本篇内容主要讲解“io请求处理过程是什么”,感兴趣的朋友不妨来看看。本文介绍的方法操作简单快捷,实用性强。下面就让小编来带大家学习“io请求处理过程是什么”吧!
上篇讲到,netty启动起来之后,就会有很多个eventloop线程会一直在循环工作(server通用特性),比如进行select或者执行task. 我们再来回顾 NioEventLoop 的实现方式吧!
我们先看看下 NioEventLoop 的类图吧:
看起来非常复杂,不管它。它核心方法自然是 run();
// io.netty.channel.nio.NioEventLoop#run @Overrideprotected void run() {// 一个死循环检测任务, 这就 eventloop 的大杀器哦for (;;) {try {switch (selectStrategy.calculateStrategy(selectNowSupplier, hasTasks())) {case SelectStrategy.CONTINUE:continue;// 有任务时执行任务, 否则阻塞等待网络事件, 或被唤醒case SelectStrategy.SELECT:// select.select(), 带超时限制select(wakenUp.getAndSet(false));// 'wakenUp.compareAndSet(false, true)' is always evaluated// before calling 'selector.wakeup()' to reduce the wake-up// overhead. (Selector.wakeup() is an expensive operation.)//// However, there is a race condition in this approach.// The race condition is triggered when 'wakenUp' is set to// true too early.//// 'wakenUp' is set to true too early if:// 1) Selector is waken up between 'wakenUp.set(false)' and// 'selector.select(...)'. (BAD)// 2) Selector is waken up between 'selector.select(...)' and// 'if (wakenUp.get()) { ... }'. (OK)//// In the first case, 'wakenUp' is set to true and the// following 'selector.select(...)' will wake up immediately.// Until 'wakenUp' is set to false again in the next round,// 'wakenUp.compareAndSet(false, true)' will fail, and therefore// any attempt to wake up the Selector will fail, too, causing// the following 'selector.select(...)' call to block// unnecessarily.//// To fix this problem, we wake up the selector again if wakenUp// is true immediately after selector.select(...).// It is inefficient in that it wakes up the selector for both// the first case (BAD - wake-up required) and the second case// (OK - no wake-up required).if (wakenUp.get()) {
selector.wakeup();
}// fall throughdefault:
}
cancelledKeys = 0;
needsToSelectAgain = false;// ioRatio 为io操作的占比, 和运行任务相比, 默认为 50:50final int ioRatio = this.ioRatio;if (ioRatio == 100) {try {// step1. 运行io操作 processSelectedKeys();
} finally {// Ensure we always run tasks.// step2. 运行task任务 runAllTasks();
}
} else {final long ioStartTime = System.nanoTime();try {
processSelectedKeys();
} finally {// Ensure we always run tasks.final long ioTime = System.nanoTime() - ioStartTime;// 运行任务的最长时间runAllTasks(ioTime * (100 - ioRatio) / ioRatio);
}
}
} catch (Throwable t) {
handleLoopException(t);
}// Always handle shutdown even if the loop processing threw an exception.try {if (isShuttingDown()) {
closeAll();if (confirmShutdown()) {return;
}
}
} catch (Throwable t) {
handleLoopException(t);
}
}
}// select, 事件循环的依据private void select(boolean oldWakenUp) throws IOException {
Selector selector = this.selector;try {int selectCnt = 0;long currentTimeNanos = System.nanoTime();// 带超时限制, 默认最大超时1s, 但当有延时任务处理时, 以它为标准long selectDeadLineNanos = currentTimeNanos + delayNanos(currentTimeNanos);for (;;) {long timeoutMillis = (selectDeadLineNanos - currentTimeNanos + 500000L) / 1000000L;if (timeoutMillis <= 0) {// 超时则立即返回if (selectCnt == 0) {
selector.selectNow();
selectCnt = 1;
}break;
}// If a task was submitted when wakenUp value was true, the task didn't get a chance to call// Selector#wakeup. So we need to check task queue again before executing select operation.// If we don't, the task might be pended until select operation was timed out.// It might be pended until idle timeout if IdleStateHandler existed in pipeline.if (hasTasks() && wakenUp.compareAndSet(false, true)) {
selector.selectNow();
selectCnt = 1;break;
}int selectedKeys = selector.select(timeoutMillis);
selectCnt ++;if (selectedKeys != 0 || oldWakenUp || wakenUp.get() || hasTasks() || hasScheduledTasks()) {// - Selected something,// - waken up by user, or// - the task queue has a pending task.// - a scheduled task is ready for processingbreak;
}if (Thread.interrupted()) {// Thread was interrupted so reset selected keys and break so we not run into a busy loop.// As this is most likely a bug in the handler of the user or it's client library we will// also log it.//// See https://github.com/netty/netty/issues/2426if (logger.isDebugEnabled()) {
logger.debug("Selector.select() returned prematurely because ">);
}
selectCnt = 1;break;
}long time = System.nanoTime();if (time - TimeUnit.MILLISECONDS.toNanos(timeoutMillis) >= currentTimeNanos) {// timeoutMillis elapsed without anything selected.selectCnt = 1;
} else if (SELECTOR_AUTO_REBUILD_THRESHOLD > 0 &&selectCnt >= SELECTOR_AUTO_REBUILD_THRESHOLD) {// The selector returned prematurely many times in a row.// Rebuild the selector to work around the problem. logger.warn("Selector.select() returned prematurely {} times in a row; rebuilding Selector {}.",
selectCnt, selector);
rebuildSelector();
selector = this.selector;// Select again to populate selectedKeys. selector.selectNow();
selectCnt = 1;break;
}
currentTimeNanos = time;
}if (selectCnt > MIN_PREMATURE_SELECTOR_RETURNS) {if (logger.isDebugEnabled()) {
logger.debug("Selector.select() returned prematurely {} times in a row for Selector {}.",
selectCnt - 1, selector);
}
}
} catch (CancelledKeyException e) {if (logger.isDebugEnabled()) {
logger.debug(CancelledKeyException.class.getSimpleName() + " raised by a Selector {} - JDK bug?",
selector, e);
}// Harmless exception - log anyway }
}大体来说就是:eventloop是一个一直在运行的线程,它会不停地检测是否发生了网络事件或者被提交上来了新任务,如果有那么就会去执行这些任务。
在处理io事件和task时,为防止调度的饥饿问题,它设置了一个ioRatio来避免发生。即如果io事件占用了ioTime时间,那么task也应该占用相应剩下比例的时间,以保持公平性。
在实现上,发现网络io事件是通过 selector.select()的,而发现task任务是通过 hasTasks()来实现检测的。每检测一次,一般不超过1s的休眠时间,以免在特殊情况下发生意外而导致系统假死。
io操作主要就是监控一些网络事件,比如新连接请求,请请求,写请求,关闭请求等。它是一个网络应用的非常核心的功能之一。从eventloop的核心循环中,我们看到其 processSelectedKeys() 就做网络io事件处理的。
// io.netty.channel.nio.NioEventLoop#processSelectedKeysprivate void processSelectedKeys() {// selectedKeys 为前面进行bind()时初始化掉的,所以不会为空if (selectedKeys != null) {
processSelectedKeysOptimized();
} else {
processSelectedKeysPlain(selector.selectedKeys());
}
} private void processSelectedKeysOptimized() {// 当无网络事件发生时,selectedKeys.size=0, 不会发生处理行为for (int i = 0; i < selectedKeys.size; ++i) {// 当有网络事件发生时,selectedKeys 为各就绪事件final SelectionKey k = selectedKeys.keys[i];// null out entry in the array to allow to have it GC'ed once the Channel close// See https://github.com/netty/netty/issues/2363selectedKeys.keys[i] = null;final Object a = k.attachment();if (a instanceof AbstractNioChannel) {// 转换成相应的channel, 调用 processSelectedKey(k, (AbstractNioChannel) a);
} else {
@SuppressWarnings("unchecked")
NioTask<SelectableChannel> task = (NioTask<SelectableChannel>) a;
processSelectedKey(k, task);
}if (needsToSelectAgain) {// null out entries in the array to allow to have it GC'ed once the Channel close// See https://github.com/netty/netty/issues/2363selectedKeys.reset(i + 1);
selectAgain();
i = -1;
}
}
}// 处理具体的socketprivate void processSelectedKey(SelectionKey k, AbstractNioChannel ch) {final AbstractNioChannel.NioUnsafe unsafe = ch.unsafe();// if (!k.isValid()) {final EventLoop eventLoop;try {
eventLoop = ch.eventLoop();
} catch (Throwable ignored) {// If the channel implementation throws an exception because there is no event loop, we ignore this// because we are only trying to determine if ch is registered to this event loop and thus has authority// to close ch.return;
}// Only close ch if ch is still registered to this EventLoop. ch could have deregistered from the event loop// and thus the SelectionKey could be cancelled as part of the deregistration process, but the channel is// still healthy and should not be closed.// See https://github.com/netty/netty/issues/5125if (eventLoop != this || eventLoop == null) {return;
}// close the channel if the key is not valid anymore unsafe.close(unsafe.voidPromise());return;
}try {// 取出就绪事件类型进行判断int readyOps = k.readyOps();// We first need to call finishConnect() before try to trigger a read(...) or write(...) as otherwise// the NIO JDK channel implementation may throw a NotYetConnectedException.// 如果是连接事件,则先进行连接操作,触发 finishConnect() 事件链if ((readyOps & SelectionKey.OP_CONNECT) != 0) {// remove OP_CONNECT as otherwise Selector.select(..) will always return without blocking// See https://github.com/netty/netty/issues/924int ops = k.interestOps();
ops &= ~SelectionKey.OP_CONNECT;
k.interestOps(ops);
unsafe.finishConnect();
}// Process OP_WRITE first as we may be able to write some queued buffers and so free memory.// 如果是写事件,则强制channel写数据if ((readyOps & SelectionKey.OP_WRITE) != 0) {// Call forceFlush which will also take care of clear the OP_WRITE once there is nothing left to write ch.unsafe().forceFlush();
}// Also check for readOps of 0 to workaround possible JDK bug which may otherwise lead// to a spin loopif ((readyOps & (SelectionKey.OP_READ | SelectionKey.OP_ACCEPT)) != 0 || readyOps == 0) {// 读取数据, OP_READ, OP_ACCEPT 会进入到此处,事件处理从此开始 unsafe.read();
}
} catch (CancelledKeyException ignored) {
unsafe.close(unsafe.voidPromise());
}
}// io.netty.channel.nio.AbstractNioMessageChannel.NioMessageUnsafe#read @Overridepublic void read() {// 此处断言,只有io线程本身才可以进行read()操作,如果被其他线程执行,那就是有问题的assert eventLoop().inEventLoop();// 取出config, Pipeline...final ChannelConfig config = config();final ChannelPipeline pipeline = pipeline();// 调用 allocator 分配接收内存, io.netty.channel.AdaptiveRecvByteBufAllocator.HandleImpl// 并重置读取状态final RecvByteBufAllocator.Handle allocHandle = unsafe().recvBufAllocHandle();
allocHandle.reset(config);boolean closed = false;
Throwable exception = null;try {try {do {// 1. 初步读取数据int localRead = doReadMessages(readBuf);if (localRead == 0) {break;
}if (localRead < 0) {
closed = true;break;
}
allocHandle.incMessagesRead(localRead);// 通过allocHandle判定是否已读取数据完成} while (allocHandle.continueReading());
} catch (Throwable t) {
exception = t;
}int size = readBuf.size();for (int i = 0; i < size; i ++) {
readPending = false;// 2. 事件通知: fireChannelRead(), accept() 之后的channel作为数据源传入pipeline中// 此 pipeline 结构为 head -> ServerBootstrapAcceptor -> tail pipeline.fireChannelRead(readBuf.get(i));
}
readBuf.clear();
allocHandle.readComplete();// 事件通知: channelReadComplete()// 注意,此时read操作极有可能还未完成,而此进进行 complete 操作是否为时过早呢?// 是的,但是不用担心,eventLoop可以保证先提交的事件会先执行,所以这里就只管放心提交吧// 这也是accept不会阻塞eventLoop的原因,即虽然大家同在 eventLoop 上,但是accept很快就返回了 pipeline.fireChannelReadComplete();if (exception != null) {
closed = closeOnReadError(exception);
pipeline.fireExceptionCaught(exception);
}if (closed) {
inputShutdown = true;if (isOpen()) {
close(voidPromise());
}
}
} finally {// Check if there is a readPending which was not processed yet.// This could be for two reasons:// * The user called Channel.read() or ChannelHandlerContext.read() in channelRead(...) method// * The user called Channel.read() or ChannelHandlerContext.read() in channelReadComplete(...) method//// See https://github.com/netty/netty/issues/2254if (!readPending && !config.isAutoRead()) {
removeReadOp();
}
}
}
}以上是处理一条io事件的大体流程:
1. 调用 AdaptiveRecvByteBufAllocator 分配一个新的 ByteBuf, 用于接收新数据;
2. 调用 doReadMessages() 转到 accept() 接收socket进来, 存入 ByteBuf 备用;
3. 对接入的socket, 调用pipeline.fireChannelRead(), 处理读过程;
4. 调用pipeline.fireChannelReadComplete() 方法,触发read完成事件;
5. 异常处理;
注意,当前运行的线程是在bossGroup中,它的pipeline是相对固定的,即只有head -> acceptor -> tail, 而我们的handler是在childGroup中的,所以我们只能再等等咯。
下面我们就来细分解下这几个步骤!
在调用AdaptiveRecvByteBufAllocator, 分配一个新的 allocHandle 之后,就进行socket的接入,实际上就是调用 serverSocketChannel.accept() 方法, 初步读取数据。来看下!
// 处理预备 allocHandle, 以便进行判定是否数据读取完成// io.netty.channel.AbstractChannel.AbstractUnsafe#recvBufAllocHandle @Overridepublic RecvByteBufAllocator.Handle recvBufAllocHandle() {if (recvHandle == null) {
recvHandle = config().getRecvByteBufAllocator().newHandle();
}return recvHandle;
}// 重置读取状态// io.netty.channel.DefaultMaxMessagesRecvByteBufAllocator.MaxMessageHandle#reset @Overridepublic void reset(ChannelConfig config) {this.config = config;
maxMessagePerRead = maxMessagesPerRead();
totalMessages = totalBytesRead = 0;
}// 通过allocHandle判定是否已读取数据完成// io.netty.channel.DefaultMaxMessagesRecvByteBufAllocator.MaxMessageHandle#continueReading() @Overridepublic boolean continueReading() {return continueReading(defaultMaybeMoreSupplier);
}
@Overridepublic boolean continueReading(UncheckedBooleanSupplier maybeMoreDataSupplier) {return config.isAutoRead() && (!respectMaybeMoreData || maybeMoreDataSupplier.get()) &&// accept 时, totalMessages = 1, 此条件必成立。// 但totalBytesRead=0, 所以必然返回false, 还需要继续读数据 totalMessages < maxMessagePerRead && totalBytesRead > 0;
}// accept 新的socket @Overrideprotected int doReadMessages(List<Object> buf) throws Exception {// 也就是说, 对于netty而言, 是先知道有事件到来, 然后才去调用 accept() 方法的// 而accept() 方法则是会阻塞当前线程的哟, 但此时select()已经唤醒, 所以也意味着数据已经准备就绪,此处将会立即返回了SocketChannel ch = SocketUtils.accept(javaChannel());try {if (ch != null) {// 将当前注册的accept() 添加的buf结果中buf.add(new NioSocketChannel(this, ch));return 1;
}
} catch (Throwable t) {
logger.warn("Failed to create a new channel from an accepted socket.", t);try {
ch.close();
} catch (Throwable t2) {
logger.warn("Failed to close a socket.", t2);
}
}return 0;
}// io.netty.util.internal.SocketUtils#acceptpublic static SocketChannel accept(final ServerSocketChannel serverSocketChannel) throws IOException {try {return AccessController.doPrivileged(new PrivilegedExceptionAction<SocketChannel>() {
@Overridepublic SocketChannel run() throws IOException {return serverSocketChannel.accept();
}
});
} catch (PrivilegedActionException e) {throw (IOException) e.getCause();
}
}将新接入的socket封装成 NioSocketChannel 后, 添加到 readBuf 中, 进入下一步.
socket 接入完成后, 会依次读取数据. (所以, 前面会同时接入多个 socket ??) pipeline 机制正式上场. 此时pipeline中有head,acceptor,tail, 但只有acceptor会真正处理数据.
// channelRead() 事件通知, 从 head 开始, 由 acceptor 处理// io.netty.channel.DefaultChannelPipeline#fireChannelRead @Overridepublic final ChannelPipeline fireChannelRead(Object msg) {// 将pipeline中的head节点作为起始channelHandler传入,处理消息// head 实现: efaultChannelPipeline.HeadContext, 它既能处理 inbound, 也能处理 outbound 数据。 // 即其实现了 ChannelOutboundHandler, ChannelInboundHandler AbstractChannelHandlerContext.invokeChannelRead(head, msg);return this;
}// io.netty.channel.AbstractChannelHandlerContext#invokeChannelRead(io.netty.channel.AbstractChannelHandlerContext, java.lang.Object)static void invokeChannelRead(final AbstractChannelHandlerContext next, Object msg) {// 此处也是一个扩展点, 如果该channel实现了 ReferenceCounted, 则创建一个新的 ReferenceCounted msg 包装, 并调用其touch 方法final Object m = next.pipeline.touch(ObjectUtil.checkNotNull(msg, "msg"), next);
EventExecutor executor = next.executor();if (executor.inEventLoop()) {// 当前事件循环发现的数据,直接走此处 next.invokeChannelRead(m);
} else {
executor.execute(new Runnable() {
@Overridepublic void run() {
next.invokeChannelRead(m);
}
});
}
}// io.netty.channel.AbstractChannelHandlerContext#invokeChannelRead(java.lang.Object)private void invokeChannelRead(Object msg) {if (invokeHandler()) {try {// 开始调用真正的 channelRead()((ChannelInboundHandler) handler()).channelRead(this, msg);
} catch (Throwable t) {
notifyHandlerException(t);
}
} else {
fireChannelRead(msg);
}
}// io.netty.channel.DefaultChannelPipeline.HeadContext#channelRead @Overridepublic void channelRead(ChannelHandlerContext ctx, Object msg) throws Exception {// head 节点没有什么特别需要处理的,直接继续调用 fireChannelRead() 即可 ctx.fireChannelRead(msg);
}// io.netty.channel.AbstractChannelHandlerContext#fireChannelRead @Overridepublic ChannelHandlerContext fireChannelRead(final Object msg) {// 查找下一个入站处理器(查找方式前面已看过,就是以当前节点作为起点查找pipeline的下一个入站 channelHandlerContext, 调用即可// 此处调用与head节点的调用不同之处在于, head的调用是硬编码的, 但此处则是动态的, 可递归的// 而真正的差别是在于 channelHandler 的实现不同,从而处理不同的业务 // 对于刚刚 accept 之后的数据,必然会经过 Acceptor, 如下 invokeChannelRead(findContextInbound(), msg);return this;
} // 几经周折, 最终转到 ServerBootstrapAcceptor, 它会进行真正的数据处理, 实际上就是提交数据到 childGroup 中// io.netty.bootstrap.ServerBootstrap.ServerBootstrapAcceptor#channelRead @Override
@SuppressWarnings("unchecked")public void channelRead(ChannelHandlerContext ctx, Object msg) {// 对外部的channel进行还原, 将业务的 childHandler 添加到 pipeline 中// 添加方式与之前的一样,会涉及到name的生成,ChannelHandlerContext的构建。。。final Channel child = (Channel) msg;// 将业务设置的 childHandler 绑定到child pipeline 中, 即此时才会触发 ChannelInitializer.initChannel()// 每次新的socket接入, 都会触发一次 initChannel() 哦 child.pipeline().addLast(childHandler);// 复制各种配置属性到 child 中 setChannelOptions(child, childOptions, logger);for (Entry<AttributeKey<?>, Object> e: childAttrs) {
child.attr((AttributeKey<Object>) e.getKey()).set(e.getValue());
}try {// 注册child, 以及添加一个 回调// register 时就会将当前channel与一个eventLoop线程绑定起来,后续所有的操作将会在这个eventloop线程上执行// 同时,它会将当前channel与 nio的selector 绑定注册起来// 到此,acceptor的任务就算完成了childGroup.register(child).addListener(new ChannelFutureListener() {
@Overridepublic void operationComplete(ChannelFuture future) throws Exception {if (!future.isSuccess()) {
forceClose(child, future.cause());
}
}
});
} catch (Throwable t) {
forceClose(child, t);
}
}acceptor 最主要的工作就是将socket提交到 childGroup 中. 而childGroup的注册过程, 与bossGroup的注册过程是一致的, 它们的最大差异在于关注的事件不一致. acceptor 关注 OP_ACCEPT, 而childGroup 关注 OP_READ.
实际上,在bossGroup中, readComplete() 事件基本是会不被关注的, 但我们也可以通过它来了解下 readComplete 的传播方式吧! 总体和 read() 事件的传播是一致的.
// io.netty.channel.DefaultChannelPipeline#fireChannelReadComplete @Overridepublic final ChannelPipeline fireChannelReadComplete() {// 同样以 head 作为起点开始传播 AbstractChannelHandlerContext.invokeChannelReadComplete(head);return this;
}// 通用的调用 handler 方式// io.netty.channel.AbstractChannelHandlerContext#invokeChannelReadComplete(io.netty.channel.AbstractChannelHandlerContext)static void invokeChannelReadComplete(final AbstractChannelHandlerContext next) {
EventExecutor executor = next.executor();if (executor.inEventLoop()) {
next.invokeChannelReadComplete();
} else {
Runnable task = next.invokeChannelReadCompleteTask;if (task == null) {
next.invokeChannelReadCompleteTask = task = new Runnable() {
@Overridepublic void run() {
next.invokeChannelReadComplete();
}
};
}
executor.execute(task);
}
}// 通用pipeline调用模型// io.netty.channel.AbstractChannelHandlerContext#invokeChannelReadComplete()private void invokeChannelReadComplete() {if (invokeHandler()) {try {
((ChannelInboundHandler) handler()).channelReadComplete(this);
} catch (Throwable t) {
notifyHandlerException(t);
}
} else {
fireChannelReadComplete();
}
}// io.netty.channel.DefaultChannelPipeline.HeadContext#channelReadComplete @Overridepublic void channelReadComplete(ChannelHandlerContext ctx) throws Exception {
ctx.fireChannelReadComplete();
readIfIsAutoRead();
}// io.netty.channel.AbstractChannelHandlerContext#fireChannelReadComplete @Overridepublic ChannelHandlerContext fireChannelReadComplete() {// 通用的 fireXXX 事件传播方式,如果想调用下一节点,则调用 fireXXX, 否则pipeline将会被终止// 以当前节点作为起点查找下一个入站处理器 handler// 在acceptor中,最终会转到 ServerBootstrapAcceptor.readComplete()中 invokeChannelReadComplete(findContextInbound());return this;
} // io.netty.channel.ChannelInboundHandlerAdapter#channelReadComplete/** * Calls {@link ChannelHandlerContext#fireChannelReadComplete()} to forward
* to the next {@link ChannelInboundHandler} in the {@link ChannelPipeline}.
*
* Sub-classes may override this method to change behavior. */@Overridepublic void channelReadComplete(ChannelHandlerContext ctx) throws Exception {// 因为 ServerBootstrapAcceptor 并没有重写 channelReadComplete 方法,所以直接忽略该事件了// 而 tail 节点中的默认 onUnhandledInboundChannelReadComplete() 也是空处理 ctx.fireChannelReadComplete();
}总结下 pipeline 的传播方式:
1. 以 pipeline.fireChannelReadComplete() 等方式触发事件传播;
2. 调用 invokeChannelReadComplete, 传入 head或者tail作为传播的起点;
3. 判断是否在 eventloop 中,如果是则直接调用 next.invokeChannelReadComplete();
4. 调用 handler.channelReadComplete(this) 触发具体的事件;
5. 具体handler处理事务,如果想向下一节点传播,则调用 ctx.fireChannelReadComplete(), 否则停止传播;
以上是以 fireChannelReadComplete 来讲解的pipeline过程,实际上也是几乎所有的事件传播的方式。
上一节讲到的是acceptor接入了socket, 他会提交到childGroup中进行处理, 然后自己就返回了。那么 childGroup 又是如何处理事务的呢?
实际上,它与bossGroup是完全一样的处理方式,差别在于它们各自的pipeline是不一样的,线程数是不一样的,从而实现处理不同业务。而它处理是的读写事件,而acceptor则是处理的OP_ACCEPT事件。它的OP_READ事件是在创建NioSocketChannel的时候注册好的。我们先看看下:
// 在bossGroup处理Accept事件时,创建 NioSocketChannel// io.netty.channel.socket.nio.NioServerSocketChannel#doReadMessages @Overrideprotected int doReadMessages(List<Object> buf) throws Exception {
SocketChannel ch = SocketUtils.accept(javaChannel());try {if (ch != null) {
buf.add(new NioSocketChannel(this, ch));return 1;
}
} catch (Throwable t) {
logger.warn("Failed to create a new channel from an accepted socket.", t);try {
ch.close();
} catch (Throwable t2) {
logger.warn("Failed to close a socket.", t2);
}
}return 0;
}// io.netty.channel.socket.nio.NioSocketChannel#NioSocketChannel/** * Create a new instance
*
* @param parent the {@link Channel} which created this instance or {@code null} if it was created by the user
* @param socket the {@link SocketChannel} which will be used */public NioSocketChannel(Channel parent, SocketChannel socket) {// 在父类中处理事件监听super(parent, socket);
config = new NioSocketChannelConfig(this, socket.socket());
}// io.netty.channel.nio.AbstractNioByteChannel#AbstractNioByteChannel/** * Create a new instance
*
* @param parent the parent {@link Channel} by which this instance was created. May be {@code null}
* @param ch the underlying {@link SelectableChannel} on which it operates */protected AbstractNioByteChannel(Channel parent, SelectableChannel ch) {// 注册 OP_READ 事件super(parent, ch, SelectionKey.OP_READ);
}ok, 说回childGroup处理事件流中。因大家都是 NioEventLoopGroup, 所以创建的eventloop自然都是一样的。即都会处理io事件和task运行。回顾下上节的processSelectedKey()操作:
// io.netty.channel.nio.NioEventLoop#processSelectedKey(java.nio.channels.SelectionKey, io.netty.channel.nio.AbstractNioChannel)private void processSelectedKey(SelectionKey k, AbstractNioChannel ch) {final AbstractNioChannel.NioUnsafe unsafe = ch.unsafe();if (!k.isValid()) {final EventLoop eventLoop;try {
eventLoop = ch.eventLoop();
} catch (Throwable ignored) {// If the channel implementation throws an exception because there is no event loop, we ignore this// because we are only trying to determine if ch is registered to this event loop and thus has authority// to close ch.return;
}// Only close ch if ch is still registered to this EventLoop. ch could have deregistered from the event loop// and thus the SelectionKey could be cancelled as part of the deregistration process, but the channel is// still healthy and should not be closed.// See https://github.com/netty/netty/issues/5125if (eventLoop != this || eventLoop == null) {return;
}// close the channel if the key is not valid anymore unsafe.close(unsafe.voidPromise());return;
}try {int readyOps = k.readyOps();// We first need to call finishConnect() before try to trigger a read(...) or write(...) as otherwise// the NIO JDK channel implementation may throw a NotYetConnectedException.if ((readyOps & SelectionKey.OP_CONNECT) != 0) {// remove OP_CONNECT as otherwise Selector.select(..) will always return without blocking// See https://github.com/netty/netty/issues/924int ops = k.interestOps();
ops &= ~SelectionKey.OP_CONNECT;
k.interestOps(ops);
unsafe.finishConnect();
}// Process OP_WRITE first as we may be able to write some queued buffers and so free memory.if ((readyOps & SelectionKey.OP_WRITE) != 0) {// Call forceFlush which will also take care of clear the OP_WRITE once there is nothing left to write ch.unsafe().forceFlush();
}// Also check for readOps of 0 to workaround possible JDK bug which may otherwise lead// to a spin loopif ((readyOps & (SelectionKey.OP_READ | SelectionKey.OP_ACCEPT)) != 0 || readyOps == 0) {// 走不一样的 unsafe 实现 unsafe.read();
}
} catch (CancelledKeyException ignored) {
unsafe.close(unsafe.voidPromise());
}
}// io.netty.channel.nio.AbstractNioByteChannel.NioByteUnsafe#read @Overridepublic final void read() {final ChannelConfig config = config();// 判断是否终止读数据,比如socket关闭等原因if (shouldBreakReadReady(config)) {
clearReadPending();return;
}// step1. 环境准备,pipeline, allocator...// 这里的 pipeline 就是我们自定义传入的各种handler了final ChannelPipeline pipeline = pipeline();final ByteBufAllocator allocator = config.getAllocator();final RecvByteBufAllocator.Handle allocHandle = recvBufAllocHandle();
allocHandle.reset(config);
ByteBuf byteBuf = null;boolean close = false;try {do {// 每次循环读取数据时,都进行重新内存分配,默认分配 1024的byte内存byteBuf = allocHandle.allocate(allocator);// step2. 将数据读取放入 byteBuf 中, 并由 allocHandle 记录读取的数据 allocHandle.lastBytesRead(doReadBytes(byteBuf));// 当数据读取完成或者进行close时,会读取 -1if (allocHandle.lastBytesRead() <= 0) {// nothing was read. release the buffer. byteBuf.release();
byteBuf = null;
close = allocHandle.lastBytesRead() < 0;if (close) {// There is nothing left to read as we received an EOF.readPending = false;
}break;
}// 读取数据记录次数 +1allocHandle.incMessagesRead(1);
readPending = false;// step3. 触发pipeline 的channelRead() 事件 pipeline.fireChannelRead(byteBuf);
byteBuf = null;
} while (allocHandle.continueReading());
allocHandle.readComplete();// 触发 channelReadComplete 事件,传播 pipeline.fireChannelReadComplete();if (close) {
closeOnRead(pipeline);
}
} catch (Throwable t) {
handleReadException(pipeline, byteBuf, t, close, allocHandle);
} finally {// Check if there is a readPending which was not processed yet.// This could be for two reasons:// * The user called Channel.read() or ChannelHandlerContext.read() in channelRead(...) method// * The user called Channel.read() or ChannelHandlerContext.read() in channelReadComplete(...) method//// See https://github.com/netty/netty/issues/2254if (!readPending && !config.isAutoRead()) {
removeReadOp();
}
}
}
}以上,就是 childGroup 处理 io 事件的基本过程了。总体和acceptor的差不多,这也是netty抽象得比较合理的地方,所有地方都可以套用同一个模式。
1. 准备环境,获取pipeline,配置config分配内存;
2. doReadBytes() 读取数据buffer, 最大读取1024字节;
3. 读取完成后记录并触发pipeline下游处理本次的channelRead()事件,保证各handler都有机会处理该部分数据;
4. 只要数据没读取完,且没有超过最大数据量限制,循环处理2/3步骤;
5. 总体触发一次 channelReadComplete 事件,并同理在pipeline中传播;
6. 异常处理,close处理;
pipeline 的传播方式, 前面我们已经见识过了,范式就是:read() 作为入站事件, 从head开始传播,依次调用各handler的channelRead()方法,直到链尾。
接下来我们就其中几个关键的步骤看下,netty都是如何实现的。
// 想想应该都能知道,就是从socket中将buffer读取存入到 byteBuf 中// io.netty.channel.socket.nio.NioSocketChannel#doReadBytes @Overrideprotected int doReadBytes(ByteBuf byteBuf) throws Exception {final RecvByteBufAllocator.Handle allocHandle = unsafe().recvBufAllocHandle();
allocHandle.attemptedBytesRead(byteBuf.writableBytes());// 获取 SocketChannel, 然后读取其中的数据, 写入 byteBuf 中,也是一个从内核到heap的一个拷贝过程return byteBuf.writeBytes(javaChannel(), allocHandle.attemptedBytesRead());
}// io.netty.buffer.AbstractByteBuf#writeBytes @Overridepublic int writeBytes(ScatteringByteChannel in, int length) throws IOException {
ensureWritable(length);int writtenBytes = setBytes(writerIndex, in, length);// 保证写指针的同步if (writtenBytes > 0) {
writerIndex += writtenBytes;
}return writtenBytes;
}// io.netty.buffer.PooledUnsafeDirectByteBuf#setBytes @Overridepublic int setBytes(int index, ScatteringByteChannel in, int length) throws IOException {
checkIndex(index, length);// 获取 ByteBuf 的共享变量,设值后 ByteBuf 可共享到// DirectByteBuffer 就体现在这里ByteBuffer tmpBuf = internalNioBuffer();
index = idx(index);
tmpBuf.clear().position(index).limit(index + length);try {// 从 socketChannel 中读取数据到 tmpBuf 中,// 此处看起来是存在内存拷贝,但实际上被使用直接内存时,并不会新建,而直接共用内核中内存数据即可return in.read(tmpBuf);
} catch (ClosedChannelException ignored) {return -1;
}
}以上就是socket数据的读取过程了,总体可以描述为内核内存到java堆内存的拷贝过程(当然具体实现方式是另一回事)。
数据读取完成后(可能是部分),就会交pipeline处理这部分数据,head -> handler... -> tail 的过程。我们还是一个具体的 netty提供的一个解码的实现:
就是一个 channelRead 处理过程 。
// io.netty.handler.codec.ByteToMessageDecoder#channelRead @Overridepublic void channelRead(ChannelHandlerContext ctx, Object msg) throws Exception {if (msg instanceof ByteBuf) {
CodecOutputList out = CodecOutputList.newInstance();try {
ByteBuf data = (ByteBuf) msg;
first = cumulation == null;// 如果是第一次进来,则直接赋值data, 后续则附加到 cumulation 中,以达到连接字节的作用// 一般每个连接进来之后,会创建一个 Decoder, 后续处理数据就会都会存在连接总是,但总体来说都是线程安全的if (first) {
cumulation = data;
} else {
cumulation = cumulator.cumulate(ctx.alloc(), cumulation, data);
}// 调用decode方法,将byte转换为string callDecode(ctx, cumulation, out);
} catch (DecoderException e) {throw e;
} catch (Exception e) {throw new DecoderException(e);
} finally {if (cumulation != null && !cumulation.isReadable()) {
numReads = 0;// 释放buffer cumulation.release();
cumulation = null;
} else if (++ numReads >= discardAfterReads) {// We did enough reads already try to discard some bytes so we not risk to see a OOME.// See https://github.com/netty/netty/issues/4275numReads = 0;
discardSomeReadBytes();
}int size = out.size();
decodeWasNull = !out.insertSinceRecycled();// 通知下游数据到来,依次遍历out的数据调用下游 fireChannelRead(ctx, out, size);
out.recycle();
}
} else {
ctx.fireChannelRead(msg);
}
}// io.netty.handler.codec.ByteToMessageDecoder#callDecode/** * Called once data should be decoded from the given {@link ByteBuf}. This method will call
* {@link #decode(ChannelHandlerContext, ByteBuf, List)} as long as decoding should take place.
*
* @param ctx the {@link ChannelHandlerContext} which this {@link ByteToMessageDecoder} belongs to
* @param in the {@link ByteBuf} from which to read data
* @param out the {@link List} to which decoded messages should be added */protected void callDecode(ChannelHandlerContext ctx, ByteBuf in, List<Object> out) {try {while (in.isReadable()) {int outSize = out.size();// 处理遗留数据if (outSize > 0) {// out中有数据,则重新触发 channelRead() 以使下游可感知该数据 fireChannelRead(ctx, out, outSize);
out.clear();// Check if this handler was removed before continuing with decoding.// If it was removed, it is not safe to continue to operate on the buffer.//// See:// - https://github.com/netty/netty/issues/4635if (ctx.isRemoved()) {break;
}
outSize = 0;
}int oldInputLength = in.readableBytes();// 调用解码方法,对对in数据进行处理,并必要情况下输出结果到 out 中 decodeRemovalReentryProtection(ctx, in, out);// Check if this handler was removed before continuing the loop.// If it was removed, it is not safe to continue to operate on the buffer.//// See https://github.com/netty/netty/issues/1664if (ctx.isRemoved()) {break;
}// 没有读取到数据,或者未满足输出数据的要求(如读取到半包),前后的 out 大小相等if (outSize == out.size()) {if (oldInputLength == in.readableBytes()) {break;
} else {continue;
}
}// 读取完成后, readableBytes() 一般会变为0if (oldInputLength == in.readableBytes()) {throw new DecoderException(
StringUtil.simpleClassName(getClass()) +
".decode() did not read anything but decoded a message.");
}if (isSingleDecode()) {break;
}
}
} catch (DecoderException e) {throw e;
} catch (Exception cause) {throw new DecoderException(cause);
}
}// io.netty.handler.codec.ByteToMessageDecoder#decodeRemovalReentryProtection/** * Decode the from one {@link ByteBuf} to an other. This method will be called till either the input
* {@link ByteBuf} has nothing to read when return from this method or till nothing was read from the input
* {@link ByteBuf}.
*
* @param ctx the {@link ChannelHandlerContext} which this {@link ByteToMessageDecoder} belongs to
* @param in the {@link ByteBuf} from which to read data
* @param out the {@link List} to which decoded messages should be added
* @throws Exception is thrown if an error occurs */final void decodeRemovalReentryProtection(ChannelHandlerContext ctx, ByteBuf in, List<Object> out)throws Exception {
decodeState = STATE_CALLING_CHILD_DECODE;try {// 将byte数据转换为想要的类型,即我们自定义处理的地方 decode(ctx, in, out);
} finally {boolean removePending = decodeState == STATE_HANDLER_REMOVED_PENDING;
decodeState = STATE_INIT;if (removePending) {
handlerRemoved(ctx);
}
}
}// 比如如下实现,将byte转换为stringpublic class MessageDecoder extends ByteToMessageDecoder {//从ByteBuf中获取字节,转换成对象,写入到List中 @Overrideprotected void decode(ChannelHandlerContext ctx, ByteBuf buffer, List<Object> out) throws Exception {
buffer.markReaderIndex();byte[] data=new byte[buffer.readableBytes()];
buffer.readBytes(data);
out.add(new String(data,"UTF-8"));
}
} // 触发pipeline下游handler处理数据// io.netty.handler.codec.ByteToMessageDecoder#fireChannelRead/** * Get {@code numElements} out of the {@link CodecOutputList} and forward these through the pipeline. */static void fireChannelRead(ChannelHandlerContext ctx, CodecOutputList msgs, int numElements) {for (int i = 0; i < numElements; i ++) {
ctx.fireChannelRead(msgs.getUnsafe(i));
}
}总结下对数据的解码过程:
1. 接收外部读取的byteBuf;
2. 判断数据是否足够进行解码,如果解码成功将其添加到out中;
3. 将out的数据传入到pipeline下游,进行业务处理;
4. 释放已读取的buffer数据,进入下一次数据读取准备;
对于短连接请求,每次都会有新的encoder, decoder, 但对于长连接而言, 则会复用之前的handler, 从而也需要处理好各数据的分界问题,即自定义协议时得够严谨以避免误读。
write 数据是向对端进行数据输出的过程,一般有 write, 和 flush 过程, write 仅向应用缓冲中写入数据,在合适的时候flush到对端。而writeAndFlush则表示立即输出数据到对端。有 DefaultChannelHandlerContext 的实现:
// io.netty.channel.AbstractChannelHandlerContext#writeAndFlush @Overridepublic ChannelFuture writeAndFlush(Object msg) {return writeAndFlush(msg, newPromise());
}// io.netty.channel.AbstractChannelHandlerContext#newPromise @Overridepublic ChannelPromise newPromise() {// channel 会从pipeline中获取, executor 即channel中绑定的io线程return new DefaultChannelPromise(channel(), executor());
}// io.netty.channel.AbstractChannelHandlerContext#writeAndFlush @Overridepublic ChannelFuture writeAndFlush(Object msg, ChannelPromise promise) {if (msg == null) {throw new NullPointerException("msg");
}// channel 等信息校验if (isNotValidPromise(promise, true)) {
ReferenceCountUtil.release(msg);// cancelledreturn promise;
}// 写数据, flush=truewrite(msg, true, promise);return promise;
}private void write(Object msg, boolean flush, ChannelPromise promise) {// write 为出站事件, 从当前节点查找 出站handler, 直到headAbstractChannelHandlerContext next = findContextOutbound();final Object m = pipeline.touch(msg, next);
EventExecutor executor = next.executor();if (executor.inEventLoop()) {if (flush) {// 下一节点处理 next.invokeWriteAndFlush(m, promise);
} else {
next.invokeWrite(m, promise);
}
} else {
AbstractWriteTask task;if (flush) {
task = WriteAndFlushTask.newInstance(next, m, promise);
} else {
task = WriteTask.newInstance(next, m, promise);
}
safeExecute(executor, task, promise, m);
}
}// io.netty.channel.AbstractChannelHandlerContext#invokeWriteAndFlushprivate void invokeWriteAndFlush(Object msg, ChannelPromise promise) {if (invokeHandler()) {// step1. write 事件写数据到缓冲区 invokeWrite0(msg, promise);// step2. flush 事件写缓冲区数据到对端 invokeFlush0();
} else {
writeAndFlush(msg, promise);
}
}write 含义明确,写数据到xxx。那这是如何实现的呢?(仅从应用层分析,咱们就不讨论底层TCP协议了)
实际上,它就是write事件的传播过程,最终由 head 节点处理。
private void invokeWrite0(Object msg, ChannelPromise promise) {try {// write 传递((ChannelOutboundHandler) handler()).write(this, msg, promise);
} catch (Throwable t) {
notifyOutboundHandlerException(t, promise);
}
} // 此处由 encoder 进行处理// io.netty.handler.codec.MessageToByteEncoder#write @Overridepublic void write(ChannelHandlerContext ctx, Object msg, ChannelPromise promise) throws Exception {
ByteBuf buf = null;try {if (acceptOutboundMessage(msg)) {
@SuppressWarnings("unchecked")
I cast = (I) msg;// 分配byteBuf, 处理输出,和读取一样,可以使用 DirectByteBufferbuf = allocateBuffer(ctx, cast, preferDirect);try {// 调用业务实现的 encode 方法,写数据到 buf 中 encode(ctx, cast, buf);
} finally {
ReferenceCountUtil.release(cast);
}if (buf.isReadable()) {// 如果被写入数据到 buf 中,则传播write事件// 直到head 完成 ctx.write(buf, promise);
} else {
buf.release();
ctx.write(Unpooled.EMPTY_BUFFER, promise);
}
buf = null;
} else {
ctx.write(msg, promise);
}
} catch (EncoderException e) {throw e;
} catch (Throwable e) {throw new EncoderException(e);
} finally {if (buf != null) {
buf.release();
}
}
}
@Overridepublic ByteBuf ioBuffer() {if (PlatformDependent.hasUnsafe()) {return directBuffer(DEFAULT_INITIAL_CAPACITY);
}return heapBuffer(DEFAULT_INITIAL_CAPACITY);
}// head 节点会处理具体的写入细节 @Overridepublic void write(ChannelHandlerContext ctx, Object msg, ChannelPromise promise) throws Exception {
unsafe.write(msg, promise);
}// io.netty.channel.AbstractChannel.AbstractUnsafe#write @Overridepublic final void write(Object msg, ChannelPromise promise) {
assertEventLoop();
ChannelOutboundBuffer outboundBuffer = this.outboundBuffer;if (outboundBuffer == null) {// If the outboundBuffer is null we know the channel was closed and so// need to fail the future right away. If it is not null the handling of the rest// will be done in flush0()// See https://github.com/netty/netty/issues/2362 safeSetFailure(promise, WRITE_CLOSED_CHANNEL_EXCEPTION);// release message now to prevent resource-leak ReferenceCountUtil.release(msg);return;
}int size;try {// 处理为 DirectByteBuffermsg = filterOutboundMessage(msg);
size = pipeline.estimatorHandle().size(msg);if (size < 0) {
size = 0;
}
} catch (Throwable t) {
safeSetFailure(promise, t);
ReferenceCountUtil.release(msg);return;
}// 添加数据到 outboundBuffer 中,即输出缓冲区 outboundBuffer.addMessage(msg, size, promise);
}// io.netty.channel.nio.AbstractNioByteChannel#filterOutboundMessage @Overrideprotected final Object filterOutboundMessage(Object msg) {if (msg instanceof ByteBuf) {
ByteBuf buf = (ByteBuf) msg;if (buf.isDirect()) {return msg;
}return newDirectBuffer(buf);
}if (msg instanceof FileRegion) {return msg;
}throw new UnsupportedOperationException("unsupported message type: " + StringUtil.simpleClassName(msg) + EXPECTED_TYPES);
}// io.netty.channel.ChannelOutboundBuffer#addMessage/** * Add given message to this {@link ChannelOutboundBuffer}. The given {@link ChannelPromise} will be notified once
* the message was written. */public void addMessage(Object msg, int size, ChannelPromise promise) {
Entry entry = Entry.newInstance(msg, size, total(msg), promise);if (tailEntry == null) {
flushedEntry = null;
} else {
Entry tail = tailEntry;
tail.next = entry;
}
tailEntry = entry;if (unflushedEntry == null) {
unflushedEntry = entry;
}// increment pending bytes after adding message to the unflushed arrays.// See https://github.com/netty/netty/issues/1619incrementPendingOutboundBytes(entry.pendingSize, false);
}private void incrementPendingOutboundBytes(long size, boolean invokeLater) {if (size == 0) {return;
}long newWriteBufferSize = TOTAL_PENDING_SIZE_UPDATER.addAndGet(this, size);if (newWriteBufferSize > channel.config().getWriteBufferHighWaterMark()) {// 超出一定数量后,需要主动flush setUnwritable(invokeLater);
}
}private void setUnwritable(boolean invokeLater) {for (;;) {final int oldValue = unwritable;final int newValue = oldValue | 1;if (UNWRITABLE_UPDATER.compareAndSet(this, oldValue, newValue)) {if (oldValue == 0 && newValue != 0) {
fireChannelWritabilityChanged(invokeLater);
}break;
}
}
}即write只向 outboundBuffer中写入数据,应该是比较快速的。但它也是经历了 pipeline 的事件流的层层处理,如果想在这其中做点什么,也是比较方便的。
上面一步写入数据到 outboundBuffer 中,并未向对端响应数据,需要进行 flush 对端才能感知到。
private void invokeWriteAndFlush(Object msg, ChannelPromise promise) {if (invokeHandler()) {
invokeWrite0(msg, promise);
invokeFlush0();
} else {
writeAndFlush(msg, promise);
}
}// io.netty.channel.AbstractChannelHandlerContext#invokeFlush0private void invokeFlush0() {try {// 由 MessageEncoder 处理((ChannelOutboundHandler) handler()).flush(this);
} catch (Throwable t) {
notifyHandlerException(t);
}
}// io.netty.channel.ChannelOutboundHandlerAdapter#flush/** * Calls {@link ChannelHandlerContext#flush()} to forward
* to the next {@link ChannelOutboundHandler} in the {@link ChannelPipeline}.
*
* Sub-classes may override this method to change behavior. */@Overridepublic void flush(ChannelHandlerContext ctx) throws Exception {
ctx.flush();
}// io.netty.channel.AbstractChannelHandlerContext#flush @Overridepublic ChannelHandlerContext flush() {// 出站handler, 依次调用, 直到headfinal AbstractChannelHandlerContext next = findContextOutbound();
EventExecutor executor = next.executor();if (executor.inEventLoop()) {
next.invokeFlush();
} else {
Runnable task = next.invokeFlushTask;if (task == null) {
next.invokeFlushTask = task = new Runnable() {
@Overridepublic void run() {
next.invokeFlush();
}
};
}
safeExecute(executor, task, channel().voidPromise(), null);
}return this;
}private void invokeFlush() {if (invokeHandler()) {// 遍历 pipeline invokeFlush0();
} else {
flush();
}
}// head 节点负责最终的数据flush// io.netty.channel.DefaultChannelPipeline.HeadContext#flush @Overridepublic void flush(ChannelHandlerContext ctx) throws Exception {// unsafe 为 NioSocketChannel$NioSocketChannelUnsafe unsafe.flush();
}// io.netty.channel.AbstractChannel.AbstractUnsafe#flush @Overridepublic final void flush() {
assertEventLoop();
ChannelOutboundBuffer outboundBuffer = this.outboundBuffer;if (outboundBuffer == null) {return;
}
outboundBuffer.addFlush();
flush0();
}// io.netty.channel.ChannelOutboundBuffer#addFlush/** * Add a flush to this {@link ChannelOutboundBuffer}. This means all previous added messages are marked as flushed
* and so you will be able to handle them. */public void addFlush() {// There is no need to process all entries if there was already a flush before and no new messages// where added in the meantime.//// See https://github.com/netty/netty/issues/2577// 使用 unflushedEntry 保存要被 flush 的数据Entry entry = unflushedEntry;if (entry != null) {if (flushedEntry == null) {// there is no flushedEntry yet, so start with the entryflushedEntry = entry;
}do {
flushed ++;if (!entry.promise.setUncancellable()) {// Was cancelled so make sure we free up memory and notify about the freed bytesint pending = entry.cancel();
decrementPendingOutboundBytes(pending, false, true);
}
entry = entry.next;
} while (entry != null);// All flushed so reset unflushedEntryunflushedEntry = null;
}
}// io.netty.channel.nio.AbstractNioChannel.AbstractNioUnsafe#flush0 @Overrideprotected final void flush0() {// Flush immediately only when there's no pending flush.// If there's a pending flush operation, event loop will call forceFlush() later,// and thus there's no need to call it now.// 第一次进入此处,将会尝试立即向socket中写入数据或者立即注册一个 OP_WRITE 事件,以触发写if (!isFlushPending()) {super.flush0();
}
}private boolean isFlushPending() {
SelectionKey selectionKey = selectionKey();return selectionKey.isValid() && (selectionKey.interestOps() & SelectionKey.OP_WRITE) != 0;
}// io.netty.channel.AbstractChannel.AbstractUnsafe#flush0@SuppressWarnings("deprecation")protected void flush0() {if (inFlush0) {// Avoid re-entrancereturn;
}final ChannelOutboundBuffer outboundBuffer = this.outboundBuffer;if (outboundBuffer == null || outboundBuffer.isEmpty()) {return;
}
inFlush0 = true;// Mark all pending write requests as failure if the channel is inactive.if (!isActive()) {try {if (isOpen()) {
outboundBuffer.failFlushed(FLUSH0_NOT_YET_CONNECTED_EXCEPTION, true);
} else {// Do not trigger channelWritabilityChanged because the channel is closed already.outboundBuffer.failFlushed(FLUSH0_CLOSED_CHANNEL_EXCEPTION, false);
}
} finally {
inFlush0 = false;
}return;
}try {
doWrite(outboundBuffer);
} catch (Throwable t) {if (t instanceof IOException && config().isAutoClose()) {/** * Just call {@link #close(ChannelPromise, Throwable, boolean)} here which will take care of
* failing all flushed messages and also ensure the actual close of the underlying transport
* will happen before the promises are notified.
*
* This is needed as otherwise {@link #isActive()} , {@link #isOpen()} and {@link #isWritable()}
* may still return {@code true} even if the channel should be closed as result of the exception. */close(voidPromise(), t, FLUSH0_CLOSED_CHANNEL_EXCEPTION, false);
} else {try {
shutdownOutput(voidPromise(), t);
} catch (Throwable t2) {
close(voidPromise(), t2, FLUSH0_CLOSED_CHANNEL_EXCEPTION, false);
}
}
} finally {
inFlush0 = false;
}
}// io.netty.channel.socket.nio.NioSocketChannel#doWrite @Overrideprotected void doWrite(ChannelOutboundBuffer in) throws Exception {
SocketChannel ch = javaChannel();int writeSpinCount = config().getWriteSpinCount();do {if (in.isEmpty()) {// All written so clear OP_WRITE clearOpWrite();// Directly return here so incompleteWrite(...) is not called.return;
}// Ensure the pending writes are made of ByteBufs only.int maxBytesPerGatheringWrite = ((NioSocketChannelConfig) config).getMaxBytesPerGatheringWrite();
ByteBuffer[] nioBuffers = in.nioBuffers(1024, maxBytesPerGatheringWrite);int nioBufferCnt = in.nioBufferCount();// Always us nioBuffers() to workaround data-corruption.// See https://github.com/netty/netty/issues/2761switch (nioBufferCnt) {case 0:// We have something else beside ByteBuffers to write so fallback to normal writes.writeSpinCount -= doWrite0(in);break;case 1: {// Only one ByteBuf so use non-gathering write// Zero length buffers are not added to nioBuffers by ChannelOutboundBuffer, so there is no need// to check if the total size of all the buffers is non-zero.ByteBuffer buffer = nioBuffers[0];int attemptedBytes = buffer.remaining();// 向socket中写入数据,完事,写入多少数据量返回,以便判定是否写完final int localWrittenBytes = ch.write(buffer);if (localWrittenBytes <= 0) {
incompleteWrite(true);return;
}
adjustMaxBytesPerGatheringWrite(attemptedBytes, localWrittenBytes, maxBytesPerGatheringWrite);
in.removeBytes(localWrittenBytes);// 减少可写次数,超过最大可写次数,退出--writeSpinCount;break;
}default: {// Zero length buffers are not added to nioBuffers by ChannelOutboundBuffer, so there is no need// to check if the total size of all the buffers is non-zero.// We limit the max amount to int above so cast is safelong attemptedBytes = in.nioBufferSize();final long localWrittenBytes = ch.write(nioBuffers, 0, nioBufferCnt);if (localWrittenBytes <= 0) {
incompleteWrite(true);return;
}// Casting to int is safe because we limit the total amount of data in the nioBuffers to int above.adjustMaxBytesPerGatheringWrite((int) attemptedBytes, (int) localWrittenBytes,
maxBytesPerGatheringWrite);
in.removeBytes(localWrittenBytes);--writeSpinCount;break;
}
}
} while (writeSpinCount > 0);// 数据未写完,注册 OP_WRITE 事件incompleteWrite(writeSpinCount < 0);
}protected final void clearOpWrite() {final SelectionKey key = selectionKey();// Check first if the key is still valid as it may be canceled as part of the deregistration// from the EventLoop// See https://github.com/netty/netty/issues/2104if (!key.isValid()) {return;
}final int interestOps = key.interestOps();// 取消写事件监听if ((interestOps & SelectionKey.OP_WRITE) != 0) {
key.interestOps(interestOps & ~SelectionKey.OP_WRITE);
}
}// 获取 nioBufers ----------------------------------------------------/** * Returns an array of direct NIO buffers if the currently pending messages are made of {@link ByteBuf} only.
* {@link #nioBufferCount()} and {@link #nioBufferSize()} will return the number of NIO buffers in the returned
* array and the total number of readable bytes of the NIO buffers respectively.
* <p>
* Note that the returned array is reused and thus should not escape
* {@link AbstractChannel#doWrite(ChannelOutboundBuffer)}.
* Refer to {@link NioSocketChannel#doWrite(ChannelOutboundBuffer)} for an example.
* </p>
* @param maxCount The maximum amount of buffers that will be added to the return value.
* @param maxBytes A hint toward the maximum number of bytes to include as part of the return value. Note that this
* value maybe exceeded because we make a best effort to include at least 1 {@link ByteBuffer}
* in the return value to ensure write progress is made. */public ByteBuffer[] nioBuffers(int maxCount, long maxBytes) {assert maxCount > 0;assert maxBytes > 0;long nioBufferSize = 0;int nioBufferCount = 0;final InternalThreadLocalMap threadLocalMap = InternalThreadLocalMap.get();
ByteBuffer[] nioBuffers = NIO_BUFFERS.get(threadLocalMap);
Entry entry = flushedEntry;while (isFlushedEntry(entry) && entry.msg instanceof ByteBuf) {if (!entry.cancelled) {
ByteBuf buf = (ByteBuf) entry.msg;final int readerIndex = buf.readerIndex();final int readableBytes = buf.writerIndex() - readerIndex;if (readableBytes > 0) {if (maxBytes - readableBytes < nioBufferSize && nioBufferCount != 0) {// If the nioBufferSize + readableBytes will overflow maxBytes, and there is at least one entry// we stop populate the ByteBuffer array. This is done for 2 reasons:// 1. bsd/osx don't allow to write more bytes then Integer.MAX_VALUE with one writev(...) call// and so will return 'EINVAL', which will raise an IOException. On Linux it may work depending// on the architecture and kernel but to be safe we also enforce the limit here.// 2. There is no sense in putting more data in the array than is likely to be accepted by the// OS.//// See also:// - https://www.freebsd.org/cgi/man.cgi?query=write&sektion=2// - http://linux.die.net/man/2/writevbreak;
}
nioBufferSize += readableBytes;int count = entry.count;if (count == -1) {//noinspection ConstantValueVariableUseentry.count = count = buf.nioBufferCount();
}int neededSpace = min(maxCount, nioBufferCount + count);if (neededSpace > nioBuffers.length) {
nioBuffers = expandNioBufferArray(nioBuffers, neededSpace, nioBufferCount);
NIO_BUFFERS.set(threadLocalMap, nioBuffers);
}if (count == 1) {
ByteBuffer nioBuf = entry.buf;if (nioBuf == null) {// cache ByteBuffer as it may need to create a new ByteBuffer instance if its a// derived bufferentry.buf = nioBuf = buf.internalNioBuffer(readerIndex, readableBytes);
}
nioBuffers[nioBufferCount++] = nioBuf;
} else {
ByteBuffer[] nioBufs = entry.bufs;if (nioBufs == null) {// cached ByteBuffers as they may be expensive to create in terms// of Object allocationentry.bufs = nioBufs = buf.nioBuffers();
}for (int i = 0; i < nioBufs.length && nioBufferCount < maxCount; ++i) {
ByteBuffer nioBuf = nioBufs[i];if (nioBuf == null) {break;
} else if (!nioBuf.hasRemaining()) {continue;
}
nioBuffers[nioBufferCount++] = nioBuf;
}
}if (nioBufferCount == maxCount) {break;
}
}
}
entry = entry.next;
}this.nioBufferCount = nioBufferCount;this.nioBufferSize = nioBufferSize;return nioBuffers;
}// 未写完数据的处理: 注册OP_WRITE事件让后续eventloop处理// io.netty.channel.nio.AbstractNioByteChannel#incompleteWriteprotected final void incompleteWrite(boolean setOpWrite) {// Did not write completely.if (setOpWrite) {
setOpWrite();
} else {// It is possible that we have set the write OP, woken up by NIO because the socket is writable, and then// use our write quantum. In this case we no longer want to set the write OP because the socket is still// writable (as far as we know). We will find out next time we attempt to write if the socket is writable// and set the write OP if necessary. clearOpWrite();// Schedule flush again later so other tasks can be picked up in the meantime eventLoop().execute(flushTask);
}
}// io.netty.channel.nio.AbstractNioByteChannel#setOpWriteprotected final void setOpWrite() {final SelectionKey key = selectionKey();// Check first if the key is still valid as it may be canceled as part of the deregistration// from the EventLoop// See https://github.com/netty/netty/issues/2104if (!key.isValid()) {return;
}final int interestOps = key.interestOps();// 如果数据未被写完整,则主动注册写事件监听,让 eventloop 去处理if ((interestOps & SelectionKey.OP_WRITE) == 0) {
key.interestOps(interestOps | SelectionKey.OP_WRITE);
}
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