Netty源码分析NioEventLoop处理IO事件相关逻辑_Java教程

前文传送门：NioEventLoop执行select操作入口

之前我们了解了执行select()操作的相关逻辑, 这一小节我们继续学习轮询到io事件的相关逻辑:

NioEventLoop的run()方法:

				?

									protected void run() {

									    for (;;) {

									        try {

									            switch (selectStrategy.calculateStrategy(selectNowSupplier, hasTasks())) {

									                case SelectStrategy.CONTINUE:

									                    continue;

									                case SelectStrategy.SELECT:

									                    //轮询io事件(1)

									                    select(wakenUp.getAndSet(false));

									                    if (wakenUp.get()) {

									                        selector.wakeup();

									                    }

									                default:

									            }

									            cancelledKeys = 0;

									            needsToSelectAgain = false;

									            //默认是50

									            final int ioRatio = this.ioRatio; 

									            if (ioRatio == 100) {

									                try {

									                    processSelectedKeys();

									                } finally {

									                    runAllTasks();

									                }

									            } else {

									                //记录下开始时间

									                final long ioStartTime = System.nanoTime();

									                try {

									                    //处理轮询到的key(2)

									                    processSelectedKeys();

									                } finally {

									                    //计算耗时

									                    final long ioTime = System.nanoTime() - ioStartTime;

									                    //执行task(3)

									                    runAllTasks(ioTime * (100 - ioRatio) / ioRatio);

									                }

									            }

									        } catch (Throwable t) {

									            handleLoopException(t);

									        }

									        //代码省略

									    }

									}

我们首先看 if (ioRatio == 100) 这个判断, ioRatio主要是用来控制processSelectedKeys()方法执行时间和任务队列执行时间的比例, 其中ioRatio默认是50, 所以会走到下一步else

首先通过 final long ioStartTime = System.nanoTime() 记录下开始时间, 再通过processSelectedKeys()方法处理轮询到的key

processSelectedKeys()方法

				?

									private void processSelectedKeys() { 

									    if (selectedKeys != null) {

									        //flip()方法会直接返回key的数组

									        processSelectedKeysOptimized(selectedKeys.flip());

									    } else {

									        processSelectedKeysPlain(selector.selectedKeys());

									    }

									}

我们知道selector通过netty优化之后, 会初始化 selectedKeys这个属性, 所以这个属性不为空就会走到 processSelectedKeysOptimized(selectedKeys.flip()) 方法, 这个方法就是对应优化过的selector进行操作的

如果是非优化的selector, 则会进入 processSelectedKeysPlain(selector.selectedKeys()) 方法

selectedKeys.flip()为selectedKey中绑定的数组, 我们之前小节讲过selectedKeys其实是通过数组存储的, 所以经过select()操作如果监听到事件selectedKeys的数组就会有值

processSelectedKeysOptimized(selectedKeys.flip())方法

				?

									private void processSelectedKeysOptimized(SelectionKey[] selectedKeys) {

									    //通过for循环遍历数组

									    for (int i = 0;; i ++) {

									        //拿到当前的selectionKey

									        final SelectionKey k = selectedKeys[i];

									        if (k == null) {

									            break;

									        }

									        //将当前引用设置为null

									        selectedKeys[i] = null;

									        //获取channel(NioSeverSocketChannel)

									        final Object a = k.attachment();

									        //如果是AbstractNioChannel, 则调用processSelectedKey()方法处理io事件

									        if (a instanceof AbstractNioChannel) {

									            processSelectedKey(k, (AbstractNioChannel) a);

									        } else {

									            @SuppressWarnings("unchecked")

									            NioTask<SelectableChannel> task = (NioTask<SelectableChannel>) a;

									            processSelectedKey(k, task);

									        }

									        //代码省略

									    }

									}

首先通过for循环遍历数组中的每一个key, 获得key之后首先将数组中对应的下标清空, 因为selector不会自动清空, 这与我们使用原生selector时候, 通过遍历selector.selectedKeys()的set的时候, 拿到key之后要执行remove()是一个意思

之后获取注册在key上的channel, 判断channel是不是AbstractNioChannel, 通常情况都是AbstractNioChannel, 所以这里会执行 processSelectedKey(k, (AbstractNioChannel) a)

processSelectedKey(k, (AbstractNioChannel) a)方法

				?

									private void processSelectedKey(SelectionKey k, AbstractNioChannel ch) {

									    //获取到channel中的unsafe

									    final AbstractNioChannel.NioUnsafe unsafe = ch.unsafe();

									    //如果这个key不是合法的, 说明这个channel可能有问题

									    if (!k.isValid()) {

									        //代码省略

									    }

									    try {

									        //如果是合法的, 拿到key的io事件

									        int readyOps = k.readyOps();

									        //链接事件

									        if ((readyOps & SelectionKey.OP_CONNECT) != 0) {

									            int ops = k.interestOps();

									            ops &= ~SelectionKey.OP_CONNECT;

									            k.interestOps(ops);

									            unsafe.finishConnect();

									        }

									        //写事件

									        if ((readyOps & SelectionKey.OP_WRITE) != 0) {

									            ch.unsafe().forceFlush();

									        }

									        //读事件和接受链接事件

									        //如果当前NioEventLoop是work线程的话, 这里就是op_read事件

									        //如果是当前NioEventLoop是boss线程的话, 这里就是op_accept事件

									        if ((readyOps & (SelectionKey.OP_READ | SelectionKey.OP_ACCEPT)) != 0 || readyOps == 0) {

									            unsafe.read();

									            if (!ch.isOpen()) {

									                return;

									            }

									        }

									    } catch (CancelledKeyException ignored) {

									        unsafe.close(unsafe.voidPromise());

									    }

									}