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/*
 * Copyright (c) 2018 - Manifold Systems LLC
 *
 * 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 manifold.util.concurrent;

import java.io.Serializable;
import java.math.BigDecimal;
import java.util.AbstractMap;
import java.util.AbstractSet;
import java.util.Arrays;
import java.util.Collections;
import java.util.Iterator;
import java.util.List;
import java.util.Set;
import java.util.concurrent.ConcurrentHashMap;
import java.util.concurrent.ConcurrentMap;
import java.util.concurrent.Executors;
import java.util.concurrent.ScheduledExecutorService;
import java.util.concurrent.ScheduledFuture;
import java.util.concurrent.TimeUnit;
import java.util.concurrent.atomic.AtomicInteger;
import java.util.concurrent.atomic.AtomicReferenceFieldUpdater;
import manifold.util.ILogger;

/**
 * static var MY_CACHE = new Cache( 1000, \ foo -> getBar( foo ) )
 */
public class Cache
{
  private ConcurrentLinkedHashMap _cacheImlp;
  private final Loader _loader;
  private final String _name;
  private final int _size;

  //statistics
  private final AtomicInteger _requests = new AtomicInteger();
  private final AtomicInteger _misses = new AtomicInteger();
  private final AtomicInteger _hits = new AtomicInteger();

  private ScheduledFuture _loggingTask;

  /**
   * This will create a new cache
   *
   * @param name        the name of the cache for logging
   * @param size        the maximum size of the log
   * @param loader      loads values into the cache, this is required not to be null
   */
  public Cache( String name, int size, Loader loader )
  {
    _name = name;
    _size = size;
    clearCacheImpl();
    _loader = loader;
  }

  private void clearCacheImpl()
  {
    _cacheImlp = new ConcurrentLinkedHashMap( ConcurrentLinkedHashMap.EvictionPolicy.SECOND_CHANCE, _size );
  }

  /**
   * This will evict a specific key from the cache.
   *
   * @param key the key to evict
   *
   * @return the current value for that key
   */
  public V evict( K key )
  {
    return _cacheImlp.remove( key );
  }

  /**
   * This will put a specific entry in the cache
   *
   * @param key   this is the key
   * @param value this is the value
   *
   * @return the old value for this key
   */
  public V put( K key, V value )
  {
    return _cacheImlp.put( key, value );
  }

  /**
   * This will get a specific entry, it will call the missHandler if it is not found.
   *
   * @param key the object to find
   *
   * @return the found object (may be null)
   */
  public V get( K key )
  {
    V value = _cacheImlp.get( key );
    _requests.incrementAndGet();
    if( value == null )
    {
      value = _loader.load( key );
      _cacheImlp.put( key, value );
      _misses.incrementAndGet();
    }
    else
    {
      _hits.incrementAndGet();
    }
    return value;
  }

  public Iterable getCachedValues()
  {
    return _cacheImlp.values();
  }

  public int getConfiguredSize()
  {
    return _size;
  }

  public int getUtilizedSize()
  {
    return _cacheImlp.size();
  }

  public int getRequests()
  {
    return _requests.get();
  }

  public int getMisses()
  {
    return _misses.get();
  }

  public int getHits()
  {
    return _hits.get();
  }

  public double getHitRate()
  {
    int requests = getRequests();
    int hits = getHits();
    if( requests == 0 )
    {
      return 0.0;
    }
    else
    {
      return ((double)hits) / requests;
    }
  }

  /**
   * Sets up a recurring task every n seconds to report on the status of this cache.  This can be useful
   * if you are doing exploratory caching and wish to monitor the performance of this cache with minimal fuss.
   * Consider
   *
   * @param seconds how often to log the entry
   * @param logger  the logger to use
   *
   * @return this
   */
  public synchronized Cache logEveryNSeconds( int seconds, final ILogger logger )
  {
    if( _loggingTask == null )
    {
      ScheduledExecutorService service = Executors.newScheduledThreadPool( 1 );
      _loggingTask = service.scheduleAtFixedRate( new Runnable()
      {
        public void run()
        {
          logger.info( Cache.this );
        }
      }, seconds, seconds, TimeUnit.SECONDS );
    }
    else
    {
      throw new IllegalStateException( "Logging for " + this + " is already enabled" );
    }
    return this;
  }

  public synchronized void stopLogging()
  {
    if( _loggingTask != null )
    {
      _loggingTask.cancel( false );
    }
  }

  public interface Loader
  {
    W load( L key );
  }

  public void clear()
  {
    clearCacheImpl();
    _hits.set( 0 );
    _misses.set( 0 );
    _requests.set( 0 );
  }

  @Override
  public String toString()
  {
    return "Cache \"" + _name + "\"( Hits:" + getHits() + ", Misses:" + getMisses() + ", Requests:" + getRequests() + ", Hit rate:" + BigDecimal.valueOf( getHitRate() * 100.0 ).setScale( 2, BigDecimal.ROUND_DOWN ) + "% )";
  }

  public static  Cache make( String name, int size, Loader handler )
  {
    return new Cache( name, size, handler );
  }

  /**
   * A {@link ConcurrentMap} with a doubly-linked list running through its entries.
   * 

* This class provides the same semantics as a {@link ConcurrentHashMap} in terms of * iterators, acceptable keys, and concurrency characteristics, but perform slightly * worse due to the added expense of maintaining the linked list. It differs from * {@link java.util.LinkedHashMap} in that it does not provide predictable iteration * order. *

* This map is intended to be used for caches and provides the following eviction policies: *

    *
  • First-in, First-out: Also known as insertion order. This policy has excellent * concurrency characteristics and an adequate hit rate. *
  • Second-chance: An enhanced FIFO policy that marks entries that have been retrieved * and saves them from being evicted until the next pass. This enhances the FIFO policy * by making it aware of "hot" entries, which increases its hit rate to be equal to an * LRU's under normal workloads. In the worst case, where all entries have been saved, * this policy degrades to a FIFO. *
  • Least Recently Used: An eviction policy based on the observation that entries that * have been used recently will likely be used again soon. This policy provides a good * approximation of an optimal algorithm, but suffers by being expensive to maintain. * The cost of reordering entries on the list during every access operation reduces * the concurrency and performance characteristics of this policy. *
*

* The Second Chance eviction policy is recommended for common use cases as it provides * the best mix of performance and efficiency of the supported replacement policies. *

* If the Least Recently Used policy is chosen then the sizing should compensate for the * proliferation of dead nodes on the linked list. While the values are removed immediately, the * nodes are evicted only when they reach the head of the list. Under FIFO-based policies, dead * nodes occur when explicit removals are requested and does not normally produce a noticeable * impact on the map's hit rate. The LRU policy creates a dead node on every successful retrieval * and a new node is placed at the tail of the list. For this reason, the LRU's efficiency cannot * be compared directly to a {@link java.util.LinkedHashMap} evicting in access order. *

* Ben Manes */ static class ConcurrentLinkedHashMap extends AbstractMap implements ConcurrentMap, Serializable { private static final long serialVersionUID = 8350170357874293408L; final List> listeners; final ConcurrentMap> data; final AtomicInteger capacity; final EvictionPolicy policy; final AtomicInteger length; final Node head; final Node tail; /** * Creates a new, empty, unbounded map with the specified maximum capacity and the default * concurrencyLevel. * * @param policy The eviction policy to apply when the size exceeds the maximum capacity. * @param maximumCapacity The maximum capacity to coerces to. The size may exceed it temporarily. * @param listeners The listeners registered for notification when an entry is evicted. */ public ConcurrentLinkedHashMap( EvictionPolicy policy, int maximumCapacity, EvictionListener... listeners ) { this( policy, maximumCapacity, 16, listeners ); } /** * Creates a new, empty, unbounded map with the specified maximum capacity and concurrency level. * * @param policy The eviction policy to apply when the size exceeds the maximum capacity. * @param maximumCapacity The maximum capacity to coerces to. The size may exceed it temporarily. * @param concurrencyLevel The estimated number of concurrently updating threads. The implementation * performs internal sizing to try to accommodate this many threads. * @param listeners The listeners registered for notification when an entry is evicted. */ public ConcurrentLinkedHashMap( EvictionPolicy policy, int maximumCapacity, int concurrencyLevel, EvictionListener... listeners ) { if( (policy == null) || (maximumCapacity < 0) || (concurrencyLevel <= 0) ) { throw new IllegalArgumentException(); } this.listeners = (listeners == null) ? Collections.>emptyList() : Arrays.asList( listeners ); this.data = new ConcurrentHashMap>( maximumCapacity, 0.75f, concurrencyLevel ); this.capacity = new AtomicInteger( maximumCapacity ); this.length = new AtomicInteger(); this.head = new Node(); this.tail = new Node(); this.policy = policy; head.setPrev( head ); head.setNext( tail ); tail.setPrev( head ); tail.setNext( tail ); } /** * Determines whether the map has exceeded its capacity. * * @return Whether the map has overflowed and an entry should be evicted. */ private boolean isOverflow() { return length.get() > capacity(); } /** * Sets the maximum capacity of the map and eagerly evicts entries until the * it shrinks to the appropriate size. * * @param capacity The maximum capacity of the map. */ public void setCapacity( int capacity ) { if( capacity < 0 ) { throw new IllegalArgumentException(); } this.capacity.set( capacity ); while( isOverflow() ) { evict(); } } /** * Retrieves the maximum capacity of the map. * * @return The maximum capacity. */ public int capacity() { return capacity.get(); } /** * {@inheritDoc} */ @Override public int size() { return data.size(); } /** * {@inheritDoc} */ @Override public void clear() { for( K key : keySet() ) { remove( key ); } } /** * {@inheritDoc} */ @Override public boolean containsKey( Object key ) { return data.containsKey( key ); } /** * {@inheritDoc} */ @Override public boolean containsValue( Object value ) { return data.containsValue( new Node( null, value ) ); } /** * Evicts a single entry if the map exceeds the maximum capacity. */ private void evict() { while( isOverflow() ) { Node node = poll(); if( node == null ) { return; } else if( policy.onEvict( this, node ) ) { V value = node.getValue(); if( value != null ) { K key = node.getKey(); data.remove( key ); notifyEviction( key, value ); } length.decrementAndGet(); return; } offer( node ); } } /** * Notifies the listeners that an entry was evicted from the map. * * @param key The entry's key. * @param value The entry's value. */ private void notifyEviction( K key, V value ) { for( int i = 0; i < listeners.size(); i++ ) { EvictionListener listener = listeners.get( i ); listener.onEviction( key, value ); } } /** * Retrieves and removes the first node on the list or null if empty. * * @return The first node on the list or null if empty. */ private Node poll() { for( ; ; ) { Node node = head.getNext(); if( head.casNext( node, node.getNext() ) ) { for( ; ; ) { if( node.casState( Node.State.LINKED, Node.State.UNLINKING ) ) { node.getNext().setPrev( head ); node.setState( Node.State.UNLINKED ); return node; } Node.State state = node.getState(); if( state == Node.State.SENTINEL ) { return null; } } } } } /** * Inserts the specified node on to the tail of the list. * * @param node An unlinked node to append to the tail of the list. */ private void offer( Node node ) { node.setState( Node.State.LINKING ); node.setNext( tail ); for( ; ; ) { Node prev = tail.getPrev(); node.setPrev( prev ); if( prev.casNext( tail, node ) ) { Node next = tail; for( ; ; ) { if( next.casPrev( prev, node ) ) { node.setState( Node.State.LINKED ); return; } // walk up the list until a node can be linked next = next.getPrev(); } } } } /** * Adds a node to the list and data store if it does not already exist. * * @param node An unlinked node to add. * * @return The previous value in the data store. */ private Node putIfAbsent( Node node ) { Node old = data.putIfAbsent( node.getKey(), node ); if( old == null ) { length.incrementAndGet(); offer( node ); evict(); } return old; } /** * {@inheritDoc} */ @Override public V get( Object key ) { Node node = data.get( key ); if( node != null ) { V value = node.getValue(); policy.onGet( this, node ); return value; } return null; } /** * {@inheritDoc} */ public V put( K key, V value ) { if( value == null ) { throw new IllegalArgumentException(); } Node old = putIfAbsent( new Node( key, value ) ); return (old == null) ? null : old.getAndSetValue( value ); } /** * {@inheritDoc} */ public V putIfAbsent( K key, V value ) { if( value == null ) { throw new IllegalArgumentException(); } Node old = putIfAbsent( new Node( key, value ) ); return (old == null) ? null : old.getValue(); } /** * {@inheritDoc} */ public V remove( Object key ) { Node node = data.remove( key ); if( node != null ) { V value = node.getValue(); policy.onRemove( this, node ); return value; } return null; } /** * {@inheritDoc} */ public boolean remove( Object key, Object value ) { Node node = data.get( key ); if( (node != null) && node.value.equals( value ) && data.remove( key, node ) ) { policy.onRemove( this, node ); return true; } return false; } /** * {@inheritDoc} */ public V replace( K key, V value ) { if( value == null ) { throw new IllegalArgumentException(); } Node node = data.get( key ); return (node == null) ? null : node.getAndSetValue( value ); } /** * {@inheritDoc} */ public boolean replace( K key, V oldValue, V newValue ) { if( newValue == null ) { throw new IllegalArgumentException(); } Node node = data.get( key ); return (node != null) && node.casValue( oldValue, newValue ); } /** * {@inheritDoc} */ public Set> entrySet() { return new EntrySetAdapter(); } /** * A listener registered for notification when an entry is evicted. */ public interface EvictionListener { /** * A call-back notification that the entry was evicted. * * @param key The evicted key. * @param value The evicted value. */ void onEviction( K key, V value ); } /** * The replacement policy to apply to determine which entry to discard to when the capacity has been reached. */ public enum EvictionPolicy { /** * Evicts entries based on insertion order. */ FIFO() { void onGet( ConcurrentLinkedHashMap map, Node node ) { // do nothing } boolean onEvict( ConcurrentLinkedHashMap map, Node node ) { return true; } }, /** * Evicts entries based on insertion order, but gives an entry a "second chance" if it has been requested recently. */ SECOND_CHANCE() { void onGet( ConcurrentLinkedHashMap map, Node node ) { node.setMarked( true ); } void onRemove( ConcurrentLinkedHashMap map, Node node ) { super.onRemove( map, node ); node.setMarked( false ); } boolean onEvict( ConcurrentLinkedHashMap map, Node node ) { if( node.isMarked() ) { node.setMarked( false ); return false; } return true; } }, /** * Evicts entries based on how recently they are used, with the least recent evicted first. */ LRU() { void onGet( ConcurrentLinkedHashMap map, Node node ) { Node newNode = new Node( node.getKey(), node.getValue() ); if( map.data.replace( node.getKey(), node, newNode ) ) { map.length.incrementAndGet(); onRemove( map, node ); map.offer( newNode ); map.evict(); } } boolean onEvict( ConcurrentLinkedHashMap map, Node node ) { return true; } }; /** * Performs any operations required by the policy after a node was successfully retrieved. * * @param map the map to for this listener * @param node the specific node */ abstract void onGet( ConcurrentLinkedHashMap map, Node node ); /** * Expires a node so that, for all intents and purposes, it is a dead on the list. The * caller of this method should have already removed the node from the mapping so that * no key can look it up. When the node reaches the head of the list it will be evicted. * * @param map the map to for this listener * @param node the specific node */ void onRemove( ConcurrentLinkedHashMap map, Node node ) { node.setValue( null ); } /** * Determines whether to evict the node at the head of the list. If false, the node is offered * to the tail. * * @param map the map to for this listener * @param node the specific node * * @return whether this node is to be evicted */ abstract boolean onEvict( ConcurrentLinkedHashMap map, Node node ); } /** * A node on the double-linked list. This list cross-cuts the data store. */ @SuppressWarnings("unchecked") static final class Node implements Serializable { private static final long serialVersionUID = 1461281468985304519L; private static final AtomicReferenceFieldUpdater valueUpdater = AtomicReferenceFieldUpdater.newUpdater( Node.class, Object.class, "value" ); private static final AtomicReferenceFieldUpdater stateUpdater = AtomicReferenceFieldUpdater.newUpdater( Node.class, State.class, "state" ); private static final AtomicReferenceFieldUpdater prevUpdater = AtomicReferenceFieldUpdater.newUpdater( Node.class, Node.class, "prev" ); private static final AtomicReferenceFieldUpdater nextUpdater = AtomicReferenceFieldUpdater.newUpdater( Node.class, Node.class, "next" ); public static enum State { SENTINEL, UNLINKED, UNLINKING, LINKING, LINKED } private final K key; private volatile V value; private volatile State state; private volatile boolean marked; private volatile Node prev = null; private volatile Node next = null; /** * Creates a sentinel node. */ public Node() { this.key = null; this.state = State.SENTINEL; } /** * Creates a new, unlinked node. * * @param key the key * @param value the value */ public Node( K key, V value ) { this.key = key; this.value = value; this.state = State.UNLINKED; } public K getKey() { return key; } public V getValue() { return value; } public void setValue( V value ) { valueUpdater.set( this, value ); } public V getAndSetValue( V value ) { return (V)valueUpdater.getAndSet( this, value ); } public boolean casValue( V expect, V update ) { return valueUpdater.compareAndSet( this, expect, update ); } public Node getPrev() { return prev; } public void setPrev( Node node ) { prevUpdater.set( this, node ); } public boolean casPrev( Node expect, Node update ) { return prevUpdater.compareAndSet( this, expect, update ); } public Node getNext() { return next; } public void setNext( Node node ) { nextUpdater.set( this, node ); } public boolean casNext( Node expect, Node update ) { return nextUpdater.compareAndSet( this, expect, update ); } public boolean isMarked() { return marked; } public void setMarked( boolean marked ) { this.marked = marked; } public State getState() { return state; } public void setState( State state ) { stateUpdater.set( this, state ); } public boolean casState( State expect, State update ) { return stateUpdater.compareAndSet( this, expect, update ); } /** * Only ensures that the values are equal, as the key may be null for look-ups. */ @Override public boolean equals( Object obj ) { if( obj == this ) { return true; } else if( !(obj instanceof Node) ) { return false; } V value = getValue(); Node node = (Node)obj; return (value == null) ? (node.getValue() == null) : value.equals( node.getValue() ); } /** * {@inheritDoc} */ @Override public int hashCode() { return ((key == null) ? 0 : key.hashCode()) ^ ((value == null) ? 0 : value.hashCode()); } @Override public String toString() { return String.format( "Node[state=%s, marked=%b, key=%s, value=%s]", getState(), isMarked(), getKey(), getValue() ); } } /** * An adapter to represent the data store's entry set in the external type. */ private final class EntrySetAdapter extends AbstractSet> { private final ConcurrentLinkedHashMap map = ConcurrentLinkedHashMap.this; /** * {@inheritDoc} */ @Override public void clear() { map.clear(); } /** * {@inheritDoc} */ public int size() { return map.size(); } /** * {@inheritDoc} */ public Iterator> iterator() { return new EntryIteratorAdapter( map.data.entrySet().iterator() ); } /** * {@inheritDoc} */ @Override public boolean contains( Object obj ) { if( !(obj instanceof Entry) ) { return false; } Entry entry = (Entry)obj; Node node = map.data.get( entry.getKey() ); return (node != null) && (node.value.equals( entry.getValue() )); } /** * {@inheritDoc} */ @Override public boolean add( Entry entry ) { return (map.putIfAbsent( entry.getKey(), entry.getValue() ) == null); } /** * {@inheritDoc} */ @Override public boolean remove( Object obj ) { if( !(obj instanceof Entry) ) { return false; } Entry entry = (Entry)obj; return map.remove( entry.getKey(), entry.getValue() ); } } /** * An adapter to represent the data store's entry iterator in the external type. */ private final class EntryIteratorAdapter implements Iterator> { private final Iterator>> iterator; private Entry> current; public EntryIteratorAdapter( Iterator>> iterator ) { this.iterator = iterator; } /** * {@inheritDoc} */ public boolean hasNext() { return iterator.hasNext(); } /** * {@inheritDoc} */ public Entry next() { current = iterator.next(); K key = current.getKey(); Node node = current.getValue(); V value = node == null ? null : node.getValue(); return new SimpleEntry( key, value ); } /** * {@inheritDoc} */ public void remove() { if( current == null ) { throw new IllegalStateException(); } ConcurrentLinkedHashMap.this.remove( current.getKey(), current.getValue() ); current = null; } } /** * This duplicates {@link AbstractMap.SimpleEntry} until the class is made accessible. * Update: SimpleEntry is public in JDK 6. */ private static final class SimpleEntry implements Entry { private final K key; private V value; public SimpleEntry( K key, V value ) { this.key = key; this.value = value; } public K getKey() { return key; } public V getValue() { return value; } public V setValue( V value ) { V oldValue = this.value; this.value = value; return oldValue; } public boolean equals( Object obj ) { if( obj == this ) { return true; } else if( !(obj instanceof Entry) ) { return false; } Entry entry = (Entry)obj; return eq( key, entry.getKey() ) && eq( value, entry.getValue() ); } public int hashCode() { return ((key == null) ? 0 : key.hashCode()) ^ ((value == null) ? 0 : value.hashCode()); } public String toString() { return key + "=" + value; } private static boolean eq( Object o1, Object o2 ) { return (o1 == null) ? (o2 == null) : o1.equals( o2 ); } } } }





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