Redisson 实现分布式锁的高性机制如下：

测试代码

下面我们将以一个秒杀的例子来说明：

下面是模拟一个商品秒杀的场景，示例代码如下：

public class RedissonTest {

public static void main(String[] args) {

//1. 配置部分

Config config = new Config();

String address = "redis://127.0.0.1:6379";

SingleServerConfig serverConfig = config.useSingleServer();

serverConfig.setAddress(address);

serverConfig.setDatabase(0);

config.setLockWatchdogTimeout(5000);

Redisson redisson = (Redisson) Redisson.create(config);

RLock rLock = redisson.getLock("goods:1000:1");

//2. 加锁

rLock.lock();

try {

System.out.println("todo 逻辑处理 1000000.");

} finally {

if (rLock.isLocked() && rLock.isHeldByCurrentThread()) {

//3. 解锁

rLock.unlock();

}

}

}

rLock.lock();​是加锁的亿华云核心代码，我们一起来看看调用栈

加锁的核心方法是：​org.redisson.RedissonLock#tryLockInnerAsync

RFuture tryLockInnerAsync(long waitTime, long leaseTime, TimeUnit unit, long threadId, RedisStrictCommand command) {

return evalWriteAsync(getRawName(), LongCodec.INSTANCE, command,

"if (redis.call(exists, KEYS[1]) == 0) then " +

"redis.call(hincrby, KEYS[1], ARGV[2], 1); " +

"redis.call(pexpire, KEYS[1], ARGV[1]); " +

"return nil; " +

"end; " +

"if (redis.call(hexists, KEYS[1], ARGV[2]) == 1) then " +

"redis.call(hincrby, KEYS[1], ARGV[2], 1); " +

"redis.call(pexpire, KEYS[1], ARGV[1]); " +

"return nil; " +

"end; " +

"return redis.call(pttl, KEYS[1]);",

Collections.singletonList(getRawName()), unit.toMillis(leaseTime), getLockName(threadId));

其实它的本质是调用一段 LUA 脚本进行加锁， 需要注意的是这个地方使用的数据类型是 hash。这里是用 hash 的好处就是可以通过同一个 key 来存储重入的 tid

锁的续期是在 org.redisson.RedissonLock#tryAcquireAsync​方法中调用 scheduleExpirationRenewal实现的。

续期需要注意的是，看门狗是设置在主线程的延迟队列的线程中。

这里的好处就是如果我在一个进程中，同时加了 1000 把锁，我们不需要启动 1000 个子线程去续期，只需要创建 1000 个续期任务对象即可，在到达续期时间才会唤醒续期线程。免费信息发布网

tryAcquireAsync 代码如下：

private RFuture tryAcquireAsync(long waitTime, long leaseTime, TimeUnit unit, long threadId) {

RFuture ttlRemainingFuture;

if (leaseTime != -1) {

ttlRemainingFuture = tryLockInnerAsync(waitTime, leaseTime, unit, threadId, RedisCommands.EVAL_LONG);

} else {

ttlRemainingFuture = tryLockInnerAsync(waitTime, internalLockLeaseTime,

TimeUnit.MILLISECONDS, threadId, RedisCommands.EVAL_LONG);

}

CompletionStagef = ttlRemainingFuture.thenApply(ttlRemaining -> {

// lock acquired

if (ttlRemaining == null) {

if (leaseTime != -1) {

internalLockLeaseTime = unit.toMillis(leaseTime);

} else {

// 锁过期时间续期

scheduleExpirationRenewal(threadId);

}

}

return ttlRemaining;

});

return new CompletableFutureWrapper<>(f);

锁续期 scheduleExpirationRenewal代码如下：

protected void scheduleExpirationRenewal(long threadId) {

ExpirationEntry entry = new ExpirationEntry();

ExpirationEntry oldEntry = EXPIRATION_RENEWAL_MAP.putIfAbsent(getEntryName(), entry);

if (oldEntry != null) {

oldEntry.addThreadId(threadId);

} else {

entry.addThreadId(threadId);

try {

renewExpiration();

} finally {

if (Thread.currentThread().isInterrupted()) {

cancelExpirationRenewal(threadId);

}

}

}

然后在调用 renewExpiration(); 执行续期逻辑, 其实这里是一个定时任务 + 递归的方式实现续期的，用定时任务的好处就是不用去开 N 个字线程，只需要创建对应的任务对象即可。

备注：如果超级极端的情况下 N 把锁，同时加锁，同时需求。我们可以考虑在锁的有效期上，给它加一个浮动时间比如 100 - 500ms. 这样就能一定程度上避免 （参考的是缓存失效/击穿的解决方案）

private void renewExpiration() {

ExpirationEntry ee = EXPIRATION_RENEWAL_MAP.get(getEntryName());

if (ee == null) {

return;

}

// 创建延迟任务

Timeout task = commandExecutor.getConnectionManager().newTimeout(new TimerTask() {

@Override

public void run(Timeout timeout) throws Exception {

ExpirationEntry ent = EXPIRATION_RENEWAL_MAP.get(getEntryName());

if (ent == null) {

return;

}

Long threadId = ent.getFirstThreadId();

if (threadId == null) {

return;

}

// 真正的续期，调用 LUA 脚本续期

RFuture future = renewExpirationAsync(threadId);

future.whenComplete((res, e) -> {

if (e != null) {

log.error("Cant update lock " + getRawName() + " expiration", e);

EXPIRATION_RENEWAL_MAP.remove(getEntryName());

return;

}

// 如果续期成功

if (res) {

// reschedule itself

renewExpiration();

} else {

cancelExpirationRenewal(null);

}

});

}

}, internalLockLeaseTime / 3, TimeUnit.MILLISECONDS);

ee.setTimeout(task);

这里还有一个小的点，就是续期的时间是 1/3 为什么呢？保证在下次续期的时候锁不过期，如果是 1/2 可能在下次定时任务执行的时候 key 已经过期，如果小于 1/3 会导致频繁续期，任务代价/收益比不高。

renewExpirationAsync方法, 里面还是WordPress模板一段 LUA 脚本，进行重新设置锁的过期时间。

protected RFuture renewExpirationAsync(long threadId) {

return evalWriteAsync(getRawName(), LongCodec.INSTANCE, RedisCommands.EVAL_BOOLEAN,

"if (redis.call(hexists, KEYS[1], ARGV[2]) == 1) then " +

"redis.call(pexpire, KEYS[1], ARGV[1]); " +

"return 1; " +

"end; " +

"return 0;",

Collections.singletonList(getRawName()),

internalLockLeaseTime, getLockName(threadId));

org.redisson.RedissonLock#lock(long, java.util.concurrent.TimeUnit, boolean)​在执行获取锁失败的时候，会进入重试。其实这里就会执行 18 行以后的 while (true)逻辑

private void lock(long leaseTime, TimeUnit unit, boolean interruptibly) throws InterruptedException {

long threadId = Thread.currentThread().getId();

Long ttl = tryAcquire(-1, leaseTime, unit, threadId);

// lock acquired

if (ttl == null) {

return;

}

// 订阅锁过期的消息

CompletableFuture future = subscribe(threadId);

RedissonLockEntry entry;

if (interruptibly) {

entry = commandExecutor.getInterrupted(future);

} else {

entry = commandExecutor.get(future);

}

try {

while (true) {

ttl = tryAcquire(-1, leaseTime, unit, threadId);

// lock acquired

if (ttl == null) {

break;

}

// waiting for message

if (ttl >= 0) {

try {

// 阻塞锁的超时时间，等锁过期后再尝试加锁

entry.getLatch().tryAcquire(ttl, TimeUnit.MILLISECONDS);

} catch (InterruptedException e) {

if (interruptibly) {

throw e;

}

entry.getLatch().tryAcquire(ttl, TimeUnit.MILLISECONDS);

}

} else {

if (interruptibly) {

entry.getLatch().acquire();

} else {

entry.getLatch().acquireUninterruptibly();

}

}

}

} finally {

unsubscribe(entry, threadId);

}

// get(lockAsync(leaseTime, unit));

entry.getLatch().tryAcquire(ttl, TimeUnit.MILLISECONDS);​其实这里就是一个间歇性自旋。等到上次锁过期的时间，在唤醒进行抢锁 entry.getLatch().acquire();

还有一个逻辑就是

CompletableFuture future = subscribe(threadId);

这里其实是会订阅一个消息，如果解锁过后，会发布解锁的消息。然后再唤醒当前多次竞争锁进入休眠的线程。

rLock.unlock(); 的核心就是释放锁，撤销续期和唤醒在等待加锁的线程（发布解锁成功消息）。

核心方法（解锁）： org.redisson.RedissonLock#unlockInnerAsync

protected RFuture unlockInnerAsync(long threadId) {

return evalWriteAsync(getRawName(), LongCodec.INSTANCE, RedisCommands.EVAL_BOOLEAN,

"if (redis.call(hexists, KEYS[1], ARGV[3]) == 0) then " +

"return nil;" +

"end; " +

"local counter = redis.call(hincrby, KEYS[1], ARGV[3], -1); " +

"if (counter > 0) then " +

"redis.call(pexpire, KEYS[1], ARGV[2]); " +

"return 0; " +

"else " +

"redis.call(del, KEYS[1]); " +

// 发布解锁成功消息

"redis.call(publish, KEYS[2], ARGV[1]); " +

"return 1; " +

"end; " +

"return nil;",

Arrays.asList(getRawName(), getChannelName()), LockPubSub.UNLOCK_MESSAGE, internalLockLeaseTime, getLockName(threadId));

还是 LUA 的执行方式。

核心方法 org.redisson.RedissonBaseLock#unlockAsync(long)

@Override

public RFuture unlockAsync(long threadId) {

// 解锁

RFuture future = unlockInnerAsync(threadId);

// 撤销续期

CompletionStagef = future.handle((opStatus, e) -> {

cancelExpirationRenewal(threadId);

if (e != null) {

throw new CompletionException(e);

}

if (opStatus == null) {

IllegalMonitorStateException cause = new IllegalMonitorStateException("attempt to unlock lock, not locked by current thread by node id: "

+ id + " thread-id: " + threadId);

throw new CompletionException(cause);

}

return null;

});

return new CompletableFutureWrapper<>(f);

在 org.redisson.pubsub.LockPubSub#onMessage中回去唤醒阻塞的线程，让执行前面的锁自旋逻辑，具体代码如下：

@Override

protected void onMessage(RedissonLockEntry value, Long message) {

if (message.equals(UNLOCK_MESSAGE)) {

Runnable runnableToExecute = value.getListeners().poll();

if (runnableToExecute != null) {

runnableToExecute.run();

}

value.getLatch().release();

} else if (message.equals(READ_UNLOCK_MESSAGE)) {

while (true) {

Runnable runnableToExecute = value.getListeners().poll();

if (runnableToExecute == null) {

break;

}

runnableToExecute.run();

}

value.getLatch().release(value.getLatch().getQueueLength());

}