文章目录
- AMS
- ActivityStack
- startActivity流程
- startActivityMayWait
- startActivityUncheckedLocked
- startActivityLocked(ActivityRecord r, boolean newTask, boolean doResume, boolean keepCurTransition)
- resumeTopActivityLocked
- 参考
AMS是个用于管理Activity和其它组件运行状态的系统进程。
AMS
AMS在系统启动的时候,创建一个线程循环处理客户端的请求。AMS会向ServiceManager注册多种Binder Server:“activity”、“meminfo”、“cpuinfo”等。
AMS启动过程:
/*frameworks/base/services/java/com/android/server/SystemServer.java*/
public static void main(String[] args) {
...
// This used to be its own separate thread, but now it is
// just the loop we run on the main thread.
ServerThread thr = new ServerThread();
thr.initAndLoop();
}
/*frameworks/base/services/java/com/android/server/SystemServer.java*/
public void run() {
…
Slog.i(TAG, "Activity Manager");
context = ActivityManagerService.main(factoryTest); //启动AMS
…
ActivityManagerService.setSystemProcess(); //向Service Manager注册
…
}
AMS提供了一个static main函数,通过它可以轻松启动AMS,通过setSystemProcess把这个重要系统服务注册到ServiceManager。
//frameworks/base/services/java/com/android/server/am/ActivityManagerService.java
public static final Context main(int factoryTest) {
AThread thr = new AThread();//AMS线程
thr.start();//启动
//这个线程执行在system server上,通过thr.mService判断AMS启动是否成功。如果成功,返回system server,否则一直等待。如果出错,就无力回天,空处理。
synchronized (thr) {
while (thr.mService == null) {
try {
thr.wait();
} catch (InterruptedException e) {
}
}
}
ActivityManagerService m = thr.mService;
mSelf = m;
ActivityThread at = ActivityThread.systemMain();
mSystemThread = at;
Context context = at.getSystemContext();
context.setTheme(android.R.style.Theme_Holo);
m.mContext = context;
m.mFactoryTest = factoryTest;
m.mIntentFirewall = new IntentFirewall(m.new IntentFirewallInterface());
m.mStackSupervisor = new ActivityStackSupervisor(m, context, thr.mLooper);
m.mBatteryStatsService.publish(context);
m.mUsageStatsService.publish(context);
m.mAppOpsService.publish(context);
//唤醒
synchronized (thr) {
thr.mReady = true;
thr.notifyAll();
}
m.startRunning(null, null, null, null);
return context;
}
这里一个wait & notify配对使用,让system server确保AMS启动成功,它自己再接着执行。这么做的原因无它,就是system server需要依赖于AMS。
将AMS注册到ServiceManager之后,它还注册了一系列和进程管理相关的服务:
public static void setSystemProcess() {
try {
ActivityManagerService m = mSelf;
ServiceManager.addService("activity", m, true);//AMS的主业
ServiceManager.addService("meminfo", new MemBinder(m));//内存使用情况
…//其他服务省略
}
要了解AMS提供的所有功能,可以查看IActivityManager.java文件。
可以把这些接口进行分类:
- 组件状态管理:例如startActivity、startService
- 组件状态查询:例如getServices
- Task相关:例如removeSubTask
- 其它:查询运行时信息,例如getMemoryInfo
ActivityStack
/*frameworks/base/services/java/com/android/server/am/ActivityManagerService.java*/
public static final Context main(int factoryTest) {/*main()函数是启动AMS的入口*/
…
ActivityManagerService m = thr.mService;
…
m.mMainStack = new ActivityStack(m, context, true, thr.mLooper);/*生成ActivityStack对象*/
…
}
ActivityStack是管理当前系统所有activity状态的一个数据结构。
它里面有个enum 叫做ActivityState :
enum ActivityState {
INITIALIZING, //正在初始化
RESUMED, //恢复
PAUSING, //正在暂停
PAUSED, //已经暂停
STOPPING, //正在停止
STOPPED, //已经停止
FINISHING, //正在完成
DESTROYING, //正在销毁
DESTROYED //已经销毁
}
ActivityStack除了管理状态,还有一系列不同功能的ArrayList成员变量,它们都是ActivityRecord,用来记录每个activity的runtime信息:
startActivity流程
startActivity()用来启动一个Activity,它有可能启动当前进程的Activity,也有可能启动其它进程的Activity。当通过Intent匹配到目标对象,如果目标对象的进程已经启动,那么AMS就会通知这个进程加载并运行这个activity。如果进程没有启动,AMS就会先启动进程,再让进程运行目标activity。
/*frameworks/base/services/java/com/android/server/am/ActivityManagerService.java*/
public final int startActivity(IApplicationThread caller, String callingPackage,
Intent intent, String resolvedType, IBinder resultTo,
String resultWho, int requestCode, int startFlags,
String profileFile, ParcelFileDescriptor profileFd, Bundle options) {
return startActivityAsUser(caller, callingPackage, intent, resolvedType,
result To, resultWho, requestCode, startFlags,
profileFile, profileFd, options,UserHandle.getCallingUserId());
}
startActivityAsUser比startActivity多了一个userId参数,用来表示调用者的用户ID,通过Binder机制的getCallingUid获得。
public final int startActivityAsUser(IApplicationThread caller, String calling Package,
Intent intent, String resolvedType, IBinder resultTo,
String resultWho, int requestCode, int startFlags, String profileFile,
ParcelFileDescriptor profileFd, Bundle options, int userId ){
enforceNotIsolatedCaller("startActivity");
userId = handleIncomingUser(Binder.getCallingPid(), Binder.getCallingUid(), userId,
false, true, "startActivity", null);
return mMainStack.startActivityMayWait(caller,-1,callingPackage,intent, resolvedType,
resultTo, resultWho, requestCode, startFlags, profileFile, profileFd,
null, null, options, userId);/*这个函数是ActivityStack提供的*/
}
startActivityAsUser的重点是做权限检查。
startActivityMayWait
startActivityMayWait的工作:
这个过程中,可能会“wait”,具体如流程图:
接着调用的是startActivityLocked,它有两个重载函数:
final int startActivityLocked(IApplicationThread caller,
Intent intent, String resolvedType,
Uri[] grantedUriPermissions,
int grantedMode, ActivityInfo aInfo, IBinder resultTo,
String resultWho, int requestCode,
int callingPid, int callingUid, boolean onlyIfNeeded,
boolean componentSpecified, ActivityRecord[] outActivity) {
int err = START_SUCCESS;
ProcessRecord callerApp = null;
if (caller != null) {
callerApp = mService.getRecordForAppLocked(caller);
if (callerApp != null) {
callingPid = callerApp.pid;
callingUid = callerApp.info.uid;
} else {
Slog.w(TAG, "Unable to find app for caller " + caller
+ " (pid=" + callingPid + ") when starting: "
+ intent.toString());
err = START_PERMISSION_DENIED;
}
}
if (err == START_SUCCESS) {
Slog.i(TAG, "START {" + intent.toShortString(true, true, true, false)
+ "} from pid " + (callerApp != null ? callerApp.pid : callingPid));
}
ActivityRecord sourceRecord = null;
ActivityRecord resultRecord = null;
if (resultTo != null) {
int index = indexOfTokenLocked(resultTo);
if (DEBUG_RESULTS) Slog.v(
TAG, "Will send result to " + resultTo + " (index " + index + ")");
if (index >= 0) {
sourceRecord = mHistory.get(index);
if (requestCode >= 0 && !sourceRecord.finishing) {
resultRecord = sourceRecord;
}
}
}
int launchFlags = intent.getFlags();
if ((launchFlags&Intent.FLAG_ACTIVITY_FORWARD_RESULT) != 0
&& sourceRecord != null) {
// Transfer the result target from the source activity to the new
// one being started, including any failures.
if (requestCode >= 0) {
return START_FORWARD_AND_REQUEST_CONFLICT;
}
resultRecord = sourceRecord.resultTo;
resultWho = sourceRecord.resultWho;
requestCode = sourceRecord.requestCode;
sourceRecord.resultTo = null;
if (resultRecord != null) {
resultRecord.removeResultsLocked(
sourceRecord, resultWho, requestCode);
}
}
if (err == START_SUCCESS && intent.getComponent() == null) {
// We couldn't find a class that can handle the given Intent.
// That's the end of that!
err = START_INTENT_NOT_RESOLVED;
}
if (err == START_SUCCESS && aInfo == null) {
// We couldn't find the specific class specified in the Intent.
// Also the end of the line.
err = START_CLASS_NOT_FOUND;
}
if (err != START_SUCCESS) {
if (resultRecord != null) {
sendActivityResultLocked(-1,
resultRecord, resultWho, requestCode,
Activity.RESULT_CANCELED, null);
}
mDismissKeyguardOnNextActivity = false;
return err;
}
final int perm = mService.checkComponentPermission(aInfo.permission, callingPid,
callingUid, aInfo.applicationInfo.uid, aInfo.exported);
if (perm != PackageManager.PERMISSION_GRANTED) {
if (resultRecord != null) {
sendActivityResultLocked(-1,
resultRecord, resultWho, requestCode,
Activity.RESULT_CANCELED, null);
}
mDismissKeyguardOnNextActivity = false;
String msg;
if (!aInfo.exported) {
msg = "Permission Denial: starting " + intent.toString()
+ " from " + callerApp + " (pid=" + callingPid
+ ", uid=" + callingUid + ")"
+ " not exported from uid " + aInfo.applicationInfo.uid;
} else {
msg = "Permission Denial: starting " + intent.toString()
+ " from " + callerApp + " (pid=" + callingPid
+ ", uid=" + callingUid + ")"
+ " requires " + aInfo.permission;
}
Slog.w(TAG, msg);
throw new SecurityException(msg);
}
if (mMainStack) {
if (mService.mController != null) {
boolean abort = false;
try {
// The Intent we give to the watcher has the extra data
// stripped off, since it can contain private information.
Intent watchIntent = intent.cloneFilter();
abort = !mService.mController.activityStarting(watchIntent,
aInfo.applicationInfo.packageName);
} catch (RemoteException e) {
mService.mController = null;
}
if (abort) {
if (resultRecord != null) {
sendActivityResultLocked(-1,
resultRecord, resultWho, requestCode,
Activity.RESULT_CANCELED, null);
}
// We pretend to the caller that it was really started, but
// they will just get a cancel result.
mDismissKeyguardOnNextActivity = false;
return START_SUCCESS;
}
}
}
ActivityRecord r = new ActivityRecord(mService, this, callerApp, callingUid,
intent, resolvedType, aInfo, mService.mConfiguration,
resultRecord, resultWho, requestCode, componentSpecified);
if (outActivity != null) {
outActivity[0] = r;
}
if (mMainStack) {
if (mResumedActivity == null
|| mResumedActivity.info.applicationInfo.uid != callingUid) {
if (!mService.checkAppSwitchAllowedLocked(callingPid, callingUid, "Activity start")) {
PendingActivityLaunch pal = new PendingActivityLaunch();
pal.r = r;
pal.sourceRecord = sourceRecord;
pal.grantedUriPermissions = grantedUriPermissions;
pal.grantedMode = grantedMode;
pal.onlyIfNeeded = onlyIfNeeded;
mService.mPendingActivityLaunches.add(pal);
mDismissKeyguardOnNextActivity = false;
return START_SWITCHES_CANCELED;
}
}
if (mService.mDidAppSwitch) {
// This is the second allowed switch since we stopped switches,
// so now just generally allow switches. Use case: user presses
// home (switches disabled, switch to home, mDidAppSwitch now true);
// user taps a home icon (coming from home so allowed, we hit here
// and now allow anyone to switch again).
mService.mAppSwitchesAllowedTime = 0;
} else {
mService.mDidAppSwitch = true;
}
mService.doPendingActivityLaunchesLocked(false);
}
err = startActivityUncheckedLocked(r, sourceRecord,
grantedUriPermissions, grantedMode, onlyIfNeeded, true);
if (mDismissKeyguardOnNextActivity && mPausingActivity == null) {
// Someone asked to have the keyguard dismissed on the next
// activity start, but we are not actually doing an activity
// switch... just dismiss the keyguard now, because we
// probably want to see whatever is behind it.
mDismissKeyguardOnNextActivity = false;
mService.mWindowManager.dismissKeyguard();
}
return err;
}
这里确保调用者本身的进程是存在的,否则返回START_PERMISSION_DENIED。这种情况出现在调用者被系统杀死,crash等。
FLAG_ACTIVITY_FORWARD_RESULT这个FLAG有跨越传递的作用,比如Activity1正常启动了Activity2,而当Activity2启动Activity3时使用了这个标志,那么当Activity3调用setResult时,result并不会像一般情况中那样传递给Activity2,而是传递给最初的Activity1。
startActivityUncheckedLocked
这个方法先拿到Intent中的FLAG,然后处理FLAG_ACTIVITY_NO_USER_ACTION,这个FLAG表示来电、闹钟等非用户主动触发的Activity事件。
这里处理了很多FLAG,例如LAUNCH_SINGLE_INSTANCE、LAUNCH_SINGLE_TASK这些,这里暂时不展开。
startActivityLocked(ActivityRecord r, boolean newTask, boolean doResume, boolean keepCurTransition)
private final void startActivityLocked(ActivityRecord r, boolean newTask,
boolean doResume, boolean keepCurTransition) {
...
if (doResume) {
resumeTopActivityLocked(null);
}
}
这里是启动activity的最后一站了,是AMS启动activity的关键。如果activity不是在新task中启动,那么程序要找出目标activity位于那个已有的task中。找到之后,如果它当前对用户不可见,就将它加入mHistory中,并在WMS中注册,但是不启动它。
接着将这个activity放在stack的最顶层:
mHistory.add(addPos, r);
r.putInHistory();
r.frontOfTask = newTask;
接下来,如果不是AMS的第一个activity,即mHistory > 0,则执行切换动画。
一个activity的UI能否显示,有个关键是WMS中必须有档案可查,就是appToken,它在startActivity中添加的:
mService.mWindowManager.addAppToken(
addPos, r.appToken, r.task.taskId, r.info.screenOrientation, r.fullscreen);
activity有affinity特性的,它们更亲近affinity相符的task,关键地方在于FLAG是否有FLAG_ACTIVITY_RESET_TASK_IF_NEEDED。
Android源码中有很多函数都有locked标志,提醒开发者必须保证它们的线程安全。
到这里startActivity分析完毕了,但是activity的启动流程还没完。
resumeTopActivityLocked
AMS会继续调用resumeTopActivityLocked来恢复最上层的Activity,并pause之前的Activity,并且在Activity切换的过程中还要首先展示切换动画,然后两个新旧Activity还会向WMS分别申请和释放Surface,最终将它们显示/不显示在屏幕上。
int i = mHistory.size()-1;//所有Activity的数量
while (i >= 0) {
ActivityRecord r = mHistory.get(i);
if (!r.finishing && r != notTop && okToShow(r)) {
return r;
}
i--;
}
return null;
这里处理ActivityRecord。
resumeTopActivityLocked执行后面的时候,可以正式启动目标activity了,但是有两种情况,一种是目标activity所属的进程已经在运行,一种是没有运行。
前者我们可以通知WMS这个Activity已经具备显示条件了:
mService.mWindowManager.setAppVisibility(next.appToken, true);
更新一系列全局变量,如果有等待启动的对象,就会通过:
next.app.thread.scheduleResumeActivity(next.appToken, mService.isNextTransitionForward());
告知目标线程要resume指定的activity。
后者的情况复杂些,会通过startSpecificActivityLocked启动进程,接着调用一系列和startActivity长得差不多的函数,最终调用zygote来fork一个新的进程:
Process.ProcessStartResult startResult =
Process.start("<strong>android.app.ActivityThread</strong>", app.processName, uid, uid, gids,
debugFlags,app.info.targetSdkVersion, null, null);
可以看出,一个进程启动的时候,实际上会加载ActivityThread。
那么新启动的进程什么时候启动activity呢?
进程启动后要通知AMS,AMS会预留一段时间等待回调。这个在不同设备上有所差异,有的10s,有的300s。如果进程指定时间内没有完成attachApplication回调,那么AMS就认为异常了。如果进程完成了attachApplication回调,AMS就会判断当前是不是有Activity在等待这个进程启动。是的话,调用realStartActivityLocked继续之前的任务。
接着就是activity的生命周期了,onCreate,onStart,onResume等,并且在WMS和SurfaceFlinger的配合下,目标Activity描述的UI界面会显示在屏幕。
startActivity流程才算真正完成。
参考
《深入理解Android内核设计思想》
