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startActivity启动流程学习

2018-11-18  本文已影响5人  kevinsong0810

举例,当进程A调用startActivity方法,启动进程B,并打开B的Activity,这个过程是怎样的?以下是学习笔记,基于Android 9.0,在线源码查看:https://www.androidos.net.cn/android/9.0.0_r8/xref

  1. 进程A调用startActivity方法,本质上是通过binder通信,调用IActivityManager#startActivity方法
    • 如果该调用在Activity中,方法调用过程:
      ContextImpl#startActivity -> mInstrumentation#execStartActivity -> IActivityManager#startActivity
      备注:IActivityManager对象保存在进程A的单例IActivityManagerSingleton中,进程启动时查询ServiceManager#getService获得,具有缓存作用

  2. SystemServer进程的binder线程响应此请求,ActivityManagerService#startActivity方法被调用,过程如下(备注:过程较复杂,涉及Activity,ActivityStack等一连串操作):
    • ActivityManagerService#startActivity
    • ActivityStarter#startActivityMayWait,其中会调用PMS#resolveIntent方法,解析Intent获得ResolveInfo,并创建ActivityInfo等对象
      ResolveInfo rInfo = mSupervisor.resolveIntent((intent, resolvedType, userId, xxx);
    • ActivityStarter#startActivity,其中会创建即将打开的ActivityRecord等
      ActivityRecord r = new ActivityRecord(mService, callerApp, callingPid, callingUid, xxxx);
    • ActivityStack#resumeTopActivityUncheckedLocked
    • ActivityStackSupervisor#startSpecificActivityLocked,这里很重要,会根据目标进程名,查询进程是否已存在,如果存在,将执行realStartActivityLocked方法;如果不存在,将执行startProcessLocked,冷启动目标进程
    void startSpecificActivityLocked(ActivityRecord r, boolean andResume, boolean checkConfig) {
        // Is this activity's application already running?
        ProcessRecord app = mService.getProcessRecordLocked(r.processName,
                r.info.applicationInfo.uid, true);
        ......
        if (app != null && app.thread != null) {
                .......
                realStartActivityLocked(r, app, andResume, checkConfig);
                return;
        }
        ......
        mService.startProcessLocked(r.processName, r.info.applicationInfo, true, 0,
    
    • 假设这里要启动新进程,执行
      ActivityManagerService#startProcessLocked -> ActivityManagerService#startProcess -> Process#start -> ZygoteProcess#startViaZygote
      a. 利用Socket通信通知Zygote进程,孵化出进程B(判断是否启动成功:Socket返回结果中目标进程pid < 0,则启动失败,抛出ZygoteStartFailedEx异常)
      b. 进程B启动成功后,方法继续执行到ActivityManagerService#handleProcessStartedLocked,其中pid等信息填入事先创建好的ProcessRecord对象中,其对应每一个App进程,保存在数组mPidsSelfLocked中

      mPidsSelfLocked是AMS的成员变量,类型:SparseArray<E>,本质是利用2个数组存储,key和object各一个。此处pid为key,ProcessRecord对象为object。查询方法为二分法

  3. 目标进程B启动后,入口函数是ActivityThread#main(静态方法),过程如下:
    • 初始化环境,创建ActivityThread对象,其子对象中如:
      a. mH,类型:ActivityThread#H,作用:主线程的Handler,处理如BIND_APPLICATION,CREATE_SERVICE等几十个消息类型,消息来源是mAppThread
      b. mAppThread,类型:ActivityThread#ApplicationThread,作用:binder实体对象,用于接收AMS的binder调用,并将消息转发mH处理
      c. mInstrumentation,类型:Instrumentation,很重要的基础类,官方描述:用来监控系统与应用的所有交互,例如newApplication,callApplicationOnCreate,callActivityOnCreate等都是其子方法
      注:平时解bug时发现,一些App的插件化hook框架,会动态替换mInstrumentation对象,如达到启动Activity时替换目标页面等目的
    • 调用ActivityThread#attach方法 [重要],其中调用IActivityManager#attachApplication,与AMS进行binder通信,将进程的mAppThread传给AMS,类似进行注册
      mAppThread,类型:ApplicationThread extends IApplicationThread.Stub,本质为binder对象,作为服务端,将来接收AMS的binder调用
    • main方法最后调用Looper.loop,进程B的主线程进入循环处理消息模式
    public static void main(String[] args) {
        // 3.1(Binder对象,继承自IApplicationThread.Stub)
        Environment.initForCurrentUser();
        Looper.prepareMainLooper();
        // 3.2
        ActivityThread thread = new ActivityThread();
        thread.attach(false, startSeq);

        if (sMainThreadHandler == null) {
            sMainThreadHandler = thread.getHandler();
        }
        // 3.3
        Looper.loop();

        throw new RuntimeException("Main thread loop unexpectedly exited");
    }
  1. SystemServer进程,作为服务端,接收到进程B的attachApplication方法调用,过程如下:
    • 从前面提到的mPidsSelfLocked中提取app对象,类型:ProcessRecord,存入applicationThread等信息
    • 注册死亡回调,以便App进程挂掉后,AMS能及时得到通知,并清除App的相关信息
    • 发起binder通信,利用applicationThread对象,调用进程B的ApplicationThread#bindApplication方法,经消息转发,最终由进程B主线程的mH对象处理,消息类型:BIND_APPLICATION
    • 检查是否有页面要显示
      ActivityStackSupervisor#attachApplicationLocked ->ActivityStackSupervisor#realStartActivityLocked(如果进程B有位于栈顶的Activity需显示) -> ClientTransaction#schedule
      利用applicationThread对象,调用进程B的ApplicationThread#scheduleTransaction方法,经消息转发,最终由进程B主线程的mH对象处理,操控Activity生命周期等,消息类型:EXECUTE_TRANSACTION
    • 检查是否有服务要启动
      ActiveServices#attachApplicationLocked -> ActivityStackSupervisor#realStartServiceLocked
      利用applicationThread对象,调用进程B的ApplicationThread#scheduleCreateService方法,后续同上类似
    • 检查是否有广播消息要处理,不再详细描述
    • 检查是否有BackupAgent要创建,不再详细描述
    private final boolean attachApplicationLocked(IApplicationThread thread,
            int pid, int callingUid, long startSeq) {
        // 4.1
        ProcessRecord app;
        if (pid != MY_PID && pid >= 0) {
                app = mPidsSelfLocked.get(pid);
        // 4.2
        try {
            AppDeathRecipient adr = new AppDeathRecipient(
                    app, pid, thread);
            thread.asBinder().linkToDeath(adr, 0);
            app.deathRecipient = adr;
        } catch (RemoteException e) {
            // ...
        }
        // 4.3
        thread.bindApplication(processName, appInfo, providers, xxx);
        // 4.4
        mStackSupervisor.attachApplicationLocked(app)) {
                    didSomething = true;
        }
        // 4.5
        didSomething |= mServices.attachApplicationLocked(app, processName);
        // 4.6
        didSomething |= sendPendingBroadcastsLocked(app);
        // 4.7
        thread.scheduleCreateBackupAgent(mBackupTarget.appInfo, xxx);

        return true;
    }

总结:

至此经前4步,至少5次关键的跨进程通信,startActivity过程已基本完成。简单描述:

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