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基于Java回顾之网络通信的应用分析

时间:2020-10-06 21:54:07 | 栏目:JAVA代码 | 点击:

TCP连接

TCP的基础是Socket,在TCP连接中,我们会使用ServerSocket和Socket,当客户端和服务器建立连接以后,剩下的基本就是对I/O的控制了。

我们先来看一个简单的TCP通信,它分为客户端和服务器端。

客户端代码如下:

复制代码 代码如下:

简单的TCP客户端
 import java.net.*;
 import java.io.*;
 public class SimpleTcpClient {

     public static void main(String[] args) throws IOException
     {
         Socket socket = null;
         BufferedReader br = null;
         PrintWriter pw = null;
         BufferedReader brTemp = null;
         try
         {
             socket = new Socket(InetAddress.getLocalHost(), 5678);
             br = new BufferedReader(new InputStreamReader(socket.getInputStream()));
             pw = new PrintWriter(socket.getOutputStream());
             brTemp = new BufferedReader(new InputStreamReader(System.in));
             while(true)
             {
                 String line = brTemp.readLine();
                 pw.println(line);
                 pw.flush();
                 if (line.equals("end")) break;
                 System.out.println(br.readLine());
             }
         }
         catch(Exception ex)
         {
             System.err.println(ex.getMessage());
         }
         finally
         {
             if (socket != null) socket.close();
             if (br != null) br.close();
             if (brTemp != null) brTemp.close();
             if (pw != null) pw.close();
         }
     }
 }

服务器端代码如下:
复制代码 代码如下:

简单版本TCP服务器端
 import java.net.*;
 import java.io.*;
 public class SimpleTcpServer {

     public static void main(String[] args) throws IOException
     {
         ServerSocket server = null;
         Socket client = null;
         BufferedReader br = null;
         PrintWriter pw = null;
         try
         {
             server = new ServerSocket(5678);
             client = server.accept();
             br = new BufferedReader(new InputStreamReader(client.getInputStream()));
             pw = new PrintWriter(client.getOutputStream());
             while(true)
             {
                 String line = br.readLine();
                 pw.println("Response:" + line);
                 pw.flush();
                 if (line.equals("end")) break;
             }
         }
         catch(Exception ex)
         {
             System.err.println(ex.getMessage());
         }
         finally
         {
             if (server != null) server.close();
             if (client != null) client.close();
             if (br != null) br.close();
             if (pw != null) pw.close();
         }
     }
 }

这里的服务器的功能非常简单,它接收客户端发来的消息,然后将消息“原封不动”的返回给客户端。当客户端发送“end”时,通信结束。

上面的代码基本上勾勒了TCP通信过程中,客户端和服务器端的主要框架,我们可以发现,上述的代码中,服务器端在任何时刻,都只能处理来自客户端的一个请求,它是串行处理的,不能并行,这和我们印象里的服务器处理方式不太相同,我们可以为服务器添加多线程,当一个客户端的请求进入后,我们就创建一个线程,来处理对应的请求。

改善后的服务器端代码如下:

复制代码 代码如下:

多线程版本的TCP服务器端
 import java.net.*;
 import java.io.*;
 public class SmartTcpServer {
     public static void main(String[] args) throws IOException
     {
         ServerSocket server = new ServerSocket(5678);
         while(true)
         {
             Socket client = server.accept();
             Thread thread = new ServerThread(client);
             thread.start();
         }
     }
 }

 class ServerThread extends Thread
 {
     private Socket socket = null;

     public ServerThread(Socket socket)
     {
         this.socket = socket;
     }

     public void run() {
         BufferedReader br = null;
         PrintWriter pw = null;
         try
         {
             br = new BufferedReader(new InputStreamReader(socket.getInputStream()));
             pw = new PrintWriter(socket.getOutputStream());
             while(true)
             {
                 String line = br.readLine();
                 pw.println("Response:" + line);
                 pw.flush();
                 if (line.equals("end")) break;
             }
         }
         catch(Exception ex)
         {
             System.err.println(ex.getMessage());
         }
         finally
         {
             if (socket != null)
                 try {
                     socket.close();
                 } catch (IOException e1) {
                     e1.printStackTrace();
                 }
             if (br != null)
                 try {
                     br.close();
                 } catch (IOException e) {
                     e.printStackTrace();
                 }
             if (pw != null) pw.close();
         }
     }
 }

修改后的服务器端,就可以同时处理来自客户端的多个请求了。

在编程的过程中,我们会有“资源”的概念,例如数据库连接就是一个典型的资源,为了提升性能,我们通常不会直接销毁数据库连接,而是使用数据库连接池的方式来对多个数据库连接进行管理,已实现重用的目的。对于Socket连接来说,它也是一种资源,当我们的程序需要大量的Socket连接时,如果每个连接都需要重新建立,那么将会是一件非常没有效率的做法。

和数据库连接池类似,我们也可以设计TCP连接池,这里的思路是我们用一个数组来维持多个Socket连接,另外一个状态数组来描述每个Socket连接是否正在使用,当程序需要Socket连接时,我们遍历状态数组,取出第一个没被使用的Socket连接,如果所有连接都在使用,抛出异常。这是一种很直观简单的“调度策略”,在很多开源或者商业的框架中(Apache/Tomcat),都会有类似的“资源池”。

TCP连接池的代码如下:

复制代码 代码如下:

一个简单的TCP连接池
 import java.net.*;
 import java.io.*;
 public class TcpConnectionPool {

     private InetAddress address = null;
     private int port;
     private Socket[] arrSockets = null;
     private boolean[] arrStatus = null;
     private int count;

     public TcpConnectionPool(InetAddress address, int port, int count)
     {
         this.address = address;
         this.port = port;
         this .count = count;
         arrSockets = new Socket[count];
         arrStatus = new boolean[count];

         init();
     }

     private void init()
     {
         try
         {
             for (int i = 0; i < count; i++)
             {
                 arrSockets[i] = new Socket(address.getHostAddress(), port);
                 arrStatus[i] = false;
             }
         }
         catch(Exception ex)
         {
             System.err.println(ex.getMessage());
         }
     }

     public Socket getConnection()
     {
         if (arrSockets == null) init();
         int i = 0;
         for(i = 0; i < count; i++)
         {
             if (arrStatus[i] == false)
             {
                 arrStatus[i] = true;
                 break;
             }
         }
         if (i == count) throw new RuntimeException("have no connection availiable for now.");

         return arrSockets[i];
     }

     public void releaseConnection(Socket socket)
     {
         if (arrSockets == null) init();
         for (int i = 0; i < count; i++)
         {
             if (arrSockets[i] == socket)
             {
                 arrStatus[i] = false;
                 break;
             }
         }
     }

     public void reBuild()
     {
         init();
     }

     public void destory()
     {
         if (arrSockets == null) return;

         for(int i = 0; i < count; i++)
         {
             try
             {
                 arrSockets[i].close();
             }
             catch(Exception ex)
             {
                 System.err.println(ex.getMessage());
                 continue;
             }
         }
     }
 }

UDP连接

UDP是一种和TCP不同的连接方式,它通常应用在对实时性要求很高,对准确定要求不高的场合,例如在线视频。UDP会有“丢包”的情况发生,在TCP中,如果Server没有启动,Client发消息时,会报出异常,但对UDP来说,不会产生任何异常。

UDP通信使用的两个类时DatagramSocket和DatagramPacket,后者存放了通信的内容。

下面是一个简单的UDP通信例子,同TCP一样,也分为Client和Server两部分,Client端代码如下:

复制代码 代码如下:

UDP通信客户端
 import java.net.*;
 import java.io.*;
 public class UdpClient {

     public static void main(String[] args)
     {
         try
         {
             InetAddress host = InetAddress.getLocalHost();
             int port = 5678;
             BufferedReader br = new BufferedReader(new InputStreamReader(System.in));
             while(true)
             {
                 String line = br.readLine();
                 byte[] message = line.getBytes();
                 DatagramPacket packet = new DatagramPacket(message, message.length, host, port);
                 DatagramSocket socket = new DatagramSocket();
                 socket.send(packet);
                 socket.close();
                 if (line.equals("end")) break;
             }
             br.close();
         }
         catch(Exception ex)
         {
             System.err.println(ex.getMessage());
         }
     }
 }

Server端代码如下:
复制代码 代码如下:

UDP通信服务器端
 import java.net.*;
 import java.io.*;
 public class UdpServer {

     public static void main(String[] args)
     {
         try
         {
             int port = 5678;
             DatagramSocket dsSocket = new DatagramSocket(port);
             byte[] buffer = new byte[1024];
             DatagramPacket packet = new DatagramPacket(buffer, buffer.length);
             while(true)
             {
                 dsSocket.receive(packet);
                 String message = new String(buffer, 0, packet.getLength());
                 System.out.println(packet.getAddress().getHostName() + ":" + message);
                 if (message.equals("end")) break;
                 packet.setLength(buffer.length);
             }
             dsSocket.close();
         }
         catch(Exception ex)
         {
             System.err.println(ex.getMessage());
         }
     }
 }

这里,我们也假设和TCP一样,当Client发出“end”消息时,认为通信结束,但其实这样的设计不是必要的,Client端可以随时断开,并不需要关心Server端状态。
多播(Multicast)

多播采用和UDP类似的方式,它会使用D类IP地址和标准的UDP端口号,D类IP地址是指224.0.0.0到239.255.255.255之间的地址,不包括224.0.0.0。

多播会使用到的类是MulticastSocket,它有两个方法需要关注:joinGroup和leaveGroup。

下面是一个多播的例子,Client端代码如下:

复制代码 代码如下:

多播通信客户端
 import java.net.*;
 import java.io.*;
 public class MulticastClient {

     public static void main(String[] args)
     {
         BufferedReader br = new BufferedReader(new InputStreamReader(System.in));
         try
         {
             InetAddress address = InetAddress.getByName("230.0.0.1");
             int port = 5678;
             while(true)
             {
                 String line = br.readLine();
                 byte[] message = line.getBytes();
                 DatagramPacket packet = new DatagramPacket(message, message.length, address, port);
                 MulticastSocket multicastSocket = new MulticastSocket();
                 multicastSocket.send(packet);
                 if (line.equals("end")) break;
             }
             br.close();
         }
         catch(Exception ex)
         {
             System.err.println(ex.getMessage());
         }
     }
 }

服务器端代码如下:
复制代码 代码如下:

多播通信服务器端
 import java.net.*;
 import java.io.*;
 public class MulticastServer {

     public static void main(String[] args)
     {
         int port = 5678;
         try
         {
             MulticastSocket multicastSocket = new MulticastSocket(port);
             InetAddress address = InetAddress.getByName("230.0.0.1");
             multicastSocket.joinGroup(address);
             byte[] buffer = new byte[1024];
             DatagramPacket packet = new DatagramPacket(buffer, buffer.length);
             while(true)
             {
                 multicastSocket.receive(packet);
                 String message = new String(buffer, packet.getLength());
                 System.out.println(packet.getAddress().getHostName() + ":" + message);
                 if (message.equals("end")) break;
                 packet.setLength(buffer.length);
             }
             multicastSocket.close();
         }
         catch(Exception ex)
         {
             System.err.println(ex.getMessage());
         }
     }
 }

NIO(New IO)

NIO是JDK1.4引入的一套新的IO API,它在缓冲区管理、网络通信、文件存取以及字符集操作方面有了新的设计。对于网络通信来说,NIO使用了缓冲区和通道的概念。

下面是一个NIO的例子,和我们上面提到的代码风格有很大的不同。

复制代码 代码如下:

NIO例子
 import java.io.*;
 import java.nio.*;
 import java.nio.channels.*;
 import java.nio.charset.*;
 import java.net.*;
 public class NewIOSample {

     public static void main(String[] args)
     {
         String host="127.0.0.1";
         int port = 5678;
         SocketChannel channel = null;
         try
         {
             InetSocketAddress address = new InetSocketAddress(host,port);
             Charset charset = Charset.forName("UTF-8");
             CharsetDecoder decoder = charset.newDecoder();
             CharsetEncoder encoder = charset.newEncoder();

             ByteBuffer buffer = ByteBuffer.allocate(1024);
             CharBuffer charBuffer = CharBuffer.allocate(1024);

             channel = SocketChannel.open();
             channel.connect(address);

             String request = "GET / \r\n\r\n";
             channel.write(encoder.encode(CharBuffer.wrap(request)));

             while((channel.read(buffer)) != -1)
             {
                 buffer.flip();
                 decoder.decode(buffer, charBuffer, false);
                 charBuffer.flip();
                 System.out.println(charBuffer);
                 buffer.clear();
                 charBuffer.clear();
             }
         }
         catch(Exception ex)
         {
             System.err.println(ex.getMessage());
         }
         finally
         {
             if (channel != null)
                 try {
                     channel.close();
                 } catch (IOException e) {
                     // TODO Auto-generated catch block
                     e.printStackTrace();
                 }
         }
     }
 }

上述代码会试图访问一个本地的网址,然后将其内容打印出来。

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