Java并发编程之ThreadLocal类

ThreadLocal类可以理解为ThreadLocalVariable(线程局部变量)提供了get与set等访问接口或方法,这些方法为每个使用该变量的线程都存有一份独立的副本,因此get总是返回当前执行线程在调用set时设置的最新值。可以将ThreadLocal<T>视为 包含了Map<Thread,T>对象,保存了特定于该线程的值。

概括起来说,对于多线程资源共享的问题,同步机制采用了以时间换空间的方式,而ThreadLocal采用了以空间换时间的方式。前者仅提供一份变量,让不同的线程排队访问,而后者为每一个线程都提供了一份变量,因此可以同时访问而互不影响。

模拟ThreadLocal

    import java.util.Collections;
    import java.util.HashMap;
    import java.util.Map;
     
    public class SimpleThreadLocal<T> {
    	private Map<Thread, T> valueMap = Collections
    			.synchronizedMap(new HashMap<Thread, T>());
     
    	public void set(T newValue) {
    		valueMap.put(Thread.currentThread(), newValue); // ①键为线程对象,值为本线程的变量副本
    	}
     
    	public T get() {
    		Thread currentThread = Thread.currentThread();
    		T o = valueMap.get(currentThread); // ②返回本线程对应的变量
    		if (o == null && !valueMap.containsKey(currentThread)) { // ③如果在Map中不存在,放到Map中保存起来。
    			o = initialValue();
    			valueMap.put(currentThread, o);
    		}
    		return o;
    	}
     
    	public void remove() {
    		valueMap.remove(Thread.currentThread());
    	}
     
    	protected T initialValue() {
    		return null;
    	}
    }
实用ThreadLocal

    class Count {
    	private SimpleThreadLocal<Integer> count = new SimpleThreadLocal<Integer>() {
    		@Override
    		protected Integer initialValue() {
    			return 0;
    		}
    	};
     
    	public Integer increase() {
    		count.set(count.get() + 1);
    		return count.get();
    	}
     
    }
     
    class TestThread implements Runnable {
    	private Count count;
     
    	public TestThread(Count count) {
    		this.count = count;
    	}
     
    	@Override
    	public void run() {
    		// TODO Auto-generated method stub
    		for (int i = 1; i <= 3; i++) {
    			System.out.println(Thread.currentThread().getName() + "\t" + i
    					+ "th\t" + count.increase());
    		}
    	}
    }
     
    public class TestThreadLocal {
    	public static void main(String[] args) {
    		Count count = new Count();
    		Thread t1 = new Thread(new TestThread(count));
    		Thread t2 = new Thread(new TestThread(count));
    		Thread t3 = new Thread(new TestThread(count));
    		Thread t4 = new Thread(new TestThread(count));
    		t1.start();
    		t2.start();
    		t3.start();
    		t4.start();
    	}
    }

输出
Thread-0    1th    1
Thread-0    2th    2
Thread-0    3th    3
Thread-3    1th    1
Thread-1    1th    1
Thread-1    2th    2
Thread-2    1th    1
Thread-1    3th    3
Thread-3    2th    2
Thread-3    3th    3
Thread-2    2th    2
Thread-2    3th    3  




posted @ 2015-03-16 20:20  Ydoing  阅读(463)  评论(0)    收藏  举报