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Provides a single jar containing all JAITools modules which you can use instead of including individual modules in your project. Note: It does not include the Jiffle scripting language or Jiffle image operator.

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/* ====================================================================
 * The Apache Software License, Version 1.1
 *
 * Copyright (c) 2002-2004 The Apache Software Foundation.  All rights
 * reserved.
 *
 * Redistribution and use in source and binary forms, with or without
 * modification, are permitted provided that the following conditions
 * are met:
 *
 * 1. Redistributions of source code must retain the above copyright
 *    notice, this list of conditions and the following disclaimer.
 *
 * 2. Redistributions in binary form must reproduce the above copyright
 *    notice, this list of conditions and the following disclaimer in
 *    the documentation and/or other materials provided with the
 *    distribution.
 *
 * 3. The end-user documentation included with the redistribution, if
 *    any, must include the following acknowledgement:
 *       "This product includes software developed by the
 *        Apache Software Foundation (http://www.apache.org/)."
 *    Alternately, this acknowledgement may appear in the software itself,
 *    if and wherever such third-party acknowledgements normally appear.
 *
 * 4. The names "The Jakarta Project", "Commons", and "Apache Software
 *    Foundation" must not be used to endorse or promote products derived
 *    from this software without prior written permission. For written
 *    permission, please contact [email protected].
 *
 * 5. Products derived from this software may not be called "Apache"
 *    nor may "Apache" appear in their names without prior written
 *    permission of the Apache Software Foundation.
 *
 * THIS SOFTWARE IS PROVIDED ``AS IS'' AND ANY EXPRESSED OR IMPLIED
 * WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
 * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
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 * ITS CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
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 * ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
 * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT
 * OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
 * SUCH DAMAGE.
 * ====================================================================
 *
 * This software consists of voluntary contributions made by many
 * individuals on behalf of the Apache Software Foundation.  For more
 * information on the Apache Software Foundation, please see
 * .
 */
package org.apache.commons.collections.map;

import java.io.IOException;
import java.io.ObjectInputStream;
import java.io.ObjectOutputStream;
import java.lang.ref.Reference;
import java.lang.ref.ReferenceQueue;
import java.lang.ref.SoftReference;
import java.lang.ref.WeakReference;
import java.util.AbstractCollection;
import java.util.AbstractMap;
import java.util.AbstractSet;
import java.util.ArrayList;
import java.util.Arrays;
import java.util.Collection;
import java.util.ConcurrentModificationException;
import java.util.Iterator;
import java.util.Map;
import java.util.NoSuchElementException;
import java.util.Set;

import org.apache.commons.collections.KeyValue;
import org.apache.commons.collections.keyvalue.DefaultMapEntry;

/**
 * Hash-based Map implementation that allows
 * mappings to be removed by the garbage collector.
 * 

* When you construct a ReferenceMap, you can * specify what kind of references are used to store the * map's keys and values. If non-hard references are * used, then the garbage collector can remove mappings * if a key or value becomes unreachable, or if the * JVM's memory is running low. For information on how * the different reference types behave, see * {@link Reference}. *

* Different types of references can be specified for keys * and values. The keys can be configured to be weak but * the values hard, in which case this class will behave * like a * WeakHashMap. However, you * can also specify hard keys and weak values, or any other * combination. The default constructor uses hard keys * and soft values, providing a memory-sensitive cache. *

* The algorithms used are basically the same as those * in {@link java.util.HashMap}. In particular, you * can specify a load factor and capacity to suit your * needs. All optional {@link Map} operations are * supported. *

* However, this {@link Map} implementation does not * allow null elements. Attempting to add a null key or * or a null value to the map will raise a * NullPointerException. *

* As usual, this implementation is not synchronized. You * can use {@link java.util.Collections#synchronizedMap} to * provide synchronized access to a ReferenceMap. * * @see java.lang.ref.Reference * * @since Commons Collections 3.0 (previously in main package v2.1) * @version $Revision: 1.9 $ $Date: 2004/01/14 21:43:11 $ * * @author Paul Jack */ public class ReferenceMap extends AbstractMap { /** * For serialization. */ private static final long serialVersionUID = -3370601314380922368L; /** * Constant indicating that hard references should be used. */ public static final int HARD = 0; /** * Constant indicating that soft references should be used. */ public static final int SOFT = 1; /** * Constant indicating that weak references should be used. */ public static final int WEAK = 2; // --- serialized instance variables: /** * The reference type for keys. Must be HARD, SOFT, WEAK. * Note: I originally marked this field as final, but then this class * didn't compile under JDK1.2.2. * @serial */ private int keyType; /** * The reference type for values. Must be HARD, SOFT, WEAK. * Note: I originally marked this field as final, but then this class * didn't compile under JDK1.2.2. * @serial */ private int valueType; /** * The threshold variable is calculated by multiplying * table.length and loadFactor. * Note: I originally marked this field as final, but then this class * didn't compile under JDK1.2.2. * @serial */ private float loadFactor; /** * Should the value be automatically purged when the associated key has been collected? */ private boolean purgeValues = false; // -- Non-serialized instance variables /** * ReferenceQueue used to eliminate stale mappings. * See purge. */ private transient ReferenceQueue queue = new ReferenceQueue(); /** * The hash table. Its length is always a power of two. */ private transient Entry[] table; /** * Number of mappings in this map. */ private transient int size; /** * When size reaches threshold, the map is resized. * See resize(). */ private transient int threshold; /** * Number of times this map has been modified. */ private transient volatile int modCount; /** * Cached key set. May be null if key set is never accessed. */ private transient Set keySet; /** * Cached entry set. May be null if entry set is never accessed. */ private transient Set entrySet; /** * Cached values. May be null if values() is never accessed. */ private transient Collection values; /** * Constructs a new ReferenceMap that will * use hard references to keys and soft references to values. */ public ReferenceMap() { this(HARD, SOFT); } /** * Constructs a new ReferenceMap that will * use the specified types of references. * * @param keyType the type of reference to use for keys; * must be {@link #HARD}, {@link #SOFT}, {@link #WEAK} * @param valueType the type of reference to use for values; * must be {@link #HARD}, {@link #SOFT}, {@link #WEAK} * @param purgeValues should the value be automatically purged when the * key is garbage collected */ public ReferenceMap(int keyType, int valueType, boolean purgeValues) { this(keyType, valueType); this.purgeValues = purgeValues; } /** * Constructs a new ReferenceMap that will * use the specified types of references. * * @param keyType the type of reference to use for keys; * must be {@link #HARD}, {@link #SOFT}, {@link #WEAK} * @param valueType the type of reference to use for values; * must be {@link #HARD}, {@link #SOFT}, {@link #WEAK} */ public ReferenceMap(int keyType, int valueType) { this(keyType, valueType, 16, 0.75f); } /** * Constructs a new ReferenceMap with the * specified reference types, load factor and initial * capacity. * * @param keyType the type of reference to use for keys; * must be {@link #HARD}, {@link #SOFT}, {@link #WEAK} * @param valueType the type of reference to use for values; * must be {@link #HARD}, {@link #SOFT}, {@link #WEAK} * @param capacity the initial capacity for the map * @param loadFactor the load factor for the map * @param purgeValues should the value be automatically purged when the * key is garbage collected */ public ReferenceMap( int keyType, int valueType, int capacity, float loadFactor, boolean purgeValues) { this(keyType, valueType, capacity, loadFactor); this.purgeValues = purgeValues; } /** * Constructs a new ReferenceMap with the * specified reference types, load factor and initial * capacity. * * @param keyType the type of reference to use for keys; * must be {@link #HARD}, {@link #SOFT}, {@link #WEAK} * @param valueType the type of reference to use for values; * must be {@link #HARD}, {@link #SOFT}, {@link #WEAK} * @param capacity the initial capacity for the map * @param loadFactor the load factor for the map */ public ReferenceMap(int keyType, int valueType, int capacity, float loadFactor) { super(); verify("keyType", keyType); verify("valueType", valueType); if (capacity <= 0) { throw new IllegalArgumentException("capacity must be positive"); } if ((loadFactor <= 0.0f) || (loadFactor >= 1.0f)) { throw new IllegalArgumentException("Load factor must be greater than 0 and less than 1."); } this.keyType = keyType; this.valueType = valueType; int v = 1; while (v < capacity) v *= 2; this.table = new Entry[v]; this.loadFactor = loadFactor; this.threshold = (int)(v * loadFactor); } // used by constructor private static void verify(String name, int type) { if ((type < HARD) || (type > WEAK)) { throw new IllegalArgumentException(name + " must be HARD, SOFT, WEAK."); } } /** * Writes this object to the given output stream. * * @param out the output stream to write to * @throws IOException if the stream raises it */ private void writeObject(ObjectOutputStream out) throws IOException { out.defaultWriteObject(); out.writeInt(table.length); // Have to use null-terminated list because size might shrink // during iteration for (Iterator iter = entrySet().iterator(); iter.hasNext();) { Map.Entry entry = (Map.Entry)iter.next(); out.writeObject(entry.getKey()); out.writeObject(entry.getValue()); } out.writeObject(null); } /** * Reads the contents of this object from the given input stream. * * @param in the input stream to read from * @throws IOException if the stream raises it * @throws ClassNotFoundException if the stream raises it */ private void readObject(ObjectInputStream in) throws IOException, ClassNotFoundException { in.defaultReadObject(); table = new Entry[in.readInt()]; threshold = (int)(table.length * loadFactor); queue = new ReferenceQueue(); Object key = in.readObject(); while (key != null) { Object value = in.readObject(); put(key, value); key = in.readObject(); } } /** * Constructs a reference of the given type to the given * referent. The reference is registered with the queue * for later purging. * * @param type HARD, SOFT or WEAK * @param referent the object to refer to * @param hash the hash code of the key of the mapping; * this number might be different from referent.hashCode() if * the referent represents a value and not a key */ private Object toReference(int type, Object referent, int hash) { switch (type) { case HARD: return referent; case SOFT: return new SoftRef(hash, referent, queue); case WEAK: return new WeakRef(hash, referent, queue); default: throw new Error(); } } /** * Returns the entry associated with the given key. * * @param key the key of the entry to look up * @return the entry associated with that key, or null * if the key is not in this map */ private Entry getEntry(Object key) { if (key == null) { return null; } int hash = key.hashCode(); int index = indexFor(hash); for (Entry entry = table[index]; entry != null; entry = entry.next) { if ((entry.hash == hash) && key.equals(entry.getKey())) { return entry; } } return null; } /** * Converts the given hash code into an index into the * hash table. */ private int indexFor(int hash) { // mix the bits to avoid bucket collisions... hash += ~(hash << 15); hash ^= (hash >>> 10); hash += (hash << 3); hash ^= (hash >>> 6); hash += ~(hash << 11); hash ^= (hash >>> 16); return hash & (table.length - 1); } /** * Resizes this hash table by doubling its capacity. * This is an expensive operation, as entries must * be copied from the old smaller table to the new * bigger table. */ private void resize() { Entry[] old = table; table = new Entry[old.length * 2]; for (int i = 0; i < old.length; i++) { Entry next = old[i]; while (next != null) { Entry entry = next; next = next.next; int index = indexFor(entry.hash); entry.next = table[index]; table[index] = entry; } old[i] = null; } threshold = (int)(table.length * loadFactor); } /** * Purges stale mappings from this map. *

* Ordinarily, stale mappings are only removed during * a write operation, although this method is called for both * read and write operations to maintain a consistent state. *

* Note that this method is not synchronized! Special * care must be taken if, for instance, you want stale * mappings to be removed on a periodic basis by some * background thread. */ private void purge() { Reference ref = queue.poll(); while (ref != null) { purge(ref); ref = queue.poll(); } } private void purge(Reference ref) { // The hashCode of the reference is the hashCode of the // mapping key, even if the reference refers to the // mapping value... int hash = ref.hashCode(); int index = indexFor(hash); Entry previous = null; Entry entry = table[index]; while (entry != null) { if (entry.purge(ref)) { if (previous == null) { table[index] = entry.next; } else { previous.next = entry.next; } this.size--; return; } previous = entry; entry = entry.next; } } /** * Returns the size of this map. * * @return the size of this map */ public int size() { purge(); return size; } /** * Returns true if this map is empty. * * @return true if this map is empty */ public boolean isEmpty() { purge(); return size == 0; } /** * Returns true if this map contains the given key. * * @return true if the given key is in this map */ public boolean containsKey(Object key) { purge(); Entry entry = getEntry(key); if (entry == null) { return false; } return entry.getValue() != null; } /** * Returns the value associated with the given key, if any. * * @return the value associated with the given key, or null * if the key maps to no value */ public Object get(Object key) { purge(); Entry entry = getEntry(key); if (entry == null) { return null; } return entry.getValue(); } /** * Associates the given key with the given value.

* Neither the key nor the value may be null. * * @param key the key of the mapping * @param value the value of the mapping * @return the last value associated with that key, or * null if no value was associated with the key * @throws NullPointerException if either the key or value * is null */ public Object put(Object key, Object value) { if (key == null) { throw new NullPointerException("null keys not allowed"); } if (value == null) { throw new NullPointerException("null values not allowed"); } purge(); if (size + 1 > threshold) { resize(); } int hash = key.hashCode(); int index = indexFor(hash); Entry entry = table[index]; while (entry != null) { if ((hash == entry.hash) && key.equals(entry.getKey())) { Object result = entry.getValue(); entry.setValue(value); return result; } entry = entry.next; } this.size++; modCount++; key = toReference(keyType, key, hash); value = toReference(valueType, value, hash); table[index] = new Entry(key, hash, value, table[index]); return null; } /** * Removes the key and its associated value from this map. * * @param key the key to remove * @return the value associated with that key, or null if * the key was not in the map */ public Object remove(Object key) { if (key == null) { return null; } purge(); int hash = key.hashCode(); int index = indexFor(hash); Entry previous = null; Entry entry = table[index]; while (entry != null) { if ((hash == entry.hash) && key.equals(entry.getKey())) { if (previous == null) { table[index] = entry.next; } else { previous.next = entry.next; } this.size--; modCount++; return entry.getValue(); } previous = entry; entry = entry.next; } return null; } /** * Clears this map. */ public void clear() { Arrays.fill(table, null); size = 0; while (queue.poll() != null) {} // drain the queue } /** * Returns a set view of this map's entries. * * @return a set view of this map's entries */ public Set entrySet() { if (entrySet != null) { return entrySet; } entrySet = new AbstractSet() { public int size() { return ReferenceMap.this.size(); } public void clear() { ReferenceMap.this.clear(); } public boolean contains(Object obj) { if (obj == null) { return false; } if (obj instanceof Map.Entry == false) { return false; } Map.Entry e = (Map.Entry) obj; Entry e2 = getEntry(e.getKey()); return (e2 != null) && e.equals(e2); } public boolean remove(Object obj) { boolean r = contains(obj); if (r) { Map.Entry e = (Map.Entry) obj; ReferenceMap.this.remove(e.getKey()); } return r; } public Iterator iterator() { return new EntryIterator(); } public Object[] toArray() { return toArray(new Object[0]); } public Object[] toArray(Object[] arr) { ArrayList list = new ArrayList(); Iterator iterator = iterator(); while (iterator.hasNext()) { Entry e = (Entry)iterator.next(); list.add(new DefaultMapEntry(e.getKey(), e.getValue())); } return list.toArray(arr); } }; return entrySet; } /** * Returns a set view of this map's keys. * * @return a set view of this map's keys */ public Set keySet() { if (keySet != null) return keySet; keySet = new AbstractSet() { public int size() { return ReferenceMap.this.size(); } public Iterator iterator() { return new KeyIterator(); } public boolean contains(Object obj) { return containsKey(obj); } public boolean remove(Object obj) { Object r = ReferenceMap.this.remove(obj); return r != null; } public void clear() { ReferenceMap.this.clear(); } public Object[] toArray() { return toArray(new Object[0]); } public Object[] toArray(Object[] arr) { Collection c = new ArrayList(size()); for (Iterator it = iterator(); it.hasNext(); ) { c.add(it.next()); } return c.toArray(arr); } }; return keySet; } /** * Returns a collection view of this map's values. * * @return a collection view of this map's values. */ public Collection values() { if (values != null) return values; values = new AbstractCollection() { public int size() { return ReferenceMap.this.size(); } public void clear() { ReferenceMap.this.clear(); } public Iterator iterator() { return new ValueIterator(); } public Object[] toArray() { return toArray(new Object[0]); } public Object[] toArray(Object[] arr) { Collection c = new ArrayList(size()); for (Iterator it = iterator(); it.hasNext(); ) { c.add(it.next()); } return c.toArray(arr); } }; return values; } //----------------------------------------------------------------------- /** * A MapEntry implementation for the map. *

* If getKey() or getValue() returns null, it means * the mapping is stale and should be removed. */ private class Entry implements Map.Entry, KeyValue { Object key; Object value; int hash; Entry next; public Entry(Object key, int hash, Object value, Entry next) { this.key = key; this.hash = hash; this.value = value; this.next = next; } public Object getKey() { return (keyType > HARD) ? ((Reference)key).get() : key; } public Object getValue() { return (valueType > HARD) ? ((Reference)value).get() : value; } public Object setValue(Object obj) { Object old = getValue(); if (valueType > HARD) { ((Reference)value).clear(); } value = toReference(valueType, obj, hash); return old; } public boolean equals(Object obj) { if (obj == this) { return true; } if (obj instanceof Map.Entry == false) { return false; } Map.Entry entry = (Map.Entry)obj; Object key = entry.getKey(); Object value = entry.getValue(); if ((key == null) || (value == null)) { return false; } return key.equals(getKey()) && value.equals(getValue()); } public int hashCode() { Object v = getValue(); return hash ^ ((v == null) ? 0 : v.hashCode()); } public String toString() { return getKey() + "=" + getValue(); } boolean purge(Reference ref) { boolean r = (keyType > HARD) && (key == ref); r = r || ((valueType > HARD) && (value == ref)); if (r) { if (keyType > HARD) { ((Reference)key).clear(); } if (valueType > HARD) { ((Reference)value).clear(); } else if (purgeValues) { value = null; } } return r; } } /** * The EntrySet iterator. */ private class EntryIterator implements Iterator { // These fields keep track of where we are in the table. int index; Entry entry; Entry previous; // These Object fields provide hard references to the // current and next entry; this assures that if hasNext() // returns true, next() will actually return a valid element. Object nextKey, nextValue; Object currentKey, currentValue; int expectedModCount; public EntryIterator() { index = (size() != 0 ? table.length : 0); // have to do this here! size() invocation above // may have altered the modCount. expectedModCount = modCount; } public boolean hasNext() { checkMod(); while (nextNull()) { Entry e = entry; int i = index; while ((e == null) && (i > 0)) { i--; e = table[i]; } entry = e; index = i; if (e == null) { currentKey = null; currentValue = null; return false; } nextKey = e.getKey(); nextValue = e.getValue(); if (nextNull()) { entry = entry.next; } } return true; } private void checkMod() { if (modCount != expectedModCount) { throw new ConcurrentModificationException(); } } private boolean nextNull() { return (nextKey == null) || (nextValue == null); } protected Entry nextEntry() { checkMod(); if (nextNull() && !hasNext()) { throw new NoSuchElementException(); } previous = entry; entry = entry.next; currentKey = nextKey; currentValue = nextValue; nextKey = null; nextValue = null; return previous; } public Object next() { return nextEntry(); } public void remove() { checkMod(); if (previous == null) { throw new IllegalStateException(); } ReferenceMap.this.remove(currentKey); previous = null; currentKey = null; currentValue = null; expectedModCount = modCount; } } /** * The values iterator. */ private class ValueIterator extends EntryIterator { public Object next() { return nextEntry().getValue(); } } /** * The keySet iterator. */ private class KeyIterator extends EntryIterator { public Object next() { return nextEntry().getKey(); } } //----------------------------------------------------------------------- // These two classes store the hashCode of the key of // of the mapping, so that after they're dequeued a quick // lookup of the bucket in the table can occur. /** * A soft reference holder. */ private static class SoftRef extends SoftReference { private int hash; public SoftRef(int hash, Object r, ReferenceQueue q) { super(r, q); this.hash = hash; } public int hashCode() { return hash; } } /** * A weak reference holder. */ private static class WeakRef extends WeakReference { private int hash; public WeakRef(int hash, Object r, ReferenceQueue q) { super(r, q); this.hash = hash; } public int hashCode() { return hash; } } }





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