听说你Binder机制学的不错,来面试下这几个问题(三)

很多文章将Binder框架定义了四个角色:Server,Client,ServiceManager、以及Binder驱动,但这容易将人引导到歧途:好像所有的Binder服务都需要去ServiceManager去注册才能使用,其实不是这样。例如,平时APP开发通过bindService启动的服务,以及有些自己定义的AIDL远程调用,都不一定都ServiceManager注册这条路,个人理解:ServiceManager主要功能是:管理系统服务,比如AMS、WMS、PKMS服务等,而APP通过的bindService启动的Binder服务其实是由SystemServer的ActivityManagerService负责管理。这篇主要关注Android APP Java层Binder通信一些奇葩点:

听说你Binder机制学的不错,来解决下这几个问题(一)
听说你Binder机制学的不错,来看看这几个问题(二)
听说你Binder机制学的不错,来看看这几个问题(三)

  • ServiceManager addService的限制(并非服务都能使用ServiceManager的addService)
  • bindService启动Service与Binder服务实体的流程
  • Java层Binder实体与与BinderProxy是如何实例化及使用的,与Native层的关系是怎样的
  • Parcel readStrongBinder与writeStrongBinder的原理(首先两端知晓)

ServiceManager addService的限制--并非所有服务都能通过addService添加到ServiceManager

ServiceManager其实主要的面向对象是系统服务,大部分系统服务都是由SystemServer进程总添加到ServiceManager中去的,在通过ServiceManager添加服务的时候,是有些权限校验的,源码如下:

int svc_can_register(unsigned uid, uint16_t *name)
 {
    unsigned n;
    // 谁有权限add_service 0进程,或者 AID_SYSTEM进程
    if ((uid == 0) || (uid == AID_SYSTEM))
        return 1;
     for (n = 0; n < sizeof(allowed) / sizeof(allowed[0]); n++)
        if ((uid == allowed[n].uid) && str16eq(name, allowed[n].name))
            return 1;
    return 0;
}

可以看到 (uid == 0) 或者 (uid == AID_SYSTEM)的进程都是可以添加服务的,uid=0,代表root用户,而uid=AID_SYSTEM,代表系统用户 。或者是一些特殊的配置进程。SystemServer进程在被Zygote创建的时候,就被分配了UID 是AID_SYSTEM(1000),

private static boolean startSystemServer()
        throws MethodAndArgsCaller, RuntimeException {
    /* Hardcoded command line to start the system server */
    String args[] = {
        "--setuid=1000",
        "--setgid=1000",
        "--setgroups=1001,1002,1003,1004,1005,1006,1007,1008,1009,1010,1018,3001,3002,3003,3006,3007",
        "--capabilities=130104352,130104352",
        "--runtime-init",
        "--nice-name=system_server",
        "com.android.server.SystemServer",
    };

Android每个APP的UID,都是不同的,用了Linux的UID那一套,但是没完全沿用,这里不探讨,总之,普通的进程是没有权限注册到ServiceManager中的,那么APP平时通过bindService启动的服务怎么注册于查询的呢?接管这个任务的就是SystemServer的ActivityManagerService

bindService启动Service与Binder服务实体的流程 (ActivityManagerService)

  • bindService的框架
  • binder服务实例化与转化
  • 业务逻辑的唤醒
  • 请求代理的转化与唤醒

bindService比startService多了一套Binder通信,其余的流程基本相同,而startService的流程,同startActivity差不多,四大组件的启动流程这里不做分析点,主要看bindService中C/S通信的建立流程,在这个流程里面,APP与服务端互为C/S的特性更明显,在APP开发的时候,binder服务是通过Service来启动的。Service的启动方式有两种startService,与bindService,这里只考虑后者,另外启动的binder服务也分为两种情况:第一种,client同server位于同一进程,可以看做内部服务,第二种,Client与Server跨进程,即使是位于同一个APP,第一桶可以不用AIDL来编写,但是第二种必须通过AIDL实现跨进程通信,看一个最简单的AIDL例子,首先在定义一个aidl接口:

IMyAidlInterface.aidl

interface IMyAidlInterface {
void communicate(int count);
}

IMyAidlInterface.aidl定义了通信的借口,通过build之后,构建工具会自动为IMyAidlInterface.aidl生成一些辅助类,这些辅助类主要作用是生成Binder通信协议框架,必须保证两方通信需要指令相同,才能解析通信内容。天王盖地虎,宝塔镇河妖。Java层Binder的对应关系Binder与BinderProxy从这里可以看出,binder采用了代理模式 stub与proxy对应,使用aidl实现的服务时候,Client如果想要获得Binder实体的代理可以通过asInterface来处理,比如如果在同一进程就是实体,不在就新建代理对象

    public interface IMyAidlInterface extends android.os.IInterface {

    public static abstract class Stub extends android.os.Binder implements com.snail.labaffinity.IMyAidlInterface {
        private static final java.lang.String DESCRIPTOR = "com.snail.labaffinity.IMyAidlInterface";

        public Stub() {
            this.attachInterface(this, DESCRIPTOR);
        }

        public static com.snail.labaffinity.IMyAidlInterface asInterface(android.os.IBinder obj) {
            if ((obj == null)) {
                return null;
            }
            android.os.IInterface iin = obj.queryLocalInterface(DESCRIPTOR);
            if (((iin != null) && (iin instanceof com.snail.labaffinity.IMyAidlInterface))) {
                return ((com.snail.labaffinity.IMyAidlInterface) iin);
            }
            return new com.snail.labaffinity.IMyAidlInterface.Stub.Proxy(obj);
        }

        @Override
        public android.os.IBinder asBinder() {
            return this;
        }

        @Override
        public boolean onTransact(int code, android.os.Parcel data, android.os.Parcel reply, int flags) throws android.os.RemoteException {
            switch (code) {
                case INTERFACE_TRANSACTION: {
                    reply.writeString(DESCRIPTOR);
                    return true;
                }
                case TRANSACTION_communicate: {
                    data.enforceInterface(DESCRIPTOR);
                    int _arg0;
                    _arg0 = data.readInt();
                    this.communicate(_arg0);
                    reply.writeNoException();
                    return true;
                }
            }
            return super.onTransact(code, data, reply, flags);
        }

        private static class Proxy implements com.snail.labaffinity.IMyAidlInterface {
            private android.os.IBinder mRemote;

            Proxy(android.os.IBinder remote) {
                mRemote = remote;
            }

            @Override
            public android.os.IBinder asBinder() {
                return mRemote;
            }

            public java.lang.String getInterfaceDescriptor() {
                return DESCRIPTOR;
            }

            @Override
            public void communicate(int count) throws android.os.RemoteException {
                android.os.Parcel _data = android.os.Parcel.obtain();
                android.os.Parcel _reply = android.os.Parcel.obtain();
                try {
                    _data.writeInterfaceToken(DESCRIPTOR);
                    _data.writeInt(count);
                    mRemote.transact(Stub.TRANSACTION_communicate, _data, _reply, 0);
                    _reply.readException();
                } finally {
                    _reply.recycle();
                    _data.recycle();
                }
            }
        }

        static final int TRANSACTION_communicate = (android.os.IBinder.FIRST_CALL_TRANSACTION + 0);
    }

    public void communicate(int count) throws android.os.RemoteException;
}

启动Binder服务端封装Service,之所以成为封装Service,是因为Service对于Binder实体的最大作用是个作为新建服务的入口:

public class AidlService extends Service {
    @Nullable
    @Override
    public IBinder onBind(Intent intent) {
        return new BBinderService();
    }

    public class BBinderService extends IMyAidlInterface.Stub {

        @Override
        public void communicate(int count) throws RemoteException {
        }
    }
}

而启动的入口:

public class MainActivity extends AppCompatActivity {
    ...
   void bind(){
    Intent intent = createExplicitFromImplicitIntent(MainActivity.this, new Intent("com.snail.labaffinity.service.AidlService"));
    bindService(intent, new ServiceConnection() {
        @Override
        public void onServiceConnected(ComponentName componentName, IBinder iBinder) {
            IMyAidlInterface  iMyAidlInterface = IMyAidlInterface.Stub.asInterface(iBinder);
        }

        @Override
        public void onServiceDisconnected(ComponentName componentName) {
        }
    }, Context.BIND_AUTO_CREATE);
    }
 }

以上四个部分就组成了AIDL跨进程服务的基本组件,现在从ActivitybindService入口开始分析:bindService大部分的流程与startActivity类似,其实都是通过AMS启动组件,这里只将一些不同的地方,Activity启动只需要Intent就可以了,而Service的bind需要一个ServiceConnection对象,这个对象其实是为了AMS端在启动Service后回调用的,ServiceConnection是个接口,其实例在ContextImpl的:

private boolean bindServiceCommon(Intent service, ServiceConnection conn, int flags,
                                  UserHandle user) {
    IServiceConnection sd;
    if (conn == null) {
        throw new IllegalArgumentException("connection is null");
    }
    if (mPackageInfo != null) {
        sd = mPackageInfo.getServiceDispatcher(conn, getOuterContext(),
                mMainThread.getHandler(), flags);
    } else {
        throw new RuntimeException("Not supported in system context");
    }
    validateServiceIntent(service);
    try {
        IBinder token = getActivityToken();
        if (token == null && (flags & BIND_AUTO_CREATE) == 0 && mPackageInfo != null
                && mPackageInfo.getApplicationInfo().targetSdkVersion
                < android.os.Build.VERSION_CODES.ICE_CREAM_SANDWICH) {
            flags |= BIND_WAIVE_PRIORITY;
        }
        service.prepareToLeaveProcess();
        int res = ActivityManagerNative.getDefault().bindService(
                mMainThread.getApplicationThread(), getActivityToken(), service,
                service.resolveTypeIfNeeded(getContentResolver()),
                sd, flags, getOpPackageName(), user.getIdentifier());
        if (res < 0) {
            throw new SecurityException(
                    "Not allowed to bind to service " + service);
        }
        return res != 0;
    } catch (RemoteException e) {
        throw new RuntimeException("Failure from system", e);
    }
}

mPackageInfo是一个LoadApk类,通过它的getServiceDispatcher获得一个IServiceConnection对象,这个对象一个Binder实体,看一下具体原理

public final IServiceConnection getServiceDispatcher(ServiceConnection c,
        Context context, Handler handler, int flags) {
    synchronized (mServices) {
        LoadedApk.ServiceDispatcher sd = null;
        ArrayMap map = mServices.get(context);
        if (map != null) {
            sd = map.get(c);
        }
        if (sd == null) {
            sd = new ServiceDispatcher(c, context, handler, flags);
            if (map == null) {
                map = new ArrayMap();
                mServices.put(context, map);
            }
            map.put(c, sd);
        } else {
            sd.validate(context, handler);
        }
        return sd.getIServiceConnection();
    }
}

在LoadApk中IServiceConnection对象是通过context键值来存储ServiceDispatcher对象,而ServiceDispatcher对象内存会有个InnerConnection对象,该对象就是getServiceDispatcher的返回对象。因此bindServiceCommon最终调用
ActivityManagerNative.getDefault().bindService(x,x,x,x,x sd, x, x, x) 的时候,传递的参数sd其实就是一个InnerConnection对象,这是个Binder实体。但是,Binder.java中的Binder只是对native层BBinder的一个简单封装,真正的实例化还是通过JNI到native层去创建一个JavaBBinderHolder对象,并初始化gBinderOffsets,让其能映射Java层Binder对象,而JavaBBinderHolder中又可以实例化BBinder的实例JavaBBinder,不过BBinder的实例化时机并不在这里,而是在Parcel对象writeStrongBinder的时候,

static struct bindernative_offsets_t
{
    // Class state.
    jclass mClass;
    jmethodID mExecTransact;

    // Object state.
    jfieldID mObject;

} gBinderOffsets;

static void android_os_Binder_init(JNIEnv* env, jobject obj)
{
    JavaBBinderHolder* jbh = new JavaBBinderHolder();
    jbh->incStrong((void*)android_os_Binder_init);
    env->SetIntField(obj, gBinderOffsets.mObject, (int)jbh);
}

继续往下看bindService,会调用到ActivityManagerProxy的bindService

public int bindService(IApplicationThread caller, IBinder token,
        Intent service, String resolvedType, IServiceConnection connection,
        int flags, int userId) throws RemoteException {
    Parcel data = Parcel.obtain();
    Parcel reply = Parcel.obtain();
    data.writeInterfaceToken(IActivityManager.descriptor);
    data.writeStrongBinder(caller != null ? caller.asBinder() : null);
    data.writeStrongBinder(token);
    service.writeToParcel(data, 0);
    data.writeString(resolvedType);
    data.writeStrongBinder(connection.asBinder());
    data.writeInt(flags);
    data.writeInt(userId);
    mRemote.transact(BIND_SERVICE_TRANSACTION, data, reply, 0);
    reply.readException();
    int res = reply.readInt();
    data.recycle();
    reply.recycle();
    return res;
}

利用Parcel的writeStrongBinder会将Binder实体写入到Parcel中去,这里首先看一下 Parcel data = Parcel.obtain();在java层Parcel只是一个容器,具体Parcel相关的操作都在Native层

static jint android_os_Parcel_create(JNIEnv* env, jclass clazz)
{
    Parcel* parcel = new Parcel();
    return reinterpret_cast(parcel);
}

这里的返回值,其实就是Parcel对象的地址,被赋值给了Parcel.java的mNativePtr成员变量,方便Native调用,接着看writeStrongBinder的实现,其实就是调用Parcel.cpp中的对应方法,通过flatten_binder将Binder实体对象打扁,创建flat_binder_object写入Parcel中,

static void android_os_Parcel_writeStrongBinder(JNIEnv* env, jclass clazz, jint nativePtr, jobject object)
{
    Parcel* parcel = reinterpret_cast(nativePtr);
    if (parcel != NULL) {
        const status_t err = parcel->writeStrongBinder(ibinderForJavaObject(env, object));
        if (err != NO_ERROR) {
            signalExceptionForError(env, clazz, err);
        }
    }
}

ibinderForJavaObject主要为Java层Binder实例化native binder对象:

sp ibinderForJavaObject(JNIEnv* env, jobject obj)
{
    if (obj == NULL) return NULL;

    if (env->IsInstanceOf(obj, gBinderOffsets.mClass)) {
        JavaBBinderHolder* jbh = (JavaBBinderHolder*)
            env->GetIntField(obj, gBinderOffsets.mObject);
        return jbh != NULL ? jbh->get(env, obj) : NULL;
    }

    if (env->IsInstanceOf(obj, gBinderProxyOffsets.mClass)) {
        return (IBinder*)
            env->GetIntField(obj, gBinderProxyOffsets.mObject);
    }
    return NULL;
}

如果BBinder还没实例化,要通过JavaBBinderHolder的get函数实例化一个BBinder对象,这里就是JavaBBinder对象,综上分析Java层与Native的Binder其对应关系如下:

听说你Binder机制学的不错,来面试下这几个问题(三)_第1张图片
Java层Binder与native 层BBiner.png

BBinder对象被Parcel转换成flat_binder_object,经过一次拷贝写入目标进程,并执行BINDER_TYPE_BINDER与BINDER_TYPE_HANDLE的转换,如下:

static void
binder_transaction(struct binder_proc *proc, struct binder_thread *thread,
    struct binder_transaction_data *tr, int reply)
    ...
 fp = (struct flat_binder_object *)(t->buffer->data + *offp);

    switch (fp->type) {
        case BINDER_TYPE_BINDER:
        case BINDER_TYPE_WEAK_BINDER: {..
            if (fp->type == BINDER_TYPE_BINDER)
                fp->type = BINDER_TYPE_HANDLE;
            else
                fp->type = BINDER_TYPE_WEAK_HANDLE;
            fp->handle = ref->desc;
        } break;
        case BINDER_TYPE_HANDLE:
        case BINDER_TYPE_WEAK_HANDLE: {..
            struct binder_ref *ref = binder_get_ref(proc, fp->handle);
            if (ref->node->proc == target_proc) {
                if (fp->type == BINDER_TYPE_HANDLE)
                    fp->type = BINDER_TYPE_BINDER;
                else
                    fp->type = BINDER_TYPE_WEAK_BINDER;
                fp->binder = ref->node->ptr;
                fp->cookie = ref->node->cookie;
            } else {
                struct binder_ref *new_ref;
                new_ref = binder_get_ref_for_node(target_proc, ref->node);
                fp->handle = new_ref->desc;
            }
        } break;
}

在内核中,bindService中的InnerConnection会由BINDER_TYPE_BINDER转换成BINDER_TYPE_HANDLE,之后,AMS线程被唤醒后,执行后面的流程,在前文分析Parcel数据转换的时候,在Binder线程被唤醒继续执行的时候,会将数据映射到一个natvie Parcel对象中

status_t IPCThreadState::executeCommand(int32_t cmd)
 {
    BBinder* obj;
    switch (cmd) {
     ..
    // read到了数据请求,这里是需要处理的逻辑 ,处理完毕,
    case BR_TRANSACTION:
        {
            binder_transaction_data tr;
            result = mIn.read(&tr, sizeof(tr));
            Parcel buffer;
            
            buffer.ipcSetDataReference(
                reinterpret_cast(tr.data.ptr.buffer),
                tr.data_size,
                reinterpret_cast(tr.data.ptr.offsets),
                tr.offsets_size/sizeof(size_t), freeBuffer, this);
            ...
          
        if (tr.target.ptr) {
            sp b((BBinder*)tr.cookie);
            const status_t error = b->transact(tr.code, buffer, &reply, tr.flags);
            if (error < NO_ERROR) reply.setError(error);
        }
        ..
      }
   }        

首先看一下关键点1 ,这里将内核数据映射到一个用户空间的Parcel对象中去,之后在调用目标Service的transact函数,进而调用他的onTrasanct函数 , 通过前面的分析知道,Java层Binder在注册时候,最终注册的是JavaBBinder对象,看一下它的onTrasanct函数:

virtual status_t onTransact(
        uint32_t code, const Parcel& data, Parcel* reply, uint32_t flags = 0)
    {
        JNIEnv* env = javavm_to_jnienv(mVM);
        IPCThreadState* thread_state = IPCThreadState::self();
        const int strict_policy_before = thread_state->getStrictModePolicy();
        thread_state->setLastTransactionBinderFlags(flags);
        ..
        jboolean res = env->CallBooleanMethod(mObject, gBinderOffsets.mExecTransact,
            code, (int32_t)&data, (int32_t)reply, flags);
        ..
        return res != JNI_FALSE ? NO_ERROR : UNKNOWN_TRANSACTION;
    }

关键代码只有一句:env->CallBooleanMethod(mObject, gBinderOffsets.mExecTransact, code, (int32_t)&data, (int32_t)reply, flags),其实就是调用Binder.java的execTransact函数,该函数首先将Native的Parcel映射成Jave层Parcel,之后调用BBinder子类的onTransact函数执行对应的业务逻辑,最后会通过data.recycle通知释放内存:

private boolean execTransact(int code, int dataObj, int replyObj,
            int flags) {
        Parcel data = Parcel.obtain(dataObj);
        Parcel reply = Parcel.obtain(replyObj);
        boolean res;
        try {
            res = onTransact(code, data, reply, flags);
        } ...
        reply.recycle();
        data.recycle();
        return res;
    }}

对于AMS而bindService对应的操作如下

public boolean onTransact(int code, Parcel data, Parcel reply, int flags)
    throws RemoteException {
    。。
    case BIND_SERVICE_TRANSACTION: {
    data.enforceInterface(IActivityManager.descriptor);
    IBinder b = data.readStrongBinder();
    IApplicationThread app = ApplicationThreadNative.asInterface(b);
    IBinder token = data.readStrongBinder();
    Intent service = Intent.CREATOR.createFromParcel(data);
    String resolvedType = data.readString();
    b = data.readStrongBinder();
    int fl = data.readInt();
    int userId = data.readInt();
    IServiceConnection conn = IServiceConnection.Stub.asInterface(b);
    int res = bindService(app, token, service, resolvedType, conn, fl, userId);
    reply.writeNoException();
    reply.writeInt(res);
    return true;
}

b = data.readStrongBinder()会先读取Binder对象,这里会调用本地函数nativeReadStrongBinder(mNativePtr),mNativePtr就是Native层Parcel的首地址:

public final IBinder readStrongBinder() {
    return nativeReadStrongBinder(mNativePtr);
}

nativeReadStrongBinder(mNativePtr)会将本地Binder对象转化成Java层对象,其实就是将传输的InnerConnection读取出来,不过由于Binder驱动将BINDER_TYPE_BINDER转换成了BINDER_TYPE_HANDLE,对于AMS其实是实例化BinderProxy

static jobject android_os_Parcel_readStrongBinder(JNIEnv* env, jclass clazz, jint nativePtr)
{
    Parcel* parcel = reinterpret_cast(nativePtr);
    if (parcel != NULL) {

        // /parcel->readStrongBinder() 其实就会创建BpBInder、
        return javaObjectForIBinder(env, parcel->readStrongBinder());
    }
    return NULL;
}

首先会利用Parcel.cpp的parcel->readStrongBinder(),读取binder对象,这里会根据flat_binder_object的类型,分别进行BBinder与BpBinder映射,如果是Binder实体直接将指针赋值out,如果不是,则根据handle获取或者新建BpBinder返回给out。

status_t unflatten_binder(const sp& proc,
    const Parcel& in, sp* out)
{
    const flat_binder_object* flat = in.readObject(false);
    
    if (flat) {
        switch (flat->type) {
            case BINDER_TYPE_BINDER:
                *out = static_cast(flat->cookie);
                return finish_unflatten_binder(NULL, *flat, in);
            case BINDER_TYPE_HANDLE:
                *out = proc->getStrongProxyForHandle(flat->handle);
                return finish_unflatten_binder(
                    static_cast(out->get()), *flat, in);
        }        
    }
    return BAD_TYPE;
}

之后会牵扯一个将native binder转换成java层Binder的操作,javaObjectForIBinder,这个函数很关键,是理解Java层BinderProxy或者BBinder实体的关键:

jobject javaObjectForIBinder(JNIEnv* env, const sp& val)
{
    if (val == NULL) return NULL;
    
    if (val->checkSubclass(&gBinderOffsets)) {
        jobject object = static_cast(val.get())->object();
        return object;
    }
    AutoMutex _l(mProxyLock);
    
    jobject object = (jobject)val->findObject(&gBinderProxyOffsets);
    if (object != NULL) {
        android_atomic_dec(&gNumProxyRefs);
        val->detachObject(&gBinderProxyOffsets);
        env->DeleteGlobalRef(object);
    }
    
    object = env->NewObject(gBinderProxyOffsets.mClass, gBinderProxyOffsets.mConstructor);
    if (object != NULL) {
        env->SetIntField(object, gBinderProxyOffsets.mObject, (int)val.get());
        val->incStrong((void*)javaObjectForIBinder);
        jobject refObject = env->NewGlobalRef(
                env->GetObjectField(object, gBinderProxyOffsets.mSelf));
        val->attachObject(&gBinderProxyOffsets, refObject,
                jnienv_to_javavm(env), proxy_cleanup);
        sp drl = new DeathRecipientList;
        drl->incStrong((void*)javaObjectForIBinder);
        env->SetIntField(object, gBinderProxyOffsets.mOrgue, reinterpret_cast(drl.get()));
        android_atomic_inc(&gNumProxyRefs);
        incRefsCreated(env);
    }
    return object;
}

先看关键点1, checkSubclass默认返回false,但是JavaBBinder,该类对此函数进行了覆盖,如果是JavaBBinder,就会返回true,但入股是BpBinder,则会返回false,

bool    checkSubclass(const void* subclassID) const
{
    return subclassID == &gBinderOffsets;
}

再看关键点2,如果是BpBinder,则需要首先在gBinderProxyOffsets中查找,是不是已经新建了Java层代理BinderProxy对象,如果没有,则新建即可,如果新建就看是否还存在缓存有效的BinderProxy。最后看关键点3 :

env->NewObject(gBinderProxyOffsets.mClass, gBinderProxyOffsets.mConstructor)

其实就是新建BinderProxy对象,Java层的BinderProxy都是Native新建的,Java层并没有BinderProxy的新建入口,之后,再通过IServiceConnection.Stub.asInterface(b)进行转换,实例化一个IServiceConnection.Proxy代理对,该对象在Binder通信的基础上封装了业务逻辑,其实就是一些具体的操作。

 public static XXXAidlInterface asInterface(android.os.IBinder obj) {
            if ((obj == null)) {
                return null;
            }
            android.os.IInterface iin = obj.queryLocalInterface(DESCRIPTOR);
            if (((iin != null) && (iin instanceof XXXAidlInterface))) {
                return ((XXXAidlInterface) iin);
            }
            return new XXXAidlInterface.Stub.Proxy(obj);
        }

这里注意一点杜宇BinderProxy,obj.queryLocalInterface(DESCRIPTOR)返回为null,对于Binder实体,返回的是Binder自身,这样就能为上层区分出是生成代理还是存根自身,整体对象转换流程如下:

听说你Binder机制学的不错,来面试下这几个问题(三)_第2张图片
ServiceConnection的回调作用

到这里分析了一半,Java层命令及回调Binder入口已经被传递给AMS,AMS之后需要负责启动Service,并通过回调入口为Client绑定服务,跟踪到AMS源码

public int bindService(IApplicationThread caller, IBinder token,
        Intent service, String resolvedType,
        IServiceConnection connection, int flags, int userId) {
    ...
    synchronized(this) {
        return mServices.bindServiceLocked(caller, token, service, resolvedType,
                connection, flags, userId);
    }
}

最后调用ActiveService的bindServiceLocked,这里会分三中情况,

  • Service已经经启动
  • Service未启动,但是进程已经启动
  • Service与进程君未启动

不过这里只讨论“ Service未启动,但是进程已经启动的情况”,关键代码如下

 int bindServiceLocked(IApplicationThread caller, IBinder token,
            Intent service, String resolvedType,
            IServiceConnection connection, int flags, int userId) {

        try {
            .。。

            if ((flags&Context.BIND_AUTO_CREATE) != 0) {
                s.lastActivity = SystemClock.uptimeMillis();
          
                if (bringUpServiceLocked(s, service.getFlags(), false) != null) {
                    return 0;
                }
            }
          
           ..
           requestServiceBindingLocked(s, b.intent, false);
           ..
        }
}

关键点1其实就是启动Service,主要是通过ApplicationThread的binder通信通知App端启动Service,这个流程同Activity启动一样。关键点2是Service特有的:requestServiceBindingLocked,这个命令是告诉APP端:“在Service启动后需要向AMS发消息,之后AMS才能向其他需要绑定该Service的Client发送反馈”。

AMS端
private final boolean requestServiceBindingLocked(ServiceRecord r,
        IntentBindRecord i, boolean rebind) {
    if ((!i.requested || rebind) && i.apps.size() > 0) {
       ..
          r.app.thread.scheduleBindService(r, i.intent.getIntent(), rebind);
       ..
      }        }
    return true;
}

 APP端
 private void handleBindService(BindServiceData data) {
    Service s = mServices.get(data.token);
    ...
    if (!data.rebind) {
        IBinder binder = s.onBind(data.intent);
        ActivityManagerNative.getDefault().publishService(
                data.token, data.intent, binder);
    }
}

ActivityManagerNative.getDefault().publishService会将启动的Binder服务实体传递给AMS,上面分析过Binder实体传输,这里的原理是一样的,AMS端在传输结束后,会获得Service端服务实体的引用,这个时候,就能通过最初的InnerConnection的回调将这个服务传递给Client端。Binder实体与引用的整体流程图如下:

听说你Binder机制学的不错,来面试下这几个问题(三)_第3张图片
bindSerivce整体流程图

如果要深究Activity的bindService流程,可以按以下几步来分析

  • 1、Activity调用bindService:通过Binder通知ActivityManagerService,要启动哪个Service
  • 2、ActivityManagerService创建ServiceRecord,并利用ApplicationThreadProxy回调,通知APP新建并启动Service启动起来
  • 3、ActivityManagerService把Service启动起来后,继续通过ApplicationThreadProxy,通知APP,bindService,其实就是让Service返回一个Binder对象给ActivityManagerService,以便AMS传递给Client
  • 4、ActivityManagerService把从Service处得到这个Binder对象传给Activity,这里是通过IServiceConnection binder实现。
  • 5、Activity被唤醒后通过Binder Stub的asInterface函数将Binder转换为代理Proxy,完成业务代理的转换,之后就能利用Proxy进行通信了。
听说你Binder机制学的不错,来面试下这几个问题(三)_第4张图片
bindService流程

听说你Binder机制学的不错,来解决下这几个问题(一)
听说你Binder机制学的不错,来看看这几个问题(二)
听说你Binder机制学的不错,来看看这几个问题(三)

作者:看书的小蜗牛
原文链接: 听说你Binder机制学的不错,来面试下这几个问题(三)

仅供参考,欢迎指正

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