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android_frameworks_base/services/java/com/android/server/ConnectivityService.java
Robert Greenwalt 599115894f Simplfy getActive* calls in ConnectivityService 
One had been simplified on GB, but somehow it didn't make it here.
bug: 4463770

Change-Id: Ica51e836b1a7a489526a223168910b8e06c99c2b
2011-05-20 12:23:41 -07:00

2259 lines
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Java
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/*
* 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 android.bluetooth.BluetoothTetheringDataTracker;
import android.content.ContentResolver;
import android.content.Context;
import android.content.Intent;
import android.content.pm.PackageManager;
import android.database.ContentObserver;
import android.net.ConnectivityManager;
import android.net.DummyDataStateTracker;
import android.net.EthernetDataTracker;
import android.net.IConnectivityManager;
import android.net.LinkAddress;
import android.net.LinkProperties;
import android.net.MobileDataStateTracker;
import android.net.NetworkConfig;
import android.net.NetworkInfo;
import android.net.NetworkStateTracker;
import android.net.NetworkUtils;
import android.net.Proxy;
import android.net.ProxyProperties;
import android.net.RouteInfo;
import android.net.vpn.VpnManager;
import android.net.wifi.WifiStateTracker;
import android.os.Binder;
import android.os.Handler;
import android.os.HandlerThread;
import android.os.IBinder;
import android.os.INetworkManagementService;
import android.os.Looper;
import android.os.Message;
import android.os.PowerManager;
import android.os.RemoteException;
import android.os.ServiceManager;
import android.os.SystemProperties;
import android.provider.Settings;
import android.text.TextUtils;
import android.util.EventLog;
import android.util.Slog;
import com.android.internal.telephony.Phone;
import com.android.server.connectivity.Tethering;
import java.io.FileDescriptor;
import java.io.FileWriter;
import java.io.IOException;
import java.io.PrintWriter;
import java.net.InetAddress;
import java.net.Inet4Address;
import java.net.UnknownHostException;
import java.util.ArrayList;
import java.util.Collection;
import java.util.concurrent.atomic.AtomicBoolean;
import java.util.GregorianCalendar;
import java.util.List;
/**
* @hide
*/
public class ConnectivityService extends IConnectivityManager.Stub {
private static final boolean DBG = true;
private static final String TAG = "ConnectivityService";
// 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";
// used in recursive route setting to add gateways for the host for which
// a host route was requested.
private static final int MAX_HOSTROUTE_CYCLE_COUNT = 10;
private Tethering mTethering;
private boolean mTetheringConfigValid = false;
/**
* Sometimes we want to refer to the individual network state
* trackers separately, and sometimes we just want to treat them
* abstractly.
*/
private NetworkStateTracker mNetTrackers[];
/**
* A per Net list of the PID's that requested access to the net
* used both as a refcount and for per-PID DNS selection
*/
private List mNetRequestersPids[];
private WifiWatchdogService mWifiWatchdogService;
// priority order of the nettrackers
// (excluding dynamically set mNetworkPreference)
// TODO - move mNetworkTypePreference into this
private int[] mPriorityList;
private Context mContext;
private int mNetworkPreference;
private int mActiveDefaultNetwork = -1;
// 0 is full bad, 100 is full good
private int mDefaultInetCondition = 0;
private int mDefaultInetConditionPublished = 0;
private boolean mInetConditionChangeInFlight = false;
private int mDefaultConnectionSequence = 0;
private int mNumDnsEntries;
private boolean mTestMode;
private static ConnectivityService sServiceInstance;
private AtomicBoolean mBackgroundDataEnabled = new AtomicBoolean(true);
private INetworkManagementService mNetd;
private static final int ENABLED = 1;
private static final int DISABLED = 0;
// Share the event space with NetworkStateTracker (which can't see this
// internal class but sends us events). If you change these, change
// NetworkStateTracker.java too.
private static final int MIN_NETWORK_STATE_TRACKER_EVENT = 1;
private static final int MAX_NETWORK_STATE_TRACKER_EVENT = 100;
/**
* used internally as a delayed event to make us switch back to the
* default network
*/
private static final int EVENT_RESTORE_DEFAULT_NETWORK =
MAX_NETWORK_STATE_TRACKER_EVENT + 1;
/**
* used internally to change our mobile data enabled flag
*/
private static final int EVENT_CHANGE_MOBILE_DATA_ENABLED =
MAX_NETWORK_STATE_TRACKER_EVENT + 2;
/**
* used internally to change our network preference setting
* arg1 = networkType to prefer
*/
private static final int EVENT_SET_NETWORK_PREFERENCE =
MAX_NETWORK_STATE_TRACKER_EVENT + 3;
/**
* used internally to synchronize inet condition reports
* arg1 = networkType
* arg2 = condition (0 bad, 100 good)
*/
private static final int EVENT_INET_CONDITION_CHANGE =
MAX_NETWORK_STATE_TRACKER_EVENT + 4;
/**
* used internally to mark the end of inet condition hold periods
* arg1 = networkType
*/
private static final int EVENT_INET_CONDITION_HOLD_END =
MAX_NETWORK_STATE_TRACKER_EVENT + 5;
/**
* used internally to set the background data preference
* arg1 = TRUE for enabled, FALSE for disabled
*/
private static final int EVENT_SET_BACKGROUND_DATA =
MAX_NETWORK_STATE_TRACKER_EVENT + 6;
/**
* used internally to set enable/disable cellular data
* arg1 = ENBALED or DISABLED
*/
private static final int EVENT_SET_MOBILE_DATA =
MAX_NETWORK_STATE_TRACKER_EVENT + 7;
/**
* used internally to clear a wakelock when transitioning
* from one net to another
*/
private static final int EVENT_CLEAR_NET_TRANSITION_WAKELOCK =
MAX_NETWORK_STATE_TRACKER_EVENT + 8;
/**
* used internally to reload global proxy settings
*/
private static final int EVENT_APPLY_GLOBAL_HTTP_PROXY =
MAX_NETWORK_STATE_TRACKER_EVENT + 9;
/**
* used internally to set external dependency met/unmet
* arg1 = ENABLED (met) or DISABLED (unmet)
* arg2 = NetworkType
*/
private static final int EVENT_SET_DEPENDENCY_MET =
MAX_NETWORK_STATE_TRACKER_EVENT + 10;
private Handler mHandler;
// list of DeathRecipients used to make sure features are turned off when
// a process dies
private List mFeatureUsers;
private boolean mSystemReady;
private Intent mInitialBroadcast;
private PowerManager.WakeLock mNetTransitionWakeLock;
private String mNetTransitionWakeLockCausedBy = "";
private int mNetTransitionWakeLockSerialNumber;
private int mNetTransitionWakeLockTimeout;
private InetAddress mDefaultDns;
// used in DBG mode to track inet condition reports
private static final int INET_CONDITION_LOG_MAX_SIZE = 15;
private ArrayList mInetLog;
// track the current default http proxy - tell the world if we get a new one (real change)
private ProxyProperties mDefaultProxy = null;
// track the global proxy.
private ProxyProperties mGlobalProxy = null;
private final Object mGlobalProxyLock = new Object();
private SettingsObserver mSettingsObserver;
NetworkConfig[] mNetConfigs;
int mNetworksDefined;
private static class RadioAttributes {
public int mSimultaneity;
public int mType;
public RadioAttributes(String init) {
String fragments[] = init.split(",");
mType = Integer.parseInt(fragments[0]);
mSimultaneity = Integer.parseInt(fragments[1]);
}
}
RadioAttributes[] mRadioAttributes;
public static synchronized ConnectivityService getInstance(Context context) {
if (sServiceInstance == null) {
sServiceInstance = new ConnectivityService(context);
}
return sServiceInstance;
}
private ConnectivityService(Context context) {
if (DBG) log("ConnectivityService starting up");
HandlerThread handlerThread = new HandlerThread("ConnectivityServiceThread");
handlerThread.start();
mHandler = new MyHandler(handlerThread.getLooper());
mBackgroundDataEnabled.set(Settings.Secure.getInt(context.getContentResolver(),
Settings.Secure.BACKGROUND_DATA, 1) == 1);
// setup our unique device name
if (TextUtils.isEmpty(SystemProperties.get("net.hostname"))) {
String id = Settings.Secure.getString(context.getContentResolver(),
Settings.Secure.ANDROID_ID);
if (id != null && id.length() > 0) {
String name = new String("android_").concat(id);
SystemProperties.set("net.hostname", name);
}
}
// read our default dns server ip
String dns = Settings.Secure.getString(context.getContentResolver(),
Settings.Secure.DEFAULT_DNS_SERVER);
if (dns == null || dns.length() == 0) {
dns = context.getResources().getString(
com.android.internal.R.string.config_default_dns_server);
}
try {
mDefaultDns = NetworkUtils.numericToInetAddress(dns);
} catch (IllegalArgumentException e) {
loge("Error setting defaultDns using " + dns);
}
mContext = context;
PowerManager powerManager = (PowerManager)mContext.getSystemService(Context.POWER_SERVICE);
mNetTransitionWakeLock = powerManager.newWakeLock(PowerManager.PARTIAL_WAKE_LOCK, TAG);
mNetTransitionWakeLockTimeout = mContext.getResources().getInteger(
com.android.internal.R.integer.config_networkTransitionTimeout);
mNetTrackers = new NetworkStateTracker[
ConnectivityManager.MAX_NETWORK_TYPE+1];
mNetworkPreference = getPersistedNetworkPreference();
mRadioAttributes = new RadioAttributes[ConnectivityManager.MAX_RADIO_TYPE+1];
mNetConfigs = new NetworkConfig[ConnectivityManager.MAX_NETWORK_TYPE+1];
// Load device network attributes from resources
String[] raStrings = context.getResources().getStringArray(
com.android.internal.R.array.radioAttributes);
for (String raString : raStrings) {
RadioAttributes r = new RadioAttributes(raString);
if (r.mType > ConnectivityManager.MAX_RADIO_TYPE) {
loge("Error in radioAttributes - ignoring attempt to define type " + r.mType);
continue;
}
if (mRadioAttributes[r.mType] != null) {
loge("Error in radioAttributes - ignoring attempt to redefine type " +
r.mType);
continue;
}
mRadioAttributes[r.mType] = r;
}
String[] naStrings = context.getResources().getStringArray(
com.android.internal.R.array.networkAttributes);
for (String naString : naStrings) {
try {
NetworkConfig n = new NetworkConfig(naString);
if (n.type > ConnectivityManager.MAX_NETWORK_TYPE) {
loge("Error in networkAttributes - ignoring attempt to define type " +
n.type);
continue;
}
if (mNetConfigs[n.type] != null) {
loge("Error in networkAttributes - ignoring attempt to redefine type " +
n.type);
continue;
}
if (mRadioAttributes[n.radio] == null) {
loge("Error in networkAttributes - ignoring attempt to use undefined " +
"radio " + n.radio + " in network type " + n.type);
continue;
}
mNetConfigs[n.type] = n;
mNetworksDefined++;
} catch(Exception e) {
// ignore it - leave the entry null
}
}
// high priority first
mPriorityList = new int[mNetworksDefined];
{
int insertionPoint = mNetworksDefined-1;
int currentLowest = 0;
int nextLowest = 0;
while (insertionPoint > -1) {
for (NetworkConfig na : mNetConfigs) {
if (na == null) continue;
if (na.priority < currentLowest) continue;
if (na.priority > currentLowest) {
if (na.priority < nextLowest || nextLowest == 0) {
nextLowest = na.priority;
}
continue;
}
mPriorityList[insertionPoint--] = na.type;
}
currentLowest = nextLowest;
nextLowest = 0;
}
}
mNetRequestersPids = new ArrayList[ConnectivityManager.MAX_NETWORK_TYPE+1];
for (int i : mPriorityList) {
mNetRequestersPids[i] = new ArrayList();
}
mFeatureUsers = new ArrayList();
mNumDnsEntries = 0;
mTestMode = SystemProperties.get("cm.test.mode").equals("true")
&& SystemProperties.get("ro.build.type").equals("eng");
/*
* Create the network state trackers for Wi-Fi and mobile
* data. Maybe this could be done with a factory class,
* but it's not clear that it's worth it, given that
* the number of different network types is not going
* to change very often.
*/
for (int netType : mPriorityList) {
switch (mNetConfigs[netType].radio) {
case ConnectivityManager.TYPE_WIFI:
if (DBG) log("Starting Wifi Service.");
WifiStateTracker wst = new WifiStateTracker();
WifiService wifiService = new WifiService(context);
ServiceManager.addService(Context.WIFI_SERVICE, wifiService);
wifiService.checkAndStartWifi();
mNetTrackers[ConnectivityManager.TYPE_WIFI] = wst;
wst.startMonitoring(context, mHandler);
//TODO: as part of WWS refactor, create only when needed
mWifiWatchdogService = new WifiWatchdogService(context);
break;
case ConnectivityManager.TYPE_MOBILE:
mNetTrackers[netType] = new MobileDataStateTracker(netType,
mNetConfigs[netType].name);
mNetTrackers[netType].startMonitoring(context, mHandler);
break;
case ConnectivityManager.TYPE_DUMMY:
mNetTrackers[netType] = new DummyDataStateTracker(netType,
mNetConfigs[netType].name);
mNetTrackers[netType].startMonitoring(context, mHandler);
break;
case ConnectivityManager.TYPE_BLUETOOTH:
mNetTrackers[netType] = BluetoothTetheringDataTracker.getInstance();
mNetTrackers[netType].startMonitoring(context, mHandler);
break;
case ConnectivityManager.TYPE_ETHERNET:
mNetTrackers[netType] = EthernetDataTracker.getInstance();
mNetTrackers[netType].startMonitoring(context, mHandler);
break;
default:
loge("Trying to create a DataStateTracker for an unknown radio type " +
mNetConfigs[netType].radio);
continue;
}
}
mTethering = new Tethering(mContext, mHandler.getLooper());
mTetheringConfigValid = (((mNetTrackers[ConnectivityManager.TYPE_MOBILE_DUN] != null) ||
!mTethering.isDunRequired()) &&
(mTethering.getTetherableUsbRegexs().length != 0 ||
mTethering.getTetherableWifiRegexs().length != 0 ||
mTethering.getTetherableBluetoothRegexs().length != 0) &&
mTethering.getUpstreamIfaceRegexs().length != 0);
if (DBG) {
mInetLog = new ArrayList();
}
mSettingsObserver = new SettingsObserver(mHandler, EVENT_APPLY_GLOBAL_HTTP_PROXY);
mSettingsObserver.observe(mContext);
loadGlobalProxy();
VpnManager.startVpnService(context);
}
/**
* Sets the preferred network.
* @param preference the new preference
*/
public void setNetworkPreference(int preference) {
enforceChangePermission();
mHandler.sendMessage(mHandler.obtainMessage(EVENT_SET_NETWORK_PREFERENCE, preference, 0));
}
public int getNetworkPreference() {
enforceAccessPermission();
int preference;
synchronized(this) {
preference = mNetworkPreference;
}
return preference;
}
private void handleSetNetworkPreference(int preference) {
if (ConnectivityManager.isNetworkTypeValid(preference) &&
mNetConfigs[preference] != null &&
mNetConfigs[preference].isDefault()) {
if (mNetworkPreference != preference) {
final ContentResolver cr = mContext.getContentResolver();
Settings.Secure.putInt(cr, Settings.Secure.NETWORK_PREFERENCE, preference);
synchronized(this) {
mNetworkPreference = preference;
}
enforcePreference();
}
}
}
private int getPersistedNetworkPreference() {
final ContentResolver cr = mContext.getContentResolver();
final int networkPrefSetting = Settings.Secure
.getInt(cr, Settings.Secure.NETWORK_PREFERENCE, -1);
if (networkPrefSetting != -1) {
return networkPrefSetting;
}
return ConnectivityManager.DEFAULT_NETWORK_PREFERENCE;
}
/**
* Make the state of network connectivity conform to the preference settings
* In this method, we only tear down a non-preferred network. Establishing
* a connection to the preferred network is taken care of when we handle
* the disconnect event from the non-preferred network
* (see {@link #handleDisconnect(NetworkInfo)}).
*/
private void enforcePreference() {
if (mNetTrackers[mNetworkPreference].getNetworkInfo().isConnected())
return;
if (!mNetTrackers[mNetworkPreference].isAvailable())
return;
for (int t=0; t <= ConnectivityManager.MAX_RADIO_TYPE; t++) {
if (t != mNetworkPreference && mNetTrackers[t] != null &&
mNetTrackers[t].getNetworkInfo().isConnected()) {
if (DBG) {
log("tearing down " + mNetTrackers[t].getNetworkInfo() +
" in enforcePreference");
}
teardown(mNetTrackers[t]);
}
}
}
private boolean teardown(NetworkStateTracker netTracker) {
if (netTracker.teardown()) {
netTracker.setTeardownRequested(true);
return true;
} else {
return false;
}
}
/**
* 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
*/
public NetworkInfo getActiveNetworkInfo() {
return getNetworkInfo(mActiveDefaultNetwork);
}
public NetworkInfo getNetworkInfo(int networkType) {
enforceAccessPermission();
if (ConnectivityManager.isNetworkTypeValid(networkType)) {
NetworkStateTracker t = mNetTrackers[networkType];
if (t != null)
return t.getNetworkInfo();
}
return null;
}
public NetworkInfo[] getAllNetworkInfo() {
enforceAccessPermission();
NetworkInfo[] result = new NetworkInfo[mNetworksDefined];
int i = 0;
for (NetworkStateTracker t : mNetTrackers) {
if(t != null) result[i++] = t.getNetworkInfo();
}
return result;
}
/**
* Return LinkProperties for the active (i.e., connected) default
* network interface. It is assumed that at most one default network
* is active at a time. If more than one is active, it is indeterminate
* which will be returned.
* @return the ip properties for the active network, or {@code null} if
* none is active
*/
public LinkProperties getActiveLinkProperties() {
return getLinkProperties(mActiveDefaultNetwork);
}
public LinkProperties getLinkProperties(int networkType) {
enforceAccessPermission();
if (ConnectivityManager.isNetworkTypeValid(networkType)) {
NetworkStateTracker t = mNetTrackers[networkType];
if (t != null) return t.getLinkProperties();
}
return null;
}
public boolean setRadios(boolean turnOn) {
boolean result = true;
enforceChangePermission();
for (NetworkStateTracker t : mNetTrackers) {
if (t != null) result = t.setRadio(turnOn) && result;
}
return result;
}
public boolean setRadio(int netType, boolean turnOn) {
enforceChangePermission();
if (!ConnectivityManager.isNetworkTypeValid(netType)) {
return false;
}
NetworkStateTracker tracker = mNetTrackers[netType];
return tracker != null && tracker.setRadio(turnOn);
}
/**
* Used to notice when the calling process dies so we can self-expire
*
* Also used to know if the process has cleaned up after itself when
* our auto-expire timer goes off. The timer has a link to an object.
*
*/
private class FeatureUser implements IBinder.DeathRecipient {
int mNetworkType;
String mFeature;
IBinder mBinder;
int mPid;
int mUid;
long mCreateTime;
FeatureUser(int type, String feature, IBinder binder) {
super();
mNetworkType = type;
mFeature = feature;
mBinder = binder;
mPid = getCallingPid();
mUid = getCallingUid();
mCreateTime = System.currentTimeMillis();
try {
mBinder.linkToDeath(this, 0);
} catch (RemoteException e) {
binderDied();
}
}
void unlinkDeathRecipient() {
mBinder.unlinkToDeath(this, 0);
}
public void binderDied() {
log("ConnectivityService FeatureUser binderDied(" +
mNetworkType + ", " + mFeature + ", " + mBinder + "), created " +
(System.currentTimeMillis() - mCreateTime) + " mSec ago");
stopUsingNetworkFeature(this, false);
}
public void expire() {
log("ConnectivityService FeatureUser expire(" +
mNetworkType + ", " + mFeature + ", " + mBinder +"), created " +
(System.currentTimeMillis() - mCreateTime) + " mSec ago");
stopUsingNetworkFeature(this, false);
}
public String toString() {
return "FeatureUser("+mNetworkType+","+mFeature+","+mPid+","+mUid+"), created " +
(System.currentTimeMillis() - mCreateTime) + " mSec ago";
}
}
// javadoc from interface
public int startUsingNetworkFeature(int networkType, String feature,
IBinder binder) {
if (DBG) {
log("startUsingNetworkFeature for net " + networkType + ": " + feature);
}
enforceChangePermission();
if (!ConnectivityManager.isNetworkTypeValid(networkType) ||
mNetConfigs[networkType] == null) {
return Phone.APN_REQUEST_FAILED;
}
FeatureUser f = new FeatureUser(networkType, feature, binder);
// TODO - move this into the MobileDataStateTracker
int usedNetworkType = networkType;
if(networkType == ConnectivityManager.TYPE_MOBILE) {
usedNetworkType = convertFeatureToNetworkType(feature);
if (usedNetworkType < 0) {
Slog.e(TAG, "Can't match any netTracker!");
usedNetworkType = networkType;
}
}
NetworkStateTracker network = mNetTrackers[usedNetworkType];
if (network != null) {
Integer currentPid = new Integer(getCallingPid());
if (usedNetworkType != networkType) {
NetworkStateTracker radio = mNetTrackers[networkType];
NetworkInfo ni = network.getNetworkInfo();
if (ni.isAvailable() == false) {
if (DBG) log("special network not available");
if (!TextUtils.equals(feature,Phone.FEATURE_ENABLE_DUN_ALWAYS)) {
return Phone.APN_TYPE_NOT_AVAILABLE;
} else {
// else make the attempt anyway - probably giving REQUEST_STARTED below
}
}
synchronized(this) {
mFeatureUsers.add(f);
if (!mNetRequestersPids[usedNetworkType].contains(currentPid)) {
// this gets used for per-pid dns when connected
mNetRequestersPids[usedNetworkType].add(currentPid);
}
}
int restoreTimer = getRestoreDefaultNetworkDelay(usedNetworkType);
if (restoreTimer >= 0) {
mHandler.sendMessageDelayed(
mHandler.obtainMessage(EVENT_RESTORE_DEFAULT_NETWORK, f), restoreTimer);
}
if ((ni.isConnectedOrConnecting() == true) &&
!network.isTeardownRequested()) {
if (ni.isConnected() == true) {
// add the pid-specific dns
handleDnsConfigurationChange(networkType);
if (DBG) log("special network already active");
return Phone.APN_ALREADY_ACTIVE;
}
if (DBG) log("special network already connecting");
return Phone.APN_REQUEST_STARTED;
}
// check if the radio in play can make another contact
// assume if cannot for now
if (DBG) log("reconnecting to special network");
network.reconnect();
return Phone.APN_REQUEST_STARTED;
} else {
// need to remember this unsupported request so we respond appropriately on stop
synchronized(this) {
mFeatureUsers.add(f);
if (!mNetRequestersPids[usedNetworkType].contains(currentPid)) {
// this gets used for per-pid dns when connected
mNetRequestersPids[usedNetworkType].add(currentPid);
}
}
return -1;
}
}
return Phone.APN_TYPE_NOT_AVAILABLE;
}
// javadoc from interface
public int stopUsingNetworkFeature(int networkType, String feature) {
enforceChangePermission();
int pid = getCallingPid();
int uid = getCallingUid();
FeatureUser u = null;
boolean found = false;
synchronized(this) {
for (int i = 0; i < mFeatureUsers.size() ; i++) {
u = (FeatureUser)mFeatureUsers.get(i);
if (uid == u.mUid && pid == u.mPid &&
networkType == u.mNetworkType &&
TextUtils.equals(feature, u.mFeature)) {
found = true;
break;
}
}
}
if (found && u != null) {
// stop regardless of how many other time this proc had called start
return stopUsingNetworkFeature(u, true);
} else {
// none found!
if (DBG) log("ignoring stopUsingNetworkFeature - not a live request");
return 1;
}
}
private int stopUsingNetworkFeature(FeatureUser u, boolean ignoreDups) {
int networkType = u.mNetworkType;
String feature = u.mFeature;
int pid = u.mPid;
int uid = u.mUid;
NetworkStateTracker tracker = null;
boolean callTeardown = false; // used to carry our decision outside of sync block
if (DBG) {
log("stopUsingNetworkFeature for net " + networkType +
": " + feature);
}
if (!ConnectivityManager.isNetworkTypeValid(networkType)) {
return -1;
}
// need to link the mFeatureUsers list with the mNetRequestersPids state in this
// sync block
synchronized(this) {
// check if this process still has an outstanding start request
if (!mFeatureUsers.contains(u)) {
if (DBG) log("ignoring - this process has no outstanding requests");
return 1;
}
u.unlinkDeathRecipient();
mFeatureUsers.remove(mFeatureUsers.indexOf(u));
// If we care about duplicate requests, check for that here.
//
// This is done to support the extension of a request - the app
// can request we start the network feature again and renew the
// auto-shutoff delay. Normal "stop" calls from the app though
// do not pay attention to duplicate requests - in effect the
// API does not refcount and a single stop will counter multiple starts.
if (ignoreDups == false) {
for (int i = 0; i < mFeatureUsers.size() ; i++) {
FeatureUser x = (FeatureUser)mFeatureUsers.get(i);
if (x.mUid == u.mUid && x.mPid == u.mPid &&
x.mNetworkType == u.mNetworkType &&
TextUtils.equals(x.mFeature, u.mFeature)) {
if (DBG) log("ignoring stopUsingNetworkFeature as dup is found");
return 1;
}
}
}
// TODO - move to MobileDataStateTracker
int usedNetworkType = networkType;
if (networkType == ConnectivityManager.TYPE_MOBILE) {
usedNetworkType = convertFeatureToNetworkType(feature);
if (usedNetworkType < 0) {
usedNetworkType = networkType;
}
}
tracker = mNetTrackers[usedNetworkType];
if (tracker == null) {
if (DBG) log("ignoring - no known tracker for net type " + usedNetworkType);
return -1;
}
if (usedNetworkType != networkType) {
Integer currentPid = new Integer(pid);
mNetRequestersPids[usedNetworkType].remove(currentPid);
reassessPidDns(pid, true);
if (mNetRequestersPids[usedNetworkType].size() != 0) {
if (DBG) log("not tearing down special network - " +
"others still using it");
return 1;
}
callTeardown = true;
} else {
if (DBG) log("not a known feature - dropping");
}
}
if (DBG) log("Doing network teardown");
if (callTeardown) {
tracker.teardown();
return 1;
} else {
return -1;
}
}
/**
* @deprecated use requestRouteToHostAddress instead
*
* 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
*/
public boolean requestRouteToHost(int networkType, int hostAddress) {
InetAddress inetAddress = NetworkUtils.intToInetAddress(hostAddress);
if (inetAddress == null) {
return false;
}
return requestRouteToHostAddress(networkType, inetAddress.getAddress());
}
/**
* 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
*/
public boolean requestRouteToHostAddress(int networkType, byte[] hostAddress) {
enforceChangePermission();
if (!ConnectivityManager.isNetworkTypeValid(networkType)) {
return false;
}
NetworkStateTracker tracker = mNetTrackers[networkType];
if (tracker == null || !tracker.getNetworkInfo().isConnected() ||
tracker.isTeardownRequested()) {
if (DBG) {
log("requestRouteToHostAddress on down network " +
"(" + networkType + ") - dropped");
}
return false;
}
try {
InetAddress addr = InetAddress.getByAddress(hostAddress);
return addHostRoute(tracker, addr, 0);
} catch (UnknownHostException e) {}
return false;
}
/**
* Ensure that a network route exists to deliver traffic to the specified
* host via the mobile data network.
* @param hostAddress the IP address of the host to which the route is desired,
* in network byte order.
* TODO - deprecate
* @return {@code true} on success, {@code false} on failure
*/
private boolean addHostRoute(NetworkStateTracker nt, InetAddress hostAddress, int cycleCount) {
LinkProperties lp = nt.getLinkProperties();
if ((lp == null) || (hostAddress == null)) return false;
String interfaceName = lp.getInterfaceName();
if (DBG) {
log("Requested host route to " + hostAddress + "(" + interfaceName + "), cycleCount=" +
cycleCount);
}
if (interfaceName == null) {
if (DBG) loge("addHostRoute failed due to null interface name");
return false;
}
RouteInfo bestRoute = RouteInfo.selectBestRoute(lp.getRoutes(), hostAddress);
InetAddress gatewayAddress = null;
if (bestRoute != null) {
gatewayAddress = bestRoute.getGateway();
// if the best route is ourself, don't relf-reference, just add the host route
if (hostAddress.equals(gatewayAddress)) gatewayAddress = null;
}
if (gatewayAddress != null) {
if (cycleCount > MAX_HOSTROUTE_CYCLE_COUNT) {
loge("Error adding hostroute - too much recursion");
return false;
}
if (!addHostRoute(nt, gatewayAddress, cycleCount+1)) return false;
}
RouteInfo route = RouteInfo.makeHostRoute(hostAddress, gatewayAddress);
try {
mNetd.addRoute(interfaceName, route);
return true;
} catch (Exception ex) {
return false;
}
}
// TODO support the removal of single host routes. Keep a ref count of them so we
// aren't over-zealous
private boolean removeHostRoute(NetworkStateTracker nt, InetAddress hostAddress) {
return false;
}
/**
* @see ConnectivityManager#getBackgroundDataSetting()
*/
public boolean getBackgroundDataSetting() {
return mBackgroundDataEnabled.get();
}
/**
* @see ConnectivityManager#setBackgroundDataSetting(boolean)
*/
public void setBackgroundDataSetting(boolean allowBackgroundDataUsage) {
mContext.enforceCallingOrSelfPermission(
android.Manifest.permission.CHANGE_BACKGROUND_DATA_SETTING,
"ConnectivityService");
mBackgroundDataEnabled.set(allowBackgroundDataUsage);
mHandler.sendMessage(mHandler.obtainMessage(EVENT_SET_BACKGROUND_DATA,
(allowBackgroundDataUsage ? ENABLED : DISABLED), 0));
}
private void handleSetBackgroundData(boolean enabled) {
Settings.Secure.putInt(mContext.getContentResolver(),
Settings.Secure.BACKGROUND_DATA, enabled ? 1 : 0);
Intent broadcast = new Intent(
ConnectivityManager.ACTION_BACKGROUND_DATA_SETTING_CHANGED);
mContext.sendBroadcast(broadcast);
}
/**
* @see ConnectivityManager#getMobileDataEnabled()
*/
public boolean getMobileDataEnabled() {
// TODO: This detail should probably be in DataConnectionTracker's
// which is where we store the value and maybe make this
// asynchronous.
enforceAccessPermission();
boolean retVal = Settings.Secure.getInt(mContext.getContentResolver(),
Settings.Secure.MOBILE_DATA, 1) == 1;
if (DBG) log("getMobileDataEnabled returning " + retVal);
return retVal;
}
public void setDataDependency(int networkType, boolean met) {
enforceChangePermission();
if (DBG) {
log("setDataDependency(" + networkType + ", " + met + ")");
}
mHandler.sendMessage(mHandler.obtainMessage(EVENT_SET_DEPENDENCY_MET,
(met ? ENABLED : DISABLED), networkType));
}
private void handleSetDependencyMet(int networkType, boolean met) {
if (mNetTrackers[networkType] != null) {
if (DBG) {
log("handleSetDependencyMet(" + networkType + ", " + met + ")");
}
mNetTrackers[networkType].setDependencyMet(met);
}
}
/**
* @see ConnectivityManager#setMobileDataEnabled(boolean)
*/
public void setMobileDataEnabled(boolean enabled) {
enforceChangePermission();
if (DBG) log("setMobileDataEnabled(" + enabled + ")");
mHandler.sendMessage(mHandler.obtainMessage(EVENT_SET_MOBILE_DATA,
(enabled ? ENABLED : DISABLED), 0));
}
private void handleSetMobileData(boolean enabled) {
if (mNetTrackers[ConnectivityManager.TYPE_MOBILE] != null) {
if (DBG) {
Slog.d(TAG, mNetTrackers[ConnectivityManager.TYPE_MOBILE].toString() + enabled);
}
mNetTrackers[ConnectivityManager.TYPE_MOBILE].setDataEnable(enabled);
}
}
private void enforceAccessPermission() {
mContext.enforceCallingOrSelfPermission(
android.Manifest.permission.ACCESS_NETWORK_STATE,
"ConnectivityService");
}
private void enforceChangePermission() {
mContext.enforceCallingOrSelfPermission(
android.Manifest.permission.CHANGE_NETWORK_STATE,
"ConnectivityService");
}
// TODO Make this a special check when it goes public
private void enforceTetherChangePermission() {
mContext.enforceCallingOrSelfPermission(
android.Manifest.permission.CHANGE_NETWORK_STATE,
"ConnectivityService");
}
private void enforceTetherAccessPermission() {
mContext.enforceCallingOrSelfPermission(
android.Manifest.permission.ACCESS_NETWORK_STATE,
"ConnectivityService");
}
private void enforceConnectivityInternalPermission() {
mContext.enforceCallingOrSelfPermission(
android.Manifest.permission.CONNECTIVITY_INTERNAL,
"ConnectivityService");
}
/**
* Handle a {@code DISCONNECTED} event. If this pertains to the non-active
* network, we ignore it. If it is for the active network, we send out a
* broadcast. But first, we check whether it might be possible to connect
* to a different network.
* @param info the {@code NetworkInfo} for the network
*/
private void handleDisconnect(NetworkInfo info) {
int prevNetType = info.getType();
mNetTrackers[prevNetType].setTeardownRequested(false);
/*
* If the disconnected network is not the active one, then don't report
* this as a loss of connectivity. What probably happened is that we're
* getting the disconnect for a network that we explicitly disabled
* in accordance with network preference policies.
*/
if (!mNetConfigs[prevNetType].isDefault()) {
List pids = mNetRequestersPids[prevNetType];
for (int i = 0; i<pids.size(); i++) {
Integer pid = (Integer)pids.get(i);
// will remove them because the net's no longer connected
// need to do this now as only now do we know the pids and
// can properly null things that are no longer referenced.
reassessPidDns(pid.intValue(), false);
}
}
Intent intent = new Intent(ConnectivityManager.CONNECTIVITY_ACTION);
intent.putExtra(ConnectivityManager.EXTRA_NETWORK_INFO, info);
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());
}
if (mNetConfigs[prevNetType].isDefault()) {
tryFailover(prevNetType);
if (mActiveDefaultNetwork != -1) {
NetworkInfo switchTo = mNetTrackers[mActiveDefaultNetwork].getNetworkInfo();
intent.putExtra(ConnectivityManager.EXTRA_OTHER_NETWORK_INFO, switchTo);
} else {
mDefaultInetConditionPublished = 0; // we're not connected anymore
intent.putExtra(ConnectivityManager.EXTRA_NO_CONNECTIVITY, true);
}
}
intent.putExtra(ConnectivityManager.EXTRA_INET_CONDITION, mDefaultInetConditionPublished);
// do this before we broadcast the change
handleConnectivityChange(prevNetType);
sendStickyBroadcast(intent);
/*
* If the failover network is already connected, then immediately send
* out a followup broadcast indicating successful failover
*/
if (mActiveDefaultNetwork != -1) {
sendConnectedBroadcast(mNetTrackers[mActiveDefaultNetwork].getNetworkInfo());
}
}
private void tryFailover(int prevNetType) {
/*
* If this is a default network, check if other defaults are available.
* Try to reconnect on all available and let them hash it out when
* more than one connects.
*/
if (mNetConfigs[prevNetType].isDefault()) {
if (mActiveDefaultNetwork == prevNetType) {
mActiveDefaultNetwork = -1;
}
// don't signal a reconnect for anything lower or equal priority than our
// current connected default
// TODO - don't filter by priority now - nice optimization but risky
// int currentPriority = -1;
// if (mActiveDefaultNetwork != -1) {
// currentPriority = mNetConfigs[mActiveDefaultNetwork].mPriority;
// }
for (int checkType=0; checkType <= ConnectivityManager.MAX_NETWORK_TYPE; checkType++) {
if (checkType == prevNetType) continue;
if (mNetConfigs[checkType] == null) continue;
if (!mNetConfigs[checkType].isDefault()) continue;
// Enabling the isAvailable() optimization caused mobile to not get
// selected if it was in the middle of error handling. Specifically
// a moble connection that took 30 seconds to complete the DEACTIVATE_DATA_CALL
// would not be available and we wouldn't get connected to anything.
// So removing the isAvailable() optimization below for now. TODO: This
// optimization should work and we need to investigate why it doesn't work.
// This could be related to how DEACTIVATE_DATA_CALL is reporting its
// complete before it is really complete.
// if (!mNetTrackers[checkType].isAvailable()) continue;
// if (currentPriority >= mNetConfigs[checkType].mPriority) continue;
NetworkStateTracker checkTracker = mNetTrackers[checkType];
NetworkInfo checkInfo = checkTracker.getNetworkInfo();
if (!checkInfo.isConnectedOrConnecting() || checkTracker.isTeardownRequested()) {
checkInfo.setFailover(true);
checkTracker.reconnect();
}
if (DBG) log("Attempting to switch to " + checkInfo.getTypeName());
}
}
}
private void sendConnectedBroadcast(NetworkInfo info) {
sendGeneralBroadcast(info, ConnectivityManager.CONNECTIVITY_ACTION);
}
private void sendInetConditionBroadcast(NetworkInfo info) {
sendGeneralBroadcast(info, ConnectivityManager.INET_CONDITION_ACTION);
}
private void sendGeneralBroadcast(NetworkInfo info, String bcastType) {
Intent intent = new Intent(bcastType);
intent.putExtra(ConnectivityManager.EXTRA_NETWORK_INFO, info);
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);
sendStickyBroadcast(intent);
}
/**
* Called when an attempt to fail over to another network has failed.
* @param info the {@link NetworkInfo} for the failed network
*/
private void handleConnectionFailure(NetworkInfo info) {
mNetTrackers[info.getType()].setTeardownRequested(false);
String reason = info.getReason();
String extraInfo = info.getExtraInfo();
String reasonText;
if (reason == null) {
reasonText = ".";
} else {
reasonText = " (" + reason + ").";
}
loge("Attempt to connect to " + info.getTypeName() + " failed" + reasonText);
Intent intent = new Intent(ConnectivityManager.CONNECTIVITY_ACTION);
intent.putExtra(ConnectivityManager.EXTRA_NETWORK_INFO, info);
if (getActiveNetworkInfo() == null) {
intent.putExtra(ConnectivityManager.EXTRA_NO_CONNECTIVITY, true);
}
if (reason != null) {
intent.putExtra(ConnectivityManager.EXTRA_REASON, reason);
}
if (extraInfo != null) {
intent.putExtra(ConnectivityManager.EXTRA_EXTRA_INFO, extraInfo);
}
if (info.isFailover()) {
intent.putExtra(ConnectivityManager.EXTRA_IS_FAILOVER, true);
info.setFailover(false);
}
if (mNetConfigs[info.getType()].isDefault()) {
tryFailover(info.getType());
if (mActiveDefaultNetwork != -1) {
NetworkInfo switchTo = mNetTrackers[mActiveDefaultNetwork].getNetworkInfo();
intent.putExtra(ConnectivityManager.EXTRA_OTHER_NETWORK_INFO, switchTo);
} else {
mDefaultInetConditionPublished = 0;
intent.putExtra(ConnectivityManager.EXTRA_NO_CONNECTIVITY, true);
}
}
intent.putExtra(ConnectivityManager.EXTRA_INET_CONDITION, mDefaultInetConditionPublished);
sendStickyBroadcast(intent);
/*
* If the failover network is already connected, then immediately send
* out a followup broadcast indicating successful failover
*/
if (mActiveDefaultNetwork != -1) {
sendConnectedBroadcast(mNetTrackers[mActiveDefaultNetwork].getNetworkInfo());
}
}
private void sendStickyBroadcast(Intent intent) {
synchronized(this) {
if (!mSystemReady) {
mInitialBroadcast = new Intent(intent);
}
intent.addFlags(Intent.FLAG_RECEIVER_REGISTERED_ONLY_BEFORE_BOOT);
mContext.sendStickyBroadcast(intent);
}
}
void systemReady() {
IBinder b = ServiceManager.getService(Context.NETWORKMANAGEMENT_SERVICE);
mNetd = INetworkManagementService.Stub.asInterface(b);
synchronized(this) {
mSystemReady = true;
if (mInitialBroadcast != null) {
mContext.sendStickyBroadcast(mInitialBroadcast);
mInitialBroadcast = null;
}
}
// load the global proxy at startup
mHandler.sendMessage(mHandler.obtainMessage(EVENT_APPLY_GLOBAL_HTTP_PROXY));
}
private void handleConnect(NetworkInfo info) {
int type = info.getType();
// snapshot isFailover, because sendConnectedBroadcast() resets it
boolean isFailover = info.isFailover();
NetworkStateTracker thisNet = mNetTrackers[type];
// if this is a default net and other default is running
// kill the one not preferred
if (mNetConfigs[type].isDefault()) {
if (mActiveDefaultNetwork != -1 && mActiveDefaultNetwork != type) {
if ((type != mNetworkPreference &&
mNetConfigs[mActiveDefaultNetwork].priority >
mNetConfigs[type].priority) ||
mNetworkPreference == mActiveDefaultNetwork) {
// don't accept this one
if (DBG) {
log("Not broadcasting CONNECT_ACTION " +
"to torn down network " + info.getTypeName());
}
teardown(thisNet);
return;
} else {
// tear down the other
NetworkStateTracker otherNet =
mNetTrackers[mActiveDefaultNetwork];
if (DBG) {
log("Policy requires " + otherNet.getNetworkInfo().getTypeName() +
" teardown");
}
if (!teardown(otherNet)) {
loge("Network declined teardown request");
return;
}
}
}
synchronized (ConnectivityService.this) {
// have a new default network, release the transition wakelock in a second
// if it's held. The second pause is to allow apps to reconnect over the
// new network
if (mNetTransitionWakeLock.isHeld()) {
mHandler.sendMessageDelayed(mHandler.obtainMessage(
EVENT_CLEAR_NET_TRANSITION_WAKELOCK,
mNetTransitionWakeLockSerialNumber, 0),
1000);
}
}
mActiveDefaultNetwork = type;
// this will cause us to come up initially as unconnected and switching
// to connected after our normal pause unless somebody reports us as reall
// disconnected
mDefaultInetConditionPublished = 0;
mDefaultConnectionSequence++;
mInetConditionChangeInFlight = false;
// Don't do this - if we never sign in stay, grey
//reportNetworkCondition(mActiveDefaultNetwork, 100);
}
thisNet.setTeardownRequested(false);
updateNetworkSettings(thisNet);
handleConnectivityChange(type);
sendConnectedBroadcast(info);
}
/**
* After a change in the connectivity state of a network. We're mainly
* concerned with making sure that the list of DNS servers is set up
* according to which networks are connected, and ensuring that the
* right routing table entries exist.
*/
private void handleConnectivityChange(int netType) {
/*
* If a non-default network is enabled, add the host routes that
* will allow it's DNS servers to be accessed.
*/
handleDnsConfigurationChange(netType);
if (mNetTrackers[netType].getNetworkInfo().isConnected()) {
if (mNetConfigs[netType].isDefault()) {
handleApplyDefaultProxy(netType);
addDefaultRoute(mNetTrackers[netType]);
} else {
addPrivateDnsRoutes(mNetTrackers[netType]);
}
/** Notify TetheringService if interface name has been changed. */
if (TextUtils.equals(mNetTrackers[netType].getNetworkInfo().getReason(),
Phone.REASON_LINK_PROPERTIES_CHANGED)) {
handleTetherIfaceChange(netType);
}
} else {
if (mNetConfigs[netType].isDefault()) {
removeDefaultRoute(mNetTrackers[netType]);
} else {
removePrivateDnsRoutes(mNetTrackers[netType]);
}
}
}
private void addPrivateDnsRoutes(NetworkStateTracker nt) {
boolean privateDnsRouteSet = nt.isPrivateDnsRouteSet();
LinkProperties p = nt.getLinkProperties();
if (p == null) return;
String interfaceName = p.getInterfaceName();
if (DBG) {
log("addPrivateDnsRoutes for " + nt +
"(" + interfaceName + ") - mPrivateDnsRouteSet = " + privateDnsRouteSet);
}
if (interfaceName != null && !privateDnsRouteSet) {
Collection<InetAddress> dnsList = p.getDnses();
for (InetAddress dns : dnsList) {
addHostRoute(nt, dns, 0);
}
nt.privateDnsRouteSet(true);
}
}
private void removePrivateDnsRoutes(NetworkStateTracker nt) {
LinkProperties p = nt.getLinkProperties();
if (p == null) return;
String interfaceName = p.getInterfaceName();
boolean privateDnsRouteSet = nt.isPrivateDnsRouteSet();
if (interfaceName != null && privateDnsRouteSet) {
if (DBG) {
log("removePrivateDnsRoutes for " + nt.getNetworkInfo().getTypeName() +
" (" + interfaceName + ")");
}
Collection<InetAddress> dnsList = p.getDnses();
for (InetAddress dns : dnsList) {
if (DBG) log(" removing " + dns);
RouteInfo route = RouteInfo.makeHostRoute(dns);
try {
mNetd.removeRoute(interfaceName, route);
} catch (Exception ex) {
loge("error (" + ex + ") removing dns route " + route);
}
}
nt.privateDnsRouteSet(false);
}
}
private void addDefaultRoute(NetworkStateTracker nt) {
LinkProperties p = nt.getLinkProperties();
if (p == null) return;
String interfaceName = p.getInterfaceName();
if (TextUtils.isEmpty(interfaceName)) return;
for (RouteInfo route : p.getRoutes()) {
//TODO - handle non-default routes
if (route.isDefaultRoute()) {
if (DBG) log("adding default route " + route);
InetAddress gateway = route.getGateway();
if (addHostRoute(nt, gateway, 0)) {
try {
mNetd.addRoute(interfaceName, route);
} catch (Exception e) {
loge("error adding default route " + route);
continue;
}
if (DBG) {
NetworkInfo networkInfo = nt.getNetworkInfo();
log("addDefaultRoute for " + networkInfo.getTypeName() +
" (" + interfaceName + "), GatewayAddr=" +
gateway.getHostAddress());
}
} else {
loge("error adding host route for default route " + route);
}
}
}
}
public void removeDefaultRoute(NetworkStateTracker nt) {
LinkProperties p = nt.getLinkProperties();
if (p == null) return;
String interfaceName = p.getInterfaceName();
if (interfaceName == null) return;
for (RouteInfo route : p.getRoutes()) {
//TODO - handle non-default routes
if (route.isDefaultRoute()) {
try {
mNetd.removeRoute(interfaceName, route);
} catch (Exception ex) {
loge("error (" + ex + ") removing default route " + route);
continue;
}
if (DBG) {
NetworkInfo networkInfo = nt.getNetworkInfo();
log("removeDefaultRoute for " + networkInfo.getTypeName() + " (" +
interfaceName + ")");
}
}
}
}
/**
* Reads the network specific TCP buffer sizes from SystemProperties
* net.tcp.buffersize.[default|wifi|umts|edge|gprs] and set them for system
* wide use
*/
public void updateNetworkSettings(NetworkStateTracker nt) {
String key = nt.getTcpBufferSizesPropName();
String bufferSizes = SystemProperties.get(key);
if (bufferSizes.length() == 0) {
loge(key + " not found in system properties. Using defaults");
// Setting to default values so we won't be stuck to previous values
key = "net.tcp.buffersize.default";
bufferSizes = SystemProperties.get(key);
}
// Set values in kernel
if (bufferSizes.length() != 0) {
if (DBG) {
log("Setting TCP values: [" + bufferSizes
+ "] which comes from [" + key + "]");
}
setBufferSize(bufferSizes);
}
}
/**
* Writes TCP buffer sizes to /sys/kernel/ipv4/tcp_[r/w]mem_[min/def/max]
* which maps to /proc/sys/net/ipv4/tcp_rmem and tcpwmem
*
* @param bufferSizes in the format of "readMin, readInitial, readMax,
* writeMin, writeInitial, writeMax"
*/
private void setBufferSize(String bufferSizes) {
try {
String[] values = bufferSizes.split(",");
if (values.length == 6) {
final String prefix = "/sys/kernel/ipv4/tcp_";
stringToFile(prefix + "rmem_min", values[0]);
stringToFile(prefix + "rmem_def", values[1]);
stringToFile(prefix + "rmem_max", values[2]);
stringToFile(prefix + "wmem_min", values[3]);
stringToFile(prefix + "wmem_def", values[4]);
stringToFile(prefix + "wmem_max", values[5]);
} else {
loge("Invalid buffersize string: " + bufferSizes);
}
} catch (IOException e) {
loge("Can't set tcp buffer sizes:" + e);
}
}
/**
* Writes string to file. Basically same as "echo -n $string > $filename"
*
* @param filename
* @param string
* @throws IOException
*/
private void stringToFile(String filename, String string) throws IOException {
FileWriter out = new FileWriter(filename);
try {
out.write(string);
} finally {
out.close();
}
}
/**
* Adjust the per-process dns entries (net.dns<x>.<pid>) based
* on the highest priority active net which this process requested.
* If there aren't any, clear it out
*/
private void reassessPidDns(int myPid, boolean doBump)
{
if (DBG) log("reassessPidDns for pid " + myPid);
for(int i : mPriorityList) {
if (mNetConfigs[i].isDefault()) {
continue;
}
NetworkStateTracker nt = mNetTrackers[i];
if (nt.getNetworkInfo().isConnected() &&
!nt.isTeardownRequested()) {
LinkProperties p = nt.getLinkProperties();
if (p == null) continue;
List pids = mNetRequestersPids[i];
for (int j=0; j<pids.size(); j++) {
Integer pid = (Integer)pids.get(j);
if (pid.intValue() == myPid) {
Collection<InetAddress> dnses = p.getDnses();
writePidDns(dnses, myPid);
if (doBump) {
bumpDns();
}
return;
}
}
}
}
// nothing found - delete
for (int i = 1; ; i++) {
String prop = "net.dns" + i + "." + myPid;
if (SystemProperties.get(prop).length() == 0) {
if (doBump) {
bumpDns();
}
return;
}
SystemProperties.set(prop, "");
}
}
// return true if results in a change
private boolean writePidDns(Collection <InetAddress> dnses, int pid) {
int j = 1;
boolean changed = false;
for (InetAddress dns : dnses) {
String dnsString = dns.getHostAddress();
if (changed || !dnsString.equals(SystemProperties.get("net.dns" + j + "." + pid))) {
changed = true;
SystemProperties.set("net.dns" + j++ + "." + pid, dns.getHostAddress());
}
}
return changed;
}
private void bumpDns() {
/*
* Bump the property that tells the name resolver library to reread
* the DNS server list from the properties.
*/
String propVal = SystemProperties.get("net.dnschange");
int n = 0;
if (propVal.length() != 0) {
try {
n = Integer.parseInt(propVal);
} catch (NumberFormatException e) {}
}
SystemProperties.set("net.dnschange", "" + (n+1));
/*
* Tell the VMs to toss their DNS caches
*/
Intent intent = new Intent(Intent.ACTION_CLEAR_DNS_CACHE);
intent.addFlags(Intent.FLAG_RECEIVER_REPLACE_PENDING);
/*
* Connectivity events can happen before boot has completed ...
*/
intent.addFlags(Intent.FLAG_RECEIVER_REGISTERED_ONLY_BEFORE_BOOT);
mContext.sendBroadcast(intent);
}
private void handleDnsConfigurationChange(int netType) {
// add default net's dns entries
NetworkStateTracker nt = mNetTrackers[netType];
if (nt != null && nt.getNetworkInfo().isConnected() && !nt.isTeardownRequested()) {
LinkProperties p = nt.getLinkProperties();
if (p == null) return;
Collection<InetAddress> dnses = p.getDnses();
boolean changed = false;
if (mNetConfigs[netType].isDefault()) {
int j = 1;
if (dnses.size() == 0 && mDefaultDns != null) {
String dnsString = mDefaultDns.getHostAddress();
if (!dnsString.equals(SystemProperties.get("net.dns1"))) {
if (DBG) {
log("no dns provided - using " + dnsString);
}
changed = true;
SystemProperties.set("net.dns1", dnsString);
}
j++;
} else {
for (InetAddress dns : dnses) {
String dnsString = dns.getHostAddress();
if (!changed && dnsString.equals(SystemProperties.get("net.dns" + j))) {
j++;
continue;
}
if (DBG) {
log("adding dns " + dns + " for " +
nt.getNetworkInfo().getTypeName());
}
changed = true;
SystemProperties.set("net.dns" + j++, dnsString);
}
}
for (int k=j ; k<mNumDnsEntries; k++) {
if (changed || !TextUtils.isEmpty(SystemProperties.get("net.dns" + k))) {
if (DBG) log("erasing net.dns" + k);
changed = true;
SystemProperties.set("net.dns" + k, "");
}
}
mNumDnsEntries = j;
} else {
// set per-pid dns for attached secondary nets
List pids = mNetRequestersPids[netType];
for (int y=0; y< pids.size(); y++) {
Integer pid = (Integer)pids.get(y);
changed = writePidDns(dnses, pid.intValue());
}
}
if (changed) bumpDns();
}
}
private int getRestoreDefaultNetworkDelay(int networkType) {
String restoreDefaultNetworkDelayStr = SystemProperties.get(
NETWORK_RESTORE_DELAY_PROP_NAME);
if(restoreDefaultNetworkDelayStr != null &&
restoreDefaultNetworkDelayStr.length() != 0) {
try {
return Integer.valueOf(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 ((networkType <= ConnectivityManager.MAX_NETWORK_TYPE) &&
(mNetConfigs[networkType] != null)) {
ret = mNetConfigs[networkType].restoreTime;
}
return ret;
}
@Override
protected void dump(FileDescriptor fd, PrintWriter pw, String[] args) {
if (mContext.checkCallingOrSelfPermission(
android.Manifest.permission.DUMP)
!= PackageManager.PERMISSION_GRANTED) {
pw.println("Permission Denial: can't dump ConnectivityService " +
"from from pid=" + Binder.getCallingPid() + ", uid=" +
Binder.getCallingUid());
return;
}
pw.println();
for (NetworkStateTracker nst : mNetTrackers) {
if (nst != null) {
if (nst.getNetworkInfo().isConnected()) {
pw.println("Active network: " + nst.getNetworkInfo().
getTypeName());
}
pw.println(nst.getNetworkInfo());
pw.println(nst);
pw.println();
}
}
pw.println("Network Requester Pids:");
for (int net : mPriorityList) {
String pidString = net + ": ";
for (Object pid : mNetRequestersPids[net]) {
pidString = pidString + pid.toString() + ", ";
}
pw.println(pidString);
}
pw.println();
pw.println("FeatureUsers:");
for (Object requester : mFeatureUsers) {
pw.println(requester.toString());
}
pw.println();
synchronized (this) {
pw.println("NetworkTranstionWakeLock is currently " +
(mNetTransitionWakeLock.isHeld() ? "" : "not ") + "held.");
pw.println("It was last requested for "+mNetTransitionWakeLockCausedBy);
}
pw.println();
mTethering.dump(fd, pw, args);
if (mInetLog != null) {
pw.println();
pw.println("Inet condition reports:");
for(int i = 0; i < mInetLog.size(); i++) {
pw.println(mInetLog.get(i));
}
}
}
// must be stateless - things change under us.
private class MyHandler extends Handler {
public MyHandler(Looper looper) {
super(looper);
}
@Override
public void handleMessage(Message msg) {
NetworkInfo info;
switch (msg.what) {
case NetworkStateTracker.EVENT_STATE_CHANGED:
info = (NetworkInfo) msg.obj;
int type = info.getType();
NetworkInfo.State state = info.getState();
if (DBG) log("ConnectivityChange for " +
info.getTypeName() + ": " +
state + "/" + info.getDetailedState());
// Connectivity state changed:
// [31-13] Reserved for future use
// [12-9] Network subtype (for mobile network, as defined
// by TelephonyManager)
// [8-3] Detailed state ordinal (as defined by
// NetworkInfo.DetailedState)
// [2-0] Network type (as defined by ConnectivityManager)
int eventLogParam = (info.getType() & 0x7) |
((info.getDetailedState().ordinal() & 0x3f) << 3) |
(info.getSubtype() << 9);
EventLog.writeEvent(EventLogTags.CONNECTIVITY_STATE_CHANGED,
eventLogParam);
if (info.getDetailedState() ==
NetworkInfo.DetailedState.FAILED) {
handleConnectionFailure(info);
} else if (state == NetworkInfo.State.DISCONNECTED) {
handleDisconnect(info);
} else if (state == NetworkInfo.State.SUSPENDED) {
// TODO: need to think this over.
// the logic here is, handle SUSPENDED the same as
// DISCONNECTED. The only difference being we are
// broadcasting an intent with NetworkInfo that's
// suspended. This allows the applications an
// opportunity to handle DISCONNECTED and SUSPENDED
// differently, or not.
handleDisconnect(info);
} else if (state == NetworkInfo.State.CONNECTED) {
handleConnect(info);
}
break;
case NetworkStateTracker.EVENT_CONFIGURATION_CHANGED:
info = (NetworkInfo) msg.obj;
handleConnectivityChange(info.getType());
break;
case EVENT_CLEAR_NET_TRANSITION_WAKELOCK:
String causedBy = null;
synchronized (ConnectivityService.this) {
if (msg.arg1 == mNetTransitionWakeLockSerialNumber &&
mNetTransitionWakeLock.isHeld()) {
mNetTransitionWakeLock.release();
causedBy = mNetTransitionWakeLockCausedBy;
}
}
if (causedBy != null) {
log("NetTransition Wakelock for " + causedBy + " released by timeout");
}
break;
case EVENT_RESTORE_DEFAULT_NETWORK:
FeatureUser u = (FeatureUser)msg.obj;
u.expire();
break;
case EVENT_INET_CONDITION_CHANGE:
{
int netType = msg.arg1;
int condition = msg.arg2;
handleInetConditionChange(netType, condition);
break;
}
case EVENT_INET_CONDITION_HOLD_END:
{
int netType = msg.arg1;
int sequence = msg.arg2;
handleInetConditionHoldEnd(netType, sequence);
break;
}
case EVENT_SET_NETWORK_PREFERENCE:
{
int preference = msg.arg1;
handleSetNetworkPreference(preference);
break;
}
case EVENT_SET_BACKGROUND_DATA:
{
boolean enabled = (msg.arg1 == ENABLED);
handleSetBackgroundData(enabled);
break;
}
case EVENT_SET_MOBILE_DATA:
{
boolean enabled = (msg.arg1 == ENABLED);
handleSetMobileData(enabled);
break;
}
case EVENT_APPLY_GLOBAL_HTTP_PROXY:
{
handleDeprecatedGlobalHttpProxy();
break;
}
case EVENT_SET_DEPENDENCY_MET:
{
boolean met = (msg.arg1 == ENABLED);
handleSetDependencyMet(msg.arg2, met);
break;
}
}
}
}
// javadoc from interface
public int tether(String iface) {
enforceTetherChangePermission();
if (isTetheringSupported()) {
return mTethering.tether(iface);
} else {
return ConnectivityManager.TETHER_ERROR_UNSUPPORTED;
}
}
// javadoc from interface
public int untether(String iface) {
enforceTetherChangePermission();
if (isTetheringSupported()) {
return mTethering.untether(iface);
} else {
return ConnectivityManager.TETHER_ERROR_UNSUPPORTED;
}
}
// javadoc from interface
public int getLastTetherError(String iface) {
enforceTetherAccessPermission();
if (isTetheringSupported()) {
return mTethering.getLastTetherError(iface);
} else {
return ConnectivityManager.TETHER_ERROR_UNSUPPORTED;
}
}
// TODO - proper iface API for selection by property, inspection, etc
public String[] getTetherableUsbRegexs() {
enforceTetherAccessPermission();
if (isTetheringSupported()) {
return mTethering.getTetherableUsbRegexs();
} else {
return new String[0];
}
}
public String[] getTetherableWifiRegexs() {
enforceTetherAccessPermission();
if (isTetheringSupported()) {
return mTethering.getTetherableWifiRegexs();
} else {
return new String[0];
}
}
public String[] getTetherableBluetoothRegexs() {
enforceTetherAccessPermission();
if (isTetheringSupported()) {
return mTethering.getTetherableBluetoothRegexs();
} else {
return new String[0];
}
}
// TODO - move iface listing, queries, etc to new module
// javadoc from interface
public String[] getTetherableIfaces() {
enforceTetherAccessPermission();
return mTethering.getTetherableIfaces();
}
public String[] getTetheredIfaces() {
enforceTetherAccessPermission();
return mTethering.getTetheredIfaces();
}
public String[] getTetheringErroredIfaces() {
enforceTetherAccessPermission();
return mTethering.getErroredIfaces();
}
// if ro.tether.denied = true we default to no tethering
// gservices could set the secure setting to 1 though to enable it on a build where it
// had previously been turned off.
public boolean isTetheringSupported() {
enforceTetherAccessPermission();
int defaultVal = (SystemProperties.get("ro.tether.denied").equals("true") ? 0 : 1);
boolean tetherEnabledInSettings = (Settings.Secure.getInt(mContext.getContentResolver(),
Settings.Secure.TETHER_SUPPORTED, defaultVal) != 0);
return tetherEnabledInSettings && mTetheringConfigValid;
}
// An API NetworkStateTrackers can call when they lose their network.
// This will automatically be cleared after X seconds or a network becomes CONNECTED,
// whichever happens first. The timer is started by the first caller and not
// restarted by subsequent callers.
public void requestNetworkTransitionWakelock(String forWhom) {
enforceConnectivityInternalPermission();
synchronized (this) {
if (mNetTransitionWakeLock.isHeld()) return;
mNetTransitionWakeLockSerialNumber++;
mNetTransitionWakeLock.acquire();
mNetTransitionWakeLockCausedBy = forWhom;
}
mHandler.sendMessageDelayed(mHandler.obtainMessage(
EVENT_CLEAR_NET_TRANSITION_WAKELOCK,
mNetTransitionWakeLockSerialNumber, 0),
mNetTransitionWakeLockTimeout);
return;
}
// 100 percent is full good, 0 is full bad.
public void reportInetCondition(int networkType, int percentage) {
if (DBG) log("reportNetworkCondition(" + networkType + ", " + percentage + ")");
mContext.enforceCallingOrSelfPermission(
android.Manifest.permission.STATUS_BAR,
"ConnectivityService");
if (DBG) {
int pid = getCallingPid();
int uid = getCallingUid();
String s = pid + "(" + uid + ") reports inet is " +
(percentage > 50 ? "connected" : "disconnected") + " (" + percentage + ") on " +
"network Type " + networkType + " at " + GregorianCalendar.getInstance().getTime();
mInetLog.add(s);
while(mInetLog.size() > INET_CONDITION_LOG_MAX_SIZE) {
mInetLog.remove(0);
}
}
mHandler.sendMessage(mHandler.obtainMessage(
EVENT_INET_CONDITION_CHANGE, networkType, percentage));
}
private void handleInetConditionChange(int netType, int condition) {
if (DBG) {
log("Inet connectivity change, net=" +
netType + ", condition=" + condition +
",mActiveDefaultNetwork=" + mActiveDefaultNetwork);
}
if (mActiveDefaultNetwork == -1) {
if (DBG) log("no active default network - aborting");
return;
}
if (mActiveDefaultNetwork != netType) {
if (DBG) log("given net not default - aborting");
return;
}
mDefaultInetCondition = condition;
int delay;
if (mInetConditionChangeInFlight == false) {
if (DBG) log("starting a change hold");
// setup a new hold to debounce this
if (mDefaultInetCondition > 50) {
delay = Settings.Secure.getInt(mContext.getContentResolver(),
Settings.Secure.INET_CONDITION_DEBOUNCE_UP_DELAY, 500);
} else {
delay = Settings.Secure.getInt(mContext.getContentResolver(),
Settings.Secure.INET_CONDITION_DEBOUNCE_DOWN_DELAY, 3000);
}
mInetConditionChangeInFlight = true;
mHandler.sendMessageDelayed(mHandler.obtainMessage(EVENT_INET_CONDITION_HOLD_END,
mActiveDefaultNetwork, mDefaultConnectionSequence), delay);
} else {
// we've set the new condition, when this hold ends that will get
// picked up
if (DBG) log("currently in hold - not setting new end evt");
}
}
private void handleInetConditionHoldEnd(int netType, int sequence) {
if (DBG) {
log("Inet hold end, net=" + netType +
", condition =" + mDefaultInetCondition +
", published condition =" + mDefaultInetConditionPublished);
}
mInetConditionChangeInFlight = false;
if (mActiveDefaultNetwork == -1) {
if (DBG) log("no active default network - aborting");
return;
}
if (mDefaultConnectionSequence != sequence) {
if (DBG) log("event hold for obsolete network - aborting");
return;
}
if (mDefaultInetConditionPublished == mDefaultInetCondition) {
if (DBG) log("no change in condition - aborting");
return;
}
NetworkInfo networkInfo = mNetTrackers[mActiveDefaultNetwork].getNetworkInfo();
if (networkInfo.isConnected() == false) {
if (DBG) log("default network not connected - aborting");
return;
}
mDefaultInetConditionPublished = mDefaultInetCondition;
sendInetConditionBroadcast(networkInfo);
return;
}
public synchronized ProxyProperties getProxy() {
if (mGlobalProxy != null) return mGlobalProxy;
if (mDefaultProxy != null) return mDefaultProxy;
return null;
}
public void setGlobalProxy(ProxyProperties proxyProperties) {
enforceChangePermission();
synchronized (mGlobalProxyLock) {
if (proxyProperties == mGlobalProxy) return;
if (proxyProperties != null && proxyProperties.equals(mGlobalProxy)) return;
if (mGlobalProxy != null && mGlobalProxy.equals(proxyProperties)) return;
String host = "";
int port = 0;
String exclList = "";
if (proxyProperties != null && !TextUtils.isEmpty(proxyProperties.getHost())) {
mGlobalProxy = new ProxyProperties(proxyProperties);
host = mGlobalProxy.getHost();
port = mGlobalProxy.getPort();
exclList = mGlobalProxy.getExclusionList();
} else {
mGlobalProxy = null;
}
ContentResolver res = mContext.getContentResolver();
Settings.Secure.putString(res, Settings.Secure.GLOBAL_HTTP_PROXY_HOST, host);
Settings.Secure.putInt(res, Settings.Secure.GLOBAL_HTTP_PROXY_PORT, port);
Settings.Secure.putString(res, Settings.Secure.GLOBAL_HTTP_PROXY_EXCLUSION_LIST,
exclList);
}
if (mGlobalProxy == null) {
proxyProperties = mDefaultProxy;
}
sendProxyBroadcast(proxyProperties);
}
private void loadGlobalProxy() {
ContentResolver res = mContext.getContentResolver();
String host = Settings.Secure.getString(res, Settings.Secure.GLOBAL_HTTP_PROXY_HOST);
int port = Settings.Secure.getInt(res, Settings.Secure.GLOBAL_HTTP_PROXY_PORT, 0);
String exclList = Settings.Secure.getString(res,
Settings.Secure.GLOBAL_HTTP_PROXY_EXCLUSION_LIST);
if (!TextUtils.isEmpty(host)) {
ProxyProperties proxyProperties = new ProxyProperties(host, port, exclList);
synchronized (mGlobalProxyLock) {
mGlobalProxy = proxyProperties;
}
}
}
public ProxyProperties getGlobalProxy() {
synchronized (mGlobalProxyLock) {
return mGlobalProxy;
}
}
private void handleApplyDefaultProxy(int type) {
// check if new default - push it out to all VM if so
ProxyProperties proxy = mNetTrackers[type].getLinkProperties().getHttpProxy();
synchronized (this) {
if (mDefaultProxy != null && mDefaultProxy.equals(proxy)) return;
if (mDefaultProxy == proxy) return;
if (!TextUtils.isEmpty(proxy.getHost())) {
mDefaultProxy = proxy;
} else {
mDefaultProxy = null;
}
}
if (DBG) log("changing default proxy to " + proxy);
if ((proxy == null && mGlobalProxy == null) || proxy.equals(mGlobalProxy)) return;
if (mGlobalProxy != null) return;
sendProxyBroadcast(proxy);
}
private void handleDeprecatedGlobalHttpProxy() {
String proxy = Settings.Secure.getString(mContext.getContentResolver(),
Settings.Secure.HTTP_PROXY);
if (!TextUtils.isEmpty(proxy)) {
String data[] = proxy.split(":");
String proxyHost = data[0];
int proxyPort = 8080;
if (data.length > 1) {
try {
proxyPort = Integer.parseInt(data[1]);
} catch (NumberFormatException e) {
return;
}
}
ProxyProperties p = new ProxyProperties(data[0], proxyPort, "");
setGlobalProxy(p);
}
}
private void sendProxyBroadcast(ProxyProperties proxy) {
if (proxy == null) proxy = new ProxyProperties("", 0, "");
log("sending Proxy Broadcast for " + proxy);
Intent intent = new Intent(Proxy.PROXY_CHANGE_ACTION);
intent.addFlags(Intent.FLAG_RECEIVER_REPLACE_PENDING |
Intent.FLAG_RECEIVER_REGISTERED_ONLY_BEFORE_BOOT);
intent.putExtra(Proxy.EXTRA_PROXY_INFO, proxy);
mContext.sendStickyBroadcast(intent);
}
private static class SettingsObserver extends ContentObserver {
private int mWhat;
private Handler mHandler;
SettingsObserver(Handler handler, int what) {
super(handler);
mHandler = handler;
mWhat = what;
}
void observe(Context context) {
ContentResolver resolver = context.getContentResolver();
resolver.registerContentObserver(Settings.Secure.getUriFor(
Settings.Secure.HTTP_PROXY), false, this);
}
@Override
public void onChange(boolean selfChange) {
mHandler.obtainMessage(mWhat).sendToTarget();
}
}
private void handleTetherIfaceChange(int type) {
String iface = mNetTrackers[type].getLinkProperties().getInterfaceName();
if (isTetheringSupported()) {
mTethering.handleTetherIfaceChange(iface);
}
}
private void log(String s) {
Slog.d(TAG, s);
}
private void loge(String s) {
Slog.e(TAG, s);
}
int convertFeatureToNetworkType(String feature){
int networkType = -1;
if (TextUtils.equals(feature, Phone.FEATURE_ENABLE_MMS)) {
networkType = ConnectivityManager.TYPE_MOBILE_MMS;
} else if (TextUtils.equals(feature, Phone.FEATURE_ENABLE_SUPL)) {
networkType = ConnectivityManager.TYPE_MOBILE_SUPL;
} else if (TextUtils.equals(feature, Phone.FEATURE_ENABLE_DUN) ||
TextUtils.equals(feature, Phone.FEATURE_ENABLE_DUN_ALWAYS)) {
networkType = ConnectivityManager.TYPE_MOBILE_DUN;
} else if (TextUtils.equals(feature, Phone.FEATURE_ENABLE_HIPRI)) {
networkType = ConnectivityManager.TYPE_MOBILE_HIPRI;
} else if (TextUtils.equals(feature, Phone.FEATURE_ENABLE_FOTA)) {
networkType = ConnectivityManager.TYPE_MOBILE_FOTA;
} else if (TextUtils.equals(feature, Phone.FEATURE_ENABLE_IMS)) {
networkType = ConnectivityManager.TYPE_MOBILE_IMS;
} else if (TextUtils.equals(feature, Phone.FEATURE_ENABLE_CBS)) {
networkType = ConnectivityManager.TYPE_MOBILE_CBS;
}
return networkType;
}
}
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