转载自: http://blog.csdn.net/oujunli/article/details/9102101#reply
对于从事Android开发的人来说,遇到ANR(Application Not Responding)是比较常见的问题。一般情况下,如果有ANR发生,系统都会在/data/anr/目录下生成trace文件,通过分析trace文件,可以定位产生ANR的原因。产生ANR的原因有很多,比如CPU使用过高、事件没有得到及时的响应、死锁等,下面将通过一次因为死锁导致的ANR问题,来说明如何通过trace文件分析ANR问题。
对应的部分trace文件内容如下:
"PowerManagerService" prio=5 tid=24 MONITOR
| group="main" sCount=1 dsCount=0 obj=0x41dd0eb0 self=0x5241b218
| sysTid=567 nice=0 sched=0/0 cgrp=apps handle=1380038664
| state=S schedstat=( 6682116007 11324451214 33313 ) utm=450 stm=219 core=1
at com.android.server.am.ActivityManagerService.broadcastIntent(ActivityManagerService.java:~13045)
- waiting to lock <0x41a874a0> (a com.android.server.am.ActivityManagerService) held by tid=12 (android.server.ServerThread)
at android.app.ContextImpl.sendBroadcast(ContextImpl.java:1144)
at com.android.server.power.PowerManagerService$DisplayBlankerImpl.unblankAllDisplays(PowerManagerService.java:3442)
at com.android.server.power.DisplayPowerState$PhotonicModulator$1.run(DisplayPowerState.java:456)
at android.os.Handler.handleCallback(Handler.java:800)
at android.os.Handler.dispatchMessage(Handler.java:100)
at android.os.Looper.loop(Looper.java:194)
at android.os.HandlerThread.run(HandlerThread.java:60)
"Binder_B" prio=5 tid=85 MONITOR
| group="main" sCount=1 dsCount=0 obj=0x42744770 self=0x58329e88
| sysTid=3700 nice=-20 sched=0/0 cgrp=apps handle=1471424616
| state=S schedstat=( 1663727513 2044643318 6806 ) utm=132 stm=34 core=1
at com.android.server.power.PowerManagerService$DisplayBlankerImpl.toString(PowerManagerService.java:~3449)
- waiting to lock <0x41a7e420> (a com.android.server.power.PowerManagerService$DisplayBlankerImpl) held by tid=24 (PowerManagerService)
at java.lang.StringBuilder.append(StringBuilder.java:202)
at com.android.server.power.PowerManagerService.dump(PowerManagerService.java:3052)
at android.os.Binder.dump(Binder.java:264)
at android.os.Binder.onTransact(Binder.java:236)
at android.os.IPowerManager$Stub.onTransact(IPowerManager.java:373)
at android.os.Binder.execTransact(Binder.java:351)
at dalvik.system.NativeStart.run(Native Method)
"android.server.ServerThread" prio=5 tid=12 MONITOR
| group="main" sCount=1 dsCount=0 obj=0x41a76178 self=0x507837a8
| sysTid=545 nice=-2 sched=0/0 cgrp=apps handle=1349936616
| state=S schedstat=( 15368096286 21707846934 69485 ) utm=1226 stm=310 core=0
at com.android.server.power.PowerManagerService.isScreenOnInternal(PowerManagerService.java:~2529)
- waiting to lock <0x41a7e2e8> (a java.lang.Object) held by tid=85 (Binder_B)
at com.android.server.power.PowerManagerService.isScreenOn(PowerManagerService.java:2522)
at com.android.server.wm.WindowManagerService.sendScreenStatusToClientsLocked(WindowManagerService.java:7749)
at com.android.server.wm.WindowManagerService.setEventDispatching(WindowManagerService.java:7628)
at com.android.server.am.ActivityManagerService.updateEventDispatchingLocked(ActivityManagerService.java:8083)
at com.android.server.am.ActivityManagerService.wakingUp(ActivityManagerService.java:8077)
at com.android.server.power.Notifier.sendWakeUpBroadcast(Notifier.java:474)
at com.android.server.power.Notifier.sendNextBroadcast(Notifier.java:455)
at com.android.server.power.Notifier.access$700(Notifier.java:62)
at com.android.server.power.Notifier$NotifierHandler.handleMessage(Notifier.java:600)
at android.os.Handler.dispatchMessage(Handler.java:107)
at android.os.Looper.loop(Looper.java:194)
at com.android.server.ServerThread.run(SystemServer.java:1328)
从trace文件看,是因为TID为24的线程等待一个TID为12的线程持有的锁,TID为12的线程等待一个TID为85的线程持有的锁,而TID为85的线程确等待一个TID为24的线程持有的锁,导致了循环等待的现象,对应的trace文件的语句如下:
TID 24:- waiting to lock <0x41a874a0> (a com.android.server.am.ActivityManagerService) held by tid=12 (android.server.ServerThread)
TID 12: - waiting to lock <0x41a7e2e8> (a java.lang.Object) held by tid=85 (Binder_B)
TID 85:- waiting to lock <0x41a7e420> (a com.android.server.power.PowerManagerService$DisplayBlankerImpl) held by tid=24 (PowerManagerService)
既然是死锁,那么先看各线程都有那些锁。
先看TID=24的线程的栈顶,ActivityManagerService的broadcastIntent函数代码如下:
public final int broadcastIntent(IApplicationThread caller,
Intent intent, String resolvedType, IIntentReceiver resultTo,
int resultCode, String resultData, Bundle map,
String requiredPermission, boolean serialized, boolean sticky, int userId) {
enforceNotIsolatedCaller("broadcastIntent");
synchronized(this) {
intent = verifyBroadcastLocked(intent);
final ProcessRecord callerApp = getRecordForAppLocked(caller);
final int callingPid = Binder.getCallingPid();
final int callingUid = Binder.getCallingUid();
final long origId = Binder.clearCallingIdentity();
int res = broadcastIntentLocked(callerApp,
callerApp != null ? callerApp.info.packageName : null,
intent, resolvedType, resultTo,
resultCode, resultData, map, requiredPermission, serialized, sticky,
callingPid, callingUid, userId);
Binder.restoreCallingIdentity(origId);
return res;
}
可以看到TID=24需要ActivityManagerService这个锁。再看TID=12线程的栈顶,PowerManagerService的isScreenOnInternal函数代码如下:
private boolean isScreenOnInternal() {
synchronized (mLock) {
return !mSystemReady
|| mDisplayPowerRequest.screenState != DisplayPowerRequest.SCREEN_STATE_OFF;
}
}
可以看到需要PowerManagerService的mlock这个锁。最后看TID=85线程的栈顶,同样在PowerManagerService里面,内部类DisplayBlankerImpl的toString函数:
public String toString() {
synchronized (this) {
return "blanked=" + mBlanked;
}
}
这是在内部类DisplayBlankerImpl里面实现的,所以需要DisplayBlankerImpl这个锁。
对应的表格如下:
表一 各线程等待的锁情况
从表一来看,没有出现死锁现象,似乎并不是我们所想的那样。难道不是死锁?开始有点小怀疑自己了,难道别的原因导致的。也许只看调用堆栈的顶端可能不行,栈顶只能看出各线程需要的锁,不能仅看自己要什么吧!一味索取可不好!人不是这样做的!看一下整个的堆栈调用流程,看看自己拥有了那些锁。
跟踪TID=24线程的堆栈,在PowerManagerService内部类DisplayBlankerImpl的unblankAllDisplays函数中持有锁:
public void unblankAllDisplays() {
synchronized (this) {
nativeSetAutoSuspend(false);
nativeSetInteractive(true);
mDisplayManagerService.unblankAllDisplaysFromPowerManager();
mBlanked = false;
///M: add for tvout and hdmi
mTvOut.tvoutPowerEnable(true);
mHDMI.hdmiPowerEnable(true);
///@}
if (DEBUG) {
Slog.d(TAG_P, "unblankAllDisplays out ...");
}
if (mBootCompleted) {
Intent intent = new Intent(ACTION_LOCK_SCREEN_SHOW);
mContext.sendBroadcast(intent);
}
}
}
最后发送广播的代码,是我们自己添加的。根据unblankAllDisplays函数和broadcastIntent函数,可以看到TID=24的线程此时持有了DisplayBlankerImpl锁(unblankAllDisplays),等待ActivityManagerService锁(broadcastIntent)释放。
同样,跟踪TID=12线程的堆栈,在ActivityManagerService的wake_up函数中持有锁:
public void wakingUp() {
if (checkCallingPermission(android.Manifest.permission.DEVICE_POWER)
!= PackageManager.PERMISSION_GRANTED) {
throw new SecurityException("Requires permission "
+ android.Manifest.permission.DEVICE_POWER);
}
synchronized(this) {
Slog.i(TAG, "wakingUp");
mWentToSleep = false;
updateEventDispatchingLocked();
comeOutOfSleepIfNeededLocked();
}
}
根据wakingUp函数和isScreenOnInternal函数,可以看到TID=12的线程持有ActivityManagerService锁(wakingUp),等待PowerManagerService.mLock锁(isScreenOnInternal)。到这,似乎看到了希望,迷雾要拨开了,有点小自信是死锁导致的,但还不能最终下结论。
一鼓作气,跟踪TID=85线程的堆栈,在PowerManagerService的dump有持有锁的操作:
protected void dump(FileDescriptor fd, PrintWriter pw, String[] args) {
....
synchronized (mLock) {
...
}
根据toString函数和dump函数,可以看到TID=85线程此时持有PowerManagerService.mLock锁(dump),需要DisplayBlankerImpl(toString)。
似乎谜底已经揭晓了,如果你还没有看出来(其实我也没看出来),来个表看看吧!
表二 各线程锁的情况
清楚了吗?多么清晰的循环等待呀!死锁都死的这么完美,还是图表效果好,看来有时候在纸上画画还是有用的!