Android Service启动流程刨析

Android Service启动流程刨析 强调一下阅读系统源码,起码要对进程间通信要了解,对binder机制非常非常清楚,binder就是指南针,要不然你会晕头转向:强行阅读,就容易睡着. Service启动先来一张图感受一下 这张图能够说明一个大致的流程,但是服务的启动肯

强调一下阅读系统源码,起码要对进程间通信要了解,对binder机制非常非常清楚,binder就是指南针,要不然你会晕头转向;强行阅读,就容易睡着。

Service启动先来一张图感受一下

这张图能够说明一个大致的流程,但是服务的启动肯定不是这么简单,但是我们先简单的总结一下,逐渐深入。服务的启动形式有两种,startService()和 binderService(),我们看startService()这一种。startService是ContextWrapper里面的方法。

ContextWrapper.java

  @Override
   public ComponentName startService(Intent service) {
       return mBase.startService(service);//mBase这里指的是ContextImpl类
   }

ContextImpl.java

   @Override
    public ComponentName startService(Intent service) {
        warnIfCallingFromSystemProcess();
        return startServiceCommon(service, mUser);
    }
  private ComponentName startServiceCommon(Intent service, UserHandle user) {
        try {
            //检验Intent
            validateServiceIntent(service);
             ......
            ComponentName cn = ActivityManagerNative.getDefault().startService(
                mMainThread.getApplicationThread(), service, service.resolveTypeIfNeeded(
                            getContentResolver()), getOpPackageName(), user.getIdentifier());
             ......
            return cn;
        } catch (RemoteException e) {
            throw new RuntimeException("Failure from system", e);
        }
    }

校验完Intent后,就调用ActivityManagerNative.getDefault(),获取一个IActivityManager对象,将启动Service这件事情交给了IActivityManager。我们看一下ActivityManagerNative的类定义

public abstract class ActivityManagerNative extends Binder implements IActivityManager

这种模式是不是非常熟悉啊? 继承了Binder,实现了一个IActivityManager接口,这个跟我们生成了远程服务通信生成的AIDL的java文件怎么那么像,现在告诉你,这就是为了远程服务通信做准备的,只是一般这种类我们都是自动生成的,ActivityManagerNative 是谷歌的人自己写

一个完整的AID L有两部分,一个是个跟服务端通信的Stub,一个是跟客户端通信的Proxy; ActivityManagerNative就是Stub,阅读源码发现在ActivityManagerNative 文件中还有个ActivityManagerProxy,那么跟客户端通信的Proxy也有了。先看IActivityManager怎么获取的

ActivityManagerNative.java

 static public IActivityManager getDefault() {
        return gDefault.get();
    }
  private static final Singleton<IActivityManager> gDefault = new Singleton<IActivityManager>() {
        protected IActivityManager create() {
          //获取名为"activity"的服务,服务都注册到ServiceManager来统一管理
            IBinder b = ServiceManager.getService("activity");
            if (false) {
                Log.v("ActivityManager", "default service binder = " + b);
            }
            IActivityManager am = asInterface(b);
            if (false) {
                Log.v("ActivityManager", "default service = " + am);
            }
            return am;
        }
    };

就是一个单例设计模式,获取到服务对象IBinder,把这个IBinder转换成IActivityManager返回了。现在由IActivityManager启动服务。

 public ComponentName startService(IApplicationThread caller, Intent service,
            String resolvedType, String callingPackage, int userId) throws RemoteException
    {
        Parcel data = Parcel.obtain();
        Parcel reply = Parcel.obtain();
        data.writeInterfaceToken(IActivityManager.descriptor);
        data.writeStrongBinder(caller != null ? caller.asBinder() : null);
        service.writeToParcel(data, 0);
        data.writeString(resolvedType);
        data.writeString(callingPackage);
        data.writeInt(userId);
        mRemote.transact(START_SERVICE_TRANSACTION, data, reply, 0);
        reply.readException();
        ComponentName res = ComponentName.readFromParcel(reply);
        data.recycle();
        reply.recycle();
        return res;
    }

上面说了ActivityManagerProxy作为binder通信的客户端,ActivityManagerNative 作为binder通信的服务端; mRemote.transact()是binder通信的客户端发起方法,经过binder驱动,最后回到binder服务端ActivityManagerNative的onTransact()方法。

   @Override
    public boolean onTransact(int code, Parcel data, Parcel reply, int flags)
            throws RemoteException {
            .......
        switch (code) {
             case START_SERVICE_TRANSACTION: {
                        data.enforceInterface(IActivityManager.descriptor);
                        IBinder b = data.readStrongBinder();
                        IApplicationThread app = ApplicationThreadNative.asInterface(b);
                        Intent service = Intent.CREATOR.createFromParcel(data);
                        String resolvedType = data.readString();
                        String callingPackage = data.readString();
                        int userId = data.readInt();
                        ComponentName cn = startService(app, service, resolvedType, callingPackage, userId);
                        reply.writeNoException();
                        ComponentName.writeToParcel(cn, reply);
                        return true;
                    }
        }
        .......
    }

ActivityManagerNative的真正实现是ActivityManagerService,所以binder通信的服务端的ActivityManagerService,ActivityManagerProxy.startService()最终调用ActivityManagerService.startService()。注意这就跨进程了,ActivityManagerService是一个服务端的进程。看ActivityManagerService中的startService方法。

ActivityManagerService.java

 public ComponentName startService(IApplicationThread caller, Intent service,
            String resolvedType, String callingPackage, int userId)
            throws TransactionTooLargeException {
        ......
        synchronized(this) {
            .......
            ComponentName res = mServices.startServiceLocked(caller, service,
                    resolvedType, callingPid, callingUid, callingPackage, userId);
            Binder.restoreCallingIdentity(origId);
            return res;
        }
    }

ActivityManagerService没有直接干这个活,而是把这个任务交给了mService, mService 是一个 ActiveServices 对象。在早期的安卓版本中并没有这个类,后来重构时抽出这个类专门用来管理Service.

ActiveServices.java

    ComponentName startServiceLocked(IApplicationThread caller, Intent service, String resolvedType,
            int callingPid, int callingUid, String callingPackage, int userId)
            throws TransactionTooLargeException {
              ........
              return startServiceInnerLocked(smap, service, r, callerFg, addToStarting);
    }

tartServiceInnerLocked调用了 bringUpServiceLocked(),bringUpServiceLocked()内部调用了realStartServiceLocked(),我们看realStartServiceLocked()方法。

private final void realStartServiceLocked(ServiceRecord r,
            ProcessRecord app, boolean execInFg) throws RemoteException {
       .......
        try {
            .......
            app.thread.scheduleCreateService(r, r.serviceInfo,
                    mAm.compatibilityInfoForPackageLocked(r.serviceInfo.applicationInfo),
                    app.repProcState);
            r.postNotification();
            created = true;
        } catch (DeadObjectException e) {
            ....
        } finally {
           ....
        }
        requestServiceBindingsLocked(r, execInFg);
        updateServiceClientActivitiesLocked(app, null, true);
        // If the service is in the started state, and there are no
        // pending arguments, then fake up one so its onStartCommand() will
        // be called.
        if (r.startRequested && r.callStart && r.pendingStarts.size() == 0) {
            r.pendingStarts.add(new ServiceRecord.StartItem(r, false, r.makeNextStartId(),
                    null, null));
        }
       // 进入onStartCommand()
        sendServiceArgsLocked(r, execInFg, true);
       ....
    }

这里的关键是

 app.thread.scheduleCreateService(r, r.serviceInfo,
                    mAm.compatibilityInfoForPackageLocked(r.serviceInfo.applicationInfo),

app 是要运行 Service 的进程对应的 ProcessRecord 对象,代表一个应用进程; 要区分一下,一般我们都是单方向通信,客户端将处理请求发送给服务端,服务端处理后返回,如果要服务端向客户端发送一个“请求”呢?这里的thread 是一个 ApplicationThreadProxy 对象,它是应用进程的 ApplicatonThread 对象在 AMS 端的代理,AMS 靠它来和应用进程进行通信。所以AMS和应用进程可以双向通信了。

ApplicationThreadProxy.java

public final void scheduleCreateService(IBinder token, ServiceInfo info,
        CompatibilityInfo compatInfo, int processState) throws RemoteException {
    Parcel data = Parcel.obtain();
    data.writeInterfaceToken(IApplicationThread.descriptor);
    data.writeStrongBinder(token);
    info.writeToParcel(data, 0);
    compatInfo.writeToParcel(data, 0);
    data.writeInt(processState);
    try {
        mRemote.transact(SCHEDULE_CREATE_SERVICE_TRANSACTION, data, null, IBinder.FLAG_ONEWAY);
    } catch (TransactionTooLargeException e) {
        throw e;
    }
    data.recycle();
}

执行mRemote.transact后,就会回调ApplicationThreadNative的onTransact,这是Binder的套路。

ApplicationThreadNative.java

public boolean onTransact(int code, Parcel data, Parcel reply, int flags)
        throws RemoteException {
    switch (code) {
    case SCHEDULE_CREATE_SERVICE_TRANSACTION: {
        data.enforceInterface(IApplicationThread.descriptor);
        IBinder token = data.readStrongBinder();
        ServiceInfo info = ServiceInfo.CREATOR.createFromParcel(data);
        CompatibilityInfo compatInfo = CompatibilityInfo.CREATOR.createFromParcel(data);
        int processState = data.readInt();
        scheduleCreateService(token, info, compatInfo, processState);
        return true;
    }
    ...
}

内部调用scheduleCreateService,看上面的图,可以知道,scheduleCreateService是属于ApplicatonThread的。

ApplicatonThread.java

 public final void scheduleCreateService(IBinder token,
                ServiceInfo info, CompatibilityInfo compatInfo, int processState) {
            updateProcessState(processState, false);
            CreateServiceData s = new CreateServiceData();
            s.token = token;
            s.info = info;
            s.compatInfo = compatInfo;
            sendMessage(H.CREATE_SERVICE, s);
        }

发送一个消息,这个消息都是由H类处理的,H类就是系统Hander,专门处理系统请求的; 比如一些Activity的生命周期等全在这里面。这个 H对象是在应用进程的主线程中创建的,所以最终的结果是把创建 Service 的消息传到了主线程,因此Service是运行在主线程中的。

H.java

private class H extends Handler {
          .........
            public void handleMessage(Message msg) {
            if (DEBUG_MESSAGES) Slog.v(TAG, ">>> handling: " + codeToString(msg.what));
            switch (msg.what) {
             case CREATE_SERVICE:
                    Trace.traceBegin(Trace.TRACE_TAG_ACTIVITY_MANAGER, "serviceCreate");
                    handleCreateService((CreateServiceData)msg.obj);
                    Trace.traceEnd(Trace.TRACE_TAG_ACTIVITY_MANAGER);
            }
        }

ActivityThread.java

private void handleCreateService(CreateServiceData data) {
        .......
        LoadedApk packageInfo = getPackageInfoNoCheck(
                data.info.applicationInfo, data.compatInfo);
        Service service = null;
        try {
            // 反射加载Service
            java.lang.ClassLoader cl = packageInfo.getClassLoader();
            service = (Service) cl.loadClass(data.info.name).newInstance();
        } catch (Exception e) {
            .......
        }
        try {
            if (localLOGV) Slog.v(TAG, "Creating service " + data.info.name);
             //创建ContextImpl对象
            ContextImpl context = ContextImpl.createAppContext(this, packageInfo);
            context.setOuterContext(service);
             //创建Application对象
            Application app = packageInfo.makeApplication(false, mInstrumentation);
            service.attach(context, this, data.info.name, data.token, app,
                    ActivityManagerNative.getDefault());
            //回调onCreate方法
            service.onCreate();
            mServices.put(data.token, service);
            try {
              //调用服务创建完成
                ActivityManagerNative.getDefault().serviceDoneExecuting(
                        data.token, SERVICE_DONE_EXECUTING_ANON, 0, 0);
            } catch (RemoteException e) {
                // nothing to do.
            }
        } catch (Exception e) {
           .......
        }
    }

到此Service的onCreate就回调了,那么onStartCommand()何时回调呢?在realStartServiceLocked中调用了sendServiceArgsLocked(r, execInFg, true),sendServiceArgsLocked与上面类似,最终也是发送了一个(SERVICE_ARGS)消息。

ApplicationThread.java

public final void scheduleServiceArgs(IBinder token, boolean taskRemoved, int startId,
            int flags ,Intent args) {
            ServiceArgsData s = new ServiceArgsData();
            s.token = token;
            s.taskRemoved = taskRemoved;
            s.startId = startId;
            s.flags = flags;
            s.args = args;
            sendMessage(H.SERVICE_ARGS, s);
        }

ActivityThread.java

private void handleServiceArgs(ServiceArgsData data) {
        Service s = mServices.get(data.token);
        if (s != null) {
            try {
                if (data.args != null) {
                    data.args.setExtrasClassLoader(s.getClassLoader());
                    data.args.prepareToEnterProcess();
                }
                int res;
                if (!data.taskRemoved) {
                //onStartCommand回调
                    res = s.onStartCommand(data.args, data.flags, data.startId);
                } else {
                    s.onTaskRemoved(data.args);
                    res = Service.START_TASK_REMOVED_COMPLETE;
                }
                QueuedWork.waitToFinish();
                try {
                    ActivityManagerNative.getDefault().serviceDoneExecuting(
                            data.token, SERVICE_DONE_EXECUTING_START, data.startId, res);
                } catch (RemoteException e) {
                    // nothing to do.
                }
                ensureJitEnabled();
            } catch (Exception e) {
               ......
            }
        }
    }

Service的onCreate的回调和onStartCommand的回调套路是完全一样的,朋友们可以自己体会,onCreate的回调先执行scheduleCreateService()方法,最终回调Service.onCreate(); onStartCommand的回调先执行scheduleServiceArgs()方法,最终回调Service.onStartCommand()

总结一下:

IActivityManager接口中定义了AMS向应用程序(本例中即Service)提供的多种API,Activity通过ActivityManagerProxy就可以使用这些API,向AMS发出请求

所以是通过ActivityManagerProxy,调用ActivityManagerProxy的startService方法; 在内部调用transact,然后会调用ActivityManagerNative中的onTransact()方法,在该方法中,将会r完成AMS与Activity的连接并调用AMS的startService()方法,那么AMS是如何Service所在的应用程序呢?比如scheduleCreateService

原来ApplicationThreadProxy 是应用进程的 ApplicatonThread 对象在 AMS 端的代理,AMS 靠它来和应用进程进行通信。这就是Activity与AMS之间的双向Binder连接;Activity用IActivityManager提供的APIActivityManagerService提出执行某个动作的请求(本例中是启动RemoteService),ActivityManagerService通过IApplicationThread提供的API来控制Activity所在的应用程序

上面的分析省去了很多的内容,如果从进程角度看服务启动过程。

  • Process A进程: 是指调用startService命令所在的进程,也就是启动服务的发起端进程
  • system_server进程: 系统进程,是java framework框架的核心载体,里面运行了大量的系统服务,比如这里提供ApplicationThreadProxy,ActivityManagerService,这个两个服务都运行在system_server进程的不同线程中
  • Zygote进程: 是由init进程孵化而来的,用于创建Java层进程的母体,所有的Java层进程都是由Zygote进程孵化而来
  • Remote Service进程: 远程服务所在进程,是由Zygote进程孵化而来的用于运行Remote服务的进程。主线程主要负责Activity/Service等组件的生命周期以及UI相关操作都运行在这个线程; 另外,每个App进程中至少会有两个binder线程 ApplicationThread和ActivityManagerProxy

启动流程:

  • Process A进程采用Binder IPC向system_server进程发起startService请求;
  • system_server进程接收到请求后,向zygote进程发送创建进程的请求;
  • zygote进程fork出新的子进程Remote Service进程;
  • Remote Service进程,通过Binder IPC向sytem_server进程发起attachApplication请求;
  • system_server进程在收到请求后,进行一系列准备工作后,再通过binder IPC向remote Service进程发送scheduleCreateService请求;
  • Remote Service进程的binder线程在收到请求后,通过handler向主线程发送CREATE_SERVICE消息;
  • 主线程在收到Message后,通过发射机制创建目标Service,并回调Service.onCreate()方法。 到此,服务便正式启动完成。当创建的是本地服务或者服务所属进程已创建时,则无需经过上述步骤2、3,直接创建服务即可

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