private final List defaultLocalAddresses =
new ArrayList();
private final List unmodifiableDefaultLocalAddresses =
Collections.unmodifiableList(defaultLocalAddresses);
private final Set boundAddresses =
new HashSet();
在调用bind或unbind方法时需要先获取绑定锁bindLock,具体的绑定操作还是在bind0这个方法中实现的。一旦绑定成功后,就会向服务监听者发出服务激活的事件(ServiceActivated),同理,解除绑定也是在unbind0这个方法中具体实现的。一旦解除绑定成功后,就会向服务监听者发出服务激活的事件(ServiceDeActivated)。
AbstractIoConnector类继承自AbstractIoService基类,并实现了IoConnect接口,连接超时检查间隔时间默认是50毫秒,超时时间默认为1分钟,用户可以自行配置。此类中重要的方法就是connect方法,其中调用了具体的连接逻辑实现connect0,
protected abstract ConnectFuture connect0(SocketAddress remoteAddress,
SocketAddress localAddress, IoSessionInitializer sessionInitializer);
AbstractIoConnector在AbstractIoService的基础上,在会话初始化结束时增加了一个功能,就是加入了一个监听者,当连接请求被取消时立即结束此会话。
protected final void finishSessionInitialization0(
final IoSession session, IoFuture future) {
// In case that ConnectFuture.cancel() is invoked before
// setSession() is invoked, add a listener that closes the
// connection immediately on cancellation.
future.addListener(new IoFutureListener() {
public void operationComplete(ConnectFuture future) {
if (future.isCanceled()) {
session.close();
}
}
});
}
下面再来看一个IoProcessor接口的基本实现类SimpleIoProcessorPool,它的泛型参数是AbstractIoSession的子类,表示此Processor管理的具体会话类型。并且这个类还实现了池化,它会将多个IoSession分布到多个IoProcessor上去管理。下面是文档中给出的一个示例:
// Create a shared pool. SimpleIoProcessorPoolpool = new SimpleIoProcessorPool (NioProcessor.class, 16); // Create two services that share the same pool. SocketAcceptor acceptor = new NioSocketAcceptor(pool); SocketConnector connector = new NioSocketConnector(pool); // Release related resources. connector.dispose(); acceptor.dispose(); pool.dispose();
与Processor池有关的包括如下这些成员变量:
private static final int DEFAULT_SIZE = Runtime.getRuntime().availableProcessors() + 1;//处理池大小,默认是处理器数+1, 便于多核分布处理
private final IoProcessor[] pool;//IoProcessor池
private final AtomicInteger processorDistributor = new AtomicInteger();
Processor池的构造过程,其中有三种构造函数供选择来构造一个Processor :
1. 带参数 ExecutorService 的构造函数.
2. 带参数为 Executor的构造函数.
3. 默认构造函数
pool = new IoProcessor[size];//构建池
boolean success = false;
try {
for (int i = 0; i < pool.length; i ++) {
IoProcessor processor = null;
//有三种构造函数供选择来构造一个Processor
try {
try {
processor = processorType.getConstructor(ExecutorService.class).newInstance(executor);
} catch (NoSuchMethodException e) {
// To the next step
}
if (processor == null) {
try {
processor = processorType.getConstructor(Executor.class).newInstance(executor);
} catch (NoSuchMethodException e) {
// To the next step
}
}
if (processor == null) {
try {
processor = processorType.getConstructor().newInstance();
} catch (NoSuchMethodException e) {
// To the next step
}
}
} catch (RuntimeException e) {
throw e;
} catch (Exception e) {
throw new RuntimeIoException(
"Failed to create a new instance of " + processorType.getName(), e);
}
pool[i] = processor;
}
success = true;
} finally {
if (!success) {
dispose();
}
}
从Processor池中分配一个processor的过程,注意一个processor是可以同时管理多个session的。
private IoProcessorgetProcessor(T session) {//返回session所在的processor,若没分配,则为之分配一个 IoProcessor p = (IoProcessor ) session.getAttribute(PROCESSOR);//看session的属性中是否保存对应的Processor if (p == null) {//还没为此session分配processor p = nextProcessor();//从池中取一个processor IoProcessor oldp = (IoProcessor ) session.setAttributeIfAbsent(PROCESSOR, p); if (oldp != null) {//原来的processor p = oldp; } } return p; } private IoProcessor nextProcessor() {//从池中分配一个Processor checkDisposal(); return pool[Math.abs(processorDistributor.getAndIncrement()) % pool.length]; }
作者:phinecos(洞庭散人)
出处:http://phinecos.cnblogs.com/