更详细UML说明可参考http://blog.csdn.net/thl789/article/details/6601558
对于普通的线程而言,执行完 run()方法内的代码后线程就结束。而异步消息处理线程是指,线程启动后会进入一个无限循环体之中,每循环一次,从其内部的消息队列中取出一个消息,并回调相应的消息处理函数,执行完一个消息后则继续循环。如果消息队列为空,线程会暂停,直到消息队列中有新的消息。
异步消息处理线程的本质仍然是一个线程 ,只不过这种线程的执行代码被设置成如上所讲的逻辑而已,一般而言,当同时有以下两种需求时使用异步消息处理线程:
• 任务需要常驻。比如用于处理用户交互的任务。
• 任务需要根据外部传递的消息做不同的操作。
实现异步线程要解决的问题具体包括:
• 每个异步线程内部包含一个消息队列 (MessageQueue) ,队列中的消息一般采用排队机制,即先 到达的消息会先得到处理。
• 线程的执行体中使用while (true)进行无限循环,循环体中从消息队列中取出消息,并根据消 息的来源,回调相应的消息处理函数。
• 其他外部线程可以向本线程的消息队列中发送消息,消息队列内部的读/写操作必须进行加锁, 即消息队列不能同时进行读/写操作。
package android.os; import android.util.Log; import android.util.Printer; import android.util.PrefixPrinter; /** * Class used to run a message loop for a thread. Threads by default do * not have a message loop associated with them; to create one, call * {@link #prepare} in the thread that is to run the loop, and then * {@link #loop} to have it process messages until the loop is stopped. * * <p>Most interaction with a message loop is through the * {@link Handler} class. * * <p>This is a typical example of the implementation of a Looper thread, * using the separation of {@link #prepare} and {@link #loop} to create an * initial Handler to communicate with the Looper. * * <pre> * class LooperThread extends Thread { * public Handler mHandler; * * public void run() { * Looper.prepare(); * * mHandler = new Handler() { * public void handleMessage(Message msg) { * // process incoming messages here * } * }; * * Looper.loop(); * } * }</pre> */ public class Looper { private static final String TAG = "Looper"; // sThreadLocal.get() will return null unless you've called prepare(). static final ThreadLocal<Looper> sThreadLocal = new ThreadLocal<Looper>(); private static Looper sMainLooper; // guarded by Looper.class final MessageQueue mQueue; final Thread mThread; volatile boolean mRun; private Printer mLogging; /** Initialize the current thread as a looper. * This gives you a chance to create handlers that then reference * this looper, before actually starting the loop. Be sure to call * {@link #loop()} after calling this method, and end it by calling * {@link #quit()}. */ public static void prepare() { prepare(true); } private static void prepare(boolean quitAllowed) { if (sThreadLocal.get() != null) { throw new RuntimeException("Only one Looper may be created per thread"); } sThreadLocal.set(new Looper(quitAllowed)); } /** * Initialize the current thread as a looper, marking it as an * application's main looper. The main looper for your application * is created by the Android environment, so you should never need * to call this function yourself. See also: {@link #prepare()} */ public static void prepareMainLooper() { prepare(false); synchronized (Looper.class) { if (sMainLooper != null) { throw new IllegalStateException("The main Looper has already been prepared."); } sMainLooper = myLooper(); } } /** Returns the application's main looper, which lives in the main thread of the application. */ public static Looper getMainLooper() { synchronized (Looper.class) { return sMainLooper; } } /** * Run the message queue in this thread. Be sure to call * {@link #quit()} to end the loop. */ public static void loop() { final Looper me = myLooper(); if (me == null) { throw new RuntimeException("No Looper; Looper.prepare() wasn't called on this thread."); } final MessageQueue queue = me.mQueue; // Make sure the identity of this thread is that of the local process, // and keep track of what that identity token actually is. Binder.clearCallingIdentity(); final long ident = Binder.clearCallingIdentity(); for (;;) { Message msg = queue.next(); // might block if (msg == null) { // No message indicates that the message queue is quitting. return; } // This must be in a local variable, in case a UI event sets the logger Printer logging = me.mLogging; if (logging != null) { logging.println(">>>>> Dispatching to " + msg.target + " " + msg.callback + ": " + msg.what); } msg.target.dispatchMessage(msg); if (logging != null) { logging.println("<<<<< Finished to " + msg.target + " " + msg.callback); } // Make sure that during the course of dispatching the // identity of the thread wasn't corrupted. final long newIdent = Binder.clearCallingIdentity(); if (ident != newIdent) { Log.wtf(TAG, "Thread identity changed from 0x" + Long.toHexString(ident) + " to 0x" + Long.toHexString(newIdent) + " while dispatching to " + msg.target.getClass().getName() + " " + msg.callback + " what=" + msg.what); } msg.recycle(); } } /** * Return the Looper object associated with the current thread. Returns * null if the calling thread is not associated with a Looper. */ public static Looper myLooper() { return sThreadLocal.get(); } /** * Control logging of messages as they are processed by this Looper. If * enabled, a log message will be written to <var>printer</var> * at the beginning and ending of each message dispatch, identifying the * target Handler and message contents. * * @param printer A Printer object that will receive log messages, or * null to disable message logging. */ public void setMessageLogging(Printer printer) { mLogging = printer; } /** * Return the {@link MessageQueue} object associated with the current * thread. This must be called from a thread running a Looper, or a * NullPointerException will be thrown. */ public static MessageQueue myQueue() { return myLooper().mQueue; } private Looper(boolean quitAllowed) { mQueue = new MessageQueue(quitAllowed); mRun = true; mThread = Thread.currentThread(); } /** * Quits the looper. * * Causes the {@link #loop} method to terminate as soon as possible. */ public void quit() { mQueue.quit(); } /** * Posts a synchronization barrier to the Looper's message queue. * * Message processing occurs as usual until the message queue encounters the * synchronization barrier that has been posted. When the barrier is encountered, * later synchronous messages in the queue are stalled (prevented from being executed) * until the barrier is released by calling {@link #removeSyncBarrier} and specifying * the token that identifies the synchronization barrier. * * This method is used to immediately postpone execution of all subsequently posted * synchronous messages until a condition is met that releases the barrier. * Asynchronous messages (see {@link Message#isAsynchronous} are exempt from the barrier * and continue to be processed as usual. * * This call must be always matched by a call to {@link #removeSyncBarrier} with * the same token to ensure that the message queue resumes normal operation. * Otherwise the application will probably hang! * * @return A token that uniquely identifies the barrier. This token must be * passed to {@link #removeSyncBarrier} to release the barrier. * * @hide */ public final int postSyncBarrier() { return mQueue.enqueueSyncBarrier(SystemClock.uptimeMillis()); } /** * Removes a synchronization barrier. * * @param token The synchronization barrier token that was returned by * {@link #postSyncBarrier}. * * @throws IllegalStateException if the barrier was not found. * * @hide */ public final void removeSyncBarrier(int token) { mQueue.removeSyncBarrier(token); } /** * Return the Thread associated with this Looper. */ public Thread getThread() { return mThread; } /** @hide */ public MessageQueue getQueue() { return mQueue; } public void dump(Printer pw, String prefix) { pw = PrefixPrinter.create(pw, prefix); pw.println(this.toString()); pw.println("mRun=" + mRun); pw.println("mThread=" + mThread); pw.println("mQueue=" + ((mQueue != null) ? mQueue : "(null")); if (mQueue != null) { synchronized (mQueue) { long now = SystemClock.uptimeMillis(); Message msg = mQueue.mMessages; int n = 0; while (msg != null) { pw.println(" Message " + n + ": " + msg.toString(now)); n++; msg = msg.next; } pw.println("(Total messages: " + n + ")"); } } } public String toString() { return "Looper{" + Integer.toHexString(System.identityHashCode(this)) + "}"; } }
public class Handler { /* * Set this flag to true to detect anonymous, local or member classes * that extend this Handler class and that are not static. These kind * of classes can potentially create leaks. */ private static final boolean FIND_POTENTIAL_LEAKS = false; private static final String TAG = "Handler"; /** * Callback interface you can use when instantiating a Handler to avoid * having to implement your own subclass of Handler. */ public interface Callback { public boolean handleMessage(Message msg); } /** * Subclasses must implement this to receive messages. */ public void handleMessage(Message msg) { } /** * Handle system messages here. */ public void dispatchMessage(Message msg) { if (msg.callback != null) { handleCallback(msg); } else { if (mCallback != null) { if (mCallback.handleMessage(msg)) { return; } } handleMessage(msg); } } /** * Default constructor associates this handler with the {@link Looper} for the * current thread. * * If this thread does not have a looper, this handler won't be able to receive messages * so an exception is thrown. */ public Handler() { this(null, false); } /** * Constructor associates this handler with the {@link Looper} for the * current thread and takes a callback interface in which you can handle * messages. * * If this thread does not have a looper, this handler won't be able to receive messages * so an exception is thrown. * * @param callback The callback interface in which to handle messages, or null. */ public Handler(Callback callback) { this(callback, false); } /** * Use the provided {@link Looper} instead of the default one. * * @param looper The looper, must not be null. */ public Handler(Looper looper) { this(looper, null, false); } /** * Use the provided {@link Looper} instead of the default one and take a callback * interface in which to handle messages. * * @param looper The looper, must not be null. * @param callback The callback interface in which to handle messages, or null. */ public Handler(Looper looper, Callback callback) { this(looper, callback, false); } /** * Use the {@link Looper} for the current thread * and set whether the handler should be asynchronous. * * Handlers are synchronous by default unless this constructor is used to make * one that is strictly asynchronous. * * Asynchronous messages represent interrupts or events that do not require global ordering * with represent to synchronous messages. Asynchronous messages are not subject to * the synchronization barriers introduced by {@link MessageQueue#enqueueSyncBarrier(long)}. * * @param async If true, the handler calls {@link Message#setAsynchronous(boolean)} for * each {@link Message} that is sent to it or {@link Runnable} that is posted to it. * * @hide */ public Handler(boolean async) { this(null, async); } /** * Use the {@link Looper} for the current thread with the specified callback interface * and set whether the handler should be asynchronous. * * Handlers are synchronous by default unless this constructor is used to make * one that is strictly asynchronous. * * Asynchronous messages represent interrupts or events that do not require global ordering * with represent to synchronous messages. Asynchronous messages are not subject to * the synchronization barriers introduced by {@link MessageQueue#enqueueSyncBarrier(long)}. * * @param callback The callback interface in which to handle messages, or null. * @param async If true, the handler calls {@link Message#setAsynchronous(boolean)} for * each {@link Message} that is sent to it or {@link Runnable} that is posted to it. * * @hide */ public Handler(Callback callback, boolean async) { 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()); } } mLooper = Looper.myLooper(); if (mLooper == null) { throw new RuntimeException( "Can't create handler inside thread that has not called Looper.prepare()"); } mQueue = mLooper.mQueue; mCallback = callback; mAsynchronous = async; } /** * Use the provided {@link Looper} instead of the default one and take a callback * interface in which to handle messages. Also set whether the handler * should be asynchronous. * * Handlers are synchronous by default unless this constructor is used to make * one that is strictly asynchronous. * * Asynchronous messages represent interrupts or events that do not require global ordering * with represent to synchronous messages. Asynchronous messages are not subject to * the synchronization barriers introduced by {@link MessageQueue#enqueueSyncBarrier(long)}. * * @param looper The looper, must not be null. * @param callback The callback interface in which to handle messages, or null. * @param async If true, the handler calls {@link Message#setAsynchronous(boolean)} for * each {@link Message} that is sent to it or {@link Runnable} that is posted to it. * * @hide */ public Handler(Looper looper, Callback callback, boolean async) { mLooper = looper; mQueue = looper.mQueue; mCallback = callback; mAsynchronous = async; } /** * Returns a string representing the name of the specified message. * The default implementation will either return the class name of the * message callback if any, or the hexadecimal representation of the * message "what" field. * * @param message The message whose name is being queried */ public String getMessageName(Message message) { if (message.callback != null) { return message.callback.getClass().getName(); } return "0x" + Integer.toHexString(message.what); } /** * Returns a new {@link android.os.Message Message} from the global message pool. More efficient than * creating and allocating new instances. The retrieved message has its handler set to this instance (Message.target == this). * If you don't want that facility, just call Message.obtain() instead. */ public final Message obtainMessage() { return Message.obtain(this); } /** * Same as {@link #obtainMessage()}, except that it also sets the what member of the returned Message. * * @param what Value to assign to the returned Message.what field. * @return A Message from the global message pool. */ public final Message obtainMessage(int what) { return Message.obtain(this, what); } /** * * Same as {@link #obtainMessage()}, except that it also sets the what and obj members * of the returned Message. * * @param what Value to assign to the returned Message.what field. * @param obj Value to assign to the returned Message.obj field. * @return A Message from the global message pool. */ public final Message obtainMessage(int what, Object obj) { return Message.obtain(this, what, obj); } /** * * Same as {@link #obtainMessage()}, except that it also sets the what, arg1 and arg2 members of the returned * Message. * @param what Value to assign to the returned Message.what field. * @param arg1 Value to assign to the returned Message.arg1 field. * @param arg2 Value to assign to the returned Message.arg2 field. * @return A Message from the global message pool. */ public final Message obtainMessage(int what, int arg1, int arg2) { return Message.obtain(this, what, arg1, arg2); } /** * * Same as {@link #obtainMessage()}, except that it also sets the what, obj, arg1,and arg2 values on the * returned Message. * @param what Value to assign to the returned Message.what field. * @param arg1 Value to assign to the returned Message.arg1 field. * @param arg2 Value to assign to the returned Message.arg2 field. * @param obj Value to assign to the returned Message.obj field. * @return A Message from the global message pool. */ public final Message obtainMessage(int what, int arg1, int arg2, Object obj) { return Message.obtain(this, what, arg1, arg2, obj); } /** * Causes the Runnable r to be added to the message queue. * The runnable will be run on the thread to which this handler is * attached. * * @param r The Runnable that will be executed. * * @return Returns true if the Runnable was successfully placed in to the * message queue. Returns false on failure, usually because the * looper processing the message queue is exiting. */ public final boolean post(Runnable r) { return sendMessageDelayed(getPostMessage(r), 0); } /** * Causes the Runnable r to be added to the message queue, to be run * at a specific time given by <var>uptimeMillis</var>. * <b>The time-base is {@link android.os.SystemClock#uptimeMillis}.</b> * The runnable will be run on the thread to which this handler is attached. * * @param r The Runnable that will be executed. * @param uptimeMillis The absolute time at which the callback should run, * using the {@link android.os.SystemClock#uptimeMillis} time-base. * * @return Returns true if the Runnable was successfully placed in to the * message queue. Returns false on failure, usually because the * looper processing the message queue is exiting. Note that a * result of true does not mean the Runnable will be processed -- if * the looper is quit before the delivery time of the message * occurs then the message will be dropped. */ public final boolean postAtTime(Runnable r, long uptimeMillis) { return sendMessageAtTime(getPostMessage(r), uptimeMillis); } /** * Causes the Runnable r to be added to the message queue, to be run * at a specific time given by <var>uptimeMillis</var>. * <b>The time-base is {@link android.os.SystemClock#uptimeMillis}.</b> * The runnable will be run on the thread to which this handler is attached. * * @param r The Runnable that will be executed. * @param uptimeMillis The absolute time at which the callback should run, * using the {@link android.os.SystemClock#uptimeMillis} time-base. * * @return Returns true if the Runnable was successfully placed in to the * message queue. Returns false on failure, usually because the * looper processing the message queue is exiting. Note that a * result of true does not mean the Runnable will be processed -- if * the looper is quit before the delivery time of the message * occurs then the message will be dropped. * * @see android.os.SystemClock#uptimeMillis */ public final boolean postAtTime(Runnable r, Object token, long uptimeMillis) { return sendMessageAtTime(getPostMessage(r, token), uptimeMillis); } /** * Causes the Runnable r to be added to the message queue, to be run * after the specified amount of time elapses. * The runnable will be run on the thread to which this handler * is attached. * * @param r The Runnable that will be executed. * @param delayMillis The delay (in milliseconds) until the Runnable * will be executed. * * @return Returns true if the Runnable was successfully placed in to the * message queue. Returns false on failure, usually because the * looper processing the message queue is exiting. Note that a * result of true does not mean the Runnable will be processed -- * if the looper is quit before the delivery time of the message * occurs then the message will be dropped. */ public final boolean postDelayed(Runnable r, long delayMillis) { return sendMessageDelayed(getPostMessage(r), delayMillis); } /** * Posts a message to an object that implements Runnable. * Causes the Runnable r to executed on the next iteration through the * message queue. The runnable will be run on the thread to which this * handler is attached. * <b>This method is only for use in very special circumstances -- it * can easily starve the message queue, cause ordering problems, or have * other unexpected side-effects.</b> * * @param r The Runnable that will be executed. * * @return Returns true if the message was successfully placed in to the * message queue. Returns false on failure, usually because the * looper processing the message queue is exiting. */ public final boolean postAtFrontOfQueue(Runnable r) { return sendMessageAtFrontOfQueue(getPostMessage(r)); } /** * Runs the specified task synchronously. * * If the current thread is the same as the handler thread, then the runnable * runs immediately without being enqueued. Otherwise, posts the runnable * to the handler and waits for it to complete before returning. * * This method is dangerous! Improper use can result in deadlocks. * Never call this method while any locks are held or use it in a * possibly re-entrant manner. * * This method is occasionally useful in situations where a background thread * must synchronously await completion of a task that must run on the * handler's thread. However, this problem is often a symptom of bad design. * Consider improving the design (if possible) before resorting to this method. * * One example of where you might want to use this method is when you just * set up a Handler thread and need to perform some initialization steps on * it before continuing execution. * * If timeout occurs then this method returns <code>false</code> but the runnable * will remain posted on the handler and may already be in progress or * complete at a later time. * * @param r The Runnable that will be executed synchronously. * @param timeout The timeout in milliseconds, or 0 to wait indefinitely. * * @return Returns true if the Runnable was successfully executed. * Returns false on failure, usually because the * looper processing the message queue is exiting. * * @hide This method is prone to abuse and should probably not be in the API. * If we ever do make it part of the API, we might want to rename it to something * less funny like runUnsafe(). */ public final boolean runWithScissors(final Runnable r, long timeout) { if (r == null) { throw new IllegalArgumentException("runnable must not be null"); } if (timeout < 0) { throw new IllegalArgumentException("timeout must be non-negative"); } if (Looper.myLooper() == mLooper) { r.run(); return true; } BlockingRunnable br = new BlockingRunnable(r); return br.postAndWait(this, timeout); } /** * Remove any pending posts of Runnable r that are in the message queue. */ public final void removeCallbacks(Runnable r) { mQueue.removeMessages(this, r, null); } /** * Remove any pending posts of Runnable <var>r</var> with Object * <var>token</var> that are in the message queue. If <var>token</var> is null, * all callbacks will be removed. */ public final void removeCallbacks(Runnable r, Object token) { mQueue.removeMessages(this, r, token); } /** * Pushes a message onto the end of the message queue after all pending messages * before the current time. It will be received in {@link #handleMessage}, * in the thread attached to this handler. * * @return Returns true if the message was successfully placed in to the * message queue. Returns false on failure, usually because the * looper processing the message queue is exiting. */ public final boolean sendMessage(Message msg) { return sendMessageDelayed(msg, 0); } /** * Sends a Message containing only the what value. * * @return Returns true if the message was successfully placed in to the * message queue. Returns false on failure, usually because the * looper processing the message queue is exiting. */ public final boolean sendEmptyMessage(int what) { return sendEmptyMessageDelayed(what, 0); } /** * Sends a Message containing only the what value, to be delivered * after the specified amount of time elapses. * @see #sendMessageDelayed(android.os.Message, long) * * @return Returns true if the message was successfully placed in to the * message queue. Returns false on failure, usually because the * looper processing the message queue is exiting. */ public final boolean sendEmptyMessageDelayed(int what, long delayMillis) { Message msg = Message.obtain(); msg.what = what; return sendMessageDelayed(msg, delayMillis); } /** * Sends a Message containing only the what value, to be delivered * at a specific time. * @see #sendMessageAtTime(android.os.Message, long) * * @return Returns true if the message was successfully placed in to the * message queue. Returns false on failure, usually because the * looper processing the message queue is exiting. */ public final boolean sendEmptyMessageAtTime(int what, long uptimeMillis) { Message msg = Message.obtain(); msg.what = what; return sendMessageAtTime(msg, uptimeMillis); } /** * Enqueue a message into the message queue after all pending messages * before (current time + delayMillis). You will receive it in * {@link #handleMessage}, in the thread attached to this handler. * * @return Returns true if the message was successfully placed in to the * message queue. Returns false on failure, usually because the * looper processing the message queue is exiting. Note that a * result of true does not mean the message will be processed -- if * the looper is quit before the delivery time of the message * occurs then the message will be dropped. */ public final boolean sendMessageDelayed(Message msg, long delayMillis) { if (delayMillis < 0) { delayMillis = 0; } return sendMessageAtTime(msg, SystemClock.uptimeMillis() + delayMillis); } /** * Enqueue a message into the message queue after all pending messages * before the absolute time (in milliseconds) <var>uptimeMillis</var>. * <b>The time-base is {@link android.os.SystemClock#uptimeMillis}.</b> * You will receive it in {@link #handleMessage}, in the thread attached * to this handler. * * @param uptimeMillis The absolute time at which the message should be * delivered, using the * {@link android.os.SystemClock#uptimeMillis} time-base. * * @return Returns true if the message was successfully placed in to the * message queue. Returns false on failure, usually because the * looper processing the message queue is exiting. Note that a * result of true does not mean the message will be processed -- if * the looper is quit before the delivery time of the message * occurs then the message will be dropped. */ 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); } /** * Enqueue a message at the front of the message queue, to be processed on * the next iteration of the message loop. You will receive it in * {@link #handleMessage}, in the thread attached to this handler. * <b>This method is only for use in very special circumstances -- it * can easily starve the message queue, cause ordering problems, or have * other unexpected side-effects.</b> * * @return Returns true if the message was successfully placed in to the * message queue. Returns false on failure, usually because the * looper processing the message queue is exiting. */ 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); } private boolean enqueueMessage(MessageQueue queue, Message msg, long uptimeMillis) { msg.target = this; if (mAsynchronous) { msg.setAsynchronous(true); } return queue.enqueueMessage(msg, uptimeMillis); } /** * Remove any pending posts of messages with code 'what' that are in the * message queue. */ public final void removeMessages(int what) { mQueue.removeMessages(this, what, null); } /** * Remove any pending posts of messages with code 'what' and whose obj is * 'object' that are in the message queue. If <var>object</var> is null, * all messages will be removed. */ public final void removeMessages(int what, Object object) { mQueue.removeMessages(this, what, object); } /** * Remove any pending posts of callbacks and sent messages whose * <var>obj</var> is <var>token</var>. If <var>token</var> is null, * all callbacks and messages will be removed. */ public final void removeCallbacksAndMessages(Object token) { mQueue.removeCallbacksAndMessages(this, token); } /** * Check if there are any pending posts of messages with code 'what' in * the message queue. */ public final boolean hasMessages(int what) { return mQueue.hasMessages(this, what, null); } /** * Check if there are any pending posts of messages with code 'what' and * whose obj is 'object' in the message queue. */ public final boolean hasMessages(int what, Object object) { return mQueue.hasMessages(this, what, object); } /** * Check if there are any pending posts of messages with callback r in * the message queue. * * @hide */ public final boolean hasCallbacks(Runnable r) { return mQueue.hasMessages(this, r, null); } // if we can get rid of this method, the handler need not remember its loop // we could instead export a getMessageQueue() method... public final Looper getLooper() { return mLooper; } public final void dump(Printer pw, String prefix) { pw.println(prefix + this + " @ " + SystemClock.uptimeMillis()); if (mLooper == null) { pw.println(prefix + "looper uninitialized"); } else { mLooper.dump(pw, prefix + " "); } } @Override public String toString() { return "Handler (" + getClass().getName() + ") {" + Integer.toHexString(System.identityHashCode(this)) + "}"; } final IMessenger getIMessenger() { synchronized (mQueue) { if (mMessenger != null) { return mMessenger; } mMessenger = new MessengerImpl(); return mMessenger; } } private final class MessengerImpl extends IMessenger.Stub { public void send(Message msg) { Handler.this.sendMessage(msg); } } private static Message getPostMessage(Runnable r) { Message m = Message.obtain(); m.callback = r; return m; } private static Message getPostMessage(Runnable r, Object token) { Message m = Message.obtain(); m.obj = token; m.callback = r; return m; } private static void handleCallback(Message message) { message.callback.run(); } final MessageQueue mQueue; final Looper mLooper; final Callback mCallback; final boolean mAsynchronous; IMessenger mMessenger; private static final class BlockingRunnable implements Runnable { private final Runnable mTask; private boolean mDone; public BlockingRunnable(Runnable task) { mTask = task; } @Override public void run() { try { mTask.run(); } finally { synchronized (this) { mDone = true; notifyAll(); } } } public boolean postAndWait(Handler handler, long timeout) { if (!handler.post(this)) { return false; } synchronized (this) { if (timeout > 0) { final long expirationTime = SystemClock.uptimeMillis() + timeout; while (!mDone) { long delay = expirationTime - SystemClock.uptimeMillis(); if (delay <= 0) { return false; // timeout } try { wait(delay); } catch (InterruptedException ex) { } } } else { while (!mDone) { try { wait(); } catch (InterruptedException ex) { } } } } return true; } } }