/* * Copyright (C) 2012 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 java.io.FileDescriptor; import java.io.PrintWriter; import android.content.BroadcastReceiver; import android.content.Context; import android.content.Intent; import android.content.IntentFilter; import android.content.pm.PackageManager; import android.net.ConnectivityManager; import android.net.INetworkManagementEventObserver; import android.net.InterfaceConfiguration; import android.os.Binder; import android.os.CommonTimeConfig; import android.os.Handler; import android.os.IBinder; import android.os.INetworkManagementService; import android.os.RemoteException; import android.os.ServiceManager; import android.os.SystemProperties; import android.util.Log; import com.android.internal.util.DumpUtils; import com.android.server.net.BaseNetworkObserver; /** * @hide *
CommonTimeManagementService manages the configuration of the native Common Time service, * reconfiguring the native service as appropriate in response to changes in network configuration. */ class CommonTimeManagementService extends Binder { /* * Constants and globals. */ private static final String TAG = CommonTimeManagementService.class.getSimpleName(); private static final int NATIVE_SERVICE_RECONNECT_TIMEOUT = 5000; private static final String AUTO_DISABLE_PROP = "ro.common_time.auto_disable"; private static final String ALLOW_WIFI_PROP = "ro.common_time.allow_wifi"; private static final String SERVER_PRIO_PROP = "ro.common_time.server_prio"; private static final String NO_INTERFACE_TIMEOUT_PROP = "ro.common_time.no_iface_timeout"; private static final boolean AUTO_DISABLE; private static final boolean ALLOW_WIFI; private static final byte BASE_SERVER_PRIO; private static final int NO_INTERFACE_TIMEOUT; private static final InterfaceScoreRule[] IFACE_SCORE_RULES; static { int tmp; AUTO_DISABLE = (0 != SystemProperties.getInt(AUTO_DISABLE_PROP, 1)); ALLOW_WIFI = (0 != SystemProperties.getInt(ALLOW_WIFI_PROP, 0)); tmp = SystemProperties.getInt(SERVER_PRIO_PROP, 1); NO_INTERFACE_TIMEOUT = SystemProperties.getInt(NO_INTERFACE_TIMEOUT_PROP, 60000); if (tmp < 1) BASE_SERVER_PRIO = 1; else if (tmp > 30) BASE_SERVER_PRIO = 30; else BASE_SERVER_PRIO = (byte)tmp; if (ALLOW_WIFI) { IFACE_SCORE_RULES = new InterfaceScoreRule[] { new InterfaceScoreRule("wlan", (byte)1), new InterfaceScoreRule("eth", (byte)2), }; } else { IFACE_SCORE_RULES = new InterfaceScoreRule[] { new InterfaceScoreRule("eth", (byte)2), }; } }; /* * Internal state */ private final Context mContext; private final Object mLock = new Object(); private INetworkManagementService mNetMgr; private CommonTimeConfig mCTConfig; private String mCurIface; private Handler mReconnectHandler = new Handler(); private Handler mNoInterfaceHandler = new Handler(); private boolean mDetectedAtStartup = false; private byte mEffectivePrio = BASE_SERVER_PRIO; /* * Callback handler implementations. */ private INetworkManagementEventObserver mIfaceObserver = new BaseNetworkObserver() { @Override public void interfaceStatusChanged(String iface, boolean up) { reevaluateServiceState(); } @Override public void interfaceLinkStateChanged(String iface, boolean up) { reevaluateServiceState(); } @Override public void interfaceAdded(String iface) { reevaluateServiceState(); } @Override public void interfaceRemoved(String iface) { reevaluateServiceState(); } }; private BroadcastReceiver mConnectivityMangerObserver = new BroadcastReceiver() { @Override public void onReceive(Context context, Intent intent) { reevaluateServiceState(); } }; private CommonTimeConfig.OnServerDiedListener mCTServerDiedListener = () -> scheduleTimeConfigReconnect(); private Runnable mReconnectRunnable = () -> connectToTimeConfig(); private Runnable mNoInterfaceRunnable = () -> handleNoInterfaceTimeout(); /* * Public interface (constructor, systemReady and dump) */ public CommonTimeManagementService(Context context) { mContext = context; } void systemRunning() { if (ServiceManager.checkService(CommonTimeConfig.SERVICE_NAME) == null) { Log.i(TAG, "No common time service detected on this platform. " + "Common time services will be unavailable."); return; } mDetectedAtStartup = true; IBinder b = ServiceManager.getService(Context.NETWORKMANAGEMENT_SERVICE); mNetMgr = INetworkManagementService.Stub.asInterface(b); // Network manager is running along-side us, so we should never receiver a remote exception // while trying to register this observer. try { mNetMgr.registerObserver(mIfaceObserver); } catch (RemoteException e) { } // Register with the connectivity manager for connectivity changed intents. IntentFilter filter = new IntentFilter(); filter.addAction(ConnectivityManager.CONNECTIVITY_ACTION); mContext.registerReceiver(mConnectivityMangerObserver, filter); // Connect to the common time config service and apply the initial configuration. connectToTimeConfig(); } @Override protected void dump(FileDescriptor fd, PrintWriter pw, String[] args) { if (!DumpUtils.checkDumpPermission(mContext, TAG, pw)) return; if (!mDetectedAtStartup) { pw.println("Native Common Time service was not detected at startup. " + "Service is unavailable"); return; } synchronized (mLock) { pw.println("Current Common Time Management Service Config:"); pw.println(String.format(" Native service : %s", (null == mCTConfig) ? "reconnecting" : "alive")); pw.println(String.format(" Bound interface : %s", (null == mCurIface ? "unbound" : mCurIface))); pw.println(String.format(" Allow WiFi : %s", ALLOW_WIFI ? "yes" : "no")); pw.println(String.format(" Allow Auto Disable : %s", AUTO_DISABLE ? "yes" : "no")); pw.println(String.format(" Server Priority : %d", mEffectivePrio)); pw.println(String.format(" No iface timeout : %d", NO_INTERFACE_TIMEOUT)); } } /* * Inner helper classes */ private static class InterfaceScoreRule { public final String mPrefix; public final byte mScore; public InterfaceScoreRule(String prefix, byte score) { mPrefix = prefix; mScore = score; } }; /* * Internal implementation */ private void cleanupTimeConfig() { mReconnectHandler.removeCallbacks(mReconnectRunnable); mNoInterfaceHandler.removeCallbacks(mNoInterfaceRunnable); if (null != mCTConfig) { mCTConfig.release(); mCTConfig = null; } } private void connectToTimeConfig() { // Get access to the common time service configuration interface. If we catch a remote // exception in the process (service crashed or no running for w/e reason), schedule an // attempt to reconnect in the future. cleanupTimeConfig(); try { synchronized (mLock) { mCTConfig = new CommonTimeConfig(); mCTConfig.setServerDiedListener(mCTServerDiedListener); mCurIface = mCTConfig.getInterfaceBinding(); mCTConfig.setAutoDisable(AUTO_DISABLE); mCTConfig.setMasterElectionPriority(mEffectivePrio); } if (NO_INTERFACE_TIMEOUT >= 0) mNoInterfaceHandler.postDelayed(mNoInterfaceRunnable, NO_INTERFACE_TIMEOUT); reevaluateServiceState(); } catch (RemoteException e) { scheduleTimeConfigReconnect(); } } private void scheduleTimeConfigReconnect() { cleanupTimeConfig(); Log.w(TAG, String.format("Native service died, will reconnect in %d mSec", NATIVE_SERVICE_RECONNECT_TIMEOUT)); mReconnectHandler.postDelayed(mReconnectRunnable, NATIVE_SERVICE_RECONNECT_TIMEOUT); } private void handleNoInterfaceTimeout() { if (null != mCTConfig) { Log.i(TAG, "Timeout waiting for interface to come up. " + "Forcing networkless master mode."); if (CommonTimeConfig.ERROR_DEAD_OBJECT == mCTConfig.forceNetworklessMasterMode()) scheduleTimeConfigReconnect(); } } private void reevaluateServiceState() { String bindIface = null; byte bestScore = -1; try { // Check to see if this interface is suitable to use for time synchronization. // // TODO : This selection algorithm needs to be enhanced for use with mobile devices. In // particular, the choice of whether to a wireless interface or not should not be an all // or nothing thing controlled by properties. It would probably be better if the // platform had some concept of public wireless networks vs. home or friendly wireless // networks (something a user would configure in settings or when a new interface is // added). Then this algorithm could pick only wireless interfaces which were flagged // as friendly, and be dormant when on public wireless networks. // // Another issue which needs to be dealt with is the use of driver supplied interface // name to determine the network type. The fact that the wireless interface on a device // is named "wlan0" is just a matter of convention; its not a 100% rule. For example, // there are devices out there where the wireless is name "tiwlan0", not "wlan0". The // internal network management interfaces in Android have all of the information needed // to make a proper classification, there is just no way (currently) to fetch an // interface's type (available from the ConnectionManager) as well as its address // (available from either the java.net interfaces or from the NetworkManagment service). // Both can enumerate interfaces, but that is no way to correlate their results (no // common shared key; although using the interface name in the connection manager would // be a good start). Until this gets resolved, we resort to substring searching for // tags like wlan and eth. // String ifaceList[] = mNetMgr.listInterfaces(); if (null != ifaceList) { for (String iface : ifaceList) { byte thisScore = -1; for (InterfaceScoreRule r : IFACE_SCORE_RULES) { if (iface.contains(r.mPrefix)) { thisScore = r.mScore; break; } } if (thisScore <= bestScore) continue; InterfaceConfiguration config = mNetMgr.getInterfaceConfig(iface); if (null == config) continue; if (config.isActive()) { bindIface = iface; bestScore = thisScore; } } } } catch (RemoteException e) { // Bad news; we should not be getting remote exceptions from the connectivity manager // since it is running in SystemServer along side of us. It probably does not matter // what we do here, but go ahead and unbind the common time service in this case, just // so we have some defined behavior. bindIface = null; } boolean doRebind = true; synchronized (mLock) { if ((null != bindIface) && (null == mCurIface)) { Log.e(TAG, String.format("Binding common time service to %s.", bindIface)); mCurIface = bindIface; } else if ((null == bindIface) && (null != mCurIface)) { Log.e(TAG, "Unbinding common time service."); mCurIface = null; } else if ((null != bindIface) && (null != mCurIface) && !bindIface.equals(mCurIface)) { Log.e(TAG, String.format("Switching common time service binding from %s to %s.", mCurIface, bindIface)); mCurIface = bindIface; } else { doRebind = false; } } if (doRebind && (null != mCTConfig)) { byte newPrio = (bestScore > 0) ? (byte)(bestScore * BASE_SERVER_PRIO) : BASE_SERVER_PRIO; if (newPrio != mEffectivePrio) { mEffectivePrio = newPrio; mCTConfig.setMasterElectionPriority(mEffectivePrio); } int res = mCTConfig.setNetworkBinding(mCurIface); if (res != CommonTimeConfig.SUCCESS) scheduleTimeConfigReconnect(); else if (NO_INTERFACE_TIMEOUT >= 0) { mNoInterfaceHandler.removeCallbacks(mNoInterfaceRunnable); if (null == mCurIface) mNoInterfaceHandler.postDelayed(mNoInterfaceRunnable, NO_INTERFACE_TIMEOUT); } } } }