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/*
* Copyright 2014 Ben Manes. All Rights Reserved.
*
* 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 com.github.benmanes.caffeine.cache;
import static com.github.benmanes.caffeine.cache.Async.ASYNC_EXPIRY;
import static com.github.benmanes.caffeine.cache.Caffeine.ceilingPowerOfTwo;
import static com.github.benmanes.caffeine.cache.Caffeine.requireArgument;
import static com.github.benmanes.caffeine.cache.Caffeine.requireState;
import static com.github.benmanes.caffeine.cache.LocalLoadingCache.newBulkMappingFunction;
import static com.github.benmanes.caffeine.cache.LocalLoadingCache.newMappingFunction;
import static com.github.benmanes.caffeine.cache.Node.PROBATION;
import static com.github.benmanes.caffeine.cache.Node.PROTECTED;
import static com.github.benmanes.caffeine.cache.Node.WINDOW;
import static java.util.Objects.requireNonNull;
import java.io.InvalidObjectException;
import java.io.ObjectInputStream;
import java.io.Serializable;
import java.lang.ref.Reference;
import java.lang.ref.ReferenceQueue;
import java.lang.ref.WeakReference;
import java.util.AbstractCollection;
import java.util.AbstractMap;
import java.util.AbstractSet;
import java.util.ArrayList;
import java.util.Collection;
import java.util.Collections;
import java.util.Comparator;
import java.util.Iterator;
import java.util.LinkedHashMap;
import java.util.LinkedHashSet;
import java.util.List;
import java.util.Map;
import java.util.NoSuchElementException;
import java.util.Optional;
import java.util.OptionalInt;
import java.util.OptionalLong;
import java.util.Set;
import java.util.Spliterator;
import java.util.concurrent.CancellationException;
import java.util.concurrent.CompletableFuture;
import java.util.concurrent.ConcurrentHashMap;
import java.util.concurrent.ConcurrentMap;
import java.util.concurrent.Executor;
import java.util.concurrent.ForkJoinPool;
import java.util.concurrent.ForkJoinTask;
import java.util.concurrent.ThreadLocalRandom;
import java.util.concurrent.TimeUnit;
import java.util.concurrent.TimeoutException;
import java.util.concurrent.locks.ReentrantLock;
import java.util.function.BiFunction;
import java.util.function.Consumer;
import java.util.function.Function;
import java.util.function.Predicate;
import java.util.function.Supplier;
import java.util.logging.Level;
import java.util.logging.Logger;
import org.checkerframework.checker.nullness.qual.NonNull;
import org.checkerframework.checker.nullness.qual.Nullable;
import com.github.benmanes.caffeine.cache.Async.AsyncExpiry;
import com.github.benmanes.caffeine.cache.LinkedDeque.PeekingIterator;
import com.github.benmanes.caffeine.cache.References.InternalReference;
import com.github.benmanes.caffeine.cache.stats.StatsCounter;
import com.google.errorprone.annotations.concurrent.GuardedBy;
/**
* An in-memory cache implementation that supports full concurrency of retrievals, a high expected
* concurrency for updates, and multiple ways to bound the cache.
*
* This class is abstract and code generated subclasses provide the complete implementation for a
* particular configuration. This is to ensure that only the fields and execution paths necessary
* for a given configuration are used.
*
* @author [email protected] (Ben Manes)
* @param the type of keys maintained by this cache
* @param the type of mapped values
*/
@SuppressWarnings("deprecation")
abstract class BoundedLocalCache extends BLCHeader.DrainStatusRef
implements LocalCache {
/*
* This class performs a best-effort bounding of a ConcurrentHashMap using a page-replacement
* algorithm to determine which entries to evict when the capacity is exceeded.
*
* Concurrency:
* ------------
* The page replacement algorithms are kept eventually consistent with the map. An update to the
* map and recording of reads may not be immediately reflected on the policy's data structures.
* These structures are guarded by a lock and operations are applied in batches to avoid lock
* contention. The penalty of applying the batches is spread across threads so that the amortized
* cost is slightly higher than performing just the ConcurrentHashMap operation [1].
*
* A memento of the reads and writes that were performed on the map are recorded in buffers. These
* buffers are drained at the first opportunity after a write or when a read buffer is full. The
* reads are offered to a buffer that will reject additions if contended on or if it is full. Due
* to the concurrent nature of the read and write operations a strict policy ordering is not
* possible, but may be observably strict when single threaded. The buffers are drained
* asynchronously to minimize the request latency and uses a state machine to determine when to
* schedule this work on an executor.
*
* Due to a lack of a strict ordering guarantee, a task can be executed out-of-order, such as a
* removal followed by its addition. The state of the entry is encoded using the key field to
* avoid additional memory. An entry is "alive" if it is in both the hash table and the page
* replacement policy. It is "retired" if it is not in the hash table and is pending removal from
* the page replacement policy. Finally an entry transitions to the "dead" state when it is not in
* the hash table nor the page replacement policy. Both the retired and dead states are
* represented by a sentinel key that should not be used for map operations.
*
* Eviction:
* ---------
* Maximum size is implemented using the Window TinyLfu policy [2] due to its high hit rate, O(1)
* time complexity, and small footprint. A new entry starts in the admission window and remains
* there as long as it has high temporal locality (recency). Eventually an entry will slip from
* the window into the main space. If the main space is already full, then a historic frequency
* filter determines whether to evict the newly admitted entry or the victim entry chosen by the
* eviction policy. This process ensures that the entries in the window were very recently used
* and entries in the main space are accessed very frequently and are moderately recent. The
* windowing allows the policy to have a high hit rate when entries exhibit bursty access pattern
* while the filter ensures that popular items are retained. The admission window uses LRU and
* the main space uses Segmented LRU.
*
* The optimal size of the window vs main spaces is workload dependent [3]. A large admission
* window is favored by recency-biased workloads while a small one favors frequency-biased
* workloads. When the window is too small then recent arrivals are prematurely evicted, but when
* too large then they pollute the cache and force the eviction of more popular entries. The
* configuration is dynamically determined using hill climbing to walk the hit rate curve. This is
* done by sampling the hit rate and adjusting the window size in the direction that is improving
* (making positive or negative steps). At each interval the step size is decreased until the
* climber converges at the optimal setting. The process is restarted when the hit rate changes
* over a threshold, indicating that the workload altered and a new setting may be required.
*
* The historic usage is retained in a compact popularity sketch, which uses hashing to
* probabilistically estimate an item's frequency. This exposes a flaw where an adversary could
* use hash flooding [4] to artificially raise the frequency of the main space's victim and cause
* all candidates to be rejected. In the worst case, by exploiting hash collisions an attacker
* could cause the cache to never hit and hold only worthless items, resulting in a
* denial-of-service attack against the underlying resource. This is protected against by
* introducing jitter so that candidates which are at least moderately popular have a small,
* random chance of being admitted. This causes the victim to be evicted, but in a way that
* marginally impacts the hit rate.
*
* Expiration:
* -----------
* Expiration is implemented in O(1) time complexity. The time-to-idle policy uses an access-order
* queue, the time-to-live policy uses a write-order queue, and variable expiration uses a
* hierarchical timer wheel [5]. The queuing policies allow for peeking at the oldest entry to
* see if it has expired and, if it has not, then the younger entries must not have too. If a
* maximum size is set then expiration will share the queues so that the per-entry footprint is
* minimized. The timer wheel based policy uses hashing and cascading in a manner that amortizes
* the penalty of sorting to achieve a similar algorithmic cost.
*
* The expiration updates are applied in a best effort fashion. The reordering of variable or
* access-order expiration may be discarded by the read buffer if full or contended on. Similarly
* the reordering of write expiration may be ignored for an entry if the last update was within a
* short time window in order to avoid overwhelming the write buffer.
*
* [1] BP-Wrapper: A Framework Making Any Replacement Algorithms (Almost) Lock Contention Free
* http://web.cse.ohio-state.edu/hpcs/WWW/HTML/publications/papers/TR-09-1.pdf
* [2] TinyLFU: A Highly Efficient Cache Admission Policy
* https://dl.acm.org/citation.cfm?id=3149371
* [3] Adaptive Software Cache Management
* https://dl.acm.org/citation.cfm?id=3274816
* [4] Denial of Service via Algorithmic Complexity Attack
* https://www.usenix.org/legacy/events/sec03/tech/full_papers/crosby/crosby.pdf
* [5] Hashed and Hierarchical Timing Wheels
* http://www.cs.columbia.edu/~nahum/w6998/papers/ton97-timing-wheels.pdf
*/
static final Logger logger = Logger.getLogger(BoundedLocalCache.class.getName());
/** The number of CPUs */
static final int NCPU = Runtime.getRuntime().availableProcessors();
/** The initial capacity of the write buffer. */
static final int WRITE_BUFFER_MIN = 4;
/** The maximum capacity of the write buffer. */
static final int WRITE_BUFFER_MAX = 128 * ceilingPowerOfTwo(NCPU);
/** The number of attempts to insert into the write buffer before yielding. */
static final int WRITE_BUFFER_RETRIES = 100;
/** The maximum weighted capacity of the map. */
static final long MAXIMUM_CAPACITY = Long.MAX_VALUE - Integer.MAX_VALUE;
/** The initial percent of the maximum weighted capacity dedicated to the main space. */
static final double PERCENT_MAIN = 0.99d;
/** The percent of the maximum weighted capacity dedicated to the main's protected space. */
static final double PERCENT_MAIN_PROTECTED = 0.80d;
/** The difference in hit rates that restarts the climber. */
static final double HILL_CLIMBER_RESTART_THRESHOLD = 0.05d;
/** The percent of the total size to adapt the window by. */
static final double HILL_CLIMBER_STEP_PERCENT = 0.0625d;
/** The rate to decrease the step size to adapt by. */
static final double HILL_CLIMBER_STEP_DECAY_RATE = 0.98d;
/** The maximum number of entries that can be transfered between queues. */
static final int QUEUE_TRANSFER_THRESHOLD = 1_000;
/** The maximum time window between entry updates before the expiration must be reordered. */
static final long EXPIRE_WRITE_TOLERANCE = TimeUnit.SECONDS.toNanos(1);
/** The maximum duration before an entry expires. */
static final long MAXIMUM_EXPIRY = (Long.MAX_VALUE >> 1); // 150 years
final MpscGrowableArrayQueue writeBuffer;
final ConcurrentHashMap> data;
@Nullable final CacheLoader cacheLoader;
final PerformCleanupTask drainBuffersTask;
final Consumer> accessPolicy;
final Buffer> readBuffer;
final NodeFactory nodeFactory;
final ReentrantLock evictionLock;
final CacheWriter writer;
final Weigher weigher;
final Executor executor;
final boolean isAsync;
// The collection views
@Nullable transient Set keySet;
@Nullable transient Collection values;
@Nullable transient Set> entrySet;
/** Creates an instance based on the builder's configuration. */
protected BoundedLocalCache(Caffeine builder,
@Nullable CacheLoader cacheLoader, boolean isAsync) {
this.isAsync = isAsync;
this.cacheLoader = cacheLoader;
executor = builder.getExecutor();
evictionLock = new ReentrantLock();
weigher = builder.getWeigher(isAsync);
writer = builder.getCacheWriter(isAsync);
drainBuffersTask = new PerformCleanupTask(this);
nodeFactory = NodeFactory.newFactory(builder, isAsync);
data = new ConcurrentHashMap<>(builder.getInitialCapacity());
readBuffer = evicts() || collectKeys() || collectValues() || expiresAfterAccess()
? new BoundedBuffer<>()
: Buffer.disabled();
accessPolicy = (evicts() || expiresAfterAccess()) ? this::onAccess : e -> {};
writeBuffer = new MpscGrowableArrayQueue<>(WRITE_BUFFER_MIN, WRITE_BUFFER_MAX);
if (evicts()) {
setMaximumSize(builder.getMaximum());
}
}
/* --------------- Shared --------------- */
/** Returns if the node's value is currently being computed, asynchronously. */
final boolean isComputingAsync(Node, ?> node) {
return isAsync && !Async.isReady((CompletableFuture>) node.getValue());
}
@GuardedBy("evictionLock")
protected AccessOrderDeque> accessOrderWindowDeque() {
throw new UnsupportedOperationException();
}
@GuardedBy("evictionLock")
protected AccessOrderDeque> accessOrderProbationDeque() {
throw new UnsupportedOperationException();
}
@GuardedBy("evictionLock")
protected AccessOrderDeque> accessOrderProtectedDeque() {
throw new UnsupportedOperationException();
}
@GuardedBy("evictionLock")
protected WriteOrderDeque> writeOrderDeque() {
throw new UnsupportedOperationException();
}
@Override
public final Executor executor() {
return executor;
}
/** Returns whether this cache notifies a writer when an entry is modified. */
protected boolean hasWriter() {
return (writer != CacheWriter.disabledWriter());
}
/* --------------- Stats Support --------------- */
@Override
public boolean isRecordingStats() {
return false;
}
@Override
public StatsCounter statsCounter() {
return StatsCounter.disabledStatsCounter();
}
@Override
public Ticker statsTicker() {
return Ticker.disabledTicker();
}
/* --------------- Removal Listener Support --------------- */
@Override
@SuppressWarnings("NullAway")
public RemovalListener removalListener() {
return null;
}
@Override
public boolean hasRemovalListener() {
return false;
}
@Override
public void notifyRemoval(@Nullable K key, @Nullable V value, RemovalCause cause) {
requireState(hasRemovalListener(), "Notification should be guarded with a check");
Runnable task = () -> {
try {
removalListener().onRemoval(key, value, cause);
} catch (Throwable t) {
logger.log(Level.WARNING, "Exception thrown by removal listener", t);
}
};
try {
executor.execute(task);
} catch (Throwable t) {
logger.log(Level.SEVERE, "Exception thrown when submitting removal listener", t);
task.run();
}
}
/* --------------- Reference Support --------------- */
/** Returns if the keys are weak reference garbage collected. */
protected boolean collectKeys() {
return false;
}
/** Returns if the values are weak or soft reference garbage collected. */
protected boolean collectValues() {
return false;
}
@SuppressWarnings("NullAway")
protected ReferenceQueue keyReferenceQueue() {
return null;
}
@SuppressWarnings("NullAway")
protected ReferenceQueue valueReferenceQueue() {
return null;
}
/* --------------- Expiration Support --------------- */
/** Returns the {@link Pacer} used to schedule the maintenance task. */
protected @Nullable Pacer pacer() {
return null;
}
/** Returns if the cache expires entries after a variable time threshold. */
protected boolean expiresVariable() {
return false;
}
/** Returns if the cache expires entries after an access time threshold. */
protected boolean expiresAfterAccess() {
return false;
}
/** Returns how long after the last access to an entry the map will retain that entry. */
protected long expiresAfterAccessNanos() {
throw new UnsupportedOperationException();
}
protected void setExpiresAfterAccessNanos(long expireAfterAccessNanos) {
throw new UnsupportedOperationException();
}
/** Returns if the cache expires entries after an write time threshold. */
protected boolean expiresAfterWrite() {
return false;
}
/** Returns how long after the last write to an entry the map will retain that entry. */
protected long expiresAfterWriteNanos() {
throw new UnsupportedOperationException();
}
protected void setExpiresAfterWriteNanos(long expireAfterWriteNanos) {
throw new UnsupportedOperationException();
}
/** Returns if the cache refreshes entries after an write time threshold. */
protected boolean refreshAfterWrite() {
return false;
}
/** Returns how long after the last write an entry becomes a candidate for refresh. */
protected long refreshAfterWriteNanos() {
throw new UnsupportedOperationException();
}
protected void setRefreshAfterWriteNanos(long refreshAfterWriteNanos) {
throw new UnsupportedOperationException();
}
@Override
public boolean hasWriteTime() {
return expiresAfterWrite() || refreshAfterWrite();
}
@SuppressWarnings("NullAway")
protected Expiry expiry() {
return null;
}
@Override
public Ticker expirationTicker() {
return Ticker.disabledTicker();
}
protected TimerWheel timerWheel() {
throw new UnsupportedOperationException();
}
/* --------------- Eviction Support --------------- */
/** Returns if the cache evicts entries due to a maximum size or weight threshold. */
protected boolean evicts() {
return false;
}
/** Returns if entries may be assigned different weights. */
protected boolean isWeighted() {
return (weigher != Weigher.singletonWeigher());
}
protected FrequencySketch frequencySketch() {
throw new UnsupportedOperationException();
}
/** Returns if an access to an entry can skip notifying the eviction policy. */
protected boolean fastpath() {
return false;
}
/** Returns the maximum weighted size. */
protected long maximum() {
throw new UnsupportedOperationException();
}
/** Returns the maximum weighted size of the window space. */
protected long windowMaximum() {
throw new UnsupportedOperationException();
}
/** Returns the maximum weighted size of the main's protected space. */
protected long mainProtectedMaximum() {
throw new UnsupportedOperationException();
}
@GuardedBy("evictionLock")
protected void setMaximum(long maximum) {
throw new UnsupportedOperationException();
}
@GuardedBy("evictionLock")
protected void setWindowMaximum(long maximum) {
throw new UnsupportedOperationException();
}
@GuardedBy("evictionLock")
protected void setMainProtectedMaximum(long maximum) {
throw new UnsupportedOperationException();
}
/** Returns the combined weight of the values in the cache (may be negative). */
protected long weightedSize() {
throw new UnsupportedOperationException();
}
/** Returns the uncorrected combined weight of the values in the window space. */
protected long windowWeightedSize() {
throw new UnsupportedOperationException();
}
/** Returns the uncorrected combined weight of the values in the main's protected space. */
protected long mainProtectedWeightedSize() {
throw new UnsupportedOperationException();
}
@GuardedBy("evictionLock")
protected void setWeightedSize(long weightedSize) {
throw new UnsupportedOperationException();
}
@GuardedBy("evictionLock")
protected void setWindowWeightedSize(long weightedSize) {
throw new UnsupportedOperationException();
}
@GuardedBy("evictionLock")
protected void setMainProtectedWeightedSize(long weightedSize) {
throw new UnsupportedOperationException();
}
protected int hitsInSample() {
throw new UnsupportedOperationException();
}
protected int missesInSample() {
throw new UnsupportedOperationException();
}
protected int sampleCount() {
throw new UnsupportedOperationException();
}
protected double stepSize() {
throw new UnsupportedOperationException();
}
protected double previousSampleHitRate() {
throw new UnsupportedOperationException();
}
protected long adjustment() {
throw new UnsupportedOperationException();
}
@GuardedBy("evictionLock")
protected void setHitsInSample(int hitCount) {
throw new UnsupportedOperationException();
}
@GuardedBy("evictionLock")
protected void setMissesInSample(int missCount) {
throw new UnsupportedOperationException();
}
@GuardedBy("evictionLock")
protected void setSampleCount(int sampleCount) {
throw new UnsupportedOperationException();
}
@GuardedBy("evictionLock")
protected void setStepSize(double stepSize) {
throw new UnsupportedOperationException();
}
@GuardedBy("evictionLock")
protected void setPreviousSampleHitRate(double hitRate) {
throw new UnsupportedOperationException();
}
@GuardedBy("evictionLock")
protected void setAdjustment(long amount) {
throw new UnsupportedOperationException();
}
/**
* Sets the maximum weighted size of the cache. The caller may need to perform a maintenance cycle
* to eagerly evicts entries until the cache shrinks to the appropriate size.
*/
@GuardedBy("evictionLock")
void setMaximumSize(long maximum) {
requireArgument(maximum >= 0, "maximum must not be negative");
if (maximum == maximum()) {
return;
}
long max = Math.min(maximum, MAXIMUM_CAPACITY);
long window = max - (long) (PERCENT_MAIN * max);
long mainProtected = (long) (PERCENT_MAIN_PROTECTED * (max - window));
setMaximum(max);
setWindowMaximum(window);
setMainProtectedMaximum(mainProtected);
setHitsInSample(0);
setMissesInSample(0);
setStepSize(-HILL_CLIMBER_STEP_PERCENT * max);
if ((frequencySketch() != null) && !isWeighted() && (weightedSize() >= (max >>> 1))) {
// Lazily initialize when close to the maximum size
frequencySketch().ensureCapacity(max);
}
}
/** Evicts entries if the cache exceeds the maximum. */
@GuardedBy("evictionLock")
void evictEntries() {
if (!evicts()) {
return;
}
int candidates = evictFromWindow();
evictFromMain(candidates);
}
/**
* Evicts entries from the window space into the main space while the window size exceeds a
* maximum.
*
* @return the number of candidate entries evicted from the window space
*/
@GuardedBy("evictionLock")
int evictFromWindow() {
int candidates = 0;
Node node = accessOrderWindowDeque().peek();
while (windowWeightedSize() > windowMaximum()) {
// The pending operations will adjust the size to reflect the correct weight
if (node == null) {
break;
}
Node next = node.getNextInAccessOrder();
if (node.getPolicyWeight() != 0) {
node.makeMainProbation();
accessOrderWindowDeque().remove(node);
accessOrderProbationDeque().add(node);
candidates++;
setWindowWeightedSize(windowWeightedSize() - node.getPolicyWeight());
}
node = next;
}
return candidates;
}
/**
* Evicts entries from the main space if the cache exceeds the maximum capacity. The main space
* determines whether admitting an entry (coming from the window space) is preferable to retaining
* the eviction policy's victim. This decision is made using a frequency filter so that the
* least frequently used entry is removed.
*
* The window space's candidates were previously placed in the MRU position and the eviction
* policy's victim is at the LRU position. The two ends of the queue are evaluated while an
* eviction is required. The number of remaining candidates is provided and decremented on
* eviction, so that when there are no more candidates the victim is evicted.
*
* @param candidates the number of candidate entries evicted from the window space
*/
@GuardedBy("evictionLock")
void evictFromMain(int candidates) {
int victimQueue = PROBATION;
Node victim = accessOrderProbationDeque().peekFirst();
Node candidate = accessOrderProbationDeque().peekLast();
while (weightedSize() > maximum()) {
// Search the admission window for additional candidates
if (candidates == 0) {
candidate = accessOrderWindowDeque().peekLast();
}
// Try evicting from the protected and window queues
if ((candidate == null) && (victim == null)) {
if (victimQueue == PROBATION) {
victim = accessOrderProtectedDeque().peekFirst();
victimQueue = PROTECTED;
continue;
} else if (victimQueue == PROTECTED) {
victim = accessOrderWindowDeque().peekFirst();
victimQueue = WINDOW;
continue;
}
// The pending operations will adjust the size to reflect the correct weight
break;
}
// Skip over entries with zero weight
if ((victim != null) && (victim.getPolicyWeight() == 0)) {
victim = victim.getNextInAccessOrder();
continue;
} else if ((candidate != null) && (candidate.getPolicyWeight() == 0)) {
candidate = (candidates > 0)
? candidate.getPreviousInAccessOrder()
: candidate.getNextInAccessOrder();
candidates--;
continue;
}
// Evict immediately if only one of the entries is present
if (victim == null) {
@SuppressWarnings("NullAway")
Node previous = candidate.getPreviousInAccessOrder();
Node evict = candidate;
candidate = previous;
candidates--;
evictEntry(evict, RemovalCause.SIZE, 0L);
continue;
} else if (candidate == null) {
Node evict = victim;
victim = victim.getNextInAccessOrder();
evictEntry(evict, RemovalCause.SIZE, 0L);
continue;
}
// Evict immediately if an entry was collected
K victimKey = victim.getKey();
K candidateKey = candidate.getKey();
if (victimKey == null) {
@NonNull Node evict = victim;
victim = victim.getNextInAccessOrder();
evictEntry(evict, RemovalCause.COLLECTED, 0L);
continue;
} else if (candidateKey == null) {
@NonNull Node evict = candidate;
candidate = (candidates > 0)
? candidate.getPreviousInAccessOrder()
: candidate.getNextInAccessOrder();
candidates--;
evictEntry(evict, RemovalCause.COLLECTED, 0L);
continue;
}
// Evict immediately if the candidate's weight exceeds the maximum
if (candidate.getPolicyWeight() > maximum()) {
Node evict = candidate;
candidate = (candidates > 0)
? candidate.getPreviousInAccessOrder()
: candidate.getNextInAccessOrder();
candidates--;
evictEntry(evict, RemovalCause.SIZE, 0L);
continue;
}
// Evict the entry with the lowest frequency
candidates--;
if (admit(candidateKey, victimKey)) {
Node evict = victim;
victim = victim.getNextInAccessOrder();
evictEntry(evict, RemovalCause.SIZE, 0L);
candidate = candidate.getPreviousInAccessOrder();
} else {
Node evict = candidate;
candidate = (candidates > 0)
? candidate.getPreviousInAccessOrder()
: candidate.getNextInAccessOrder();
evictEntry(evict, RemovalCause.SIZE, 0L);
}
}
}
/**
* Determines if the candidate should be accepted into the main space, as determined by its
* frequency relative to the victim. A small amount of randomness is used to protect against hash
* collision attacks, where the victim's frequency is artificially raised so that no new entries
* are admitted.
*
* @param candidateKey the key for the entry being proposed for long term retention
* @param victimKey the key for the entry chosen by the eviction policy for replacement
* @return if the candidate should be admitted and the victim ejected
*/
@GuardedBy("evictionLock")
boolean admit(K candidateKey, K victimKey) {
int victimFreq = frequencySketch().frequency(victimKey);
int candidateFreq = frequencySketch().frequency(candidateKey);
if (candidateFreq > victimFreq) {
return true;
} else if (candidateFreq <= 5) {
// The maximum frequency is 15 and halved to 7 after a reset to age the history. An attack
// exploits that a hot candidate is rejected in favor of a hot victim. The threshold of a warm
// candidate reduces the number of random acceptances to minimize the impact on the hit rate.
return false;
}
int random = ThreadLocalRandom.current().nextInt();
return ((random & 127) == 0);
}
/** Expires entries that have expired by access, write, or variable. */
@GuardedBy("evictionLock")
void expireEntries() {
long now = expirationTicker().read();
expireAfterAccessEntries(now);
expireAfterWriteEntries(now);
expireVariableEntries(now);
Pacer pacer = pacer();
if (pacer != null) {
long delay = getExpirationDelay(now);
if (delay == Long.MAX_VALUE) {
pacer.cancel();
} else {
pacer.schedule(executor, drainBuffersTask, now, delay);
}
}
}
/** Expires entries in the access-order queue. */
@GuardedBy("evictionLock")
void expireAfterAccessEntries(long now) {
if (!expiresAfterAccess()) {
return;
}
expireAfterAccessEntries(accessOrderWindowDeque(), now);
if (evicts()) {
expireAfterAccessEntries(accessOrderProbationDeque(), now);
expireAfterAccessEntries(accessOrderProtectedDeque(), now);
}
}
/** Expires entries in an access-order queue. */
@GuardedBy("evictionLock")
void expireAfterAccessEntries(AccessOrderDeque> accessOrderDeque, long now) {
long duration = expiresAfterAccessNanos();
for (;;) {
Node node = accessOrderDeque.peekFirst();
if ((node == null) || ((now - node.getAccessTime()) < duration)
|| !evictEntry(node, RemovalCause.EXPIRED, now)) {
return;
}
}
}
/** Expires entries on the write-order queue. */
@GuardedBy("evictionLock")
void expireAfterWriteEntries(long now) {
if (!expiresAfterWrite()) {
return;
}
long duration = expiresAfterWriteNanos();
for (;;) {
Node node = writeOrderDeque().peekFirst();
if ((node == null) || ((now - node.getWriteTime()) < duration)
|| !evictEntry(node, RemovalCause.EXPIRED, now)) {
break;
}
}
}
/** Expires entries in the timer wheel. */
@GuardedBy("evictionLock")
void expireVariableEntries(long now) {
if (expiresVariable()) {
timerWheel().advance(now);
}
}
/** Returns the duration until the next item expires, or {@link Long.MAX_VALUE} if none. */
@GuardedBy("evictionLock")
private long getExpirationDelay(long now) {
long delay = Long.MAX_VALUE;
if (expiresAfterAccess()) {
Node node = accessOrderWindowDeque().peekFirst();
if (node != null) {
delay = Math.min(delay, expiresAfterAccessNanos() - (now - node.getAccessTime()));
}
if (evicts()) {
node = accessOrderProbationDeque().peekFirst();
if (node != null) {
delay = Math.min(delay, expiresAfterAccessNanos() - (now - node.getAccessTime()));
}
node = accessOrderProtectedDeque().peekFirst();
if (node != null) {
delay = Math.min(delay, expiresAfterAccessNanos() - (now - node.getAccessTime()));
}
}
}
if (expiresAfterWrite()) {
Node node = writeOrderDeque().peekFirst();
if (node != null) {
delay = Math.min(delay, expiresAfterWriteNanos() - (now - node.getWriteTime()));
}
}
if (expiresVariable()) {
delay = Math.min(delay, timerWheel().getExpirationDelay());
}
return delay;
}
/** Returns if the entry has expired. */
@SuppressWarnings("ShortCircuitBoolean")
boolean hasExpired(Node node, long now) {
if (isComputingAsync(node)) {
return false;
}
return (expiresAfterAccess() && (now - node.getAccessTime() >= expiresAfterAccessNanos()))
| (expiresAfterWrite() && (now - node.getWriteTime() >= expiresAfterWriteNanos()))
| (expiresVariable() && (now - node.getVariableTime() >= 0));
}
/**
* Attempts to evict the entry based on the given removal cause. A removal due to may be ignored
* if the entry was updated and is no longer eligible for eviction.
*
* @param node the entry to evict
* @param cause the reason to evict
* @param now the current time, used only if expiring
* @return if the entry was evicted
*/
@GuardedBy("evictionLock")
@SuppressWarnings({"PMD.CollapsibleIfStatements", "GuardedByChecker", "NullAway"})
boolean evictEntry(Node node, RemovalCause cause, long now) {
K key = node.getKey();
@SuppressWarnings("unchecked")
V[] value = (V[]) new Object[1];
boolean[] removed = new boolean[1];
boolean[] resurrect = new boolean[1];
RemovalCause[] actualCause = new RemovalCause[1];
data.computeIfPresent(node.getKeyReference(), (k, n) -> {
if (n != node) {
return n;
}
synchronized (n) {
value[0] = n.getValue();
if ((key == null) || (value[0] == null)) {
actualCause[0] = RemovalCause.COLLECTED;
} else if (cause == RemovalCause.COLLECTED) {
resurrect[0] = true;
return n;
} else {
actualCause[0] = cause;
}
if (actualCause[0] == RemovalCause.EXPIRED) {
boolean expired = false;
if (expiresAfterAccess()) {
expired |= ((now - n.getAccessTime()) >= expiresAfterAccessNanos());
}
if (expiresAfterWrite()) {
expired |= ((now - n.getWriteTime()) >= expiresAfterWriteNanos());
}
if (expiresVariable()) {
expired |= (n.getVariableTime() <= now);
}
if (!expired) {
resurrect[0] = true;
return n;
}
} else if (actualCause[0] == RemovalCause.SIZE) {
int weight = node.getWeight();
if (weight == 0) {
resurrect[0] = true;
return n;
}
}
writer.delete(key, value[0], actualCause[0]);
makeDead(n);
}
removed[0] = true;
return null;
});
// The entry is no longer eligible for eviction
if (resurrect[0]) {
return false;
}
// If the eviction fails due to a concurrent removal of the victim, that removal may cancel out
// the addition that triggered this eviction. The victim is eagerly unlinked before the removal
// task so that if an eviction is still required then a new victim will be chosen for removal.
if (node.inWindow() && (evicts() || expiresAfterAccess())) {
accessOrderWindowDeque().remove(node);
} else if (evicts()) {
if (node.inMainProbation()) {
accessOrderProbationDeque().remove(node);
} else {
accessOrderProtectedDeque().remove(node);
}
}
if (expiresAfterWrite()) {
writeOrderDeque().remove(node);
} else if (expiresVariable()) {
timerWheel().deschedule(node);
}
if (removed[0]) {
statsCounter().recordEviction(node.getWeight(), actualCause[0]);
if (hasRemovalListener()) {
// Notify the listener only if the entry was evicted. This must be performed as the last
// step during eviction to safe guard against the executor rejecting the notification task.
notifyRemoval(key, value[0], actualCause[0]);
}
} else {
// Eagerly decrement the size to potentially avoid an additional eviction, rather than wait
// for the removal task to do it on the next maintenance cycle.
makeDead(node);
}
return true;
}
/** Adapts the eviction policy to towards the optimal recency / frequency configuration. */
@GuardedBy("evictionLock")
void climb() {
if (!evicts()) {
return;
}
determineAdjustment();
demoteFromMainProtected();
long amount = adjustment();
if (amount == 0) {
return;
} else if (amount > 0) {
increaseWindow();
} else {
decreaseWindow();
}
}
/** Calculates the amount to adapt the window by and sets {@link #adjustment()} accordingly. */
@GuardedBy("evictionLock")
void determineAdjustment() {
if (frequencySketch().isNotInitialized()) {
setPreviousSampleHitRate(0.0);
setMissesInSample(0);
setHitsInSample(0);
return;
}
int requestCount = hitsInSample() + missesInSample();
if (requestCount < frequencySketch().sampleSize) {
return;
}
double hitRate = (double) hitsInSample() / requestCount;
double hitRateChange = hitRate - previousSampleHitRate();
double amount = (hitRateChange >= 0) ? stepSize() : -stepSize();
double nextStepSize = (Math.abs(hitRateChange) >= HILL_CLIMBER_RESTART_THRESHOLD)
? HILL_CLIMBER_STEP_PERCENT * maximum() * (amount >= 0 ? 1 : -1)
: HILL_CLIMBER_STEP_DECAY_RATE * amount;
setPreviousSampleHitRate(hitRate);
setAdjustment((long) amount);
setStepSize(nextStepSize);
setMissesInSample(0);
setHitsInSample(0);
}
/**
* Increases the size of the admission window by shrinking the portion allocated to the main
* space. As the main space is partitioned into probation and protected regions (80% / 20%), for
* simplicity only the protected is reduced. If the regions exceed their maximums, this may cause
* protected items to be demoted to the probation region and probation items to be demoted to the
* admission window.
*/
@GuardedBy("evictionLock")
void increaseWindow() {
if (mainProtectedMaximum() == 0) {
return;
}
long quota = Math.min(adjustment(), mainProtectedMaximum());
setMainProtectedMaximum(mainProtectedMaximum() - quota);
setWindowMaximum(windowMaximum() + quota);
demoteFromMainProtected();
for (int i = 0; i < QUEUE_TRANSFER_THRESHOLD; i++) {
Node candidate = accessOrderProbationDeque().peek();
boolean probation = true;
if ((candidate == null) || (quota < candidate.getPolicyWeight())) {
candidate = accessOrderProtectedDeque().peek();
probation = false;
}
if (candidate == null) {
break;
}
int weight = candidate.getPolicyWeight();
if (quota < weight) {
break;
}
quota -= weight;
if (probation) {
accessOrderProbationDeque().remove(candidate);
} else {
setMainProtectedWeightedSize(mainProtectedWeightedSize() - weight);
accessOrderProtectedDeque().remove(candidate);
}
setWindowWeightedSize(windowWeightedSize() + weight);
accessOrderWindowDeque().add(candidate);
candidate.makeWindow();
}
setMainProtectedMaximum(mainProtectedMaximum() + quota);
setWindowMaximum(windowMaximum() - quota);
setAdjustment(quota);
}
/** Decreases the size of the admission window and increases the main's protected region. */
@GuardedBy("evictionLock")
void decreaseWindow() {
if (windowMaximum() <= 1) {
return;
}
long quota = Math.min(-adjustment(), Math.max(0, windowMaximum() - 1));
setMainProtectedMaximum(mainProtectedMaximum() + quota);
setWindowMaximum(windowMaximum() - quota);
for (int i = 0; i < QUEUE_TRANSFER_THRESHOLD; i++) {
Node candidate = accessOrderWindowDeque().peek();
if (candidate == null) {
break;
}
int weight = candidate.getPolicyWeight();
if (quota < weight) {
break;
}
quota -= weight;
setWindowWeightedSize(windowWeightedSize() - weight);
accessOrderWindowDeque().remove(candidate);
accessOrderProbationDeque().add(candidate);
candidate.makeMainProbation();
}
setMainProtectedMaximum(mainProtectedMaximum() - quota);
setWindowMaximum(windowMaximum() + quota);
setAdjustment(-quota);
}
/** Transfers the nodes from the protected to the probation region if it exceeds the maximum. */
@GuardedBy("evictionLock")
void demoteFromMainProtected() {
long mainProtectedMaximum = mainProtectedMaximum();
long mainProtectedWeightedSize = mainProtectedWeightedSize();
if (mainProtectedWeightedSize <= mainProtectedMaximum) {
return;
}
for (int i = 0; i < QUEUE_TRANSFER_THRESHOLD; i++) {
if (mainProtectedWeightedSize <= mainProtectedMaximum) {
break;
}
Node demoted = accessOrderProtectedDeque().poll();
if (demoted == null) {
break;
}
demoted.makeMainProbation();
accessOrderProbationDeque().add(demoted);
mainProtectedWeightedSize -= demoted.getPolicyWeight();
}
setMainProtectedWeightedSize(mainProtectedWeightedSize);
}
/**
* Performs the post-processing work required after a read.
*
* @param node the entry in the page replacement policy
* @param now the current time, in nanoseconds
* @param recordHit if the hit count should be incremented
*/
void afterRead(Node node, long now, boolean recordHit) {
if (recordHit) {
statsCounter().recordHits(1);
}
boolean delayable = skipReadBuffer() || (readBuffer.offer(node) != Buffer.FULL);
if (shouldDrainBuffers(delayable)) {
scheduleDrainBuffers();
}
refreshIfNeeded(node, now);
}
/** Returns if the cache should bypass the read buffer. */
boolean skipReadBuffer() {
return fastpath() && frequencySketch().isNotInitialized();
}
/**
* Asynchronously refreshes the entry if eligible.
*
* @param node the entry in the cache to refresh
* @param now the current time, in nanoseconds
*/
@SuppressWarnings("FutureReturnValueIgnored")
void refreshIfNeeded(Node node, long now) {
if (!refreshAfterWrite()) {
return;
}
K key;
V oldValue;
long oldWriteTime = node.getWriteTime();
long refreshWriteTime = (now + ASYNC_EXPIRY);
if (((now - oldWriteTime) > refreshAfterWriteNanos())
&& ((key = node.getKey()) != null) && ((oldValue = node.getValue()) != null)
&& node.casWriteTime(oldWriteTime, refreshWriteTime)) {
try {
CompletableFuture refreshFuture;
long startTime = statsTicker().read();
if (isAsync) {
@SuppressWarnings("unchecked")
CompletableFuture future = (CompletableFuture) oldValue;
if (Async.isReady(future)) {
@SuppressWarnings("NullAway")
CompletableFuture refresh = future.thenCompose(value ->
cacheLoader.asyncReload(key, value, executor));
refreshFuture = refresh;
} else {
// no-op if load is pending
node.casWriteTime(refreshWriteTime, oldWriteTime);
return;
}
} else {
@SuppressWarnings("NullAway")
CompletableFuture refresh = cacheLoader.asyncReload(key, oldValue, executor);
refreshFuture = refresh;
}
refreshFuture.whenComplete((newValue, error) -> {
long loadTime = statsTicker().read() - startTime;
if (error != null) {
if (!(error instanceof CancellationException) && !(error instanceof TimeoutException)) {
logger.log(Level.WARNING, "Exception thrown during refresh", error);
}
node.casWriteTime(refreshWriteTime, oldWriteTime);
statsCounter().recordLoadFailure(loadTime);
return;
}
@SuppressWarnings("unchecked")
V value = (isAsync && (newValue != null)) ? (V) refreshFuture : newValue;
boolean[] discard = new boolean[1];
compute(key, (k, currentValue) -> {
if (currentValue == null) {
return value;
} else if ((currentValue == oldValue) && (node.getWriteTime() == refreshWriteTime)) {
return value;
}
discard[0] = true;
return currentValue;
}, /* recordMiss */ false, /* recordLoad */ false, /* recordLoadFailure */ true);
if (discard[0] && hasRemovalListener()) {
notifyRemoval(key, value, RemovalCause.REPLACED);
}
if (newValue == null) {
statsCounter().recordLoadFailure(loadTime);
} else {
statsCounter().recordLoadSuccess(loadTime);
}
});
} catch (Throwable t) {
node.casWriteTime(refreshWriteTime, oldWriteTime);
logger.log(Level.SEVERE, "Exception thrown when submitting refresh task", t);
}
}
}
/**
* Returns the expiration time for the entry after being created.
*
* @param key the key of the entry that was created
* @param value the value of the entry that was created
* @param expiry the calculator for the expiration time
* @param now the current time, in nanoseconds
* @return the expiration time
*/
long expireAfterCreate(@Nullable K key, @Nullable V value, Expiry expiry, long now) {
if (expiresVariable() && (key != null) && (value != null)) {
long duration = expiry.expireAfterCreate(key, value, now);
return isAsync ? (now + duration) : (now + Math.min(duration, MAXIMUM_EXPIRY));
}
return 0L;
}
/**
* Returns the expiration time for the entry after being updated.
*
* @param node the entry in the page replacement policy
* @param key the key of the entry that was updated
* @param value the value of the entry that was updated
* @param expiry the calculator for the expiration time
* @param now the current time, in nanoseconds
* @return the expiration time
*/
long expireAfterUpdate(Node node, @Nullable K key,
@Nullable V value, Expiry expiry, long now) {
if (expiresVariable() && (key != null) && (value != null)) {
long currentDuration = Math.max(1, node.getVariableTime() - now);
long duration = expiry.expireAfterUpdate(key, value, now, currentDuration);
return isAsync ? (now + duration) : (now + Math.min(duration, MAXIMUM_EXPIRY));
}
return 0L;
}
/**
* Returns the access time for the entry after a read.
*
* @param node the entry in the page replacement policy
* @param key the key of the entry that was read
* @param value the value of the entry that was read
* @param expiry the calculator for the expiration time
* @param now the current time, in nanoseconds
* @return the expiration time
*/
long expireAfterRead(Node node, @Nullable K key,
@Nullable V value, Expiry expiry, long now) {
if (expiresVariable() && (key != null) && (value != null)) {
long currentDuration = Math.max(1, node.getVariableTime() - now);
long duration = expiry.expireAfterRead(key, value, now, currentDuration);
return isAsync ? (now + duration) : (now + Math.min(duration, MAXIMUM_EXPIRY));
}
return 0L;
}
/**
* Attempts to update the access time for the entry after a read.
*
* @param node the entry in the page replacement policy
* @param key the key of the entry that was read
* @param value the value of the entry that was read
* @param expiry the calculator for the expiration time
* @param now the current time, in nanoseconds
*/
void tryExpireAfterRead(Node node, @Nullable K key,
@Nullable V value, Expiry expiry, long now) {
if (!expiresVariable() || (key == null) || (value == null)) {
return;
}
long variableTime = node.getVariableTime();
long currentDuration = Math.max(1, variableTime - now);
if (isAsync && (currentDuration > MAXIMUM_EXPIRY)) {
// expireAfterCreate has not yet set the duration after completion
return;
}
long duration = expiry.expireAfterRead(key, value, now, currentDuration);
if (duration != currentDuration) {
long expirationTime = isAsync ? (now + duration) : (now + Math.min(duration, MAXIMUM_EXPIRY));
node.casVariableTime(variableTime, expirationTime);
}
}
void setVariableTime(Node node, long expirationTime) {
if (expiresVariable()) {
node.setVariableTime(expirationTime);
}
}
void setWriteTime(Node node, long now) {
if (expiresAfterWrite() || refreshAfterWrite()) {
node.setWriteTime(now);
}
}
void setAccessTime(Node node, long now) {
if (expiresAfterAccess()) {
node.setAccessTime(now);
}
}
/**
* Performs the post-processing work required after a write.
*
* @param task the pending operation to be applied
*/
void afterWrite(Runnable task) {
for (int i = 0; i < WRITE_BUFFER_RETRIES; i++) {
if (writeBuffer.offer(task)) {
scheduleAfterWrite();
return;
}
scheduleDrainBuffers();
}
// The maintenance task may be scheduled but not running. This might occur due to all of the
// executor's threads being busy (perhaps writing into this cache), the write rate greatly
// exceeds the consuming rate, priority inversion, or if the executor silently discarded the
// maintenance task. In these scenarios then the writing threads cannot make progress and
// instead writers provide assistance by performing this work directly.
try {
performCleanUp(task);
} catch (RuntimeException e) {
logger.log(Level.SEVERE, "Exception thrown when performing the maintenance task", e);
}
}
/**
* Conditionally schedules the asynchronous maintenance task after a write operation. If the
* task status was IDLE or REQUIRED then the maintenance task is scheduled immediately. If it
* is already processing then it is set to transition to REQUIRED upon completion so that a new
* execution is triggered by the next operation.
*/
void scheduleAfterWrite() {
for (;;) {
switch (drainStatus()) {
case IDLE:
casDrainStatus(IDLE, REQUIRED);
scheduleDrainBuffers();
return;
case REQUIRED:
scheduleDrainBuffers();
return;
case PROCESSING_TO_IDLE:
if (casDrainStatus(PROCESSING_TO_IDLE, PROCESSING_TO_REQUIRED)) {
return;
}
continue;
case PROCESSING_TO_REQUIRED:
return;
default:
throw new IllegalStateException();
}
}
}
/**
* Attempts to schedule an asynchronous task to apply the pending operations to the page
* replacement policy. If the executor rejects the task then it is run directly.
*/
void scheduleDrainBuffers() {
if (drainStatus() >= PROCESSING_TO_IDLE) {
return;
}
if (evictionLock.tryLock()) {
try {
int drainStatus = drainStatus();
if (drainStatus >= PROCESSING_TO_IDLE) {
return;
}
lazySetDrainStatus(PROCESSING_TO_IDLE);
executor.execute(drainBuffersTask);
} catch (Throwable t) {
logger.log(Level.WARNING, "Exception thrown when submitting maintenance task", t);
maintenance(/* ignored */ null);
} finally {
evictionLock.unlock();
}
}
}
@Override
public void cleanUp() {
try {
performCleanUp(/* ignored */ null);
} catch (RuntimeException e) {
logger.log(Level.SEVERE, "Exception thrown when performing the maintenance task", e);
}
}
/**
* Performs the maintenance work, blocking until the lock is acquired. Any exception thrown, such
* as by {@link CacheWriter#delete}, is propagated to the caller.
*
* @param task an additional pending task to run, or {@code null} if not present
*/
void performCleanUp(@Nullable Runnable task) {
evictionLock.lock();
try {
maintenance(task);
} finally {
evictionLock.unlock();
}
if ((drainStatus() == REQUIRED) && (executor == ForkJoinPool.commonPool())) {
scheduleDrainBuffers();
}
}
/**
* Performs the pending maintenance work and sets the state flags during processing to avoid
* excess scheduling attempts. The read buffer, write buffer, and reference queues are
* drained, followed by expiration, and size-based eviction.
*
* @param task an additional pending task to run, or {@code null} if not present
*/
@GuardedBy("evictionLock")
void maintenance(@Nullable Runnable task) {
lazySetDrainStatus(PROCESSING_TO_IDLE);
try {
drainReadBuffer();
drainWriteBuffer();
if (task != null) {
task.run();
}
drainKeyReferences();
drainValueReferences();
expireEntries();
evictEntries();
climb();
} finally {
if ((drainStatus() != PROCESSING_TO_IDLE) || !casDrainStatus(PROCESSING_TO_IDLE, IDLE)) {
lazySetDrainStatus(REQUIRED);
}
}
}
/** Drains the weak key references queue. */
@GuardedBy("evictionLock")
void drainKeyReferences() {
if (!collectKeys()) {
return;
}
Reference extends K> keyRef;
while ((keyRef = keyReferenceQueue().poll()) != null) {
Node node = data.get(keyRef);
if (node != null) {
evictEntry(node, RemovalCause.COLLECTED, 0L);
}
}
}
/** Drains the weak / soft value references queue. */
@GuardedBy("evictionLock")
void drainValueReferences() {
if (!collectValues()) {
return;
}
Reference extends V> valueRef;
while ((valueRef = valueReferenceQueue().poll()) != null) {
@SuppressWarnings("unchecked")
InternalReference ref = (InternalReference) valueRef;
Node node = data.get(ref.getKeyReference());
if ((node != null) && (valueRef == node.getValueReference())) {
evictEntry(node, RemovalCause.COLLECTED, 0L);
}
}
}
/** Drains the read buffer. */
@GuardedBy("evictionLock")
void drainReadBuffer() {
if (!skipReadBuffer()) {
readBuffer.drainTo(accessPolicy);
}
}
/** Updates the node's location in the page replacement policy. */
@GuardedBy("evictionLock")
void onAccess(Node node) {
if (evicts()) {
K key = node.getKey();
if (key == null) {
return;
}
frequencySketch().increment(key);
if (node.inWindow()) {
reorder(accessOrderWindowDeque(), node);
} else if (node.inMainProbation()) {
reorderProbation(node);
} else {
reorder(accessOrderProtectedDeque(), node);
}
setHitsInSample(hitsInSample() + 1);
} else if (expiresAfterAccess()) {
reorder(accessOrderWindowDeque(), node);
}
if (expiresVariable()) {
timerWheel().reschedule(node);
}
}
/** Promote the node from probation to protected on an access. */
@GuardedBy("evictionLock")
void reorderProbation(Node node) {
if (!accessOrderProbationDeque().contains(node)) {
// Ignore stale accesses for an entry that is no longer present
return;
} else if (node.getPolicyWeight() > mainProtectedMaximum()) {
return;
}
// If the protected space exceeds its maximum, the LRU items are demoted to the probation space.
// This is deferred to the adaption phase at the end of the maintenance cycle.
setMainProtectedWeightedSize(mainProtectedWeightedSize() + node.getPolicyWeight());
accessOrderProbationDeque().remove(node);
accessOrderProtectedDeque().add(node);
node.makeMainProtected();
}
/** Updates the node's location in the policy's deque. */
static void reorder(LinkedDeque> deque, Node node) {
// An entry may be scheduled for reordering despite having been removed. This can occur when the
// entry was concurrently read while a writer was removing it. If the entry is no longer linked
// then it does not need to be processed.
if (deque.contains(node)) {
deque.moveToBack(node);
}
}
/** Drains the write buffer. */
@GuardedBy("evictionLock")
void drainWriteBuffer() {
for (int i = 0; i <= WRITE_BUFFER_MAX; i++) {
Runnable task = writeBuffer.poll();
if (task == null) {
return;
}
task.run();
}
lazySetDrainStatus(PROCESSING_TO_REQUIRED);
}
/**
* Atomically transitions the node to the dead state and decrements the
* weightedSize .
*
* @param node the entry in the page replacement policy
*/
@GuardedBy("evictionLock")
void makeDead(Node node) {
synchronized (node) {
if (node.isDead()) {
return;
}
if (evicts()) {
// The node's policy weight may be out of sync due to a pending update waiting to be
// processed. At this point the node's weight is finalized, so the weight can be safely
// taken from the node's perspective and the sizes will be adjusted correctly.
if (node.inWindow()) {
setWindowWeightedSize(windowWeightedSize() - node.getWeight());
} else if (node.inMainProtected()) {
setMainProtectedWeightedSize(mainProtectedWeightedSize() - node.getWeight());
}
setWeightedSize(weightedSize() - node.getWeight());
}
node.die();
}
}
/** Adds the node to the page replacement policy. */
final class AddTask implements Runnable {
final Node node;
final int weight;
AddTask(Node node, int weight) {
this.weight = weight;
this.node = node;
}
@Override
@GuardedBy("evictionLock")
@SuppressWarnings("FutureReturnValueIgnored")
public void run() {
if (evicts()) {
long weightedSize = weightedSize();
setWeightedSize(weightedSize + weight);
setWindowWeightedSize(windowWeightedSize() + weight);
node.setPolicyWeight(node.getPolicyWeight() + weight);
long maximum = maximum();
if (weightedSize >= (maximum >>> 1)) {
// Lazily initialize when close to the maximum
long capacity = isWeighted() ? data.mappingCount() : maximum;
frequencySketch().ensureCapacity(capacity);
}
K key = node.getKey();
if (key != null) {
frequencySketch().increment(key);
}
setMissesInSample(missesInSample() + 1);
}
// ignore out-of-order write operations
boolean isAlive;
synchronized (node) {
isAlive = node.isAlive();
}
if (isAlive) {
if (expiresAfterWrite()) {
writeOrderDeque().add(node);
}
if (evicts() && (weight > windowMaximum())) {
accessOrderWindowDeque().offerFirst(node);
} else if (evicts() || expiresAfterAccess()) {
accessOrderWindowDeque().offerLast(node);
}
if (expiresVariable()) {
timerWheel().schedule(node);
}
}
// Ensure that in-flight async computation cannot expire (reset on a completion callback)
if (isComputingAsync(node)) {
synchronized (node) {
if (!Async.isReady((CompletableFuture>) node.getValue())) {
long expirationTime = expirationTicker().read() + ASYNC_EXPIRY;
setVariableTime(node, expirationTime);
setAccessTime(node, expirationTime);
setWriteTime(node, expirationTime);
}
}
}
}
}
/** Removes a node from the page replacement policy. */
final class RemovalTask implements Runnable {
final Node node;
RemovalTask(Node node) {
this.node = node;
}
@Override
@GuardedBy("evictionLock")
public void run() {
// add may not have been processed yet
if (node.inWindow() && (evicts() || expiresAfterAccess())) {
accessOrderWindowDeque().remove(node);
} else if (evicts()) {
if (node.inMainProbation()) {
accessOrderProbationDeque().remove(node);
} else {
accessOrderProtectedDeque().remove(node);
}
}
if (expiresAfterWrite()) {
writeOrderDeque().remove(node);
} else if (expiresVariable()) {
timerWheel().deschedule(node);
}
makeDead(node);
}
}
/** Updates the weighted size. */
final class UpdateTask implements Runnable {
final int weightDifference;
final Node node;
public UpdateTask(Node node, int weightDifference) {
this.weightDifference = weightDifference;
this.node = node;
}
@Override
@GuardedBy("evictionLock")
public void run() {
if (evicts()) {
int oldWeightedSize = node.getPolicyWeight();
node.setPolicyWeight(oldWeightedSize + weightDifference);
if (node.inWindow()) {
if (node.getPolicyWeight() <= windowMaximum()) {
onAccess(node);
} else if (accessOrderWindowDeque().contains(node)) {
accessOrderWindowDeque().moveToFront(node);
}
setWindowWeightedSize(windowWeightedSize() + weightDifference);
} else if (node.inMainProbation()) {
if (node.getPolicyWeight() <= maximum()) {
onAccess(node);
} else if (accessOrderProbationDeque().remove(node)) {
accessOrderWindowDeque().addFirst(node);
setWindowWeightedSize(windowWeightedSize() + node.getPolicyWeight());
}
} else if (node.inMainProtected()) {
if (node.getPolicyWeight() <= maximum()) {
onAccess(node);
setMainProtectedWeightedSize(mainProtectedWeightedSize() + weightDifference);
} else if (accessOrderProtectedDeque().remove(node)) {
accessOrderWindowDeque().addFirst(node);
setWindowWeightedSize(windowWeightedSize() + node.getPolicyWeight());
setMainProtectedWeightedSize(mainProtectedWeightedSize() - oldWeightedSize);
} else {
setMainProtectedWeightedSize(mainProtectedWeightedSize() - oldWeightedSize);
}
}
setWeightedSize(weightedSize() + weightDifference);
} else if (expiresAfterAccess()) {
onAccess(node);
}
if (expiresAfterWrite()) {
reorder(writeOrderDeque(), node);
} else if (expiresVariable()) {
timerWheel().reschedule(node);
}
}
}
/* --------------- Concurrent Map Support --------------- */
@Override
public boolean isEmpty() {
return data.isEmpty();
}
@Override
public int size() {
return data.size();
}
@Override
public long estimatedSize() {
return data.mappingCount();
}
@Override
@SuppressWarnings("FutureReturnValueIgnored")
public void clear() {
evictionLock.lock();
try {
long now = expirationTicker().read();
// Apply all pending writes
Runnable task;
while ((task = writeBuffer.poll()) != null) {
task.run();
}
// Discard all entries
for (Node node : data.values()) {
removeNode(node, now);
}
// Cancel the scheduled cleanup
Pacer pacer = pacer();
if (pacer != null) {
pacer.cancel();
}
// Discard all pending reads
readBuffer.drainTo(e -> {});
} finally {
evictionLock.unlock();
}
}
@GuardedBy("evictionLock")
@SuppressWarnings("GuardedByChecker")
void removeNode(Node node, long now) {
K key = node.getKey();
@SuppressWarnings("unchecked")
V[] value = (V[]) new Object[1];
RemovalCause[] cause = new RemovalCause[1];
data.computeIfPresent(node.getKeyReference(), (k, n) -> {
if (n != node) {
return n;
}
synchronized (n) {
value[0] = n.getValue();
if ((key == null) || (value[0] == null)) {
cause[0] = RemovalCause.COLLECTED;
} else if (hasExpired(n, now)) {
cause[0] = RemovalCause.EXPIRED;
} else {
cause[0] = RemovalCause.EXPLICIT;
}
if (key != null) {
writer.delete(key, value[0], cause[0]);
}
makeDead(n);
return null;
}
});
if (node.inWindow() && (evicts() || expiresAfterAccess())) {
accessOrderWindowDeque().remove(node);
} else if (evicts()) {
if (node.inMainProbation()) {
accessOrderProbationDeque().remove(node);
} else {
accessOrderProtectedDeque().remove(node);
}
}
if (expiresAfterWrite()) {
writeOrderDeque().remove(node);
} else if (expiresVariable()) {
timerWheel().deschedule(node);
}
if ((cause[0] != null) && hasRemovalListener()) {
notifyRemoval(key, value[0], cause[0]);
}
}
@Override
public boolean containsKey(Object key) {
Node node = data.get(nodeFactory.newLookupKey(key));
return (node != null) && (node.getValue() != null)
&& !hasExpired(node, expirationTicker().read());
}
@Override
public boolean containsValue(Object value) {
requireNonNull(value);
long now = expirationTicker().read();
for (Node node : data.values()) {
if (node.containsValue(value) && !hasExpired(node, now) && (node.getKey() != null)) {
return true;
}
}
return false;
}
@Override
public @Nullable V get(Object key) {
return getIfPresent(key, /* recordStats */ false);
}
@Override
public @Nullable V getIfPresent(Object key, boolean recordStats) {
Node node = data.get(nodeFactory.newLookupKey(key));
if (node == null) {
if (recordStats) {
statsCounter().recordMisses(1);
}
if (drainStatus() == REQUIRED) {
scheduleDrainBuffers();
}
return null;
}
V value = node.getValue();
long now = expirationTicker().read();
if (hasExpired(node, now) || (collectValues() && (value == null))) {
if (recordStats) {
statsCounter().recordMisses(1);
}
scheduleDrainBuffers();
return null;
}
if (!isComputingAsync(node)) {
@SuppressWarnings("unchecked")
K castedKey = (K) key;
setAccessTime(node, now);
tryExpireAfterRead(node, castedKey, value, expiry(), now);
}
afterRead(node, now, recordStats);
return value;
}
@Override
public @Nullable V getIfPresentQuietly(Object key, long[/* 1 */] writeTime) {
V value;
Node node = data.get(nodeFactory.newLookupKey(key));
if ((node == null) || ((value = node.getValue()) == null)
|| hasExpired(node, expirationTicker().read())) {
return null;
}
writeTime[0] = node.getWriteTime();
return value;
}
@Override
public Map getAllPresent(Iterable> keys) {
Set uniqueKeys = new LinkedHashSet<>();
for (Object key : keys) {
uniqueKeys.add(key);
}
int misses = 0;
long now = expirationTicker().read();
Map result = new LinkedHashMap<>(uniqueKeys.size());
for (Object key : uniqueKeys) {
V value;
Node node = data.get(nodeFactory.newLookupKey(key));
if ((node == null) || ((value = node.getValue()) == null) || hasExpired(node, now)) {
misses++;
} else {
result.put(key, value);
if (!isComputingAsync(node)) {
@SuppressWarnings("unchecked")
K castedKey = (K) key;
tryExpireAfterRead(node, castedKey, value, expiry(), now);
setAccessTime(node, now);
}
afterRead(node, now, /* recordHit */ false);
}
}
statsCounter().recordMisses(misses);
statsCounter().recordHits(result.size());
@SuppressWarnings("unchecked")
Map castedResult = (Map) result;
return Collections.unmodifiableMap(castedResult);
}
@Override
public @Nullable V put(K key, V value) {
return put(key, value, expiry(), /* notifyWriter */ true, /* onlyIfAbsent */ false);
}
@Override
public @Nullable V put(K key, V value, boolean notifyWriter) {
return put(key, value, expiry(), notifyWriter, /* onlyIfAbsent */ false);
}
@Override
public @Nullable V putIfAbsent(K key, V value) {
return put(key, value, expiry(), /* notifyWriter */ true, /* onlyIfAbsent */ true);
}
/**
* Adds a node to the policy and the data store. If an existing node is found, then its value is
* updated if allowed.
*
* @param key key with which the specified value is to be associated
* @param value value to be associated with the specified key
* @param expiry the calculator for the expiration time
* @param notifyWriter if the writer should be notified for an inserted or updated entry
* @param onlyIfAbsent a write is performed only if the key is not already associated with a value
* @return the prior value in or null if no mapping was found
*/
@Nullable V put(K key, V value, Expiry expiry, boolean notifyWriter, boolean onlyIfAbsent) {
requireNonNull(key);
requireNonNull(value);
Node node = null;
long now = expirationTicker().read();
int newWeight = weigher.weigh(key, value);
for (;;) {
Node prior = data.get(nodeFactory.newLookupKey(key));
if (prior == null) {
if (node == null) {
node = nodeFactory.newNode(key, keyReferenceQueue(),
value, valueReferenceQueue(), newWeight, now);
setVariableTime(node, expireAfterCreate(key, value, expiry, now));
}
if (notifyWriter && hasWriter()) {
Node computed = node;
prior = data.computeIfAbsent(node.getKeyReference(), k -> {
writer.write(key, value);
return computed;
});
if (prior == node) {
afterWrite(new AddTask(node, newWeight));
return null;
} else if (onlyIfAbsent) {
// An optimistic fast path to avoid unnecessary locking
V currentValue = prior.getValue();
if ((currentValue != null) && !hasExpired(prior, now)) {
if (!isComputingAsync(prior)) {
tryExpireAfterRead(prior, key, currentValue, expiry(), now);
setAccessTime(prior, now);
}
afterRead(prior, now, /* recordHit */ false);
return currentValue;
}
}
} else {
prior = data.putIfAbsent(node.getKeyReference(), node);
if (prior == null) {
afterWrite(new AddTask(node, newWeight));
return null;
} else if (onlyIfAbsent) {
// An optimistic fast path to avoid unnecessary locking
V currentValue = prior.getValue();
if ((currentValue != null) && !hasExpired(prior, now)) {
if (!isComputingAsync(prior)) {
tryExpireAfterRead(prior, key, currentValue, expiry(), now);
setAccessTime(prior, now);
}
afterRead(prior, now, /* recordHit */ false);
return currentValue;
}
}
}
} else if (onlyIfAbsent) {
// An optimistic fast path to avoid unnecessary locking
V currentValue = prior.getValue();
if ((currentValue != null) && !hasExpired(prior, now)) {
if (!isComputingAsync(prior)) {
tryExpireAfterRead(prior, key, currentValue, expiry(), now);
setAccessTime(prior, now);
}
afterRead(prior, now, /* recordHit */ false);
return currentValue;
}
}
V oldValue;
long varTime;
int oldWeight;
boolean expired = false;
boolean mayUpdate = true;
boolean exceedsTolerance = false;
synchronized (prior) {
if (!prior.isAlive()) {
continue;
}
oldValue = prior.getValue();
oldWeight = prior.getWeight();
if (oldValue == null) {
varTime = expireAfterCreate(key, value, expiry, now);
writer.delete(key, null, RemovalCause.COLLECTED);
} else if (hasExpired(prior, now)) {
expired = true;
varTime = expireAfterCreate(key, value, expiry, now);
writer.delete(key, oldValue, RemovalCause.EXPIRED);
} else if (onlyIfAbsent) {
mayUpdate = false;
varTime = expireAfterRead(prior, key, value, expiry, now);
} else {
varTime = expireAfterUpdate(prior, key, value, expiry, now);
}
if (notifyWriter && (expired || (mayUpdate && (value != oldValue)))) {
writer.write(key, value);
}
if (mayUpdate) {
exceedsTolerance =
(expiresAfterWrite() && (now - prior.getWriteTime()) > EXPIRE_WRITE_TOLERANCE)
|| (expiresVariable()
&& Math.abs(varTime - prior.getVariableTime()) > EXPIRE_WRITE_TOLERANCE);
setWriteTime(prior, now);
prior.setWeight(newWeight);
prior.setValue(value, valueReferenceQueue());
}
setVariableTime(prior, varTime);
setAccessTime(prior, now);
}
if (hasRemovalListener()) {
if (expired) {
notifyRemoval(key, oldValue, RemovalCause.EXPIRED);
} else if (oldValue == null) {
notifyRemoval(key, /* oldValue */ null, RemovalCause.COLLECTED);
} else if (mayUpdate && (value != oldValue)) {
notifyRemoval(key, oldValue, RemovalCause.REPLACED);
}
}
int weightedDifference = mayUpdate ? (newWeight - oldWeight) : 0;
if ((oldValue == null) || (weightedDifference != 0) || expired) {
afterWrite(new UpdateTask(prior, weightedDifference));
} else if (!onlyIfAbsent && exceedsTolerance) {
afterWrite(new UpdateTask(prior, weightedDifference));
} else {
if (mayUpdate) {
setWriteTime(prior, now);
}
afterRead(prior, now, /* recordHit */ false);
}
return expired ? null : oldValue;
}
}
@Override
public @Nullable V remove(Object key) {
@SuppressWarnings("unchecked")
K castKey = (K) key;
@SuppressWarnings({"unchecked", "rawtypes"})
Node[] node = new Node[1];
@SuppressWarnings("unchecked")
V[] oldValue = (V[]) new Object[1];
RemovalCause[] cause = new RemovalCause[1];
data.computeIfPresent(nodeFactory.newLookupKey(key), (k, n) -> {
synchronized (n) {
oldValue[0] = n.getValue();
if (oldValue[0] == null) {
cause[0] = RemovalCause.COLLECTED;
} else if (hasExpired(n, expirationTicker().read())) {
cause[0] = RemovalCause.EXPIRED;
} else {
cause[0] = RemovalCause.EXPLICIT;
}
writer.delete(castKey, oldValue[0], cause[0]);
n.retire();
}
node[0] = n;
return null;
});
if (cause[0] != null) {
afterWrite(new RemovalTask(node[0]));
if (hasRemovalListener()) {
notifyRemoval(castKey, oldValue[0], cause[0]);
}
}
return (cause[0] == RemovalCause.EXPLICIT) ? oldValue[0] : null;
}
@Override
public boolean remove(Object key, Object value) {
requireNonNull(key);
if (value == null) {
return false;
}
@SuppressWarnings({"unchecked", "rawtypes"})
Node[] removed = new Node[1];
@SuppressWarnings("unchecked")
K[] oldKey = (K[]) new Object[1];
@SuppressWarnings("unchecked")
V[] oldValue = (V[]) new Object[1];
RemovalCause[] cause = new RemovalCause[1];
data.computeIfPresent(nodeFactory.newLookupKey(key), (kR, node) -> {
synchronized (node) {
oldKey[0] = node.getKey();
oldValue[0] = node.getValue();
if (oldKey[0] == null) {
cause[0] = RemovalCause.COLLECTED;
} else if (hasExpired(node, expirationTicker().read())) {
cause[0] = RemovalCause.EXPIRED;
} else if (node.containsValue(value)) {
cause[0] = RemovalCause.EXPLICIT;
} else {
return node;
}
writer.delete(oldKey[0], oldValue[0], cause[0]);
removed[0] = node;
node.retire();
return null;
}
});
if (removed[0] == null) {
return false;
} else if (hasRemovalListener()) {
notifyRemoval(oldKey[0], oldValue[0], cause[0]);
}
afterWrite(new RemovalTask(removed[0]));
return (cause[0] == RemovalCause.EXPLICIT);
}
@Override
public @Nullable V replace(K key, V value) {
requireNonNull(key);
requireNonNull(value);
int[] oldWeight = new int[1];
@SuppressWarnings("unchecked")
K[] nodeKey = (K[]) new Object[1];
@SuppressWarnings("unchecked")
V[] oldValue = (V[]) new Object[1];
long[] now = new long[1];
int weight = weigher.weigh(key, value);
Node node = data.computeIfPresent(nodeFactory.newLookupKey(key), (k, n) -> {
synchronized (n) {
nodeKey[0] = n.getKey();
oldValue[0] = n.getValue();
oldWeight[0] = n.getWeight();
if ((nodeKey[0] == null) || (oldValue[0] == null)
|| hasExpired(n, now[0] = expirationTicker().read())) {
oldValue[0] = null;
return n;
}
long varTime = expireAfterUpdate(n, key, value, expiry(), now[0]);
if (value != oldValue[0]) {
writer.write(nodeKey[0], value);
}
n.setValue(value, valueReferenceQueue());
n.setWeight(weight);
setVariableTime(n, varTime);
setAccessTime(n, now[0]);
setWriteTime(n, now[0]);
return n;
}
});
if (oldValue[0] == null) {
return null;
}
int weightedDifference = (weight - oldWeight[0]);
if (expiresAfterWrite() || (weightedDifference != 0)) {
afterWrite(new UpdateTask(node, weightedDifference));
} else {
afterRead(node, now[0], /* recordHit */ false);
}
if (hasRemovalListener() && (value != oldValue[0])) {
notifyRemoval(nodeKey[0], oldValue[0], RemovalCause.REPLACED);
}
return oldValue[0];
}
@Override
public boolean replace(K key, V oldValue, V newValue) {
requireNonNull(key);
requireNonNull(oldValue);
requireNonNull(newValue);
int weight = weigher.weigh(key, newValue);
boolean[] replaced = new boolean[1];
@SuppressWarnings("unchecked")
K[] nodeKey = (K[]) new Object[1];
@SuppressWarnings("unchecked")
V[] prevValue = (V[]) new Object[1];
int[] oldWeight = new int[1];
long[] now = new long[1];
Node node = data.computeIfPresent(nodeFactory.newLookupKey(key), (k, n) -> {
synchronized (n) {
nodeKey[0] = n.getKey();
prevValue[0] = n.getValue();
oldWeight[0] = n.getWeight();
if ((nodeKey[0] == null) || (prevValue[0] == null) || !n.containsValue(oldValue)
|| hasExpired(n, now[0] = expirationTicker().read())) {
return n;
}
long varTime = expireAfterUpdate(n, key, newValue, expiry(), now[0]);
if (newValue != prevValue[0]) {
writer.write(key, newValue);
}
n.setValue(newValue, valueReferenceQueue());
n.setWeight(weight);
setVariableTime(n, varTime);
setAccessTime(n, now[0]);
setWriteTime(n, now[0]);
replaced[0] = true;
}
return n;
});
if (!replaced[0]) {
return false;
}
int weightedDifference = (weight - oldWeight[0]);
if (expiresAfterWrite() || (weightedDifference != 0)) {
afterWrite(new UpdateTask(node, weightedDifference));
} else {
afterRead(node, now[0], /* recordHit */ false);
}
if (hasRemovalListener() && (oldValue != newValue)) {
notifyRemoval(nodeKey[0], prevValue[0], RemovalCause.REPLACED);
}
return true;
}
@Override
public void replaceAll(BiFunction super K, ? super V, ? extends V> function) {
requireNonNull(function);
BiFunction remappingFunction = (key, oldValue) -> {
V newValue = requireNonNull(function.apply(key, oldValue));
if (oldValue != newValue) {
writer.write(key, newValue);
}
return newValue;
};
for (K key : keySet()) {
long[] now = { expirationTicker().read() };
Object lookupKey = nodeFactory.newLookupKey(key);
remap(key, lookupKey, remappingFunction, now, /* computeIfAbsent */ false);
}
}
@Override
public @Nullable V computeIfAbsent(K key, Function super K, ? extends V> mappingFunction,
boolean recordStats, boolean recordLoad) {
requireNonNull(key);
requireNonNull(mappingFunction);
long now = expirationTicker().read();
// An optimistic fast path to avoid unnecessary locking
Node node = data.get(nodeFactory.newLookupKey(key));
if (node != null) {
V value = node.getValue();
if ((value != null) && !hasExpired(node, now)) {
if (!isComputingAsync(node)) {
tryExpireAfterRead(node, key, value, expiry(), now);
setAccessTime(node, now);
}
afterRead(node, now, /* recordHit */ recordStats);
return value;
}
}
if (recordStats) {
mappingFunction = statsAware(mappingFunction, recordLoad);
}
Object keyRef = nodeFactory.newReferenceKey(key, keyReferenceQueue());
return doComputeIfAbsent(key, keyRef, mappingFunction, new long[] { now }, recordStats);
}
/** Returns the current value from a computeIfAbsent invocation. */
@Nullable V doComputeIfAbsent(K key, Object keyRef,
Function super K, ? extends V> mappingFunction, long[/* 1 */] now, boolean recordStats) {
@SuppressWarnings("unchecked")
V[] oldValue = (V[]) new Object[1];
@SuppressWarnings("unchecked")
V[] newValue = (V[]) new Object[1];
@SuppressWarnings("unchecked")
K[] nodeKey = (K[]) new Object[1];
@SuppressWarnings({"unchecked", "rawtypes"})
Node[] removed = new Node[1];
int[] weight = new int[2]; // old, new
RemovalCause[] cause = new RemovalCause[1];
Node node = data.compute(keyRef, (k, n) -> {
if (n == null) {
newValue[0] = mappingFunction.apply(key);
if (newValue[0] == null) {
return null;
}
now[0] = expirationTicker().read();
weight[1] = weigher.weigh(key, newValue[0]);
n = nodeFactory.newNode(key, keyReferenceQueue(),
newValue[0], valueReferenceQueue(), weight[1], now[0]);
setVariableTime(n, expireAfterCreate(key, newValue[0], expiry(), now[0]));
return n;
}
synchronized (n) {
nodeKey[0] = n.getKey();
weight[0] = n.getWeight();
oldValue[0] = n.getValue();
if ((nodeKey[0] == null) || (oldValue[0] == null)) {
cause[0] = RemovalCause.COLLECTED;
} else if (hasExpired(n, now[0])) {
cause[0] = RemovalCause.EXPIRED;
} else {
return n;
}
writer.delete(nodeKey[0], oldValue[0], cause[0]);
newValue[0] = mappingFunction.apply(key);
if (newValue[0] == null) {
removed[0] = n;
n.retire();
return null;
}
weight[1] = weigher.weigh(key, newValue[0]);
n.setValue(newValue[0], valueReferenceQueue());
n.setWeight(weight[1]);
now[0] = expirationTicker().read();
setVariableTime(n, expireAfterCreate(key, newValue[0], expiry(), now[0]));
setAccessTime(n, now[0]);
setWriteTime(n, now[0]);
return n;
}
});
if (node == null) {
if (removed[0] != null) {
afterWrite(new RemovalTask(removed[0]));
}
return null;
}
if (cause[0] != null) {
if (hasRemovalListener()) {
notifyRemoval(nodeKey[0], oldValue[0], cause[0]);
}
statsCounter().recordEviction(weight[0], cause[0]);
}
if (newValue[0] == null) {
if (!isComputingAsync(node)) {
tryExpireAfterRead(node, key, oldValue[0], expiry(), now[0]);
setAccessTime(node, now[0]);
}
afterRead(node, now[0], /* recordHit */ recordStats);
return oldValue[0];
}
if ((oldValue[0] == null) && (cause[0] == null)) {
afterWrite(new AddTask(node, weight[1]));
} else {
int weightedDifference = (weight[1] - weight[0]);
afterWrite(new UpdateTask(node, weightedDifference));
}
return newValue[0];
}
@Override
public @Nullable V computeIfPresent(K key,
BiFunction super K, ? super V, ? extends V> remappingFunction) {
requireNonNull(key);
requireNonNull(remappingFunction);
// A optimistic fast path to avoid unnecessary locking
Object lookupKey = nodeFactory.newLookupKey(key);
@Nullable Node node = data.get(lookupKey);
long now;
if (node == null) {
return null;
} else if ((node.getValue() == null) || hasExpired(node, (now = expirationTicker().read()))) {
scheduleDrainBuffers();
return null;
}
BiFunction super K, ? super V, ? extends V> statsAwareRemappingFunction =
statsAware(remappingFunction, /* recordMiss */ false,
/* recordLoad */ true, /* recordLoadFailure */ true);
return remap(key, lookupKey, statsAwareRemappingFunction,
new long[] { now }, /* computeIfAbsent */ false);
}
@Override
public @Nullable V compute(K key, BiFunction super K, ? super V, ? extends V> remappingFunction,
boolean recordMiss, boolean recordLoad, boolean recordLoadFailure) {
requireNonNull(key);
requireNonNull(remappingFunction);
long[] now = { expirationTicker().read() };
Object keyRef = nodeFactory.newReferenceKey(key, keyReferenceQueue());
BiFunction super K, ? super V, ? extends V> statsAwareRemappingFunction =
statsAware(remappingFunction, recordMiss, recordLoad, recordLoadFailure);
return remap(key, keyRef, statsAwareRemappingFunction, now, /* computeIfAbsent */ true);
}
@Override
public @Nullable V merge(K key, V value,
BiFunction super V, ? super V, ? extends V> remappingFunction) {
requireNonNull(key);
requireNonNull(value);
requireNonNull(remappingFunction);
long[] now = { expirationTicker().read() };
Object keyRef = nodeFactory.newReferenceKey(key, keyReferenceQueue());
BiFunction super K, ? super V, ? extends V> mergeFunction = (k, oldValue) ->
(oldValue == null) ? value : statsAware(remappingFunction).apply(oldValue, value);
return remap(key, keyRef, mergeFunction, now, /* computeIfAbsent */ true);
}
/**
* Attempts to compute a mapping for the specified key and its current mapped value (or
* {@code null} if there is no current mapping).
*
* An entry that has expired or been reference collected is evicted and the computation continues
* as if the entry had not been present. This method does not pre-screen and does not wrap the
* remappingFunction to be statistics aware.
*
* @param key key with which the specified value is to be associated
* @param keyRef the key to associate with or a lookup only key if not computeIfAbsent
* @param remappingFunction the function to compute a value
* @param now the current time, according to the ticker
* @param computeIfAbsent if an absent entry can be computed
* @return the new value associated with the specified key, or null if none
*/
@SuppressWarnings("PMD.EmptyIfStmt")
@Nullable V remap(K key, Object keyRef,
BiFunction super K, ? super V, ? extends V> remappingFunction,
long[/* 1 */] now, boolean computeIfAbsent) {
@SuppressWarnings("unchecked")
K[] nodeKey = (K[]) new Object[1];
@SuppressWarnings("unchecked")
V[] oldValue = (V[]) new Object[1];
@SuppressWarnings("unchecked")
V[] newValue = (V[]) new Object[1];
@SuppressWarnings({"unchecked", "rawtypes"})
Node[] removed = new Node[1];
int[] weight = new int[2]; // old, new
RemovalCause[] cause = new RemovalCause[1];
Node node = data.compute(keyRef, (kr, n) -> {
if (n == null) {
if (!computeIfAbsent) {
return null;
}
newValue[0] = remappingFunction.apply(key, null);
if (newValue[0] == null) {
return null;
}
now[0] = expirationTicker().read();
weight[1] = weigher.weigh(key, newValue[0]);
n = nodeFactory.newNode(keyRef, newValue[0],
valueReferenceQueue(), weight[1], now[0]);
setVariableTime(n, expireAfterCreate(key, newValue[0], expiry(), now[0]));
return n;
}
synchronized (n) {
nodeKey[0] = n.getKey();
oldValue[0] = n.getValue();
if ((nodeKey[0] == null) || (oldValue[0] == null)) {
cause[0] = RemovalCause.COLLECTED;
} else if (hasExpired(n, now[0])) {
cause[0] = RemovalCause.EXPIRED;
}
if (cause[0] != null) {
writer.delete(nodeKey[0], oldValue[0], cause[0]);
if (!computeIfAbsent) {
removed[0] = n;
n.retire();
return null;
}
}
newValue[0] = remappingFunction.apply(nodeKey[0],
(cause[0] == null) ? oldValue[0] : null);
if (newValue[0] == null) {
if (cause[0] == null) {
cause[0] = RemovalCause.EXPLICIT;
}
removed[0] = n;
n.retire();
return null;
}
weight[0] = n.getWeight();
weight[1] = weigher.weigh(key, newValue[0]);
now[0] = expirationTicker().read();
if (cause[0] == null) {
if (newValue[0] != oldValue[0]) {
cause[0] = RemovalCause.REPLACED;
}
setVariableTime(n, expireAfterUpdate(n, key, newValue[0], expiry(), now[0]));
} else {
setVariableTime(n, expireAfterCreate(key, newValue[0], expiry(), now[0]));
}
n.setValue(newValue[0], valueReferenceQueue());
n.setWeight(weight[1]);
setAccessTime(n, now[0]);
setWriteTime(n, now[0]);
return n;
}
});
if (cause[0] != null) {
if (cause[0].wasEvicted()) {
statsCounter().recordEviction(weight[0], cause[0]);
}
if (hasRemovalListener()) {
notifyRemoval(nodeKey[0], oldValue[0], cause[0]);
}
}
if (removed[0] != null) {
afterWrite(new RemovalTask(removed[0]));
} else if (node == null) {
// absent and not computable
} else if ((oldValue[0] == null) && (cause[0] == null)) {
afterWrite(new AddTask(node, weight[1]));
} else {
int weightedDifference = weight[1] - weight[0];
if (expiresAfterWrite() || (weightedDifference != 0)) {
afterWrite(new UpdateTask(node, weightedDifference));
} else {
if (cause[0] == null) {
if (!isComputingAsync(node)) {
tryExpireAfterRead(node, key, newValue[0], expiry(), now[0]);
setAccessTime(node, now[0]);
}
} else if (cause[0] == RemovalCause.COLLECTED) {
scheduleDrainBuffers();
}
afterRead(node, now[0], /* recordHit */ false);
}
}
return newValue[0];
}
@Override
public Set keySet() {
final Set ks = keySet;
return (ks == null) ? (keySet = new KeySetView<>(this)) : ks;
}
@Override
public Collection values() {
final Collection vs = values;
return (vs == null) ? (values = new ValuesView<>(this)) : vs;
}
@Override
public Set> entrySet() {
final Set> es = entrySet;
return (es == null) ? (entrySet = new EntrySetView<>(this)) : es;
}
/**
* Returns an unmodifiable snapshot map ordered in eviction order, either ascending or descending.
* Beware that obtaining the mappings is NOT a constant-time operation.
*
* @param limit the maximum number of entries
* @param transformer a function that unwraps the value
* @param hottest the iteration order
* @return an unmodifiable snapshot in a specified order
*/
@SuppressWarnings("GuardedByChecker")
Map evictionOrder(int limit, Function transformer, boolean hottest) {
Supplier>> iteratorSupplier = () -> {
Comparator> comparator = Comparator.comparingInt(node -> {
K key = node.getKey();
return (key == null) ? 0 : frequencySketch().frequency(key);
});
if (hottest) {
PeekingIterator> secondary = PeekingIterator.comparing(
accessOrderProbationDeque().descendingIterator(),
accessOrderWindowDeque().descendingIterator(), comparator);
return PeekingIterator.concat(accessOrderProtectedDeque().descendingIterator(), secondary);
} else {
PeekingIterator> primary = PeekingIterator.comparing(
accessOrderWindowDeque().iterator(), accessOrderProbationDeque().iterator(),
comparator.reversed());
return PeekingIterator.concat(primary, accessOrderProtectedDeque().iterator());
}
};
return fixedSnapshot(iteratorSupplier, limit, transformer);
}
/**
* Returns an unmodifiable snapshot map ordered in access expiration order, either ascending or
* descending. Beware that obtaining the mappings is NOT a constant-time operation.
*
* @param limit the maximum number of entries
* @param transformer a function that unwraps the value
* @param oldest the iteration order
* @return an unmodifiable snapshot in a specified order
*/
@SuppressWarnings("GuardedByChecker")
Map expireAfterAccessOrder(int limit, Function transformer, boolean oldest) {
if (!evicts()) {
Supplier>> iteratorSupplier = () -> oldest
? accessOrderWindowDeque().iterator()
: accessOrderWindowDeque().descendingIterator();
return fixedSnapshot(iteratorSupplier, limit, transformer);
}
Supplier>> iteratorSupplier = () -> {
Comparator> comparator = Comparator.comparingLong(Node::getAccessTime);
PeekingIterator> first, second, third;
if (oldest) {
first = accessOrderWindowDeque().iterator();
second = accessOrderProbationDeque().iterator();
third = accessOrderProtectedDeque().iterator();
} else {
comparator = comparator.reversed();
first = accessOrderWindowDeque().descendingIterator();
second = accessOrderProbationDeque().descendingIterator();
third = accessOrderProtectedDeque().descendingIterator();
}
return PeekingIterator.comparing(
PeekingIterator.comparing(first, second, comparator), third, comparator);
};
return fixedSnapshot(iteratorSupplier, limit, transformer);
}
/**
* Returns an unmodifiable snapshot map ordered in write expiration order, either ascending or
* descending. Beware that obtaining the mappings is NOT a constant-time operation.
*
* @param limit the maximum number of entries
* @param transformer a function that unwraps the value
* @param oldest the iteration order
* @return an unmodifiable snapshot in a specified order
*/
@SuppressWarnings("GuardedByChecker")
Map expireAfterWriteOrder(int limit, Function transformer, boolean oldest) {
Supplier>> iteratorSupplier = () -> oldest
? writeOrderDeque().iterator()
: writeOrderDeque().descendingIterator();
return fixedSnapshot(iteratorSupplier, limit, transformer);
}
/**
* Returns an unmodifiable snapshot map ordered by the provided iterator. Beware that obtaining
* the mappings is NOT a constant-time operation.
*
* @param iteratorSupplier the iterator
* @param limit the maximum number of entries
* @param transformer a function that unwraps the value
* @return an unmodifiable snapshot in the iterator's order
*/
Map fixedSnapshot(Supplier>> iteratorSupplier,
int limit, Function transformer) {
requireArgument(limit >= 0);
evictionLock.lock();
try {
maintenance(/* ignored */ null);
int initialCapacity = Math.min(limit, size());
Iterator> iterator = iteratorSupplier.get();
Map map = new LinkedHashMap<>(initialCapacity);
while ((map.size() < limit) && iterator.hasNext()) {
Node node = iterator.next();
K key = node.getKey();
V value = transformer.apply(node.getValue());
if ((key != null) && (value != null) && node.isAlive()) {
map.put(key, value);
}
}
return Collections.unmodifiableMap(map);
} finally {
evictionLock.unlock();
}
}
/**
* Returns an unmodifiable snapshot map roughly ordered by the expiration time. The wheels are
* evaluated in order, but the timers that fall within the bucket's range are not sorted. Beware
* that obtaining the mappings is NOT a constant-time operation.
*
* @param ascending the direction
* @param limit the maximum number of entries
* @param transformer a function that unwraps the value
* @return an unmodifiable snapshot in the desired order
*/
Map variableSnapshot(boolean ascending, int limit, Function transformer) {
evictionLock.lock();
try {
maintenance(/* ignored */ null);
return timerWheel().snapshot(ascending, limit, transformer);
} finally {
evictionLock.unlock();
}
}
/** An adapter to safely externalize the keys. */
static final class KeySetView extends AbstractSet {
final BoundedLocalCache cache;
KeySetView(BoundedLocalCache cache) {
this.cache = requireNonNull(cache);
}
@Override
public int size() {
return cache.size();
}
@Override
public void clear() {
cache.clear();
}
@Override
public boolean contains(Object obj) {
return cache.containsKey(obj);
}
@Override
public boolean remove(Object obj) {
return (cache.remove(obj) != null);
}
@Override
public Iterator iterator() {
return new KeyIterator<>(cache);
}
@Override
public Spliterator spliterator() {
return new KeySpliterator<>(cache);
}
@Override
public Object[] toArray() {
List keys = new ArrayList<>(size());
for (Object key : this) {
keys.add(key);
}
return keys.toArray();
}
@Override
public T[] toArray(T[] array) {
List keys = new ArrayList<>(size());
for (Object key : this) {
keys.add(key);
}
return keys.toArray(array);
}
}
/** An adapter to safely externalize the key iterator. */
static final class KeyIterator implements Iterator {
final EntryIterator iterator;
KeyIterator(BoundedLocalCache cache) {
this.iterator = new EntryIterator<>(cache);
}
@Override
public boolean hasNext() {
return iterator.hasNext();
}
@Override
public K next() {
return iterator.nextKey();
}
@Override
public void remove() {
iterator.remove();
}
}
/** An adapter to safely externalize the key spliterator. */
static final class KeySpliterator implements Spliterator {
final Spliterator> spliterator;
final BoundedLocalCache cache;
KeySpliterator(BoundedLocalCache cache) {
this(cache, cache.data.values().spliterator());
}
KeySpliterator(BoundedLocalCache cache, Spliterator> spliterator) {
this.spliterator = requireNonNull(spliterator);
this.cache = requireNonNull(cache);
}
@Override
public void forEachRemaining(Consumer super K> action) {
requireNonNull(action);
Consumer> consumer = node -> {
K key = node.getKey();
V value = node.getValue();
long now = cache.expirationTicker().read();
if ((key != null) && (value != null) && node.isAlive() && !cache.hasExpired(node, now)) {
action.accept(key);
}
};
spliterator.forEachRemaining(consumer);
}
@Override
public boolean tryAdvance(Consumer super K> action) {
requireNonNull(action);
boolean[] advanced = { false };
Consumer> consumer = node -> {
K key = node.getKey();
V value = node.getValue();
long now = cache.expirationTicker().read();
if ((key != null) && (value != null) && node.isAlive() && !cache.hasExpired(node, now)) {
action.accept(key);
advanced[0] = true;
}
};
for (;;) {
if (spliterator.tryAdvance(consumer)) {
if (advanced[0]) {
return true;
}
continue;
}
return false;
}
}
@Override
public @Nullable Spliterator trySplit() {
Spliterator> split = spliterator.trySplit();
return (split == null) ? null : new KeySpliterator<>(cache, split);
}
@Override
public long estimateSize() {
return spliterator.estimateSize();
}
@Override
public int characteristics() {
return Spliterator.DISTINCT | Spliterator.CONCURRENT | Spliterator.NONNULL;
}
}
/** An adapter to safely externalize the values. */
static final class ValuesView extends AbstractCollection {
final BoundedLocalCache cache;
ValuesView(BoundedLocalCache cache) {
this.cache = requireNonNull(cache);
}
@Override
public int size() {
return cache.size();
}
@Override
public void clear() {
cache.clear();
}
@Override
public boolean contains(Object o) {
return cache.containsValue(o);
}
@Override
public boolean removeIf(Predicate super V> filter) {
requireNonNull(filter);
boolean removed = false;
for (Entry entry : cache.entrySet()) {
if (filter.test(entry.getValue())) {
removed |= cache.remove(entry.getKey(), entry.getValue());
}
}
return removed;
}
@Override
public Iterator iterator() {
return new ValueIterator<>(cache);
}
@Override
public Spliterator spliterator() {
return new ValueSpliterator<>(cache);
}
}
/** An adapter to safely externalize the value iterator. */
static final class ValueIterator implements Iterator {
final EntryIterator iterator;
ValueIterator(BoundedLocalCache cache) {
this.iterator = new EntryIterator<>(cache);
}
@Override
public boolean hasNext() {
return iterator.hasNext();
}
@Override
public V next() {
return iterator.nextValue();
}
@Override
public void remove() {
iterator.remove();
}
}
/** An adapter to safely externalize the value spliterator. */
static final class ValueSpliterator implements Spliterator {
final Spliterator> spliterator;
final BoundedLocalCache cache;
ValueSpliterator(BoundedLocalCache cache) {
this(cache, cache.data.values().spliterator());
}
ValueSpliterator(BoundedLocalCache cache, Spliterator> spliterator) {
this.spliterator = requireNonNull(spliterator);
this.cache = requireNonNull(cache);
}
@Override
public void forEachRemaining(Consumer super V> action) {
requireNonNull(action);
Consumer> consumer = node -> {
K key = node.getKey();
V value = node.getValue();
long now = cache.expirationTicker().read();
if ((key != null) && (value != null) && node.isAlive() && !cache.hasExpired(node, now)) {
action.accept(value);
}
};
spliterator.forEachRemaining(consumer);
}
@Override
public boolean tryAdvance(Consumer super V> action) {
requireNonNull(action);
boolean[] advanced = { false };
long now = cache.expirationTicker().read();
Consumer> consumer = node -> {
K key = node.getKey();
V value = node.getValue();
if ((key != null) && (value != null) && !cache.hasExpired(node, now) && node.isAlive()) {
action.accept(value);
advanced[0] = true;
}
};
for (;;) {
if (spliterator.tryAdvance(consumer)) {
if (advanced[0]) {
return true;
}
continue;
}
return false;
}
}
@Override
public @Nullable Spliterator trySplit() {
Spliterator> split = spliterator.trySplit();
return (split == null) ? null : new ValueSpliterator<>(cache, split);
}
@Override
public long estimateSize() {
return spliterator.estimateSize();
}
@Override
public int characteristics() {
return Spliterator.CONCURRENT | Spliterator.NONNULL;
}
}
/** An adapter to safely externalize the entries. */
static final class EntrySetView extends AbstractSet> {
final BoundedLocalCache cache;
EntrySetView(BoundedLocalCache cache) {
this.cache = requireNonNull(cache);
}
@Override
public int size() {
return cache.size();
}
@Override
public void clear() {
cache.clear();
}
@Override
public boolean contains(Object obj) {
if (!(obj instanceof Entry, ?>)) {
return false;
}
Entry, ?> entry = (Entry, ?>) obj;
Object key = entry.getKey();
Object value = entry.getValue();
if ((key == null) || (value == null)) {
return false;
}
Node node = cache.data.get(cache.nodeFactory.newLookupKey(key));
return (node != null) && node.containsValue(value);
}
@Override
public boolean remove(Object obj) {
if (!(obj instanceof Entry, ?>)) {
return false;
}
Entry, ?> entry = (Entry, ?>) obj;
return cache.remove(entry.getKey(), entry.getValue());
}
@Override
public boolean removeIf(Predicate super Entry> filter) {
requireNonNull(filter);
boolean removed = false;
for (Entry entry : this) {
if (filter.test(entry)) {
removed |= cache.remove(entry.getKey(), entry.getValue());
}
}
return removed;
}
@Override
public Iterator> iterator() {
return new EntryIterator<>(cache);
}
@Override
public Spliterator> spliterator() {
return new EntrySpliterator<>(cache);
}
}
/** An adapter to safely externalize the entry iterator. */
static final class EntryIterator implements Iterator> {
final BoundedLocalCache cache;
final Iterator> iterator;
final long now;
@Nullable K key;
@Nullable V value;
@Nullable K removalKey;
@Nullable Node next;
EntryIterator(BoundedLocalCache cache) {
this.iterator = cache.data.values().iterator();
this.now = cache.expirationTicker().read();
this.cache = cache;
}
@Override
public boolean hasNext() {
if (next != null) {
return true;
}
for (;;) {
if (iterator.hasNext()) {
next = iterator.next();
value = next.getValue();
key = next.getKey();
boolean evictable = cache.hasExpired(next, now) || (key == null) || (value == null);
if (evictable || !next.isAlive()) {
if (evictable) {
cache.scheduleDrainBuffers();
}
value = null;
next = null;
key = null;
continue;
}
return true;
}
return false;
}
}
@SuppressWarnings("NullAway")
K nextKey() {
if (!hasNext()) {
throw new NoSuchElementException();
}
removalKey = key;
value = null;
next = null;
key = null;
return removalKey;
}
@SuppressWarnings("NullAway")
V nextValue() {
if (!hasNext()) {
throw new NoSuchElementException();
}
removalKey = key;
V val = value;
value = null;
next = null;
key = null;
return val;
}
@Override
public Entry next() {
if (!hasNext()) {
throw new NoSuchElementException();
}
@SuppressWarnings("NullAway")
Entry entry = new WriteThroughEntry<>(cache, key, value);
removalKey = key;
value = null;
next = null;
key = null;
return entry;
}
@Override
public void remove() {
if (removalKey == null) {
throw new IllegalStateException();
}
cache.remove(removalKey);
removalKey = null;
}
}
/** An adapter to safely externalize the entry spliterator. */
static final class EntrySpliterator implements Spliterator> {
final Spliterator> spliterator;
final BoundedLocalCache cache;
EntrySpliterator(BoundedLocalCache cache) {
this(cache, cache.data.values().spliterator());
}
EntrySpliterator(BoundedLocalCache cache, Spliterator> spliterator) {
this.spliterator = requireNonNull(spliterator);
this.cache = requireNonNull(cache);
}
@Override
public void forEachRemaining(Consumer super Entry> action) {
requireNonNull(action);
Consumer> consumer = node -> {
K key = node.getKey();
V value = node.getValue();
long now = cache.expirationTicker().read();
if ((key != null) && (value != null) && node.isAlive() && !cache.hasExpired(node, now)) {
action.accept(new WriteThroughEntry<>(cache, key, value));
}
};
spliterator.forEachRemaining(consumer);
}
@Override
public boolean tryAdvance(Consumer super Entry> action) {
requireNonNull(action);
boolean[] advanced = { false };
Consumer> consumer = node -> {
K key = node.getKey();
V value = node.getValue();
long now = cache.expirationTicker().read();
if ((key != null) && (value != null) && node.isAlive() && !cache.hasExpired(node, now)) {
action.accept(new WriteThroughEntry<>(cache, key, value));
advanced[0] = true;
}
};
for (;;) {
if (spliterator.tryAdvance(consumer)) {
if (advanced[0]) {
return true;
}
continue;
}
return false;
}
}
@Override
public @Nullable Spliterator> trySplit() {
Spliterator> split = spliterator.trySplit();
return (split == null) ? null : new EntrySpliterator<>(cache, split);
}
@Override
public long estimateSize() {
return spliterator.estimateSize();
}
@Override
public int characteristics() {
return Spliterator.DISTINCT | Spliterator.CONCURRENT | Spliterator.NONNULL;
}
}
/** A reusable task that performs the maintenance work; used to avoid wrapping by ForkJoinPool. */
static final class PerformCleanupTask extends ForkJoinTask implements Runnable {
private static final long serialVersionUID = 1L;
final WeakReference> reference;
PerformCleanupTask(BoundedLocalCache, ?> cache) {
reference = new WeakReference>(cache);
}
@Override
public boolean exec() {
try {
run();
} catch (Throwable t) {
logger.log(Level.SEVERE, "Exception thrown when performing the maintenance task", t);
}
// Indicates that the task has not completed to allow subsequent submissions to execute
return false;
}
@Override
public void run() {
BoundedLocalCache, ?> cache = reference.get();
if (cache != null) {
cache.performCleanUp(/* ignored */ null);
}
}
/**
* This method cannot be ignored due to being final, so a hostile user supplied Executor could
* forcibly complete the task and halt future executions. There are easier ways to intentionally
* harm a system, so this is assumed to not happen in practice.
*/
// public final void quietlyComplete() {}
@Override public Void getRawResult() { return null; }
@Override public void setRawResult(Void v) {}
@Override public void complete(Void value) {}
@Override public void completeExceptionally(Throwable ex) {}
@Override public boolean cancel(boolean mayInterruptIfRunning) { return false; }
}
/** Creates a serialization proxy based on the common configuration shared by all cache types. */
static SerializationProxy makeSerializationProxy(
BoundedLocalCache, ?> cache, boolean isWeighted) {
SerializationProxy proxy = new SerializationProxy<>();
proxy.weakKeys = cache.collectKeys();
proxy.weakValues = cache.nodeFactory.weakValues();
proxy.softValues = cache.nodeFactory.softValues();
proxy.isRecordingStats = cache.isRecordingStats();
proxy.removalListener = cache.removalListener();
proxy.ticker = cache.expirationTicker();
proxy.writer = cache.writer;
if (cache.expiresAfterAccess()) {
proxy.expiresAfterAccessNanos = cache.expiresAfterAccessNanos();
}
if (cache.expiresAfterWrite()) {
proxy.expiresAfterWriteNanos = cache.expiresAfterWriteNanos();
}
if (cache.expiresVariable()) {
proxy.expiry = cache.expiry();
}
if (cache.evicts()) {
if (isWeighted) {
proxy.weigher = cache.weigher;
proxy.maximumWeight = cache.maximum();
} else {
proxy.maximumSize = cache.maximum();
}
}
return proxy;
}
/* --------------- Manual Cache --------------- */
static class BoundedLocalManualCache implements LocalManualCache, Serializable {
private static final long serialVersionUID = 1;
final BoundedLocalCache cache;
final boolean isWeighted;
@Nullable Policy policy;
BoundedLocalManualCache(Caffeine builder) {
this(builder, null);
}
BoundedLocalManualCache(Caffeine builder, @Nullable CacheLoader super K, V> loader) {
cache = LocalCacheFactory.newBoundedLocalCache(builder, loader, /* async */ false);
isWeighted = builder.isWeighted();
}
@Override
public BoundedLocalCache cache() {
return cache;
}
@Override
public Policy policy() {
return (policy == null)
? (policy = new BoundedPolicy<>(cache, Function.identity(), isWeighted))
: policy;
}
@SuppressWarnings("UnusedVariable")
private void readObject(ObjectInputStream stream) throws InvalidObjectException {
throw new InvalidObjectException("Proxy required");
}
Object writeReplace() {
return makeSerializationProxy(cache, isWeighted);
}
}
static final class BoundedPolicy implements Policy {
final BoundedLocalCache cache;
final Function transformer;
final boolean isWeighted;
@Nullable Optional> eviction;
@Nullable Optional> refreshes;
@Nullable Optional> afterWrite;
@Nullable Optional> afterAccess;
@Nullable Optional> variable;
BoundedPolicy(BoundedLocalCache cache, Function transformer, boolean isWeighted) {
this.transformer = transformer;
this.isWeighted = isWeighted;
this.cache = cache;
}
@Override public boolean isRecordingStats() {
return cache.isRecordingStats();
}
@Override public @Nullable V getIfPresentQuietly(Object key) {
Node node = cache.data.get(cache.nodeFactory.newLookupKey(key));
if ((node == null) || cache.hasExpired(node, cache.expirationTicker().read())) {
return null;
}
return transformer.apply(node.getValue());
}
@Override public Optional> eviction() {
return cache.evicts()
? (eviction == null) ? (eviction = Optional.of(new BoundedEviction())) : eviction
: Optional.empty();
}
@Override public Optional> expireAfterAccess() {
if (!cache.expiresAfterAccess()) {
return Optional.empty();
}
return (afterAccess == null)
? (afterAccess = Optional.of(new BoundedExpireAfterAccess()))
: afterAccess;
}
@Override public Optional> expireAfterWrite() {
if (!cache.expiresAfterWrite()) {
return Optional.empty();
}
return (afterWrite == null)
? (afterWrite = Optional.of(new BoundedExpireAfterWrite()))
: afterWrite;
}
@Override public Optional> expireVariably() {
if (!cache.expiresVariable()) {
return Optional.empty();
}
return (variable == null)
? (variable = Optional.of(new BoundedVarExpiration()))
: variable;
}
@Override public Optional> refreshAfterWrite() {
if (!cache.refreshAfterWrite()) {
return Optional.empty();
}
return (refreshes == null)
? (refreshes = Optional.of(new BoundedRefreshAfterWrite()))
: refreshes;
}
final class BoundedEviction implements Eviction {
@Override public boolean isWeighted() {
return isWeighted;
}
@Override public OptionalInt weightOf(@NonNull K key) {
requireNonNull(key);
if (!isWeighted) {
return OptionalInt.empty();
}
Node node = cache.data.get(cache.nodeFactory.newLookupKey(key));
if (node == null) {
return OptionalInt.empty();
}
synchronized (node) {
return OptionalInt.of(node.getWeight());
}
}
@Override public OptionalLong weightedSize() {
if (cache.evicts() && isWeighted()) {
cache.evictionLock.lock();
try {
return OptionalLong.of(Math.max(0, cache.weightedSize()));
} finally {
cache.evictionLock.unlock();
}
}
return OptionalLong.empty();
}
@Override public long getMaximum() {
cache.evictionLock.lock();
try {
return cache.maximum();
} finally {
cache.evictionLock.unlock();
}
}
@Override public void setMaximum(long maximum) {
cache.evictionLock.lock();
try {
cache.setMaximumSize(maximum);
cache.maintenance(/* ignored */ null);
} finally {
cache.evictionLock.unlock();
}
}
@Override public Map