ChannelPipeline在Netty中是用来处理请求的责任链,默认实现是DefaultChannelPipeline,其构造方法如下:

 1 private final Channel channel;
 2 private final ChannelFuture succeededFuture;
 3 private final VoidChannelPromise voidPromise;
 4 final AbstractChannelHandlerContext head;
 5 final AbstractChannelHandlerContext tail;
 6 
 7 protected DefaultChannelPipeline(Channel channel) {
 8     this.channel = (Channel)ObjectUtil.checkNotNull(channel, "channel");
 9     this.succeededFuture = new SucceededChannelFuture(channel, (EventExecutor)null);
10     this.voidPromise = new VoidChannelPromise(channel, true);
11     this.tail = new DefaultChannelPipeline.TailContext(this);
12     this.head = new DefaultChannelPipeline.HeadContext(this);
13     this.head.next = this.tail;
14     this.tail.prev = this.head;
15 }

ChannelPipeline和Channel是一一对应关系,一个Channel绑定一条ChannelPipeline责任链
succeededFuture 和voidPromise用来处理异步操作
AbstractChannelHandlerContext 是持有请求的上下文对象,其和ChannelHandler是对应关系(在使用Sharable注解的情况下,不同的AbstractChannelHandlerContext 还可以对应同一个ChannelHandler),ChannelPipeline责任链
处理的就AbstractChannelHandlerContext ,再将最后的AbstractChannelHandlerContext 交给ChannelHandler去做正真的逻辑处理

AbstractChannelHandlerContext构造方法如下:

 1 private final String name;
 2 private final DefaultChannelPipeline pipeline;
 3 final EventExecutor executor;
 4 private final boolean inbound;
 5 private final boolean outbound;
 6 private final boolean ordered;
 7 volatile AbstractChannelHandlerContext next;
 8 volatile AbstractChannelHandlerContext prev;
 9 
10 AbstractChannelHandlerContext(DefaultChannelPipeline pipeline, EventExecutor executor, String name, boolean inbound, boolean outbound) {
11     this.name = (String)ObjectUtil.checkNotNull(name, "name");
12     this.pipeline = pipeline;
13     this.executor = executor;
14     this.inbound = inbound;
15     this.outbound = outbound;
16     this.ordered = executor == null || executor instanceof OrderedEventExecutor;
17 }

name是AbstractChannelHandlerContext的名称,pipeline就是上面说的ChannelPipeline;executor是用来进行异步操作的,默认使用的是在前面博客中说过的NioEventLoop  (Netty中NioEventLoopGroup的创建源码分析

inbound 和outbound 代表两种请求处理方式,对应Netty中的I/O操作,若是inbound则处理Input操作,由ChannelPipeline从head 开始向后遍历链表,并且只处理ChannelInboundHandler类型的AbstractChannelHandlerContext;若是outbound 则处理Output操作,由ChannelPipeline从tail开始向前遍历链表,并且只处理ChannelOutboundHandler类型的AbstractChannelHandlerContext;
ordered 是判断是否需要提供executor。

由next和prev成员可以知道,ChannelPipeline维护的是一条AbstractChannelHandlerContext的双向链表
其头节点head和尾节点tail分别默认初始化了HeadContext和TailContext

HeadContext的构造:

1 final class HeadContext extends AbstractChannelHandlerContext implements ChannelOutboundHandler, ChannelInboundHandler {
2     private final Unsafe unsafe;
3     
4     HeadContext(DefaultChannelPipeline pipeline) {
5     super(pipeline, (EventExecutor)null, DefaultChannelPipeline.HEAD_NAME, false, true);
6     this.unsafe = pipeline.channel().unsafe();
7     this.setAddComplete();
8     }
9 }

其中setAddComplete是由AbstractChannelHandlerContext实现的:

1 final void setAddComplete() {
2     int oldState;
3     do {
4         oldState = this.handlerState;
5     } while(oldState != 3 && !HANDLER_STATE_UPDATER.compareAndSet(this, oldState, 2));
6 
7 }

handlerState表示AbstractChannelHandlerContext对应的ChannelHandler的状态,有一下几种:

1 private static final int ADD_PENDING = 1;
2 private static final int ADD_COMPLETE = 2;
3 private static final int REMOVE_COMPLETE = 3;
4 private static final int INIT = 0;
5 private volatile int handlerState = 0;    

handlerState初始化默认是INIT状态。

HANDLER_STATE_UPDATER是一个原子更新器:

1 private static final AtomicIntegerFieldUpdater<AbstractChannelHandlerContext> HANDLER_STATE_UPDATER = AtomicIntegerFieldUpdater.newUpdater(AbstractChannelHandlerContext.class, "handlerState");

所以setAddComplete方法,就是通过CAS操作,将handlerState状态更新为ADD_COMPLETE

TailContext的构造:

1 final class TailContext extends AbstractChannelHandlerContext implements ChannelInboundHandler {
2     TailContext(DefaultChannelPipeline pipeline) {
3         super(pipeline, (EventExecutor)null, DefaultChannelPipeline.TAIL_NAME, true, false);
4         this.setAddComplete();
5     }
6 }

和HeadContext一样,将handlerState状态更新为ADD_COMPLETE

结合官方给出的ChannelPipeline的图示更容易理解:

 1                                              I/O Request
 2                                         via Channel or
 3                                     ChannelHandlerContext
 4                                                   |
 5 +---------------------------------------------------+---------------+
 6 |                           ChannelPipeline         |               |
 7 |                                                  \|/              |
 8 |    +---------------------+            +-----------+----------+    |
 9 |    | Inbound Handler  N  |            | Outbound Handler  1  |    |
10 |    +----------+----------+            +-----------+----------+    |
11 |              /|\                                  |               |
12 |               |                                  \|/              |
13 |    +----------+----------+            +-----------+----------+    |
14 |    | Inbound Handler N-1 |            | Outbound Handler  2  |    |
15 |    +----------+----------+            +-----------+----------+    |
16 |              /|\                                  .               |
17 |               .                                   .               |
18 | ChannelHandlerContext.fireIN_EVT() ChannelHandlerContext.OUT_EVT()|
19 |        [ method call]                       [method call]         |
20 |               .                                   .               |
21 |               .                                  \|/              |
22 |    +----------+----------+            +-----------+----------+    |
23 |    | Inbound Handler  2  |            | Outbound Handler M-1 |    |
24 |    +----------+----------+            +-----------+----------+    |
25 |              /|\                                  |               |
26 |               |                                  \|/              |
27 |    +----------+----------+            +-----------+----------+    |
28 |    | Inbound Handler  1  |            | Outbound Handler  M  |    |
29 |    +----------+----------+            +-----------+----------+    |
30 |              /|\                                  |               |
31 +---------------+-----------------------------------+---------------+
32               |                                  \|/
33 +---------------+-----------------------------------+---------------+
34 |               |                                   |               |
35 |       [ Socket.read() ]                    [ Socket.write() ]     |
36 |                                                                   |
37 |  Netty Internal I/O Threads (Transport Implementation)            |
38 +-------------------------------------------------------------------+

 

下面对一些主要方法分析:
addFirst方法,有如下几种重载:

 1 public final ChannelPipeline addFirst(ChannelHandler handler) {
 2     return this.addFirst((String)null, (ChannelHandler)handler);
 3 }
 4 
 5 public final ChannelPipeline addFirst(String name, ChannelHandler handler) {
 6     return this.addFirst((EventExecutorGroup)null, name, handler);
 7 }
 8 
 9 public final ChannelPipeline addFirst(ChannelHandler... handlers) {
10     return this.addFirst((EventExecutorGroup)null, (ChannelHandler[])handlers);
11 }
12 
13 public final ChannelPipeline addFirst(EventExecutorGroup executor, ChannelHandler... handlers) {
14     if (handlers == null) {
15         throw new NullPointerException("handlers");
16     } else if (handlers.length != 0 && handlers[0] != null) {
17         int size;
18         for(size = 1; size < handlers.length && handlers[size] != null; ++size) {
19             ;
20         }
21 
22         for(int i = size - 1; i >= 0; --i) {
23             ChannelHandler h = handlers[i];
24             this.addFirst(executor, (String)null, h);
25         }
26 
27         return this;
28     } else {
29         return this;
30     }
31 }
32 
33 public final ChannelPipeline addFirst(EventExecutorGroup group, String name, ChannelHandler handler) {
34     final AbstractChannelHandlerContext newCtx;
35     synchronized(this) {
36         checkMultiplicity(handler);
37         name = this.filterName(name, handler);
38         newCtx = this.newContext(group, name, handler);
39         this.addFirst0(newCtx);
40         if (!this.registered) {
41             newCtx.setAddPending();
42             this.callHandlerCallbackLater(newCtx, true);
43             return this;
44         }
45 
46         EventExecutor executor = newCtx.executor();
47         if (!executor.inEventLoop()) {
48             newCtx.setAddPending();
49             executor.execute(new Runnable() {
50                 public void run() {
51                     DefaultChannelPipeline.this.callHandlerAdded0(newCtx);
52                 }
53             });
54             return this;
55         }
56     }
57 
58     this.callHandlerAdded0(newCtx);
59     return this;
60 }

前面几种都是间接调用的第四种没什么好说的,直接看第四种addFirst
首先调用checkMultiplicity,检查ChannelHandlerAdapter在不共享的情况下是否重复:

 1 private static void checkMultiplicity(ChannelHandler handler) {
 2     if (handler instanceof ChannelHandlerAdapter) {
 3         ChannelHandlerAdapter h = (ChannelHandlerAdapter)handler;
 4         if (!h.isSharable() && h.added) {
 5             throw new ChannelPipelineException(h.getClass().getName() + " is not a @Sharable handler, so can't be added or removed multiple times.");
 6         }
 7 
 8         h.added = true;
 9     }
10 
11 }

isSharable方法:

 1 public boolean isSharable() {
 2     Class<?> clazz = this.getClass();
 3     Map<Class<?>, Boolean> cache = InternalThreadLocalMap.get().handlerSharableCache();
 4     Boolean sharable = (Boolean)cache.get(clazz);
 5     if (sharable == null) {
 6         sharable = clazz.isAnnotationPresent(Sharable.class);
 7         cache.put(clazz, sharable);
 8     }
 9 
10     return sharable;
11 }

首先尝试从当前线程的InternalThreadLocalMap中获取handlerSharableCache,(InternalThreadLocalMap是在Netty中使用高效的FastThreadLocal替代JDK的ThreadLocal使用的 Netty中FastThreadLocal源码分析
InternalThreadLocalMap的handlerSharableCache方法:

1 public Map<Class<?>, Boolean> handlerSharableCache() {
2     Map<Class<?>, Boolean> cache = this.handlerSharableCache;
3     if (cache == null) {
4         this.handlerSharableCache = (Map)(cache = new WeakHashMap(4));
5     }
6 
7     return (Map)cache;
8 }

当当前线程的InternalThreadLocalMap中没有handlerSharableCache时,直接创建一个大小为4的WeakHashMap弱引用Map;

根据clazz从map中get,若是没有,需要检测当前clazz是否有Sharable注解,添加了Sharable注解的ChannelHandlerAdapter可以在不同Channel中共享使用一个单例,前提是确保线程安全;
之后会将该clazz以及是否实现Sharable注解的情况添加在cache缓存中;
其中ChannelHandler的added是用来标识是否添加过;

回到addFirst方法:
checkMultiplicity成功结束后,调用filterName方法,给当前要产生的AbstractChannelHandlerContext对象产生一个名称,
然后调用newContext方法,产生AbstractChannelHandlerContext对象:

1 private AbstractChannelHandlerContext newContext(EventExecutorGroup group, String name, ChannelHandler handler) {
2     return new DefaultChannelHandlerContext(this, this.childExecutor(group), name, handler);
3 }

这里实际上产生了一个DefaultChannelHandlerContext对象:

 1 final class DefaultChannelHandlerContext extends AbstractChannelHandlerContext {
 2     private final ChannelHandler handler;
 3 
 4     DefaultChannelHandlerContext(DefaultChannelPipeline pipeline, EventExecutor executor, String name, ChannelHandler handler) {
 5         super(pipeline, executor, name, isInbound(handler), isOutbound(handler));
 6         if (handler == null) {
 7             throw new NullPointerException("handler");
 8         } else {
 9             this.handler = handler;
10         }
11     }
12 
13     public ChannelHandler handler() {
14         return this.handler;
15     }
16 
17     private static boolean isInbound(ChannelHandler handler) {
18         return handler instanceof ChannelInboundHandler;
19     }
20 
21     private static boolean isOutbound(ChannelHandler handler) {
22         return handler instanceof ChannelOutboundHandler;
23     }
24 }

可以看到DefaultChannelHandlerContext 仅仅是将AbstractChannelHandlerContext和ChannelHandler封装了

在产生了DefaultChannelHandlerContext 对象后,调用addFirst0方法:

1 private void addFirst0(AbstractChannelHandlerContext newCtx) {
2     AbstractChannelHandlerContext nextCtx = this.head.next;
3     newCtx.prev = this.head;
4     newCtx.next = nextCtx;
5     this.head.next = newCtx;
6     nextCtx.prev = newCtx;
7 }

这里就是一个简单的双向链表的操作,将newCtx节点插入到了head后面

然后判断registered成员的状态:

1 private boolean registered;

在初始化时是false

registered若是false,首先调用AbstractChannelHandlerContext的setAddPending方法:

1 final void setAddPending() {
2    boolean updated = HANDLER_STATE_UPDATER.compareAndSet(this, 0, 1);
3 
4     assert updated;
5 
6 }

和前面说过的setAddComplete方法同理,通过CAS操作,将handlerState状态设置为ADD_PENDING
接着调用callHandlerCallbackLater方法:

 1 private void callHandlerCallbackLater(AbstractChannelHandlerContext ctx, boolean added) {
 2     assert !this.registered;
 3 
 4     DefaultChannelPipeline.PendingHandlerCallback task = added ? new DefaultChannelPipeline.PendingHandlerAddedTask(ctx) : new DefaultChannelPipeline.PendingHandlerRemovedTask(ctx);
 5     DefaultChannelPipeline.PendingHandlerCallback pending = this.pendingHandlerCallbackHead;
 6     if (pending == null) {
 7         this.pendingHandlerCallbackHead = (DefaultChannelPipeline.PendingHandlerCallback)task;
 8     } else {
 9         while(pending.next != null) {
10             pending = pending.next;
11         }
12 
13         pending.next = (DefaultChannelPipeline.PendingHandlerCallback)task;
14     }
15 
16 }

首先断言判断registered可能存在的多线程改变,然后根据added判断产生何种类型的PendingHandlerCallback
PendingHandlerCallback是用来处理ChannelHandler的两种回调,定义如下:

 1 private abstract static class PendingHandlerCallback implements Runnable {
 2     final AbstractChannelHandlerContext ctx;
 3     DefaultChannelPipeline.PendingHandlerCallback next;
 4 
 5     PendingHandlerCallback(AbstractChannelHandlerContext ctx) {
 6         this.ctx = ctx;
 7     }
 8 
 9     abstract void execute();
10 }

PendingHandlerAddedTask定义如下:

 1 private final class PendingHandlerAddedTask extends DefaultChannelPipeline.PendingHandlerCallback {
 2     PendingHandlerAddedTask(AbstractChannelHandlerContext ctx) {
 3         super(ctx);
 4     }
 5 
 6     public void run() {
 7         DefaultChannelPipeline.this.callHandlerAdded0(this.ctx);
 8     }
 9 
10     void execute() {
11         EventExecutor executor = this.ctx.executor();
12         if (executor.inEventLoop()) {
13             DefaultChannelPipeline.this.callHandlerAdded0(this.ctx);
14         } else {
15             try {
16                 executor.execute(this);
17             } catch (RejectedExecutionException var3) {
18                 if (DefaultChannelPipeline.logger.isWarnEnabled()) {
19                     DefaultChannelPipeline.logger.warn("Can't invoke handlerAdded() as the EventExecutor {} rejected it, removing handler {}.", new Object[]{executor, this.ctx.name(), var3});
20                 }
21 
22                 DefaultChannelPipeline.remove0(this.ctx);
23                 this.ctx.setRemoved();
24             }
25         }
26 
27     }
28 }

除去异常处理,无论是在execute方法还是在run方法中,主要核心是异步执行callHandlerAdded0方法:

 1 private void callHandlerAdded0(AbstractChannelHandlerContext ctx) {
 2     try {
 3         ctx.setAddComplete();
 4         ctx.handler().handlerAdded(ctx);
 5     } catch (Throwable var10) {
 6         boolean removed = false;
 7 
 8         try {
 9             remove0(ctx);
10 
11             try {
12                 ctx.handler().handlerRemoved(ctx);
13             } finally {
14                 ctx.setRemoved();
15             }
16 
17             removed = true;
18         } catch (Throwable var9) {
19             if (logger.isWarnEnabled()) {
20                 logger.warn("Failed to remove a handler: " + ctx.name(), var9);
21             }
22         }
23 
24         if (removed) {
25             this.fireExceptionCaught(new ChannelPipelineException(ctx.handler().getClass().getName() + ".handlerAdded() has thrown an exception; removed.", var10));
26         } else {
27             this.fireExceptionCaught(new ChannelPipelineException(ctx.handler().getClass().getName() + ".handlerAdded() has thrown an exception; also failed to remove.", var10));
28         }
29     }
30 
31 }

除去异常处理,主要核心就两行代码,首先通过setAddComplete方法,设置handlerState状态为ADD_COMPLETE,然后回调ChannelHandler的handlerAdded方法,这个handlerAdded方法就很熟悉了,在使用Netty处理业务逻辑时,会覆盖这个方法。

PendingHandlerRemovedTask定义如下:

 1 private final class PendingHandlerRemovedTask extends DefaultChannelPipeline.PendingHandlerCallback {
 2     PendingHandlerRemovedTask(AbstractChannelHandlerContext ctx) {
 3         super(ctx);
 4     }
 5 
 6     public void run() {
 7         DefaultChannelPipeline.this.callHandlerRemoved0(this.ctx);
 8     }
 9 
10     void execute() {
11         EventExecutor executor = this.ctx.executor();
12         if (executor.inEventLoop()) {
13             DefaultChannelPipeline.this.callHandlerRemoved0(this.ctx);
14         } else {
15             try {
16                 executor.execute(this);
17             } catch (RejectedExecutionException var3) {
18                 if (DefaultChannelPipeline.logger.isWarnEnabled()) {
19                     DefaultChannelPipeline.logger.warn("Can't invoke handlerRemoved() as the EventExecutor {} rejected it, removing handler {}.", new Object[]{executor, this.ctx.name(), var3});
20                 }
21 
22                 this.ctx.setRemoved();
23             }
24         }
25 
26     }
27 }

和PendingHandlerAddedTask一样,主要还是异步调用callHandlerRemoved0方法:

 1 private void callHandlerRemoved0(AbstractChannelHandlerContext ctx) {
 2     try {
 3         try {
 4             ctx.handler().handlerRemoved(ctx);
 5         } finally {
 6             ctx.setRemoved();
 7         }
 8     } catch (Throwable var6) {
 9         this.fireExceptionCaught(new ChannelPipelineException(ctx.handler().getClass().getName() + ".handlerRemoved() has thrown an exception.", var6));
10     }
11 
12 }

首先直接回调ChannelHandler的handlerRemoved方法,然后通过setRemoved方法将handlerState状态设置为REMOVE_COMPLETE

回到callHandlerCallbackLater,其中成员pendingHandlerCallbackHead定义:

1 private DefaultChannelPipeline.PendingHandlerCallback pendingHandlerCallbackHead;

结合PendingHandlerCallback 可知,这个pendingHandlerCallbackHead是 DefaultChannelPipeline存储的一条PendingHandlerCallback单链表,用来处理ChannelHandler的handlerAdded和handlerRemoved的回调,在add的这些方法里调用callHandlerCallbackLater时,added参数都为true,所以add的ChannelHandler只向pendingHandlerCallbackHead添加了handlerAdded的回调。

回到addFirst方法,若是registered为true,先获取EventExecutor,判断是否处于轮询中,若不是,则需要开启轮询线程直接异步执行callHandlerAdded0方法,若处于轮询,由于ChannelPipeline的调用是发生在轮询时的,所以还是直接异步执行callHandlerAdded0方法。

addFirst方法到此结束,再来看addLast方法,同样有好几种重载:

 1 public final ChannelPipeline addLast(ChannelHandler handler) {
 2     return this.addLast((String)null, (ChannelHandler)handler);
 3 }
 4 
 5 public final ChannelPipeline addLast(String name, ChannelHandler handler) {
 6     return this.addLast((EventExecutorGroup)null, name, handler);
 7 }
 8 
 9 public final ChannelPipeline addLast(ChannelHandler... handlers) {
10     return this.addLast((EventExecutorGroup)null, (ChannelHandler[])handlers);
11 }
12 
13 public final ChannelPipeline addLast(EventExecutorGroup executor, ChannelHandler... handlers) {
14     if (handlers == null) {
15         throw new NullPointerException("handlers");
16     } else {
17         ChannelHandler[] var3 = handlers;
18         int var4 = handlers.length;
19 
20         for(int var5 = 0; var5 < var4; ++var5) {
21             ChannelHandler h = var3[var5];
22             if (h == null) {
23                 break;
24             }
25 
26             this.addLast(executor, (String)null, h);
27         }
28 
29         return this;
30     }
31 }
32 
33 public final ChannelPipeline addLast(EventExecutorGroup group, String name, ChannelHandler handler) {
34     final AbstractChannelHandlerContext newCtx;
35     synchronized(this) {
36         checkMultiplicity(handler);
37         newCtx = this.newContext(group, this.filterName(name, handler), handler);
38         this.addLast0(newCtx);
39         if (!this.registered) {
40             newCtx.setAddPending();
41             this.callHandlerCallbackLater(newCtx, true);
42             return this;
43         }
44 
45         EventExecutor executor = newCtx.executor();
46         if (!executor.inEventLoop()) {
47             newCtx.setAddPending();
48             executor.execute(new Runnable() {
49                 public void run() {
50                     DefaultChannelPipeline.this.callHandlerAdded0(newCtx);
51                 }
52             });
53             return this;
54         }
55     }
56 
57     this.callHandlerAdded0(newCtx);
58     return this;
59 }

还是间接调用最后一种:
对比addFirst来看,只有addLast0不一样:

1 private void addLast0(AbstractChannelHandlerContext newCtx) {
2     AbstractChannelHandlerContext prev = this.tail.prev;
3     newCtx.prev = prev;
4     newCtx.next = this.tail;
5     prev.next = newCtx;
6     this.tail.prev = newCtx;
7 }

还是非常简单的双向链表基本操作,只不过这次,是将AbstractChannelHandlerContext插入到了tail之前
还有两个,addBefore和addAfter方法,和上述方法类似,就不再累赘

接下来看看ChannelPipeline是如何完成请求的传递的:
invokeHandlerAddedIfNeeded方法:

1 final void invokeHandlerAddedIfNeeded() {
2     assert this.channel.eventLoop().inEventLoop();
3 
4     if (this.firstRegistration) {
5         this.firstRegistration = false;
6         this.callHandlerAddedForAllHandlers();
7     }
8 
9 }

断言判断是否处于轮询线程(ChannelPipeline处理请求都是在轮询线程中,都需要异步处理)
其中firstRegistration成员在DefaultChannelPipeline初始化时为true:

1 private boolean firstRegistration = true;

此时设置为false,表示第一次调用,以后都不再调用后面的callHandlerAddedForAllHandlers:

 1 private void callHandlerAddedForAllHandlers() {
 2     DefaultChannelPipeline.PendingHandlerCallback pendingHandlerCallbackHead;
 3     synchronized(this) {
 4         assert !this.registered;
 5 
 6         this.registered = true;
 7         pendingHandlerCallbackHead = this.pendingHandlerCallbackHead;
 8         this.pendingHandlerCallbackHead = null;
 9     }
10 
11     for(DefaultChannelPipeline.PendingHandlerCallback task = pendingHandlerCallbackHead; task != null; task = task.next) {
12         task.execute();
13     }
14 
15 }

刚才说过registered初始是false,在这里判断符合,之后就令其为true,然后获取处理ChannelHandler的回调链表pendingHandlerCallbackHead,并且将pendingHandlerCallbackHead置为null
然后遍历这个单链表,处理ChannelHandler的handlerAdded和handlerRemoved的回调

fireChannelRegistered方法,当Channel完成了向Selector的注册后,会由channel的Unsafe进行回调,异步处理:

1 public final ChannelPipeline fireChannelRegistered() {
2     AbstractChannelHandlerContext.invokeChannelRegistered(this.head);
3     return this;
4 }

实际上的处理由AbstractChannelHandlerContext的静态方法invokeChannelRegistered完成,这里传递的参数head就是DefaultChannelPipeline初始化时创建的HeadContext:

 1 static void invokeChannelRegistered(final AbstractChannelHandlerContext next) {
 2     EventExecutor executor = next.executor();
 3     if (executor.inEventLoop()) {
 4         next.invokeChannelRegistered();
 5     } else {
 6         executor.execute(new Runnable() {
 7             public void run() {
 8                 next.invokeChannelRegistered();
 9             }
10         });
11     }
12 
13 }

可以看到实际上是异步执行head对象的invokeChannelRegistered方法:

 1 private void invokeChannelRegistered() {
 2     if (this.invokeHandler()) {
 3         try {
 4             ((ChannelInboundHandler)this.handler()).channelRegistered(this);
 5         } catch (Throwable var2) {
 6             this.notifyHandlerException(var2);
 7         }
 8     } else {
 9         this.fireChannelRegistered();
10     }
11 
12 }

其中invokeHandler是用来判断当前的handlerState状态:

1 private boolean invokeHandler() {
2     int handlerState = this.handlerState;
3     return handlerState == 2 || !this.ordered && handlerState == 1;
4 }

若是当前handlerState状态为ADD_COMPLETE,或者不需要提供EventExecutor并且状态为ADD_PENDING时返回true,否则返回false
在成立的情况下,调用ChannelInboundHandler的channelRegistered方法,由于当前是head,所以由HeadContext实现了:

1 public void channelRegistered(ChannelHandlerContext ctx) throws Exception {
2     DefaultChannelPipeline.this.invokeHandlerAddedIfNeeded();
3     ctx.fireChannelRegistered();
4 }

首先调用invokeHandlerAddedIfNeeded,处理ChannelHandler的handlerAdded和handlerRemoved的回调
然后调用ctx的fireChannelRegistered方法:

1 public ChannelHandlerContext fireChannelRegistered() {
2     invokeChannelRegistered(this.findContextInbound());
3     return this;
4 }

findContextInbound方法,用来找出下一个ChannelInboundInvoker:

1 private AbstractChannelHandlerContext findContextInbound() {
2     AbstractChannelHandlerContext ctx = this;
3 
4     do {
5         ctx = ctx.next;
6     } while(!ctx.inbound);
7 
8     return ctx;
9 }

从当前节点向后遍历,inbound之前说过,该方法就是找到下一个ChannelInboundInvoker的类型的AbstractChannelHandlerContext,然后调用静态方法invokeChannelRegistered,重复上述操作,若是在ChannelInboundHandler中没有重写channelRegistered方法,会一直执直到完所有ChannelHandler的channelRegistered方法。
ChannelInboundHandlerAdapter中的默认channelRegistered方法:

1 public void channelRegistered(ChannelHandlerContext ctx) throws Exception {
2     ctx.fireChannelRegistered();
3 }

比HeadContext中的实现还简单,直接调用fireChannelRegistered向后传递

fireChannelRead方法,是在Selector轮循到读事件就绪,会由channel的Unsafe进行回调,异步处理:

1 public final ChannelPipeline fireChannelRead(Object msg) {
2     AbstractChannelHandlerContext.invokeChannelRead(this.head, msg);
3     return this;
4 }

还是从head开始调用AbstractChannelHandlerContext的静态方法invokeChannelRead:

 1 static void invokeChannelRead(final AbstractChannelHandlerContext next, Object msg) {
 2     final Object m = next.pipeline.touch(ObjectUtil.checkNotNull(msg, "msg"), next);
 3     EventExecutor executor = next.executor();
 4     if (executor.inEventLoop()) {
 5         next.invokeChannelRead(m);
 6     } else {
 7         executor.execute(new Runnable() {
 8             public void run() {
 9                 next.invokeChannelRead(m);
10             }
11         });
12     }
13 
14 }

和上面一个逻辑异步调用AbstractChannelHandlerContext对象的invokeChannelRead方法:

 1 private void invokeChannelRead(Object msg) {
 2     if (this.invokeHandler()) {
 3         try {
 4             ((ChannelInboundHandler)this.handler()).channelRead(this, msg);
 5         } catch (Throwable var3) {
 6             this.notifyHandlerException(var3);
 7         }
 8     } else {
 9         this.fireChannelRead(msg);
10     }
11 
12 }

这里也和上面一样,调用了HeadContext的channelRead方法:

1 public void channelRead(ChannelHandlerContext ctx, Object msg) throws Exception {
2     ctx.fireChannelRead(msg);
3 }

这里直接不处理,调用ChannelHandlerContext 的fireChannelRead方法:

1 public ChannelHandlerContext fireChannelRead(Object msg) {
2     invokeChannelRead(this.findContextInbound(), msg);
3     return this;
4 }

和之前注册一样,选择下一个ChannelInboundHandler,重复执行上述操作。

再来看到writeAndFlush方法,和上面的就不太一样,这个发生在轮询前,用户通过channel来间接调用,在AbstractChannel中实现:

1 public ChannelFuture writeAndFlush(Object msg) {
2     return this.pipeline.writeAndFlush(msg);
3 }

实际上直接调用了DefaultChannelPipeline的writeAndFlush方法:

1 public final ChannelFuture writeAndFlush(Object msg) {
2     return this.tail.writeAndFlush(msg);
3 }

这里又有些不一样了,调用了tail的writeAndFlush方法,即TailContext的writeAndFlush,在AbstractChannelHandlerContext中实现:

1 public ChannelFuture writeAndFlush(Object msg) {
2     return this.writeAndFlush(msg, this.newPromise());
3 }

newPromise产生了一个ChannelPromise,用来处理异步事件的;实际上调用了writeAndFlush的重载:

 1 public ChannelFuture writeAndFlush(Object msg, ChannelPromise promise) {
 2     if (msg == null) {
 3         throw new NullPointerException("msg");
 4     } else if (this.isNotValidPromise(promise, true)) {
 5         ReferenceCountUtil.release(msg);
 6         return promise;
 7     } else {
 8         this.write(msg, true, promise);
 9         return promise;
10     }
11 }

继续调用write方法:

 1 private void write(Object msg, boolean flush, ChannelPromise promise) {
 2     AbstractChannelHandlerContext next = this.findContextOutbound();
 3     Object m = this.pipeline.touch(msg, next);
 4     EventExecutor executor = next.executor();
 5     if (executor.inEventLoop()) {
 6         if (flush) {
 7             next.invokeWriteAndFlush(m, promise);
 8         } else {
 9             next.invokeWrite(m, promise);
10         }
11     } else {
12         Object task;
13         if (flush) {
14             task = AbstractChannelHandlerContext.WriteAndFlushTask.newInstance(next, m, promise);
15         } else {
16             task = AbstractChannelHandlerContext.WriteTask.newInstance(next, m, promise);
17         }
18 
19         safeExecute(executor, (Runnable)task, promise, m);
20     }
21 
22 }

还是很相似,只不过先调用findContextOutbound找到下一个ChannelOutboundInvoker类型的ChannelHandlerContext,而且这里是从尾部往前遍历的,这样来看前面所给的图是没有任何问题的
在找到ChannelOutboundInvoker后,调用invokeWriteAndFlush或者invokeWrite方法:
invokeWriteAndFlush方法:

 1 private void invokeWriteAndFlush(Object msg, ChannelPromise promise) {
 2     if (this.invokeHandler()) {
 3         this.invokeWrite0(msg, promise);
 4         this.invokeFlush0();
 5     } else {
 6         this.writeAndFlush(msg, promise);
 7     }
 8 
 9 }
10 
11 private void invokeWrite0(Object msg, ChannelPromise promise) {
12     try {
13         ((ChannelOutboundHandler)this.handler()).write(this, msg, promise);
14     } catch (Throwable var4) {
15         notifyOutboundHandlerException(var4, promise);
16     }
17 
18 }
19 
20 private void invokeFlush0() {
21     try {
22         ((ChannelOutboundHandler)this.handler()).flush(this);
23     } catch (Throwable var2) {
24         this.notifyHandlerException(var2);
25     }
26 
27 }

可以看到invokeWriteAndFlush回调了ChannelOutboundHandler的write和flush方法

最终会调用HeadContext的write和flush方法:

1 public void write(ChannelHandlerContext ctx, Object msg, ChannelPromise promise) throws Exception {
2     this.unsafe.write(msg, promise);
3 }
4 
5 public void flush(ChannelHandlerContext ctx) throws Exception {
6     this.unsafe.flush();
7 }

可以看到调用了unsafe的write和flush方法,向unsafe缓冲区写入了消息,当Selector轮询到写事件就绪时,就会通过unsafe将刚才写入的内容交由JDK的SocketChannel完成最终的write操作。

ChannelPipeline的分析到此全部结束。

 

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