概念
网络编程知识
- DNS域名系统(属于应用层):用于将域名解析成IP(单域名解析多IP可实现负载均衡)
- IP网际互连协议:用于实现广域网中的数据传输(ip是根据网络拓扑分配的,解决我在哪的问题)
- MAC:用于实现局域网中的数据传输(mac是由网卡制造商分配的,解决我是谁的问题)
- ARP地址解析协议:映射Mac地址与IP地址的协议 - 核心①映射缓存 ②ARP请求广播(用于构建映射缓存)
- TCP协议:三次握手和四次挥手
- SSL安全套接字协议:加密 ①客户端hello ②服务端hello+证书+验证性加密数据 ③客户端验证 + 密钥交换 + 验证性加密数据 ④服务端验证
- HTTP协议(应用层协议):
Socket 和 IO多路复用
Socket编程 - BIO(同步阻塞IO):每一个连接对应一个线程,执行Socket的读写操作均会阻塞线程
SocketChannel编程 - NIO(同步非阻塞IO):轮询 - 每一个请求对应一个线程,线程会阻塞在selector.select(),当出现活跃请求时,需轮询查找活跃请求并处理,O(n) 同步IO(需等待IO完成)
AsynchronousSocketChannel编程 - AIO(异步非阻塞IO):回调 - 每一个有效请求对应一个线程,当出现活跃请求时,直接调用请求对应的回调方法实现处理,O(1) 异步IO(Future实现)
select: 当事件发生,但不知道具体是哪个流,通过轮询查找,时间复杂度O(N)
poll: 作用等同于select,链表结构存储(无限大),通过轮询查找, 时间复杂度O(N)
epoll: 事件驱动,callback方式,时间复杂度O(1) – 采用mmap共享内存实现内核-用户空间的数据传递
demo
BIO
核心组件:①ServerSocket建立服务器监听,②Socket代表一个连接
阻塞IO,socket调用读写方法时,会进入阻塞,直到数据到达
public class ServerSocketDemo {
private static ExecutorService executors = Executors.newFixedThreadPool(4);
public static void main(String[] args) {
// 服务端开启Socket监听
try (ServerSocket serverSocket = new ServerSocket(8080);){
while(true){
// 当请求到达时,新建线程处理对应socket
Socket socket = serverSocket.accept();
executors.execute(()->ServerSocketHandler.handler(socket));
}
} catch (IOException e) {
e.printStackTrace();
}
}
}
public class ServerSocketHandler {
public static void handler(Socket socket){
// server中socket流的获取与client中流的获取顺序需相反(否则可能资源死等)
try (InputStream is = socket.getInputStream();
ObjectInputStream ois = new ObjectInputStream(is);
OutputStream os = socket.getOutputStream();
ObjectOutputStream oos = new ObjectOutputStream(os);)
{
// 读操作(在数据未到达之前将阻塞)
User msg = (User) ois.readObject();
System.out.println(Thread.currentThread().getName() + " - 读入:" + msg);
// 写操作
oos.writeObject(msg);
oos.flush();
} catch (IOException | ClassNotFoundException e) {
e.printStackTrace();
}
}
}
public class ClientSocketDemo {
public static void main(String[] args) {
// 客户端直接采用Socket建立连接
try(Socket socket = new Socket("localhost",8080);){
ClientSocketHandler.handler(socket);
} catch (IOException e) {
e.printStackTrace();
}
}
}
public class ClientSocketHandler {
public static void handler(Socket socket){
// server中socket流的获取与client中流的获取顺序需相反(否则可能资源死等)
try (OutputStream os = socket.getOutputStream();
ObjectOutputStream oos = new ObjectOutputStream(os);
InputStream is = socket.getInputStream();
ObjectInputStream ois = new ObjectInputStream(is);
){
// 写操作 - 执行操作也需相反。。。
oos.writeObject(new User("kiqi",18));
oos.flush();
// 读操作
User msg = (User) ois.readObject();
System.out.println("客户端 - 读入:" + msg);
Thread.sleep(1000);
} catch (IOException | ClassNotFoundException | InterruptedException e) {
e.printStackTrace();
}
}
}
NIO
核心组件:①selector,用于判断是否存在活跃事件 ②ServerSocketChannel,用于连接事件通道 ③SocketChannel,用于读写事件通道 ④register(selector, SelectionKey.OP_ACCEPT);
非阻塞IO,将socketChannel与相应事件注册到selector,当出现活跃事件时,selector.select()将解除阻塞,通过轮询获取并处理已经到达的事件(只能做到存在活跃事件,不知道具体是哪一个)
public class ServerSocketChannelDemo {
private static Selector selector;
public static void main(String[] args) {
try {
// 开启selector功能(底层由操作系统提供支持 select,poll或epoll)
selector = Selector.open();
// ServerSocketChannel,开启服务端口监听
ServerSocketChannel channel = ServerSocketChannel.open();
channel.configureBlocking(false);
channel.socket().bind(new InetSocketAddress(8080));
// 将ServerSocketChannel与对应事件绑定到selector,当事件发生时,selector.select()将接触阻塞
channel.register(selector, SelectionKey.OP_ACCEPT);
while (true){
// 阻塞,直到出现活跃事件
selector.select();
// 无法获知具体事件,需轮询判断
Set<SelectionKey> selectionKeySet = selector.selectedKeys();
Iterator<SelectionKey> iterator = selectionKeySet.iterator();
while (iterator.hasNext()){
SelectionKey selectionKey = iterator.next();
iterator.remove();
// 链接事件
if(selectionKey.isAcceptable()){
handleAccept(selectionKey);
// 读事件
}else if(selectionKey.isReadable()){
handleRead(selectionKey);
((SocketChannel)selectionKey.channel()).write(ByteBuffer.wrap("server_msg - 啥玩意啊,这么难用".getBytes()));
}
}
}
} catch (IOException e) {
e.printStackTrace();
}
}
private static void handleAccept(SelectionKey selectionKey) {
// 处理连接事件,并将该连接通道的读事件注册到Selector
ServerSocketChannel serverSocketChannel = (ServerSocketChannel) selectionKey.channel();
try {
SocketChannel channel = serverSocketChannel.accept();
channel.configureBlocking(false);
channel.register(selector,SelectionKey.OP_READ);
} catch (IOException e) {
e.printStackTrace();
}
}
private static void handleRead(SelectionKey selectionKey) {
// 处理读事件
SocketChannel channel = (SocketChannel) selectionKey.channel();
ByteBuffer byteBuffer = ByteBuffer.allocate(1024);
try {
channel.read(byteBuffer);
System.out.println("Server - 嘛玩意啊,超级难用 - " + new String(byteBuffer.array()));
} catch (IOException e) {
e.printStackTrace();
}
}
}
public class ClientSocketChannelDemo {
private static Selector selector;
public static void main(String[] args) {
try {
// 开启selector功能(底层由操作系统提供支持 select,poll或epoll)
selector = Selector.open();
// SocketChannel,建立连接通道
SocketChannel channel = SocketChannel.open();
channel.configureBlocking(false);
channel.connect(new InetSocketAddress("localhost",8080));
// 将连接事件注册到selector
channel.register(selector, SelectionKey.OP_CONNECT);
while (true) {
// 阻塞,直到连接事件成功
selector.select();
Set<SelectionKey> selectionKeySet = selector.selectedKeys();
Iterator<SelectionKey> iterator = selectionKeySet.iterator();
while (iterator.hasNext()) {
SelectionKey selectionKey = iterator.next();
iterator.remove();
// 连接就绪,处理连接事件
if (selectionKey.isConnectable()) {
handleConnect(selectionKey);
((SocketChannel)selectionKey.channel()).write(ByteBuffer.wrap("server_msg - 啥玩意啊,这么难用".getBytes()));
// 处理读事件
} else if (selectionKey.isReadable()) {
handleRead(selectionKey);
}
}
}
} catch (IOException e) {
e.printStackTrace();
}
}
private static void handleConnect(SelectionKey selectionKey) {
SocketChannel channel = (SocketChannel) selectionKey.channel();
try {
// 未调用channel.finishConnect()的连接,处于连接中,还无法进行读写
if(channel.isConnectionPending()){
channel.finishConnect();
}
channel.configureBlocking(false);
// 注册读事件
channel.register(selector,SelectionKey.OP_READ);
} catch (IOException e) {
e.printStackTrace();
}
}
private static void handleRead(SelectionKey selectionKey) {
// 处理读事件
SocketChannel channel = (SocketChannel) selectionKey.channel();
ByteBuffer byteBuffer = ByteBuffer.allocate(1024);
try {
channel.read(byteBuffer);
System.out.println("Client - 嘛玩意啊,超级难用 - " + new String(byteBuffer.array()));
} catch (IOException e) {
e.printStackTrace();
}
}
}
AIO
核心组件:①AsynchronousServerSocketChannel,用于建立服务器监听。 ②channel.accept(),接受连接, ③AsynchronousSocketChannel,用于处理连接的读写事件
④Future,用于异步等待IO完成 ⑤CompletionHandler接口,当IO完成后,执行的回调接口方法
异步非阻塞式IO,①提供了回调式处理,当活跃事件发生时,直接回调接口方法O(1) ②Future<?>异步IO(内部建立了内核空间与用户空间的内存)。
// AsynchronousSocketChannel代表一个连接,通过连接完成读写事件处理
// 方式一:CompletionHandler接口回调
public class AysnServerSocketChannelDemo {
public static void main(String[] args) throws InterruptedException {
try {
// 服务端建立端口监听
AsynchronousServerSocketChannel channel = AsynchronousServerSocketChannel.open();
channel.bind(new InetSocketAddress(8080));
// 接受连接事件,当事件发生并且执行完IO后,会回调CompletionHandler接口
channel.accept(null, new CompletionHandler<AsynchronousSocketChannel, Object>() {
@Override
public void completed(AsynchronousSocketChannel result, Object attachment) {
// 需再次开启接受连接事件
channel.accept(null, this);
// 处理已连接通道
handle(result);
}
// 失败时执行逻辑
@Override
public void failed(Throwable exc, Object attachment) {
exc.printStackTrace();
}
});
} catch (IOException e) {
e.printStackTrace();
}
Thread.sleep(100000);
}
public static void handle(AsynchronousSocketChannel channel) {
try {
final ByteBuffer buffer = ByteBuffer.allocate(1024);
final long timeout = 10L;
// 读事件,完成IO后回调CompletionHandler接口方法
channel.read(buffer, timeout, TimeUnit.SECONDS, null, new CompletionHandler<Integer, Object>() {
@Override
public void completed(Integer result, Object attachment) {
System.out.println("read:" + result);
if (result == -1) {
try {
channel.close();
} catch (IOException e) {
e.printStackTrace();
}
return;
}
buffer.flip();
System.out.println("received message:" + Charset.forName("UTF-8").decode(buffer));
buffer.clear();
channel.read(buffer, timeout, TimeUnit.SECONDS, null, this);
}
@Override
public void failed(Throwable exc, Object attachment) {
exc.printStackTrace();
}
});
} catch (Exception e) {
e.printStackTrace();
}
}
}
// 方式二:Future<?>.get()异步方法等待结果
public class AsynClientSocketChannelDemo {
private static AsynchronousSocketChannel client;
public static void main(String[] args) throws InterruptedException {
try {
// 创建连接通道并建立连接
client = AsynchronousSocketChannel.open();
Future<?> future = client.connect(new InetSocketAddress("localhost",8080));
// get()方法,等待连接完成
future.get();
// 执行读写时间
client.write(ByteBuffer.wrap("???".getBytes()));
} catch (IOException | InterruptedException | ExecutionException e) {
e.printStackTrace();
}
Thread.sleep(100000);
}
}