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/*
* Copyright 2010 Google Inc. 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 ml.karmaconfigs.shaded.maputil;
import java.io.InvalidObjectException;
import java.io.ObjectInputStream;
import java.io.Serializable;
import java.util.*;
import java.util.concurrent.ConcurrentHashMap;
import java.util.concurrent.ConcurrentLinkedQueue;
import java.util.concurrent.ConcurrentMap;
import java.util.concurrent.atomic.AtomicLong;
import java.util.concurrent.atomic.AtomicReference;
import java.util.concurrent.locks.Lock;
import java.util.concurrent.locks.ReentrantLock;
import static ml.karmaconfigs.shaded.maputil.ConcurrentLinkedHashMap.DrainStatus.*;
import static java.util.Collections.*;
/**
* A hash table supporting full concurrency of retrievals, adjustable expected
* concurrency for updates, and a maximum capacity to bound the map by. This
* implementation differs from {@link ConcurrentHashMap} in that it maintains a
* page replacement algorithm that is used to evict an entry when the map has
* exceeded its capacity. Unlike the Java Collections Framework, this
* map does not have a publicly visible constructor and instances are created
* through a {@link Builder}.
*
* An entry is evicted from the map when the weighted capacity exceeds
* its maximum weighted capacity threshold. A {@link EntryWeigher}
* determines how many units of capacity that an entry consumes. The default
* weigher assigns each value a weight of 1 to bound the map by the
* total number of key-value pairs. A map that holds collections may choose to
* weigh values by the number of elements in the collection and bound the map
* by the total number of elements that it contains. A change to a value that
* modifies its weight requires that an update operation is performed on the
* map.
*
* An {@link EvictionListener} may be supplied for notification when an entry
* is evicted from the map. This listener is invoked on a caller's thread and
* will not block other threads from operating on the map. An implementation
* should be aware that the caller's thread will not expect long execution
* times or failures as a side effect of the listener being notified. Execution
* safety and a fast turn around time can be achieved by performing the
* operation asynchronously, such as by submitting a task to an
* {@link java.util.concurrent.ExecutorService}.
*
* The concurrency level determines the number of threads that can
* concurrently modify the table. Using a significantly higher or lower value
* than needed can waste space or lead to thread contention, but an estimate
* within an order of magnitude of the ideal value does not usually have a
* noticeable impact. Because placement in hash tables is essentially random,
* the actual concurrency will vary.
*
* This class and its views and iterators implement all of the
* optional methods of the {@link Map} and {@link Iterator}
* interfaces.
*
* Like {@link java.util.Hashtable} but unlike {@link HashMap}, this class
* does not allow null to be used as a key or value. Unlike
* {@link java.util.LinkedHashMap}, this class does not provide
* predictable iteration order. A snapshot of the keys and entries may be
* obtained in ascending and descending order of retention.
*
* @param the type of keys maintained by this map
* @param the type of mapped values
* @author [email protected] (Ben Manes)
* @see
* http://code.google.com/p/concurrentlinkedhashmap/
*/
public final class ConcurrentLinkedHashMap extends AbstractMap
implements ConcurrentMap, Serializable {
/*
* 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.
*
* The page replacement algorithm's data structures are kept eventually
* consistent with the map. An update to the map and recording of reads may
* not be immediately reflected on the algorithm'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.
*
* 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 the read buffer exceeds a threshold size. The reads
* are recorded in a lossy buffer, allowing the reordering operations to be
* discarded if the draining process cannot keep up. Due to the concurrent
* nature of the read and write operations a strict policy ordering is not
* possible, but is observably strict when single threaded.
*
* 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 within the value's weight.
*
* Alive: The entry is in both the hash-table and the page replacement policy.
* This is represented by a positive weight.
*
* Retired: The entry is not in the hash-table and is pending removal from the
* page replacement policy. This is represented by a negative weight.
*
* Dead: The entry is not in the hash-table and is not in the page replacement
* policy. This is represented by a weight of zero.
*
* The Least Recently Used page replacement algorithm was chosen due to its
* simplicity, high hit rate, and ability to be implemented with O(1) time
* complexity.
*/
/**
* The number of CPUs
*/
static final int NCPU = Runtime.getRuntime().availableProcessors();
/**
* The maximum weighted capacity of the map.
*/
static final long MAXIMUM_CAPACITY = Long.MAX_VALUE - Integer.MAX_VALUE;
/**
* The number of read buffers to use.
*/
static final int NUMBER_OF_READ_BUFFERS = ceilingNextPowerOfTwo(NCPU);
/**
* Mask value for indexing into the read buffers.
*/
static final int READ_BUFFERS_MASK = NUMBER_OF_READ_BUFFERS - 1;
/**
* The number of pending read operations before attempting to drain.
*/
static final int READ_BUFFER_THRESHOLD = 32;
/**
* The maximum number of read operations to perform per amortized drain.
*/
static final int READ_BUFFER_DRAIN_THRESHOLD = 2 * READ_BUFFER_THRESHOLD;
/**
* The maximum number of pending reads per buffer.
*/
static final int READ_BUFFER_SIZE = 2 * READ_BUFFER_DRAIN_THRESHOLD;
/**
* Mask value for indexing into the read buffer.
*/
static final int READ_BUFFER_INDEX_MASK = READ_BUFFER_SIZE - 1;
/**
* The maximum number of write operations to perform per amortized drain.
*/
static final int WRITE_BUFFER_DRAIN_THRESHOLD = 16;
/**
* A queue that discards all entries.
*/
static final Queue> DISCARDING_QUEUE = new DiscardingQueue();
static final long serialVersionUID = 1;
// The backing data store holding the key-value associations
final ConcurrentMap> data;
final int concurrencyLevel;
// These fields provide support to bound the map by a maximum capacity
final long[] readBufferReadCount;
final LinkedDeque> evictionDeque;
final AtomicLong weightedSize;
final AtomicLong capacity;
final Lock evictionLock;
final Queue writeBuffer;
final AtomicLong[] readBufferWriteCount;
final AtomicLong[] readBufferDrainAtWriteCount;
final AtomicReference>[][] readBuffers;
final AtomicReference drainStatus;
final EntryWeigher super K, ? super V> weigher;
// These fields provide support for notifying a listener.
final Queue> pendingNotifications;
final EvictionListener listener;
transient Set keySet;
transient Collection values;
transient Set> entrySet;
/**
* Creates an instance based on the builder's configuration.
*/
@SuppressWarnings({"unchecked", "cast"})
private ConcurrentLinkedHashMap(Builder builder) {
// The data store and its maximum capacity
concurrencyLevel = builder.concurrencyLevel;
capacity = new AtomicLong(Math.min(builder.capacity, MAXIMUM_CAPACITY));
data = new ConcurrentHashMapV8>(builder.initialCapacity, 0.75f, concurrencyLevel);
// The eviction support
weigher = builder.weigher;
evictionLock = new ReentrantLock();
weightedSize = new AtomicLong();
evictionDeque = new LinkedDeque>();
writeBuffer = new ConcurrentLinkedQueue();
drainStatus = new AtomicReference(IDLE);
readBufferReadCount = new long[NUMBER_OF_READ_BUFFERS];
readBufferWriteCount = new AtomicLong[NUMBER_OF_READ_BUFFERS];
readBufferDrainAtWriteCount = new AtomicLong[NUMBER_OF_READ_BUFFERS];
readBuffers = new AtomicReference[NUMBER_OF_READ_BUFFERS][READ_BUFFER_SIZE];
for (int i = 0; i < NUMBER_OF_READ_BUFFERS; i++) {
readBufferWriteCount[i] = new AtomicLong();
readBufferDrainAtWriteCount[i] = new AtomicLong();
readBuffers[i] = new AtomicReference[READ_BUFFER_SIZE];
for (int j = 0; j < READ_BUFFER_SIZE; j++) {
readBuffers[i][j] = new AtomicReference>();
}
}
// The notification queue and listener
listener = builder.listener;
pendingNotifications = (listener == DiscardingListener.INSTANCE)
? (Queue>) DISCARDING_QUEUE
: new ConcurrentLinkedQueue>();
}
static int ceilingNextPowerOfTwo(int x) {
// From Hacker's Delight, Chapter 3, Harry S. Warren Jr.
return 1 << (Integer.SIZE - Integer.numberOfLeadingZeros(x - 1));
}
/**
* Ensures that the object is not null.
*/
static void checkNotNull(Object o) {
if (o == null) {
throw new NullPointerException();
}
}
/**
* Ensures that the argument expression is true.
*/
static void checkArgument(boolean expression) {
if (!expression) {
throw new IllegalArgumentException();
}
}
/* ---------------- Eviction Support -------------- */
/**
* Ensures that the state expression is true.
*/
static void checkState(boolean expression) {
if (!expression) {
throw new IllegalStateException();
}
}
/**
* Returns the index to the read buffer to record into.
*/
static int readBufferIndex() {
// A buffer is chosen by the thread's id so that tasks are distributed in a
// pseudo evenly manner. This helps avoid hot entries causing contention
// due to other threads trying to append to the same buffer.
return ((int) Thread.currentThread().getId()) & READ_BUFFERS_MASK;
}
/**
* Retrieves the maximum weighted capacity of the map.
*
* @return the maximum weighted capacity
*/
public long capacity() {
return capacity.get();
}
/**
* Sets the maximum weighted capacity of the map and eagerly evicts entries
* until it shrinks to the appropriate size.
*
* @param capacity the maximum weighted capacity of the map
* @throws IllegalArgumentException if the capacity is negative
*/
public void setCapacity(long capacity) {
checkArgument(capacity >= 0);
evictionLock.lock();
try {
this.capacity.lazySet(Math.min(capacity, MAXIMUM_CAPACITY));
drainBuffers();
evict();
} finally {
evictionLock.unlock();
}
notifyListener();
}
/**
* Determines whether the map has exceeded its capacity.
*/
boolean hasOverflowed() {
return weightedSize.get() > capacity.get();
}
/**
* Evicts entries from the map while it exceeds the capacity and appends
* evicted entries to the notification queue for processing.
*/
void evict() {
// Attempts to evict entries from the map if it exceeds the maximum
// capacity. 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.
while (hasOverflowed()) {
final Node node = evictionDeque.poll();
// If weighted values are used, then the pending operations will adjust
// the size to reflect the correct weight
if (node == null) {
return;
}
// Notify the listener only if the entry was evicted
if (data.remove(node.key, node)) {
pendingNotifications.add(node);
}
makeDead(node);
}
}
/**
* Performs the post-processing work required after a read.
*
* @param node the entry in the page replacement policy
*/
void afterRead(Node node) {
final int bufferIndex = readBufferIndex();
final long writeCount = recordRead(bufferIndex, node);
drainOnReadIfNeeded(bufferIndex, writeCount);
notifyListener();
}
/**
* Records a read in the buffer and return its write count.
*
* @param bufferIndex the index to the chosen read buffer
* @param node the entry in the page replacement policy
* @return the number of writes on the chosen read buffer
*/
long recordRead(int bufferIndex, Node node) {
// The location in the buffer is chosen in a racy fashion as the increment
// is not atomic with the insertion. This means that concurrent reads can
// overlap and overwrite one another, resulting in a lossy buffer.
final AtomicLong counter = readBufferWriteCount[bufferIndex];
final long writeCount = counter.get();
counter.lazySet(writeCount + 1);
final int index = (int) (writeCount & READ_BUFFER_INDEX_MASK);
readBuffers[bufferIndex][index].lazySet(node);
return writeCount;
}
/**
* Attempts to drain the buffers if it is determined to be needed when
* post-processing a read.
*
* @param bufferIndex the index to the chosen read buffer
* @param writeCount the number of writes on the chosen read buffer
*/
void drainOnReadIfNeeded(int bufferIndex, long writeCount) {
final long pending = (writeCount - readBufferDrainAtWriteCount[bufferIndex].get());
final boolean delayable = (pending < READ_BUFFER_THRESHOLD);
final DrainStatus status = drainStatus.get();
if (status.shouldDrainBuffers(delayable)) {
tryToDrainBuffers();
}
}
/**
* Performs the post-processing work required after a write.
*
* @param task the pending operation to be applied
*/
void afterWrite(Runnable task) {
writeBuffer.add(task);
drainStatus.lazySet(REQUIRED);
tryToDrainBuffers();
notifyListener();
}
/**
* Attempts to acquire the eviction lock and apply the pending operations, up
* to the amortized threshold, to the page replacement policy.
*/
void tryToDrainBuffers() {
if (evictionLock.tryLock()) {
try {
drainStatus.lazySet(PROCESSING);
drainBuffers();
} finally {
drainStatus.compareAndSet(PROCESSING, IDLE);
evictionLock.unlock();
}
}
}
/**
* Drains the read and write buffers up to an amortized threshold.
*/
void drainBuffers() {
drainReadBuffers();
drainWriteBuffer();
}
/**
* Drains the read buffers, each up to an amortized threshold.
*/
void drainReadBuffers() {
final int start = (int) Thread.currentThread().getId();
final int end = start + NUMBER_OF_READ_BUFFERS;
for (int i = start; i < end; i++) {
drainReadBuffer(i & READ_BUFFERS_MASK);
}
}
/**
* Drains the read buffer up to an amortized threshold.
*/
void drainReadBuffer(int bufferIndex) {
final long writeCount = readBufferWriteCount[bufferIndex].get();
for (int i = 0; i < READ_BUFFER_DRAIN_THRESHOLD; i++) {
final int index = (int) (readBufferReadCount[bufferIndex] & READ_BUFFER_INDEX_MASK);
final AtomicReference> slot = readBuffers[bufferIndex][index];
final Node node = slot.get();
if (node == null) {
break;
}
slot.lazySet(null);
applyRead(node);
readBufferReadCount[bufferIndex]++;
}
readBufferDrainAtWriteCount[bufferIndex].lazySet(writeCount);
}
/**
* Updates the node's location in the page replacement policy.
*/
void applyRead(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 (evictionDeque.contains(node)) {
evictionDeque.moveToBack(node);
}
}
/**
* Drains the read buffer up to an amortized threshold.
*/
void drainWriteBuffer() {
for (int i = 0; i < WRITE_BUFFER_DRAIN_THRESHOLD; i++) {
final Runnable task = writeBuffer.poll();
if (task == null) {
break;
}
task.run();
}
}
/**
* Attempts to transition the node from the alive state to the
* retired state.
*
* @param node the entry in the page replacement policy
* @param expect the expected weighted value
* @return if successful
*/
boolean tryToRetire(Node node, WeightedValue expect) {
if (expect.isAlive()) {
final WeightedValue retired = new WeightedValue(expect.value, -expect.weight);
return node.compareAndSet(expect, retired);
}
return false;
}
/**
* Atomically transitions the node from the alive state to the
* retired state, if a valid transition.
*
* @param node the entry in the page replacement policy
*/
void makeRetired(Node node) {
for (; ; ) {
final WeightedValue current = node.get();
if (!current.isAlive()) {
return;
}
final WeightedValue retired = new WeightedValue(current.value, -current.weight);
if (node.compareAndSet(current, retired)) {
return;
}
}
}
/**
* Atomically transitions the node to the dead state and decrements
* the weightedSize.
*
* @param node the entry in the page replacement policy
*/
void makeDead(Node node) {
for (; ; ) {
WeightedValue current = node.get();
WeightedValue dead = new WeightedValue(current.value, 0);
if (node.compareAndSet(current, dead)) {
weightedSize.lazySet(weightedSize.get() - Math.abs(current.weight));
return;
}
}
}
/**
* Notifies the listener of entries that were evicted.
*/
void notifyListener() {
Node node;
while ((node = pendingNotifications.poll()) != null) {
listener.onEviction(node.key, node.getValue());
}
}
@Override
public boolean isEmpty() {
return data.isEmpty();
}
@Override
public int size() {
return data.size();
}
/* ---------------- Concurrent Map Support -------------- */
/**
* Returns the weighted size of this map.
*
* @return the combined weight of the values in this map
*/
public long weightedSize() {
return Math.max(0, weightedSize.get());
}
@Override
public void clear() {
evictionLock.lock();
try {
// Discard all entries
Node node;
while ((node = evictionDeque.poll()) != null) {
data.remove(node.key, node);
makeDead(node);
}
// Discard all pending reads
for (AtomicReference>[] buffer : readBuffers) {
for (AtomicReference> slot : buffer) {
slot.lazySet(null);
}
}
// Apply all pending writes
Runnable task;
while ((task = writeBuffer.poll()) != null) {
task.run();
}
} finally {
evictionLock.unlock();
}
}
@Override
public boolean containsKey(Object key) {
return data.containsKey(key);
}
@Override
public boolean containsValue(Object value) {
checkNotNull(value);
for (Node node : data.values()) {
if (node.getValue().equals(value)) {
return true;
}
}
return false;
}
@Override
public V get(Object key) {
final Node node = data.get(key);
if (node == null) {
return null;
}
afterRead(node);
return node.getValue();
}
/**
* Returns the value to which the specified key is mapped, or {@code null}
* if this map contains no mapping for the key. This method differs from
* {@link #get(Object)} in that it does not record the operation with the
* page replacement policy.
*
* @param key the key whose associated value is to be returned
* @return the value to which the specified key is mapped, or
* {@code null} if this map contains no mapping for the key
* @throws NullPointerException if the specified key is null
*/
public V getQuietly(Object key) {
final Node node = data.get(key);
return (node == null) ? null : node.getValue();
}
@Override
public V put(K key, V value) {
return put(key, value, false);
}
@Override
public V putIfAbsent(K key, V value) {
return put(key, value, true);
}
/**
* Adds a node to the list 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 onlyIfAbsent a write is performed only if the key is not already
* associated with a value
* @return the prior value in the data store or null if no mapping was found
*/
V put(K key, V value, boolean onlyIfAbsent) {
checkNotNull(key);
checkNotNull(value);
final int weight = weigher.weightOf(key, value);
final WeightedValue weightedValue = new WeightedValue(value, weight);
final Node node = new Node(key, weightedValue);
for (; ; ) {
final Node prior = data.putIfAbsent(node.key, node);
if (prior == null) {
afterWrite(new AddTask(node, weight));
return null;
} else if (onlyIfAbsent) {
afterRead(prior);
return prior.getValue();
}
for (; ; ) {
final WeightedValue oldWeightedValue = prior.get();
if (!oldWeightedValue.isAlive()) {
break;
}
if (prior.compareAndSet(oldWeightedValue, weightedValue)) {
final int weightedDifference = weight - oldWeightedValue.weight;
if (weightedDifference == 0) {
afterRead(prior);
} else {
afterWrite(new UpdateTask(prior, weightedDifference));
}
return oldWeightedValue.value;
}
}
}
}
@Override
public V remove(Object key) {
final Node node = data.remove(key);
if (node == null) {
return null;
}
makeRetired(node);
afterWrite(new RemovalTask(node));
return node.getValue();
}
@Override
public boolean remove(Object key, Object value) {
final Node node = data.get(key);
if ((node == null) || (value == null)) {
return false;
}
WeightedValue weightedValue = node.get();
for (; ; ) {
if (weightedValue.contains(value)) {
if (tryToRetire(node, weightedValue)) {
if (data.remove(key, node)) {
afterWrite(new RemovalTask(node));
return true;
}
} else {
weightedValue = node.get();
if (weightedValue.isAlive()) {
// retry as an intermediate update may have replaced the value with
// an equal instance that has a different reference identity
continue;
}
}
}
return false;
}
}
@Override
public V replace(K key, V value) {
checkNotNull(key);
checkNotNull(value);
final int weight = weigher.weightOf(key, value);
final WeightedValue weightedValue = new WeightedValue(value, weight);
final Node node = data.get(key);
if (node == null) {
return null;
}
for (; ; ) {
final WeightedValue oldWeightedValue = node.get();
if (!oldWeightedValue.isAlive()) {
return null;
}
if (node.compareAndSet(oldWeightedValue, weightedValue)) {
final int weightedDifference = weight - oldWeightedValue.weight;
if (weightedDifference == 0) {
afterRead(node);
} else {
afterWrite(new UpdateTask(node, weightedDifference));
}
return oldWeightedValue.value;
}
}
}
@Override
public boolean replace(K key, V oldValue, V newValue) {
checkNotNull(key);
checkNotNull(oldValue);
checkNotNull(newValue);
final int weight = weigher.weightOf(key, newValue);
final WeightedValue newWeightedValue = new WeightedValue(newValue, weight);
final Node node = data.get(key);
if (node == null) {
return false;
}
for (; ; ) {
final WeightedValue weightedValue = node.get();
if (!weightedValue.isAlive() || !weightedValue.contains(oldValue)) {
return false;
}
if (node.compareAndSet(weightedValue, newWeightedValue)) {
final int weightedDifference = weight - weightedValue.weight;
if (weightedDifference == 0) {
afterRead(node);
} else {
afterWrite(new UpdateTask(node, weightedDifference));
}
return true;
}
}
}
@Override
public Set keySet() {
final Set ks = keySet;
return (ks == null) ? (keySet = new KeySet()) : ks;
}
/**
* Returns a unmodifiable snapshot {@link Set} view of the keys contained in
* this map. The set's iterator returns the keys whose order of iteration is
* the ascending order in which its entries are considered eligible for
* retention, from the least-likely to be retained to the most-likely.
*
* Beware that, unlike in {@link #keySet()}, obtaining the set is NOT
* a constant-time operation. Because of the asynchronous nature of the page
* replacement policy, determining the retention ordering requires a traversal
* of the keys.
*
* @return an ascending snapshot view of the keys in this map
*/
public Set ascendingKeySet() {
return ascendingKeySetWithLimit(Integer.MAX_VALUE);
}
/**
* Returns an unmodifiable snapshot {@link Set} view of the keys contained in
* this map. The set's iterator returns the keys whose order of iteration is
* the ascending order in which its entries are considered eligible for
* retention, from the least-likely to be retained to the most-likely.
*
* Beware that, unlike in {@link #keySet()}, obtaining the set is NOT
* a constant-time operation. Because of the asynchronous nature of the page
* replacement policy, determining the retention ordering requires a traversal
* of the keys.
*
* @param limit the maximum size of the returned set
* @return a ascending snapshot view of the keys in this map
* @throws IllegalArgumentException if the limit is negative
*/
public Set ascendingKeySetWithLimit(int limit) {
return orderedKeySet(true, limit);
}
/**
* Returns an unmodifiable snapshot {@link Set} view of the keys contained in
* this map. The set's iterator returns the keys whose order of iteration is
* the descending order in which its entries are considered eligible for
* retention, from the most-likely to be retained to the least-likely.
*
* Beware that, unlike in {@link #keySet()}, obtaining the set is NOT
* a constant-time operation. Because of the asynchronous nature of the page
* replacement policy, determining the retention ordering requires a traversal
* of the keys.
*
* @return a descending snapshot view of the keys in this map
*/
public Set descendingKeySet() {
return descendingKeySetWithLimit(Integer.MAX_VALUE);
}
/**
* Returns an unmodifiable snapshot {@link Set} view of the keys contained in
* this map. The set's iterator returns the keys whose order of iteration is
* the descending order in which its entries are considered eligible for
* retention, from the most-likely to be retained to the least-likely.
*
* Beware that, unlike in {@link #keySet()}, obtaining the set is NOT
* a constant-time operation. Because of the asynchronous nature of the page
* replacement policy, determining the retention ordering requires a traversal
* of the keys.
*
* @param limit the maximum size of the returned set
* @return a descending snapshot view of the keys in this map
* @throws IllegalArgumentException if the limit is negative
*/
public Set descendingKeySetWithLimit(int limit) {
return orderedKeySet(false, limit);
}
Set orderedKeySet(boolean ascending, int limit) {
checkArgument(limit >= 0);
evictionLock.lock();
try {
drainBuffers();
final int initialCapacity = (weigher == Weighers.entrySingleton())
? Math.min(limit, (int) weightedSize())
: 16;
final Set keys = new LinkedHashSet(initialCapacity);
final Iterator> iterator = ascending
? evictionDeque.iterator()
: evictionDeque.descendingIterator();
while (iterator.hasNext() && (limit > keys.size())) {
keys.add(iterator.next().key);
}
return unmodifiableSet(keys);
} finally {
evictionLock.unlock();
}
}
@Override
public Collection values() {
final Collection vs = values;
return (vs == null) ? (values = new Values()) : vs;
}
@Override
public Set> entrySet() {
final Set> es = entrySet;
return (es == null) ? (entrySet = new EntrySet()) : es;
}
/**
* Returns an unmodifiable snapshot {@link Map} view of the mappings contained
* in this map. The map's collections return the mappings whose order of
* iteration is the ascending order in which its entries are considered
* eligible for retention, from the least-likely to be retained to the
* most-likely.
*
* Beware that obtaining the mappings is NOT a constant-time
* operation. Because of the asynchronous nature of the page replacement
* policy, determining the retention ordering requires a traversal of the
* entries.
*
* @return a ascending snapshot view of this map
*/
public Map ascendingMap() {
return ascendingMapWithLimit(Integer.MAX_VALUE);
}
/**
* Returns an unmodifiable snapshot {@link Map} view of the mappings contained
* in this map. The map's collections return the mappings whose order of
* iteration is the ascending order in which its entries are considered
* eligible for retention, from the least-likely to be retained to the
* most-likely.
*
* Beware that obtaining the mappings is NOT a constant-time
* operation. Because of the asynchronous nature of the page replacement
* policy, determining the retention ordering requires a traversal of the
* entries.
*
* @param limit the maximum size of the returned map
* @return a ascending snapshot view of this map
* @throws IllegalArgumentException if the limit is negative
*/
public Map ascendingMapWithLimit(int limit) {
return orderedMap(true, limit);
}
/**
* Returns an unmodifiable snapshot {@link Map} view of the mappings contained
* in this map. The map's collections return the mappings whose order of
* iteration is the descending order in which its entries are considered
* eligible for retention, from the most-likely to be retained to the
* least-likely.
*
* Beware that obtaining the mappings is NOT a constant-time
* operation. Because of the asynchronous nature of the page replacement
* policy, determining the retention ordering requires a traversal of the
* entries.
*
* @return a descending snapshot view of this map
*/
public Map descendingMap() {
return descendingMapWithLimit(Integer.MAX_VALUE);
}
/**
* Returns an unmodifiable snapshot {@link Map} view of the mappings contained
* in this map. The map's collections return the mappings whose order of
* iteration is the descending order in which its entries are considered
* eligible for retention, from the most-likely to be retained to the
* least-likely.
*
* Beware that obtaining the mappings is NOT a constant-time
* operation. Because of the asynchronous nature of the page replacement
* policy, determining the retention ordering requires a traversal of the
* entries.
*
* @param limit the maximum size of the returned map
* @return a descending snapshot view of this map
* @throws IllegalArgumentException if the limit is negative
*/
public Map descendingMapWithLimit(int limit) {
return orderedMap(false, limit);
}
Map orderedMap(boolean ascending, int limit) {
checkArgument(limit >= 0);
evictionLock.lock();
try {
drainBuffers();
final int initialCapacity = (weigher == Weighers.entrySingleton())
? Math.min(limit, (int) weightedSize())
: 16;
final Map map = new LinkedHashMap(initialCapacity);
final Iterator> iterator = ascending
? evictionDeque.iterator()
: evictionDeque.descendingIterator();
while (iterator.hasNext() && (limit > map.size())) {
Node node = iterator.next();
map.put(node.key, node.getValue());
}
return unmodifiableMap(map);
} finally {
evictionLock.unlock();
}
}
Object writeReplace() {
return new SerializationProxy(this);
}
private void readObject(ObjectInputStream stream) throws InvalidObjectException {
throw new InvalidObjectException("Proxy required");
}
/**
* The draining status of the buffers.
*/
enum DrainStatus {
/**
* A drain is not taking place.
*/
IDLE {
@Override
boolean shouldDrainBuffers(boolean delayable) {
return !delayable;
}
},
/**
* A drain is required due to a pending write modification.
*/
REQUIRED {
@Override
boolean shouldDrainBuffers(boolean delayable) {
return true;
}
},
/**
* A drain is in progress.
*/
PROCESSING {
@Override
boolean shouldDrainBuffers(boolean delayable) {
return false;
}
};
/**
* Determines whether the buffers should be drained.
*
* @param delayable if a drain should be delayed until required
* @return if a drain should be attempted
*/
abstract boolean shouldDrainBuffers(boolean delayable);
}
/**
* A listener that ignores all notifications.
*/
enum DiscardingListener implements EvictionListener