原创源码角度分析Android的消息机制系列——MessageQueue的工作原理
Posted
tags:
篇首语:本文由小常识网(cha138.com)小编为大家整理,主要介绍了原创源码角度分析Android的消息机制系列——MessageQueue的工作原理相关的知识,希望对你有一定的参考价值。
ι 版权声明:本文为博主原创文章,未经博主允许不得转载。
MessageQueue,主要包含2个操作:插入和读取。读取操作会伴随着删除操作,插入和读取对应的方法分别为enqueueMessage和next,其中enqueueMessage的作用是往消息队列中插入一条消息,而next的作用是从消息队列中取出一条消息并将其从消息队列中移除。虽然MessageQueue叫消息队列,但是它的内部实现并不是用的队列,实际上它是通过一个单链表的数据结构来维护消息列表,单链表在插入和删除上比较有优势。
先看MessageQueue的定义:
/** * Low-level class holding the list of messages to be dispatched by a * {@link Looper}. Messages are not added directly to a MessageQueue, * but rather through {@link Handler} objects associated with the Looper. * * <p>You can retrieve the MessageQueue for the current thread with * {@link Looper#myQueue() Looper.myQueue()}. */ public final class MessageQueue
通过源码我们可以知道,MessageQueue维护了一个消息列表。Messgae并不是直接添加到MessageQueue中,而是通过和Looper相关联的Handler来添加的。在当前线程中可以通过调用Looper.myQueue()方法来获取当前线程的MessageQueue。
下面再看它的enqueueMessage插入方法:
boolean enqueueMessage(Message msg, long when) { if (msg.target == null) { throw new IllegalArgumentException("Message must have a target."); } if (msg.isInUse()) { throw new IllegalStateException(msg + " This message is already in use."); } synchronized (this) { if (mQuitting) { IllegalStateException e = new IllegalStateException( msg.target + " sending message to a Handler on a dead thread"); Log.w(TAG, e.getMessage(), e); msg.recycle(); return false; } msg.markInUse(); msg.when = when; Message p = mMessages; boolean needWake; if (p == null || when == 0 || when < p.when) { // New head, wake up the event queue if blocked. msg.next = p; mMessages = msg; needWake = mBlocked; } else { // Inserted within the middle of the queue. Usually we don‘t have to wake // up the event queue unless there is a barrier at the head of the queue // and the message is the earliest asynchronous message in the queue. 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; // invariant: p == prev.next prev.next = msg; } // We can assume mPtr != 0 because mQuitting is false. if (needWake) { nativeWake(mPtr); } } return true; }
在Message的源码中定义了一个成员属性target,其类型为Handler。由上面enqueuMessage的源码,我们可以看到,当Message没有处理其的Handler或该Message正在被处理的时候,都不能正常进入MessageQueue,这一点也是很容易理解的。当线程处于死亡状态的时候,Message会被回收掉,而不再进入该线程对应的MessageQueue中。否则,一切正常,enqueMessage就执行单链表的插入操作,将Message插入到MessageQueue中。
再来看MessageQueue的next读取操作:
Message next() { // Return here if the message loop has already quit and been disposed. // This can happen if the application tries to restart a looper after quit // which is not supported. final long ptr = mPtr; if (ptr == 0) { return null; } int pendingIdleHandlerCount = -1; // -1 only during first iteration int nextPollTimeoutMillis = 0; for (;;) { if (nextPollTimeoutMillis != 0) { Binder.flushPendingCommands(); } nativePollOnce(ptr, nextPollTimeoutMillis); synchronized (this) { // Try to retrieve the next message. Return if found. final long now = SystemClock.uptimeMillis(); Message prevMsg = null; Message msg = mMessages; if (msg != null && msg.target == null) { // Stalled by a barrier. Find the next asynchronous message in the queue. do { prevMsg = msg; msg = msg.next; } while (msg != null && !msg.isAsynchronous()); } if (msg != null) { if (now < msg.when) { // Next message is not ready. Set a timeout to wake up when it is ready. nextPollTimeoutMillis = (int) Math.min(msg.when - now, Integer.MAX_VALUE); } else { // Got a message. mBlocked = false; if (prevMsg != null) { prevMsg.next = msg.next; } else { mMessages = msg.next; } msg.next = null; if (DEBUG) Log.v(TAG, "Returning message: " + msg); msg.markInUse(); return msg; } } else { // No more messages. } // Process the quit message now that all pending messages have been handled. if (mQuitting) { dispose(); return null; } // If first time idle, then get the number of idlers to run. // Idle handles only run if the queue is empty or if the first message // in the queue (possibly a barrier) is due to be handled in the future. if (pendingIdleHandlerCount < 0 && (mMessages == null || now < mMessages.when)) { pendingIdleHandlerCount = mIdleHandlers.size(); } if (pendingIdleHandlerCount <= 0) { // No idle handlers to run. Loop and wait some more. mBlocked = true; continue; } if (mPendingIdleHandlers == null) { mPendingIdleHandlers = new IdleHandler[Math.max(pendingIdleHandlerCount, 4)]; } mPendingIdleHandlers = mIdleHandlers.toArray(mPendingIdleHandlers); } // Run the idle handlers. // We only ever reach this code block during the first iteration. for (int i = 0; i < pendingIdleHandlerCount; i++) { final IdleHandler idler = mPendingIdleHandlers[i]; mPendingIdleHandlers[i] = null; // release the reference to the handler boolean keep = false; try { keep = idler.queueIdle(); } catch (Throwable t) { Log.wtf(TAG, "IdleHandler threw exception", t); } if (!keep) { synchronized (this) { mIdleHandlers.remove(idler); } } } // Reset the idle handler count to 0 so we do not run them again. pendingIdleHandlerCount = 0; // While calling an idle handler, a new message could have been delivered // so go back and look again for a pending message without waiting. nextPollTimeoutMillis = 0; } }
通过源码我们可以知道,next方法会不停地去循环读取MessageQueue中的Message。若MessageQueue中没有消息了,则next方法会暂时阻塞( nextPollTimeoutMillis = -1)。有消息到来时,next会继续读取消息,返回该消息,并将其从单链表中移除。
以上是关于原创源码角度分析Android的消息机制系列——MessageQueue的工作原理的主要内容,如果未能解决你的问题,请参考以下文章
原创源码角度分析Android的消息机制系列——Handler的工作原理
原创源码角度分析Android的消息机制系列——ThreadLocal的工作原理
原创源码角度分析Android的消息机制系列——MessageQueue的工作原理
原创源码角度分析Android的消息机制系列——ThreadLocal的工作过程