiesBlocked(nc, uid, false)) {
return;
}
// Send CONNECTIVITY_REPORTED event before re-validating the Network to force an ordering of
// ConnDiags events. This ensures that #onNetworkConnectivityReported() will be called
// before #onConnectivityReportAvailable(), which is called once Network evaluation is
// completed.
mConnectivityDiagnosticsHandler.sendMessage(
mConnectivityDiagnosticsHandler.obtainMessage(
ConnectivityDiagnosticsHandler.EVENT_NETWORK_CONNECTIVITY_REPORTED,
new ReportedNetworkConnectivityInfo(
hasConnectivity, true /* isNetworkRevalidating */, uid, nai)));
nai.networkMonitor().forceReevaluation(uid);
}
// TODO: call into netd.
private boolean queryUserAccess(int uid, Network network) {
final NetworkAgentInfo nai = getNetworkAgentInfoForNetwork(network);
if (nai == null) return false;
// Any UID can use its default network.
if (nai == getDefaultNetworkForUid(uid)) return true;
// Privileged apps can use any network.
if (mPermissionMonitor.hasRestrictedNetworksPermission(uid)) {
return true;
}
// An unprivileged UID can use a VPN iff the VPN applies to it.
if (nai.isVPN()) {
return nai.networkCapabilities.appliesToUid(uid);
}
// An unprivileged UID can bypass the VPN that applies to it only if it can protect its
// sockets, i.e., if it is the owner.
final NetworkAgentInfo vpn = getVpnForUid(uid);
if (vpn != null && !vpn.networkAgentConfig.allowBypass
&& uid != vpn.networkCapabilities.getOwnerUid()) {
return false;
}
// The UID's permission must be at least sufficient for the network. Since the restricted
// permission was already checked above, that just leaves background networks.
if (!nai.networkCapabilities.hasCapability(NET_CAPABILITY_FOREGROUND)) {
return mPermissionMonitor.hasUseBackgroundNetworksPermission(uid);
}
// Unrestricted network. Anyone gets to use it.
return true;
}
/**
* Returns information about the proxy a certain network is using. If given a null network, it
* it will return the proxy for the bound network for the caller app or the default proxy if
* none.
*
* @param network the network we want to get the proxy information for.
* @return Proxy information if a network has a proxy configured, or otherwise null.
*/
@Override
public ProxyInfo getProxyForNetwork(Network network) {
final ProxyInfo globalProxy = mProxyTracker.getGlobalProxy();
if (globalProxy != null) return globalProxy;
if (network == null) {
// Get the network associated with the calling UID.
final Network activeNetwork = getActiveNetworkForUidInternal(mDeps.getCallingUid(),
true);
if (activeNetwork == null) {
return null;
}
return getLinkPropertiesProxyInfo(activeNetwork);
} else if (mDeps.queryUserAccess(mDeps.getCallingUid(), network, this)) {
// Don't call getLinkProperties() as it requires ACCESS_NETWORK_STATE permission, which
// caller may not have.
return getLinkPropertiesProxyInfo(network);
}
// No proxy info available if the calling UID does not have network access.
return null;
}
private ProxyInfo getLinkPropertiesProxyInfo(Network network) {
final NetworkAgentInfo nai = getNetworkAgentInfoForNetwork(network);
if (nai == null) return null;
synchronized (nai) {
final ProxyInfo linkHttpProxy = nai.linkProperties.getHttpProxy();
return linkHttpProxy == null ? null : new ProxyInfo(linkHttpProxy);
}
}
@Override
public void setGlobalProxy(@Nullable final ProxyInfo proxyProperties) {
enforceNetworkStackPermission(mContext);
mProxyTracker.setGlobalProxy(proxyProperties);
}
@Override
@Nullable
public ProxyInfo getGlobalProxy() {
return mProxyTracker.getGlobalProxy();
}
private void handlePacProxyServiceStarted(@Nullable Network net, @Nullable ProxyInfo proxy) {
mProxyTracker.setDefaultProxy(proxy);
final NetworkAgentInfo nai = getDefaultNetwork();
// TODO : this method should check that net == nai.network, unfortunately at this point
// 'net' is always null in practice (see PacProxyService#sendPacBroadcast). PAC proxy
// is only ever installed on the default network so in practice this is okay.
if (null == nai) return;
// PAC proxies only work on the default network. Therefore, only the default network
// should have its link properties fixed up for PAC proxies.
mProxyTracker.updateDefaultNetworkProxyPortForPAC(nai.linkProperties, nai.network);
if (nai.everConnected()) {
notifyNetworkCallbacks(nai, ConnectivityManager.CALLBACK_IP_CHANGED);
}
}
// If the proxy has changed from oldLp to newLp, resend proxy broadcast. This method gets called
// when any network changes proxy.
// TODO: Remove usage of broadcast extras as they are deprecated and not applicable in a
// multi-network world where an app might be bound to a non-default network.
private void updateProxy(@NonNull LinkProperties newLp, @Nullable LinkProperties oldLp) {
ProxyInfo newProxyInfo = newLp.getHttpProxy();
ProxyInfo oldProxyInfo = oldLp == null ? null : oldLp.getHttpProxy();
if (!ProxyTracker.proxyInfoEqual(newProxyInfo, oldProxyInfo)) {
mProxyTracker.sendProxyBroadcast();
}
}
private static class SettingsObserver extends ContentObserver {
final private HashMap<Uri, Integer> mUriEventMap;
final private Context mContext;
final private Handler mHandler;
SettingsObserver(Context context, Handler handler) {
super(null);
mUriEventMap = new HashMap<>();
mContext = context;
mHandler = handler;
}
void observe(Uri uri, int what) {
mUriEventMap.put(uri, what);
final ContentResolver resolver = mContext.getContentResolver();
resolver.registerContentObserver(uri, false, this);
}
@Override
public void onChange(boolean selfChange) {
Log.wtf(TAG, "Should never be reached.");
}
@Override
public void onChange(boolean selfChange, Uri uri) {
final Integer what = mUriEventMap.get(uri);
if (what != null) {
mHandler.obtainMessage(what).sendToTarget();
} else {
loge("No matching event to send for URI=" + uri);
}
}
}
private static void log(String s) {
Log.d(TAG, s);
}
private static void logw(String s) {
Log.w(TAG, s);
}
private static void logwtf(String s) {
Log.wtf(TAG, s);
}
private static void logwtf(String s, Throwable t) {
Log.wtf(TAG, s, t);
}
private static void loge(String s) {
Log.e(TAG, s);
}
private static void loge(String s, Throwable t) {
Log.e(TAG, s, t);
}
/**
* Return the information of all ongoing VPNs.
*
* <p>This method is used to update NetworkStatsService.
*
* <p>Must be called on the handler thread.
*/
private UnderlyingNetworkInfo[] getAllVpnInfo() {
ensureRunningOnConnectivityServiceThread();
if (mLockdownEnabled) {
return new UnderlyingNetworkInfo[0];
}
List<UnderlyingNetworkInfo> infoList = new ArrayList<>();
for (NetworkAgentInfo nai : mNetworkAgentInfos) {
UnderlyingNetworkInfo info = createVpnInfo(nai);
if (info != null) {
infoList.add(info);
}
}
return infoList.toArray(new UnderlyingNetworkInfo[infoList.size()]);
}
/**
* @return VPN information for accounting, or null if we can't retrieve all required
* information, e.g underlying ifaces.
*/
private UnderlyingNetworkInfo createVpnInfo(NetworkAgentInfo nai) {
Network[] underlyingNetworks = nai.declaredUnderlyingNetworks;
// see VpnService.setUnderlyingNetworks()'s javadoc about how to interpret
// the underlyingNetworks list.
// TODO: stop using propagateUnderlyingCapabilities here, for example, by always
// initializing NetworkAgentInfo#declaredUnderlyingNetworks to an empty array.
if (underlyingNetworks == null && nai.propagateUnderlyingCapabilities()) {
final NetworkAgentInfo defaultNai = getDefaultNetworkForUid(
nai.networkCapabilities.getOwnerUid());
if (defaultNai != null) {
underlyingNetworks = new Network[] { defaultNai.network };
}
}
if (CollectionUtils.isEmpty(underlyingNetworks)) return null;
List<String> interfaces = new ArrayList<>();
for (Network network : underlyingNetworks) {
NetworkAgentInfo underlyingNai = getNetworkAgentInfoForNetwork(network);
if (underlyingNai == null) continue;
LinkProperties lp = underlyingNai.linkProperties;
for (String iface : lp.getAllInterfaceNames()) {
if (!TextUtils.isEmpty(iface)) {
interfaces.add(iface);
}
}
}
if (interfaces.isEmpty()) return null;
// Must be non-null or NetworkStatsService will crash.
// Cannot happen in production code because Vpn only registers the NetworkAgent after the
// tun or ipsec interface is created.
// TODO: Remove this check.
if (nai.linkProperties.getInterfaceName() == null) return null;
return new UnderlyingNetworkInfo(nai.networkCapabilities.getOwnerUid(),
nai.linkProperties.getInterfaceName(), interfaces);
}
// TODO This needs to be the default network that applies to the NAI.
private Network[] underlyingNetworksOrDefault(final int ownerUid,
Network[] underlyingNetworks) {
final Network defaultNetwork = getNetwork(getDefaultNetworkForUid(ownerUid));
if (underlyingNetworks == null && defaultNetwork != null) {
// null underlying networks means to track the default.
underlyingNetworks = new Network[] { defaultNetwork };
}
return underlyingNetworks;
}
// Returns true iff |network| is an underlying network of |nai|.
private boolean hasUnderlyingNetwork(NetworkAgentInfo nai, Network network) {
// TODO: support more than one level of underlying networks, either via a fixed-depth search
// (e.g., 2 levels of underlying networks), or via loop detection, or....
if (!nai.propagateUnderlyingCapabilities()) return false;
final Network[] underlying = underlyingNetworksOrDefault(
nai.networkCapabilities.getOwnerUid(), nai.declaredUnderlyingNetworks);
return CollectionUtils.contains(underlying, network);
}
/**
* Recompute the capabilities for any networks that had a specific network as underlying.
*
* When underlying networks change, such networks may have to update capabilities to reflect
* things like the metered bit, their transports, and so on. The capabilities are calculated
* immediately. This method runs on the ConnectivityService thread.
*/
private void propagateUnderlyingNetworkCapabilities(Network updatedNetwork) {
ensureRunningOnConnectivityServiceThread();
for (NetworkAgentInfo nai : mNetworkAgentInfos) {
if (updatedNetwork == null || hasUnderlyingNetwork(nai, updatedNetwork)) {
updateCapabilitiesForNetwork(nai);
}
}
}
private boolean isUidBlockedByVpn(int uid, List<UidRange> blockedUidRanges) {
// Determine whether this UID is blocked because of always-on VPN lockdown. If a VPN applies
// to the UID, then the UID is not blocked because always-on VPN lockdown applies only when
// a VPN is not up.
final NetworkAgentInfo vpnNai = getVpnForUid(uid);
if (vpnNai != null && !vpnNai.networkAgentConfig.allowBypass) return false;
for (UidRange range : blockedUidRanges) {
if (range.contains(uid)) return true;
}
return false;
}
@Override
public void setRequireVpnForUids(boolean requireVpn, UidRange[] ranges) {
enforceNetworkStackOrSettingsPermission();
mHandler.sendMessage(mHandler.obtainMessage(EVENT_SET_REQUIRE_VPN_FOR_UIDS,
encodeBool(requireVpn), 0 /* arg2 */, ranges));
}
private void handleSetRequireVpnForUids(boolean requireVpn, UidRange[] ranges) {
if (DBG) {
Log.d(TAG, "Setting VPN " + (requireVpn ? "" : "not ") + "required for UIDs: "
+ Arrays.toString(ranges));
}
// Cannot use a Set since the list of UID ranges might contain duplicates.
final List<UidRange> newVpnBlockedUidRanges = new ArrayList(mVpnBlockedUidRanges);
for (int i = 0; i < ranges.length; i++) {
if (requireVpn) {
newVpnBlockedUidRanges.add(ranges[i]);
} else {
newVpnBlockedUidRanges.remove(ranges[i]);
}
}
try {
mNetd.networkRejectNonSecureVpn(requireVpn, toUidRangeStableParcels(ranges));
} catch (RemoteException | ServiceSpecificException e) {
Log.e(TAG, "setRequireVpnForUids(" + requireVpn + ", "
+ Arrays.toString(ranges) + "): netd command failed: " + e);
}
if (mDeps.isAtLeastT()) {
mPermissionMonitor.updateVpnLockdownUidRanges(requireVpn, ranges);
}
for (final NetworkAgentInfo nai : mNetworkAgentInfos) {
final boolean curMetered = nai.networkCapabilities.isMetered();
maybeNotifyNetworkBlocked(nai, curMetered, curMetered,
mVpnBlockedUidRanges, newVpnBlockedUidRanges);
}
mVpnBlockedUidRanges = newVpnBlockedUidRanges;
}
@Override
public void setLegacyLockdownVpnEnabled(boolean enabled) {
enforceNetworkStackOrSettingsPermission();
mHandler.post(() -> mLockdownEnabled = enabled);
}
private boolean isLegacyLockdownNai(NetworkAgentInfo nai) {
return mLockdownEnabled
&& getVpnType(nai) == VpnManager.TYPE_VPN_LEGACY
&& nai.networkCapabilities.appliesToUid(Process.FIRST_APPLICATION_UID);
}
private NetworkAgentInfo getLegacyLockdownNai() {
if (!mLockdownEnabled) {
return null;
}
// The legacy lockdown VPN always only applies to userId 0.
final NetworkAgentInfo nai = getVpnForUid(Process.FIRST_APPLICATION_UID);
if (nai == null || !isLegacyLockdownNai(nai)) return null;
// The legacy lockdown VPN must always have exactly one underlying network.
// This code may run on any thread and declaredUnderlyingNetworks may change, so store it in
// a local variable. There is no need to make a copy because its contents cannot change.
final Network[] underlying = nai.declaredUnderlyingNetworks;
if (underlying == null || underlying.length != 1) {
return null;
}
// The legacy lockdown VPN always uses the default network.
// If the VPN's underlying network is no longer the current default network, it means that
// the default network has just switched, and the VPN is about to disconnect.
// Report that the VPN is not connected, so the state of NetworkInfo objects overwritten
// by filterForLegacyLockdown will be set to CONNECTING and not CONNECTED.
final NetworkAgentInfo defaultNetwork = getDefaultNetwork();
if (defaultNetwork == null || !defaultNetwork.network.equals(underlying[0])) {
return null;
}
return nai;
};
// TODO: move all callers to filterForLegacyLockdown and delete this method.
// This likely requires making sendLegacyNetworkBroadcast take a NetworkInfo object instead of
// just a DetailedState object.
private DetailedState getLegacyLockdownState(DetailedState origState) {
if (origState != DetailedState.CONNECTED) {
return origState;
}
return (mLockdownEnabled && getLegacyLockdownNai() == null)
? DetailedState.CONNECTING
: DetailedState.CONNECTED;
}
private void filterForLegacyLockdown(NetworkInfo ni) {
if (!mLockdownEnabled || !ni.isConnected()) return;
// The legacy lockdown VPN replaces the state of every network in CONNECTED state with the
// state of its VPN. This is to ensure that when an underlying network connects, apps will
// not see a CONNECTIVITY_ACTION broadcast for a network in state CONNECTED until the VPN
// comes up, at which point there is a new CONNECTIVITY_ACTION broadcast for the underlying
// network, this time with a state of CONNECTED.
//
// Now that the legacy lockdown code lives in ConnectivityService, and no longer has access
// to the internal state of the Vpn object, always replace the state with CONNECTING. This
// is not too far off the truth, since an always-on VPN, when not connected, is always
// trying to reconnect.
if (getLegacyLockdownNai() == null) {
ni.setDetailedState(DetailedState.CONNECTING, "", null);
}
}
@Override
public void setProvisioningNotificationVisible(boolean visible, int networkType,
String action) {
enforceSettingsPermission();
if (!ConnectivityManager.isNetworkTypeValid(networkType)) {
return;
}
final long ident = Binder.clearCallingIdentity();
try {
// Concatenate the range of types onto the range of NetIDs.
int id = NetIdManager.MAX_NET_ID + 1 + (networkType - ConnectivityManager.TYPE_NONE);
mNotifier.setProvNotificationVisible(visible, id, action);
} finally {
Binder.restoreCallingIdentity(ident);
}
}
@Override
public void setAirplaneMode(boolean enable) {
enforceAirplaneModePermission();
final long ident = Binder.clearCallingIdentity();
try {
final ContentResolver cr = mContext.getContentResolver();
Settings.Global.putInt(cr, Settings.Global.AIRPLANE_MODE_ON, encodeBool(enable));
Intent intent = new Intent(Intent.ACTION_AIRPLANE_MODE_CHANGED);
intent.putExtra("state", enable);
mContext.sendBroadcastAsUser(intent, UserHandle.ALL);
} finally {
Binder.restoreCallingIdentity(ident);
}
}
private void onUserAdded(@NonNull final UserHandle user) {
if (mOemNetworkPreferences.getNetworkPreferences().size() > 0) {
handleSetOemNetworkPreference(mOemNetworkPreferences, null);
}
updateProfileAllowedNetworks();
}
private void onUserRemoved(@NonNull final UserHandle user) {
// If there was a network preference for this user, remove it.
handleSetProfileNetworkPreference(
List.of(new ProfileNetworkPreferenceInfo(user, null, true,
false /* blockingNonEnterprise */)),
null /* listener */);
if (mOemNetworkPreferences.getNetworkPreferences().size() > 0) {
handleSetOemNetworkPreference(mOemNetworkPreferences, null);
}
}
private void onPackageChanged(@NonNull final String packageName) {
// This is necessary in case a package is added or removed, but also when it's replaced to
// run as a new UID by its manifest rules. Also, if a separate package shares the same UID
// as one in the preferences, then it should follow the same routing as that other package,
// which means updating the rules is never to be needed in this case (whether it joins or
// leaves a UID with a preference).
if (isMappedInOemNetworkPreference(packageName)) {
handleSetOemNetworkPreference(mOemNetworkPreferences, null);
}
// Invalidates cache entry when the package is updated.
synchronized (mSelfCertifiedCapabilityCache) {
mSelfCertifiedCapabilityCache.remove(packageName);
}
}
private final BroadcastReceiver mUserIntentReceiver = new BroadcastReceiver() {
@Override
public void onReceive(Context context, Intent intent) {
ensureRunningOnConnectivityServiceThread();
final String action = intent.getAction();
final UserHandle user = intent.getParcelableExtra(Intent.EXTRA_USER);
// User should be filled for below intents, check the existence.
if (user == null) {
Log.wtf(TAG, intent.getAction() + " broadcast without EXTRA_USER");
return;
}
if (Intent.ACTION_USER_ADDED.equals(action)) {
onUserAdded(user);
} else if (Intent.ACTION_USER_REMOVED.equals(action)) {
onUserRemoved(user);
} else {
Log.wtf(TAG, "received unexpected intent: " + action);
}
}
};
private final BroadcastReceiver mPackageIntentReceiver = new BroadcastReceiver() {
@Override
public void onReceive(Context context, Intent intent) {
ensureRunningOnConnectivityServiceThread();
switch (intent.getAction()) {
case Intent.ACTION_PACKAGE_ADDED:
case Intent.ACTION_PACKAGE_REMOVED:
case Intent.ACTION_PACKAGE_REPLACED:
onPackageChanged(intent.getData().getSchemeSpecificPart());
break;
default:
Log.wtf(TAG, "received unexpected intent: " + intent.getAction());
}
}
};
@RequiresApi(Build.VERSION_CODES.TIRAMISU)
private final BroadcastReceiver mDataSaverReceiver = new BroadcastReceiver() {
@Override
public void onReceive(Context context, Intent intent) {
if (mDeps.isAtLeastV()) {
throw new IllegalStateException(
"data saver status should be updated from platform");
}
ensureRunningOnConnectivityServiceThread();
switch (intent.getAction()) {
case ACTION_RESTRICT_BACKGROUND_CHANGED:
// If the uid is present in the deny list, the API will consistently
// return ENABLED. To retrieve the global switch status, the system
// uid is chosen because it will never be included in the deny list.
final int dataSaverForSystemUid =
mPolicyManager.getRestrictBackgroundStatus(Process.SYSTEM_UID);
final boolean isDataSaverEnabled = (dataSaverForSystemUid
!= ConnectivityManager.RESTRICT_BACKGROUND_STATUS_DISABLED);
mBpfNetMaps.setDataSaverEnabled(isDataSaverEnabled);
break;
default:
Log.wtf(TAG, "received unexpected intent: " + intent.getAction());
}
}
};
private final HashMap<Messenger, NetworkProviderInfo> mNetworkProviderInfos = new HashMap<>();
private final HashMap<NetworkRequest, NetworkRequestInfo> mNetworkRequests = new HashMap<>();
private static class NetworkProviderInfo {
public final String name;
public final Messenger messenger;
private final IBinder.DeathRecipient mDeathRecipient;
public final int providerId;
NetworkProviderInfo(String name, Messenger messenger, int providerId,
@NonNull IBinder.DeathRecipient deathRecipient) {
this.name = name;
this.messenger = messenger;
this.providerId = providerId;
mDeathRecipient = deathRecipient;
if (mDeathRecipient == null) {
throw new AssertionError("Must pass a deathRecipient");
}
}
void connect(Context context, Handler handler) {
try {
messenger.getBinder().linkToDeath(mDeathRecipient, 0);
} catch (RemoteException e) {
mDeathRecipient.binderDied();
}
}
}
private void ensureAllNetworkRequestsHaveType(List<NetworkRequest> requests) {
for (int i = 0; i < requests.size(); i++) {
ensureNetworkRequestHasType(requests.get(i));
}
}
private void ensureNetworkRequestHasType(NetworkRequest request) {
if (request.type == NetworkRequest.Type.NONE) {
throw new IllegalArgumentException(
"All NetworkRequests in ConnectivityService must have a type");
}
}
/**
* Tracks info about the requester.
* Also used to notice when the calling process dies so as to self-expire
*/
@VisibleForTesting
protected class NetworkRequestInfo implements IBinder.DeathRecipient {
// The requests to be satisfied in priority order. Non-multilayer requests will only have a
// single NetworkRequest in mRequests.
final List<NetworkRequest> mRequests;
// mSatisfier and mActiveRequest rely on one another therefore set them together.
void setSatisfier(
@Nullable final NetworkAgentInfo satisfier,
@Nullable final NetworkRequest activeRequest) {
mSatisfier = satisfier;
mActiveRequest = activeRequest;
}
// The network currently satisfying this NRI. Only one request in an NRI can have a
// satisfier. For non-multilayer requests, only non-listen requests can have a satisfier.
@Nullable
private NetworkAgentInfo mSatisfier;
NetworkAgentInfo getSatisfier() {
return mSatisfier;
}
// The request in mRequests assigned to a network agent. This is null if none of the
// requests in mRequests can be satisfied. This member has the constraint of only being
// accessible on the handler thread.
@Nullable
private NetworkRequest mActiveRequest;
NetworkRequest getActiveRequest() {
return mActiveRequest;
}
final PendingIntent mPendingIntent;
boolean mPendingIntentSent;
@Nullable
final Messenger mMessenger;
// Information about the caller that caused this object to be created.
@Nullable
private final IBinder mBinder;
final int mPid;
final int mUid;
final @NetworkCallback.Flag int mCallbackFlags;
@Nullable
final String mCallingAttributionTag;
// Counter keeping track of this NRI.
final RequestInfoPerUidCounter mPerUidCounter;
// Effective UID of this request. This is different from mUid when a privileged process
// files a request on behalf of another UID. This UID is used to determine blocked status,
// UID matching, and so on. mUid above is used for permission checks and to enforce the
// maximum limit of registered callbacks per UID.
final int mAsUid;
// Preference order of this request.
final int mPreferenceOrder;
// In order to preserve the mapping of NetworkRequest-to-callback when apps register
// callbacks using a returned NetworkRequest, the original NetworkRequest needs to be
// maintained for keying off of. This is only a concern when the original nri
// mNetworkRequests changes which happens currently for apps that register callbacks to
// track the default network. In those cases, the nri is updated to have mNetworkRequests
// that match the per-app default nri that currently tracks the calling app's uid so that
// callbacks are fired at the appropriate time. When the callbacks fire,
// mNetworkRequestForCallback will be used so as to preserve the caller's mapping. When
// callbacks are updated to key off of an nri vs NetworkRequest, this stops being an issue.
// TODO b/177608132: make sure callbacks are indexed by NRIs and not NetworkRequest objects.
@NonNull
private final NetworkRequest mNetworkRequestForCallback;
NetworkRequest getNetworkRequestForCallback() {
return mNetworkRequestForCallback;
}
/**
* Get the list of UIDs this nri applies to.
*/
@NonNull
Set<UidRange> getUids() {
// networkCapabilities.getUids() returns a defensive copy.
// multilayer requests will all have the same uids so return the first one.
final Set<UidRange> uids = mRequests.get(0).networkCapabilities.getUidRanges();
return (null == uids) ? new ArraySet<>() : uids;
}
NetworkRequestInfo(int asUid, @NonNull final NetworkRequest r,
@Nullable final PendingIntent pi, @Nullable String callingAttributionTag) {
this(asUid, Collections.singletonList(r), r, pi, callingAttributionTag,
PREFERENCE_ORDER_INVALID);
}
NetworkRequestInfo(int asUid, @NonNull final List<NetworkRequest> r,
@NonNull final NetworkRequest requestForCallback, @Nullable final PendingIntent pi,
@Nullable String callingAttributionTag, final int preferenceOrder) {
ensureAllNetworkRequestsHaveType(r);
mRequests = initializeRequests(r);
mNetworkRequestForCallback = requestForCallback;
mPendingIntent = pi;
mMessenger = null;
mBinder = null;
mPid = getCallingPid();
mUid = mDeps.getCallingUid();
mAsUid = asUid;
mPerUidCounter = getRequestCounter(this);
mPerUidCounter.incrementCountOrThrow(mUid);
/**
* Location sensitive data not included in pending intent. Only included in
* {@link NetworkCallback}.
*/
mCallbackFlags = NetworkCallback.FLAG_NONE;
mCallingAttributionTag = callingAttributionTag;
mPreferenceOrder = preferenceOrder;
}
NetworkRequestInfo(int asUid, @NonNull final NetworkRequest r, @Nullable final Messenger m,
@Nullable final IBinder binder,
@NetworkCallback.Flag int callbackFlags,
@Nullable String callingAttributionTag) {
this(asUid, Collections.singletonList(r), r, m, binder, callbackFlags,
callingAttributionTag);
}
NetworkRequestInfo(int asUid, @NonNull final List<NetworkRequest> r,
@NonNull final NetworkRequest requestForCallback, @Nullable final Messenger m,
@Nullable final IBinder binder,
@NetworkCallback.Flag int callbackFlags,
@Nullable String callingAttributionTag) {
super();
ensureAllNetworkRequestsHaveType(r);
mRequests = initializeRequests(r);
mNetworkRequestForCallback = requestForCallback;
mMessenger = m;
mBinder = binder;
mPid = getCallingPid();
mUid = mDeps.getCallingUid();
mAsUid = asUid;
mPendingIntent = null;
mPerUidCounter = getRequestCounter(this);
mPerUidCounter.incrementCountOrThrow(mUid);
mCallbackFlags = callbackFlags;
mCallingAttributionTag = callingAttributionTag;
mPreferenceOrder = PREFERENCE_ORDER_INVALID;
linkDeathRecipient();
}
NetworkRequestInfo(@NonNull final NetworkRequestInfo nri,
@NonNull final List<NetworkRequest> r) {
super();
ensureAllNetworkRequestsHaveType(r);
mRequests = initializeRequests(r);
mNetworkRequestForCallback = nri.getNetworkRequestForCallback();
final NetworkAgentInfo satisfier = nri.getSatisfier();
if (null != satisfier) {
// If the old NRI was satisfied by an NAI, then it may have had an active request.
// The active request is necessary to figure out what callbacks to send, in
// particular when a network updates its capabilities.
// As this code creates a new NRI with a new set of requests, figure out which of
// the list of requests should be the active request. It is always the first
// request of the list that can be satisfied by the satisfier since the order of
// requests is a priority order.
// Note even in the presence of a satisfier there may not be an active request,
// when the satisfier is the no-service network.
NetworkRequest activeRequest = null;
for (final NetworkRequest candidate : r) {
if (candidate.canBeSatisfiedBy(satisfier.networkCapabilities)) {
activeRequest = candidate;
break;
}
}
setSatisfier(satisfier, activeRequest);
}
mMessenger = nri.mMessenger;
mBinder = nri.mBinder;
mPid = nri.mPid;
mUid = nri.mUid;
mAsUid = nri.mAsUid;
mPendingIntent = nri.mPendingIntent;
mPerUidCounter = nri.mPerUidCounter;
mPerUidCounter.incrementCountOrThrow(mUid);
mCallbackFlags = nri.mCallbackFlags;
mCallingAttributionTag = nri.mCallingAttributionTag;
mPreferenceOrder = PREFERENCE_ORDER_INVALID;
linkDeathRecipient();
}
NetworkRequestInfo(int asUid, @NonNull final NetworkRequest r) {
this(asUid, Collections.singletonList(r), PREFERENCE_ORDER_INVALID);
}
NetworkRequestInfo(int asUid, @NonNull final List<NetworkRequest> r,
final int preferenceOrder) {
this(asUid, r, r.get(0), null /* pi */, null /* callingAttributionTag */,
preferenceOrder);
}
// True if this NRI is being satisfied. It also accounts for if the nri has its satisifer
// set to the mNoServiceNetwork in which case mActiveRequest will be null thus returning
// false.
boolean isBeingSatisfied() {
return (null != mSatisfier && null != mActiveRequest);
}
boolean isMultilayerRequest() {
return mRequests.size() > 1;
}
private List<NetworkRequest> initializeRequests(List<NetworkRequest> r) {
// Creating a defensive copy to prevent the sender from modifying the list being
// reflected in the return value of this method.
final List<NetworkRequest> tempRequests = new ArrayList<>(r);
return Collections.unmodifiableList(tempRequests);
}
void linkDeathRecipient() {
if (null != mBinder) {
try {
mBinder.linkToDeath(this, 0);
} catch (RemoteException e) {
binderDied();
}
}
}
void unlinkDeathRecipient() {
if (null != mBinder) {
try {
mBinder.unlinkToDeath(this, 0);
} catch (NoSuchElementException e) {
// Temporary workaround for b/194394697 pending analysis of additional logs
Log.wtf(TAG, "unlinkToDeath for already unlinked NRI " + this);
}
}
}
boolean hasHigherOrderThan(@NonNull final NetworkRequestInfo target) {
// Compare two preference orders.
return mPreferenceOrder < target.mPreferenceOrder;
}
int getPreferenceOrderForNetd() {
if (mPreferenceOrder >= PREFERENCE_ORDER_NONE
&& mPreferenceOrder <= PREFERENCE_ORDER_LOWEST) {
return mPreferenceOrder;
}
return PREFERENCE_ORDER_NONE;
}
@Override
public void binderDied() {
// As an immutable collection, mRequests cannot change by the time the
// lambda is evaluated on the handler thread so calling .get() from a binder thread
// is acceptable. Use handleReleaseNetworkRequest and not directly
// handleRemoveNetworkRequest so as to force a lookup in the requests map, in case
// the app already unregistered the request.
mHandler.post(() -> handleReleaseNetworkRequest(mRequests.get(0),
mUid, false /* callOnUnavailable */));
}
@Override
public String toString() {
final String asUidString = (mAsUid == mUid) ? "" : " asUid: " + mAsUid;
return "uid/pid:" + mUid + "/" + mPid + asUidString + " activeRequest: "
+ (mActiveRequest == null ? null : mActiveRequest.requestId)
+ " callbackRequest: "
+ mNetworkRequestForCallback.requestId
+ " " + mRequests
+ (mPendingIntent == null ? "" : " to trigger " + mPendingIntent)
+ " callback flags: " + mCallbackFlags
+ " order: " + mPreferenceOrder;
}
}
// Keep backward compatibility since the ServiceSpecificException is used by
// the API surface, see {@link ConnectivityManager#convertServiceException}.
public static class RequestInfoPerUidCounter extends PerUidCounter {
RequestInfoPerUidCounter(int maxCountPerUid) {
super(maxCountPerUid);
}
@Override
public synchronized void incrementCountOrThrow(int uid) {
try {
super.incrementCountOrThrow(uid);
} catch (IllegalStateException e) {
throw new ServiceSpecificException(
ConnectivityManager.Errors.TOO_MANY_REQUESTS,
"Uid " + uid + " exceeded its allotted requests limit");
}
}
@Override
public synchronized void decrementCountOrThrow(int uid) {
throw new UnsupportedOperationException("Use decrementCount instead.");
}
public synchronized void decrementCount(int uid) {
try {
super.decrementCountOrThrow(uid);
} catch (IllegalStateException e) {
logwtf("Exception when decrement per uid request count: ", e);
}
}
}
// This checks that the passed capabilities either do not request a
// specific SSID/SignalStrength, or the calling app has permission to do so.
private void ensureSufficientPermissionsForRequest(NetworkCapabilities nc,
int callerPid, int callerUid, String callerPackageName) {
if (null != nc.getSsid() && !checkSettingsPermission(callerPid, callerUid)) {
throw new SecurityException("Insufficient permissions to request a specific SSID");
}
if (nc.hasSignalStrength()
&& !checkNetworkSignalStrengthWakeupPermission(callerPid, callerUid)) {
throw new SecurityException(
"Insufficient permissions to request a specific signal strength");
}
mAppOpsManager.checkPackage(callerUid, callerPackageName);
if (!nc.getSubscriptionIds().isEmpty()) {
enforceNetworkFactoryPermission();
}
}
private int[] getSignalStrengthThresholds(@NonNull final NetworkAgentInfo nai) {
final SortedSet<Integer> thresholds = new TreeSet<>();
synchronized (nai) {
// mNetworkRequests may contain the same value multiple times in case of
// multilayer requests. It won't matter in this case because the thresholds
// will then be the same and be deduplicated as they enter the `thresholds` set.
// TODO : have mNetworkRequests be a Set<NetworkRequestInfo> or the like.
for (final NetworkRequestInfo nri : mNetworkRequests.values()) {
for (final NetworkRequest req : nri.mRequests) {
if (req.networkCapabilities.hasSignalStrength()
&& nai.satisfiesImmutableCapabilitiesOf(req)) {
thresholds.add(req.networkCapabilities.getSignalStrength());
}
}
}
}
return CollectionUtils.toIntArray(new ArrayList<>(thresholds));
}
private void updateSignalStrengthThresholds(
NetworkAgentInfo nai, String reason, NetworkRequest request) {
final int[] thresholdsArray = getSignalStrengthThresholds(nai);
if (VDBG || (DBG && !"CONNECT".equals(reason))) {
String detail;
if (request != null && request.networkCapabilities.hasSignalStrength()) {
detail = reason + " " + request.networkCapabilities.getSignalStrength();
} else {
detail = reason;
}
log(String.format("updateSignalStrengthThresholds: %s, sending %s to %s",
detail, Arrays.toString(thresholdsArray), nai.toShortString()));
}
nai.onSignalStrengthThresholdsUpdated(thresholdsArray);
}
private static void ensureValidNetworkSpecifier(NetworkCapabilities nc) {
if (nc == null) {
return;
}
NetworkSpecifier ns = nc.getNetworkSpecifier();
if (ns == null) {
return;
}
if (ns instanceof MatchAllNetworkSpecifier) {
throw new IllegalArgumentException("A MatchAllNetworkSpecifier is not permitted");
}
}
private static void ensureListenableCapabilities(@NonNull final NetworkCapabilities nc) {
ensureValidNetworkSpecifier(nc);
if (nc.isPrivateDnsBroken()) {
throw new IllegalArgumentException("Can't request broken private DNS");
}
if (nc.hasAllowedUids()) {
throw new IllegalArgumentException("Can't request access UIDs");
}
}
private void ensureRequestableCapabilities(@NonNull final NetworkCapabilities nc) {
ensureListenableCapabilities(nc);
final String badCapability = nc.describeFirstNonRequestableCapability();
if (badCapability != null) {
throw new IllegalArgumentException("Cannot request network with " + badCapability);
}
}
// TODO: Set the mini sdk to 31 and remove @TargetApi annotation when b/205923322 is addressed.
@TargetApi(Build.VERSION_CODES.S)
private boolean isTargetSdkAtleast(int version, int callingUid,
@NonNull String callingPackageName) {
final UserHandle user = UserHandle.getUserHandleForUid(callingUid);
final PackageManager pm =
mContext.createContextAsUser(user, 0 /* flags */).getPackageManager();
try {
final int callingVersion = pm.getTargetSdkVersion(callingPackageName);
if (callingVersion < version) return false;
} catch (PackageManager.NameNotFoundException e) { }
return true;
}
@Override
public NetworkRequest requestNetwork(int asUid, NetworkCapabilities networkCapabilities,
int reqTypeInt, Messenger messenger, int timeoutMs, final IBinder binder,
int legacyType, int callbackFlags, @NonNull String callingPackageName,
@Nullable String callingAttributionTag) {
if (legacyType != TYPE_NONE && !checkNetworkStackPermission()) {
if (isTargetSdkAtleast(Build.VERSION_CODES.M, mDeps.getCallingUid(),
callingPackageName)) {
throw new SecurityException("Insufficient permissions to specify legacy type");
}
}
final NetworkCapabilities defaultNc = mDefaultRequest.mRequests.get(0).networkCapabilities;
final int callingUid = mDeps.getCallingUid();
// Privileged callers can track the default network of another UID by passing in a UID.
if (asUid != Process.INVALID_UID) {
enforceSettingsPermission();
} else {
asUid = callingUid;
}
final NetworkRequest.Type reqType;
try {
reqType = NetworkRequest.Type.values()[reqTypeInt];
} catch (ArrayIndexOutOfBoundsException e) {
throw new IllegalArgumentException("Unsupported request type " + reqTypeInt);
}
switch (reqType) {
case TRACK_DEFAULT:
// If the request type is TRACK_DEFAULT, the passed {@code networkCapabilities}
// is unused and will be replaced by ones appropriate for the UID (usually, the
// calling app). This allows callers to keep track of the default network.
networkCapabilities = copyDefaultNetworkCapabilitiesForUid(
defaultNc, asUid, callingUid, callingPackageName);
enforceAccessPermission();
break;
case TRACK_SYSTEM_DEFAULT:
enforceSettingsOrSetupWizardOrUseRestrictedNetworksPermission();
networkCapabilities = new NetworkCapabilities(defaultNc);
break;
case BACKGROUND_REQUEST:
enforceNetworkStackOrSettingsPermission();
// Fall-through since other checks are the same with normal requests.
case REQUEST:
networkCapabilities = new NetworkCapabilities(networkCapabilities);
enforceNetworkRequestPermissions(networkCapabilities, callingPackageName,
callingAttributionTag, callingUid);
// TODO: this is incorrect. We mark the request as metered or not depending on
// the state of the app when the request is filed, but we never change the
// request if the app changes network state. http://b/29964605
enforceMeteredApnPolicy(networkCapabilities);
break;
case LISTEN_FOR_BEST:
enforceAccessPermission();
networkCapabilities = new NetworkCapabilities(networkCapabilities);
break;
default:
throw new IllegalArgumentException("Unsupported request type " + reqType);
}
ensureRequestableCapabilities(networkCapabilities);
ensureSufficientPermissionsForRequest(networkCapabilities,
Binder.getCallingPid(), callingUid, callingPackageName);
// Enforce FOREGROUND if the caller does not have permission to use background network.
if (reqType == LISTEN_FOR_BEST) {
restrictBackgroundRequestForCaller(networkCapabilities);
}
// Set the UID range for this request to the single UID of the requester, unless the
// requester has the permission to specify other UIDs.
// This will overwrite any allowed UIDs in the requested capabilities. Though there
// are no visible methods to set the UIDs, an app could use reflection to try and get
// networks for other apps so it's essential that the UIDs are overwritten.
// Also set the requester UID and package name in the request.
restrictRequestUidsForCallerAndSetRequestorInfo(networkCapabilities,
callingUid, callingPackageName);
if (timeoutMs < 0) {
throw new IllegalArgumentException("Bad timeout specified");
}
final NetworkRequest networkRequest = new NetworkRequest(networkCapabilities, legacyType,
nextNetworkRequestId(), reqType);
final NetworkRequestInfo nri = getNriToRegister(
asUid, networkRequest, messenger, binder, callbackFlags,
callingAttributionTag);
if (DBG) log("requestNetwork for " + nri);
// For TRACK_SYSTEM_DEFAULT callbacks, the capabilities have been modified since they were
// copied from the default request above. (This is necessary to ensure, for example, that
// the callback does not leak sensitive information to unprivileged apps.) Check that the
// changes don't alter request matching.
if (reqType == NetworkRequest.Type.TRACK_SYSTEM_DEFAULT &&
(!networkCapabilities.equalRequestableCapabilities(defaultNc))) {
throw new IllegalStateException(
"TRACK_SYSTEM_DEFAULT capabilities don't match default request: "
+ networkCapabilities + " vs. " + defaultNc);
}
mHandler.sendMessage(mHandler.obtainMessage(EVENT_REGISTER_NETWORK_REQUEST, nri));
if (timeoutMs > 0) {
mHandler.sendMessageDelayed(mHandler.obtainMessage(EVENT_TIMEOUT_NETWORK_REQUEST,
nri), timeoutMs);
}
return networkRequest;
}
/**
* Return the nri to be used when registering a network request. Specifically, this is used with
* requests registered to track the default request. If there is currently a per-app default
* tracking the app requestor, then we need to create a version of this nri that mirrors that of
* the tracking per-app default so that callbacks are sent to the app requestor appropriately.
* @param asUid the uid on behalf of which to file the request. Different from requestorUid
* when a privileged caller is tracking the default network for another uid.
* @param nr the network request for the nri.
* @param msgr the messenger for the nri.
* @param binder the binder for the nri.
* @param callingAttributionTag the calling attribution tag for the nri.
* @return the nri to register.
*/
private NetworkRequestInfo getNriToRegister(final int asUid, @NonNull final NetworkRequest nr,
@Nullable final Messenger msgr, @Nullable final IBinder binder,
@NetworkCallback.Flag int callbackFlags,
@Nullable String callingAttributionTag) {
final List<NetworkRequest> requests;
if (NetworkRequest.Type.TRACK_DEFAULT == nr.type) {
requests = copyDefaultNetworkRequestsForUid(
asUid, nr.getRequestorUid(), nr.getRequestorPackageName());
} else {
requests = Collections.singletonList(nr);
}
return new NetworkRequestInfo(
asUid, requests, nr, msgr, binder, callbackFlags, callingAttributionTag);
}
private boolean shouldCheckCapabilitiesDeclaration(
@NonNull final NetworkCapabilities networkCapabilities, final int callingUid,
@NonNull final String callingPackageName) {
final UserHandle user = UserHandle.getUserHandleForUid(callingUid);
// Only run the check if the change is enabled.
if (!mDeps.isChangeEnabled(
ConnectivityCompatChanges.ENABLE_SELF_CERTIFIED_CAPABILITIES_DECLARATION,
callingPackageName, user)) {
return false;
}
return networkCapabilities.hasCapability(
NetworkCapabilities.NET_CAPABILITY_PRIORITIZE_BANDWIDTH)
|| networkCapabilities.hasCapability(
NetworkCapabilities.NET_CAPABILITY_PRIORITIZE_LATENCY);
}
private void enforceRequestCapabilitiesDeclaration(@NonNull final String callerPackageName,
@NonNull final NetworkCapabilities networkCapabilities, int callingUid) {
// This check is added to fix the linter error for "current min is 30", which is not going
// to happen because Connectivity service always run in S+.
if (!mDeps.isAtLeastS()) {
Log.wtf(TAG, "Connectivity service should always run in at least SDK S");
return;
}
ApplicationSelfCertifiedNetworkCapabilities applicationNetworkCapabilities;
final long ident = Binder.clearCallingIdentity();
try {
synchronized (mSelfCertifiedCapabilityCache) {
applicationNetworkCapabilities = mSelfCertifiedCapabilityCache.get(
callerPackageName);
if (applicationNetworkCapabilities == null) {
final PackageManager packageManager =
mContext.createContextAsUser(UserHandle.getUserHandleForUid(
callingUid), 0 /* flags */).getPackageManager();
final PackageManager.Property networkSliceProperty = packageManager.getProperty(
ConstantsShim.PROPERTY_SELF_CERTIFIED_NETWORK_CAPABILITIES,
callerPackageName
);
final XmlResourceParser parser = packageManager
.getResourcesForApplication(callerPackageName)
.getXml(networkSliceProperty.getResourceId());
applicationNetworkCapabilities =
ApplicationSelfCertifiedNetworkCapabilities.createFromXml(parser);
mSelfCertifiedCapabilityCache.put(callerPackageName,
applicationNetworkCapabilities);
}
}
} catch (PackageManager.NameNotFoundException ne) {
throw new SecurityException(
"Cannot find " + ConstantsShim.PROPERTY_SELF_CERTIFIED_NETWORK_CAPABILITIES
+ " property");
} catch (XmlPullParserException | IOException | InvalidTagException e) {
throw new SecurityException(e.getMessage());
} finally {
Binder.restoreCallingIdentity(ident);
}
applicationNetworkCapabilities.enforceSelfCertifiedNetworkCapabilitiesDeclared(
networkCapabilities);
}
private void enforceNetworkRequestPermissions(NetworkCapabilities networkCapabilities,
String callingPackageName, String callingAttributionTag, final int callingUid) {
if (shouldCheckCapabilitiesDeclaration(networkCapabilities, callingUid,
callingPackageName)) {
enforceRequestCapabilitiesDeclaration(callingPackageName, networkCapabilities,
callingUid);
}
if (networkCapabilities.hasCapability(NET_CAPABILITY_NOT_RESTRICTED) == false) {
// For T+ devices, callers with carrier privilege could request with CBS capabilities.
if (networkCapabilities.hasCapability(NetworkCapabilities.NET_CAPABILITY_CBS)
&& hasCarrierPrivilegeForNetworkCaps(callingUid, networkCapabilities)) {
return;
}
enforceConnectivityRestrictedNetworksPermission(true /* checkUidsAllowedList */);
} else {
enforceChangePermission(callingPackageName, callingAttributionTag);
}
}
@Override
public boolean requestBandwidthUpdate(Network network) {
enforceAccessPermission();
NetworkAgentInfo nai = null;
if (network == null) {
return false;
}
synchronized (mNetworkForNetId) {
nai = mNetworkForNetId.get(network.getNetId());
}
if (nai != null) {
nai.onBandwidthUpdateRequested();
synchronized (mBandwidthRequests) {
final int uid = mDeps.getCallingUid();
Integer uidReqs = mBandwidthRequests.get(uid);
if (uidReqs == null) {
uidReqs = 0;
}
mBandwidthRequests.put(uid, ++uidReqs);
}
return true;
}
return false;
}
private boolean isSystem(int uid) {
return uid < Process.FIRST_APPLICATION_UID;
}
private void enforceMeteredApnPolicy(NetworkCapabilities networkCapabilities) {
final int uid = mDeps.getCallingUid();
if (isSystem(uid)) {
// Exemption for system uid.
return;
}
if (networkCapabilities.hasCapability(NET_CAPABILITY_NOT_METERED)) {
// Policy already enforced.
return;
}
final long ident = Binder.clearCallingIdentity();
try {
if (mPolicyManager.isUidRestrictedOnMeteredNetworks(uid)) {
// If UID is restricted, don't allow them to bring up metered APNs.
networkCapabilities.addCapability(NET_CAPABILITY_NOT_METERED);
}
} finally {
Binder.restoreCallingIdentity(ident);
}
}
@Override
public NetworkRequest pendingRequestForNetwork(NetworkCapabilities networkCapabilities,
PendingIntent operation, @NonNull String callingPackageName,
@Nullable String callingAttributionTag) {
Objects.requireNonNull(operation, "PendingIntent cannot be null.");
final int callingUid = mDeps.getCallingUid();
networkCapabilities = new NetworkCapabilities(networkCapabilities);
enforceNetworkRequestPermissions(networkCapabilities, callingPackageName,
callingAttributionTag, callingUid);
enforceMeteredApnPolicy(networkCapabilities);
ensureRequestableCapabilities(networkCapabilities);
ensureSufficientPermissionsForRequest(networkCapabilities,
Binder.getCallingPid(), callingUid, callingPackageName);
restrictRequestUidsForCallerAndSetRequestorInfo(networkCapabilities,
callingUid, callingPackageName);
NetworkRequest networkRequest = new NetworkRequest(networkCapabilities, TYPE_NONE,
nextNetworkRequestId(), NetworkRequest.Type.REQUEST);
NetworkRequestInfo nri = new NetworkRequestInfo(callingUid, networkRequest, operation,
callingAttributionTag);
if (DBG) log("pendingRequest for " + nri);
mHandler.sendMessage(mHandler.obtainMessage(EVENT_REGISTER_NETWORK_REQUEST_WITH_INTENT,
nri));
return networkRequest;
}
private void releasePendingNetworkRequestWithDelay(PendingIntent operation) {
mHandler.sendMessageDelayed(
mHandler.obtainMessage(EVENT_RELEASE_NETWORK_REQUEST_WITH_INTENT,
mDeps.getCallingUid(), 0, operation), mReleasePendingIntentDelayMs);
}
@Override
public void releasePendingNetworkRequest(PendingIntent operation) {
Objects.requireNonNull(operation, "PendingIntent cannot be null.");
mHandler.sendMessage(mHandler.obtainMessage(EVENT_RELEASE_NETWORK_REQUEST_WITH_INTENT,
mDeps.getCallingUid(), 0, operation));
}
// In order to implement the compatibility measure for pre-M apps that call
// WifiManager.enableNetwork(..., true) without also binding to that network explicitly,
// WifiManager registers a network listen for the purpose of calling setProcessDefaultNetwork.
// This ensures it has permission to do so.
private boolean hasWifiNetworkListenPermission(NetworkCapabilities nc) {
if (nc == null) {
return false;
}
int[] transportTypes = nc.getTransportTypes();
if (transportTypes.length != 1 || transportTypes[0] != NetworkCapabilities.TRANSPORT_WIFI) {
return false;
}
try {
mContext.enforceCallingOrSelfPermission(
android.Manifest.permission.ACCESS_WIFI_STATE,
"ConnectivityService");
} catch (SecurityException e) {
return false;
}
return true;
}
@Override
public NetworkRequest listenForNetwork(NetworkCapabilities networkCapabilities,
Messenger messenger, IBinder binder,
@NetworkCallback.Flag int callbackFlags,
@NonNull String callingPackageName, @NonNull String callingAttributionTag) {
final int callingUid = mDeps.getCallingUid();
if (!hasWifiNetworkListenPermission(networkCapabilities)) {
enforceAccessPermission();
}
NetworkCapabilities nc = new NetworkCapabilities(networkCapabilities);
ensureSufficientPermissionsForRequest(networkCapabilities,
Binder.getCallingPid(), callingUid, callingPackageName);
restrictRequestUidsForCallerAndSetRequestorInfo(nc, callingUid, callingPackageName);
// Apps without the CHANGE_NETWORK_STATE permission can't use background networks, so
// make all their listens include NET_CAPABILITY_FOREGROUND. That way, they will get
// onLost and onAvailable callbacks when networks move in and out of the background.
// There is no need to do this for requests because an app without CHANGE_NETWORK_STATE
// can't request networks.
restrictBackgroundRequestForCaller(nc);
ensureListenableCapabilities(nc);
NetworkRequest networkRequest = new NetworkRequest(nc, TYPE_NONE, nextNetworkRequestId(),
NetworkRequest.Type.LISTEN);
NetworkRequestInfo nri =
new NetworkRequestInfo(callingUid, networkRequest, messenger, binder, callbackFlags,
callingAttributionTag);
if (VDBG) log("listenForNetwork for " + nri);
mHandler.sendMessage(mHandler.obtainMessage(EVENT_REGISTER_NETWORK_LISTENER, nri));
return networkRequest;
}
@Override
public void pendingListenForNetwork(NetworkCapabilities networkCapabilities,
PendingIntent operation, @NonNull String callingPackageName,
@Nullable String callingAttributionTag) {
Objects.requireNonNull(operation, "PendingIntent cannot be null.");
final int callingUid = mDeps.getCallingUid();
if (!hasWifiNetworkListenPermission(networkCapabilities)) {
enforceAccessPermission();
}
ensureListenableCapabilities(networkCapabilities);
ensureSufficientPermissionsForRequest(networkCapabilities,
Binder.getCallingPid(), callingUid, callingPackageName);
final NetworkCapabilities nc = new NetworkCapabilities(networkCapabilities);
restrictRequestUidsForCallerAndSetRequestorInfo(nc, callingUid, callingPackageName);
NetworkRequest networkRequest = new NetworkRequest(nc, TYPE_NONE, nextNetworkRequestId(),
NetworkRequest.Type.LISTEN);
NetworkRequestInfo nri = new NetworkRequestInfo(callingUid, networkRequest, operation,
callingAttributionTag);
if (VDBG) log("pendingListenForNetwork for " + nri);
mHandler.sendMessage(mHandler.obtainMessage(
EVENT_REGISTER_NETWORK_LISTENER_WITH_INTENT, nri));
}
/** Returns the next Network provider ID. */
public final int nextNetworkProviderId() {
return mNextNetworkProviderId.getAndIncrement();
}
@Override
public void releaseNetworkRequest(NetworkRequest networkRequest) {
ensureNetworkRequestHasType(networkRequest);
mHandler.sendMessage(mHandler.obtainMessage(
EVENT_RELEASE_NETWORK_REQUEST, mDeps.getCallingUid(), 0, networkRequest));
}
private void handleRegisterNetworkProvider(NetworkProviderInfo npi) {
if (mNetworkProviderInfos.containsKey(npi.messenger)) {
// Avoid creating duplicates. even if an app makes a direct AIDL call.
// This will never happen if an app calls ConnectivityManager#registerNetworkProvider,
// as that will throw if a duplicate provider is registered.
loge("Attempt to register existing NetworkProviderInfo "
+ mNetworkProviderInfos.get(npi.messenger).name);
return;
}
if (DBG) log("Got NetworkProvider Messenger for " + npi.name);
mNetworkProviderInfos.put(npi.messenger, npi);
npi.connect(mContext, mTrackerHandler);
}
@Override
public int registerNetworkProvider(Messenger messenger, String name) {
enforceNetworkFactoryOrSettingsPermission();
Objects.requireNonNull(messenger, "messenger must be non-null");
NetworkProviderInfo npi = new NetworkProviderInfo(name, messenger,
nextNetworkProviderId(), () -> unregisterNetworkProvider(messenger));
mHandler.sendMessage(mHandler.obtainMessage(EVENT_REGISTER_NETWORK_PROVIDER, npi));
return npi.providerId;
}
@Override
public void unregisterNetworkProvider(Messenger messenger) {
enforceNetworkFactoryOrSettingsPermission();
mHandler.sendMessage(mHandler.obtainMessage(EVENT_UNREGISTER_NETWORK_PROVIDER, messenger));
}
@Override
public void offerNetwork(final int providerId,
@NonNull final NetworkScore score, @NonNull final NetworkCapabilities caps,
@NonNull final INetworkOfferCallback callback) {
Objects.requireNonNull(score);
Objects.requireNonNull(caps);
Objects.requireNonNull(callback);
final boolean yieldToBadWiFi = caps.hasTransport(TRANSPORT_CELLULAR) && !avoidBadWifi();
final NetworkOffer offer = new NetworkOffer(
FullScore.makeProspectiveScore(score, caps, yieldToBadWiFi),
caps, callback, providerId);
mHandler.sendMessage(mHandler.obtainMessage(EVENT_REGISTER_NETWORK_OFFER, offer));
}
private void updateOfferScore(final NetworkOffer offer) {
final boolean yieldToBadWiFi =
offer.caps.hasTransport(TRANSPORT_CELLULAR) && !avoidBadWifi();
final NetworkOffer newOffer = new NetworkOffer(
offer.score.withYieldToBadWiFi(yieldToBadWiFi),
offer.caps, offer.callback, offer.providerId);
if (offer.equals(newOffer)) return;
handleRegisterNetworkOffer(newOffer);
}
@Override
public void unofferNetwork(@NonNull final INetworkOfferCallback callback) {
Objects.requireNonNull(callback);
mHandler.sendMessage(mHandler.obtainMessage(EVENT_UNREGISTER_NETWORK_OFFER, callback));
}
private void handleUnregisterNetworkProvider(Messenger messenger) {
NetworkProviderInfo npi = mNetworkProviderInfos.remove(messenger);
if (npi == null) {
loge("Failed to find Messenger in unregisterNetworkProvider");
return;
}
// Unregister all the offers from this provider
final ArrayList<NetworkOfferInfo> toRemove = new ArrayList<>();
for (final NetworkOfferInfo noi : mNetworkOffers) {
if (noi.offer.providerId == npi.providerId) {
// Can't call handleUnregisterNetworkOffer here because iteration is in progress
toRemove.add(noi);
}
}
for (final NetworkOfferInfo noi : toRemove) {
handleUnregisterNetworkOffer(noi);
}
if (DBG) log("unregisterNetworkProvider for " + npi.name);
}
@Override
public void declareNetworkRequestUnfulfillable(@NonNull final NetworkRequest request) {
if (request.hasTransport(TRANSPORT_TEST)) {
enforceNetworkFactoryOrTestNetworksPermission();
} else {
enforceNetworkFactoryPermission();
}
final NetworkRequestInfo nri = mNetworkRequests.get(request);
if (nri != null) {
// declareNetworkRequestUnfulfillable() paths don't apply to multilayer requests.
ensureNotMultilayerRequest(nri, "declareNetworkRequestUnfulfillable");
mHandler.post(() -> handleReleaseNetworkRequest(
nri.mRequests.get(0), mDeps.getCallingUid(), true));
}
}
// NOTE: Accessed on multiple threads, must be synchronized on itself.
@GuardedBy("mNetworkForNetId")
private final SparseArray<NetworkAgentInfo> mNetworkForNetId = new SparseArray<>();
// NOTE: Accessed on multiple threads, synchronized with mNetworkForNetId.
// An entry is first reserved with NetIdManager, prior to being added to mNetworkForNetId, so
// there may not be a strict 1:1 correlation between the two.
private final NetIdManager mNetIdManager;
// Tracks all NetworkAgents that are currently registered.
// NOTE: Only should be accessed on ConnectivityServiceThread, except dump().
private final ArraySet<NetworkAgentInfo> mNetworkAgentInfos = new ArraySet<>();
// UID ranges for users that are currently blocked by VPNs.
// This array is accessed and iterated on multiple threads without holding locks, so its
// contents must never be mutated. When the ranges change, the array is replaced with a new one
// (on the handler thread).
private volatile List<UidRange> mVpnBlockedUidRanges = new ArrayList<>();
// Must only be accessed on the handler thread
@NonNull
private final ArrayList<NetworkOfferInfo> mNetworkOffers = new ArrayList<>();
@GuardedBy("mBlockedAppUids")
private final HashSet<Integer> mBlockedAppUids = new HashSet<>();
// Current OEM network preferences. This object must only be written to on the handler thread.
// Since it is immutable and always non-null, other threads may read it if they only care
// about seeing a consistent object but not that it is current.
@NonNull
private OemNetworkPreferences mOemNetworkPreferences =
new OemNetworkPreferences.Builder().build();
// Current per-profile network preferences. This object follows the same threading rules as
// the OEM network preferences above.
@NonNull
private NetworkPreferenceList<UserHandle, ProfileNetworkPreferenceInfo>
mProfileNetworkPreferences = new NetworkPreferenceList<>();
// Current VPN network preferences. This object follows the same threading rules as the OEM
// network preferences above.
@NonNull
private NetworkPreferenceList<String, VpnNetworkPreferenceInfo>
mVpnNetworkPreferences = new NetworkPreferenceList<>();
// A set of UIDs that should use mobile data preferentially if available. This object follows
// the same threading rules as the OEM network preferences above.
@NonNull
private Set<Integer> mMobileDataPreferredUids = new ArraySet<>();
// OemNetworkPreferences activity String log entries.
private static final int MAX_OEM_NETWORK_PREFERENCE_LOGS = 20;
@NonNull
private final LocalLog mOemNetworkPreferencesLogs =
new LocalLog(MAX_OEM_NETWORK_PREFERENCE_LOGS);
/**
* Determine whether a given package has a mapping in the current OemNetworkPreferences.
* @param packageName the package name to check existence of a mapping for.
* @return true if a mapping exists, false otherwise
*/
private boolean isMappedInOemNetworkPreference(@NonNull final String packageName) {
return mOemNetworkPreferences.getNetworkPreferences().containsKey(packageName);
}
// The always-on request for an Internet-capable network that apps without a specific default
// fall back to.
@VisibleForTesting
@NonNull
final NetworkRequestInfo mDefaultRequest;
// Collection of NetworkRequestInfo's used for default networks.
@VisibleForTesting
@NonNull
final ArraySet<NetworkRequestInfo> mDefaultNetworkRequests = new ArraySet<>();
private boolean isPerAppDefaultRequest(@NonNull final NetworkRequestInfo nri) {
return (mDefaultNetworkRequests.contains(nri) && mDefaultRequest != nri);
}
/**
* Return the default network request currently tracking the given uid.
* @param uid the uid to check.
* @return the NetworkRequestInfo tracking the given uid.
*/
@NonNull
private NetworkRequestInfo getDefaultRequestTrackingUid(final int uid) {
NetworkRequestInfo highestPriorityNri = mDefaultRequest;
for (final NetworkRequestInfo nri : mDefaultNetworkRequests) {
// Checking the first request is sufficient as only multilayer requests will have more
// than one request and for multilayer, all requests will track the same uids.
if (nri.mRequests.get(0).networkCapabilities.appliesToUid(uid)) {
// Find out the highest priority request.
if (nri.hasHigherOrderThan(highestPriorityNri)) {
highestPriorityNri = nri;
}
}
}
return highestPriorityNri;
}
/**
* Get a copy of the network requests of the default request that is currently tracking the
* given uid.
* @param asUid the uid on behalf of which to file the request. Different from requestorUid
* when a privileged caller is tracking the default network for another uid.
* @param requestorUid the uid to check the default for.
* @param requestorPackageName the requestor's package name.
* @return a copy of the default's NetworkRequest that is tracking the given uid.
*/
@NonNull
private List<NetworkRequest> copyDefaultNetworkRequestsForUid(
final int asUid, final int requestorUid, @NonNull final String requestorPackageName) {
return copyNetworkRequestsForUid(
getDefaultRequestTrackingUid(asUid).mRequests,
asUid, requestorUid, requestorPackageName);
}
/**
* Copy the given nri's NetworkRequest collection.
* @param requestsToCopy the NetworkRequest collection to be copied.
* @param asUid the uid on behalf of which to file the request. Different from requestorUid
* when a privileged caller is tracking the default network for another uid.
* @param requestorUid the uid to set on the copied collection.
* @param requestorPackageName the package name to set on the copied collection.
* @return the copied NetworkRequest collection.
*/
@NonNull
private List<NetworkRequest> copyNetworkRequestsForUid(
@NonNull final List<NetworkRequest> requestsToCopy, final int asUid,
final int requestorUid, @NonNull final String requestorPackageName) {
final List<NetworkRequest> requests = new ArrayList<>();
for (final NetworkRequest nr : requestsToCopy) {
requests.add(new NetworkRequest(copyDefaultNetworkCapabilitiesForUid(
nr.networkCapabilities, asUid, requestorUid, requestorPackageName),
nr.legacyType, nextNetworkRequestId(), nr.type));
}
return requests;
}
@NonNull
private NetworkCapabilities copyDefaultNetworkCapabilitiesForUid(
@NonNull final NetworkCapabilities netCapToCopy, final int asUid,
final int requestorUid, @NonNull final String requestorPackageName) {
// These capabilities are for a TRACK_DEFAULT callback, so:
// 1. Remove NET_CAPABILITY_VPN, because it's (currently!) the only difference between
// mDefaultRequest and a per-UID default request.
// TODO: stop depending on the fact that these two unrelated things happen to be the same
// 2. Always set the UIDs to asUid. restrictRequestUidsForCallerAndSetRequestorInfo will
// not do this in the case of a privileged application.
final NetworkCapabilities netCap = new NetworkCapabilities(netCapToCopy);
netCap.removeCapability(NET_CAPABILITY_NOT_VPN);
netCap.setSingleUid(asUid);
restrictRequestUidsForCallerAndSetRequestorInfo(
netCap, requestorUid, requestorPackageName);
return netCap;
}
/**
* Get the nri that is currently being tracked for callbacks by per-app defaults.
* @param nr the network request to check for equality against.
* @return the nri if one exists, null otherwise.
*/
@Nullable
private NetworkRequestInfo getNriForAppRequest(@NonNull final NetworkRequest nr) {
for (final NetworkRequestInfo nri : mNetworkRequests.values()) {
if (nri.getNetworkRequestForCallback().equals(nr)) {
return nri;
}
}
return null;
}
/**
* Check if an nri is currently being managed by per-app default networking.
* @param nri the nri to check.
* @return true if this nri is currently being managed by per-app default networking.
*/
private boolean isPerAppTrackedNri(@NonNull final NetworkRequestInfo nri) {
// nri.mRequests.get(0) is only different from the original request filed in
// nri.getNetworkRequestForCallback() if nri.mRequests was changed by per-app default
// functionality therefore if these two don't match, it means this particular nri is
// currently being managed by a per-app default.
return nri.getNetworkRequestForCallback() != nri.mRequests.get(0);
}
/**
* Determine if an nri is a managed default request that disallows default networking.
* @param nri the request to evaluate
* @return true if device-default networking is disallowed
*/
private boolean isDefaultBlocked(@NonNull final NetworkRequestInfo nri) {
// Check if this nri is a managed default that supports the default network at its
// lowest priority request.
final NetworkRequest defaultNetworkRequest = mDefaultRequest.mRequests.get(0);
final NetworkCapabilities lowestPriorityNetCap =
nri.mRequests.get(nri.mRequests.size() - 1).networkCapabilities;
return isPerAppDefaultRequest(nri)
&& !(defaultNetworkRequest.networkCapabilities.equalRequestableCapabilities(
lowestPriorityNetCap));
}
// Request used to optionally keep mobile data active even when higher
// priority networks like Wi-Fi are active.
private final NetworkRequest mDefaultMobileDataRequest;
// Request used to optionally keep wifi data active even when higher
// priority networks like ethernet are active.
private final NetworkRequest mDefaultWifiRequest;
// Request used to optionally keep vehicle internal network always active
private final NetworkRequest mDefaultVehicleRequest;
// Sentinel NAI used to direct apps with default networks that should have no connectivity to a
// network with no service. This NAI should never be matched against, nor should any public API
// ever return the associated network. For this reason, this NAI is not in the list of available
// NAIs. It is used in computeNetworkReassignment() to be set as the satisfier for non-device
// default requests that don't support using the device default network which will ultimately
// allow ConnectivityService to use this no-service network when calling makeDefaultForApps().
@VisibleForTesting
final NetworkAgentInfo mNoServiceNetwork;
// The NetworkAgentInfo currently satisfying the default request, if any.
private NetworkAgentInfo getDefaultNetwork() {
return mDefaultRequest.mSatisfier;
}
private NetworkAgentInfo getDefaultNetworkForUid(final int uid) {
NetworkRequestInfo highestPriorityNri = mDefaultRequest;
for (final NetworkRequestInfo nri : mDefaultNetworkRequests) {
// Currently, all network requests will have the same uids therefore checking the first
// one is sufficient. If/when uids are tracked at the nri level, this can change.
final Set<UidRange> uids = nri.mRequests.get(0).networkCapabilities.getUidRanges();
if (null == uids) {
continue;
}
for (final UidRange range : uids) {
if (range.contains(uid)) {
if (nri.hasHigherOrderThan(highestPriorityNri)) {
highestPriorityNri = nri;
}
}
}
}
if (!highestPriorityNri.isBeingSatisfied()) return null;
return highestPriorityNri.getSatisfier();
}
@Nullable
private Network getNetwork(@Nullable NetworkAgentInfo nai) {
return nai != null ? nai.network : null;
}
private void ensureRunningOnConnectivityServiceThread() {
if (mHandler.getLooper().getThread() != Thread.currentThread()) {
throw new IllegalStateException(
"Not running on ConnectivityService thread: "
+ Thread.currentThread().getName());
}
}
@VisibleForTesting
protected boolean isDefaultNetwork(NetworkAgentInfo nai) {
return nai == getDefaultNetwork();
}
/**
* Returns whether local agents are supported on this device.
*
* Local agents are supported from U on TVs, and from V on all devices.
*/
@VisibleForTesting
public boolean areLocalAgentsSupported() {
final PackageManager pm = mContext.getPackageManager();
// Local agents are supported starting on U on TVs and on V on everything else.
return mDeps.isAtLeastV() || (mDeps.isAtLeastU() && pm.hasSystemFeature(FEATURE_LEANBACK));
}
/**
* Register a new agent with ConnectivityService to handle a network.
*
* @param na a reference for ConnectivityService to contact the agent asynchronously.
* @param networkInfo the initial info associated with this network. It can be updated later :
* see {@link #updateNetworkInfo}.
* @param linkProperties the initial link properties of this network. They can be updated
* later : see {@link #updateLinkProperties}.
* @param networkCapabilities the initial capabilites of this network. They can be updated
* later : see {@link #updateCapabilities}.
* @param initialScore the initial score of the network. See {@link NetworkAgentInfo#getScore}.
* @param localNetworkConfig config about this local network, or null if not a local network
* @param networkAgentConfig metadata about the network. This is never updated.
* @param providerId the ID of the provider owning this NetworkAgent.
* @return the network created for this agent.
*/
public Network registerNetworkAgent(INetworkAgent na,
NetworkInfo networkInfo,
LinkProperties linkProperties,
NetworkCapabilities networkCapabilities,
@NonNull NetworkScore initialScore,
@Nullable LocalNetworkConfig localNetworkConfig,
NetworkAgentConfig networkAgentConfig,
int providerId) {
Objects.requireNonNull(networkInfo, "networkInfo must not be null");
Objects.requireNonNull(linkProperties, "linkProperties must not be null");
Objects.requireNonNull(networkCapabilities, "networkCapabilities must not be null");
Objects.requireNonNull(initialScore, "initialScore must not be null");
Objects.requireNonNull(networkAgentConfig, "networkAgentConfig must not be null");
if (networkCapabilities.hasTransport(TRANSPORT_TEST)) {
enforceAnyPermissionOf(mContext, Manifest.permission.MANAGE_TEST_NETWORKS);
} else {
enforceNetworkFactoryPermission();
}
final boolean hasLocalCap =
networkCapabilities.hasCapability(NET_CAPABILITY_LOCAL_NETWORK);
if (hasLocalCap && !areLocalAgentsSupported()) {
// Before U, netd doesn't support PHYSICAL_LOCAL networks so this can't work.
throw new IllegalArgumentException("Local agents are not supported in this version");
}
final boolean hasLocalNetworkConfig = null != localNetworkConfig;
if (hasLocalCap != hasLocalNetworkConfig) {
throw new IllegalArgumentException(null != localNetworkConfig
? "Only local network agents can have a LocalNetworkConfig"
: "Local network agents must have a LocalNetworkConfig"
);
}
final int uid = mDeps.getCallingUid();
final long token = Binder.clearCallingIdentity();
try {
return registerNetworkAgentInternal(na, networkInfo, linkProperties,
networkCapabilities, initialScore, networkAgentConfig, localNetworkConfig,
providerId, uid);
} finally {
Binder.restoreCallingIdentity(token);
}
}
private Network registerNetworkAgentInternal(INetworkAgent na, NetworkInfo networkInfo,
LinkProperties linkProperties, NetworkCapabilities networkCapabilities,
NetworkScore currentScore, NetworkAgentConfig networkAgentConfig,
@Nullable LocalNetworkConfig localNetworkConfig, int providerId,
int uid) {
// Make a copy of the passed NI, LP, NC as the caller may hold a reference to them
// and mutate them at any time.
final NetworkInfo niCopy = new NetworkInfo(networkInfo);
final NetworkCapabilities ncCopy = new NetworkCapabilities(networkCapabilities);
final LinkProperties lpCopy = new LinkProperties(linkProperties);
// No need to copy |localNetworkConfiguration| as it is immutable.
// At this point the capabilities/properties are untrusted and unverified, e.g. checks that
// the capabilities' access UIDs comply with security limitations. They will be sanitized
// as the NAI registration finishes, in handleRegisterNetworkAgent(). This is
// because some of the checks must happen on the handler thread.
final NetworkAgentInfo nai = new NetworkAgentInfo(na,
new Network(mNetIdManager.reserveNetId()), niCopy, lpCopy, ncCopy,
localNetworkConfig, currentScore, mContext, mTrackerHandler,
new NetworkAgentConfig(networkAgentConfig), this, mNetd, mDnsResolver, providerId,
uid, mLingerDelayMs, mQosCallbackTracker, mDeps);
final String extraInfo = niCopy.getExtraInfo();
final String name = TextUtils.isEmpty(extraInfo)
? nai.networkCapabilities.getSsid() : extraInfo;
if (DBG) log("registerNetworkAgent " + nai);
mDeps.getNetworkStack().makeNetworkMonitor(
nai.network, name, new NetworkMonitorCallbacks(nai));
// NetworkAgentInfo registration will finish when the NetworkMonitor is created.
// If the network disconnects or sends any other event before that, messages are deferred by
// NetworkAgent until nai.connect(), which will be called when finalizing the
// registration.
return nai.network;
}
private void handleRegisterNetworkAgent(NetworkAgentInfo nai, INetworkMonitor networkMonitor) {
if (VDBG) log("Network Monitor created for " + nai);
// Store a copy of the declared capabilities.
nai.setDeclaredCapabilities(nai.networkCapabilities);
// Make sure the LinkProperties and NetworkCapabilities reflect what the agent info said.
nai.getAndSetNetworkCapabilities(mixInCapabilities(nai,
nai.getDeclaredCapabilitiesSanitized(mCarrierPrivilegeAuthenticator)));
processLinkPropertiesFromAgent(nai, nai.linkProperties);
nai.onNetworkMonitorCreated(networkMonitor);
mNetworkAgentInfos.add(nai);
synchronized (mNetworkForNetId) {
mNetworkForNetId.put(nai.network.getNetId(), nai);
}
try {
networkMonitor.start();
} catch (RemoteException e) {
e.rethrowAsRuntimeException();
}
if (nai.isLocalNetwork()) {
handleUpdateLocalNetworkConfig(nai, null /* oldConfig */, nai.localNetworkConfig);
}
nai.notifyRegistered();
NetworkInfo networkInfo = nai.networkInfo;
updateNetworkInfo(nai, networkInfo);
updateVpnUids(nai, null, nai.networkCapabilities);
}
private class NetworkOfferInfo implements IBinder.DeathRecipient {
@NonNull public final NetworkOffer offer;
NetworkOfferInfo(@NonNull final NetworkOffer offer) {
this.offer = offer;
}
@Override
public void binderDied() {
mHandler.post(() -> handleUnregisterNetworkOffer(this));
}
}
private boolean isNetworkProviderWithIdRegistered(final int providerId) {
for (final NetworkProviderInfo npi : mNetworkProviderInfos.values()) {
if (npi.providerId == providerId) return true;
}
return false;
}
/**
* Register or update a network offer.
* @param newOffer The new offer. If the callback member is the same as an existing
* offer, it is an update of that offer.
*/
// TODO : rename this to handleRegisterOrUpdateNetworkOffer
private void handleRegisterNetworkOffer(@NonNull final NetworkOffer newOffer) {
ensureRunningOnConnectivityServiceThread();
if (!isNetworkProviderWithIdRegistered(newOffer.providerId)) {
// This may actually happen if a provider updates its score or registers and then
// immediately unregisters. The offer would still be in the handler queue, but the
// provider would have been removed.
if (DBG) log("Received offer from an unregistered provider");
return;
}
final NetworkOfferInfo existingOffer = findNetworkOfferInfoByCallback(newOffer.callback);
if (null != existingOffer) {
handleUnregisterNetworkOffer(existingOffer);
newOffer.migrateFrom(existingOffer.offer);
if (DBG) {
// handleUnregisterNetworkOffer has already logged the old offer
log("update offer from providerId " + newOffer.providerId + " new : " + newOffer);
}
} else {
if (DBG) {
log("register offer from providerId " + newOffer.providerId + " : " + newOffer);
}
}
final NetworkOfferInfo noi = new NetworkOfferInfo(newOffer);
try {
noi.offer.callback.asBinder().linkToDeath(noi, 0 /* flags */);
} catch (RemoteException e) {
noi.binderDied();
return;
}
mNetworkOffers.add(noi);
issueNetworkNeeds(noi);
}
private void handleUnregisterNetworkOffer(@NonNull final NetworkOfferInfo noi) {
ensureRunningOnConnectivityServiceThread();
if (DBG) {
log("unregister offer from providerId " + noi.offer.providerId + " : " + noi.offer);
}
// If the provider removes the offer and dies immediately afterwards this
// function may be called twice in a row, but the array will no longer contain
// the offer.
if (!mNetworkOffers.remove(noi)) return;
noi.offer.callback.asBinder().unlinkToDeath(noi, 0 /* flags */);
}
@Nullable private NetworkOfferInfo findNetworkOfferInfoByCallback(
@NonNull final INetworkOfferCallback callback) {
ensureRunningOnConnectivityServiceThread();
for (final NetworkOfferInfo noi : mNetworkOffers) {
if (noi.offer.callback.asBinder().equals(callback.asBinder())) return noi;
}
return null;
}
/**
* Called when receiving LinkProperties directly from a NetworkAgent.
* Stores into |nai| any data coming from the agent that might also be written to the network's
* LinkProperties by ConnectivityService itself. This ensures that the data provided by the
* agent is not lost when updateLinkProperties is called.
* This method should never alter the agent's LinkProperties, only store data in |nai|.
*/
private void processLinkPropertiesFromAgent(NetworkAgentInfo nai, LinkProperties lp) {
lp.ensureDirectlyConnectedRoutes();
nai.clatd.setNat64PrefixFromRa(lp.getNat64Prefix());
nai.networkAgentPortalData = lp.getCaptivePortalData();
}
private void updateLinkProperties(NetworkAgentInfo networkAgent, @NonNull LinkProperties newLp,
@Nullable LinkProperties oldLp) {
int netId = networkAgent.network.getNetId();
// The NetworkAgent does not know whether clatd is running on its network or not, or whether
// a NAT64 prefix was discovered by the DNS resolver. Before we do anything else, make sure
// the LinkProperties for the network are accurate.
networkAgent.clatd.fixupLinkProperties(oldLp, newLp);
updateInterfaces(newLp, oldLp, netId, networkAgent);
// update filtering rules, need to happen after the interface update so netd knows about the
// new interface (the interface name -> index map becomes initialized)
updateVpnFiltering(newLp, oldLp, networkAgent);
updateMtu(newLp, oldLp);
// TODO - figure out what to do for clat
// for (LinkProperties lp : newLp.getStackedLinks()) {
// updateMtu(lp, null);
// }
if (isDefaultNetwork(networkAgent)) {
mProxyTracker.updateDefaultNetworkProxyPortForPAC(newLp, null);
updateTcpBufferSizes(newLp.getTcpBufferSizes());
}
updateRoutes(newLp, oldLp, netId);
updateDnses(newLp, oldLp, netId);
// Make sure LinkProperties represents the latest private DNS status.
// This does not need to be done before updateDnses because the
// LinkProperties are not the source of the private DNS configuration.
// updateDnses will fetch the private DNS configuration from DnsManager.
mDnsManager.updatePrivateDnsStatus(netId, newLp);
if (isDefaultNetwork(networkAgent)) {
mProxyTracker.setDefaultProxy(newLp.getHttpProxy());
} else if (networkAgent.everConnected()) {
updateProxy(newLp, oldLp);
}
updateWakeOnLan(newLp);
// Captive portal data is obtained from NetworkMonitor and stored in NetworkAgentInfo.
// It is not always contained in the LinkProperties sent from NetworkAgents, and if it
// does, it needs to be merged here.
newLp.setCaptivePortalData(mergeCaptivePortalData(networkAgent.networkAgentPortalData,
networkAgent.capportApiData));
// TODO - move this check to cover the whole function
if (!Objects.equals(newLp, oldLp)) {
synchronized (networkAgent) {
networkAgent.linkProperties = newLp;
}
// Start or stop DNS64 detection and 464xlat according to network state.
networkAgent.clatd.update();
// Notify NSS when relevant events happened. Currently, NSS only cares about
// interface changed to update clat interfaces accounting.
final boolean interfacesChanged = oldLp == null
|| !Objects.equals(newLp.getAllInterfaceNames(), oldLp.getAllInterfaceNames());
if (interfacesChanged) {
notifyIfacesChangedForNetworkStats();
}
networkAgent.networkMonitor().notifyLinkPropertiesChanged(
new LinkProperties(newLp, true /* parcelSensitiveFields */));
notifyNetworkCallbacks(networkAgent, ConnectivityManager.CALLBACK_IP_CHANGED);
}
mKeepaliveTracker.handleCheckKeepalivesStillValid(networkAgent);
}
private void applyInitialLinkProperties(@NonNull NetworkAgentInfo nai) {
updateLinkProperties(nai, new LinkProperties(nai.linkProperties), null);
}
/**
* @param naData captive portal data from NetworkAgent
* @param apiData captive portal data from capport API
*/
@Nullable
private CaptivePortalData mergeCaptivePortalData(CaptivePortalData naData,
CaptivePortalData apiData) {
if (naData == null || apiData == null) {
return naData == null ? apiData : naData;
}
final CaptivePortalData.Builder captivePortalBuilder =
new CaptivePortalData.Builder(naData);
if (apiData.isCaptive()) {
captivePortalBuilder.setCaptive(true);
}
if (apiData.isSessionExtendable()) {
captivePortalBuilder.setSessionExtendable(true);
}
if (apiData.getExpiryTimeMillis() >= 0 || apiData.getByteLimit() >= 0) {
// Expiry time, bytes remaining, refresh time all need to come from the same source,
// otherwise data would be inconsistent. Prefer the capport API info if present,
// as it can generally be refreshed more often.
captivePortalBuilder.setExpiryTime(apiData.getExpiryTimeMillis());
captivePortalBuilder.setBytesRemaining(apiData.getByteLimit());
captivePortalBuilder.setRefreshTime(apiData.getRefreshTimeMillis());
} else if (naData.getExpiryTimeMillis() < 0 && naData.getByteLimit() < 0) {
// No source has time / bytes remaining information: surface the newest refresh time
// for other fields
captivePortalBuilder.setRefreshTime(
Math.max(naData.getRefreshTimeMillis(), apiData.getRefreshTimeMillis()));
}
// Prioritize the user portal URL from the network agent if the source is authenticated.
if (apiData.getUserPortalUrl() != null && naData.getUserPortalUrlSource()
!= CaptivePortalData.CAPTIVE_PORTAL_DATA_SOURCE_PASSPOINT) {
captivePortalBuilder.setUserPortalUrl(apiData.getUserPortalUrl(),
apiData.getUserPortalUrlSource());
}
// Prioritize the venue information URL from the network agent if the source is
// authenticated.
if (apiData.getVenueInfoUrl() != null && naData.getVenueInfoUrlSource()
!= CaptivePortalData.CAPTIVE_PORTAL_DATA_SOURCE_PASSPOINT) {
captivePortalBuilder.setVenueInfoUrl(apiData.getVenueInfoUrl(),
apiData.getVenueInfoUrlSource());
}
return captivePortalBuilder.build();
}
@VisibleForTesting
static String makeNflogPrefix(String iface, long networkHandle) {
// This needs to be kept in sync and backwards compatible with the decoding logic in
// NetdEventListenerService, which is non-mainline code.
return SdkLevel.isAtLeastU() ? (networkHandle + ":" + iface) : ("iface:" + iface);
}
private static boolean isWakeupMarkingSupported(NetworkCapabilities capabilities) {
if (capabilities.hasTransport(TRANSPORT_WIFI)) {
return true;
}
if (SdkLevel.isAtLeastU() && capabilities.hasTransport(TRANSPORT_CELLULAR)) {
return true;
}
return false;
}
private void wakeupModifyInterface(String iface, NetworkAgentInfo nai, boolean add) {
// Marks are only available on WiFi interfaces. Checking for
// marks on unsupported interfaces is harmless.
if (!isWakeupMarkingSupported(nai.networkCapabilities)) {
return;
}
// Mask/mark of zero will not detect anything interesting.
// Don't install rules unless both values are nonzero.
if (mWakeUpMark == 0 || mWakeUpMask == 0) {
return;
}
final String prefix = makeNflogPrefix(iface, nai.network.getNetworkHandle());
try {
if (add) {
mNetd.wakeupAddInterface(iface, prefix, mWakeUpMark, mWakeUpMask);
} else {
mNetd.wakeupDelInterface(iface, prefix, mWakeUpMark, mWakeUpMask);
}
} catch (Exception e) {
loge("Exception modifying wakeup packet monitoring: " + e);
}
}
private void updateInterfaces(final @NonNull LinkProperties newLp,
final @Nullable LinkProperties oldLp, final int netId,
final @NonNull NetworkAgentInfo nai) {
final CompareResult<String> interfaceDiff = new CompareResult<>(
oldLp != null ? oldLp.getAllInterfaceNames() : null, newLp.getAllInterfaceNames());
if (!interfaceDiff.added.isEmpty()) {
for (final String iface : interfaceDiff.added) {
try {
if (DBG) log("Adding iface " + iface + " to network " + netId);
mRoutingCoordinatorService.addInterfaceToNetwork(netId, iface);
wakeupModifyInterface(iface, nai, true);
mDeps.reportNetworkInterfaceForTransports(mContext, iface,
nai.networkCapabilities.getTransportTypes());
} catch (Exception e) {
logw("Exception adding interface: " + e);
}
}
}
for (final String iface : interfaceDiff.removed) {
try {
if (DBG) log("Removing iface " + iface + " from network " + netId);
wakeupModifyInterface(iface, nai, false);
mRoutingCoordinatorService.removeInterfaceFromNetwork(netId, iface);
} catch (Exception e) {
loge("Exception removing interface: " + e);
}
}
}
/**
* Have netd update routes from oldLp to newLp.
* @return true if routes changed between oldLp and newLp
*/
private boolean updateRoutes(@NonNull LinkProperties newLp, @Nullable LinkProperties oldLp,
int netId) {
// compare the route diff to determine which routes have been updated
final CompareOrUpdateResult<RouteInfo.RouteKey, RouteInfo> routeDiff =
new CompareOrUpdateResult<>(
oldLp != null ? oldLp.getAllRoutes() : null,
newLp.getAllRoutes(),
(r) -> r.getRouteKey());
// add routes before removing old in case it helps with continuous connectivity
// do this twice, adding non-next-hop routes first, then routes they are dependent on
for (RouteInfo route : routeDiff.added) {
if (route.hasGateway()) continue;
if (VDBG || DDBG) log("Adding Route [" + route + "] to network " + netId);
try {
mRoutingCoordinatorService.addRoute(netId, route);
} catch (Exception e) {
if ((route.getDestination().getAddress() instanceof Inet4Address) || VDBG) {
loge("Exception in addRoute for non-gateway: " + e);
}
}
}
for (RouteInfo route : routeDiff.added) {
if (!route.hasGateway()) continue;
if (VDBG || DDBG) log("Adding Route [" + route + "] to network " + netId);
try {
mRoutingCoordinatorService.addRoute(netId, route);
} catch (Exception e) {
if ((route.getGateway() instanceof Inet4Address) || VDBG) {
loge("Exception in addRoute for gateway: " + e);
}
}
}
for (RouteInfo route : routeDiff.removed) {
if (VDBG || DDBG) log("Removing Route [" + route + "] from network " + netId);
try {
mRoutingCoordinatorService.removeRoute(netId, route);
} catch (Exception e) {
loge("Exception in removeRoute: " + e);
}
}
for (RouteInfo route : routeDiff.updated) {
if (VDBG || DDBG) log("Updating Route [" + route + "] from network " + netId);
try {
mRoutingCoordinatorService.updateRoute(netId, route);
} catch (Exception e) {
loge("Exception in updateRoute: " + e);
}
}
return !routeDiff.added.isEmpty() || !routeDiff.removed.isEmpty()
|| !routeDiff.updated.isEmpty();
}
private void updateDnses(@NonNull LinkProperties newLp, @Nullable LinkProperties oldLp,
int netId) {
if (oldLp != null && newLp.isIdenticalDnses(oldLp)) {
return; // no updating necessary
}
if (DBG) {
final Collection<InetAddress> dnses = newLp.getDnsServers();
log("Setting DNS servers for network " + netId + " to " + dnses);
}
try {
mDnsManager.noteDnsServersForNetwork(netId, newLp);
mDnsManager.flushVmDnsCache();
} catch (Exception e) {
loge("Exception in setDnsConfigurationForNetwork: " + e);
}
}
private void updateVpnFiltering(@NonNull LinkProperties newLp, @Nullable LinkProperties oldLp,
@NonNull NetworkAgentInfo nai) {
final String oldIface = getVpnIsolationInterface(nai, nai.networkCapabilities, oldLp);
final String newIface = getVpnIsolationInterface(nai, nai.networkCapabilities, newLp);
final boolean wasFiltering = requiresVpnAllowRule(nai, oldLp, oldIface);
final boolean needsFiltering = requiresVpnAllowRule(nai, newLp, newIface);
if (!wasFiltering && !needsFiltering) {
// Nothing to do.
return;
}
if (Objects.equals(oldIface, newIface) && (wasFiltering == needsFiltering)) {
// Nothing changed.
return;
}
final Set<UidRange> ranges = nai.networkCapabilities.getUidRanges();
if (ranges == null || ranges.isEmpty()) {
return;
}
final int vpnAppUid = nai.networkCapabilities.getOwnerUid();
// TODO: this create a window of opportunity for apps to receive traffic between the time
// when the old rules are removed and the time when new rules are added. To fix this,
// make eBPF support two allowlisted interfaces so here new rules can be added before the
// old rules are being removed.
if (wasFiltering) {
mPermissionMonitor.onVpnUidRangesRemoved(oldIface, ranges, vpnAppUid);
}
if (needsFiltering) {
mPermissionMonitor.onVpnUidRangesAdded(newIface, ranges, vpnAppUid);
}
}
private void updateWakeOnLan(@NonNull LinkProperties lp) {
if (mWolSupportedInterfaces == null) {
mWolSupportedInterfaces = new ArraySet<>(mResources.get().getStringArray(
R.array.config_wakeonlan_supported_interfaces));
}
lp.setWakeOnLanSupported(mWolSupportedInterfaces.contains(lp.getInterfaceName()));
}
private int getNetworkPermission(NetworkCapabilities nc) {
if (!nc.hasCapability(NET_CAPABILITY_NOT_RESTRICTED)) {
return INetd.PERMISSION_SYSTEM;
}
if (!nc.hasCapability(NET_CAPABILITY_FOREGROUND)) {
return INetd.PERMISSION_NETWORK;
}
return INetd.PERMISSION_NONE;
}
private void updateNetworkPermissions(@NonNull final NetworkAgentInfo nai,
@NonNull final NetworkCapabilities newNc) {
final int oldPermission = getNetworkPermission(nai.networkCapabilities);
final int newPermission = getNetworkPermission(newNc);
if (oldPermission != newPermission && nai.isCreated() && !nai.isVPN()) {
try {
mNetd.networkSetPermissionForNetwork(nai.network.getNetId(), newPermission);
} catch (RemoteException | ServiceSpecificException e) {
loge("Exception in networkSetPermissionForNetwork: " + e);
}
}
}
/** Modifies |newNc| based on the capabilities of |underlyingNetworks| and |agentCaps|. */
@VisibleForTesting
void applyUnderlyingCapabilities(@Nullable Network[] underlyingNetworks,
@NonNull NetworkCapabilities agentCaps, @NonNull NetworkCapabilities newNc) {
underlyingNetworks = underlyingNetworksOrDefault(
agentCaps.getOwnerUid(), underlyingNetworks);
long transportTypes = BitUtils.packBits(agentCaps.getTransportTypes());
int downKbps = NetworkCapabilities.LINK_BANDWIDTH_UNSPECIFIED;
int upKbps = NetworkCapabilities.LINK_BANDWIDTH_UNSPECIFIED;
// metered if any underlying is metered, or originally declared metered by the agent.
boolean metered = !agentCaps.hasCapability(NET_CAPABILITY_NOT_METERED);
boolean roaming = false; // roaming if any underlying is roaming
boolean congested = false; // congested if any underlying is congested
boolean suspended = true; // suspended if all underlying are suspended
boolean hadUnderlyingNetworks = false;
ArrayList<Network> newUnderlyingNetworks = null;
if (null != underlyingNetworks) {
newUnderlyingNetworks = new ArrayList<>();
for (Network underlyingNetwork : underlyingNetworks) {
final NetworkAgentInfo underlying =
getNetworkAgentInfoForNetwork(underlyingNetwork);
if (underlying == null) continue;
final NetworkCapabilities underlyingCaps = underlying.networkCapabilities;
hadUnderlyingNetworks = true;
for (int underlyingType : underlyingCaps.getTransportTypes()) {
transportTypes |= 1L << underlyingType;
}
// Merge capabilities of this underlying network. For bandwidth, assume the
// worst case.
downKbps = NetworkCapabilities.minBandwidth(downKbps,
underlyingCaps.getLinkDownstreamBandwidthKbps());
upKbps = NetworkCapabilities.minBandwidth(upKbps,
underlyingCaps.getLinkUpstreamBandwidthKbps());
// If this underlying network is metered, the VPN is metered (it may cost money
// to send packets on this network).
metered |= !underlyingCaps.hasCapability(NET_CAPABILITY_NOT_METERED);
// If this underlying network is roaming, the VPN is roaming (the billing structure
// is different than the usual, local one).
roaming |= !underlyingCaps.hasCapability(NET_CAPABILITY_NOT_ROAMING);
// If this underlying network is congested, the VPN is congested (the current
// condition of the network affects the performance of this network).
congested |= !underlyingCaps.hasCapability(NET_CAPABILITY_NOT_CONGESTED);
// If this network is not suspended, the VPN is not suspended (the VPN
// is able to transfer some data).
suspended &= !underlyingCaps.hasCapability(NET_CAPABILITY_NOT_SUSPENDED);
newUnderlyingNetworks.add(underlyingNetwork);
}
}
if (!hadUnderlyingNetworks) {
// No idea what the underlying networks are; assume reasonable defaults
metered = true;
roaming = false;
congested = false;
suspended = false;
}
newNc.setTransportTypes(BitUtils.unpackBits(transportTypes));
newNc.setLinkDownstreamBandwidthKbps(downKbps);
newNc.setLinkUpstreamBandwidthKbps(upKbps);
newNc.setCapability(NET_CAPABILITY_NOT_METERED, !metered);
newNc.setCapability(NET_CAPABILITY_NOT_ROAMING, !roaming);
newNc.setCapability(NET_CAPABILITY_NOT_CONGESTED, !congested);
newNc.setCapability(NET_CAPABILITY_NOT_SUSPENDED, !suspended);
newNc.setUnderlyingNetworks(newUnderlyingNetworks);
}
/**
* Augments the NetworkCapabilities passed in by a NetworkAgent with capabilities that are
* maintained here that the NetworkAgent is not aware of (e.g., validated, captive portal,
* and foreground status).
*/
@NonNull
private NetworkCapabilities mixInCapabilities(NetworkAgentInfo nai, NetworkCapabilities nc) {
// Once a NetworkAgent is connected, complain if some immutable capabilities are removed.
// Don't complain for VPNs since they're not driven by requests and there is no risk of
// causing a connect/teardown loop.
// TODO: remove this altogether and make it the responsibility of the NetworkProviders to
// avoid connect/teardown loops.
if (nai.everConnected()
&& !nai.isVPN()
&& !nai.networkCapabilities.satisfiedByImmutableNetworkCapabilities(nc)) {
// TODO: consider not complaining when a network agent degrades its capabilities if this
// does not cause any request (that is not a listen) currently matching that agent to
// stop being matched by the updated agent.
String diff = nai.networkCapabilities.describeImmutableDifferences(nc);
if (!TextUtils.isEmpty(diff)) {
Log.wtf(TAG, "BUG: " + nai + " lost immutable capabilities:" + diff);
}
}
// Don't modify caller's NetworkCapabilities.
final NetworkCapabilities newNc = new NetworkCapabilities(nc);
if (nai.isValidated()) {
newNc.addCapability(NET_CAPABILITY_VALIDATED);
} else {
newNc.removeCapability(NET_CAPABILITY_VALIDATED);
}
if (nai.captivePortalDetected()) {
newNc.addCapability(NET_CAPABILITY_CAPTIVE_PORTAL);
} else {
newNc.removeCapability(NET_CAPABILITY_CAPTIVE_PORTAL);
}
if (nai.isBackgroundNetwork()) {
newNc.removeCapability(NET_CAPABILITY_FOREGROUND);
} else {
newNc.addCapability(NET_CAPABILITY_FOREGROUND);
}
if (nai.partialConnectivity()) {
newNc.addCapability(NET_CAPABILITY_PARTIAL_CONNECTIVITY);
} else {
newNc.removeCapability(NET_CAPABILITY_PARTIAL_CONNECTIVITY);
}
newNc.setPrivateDnsBroken(nai.networkCapabilities.isPrivateDnsBroken());
// TODO : remove this once all factories are updated to send NOT_SUSPENDED and NOT_ROAMING
if (!newNc.hasTransport(TRANSPORT_CELLULAR)) {
newNc.addCapability(NET_CAPABILITY_NOT_SUSPENDED);
newNc.addCapability(NET_CAPABILITY_NOT_ROAMING);
}
if (nai.propagateUnderlyingCapabilities()) {
applyUnderlyingCapabilities(nai.declaredUnderlyingNetworks,
nai.getDeclaredCapabilitiesSanitized(mCarrierPrivilegeAuthenticator),
newNc);
}
return newNc;
}
private void updateNetworkInfoForRoamingAndSuspended(NetworkAgentInfo nai,
NetworkCapabilities prevNc, NetworkCapabilities newNc) {
final boolean prevSuspended = !prevNc.hasCapability(NET_CAPABILITY_NOT_SUSPENDED);
final boolean suspended = !newNc.hasCapability(NET_CAPABILITY_NOT_SUSPENDED);
final boolean prevRoaming = !prevNc.hasCapability(NET_CAPABILITY_NOT_ROAMING);
final boolean roaming = !newNc.hasCapability(NET_CAPABILITY_NOT_ROAMING);
if (prevSuspended != suspended) {
// TODO (b/73132094) : remove this call once the few users of onSuspended and
// onResumed have been removed.
notifyNetworkCallbacks(nai, suspended ? ConnectivityManager.CALLBACK_SUSPENDED
: ConnectivityManager.CALLBACK_RESUMED);
}
if (prevSuspended != suspended || prevRoaming != roaming) {
// updateNetworkInfo will mix in the suspended info from the capabilities and
// take appropriate action for the network having possibly changed state.
updateNetworkInfo(nai, nai.networkInfo);
}
}
/**
* Update the NetworkCapabilities for {@code nai} to {@code nc}. Specifically:
*
* 1. Calls mixInCapabilities to merge the passed-in NetworkCapabilities {@code nc} with the
* capabilities we manage and store in {@code nai}, such as validated status and captive
* portal status)
* 2. Takes action on the result: changes network permissions, sends CAP_CHANGED callbacks, and
* potentially triggers rematches.
* 3. Directly informs other network stack components (NetworkStatsService, VPNs, etc. of the
* change.)
*
* @param oldScore score of the network before any of the changes that prompted us
* to call this function.
* @param nai the network having its capabilities updated.
* @param nc the new network capabilities.
*/
private void updateCapabilities(final FullScore oldScore, @NonNull final NetworkAgentInfo nai,
@NonNull final NetworkCapabilities nc) {
NetworkCapabilities newNc = mixInCapabilities(nai, nc);
if (Objects.equals(nai.networkCapabilities, newNc)) return;
final String differences = newNc.describeCapsDifferencesFrom(nai.networkCapabilities);
if (null != differences) {
Log.i(TAG, "Update capabilities for net " + nai.network + " : " + differences);
}
updateNetworkPermissions(nai, newNc);
final NetworkCapabilities prevNc = nai.getAndSetNetworkCapabilities(newNc);
updateVpnUids(nai, prevNc, newNc);
updateAllowedUids(nai, prevNc, newNc);
nai.updateScoreForNetworkAgentUpdate();
if (nai.getScore().equals(oldScore) && newNc.equalRequestableCapabilities(prevNc)) {
// If the requestable capabilities haven't changed, and the score hasn't changed, then
// the change we're processing can't affect any requests, it can only affect the listens
// on this network. We might have been called by rematchNetworkAndRequests when a
// network changed foreground state.
processListenRequests(nai);
} else {
// If the requestable capabilities have changed or the score changed, we can't have been
// called by rematchNetworkAndRequests, so it's safe to start a rematch.
rematchAllNetworksAndRequests();
notifyNetworkCallbacks(nai, ConnectivityManager.CALLBACK_CAP_CHANGED);
}
updateNetworkInfoForRoamingAndSuspended(nai, prevNc, newNc);
final boolean oldMetered = prevNc.isMetered();
final boolean newMetered = newNc.isMetered();
final boolean meteredChanged = oldMetered != newMetered;
if (meteredChanged) {
maybeNotifyNetworkBlocked(nai, oldMetered, newMetered,
mVpnBlockedUidRanges, mVpnBlockedUidRanges);
}
final boolean roamingChanged = prevNc.hasCapability(NET_CAPABILITY_NOT_ROAMING)
!= newNc.hasCapability(NET_CAPABILITY_NOT_ROAMING);
// Report changes that are interesting for network statistics tracking.
if (meteredChanged || roamingChanged) {
notifyIfacesChangedForNetworkStats();
}
// This network might have been underlying another network. Propagate its capabilities.
propagateUnderlyingNetworkCapabilities(nai.network);
if (meteredChanged || !newNc.equalsTransportTypes(prevNc)) {
mDnsManager.updateCapabilitiesForNetwork(nai.network.getNetId(), newNc);
}
maybeSendProxyBroadcast(nai, prevNc, newNc);
}
/** Convenience method to update the capabilities for a given network. */
private void updateCapabilitiesForNetwork(NetworkAgentInfo nai) {
updateCapabilities(nai.getScore(), nai, nai.networkCapabilities);
}
// oldConfig is null iff this is the original registration of the local network config
private void handleUpdateLocalNetworkConfig(@NonNull final NetworkAgentInfo nai,
@Nullable final LocalNetworkConfig oldConfig,
@NonNull final LocalNetworkConfig newConfig) {
if (!nai.isLocalNetwork()) {
Log.wtf(TAG, "Ignoring update of a local network info on non-local network " + nai);
return;
}
if (VDBG) {
Log.v(TAG, "Update local network config " + nai.network.netId + " : " + newConfig);
}
final LocalNetworkConfig.Builder configBuilder = new LocalNetworkConfig.Builder();
// TODO : apply the diff for multicast routing.
configBuilder.setUpstreamMulticastRoutingConfig(
newConfig.getUpstreamMulticastRoutingConfig());
configBuilder.setDownstreamMulticastRoutingConfig(
newConfig.getDownstreamMulticastRoutingConfig());
final NetworkRequest oldRequest =
(null == oldConfig) ? null : oldConfig.getUpstreamSelector();
final NetworkCapabilities oldCaps =
(null == oldRequest) ? null : oldRequest.networkCapabilities;
final NetworkRequestInfo oldNri =
null == oldRequest ? null : mNetworkRequests.get(oldRequest);
final NetworkAgentInfo oldSatisfier =
null == oldNri ? null : oldNri.getSatisfier();
final NetworkRequest newRequest = newConfig.getUpstreamSelector();
final NetworkCapabilities newCaps =
(null == newRequest) ? null : newRequest.networkCapabilities;
final boolean requestUpdated = !Objects.equals(newCaps, oldCaps);
if (null != oldRequest && requestUpdated) {
handleRemoveNetworkRequest(mNetworkRequests.get(oldRequest));
if (null == newRequest && null != oldSatisfier) {
// If there is an old satisfier, but no new request, then remove the old upstream.
removeLocalNetworkUpstream(nai, oldSatisfier);
nai.localNetworkConfig = configBuilder.build();
// When there is a new request, the rematch sees the new request and sends the
// LOCAL_NETWORK_INFO_CHANGED callbacks accordingly.
// But here there is no new request, so the rematch won't see anything. Send
// callbacks to apps now to tell them about the loss of upstream.
notifyNetworkCallbacks(nai,
ConnectivityManager.CALLBACK_LOCAL_NETWORK_INFO_CHANGED);
return;
}
}
if (null != newRequest && requestUpdated) {
// File the new request if :
// - it has changed (requestUpdated), or
// - it's the first time this local info (null == oldConfig)
// is updated and the request has not been filed yet.
// Requests for local info are always LISTEN_FOR_BEST, because they have at most one
// upstream (the best) but never request it to be brought up.
final NetworkRequest nr = new NetworkRequest(newCaps, ConnectivityManager.TYPE_NONE,
nextNetworkRequestId(), LISTEN_FOR_BEST);
configBuilder.setUpstreamSelector(nr);
final NetworkRequestInfo nri = new NetworkRequestInfo(
nai.creatorUid, nr, null /* messenger */, null /* binder */,
0 /* callbackFlags */, null /* attributionTag */);
if (null != oldSatisfier) {
// Set the old satisfier in the new NRI so that the rematch will see any changes
nri.setSatisfier(oldSatisfier, nr);
}
nai.localNetworkConfig = configBuilder.build();
// handleRegisterNetworkRequest causes a rematch. The rematch must happen after
// nai.localNetworkConfig is set, since it will base its callbacks on the old
// satisfier and the new request.
handleRegisterNetworkRequest(nri);
} else {
configBuilder.setUpstreamSelector(oldRequest);
nai.localNetworkConfig = configBuilder.build();
}
}
/**
* Returns the interface which requires VPN isolation (ingress interface filtering).
*
* Ingress interface filtering enforces that all apps under the given network can only receive
* packets from the network's interface (and loopback). This is important for VPNs because
* apps that cannot bypass a fully-routed VPN shouldn't be able to receive packets from any
* non-VPN interfaces.
*
* As a result, this method should return Non-null interface iff
* 1. the network is an app VPN (not legacy VPN)
* 2. the VPN does not allow bypass
* 3. the VPN is fully-routed
* 4. the VPN interface is non-null
*
* @see INetd#firewallAddUidInterfaceRules
* @see INetd#firewallRemoveUidInterfaceRules
*/
@Nullable
private String getVpnIsolationInterface(@NonNull NetworkAgentInfo nai, NetworkCapabilities nc,
LinkProperties lp) {
if (nc == null || lp == null) return null;
if (nai.isVPN()
&& !nai.networkAgentConfig.allowBypass
&& nc.getOwnerUid() != Process.SYSTEM_UID
&& lp.getInterfaceName() != null
&& (lp.hasIpv4DefaultRoute() || lp.hasIpv4UnreachableDefaultRoute())
&& (lp.hasIpv6DefaultRoute() || lp.hasIpv6UnreachableDefaultRoute())
&& !lp.hasExcludeRoute()) {
return lp.getInterfaceName();
}
return null;
}
/**
* Returns whether we need to set interface filtering rule or not
*/
private boolean requiresVpnAllowRule(NetworkAgentInfo nai, LinkProperties lp,
String isolationIface) {
// Allow rules are always needed if VPN isolation is enabled.
if (isolationIface != null) return true;
// On T and above, allow rules are needed for all VPNs. Allow rule with null iface is a
// wildcard to allow apps to receive packets on all interfaces. This is required to accept
// incoming traffic in Lockdown mode by overriding the Lockdown blocking rule.
return mDeps.isAtLeastT() && nai.isVPN() && lp != null && lp.getInterfaceName() != null;
}
private static UidRangeParcel[] toUidRangeStableParcels(final @NonNull Set<UidRange> ranges) {
final UidRangeParcel[] stableRanges = new UidRangeParcel[ranges.size()];
int index = 0;
for (UidRange range : ranges) {
stableRanges[index] = new UidRangeParcel(range.start, range.stop);
index++;
}
return stableRanges;
}
private static UidRangeParcel[] intsToUidRangeStableParcels(
final @NonNull ArraySet<Integer> uids) {
final UidRangeParcel[] stableRanges = new UidRangeParcel[uids.size()];
int index = 0;
for (int uid : uids) {
stableRanges[index] = new UidRangeParcel(uid, uid);
index++;
}
return stableRanges;
}
private static UidRangeParcel[] toUidRangeStableParcels(UidRange[] ranges) {
final UidRangeParcel[] stableRanges = new UidRangeParcel[ranges.length];
for (int i = 0; i < ranges.length; i++) {
stableRanges[i] = new UidRangeParcel(ranges[i].start, ranges[i].stop);
}
return stableRanges;
}
private void maybeCloseSockets(NetworkAgentInfo nai, Set<UidRange> ranges,
UidRangeParcel[] uidRangeParcels, int[] exemptUids) {
if (nai.isVPN() && !nai.networkAgentConfig.allowBypass) {
try {
if (mDeps.isAtLeastU()) {
final Set<Integer> exemptUidSet = new ArraySet<>();
for (final int uid: exemptUids) {
exemptUidSet.add(uid);
}
mDeps.destroyLiveTcpSockets(UidRange.toIntRanges(ranges), exemptUidSet);
} else {
mNetd.socketDestroy(uidRangeParcels, exemptUids);
}
} catch (Exception e) {
loge("Exception in socket destroy: ", e);
}
}
}
private void updateVpnUidRanges(boolean add, NetworkAgentInfo nai, Set<UidRange> uidRanges) {
int[] exemptUids = new int[2];
// TODO: Excluding VPN_UID is necessary in order to not to kill the TCP connection used
// by PPTP. Fix this by making Vpn set the owner UID to VPN_UID instead of system when
// starting a legacy VPN, and remove VPN_UID here. (b/176542831)
exemptUids[0] = VPN_UID;
exemptUids[1] = nai.networkCapabilities.getOwnerUid();
UidRangeParcel[] ranges = toUidRangeStableParcels(uidRanges);
// Close sockets before modifying uid ranges so that RST packets can reach to the server.
maybeCloseSockets(nai, uidRanges, ranges, exemptUids);
try {
if (add) {
mNetd.networkAddUidRangesParcel(new NativeUidRangeConfig(
nai.network.netId, ranges, PREFERENCE_ORDER_VPN));
} else {
mNetd.networkRemoveUidRangesParcel(new NativeUidRangeConfig(
nai.network.netId, ranges, PREFERENCE_ORDER_VPN));
}
} catch (Exception e) {
loge("Exception while " + (add ? "adding" : "removing") + " uid ranges " + uidRanges +
" on netId " + nai.network.netId + ". " + e);
}
// Close sockets that established connection while requesting netd.
maybeCloseSockets(nai, uidRanges, ranges, exemptUids);
}
private boolean isProxySetOnAnyDefaultNetwork() {
ensureRunningOnConnectivityServiceThread();
for (final NetworkRequestInfo nri : mDefaultNetworkRequests) {
final NetworkAgentInfo nai = nri.getSatisfier();
if (nai != null && nai.linkProperties.getHttpProxy() != null) {
return true;
}
}
return false;
}
private void maybeSendProxyBroadcast(NetworkAgentInfo nai, NetworkCapabilities prevNc,
NetworkCapabilities newNc) {
// When the apps moved from/to a VPN, a proxy broadcast is needed to inform the apps that
// the proxy might be changed since the default network satisfied by the apps might also
// changed.
// TODO: Try to track the default network that apps use and only send a proxy broadcast when
// that happens to prevent false alarms.
final Set<UidRange> prevUids = prevNc == null ? null : prevNc.getUidRanges();
final Set<UidRange> newUids = newNc == null ? null : newNc.getUidRanges();
if (nai.isVPN() && nai.everConnected() && !UidRange.hasSameUids(prevUids, newUids)
&& (nai.linkProperties.getHttpProxy() != null || isProxySetOnAnyDefaultNetwork())) {
mProxyTracker.sendProxyBroadcast();
}
}
private void updateVpnUids(@NonNull NetworkAgentInfo nai, @Nullable NetworkCapabilities prevNc,
@Nullable NetworkCapabilities newNc) {
Set<UidRange> prevRanges = null == prevNc ? null : prevNc.getUidRanges();
Set<UidRange> newRanges = null == newNc ? null : newNc.getUidRanges();
if (null == prevRanges) prevRanges = new ArraySet<>();
if (null == newRanges) newRanges = new ArraySet<>();
final Set<UidRange> prevRangesCopy = new ArraySet<>(prevRanges);
prevRanges.removeAll(newRanges);
newRanges.removeAll(prevRangesCopy);
try {
// When updating the VPN uid routing rules, add the new range first then remove the old
// range. If old range were removed first, there would be a window between the old
// range being removed and the new range being added, during which UIDs contained
// in both ranges are not subject to any VPN routing rules. Adding new range before
// removing old range works because, unlike the filtering rules below, it's possible to
// add duplicate UID routing rules.
// TODO: calculate the intersection of add & remove. Imagining that we are trying to
// remove uid 3 from a set containing 1-5. Intersection of the prev and new sets is:
// [1-5] & [1-2],[4-5] == [3]
// Then we can do:
// maybeCloseSockets([3])
// mNetd.networkAddUidRanges([1-2],[4-5])
// mNetd.networkRemoveUidRanges([1-5])
// maybeCloseSockets([3])
// This can prevent the sockets of uid 1-2, 4-5 from being closed. It also reduce the
// number of binder calls from 6 to 4.
if (!newRanges.isEmpty()) {
updateVpnUidRanges(true, nai, newRanges);
}
if (!prevRanges.isEmpty()) {
updateVpnUidRanges(false, nai, prevRanges);
}
final String oldIface = getVpnIsolationInterface(nai, prevNc, nai.linkProperties);
final String newIface = getVpnIsolationInterface(nai, newNc, nai.linkProperties);
final boolean wasFiltering = requiresVpnAllowRule(nai, nai.linkProperties, oldIface);
final boolean shouldFilter = requiresVpnAllowRule(nai, nai.linkProperties, newIface);
// For VPN uid interface filtering, old ranges need to be removed before new ranges can
// be added, due to the range being expanded and stored as individual UIDs. For example
// the UIDs might be updated from [0, 99999] to ([0, 10012], [10014, 99999]) which means
// prevRanges = [0, 99999] while newRanges = [0, 10012], [10014, 99999]. If prevRanges
// were added first and then newRanges got removed later, there would be only one uid
// 10013 left. A consequence of removing old ranges before adding new ranges is that
// there is now a window of opportunity when the UIDs are not subject to any filtering.
// Note that this is in contrast with the (more robust) update of VPN routing rules
// above, where the addition of new ranges happens before the removal of old ranges.
// TODO Fix this window by computing an accurate diff on Set<UidRange>, so the old range
// to be removed will never overlap with the new range to be added.
if (wasFiltering && !prevRanges.isEmpty()) {
mPermissionMonitor.onVpnUidRangesRemoved(oldIface, prevRanges,
prevNc.getOwnerUid());
}
if (shouldFilter && !newRanges.isEmpty()) {
mPermissionMonitor.onVpnUidRangesAdded(newIface, newRanges, newNc.getOwnerUid());
}
} catch (Exception e) {
// Never crash!
loge("Exception in updateVpnUids: ", e);
}
}
private void updateAllowedUids(@NonNull NetworkAgentInfo nai,
@Nullable NetworkCapabilities prevNc, @Nullable NetworkCapabilities newNc) {
// In almost all cases both NC code for empty access UIDs. return as fast as possible.
final boolean prevEmpty = null == prevNc || prevNc.getAllowedUidsNoCopy().isEmpty();
final boolean newEmpty = null == newNc || newNc.getAllowedUidsNoCopy().isEmpty();
if (prevEmpty && newEmpty) return;
final ArraySet<Integer> prevUids =
null == prevNc ? new ArraySet<>() : prevNc.getAllowedUidsNoCopy();
final ArraySet<Integer> newUids =
null == newNc ? new ArraySet<>() : newNc.getAllowedUidsNoCopy();
if (prevUids.equals(newUids)) return;
// This implementation is very simple and vastly faster for sets of Integers than
// CompareOrUpdateResult, which is tuned for sets that need to be compared based on
// a key computed from the value and has storage for that.
final ArraySet<Integer> toRemove = new ArraySet<>(prevUids);
final ArraySet<Integer> toAdd = new ArraySet<>(newUids);
toRemove.removeAll(newUids);
toAdd.removeAll(prevUids);
try {
if (!toAdd.isEmpty()) {
mNetd.networkAddUidRangesParcel(new NativeUidRangeConfig(
nai.network.netId,
intsToUidRangeStableParcels(toAdd),
PREFERENCE_ORDER_IRRELEVANT_BECAUSE_NOT_DEFAULT));
}
if (!toRemove.isEmpty()) {
mNetd.networkRemoveUidRangesParcel(new NativeUidRangeConfig(
nai.network.netId,
intsToUidRangeStableParcels(toRemove),
PREFERENCE_ORDER_IRRELEVANT_BECAUSE_NOT_DEFAULT));
}
} catch (ServiceSpecificException e) {
// Has the interface disappeared since the network was built ?
Log.i(TAG, "Can't set access UIDs for network " + nai.network, e);
} catch (RemoteException e) {
// Netd died. This usually causes a runtime restart anyway.
}
}
public void handleUpdateLinkProperties(@NonNull NetworkAgentInfo nai,
@NonNull LinkProperties newLp) {
ensureRunningOnConnectivityServiceThread();
if (!mNetworkAgentInfos.contains(nai)) {
// Ignore updates for disconnected networks
return;
}
if (VDBG || DDBG) {
log("Update of LinkProperties for " + nai.toShortString()
+ "; created=" + nai.getCreatedTime()
+ "; firstConnected=" + nai.getConnectedTime());
}
// TODO: eliminate this defensive copy after confirming that updateLinkProperties does not
// modify its oldLp parameter.
updateLinkProperties(nai, newLp, new LinkProperties(nai.linkProperties));
}
private void sendPendingIntentForRequest(NetworkRequestInfo nri, NetworkAgentInfo networkAgent,
int notificationType) {
if (notificationType == ConnectivityManager.CALLBACK_AVAILABLE && !nri.mPendingIntentSent) {
Intent intent = new Intent();
intent.putExtra(ConnectivityManager.EXTRA_NETWORK, networkAgent.network);
// If apps could file multi-layer requests with PendingIntents, they'd need to know
// which of the layer is satisfied alongside with some ID for the request. Hence, if
// such an API is ever implemented, there is no doubt the right request to send in
// EXTRA_NETWORK_REQUEST is the active request, and whatever ID would be added would
// need to be sent as a separate extra.
final NetworkRequest req = nri.isMultilayerRequest()
? nri.getActiveRequest()
// Non-multilayer listen requests do not have an active request
: nri.mRequests.get(0);
if (req == null) {
Log.wtf(TAG, "No request in NRI " + nri);
}
intent.putExtra(ConnectivityManager.EXTRA_NETWORK_REQUEST, req);
nri.mPendingIntentSent = true;
sendIntent(nri.mPendingIntent, intent);
}
// else not handled
}
// TODO(b/193460475): Remove when tooling supports SystemApi to public API.
@SuppressLint("NewApi")
private void sendIntent(PendingIntent pendingIntent, Intent intent) {
mPendingIntentWakeLock.acquire();
try {
if (DBG) log("Sending " + pendingIntent);
final BroadcastOptions options = BroadcastOptions.makeBasic();
if (mDeps.isAtLeastT()) {
// Explicitly disallow the receiver from starting activities, to prevent apps from
// utilizing the PendingIntent as a backdoor to do this.
options.setPendingIntentBackgroundActivityLaunchAllowed(false);
}
pendingIntent.send(mContext, 0, intent, this /* onFinished */, null /* Handler */,
null /* requiredPermission */,
mDeps.isAtLeastT() ? options.toBundle() : null);
} catch (PendingIntent.CanceledException e) {
if (DBG) log(pendingIntent + " was not sent, it had been canceled.");
mPendingIntentWakeLock.release();
releasePendingNetworkRequest(pendingIntent);
}
// ...otherwise, mPendingIntentWakeLock.release() gets called by onSendFinished()
}
@Override
public void onSendFinished(PendingIntent pendingIntent, Intent intent, int resultCode,
String resultData, Bundle resultExtras) {
if (DBG) log("Finished sending " + pendingIntent);
mPendingIntentWakeLock.release();
// Release with a delay so the receiving client has an opportunity to put in its
// own request.
releasePendingNetworkRequestWithDelay(pendingIntent);
}
@Nullable
private LocalNetworkInfo localNetworkInfoForNai(@NonNull final NetworkAgentInfo nai) {
if (!nai.isLocalNetwork()) return null;
final Network upstream;
final NetworkRequest selector = nai.localNetworkConfig.getUpstreamSelector();
if (null == selector) {
upstream = null;
} else {
final NetworkRequestInfo upstreamNri = mNetworkRequests.get(selector);
final NetworkAgentInfo satisfier = upstreamNri.getSatisfier();
upstream = (null == satisfier) ? null : satisfier.network;
}
return new LocalNetworkInfo.Builder().setUpstreamNetwork(upstream).build();
}
// networkAgent is only allowed to be null if notificationType is
// CALLBACK_UNAVAIL. This is because UNAVAIL is about no network being
// available, while all other cases are about some particular network.
private void callCallbackForRequest(@NonNull final NetworkRequestInfo nri,
@Nullable final NetworkAgentInfo networkAgent, final int notificationType,
final int arg1) {
if (nri.mMessenger == null) {
// Default request has no msgr. Also prevents callbacks from being invoked for
// NetworkRequestInfos registered with ConnectivityDiagnostics requests. Those callbacks
// are Type.LISTEN, but should not have NetworkCallbacks invoked.
return;
}
final Bundle bundle = new Bundle();
// TODO b/177608132: make sure callbacks are indexed by NRIs and not NetworkRequest objects.
// TODO: check if defensive copies of data is needed.
final NetworkRequest nrForCallback = nri.getNetworkRequestForCallback();
putParcelable(bundle, nrForCallback);
Message msg = Message.obtain();
if (notificationType != ConnectivityManager.CALLBACK_UNAVAIL) {
putParcelable(bundle, networkAgent.network);
}
final boolean includeLocationSensitiveInfo =
(nri.mCallbackFlags & NetworkCallback.FLAG_INCLUDE_LOCATION_INFO) != 0;
switch (notificationType) {
case ConnectivityManager.CALLBACK_AVAILABLE: {
final NetworkCapabilities nc =
createWithLocationInfoSanitizedIfNecessaryWhenParceled(
networkCapabilitiesRestrictedForCallerPermissions(
networkAgent.networkCapabilities, nri.mPid, nri.mUid),
includeLocationSensitiveInfo, nri.mPid, nri.mUid,
nrForCallback.getRequestorPackageName(),
nri.mCallingAttributionTag);
putParcelable(bundle, nc);
putParcelable(bundle, linkPropertiesRestrictedForCallerPermissions(
networkAgent.linkProperties, nri.mPid, nri.mUid));
// The local network info is often null, so can't use the static putParcelable
// method here.
bundle.putParcelable(LocalNetworkInfo.class.getSimpleName(),
localNetworkInfoForNai(networkAgent));
// For this notification, arg1 contains the blocked status.
msg.arg1 = arg1;
break;
}
case ConnectivityManager.CALLBACK_LOSING: {
msg.arg1 = arg1;
break;
}
case ConnectivityManager.CALLBACK_CAP_CHANGED: {
// networkAgent can't be null as it has been accessed a few lines above.
final NetworkCapabilities netCap =
networkCapabilitiesRestrictedForCallerPermissions(
networkAgent.networkCapabilities, nri.mPid, nri.mUid);
putParcelable(
bundle,
createWithLocationInfoSanitizedIfNecessaryWhenParceled(
netCap, includeLocationSensitiveInfo, nri.mPid, nri.mUid,
nrForCallback.getRequestorPackageName(),
nri.mCallingAttributionTag));
break;
}
case ConnectivityManager.CALLBACK_IP_CHANGED: {
putParcelable(bundle, linkPropertiesRestrictedForCallerPermissions(
networkAgent.linkProperties, nri.mPid, nri.mUid));
break;
}
case ConnectivityManager.CALLBACK_BLK_CHANGED: {
maybeLogBlockedStatusChanged(nri, networkAgent.network, arg1);
msg.arg1 = arg1;
break;
}
case ConnectivityManager.CALLBACK_LOCAL_NETWORK_INFO_CHANGED: {
if (!networkAgent.isLocalNetwork()) {
Log.wtf(TAG, "Callback for local info for a non-local network");
return;
}
putParcelable(bundle, localNetworkInfoForNai(networkAgent));
break;
}
}
msg.what = notificationType;
msg.setData(bundle);
try {
if (VDBG) {
String notification = ConnectivityManager.getCallbackName(notificationType);
log("sending notification " + notification + " for " + nrForCallback);
}
nri.mMessenger.send(msg);
} catch (RemoteException e) {
// may occur naturally in the race of binder death.
loge("RemoteException caught trying to send a callback msg for " + nrForCallback);
}
}
private static <T extends Parcelable> void putParcelable(Bundle bundle, T t) {
bundle.putParcelable(t.getClass().getSimpleName(), t);
}
/**
* Returns whether reassigning a request from an NAI to another can be done gracefully.
*
* When a request should be assigned to a new network, it is normally lingered to give
* time for apps to gracefully migrate their connections. When both networks are on the same
* radio, but that radio can't do time-sharing efficiently, this may end up being
* counter-productive because any traffic on the old network may drastically reduce the
* performance of the new network.
* The stack supports a configuration to let modem vendors state that their radio can't
* do time-sharing efficiently. If this configuration is set, the stack assumes moving
* from one cell network to another can't be done gracefully.
*
* @param oldNai the old network serving the request
* @param newNai the new network serving the request
* @return whether the switch can be graceful
*/
private boolean canSupportGracefulNetworkSwitch(@NonNull final NetworkAgentInfo oldSatisfier,
@NonNull final NetworkAgentInfo newSatisfier) {
if (mCellularRadioTimesharingCapable) return true;
return !oldSatisfier.networkCapabilities.hasSingleTransport(TRANSPORT_CELLULAR)
|| !newSatisfier.networkCapabilities.hasSingleTransport(TRANSPORT_CELLULAR)
|| !newSatisfier.getScore().hasPolicy(POLICY_TRANSPORT_PRIMARY);
}
private void teardownUnneededNetwork(NetworkAgentInfo nai) {
if (nai.numRequestNetworkRequests() != 0) {
for (int i = 0; i < nai.numNetworkRequests(); i++) {
NetworkRequest nr = nai.requestAt(i);
// Ignore listening and track default requests.
if (!nr.isRequest()) continue;
loge("Dead network still had at least " + nr);
break;
}
}
nai.disconnect();
}
private void handleLingerComplete(NetworkAgentInfo oldNetwork) {
if (oldNetwork == null) {
loge("Unknown NetworkAgentInfo in handleLingerComplete");
return;
}
if (DBG) log("handleLingerComplete for " + oldNetwork.toShortString());
// If we get here it means that the last linger timeout for this network expired. So there
// must be no other active linger timers, and we must stop lingering.
oldNetwork.clearInactivityState();
if (unneeded(oldNetwork, UnneededFor.TEARDOWN)) {
// Tear the network down.
teardownUnneededNetwork(oldNetwork);
} else {
// Put the network in the background if it doesn't satisfy any foreground request.
updateCapabilitiesForNetwork(oldNetwork);
}
}
private void processDefaultNetworkChanges(@NonNull final NetworkReassignment changes) {
boolean isDefaultChanged = false;
for (final NetworkRequestInfo defaultRequestInfo : mDefaultNetworkRequests) {
final NetworkReassignment.RequestReassignment reassignment =
changes.getReassignment(defaultRequestInfo);
if (null == reassignment) {
continue;
}
// reassignment only contains those instances where the satisfying network changed.
isDefaultChanged = true;
// Notify system services of the new default.
makeDefault(defaultRequestInfo, reassignment.mOldNetwork, reassignment.mNewNetwork);
}
if (isDefaultChanged) {
// Hold a wakelock for a short time to help apps in migrating to a new default.
scheduleReleaseNetworkTransitionWakelock();
}
}
private void resetHttpProxyForNonDefaultNetwork(NetworkAgentInfo oldDefaultNetwork) {
if (null == oldDefaultNetwork) return;
// The network stopped being the default. If it was using a PAC proxy, then the
// proxy needs to be reset, otherwise HTTP requests on this network may be sent
// to the local proxy server, which would forward them over the newly default network.
final ProxyInfo proxyInfo = oldDefaultNetwork.linkProperties.getHttpProxy();
if (null == proxyInfo || !proxyInfo.isPacProxy()) return;
oldDefaultNetwork.linkProperties.setHttpProxy(new ProxyInfo(proxyInfo.getPacFileUrl()));
notifyNetworkCallbacks(oldDefaultNetwork, CALLBACK_IP_CHANGED);
}
private void makeDefault(@NonNull final NetworkRequestInfo nri,
@Nullable final NetworkAgentInfo oldDefaultNetwork,
@Nullable final NetworkAgentInfo newDefaultNetwork) {
if (DBG) {
log("Switching to new default network for: " + nri + " using " + newDefaultNetwork);
}
// Fix up the NetworkCapabilities of any networks that have this network as underlying.
if (newDefaultNetwork != null) {
propagateUnderlyingNetworkCapabilities(newDefaultNetwork.network);
}
// Set an app level managed default and return since further processing only applies to the
// default network.
if (mDefaultRequest != nri) {
makeDefaultForApps(nri, oldDefaultNetwork, newDefaultNetwork);
return;
}
makeDefaultNetwork(newDefaultNetwork);
if (oldDefaultNetwork != null) {
mLingerMonitor.noteLingerDefaultNetwork(oldDefaultNetwork, newDefaultNetwork);
}
mNetworkActivityTracker.updateDefaultNetwork(newDefaultNetwork, oldDefaultNetwork);
maybeClosePendingFrozenSockets(newDefaultNetwork, oldDefaultNetwork);
mProxyTracker.setDefaultProxy(null != newDefaultNetwork
? newDefaultNetwork.linkProperties.getHttpProxy() : null);
resetHttpProxyForNonDefaultNetwork(oldDefaultNetwork);
updateTcpBufferSizes(null != newDefaultNetwork
? newDefaultNetwork.linkProperties.getTcpBufferSizes() : null);
notifyIfacesChangedForNetworkStats();
}
private void makeDefaultForApps(@NonNull final NetworkRequestInfo nri,
@Nullable final NetworkAgentInfo oldDefaultNetwork,
@Nullable final NetworkAgentInfo newDefaultNetwork) {
try {
if (VDBG) {
log("Setting default network for " + nri
+ " using UIDs " + nri.getUids()
+ " with old network " + (oldDefaultNetwork != null
? oldDefaultNetwork.network().getNetId() : "null")
+ " and new network " + (newDefaultNetwork != null
? newDefaultNetwork.network().getNetId() : "null"));
}
if (nri.getUids().isEmpty()) {
throw new IllegalStateException("makeDefaultForApps called without specifying"
+ " any applications to set as the default." + nri);
}
if (null != newDefaultNetwork) {
mNetd.networkAddUidRangesParcel(new NativeUidRangeConfig(
newDefaultNetwork.network.getNetId(),
toUidRangeStableParcels(nri.getUids()),
nri.getPreferenceOrderForNetd()));
}
if (null != oldDefaultNetwork) {
mNetd.networkRemoveUidRangesParcel(new NativeUidRangeConfig(
oldDefaultNetwork.network.getNetId(),
toUidRangeStableParcels(nri.getUids()),
nri.getPreferenceOrderForNetd()));
}
} catch (RemoteException | ServiceSpecificException e) {
loge("Exception setting app default network", e);
}
}
/**
* Collect restricted uid ranges for the given network and UserHandle, these uids
* are not restricted for matched enterprise networks but being restricted for non-matched
* enterprise networks and non-enterprise networks.
*/
@NonNull
private ArraySet<UidRange> getRestrictedUidRangesForEnterpriseBlocking(
@NonNull NetworkAgentInfo nai, @NonNull UserHandle user) {
final ArraySet<UidRange> restrictedUidRanges = new ArraySet<>();
for (final ProfileNetworkPreferenceInfo pref : mProfileNetworkPreferences) {
if (!pref.user.equals(user) || !pref.blockingNonEnterprise) continue;
if (nai.networkCapabilities.hasCapability(NET_CAPABILITY_ENTERPRISE)) {
// The NC is built from a `ProfileNetworkPreference` which has only one
// enterprise ID, so it's guaranteed to have exactly one.
final int prefId = pref.capabilities.getEnterpriseIds()[0];
if (nai.networkCapabilities.hasEnterpriseId(prefId)) {
continue;
}
}
if (UidRangeUtils.doesRangeSetOverlap(restrictedUidRanges,
pref.capabilities.getUidRanges())) {
throw new IllegalArgumentException(
"Overlapping uid range in preference: " + pref);
}
restrictedUidRanges.addAll(pref.capabilities.getUidRanges());
}
return restrictedUidRanges;
}
private void updateProfileAllowedNetworks() {
// Netd command is not implemented before U.
if (!mDeps.isAtLeastU()) return;
ensureRunningOnConnectivityServiceThread();
final ArrayList<NativeUidRangeConfig> configs = new ArrayList<>();
final List<UserHandle> users = mContext.getSystemService(UserManager.class)
.getUserHandles(true /* excludeDying */);
if (users.isEmpty()) {
throw new IllegalStateException("No user is available");
}
for (final NetworkAgentInfo nai : mNetworkAgentInfos) {
ArraySet<UidRange> allowedUidRanges = new ArraySet<>();
for (final UserHandle user : users) {
final ArraySet<UidRange> restrictedUidRanges =
getRestrictedUidRangesForEnterpriseBlocking(nai, user);
allowedUidRanges.addAll(UidRangeUtils.removeRangeSetFromUidRange(
UidRange.createForUser(user), restrictedUidRanges));
}
final UidRangeParcel[] rangesParcel = toUidRangeStableParcels(allowedUidRanges);
configs.add(new NativeUidRangeConfig(
nai.network.netId, rangesParcel, 0 /* subPriority */));
}
// The netd API replaces the previous configs with the current configs.
// Thus, for network disconnection or preference removal, no need to
// unset previous config. Instead, collecting all currently needed
// configs and issue to netd.
try {
mNetd.setNetworkAllowlist(configs.toArray(new NativeUidRangeConfig[0]));
} catch (ServiceSpecificException e) {
// Has the interface disappeared since the network was built?
Log.wtf(TAG, "Unexpected ServiceSpecificException", e);
} catch (RemoteException e) {
// Netd died. This will cause a runtime restart anyway.
Log.wtf(TAG, "Unexpected RemoteException", e);
}
}
private void makeDefaultNetwork(@Nullable final NetworkAgentInfo newDefaultNetwork) {
try {
if (null != newDefaultNetwork) {
mNetd.networkSetDefault(newDefaultNetwork.network.getNetId());
} else {
mNetd.networkClearDefault();
}
} catch (RemoteException | ServiceSpecificException e) {
loge("Exception setting default network :" + e);
}
}
private void processListenRequests(@NonNull final NetworkAgentInfo nai) {
// For consistency with previous behaviour, send onLost callbacks before onAvailable.
processNewlyLostListenRequests(nai);
notifyNetworkCallbacks(nai, ConnectivityManager.CALLBACK_CAP_CHANGED);
processNewlySatisfiedListenRequests(nai);
}
private void processNewlyLostListenRequests(@NonNull final NetworkAgentInfo nai) {
for (final NetworkRequestInfo nri : mNetworkRequests.values()) {
if (nri.isMultilayerRequest()) {
continue;
}
final NetworkRequest nr = nri.mRequests.get(0);
if (!nr.isListen()) continue;
if (nai.isSatisfyingRequest(nr.requestId) && !nai.satisfies(nr)) {
nai.removeRequest(nr.requestId);
callCallbackForRequest(nri, nai, ConnectivityManager.CALLBACK_LOST, 0);
}
}
}
private void processNewlySatisfiedListenRequests(@NonNull final NetworkAgentInfo nai) {
for (final NetworkRequestInfo nri : mNetworkRequests.values()) {
if (nri.isMultilayerRequest()) {
continue;
}
final NetworkRequest nr = nri.mRequests.get(0);
if (!nr.isListen()) continue;
if (nai.satisfies(nr) && !nai.isSatisfyingRequest(nr.requestId)) {
nai.addRequest(nr);
notifyNetworkAvailable(nai, nri);
}
}
}
// An accumulator class to gather the list of changes that result from a rematch.
private static class NetworkReassignment {
static class RequestReassignment {
@NonNull public final NetworkRequestInfo mNetworkRequestInfo;
@Nullable public final NetworkRequest mOldNetworkRequest;
@Nullable public final NetworkRequest mNewNetworkRequest;
@Nullable public final NetworkAgentInfo mOldNetwork;
@Nullable public final NetworkAgentInfo mNewNetwork;
RequestReassignment(@NonNull final NetworkRequestInfo networkRequestInfo,
@Nullable final NetworkRequest oldNetworkRequest,
@Nullable final NetworkRequest newNetworkRequest,
@Nullable final NetworkAgentInfo oldNetwork,
@Nullable final NetworkAgentInfo newNetwork) {
mNetworkRequestInfo = networkRequestInfo;
mOldNetworkRequest = oldNetworkRequest;
mNewNetworkRequest = newNetworkRequest;
mOldNetwork = oldNetwork;
mNewNetwork = newNetwork;
}
public String toString() {
final NetworkRequest requestToShow = null != mNewNetworkRequest
? mNewNetworkRequest : mNetworkRequestInfo.mRequests.get(0);
return requestToShow.requestId + " : "
+ (null != mOldNetwork ? mOldNetwork.network.getNetId() : "null")
+ " → " + (null != mNewNetwork ? mNewNetwork.network.getNetId() : "null");
}
}
@NonNull private final ArrayList<RequestReassignment> mReassignments = new ArrayList<>();
@NonNull Iterable<RequestReassignment> getRequestReassignments() {
return mReassignments;
}
void addRequestReassignment(@NonNull final RequestReassignment reassignment) {
if (Build.isDebuggable()) {
// The code is never supposed to add two reassignments of the same request. Make
// sure this stays true, but without imposing this expensive check on all
// reassignments on all user devices.
for (final RequestReassignment existing : mReassignments) {
if (existing.mNetworkRequestInfo.equals(reassignment.mNetworkRequestInfo)) {
throw new IllegalStateException("Trying to reassign ["
+ reassignment + "] but already have ["
+ existing + "]");
}
}
}
mReassignments.add(reassignment);
}
// Will return null if this reassignment does not change the network assigned to
// the passed request.
@Nullable
private RequestReassignment getReassignment(@NonNull final NetworkRequestInfo nri) {
for (final RequestReassignment event : getRequestReassignments()) {
if (nri == event.mNetworkRequestInfo) return event;
}
return null;
}
public String toString() {
final StringJoiner sj = new StringJoiner(", " /* delimiter */,
"NetReassign [" /* prefix */, "]" /* suffix */);
if (mReassignments.isEmpty()) return sj.add("no changes").toString();
for (final RequestReassignment rr : getRequestReassignments()) {
sj.add(rr.toString());
}
return sj.toString();
}
public String debugString() {
final StringBuilder sb = new StringBuilder();
sb.append("NetworkReassignment :");
if (mReassignments.isEmpty()) return sb.append(" no changes").toString();
for (final RequestReassignment rr : getRequestReassignments()) {
sb.append("\n ").append(rr);
}
return sb.append("\n").toString();
}
}
private void updateSatisfiersForRematchRequest(@NonNull final NetworkRequestInfo nri,
@Nullable final NetworkRequest previousRequest,
@Nullable final NetworkRequest newRequest,
@Nullable final NetworkAgentInfo previousSatisfier,
@Nullable final NetworkAgentInfo newSatisfier,
final long now) {
if (null != newSatisfier && mNoServiceNetwork != newSatisfier) {
if (VDBG) log("rematch for " + newSatisfier.toShortString());
if (null != previousRequest && null != previousSatisfier) {
if (VDBG || DDBG) {
log(" accepting network in place of " + previousSatisfier.toShortString()
+ " for " + newRequest);
}
previousSatisfier.removeRequest(previousRequest.requestId);
if (canSupportGracefulNetworkSwitch(previousSatisfier, newSatisfier)
&& !previousSatisfier.isDestroyed()) {
// If this network switch can't be supported gracefully, the request is not
// lingered. This allows letting go of the network sooner to reclaim some
// performance on the new network, since the radio can't do both at the same
// time while preserving good performance.
//
// Also don't linger the request if the old network has been destroyed.
// A destroyed network does not provide actual network connectivity, so
// lingering it is not useful. In particular this ensures that a destroyed
// network is outscored by its replacement,
// then it is torn down immediately instead of being lingered, and any apps that
// were using it immediately get onLost and can connect using the new network.
previousSatisfier.lingerRequest(previousRequest.requestId, now);
}
} else {
if (VDBG || DDBG) log(" accepting network in place of null for " + newRequest);
}
// To prevent constantly CPU wake up for nascent timer, if a network comes up
// and immediately satisfies a request then remove the timer. This will happen for
// all networks except in the case of an underlying network for a VCN.
if (newSatisfier.isNascent()) {
newSatisfier.unlingerRequest(NetworkRequest.REQUEST_ID_NONE);
newSatisfier.unsetInactive();
}
// if newSatisfier is not null, then newRequest may not be null.
newSatisfier.unlingerRequest(newRequest.requestId);
if (!newSatisfier.addRequest(newRequest)) {
Log.wtf(TAG, "BUG: " + newSatisfier.toShortString() + " already has "
+ newRequest);
}
} else if (null != previousRequest && null != previousSatisfier) {
if (DBG) {
log("Network " + previousSatisfier.toShortString() + " stopped satisfying"
+ " request " + previousRequest.requestId);
}
previousSatisfier.removeRequest(previousRequest.requestId);
}
nri.setSatisfier(newSatisfier, newRequest);
}
/**
* This function is triggered when something can affect what network should satisfy what
* request, and it computes the network reassignment from the passed collection of requests to
* network match to the one that the system should now have. That data is encoded in an
* object that is a list of changes, each of them having an NRI, and old satisfier, and a new
* satisfier.
*
* After the reassignment is computed, it is applied to the state objects.
*
* @param networkRequests the nri objects to evaluate for possible network reassignment
* @return NetworkReassignment listing of proposed network assignment changes
*/
@NonNull
private NetworkReassignment computeNetworkReassignment(
@NonNull final Collection<NetworkRequestInfo> networkRequests) {
final NetworkReassignment changes = new NetworkReassignment();
// Gather the list of all relevant agents.
final ArrayList<NetworkAgentInfo> nais = new ArrayList<>();
for (final NetworkAgentInfo nai : mNetworkAgentInfos) {
nais.add(nai);
}
for (final NetworkRequestInfo nri : networkRequests) {
// Non-multilayer listen requests can be ignored.
if (!nri.isMultilayerRequest() && nri.mRequests.get(0).isListen()) {
continue;
}
NetworkAgentInfo bestNetwork = null;
NetworkRequest bestRequest = null;
for (final NetworkRequest req : nri.mRequests) {
bestNetwork = mNetworkRanker.getBestNetwork(req, nais, nri.getSatisfier());
// Stop evaluating as the highest possible priority request is satisfied.
if (null != bestNetwork) {
bestRequest = req;
break;
}
}
if (null == bestNetwork && isDefaultBlocked(nri)) {
// Remove default networking if disallowed for managed default requests.
bestNetwork = mNoServiceNetwork;
}
if (nri.getSatisfier() != bestNetwork) {
// bestNetwork may be null if no network can satisfy this request.
changes.addRequestReassignment(new NetworkReassignment.RequestReassignment(
nri, nri.mActiveRequest, bestRequest, nri.getSatisfier(), bestNetwork));
}
}
return changes;
}
private Set<NetworkRequestInfo> getNrisFromGlobalRequests() {
return new HashSet<>(mNetworkRequests.values());
}
/**
* Attempt to rematch all Networks with all NetworkRequests. This may result in Networks
* being disconnected.
*/
private void rematchAllNetworksAndRequests() {
rematchNetworksAndRequests(getNrisFromGlobalRequests());
}
/**
* Attempt to rematch all Networks with given NetworkRequests. This may result in Networks
* being disconnected.
*/
private void rematchNetworksAndRequests(
@NonNull final Set<NetworkRequestInfo> networkRequests) {
ensureRunningOnConnectivityServiceThread();
// TODO: This may be slow, and should be optimized.
final long start = SystemClock.elapsedRealtime();
final NetworkReassignment changes = computeNetworkReassignment(networkRequests);
final long computed = SystemClock.elapsedRealtime();
applyNetworkReassignment(changes, start);
final long applied = SystemClock.elapsedRealtime();
issueNetworkNeeds();
final long end = SystemClock.elapsedRealtime();
if (VDBG || DDBG) {
log(String.format("Rematched networks [computed %dms] [applied %dms] [issued %d]",
computed - start, applied - computed, end - applied));
log(changes.debugString());
} else if (DBG) {
// Shorter form, only one line of log
log(String.format("%s [c %d] [a %d] [i %d]", changes.toString(),
computed - start, applied - computed, end - applied));
}
}
private boolean hasSameInterfaceName(@Nullable final NetworkAgentInfo nai1,
@Nullable final NetworkAgentInfo nai2) {
if (null == nai1) return null == nai2;
if (null == nai2) return false;
return nai1.linkProperties.getInterfaceName()
.equals(nai2.linkProperties.getInterfaceName());
}
private void applyNetworkReassignment(@NonNull final NetworkReassignment changes,
final long now) {
final Collection<NetworkAgentInfo> nais = mNetworkAgentInfos;
// Since most of the time there are only 0 or 1 background networks, it would probably
// be more efficient to just use an ArrayList here. TODO : measure performance
final ArraySet<NetworkAgentInfo> oldBgNetworks = new ArraySet<>();
for (final NetworkAgentInfo nai : nais) {
if (nai.isBackgroundNetwork()) oldBgNetworks.add(nai);
}
// First, update the lists of satisfied requests in the network agents. This is necessary
// because some code later depends on this state to be correct, most prominently computing
// the linger status.
for (final NetworkReassignment.RequestReassignment event :
changes.getRequestReassignments()) {
updateSatisfiersForRematchRequest(event.mNetworkRequestInfo,
event.mOldNetworkRequest, event.mNewNetworkRequest,
event.mOldNetwork, event.mNewNetwork,
now);
}
// Process default network changes if applicable.
processDefaultNetworkChanges(changes);
// Update forwarding rules for the upstreams of local networks. Do this before sending
// onAvailable so that by the time onAvailable is sent the forwarding rules are set up.
// Don't send CALLBACK_LOCAL_NETWORK_INFO_CHANGED yet though : they should be sent after
// onAvailable so clients know what network the change is about. Store such changes in
// an array that's only allocated if necessary (because it's almost never necessary).
ArrayList<NetworkAgentInfo> localInfoChangedAgents = null;
for (final NetworkAgentInfo nai : mNetworkAgentInfos) {
if (!nai.isLocalNetwork()) continue;
final NetworkRequest nr = nai.localNetworkConfig.getUpstreamSelector();
if (null == nr) continue; // No upstream for this local network
final NetworkRequestInfo nri = mNetworkRequests.get(nr);
final NetworkReassignment.RequestReassignment change = changes.getReassignment(nri);
if (null == change) continue; // No change in upstreams for this network
final String fromIface = nai.linkProperties.getInterfaceName();
if (!hasSameInterfaceName(change.mOldNetwork, change.mNewNetwork)
|| change.mOldNetwork.isDestroyed()) {
// There can be a change with the same interface name if the new network is the
// replacement for the old network that was unregisteredAfterReplacement.
try {
if (null != change.mOldNetwork) {
mRoutingCoordinatorService.removeInterfaceForward(fromIface,
change.mOldNetwork.linkProperties.getInterfaceName());
}
// If the new upstream is already destroyed, there is no point in setting up
// a forward (in fact, it might forward to the interface for some new network !)
// Later when the upstream disconnects CS will try to remove the forward, which
// is ignored with a benign log by RoutingCoordinatorService.
if (null != change.mNewNetwork && !change.mNewNetwork.isDestroyed()) {
mRoutingCoordinatorService.addInterfaceForward(fromIface,
change.mNewNetwork.linkProperties.getInterfaceName());
}
} catch (final RemoteException e) {
loge("Can't update forwarding rules", e);
}
}
if (null == localInfoChangedAgents) localInfoChangedAgents = new ArrayList<>();
localInfoChangedAgents.add(nai);
}
// Notify requested networks are available after the default net is switched, but
// before LegacyTypeTracker sends legacy broadcasts
for (final NetworkReassignment.RequestReassignment event :
changes.getRequestReassignments()) {
if (null != event.mNewNetwork) {
notifyNetworkAvailable(event.mNewNetwork, event.mNetworkRequestInfo);
} else {
callCallbackForRequest(event.mNetworkRequestInfo, event.mOldNetwork,
ConnectivityManager.CALLBACK_LOST, 0);
}
}
// Update the inactivity state before processing listen callbacks, because the background
// computation depends on whether the network is inactive. Don't send the LOSING callbacks
// just yet though, because they have to be sent after the listens are processed to keep
// backward compatibility.
final ArrayList<NetworkAgentInfo> inactiveNetworks = new ArrayList<>();
for (final NetworkAgentInfo nai : nais) {
// Rematching may have altered the inactivity state of some networks, so update all
// inactivity timers. updateInactivityState reads the state from the network agent
// and does nothing if the state has not changed : the source of truth is controlled
// with NetworkAgentInfo#lingerRequest and NetworkAgentInfo#unlingerRequest, which
// have been called while rematching the individual networks above.
if (updateInactivityState(nai, now)) {
inactiveNetworks.add(nai);
}
}
for (final NetworkAgentInfo nai : nais) {
final boolean oldBackground = oldBgNetworks.contains(nai);
// Process listen requests and update capabilities if the background state has
// changed for this network. For consistency with previous behavior, send onLost
// callbacks before onAvailable.
processNewlyLostListenRequests(nai);
if (oldBackground != nai.isBackgroundNetwork()) {
applyBackgroundChangeForRematch(nai);
}
processNewlySatisfiedListenRequests(nai);
}
for (final NetworkAgentInfo nai : inactiveNetworks) {
// For nascent networks, if connecting with no foreground request, skip broadcasting
// LOSING for backward compatibility. This is typical when mobile data connected while
// wifi connected with mobile data always-on enabled.
if (nai.isNascent()) continue;
notifyNetworkLosing(nai, now);
}
// Send LOCAL_NETWORK_INFO_CHANGED callbacks now that onAvailable and onLost have been sent.
if (null != localInfoChangedAgents) {
for (final NetworkAgentInfo nai : localInfoChangedAgents) {
notifyNetworkCallbacks(nai,
ConnectivityManager.CALLBACK_LOCAL_NETWORK_INFO_CHANGED);
}
}
updateLegacyTypeTrackerAndVpnLockdownForRematch(changes, nais);
// Tear down all unneeded networks.
for (NetworkAgentInfo nai : mNetworkAgentInfos) {
if (unneeded(nai, UnneededFor.TEARDOWN)) {
if (nai.getInactivityExpiry() > 0) {
// This network has active linger timers and no requests, but is not
// lingering. Linger it.
//
// One way (the only way?) this can happen if this network is unvalidated
// and became unneeded due to another network improving its score to the
// point where this network will no longer be able to satisfy any requests
// even if it validates.
if (updateInactivityState(nai, now)) {
notifyNetworkLosing(nai, now);
}
} else {
if (DBG) log("Reaping " + nai.toShortString());
teardownUnneededNetwork(nai);
}
}
}
}
/**
* Apply a change in background state resulting from rematching networks with requests.
*
* During rematch, a network may change background states by starting to satisfy or stopping
* to satisfy a foreground request. Listens don't count for this. When a network changes
* background states, its capabilities need to be updated and callbacks fired for the
* capability change.
*
* @param nai The network that changed background states
*/
private void applyBackgroundChangeForRematch(@NonNull final NetworkAgentInfo nai) {
final NetworkCapabilities newNc = mixInCapabilities(nai, nai.networkCapabilities);
if (Objects.equals(nai.networkCapabilities, newNc)) return;
updateNetworkPermissions(nai, newNc);
nai.getAndSetNetworkCapabilities(newNc);
notifyNetworkCallbacks(nai, ConnectivityManager.CALLBACK_CAP_CHANGED);
}
private void updateLegacyTypeTrackerAndVpnLockdownForRematch(
@NonNull final NetworkReassignment changes,
@NonNull final Collection<NetworkAgentInfo> nais) {
final NetworkReassignment.RequestReassignment reassignmentOfDefault =
changes.getReassignment(mDefaultRequest);
final NetworkAgentInfo oldDefaultNetwork =
null != reassignmentOfDefault ? reassignmentOfDefault.mOldNetwork : null;
final NetworkAgentInfo newDefaultNetwork =
null != reassignmentOfDefault ? reassignmentOfDefault.mNewNetwork : null;
if (oldDefaultNetwork != newDefaultNetwork) {
// Maintain the illusion : since the legacy API only understands one network at a time,
// if the default network changed, apps should see a disconnected broadcast for the
// old default network before they see a connected broadcast for the new one.
if (oldDefaultNetwork != null) {
mLegacyTypeTracker.remove(oldDefaultNetwork.networkInfo.getType(),
oldDefaultNetwork, true);
}
if (newDefaultNetwork != null) {
// The new default network can be newly null if and only if the old default
// network doesn't satisfy the default request any more because it lost a
// capability.
mDefaultInetConditionPublished = newDefaultNetwork.isValidated() ? 100 : 0;
mLegacyTypeTracker.add(
newDefaultNetwork.networkInfo.getType(), newDefaultNetwork);
}
}
// Now that all the callbacks have been sent, send the legacy network broadcasts
// as needed. This is necessary so that legacy requests correctly bind dns
// requests to this network. The legacy users are listening for this broadcast
// and will generally do a dns request so they can ensureRouteToHost and if
// they do that before the callbacks happen they'll use the default network.
//
// TODO: Is there still a race here? The legacy broadcast will be sent after sending
// callbacks, but if apps can receive the broadcast before the callback, they still might
// have an inconsistent view of networking.
//
// This *does* introduce a race where if the user uses the new api
// (notification callbacks) and then uses the old api (getNetworkInfo(type))
// they may get old info. Reverse this after the old startUsing api is removed.
// This is on top of the multiple intent sequencing referenced in the todo above.
for (NetworkAgentInfo nai : nais) {
if (nai.everConnected()) {
addNetworkToLegacyTypeTracker(nai);
}
}
}
private void issueNetworkNeeds() {
ensureRunningOnConnectivityServiceThread();
for (final NetworkOfferInfo noi : mNetworkOffers) {
issueNetworkNeeds(noi);
}
}
private void issueNetworkNeeds(@NonNull final NetworkOfferInfo noi) {
ensureRunningOnConnectivityServiceThread();
for (final NetworkRequestInfo nri : mNetworkRequests.values()) {
informOffer(nri, noi.offer, mNetworkRanker);
}
}
/**
* Inform a NetworkOffer about any new situation of a request.
*
* This function handles updates to offers. A number of events may happen that require
* updating the registrant for this offer about the situation :
* • The offer itself was updated. This may lead the offer to no longer being able
* to satisfy a request or beat a satisfier (and therefore be no longer needed),
* or conversely being strengthened enough to beat the satisfier (and therefore
* start being needed)
* • The network satisfying a request changed (including cases where the request
* starts or stops being satisfied). The new network may be a stronger or weaker
* match than the old one, possibly affecting whether the offer is needed.
* • The network satisfying a request updated their score. This may lead the offer
* to no longer be able to beat it if the current satisfier got better, or
* conversely start being a good choice if the current satisfier got weaker.
*
* @param nri The request
* @param offer The offer. This may be an updated offer.
*/
private static void informOffer(@NonNull NetworkRequestInfo nri,
@NonNull final NetworkOffer offer, @NonNull final NetworkRanker networkRanker) {
final NetworkRequest activeRequest = nri.isBeingSatisfied() ? nri.getActiveRequest() : null;
final NetworkAgentInfo satisfier = null != activeRequest ? nri.getSatisfier() : null;
// Multi-layer requests have a currently active request, the one being satisfied.
// Since the system will try to bring up a better network than is currently satisfying
// the request, NetworkProviders need to be told the offers matching the requests *above*
// the currently satisfied one are needed, that the ones *below* the satisfied one are
// not needed, and the offer is needed for the active request iff the offer can beat
// the satisfier.
// For non-multilayer requests, the logic above gracefully degenerates to only the
// last case.
// To achieve this, the loop below will proceed in three steps. In a first phase, inform
// providers that the offer is needed for this request, until the active request is found.
// In a second phase, deal with the currently active request. In a third phase, inform
// the providers that offer is unneeded for the remaining requests.
// First phase : inform providers of all requests above the active request.
int i;
for (i = 0; nri.mRequests.size() > i; ++i) {
final NetworkRequest request = nri.mRequests.get(i);
if (activeRequest == request) break; // Found the active request : go to phase 2
if (!request.isRequest()) continue; // Listens/track defaults are never sent to offers
// Since this request is higher-priority than the one currently satisfied, if the
// offer can satisfy it, the provider should try and bring up the network for sure ;
// no need to even ask the ranker – an offer that can satisfy is always better than
// no network. Hence tell the provider so unless it already knew.
if (request.canBeSatisfiedBy(offer.caps) && !offer.neededFor(request)) {
offer.onNetworkNeeded(request);
}
}
// Second phase : deal with the active request (if any)
if (null != activeRequest && activeRequest.isRequest()) {
final boolean oldNeeded = offer.neededFor(activeRequest);
// If an offer can satisfy the request, it is considered needed if it is currently
// served by this provider or if this offer can beat the current satisfier.
final boolean currentlyServing = satisfier != null
&& satisfier.factorySerialNumber == offer.providerId
&& activeRequest.canBeSatisfiedBy(offer.caps);
final boolean newNeeded = currentlyServing
|| networkRanker.mightBeat(activeRequest, satisfier, offer);
if (newNeeded != oldNeeded) {
if (newNeeded) {
offer.onNetworkNeeded(activeRequest);
} else {
// The offer used to be able to beat the satisfier. Now it can't.
offer.onNetworkUnneeded(activeRequest);
}
}
}
// Third phase : inform the providers that the offer isn't needed for any request
// below the active one.
for (++i /* skip the active request */; nri.mRequests.size() > i; ++i) {
final NetworkRequest request = nri.mRequests.get(i);
if (!request.isRequest()) continue; // Listens/track defaults are never sent to offers
// Since this request is lower-priority than the one currently satisfied, if the
// offer can satisfy it, the provider should not try and bring up the network.
// Hence tell the provider so unless it already knew.
if (offer.neededFor(request)) {
offer.onNetworkUnneeded(request);
}
}
}
private void addNetworkToLegacyTypeTracker(@NonNull final NetworkAgentInfo nai) {
for (int i = 0; i < nai.numNetworkRequests(); i++) {
NetworkRequest nr = nai.requestAt(i);
if (nr.legacyType != TYPE_NONE && nr.isRequest()) {
// legacy type tracker filters out repeat adds
mLegacyTypeTracker.add(nr.legacyType, nai);
}
}
// A VPN generally won't get added to the legacy tracker in the "for (nri)" loop above,
// because usually there are no NetworkRequests it satisfies (e.g., mDefaultRequest
// wants the NOT_VPN capability, so it will never be satisfied by a VPN). So, add the
// newNetwork to the tracker explicitly (it's a no-op if it has already been added).
if (nai.isVPN()) {
mLegacyTypeTracker.add(TYPE_VPN, nai);
}
}
private void updateInetCondition(NetworkAgentInfo nai) {
// Don't bother updating until we've graduated to validated at least once.
if (!nai.everValidated()) return;
// For now only update icons for the default connection.
// TODO: Update WiFi and cellular icons separately. b/17237507
if (!isDefaultNetwork(nai)) return;
int newInetCondition = nai.isValidated() ? 100 : 0;
// Don't repeat publish.
if (newInetCondition == mDefaultInetConditionPublished) return;
mDefaultInetConditionPublished = newInetCondition;
sendInetConditionBroadcast(nai.networkInfo);
}
@NonNull
private NetworkInfo mixInInfo(@NonNull final NetworkAgentInfo nai, @NonNull NetworkInfo info) {
final NetworkInfo newInfo = new NetworkInfo(info);
// The suspended and roaming bits are managed in NetworkCapabilities.
final boolean suspended =
!nai.networkCapabilities.hasCapability(NET_CAPABILITY_NOT_SUSPENDED);
if (suspended && info.getDetailedState() == NetworkInfo.DetailedState.CONNECTED) {
// Only override the state with SUSPENDED if the network is currently in CONNECTED
// state. This is because the network could have been suspended before connecting,
// or it could be disconnecting while being suspended, and in both these cases
// the state should not be overridden. Note that the only detailed state that
// maps to State.CONNECTED is DetailedState.CONNECTED, so there is also no need to
// worry about multiple different substates of CONNECTED.
newInfo.setDetailedState(NetworkInfo.DetailedState.SUSPENDED, info.getReason(),
info.getExtraInfo());
} else if (!suspended && info.getDetailedState() == NetworkInfo.DetailedState.SUSPENDED) {
// SUSPENDED state is currently only overridden from CONNECTED state. In the case the
// network agent is created, then goes to suspended, then goes out of suspended without
// ever setting connected. Check if network agent is ever connected to update the state.
newInfo.setDetailedState(nai.everConnected()
? NetworkInfo.DetailedState.CONNECTED
: NetworkInfo.DetailedState.CONNECTING,
info.getReason(),
info.getExtraInfo());
}
newInfo.setRoaming(!nai.networkCapabilities.hasCapability(NET_CAPABILITY_NOT_ROAMING));
return newInfo;
}
private void updateNetworkInfo(NetworkAgentInfo networkAgent, NetworkInfo info) {
final NetworkInfo newInfo = mixInInfo(networkAgent, info);
final NetworkInfo.State state = newInfo.getState();
NetworkInfo oldInfo = null;
synchronized (networkAgent) {
oldInfo = networkAgent.networkInfo;
networkAgent.networkInfo = newInfo;
}
if (DBG) {
log(networkAgent.toShortString() + " EVENT_NETWORK_INFO_CHANGED, going from "
+ oldInfo.getState() + " to " + state);
}
if (shouldCreateNativeNetwork(networkAgent, state)) {
// A network that has just connected has zero requests and is thus a foreground network.
networkAgent.networkCapabilities.addCapability(NET_CAPABILITY_FOREGROUND);
if (!createNativeNetwork(networkAgent)) return;
networkAgent.setCreated();
// If the network is created immediately on register, then apply the LinkProperties now.
// Otherwise, this is done further down when the network goes into connected state.
// Applying the LinkProperties means that the network is ready to carry traffic -
// interfaces and routing rules have been added, DNS servers programmed, etc.
// For VPNs, this must be done before the capabilities are updated, because as soon as
// that happens, UIDs are routed to the network.
if (shouldCreateNetworksImmediately()) {
applyInitialLinkProperties(networkAgent);
}
// TODO: should this move earlier? It doesn't seem to have anything to do with whether
// a network is created or not.
if (networkAgent.propagateUnderlyingCapabilities()) {
// Initialize the network's capabilities to their starting values according to the
// underlying networks. This ensures that the capabilities are correct before
// anything happens to the network.
updateCapabilitiesForNetwork(networkAgent);
}
networkAgent.onNetworkCreated();
updateAllowedUids(networkAgent, null, networkAgent.networkCapabilities);
updateProfileAllowedNetworks();
}
if (!networkAgent.everConnected() && state == NetworkInfo.State.CONNECTED) {
networkAgent.setConnected();
// NetworkCapabilities need to be set before sending the private DNS config to
// NetworkMonitor, otherwise NetworkMonitor cannot determine if validation is required.
networkAgent.getAndSetNetworkCapabilities(networkAgent.networkCapabilities);
handlePerNetworkPrivateDnsConfig(networkAgent, mDnsManager.getPrivateDnsConfig());
if (!shouldCreateNetworksImmediately()) {
applyInitialLinkProperties(networkAgent);
} else {
// The network was created when the agent registered, and the LinkProperties are
// already up-to-date. However, updateLinkProperties also makes some changes only
// when the network connects. Apply those changes here. On T and below these are
// handled by the applyInitialLinkProperties call just above.
// TODO: stop relying on updateLinkProperties(..., null) to do this.
// If something depends on both LinkProperties and connected state, it should be in
// this method as well.
networkAgent.clatd.update();
updateProxy(networkAgent.linkProperties, null);
}
// If a rate limit has been configured and is applicable to this network (network
// provides internet connectivity), apply it. The tc police filter cannot be attached
// before the clsact qdisc is added which happens as part of updateLinkProperties ->
// updateInterfaces -> RoutingCoordinatorManager#addInterfaceToNetwork
// Note: in case of a system server crash, the NetworkController constructor in netd
// (called when netd starts up) deletes the clsact qdisc of all interfaces.
if (canNetworkBeRateLimited(networkAgent) && mIngressRateLimit >= 0) {
mDeps.enableIngressRateLimit(networkAgent.linkProperties.getInterfaceName(),
mIngressRateLimit);
}
// Until parceled LinkProperties are sent directly to NetworkMonitor, the connect
// command must be sent after updating LinkProperties to maximize chances of
// NetworkMonitor seeing the correct LinkProperties when starting.
// TODO: pass LinkProperties to the NetworkMonitor in the notifyNetworkConnected call.
if (networkAgent.networkAgentConfig.acceptPartialConnectivity) {
networkAgent.networkMonitor().setAcceptPartialConnectivity();
}
final NetworkMonitorParameters params = new NetworkMonitorParameters();
params.networkAgentConfig = networkAgent.networkAgentConfig;
params.networkCapabilities = networkAgent.networkCapabilities;
params.linkProperties = new LinkProperties(networkAgent.linkProperties,
true /* parcelSensitiveFields */);
// isAtLeastT() is conservative here, as recent versions of NetworkStack support the
// newer callback even before T. However getInterfaceVersion is a synchronized binder
// call that would cause a Log.wtf to be emitted from the system_server process, and
// in the absence of a satisfactory, scalable solution which follows an easy/standard
// process to check the interface version, just use an SDK check. NetworkStack will
// always be new enough when running on T+.
if (mDeps.isAtLeastT()) {
networkAgent.networkMonitor().notifyNetworkConnected(params);
} else {
networkAgent.networkMonitor().notifyNetworkConnected(params.linkProperties,
params.networkCapabilities);
}
final long evaluationDelay;
if (!networkAgent.networkCapabilities.hasSingleTransport(TRANSPORT_WIFI)) {
// If the network is anything other than pure wifi, use the default timeout.
evaluationDelay = DEFAULT_EVALUATION_TIMEOUT_MS;
} else if (networkAgent.networkAgentConfig.isExplicitlySelected()) {
// If the network is explicitly selected, use the default timeout because it's
// shorter and the user is likely staring at the screen expecting it to validate
// right away.
evaluationDelay = DEFAULT_EVALUATION_TIMEOUT_MS;
} else if (avoidBadWifi() || !activelyPreferBadWifi()) {
// If avoiding bad wifi, or if not avoiding but also not preferring bad wifi
evaluationDelay = DEFAULT_EVALUATION_TIMEOUT_MS;
} else {
// It's wifi, automatically connected, and bad wifi is preferred : use the
// longer timeout to avoid the device switching to captive portals with bad
// signal or very slow response.
evaluationDelay = ACTIVELY_PREFER_BAD_WIFI_INITIAL_TIMEOUT_MS;
}
scheduleEvaluationTimeout(networkAgent.network, evaluationDelay);
// Whether a particular NetworkRequest listen should cause signal strength thresholds to
// be communicated to a particular NetworkAgent depends only on the network's immutable,
// capabilities, so it only needs to be done once on initial connect, not every time the
// network's capabilities change. Note that we do this before rematching the network,
// so we could decide to tear it down immediately afterwards. That's fine though - on
// disconnection NetworkAgents should stop any signal strength monitoring they have been
// doing.
updateSignalStrengthThresholds(networkAgent, "CONNECT", null);
// Before first rematching networks, put an inactivity timer without any request, this
// allows {@code updateInactivityState} to update the state accordingly and prevent
// tearing down for any {@code unneeded} evaluation in this period.
// Note that the timer will not be rescheduled since the expiry time is
// fixed after connection regardless of the network satisfying other requests or not.
// But it will be removed as soon as the network satisfies a request for the first time.
networkAgent.lingerRequest(NetworkRequest.REQUEST_ID_NONE,
SystemClock.elapsedRealtime(), mNascentDelayMs);
networkAgent.setInactive();
if (mTrackMultiNetworkActivities) {
// Start tracking activity of this network.
// This must be called before rematchAllNetworksAndRequests since the network
// should be tracked when the network becomes the default network.
// This method does not trigger any callbacks or broadcasts. Callbacks or broadcasts
// can be triggered later if this network becomes the default network.
mNetworkActivityTracker.setupDataActivityTracking(networkAgent);
}
// Consider network even though it is not yet validated.
rematchAllNetworksAndRequests();
// This has to happen after matching the requests, because callbacks are just requests.
notifyNetworkCallbacks(networkAgent, ConnectivityManager.CALLBACK_PRECHECK);
} else if (state == NetworkInfo.State.DISCONNECTED) {
networkAgent.disconnect();
if (networkAgent.isVPN()) {
updateVpnUids(networkAgent, networkAgent.networkCapabilities, null);
}
disconnectAndDestroyNetwork(networkAgent);
if (networkAgent.isVPN()) {
// As the active or bound network changes for apps, broadcast the default proxy, as
// apps may need to update their proxy data. This is called after disconnecting from
// VPN to make sure we do not broadcast the old proxy data.
// TODO(b/122649188): send the broadcast only to VPN users.
mProxyTracker.sendProxyBroadcast();
}
} else if (networkAgent.isCreated() && (oldInfo.getState() == NetworkInfo.State.SUSPENDED
|| state == NetworkInfo.State.SUSPENDED)) {
mLegacyTypeTracker.update(networkAgent);
}
}
private void updateNetworkScore(@NonNull final NetworkAgentInfo nai, final NetworkScore score) {
if (VDBG || DDBG) log("updateNetworkScore for " + nai.toShortString() + " to " + score);
nai.setScore(score);
rematchAllNetworksAndRequests();
}
// Notify only this one new request of the current state. Transfer all the
// current state by calling NetworkCapabilities and LinkProperties callbacks
// so that callers can be guaranteed to have as close to atomicity in state
// transfer as can be supported by this current API.
protected void notifyNetworkAvailable(NetworkAgentInfo nai, NetworkRequestInfo nri) {
mHandler.removeMessages(EVENT_TIMEOUT_NETWORK_REQUEST, nri);
if (nri.mPendingIntent != null) {
sendPendingIntentForRequest(nri, nai, ConnectivityManager.CALLBACK_AVAILABLE);
// Attempt no subsequent state pushes where intents are involved.
return;
}
final int blockedReasons = mUidBlockedReasons.get(nri.mAsUid, BLOCKED_REASON_NONE);
final boolean metered = nai.networkCapabilities.isMetered();
final boolean vpnBlocked = isUidBlockedByVpn(nri.mAsUid, mVpnBlockedUidRanges);
callCallbackForRequest(nri, nai, ConnectivityManager.CALLBACK_AVAILABLE,
getBlockedState(blockedReasons, metered, vpnBlocked));
}
// Notify the requests on this NAI that the network is now lingered.
private void notifyNetworkLosing(@NonNull final NetworkAgentInfo nai, final long now) {
final int lingerTime = (int) (nai.getInactivityExpiry() - now);
notifyNetworkCallbacks(nai, ConnectivityManager.CALLBACK_LOSING, lingerTime);
}
private static int getBlockedState(int reasons, boolean metered, boolean vpnBlocked) {
if (!metered) reasons &= ~BLOCKED_METERED_REASON_MASK;
return vpnBlocked
? reasons | BLOCKED_REASON_LOCKDOWN_VPN
: reasons & ~BLOCKED_REASON_LOCKDOWN_VPN;
}
private void setUidBlockedReasons(int uid, @BlockedReason int blockedReasons) {
if (blockedReasons == BLOCKED_REASON_NONE) {
mUidBlockedReasons.delete(uid);
} else {
mUidBlockedReasons.put(uid, blockedReasons);
}
}
/**
* Notify of the blocked state apps with a registered callback matching a given NAI.
*
* Unlike other callbacks, blocked status is different between each individual uid. So for
* any given nai, all requests need to be considered according to the uid who filed it.
*
* @param nai The target NetworkAgentInfo.
* @param oldMetered True if the previous network capabilities were metered.
* @param newMetered True if the current network capabilities are metered.
* @param oldBlockedUidRanges list of UID ranges previously blocked by lockdown VPN.
* @param newBlockedUidRanges list of UID ranges blocked by lockdown VPN.
*/
private void maybeNotifyNetworkBlocked(NetworkAgentInfo nai, boolean oldMetered,
boolean newMetered, List<UidRange> oldBlockedUidRanges,
List<UidRange> newBlockedUidRanges) {
for (int i = 0; i < nai.numNetworkRequests(); i++) {
NetworkRequest nr = nai.requestAt(i);
NetworkRequestInfo nri = mNetworkRequests.get(nr);
final int blockedReasons = mUidBlockedReasons.get(nri.mAsUid, BLOCKED_REASON_NONE);
final boolean oldVpnBlocked = isUidBlockedByVpn(nri.mAsUid, oldBlockedUidRanges);
final boolean newVpnBlocked = (oldBlockedUidRanges != newBlockedUidRanges)
? isUidBlockedByVpn(nri.mAsUid, newBlockedUidRanges)
: oldVpnBlocked;
final int oldBlockedState = getBlockedState(blockedReasons, oldMetered, oldVpnBlocked);
final int newBlockedState = getBlockedState(blockedReasons, newMetered, newVpnBlocked);
if (oldBlockedState != newBlockedState) {
callCallbackForRequest(nri, nai, ConnectivityManager.CALLBACK_BLK_CHANGED,
newBlockedState);
}
}
}
/**
* Notify apps with a given UID of the new blocked state according to new uid state.
* @param uid The uid for which the rules changed.
* @param blockedReasons The reasons for why an uid is blocked.
*/
private void maybeNotifyNetworkBlockedForNewState(int uid, @BlockedReason int blockedReasons) {
for (final NetworkAgentInfo nai : mNetworkAgentInfos) {
final boolean metered = nai.networkCapabilities.isMetered();
final boolean vpnBlocked = isUidBlockedByVpn(uid, mVpnBlockedUidRanges);
final int oldBlockedState = getBlockedState(
mUidBlockedReasons.get(uid, BLOCKED_REASON_NONE), metered, vpnBlocked);
final int newBlockedState = getBlockedState(blockedReasons, metered, vpnBlocked);
if (oldBlockedState == newBlockedState) {
continue;
}
for (int i = 0; i < nai.numNetworkRequests(); i++) {
NetworkRequest nr = nai.requestAt(i);
NetworkRequestInfo nri = mNetworkRequests.get(nr);
if (nri != null && nri.mAsUid == uid) {
callCallbackForRequest(nri, nai, ConnectivityManager.CALLBACK_BLK_CHANGED,
newBlockedState);
}
}
}
}
@VisibleForTesting
protected void sendLegacyNetworkBroadcast(NetworkAgentInfo nai, DetailedState state, int type) {
// The NetworkInfo we actually send out has no bearing on the real
// state of affairs. For example, if the default connection is mobile,
// and a request for HIPRI has just gone away, we need to pretend that
// HIPRI has just disconnected. So we need to set the type to HIPRI and
// the state to DISCONNECTED, even though the network is of type MOBILE
// and is still connected.
NetworkInfo info = new NetworkInfo(nai.networkInfo);
info.setType(type);
filterForLegacyLockdown(info);
if (state != DetailedState.DISCONNECTED) {
info.setDetailedState(state, null, info.getExtraInfo());
sendConnectedBroadcast(info);
} else {
info.setDetailedState(state, info.getReason(), info.getExtraInfo());
Intent intent = new Intent(ConnectivityManager.CONNECTIVITY_ACTION);
intent.putExtra(ConnectivityManager.EXTRA_NETWORK_INFO, info);
intent.putExtra(ConnectivityManager.EXTRA_NETWORK_TYPE, info.getType());
if (info.isFailover()) {
intent.putExtra(ConnectivityManager.EXTRA_IS_FAILOVER, true);
nai.networkInfo.setFailover(false);
}
if (info.getReason() != null) {
intent.putExtra(ConnectivityManager.EXTRA_REASON, info.getReason());
}
if (info.getExtraInfo() != null) {
intent.putExtra(ConnectivityManager.EXTRA_EXTRA_INFO, info.getExtraInfo());
}
NetworkAgentInfo newDefaultAgent = null;
if (nai.isSatisfyingRequest(mDefaultRequest.mRequests.get(0).requestId)) {
newDefaultAgent = mDefaultRequest.getSatisfier();
if (newDefaultAgent != null) {
intent.putExtra(ConnectivityManager.EXTRA_OTHER_NETWORK_INFO,
newDefaultAgent.networkInfo);
} else {
intent.putExtra(ConnectivityManager.EXTRA_NO_CONNECTIVITY, true);
}
}
intent.putExtra(ConnectivityManager.EXTRA_INET_CONDITION,
mDefaultInetConditionPublished);
sendStickyBroadcast(intent);
if (newDefaultAgent != null) {
sendConnectedBroadcast(newDefaultAgent.networkInfo);
}
}
}
protected void notifyNetworkCallbacks(NetworkAgentInfo networkAgent, int notifyType, int arg1) {
if (VDBG || DDBG) {
String notification = ConnectivityManager.getCallbackName(notifyType);
log("notifyType " + notification + " for " + networkAgent.toShortString());
}
for (int i = 0; i < networkAgent.numNetworkRequests(); i++) {
NetworkRequest nr = networkAgent.requestAt(i);
NetworkRequestInfo nri = mNetworkRequests.get(nr);
if (VDBG) log(" sending notification for " + nr);
if (nri.mPendingIntent == null) {
callCallbackForRequest(nri, networkAgent, notifyType, arg1);
} else {
sendPendingIntentForRequest(nri, networkAgent, notifyType);
}
}
}
protected void notifyNetworkCallbacks(NetworkAgentInfo networkAgent, int notifyType) {
notifyNetworkCallbacks(networkAgent, notifyType, 0);
}
/**
* Returns the list of all interfaces that could be used by network traffic that does not
* explicitly specify a network. This includes the default network, but also all VPNs that are
* currently connected.
*
* Must be called on the handler thread.
*/
@NonNull
private ArrayList<Network> getDefaultNetworks() {
ensureRunningOnConnectivityServiceThread();
final ArrayList<Network> defaultNetworks = new ArrayList<>();
final Set<Integer> activeNetIds = new ArraySet<>();
for (final NetworkRequestInfo nri : mDefaultNetworkRequests) {
if (nri.isBeingSatisfied()) {
activeNetIds.add(nri.getSatisfier().network().netId);
}
}
for (NetworkAgentInfo nai : mNetworkAgentInfos) {
if (activeNetIds.contains(nai.network().netId) || nai.isVPN()) {
defaultNetworks.add(nai.network);
}
}
return defaultNetworks;
}
/**
* Notify NetworkStatsService that the set of active ifaces has changed, or that one of the
* active iface's tracked properties has changed.
*/
private void notifyIfacesChangedForNetworkStats() {
ensureRunningOnConnectivityServiceThread();
String activeIface = null;
LinkProperties activeLinkProperties = getActiveLinkProperties();
if (activeLinkProperties != null) {
activeIface = activeLinkProperties.getInterfaceName();
}
final UnderlyingNetworkInfo[] underlyingNetworkInfos = getAllVpnInfo();
try {
final ArrayList<NetworkStateSnapshot> snapshots = new ArrayList<>();
snapshots.addAll(getAllNetworkStateSnapshots());
mStatsManager.notifyNetworkStatus(getDefaultNetworks(),
snapshots, activeIface, Arrays.asList(underlyingNetworkInfos));
} catch (Exception ignored) {
}
}
@Override
public String getCaptivePortalServerUrl() {
enforceNetworkStackOrSettingsPermission();
String settingUrl = mResources.get().getString(
R.string.config_networkCaptivePortalServerUrl);
if (!TextUtils.isEmpty(settingUrl)) {
return settingUrl;
}
settingUrl = Settings.Global.getString(mContext.getContentResolver(),
ConnectivitySettingsManager.CAPTIVE_PORTAL_HTTP_URL);
if (!TextUtils.isEmpty(settingUrl)) {
return settingUrl;
}
return DEFAULT_CAPTIVE_PORTAL_HTTP_URL;
}
@Override
public void startNattKeepalive(Network network, int intervalSeconds,
ISocketKeepaliveCallback cb, String srcAddr, int srcPort, String dstAddr) {
enforceKeepalivePermission();
mKeepaliveTracker.startNattKeepalive(
getNetworkAgentInfoForNetwork(network), null /* fd */,
intervalSeconds, cb, srcAddr, srcPort, dstAddr, NattSocketKeepalive.NATT_PORT,
// Keep behavior of the deprecated method as it is. Set automaticOnOffKeepalives to
// false and set the underpinned network to null because there is no way and no
// plan to configure automaticOnOffKeepalives or underpinnedNetwork in this
// deprecated method.
false /* automaticOnOffKeepalives */, null /* underpinnedNetwork */);
}
@Override
public void startNattKeepaliveWithFd(Network network, ParcelFileDescriptor pfd, int resourceId,
int intervalSeconds, ISocketKeepaliveCallback cb, String srcAddr,
String dstAddr, boolean automaticOnOffKeepalives, Network underpinnedNetwork) {
try {
final FileDescriptor fd = pfd.getFileDescriptor();
mKeepaliveTracker.startNattKeepalive(
getNetworkAgentInfoForNetwork(network), fd, resourceId,
intervalSeconds, cb, srcAddr, dstAddr, NattSocketKeepalive.NATT_PORT,
automaticOnOffKeepalives, underpinnedNetwork);
} finally {
// FileDescriptors coming from AIDL calls must be manually closed to prevent leaks.
// startNattKeepalive calls Os.dup(fd) before returning, so we can close immediately.
if (pfd != null && Binder.getCallingPid() != Process.myPid()) {
IoUtils.closeQuietly(pfd);
}
}
}
@Override
public void startTcpKeepalive(Network network, ParcelFileDescriptor pfd, int intervalSeconds,
ISocketKeepaliveCallback cb) {
try {
enforceKeepalivePermission();
final FileDescriptor fd = pfd.getFileDescriptor();
mKeepaliveTracker.startTcpKeepalive(
getNetworkAgentInfoForNetwork(network), fd, intervalSeconds, cb);
} finally {
// FileDescriptors coming from AIDL calls must be manually closed to prevent leaks.
// startTcpKeepalive calls Os.dup(fd) before returning, so we can close immediately.
if (pfd != null && Binder.getCallingPid() != Process.myPid()) {
IoUtils.closeQuietly(pfd);
}
}
}
@Override
public void stopKeepalive(@NonNull final ISocketKeepaliveCallback cb) {
mHandler.sendMessage(mHandler.obtainMessage(
NetworkAgent.CMD_STOP_SOCKET_KEEPALIVE, 0, SocketKeepalive.SUCCESS,
Objects.requireNonNull(cb).asBinder()));
}
@Override
public int[] getSupportedKeepalives() {
enforceAnyPermissionOf(mContext, android.Manifest.permission.NETWORK_SETTINGS,
// Backwards compatibility with CTS 13
android.Manifest.permission.QUERY_ALL_PACKAGES);
return BinderUtils.withCleanCallingIdentity(() ->
KeepaliveResourceUtil.getSupportedKeepalives(mContext));
}
@Override
public void factoryReset() {
enforceSettingsPermission();
final int uid = mDeps.getCallingUid();
final long token = Binder.clearCallingIdentity();
try {
if (mUserManager.hasUserRestrictionForUser(UserManager.DISALLOW_NETWORK_RESET,
UserHandle.getUserHandleForUid(uid))) {
return;
}
final IpMemoryStore ipMemoryStore = IpMemoryStore.getMemoryStore(mContext);
ipMemoryStore.factoryReset();
// Turn airplane mode off
setAirplaneMode(false);
// restore private DNS settings to default mode (opportunistic)
if (!mUserManager.hasUserRestrictionForUser(UserManager.DISALLOW_CONFIG_PRIVATE_DNS,
UserHandle.getUserHandleForUid(uid))) {
ConnectivitySettingsManager.setPrivateDnsMode(mContext,
PRIVATE_DNS_MODE_OPPORTUNISTIC);
}
Settings.Global.putString(mContext.getContentResolver(),
ConnectivitySettingsManager.NETWORK_AVOID_BAD_WIFI, null);
} finally {
Binder.restoreCallingIdentity(token);
}
}
@Override
public byte[] getNetworkWatchlistConfigHash() {
NetworkWatchlistManager nwm = mContext.getSystemService(NetworkWatchlistManager.class);
if (nwm == null) {
loge("Unable to get NetworkWatchlistManager");
return null;
}
// Redirect it to network watchlist service to access watchlist file and calculate hash.
return nwm.getWatchlistConfigHash();
}
private void logNetworkEvent(NetworkAgentInfo nai, int evtype) {
int[] transports = nai.networkCapabilities.getTransportTypes();
mMetricsLog.log(nai.network.getNetId(), transports, new NetworkEvent(evtype));
}
private static boolean toBool(int encodedBoolean) {
return encodedBoolean != 0; // Only 0 means false.
}
private static int encodeBool(boolean b) {
return b ? 1 : 0;
}
@Override
public int handleShellCommand(@NonNull ParcelFileDescriptor in,
@NonNull ParcelFileDescriptor out, @NonNull ParcelFileDescriptor err,
@NonNull String[] args) {
return new ShellCmd().exec(this, in.getFileDescriptor(), out.getFileDescriptor(),
err.getFileDescriptor(), args);
}
private Boolean parseBooleanArgument(final String arg) {
if ("true".equals(arg)) {
return true;
} else if ("false".equals(arg)) {
return false;
} else {
return null;
}
}
private class ShellCmd extends BasicShellCommandHandler {
@Override
public int onCommand(String cmd) {
if (cmd == null) {
return handleDefaultCommands(cmd);
}
final PrintWriter pw = getOutPrintWriter();
try {
switch (cmd) {
case "airplane-mode":
// Usage : adb shell cmd connectivity airplane-mode [enable|disable]
// If no argument, get and display the current status
final String action = getNextArg();
if ("enable".equals(action)) {
setAirplaneMode(true);
return 0;
} else if ("disable".equals(action)) {
setAirplaneMode(false);
return 0;
} else if (action == null) {
final ContentResolver cr = mContext.getContentResolver();
final int enabled = Settings.Global.getInt(cr,
Settings.Global.AIRPLANE_MODE_ON);
pw.println(enabled == 0 ? "disabled" : "enabled");
return 0;
} else {
onHelp();
return -1;
}
case "set-chain3-enabled": {
final Boolean enabled = parseBooleanArgument(getNextArg());
if (null == enabled) {
onHelp();
return -1;
}
Log.i(TAG, (enabled ? "En" : "Dis") + "abled FIREWALL_CHAIN_OEM_DENY_3");
setFirewallChainEnabled(ConnectivityManager.FIREWALL_CHAIN_OEM_DENY_3,
enabled);
return 0;
}
case "get-chain3-enabled": {
final boolean chainEnabled = getFirewallChainEnabled(
ConnectivityManager.FIREWALL_CHAIN_OEM_DENY_3);
pw.println("chain:" + (chainEnabled ? "enabled" : "disabled"));
return 0;
}
case "set-package-networking-enabled": {
final Boolean enabled = parseBooleanArgument(getNextArg());
final String packageName = getNextArg();
if (null == enabled || null == packageName) {
onHelp();
return -1;
}
// Throws NameNotFound if the package doesn't exist.
final int appId = setPackageFirewallRule(
ConnectivityManager.FIREWALL_CHAIN_OEM_DENY_3,
packageName, enabled ? FIREWALL_RULE_DEFAULT : FIREWALL_RULE_DENY);
final String msg = (enabled ? "Enabled" : "Disabled")
+ " networking for " + packageName + ", appId " + appId;
Log.i(TAG, msg);
pw.println(msg);
return 0;
}
case "get-package-networking-enabled": {
final String packageName = getNextArg();
final int rule = getPackageFirewallRule(
ConnectivityManager.FIREWALL_CHAIN_OEM_DENY_3, packageName);
if (FIREWALL_RULE_ALLOW == rule || FIREWALL_RULE_DEFAULT == rule) {
pw.println(packageName + ":" + "allow");
} else if (FIREWALL_RULE_DENY == rule) {
pw.println(packageName + ":" + "deny");
} else {
throw new IllegalStateException("Unknown rule " + rule + " for package "
+ packageName);
}
return 0;
}
case "reevaluate":
// Usage : adb shell cmd connectivity reevaluate <netId>
// If netId is omitted, then reevaluate the default network
final String netId = getNextArg();
final NetworkAgentInfo nai;
if (null == netId) {
// Note that the command is running on the wrong thread to call this,
// so this could in principle return stale data. But it can't crash.
nai = getDefaultNetwork();
} else {
// If netId can't be parsed, this throws NumberFormatException, which
// is passed back to adb who prints it.
nai = getNetworkAgentInfoForNetId(Integer.parseInt(netId));
}
if (null == nai) {
pw.println("Unknown network (net ID not found or no default network)");
return 0;
}
Log.d(TAG, "Reevaluating network " + nai.network);
reportNetworkConnectivity(nai.network, !nai.isValidated());
return 0;
case "bpf-get-cgroup-program-id": {
// Usage : adb shell cmd connectivity bpf-get-cgroup-program-id <type>
// Get cgroup bpf program Id for the given type. See BpfUtils#getProgramId
// for more detail.
// If type can't be parsed, this throws NumberFormatException, which
// is passed back to adb who prints it.
final int type = Integer.parseInt(getNextArg());
final int ret = BpfUtils.getProgramId(type);
pw.println(ret);
return 0;
}
default:
return handleDefaultCommands(cmd);
}
} catch (Exception e) {
pw.println(e);
}
return -1;
}
@Override
public void onHelp() {
PrintWriter pw = getOutPrintWriter();
pw.println("Connectivity service commands:");
pw.println(" help");
pw.println(" Print this help text.");
pw.println(" airplane-mode [enable|disable]");
pw.println(" Turn airplane mode on or off.");
pw.println(" airplane-mode");
pw.println(" Get airplane mode.");
pw.println(" set-chain3-enabled [true|false]");
pw.println(" Enable or disable FIREWALL_CHAIN_OEM_DENY_3 for debugging.");
pw.println(" get-chain3-enabled");
pw.println(" Returns whether FIREWALL_CHAIN_OEM_DENY_3 is enabled.");
pw.println(" set-package-networking-enabled [true|false] [package name]");
pw.println(" Set the deny bit in FIREWALL_CHAIN_OEM_DENY_3 to package. This has\n"
+ " no effect if the chain is disabled.");
pw.println(" get-package-networking-enabled [package name]");
pw.println(" Get the deny bit in FIREWALL_CHAIN_OEM_DENY_3 for package.");
}
}
private int getVpnType(@Nullable NetworkAgentInfo vpn) {
if (vpn == null) return VpnManager.TYPE_VPN_NONE;
final TransportInfo ti = vpn.networkCapabilities.getTransportInfo();
if (!(ti instanceof VpnTransportInfo)) return VpnManager.TYPE_VPN_NONE;
return ((VpnTransportInfo) ti).getType();
}
private void maybeUpdateWifiRoamTimestamp(@NonNull NetworkAgentInfo nai,
@NonNull NetworkCapabilities nc) {
final TransportInfo prevInfo = nai.networkCapabilities.getTransportInfo();
final TransportInfo newInfo = nc.getTransportInfo();
if (!(prevInfo instanceof WifiInfo) || !(newInfo instanceof WifiInfo)) {
return;
}
if (!TextUtils.equals(((WifiInfo)prevInfo).getBSSID(), ((WifiInfo)newInfo).getBSSID())) {
nai.lastRoamTime = SystemClock.elapsedRealtime();
}
}
/**
* @param connectionInfo the connection to resolve.
* @return {@code uid} if the connection is found and the app has permission to observe it
* (e.g., if it is associated with the calling VPN app's tunnel) or {@code INVALID_UID} if the
* connection is not found.
*/
public int getConnectionOwnerUid(ConnectionInfo connectionInfo) {
if (connectionInfo.protocol != IPPROTO_TCP && connectionInfo.protocol != IPPROTO_UDP) {
throw new IllegalArgumentException("Unsupported protocol " + connectionInfo.protocol);
}
final int uid = mDeps.getConnectionOwnerUid(connectionInfo.protocol,
connectionInfo.local, connectionInfo.remote);
if (uid == INVALID_UID) return uid; // Not found.
// Connection owner UIDs are visible only to the network stack and to the VpnService-based
// VPN, if any, that applies to the UID that owns the connection.
if (checkNetworkStackPermission()) return uid;
final NetworkAgentInfo vpn = getVpnForUid(uid);
if (vpn == null || getVpnType(vpn) != VpnManager.TYPE_VPN_SERVICE
|| vpn.networkCapabilities.getOwnerUid() != mDeps.getCallingUid()) {
return INVALID_UID;
}
return uid;
}
/**
* Returns a IBinder to a TestNetworkService. Will be lazily created as needed.
*
* <p>The TestNetworkService must be run in the system server due to TUN creation.
*/
@Override
public IBinder startOrGetTestNetworkService() {
synchronized (mTNSLock) {
TestNetworkService.enforceTestNetworkPermissions(mContext);
if (mTNS == null) {
mTNS = new TestNetworkService(mContext);
}
return mTNS;
}
}
/**
* Handler used for managing all Connectivity Diagnostics related functions.
*
* @see android.net.ConnectivityDiagnosticsManager
*
* TODO(b/147816404): Explore moving ConnectivityDiagnosticsHandler to a separate file
*/
@VisibleForTesting
class ConnectivityDiagnosticsHandler extends Handler {
private final String mTag = ConnectivityDiagnosticsHandler.class.getSimpleName();
/**
* Used to handle ConnectivityDiagnosticsCallback registration events from {@link
* android.net.ConnectivityDiagnosticsManager}.
* obj = ConnectivityDiagnosticsCallbackInfo with IConnectivityDiagnosticsCallback and
* NetworkRequestInfo to be registered
*/
private static final int EVENT_REGISTER_CONNECTIVITY_DIAGNOSTICS_CALLBACK = 1;
/**
* Used to handle ConnectivityDiagnosticsCallback unregister events from {@link
* android.net.ConnectivityDiagnosticsManager}.
* obj = the IConnectivityDiagnosticsCallback to be unregistered
* arg1 = the uid of the caller
*/
private static final int EVENT_UNREGISTER_CONNECTIVITY_DIAGNOSTICS_CALLBACK = 2;
/**
* Event for {@link NetworkStateTrackerHandler} to trigger ConnectivityReport callbacks
* after processing {@link #CMD_SEND_CONNECTIVITY_REPORT} events.
* obj = {@link ConnectivityReportEvent} representing ConnectivityReport info reported from
* NetworkMonitor.
* data = PersistableBundle of extras passed from NetworkMonitor.
*/
private static final int CMD_SEND_CONNECTIVITY_REPORT = 3;
/**
* Event for NetworkMonitor to inform ConnectivityService that a potential data stall has
* been detected on the network.
* obj = Long the timestamp (in millis) for when the suspected data stall was detected.
* arg1 = {@link DataStallReport#DetectionMethod} indicating the detection method.
* arg2 = NetID.
* data = PersistableBundle of extras passed from NetworkMonitor.
*/
private static final int EVENT_DATA_STALL_SUSPECTED = 4;
/**
* Event for ConnectivityDiagnosticsHandler to handle network connectivity being reported to
* the platform. This event will invoke {@link
* IConnectivityDiagnosticsCallback#onNetworkConnectivityReported} for permissioned
* callbacks.
* obj = ReportedNetworkConnectivityInfo with info on reported Network connectivity.
*/
private static final int EVENT_NETWORK_CONNECTIVITY_REPORTED = 5;
private ConnectivityDiagnosticsHandler(Looper looper) {
super(looper);
}
@Override
public void handleMessage(Message msg) {
switch (msg.what) {
case EVENT_REGISTER_CONNECTIVITY_DIAGNOSTICS_CALLBACK: {
handleRegisterConnectivityDiagnosticsCallback(
(ConnectivityDiagnosticsCallbackInfo) msg.obj);
break;
}
case EVENT_UNREGISTER_CONNECTIVITY_DIAGNOSTICS_CALLBACK: {
handleUnregisterConnectivityDiagnosticsCallback(
(IConnectivityDiagnosticsCallback) msg.obj, msg.arg1);
break;
}
case CMD_SEND_CONNECTIVITY_REPORT: {
final ConnectivityReportEvent reportEvent =
(ConnectivityReportEvent) msg.obj;
handleNetworkTestedWithExtras(reportEvent, reportEvent.mExtras);
break;
}
case EVENT_DATA_STALL_SUSPECTED: {
final NetworkAgentInfo nai = getNetworkAgentInfoForNetId(msg.arg2);
final Pair<Long, PersistableBundle> arg =
(Pair<Long, PersistableBundle>) msg.obj;
if (nai == null) break;
handleDataStallSuspected(nai, arg.first, msg.arg1, arg.second);
break;
}
case EVENT_NETWORK_CONNECTIVITY_REPORTED: {
handleNetworkConnectivityReported((ReportedNetworkConnectivityInfo) msg.obj);
break;
}
default: {
Log.e(mTag, "Unrecognized event in ConnectivityDiagnostics: " + msg.what);
}
}
}
}
/** Class used for cleaning up IConnectivityDiagnosticsCallback instances after their death. */
@VisibleForTesting
class ConnectivityDiagnosticsCallbackInfo implements Binder.DeathRecipient {
@NonNull private final IConnectivityDiagnosticsCallback mCb;
@NonNull private final NetworkRequestInfo mRequestInfo;
@NonNull private final String mCallingPackageName;
@VisibleForTesting
ConnectivityDiagnosticsCallbackInfo(
@NonNull IConnectivityDiagnosticsCallback cb,
@NonNull NetworkRequestInfo nri,
@NonNull String callingPackageName) {
mCb = cb;
mRequestInfo = nri;
mCallingPackageName = callingPackageName;
}
@Override
public void binderDied() {
log("ConnectivityDiagnosticsCallback IBinder died.");
unregisterConnectivityDiagnosticsCallback(mCb);
}
}
/**
* Class used for sending information from {@link
* NetworkMonitorCallbacks#notifyNetworkTestedWithExtras} to the handler for processing it.
*/
private static class NetworkTestedResults {
private final int mNetId;
private final int mTestResult;
@Nullable private final String mRedirectUrl;
private NetworkTestedResults(
int netId, int testResult, long timestampMillis, @Nullable String redirectUrl) {
mNetId = netId;
mTestResult = testResult;
mRedirectUrl = redirectUrl;
}
}
/**
* Class used for sending information from {@link NetworkStateTrackerHandler} to {@link
* ConnectivityDiagnosticsHandler}.
*/
private static class ConnectivityReportEvent {
private final long mTimestampMillis;
@NonNull private final NetworkAgentInfo mNai;
private final PersistableBundle mExtras;
private ConnectivityReportEvent(long timestampMillis, @NonNull NetworkAgentInfo nai,
PersistableBundle p) {
mTimestampMillis = timestampMillis;
mNai = nai;
mExtras = p;
}
}
/**
* Class used for sending info for a call to {@link #reportNetworkConnectivity()} to {@link
* ConnectivityDiagnosticsHandler}.
*/
private static class ReportedNetworkConnectivityInfo {
public final boolean hasConnectivity;
public final boolean isNetworkRevalidating;
public final int reporterUid;
@NonNull public final NetworkAgentInfo nai;
private ReportedNetworkConnectivityInfo(
boolean hasConnectivity,
boolean isNetworkRevalidating,
int reporterUid,
@NonNull NetworkAgentInfo nai) {
this.hasConnectivity = hasConnectivity;
this.isNetworkRevalidating = isNetworkRevalidating;
this.reporterUid = reporterUid;
this.nai = nai;
}
}
private void handleRegisterConnectivityDiagnosticsCallback(
@NonNull ConnectivityDiagnosticsCallbackInfo cbInfo) {
ensureRunningOnConnectivityServiceThread();
final IConnectivityDiagnosticsCallback cb = cbInfo.mCb;
final IBinder iCb = cb.asBinder();
final NetworkRequestInfo nri = cbInfo.mRequestInfo;
// Connectivity Diagnostics are meant to be used with a single network request. It would be
// confusing for these networks to change when an NRI is satisfied in another layer.
if (nri.isMultilayerRequest()) {
throw new IllegalArgumentException("Connectivity Diagnostics do not support multilayer "
+ "network requests.");
}
// This means that the client registered the same callback multiple times. Do
// not override the previous entry, and exit silently.
if (mConnectivityDiagnosticsCallbacks.containsKey(iCb)) {
if (VDBG) log("Diagnostics callback is already registered");
// Decrement the reference count for this NetworkRequestInfo. The reference count is
// incremented when the NetworkRequestInfo is created as part of
// enforceRequestCountLimit().
nri.mPerUidCounter.decrementCount(nri.mUid);
return;
}
mConnectivityDiagnosticsCallbacks.put(iCb, cbInfo);
try {
iCb.linkToDeath(cbInfo, 0);
} catch (RemoteException e) {
cbInfo.binderDied();
return;
}
// Once registered, provide ConnectivityReports for matching Networks
final List<NetworkAgentInfo> matchingNetworks = new ArrayList<>();
synchronized (mNetworkForNetId) {
for (int i = 0; i < mNetworkForNetId.size(); i++) {
final NetworkAgentInfo nai = mNetworkForNetId.valueAt(i);
// Connectivity Diagnostics rejects multilayer requests at registration hence get(0)
if (nai.satisfies(nri.mRequests.get(0))) {
matchingNetworks.add(nai);
}
}
}
for (final NetworkAgentInfo nai : matchingNetworks) {
final ConnectivityReport report = nai.getConnectivityReport();
if (report == null) {
continue;
}
if (!checkConnectivityDiagnosticsPermissions(
nri.mPid, nri.mUid, nai, cbInfo.mCallingPackageName)) {
continue;
}
try {
cb.onConnectivityReportAvailable(report);
} catch (RemoteException e) {
// Exception while sending the ConnectivityReport. Move on to the next network.
}
}
}
private void handleUnregisterConnectivityDiagnosticsCallback(
@NonNull IConnectivityDiagnosticsCallback cb, int uid) {
ensureRunningOnConnectivityServiceThread();
final IBinder iCb = cb.asBinder();
final ConnectivityDiagnosticsCallbackInfo cbInfo =
mConnectivityDiagnosticsCallbacks.remove(iCb);
if (cbInfo == null) {
if (VDBG) log("Removing diagnostics callback that is not currently registered");
return;
}
final NetworkRequestInfo nri = cbInfo.mRequestInfo;
// Caller's UID must either be the registrants (if they are unregistering) or the System's
// (if the Binder died)
if (uid != nri.mUid && uid != Process.SYSTEM_UID) {
if (DBG) loge("Uid(" + uid + ") not registrant's (" + nri.mUid + ") or System's");
return;
}
// Decrement the reference count for this NetworkRequestInfo. The reference count is
// incremented when the NetworkRequestInfo is created as part of
// enforceRequestCountLimit().
nri.mPerUidCounter.decrementCount(nri.mUid);
iCb.unlinkToDeath(cbInfo, 0);
}
private void handleNetworkTestedWithExtras(
@NonNull ConnectivityReportEvent reportEvent, @NonNull PersistableBundle extras) {
final NetworkAgentInfo nai = reportEvent.mNai;
final NetworkCapabilities networkCapabilities =
getNetworkCapabilitiesWithoutUids(nai.networkCapabilities);
final ConnectivityReport report =
new ConnectivityReport(
reportEvent.mNai.network,
reportEvent.mTimestampMillis,
nai.linkProperties,
networkCapabilities,
extras);
nai.setConnectivityReport(report);
final List<IConnectivityDiagnosticsCallback> results =
getMatchingPermissionedCallbacks(nai, Process.INVALID_UID);
for (final IConnectivityDiagnosticsCallback cb : results) {
try {
cb.onConnectivityReportAvailable(report);
} catch (RemoteException ex) {
loge("Error invoking onConnectivityReportAvailable", ex);
}
}
}
private void handleDataStallSuspected(
@NonNull NetworkAgentInfo nai, long timestampMillis, int detectionMethod,
@NonNull PersistableBundle extras) {
final NetworkCapabilities networkCapabilities =
getNetworkCapabilitiesWithoutUids(nai.networkCapabilities);
final DataStallReport report =
new DataStallReport(
nai.network,
timestampMillis,
detectionMethod,
nai.linkProperties,
networkCapabilities,
extras);
final List<IConnectivityDiagnosticsCallback> results =
getMatchingPermissionedCallbacks(nai, Process.INVALID_UID);
for (final IConnectivityDiagnosticsCallback cb : results) {
try {
cb.onDataStallSuspected(report);
} catch (RemoteException ex) {
loge("Error invoking onDataStallSuspected", ex);
}
}
}
private void handleNetworkConnectivityReported(
@NonNull ReportedNetworkConnectivityInfo reportedNetworkConnectivityInfo) {
final NetworkAgentInfo nai = reportedNetworkConnectivityInfo.nai;
final ConnectivityReport cachedReport = nai.getConnectivityReport();
// If the Network is being re-validated as a result of this call to
// reportNetworkConnectivity(), notify all permissioned callbacks. Otherwise, only notify
// permissioned callbacks registered by the reporter.
final List<IConnectivityDiagnosticsCallback> results =
getMatchingPermissionedCallbacks(
nai,
reportedNetworkConnectivityInfo.isNetworkRevalidating
? Process.INVALID_UID
: reportedNetworkConnectivityInfo.reporterUid);
for (final IConnectivityDiagnosticsCallback cb : results) {
try {
cb.onNetworkConnectivityReported(
nai.network, reportedNetworkConnectivityInfo.hasConnectivity);
} catch (RemoteException ex) {
loge("Error invoking onNetworkConnectivityReported", ex);
}
// If the Network isn't re-validating, also provide the cached report. If there is no
// cached report, the Network is still being validated and a report will be sent once
// validation is complete. Note that networks which never undergo validation will still
// have a cached ConnectivityReport with RESULT_SKIPPED.
if (!reportedNetworkConnectivityInfo.isNetworkRevalidating && cachedReport != null) {
try {
cb.onConnectivityReportAvailable(cachedReport);
} catch (RemoteException ex) {
loge("Error invoking onConnectivityReportAvailable", ex);
}
}
}
}
private NetworkCapabilities getNetworkCapabilitiesWithoutUids(@NonNull NetworkCapabilities nc) {
final NetworkCapabilities sanitized = new NetworkCapabilities(nc,
NetworkCapabilities.REDACT_ALL);
sanitized.setUids(null);
sanitized.setAdministratorUids(new int[0]);
sanitized.setOwnerUid(Process.INVALID_UID);
return sanitized;
}
/**
* Gets a list of ConnectivityDiagnostics callbacks that match the specified Network and uid.
*
* <p>If Process.INVALID_UID is specified, all matching callbacks will be returned.
*/
private List<IConnectivityDiagnosticsCallback> getMatchingPermissionedCallbacks(
@NonNull NetworkAgentInfo nai, int uid) {
final List<IConnectivityDiagnosticsCallback> results = new ArrayList<>();
for (Entry<IBinder, ConnectivityDiagnosticsCallbackInfo> entry :
mConnectivityDiagnosticsCallbacks.entrySet()) {
final ConnectivityDiagnosticsCallbackInfo cbInfo = entry.getValue();
final NetworkRequestInfo nri = cbInfo.mRequestInfo;
// Connectivity Diagnostics rejects multilayer requests at registration hence get(0).
if (!nai.satisfies(nri.mRequests.get(0))) {
continue;
}
// UID for this callback must either be:
// - INVALID_UID (which sends callbacks to all UIDs), or
// - The callback's owner (the owner called reportNetworkConnectivity() and is being
// notified as a result)
if (uid != Process.INVALID_UID && uid != nri.mUid) {
continue;
}
if (!checkConnectivityDiagnosticsPermissions(
nri.mPid, nri.mUid, nai, cbInfo.mCallingPackageName)) {
continue;
}
results.add(entry.getValue().mCb);
}
return results;
}
private boolean isLocationPermissionRequiredForConnectivityDiagnostics(
@NonNull NetworkAgentInfo nai) {
// TODO(b/188483916): replace with a transport-agnostic location-aware check
return nai.networkCapabilities.hasTransport(TRANSPORT_WIFI);
}
private boolean hasLocationPermission(String packageName, int uid) {
// LocationPermissionChecker#checkLocationPermission can throw SecurityException if the uid
// and package name don't match. Throwing on the CS thread is not acceptable, so wrap the
// call in a try-catch.
try {
if (!mLocationPermissionChecker.checkLocationPermission(
packageName, null /* featureId */, uid, null /* message */)) {
return false;
}
} catch (SecurityException e) {
return false;
}
return true;
}
private boolean ownsVpnRunningOverNetwork(int uid, Network network) {
for (NetworkAgentInfo virtual : mNetworkAgentInfos) {
if (virtual.propagateUnderlyingCapabilities()
&& virtual.networkCapabilities.getOwnerUid() == uid
&& CollectionUtils.contains(virtual.declaredUnderlyingNetworks, network)) {
return true;
}
}
return false;
}
@VisibleForTesting
boolean checkConnectivityDiagnosticsPermissions(
int callbackPid, int callbackUid, NetworkAgentInfo nai, String callbackPackageName) {
if (checkNetworkStackPermission(callbackPid, callbackUid)) {
return true;
}
if (mAllowSysUiConnectivityReports
&& checkSystemBarServicePermission(callbackPid, callbackUid)) {
return true;
}
// Administrator UIDs also contains the Owner UID
final int[] administratorUids = nai.networkCapabilities.getAdministratorUids();
if (!CollectionUtils.contains(administratorUids, callbackUid)
&& !ownsVpnRunningOverNetwork(callbackUid, nai.network)) {
return false;
}
return !isLocationPermissionRequiredForConnectivityDiagnostics(nai)
|| hasLocationPermission(callbackPackageName, callbackUid);
}
@Override
public void registerConnectivityDiagnosticsCallback(
@NonNull IConnectivityDiagnosticsCallback callback,
@NonNull NetworkRequest request,
@NonNull String callingPackageName) {
Objects.requireNonNull(callback, "callback must not be null");
Objects.requireNonNull(request, "request must not be null");
Objects.requireNonNull(callingPackageName, "callingPackageName must not be null");
if (request.legacyType != TYPE_NONE) {
throw new IllegalArgumentException("ConnectivityManager.TYPE_* are deprecated."
+ " Please use NetworkCapabilities instead.");
}
final int callingUid = mDeps.getCallingUid();
mAppOpsManager.checkPackage(callingUid, callingPackageName);
// This NetworkCapabilities is only used for matching to Networks. Clear out its owner uid
// and administrator uids to be safe.
final NetworkCapabilities nc = new NetworkCapabilities(request.networkCapabilities);
restrictRequestUidsForCallerAndSetRequestorInfo(nc, callingUid, callingPackageName);
final NetworkRequest requestWithId =
new NetworkRequest(
nc, TYPE_NONE, nextNetworkRequestId(), NetworkRequest.Type.LISTEN);
// NetworkRequestInfos created here count towards MAX_NETWORK_REQUESTS_PER_UID limit.
//
// nri is not bound to the death of callback. Instead, callback.bindToDeath() is set in
// handleRegisterConnectivityDiagnosticsCallback(). nri will be cleaned up as part of the
// callback's binder death.
final NetworkRequestInfo nri = new NetworkRequestInfo(callingUid, requestWithId);
final ConnectivityDiagnosticsCallbackInfo cbInfo =
new ConnectivityDiagnosticsCallbackInfo(callback, nri, callingPackageName);
mConnectivityDiagnosticsHandler.sendMessage(
mConnectivityDiagnosticsHandler.obtainMessage(
ConnectivityDiagnosticsHandler
.EVENT_REGISTER_CONNECTIVITY_DIAGNOSTICS_CALLBACK,
cbInfo));
}
@Override
public void unregisterConnectivityDiagnosticsCallback(
@NonNull IConnectivityDiagnosticsCallback callback) {
Objects.requireNonNull(callback, "callback must be non-null");
mConnectivityDiagnosticsHandler.sendMessage(
mConnectivityDiagnosticsHandler.obtainMessage(
ConnectivityDiagnosticsHandler
.EVENT_UNREGISTER_CONNECTIVITY_DIAGNOSTICS_CALLBACK,
mDeps.getCallingUid(),
0,
callback));
}
private boolean hasUnderlyingTestNetworks(NetworkCapabilities nc) {
final List<Network> underlyingNetworks = nc.getUnderlyingNetworks();
if (underlyingNetworks == null) return false;
for (Network network : underlyingNetworks) {
if (getNetworkCapabilitiesInternal(network).hasTransport(TRANSPORT_TEST)) {
return true;
}
}
return false;
}
@Override
public void simulateDataStall(int detectionMethod, long timestampMillis,
@NonNull Network network, @NonNull PersistableBundle extras) {
Objects.requireNonNull(network, "network must not be null");
Objects.requireNonNull(extras, "extras must not be null");
enforceAnyPermissionOf(mContext,
android.Manifest.permission.MANAGE_TEST_NETWORKS,
android.Manifest.permission.NETWORK_STACK);
final NetworkCapabilities nc = getNetworkCapabilitiesInternal(network);
if (!nc.hasTransport(TRANSPORT_TEST) && !hasUnderlyingTestNetworks(nc)) {
throw new SecurityException(
"Data Stall simulation is only possible for test networks or networks built on"
+ " top of test networks");
}
final NetworkAgentInfo nai = getNetworkAgentInfoForNetwork(network);
if (nai == null
|| (nai.creatorUid != mDeps.getCallingUid()
&& nai.creatorUid != Process.SYSTEM_UID)) {
throw new SecurityException(
"Data Stall simulation is only possible for network " + "creators");
}
// Instead of passing the data stall directly to the ConnectivityDiagnostics handler, treat
// this as a Data Stall received directly from NetworkMonitor. This requires wrapping the
// Data Stall information as a DataStallReportParcelable and passing to
// #notifyDataStallSuspected. This ensures that unknown Data Stall detection methods are
// still passed to ConnectivityDiagnostics (with new detection methods masked).
final DataStallReportParcelable p = new DataStallReportParcelable();
p.timestampMillis = timestampMillis;
p.detectionMethod = detectionMethod;
if (hasDataStallDetectionMethod(p, DETECTION_METHOD_DNS_EVENTS)) {
p.dnsConsecutiveTimeouts = extras.getInt(KEY_DNS_CONSECUTIVE_TIMEOUTS);
}
if (hasDataStallDetectionMethod(p, DETECTION_METHOD_TCP_METRICS)) {
p.tcpPacketFailRate = extras.getInt(KEY_TCP_PACKET_FAIL_RATE);
p.tcpMetricsCollectionPeriodMillis = extras.getInt(
KEY_TCP_METRICS_COLLECTION_PERIOD_MILLIS);
}
notifyDataStallSuspected(p, network.getNetId());
}
/**
* Class to hold the information for network activity change event from idle timers
* {@link NetdCallback#onInterfaceClassActivityChanged(boolean, int, long, int)}
*/
private static final class NetworkActivityParams {
public final boolean isActive;
// If TrackMultiNetworkActivities is enabled, idleTimer label is netid.
// If TrackMultiNetworkActivities is disabled, idleTimer label is transport type.
public final int label;
public final long timestampNs;
// Uid represents the uid that was responsible for waking the radio.
// -1 for no uid and uid is -1 if isActive is false.
public final int uid;
NetworkActivityParams(boolean isActive, int label, long timestampNs, int uid) {
this.isActive = isActive;
this.label = label;
this.timestampNs = timestampNs;
this.uid = uid;
}
}
private class NetdCallback extends BaseNetdUnsolicitedEventListener {
@Override
public void onInterfaceClassActivityChanged(boolean isActive, int label,
long timestampNs, int uid) {
mHandler.sendMessage(mHandler.obtainMessage(EVENT_REPORT_NETWORK_ACTIVITY,
new NetworkActivityParams(isActive, label, timestampNs, uid)));
}
@Override
public void onInterfaceLinkStateChanged(@NonNull String iface, boolean up) {
mHandler.post(() -> {
for (NetworkAgentInfo nai : mNetworkAgentInfos) {
nai.clatd.handleInterfaceLinkStateChanged(iface, up);
}
});
}
@Override
public void onInterfaceRemoved(@NonNull String iface) {
mHandler.post(() -> {
for (NetworkAgentInfo nai : mNetworkAgentInfos) {
nai.clatd.handleInterfaceRemoved(iface);
}
});
}
}
private final boolean mTrackMultiNetworkActivities;
private final LegacyNetworkActivityTracker mNetworkActivityTracker;
/**
* Class used for updating network activity tracking with netd and notify network activity
* changes.
*/
@VisibleForTesting
public static final class LegacyNetworkActivityTracker {
private static final int NO_UID = -1;
private final Context mContext;
private final INetd mNetd;
private final Handler mHandler;
private final RemoteCallbackList<INetworkActivityListener> mNetworkActivityListeners =
new RemoteCallbackList<>();
// Indicate the current system default network activity is active or not.
// This needs to be volatile to allow non handler threads to read this value without lock.
// If there is no default network, default network is considered active to keep the existing
// behavior. Initial value is used until first connect to the default network.
private volatile boolean mIsDefaultNetworkActive = true;
private Network mDefaultNetwork;
// Key is netId. Value is configured idle timer information.
private final SparseArray<IdleTimerParams> mActiveIdleTimers = new SparseArray<>();
private final boolean mTrackMultiNetworkActivities;
// Store netIds of Wi-Fi networks whose idletimers report that they are active
private final Set<Integer> mActiveWifiNetworks = new ArraySet<>();
// Store netIds of cellular networks whose idletimers report that they are active
private final Set<Integer> mActiveCellularNetworks = new ArraySet<>();
private static class IdleTimerParams {
public final int timeout;
public final int transportType;
IdleTimerParams(int timeout, int transport) {
this.timeout = timeout;
this.transportType = transport;
}
}
LegacyNetworkActivityTracker(@NonNull Context context, @NonNull INetd netd,
@NonNull Handler handler, boolean trackMultiNetworkActivities) {
mContext = context;
mNetd = netd;
mHandler = handler;
mTrackMultiNetworkActivities = trackMultiNetworkActivities;
}
private void ensureRunningOnConnectivityServiceThread() {
if (mHandler.getLooper().getThread() != Thread.currentThread()) {
throw new IllegalStateException("Not running on ConnectivityService thread: "
+ Thread.currentThread().getName());
}
}
/**
* Update network activity and call BatteryStats to update radio power state if the
* mobile or Wi-Fi activity is changed.
* LegacyNetworkActivityTracker considers the mobile network is active if at least one
* mobile network is active since BatteryStatsService only maintains a single power state
* for the mobile network.
* The Wi-Fi network is also the same.
*
* {@link #setupDataActivityTracking} and {@link #removeDataActivityTracking} use
* TRANSPORT_CELLULAR as the transportType argument if the network has both cell and Wi-Fi
* transports.
*/
private void maybeUpdateRadioPowerState(final int netId, final int transportType,
final boolean isActive, final int uid) {
if (transportType != TRANSPORT_WIFI && transportType != TRANSPORT_CELLULAR) {
Log.e(TAG, "Unexpected transportType in maybeUpdateRadioPowerState: "
+ transportType);
return;
}
final Set<Integer> activeNetworks = transportType == TRANSPORT_WIFI
? mActiveWifiNetworks : mActiveCellularNetworks;
final boolean wasEmpty = activeNetworks.isEmpty();
if (isActive) {
activeNetworks.add(netId);
} else {
activeNetworks.remove(netId);
}
if (wasEmpty != activeNetworks.isEmpty()) {
updateRadioPowerState(isActive, transportType, uid);
}
}
private void handleDefaultNetworkActivity(final int transportType,
final boolean isActive, final long timestampNs) {
mIsDefaultNetworkActive = isActive;
sendDataActivityBroadcast(transportTypeToLegacyType(transportType),
isActive, timestampNs);
if (isActive) {
reportNetworkActive();
}
}
private void handleReportNetworkActivityWithNetIdLabel(
NetworkActivityParams activityParams) {
final int netId = activityParams.label;
final IdleTimerParams idleTimerParams = mActiveIdleTimers.get(netId);
if (idleTimerParams == null) {
// This network activity change is not tracked anymore
// This can happen if netd callback post activity change event message but idle
// timer is removed before processing this message.
return;
}
// TODO: if a network changes transports, storing the transport type in the
// IdleTimerParams is not correct. Consider getting it from the network's
// NetworkCapabilities instead.
final int transportType = idleTimerParams.transportType;
maybeUpdateRadioPowerState(netId, transportType,
activityParams.isActive, activityParams.uid);
if (mDefaultNetwork == null || mDefaultNetwork.netId != netId) {
// This activity change is not for the default network.
return;
}
handleDefaultNetworkActivity(transportType, activityParams.isActive,
activityParams.timestampNs);
}
private void handleReportNetworkActivityWithTransportTypeLabel(
NetworkActivityParams activityParams) {
if (mActiveIdleTimers.size() == 0) {
// This activity change is not for the current default network.
// This can happen if netd callback post activity change event message but
// the default network is lost before processing this message.
return;
}
handleDefaultNetworkActivity(activityParams.label, activityParams.isActive,
activityParams.timestampNs);
}
/**
* Handle network activity change
*/
public void handleReportNetworkActivity(NetworkActivityParams activityParams) {
ensureRunningOnConnectivityServiceThread();
if (mTrackMultiNetworkActivities) {
handleReportNetworkActivityWithNetIdLabel(activityParams);
} else {
handleReportNetworkActivityWithTransportTypeLabel(activityParams);
}
}
private void reportNetworkActive() {
final int length = mNetworkActivityListeners.beginBroadcast();
if (DDBG) log("reportNetworkActive, notify " + length + " listeners");
try {
for (int i = 0; i < length; i++) {
try {
mNetworkActivityListeners.getBroadcastItem(i).onNetworkActive();
} catch (RemoteException | RuntimeException e) {
loge("Fail to send network activity to listener " + e);
}
}
} finally {
mNetworkActivityListeners.finishBroadcast();
}
}
// This is deprecated and only to support legacy use cases.
private int transportTypeToLegacyType(int type) {
switch (type) {
case NetworkCapabilities.TRANSPORT_CELLULAR:
return TYPE_MOBILE;
case NetworkCapabilities.TRANSPORT_WIFI:
return TYPE_WIFI;
case NetworkCapabilities.TRANSPORT_BLUETOOTH:
return TYPE_BLUETOOTH;
case NetworkCapabilities.TRANSPORT_ETHERNET:
return TYPE_ETHERNET;
default:
loge("Unexpected transport in transportTypeToLegacyType: " + type);
}
return ConnectivityManager.TYPE_NONE;
}
public void sendDataActivityBroadcast(int deviceType, boolean active, long tsNanos) {
final Intent intent = new Intent(ConnectivityManager.ACTION_DATA_ACTIVITY_CHANGE);
intent.putExtra(ConnectivityManager.EXTRA_DEVICE_TYPE, deviceType);
intent.putExtra(ConnectivityManager.EXTRA_IS_ACTIVE, active);
intent.putExtra(ConnectivityManager.EXTRA_REALTIME_NS, tsNanos);
final long ident = Binder.clearCallingIdentity();
try {
mContext.sendOrderedBroadcastAsUser(intent, UserHandle.ALL,
RECEIVE_DATA_ACTIVITY_CHANGE,
null /* resultReceiver */,
null /* scheduler */,
0 /* initialCode */,
null /* initialData */,
null /* initialExtra */);
} finally {
Binder.restoreCallingIdentity(ident);
}
}
/**
* Get idle timer label
*/
@VisibleForTesting
public static int getIdleTimerLabel(final boolean trackMultiNetworkActivities,
final int netId, final int transportType) {
return trackMultiNetworkActivities ? netId : transportType;
}
private boolean maybeCreateIdleTimer(
String iface, int netId, int timeout, int transportType) {
if (timeout <= 0 || iface == null) return false;
try {
final String label = Integer.toString(getIdleTimerLabel(
mTrackMultiNetworkActivities, netId, transportType));
mNetd.idletimerAddInterface(iface, timeout, label);
mActiveIdleTimers.put(netId, new IdleTimerParams(timeout, transportType));
return true;
} catch (Exception e) {
loge("Exception in createIdleTimer", e);
return false;
}
}
/**
* Setup data activity tracking for the given network.
*
* Every {@code setupDataActivityTracking} should be paired with a
* {@link #removeDataActivityTracking} for cleanup.
*
* @return true if the idleTimer is added to the network, false otherwise
*/
private boolean setupDataActivityTracking(NetworkAgentInfo networkAgent) {
ensureRunningOnConnectivityServiceThread();
final String iface = networkAgent.linkProperties.getInterfaceName();
final int netId = networkAgent.network().netId;
final int timeout;
final int type;
if (!networkAgent.networkCapabilities.hasCapability(NET_CAPABILITY_NOT_VPN)) {
// Do not track VPN network.
return false;
} else if (networkAgent.networkCapabilities.hasTransport(
NetworkCapabilities.TRANSPORT_CELLULAR)) {
timeout = Settings.Global.getInt(mContext.getContentResolver(),
ConnectivitySettingsManager.DATA_ACTIVITY_TIMEOUT_MOBILE,
10);
type = NetworkCapabilities.TRANSPORT_CELLULAR;
} else if (networkAgent.networkCapabilities.hasTransport(
NetworkCapabilities.TRANSPORT_WIFI)) {
timeout = Settings.Global.getInt(mContext.getContentResolver(),
ConnectivitySettingsManager.DATA_ACTIVITY_TIMEOUT_WIFI,
15);
type = NetworkCapabilities.TRANSPORT_WIFI;
} else {
return false; // do not track any other networks
}
final boolean hasIdleTimer = maybeCreateIdleTimer(iface, netId, timeout, type);
if (hasIdleTimer || !mTrackMultiNetworkActivities) {
// If trackMultiNetwork is disabled, NetworkActivityTracker updates radio power
// state in all cases. If trackMultiNetwork is enabled, it updates radio power
// state only about a network that has an idletimer.
maybeUpdateRadioPowerState(netId, type, true /* isActive */, NO_UID);
}
return hasIdleTimer;
}
/**
* Remove data activity tracking when network disconnects.
*/
public void removeDataActivityTracking(NetworkAgentInfo networkAgent) {
ensureRunningOnConnectivityServiceThread();
final String iface = networkAgent.linkProperties.getInterfaceName();
final int netId = networkAgent.network().netId;
final NetworkCapabilities caps = networkAgent.networkCapabilities;
if (iface == null) return;
final int type;
if (!networkAgent.networkCapabilities.hasCapability(NET_CAPABILITY_NOT_VPN)) {
// Do not track VPN network.
return;
} else if (caps.hasTransport(NetworkCapabilities.TRANSPORT_CELLULAR)) {
type = NetworkCapabilities.TRANSPORT_CELLULAR;
} else if (caps.hasTransport(NetworkCapabilities.TRANSPORT_WIFI)) {
type = NetworkCapabilities.TRANSPORT_WIFI;
} else {
return; // do not track any other networks
}
try {
maybeUpdateRadioPowerState(netId, type, false /* isActive */, NO_UID);
final IdleTimerParams params = mActiveIdleTimers.get(netId);
if (params == null) {
// IdleTimer is not added if the configured timeout is 0 or negative value
return;
}
mActiveIdleTimers.remove(netId);
final String label = Integer.toString(getIdleTimerLabel(
mTrackMultiNetworkActivities, netId, params.transportType));
// The call fails silently if no idle timer setup for this interface
mNetd.idletimerRemoveInterface(iface, params.timeout, label);
} catch (Exception e) {
// You shall not crash!
loge("Exception in removeDataActivityTracking " + e);
}
}
private void updateDefaultNetworkActivity(NetworkAgentInfo defaultNetwork,
boolean hasIdleTimer) {
if (defaultNetwork != null) {
mDefaultNetwork = defaultNetwork.network();
mIsDefaultNetworkActive = true;
// If only the default network is tracked, callbacks are called only when the
// network has the idle timer.
if (mTrackMultiNetworkActivities || hasIdleTimer) {
reportNetworkActive();
}
} else {
mDefaultNetwork = null;
// If there is no default network, default network is considered active to keep the
// existing behavior.
mIsDefaultNetworkActive = true;
}
}
/**
* Update the default network this class tracks the activity of.
*/
public void updateDefaultNetwork(NetworkAgentInfo newNetwork,
NetworkAgentInfo oldNetwork) {
ensureRunningOnConnectivityServiceThread();
// If TrackMultiNetworkActivities is enabled, devices add idleTimer when the network is
// first connected and remove when the network is disconnected.
// If TrackMultiNetworkActivities is disabled, devices add idleTimer when the network
// becomes the default network and remove when the network becomes no longer the default
// network.
boolean hasIdleTimer = false;
if (!mTrackMultiNetworkActivities && newNetwork != null) {
hasIdleTimer = setupDataActivityTracking(newNetwork);
}
updateDefaultNetworkActivity(newNetwork, hasIdleTimer);
if (!mTrackMultiNetworkActivities && oldNetwork != null) {
removeDataActivityTracking(oldNetwork);
}
}
private void updateRadioPowerState(boolean isActive, int transportType, int uid) {
final BatteryStatsManager bs = mContext.getSystemService(BatteryStatsManager.class);
switch (transportType) {
case NetworkCapabilities.TRANSPORT_CELLULAR:
bs.reportMobileRadioPowerState(isActive, uid);
break;
case NetworkCapabilities.TRANSPORT_WIFI:
bs.reportWifiRadioPowerState(isActive, uid);
break;
default:
logw("Untracked transport type:" + transportType);
}
}
public boolean isDefaultNetworkActive() {
return mIsDefaultNetworkActive;
}
public void registerNetworkActivityListener(@NonNull INetworkActivityListener l) {
mNetworkActivityListeners.register(l);
}
public void unregisterNetworkActivityListener(@NonNull INetworkActivityListener l) {
mNetworkActivityListeners.unregister(l);
}
public void dump(IndentingPrintWriter pw) {
pw.print("mTrackMultiNetworkActivities="); pw.println(mTrackMultiNetworkActivities);
pw.print("mIsDefaultNetworkActive="); pw.println(mIsDefaultNetworkActive);
pw.print("mDefaultNetwork="); pw.println(mDefaultNetwork);
pw.println("Idle timers:");
try {
for (int i = 0; i < mActiveIdleTimers.size(); i++) {
pw.print(" "); pw.print(mActiveIdleTimers.keyAt(i)); pw.println(":");
final IdleTimerParams params = mActiveIdleTimers.valueAt(i);
pw.print(" timeout="); pw.print(params.timeout);
pw.print(" type="); pw.println(params.transportType);
}
pw.println("WiFi active networks: " + mActiveWifiNetworks);
pw.println("Cellular active networks: " + mActiveCellularNetworks);
} catch (Exception e) {
// mActiveIdleTimers, mActiveWifiNetworks, and mActiveCellularNetworks should only
// be accessed from handler thread, except dump(). As dump() is never called in
// normal usage, it would be needlessly expensive to lock the collection only for
// its benefit. Also, they are not expected to be updated frequently.
// So catching the exception and logging.
pw.println("Failed to dump NetworkActivityTracker: " + e);
}
}
}
/**
* Registers {@link QosSocketFilter} with {@link IQosCallback}.
*
* @param socketInfo the socket information
* @param callback the callback to register
*/
@Override
public void registerQosSocketCallback(@NonNull final QosSocketInfo socketInfo,
@NonNull final IQosCallback callback) {
final NetworkAgentInfo nai = getNetworkAgentInfoForNetwork(socketInfo.getNetwork());
if (nai == null || nai.networkCapabilities == null) {
try {
callback.onError(QosCallbackException.EX_TYPE_FILTER_NETWORK_RELEASED);
} catch (final RemoteException ex) {
loge("registerQosCallbackInternal: RemoteException", ex);
}
return;
}
registerQosCallbackInternal(new QosSocketFilter(socketInfo), callback, nai);
}
/**
* Register a {@link IQosCallback} with base {@link QosFilter}.
*
* @param filter the filter to register
* @param callback the callback to register
* @param nai the agent information related to the filter's network
*/
@VisibleForTesting
public void registerQosCallbackInternal(@NonNull final QosFilter filter,
@NonNull final IQosCallback callback, @NonNull final NetworkAgentInfo nai) {
Objects.requireNonNull(filter, "filter must be non-null");
Objects.requireNonNull(callback, "callback must be non-null");
if (!nai.networkCapabilities.hasCapability(NET_CAPABILITY_NOT_RESTRICTED)) {
// TODO: Check allowed list here and ensure that either a) any QoS callback registered
// on this network is unregistered when the app loses permission or b) no QoS
// callbacks are sent for restricted networks unless the app currently has permission
// to access restricted networks.
enforceConnectivityRestrictedNetworksPermission(false /* checkUidsAllowedList */);
}
mQosCallbackTracker.registerCallback(callback, filter, nai);
}
/**
* Unregisters the given callback.
*
* @param callback the callback to unregister
*/
@Override
public void unregisterQosCallback(@NonNull final IQosCallback callback) {
Objects.requireNonNull(callback, "callback must be non-null");
mQosCallbackTracker.unregisterCallback(callback);
}
private boolean isNetworkPreferenceAllowedForProfile(@NonNull UserHandle profile) {
// UserManager.isManagedProfile returns true for all apps in managed user profiles.
// Enterprise device can be fully managed like device owner and such use case
// also should be supported. Calling app check for work profile and fully managed device
// is already done in DevicePolicyManager.
// This check is an extra caution to be sure device is fully managed or not.
final UserManager um = mContext.getSystemService(UserManager.class);
final DevicePolicyManager dpm = mContext.getSystemService(DevicePolicyManager.class);
if (um.isManagedProfile(profile.getIdentifier())) {
return true;
}
if (mDeps.isAtLeastT() && dpm.getDeviceOwner() != null) return true;
return false;
}
/**
* Set a list of default network selection policies for a user profile or device owner.
*
* See the documentation for the individual preferences for a description of the supported
* behaviors.
*
* @param profile If the device owner is set, any profile is allowed.
Otherwise, the given profile can only be managed profile.
* @param preferences the list of profile network preferences for the
* provided profile.
* @param listener an optional listener to listen for completion of the operation.
*/
@Override
public void setProfileNetworkPreferences(
@NonNull final UserHandle profile,
@NonNull List<ProfileNetworkPreference> preferences,
@Nullable final IOnCompleteListener listener) {
Objects.requireNonNull(preferences);
Objects.requireNonNull(profile);
if (preferences.size() == 0) {
final ProfileNetworkPreference pref = new ProfileNetworkPreference.Builder()
.setPreference(ConnectivityManager.PROFILE_NETWORK_PREFERENCE_DEFAULT)
.build();
preferences.add(pref);
}
enforceNetworkStackPermission(mContext);
if (DBG) {
log("setProfileNetworkPreferences " + profile + " to " + preferences);
}
if (profile.getIdentifier() < 0) {
throw new IllegalArgumentException("Must explicitly specify a user handle ("
+ "UserHandle.CURRENT not supported)");
}
if (!isNetworkPreferenceAllowedForProfile(profile)) {
throw new IllegalArgumentException("Profile must be a managed profile "
+ "or the device owner must be set. ");
}
final List<ProfileNetworkPreferenceInfo> preferenceList = new ArrayList<>();
boolean hasDefaultPreference = false;
for (final ProfileNetworkPreference preference : preferences) {
final NetworkCapabilities nc;
boolean allowFallback = true;
boolean blockingNonEnterprise = false;
switch (preference.getPreference()) {
case ConnectivityManager.PROFILE_NETWORK_PREFERENCE_DEFAULT:
nc = null;
hasDefaultPreference = true;
if (preference.getPreferenceEnterpriseId() != 0) {
throw new IllegalArgumentException(
"Invalid enterprise identifier in setProfileNetworkPreferences");
}
break;
case ConnectivityManager.PROFILE_NETWORK_PREFERENCE_ENTERPRISE_BLOCKING:
blockingNonEnterprise = true;
// continue to process the enterprise preference.
case ConnectivityManager.PROFILE_NETWORK_PREFERENCE_ENTERPRISE_NO_FALLBACK:
allowFallback = false;
// continue to process the enterprise preference.
case ConnectivityManager.PROFILE_NETWORK_PREFERENCE_ENTERPRISE:
// This code is needed even though there is a check later on,
// because isRangeAlreadyInPreferenceList assumes that every preference
// has a UID list.
if (hasDefaultPreference) {
throw new IllegalArgumentException(
"Default profile preference should not be set along with other "
+ "preference");
}
if (!isEnterpriseIdentifierValid(preference.getPreferenceEnterpriseId())) {
throw new IllegalArgumentException(
"Invalid enterprise identifier in setProfileNetworkPreferences");
}
final Set<UidRange> uidRangeSet =
getUidListToBeAppliedForNetworkPreference(profile, preference);
if (!isRangeAlreadyInPreferenceList(preferenceList, uidRangeSet)) {
nc = createDefaultNetworkCapabilitiesForUidRangeSet(uidRangeSet);
} else {
throw new IllegalArgumentException(
"Overlapping uid range in setProfileNetworkPreferences");
}
nc.addCapability(NET_CAPABILITY_ENTERPRISE);
nc.addEnterpriseId(
preference.getPreferenceEnterpriseId());
nc.removeCapability(NET_CAPABILITY_NOT_RESTRICTED);
break;
default:
throw new IllegalArgumentException(
"Invalid preference in setProfileNetworkPreferences");
}
preferenceList.add(new ProfileNetworkPreferenceInfo(
profile, nc, allowFallback, blockingNonEnterprise));
if (hasDefaultPreference && preferenceList.size() > 1) {
throw new IllegalArgumentException(
"Default profile preference should not be set along with other preference");
}
}
mHandler.sendMessage(mHandler.obtainMessage(EVENT_SET_PROFILE_NETWORK_PREFERENCE,
new Pair<>(preferenceList, listener)));
}
private Set<UidRange> getUidListToBeAppliedForNetworkPreference(
@NonNull final UserHandle profile,
@NonNull final ProfileNetworkPreference profileNetworkPreference) {
final UidRange profileUids = UidRange.createForUser(profile);
Set<UidRange> uidRangeSet = UidRangeUtils.convertArrayToUidRange(
profileNetworkPreference.getIncludedUids());
if (uidRangeSet.size() > 0) {
if (!UidRangeUtils.isRangeSetInUidRange(profileUids, uidRangeSet)) {
throw new IllegalArgumentException(
"Allow uid range is outside the uid range of profile.");
}
} else {
ArraySet<UidRange> disallowUidRangeSet = UidRangeUtils.convertArrayToUidRange(
profileNetworkPreference.getExcludedUids());
if (disallowUidRangeSet.size() > 0) {
if (!UidRangeUtils.isRangeSetInUidRange(profileUids, disallowUidRangeSet)) {
throw new IllegalArgumentException(
"disallow uid range is outside the uid range of profile.");
}
uidRangeSet = UidRangeUtils.removeRangeSetFromUidRange(profileUids,
disallowUidRangeSet);
} else {
uidRangeSet = new ArraySet<>();
uidRangeSet.add(profileUids);
}
}
return uidRangeSet;
}
private boolean isEnterpriseIdentifierValid(
@NetworkCapabilities.EnterpriseId int identifier) {
if ((identifier >= NET_ENTERPRISE_ID_1) && (identifier <= NET_ENTERPRISE_ID_5)) {
return true;
}
return false;
}
private ArraySet<NetworkRequestInfo> createNrisFromProfileNetworkPreferences(
@NonNull final NetworkPreferenceList<UserHandle, ProfileNetworkPreferenceInfo> prefs) {
final ArraySet<NetworkRequestInfo> result = new ArraySet<>();
for (final ProfileNetworkPreferenceInfo pref : prefs) {
// The NRI for a user should contain the request for capabilities.
// If fallback to default network is needed then NRI should include
// the request for the default network. Create an image of it to
// have the correct UIDs in it (also a request can only be part of one NRI, because
// of lookups in 1:1 associations like mNetworkRequests).
final ArrayList<NetworkRequest> nrs = new ArrayList<>();
nrs.add(createNetworkRequest(NetworkRequest.Type.REQUEST, pref.capabilities));
if (pref.allowFallback) {
nrs.add(createDefaultInternetRequestForTransport(
TYPE_NONE, NetworkRequest.Type.TRACK_DEFAULT));
}
if (VDBG) {
loge("pref.capabilities.getUids():" + UidRange.fromIntRanges(
pref.capabilities.getUids()));
}
setNetworkRequestUids(nrs, UidRange.fromIntRanges(pref.capabilities.getUids()));
final NetworkRequestInfo nri = new NetworkRequestInfo(Process.myUid(), nrs,
PREFERENCE_ORDER_PROFILE);
result.add(nri);
}
return result;
}
/**
* Compare if the given UID range sets have the same UIDs.
*
*/
private boolean isRangeAlreadyInPreferenceList(
@NonNull List<ProfileNetworkPreferenceInfo> preferenceList,
@NonNull Set<UidRange> uidRangeSet) {
if (uidRangeSet.size() == 0 || preferenceList.size() == 0) {
return false;
}
for (ProfileNetworkPreferenceInfo pref : preferenceList) {
if (UidRangeUtils.doesRangeSetOverlap(
UidRange.fromIntRanges(pref.capabilities.getUids()), uidRangeSet)) {
return true;
}
}
return false;
}
private void handleSetProfileNetworkPreference(
@NonNull final List<ProfileNetworkPreferenceInfo> preferenceList,
@Nullable final IOnCompleteListener listener) {
/*
* handleSetProfileNetworkPreference is always called for single user.
* preferenceList only contains preferences for different uids within the same user
* (enforced by getUidListToBeAppliedForNetworkPreference).
* Clear all the existing preferences for the user before applying new preferences.
*
*/
mProfileNetworkPreferences = mProfileNetworkPreferences.minus(preferenceList.get(0).user);
for (final ProfileNetworkPreferenceInfo preference : preferenceList) {
mProfileNetworkPreferences = mProfileNetworkPreferences.plus(preference);
}
removeDefaultNetworkRequestsForPreference(PREFERENCE_ORDER_PROFILE);
addPerAppDefaultNetworkRequests(
createNrisFromProfileNetworkPreferences(mProfileNetworkPreferences));
updateProfileAllowedNetworks();
// Finally, rematch.
rematchAllNetworksAndRequests();
if (null != listener) {
try {
listener.onComplete();
} catch (RemoteException e) {
loge("Listener for setProfileNetworkPreference has died");
}
}
}
@VisibleForTesting
@NonNull
ArraySet<NetworkRequestInfo> createNrisFromMobileDataPreferredUids(
@NonNull final Set<Integer> uids) {
final ArraySet<NetworkRequestInfo> nris = new ArraySet<>();
if (uids.size() == 0) {
// Should not create NetworkRequestInfo if no preferences. Without uid range in
// NetworkRequestInfo, makeDefaultForApps() would treat it as a illegal NRI.
if (DBG) log("Don't create NetworkRequestInfo because no preferences");
return nris;
}
final List<NetworkRequest> requests = new ArrayList<>();
// The NRI should be comprised of two layers:
// - The request for the mobile network preferred.
// - The request for the default network, for fallback.
requests.add(createDefaultInternetRequestForTransport(
TRANSPORT_CELLULAR, NetworkRequest.Type.REQUEST));
requests.add(createDefaultInternetRequestForTransport(
TYPE_NONE, NetworkRequest.Type.TRACK_DEFAULT));
final Set<UidRange> ranges = new ArraySet<>();
for (final int uid : uids) {
ranges.add(new UidRange(uid, uid));
}
setNetworkRequestUids(requests, ranges);
nris.add(new NetworkRequestInfo(Process.myUid(), requests,
PREFERENCE_ORDER_MOBILE_DATA_PREFERERRED));
return nris;
}
private void handleMobileDataPreferredUidsChanged() {
mMobileDataPreferredUids = ConnectivitySettingsManager.getMobileDataPreferredUids(mContext);
removeDefaultNetworkRequestsForPreference(PREFERENCE_ORDER_MOBILE_DATA_PREFERERRED);
addPerAppDefaultNetworkRequests(
createNrisFromMobileDataPreferredUids(mMobileDataPreferredUids));
// Finally, rematch.
rematchAllNetworksAndRequests();
}
private void handleIngressRateLimitChanged() {
final long oldIngressRateLimit = mIngressRateLimit;
mIngressRateLimit = ConnectivitySettingsManager.getIngressRateLimitInBytesPerSecond(
mContext);
for (final NetworkAgentInfo networkAgent : mNetworkAgentInfos) {
if (canNetworkBeRateLimited(networkAgent)) {
// If rate limit has previously been enabled, remove the old limit first.
if (oldIngressRateLimit >= 0) {
mDeps.disableIngressRateLimit(networkAgent.linkProperties.getInterfaceName());
}
if (mIngressRateLimit >= 0) {
mDeps.enableIngressRateLimit(networkAgent.linkProperties.getInterfaceName(),
mIngressRateLimit);
}
}
}
}
private boolean canNetworkBeRateLimited(@NonNull final NetworkAgentInfo networkAgent) {
// Rate-limiting cannot run correctly before T because the BPF program is not loaded.
if (!mDeps.isAtLeastT()) return false;
final NetworkCapabilities agentCaps = networkAgent.networkCapabilities;
// Only test networks (they cannot hold NET_CAPABILITY_INTERNET) and networks that provide
// internet connectivity can be rate limited.
if (!agentCaps.hasCapability(NET_CAPABILITY_INTERNET) && !agentCaps.hasTransport(
TRANSPORT_TEST)) {
return false;
}
final String iface = networkAgent.linkProperties.getInterfaceName();
if (iface == null) {
// This may happen in tests, but if there is no interface then there is nothing that
// can be rate limited.
loge("canNetworkBeRateLimited: LinkProperties#getInterfaceName returns null");
return false;
}
return true;
}
private void enforceAutomotiveDevice() {
PermissionUtils.enforceSystemFeature(mContext, PackageManager.FEATURE_AUTOMOTIVE,
"setOemNetworkPreference() is only available on automotive devices.");
}
/**
* Used by automotive devices to set the network preferences used to direct traffic at an
* application level as per the given OemNetworkPreferences. An example use-case would be an
* automotive OEM wanting to provide connectivity for applications critical to the usage of a
* vehicle via a particular network.
*
* Calling this will overwrite the existing preference.
*
* @param preference {@link OemNetworkPreferences} The application network preference to be set.
* @param listener {@link ConnectivityManager.OnCompleteListener} Listener used
* to communicate completion of setOemNetworkPreference();
*/
@Override
public void setOemNetworkPreference(
@NonNull final OemNetworkPreferences preference,
@Nullable final IOnCompleteListener listener) {
Objects.requireNonNull(preference, "OemNetworkPreferences must be non-null");
// Only bypass the permission/device checks if this is a valid test request.
if (isValidTestOemNetworkPreference(preference)) {
enforceManageTestNetworksPermission();
} else {
enforceAutomotiveDevice();
enforceOemNetworkPreferencesPermission();
validateOemNetworkPreferences(preference);
}
mHandler.sendMessage(mHandler.obtainMessage(EVENT_SET_OEM_NETWORK_PREFERENCE,
new Pair<>(preference, listener)));
}
/**
* Sets the specified UIDs to get/receive the VPN as the only default network.
*
* Calling this will overwrite the existing network preference for this session, and the
* specified UIDs won't get any default network when no VPN is connected.
*
* @param session The VPN session which manages the passed UIDs.
* @param ranges The uid ranges which will treat VPN as the only preferred network. Clear the
* setting for this session if the array is empty. Null is not allowed, the
* method will use {@link Objects#requireNonNull(Object)} to check this variable.
* @hide
*/
@Override
public void setVpnNetworkPreference(String session, UidRange[] ranges) {
Objects.requireNonNull(ranges);
enforceNetworkStackOrSettingsPermission();
final UidRange[] sortedRanges = UidRangeUtils.sortRangesByStartUid(ranges);
if (UidRangeUtils.sortedRangesContainOverlap(sortedRanges)) {
throw new IllegalArgumentException(
"setVpnNetworkPreference: Passed UID ranges overlap");
}
mHandler.sendMessage(mHandler.obtainMessage(EVENT_SET_VPN_NETWORK_PREFERENCE,
new VpnNetworkPreferenceInfo(session,
new ArraySet<UidRange>(Arrays.asList(ranges)))));
}
private void handleSetVpnNetworkPreference(VpnNetworkPreferenceInfo preferenceInfo) {
Log.d(TAG, "handleSetVpnNetworkPreference: preferenceInfo = " + preferenceInfo);
mVpnNetworkPreferences = mVpnNetworkPreferences.minus(preferenceInfo.getKey());
mVpnNetworkPreferences = mVpnNetworkPreferences.plus(preferenceInfo);
removeDefaultNetworkRequestsForPreference(PREFERENCE_ORDER_VPN);
addPerAppDefaultNetworkRequests(createNrisForVpnNetworkPreference(mVpnNetworkPreferences));
// Finally, rematch.
rematchAllNetworksAndRequests();
}
private ArraySet<NetworkRequestInfo> createNrisForVpnNetworkPreference(
@NonNull NetworkPreferenceList<String, VpnNetworkPreferenceInfo> preferenceList) {
final ArraySet<NetworkRequestInfo> nris = new ArraySet<>();
for (VpnNetworkPreferenceInfo preferenceInfo : preferenceList) {
final List<NetworkRequest> requests = new ArrayList<>();
// Request VPN only, so other networks won't be the fallback options when VPN is not
// connected temporarily.
requests.add(createVpnRequest());
final Set<UidRange> uidRanges = new ArraySet(preferenceInfo.getUidRangesNoCopy());
setNetworkRequestUids(requests, uidRanges);
nris.add(new NetworkRequestInfo(Process.myUid(), requests, PREFERENCE_ORDER_VPN));
}
return nris;
}
/**
* Check the validity of an OEM network preference to be used for testing purposes.
* @param preference the preference to validate
* @return true if this is a valid OEM network preference test request.
*/
private boolean isValidTestOemNetworkPreference(
@NonNull final OemNetworkPreferences preference) {
// Allow for clearing of an existing OemNetworkPreference used for testing.
// This isn't called on the handler thread so it is possible that mOemNetworkPreferences
// changes after this check is complete. This is an unlikely scenario as calling of this API
// is controlled by the OEM therefore the added complexity is not worth adding given those
// circumstances. That said, it is an edge case to be aware of hence this comment.
final boolean isValidTestClearPref = preference.getNetworkPreferences().size() == 0
&& isTestOemNetworkPreference(mOemNetworkPreferences);
return isTestOemNetworkPreference(preference) || isValidTestClearPref;
}
private boolean isTestOemNetworkPreference(@NonNull final OemNetworkPreferences preference) {
final Map<String, Integer> prefMap = preference.getNetworkPreferences();
return prefMap.size() == 1
&& (prefMap.containsValue(OEM_NETWORK_PREFERENCE_TEST)
|| prefMap.containsValue(OEM_NETWORK_PREFERENCE_TEST_ONLY));
}
private void validateOemNetworkPreferences(@NonNull OemNetworkPreferences preference) {
for (@OemNetworkPreferences.OemNetworkPreference final int pref
: preference.getNetworkPreferences().values()) {
if (pref <= 0 || OemNetworkPreferences.OEM_NETWORK_PREFERENCE_MAX < pref) {
throw new IllegalArgumentException(
OemNetworkPreferences.oemNetworkPreferenceToString(pref)
+ " is an invalid value.");
}
}
}
private void handleSetOemNetworkPreference(
@NonNull final OemNetworkPreferences preference,
@Nullable final IOnCompleteListener listener) {
Objects.requireNonNull(preference, "OemNetworkPreferences must be non-null");
if (DBG) {
log("set OEM network preferences :" + preference.toString());
}
mOemNetworkPreferencesLogs.log("UPDATE INITIATED: " + preference);
removeDefaultNetworkRequestsForPreference(PREFERENCE_ORDER_OEM);
addPerAppDefaultNetworkRequests(new OemNetworkRequestFactory()
.createNrisFromOemNetworkPreferences(preference));
mOemNetworkPreferences = preference;
if (null != listener) {
try {
listener.onComplete();
} catch (RemoteException e) {
loge("Can't send onComplete in handleSetOemNetworkPreference", e);
}
}
}
private void removeDefaultNetworkRequestsForPreference(final int preferenceOrder) {
// Skip the requests which are set by other network preference. Because the uid range rules
// should stay in netd.
final Set<NetworkRequestInfo> requests = new ArraySet<>(mDefaultNetworkRequests);
requests.removeIf(request -> request.mPreferenceOrder != preferenceOrder);
handleRemoveNetworkRequests(requests);
}
private void addPerAppDefaultNetworkRequests(@NonNull final Set<NetworkRequestInfo> nris) {
ensureRunningOnConnectivityServiceThread();
mDefaultNetworkRequests.addAll(nris);
final ArraySet<NetworkRequestInfo> perAppCallbackRequestsToUpdate =
getPerAppCallbackRequestsToUpdate();
final ArraySet<NetworkRequestInfo> nrisToRegister = new ArraySet<>(nris);
handleRemoveNetworkRequests(perAppCallbackRequestsToUpdate);
nrisToRegister.addAll(
createPerAppCallbackRequestsToRegister(perAppCallbackRequestsToUpdate));
handleRegisterNetworkRequests(nrisToRegister);
}
/**
* All current requests that are tracking the default network need to be assessed as to whether
* or not the current set of per-application default requests will be changing their default
* network. If so, those requests will need to be updated so that they will send callbacks for
* default network changes at the appropriate time. Additionally, those requests tracking the
* default that were previously updated by this flow will need to be reassessed.
* @return the nris which will need to be updated.
*/
private ArraySet<NetworkRequestInfo> getPerAppCallbackRequestsToUpdate() {
final ArraySet<NetworkRequestInfo> defaultCallbackRequests = new ArraySet<>();
// Get the distinct nris to check since for multilayer requests, it is possible to have the
// same nri in the map's values for each of its NetworkRequest objects.
final ArraySet<NetworkRequestInfo> nris = new ArraySet<>(mNetworkRequests.values());
for (final NetworkRequestInfo nri : nris) {
// Include this nri if it is currently being tracked.
if (isPerAppTrackedNri(nri)) {
defaultCallbackRequests.add(nri);
continue;
}
// We only track callbacks for requests tracking the default.
if (NetworkRequest.Type.TRACK_DEFAULT != nri.mRequests.get(0).type) {
continue;
}
// Include this nri if it will be tracked by the new per-app default requests.
final boolean isNriGoingToBeTracked =
getDefaultRequestTrackingUid(nri.mAsUid) != mDefaultRequest;
if (isNriGoingToBeTracked) {
defaultCallbackRequests.add(nri);
}
}
return defaultCallbackRequests;
}
/**
* Create nris for those network requests that are currently tracking the default network that
* are being controlled by a per-application default.
* @param perAppCallbackRequestsForUpdate the baseline network requests to be used as the
* foundation when creating the nri. Important items include the calling uid's original
* NetworkRequest to be used when mapping callbacks as well as the caller's uid and name. These
* requests are assumed to have already been validated as needing to be updated.
* @return the Set of nris to use when registering network requests.
*/
private ArraySet<NetworkRequestInfo> createPerAppCallbackRequestsToRegister(
@NonNull final ArraySet<NetworkRequestInfo> perAppCallbackRequestsForUpdate) {
final ArraySet<NetworkRequestInfo> callbackRequestsToRegister = new ArraySet<>();
for (final NetworkRequestInfo callbackRequest : perAppCallbackRequestsForUpdate) {
final NetworkRequestInfo trackingNri =
getDefaultRequestTrackingUid(callbackRequest.mAsUid);
// If this nri is not being tracked, then change it back to an untracked nri.
if (trackingNri == mDefaultRequest) {
callbackRequestsToRegister.add(new NetworkRequestInfo(
callbackRequest,
Collections.singletonList(callbackRequest.getNetworkRequestForCallback())));
continue;
}
final NetworkRequest request = callbackRequest.mRequests.get(0);
callbackRequestsToRegister.add(new NetworkRequestInfo(
callbackRequest,
copyNetworkRequestsForUid(
trackingNri.mRequests, callbackRequest.mAsUid,
callbackRequest.mUid, request.getRequestorPackageName())));
}
return callbackRequestsToRegister;
}
private static void setNetworkRequestUids(@NonNull final List<NetworkRequest> requests,
@NonNull final Set<UidRange> uids) {
for (final NetworkRequest req : requests) {
req.networkCapabilities.setUids(UidRange.toIntRanges(uids));
}
}
/**
* Class used to generate {@link NetworkRequestInfo} based off of {@link OemNetworkPreferences}.
*/
@VisibleForTesting
final class OemNetworkRequestFactory {
ArraySet<NetworkRequestInfo> createNrisFromOemNetworkPreferences(
@NonNull final OemNetworkPreferences preference) {
final ArraySet<NetworkRequestInfo> nris = new ArraySet<>();
final SparseArray<Set<Integer>> uids =
createUidsFromOemNetworkPreferences(preference);
for (int i = 0; i < uids.size(); i++) {
final int key = uids.keyAt(i);
final Set<Integer> value = uids.valueAt(i);
final NetworkRequestInfo nri = createNriFromOemNetworkPreferences(key, value);
// No need to add an nri without any requests.
if (0 == nri.mRequests.size()) {
continue;
}
nris.add(nri);
}
return nris;
}
private SparseArray<Set<Integer>> createUidsFromOemNetworkPreferences(
@NonNull final OemNetworkPreferences preference) {
final SparseArray<Set<Integer>> prefToUids = new SparseArray<>();
final PackageManager pm = mContext.getPackageManager();
final List<UserHandle> users =
mContext.getSystemService(UserManager.class).getUserHandles(true);
if (null == users || users.size() == 0) {
if (VDBG || DDBG) {
log("No users currently available for setting the OEM network preference.");
}
return prefToUids;
}
for (final Map.Entry<String, Integer> entry :
preference.getNetworkPreferences().entrySet()) {
@OemNetworkPreferences.OemNetworkPreference final int pref = entry.getValue();
// Add the rules for all users as this policy is device wide.
for (final UserHandle user : users) {
try {
final int uid = pm.getApplicationInfoAsUser(entry.getKey(), 0, user).uid;
if (!prefToUids.contains(pref)) {
prefToUids.put(pref, new ArraySet<>());
}
prefToUids.get(pref).add(uid);
} catch (PackageManager.NameNotFoundException e) {
// Although this may seem like an error scenario, it is ok that uninstalled
// packages are sent on a network preference as the system will watch for
// package installations associated with this network preference and update
// accordingly. This is done to minimize race conditions on app install.
continue;
}
}
}
return prefToUids;
}
private NetworkRequestInfo createNriFromOemNetworkPreferences(
@OemNetworkPreferences.OemNetworkPreference final int preference,
@NonNull final Set<Integer> uids) {
final List<NetworkRequest> requests = new ArrayList<>();
// Requests will ultimately be evaluated by order of insertion therefore it matters.
switch (preference) {
case OemNetworkPreferences.OEM_NETWORK_PREFERENCE_OEM_PAID:
requests.add(createUnmeteredNetworkRequest());
requests.add(createOemPaidNetworkRequest());
requests.add(createDefaultInternetRequestForTransport(
TYPE_NONE, NetworkRequest.Type.TRACK_DEFAULT));
break;
case OemNetworkPreferences.OEM_NETWORK_PREFERENCE_OEM_PAID_NO_FALLBACK:
requests.add(createUnmeteredNetworkRequest());
requests.add(createOemPaidNetworkRequest());
break;
case OemNetworkPreferences.OEM_NETWORK_PREFERENCE_OEM_PAID_ONLY:
requests.add(createOemPaidNetworkRequest());
break;
case OemNetworkPreferences.OEM_NETWORK_PREFERENCE_OEM_PRIVATE_ONLY:
requests.add(createOemPrivateNetworkRequest());
break;
case OEM_NETWORK_PREFERENCE_TEST:
requests.add(createUnmeteredNetworkRequest());
requests.add(createTestNetworkRequest());
requests.add(createDefaultRequest());
break;
case OEM_NETWORK_PREFERENCE_TEST_ONLY:
requests.add(createTestNetworkRequest());
break;
default:
// This should never happen.
throw new IllegalArgumentException("createNriFromOemNetworkPreferences()"
+ " called with invalid preference of " + preference);
}
final ArraySet<UidRange> ranges = new ArraySet<>();
for (final int uid : uids) {
ranges.add(new UidRange(uid, uid));
}
setNetworkRequestUids(requests, ranges);
return new NetworkRequestInfo(Process.myUid(), requests, PREFERENCE_ORDER_OEM);
}
private NetworkRequest createUnmeteredNetworkRequest() {
final NetworkCapabilities netcap = createDefaultPerAppNetCap()
.addCapability(NET_CAPABILITY_NOT_METERED)
.addCapability(NET_CAPABILITY_VALIDATED);
return createNetworkRequest(NetworkRequest.Type.LISTEN, netcap);
}
private NetworkRequest createOemPaidNetworkRequest() {
// NET_CAPABILITY_OEM_PAID is a restricted capability.
final NetworkCapabilities netcap = createDefaultPerAppNetCap()
.addCapability(NET_CAPABILITY_OEM_PAID)
.removeCapability(NET_CAPABILITY_NOT_RESTRICTED);
return createNetworkRequest(NetworkRequest.Type.REQUEST, netcap);
}
private NetworkRequest createOemPrivateNetworkRequest() {
// NET_CAPABILITY_OEM_PRIVATE is a restricted capability.
final NetworkCapabilities netcap = createDefaultPerAppNetCap()
.addCapability(NET_CAPABILITY_OEM_PRIVATE)
.removeCapability(NET_CAPABILITY_NOT_RESTRICTED);
return createNetworkRequest(NetworkRequest.Type.REQUEST, netcap);
}
private NetworkCapabilities createDefaultPerAppNetCap() {
final NetworkCapabilities netcap = new NetworkCapabilities();
netcap.addCapability(NET_CAPABILITY_INTERNET);
netcap.setRequestorUidAndPackageName(Process.myUid(), mContext.getPackageName());
return netcap;
}
private NetworkRequest createTestNetworkRequest() {
final NetworkCapabilities netcap = new NetworkCapabilities();
netcap.clearAll();
netcap.addTransportType(TRANSPORT_TEST);
return createNetworkRequest(NetworkRequest.Type.REQUEST, netcap);
}
}
@RequiresApi(Build.VERSION_CODES.TIRAMISU)
@Override
public void setDataSaverEnabled(final boolean enable) {
enforceNetworkStackOrSettingsPermission();
try {
final boolean ret = mNetd.bandwidthEnableDataSaver(enable);
if (!ret) {
throw new IllegalStateException("Error when changing iptables: " + enable);
}
} catch (RemoteException e) {
// Lack of permission or binder errors.
throw new IllegalStateException(e);
}
try {
mBpfNetMaps.setDataSaverEnabled(enable);
} catch (ServiceSpecificException | UnsupportedOperationException e) {
Log.e(TAG, "Failed to set data saver " + enable + " : " + e);
}
}
@Override
public void updateMeteredNetworkAllowList(final int uid, final boolean add) {
enforceNetworkStackOrSettingsPermission();
try {
if (add) {
mBpfNetMaps.addNiceApp(uid);
} else {
mBpfNetMaps.removeNiceApp(uid);
}
} catch (ServiceSpecificException e) {
throw new IllegalStateException(e);
}
}
@Override
public void updateMeteredNetworkDenyList(final int uid, final boolean add) {
enforceNetworkStackOrSettingsPermission();
try {
if (add) {
mBpfNetMaps.addNaughtyApp(uid);
} else {
mBpfNetMaps.removeNaughtyApp(uid);
}
} catch (ServiceSpecificException e) {
throw new IllegalStateException(e);
}
}
private int setPackageFirewallRule(final int chain, final String packageName, final int rule)
throws PackageManager.NameNotFoundException {
final PackageManager pm = mContext.getPackageManager();
final int appId = UserHandle.getAppId(pm.getPackageUid(packageName, 0 /* flags */));
if (appId < Process.FIRST_APPLICATION_UID) {
throw new RuntimeException("Can't set package firewall rule for system app "
+ packageName + " with appId " + appId);
}
for (final UserHandle uh : mUserManager.getUserHandles(false /* excludeDying */)) {
final int uid = uh.getUid(appId);
setUidFirewallRule(chain, uid, rule);
}
return appId;
}
@Override
public void setUidFirewallRule(final int chain, final int uid, final int rule) {
enforceNetworkStackOrSettingsPermission();
// There are only two type of firewall rule: FIREWALL_RULE_ALLOW or FIREWALL_RULE_DENY
int firewallRule = getFirewallRuleType(chain, rule);
if (firewallRule != FIREWALL_RULE_ALLOW && firewallRule != FIREWALL_RULE_DENY) {
throw new IllegalArgumentException("setUidFirewallRule with invalid rule: " + rule);
}
try {
mBpfNetMaps.setUidRule(chain, uid, firewallRule);
} catch (ServiceSpecificException e) {
throw new IllegalStateException(e);
}
}
private int getPackageFirewallRule(final int chain, final String packageName)
throws PackageManager.NameNotFoundException {
final PackageManager pm = mContext.getPackageManager();
final int appId = UserHandle.getAppId(pm.getPackageUid(packageName, 0 /* flags */));
return getUidFirewallRule(chain, appId);
}
@Override
public int getUidFirewallRule(final int chain, final int uid) {
enforceNetworkStackOrSettingsPermission();
return mBpfNetMaps.getUidRule(chain, uid);
}
private int getFirewallRuleType(int chain, int rule) {
final int defaultRule;
switch (chain) {
case ConnectivityManager.FIREWALL_CHAIN_STANDBY:
case ConnectivityManager.FIREWALL_CHAIN_OEM_DENY_1:
case ConnectivityManager.FIREWALL_CHAIN_OEM_DENY_2:
case ConnectivityManager.FIREWALL_CHAIN_OEM_DENY_3:
defaultRule = FIREWALL_RULE_ALLOW;
break;
case ConnectivityManager.FIREWALL_CHAIN_DOZABLE:
case ConnectivityManager.FIREWALL_CHAIN_POWERSAVE:
case ConnectivityManager.FIREWALL_CHAIN_RESTRICTED:
case ConnectivityManager.FIREWALL_CHAIN_LOW_POWER_STANDBY:
case ConnectivityManager.FIREWALL_CHAIN_BACKGROUND:
defaultRule = FIREWALL_RULE_DENY;
break;
default:
throw new IllegalArgumentException("Unsupported firewall chain: " + chain);
}
if (rule == FIREWALL_RULE_DEFAULT) rule = defaultRule;
return rule;
}
private void closeSocketsForFirewallChainLocked(final int chain)
throws ErrnoException, SocketException, InterruptedIOException {
if (BpfNetMapsUtils.isFirewallAllowList(chain)) {
// Allowlist means the firewall denies all by default, uids must be explicitly allowed
// So, close all non-system socket owned by uids that are not explicitly allowed
Set<Range<Integer>> ranges = new ArraySet<>();
ranges.add(new Range<>(Process.FIRST_APPLICATION_UID, Integer.MAX_VALUE));
final Set<Integer> exemptUids = mBpfNetMaps.getUidsWithAllowRuleOnAllowListChain(chain);
mDeps.destroyLiveTcpSockets(ranges, exemptUids);
} else {
// Denylist means the firewall allows all by default, uids must be explicitly denied
// So, close socket owned by uids that are explicitly denied
final Set<Integer> ownerUids = mBpfNetMaps.getUidsWithDenyRuleOnDenyListChain(chain);
mDeps.destroyLiveTcpSocketsByOwnerUids(ownerUids);
}
}
@Override
public void setFirewallChainEnabled(final int chain, final boolean enable) {
enforceNetworkStackOrSettingsPermission();
try {
mBpfNetMaps.setChildChain(chain, enable);
} catch (ServiceSpecificException e) {
throw new IllegalStateException(e);
}
if (mDeps.isAtLeastU() && enable) {
try {
closeSocketsForFirewallChainLocked(chain);
} catch (ErrnoException | SocketException | InterruptedIOException e) {
Log.e(TAG, "Failed to close sockets after enabling chain (" + chain + "): " + e);
}
}
}
@Override
public boolean getFirewallChainEnabled(final int chain) {
enforceNetworkStackOrSettingsPermission();
return mBpfNetMaps.isChainEnabled(chain);
}
@Override
public void replaceFirewallChain(final int chain, final int[] uids) {
enforceNetworkStackOrSettingsPermission();
mBpfNetMaps.replaceUidChain(chain, uids);
}
@Override
public IBinder getCompanionDeviceManagerProxyService() {
enforceNetworkStackPermission(mContext);
return mCdmps;
}
@Override
public IBinder getRoutingCoordinatorService() {
enforceNetworkStackPermission(mContext);
return mRoutingCoordinatorService;
}
}