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Internal ehcache-core module. This artifact is not meant to be used directly for jdk 1.5
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/**
* Copyright Terracotta, Inc.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
package net.sf.ehcache.constructs.blocking;
import static net.sf.ehcache.statistics.StatisticBuilder.operation;
import java.io.Serializable;
import java.util.Collection;
import java.util.Map;
import java.util.concurrent.atomic.AtomicReference;
import net.sf.ehcache.CacheException;
import net.sf.ehcache.Ehcache;
import net.sf.ehcache.Element;
import net.sf.ehcache.concurrent.CacheLockProvider;
import net.sf.ehcache.concurrent.LockType;
import net.sf.ehcache.concurrent.StripedReadWriteLockSync;
import net.sf.ehcache.concurrent.Sync;
import net.sf.ehcache.constructs.EhcacheDecoratorAdapter;
import net.sf.ehcache.constructs.blocking.BlockingCacheOperationOutcomes.GetOutcome;
import net.sf.ehcache.loader.CacheLoader;
import org.terracotta.statistics.observer.OperationObserver;
/**
* A blocking decorator for an Ehcache, backed by a {@link Ehcache}.
*
* It allows concurrent read access to elements already in the cache. If the element is null, other
* reads will block until an element with the same key is put into the cache.
*
* This is useful for constructing read-through or self-populating caches.
*
* This implementation uses the {@link net.sf.ehcache.concurrent.ReadWriteLockSync} class. If you wish to use
* this class, you will need the concurrent package in your class path.
*
* It features:
*
* - Excellent liveness.
*
- Fine-grained locking on each element, rather than the cache as a whole.
*
- Scalability to a large number of threads.
*
*
* "Hashtable / synchronizedMap uses the "one big fat lock" approach to guard the mutable state of the map.
* That works, but is a big concurrency bottleneck, as you've observed. You went to the opposite extreme, one lock per key.
* That works (as long as you've got sufficient synchronization in the cache itself to protect its own data structures.)
*
* Lock striping is a middle ground, partitioning keys into a fixed number of subsets, like the trick used at large
* theaters for will-call ticket pickup -- there are separate lines for "A-F, G-M, N-R, and S-Z".
* This way, there are a fixed number of locks, each guarding (hopefully) 1/Nth of the keys."
* - Brian Goetz
*
* Further improvements to hashing suggested by Joe Bowbeer.
*
* @author Greg Luck
* @version $Id: BlockingCache.java 6907 2013-01-18 16:16:39Z cdennis $
*/
public class BlockingCache extends EhcacheDecoratorAdapter {
/**
* The amount of time to block a thread before a LockTimeoutException is thrown
*/
protected volatile int timeoutMillis;
private final int stripes;
private final AtomicReference cacheLockProviderReference;
private final OperationObserver getObserver = operation(GetOutcome.class).named("get").of(this).tag("blocking-cache").build();
/**
* Creates a BlockingCache which decorates the supplied cache.
*
* @param cache a backing ehcache.
* @param numberOfStripes how many stripes to has the keys against. Must be a non-zero even number. This is a trade-off between
* memory use and concurrency
* @throws CacheException shouldn't happen
* @since 1.2
*/
public BlockingCache(final Ehcache cache, int numberOfStripes) throws CacheException {
super(cache);
this.stripes = numberOfStripes;
this.cacheLockProviderReference = new AtomicReference();
}
/**
* Creates a BlockingCache which decorates the supplied cache.
*
* @param cache a backing ehcache.
* @throws CacheException shouldn't happen
* @since 1.6.1
*/
public BlockingCache(final Ehcache cache) throws CacheException {
this(cache, StripedReadWriteLockSync.DEFAULT_NUMBER_OF_MUTEXES);
}
private CacheLockProvider getCacheLockProvider() {
CacheLockProvider provider = cacheLockProviderReference.get();
while (provider == null) {
cacheLockProviderReference.compareAndSet(null, createCacheLockProvider());
provider = cacheLockProviderReference.get();
}
return provider;
}
private CacheLockProvider createCacheLockProvider() {
Object context = underlyingCache.getInternalContext();
if (underlyingCache.getCacheConfiguration().isTerracottaClustered() && context != null) {
return (CacheLockProvider) context;
} else {
return new StripedReadWriteLockSync(stripes);
}
}
/**
* Retrieve the EHCache backing cache
*
* @return the backing cache
*/
protected Ehcache getCache() {
return underlyingCache;
}
/**
* Looks up an entry. Blocks if the entry is null until a call to {@link #put} is done
* to put an Element in.
*
* If a put is not done, the lock is never released.
*
* If this method throws an exception, it is the responsibility of the caller to catch that exception and call
* put(new Element(key, null)); to release the lock acquired. See {@link net.sf.ehcache.constructs.blocking.SelfPopulatingCache}
* for an example.
*
* Note. If a LockTimeoutException is thrown while doing a get it means the lock was never acquired,
* therefore it is a threading error to call {@link #put}
*
* @throws LockTimeoutException if timeout millis is non zero and this method has been unable to
* acquire a lock in that time
* @throws RuntimeException if thrown the lock will not released. Catch and callput(new Element(key, null));
* to release the lock acquired.
*/
@Override
public Element get(final Object key) throws RuntimeException, LockTimeoutException {
getObserver.begin();
Sync lock = getLockForKey(key);
acquiredLockForKey(key, lock, LockType.READ);
Element element;
try {
element = underlyingCache.get(key);
} finally {
lock.unlock(LockType.READ);
}
if (element == null) {
acquiredLockForKey(key, lock, LockType.WRITE);
element = underlyingCache.get(key);
if (element != null) {
lock.unlock(LockType.WRITE);
getObserver.end(GetOutcome.HIT);
} else {
getObserver.end(GetOutcome.MISS_AND_LOCKED);
}
return element;
} else {
getObserver.end(GetOutcome.HIT);
return element;
}
}
private void acquiredLockForKey(final Object key, final Sync lock, final LockType lockType) {
if (timeoutMillis > 0) {
try {
boolean acquired = lock.tryLock(lockType, timeoutMillis);
if (!acquired) {
StringBuilder message = new StringBuilder("Lock timeout. Waited more than ")
.append(timeoutMillis)
.append("ms to acquire lock for key ")
.append(key).append(" on blocking cache ").append(underlyingCache.getName());
throw new LockTimeoutException(message.toString());
}
} catch (InterruptedException e) {
throw new LockTimeoutException("Got interrupted while trying to acquire lock for key " + key, e);
}
} else {
lock.lock(lockType);
}
}
/**
* Gets the Sync to use for a given key.
*
* @param key the key
* @return one of a limited number of Sync's.
*/
protected Sync getLockForKey(final Object key) {
return getCacheLockProvider().getSyncForKey(key);
}
/**
* Adds an entry and unlocks it
*/
@Override
public void put(final Element element) {
doAndReleaseWriteLock(new PutAction(element) {
@Override
public Void put() {
if (element.getObjectValue() != null) {
underlyingCache.put(element);
} else {
underlyingCache.remove(element.getObjectKey());
}
return null;
}
});
}
@Override
public void put(final Element element, final boolean doNotNotifyCacheReplicators)
throws IllegalArgumentException, IllegalStateException, CacheException {
doAndReleaseWriteLock(new PutAction(element) {
@Override
public Void put() {
underlyingCache.put(element, doNotNotifyCacheReplicators);
return null;
}
});
}
@Override
public void putQuiet(final Element element) throws IllegalArgumentException, IllegalStateException, CacheException {
doAndReleaseWriteLock(new PutAction(element) {
@Override
public Void put() {
underlyingCache.putQuiet(element);
return null;
}
});
}
@Override
public void putWithWriter(final Element element) throws IllegalArgumentException, IllegalStateException, CacheException {
doAndReleaseWriteLock(new PutAction(element) {
@Override
public Void put() {
underlyingCache.putWithWriter(element);
return null;
}
});
}
@Override
public Element putIfAbsent(final Element element) throws NullPointerException {
return doAndReleaseWriteLock(new PutAction(element) {
@Override
public Element put() {
return underlyingCache.putIfAbsent(element);
}
});
}
@Override
public Element putIfAbsent(final Element element, final boolean doNotNotifyCacheReplicators) throws NullPointerException {
return doAndReleaseWriteLock(new PutAction(element) {
@Override
public Element put() {
return underlyingCache.putIfAbsent(element, doNotNotifyCacheReplicators);
}
});
}
private V doAndReleaseWriteLock(PutAction putAction) {
if (putAction.element == null) {
return null;
}
Object key = putAction.element.getObjectKey();
Sync lock = getLockForKey(key);
if (!lock.isHeldByCurrentThread(LockType.WRITE)) {
lock.lock(LockType.WRITE);
}
try {
return putAction.put();
} finally {
//Release the writelock here. This will have been acquired in the get, where the element was null
lock.unlock(LockType.WRITE);
}
}
/**
* Gets an element from the cache. Updates Element Statistics
*
* Note that the Element's lastAccessTime is always the time of this get.
* Use {@link #getQuiet(Object)} to peak into the Element to see its last access time with get
*
* @param key a serializable value
* @return the element, or null, if it does not exist.
* @throws IllegalStateException if the cache is not {@link net.sf.ehcache.Status#STATUS_ALIVE}
* @see #isExpired
*/
@Override
public Element get(Serializable key) throws IllegalStateException, CacheException {
return this.get((Object) key);
}
/**
* Synchronized version of getName to test liveness of the object lock.
*
* The time taken for this method to return is a useful measure of runtime contention on the cache.
*
* @return the name of the cache.
*/
public synchronized String liveness() {
return getName();
}
/**
* Sets the time to wait to acquire a lock. This may be modified at any time.
*
* The consequences of setting a timeout are:
*
* - if a lock cannot be acquired in the given time a LockTimeoutException is thrown.
*
- if there is a queue of threads waiting for the first thread to complete, but it does not complete within
* the time out period, the successive threads may find that they have exceeded their lock timeouts and fail. This
* is usually a good thing because it stops a build up of threads from overwhelming a busy resource, but it does
* need to be considered in the design of user interfaces. The timeout should be set no greater than the time a user
* would be expected to wait before considering the action will never return
*
- it will be common to see a number of threads timeout trying to get the same lock. This is a normal and desired
* consequence.
*
* The consequences of not setting a timeout (or setting it to 0) are:
*
* - There are no partial failures in the system. But there is a greater possibility that a temporary overload
* in one part of the system can cause a back up that may take a long time to recover from.
*
- A failing method that perhaps fails because a resource is overloaded will be hit by each thread in turn, no matter whether there is a still a user who
* cares about getting a response.
*
*
* @param timeoutMillis the time in ms. Must be a positive number. 0 means wait forever.
*/
public void setTimeoutMillis(int timeoutMillis) {
if (timeoutMillis < 0) {
throw new CacheException("The lock timeout must be a positive number of ms. Value was " + timeoutMillis);
}
this.timeoutMillis = timeoutMillis;
}
/**
* Gets the time to wait to acquire a lock.
*
* @return the time in ms.
*/
public int getTimeoutMillis() {
return timeoutMillis;
}
/**
* Register a {@link CacheLoader} with the cache. It will then be tied into the cache lifecycle.
*
* If the CacheLoader is not initialised, initialise it.
*
* @param cacheLoader A Cache Loader to register
*/
@Override
public void registerCacheLoader(CacheLoader cacheLoader) {
throw new CacheException("This method is not appropriate for a blocking cache.");
}
/**
* Unregister a {@link CacheLoader} with the cache. It will then be detached from the cache lifecycle.
*
* @param cacheLoader A Cache Loader to unregister
*/
@Override
public void unregisterCacheLoader(CacheLoader cacheLoader) {
throw new CacheException("This method is not appropriate for a blocking cache.");
}
/**
* This method is not appropriate to use with BlockingCache.
*
* @throws CacheException if this method is called
*/
@Override
public Element getWithLoader(Object key, CacheLoader loader, Object loaderArgument) throws CacheException {
throw new CacheException("This method is not appropriate for a Blocking Cache");
}
/**
* This method is not appropriate to use with BlockingCache.
*
* @throws CacheException if this method is called
*/
@Override
public Map getAllWithLoader(Collection keys, Object loaderArgument) throws CacheException {
throw new CacheException("This method is not appropriate for a Blocking Cache");
}
/**
* This method is not appropriate to use with BlockingCache.
*
* @throws CacheException if this method is called
*/
@Override
public void load(Object key) throws CacheException {
throw new CacheException("This method is not appropriate for a Blocking Cache");
}
/**
* This method is not appropriate to use with BlockingCache.
*
* @throws CacheException if this method is called
*/
@Override
public void loadAll(Collection keys, Object argument) throws CacheException {
throw new CacheException("This method is not appropriate for a Blocking Cache");
}
/**
* Callable like class to actually execute one of the many Ehcache.put* methods in the context of a BlockingCache
* @param
*/
private abstract static class PutAction {
private final Element element;
private PutAction(Element element) {
this.element = element;
}
/**
* implement method with the put*
* @return the return value of the put*
*/
abstract V put();
}
}