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/* WeakIdentityMap.java

	Purpose:
		
	Description:
		
	History:
		Sep 2, 2011 11:04:57 AM, Created by henrichen

Copyright (C) 2011 Potix Corporation. All Rights Reserved.
*/

package org.zkoss.bind.impl;

/*
 *  Copyright 2004 Brian S O'Neill
 *
 *  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.
 */

//revised from cojen

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.Collection;
import java.util.Collections;
import java.util.ConcurrentModificationException;
import java.util.Iterator;
import java.util.Map;
import java.util.NoSuchElementException;
import java.util.Set;
import java.util.concurrent.atomic.AtomicInteger;

/**
 * WeakIdentityMap is like WeakHashMap, except it uses a key's identity
 * hashcode and equals methods. WeakIdentityMap is not thread-safe and must be
 * wrapped with Collections.synchronizedMap to be made thread-safe.
 * 

* The documentation for WeakHashMap states that it is intended primarily for * use with key objects whose equals methods test for object identity using the * == operator. Because WeakIdentityMap strictly follows this behavior, it is * better suited for this purpose. *

* Note: Weakly referenced entries may be automatically removed during * either accessor or mutator operations, possibly causing a concurrent * modification to be detected. Therefore, even if multiple threads are only * accessing this map, be sure to synchronize this map first. Also, do not * rely on the value returned by size() when using an iterator from this map. * The iterators may return less entries than the amount reported by size(). * * @author Brian S O'Neill * * @since 6.0.0 */ @SuppressWarnings("unchecked") public class WeakIdentityMap extends AbstractMap implements Map { // Types of Iterators static final int KEYS = 0; static final int VALUES = 1; static final int ENTRIES = 2; /** * Converts a collection to string, supporting collections that contain * self references */ static String toString(Collection c) { if (c.size() == 0) { return "[]"; } StringBuffer buf = new StringBuffer(32 * c.size()); buf.append('['); Iterator it = c.iterator(); boolean hasNext = it.hasNext(); while (hasNext) { Object obj = it.next(); buf.append(obj == c ? "(this Collection)" : obj); hasNext = it.hasNext(); if (hasNext) { buf.append(", "); } } buf.append("]"); return buf.toString(); } /** * Converts a map to string, supporting maps that contain self references */ static String toString(Map m) { if (m.size() == 0) { return "{}"; } StringBuffer buf = new StringBuffer(32 * m.size()); buf.append('{'); Iterator it = m.entrySet().iterator(); boolean hasNext = it.hasNext(); while (hasNext) { Map.Entry entry = (Map.Entry) it.next(); Object key = entry.getKey(); Object value = entry.getValue(); buf.append(key == m ? "(this Map)" : key).append('=').append(value == m ? "(this Map)" : value); hasNext = it.hasNext(); if (hasNext) { buf.append(',').append(' '); } } buf.append('}'); return buf.toString(); } /** * Gets the map as a String. * * @return a string version of the map */ public String toString() { return toString(this); } private transient Entry[] table; private transient int count; private int threshold; private final float loadFactor; private final ReferenceQueue queue; //this field volatile to detect concurrent modification, //check line if (WeakIdentityMap.this.modCount != this.expectedModCount) { private transient AtomicInteger modCount = new AtomicInteger(); // Views private transient Set keySet; private transient Set> entrySet; private transient Collection values; public WeakIdentityMap(int initialCapacity, float loadFactor) { if (initialCapacity <= 0) { throw new IllegalArgumentException("Initial capacity must be greater than 0"); } if (loadFactor <= 0 || Float.isNaN(loadFactor)) { throw new IllegalArgumentException("Load factor must be greater than 0"); } this.loadFactor = loadFactor; this.table = new Entry[initialCapacity]; this.threshold = (int) (initialCapacity * loadFactor); this.queue = new ReferenceQueue(); } public WeakIdentityMap(int initialCapacity) { this(initialCapacity, 0.75f); } public WeakIdentityMap() { this(11, 0.75f); } public WeakIdentityMap(Map t) { this(Math.max(2 * t.size(), 11), 0.75f); putAll(t); } public int size() { // Cleanup right before, to report a more accurate size. cleanup(); return this.count; } public boolean isEmpty() { return this.count == 0; } public boolean containsValue(Object value) { Entry[] tab = this.table; if (value == null) { for (int i = tab.length; i-- > 0;) { for (Entry e = tab[i], prev = null; e != null; e = e.next) { if (e.get() == null) { // Clean up after a cleared Reference. this.modCount.incrementAndGet(); if (prev != null) { prev.next = e.next; } else { tab[i] = e.next; } this.count--; } else if (e.value == null) { return true; } else { prev = e; } } } } else { for (int i = tab.length; i-- > 0;) { for (Entry e = tab[i], prev = null; e != null; e = e.next) { if (e.get() == null) { // Clean up after a cleared Reference. this.modCount.incrementAndGet(); if (prev != null) { prev.next = e.next; } else { tab[i] = e.next; } this.count--; } else if (value.equals(e.value)) { return true; } else { prev = e; } } } } return false; } public boolean containsKey(Object key) { if (key == null) { key = KeyFactory.NULL; } Entry[] tab = this.table; int hash = System.identityHashCode(key); int index = (hash & 0x7fffffff) % tab.length; for (Entry e = tab[index], prev = null; e != null; e = e.next) { Object entryKey = e.get(); if (entryKey == null) { // Clean up after a cleared Reference. this.modCount.incrementAndGet(); if (prev != null) { prev.next = e.next; } else { tab[index] = e.next; } this.count--; } else if (e.hash == hash && key == entryKey) { return true; } else { prev = e; } } return false; } public V get(Object key) { if (key == null) { key = KeyFactory.NULL; } Entry[] tab = this.table; int hash = System.identityHashCode(key); int index = (hash & 0x7fffffff) % tab.length; for (Entry e = tab[index], prev = null; e != null; e = e.next) { Object entryKey = e.get(); if (entryKey == null) { // Clean up after a cleared Reference. this.modCount.incrementAndGet(); if (prev != null) { prev.next = e.next; } else { tab[index] = e.next; } this.count--; } else if (e.hash == hash && key == entryKey) { return e.value; } else { prev = e; } } return null; } private void cleanup() { // Cleanup after cleared References. Entry[] tab = this.table; ReferenceQueue queue = this.queue; Reference ref; while ((ref = queue.poll()) != null) { // Since buckets are single-linked, traverse entire list and // cleanup all cleared references in it. int index = (((Entry) ref).hash & 0x7fffffff) % tab.length; for (Entry e = tab[index], prev = null; e != null; e = e.next) { if (e.get() == null) { this.modCount.incrementAndGet(); if (prev != null) { prev.next = e.next; } else { tab[index] = e.next; } this.count--; } else { prev = e; } } } } private void rehash() { int oldCapacity = this.table.length; Entry[] oldMap = this.table; int newCapacity = oldCapacity * 2 + 1; if (newCapacity <= 0) { // Overflow. if ((newCapacity = Integer.MAX_VALUE) == oldCapacity) { return; } } Entry[] newMap = new Entry[newCapacity]; this.modCount.incrementAndGet(); this.threshold = (int) (newCapacity * this.loadFactor); this.table = newMap; for (int i = oldCapacity; i-- > 0;) { for (Entry old = oldMap[i]; old != null;) { Entry e = old; old = old.next; // Only copy entry if its key hasn't been cleared. if (e.get() == null) { this.count--; } else { int index = (e.hash & 0x7fffffff) % newCapacity; e.next = newMap[index]; newMap[index] = e; } } } } public V put(K key, V value) { if (key == null) { key = (K) KeyFactory.NULL; } cleanup(); // Make sure the key is not already in the WeakIdentityMap. Entry[] tab = this.table; int hash = System.identityHashCode(key); int index = (hash & 0x7fffffff) % tab.length; for (Entry e = tab[index], prev = null; e != null; e = e.next) { Object entryKey = e.get(); if (entryKey == null) { // Clean up after a cleared Reference. this.modCount.incrementAndGet(); if (prev != null) { prev.next = e.next; } else { tab[index] = e.next; } this.count--; } else if (e.hash == hash && key == entryKey) { Object old = e.value; e.value = value; return (V) old; } else { prev = e; } } this.modCount.incrementAndGet(); if (this.count >= this.threshold) { // Rehash the table if the threshold is still exceeded. rehash(); tab = this.table; index = (hash & 0x7fffffff) % tab.length; } // Creates the new entry. Entry e = new Entry(hash, key, this.queue, value, tab[index]); tab[index] = e; this.count++; return null; } public V remove(Object key) { if (key == null) { key = KeyFactory.NULL; } Entry[] tab = this.table; int hash = System.identityHashCode(key); int index = (hash & 0x7fffffff) % tab.length; for (Entry e = tab[index], prev = null; e != null; e = e.next) { Object entryKey = e.get(); if (entryKey == null) { // Clean up after a cleared Reference. this.modCount.incrementAndGet(); if (prev != null) { prev.next = e.next; } else { tab[index] = e.next; } this.count--; } else if (e.hash == hash && key == entryKey) { this.modCount.incrementAndGet(); if (prev != null) { prev.next = e.next; } else { tab[index] = e.next; } this.count--; V oldValue = e.value; e.value = null; return oldValue; } else { prev = e; } } return null; } public void putAll(Map t) { Iterator i = t.entrySet().iterator(); while (i.hasNext()) { Map.Entry e = (Map.Entry) i.next(); put((K) e.getKey(), (V) e.getValue()); } } public void clear() { Entry[] tab = this.table; this.modCount.incrementAndGet(); for (int index = tab.length; --index >= 0;) { tab[index] = null; } this.count = 0; } public Object clone() { try { WeakIdentityMap t = (WeakIdentityMap) super.clone(); t.table = new Entry[this.table.length]; for (int i = this.table.length; i-- > 0;) { t.table[i] = (this.table[i] != null) ? (Entry) this.table[i].copy(this.queue) : null; } t.keySet = null; t.entrySet = null; t.values = null; t.modCount.set(0); return t; } catch (CloneNotSupportedException e) { // this shouldn't happen, since we are Cloneable throw new InternalError(); } } public Set keySet() { if (this.keySet == null) { this.keySet = new AbstractSet() { public Iterator iterator() { return createHashIterator(KEYS); } public int size() { return WeakIdentityMap.this.count; } public boolean contains(Object o) { return containsKey(o); } public boolean remove(Object o) { return o == null ? false : WeakIdentityMap.this.remove(o) == o; } //20140717, henrichen: ZK-2289 public boolean add(K o) { final boolean contains = containsKey(o); WeakIdentityMap.this.put(o, null); return !contains; } //20140717, henrichen: ZK-2289 public boolean addAll(Collection c) { boolean changed = false; for (K item : c) { final boolean ichanged = this.add(item); if (!changed && ichanged) changed = true; } return changed; } public void clear() { WeakIdentityMap.this.clear(); } public String toString() { return WeakIdentityMap.toString(this); } }; } return this.keySet; } public Collection values() { if (this.values == null) { this.values = new AbstractCollection() { public Iterator iterator() { return createHashIterator(VALUES); } public int size() { return WeakIdentityMap.this.count; } public boolean contains(Object o) { return containsValue(o); } public void clear() { WeakIdentityMap.this.clear(); } public String toString() { return WeakIdentityMap.toString(this); } }; } return this.values; } public Set> entrySet() { if (this.entrySet == null) { this.entrySet = new AbstractSet>() { public Iterator> iterator() { return createHashIterator(ENTRIES); } public boolean contains(Object o) { if (!(o instanceof Map.Entry)) { return false; } Map.Entry entry = (Map.Entry) o; Object key = entry.getKey(); Entry[] tab = WeakIdentityMap.this.table; int hash = System.identityHashCode(key); int index = (hash & 0x7fffffff) % tab.length; for (Entry e = tab[index], prev = null; e != null; e = e.next) { Object entryKey = e.get(); if (entryKey == null) { // Clean up after a cleared Reference. WeakIdentityMap.this.modCount.incrementAndGet(); if (prev != null) { prev.next = e.next; } else { tab[index] = e.next; } WeakIdentityMap.this.count--; } else if (e.hash == hash && e.equals(entry)) { return true; } else { prev = e; } } return false; } public boolean remove(Object o) { if (!(o instanceof Map.Entry)) { return false; } Map.Entry entry = (Map.Entry) o; Object key = entry.getKey(); Entry[] tab = WeakIdentityMap.this.table; int hash = System.identityHashCode(key); int index = (hash & 0x7fffffff) % tab.length; for (Entry e = tab[index], prev = null; e != null; e = e.next) { if (e.get() == null) { // Clean up after a cleared Reference. WeakIdentityMap.this.modCount.incrementAndGet(); if (prev != null) { prev.next = e.next; } else { tab[index] = e.next; } WeakIdentityMap.this.count--; } else if (e.hash == hash && e.equals(entry)) { WeakIdentityMap.this.modCount.incrementAndGet(); if (prev != null) { prev.next = e.next; } else { tab[index] = e.next; } WeakIdentityMap.this.count--; e.value = null; return true; } else { prev = e; } } return false; } public int size() { return WeakIdentityMap.this.count; } public void clear() { WeakIdentityMap.this.clear(); } public String toString() { return WeakIdentityMap.toString(this); } }; } return this.entrySet; } private Iterator createHashIterator(int type) { if (this.count == 0) { return Collections.EMPTY_SET.iterator(); } else { return new HashIterator(type); } } /** * WeakIdentityMap collision list entry. */ private static class Entry extends WeakReference implements Map.Entry { int hash; V value; Entry next; Entry(int hash, K key, ReferenceQueue queue, V value, Entry next) { super(key, queue); this.hash = hash; this.value = value; this.next = next; } public void clear() { // Do nothing if reference is explicity cleared. This prevents // backdoor modification of map entries. } public K getKey() { K key = Entry.this.get(); return key == KeyFactory.NULL ? null : key; } public V getValue() { return this.value; } public V setValue(V value) { V oldValue = this.value; this.value = value; return oldValue; } public boolean equals(Object obj) { if (!(obj instanceof Map.Entry)) { return false; } return equals((Map.Entry) obj); } boolean equals(Map.Entry e) { Object thisKey = get(); if (thisKey == null) { return false; } else if (thisKey == KeyFactory.NULL) { thisKey = null; } return (thisKey == e.getKey()) && (this.value == null ? e.getValue() == null : this.value.equals(e.getValue())); } public int hashCode() { return this.hash ^ (this.value == null ? 0 : this.value.hashCode()); } public String toString() { return getKey() + "=" + this.value; } protected Object copy(ReferenceQueue queue) { return new Entry(this.hash, get(), queue, this.value, (this.next == null ? null : (Entry) this.next.copy(queue))); } } private class HashIterator implements Iterator { private final int type; private final Entry[] table; private int index; // To ensure that the iterator doesn't return cleared entries, keep a // hard reference to the key. Its existence will prevent the weak // key from being cleared. Object entryKey; Entry entry; Entry last; /** * The modCount value that the iterator believes that the backing * List should have. If this expectation is violated, the iterator * has detected concurrent modification. */ private int expectedModCount = WeakIdentityMap.this.modCount.get(); HashIterator(int type) { this.table = WeakIdentityMap.this.table; this.type = type; this.index = table.length; } public boolean hasNext() { while (this.entry == null || (this.entryKey = this.entry.get()) == null) { if (this.entry != null) { // Clean up after a cleared Reference. remove(this.entry); this.entry = this.entry.next; } else { if (this.index <= 0) { return false; } else { this.entry = this.table[--this.index]; } } } return true; } public Object next() { if (WeakIdentityMap.this.modCount.get() != this.expectedModCount) { throw new ConcurrentModificationException(); } if (!hasNext()) { throw new NoSuchElementException(); } this.last = this.entry; this.entry = this.entry.next; return this.type == KEYS ? this.last.getKey() : (this.type == VALUES ? this.last.getValue() : this.last); } public void remove() { if (this.last == null) { throw new IllegalStateException(); } if (WeakIdentityMap.this.modCount.get() != this.expectedModCount) { throw new ConcurrentModificationException(); } remove(this.last); this.last = null; } private void remove(Entry toRemove) { Entry[] tab = this.table; int index = (toRemove.hash & 0x7fffffff) % tab.length; for (Entry e = tab[index], prev = null; e != null; e = e.next) { if (e == toRemove) { WeakIdentityMap.this.modCount.incrementAndGet(); expectedModCount++; if (prev == null) { tab[index] = e.next; } else { prev.next = e.next; } WeakIdentityMap.this.count--; return; } else { prev = e; } } throw new ConcurrentModificationException(); } public String toString() { if (this.last != null) { return "Iterator[" + this.last + ']'; } else { return "Iterator[]"; } } } }





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