在java并发包中提供了若干锁的实现,它们是用于单个java虚拟机进程中的;而分布式锁能够在一组进程之间提供互斥机制,保证在任何时刻只有一个进程可以持有锁。
分布式环境中多个进程的锁则可以使用Zookeeper来实现。
下面这种方法是使用顺序节点实现共享锁,流程如下:
对于lock()操作,首先让所有参与争锁的客户端都在/_locks目录下创建临时顺序节点,然后获取该路径下的所有节点,如果客户端创建的节点序列号最小则获得锁。否则开始监视它前一个节点并进入等待状态。
对于unlock()操作,将自身创建的节点删除。此时后一个节点的监控将被触发,对应的客户端退出等待状态,取得锁。
下面是一个简单的示例:
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/** * 分布式锁 */ public class DisLock implements Watcher { public static final String LOCK_ROOT = "/__locks__"; private ZooKeeper zk; //锁名称,标识竞争的是哪个锁 private String lockName; //当前创建的节点路径 private String path; //前一个节点的路径 private String prePath; //是否获取锁 private boolean acquired; //构造函数,连接zk,检查父节点存在 public DisLock(String lockName) throws KeeperException, InterruptedException, IOException { this.lockName = "/" + lockName; this.zk = new ZooKeeper("localhost:2181", 30000, this); Assert.notNull(zk, "zookeeper is null"); if (zk.exists(LOCK_ROOT, false) == null) { zk.create(LOCK_ROOT, new byte[0], ZooDefs.Ids.OPEN_ACL_UNSAFE, CreateMode.PERSISTENT); } if (zk.exists(LOCK_ROOT + this.lockName, false) == null) { zk.create(LOCK_ROOT + this.lockName, new byte[0], ZooDefs.Ids.OPEN_ACL_UNSAFE, CreateMode.PERSISTENT); } } public void lock() { if (tryLock()) { return; } else { waitLock(); } } //尝试获取锁 public boolean tryLock() { if (acquired) { return true; } try { //创建临时节点,自动编号 path = zk.create(LOCK_ROOT + lockName + "/", new byte[0], ZooDefs.Ids.OPEN_ACL_UNSAFE, CreateMode.EPHEMERAL_SEQUENTIAL); List<String> ls = zk.getChildren(LOCK_ROOT + lockName, false); Collections.sort(ls); if (path.equals(LOCK_ROOT + lockName + "/" + ls.get(0))) { acquired = true; return true; } for (int i = 0; i < ls.size(); i++) { if (path.equals(LOCK_ROOT + lockName + "/" + ls.get(i))) { prePath = LOCK_ROOT + lockName + "/" + ls.get(i - 1); break; } } return false; } catch (KeeperException e) { e.printStackTrace(); } catch (InterruptedException e) { e.printStackTrace(); } return false; } //释放锁 public void unlock() { if (!acquired) { return; } try { zk.delete(path, -1); acquired = false; //System.out.println(Thread.currentThread().getName() + " free lock"); } catch (InterruptedException e) { e.printStackTrace(); } catch (KeeperException e) { e.printStackTrace(); } } //设置监控并等待锁,前一个节点被删除后退出等待,得到锁 private synchronized void waitLock() { try { Stat s = zk.exists(prePath, true); if (s == null) { //等到锁,返回 acquired = true; return; } this.wait(); } catch (InterruptedException e) { e.printStackTrace(); } catch (KeeperException e) { e.printStackTrace(); } waitLock(); return; } //监视节点变化,被监控节点被删除时激活等待锁的线程 @Override public synchronized void process(WatchedEvent watchedEvent) { if (watchedEvent.getType() == Event.EventType.NodeDeleted) { //System.out.println("触发:"+watchedEvent.getPath()); this.notify(); } } }
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其中waitLock和process方法需要加synchronized关键字,以便使用wait和notify方法。
测试方法:
Zookeeper的另一种应用场景是处理FIFO消息队列,利用zk的自动编号,存储数据和数据一致性能力,模拟生产者-消费者模型。
创建3个消费者从zk中获取数据,此时需要使用分布式锁,加锁获取数据的部分。出于模拟生产者和消费者都在不同的进程,所有不共享zk等对象。
示例代码如下:
生产者:
public class Producer extends Thread { private ZooKeeper zk; private Random ran = new Random(); private static AtomicInteger count = new AtomicInteger(0); Producer() throws IOException { this.zk = new ZooKeeper("localhost:2181", 30000, null); } void produce(String str) throws KeeperException, InterruptedException { String name = zk.create(ZkQueue.root + "/element", str.getBytes(), ZooDefs.Ids.OPEN_ACL_UNSAFE, CreateMode.PERSISTENT_SEQUENTIAL); //System.out.println(getName() + " create: " + str); } @Override public void run() { try { while (true) { String msg = "msg" + count.getAndIncrement(); produce(msg); Thread.sleep(ran.nextInt(1000)); } } catch (KeeperException e) { e.printStackTrace(); } catch (InterruptedException e) { e.printStackTrace(); } finally { } } }
---循环向zk中写入递增的信息,中间延迟随机毫秒
消费者:
public class Consumer extends Thread { private ZooKeeper zk; private DisLock lock; Consumer() throws IOException, KeeperException, InterruptedException { lock = new DisLock("queue"); this.zk = new ZooKeeper("localhost:2181", 30000, null); } private boolean consume() throws KeeperException, InterruptedException { lock.lock(); try { List<String> list = zk.getChildren(root, true); if (list.isEmpty()) { return true; } Collections.sort(list); String first = list.get(0); byte[] b = zk.getData(root + "/" + first, false, null); zk.delete(root + "/" + first, -1); String str = new String(b); System.out.println(getName() + " get:" + str); } finally { lock.unlock(); } return false; } @Override public void run() { try { while (true) { if (consume()) { Thread.sleep(1000); } } } catch (KeeperException e) { e.printStackTrace(); } catch (InterruptedException e) { e.printStackTrace(); } finally { } } }
---循环从zk中取节点然后删除节点,对整个过程加锁
启动类:
public class ZkQueue implements Watcher{ @Override public void process(WatchedEvent watchedEvent) { System.out.printf("---->%s %s ",watchedEvent.getPath(),watchedEvent.getType()); } private static ZooKeeper zk; public static final String root = "/zkqueue"; public static void main(String[] args) throws IOException, KeeperException, InterruptedException { zk = new ZooKeeper("localhost:2181", 30000, null); ZkUtils.delete(zk, "/__locks__/queue");//此处需保证该路径下没有子节点,否则可能获取到为最小 ZkUtils.delete(zk, root); zk.create(root, "queue".getBytes(), ZooDefs.Ids.OPEN_ACL_UNSAFE, CreateMode.PERSISTENT); //模拟2个生产者 new Producer().start(); new Producer().start(); //模拟3个消费者 new Consumer().start(); new Consumer().start(); new Consumer().start(); Scanner s = new Scanner(System.in); s.nextLine(); ZkUtils.delete(zk, root); // 关闭连接 zk.close(); } }
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输出结果:
Thread-2 get lock Thread-2 get:msg0 Thread-2 free lock Thread-3 get lock Thread-3 get:msg2 Thread-3 free lock Thread-2 get lock Thread-2 get:msg3 Thread-3 get lock Thread-2 free lock Thread-3 get:msg4 Thread-3 free lock Thread-2 get lock Thread-2 get:msg5 Thread-2 free lock Thread-4 get lock Thread-4 get:msg6 Thread-4 free lock Thread-3 get lock Thread-3 get:msg7 Thread-3 free lock Thread-2 get lock Thread-2 get:msg8 Thread-2 free lock Thread-4 get lock Thread-4 get:msg1 Thread-4 free lock Thread-3 get lock Thread-3 get:msg9 Thread-3 free lock Thread-2 get lock Thread-2 get:msg10 Thread-2 free lock Thread-4 get lock Thread-4 get:msg11 Thread-4 free lock Thread-3 get lock Thread-3 get:msg12 Thread-3 free lock Thread-2 get lock Thread-2 get:msg13 Thread-2 free lock Thread-4 get lock Thread-4 get:msg14 Thread-4 free lock Thread-3 get lock Thread-3 get:msg15 Thread-3 free lock Thread-2 get lock Thread-2 get:msg16 Thread-2 free lock Thread-4 get lock Thread-4 get:msg17 Thread-4 free lock Thread-3 get lock Thread-3 get:msg18 Thread-3 free lock Thread-2 get lock Thread-2 get:msg19 Thread-2 free lock Thread-4 get lock Thread-4 get:msg20 Thread-4 free lock Thread-3 get lock Thread-3 get:msg21 Thread-3 free lock Thread-2 get lock Thread-2 get:msg22 Thread-2 free lock Thread-4 get lock Thread-4 get:msg23 Thread-4 free lock Thread-3 get lock Thread-3 get:msg24 Thread-3 free lock Thread-2 get lock Thread-2 get:msg25 Thread-2 free lock Thread-4 get lock Thread-4 get:msg26 Thread-4 free lock Thread-3 get lock Thread-3 get:msg27 Thread-3 free lock Thread-2 get lock Thread-2 get:msg28 Thread-2 free lock Thread-4 get lock Thread-4 get:msg29 Thread-4 free lock Thread-3 get lock Thread-3 get:msg30 Thread-3 free lock Thread-2 get lock Thread-2 free lock Thread-4 get lock Thread-4 free lock Thread-3 get lock Thread-3 free lock Thread-2 get lock Thread-2 get:msg31 Thread-2 free lock Thread-2 get lock Thread-2 get:msg32 Thread-2 free lock Thread-2 get lock Thread-2 get:msg33 Thread-2 free lock Thread-4 get lock Thread-4 get:msg34 Thread-4 free lock Thread-3 get lock Thread-3 get:msg35 Thread-3 free lock Thread-2 get lock Thread-2 get:msg36 Thread-2 free lock Thread-4 get lock Thread-4 free lock Thread-3 get lock Thread-3 free lock Thread-2 get lock Thread-2 free lock Thread-4 get lock Thread-4 get:msg37 Thread-4 free lock Thread-2 get lock Thread-2 get:msg38 Thread-2 free lock Thread-3 get lock Thread-3 get:msg39 Thread-3 free lock Thread-4 get lock Thread-4 get:msg40 Thread-4 free lock Thread-2 get lock Thread-2 get:msg41 Thread-2 free lock Thread-3 get lock Thread-3 free lock Thread-4 get lock Thread-4 free lock Thread-2 get lock Thread-2 free lock Thread-4 get lock Thread-4 get:msg42 Thread-4 free lock Thread-2 get lock Thread-2 get:msg43 Thread-2 free lock Thread-3 get lock Thread-3 get:msg44 Thread-3 free lock Thread-4 get lock Thread-4 free lock Thread-2 get lock Thread-2 free lock Thread-3 get lock Thread-3 free lock Thread-4 get lock Thread-4 get:msg45 Thread-4 free lock ....
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可见3个消费者线程随机获取到锁,数据在锁中被递增取出,没有重复和遗漏
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