预想架构一个好的项目,必须清楚以下几点:
一、IT软件系统的架构强调的是解耦,构讹件式开发强调的是内聚和重用
IT系统需要不断优化重构(构件的替换或者整体项目升级)但是切记过度的重构和优化会适得其反
二、IT系统的内核
-------系统架构和核心技术
-------组件化开发,分布式架构
三、IT系统的裂变主要发生在需求调整和新技术的应用时
四、一般系统的架构分为:
系统接口区 数据服务区 核心功能区 构件访问区 场务控制区
五、核心业务引擎设计
主要分为两大类:
1、事件驱动
2、作业驱动
这样一来系统各个构件间通信可以通过(Active MQ)消息中间件来访问
六、潜意识的系统架构
util:工具层
web: web层
Job: 定时任务作业层
daemon:JDK守护进程层
stp: 通信协议层
Spi : 服务接口提供层(主要通过Provider提供一些服务接口出来,供外部系统访问)
近期通过对系统架构的专业学习,接下来鼠标给大家分享一个自己实现的RPC架构
该接口提供服务
public interface HelloService { String sayHi(String name);}接口的实现
服务中心代码的实现
public interface Server {
public void stop();
public void start() throws IOException;
public void register(Class serviceInterface, Class impl);
public boolean isRunning();
public int getPort();
}
public class ServiceCenter implements Server {
private static ExecutorService executor = Executors.newFixedThreadPool(Runtime.getRuntime().availableProcessors());
private static final HashMap<String, Class> serviceRegistry = new HashMap<String, Class>();
private static boolean isRunning = false;
private static int port;
public ServiceCenter(int port) {
this.port = port;
}
public void stop() {
isRunning = false;
executor.shutdown();
}
public void start() throws IOException {
ServerSocket server = new ServerSocket();
server.bind(new InetSocketAddress(port));
System.out.println("start server");
try {
while (true) {
// 1.监听客户端的TCP连接,接到TCP连接后将其封装成task,由线程池执行
executor.execute(new ServiceTask(server.accept()));
}
} finally {
server.close();
}
}
public void register(Class serviceInterface, Class impl) {
serviceRegistry.put(serviceInterface.getName(), impl);
}
public boolean isRunning() {
return isRunning;
}
public int getPort() {
return port;
}
private static class ServiceTask implements Runnable {
Socket clent = null;
public ServiceTask(Socket client) {
this.clent = client;
}
public void run() {
ObjectInputStream input = null;
ObjectOutputStream output = null;
try {
// 2.将客户端发送的码流反序列化成对象,反射调用服务实现者,获取执行结果
input = new ObjectInputStream(clent.getInputStream());
String serviceName = input.readUTF();
String methodName = input.readUTF();
Class<?>[] parameterTypes = (Class<?>[]) input.readObject();
Object[] arguments = (Object[]) input.readObject();
Class serviceClass = serviceRegistry.get(serviceName);
if (serviceClass == null) {
throw new ClassNotFoundException(serviceName + " not found");
}
Method method = serviceClass.getMethod(methodName, parameterTypes);
Object result = method.invoke(serviceClass.newInstance(), arguments);
// 3.将执行结果反序列化,通过socket发送给客户端
output = new ObjectOutputStream(clent.getOutputStream());
output.writeObject(result);
} catch (Exception e) {
e.printStackTrace();
} finally {
if (output != null) {
try {
output.close();
} catch (IOException e) {
e.printStackTrace();
}
}
if (input != null) {
try {
input.close();
} catch (IOException e) {
e.printStackTrace();
}
}
if (clent != null) {
try {
clent.close();
} catch (IOException e) {
e.printStackTrace();
}
}
}
}
}
}
public class RPCClient<T> {
public static <T> T getRemoteProxyObj(final Class<?> serviceInterface, final InetSocketAddress addr) {
// 1.将本地的接口调用转换成JDK的动态代理,在动态代理中实现接口的远程调用
return (T) Proxy.newProxyInstance(serviceInterface.getClassLoader(), new Class<?>[]{serviceInterface},
new InvocationHandler() {
public Object invoke(Object proxy, Method method, Object[] args) throws Throwable {
Socket socket = null;
ObjectOutputStream output = null;
ObjectInputStream input = null;
try {
// 2.创建Socket客户端,根据指定地址连接远程服务提供者
socket = new Socket();
socket.connect(addr);
// 3.将远程服务调用所需的接口类、方法名、参数列表等编码后发送给服务提供者
output = new ObjectOutputStream(socket.getOutputStream());
output.writeUTF(serviceInterface.getName());
output.writeUTF(method.getName());
output.writeObject(method.getParameterTypes());
output.writeObject(args);
// 4.同步阻塞等待服务器返回应答,获取应答后返回
input = new ObjectInputStream(socket.getInputStream());
return input.readObject();
} finally {
if (socket != null) socket.close();
if (output != null) output.close();
if (input != null) input.close();
}
}
});
}
}
public class RPCTest {
public static void main(String[] args) throws IOException {
new Thread(new Runnable() {
public void run() {
try {
Server serviceServer = new ServiceCenter(8088);
serviceServer.register(HelloService.class, HelloServiceImpl.class);
serviceServer.start();
} catch (IOException e) {
e.printStackTrace();
}
}
}).start();
HelloService service = RPCClient.getRemoteProxyObj(HelloService.class, new InetSocketAddress("localhost", 8088));
System.out.println(service.sayHi("test"));
}
}
最后为测试类:
这样一来一个简单的RPC架构就完成了。
其实到这里大家不难看清楚,RPC就是一个消息处理模型,它屏蔽了底层一些通信的细节,实现了调用远程服务就==调用本地服务一样
大家跟着鼠标来分析下:
最后送上一段经典代码:
/**
* @author shubiao
* @author Administrator
* @version 0.2.1.0
*/
public class Guard {
/*静态内部类单例实例*/
private Guard(){
};
private static class GuardHolder{
private static final Guard instance = new Guard();
}
public static final Guard me(){
return GuardHolder.instance;
}
//-------------------------------------
public static Guard build(){
return new Guard();
}
}