目录
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1.handler作用:
1)传递消息Message
//2种创建消息方法
//1.通过handler实例获取
Handler handler = new Handler();
Message message=handler.obtainMessage();
//2.通过Message获取
Message message=Message.obtain();
//源码中第一种获取方式其实也是内部调用了第二种:
public final Message obtainMessage(){
return Message.obtain(this);
}不建议直接new Message,Message内部保存了一个缓存的消息池,我们可以用obtain从缓存池获得一个消息,Message使用完后系统会调用recycle回收,如果自己new很多Message,每次使用完后系统放入缓存池,会占用很多内存的。
//传递的数据
Bundle bundle = new Bundle();
bundle.putString("msg", "传递我这个消息");
//发送数据
Message message = Message.obtain();
message.setData(bundle); //message.obj=bundle 传值也行
message.what = 0x11;
handler.sendMessage(message);
//数据的接收
final Handler handler = new Handler() {
@Override
public void handleMessage(Message msg) {
super.handleMessage(msg);
if (msg.what == 0x11) {
Bundle bundle = msg.getData();
String date = bundle.getString("msg");
}
}
};2)子线程通知主线程更新ui
//创建handler
final Handler handler = new Handler() {
@Override
public void handleMessage(Message msg) {
super.handleMessage(msg);
if (msg.what == 0x11) {
//更新ui
......
}
}
};
new Thread(new Runnable() {
@Override
public void run() {
//FIXME 这里直接更新ui是不行的
//还有其他更新ui方式,runOnUiThread()等
message.what = 0x11;
handler.sendMessage(message);
}
}).start();2.常用api
//消息
Message message = Message.obtain();
//发送消息
new Handler().sendMessage(message);
//延时1s发送消息
new Handler().sendMessageDelayed(message, 1000);
//发送带标记的消息(内部创建了message,并设置msg.what = 0x1)
new Handler().sendEmptyMessage(0x1);
//延时1s发送带标记的消息
new Handler().sendEmptyMessageDelayed(0x1, 1000);
//延时1秒发送消息(第二个参数为:相对系统开机时间的绝对时间,而SystemClock.uptimeMillis()是当前开机时间)
new Handler().sendMessageAtTime(message, SystemClock.uptimeMillis() + 1000);
//避免内存泄露的方法:
//移除标记为0x1的消息
new Handler().removeMessages(0x1);
//移除回调的消息
new Handler().removeCallbacks(Runnable);
//移除回调和所有message
new Handler().removeCallbacksAndMessages(null);3.handler使用避免内存泄露
1)handler怎么使用会产生内存泄露?
public class MainActivity extends AppCompatActivity {
final Handler handler = new Handler() {
@Override
public void handleMessage(Message msg) {
super.handleMessage(msg);
......
}
};
@Override
protected void onCreate(Bundle savedInstanceState) {
super.onCreate(savedInstanceState);
setContentView(R.layout.activity_main);
//activity被执行时,被延迟的这个消息存于主线程消息队列中1分钟,
//此消息包含handler引用,而handler由匿名内部类创建,持有activity引用,
//activity便不能正常销毁,从而泄露
handler.postDelayed(new Runnable() {
@Override
public void run() {
......
}
}, 1000 * 60);
}
}2)如何避免handler的内存泄露?
public class MainActivity extends AppCompatActivity {
//创建静态内部类
private static class MyHandler extends Handler{
//持有弱引用MainActivity,GC回收时会被回收掉.
private final WeakReference<MainActivity> mAct;
public MyHandler(MainActivity mainActivity){
mAct =new WeakReference<MainActivity>(mainActivity);
}
@Override
public void handleMessage(Message msg) {
MainActivity mainAct=mAct.get();
super.handleMessage(msg);
if(mainAct!=null){
//执行业务逻辑
}
}
}
private static final Runnable myRunnable = new Runnable() {
@Override
public void run() {
//执行我们的业务逻辑
}
};
@Override
protected void onCreate(Bundle savedInstanceState) {
super.onCreate(savedInstanceState);
setContentView(R.layout.activity_main);
MyHandler myHandler=new MyHandler(this);
//延迟5分钟后发送
myHandler.postDelayed(myRunnable, 1000 * 60 * 5);
}
}3) 雷区
a)Handler.post(Runnable)其实就是生成一个what为0的Message,调用
myHandler.removeMessages(0);会使runnable任务从消息队列中清除。
详细解释:https://www.cnblogs.com/coding-way/p/5110125.html(转)
b) 子线程直接创建Handler,抛异常Can't create handler inside thread that has not called Looper.prepare()
原因是非主线程没有loop对象,所以要调用Looper.prepare()方法,而且如果主线程给子线程发送消息,还要调用一个Looper.loop()的方法(此方法保证消息队列中的消息被不停的拿出,并被处理)
class MyThread extends Thread{
@Override
public void run() {
super.run();
Looper.prepare();
Handler handler = new Handler() {
@Override
public void handleMessage(Message msg) {
super.handleMessage(msg);
//处理消息
}
};
Looper.loop();
}
}
c)activity如被finish,但是handler刚好还在处理消息,如果需要用的资源已被释放,则会出现空指针异常。
所以在ondestory中去remove掉我们要处理的事件,还是有必要的。不想处理就直接try catch或者判空。
d)有时候你会发现removeCallbacks会失效,不能从消息队列中移除。
出现这情况是activity切入后台,再回到前台,此时的runnable由于被重定义,就会和原先的runnable并非同一个对象。所以这么做,加上static即可
static Handler handler = new Handler();
static Runnable myRunnable = new Runnable() {
@Override
public void run() {
//执行我们的业务逻辑
}
};这样,因为静态变量在内存中只有一个拷贝,保证runnable始终是同一个对象。
4.handlerThread
1) handlerThread是什么?
(题外话:异步存在形式有thread,handlerThead,asyncTask,线程池,intentService)
handlerThread继承thread,不过内部比普通线程多了一个Looper
//内部Looper.prepare()
@Override
public void run() {
mTid = Process.myTid();
Looper.prepare();
synchronized (this) {
mLooper = Looper.myLooper();
notifyAll();
}
Process.setThreadPriority(mPriority);
onLooperPrepared();
Looper.loop();
mTid = -1;
}2)HandlerThread使用及销毁
public class MainActivity extends AppCompatActivity {
private HandlerThread thread;
static Handler mHandler;
@Override
protected void onCreate(Bundle savedInstanceState) {
super.onCreate(savedInstanceState);
setContentView(R.layout.activity_main);
//创建一个HandlerThread并启动它
thread = new HandlerThread("MyHandlerThread");
thread.start();
//使用HandlerThread的looper对象创建Handler
mHandler = new Handler(thread.getLooper(), new Handler.Callback() {
@Override
public boolean handleMessage(Message msg) {
//这个方法是运行在 handler-thread 线程中的,可以执行耗时操作,因此不能更新ui,要注意
if (msg.what == 0x1) {
try {
Thread.sleep(3000);
Log.e("测试: ", "执行了3s的耗时操作");
} catch (InterruptedException e) {
e.printStackTrace();
}
//这个方法是运行在 handler-thread 线程中的,可以执行耗时操作,因此不能更新ui,要注意
// ((Button) MainActivity.this.findViewById(R.id.button)).setText("hello");
}
return false;
}
});
//停止handlerthread接收事件
findViewById(R.id.button).setOnClickListener(new View.OnClickListener() {
@Override
public void onClick(View v) {
thread.quit();
}
});
//运行
mHandler.sendEmptyMessage(0x1);
}
}上面demo中,只要调用了
mHandler.sendEmptyMessage(0x1);就会开始执行任务
几个地方要注意:
a.handleMessage()可以做耗时操作,但是不能更新ui
b.如果不手动的调用HandlerThread.quit()或者HandlerThread..quitSafely()方法,HandlerThread会将持续的接收新的任务事件。
c.只有handleMessage()方法执行完,这轮的任务才算完成,HandlerThread才会去执行下一个任务。而且在此次执行时,即使手动的去调用quit()方法,HandlerThread的此次任务也不会停止。但是,会停止下轮任务的接收。
举例:
//耗时任务换成这个,点击按钮执行quit()方法,发现此次任务依旧执行
for (int i = 0; i < 99999999; i++) {
Log.e("测试: ", "输出" +i);
}d.HandlerThread的2种停止接收事件的方法。
第一个就是quit(),实际上执行了MessageQueue中的removeAllMessagesLocked方法,该方法的作用是把MessageQueue消息池中所有的消息全部清空,无论是延迟消息(带Delayed的)还是非延迟消息。
第二个就是quitSafely(),执行了MessageQueue中的removeAllFutureMessagesLocked方法,该方法只会清空MessageQueue消息池中所有的延迟消息,并将消息池中所有的非延迟消息派发出去让Handler去处理,quitSafely相比于quit方法安全之处在于清空消息之前会派发所有的非延迟消息。
MessageQueue中源码:
void quit(boolean safe) {
if (!mQuitAllowed) {
throw new IllegalStateException("Main thread not allowed to quit.");
}
synchronized (this) {
if (mQuitting) {
return;
}
mQuitting = true;
if (safe) {
removeAllFutureMessagesLocked();
} else {
removeAllMessagesLocked();
}
// We can assume mPtr != 0 because mQuitting was previously false.
nativeWake(mPtr);
}
}举例:
//quit方法后,即使发送新事件,也不会被接收
findViewById(R.id.button).setOnClickListener(new View.OnClickListener() {
@Override
public void onClick(View v) {
thread.quit();
//发送新事件
mHandler.sendEmptyMessage(0x1);
}
);e.即使多次执行mHandler.sendEmptyMessage(0x1),任务队列中的任务依然只能一个一个的被处理。上一任务结束,开始执行下一个。
日志显示:输出0-99的任务结束,才执行下个输出0-99的任务
08-09 20:17:05.552 12618-12762/com.bihucj.mcandroid E/测试:: 输出95
08-09 20:17:05.552 12618-12762/com.bihucj.mcandroid E/测试:: 输出96
08-09 20:17:05.552 12618-12762/com.bihucj.mcandroid E/测试:: 输出97
08-09 20:17:05.552 12618-12762/com.bihucj.mcandroid E/测试:: 输出98
08-09 20:17:05.552 12618-12762/com.bihucj.mcandroid E/测试:: 输出99
08-09 20:17:05.718 12618-12762/com.bihucj.mcandroid E/测试:: 输出0
08-09 20:17:05.718 12618-12762/com.bihucj.mcandroid E/测试:: 输出1
08-09 20:17:05.719 12618-12762/com.bihucj.mcandroid E/测试:: 输出2
08-09 20:17:05.719 12618-12762/com.bihucj.mcandroid E/测试:: 输出3
08-09 20:17:05.719 12618-12762/com.bihucj.mcandroid E/测试:: 输出4
08-09 20:17:05.719 12618-12762/com.bihucj.mcandroid E/测试:: 输出55.源码解析
说到源码,主要还是几个关键词。分别为Message,Looper,MessageQueue,Handler。还有Thread
先说Looper,MessageQueue,Handler3者关联的思路:
主线程-->prepareMainLooper()(内部调用prepare() ,去实例化Looper,Looper实例化同时创建了messagequeue,11对应关系)-->主线程中的handler获取当前线程的Looper-->3者关联
插播主线程ActivityThread:
public static void main(String[] args) {
......
Looper.prepareMainLooper();
......
//区别:子线程是创建handler;
//主线程是通过getHandler()获取内部类实例
if(sMainThreadHandler==null){
sMainThreadHandler=thread.getHandler();
}
......
}
private class H extends Handler{
......
}子线程-->直接通过Looper.prepare()去实例化Looper,Looper实例化同时创建了messagequeue(11对应关系) -->实例化Handler同时获取当前子线程的Looper-->3者关联
1)Message消息
public final class Message implements Parcelable {
//用户定义的消息代码,以便接收者能够识别
public int what;
//arg1和arg2是使用成本较低的替代品-也可以用来存储int值
public int arg1;
public int arg2;
//存放任意类型的对象
public Object obj;
//消息触发时间
long when;
//消息携带内容
Bundle data;
//消息响应方
Handler target;
//消息管理器,会关联到一个handler
public Messanger replyTo;
//回调方法
Runnable callback;
//消息存储的链表。这样sPool就成为了一个Messages的缓存链表。
Message next;
//消息池
private static Message sPool;
//消息池的默认大小
private static final int MAX_POOL_SIZE = 50;
//从消息池中获取消息
public static Message obtain() {
synchronized (sPoolSync) {
if (sPool != null) {
Message m = sPool; //从sPool的表头拿出Message
sPool = m.next; //将消息池的表头指向下一个Message
m.next = null; //将取出消息的链表断开
m.flags = 0; // 清除flag----flag标记判断此消息是否正被使用(下方isInUse方法)
sPoolSize--; //消息池可用大小进行减1
return m;
}
}
return new Message(); //消息池为空-直接创建Message
}
//通过标记判断消息是否正被使用
boolean isInUse() {
return ((flags & FLAG_IN_USE) == FLAG_IN_USE);
}
//5.0后为true,之前为false.
private static boolean gCheckRecycle = true;
public void recycle() {
if (isInUse()) {
if (gCheckRecycle) {
throw new IllegalStateException("This message cannot be recycled because it is still in use.");
}
return;
}
recycleUnchecked(); //消息没在使用,回收
}
//对于不再使用的消息,加入到消息池
void recycleUnchecked() {
//将消息标示位置为IN_USE,并清空消息所有的参数。
flags = FLAG_IN_USE;
what = 0;
arg1 = 0;
arg2 = 0;
obj = null;
replyTo = null;
sendingUid = -1;
when = 0;
target = null;
callback = null;
data = null;
synchronized (sPoolSync) {
if (sPoolSize < MAX_POOL_SIZE) {
next = sPool;
sPool = this; //当消息池没有满时,将Message加入消息池
sPoolSize++; //消息池可用大小加1
}
}
}2)Looper
https://blog.csdn.net/woshiluoye9/article/details/72544764 (转)
插播ThreadLocal:
ThreadLocal是线程的局部变量, 是每一个线程所单独持有的,其他线程不能对其进行访问。主线程和子线程中的Looper的初始化
public final class Looper {
//内部消息队列MessageQueue
final MessageQueue mQueue;
//Looper所在的线程
final Thread mThread;
//Looper的变量存储
static final ThreadLocal<Looper> sThreadLocal = new ThreadLocal<Looper>();
//主looper
private static Looper sMainLooper;
//私有构造方法,不能通过New实例化。
private Looper(boolean quitAllowed) {
mQueue = new MessageQueue(quitAllowed);//创建与其绑定的消息队列MessageQueue
mThread = Thread.currentThread(); //绑定当前线程
}
//子线程的调用----->最终通过prepare(boolean)实例化Looper
public static void prepare() {
prepare(true);
}
//主线程的调用----->最终通过prepare(boolean)实例化Looper
public static void prepareMainLooper() {
prepare(false);
synchronized (Looper.class) {
if (sMainLooper != null) {
throw new IllegalStateException("The main Looper has already been prepared.");
}
sMainLooper = myLooper();//存储区中looper作为主looper
}
}
public static @Nullable Looper myLooper() {
return sThreadLocal.get();
}
//quitAllowed代表是否允许退出,主线程调用为不允许退出,子线程为可退出
private static void prepare(boolean quitAllowed) {
if (sThreadLocal.get() != null) {
//看出一个线程只能存在一个Looper-->则调用二次Looper.prepare抛出异常
throw new RuntimeException("Only one Looper may be created per thread");
}
sThreadLocal.set(new Looper(quitAllowed));//Looper的变量存储+实例化Looper
}
Loop()方法,循环取出messagequeue消息队列中的消息,并分发出去。再把分发后的Message回收到消息池,以便重复利用。
public static void loop() {
final Looper me = myLooper(); //从存储区拿出looper
if (me == null) {
throw new RuntimeException("No Looper; Looper.prepare() wasn't called on this thread.");
}
final MessageQueue queue = me.mQueue; //获取Looper对象中的消息队列
......
//进入loop的主循环方法
for (;;) {
Message msg = queue.next(); //可能会阻塞
if (msg == null) { //没有消息,则退出循环
return;
}
......
//target是handler,此处用于分发Message
msg.target.dispatchMessage(msg);
......
msg.recycleUnchecked(); //将Message放入消息池
}
}Looper中的quit方法-->调用的还是messageQueue中的quit()
public void quit() {
mQueue.quit(false);
}3) MessageQueue消息队列
a)主要参数和构造方法
public final class MessageQueue {
//供native代码使用
@SuppressWarnings("unused")
private long mPtr;
//交给native层来处理的核心方法
private native static long nativeInit();
private native static void nativeDestroy(long ptr);
private native void nativePollOnce(long ptr, int timeoutMillis); //阻塞操作
private native static void nativeWake(long ptr);
private native static boolean nativeIsPolling(long ptr);
private native static void nativeSetFileDescriptorEvents(long ptr, int fd, int events);
Message mMessages;
//消息队列是否可以退出
private final boolean mQuitAllowed;
//构造方法
MessageQueue(boolean quitAllowed) {
mQuitAllowed = quitAllowed;
mPtr = nativeInit(); //通过native方法初始化消息队列,其中mPtr是供native代码使用
}b)核心的next()方法
//不停提取下一条message
Message next() {
final long ptr = mPtr;
//判断是否退出消息循环
if (ptr == 0) {
return null;
}
int pendingIdleHandlerCount = -1;
//代表下一个消息到来前,还需要等待的时长
int nextPollTimeoutMillis = 0;
for (;;) {
if (nextPollTimeoutMillis != 0) {
Binder.flushPendingCommands();
}
//native层阻塞cpu。如果被阻塞,唤醒事件队列
nativePollOnce(ptr, nextPollTimeoutMillis);
synchronized (this) {
final long now = SystemClock.uptimeMillis();
Message prevMsg = null;
Message msg = mMessages;
//如果当前消息是异步消息,都将赋值给prevMsg,过滤掉,直到取到了非异步消息
if (msg != null && msg.target == null) {
do {
prevMsg = msg;
msg = msg.next;
} while (msg != null && !msg.isAsynchronous());
}
//获取到了非异步消息
if (msg != null) {
//任务执行时间大于现在的时间
if (now < msg.when) {
//设置下一次轮询的超时时长
nextPollTimeoutMillis = (int) Math.min(msg.when - now, Integer.MAX_VALUE);
} else {
mBlocked = false;//指定为非阻塞任务
if (prevMsg != null) {
prevMsg.next = msg.next;
} else {
mMessages = msg.next;
}
msg.next = null;
//设置消息的使用状态,即flags |= FLAG_IN_USE
msg.markInUse();
return msg; //成功地获取MessageQueue中的下一条即将要执行的消息
}
} else {
//表示消息队列中无消息,会一直等待下去
nextPollTimeoutMillis = -1;
}
......
//IdleHandler为发现线程何时阻塞的回调接口
for (int i = 0; i < pendingIdleHandlerCount; i++) {
final IdleHandler idler = mPendingIdleHandlers[i];
mPendingIdleHandlers[i] = null; //去除handler引用
boolean keep = false;
//queueIdle返回true会被空闲的处理器处理,false就会被移走
try {
keep = idler.queueIdle(); //idle时执行的方法
} catch (Throwable t) {
Log.wtf(TAG, "IdleHandler threw exception", t);
}
if (!keep) {
synchronized (this) {
mIdleHandlers.remove(idler); //被移走
}
}
}
//重置idle handler个数为0,保证不会再次重复运行
pendingIdleHandlerCount = 0;
nextPollTimeoutMillis = 0;
}
}next()方法中,做了异步Message消息的判断,特殊的是这个Message没有设置target,即msg.target为null。
c)核心的enqueueMessage()方法
boolean enqueueMessage(Message msg, long when) {
// 每一个普通Message必须有一个target-handler
if (msg.target == null) {
throw new IllegalArgumentException("Message must have a target.");
}
//已在使用状态
if (msg.isInUse()) {
throw new IllegalStateException(msg + " This message is already in use.");
}
synchronized (this) {
//消息在退出状态->被回收到消息池
if (mQuitting) {
msg.recycle();
return false;
}
//标记使用状态,记录执行时间
msg.markInUse();
msg.when = when;
Message p = mMessages;
boolean needWake;
//p为null代表MessageQueue没有消息或者msg的触发时间是队列中最早的
if (p == null || when == 0 || when < p.when) {
msg.next = p;
mMessages = msg;
needWake = mBlocked; //当阻塞时需要唤醒
} else {
//将消息按时间顺序插入到MessageQueue。
needWake = mBlocked && p.target == null && msg.isAsynchronous();
Message prev;
for (;;) {
prev = p;
p = p.next;
if (p == null || when < p.when) {
break;
}
if (needWake && p.isAsynchronous()) {
needWake = false;
}
}
msg.next = p;
prev.next = msg;
}
if (needWake) {
nativeWake(mPtr);
}
}
return true;
}队列中的Message触发时间是有先后顺序的。当消息加入消息队列时,会从队列头开始遍历,直到找到消息应该插入的合适位置,以保证所有消息的时间顺序(内部遍历队列中Message,找到when比当前Message的when大的Message,将Message插入到该Message之前,如果没找到则将Message插入到队列最后)。一般是当前队列为空的情况下,next那边会进入睡眠,需要的时候MessageQueue这边会唤醒next方法。
d)removeMessages()和removeCallbacksAndMessages()方法
void removeMessages(Handler h, int what, Object object) {
if (h == null) {
return;
}
synchronized (this) {
Message p = mMessages;
//从消息队列的头部开始,移除所有符合条件的消息
while (p != null && p.target == h && p.what == what
&& (object == null || p.obj == object)) {
Message n = p.next;
mMessages = n;
p.recycleUnchecked();
p = n;
}
//移除剩余的符合要求的消息
while (p != null) {
Message n = p.next;
if (n != null) {
if (n.target == h && n.what == what
&& (object == null || n.obj == object)) {
Message nn = n.next;
n.recycleUnchecked();
p.next = nn;
continue;
}
}
p = n;
}
}
}
void removeCallbacksAndMessages(Handler h, Object object) {
if (h == null) {
return;
}
synchronized (this) {
Message p = mMessages;
while (p != null && p.target == h
&& (object == null || p.obj == object)) {
Message n = p.next;
mMessages = n;
p.recycleUnchecked();
p = n;
}
while (p != null) {
Message n = p.next;
if (n != null) {
if (n.target == h && (object == null || n.obj == object)) {
Message nn = n.next;
n.recycleUnchecked();
p.next = nn;
continue;
}
}
p = n;
}
}
}4)Handler
a)主要参数和构造方法
public class Handler {
final Looper mLooper;
final MessageQueue mQueue;
final Callback mCallback; //回调
final boolean mAsynchronous; //是否异步消息
IMessenger mMessenger;
public interface Callback {
//如果不需要进一步的处理,则返回True
public boolean handleMessage(Message msg);
}
//有参构造
public Handler(Looper looper) {
this(looper, null, false);
}
//有参构造
public Handler(Looper looper, Callback callback, boolean async) {
mLooper = looper;
mQueue = looper.mQueue;
mCallback = callback;
mAsynchronous = async;
}
public Handler(Callback callback, boolean async) {
//匿名类、内部类或本地类都必须申明为static,否则会警告可能出现内存泄露
if (FIND_POTENTIAL_LEAKS) {
final Class<? extends Handler> klass = getClass();
if ((klass.isAnonymousClass() || klass.isMemberClass() || klass.isLocalClass()) &&
(klass.getModifiers() & Modifier.STATIC) == 0) {
Log.w(TAG, "The following Handler class should be static or leaks might occur: " +
klass.getCanonicalName());
}
}
//从Looper类中的(ThreadLocal)获取Looper对象
mLooper = Looper.myLooper();
if (mLooper == null) {
throw new RuntimeException("");
}
mQueue = mLooper.mQueue; //Looper取出消息队列
mCallback = callback; //回调
mAsynchronous = async; //设置消息是否为异步处理方式
} b)消息的发送:
1.post--->调用sendMessageDelayed
public final boolean post(Runnable r){
return sendMessageDelayed(getPostMessage(r), 0);
}
2.postAtTime--->调用sendMessageAtTime
public final boolean postAtTime(Runnable r, long uptimeMillis){
return sendMessageAtTime(getPostMessage(r), uptimeMillis);
}
3.postAtTime--->调用sendMessageAtTime
public final boolean postAtTime(Runnable r, Object token, long uptimeMillis){
return sendMessageAtTime(getPostMessage(r, token), uptimeMillis);
}
4.postDelayed--->调用sendMessageDelayed
public final boolean postDelayed(Runnable r, long delayMillis){
return sendMessageDelayed(getPostMessage(r), delayMillis);
}
5.postAtFrontOfQueue--->调用sendMessageAtFrontOfQueue
public final boolean postAtFrontOfQueue(Runnable r){
return sendMessageAtFrontOfQueue(getPostMessage(r));
}
6.sendMessage--->调用sendMessageDelayed
public final boolean sendMessage(Message msg){
return sendMessageDelayed(msg, 0);
}
7.sendEmptyMessage--->调用sendEmptyMessageDelayed
public final boolean sendEmptyMessage(int what){
return sendEmptyMessageDelayed(what, 0);
}
8.sendEmptyMessageDelayed--->调用sendMessageDelayed
public final boolean sendEmptyMessageDelayed(int what, long delayMillis) {
Message msg = Message.obtain();
msg.what = what;
return sendMessageDelayed(msg, delayMillis);
}
9.sendEmptyMessageAtTime--->调用sendMessageAtTime
public final boolean sendEmptyMessageAtTime(int what, long uptimeMillis) {
Message msg = Message.obtain();
msg.what = what;
return sendMessageAtTime(msg, uptimeMillis);
}
10.sendMessageDelayed--->调用sendMessageAtTime
public final boolean sendMessageDelayed(Message msg, long delayMillis){
if (delayMillis < 0) {
delayMillis = 0;
}
return sendMessageAtTime(msg, SystemClock.uptimeMillis() + delayMillis);
}
11.sendMessageAtTime--->调用enqueueMessage
public boolean sendMessageAtTime(Message msg, long uptimeMillis) {
MessageQueue queue = mQueue;
if (queue == null) {
RuntimeException e = new RuntimeException(
this + " sendMessageAtTime() called with no mQueue");
Log.w("Looper", e.getMessage(), e);
return false;
}
return enqueueMessage(queue, msg, uptimeMillis);
}
12.sendMessageAtFrontOfQueue--->调用enqueueMessage
//FIXME 该方法通过设置消息的触发时间为0,从而使Message加入到消息队列的队头
public final boolean sendMessageAtFrontOfQueue(Message msg) {
MessageQueue queue = mQueue;
if (queue == null) {
RuntimeException e = new RuntimeException(
this + " sendMessageAtTime() called with no mQueue");
Log.w("Looper", e.getMessage(), e);
return false;
}
return enqueueMessage(queue, msg, 0);
}
13.enqueueMessage调用MessageQueue中的enqueueMessage
private boolean enqueueMessage(MessageQueue queue, Message msg, long uptimeMillis) {
msg.target = this;
if (mAsynchronous) {
msg.setAsynchronous(true);
}
//uptimeMillis为系统当前的运行时间
return queue.enqueueMessage(msg, uptimeMillis);
}if (mAsynchronous) {
msg.setAsynchronous(true);
}可以看到enqueueMessage方法时,每次都判断是否是异步消息。这就和MessageQueue中的Next()判断联系到了一起。
c)消息的移除--都会调用消息队列中的移除方法
public final void removeCallbacks(Runnable r){
mQueue.removeMessages(this, r, null);
}
public final void removeCallbacks(Runnable r, Object token){
mQueue.removeMessages(this, r, token);
}
public final void removeMessages(int what) {
mQueue.removeMessages(this, what, null);
}
public final void removeMessages(int what, Object object) {
mQueue.removeMessages(this, what, object);
}
public final void removeCallbacksAndMessages(Object token) {
mQueue.removeCallbacksAndMessages(this, token);
}d)handleMessage(处理消息)和 dispatchMessage(分发消息)
//处理消息
public void handleMessage(Message msg) {
}
//分发消息
public void dispatchMessage(Message msg) {
if (msg.callback != null) {
//当Message存在回调方法,回调方法msg.callback.run()
handleCallback(msg);
} else {
//当Handler存在Callback成员变量时,回调方法mCallback.handleMessage();
if (mCallback != null) {
if (mCallback.handleMessage(msg)) {
return;
}
}
//Handler子类通过覆写该方法来完成具体的逻辑
handleMessage(msg);
}
}优先级:
Message的回调方法>Handler的回调方法>Handler的默认方法
6.总结
- Handler通过sendMessage()方法发送Message到MessageQueue队列
- 当前Thread中Looper通过调用loop(),不断取出达到触发条件的Message,通过对应target(Handler)的dispatchMessage()方法,将Message交给Handler的handleMessage()方法来处理。
- 一个线程对应一个Looper,一个Looper对应一个MessageQueue,一个MessageQueue可以对用多个Message。但是一个Message只能让一个handler来处理(就是Message中target所指定的handler)。
参考:
handler发送异步消息:https://blog.csdn.net/cdecde111/article/details/54670136
https://blog.csdn.net/woshiluoye9/article/details/72544764
http://gityuan.com/2015/12/26/handler-message-framework/
https://blog.csdn.net/iispring/article/details/47180325