基于redis的分布式锁怎么实现
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基于redis的分布式锁
/** *分布式锁工厂类 */ public class RedisLockUtil { private static final Logger logger = Logger.getLogger(RedisLockUtil.class); private static Object schemeLock = new Object(); private static Mapinstances = new ConcurrentHashMap(); public static RedisLockUtil getInstance(String schema){ RedisLockUtil u = instances.get(schema); if(u==null){ synchronized(schemeLock){ u = instances.get(schema); if(u == null){ LockObserver lo = new LockObserver(schema); u = new RedisLockUtil(schema,lo); instances.put(schema, u); } } } return u; } private Object mutexLock = new Object(); private Map mutexLockMap = new ConcurrentHashMap(); private Map cache = new ConcurrentHashMap (); private DelayQueue dq = new DelayQueue (); private AbstractLockObserver lo; public RedisLockUtil(String schema, AbstractLockObserver lo){ Thread th = new Thread(lo); th.setDaemon(false); th.setName("Lock Observer:"+schema); th.start(); clearUselessLocks(schema); this.lo = lo; } public void clearUselessLocks(String schema){ Thread th = new Thread(new Runnable(){ @Override public void run() { while(!SystemExitListener.isOver()){ try { RedisReentrantLock t = dq.take(); if(t.clear()){ String key = t.getKey(); synchronized(getMutex(key)){ cache.remove(key); } } t.resetCleartime(); } catch (InterruptedException e) { } } } }); th.setDaemon(true); th.setName("Lock cleaner:"+schema); th.start(); } private Object getMutex(String key){ Object mx = mutexLockMap.get(key); if(mx == null){ synchronized(mutexLock){ mx = mutexLockMap.get(key); if(mx==null){ mx = new Object(); mutexLockMap.put(key,mx); } } } return mx; } private RedisReentrantLock getLock(String key,boolean addref){ RedisReentrantLock lock = cache.get(key); if(lock == null){ synchronized(getMutex(key)){ lock = cache.get(key); if(lock == null){ lock = new RedisReentrantLock(key,lo); cache.put(key, lock); } } } if(addref){ if(!lock.incRef()){ synchronized(getMutex(key)){ lock = cache.get(key); if(!lock.incRef()){ lock = new RedisReentrantLock(key,lo); cache.put(key, lock); } } } } return lock; } public void reset(){ for(String s : cache.keySet()){ getLock(s,false).unlock(); } } /** * 尝试加锁 * 如果当前线程已经拥有该锁的话,直接返回,表示不用再次加锁,此时不应该再调用unlock进行解锁 * * @param key * @return * @throws Exception * @throws InterruptedException * @throws KeeperException */ public LockStat lock(String key) { return lock(key,-1); } public LockStat lock(String key,int timeout) { RedisReentrantLock ll = getLock(key,true); ll.incRef(); try{ if(ll.isOwner(false)){ ll.descrRef(); return LockStat.NONEED; } if(ll.lock(timeout)){ return LockStat.SUCCESS; }else{ ll.descrRef(); if(ll.setCleartime()){ dq.put(ll); } return null; } }catch(LockNotExistsException e){ ll.descrRef(); return lock(key,timeout); }catch(RuntimeException e){ ll.descrRef(); throw e; } } public void unlock(String key,LockStat stat) { unlock(key,stat,false); } public void unlock(String key,LockStat stat,boolean keepalive){ if(stat == null) return; if(LockStat.SUCCESS.equals(stat)){ RedisReentrantLock lock = getLock(key,false); boolean candestroy = lock.unlock(); if(candestroy && !keepalive){ if(lock.setCleartime()){ dq.put(lock); } } } } public static enum LockStat{ NONEED, SUCCESS } }
/**
*分布式锁本地代理类
*/
public class RedisReentrantLock implements Delayed{
private static final Logger logger = Logger.getLogger(RedisReentrantLock.class);
private ReentrantLock reentrantLock = new ReentrantLock();
private RedisLock redisLock;
private long timeout = 3*60;
private CountDownLatch lockcount = new CountDownLatch(1);
private String key;
private AbstractLockObserver observer;
private int ref = 0;
private Object refLock = new Object();
private boolean destroyed = false;
private long cleartime = -1;
public RedisReentrantLock(String key,AbstractLockObserver observer) {
this.key = key;
this.observer = observer;
initWriteLock();
}
public boolean isDestroyed() {
return destroyed;
}
private synchronized void initWriteLock(){
redisLock = new RedisLock(key,new LockListener(){
@Override
public void lockAcquired() {
lockcount.countDown();
}
@Override
public long getExpire() {
return 0;
}
@Override
public void lockError() {
/*synchronized(mutex){
mutex.notify();
}*/
lockcount.countDown();
}
},observer);
}
public boolean incRef(){
synchronized(refLock){
if(destroyed) return false;
ref ++;
}
return true;
}
public void descrRef(){
synchronized(refLock){
ref --;
}
}
public boolean clear() {
if(destroyed) return true;
synchronized(refLock){
if(ref > 0){
return false;
}
destroyed = true;
redisLock.clear();
redisLock = null;
return true;
}
}
public boolean lock(long timeout) throws LockNotExistsException{
if(timeout <= 0) timeout = this.timeout;
//incRef();
reentrantLock.lock();//多线程竞争时,先拿到第一层锁
if(redisLock == null){
reentrantLock.unlock();
//descrRef();
throw new LockNotExistsException();
}
try{
lockcount = new CountDownLatch(1);
boolean res = redisLock.trylock(timeout);
if(!res){
lockcount.await(timeout, TimeUnit.SECONDS);
//mutex.wait(timeout*1000);
if(!redisLock.doExpire()){
reentrantLock.unlock();
return false;
}
}
return true;
}catch(InterruptedException e){
reentrantLock.unlock();
return false;
}
}
public boolean lock() throws LockNotExistsException {
return lock(timeout);
}
public boolean unlock(){
if(!isOwner(true)) {
try{
throw new RuntimeException("big ================================================ error.key:"+key);
}catch(Exception e){
logger.error("err:"+e,e);
}
return false;
}
try{
redisLock.unlock();
reentrantLock.unlock();//多线程竞争时,释放最外层锁
}catch(RuntimeException e){
reentrantLock.unlock();//多线程竞争时,释放最外层锁
throw e;
}finally{
descrRef();
}
return canDestroy();
}
public boolean canDestroy(){
synchronized(refLock){
return ref <= 0;
}
}
public String getKey() {
return key;
}
public void setKey(String key) {
this.key = key;
}
public boolean isOwner(boolean check) {
synchronized(refLock){
if(redisLock == null) {
logger.error("reidsLock is null:key="+key);
return false;
}
boolean a = reentrantLock.isHeldByCurrentThread();
boolean b = redisLock.isOwner();
if(check){
if(!a || !b){
logger.error(key+";a:"+a+";b:"+b);
}
}
return a && b;
}
}
public boolean setCleartime() {
synchronized(this){
if(cleartime>0) return false;
this.cleartime = System.currentTimeMillis() + 10*1000;
return true;
}
}
public void resetCleartime(){
synchronized(this){
this.cleartime = -1;
}
}
@Override
public int compareTo(Delayed object) {
if(object instanceof RedisReentrantLock){
RedisReentrantLock t = (RedisReentrantLock)object;
long l = this.cleartime - t.cleartime;
if(l > 0) return 1 ; //比当前的小则返回1,比当前的大则返回-1,否则为0
else if(l < 0 ) return -1;
else return 0;
}
return 0;
}
@Override
public long getDelay(TimeUnit unit) {
long d = unit.convert(cleartime - System.currentTimeMillis(), TimeUnit.MILLISECONDS);
return d;
}
}
/** *使用Redis实现的分布式锁 *基本工作原理如下: *1. 使用setnx(key,时间戮+超时),如果设置成功,则直接拿到锁 *2. 如果设置不成功,获取key的值v1(它的到期时间戮),跟当前时间对比,看是否已经超时 *3. 如果超时(说明拿到锁的结点已经挂掉),v2=getset(key,时间戮+超时+1),判断v2是否等于v1,如果相等,加锁成功,否则加锁失败,等过段时间再重试(200MS) */ public class RedisLock implements LockListener{ private String key; private boolean owner = false; private AbstractLockObserver observer = null; private LockListener lockListener = null; private boolean waiting = false; private long expire;//锁超时时间,以秒为单位 private boolean expired = false; public RedisLock(String key, LockListener lockListener, AbstractLockObserver observer) { this.key = key; this.lockListener = lockListener; this.observer = observer; } public boolean trylock(long expire) { synchronized(this){ if(owner){ return true; } this.expire = expire; this.expired = false; if(!waiting){ owner = observer.tryLock(key,expire); if(!owner){ waiting = true; observer.addLockListener(key, this); } } return owner; } } public boolean isOwner() { return owner; } public void unlock() { synchronized(this){ observer.unLock(key); owner = false; } } public void clear() { synchronized(this){ if(waiting) { observer.removeLockListener(key); waiting = false; } } } public boolean doExpire(){ synchronized(this){ if(owner) return true; if(expired) return false; expired = true; clear(); } return false; } @Override public void lockAcquired() { synchronized(this){ if(expired){ unlock(); return; } owner = true; waiting = false; } lockListener.lockAcquired(); } @Override public long getExpire() { return this.expire; } @Override public void lockError() { synchronized(this){ owner = false; waiting = false; lockListener.lockError(); } } }
使用本方案实现的分布式锁,可以完美地解决锁重入问题;通过引入超时也避免了死锁问题;性能方面,笔者自测试结果如下:public class LockObserver extends AbstractLockObserver implements Runnable{
private CacheRedisClient client;
private Object mutex = new Object();
private Map
500线程 tps = 35000
[root@DB1 benchtest-util]# target/benchtest/bin/TestFastRedis /data/config/util/config_0_11.properties lock 500 500000
线程总时间:6553466;平均:13.106932
实际总时间:13609; 平均:0.027218
TPS达到35000,比方案1强了整整一个数量级
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