分布式锁
实现原理:有序节点+watch监听机制实现
分布式锁有多种实现方式,比如通过数据库、redis都可实现。作为分布式协同工具Zookeeper,当然也有着标准的实现方式。下面介绍在zookeeper
设计思路
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每个客户端往
/Locks下创建临时有序节点/Locks/Lock_,创建成功后/Locks下面会有每个客户端对应的节点,如/Locks/Lock_000000001 -
客户端取得/Locks下子节点,并进行排序,判断排在前面的是否为自己,如果自己的锁节点在第一位,代表获取锁成功
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如果自己的锁节点不在第一位,则监听自己前一位的锁节点。例如,自己锁节点
Lock_000000002,那么则监听Lock_000000001 -
当前一位锁节点
(Lock_000000001)对应的客户端执行完成,释放了锁,将会触发监听客户端(Lock_000000002)的逻辑 -
监听客户端重新执行第
2步逻辑,判断自己是否获得了锁 - zookeeper是有工具包的(这里采用手写)
// 线程测试类 public class ThreadTest { public static void delayOperation(){ try { TimeUnit.SECONDS.sleep(5); } catch (InterruptedException e) { e.printStackTrace(); } } static interface Runable{ void run(); } public static void run(Runable runable,int threadNum){ ThreadPoolExecutor threadPoolExecutor = new ThreadPoolExecutor(30, 30, 0, TimeUnit.SECONDS, new ArrayBlockingQueue<>(10)); for (int i = 0; i < threadNum; i++) { threadPoolExecutor.execute(runable::run); } threadPoolExecutor.shutdown(); } public static void main(String[] args) { // DistributedLock distributedLock = new DistributedLock(); // distributedLock.acquireLock(); // delayOperation(); // distributedLock.releaseLock(); DateTimeFormatter dateTimeFormatter = DateTimeFormatter.ofPattern("yyyy-MM-dd HH:mm:ss"); // 每秒打印信息 run(() -> { for (int i = 0; i < 999999999; i++) { try { TimeUnit.SECONDS.sleep(1); } catch (InterruptedException e) { e.printStackTrace(); } String format = dateTimeFormatter.format(LocalDateTime.now()); System.out.println(format); } },1); // 线程测试 run(() -> { DistributedLock distributedLock = new DistributedLock(); distributedLock.acquireLock(); delayOperation(); distributedLock.releaseLock(); },30); } } public class DistributedLock { private String IP = "192.168.133.133:2181"; private final String ROOT_LOCK = "/Root_Lock"; private final String LOCK_PREFIX = "/Lock_"; private final CountDownLatch countDownLatch = new CountDownLatch(1); private final byte[] DATA = new byte[0]; private ZooKeeper zookeeper; private String path; private void init(){ // 初始化 try { zookeeper = new ZooKeeper(IP, 200000, w -> { if(w.getState() == Watcher.Event.KeeperState.SyncConnected){ System.out.println("连接成功"); } countDownLatch.countDown(); }); countDownLatch.await(); } catch (IOException | InterruptedException e) { e.printStackTrace(); } } // 暴露的外部方法,主逻辑 public void acquireLock(){ init(); createLock(); attemptLock(); } // 暴露的外部方法,主逻辑 public void releaseLock(){ try { zookeeper.delete(path,-1); System.out.println("锁释放了" + path); } catch (InterruptedException | KeeperException e) { e.printStackTrace(); } } private void createLock(){ try { // 创建一个目录节点 Stat root = zookeeper.exists(ROOT_LOCK, false); if(root == null) zookeeper.create(ROOT_LOCK, DATA, ZooDefs.Ids.OPEN_ACL_UNSAFE, CreateMode.PERSISTENT); // 目录下创建子节点 path = zookeeper.create(ROOT_LOCK + LOCK_PREFIX, DATA, ZooDefs.Ids.OPEN_ACL_UNSAFE, CreateMode.EPHEMERAL_SEQUENTIAL); } catch (KeeperException | InterruptedException e) { e.printStackTrace(); } } private Watcher watcher = new Watcher() { @Override public void process(WatchedEvent watchedEvent) { if (watchedEvent.getType() == Event.EventType.NodeDeleted){ synchronized (this){ this.notifyAll(); } } } }; private void attemptLock(){ try { // 获取正在排队的节点,由于是zookeeper生成的临时节点,不会出错,这里不能加监视器 // 因为添加了监视器后,任何子节点的变化都会触发监视器 List<String> nodes = zookeeper.getChildren(ROOT_LOCK,false); nodes.sort(String::compareTo); // 获取自身节点的排名 int ranking = nodes.indexOf(path.substring(ROOT_LOCK.length() + 1)); // 已经是最靠前的节点了,获取锁 if(ranking == 0){ return; }else { // 并不是靠前的锁,监视自身节点的前一个节点 Stat status = zookeeper.exists(ROOT_LOCK+"/"+nodes.get(ranking - 1), watcher); // 有可能这这个判断的瞬间,0号完成了操作(此时我们应该判断成功自旋才对),但是上面的status变量已经获取了值并且不为空,1号沉睡 // 但是,请注意自行测试,虽然1号表面上沉睡了,但是实际上watcher.wait()是瞬间唤醒的 if(status == null){ attemptLock(); }else { synchronized (watcher){ watcher.wait(); } attemptLock(); } } } catch (KeeperException | InterruptedException e) { e.printStackTrace(); } } }