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Comparing jsr166/src/main/java/util/TreeMap.java (file contents):
Revision 1.15 by jsr166, Wed May 18 01:39:35 2005 UTC vs.
Revision 1.42 by jsr166, Tue Jan 30 03:54:29 2007 UTC

#	Line 1 | Line 1
1		/*
2		* %W% %E%
3		*
4	<	* Copyright 2005 Sun Microsystems, Inc. All rights reserved.
4	>	* Copyright 2007 Sun Microsystems, Inc. All rights reserved.
5		* SUN PROPRIETARY/CONFIDENTIAL. Use is subject to license terms.
6		*/
7
#	Line 30 | Line 30 | package java.util;
30		* <i>is</i> well-defined even if its ordering is inconsistent with equals; it
31		* just fails to obey the general contract of the <tt>Map</tt> interface.
32		*
33	<	* <p><b>Note that this implementation is not synchronized.</b> If multiple
34	<	* threads access a map concurrently, and at least one of the threads modifies
35	<	* the map structurally, it <i>must</i> be synchronized externally.  (A
36	<	* structural modification is any operation that adds or deletes one or more
37	<	* mappings; merely changing the value associated with an existing key is not
38	<	* a structural modification.)  This is typically accomplished by
39	<	* synchronizing on some object that naturally encapsulates the map.  If no
40	<	* such object exists, the map should be "wrapped" using the
41	<	* <tt>Collections.synchronizedMap</tt> method.  This is best done at creation
42	<	* time, to prevent accidental unsynchronized access to the map:
43	<	* <pre>
44	<	*     Map m = Collections.synchronizedMap(new TreeMap(...));
45	<	* </pre>
33	>	* <p><strong>Note that this implementation is not synchronized.</strong>
34	>	* If multiple threads access a map concurrently, and at least one of the
35	>	* threads modifies the map structurally, it <i>must</i> be synchronized
36	>	* externally.  (A structural modification is any operation that adds or
37	>	* deletes one or more mappings; merely changing the value associated
38	>	* with an existing key is not a structural modification.)  This is
39	>	* typically accomplished by synchronizing on some object that naturally
40	>	* encapsulates the map.
41	>	* If no such object exists, the map should be "wrapped" using the
42	>	* {@link Collections#synchronizedSortedMap Collections.synchronizedSortedMap}
43	>	* method.  This is best done at creation time, to prevent accidental
44	>	* unsynchronized access to the map: <pre>
45	>	*   SortedMap m = Collections.synchronizedSortedMap(new TreeMap(...));</pre>
46		*
47		* <p>The iterators returned by the <tt>iterator</tt> method of the collections
48		* returned by all of this class's "collection view methods" are
#	Line 68 | Line 68 | package java.util;
68		* associated map using <tt>put</tt>.)
69		*
70		* <p>This class is a member of the
71	<	* <a href="{@docRoot}/../guide/collections/index.html">
71	>	* <a href="{@docRoot}/../technotes/guides/collections/index.html">
72		* Java Collections Framework</a>.
73		*
74		* @param <K> the type of keys maintained by this map
#	Line 82 | Line 82 | package java.util;
82		* @see Comparable
83		* @see Comparator
84		* @see Collection
85	–	* @see Collections#synchronizedMap(Map)
85		* @since 1.2
86		*/
87
#	Line 96 | Line 95 | public class TreeMap<K,V>
95		*
96		* @serial
97		*/
98	<	private Comparator<? super K> comparator = null;
98	>	private final Comparator<? super K> comparator;
99
100		private transient Entry<K,V> root = null;
101
#	Line 110 | Line 109 | public class TreeMap<K,V>
109		*/
110		private transient int modCount = 0;
111
113	–	private void incrementSize()   { modCount++; size++; }
114	–	private void decrementSize()   { modCount++; size--; }
115	–
112		/**
113		* Constructs a new, empty tree map, using the natural ordering of its
114		* keys.  All keys inserted into the map must implement the {@link
#	Line 126 | Line 122 | public class TreeMap<K,V>
122		* <tt>ClassCastException</tt>.
123		*/
124		public TreeMap() {
125	+	comparator = null;
126		}
127
128		/**
#	Line 161 | Line 158 | public class TreeMap<K,V>
158		* @throws NullPointerException if the specified map is null
159		*/
160		public TreeMap(Map<? extends K, ? extends V> m) {
161	+	comparator = null;
162		putAll(m);
163		}
164
#	Line 216 | Line 214 | public class TreeMap<K,V>
214		* specified value.  More formally, returns <tt>true</tt> if and only if
215		* this map contains at least one mapping to a value <tt>v</tt> such
216		* that <tt>(value==null ? v==null : value.equals(v))</tt>.  This
217	<	* operation requires time linear in the map size.
217	>	* operation will probably require time linear in the map size for
218	>	* most implementations.
219		*
220		* @param value value whose presence in this map is to be tested
221		* @return <tt>true</tt> if a mapping to <tt>value</tt> exists;
#	Line 224 | Line 223 | public class TreeMap<K,V>
223		* @since 1.2
224		*/
225		public boolean containsValue(Object value) {
226	<	return (root==null ? false :
227	<	(value==null ? valueSearchNull(root)
228	<	: valueSearchNonNull(root, value)));
229	<	}
231	<
232	<	private boolean valueSearchNull(Entry n) {
233	<	if (n.value == null)
234	<	return true;
235	<
236	<	// Check left and right subtrees for value
237	<	return (n.left  != null && valueSearchNull(n.left)) ||
238	<	(n.right != null && valueSearchNull(n.right));
239	<	}
240	<
241	<	private boolean valueSearchNonNull(Entry n, Object value) {
242	<	// Check this node for the value
243	<	if (value.equals(n.value))
244	<	return true;
245	<
246	<	// Check left and right subtrees for value
247	<	return (n.left  != null && valueSearchNonNull(n.left, value)) ||
248	<	(n.right != null && valueSearchNonNull(n.right, value));
226	>	for (Entry<K,V> e = getFirstEntry(); e != null; e = successor(e))
227	>	if (valEquals(value, e.value))
228	>	return true;
229	>	return false;
230		}
231
232		/**
233	<	* Returns the value to which this map maps the specified key, or
234	<	* <tt>null</tt> if the map contains no mapping for the key.  A return
235	<	* value of <tt>null</tt> does not <i>necessarily</i> indicate that the
236	<	* map contains no mapping for the key; it's also possible that the map
237	<	* explicitly maps the key to <tt>null</tt>.  The {@link #containsKey}
238	<	* operation may be used to distinguish these two cases.
233	>	* Returns the value to which the specified key is mapped,
234	>	* or {@code null} if this map contains no mapping for the key.
235	>	*
236	>	* <p>More formally, if this map contains a mapping from a key
237	>	* {@code k} to a value {@code v} such that {@code key} compares
238	>	* equal to {@code k} according to the map's ordering, then this
239	>	* method returns {@code v}; otherwise it returns {@code null}.
240	>	* (There can be at most one such mapping.)
241	>	*
242	>	* <p>A return value of {@code null} does not <i>necessarily</i>
243	>	* indicate that the map contains no mapping for the key; it's also
244	>	* possible that the map explicitly maps the key to {@code null}.
245	>	* The {@link #containsKey containsKey} operation may be used to
246	>	* distinguish these two cases.
247		*
259	–	* @param key key whose associated value is to be returned
260	–	* @return the value to which this map maps the specified key, or
261	–	*         <tt>null</tt> if the map contains no mapping for the key
248		* @throws ClassCastException if the specified key cannot be compared
249		*         with the keys currently in the map
250		* @throws NullPointerException if the specified key is null
#	Line 330 | Line 316 | public class TreeMap<K,V>
316		*         and this map uses natural ordering, or its comparator
317		*         does not permit null keys
318		*/
319	<	private Entry<K,V> getEntry(Object key) {
319	>	final Entry<K,V> getEntry(Object key) {
320		// Offload comparator-based version for sake of performance
321		if (comparator != null)
322		return getEntryUsingComparator(key);
323	+	if (key == null)
324	+	throw new NullPointerException();
325		Comparable<? super K> k = (Comparable<? super K>) key;
326		Entry<K,V> p = root;
327		while (p != null) {
#	Line 354 | Line 342 | public class TreeMap<K,V>
342		* that are less dependent on comparator performance, but is
343		* worthwhile here.)
344		*/
345	<	private Entry<K,V> getEntryUsingComparator(Object key) {
345	>	final Entry<K,V> getEntryUsingComparator(Object key) {
346		K k = (K) key;
347		Comparator<? super K> cpr = comparator;
348	<	Entry<K,V> p = root;
349	<	while (p != null) {
350	<	int cmp = cpr.compare(k, p.key);
351	<	if (cmp < 0)
352	<	p = p.left;
353	<	else if (cmp > 0)
354	<	p = p.right;
355	<	else
356	<	return p;
348	>	if (cpr != null) {
349	>	Entry<K,V> p = root;
350	>	while (p != null) {
351	>	int cmp = cpr.compare(k, p.key);
352	>	if (cmp < 0)
353	>	p = p.left;
354	>	else if (cmp > 0)
355	>	p = p.right;
356	>	else
357	>	return p;
358	>	}
359		}
360		return null;
361		}
#	Line 376 | Line 366 | public class TreeMap<K,V>
366		* key; if no such entry exists (i.e., the greatest key in the Tree is less
367		* than the specified key), returns <tt>null</tt>.
368		*/
369	<	private Entry<K,V> getCeilingEntry(K key) {
369	>	final Entry<K,V> getCeilingEntry(K key) {
370		Entry<K,V> p = root;
371	<	if (p==null)
382	<	return null;
383	<
384	<	while (true) {
371	>	while (p != null) {
372		int cmp = compare(key, p.key);
373		if (cmp < 0) {
374		if (p.left != null)
#	Line 403 | Line 390 | public class TreeMap<K,V>
390		} else
391		return p;
392		}
393	+	return null;
394		}
395
396		/**
#	Line 410 | Line 398 | public class TreeMap<K,V>
398		* exists, returns the entry for the greatest key less than the specified
399		* key; if no such entry exists, returns <tt>null</tt>.
400		*/
401	<	private Entry<K,V> getFloorEntry(K key) {
401	>	final Entry<K,V> getFloorEntry(K key) {
402		Entry<K,V> p = root;
403	<	if (p==null)
416	<	return null;
417	<
418	<	while (true) {
403	>	while (p != null) {
404		int cmp = compare(key, p.key);
405		if (cmp > 0) {
406		if (p.right != null)
#	Line 438 | Line 423 | public class TreeMap<K,V>
423		return p;
424
425		}
426	+	return null;
427		}
428
429		/**
#	Line 446 | Line 432 | public class TreeMap<K,V>
432		* key greater than the specified key; if no such entry exists
433		* returns <tt>null</tt>.
434		*/
435	<	private Entry<K,V> getHigherEntry(K key) {
435	>	final Entry<K,V> getHigherEntry(K key) {
436		Entry<K,V> p = root;
437	<	if (p==null)
452	<	return null;
453	<
454	<	while (true) {
437	>	while (p != null) {
438		int cmp = compare(key, p.key);
439		if (cmp < 0) {
440		if (p.left != null)
#	Line 472 | Line 455 | public class TreeMap<K,V>
455		}
456		}
457		}
458	+	return null;
459		}
460
461		/**
#	Line 479 | Line 463 | public class TreeMap<K,V>
463		* no such entry exists (i.e., the least key in the Tree is greater than
464		* the specified key), returns <tt>null</tt>.
465		*/
466	<	private Entry<K,V> getLowerEntry(K key) {
466	>	final Entry<K,V> getLowerEntry(K key) {
467		Entry<K,V> p = root;
468	<	if (p==null)
485	<	return null;
486	<
487	<	while (true) {
468	>	while (p != null) {
469		int cmp = compare(key, p.key);
470		if (cmp > 0) {
471		if (p.right != null)
#	Line 505 | Line 486 | public class TreeMap<K,V>
486		}
487		}
488		}
489	<	}
509	<
510	<	/**
511	<	* Returns the key corresponding to the specified Entry.
512	<	* @throws NoSuchElementException if the Entry is null
513	<	*/
514	<	private static <K> K key(Entry<K,?> e) {
515	<	if (e==null)
516	<	throw new NoSuchElementException();
517	<	return e.key;
489	>	return null;
490		}
491
492		/**
493		* Associates the specified value with the specified key in this map.
494	<	* If the map previously contained a mapping for this key, the old
494	>	* If the map previously contained a mapping for the key, the old
495		* value is replaced.
496		*
497		* @param key key with which the specified value is to be associated
#	Line 537 | Line 509 | public class TreeMap<K,V>
509		*/
510		public V put(K key, V value) {
511		Entry<K,V> t = root;
540	–
512		if (t == null) {
513	<	if (key == null) {
514	<	if (comparator == null)
515	<	throw new NullPointerException();
516	<	comparator.compare(key, key);
517	<	}
547	<	incrementSize();
513	>	// TBD:
514	>	// 5045147: (coll) Adding null to an empty TreeSet should
515	>	// throw NullPointerException
516	>	//
517	>	// compare(key, key); // type check
518		root = new Entry<K,V>(key, value, null);
519	+	size = 1;
520	+	modCount++;
521		return null;
522		}
523	<
524	<	while (true) {
525	<	int cmp = compare(key, t.key);
526	<	if (cmp == 0) {
527	<	return t.setValue(value);
528	<	} else if (cmp < 0) {
529	<	if (t.left != null) {
523	>	int cmp;
524	>	Entry<K,V> parent;
525	>	// split comparator and comparable paths
526	>	Comparator<? super K> cpr = comparator;
527	>	if (cpr != null) {
528	>	do {
529	>	parent = t;
530	>	cmp = cpr.compare(key, t.key);
531	>	if (cmp < 0)
532		t = t.left;
533	<	} else {
560	<	incrementSize();
561	<	t.left = new Entry<K,V>(key, value, t);
562	<	fixAfterInsertion(t.left);
563	<	return null;
564	<	}
565	<	} else { // cmp > 0
566	<	if (t.right != null) {
533	>	else if (cmp > 0)
534		t = t.right;
535	<	} else {
536	<	incrementSize();
537	<	t.right = new Entry<K,V>(key, value, t);
571	<	fixAfterInsertion(t.right);
572	<	return null;
573	<	}
574	<	}
535	>	else
536	>	return t.setValue(value);
537	>	} while (t != null);
538		}
539	+	else {
540	+	if (key == null)
541	+	throw new NullPointerException();
542	+	Comparable<? super K> k = (Comparable<? super K>) key;
543	+	do {
544	+	parent = t;
545	+	cmp = k.compareTo(t.key);
546	+	if (cmp < 0)
547	+	t = t.left;
548	+	else if (cmp > 0)
549	+	t = t.right;
550	+	else
551	+	return t.setValue(value);
552	+	} while (t != null);
553	+	}
554	+	Entry<K,V> e = new Entry<K,V>(key, value, parent);
555	+	if (cmp < 0)
556	+	parent.left = e;
557	+	else
558	+	parent.right = e;
559	+	fixAfterInsertion(e);
560	+	size++;
561	+	modCount++;
562	+	return null;
563		}
564
565		/**
#	Line 628 | Line 615 | public class TreeMap<K,V>
615		clone.size = 0;
616		clone.modCount = 0;
617		clone.entrySet = null;
618	<	clone.descendingEntrySet = null;
619	<	clone.descendingKeySet = null;
618	>	clone.navigableKeySet = null;
619	>	clone.descendingMap = null;
620
621		// Initialize clone with our mappings
622		try {
#	Line 643 | Line 630 | public class TreeMap<K,V>
630
631		// NavigableMap API methods
632
633	+	/**
634	+	* @since 1.6
635	+	*/
636		public Map.Entry<K,V> firstEntry() {
637	<	Entry<K,V> e = getFirstEntry();
648	<	return (e == null)? null : new AbstractMap.SimpleImmutableEntry(e);
637	>	return exportEntry(getFirstEntry());
638		}
639
640	+	/**
641	+	* @since 1.6
642	+	*/
643		public Map.Entry<K,V> lastEntry() {
644	<	Entry<K,V> e = getLastEntry();
653	<	return (e == null)? null : new AbstractMap.SimpleImmutableEntry(e);
644	>	return exportEntry(getLastEntry());
645		}
646
647	+	/**
648	+	* @since 1.6
649	+	*/
650		public Map.Entry<K,V> pollFirstEntry() {
651		Entry<K,V> p = getFirstEntry();
652	<	if (p == null)
653	<	return null;
654	<	Map.Entry result = new AbstractMap.SimpleImmutableEntry(p);
661	<	deleteEntry(p);
652	>	Map.Entry<K,V> result = exportEntry(p);
653	>	if (p != null)
654	>	deleteEntry(p);
655		return result;
656		}
657
658	+	/**
659	+	* @since 1.6
660	+	*/
661		public Map.Entry<K,V> pollLastEntry() {
662		Entry<K,V> p = getLastEntry();
663	<	if (p == null)
664	<	return null;
665	<	Map.Entry result = new AbstractMap.SimpleImmutableEntry(p);
670	<	deleteEntry(p);
663	>	Map.Entry<K,V> result = exportEntry(p);
664	>	if (p != null)
665	>	deleteEntry(p);
666		return result;
667		}
668
#	Line 676 | Line 671 | public class TreeMap<K,V>
671		* @throws NullPointerException if the specified key is null
672		*         and this map uses natural ordering, or its comparator
673		*         does not permit null keys
674	+	* @since 1.6
675		*/
676		public Map.Entry<K,V> lowerEntry(K key) {
677	<	Entry<K,V> e =  getLowerEntry(key);
682	<	return (e == null)? null : new AbstractMap.SimpleImmutableEntry(e);
677	>	return exportEntry(getLowerEntry(key));
678		}
679
680		/**
#	Line 687 | Line 682 | public class TreeMap<K,V>
682		* @throws NullPointerException if the specified key is null
683		*         and this map uses natural ordering, or its comparator
684		*         does not permit null keys
685	+	* @since 1.6
686		*/
687		public K lowerKey(K key) {
688	<	Entry<K,V> e =  getLowerEntry(key);
693	<	return (e == null)? null : e.key;
688	>	return keyOrNull(getLowerEntry(key));
689		}
690
691		/**
#	Line 698 | Line 693 | public class TreeMap<K,V>
693		* @throws NullPointerException if the specified key is null
694		*         and this map uses natural ordering, or its comparator
695		*         does not permit null keys
696	+	* @since 1.6
697		*/
698		public Map.Entry<K,V> floorEntry(K key) {
699	<	Entry<K,V> e = getFloorEntry(key);
704	<	return (e == null)? null : new AbstractMap.SimpleImmutableEntry(e);
699	>	return exportEntry(getFloorEntry(key));
700		}
701
702		/**
#	Line 709 | Line 704 | public class TreeMap<K,V>
704		* @throws NullPointerException if the specified key is null
705		*         and this map uses natural ordering, or its comparator
706		*         does not permit null keys
707	+	* @since 1.6
708		*/
709		public K floorKey(K key) {
710	<	Entry<K,V> e = getFloorEntry(key);
715	<	return (e == null)? null : e.key;
710	>	return keyOrNull(getFloorEntry(key));
711		}
712
713		/**
#	Line 720 | Line 715 | public class TreeMap<K,V>
715		* @throws NullPointerException if the specified key is null
716		*         and this map uses natural ordering, or its comparator
717		*         does not permit null keys
718	+	* @since 1.6
719		*/
720		public Map.Entry<K,V> ceilingEntry(K key) {
721	<	Entry<K,V> e = getCeilingEntry(key);
726	<	return (e == null)? null : new AbstractMap.SimpleImmutableEntry(e);
721	>	return exportEntry(getCeilingEntry(key));
722		}
723
724		/**
#	Line 731 | Line 726 | public class TreeMap<K,V>
726		* @throws NullPointerException if the specified key is null
727		*         and this map uses natural ordering, or its comparator
728		*         does not permit null keys
729	+	* @since 1.6
730		*/
731		public K ceilingKey(K key) {
732	<	Entry<K,V> e = getCeilingEntry(key);
737	<	return (e == null)? null : e.key;
732	>	return keyOrNull(getCeilingEntry(key));
733		}
734
735		/**
#	Line 742 | Line 737 | public class TreeMap<K,V>
737		* @throws NullPointerException if the specified key is null
738		*         and this map uses natural ordering, or its comparator
739		*         does not permit null keys
740	+	* @since 1.6
741		*/
742		public Map.Entry<K,V> higherEntry(K key) {
743	<	Entry<K,V> e = getHigherEntry(key);
748	<	return (e == null)? null : new AbstractMap.SimpleImmutableEntry(e);
743	>	return exportEntry(getHigherEntry(key));
744		}
745
746		/**
#	Line 753 | Line 748 | public class TreeMap<K,V>
748		* @throws NullPointerException if the specified key is null
749		*         and this map uses natural ordering, or its comparator
750		*         does not permit null keys
751	+	* @since 1.6
752		*/
753		public K higherKey(K key) {
754	<	Entry<K,V> e = getHigherEntry(key);
759	<	return (e == null)? null : e.key;
754	>	return keyOrNull(getHigherEntry(key));
755		}
756
757		// Views
#	Line 766 | Line 761 | public class TreeMap<K,V>
761		* the first time this view is requested.  Views are stateless, so
762		* there's no reason to create more than one.
763		*/
764	<	private transient Set<Map.Entry<K,V>> entrySet = null;
765	<	private transient Set<Map.Entry<K,V>> descendingEntrySet = null;
766	<	private transient Set<K> descendingKeySet = null;
764	>	private transient EntrySet entrySet = null;
765	>	private transient KeySet<K> navigableKeySet = null;
766	>	private transient NavigableMap<K,V> descendingMap = null;
767
768		/**
769		* Returns a {@link Set} view of the keys contained in this map.
#	Line 785 | Line 780 | public class TreeMap<K,V>
780		* operations.
781		*/
782		public Set<K> keySet() {
783	<	Set<K> ks = keySet;
789	<	return (ks != null) ? ks : (keySet = new KeySet());
783	>	return navigableKeySet();
784		}
785
786	<	class KeySet extends AbstractSet<K> {
787	<	public Iterator<K> iterator() {
788	<	return new KeyIterator(getFirstEntry());
789	<	}
790	<
791	<	public int size() {
792	<	return TreeMap.this.size();
799	<	}
800	<
801	<	public boolean contains(Object o) {
802	<	return containsKey(o);
803	<	}
804	<
805	<	public boolean remove(Object o) {
806	<	int oldSize = size;
807	<	TreeMap.this.remove(o);
808	<	return size != oldSize;
809	<	}
786	>	/**
787	>	* @since 1.6
788	>	*/
789	>	public NavigableSet<K> navigableKeySet() {
790	>	KeySet<K> nks = navigableKeySet;
791	>	return (nks != null) ? nks : (navigableKeySet = new KeySet(this));
792	>	}
793
794	<	public void clear() {
795	<	TreeMap.this.clear();
796	<	}
794	>	/**
795	>	* @since 1.6
796	>	*/
797	>	public NavigableSet<K> descendingKeySet() {
798	>	return descendingMap().navigableKeySet();
799		}
800
801		/**
#	Line 833 | Line 818 | public class TreeMap<K,V>
818		return (vs != null) ? vs : (values = new Values());
819		}
820
821	+	/**
822	+	* Returns a {@link Set} view of the mappings contained in this map.
823	+	* The set's iterator returns the entries in ascending key order.
824	+	* The set is backed by the map, so changes to the map are
825	+	* reflected in the set, and vice-versa.  If the map is modified
826	+	* while an iteration over the set is in progress (except through
827	+	* the iterator's own <tt>remove</tt> operation, or through the
828	+	* <tt>setValue</tt> operation on a map entry returned by the
829	+	* iterator) the results of the iteration are undefined.  The set
830	+	* supports element removal, which removes the corresponding
831	+	* mapping from the map, via the <tt>Iterator.remove</tt>,
832	+	* <tt>Set.remove</tt>, <tt>removeAll</tt>, <tt>retainAll</tt> and
833	+	* <tt>clear</tt> operations.  It does not support the
834	+	* <tt>add</tt> or <tt>addAll</tt> operations.
835	+	*/
836	+	public Set<Map.Entry<K,V>> entrySet() {
837	+	EntrySet es = entrySet;
838	+	return (es != null) ? es : (entrySet = new EntrySet());
839	+	}
840	+
841	+	/**
842	+	* @since 1.6
843	+	*/
844	+	public NavigableMap<K, V> descendingMap() {
845	+	NavigableMap<K, V> km = descendingMap;
846	+	return (km != null) ? km :
847	+	(descendingMap = new DescendingSubMap(this,
848	+	true, null, true,
849	+	true, null, true));
850	+	}
851	+
852	+	/**
853	+	* @throws ClassCastException       {@inheritDoc}
854	+	* @throws NullPointerException if <tt>fromKey</tt> or <tt>toKey</tt> is
855	+	*         null and this map uses natural ordering, or its comparator
856	+	*         does not permit null keys
857	+	* @throws IllegalArgumentException {@inheritDoc}
858	+	* @since 1.6
859	+	*/
860	+	public NavigableMap<K,V> subMap(K fromKey, boolean fromInclusive,
861	+	K toKey,   boolean toInclusive) {
862	+	return new AscendingSubMap(this,
863	+	false, fromKey, fromInclusive,
864	+	false, toKey,   toInclusive);
865	+	}
866	+
867	+	/**
868	+	* @throws ClassCastException       {@inheritDoc}
869	+	* @throws NullPointerException if <tt>toKey</tt> is null
870	+	*         and this map uses natural ordering, or its comparator
871	+	*         does not permit null keys
872	+	* @throws IllegalArgumentException {@inheritDoc}
873	+	* @since 1.6
874	+	*/
875	+	public NavigableMap<K,V> headMap(K toKey, boolean inclusive) {
876	+	return new AscendingSubMap(this,
877	+	true,  null,  true,
878	+	false, toKey, inclusive);
879	+	}
880	+
881	+	/**
882	+	* @throws ClassCastException       {@inheritDoc}
883	+	* @throws NullPointerException if <tt>fromKey</tt> is null
884	+	*         and this map uses natural ordering, or its comparator
885	+	*         does not permit null keys
886	+	* @throws IllegalArgumentException {@inheritDoc}
887	+	* @since 1.6
888	+	*/
889	+	public NavigableMap<K,V> tailMap(K fromKey, boolean inclusive) {
890	+	return new AscendingSubMap(this,
891	+	false, fromKey, inclusive,
892	+	true,  null,    true);
893	+	}
894	+
895	+	/**
896	+	* @throws ClassCastException       {@inheritDoc}
897	+	* @throws NullPointerException if <tt>fromKey</tt> or <tt>toKey</tt> is
898	+	*         null and this map uses natural ordering, or its comparator
899	+	*         does not permit null keys
900	+	* @throws IllegalArgumentException {@inheritDoc}
901	+	*/
902	+	public SortedMap<K,V> subMap(K fromKey, K toKey) {
903	+	return subMap(fromKey, true, toKey, false);
904	+	}
905	+
906	+	/**
907	+	* @throws ClassCastException       {@inheritDoc}
908	+	* @throws NullPointerException if <tt>toKey</tt> is null
909	+	*         and this map uses natural ordering, or its comparator
910	+	*         does not permit null keys
911	+	* @throws IllegalArgumentException {@inheritDoc}
912	+	*/
913	+	public SortedMap<K,V> headMap(K toKey) {
914	+	return headMap(toKey, false);
915	+	}
916	+
917	+	/**
918	+	* @throws ClassCastException       {@inheritDoc}
919	+	* @throws NullPointerException if <tt>fromKey</tt> is null
920	+	*         and this map uses natural ordering, or its comparator
921	+	*         does not permit null keys
922	+	* @throws IllegalArgumentException {@inheritDoc}
923	+	*/
924	+	public SortedMap<K,V> tailMap(K fromKey) {
925	+	return tailMap(fromKey, true);
926	+	}
927	+
928	+	// View class support
929	+
930		class Values extends AbstractCollection<V> {
931		public Iterator<V> iterator() {
932		return new ValueIterator(getFirstEntry());
#	Line 843 | Line 937 | public class TreeMap<K,V>
937		}
938
939		public boolean contains(Object o) {
940	<	for (Entry<K,V> e = getFirstEntry(); e != null; e = successor(e))
847	<	if (valEquals(e.getValue(), o))
848	<	return true;
849	<	return false;
940	>	return TreeMap.this.containsValue(o);
941		}
942
943		public boolean remove(Object o) {
#	Line 864 | Line 955 | public class TreeMap<K,V>
955		}
956		}
957
867	–	/**
868	–	* Returns a {@link Set} view of the mappings contained in this map.
869	–	* The set's iterator returns the entries in ascending key order.
870	–	* The set is backed by the map, so changes to the map are
871	–	* reflected in the set, and vice-versa.  If the map is modified
872	–	* while an iteration over the set is in progress (except through
873	–	* the iterator's own <tt>remove</tt> operation, or through the
874	–	* <tt>setValue</tt> operation on a map entry returned by the
875	–	* iterator) the results of the iteration are undefined.  The set
876	–	* supports element removal, which removes the corresponding
877	–	* mapping from the map, via the <tt>Iterator.remove</tt>,
878	–	* <tt>Set.remove</tt>, <tt>removeAll</tt>, <tt>retainAll</tt> and
879	–	* <tt>clear</tt> operations.  It does not support the
880	–	* <tt>add</tt> or <tt>addAll</tt> operations.
881	–	*/
882	–	public Set<Map.Entry<K,V>> entrySet() {
883	–	Set<Map.Entry<K,V>> es = entrySet;
884	–	return (es != null) ? es : (entrySet = new EntrySet());
885	–	}
886	–
958		class EntrySet extends AbstractSet<Map.Entry<K,V>> {
959		public Iterator<Map.Entry<K,V>> iterator() {
960		return new EntryIterator(getFirstEntry());
#	Line 920 | Line 991 | public class TreeMap<K,V>
991		}
992		}
993
994	<	public Set<Map.Entry<K,V>> descendingEntrySet() {
995	<	Set<Map.Entry<K,V>> es = descendingEntrySet;
996	<	return (es != null) ? es : (descendingEntrySet = new DescendingEntrySet());
994	>	/*
995	>	* Unlike Values and EntrySet, the KeySet class is static,
996	>	* delegating to a NavigableMap to allow use by SubMaps, which
997	>	* outweighs the ugliness of needing type-tests for the following
998	>	* Iterator methods that are defined appropriately in main versus
999	>	* submap classes.
1000	>	*/
1001	>
1002	>	Iterator<K> keyIterator() {
1003	>	return new KeyIterator(getFirstEntry());
1004	>	}
1005	>
1006	>	Iterator<K> descendingKeyIterator() {
1007	>	return new DescendingKeyIterator(getFirstEntry());
1008	>	}
1009	>
1010	>	static final class KeySet<E> extends AbstractSet<E> implements NavigableSet<E> {
1011	>	private final NavigableMap<E, Object> m;
1012	>	KeySet(NavigableMap<E,Object> map) { m = map; }
1013	>
1014	>	public Iterator<E> iterator() {
1015	>	if (m instanceof TreeMap)
1016	>	return ((TreeMap<E,Object>)m).keyIterator();
1017	>	else
1018	>	return (Iterator<E>)(((TreeMap.NavigableSubMap)m).keyIterator());
1019	>	}
1020	>
1021	>	public Iterator<E> descendingIterator() {
1022	>	if (m instanceof TreeMap)
1023	>	return ((TreeMap<E,Object>)m).descendingKeyIterator();
1024	>	else
1025	>	return (Iterator<E>)(((TreeMap.NavigableSubMap)m).descendingKeyIterator());
1026	>	}
1027	>
1028	>	public int size() { return m.size(); }
1029	>	public boolean isEmpty() { return m.isEmpty(); }
1030	>	public boolean contains(Object o) { return m.containsKey(o); }
1031	>	public void clear() { m.clear(); }
1032	>	public E lower(E e) { return m.lowerKey(e); }
1033	>	public E floor(E e) { return m.floorKey(e); }
1034	>	public E ceiling(E e) { return m.ceilingKey(e); }
1035	>	public E higher(E e) { return m.higherKey(e); }
1036	>	public E first() { return m.firstKey(); }
1037	>	public E last() { return m.lastKey(); }
1038	>	public Comparator<? super E> comparator() { return m.comparator(); }
1039	>	public E pollFirst() {
1040	>	Map.Entry<E,Object> e = m.pollFirstEntry();
1041	>	return e == null? null : e.getKey();
1042	>	}
1043	>	public E pollLast() {
1044	>	Map.Entry<E,Object> e = m.pollLastEntry();
1045	>	return e == null? null : e.getKey();
1046	>	}
1047	>	public boolean remove(Object o) {
1048	>	int oldSize = size();
1049	>	m.remove(o);
1050	>	return size() != oldSize;
1051	>	}
1052	>	public NavigableSet<E> subSet(E fromElement, boolean fromInclusive,
1053	>	E toElement,   boolean toInclusive) {
1054	>	return new TreeSet<E>(m.subMap(fromElement, fromInclusive,
1055	>	toElement,   toInclusive));
1056	>	}
1057	>	public NavigableSet<E> headSet(E toElement, boolean inclusive) {
1058	>	return new TreeSet<E>(m.headMap(toElement, inclusive));
1059	>	}
1060	>	public NavigableSet<E> tailSet(E fromElement, boolean inclusive) {
1061	>	return new TreeSet<E>(m.tailMap(fromElement, inclusive));
1062	>	}
1063	>	public SortedSet<E> subSet(E fromElement, E toElement) {
1064	>	return subSet(fromElement, true, toElement, false);
1065	>	}
1066	>	public SortedSet<E> headSet(E toElement) {
1067	>	return headSet(toElement, false);
1068	>	}
1069	>	public SortedSet<E> tailSet(E fromElement) {
1070	>	return tailSet(fromElement, true);
1071	>	}
1072	>	public NavigableSet<E> descendingSet() {
1073	>	return new TreeSet(m.descendingMap());
1074	>	}
1075	>	}
1076	>
1077	>	/**
1078	>	* Base class for TreeMap Iterators
1079	>	*/
1080	>	abstract class PrivateEntryIterator<T> implements Iterator<T> {
1081	>	Entry<K,V> next;
1082	>	Entry<K,V> lastReturned;
1083	>	int expectedModCount;
1084	>
1085	>	PrivateEntryIterator(Entry<K,V> first) {
1086	>	expectedModCount = modCount;
1087	>	lastReturned = null;
1088	>	next = first;
1089	>	}
1090	>
1091	>	public final boolean hasNext() {
1092	>	return next != null;
1093	>	}
1094	>
1095	>	final Entry<K,V> nextEntry() {
1096	>	Entry<K,V> e = lastReturned = next;
1097	>	if (e == null)
1098	>	throw new NoSuchElementException();
1099	>	if (modCount != expectedModCount)
1100	>	throw new ConcurrentModificationException();
1101	>	next = successor(e);
1102	>	return e;
1103	>	}
1104	>
1105	>	final Entry<K,V> prevEntry() {
1106	>	Entry<K,V> e = lastReturned= next;
1107	>	if (e == null)
1108	>	throw new NoSuchElementException();
1109	>	if (modCount != expectedModCount)
1110	>	throw new ConcurrentModificationException();
1111	>	next = predecessor(e);
1112	>	return e;
1113	>	}
1114	>
1115	>	public void remove() {
1116	>	if (lastReturned == null)
1117	>	throw new IllegalStateException();
1118	>	if (modCount != expectedModCount)
1119	>	throw new ConcurrentModificationException();
1120	>	// deleted entries are replaced by their successors
1121	>	if (lastReturned.left != null && lastReturned.right != null)
1122	>	next = lastReturned;
1123	>	deleteEntry(lastReturned);
1124	>	expectedModCount = modCount;
1125	>	lastReturned = null;
1126	>	}
1127	>	}
1128	>
1129	>	final class EntryIterator extends PrivateEntryIterator<Map.Entry<K,V>> {
1130	>	EntryIterator(Entry<K,V> first) {
1131	>	super(first);
1132	>	}
1133	>	public Map.Entry<K,V> next() {
1134	>	return nextEntry();
1135	>	}
1136		}
1137
1138	<	class DescendingEntrySet extends EntrySet {
1139	<	public Iterator<Map.Entry<K,V>> iterator() {
1140	<	return new DescendingEntryIterator(getLastEntry());
1138	>	final class ValueIterator extends PrivateEntryIterator<V> {
1139	>	ValueIterator(Entry<K,V> first) {
1140	>	super(first);
1141	>	}
1142	>	public V next() {
1143	>	return nextEntry().value;
1144		}
1145		}
1146
1147	<	public Set<K> descendingKeySet() {
1148	<	Set<K> ks = descendingKeySet;
1149	<	return (ks != null) ? ks : (descendingKeySet = new DescendingKeySet());
1147	>	final class KeyIterator extends PrivateEntryIterator<K> {
1148	>	KeyIterator(Entry<K,V> first) {
1149	>	super(first);
1150	>	}
1151	>	public K next() {
1152	>	return nextEntry().key;
1153	>	}
1154		}
1155
1156	<	class DescendingKeySet extends KeySet {
1157	<	public Iterator<K> iterator() {
1158	<	return new DescendingKeyIterator(getLastEntry());
1156	>	final class DescendingKeyIterator extends PrivateEntryIterator<K> {
1157	>	DescendingKeyIterator(Entry<K,V> first) {
1158	>	super(first);
1159	>	}
1160	>	public K next() {
1161	>	return prevEntry().key;
1162		}
1163		}
1164
1165	+	// Little utilities
1166	+
1167		/**
1168	<	* @throws ClassCastException       {@inheritDoc}
947	<	* @throws NullPointerException if <tt>fromKey</tt> or <tt>toKey</tt> is
948	<	*         null and this map uses natural ordering, or its comparator
949	<	*         does not permit null keys
950	<	* @throws IllegalArgumentException {@inheritDoc}
1168	>	* Compares two keys using the correct comparison method for this TreeMap.
1169		*/
1170	<	public NavigableMap<K,V> navigableSubMap(K fromKey, K toKey) {
1171	<	return new SubMap(fromKey, toKey);
1170	>	final int compare(Object k1, Object k2) {
1171	>	return comparator==null ? ((Comparable<? super K>)k1).compareTo((K)k2)
1172	>	: comparator.compare((K)k1, (K)k2);
1173		}
1174
1175		/**
1176	<	* @throws ClassCastException       {@inheritDoc}
1177	<	* @throws NullPointerException if <tt>toKey</tt> is null
959	<	*         and this map uses natural ordering, or its comparator
960	<	*         does not permit null keys
961	<	* @throws IllegalArgumentException {@inheritDoc}
1176	>	* Test two values for equality.  Differs from o1.equals(o2) only in
1177	>	* that it copes with <tt>null</tt> o1 properly.
1178		*/
1179	<	public NavigableMap<K,V> navigableHeadMap(K toKey) {
1180	<	return new SubMap(toKey, true);
1179	>	final static boolean valEquals(Object o1, Object o2) {
1180	>	return (o1==null ? o2==null : o1.equals(o2));
1181		}
1182
1183		/**
1184	<	* @throws ClassCastException       {@inheritDoc}
969	<	* @throws NullPointerException if <tt>fromKey</tt> is null
970	<	*         and this map uses natural ordering, or its comparator
971	<	*         does not permit null keys
972	<	* @throws IllegalArgumentException {@inheritDoc}
1184	>	* Return SimpleImmutableEntry for entry, or null if null
1185		*/
1186	<	public NavigableMap<K,V> navigableTailMap(K fromKey) {
1187	<	return new SubMap(fromKey, false);
1186	>	static <K,V> Map.Entry<K,V> exportEntry(TreeMap.Entry<K,V> e) {
1187	>	return e == null? null :
1188	>	new AbstractMap.SimpleImmutableEntry<K,V>(e);
1189		}
1190
1191		/**
1192	<	* Equivalent to {@link #navigableSubMap} but with a return type
980	<	* conforming to the <tt>SortedMap</tt> interface.
981	<	*
982	<	* <p>{@inheritDoc}
983	<	*
984	<	* @throws ClassCastException       {@inheritDoc}
985	<	* @throws NullPointerException if <tt>fromKey</tt> or <tt>toKey</tt> is
986	<	*         null and this map uses natural ordering, or its comparator
987	<	*         does not permit null keys
988	<	* @throws IllegalArgumentException {@inheritDoc}
1192	>	* Return key for entry, or null if null
1193		*/
1194	<	public SortedMap<K,V> subMap(K fromKey, K toKey) {
1195	<	return new SubMap(fromKey, toKey);
1194	>	static <K,V> K keyOrNull(TreeMap.Entry<K,V> e) {
1195	>	return e == null? null : e.key;
1196		}
1197
1198		/**
1199	<	* Equivalent to {@link #navigableHeadMap} but with a return type
1200	<	* conforming to the <tt>SortedMap</tt> interface.
997	<	*
998	<	* <p>{@inheritDoc}
999	<	*
1000	<	* @throws ClassCastException       {@inheritDoc}
1001	<	* @throws NullPointerException if <tt>toKey</tt> is null
1002	<	*         and this map uses natural ordering, or its comparator
1003	<	*         does not permit null keys
1004	<	* @throws IllegalArgumentException {@inheritDoc}
1199	>	* Returns the key corresponding to the specified Entry.
1200	>	* @throws NoSuchElementException if the Entry is null
1201		*/
1202	<	public SortedMap<K,V> headMap(K toKey) {
1203	<	return new SubMap(toKey, true);
1202	>	static <K> K key(Entry<K,?> e) {
1203	>	if (e==null)
1204	>	throw new NoSuchElementException();
1205	>	return e.key;
1206		}
1207
1208	+
1209	+	// SubMaps
1210	+
1211		/**
1212	<	* Equivalent to {@link #navigableTailMap} but with a return type
1213	<	* conforming to the <tt>SortedMap</tt> interface.
1013	<	*
1014	<	* <p>{@inheritDoc}
1015	<	*
1016	<	* @throws ClassCastException       {@inheritDoc}
1017	<	* @throws NullPointerException if <tt>fromKey</tt> is null
1018	<	*         and this map uses natural ordering, or its comparator
1019	<	*         does not permit null keys
1020	<	* @throws IllegalArgumentException {@inheritDoc}
1212	>	* Dummy value serving as unmatchable fence key for unbounded
1213	>	* SubMapIterators
1214		*/
1215	<	public SortedMap<K,V> tailMap(K fromKey) {
1023	<	return new SubMap(fromKey, false);
1024	<	}
1215	>	private static final Object UNBOUNDED = new Object();
1216
1217	<	private class SubMap
1218	<	extends AbstractMap<K,V>
1219	<	implements NavigableMap<K,V>, java.io.Serializable {
1220	<	private static final long serialVersionUID = -6520786458950516097L;
1217	>	/**
1218	>	* @serial include
1219	>	*/
1220	>	static abstract class NavigableSubMap<K,V> extends AbstractMap<K,V>
1221	>	implements NavigableMap<K,V>, java.io.Serializable {
1222	>	/**
1223	>	* The backing map.
1224	>	*/
1225	>	final TreeMap<K,V> m;
1226
1227		/**
1228	<	* fromKey is significant only if fromStart is false.  Similarly,
1229	<	* toKey is significant only if toStart is false.
1228	>	* Endpoints are represented as triples (fromStart, lo,
1229	>	* loInclusive) and (toEnd, hi, hiInclusive). If fromStart is
1230	>	* true, then the low (absolute) bound is the start of the
1231	>	* backing map, and the other values are ignored. Otherwise,
1232	>	* if loInclusive is true, lo is the inclusive bound, else lo
1233	>	* is the exclusive bound. Similarly for the upper bound.
1234		*/
1235	<	private boolean fromStart = false, toEnd = false;
1236	<	private K fromKey, toKey;
1235	>	final K lo, hi;
1236	>	final boolean fromStart, toEnd;
1237	>	final boolean loInclusive, hiInclusive;
1238	>
1239	>	NavigableSubMap(TreeMap<K,V> m,
1240	>	boolean fromStart, K lo, boolean loInclusive,
1241	>	boolean toEnd,     K hi, boolean hiInclusive) {
1242	>	if (!fromStart && !toEnd) {
1243	>	if (m.compare(lo, hi) > 0)
1244	>	throw new IllegalArgumentException("fromKey > toKey");
1245	>	} else {
1246	>	if (!fromStart) // type check
1247	>	m.compare(lo, lo);
1248	>	if (!toEnd)
1249	>	m.compare(hi, hi);
1250	>	}
1251
1252	<	SubMap(K fromKey, K toKey) {
1253	<	if (compare(fromKey, toKey) > 0)
1254	<	throw new IllegalArgumentException("fromKey > toKey");
1255	<	this.fromKey = fromKey;
1256	<	this.toKey = toKey;
1252	>	this.m = m;
1253	>	this.fromStart = fromStart;
1254	>	this.lo = lo;
1255	>	this.loInclusive = loInclusive;
1256	>	this.toEnd = toEnd;
1257	>	this.hi = hi;
1258	>	this.hiInclusive = hiInclusive;
1259		}
1260
1261	<	SubMap(K key, boolean headMap) {
1262	<	compare(key, key); // Type-check key
1263	<
1264	<	if (headMap) {
1265	<	fromStart = true;
1266	<	toKey = key;
1267	<	} else {
1052	<	toEnd = true;
1053	<	fromKey = key;
1261	>	// internal utilities
1262	>
1263	>	final boolean tooLow(Object key) {
1264	>	if (!fromStart) {
1265	>	int c = m.compare(key, lo);
1266	>	if (c < 0 || (c == 0 && !loInclusive))
1267	>	return true;
1268		}
1269	+	return false;
1270		}
1271
1272	<	SubMap(boolean fromStart, K fromKey, boolean toEnd, K toKey) {
1273	<	this.fromStart = fromStart;
1274	<	this.fromKey= fromKey;
1275	<	this.toEnd = toEnd;
1276	<	this.toKey = toKey;
1272	>	final boolean tooHigh(Object key) {
1273	>	if (!toEnd) {
1274	>	int c = m.compare(key, hi);
1275	>	if (c > 0 || (c == 0 && !hiInclusive))
1276	>	return true;
1277	>	}
1278	>	return false;
1279	>	}
1280	>
1281	>	final boolean inRange(Object key) {
1282	>	return !tooLow(key) && !tooHigh(key);
1283	>	}
1284	>
1285	>	final boolean inClosedRange(Object key) {
1286	>	return (fromStart || m.compare(key, lo) >= 0)
1287	>	&& (toEnd || m.compare(hi, key) >= 0);
1288	>	}
1289	>
1290	>	final boolean inRange(Object key, boolean inclusive) {
1291	>	return inclusive ? inRange(key) : inClosedRange(key);
1292	>	}
1293	>
1294	>	/*
1295	>	* Absolute versions of relation operations.
1296	>	* Subclasses map to these using like-named "sub"
1297	>	* versions that invert senses for descending maps
1298	>	*/
1299	>
1300	>	final TreeMap.Entry<K,V> absLowest() {
1301	>	TreeMap.Entry<K,V> e =
1302	>	(fromStart ?  m.getFirstEntry() :
1303	>	(loInclusive ? m.getCeilingEntry(lo) :
1304	>	m.getHigherEntry(lo)));
1305	>	return (e == null || tooHigh(e.key)) ? null : e;
1306	>	}
1307	>
1308	>	final TreeMap.Entry<K,V> absHighest() {
1309	>	TreeMap.Entry<K,V> e =
1310	>	(toEnd ?  m.getLastEntry() :
1311	>	(hiInclusive ?  m.getFloorEntry(hi) :
1312	>	m.getLowerEntry(hi)));
1313	>	return (e == null || tooLow(e.key)) ? null : e;
1314	>	}
1315	>
1316	>	final TreeMap.Entry<K,V> absCeiling(K key) {
1317	>	if (tooLow(key))
1318	>	return absLowest();
1319	>	TreeMap.Entry<K,V> e = m.getCeilingEntry(key);
1320	>	return (e == null || tooHigh(e.key)) ? null : e;
1321	>	}
1322	>
1323	>	final TreeMap.Entry<K,V> absHigher(K key) {
1324	>	if (tooLow(key))
1325	>	return absLowest();
1326	>	TreeMap.Entry<K,V> e = m.getHigherEntry(key);
1327	>	return (e == null || tooHigh(e.key)) ? null : e;
1328		}
1329
1330	+	final TreeMap.Entry<K,V> absFloor(K key) {
1331	+	if (tooHigh(key))
1332	+	return absHighest();
1333	+	TreeMap.Entry<K,V> e = m.getFloorEntry(key);
1334	+	return (e == null || tooLow(e.key)) ? null : e;
1335	+	}
1336	+
1337	+	final TreeMap.Entry<K,V> absLower(K key) {
1338	+	if (tooHigh(key))
1339	+	return absHighest();
1340	+	TreeMap.Entry<K,V> e = m.getLowerEntry(key);
1341	+	return (e == null || tooLow(e.key)) ? null : e;
1342	+	}
1343	+
1344	+	/** Returns the absolute high fence for ascending traversal */
1345	+	final TreeMap.Entry<K,V> absHighFence() {
1346	+	return (toEnd ? null : (hiInclusive ?
1347	+	m.getHigherEntry(hi) :
1348	+	m.getCeilingEntry(hi)));
1349	+	}
1350	+
1351	+	/** Return the absolute low fence for descending traversal  */
1352	+	final TreeMap.Entry<K,V> absLowFence() {
1353	+	return (fromStart ? null : (loInclusive ?
1354	+	m.getLowerEntry(lo) :
1355	+	m.getFloorEntry(lo)));
1356	+	}
1357	+
1358	+	// Abstract methods defined in ascending vs descending classes
1359	+	// These relay to the appropriate absolute versions
1360	+
1361	+	abstract TreeMap.Entry<K,V> subLowest();
1362	+	abstract TreeMap.Entry<K,V> subHighest();
1363	+	abstract TreeMap.Entry<K,V> subCeiling(K key);
1364	+	abstract TreeMap.Entry<K,V> subHigher(K key);
1365	+	abstract TreeMap.Entry<K,V> subFloor(K key);
1366	+	abstract TreeMap.Entry<K,V> subLower(K key);
1367	+
1368	+	/** Returns ascending iterator from the perspective of this submap */
1369	+	abstract Iterator<K> keyIterator();
1370	+
1371	+	/** Returns descending iterator from the perspective of this submap */
1372	+	abstract Iterator<K> descendingKeyIterator();
1373	+
1374	+	// public methods
1375	+
1376		public boolean isEmpty() {
1377	<	return entrySet().isEmpty();
1377	>	return (fromStart && toEnd) ? m.isEmpty() : entrySet().isEmpty();
1378		}
1379
1380	<	public boolean containsKey(Object key) {
1381	<	return inRange((K) key) && TreeMap.this.containsKey(key);
1380	>	public int size() {
1381	>	return (fromStart && toEnd) ? m.size() : entrySet().size();
1382		}
1383
1384	<	public V get(Object key) {
1385	<	if (!inRange((K) key))
1074	<	return null;
1075	<	return TreeMap.this.get(key);
1384	>	public final boolean containsKey(Object key) {
1385	>	return inRange(key) && m.containsKey(key);
1386		}
1387
1388	<	public V put(K key, V value) {
1388	>	public final V put(K key, V value) {
1389		if (!inRange(key))
1390		throw new IllegalArgumentException("key out of range");
1391	<	return TreeMap.this.put(key, value);
1391	>	return m.put(key, value);
1392		}
1393
1394	<	public V remove(Object key) {
1395	<	if (!inRange((K) key))
1086	<	return null;
1087	<	return TreeMap.this.remove(key);
1394	>	public final V get(Object key) {
1395	>	return !inRange(key)? null :  m.get(key);
1396		}
1397
1398	<	public Comparator<? super K> comparator() {
1399	<	return comparator;
1398	>	public final V remove(Object key) {
1399	>	return !inRange(key)? null  : m.remove(key);
1400		}
1401
1402	<	public K firstKey() {
1403	<	TreeMap.Entry<K,V> e = fromStart ? getFirstEntry() : getCeilingEntry(fromKey);
1096	<	K first = key(e);
1097	<	if (!toEnd && compare(first, toKey) >= 0)
1098	<	throw new NoSuchElementException();
1099	<	return first;
1402	>	public final Map.Entry<K,V> ceilingEntry(K key) {
1403	>	return exportEntry(subCeiling(key));
1404		}
1405
1406	<	public K lastKey() {
1407	<	TreeMap.Entry<K,V> e = toEnd ? getLastEntry() : getLowerEntry(toKey);
1104	<	K last = key(e);
1105	<	if (!fromStart && compare(last, fromKey) < 0)
1106	<	throw new NoSuchElementException();
1107	<	return last;
1406	>	public final K ceilingKey(K key) {
1407	>	return keyOrNull(subCeiling(key));
1408		}
1409
1410	<	public Map.Entry<K,V> firstEntry() {
1411	<	TreeMap.Entry<K,V> e = fromStart ?
1112	<	getFirstEntry() : getCeilingEntry(fromKey);
1113	<	if (e == null || (!toEnd && compare(e.key, toKey) >= 0))
1114	<	return null;
1115	<	return e;
1410	>	public final Map.Entry<K,V> higherEntry(K key) {
1411	>	return exportEntry(subHigher(key));
1412		}
1413
1414	<	public Map.Entry<K,V> lastEntry() {
1415	<	TreeMap.Entry<K,V> e = toEnd ?
1120	<	getLastEntry() : getLowerEntry(toKey);
1121	<	if (e == null || (!fromStart && compare(e.key, fromKey) < 0))
1122	<	return null;
1123	<	return e;
1414	>	public final K higherKey(K key) {
1415	>	return keyOrNull(subHigher(key));
1416		}
1417
1418	<	public Map.Entry<K,V> pollFirstEntry() {
1419	<	TreeMap.Entry<K,V> e = fromStart ?
1128	<	getFirstEntry() : getCeilingEntry(fromKey);
1129	<	if (e == null || (!toEnd && compare(e.key, toKey) >= 0))
1130	<	return null;
1131	<	Map.Entry result = new AbstractMap.SimpleImmutableEntry(e);
1132	<	deleteEntry(e);
1133	<	return result;
1418	>	public final Map.Entry<K,V> floorEntry(K key) {
1419	>	return exportEntry(subFloor(key));
1420		}
1421
1422	<	public Map.Entry<K,V> pollLastEntry() {
1423	<	TreeMap.Entry<K,V> e = toEnd ?
1138	<	getLastEntry() : getLowerEntry(toKey);
1139	<	if (e == null || (!fromStart && compare(e.key, fromKey) < 0))
1140	<	return null;
1141	<	Map.Entry result = new AbstractMap.SimpleImmutableEntry(e);
1142	<	deleteEntry(e);
1143	<	return result;
1422	>	public final K floorKey(K key) {
1423	>	return keyOrNull(subFloor(key));
1424		}
1425
1426	<	private TreeMap.Entry<K,V> subceiling(K key) {
1427	<	TreeMap.Entry<K,V> e = (!fromStart && compare(key, fromKey) < 0)?
1148	<	getCeilingEntry(fromKey) : getCeilingEntry(key);
1149	<	if (e == null || (!toEnd && compare(e.key, toKey) >= 0))
1150	<	return null;
1151	<	return e;
1426	>	public final Map.Entry<K,V> lowerEntry(K key) {
1427	>	return exportEntry(subLower(key));
1428		}
1429
1430	<	public Map.Entry<K,V> ceilingEntry(K key) {
1431	<	TreeMap.Entry<K,V> e = subceiling(key);
1156	<	return e == null? null : new AbstractMap.SimpleImmutableEntry(e);
1430	>	public final K lowerKey(K key) {
1431	>	return keyOrNull(subLower(key));
1432		}
1433
1434	<	public K ceilingKey(K key) {
1435	<	TreeMap.Entry<K,V> e = subceiling(key);
1161	<	return e == null? null : e.key;
1434	>	public final K firstKey() {
1435	>	return key(subLowest());
1436		}
1437
1438	<
1439	<	private TreeMap.Entry<K,V> subhigher(K key) {
1166	<	TreeMap.Entry<K,V> e = (!fromStart && compare(key, fromKey) < 0)?
1167	<	getCeilingEntry(fromKey) : getHigherEntry(key);
1168	<	if (e == null || (!toEnd && compare(e.key, toKey) >= 0))
1169	<	return null;
1170	<	return e;
1438	>	public final K lastKey() {
1439	>	return key(subHighest());
1440		}
1441
1442	<	public Map.Entry<K,V> higherEntry(K key) {
1443	<	TreeMap.Entry<K,V> e = subhigher(key);
1175	<	return e == null? null : new AbstractMap.SimpleImmutableEntry(e);
1442	>	public final Map.Entry<K,V> firstEntry() {
1443	>	return exportEntry(subLowest());
1444		}
1445
1446	<	public K higherKey(K key) {
1447	<	TreeMap.Entry<K,V> e = subhigher(key);
1180	<	return e == null? null : e.key;
1446	>	public final Map.Entry<K,V> lastEntry() {
1447	>	return exportEntry(subHighest());
1448		}
1449
1450	<	private TreeMap.Entry<K,V> subfloor(K key) {
1451	<	TreeMap.Entry<K,V> e = (!toEnd && compare(key, toKey) >= 0)?
1452	<	getLowerEntry(toKey) : getFloorEntry(key);
1453	<	if (e == null || (!fromStart && compare(e.key, fromKey) < 0))
1454	<	return null;
1455	<	return e;
1450	>	public final Map.Entry<K,V> pollFirstEntry() {
1451	>	TreeMap.Entry<K,V> e = subLowest();
1452	>	Map.Entry<K,V> result = exportEntry(e);
1453	>	if (e != null)
1454	>	m.deleteEntry(e);
1455	>	return result;
1456		}
1457
1458	<	public Map.Entry<K,V> floorEntry(K key) {
1459	<	TreeMap.Entry<K,V> e = subfloor(key);
1460	<	return e == null? null : new AbstractMap.SimpleImmutableEntry(e);
1458	>	public final Map.Entry<K,V> pollLastEntry() {
1459	>	TreeMap.Entry<K,V> e = subHighest();
1460	>	Map.Entry<K,V> result = exportEntry(e);
1461	>	if (e != null)
1462	>	m.deleteEntry(e);
1463	>	return result;
1464		}
1465
1466	<	public K floorKey(K key) {
1467	<	TreeMap.Entry<K,V> e = subfloor(key);
1468	<	return e == null? null : e.key;
1466	>	// Views
1467	>	transient NavigableMap<K,V> descendingMapView = null;
1468	>	transient EntrySetView entrySetView = null;
1469	>	transient KeySet<K> navigableKeySetView = null;
1470	>
1471	>	public final NavigableSet<K> navigableKeySet() {
1472	>	KeySet<K> nksv = navigableKeySetView;
1473	>	return (nksv != null) ? nksv :
1474	>	(navigableKeySetView = new TreeMap.KeySet(this));
1475		}
1476
1477	<	private TreeMap.Entry<K,V> sublower(K key) {
1478	<	TreeMap.Entry<K,V> e = (!toEnd && compare(key, toKey) >= 0)?
1203	<	getLowerEntry(toKey) :  getLowerEntry(key);
1204	<	if (e == null || (!fromStart && compare(e.key, fromKey) < 0))
1205	<	return null;
1206	<	return e;
1477	>	public final Set<K> keySet() {
1478	>	return navigableKeySet();
1479		}
1480
1481	<	public Map.Entry<K,V> lowerEntry(K key) {
1482	<	TreeMap.Entry<K,V> e = sublower(key);
1211	<	return e == null? null : new AbstractMap.SimpleImmutableEntry(e);
1481	>	public NavigableSet<K> descendingKeySet() {
1482	>	return descendingMap().navigableKeySet();
1483		}
1484
1485	<	public K lowerKey(K key) {
1486	<	TreeMap.Entry<K,V> e = sublower(key);
1216	<	return e == null? null : e.key;
1485	>	public final SortedMap<K,V> subMap(K fromKey, K toKey) {
1486	>	return subMap(fromKey, true, toKey, false);
1487		}
1488
1489	<	private transient Set<Map.Entry<K,V>> entrySet = null;
1489	>	public final SortedMap<K,V> headMap(K toKey) {
1490	>	return headMap(toKey, false);
1491	>	}
1492
1493	<	public Set<Map.Entry<K,V>> entrySet() {
1494	<	Set<Map.Entry<K,V>> es = entrySet;
1223	<	return (es != null)? es : (entrySet = new EntrySetView());
1493	>	public final SortedMap<K,V> tailMap(K fromKey) {
1494	>	return tailMap(fromKey, true);
1495		}
1496
1497	<	private class EntrySetView extends AbstractSet<Map.Entry<K,V>> {
1497	>	// View classes
1498	>
1499	>	abstract class EntrySetView extends AbstractSet<Map.Entry<K,V>> {
1500		private transient int size = -1, sizeModCount;
1501
1502		public int size() {
1503	<	if (size == -1 || sizeModCount != TreeMap.this.modCount) {
1504	<	size = 0;  sizeModCount = TreeMap.this.modCount;
1503	>	if (fromStart && toEnd)
1504	>	return m.size();
1505	>	if (size == -1 || sizeModCount != m.modCount) {
1506	>	sizeModCount = m.modCount;
1507	>	size = 0;
1508		Iterator i = iterator();
1509		while (i.hasNext()) {
1510		size++;
#	Line 1239 | Line 1515 | public class TreeMap<K,V>
1515		}
1516
1517		public boolean isEmpty() {
1518	<	return !iterator().hasNext();
1518	>	TreeMap.Entry<K,V> n = absLowest();
1519	>	return n == null || tooHigh(n.key);
1520		}
1521
1522		public boolean contains(Object o) {
#	Line 1249 | Line 1526 | public class TreeMap<K,V>
1526		K key = entry.getKey();
1527		if (!inRange(key))
1528		return false;
1529	<	TreeMap.Entry node = getEntry(key);
1529	>	TreeMap.Entry node = m.getEntry(key);
1530		return node != null &&
1531	<	valEquals(node.getValue(), entry.getValue());
1531	>	valEquals(node.getValue(), entry.getValue());
1532		}
1533
1534		public boolean remove(Object o) {
#	Line 1261 | Line 1538 | public class TreeMap<K,V>
1538		K key = entry.getKey();
1539		if (!inRange(key))
1540		return false;
1541	<	TreeMap.Entry<K,V> node = getEntry(key);
1541	>	TreeMap.Entry<K,V> node = m.getEntry(key);
1542		if (node!=null && valEquals(node.getValue(),entry.getValue())){
1543	<	deleteEntry(node);
1543	>	m.deleteEntry(node);
1544		return true;
1545		}
1546		return false;
1547		}
1271	–
1272	–	public Iterator<Map.Entry<K,V>> iterator() {
1273	–	return new SubMapEntryIterator(
1274	–	(fromStart ? getFirstEntry() : getCeilingEntry(fromKey)),
1275	–	(toEnd     ? null            : getCeilingEntry(toKey)));
1276	–	}
1548		}
1549
1550	<	private transient Set<Map.Entry<K,V>> descendingEntrySetView = null;
1551	<	private transient Set<K> descendingKeySetView = null;
1552	<
1553	<	public Set<Map.Entry<K,V>> descendingEntrySet() {
1554	<	Set<Map.Entry<K,V>> es = descendingEntrySetView;
1555	<	return (es != null) ? es :
1556	<	(descendingEntrySetView = new DescendingEntrySetView());
1557	<	}
1287	<
1288	<	public Set<K> descendingKeySet() {
1289	<	Set<K> ks = descendingKeySetView;
1290	<	return (ks != null) ? ks :
1291	<	(descendingKeySetView = new DescendingKeySetView());
1292	<	}
1550	>	/**
1551	>	* Iterators for SubMaps
1552	>	*/
1553	>	abstract class SubMapIterator<T> implements Iterator<T> {
1554	>	TreeMap.Entry<K,V> lastReturned;
1555	>	TreeMap.Entry<K,V> next;
1556	>	final Object fenceKey;
1557	>	int expectedModCount;
1558
1559	<	private class DescendingEntrySetView extends EntrySetView {
1560	<	public Iterator<Map.Entry<K,V>> iterator() {
1561	<	return new DescendingSubMapEntryIterator
1562	<	((toEnd     ? getLastEntry()  : getLowerEntry(toKey)),
1563	<	(fromStart ? null            : getLowerEntry(fromKey)));
1559	>	SubMapIterator(TreeMap.Entry<K,V> first,
1560	>	TreeMap.Entry<K,V> fence) {
1561	>	expectedModCount = m.modCount;
1562	>	lastReturned = null;
1563	>	next = first;
1564	>	fenceKey = fence == null ? UNBOUNDED : fence.key;
1565		}
1300	–	}
1566
1567	<	private class DescendingKeySetView extends AbstractSet<K> {
1568	<	public Iterator<K> iterator() {
1304	<	return new Iterator<K>() {
1305	<	private Iterator<Entry<K,V>> i = descendingEntrySet().iterator();
1306	<
1307	<	public boolean hasNext() { return i.hasNext(); }
1308	<	public K next() { return i.next().getKey(); }
1309	<	public void remove() { i.remove(); }
1310	<	};
1567	>	public final boolean hasNext() {
1568	>	return next != null && next.key != fenceKey;
1569		}
1570
1571	<	public int size() {
1572	<	return SubMap.this.size();
1571	>	final TreeMap.Entry<K,V> nextEntry() {
1572	>	TreeMap.Entry<K,V> e = lastReturned = next;
1573	>	if (e == null || e.key == fenceKey)
1574	>	throw new NoSuchElementException();
1575	>	if (m.modCount != expectedModCount)
1576	>	throw new ConcurrentModificationException();
1577	>	next = successor(e);
1578	>	return e;
1579		}
1580
1581	<	public boolean contains(Object k) {
1582	<	return SubMap.this.containsKey(k);
1581	>	final TreeMap.Entry<K,V> prevEntry() {
1582	>	TreeMap.Entry<K,V> e = lastReturned = next;
1583	>	if (e == null || e.key == fenceKey)
1584	>	throw new NoSuchElementException();
1585	>	if (m.modCount != expectedModCount)
1586	>	throw new ConcurrentModificationException();
1587	>	next = predecessor(e);
1588	>	return e;
1589		}
1320	–	}
1590
1591	<	public NavigableMap<K,V> navigableSubMap(K fromKey, K toKey) {
1592	<	if (!inRange2(fromKey))
1593	<	throw new IllegalArgumentException("fromKey out of range");
1594	<	if (!inRange2(toKey))
1595	<	throw new IllegalArgumentException("toKey out of range");
1596	<	return new SubMap(fromKey, toKey);
1597	<	}
1591	>	final void removeAscending() {
1592	>	if (lastReturned == null)
1593	>	throw new IllegalStateException();
1594	>	if (m.modCount != expectedModCount)
1595	>	throw new ConcurrentModificationException();
1596	>	// deleted entries are replaced by their successors
1597	>	if (lastReturned.left != null && lastReturned.right != null)
1598	>	next = lastReturned;
1599	>	m.deleteEntry(lastReturned);
1600	>	lastReturned = null;
1601	>	expectedModCount = m.modCount;
1602	>	}
1603
1604	<	public NavigableMap<K,V> navigableHeadMap(K toKey) {
1605	<	if (!inRange2(toKey))
1606	<	throw new IllegalArgumentException("toKey out of range");
1607	<	return new SubMap(fromStart, fromKey, false, toKey);
1608	<	}
1604	>	final void removeDescending() {
1605	>	if (lastReturned == null)
1606	>	throw new IllegalStateException();
1607	>	if (m.modCount != expectedModCount)
1608	>	throw new ConcurrentModificationException();
1609	>	m.deleteEntry(lastReturned);
1610	>	lastReturned = null;
1611	>	expectedModCount = m.modCount;
1612	>	}
1613
1336	–	public NavigableMap<K,V> navigableTailMap(K fromKey) {
1337	–	if (!inRange2(fromKey))
1338	–	throw new IllegalArgumentException("fromKey out of range");
1339	–	return new SubMap(false, fromKey, toEnd, toKey);
1614		}
1615
1616	<	public SortedMap<K,V> subMap(K fromKey, K toKey) {
1617	<	return navigableSubMap(fromKey, toKey);
1616	>	final class SubMapEntryIterator extends SubMapIterator<Map.Entry<K,V>> {
1617	>	SubMapEntryIterator(TreeMap.Entry<K,V> first,
1618	>	TreeMap.Entry<K,V> fence) {
1619	>	super(first, fence);
1620	>	}
1621	>	public Map.Entry<K,V> next() {
1622	>	return nextEntry();
1623	>	}
1624	>	public void remove() {
1625	>	removeAscending();
1626	>	}
1627		}
1628
1629	<	public SortedMap<K,V> headMap(K toKey) {
1630	<	return navigableHeadMap(toKey);
1629	>	final class SubMapKeyIterator extends SubMapIterator<K> {
1630	>	SubMapKeyIterator(TreeMap.Entry<K,V> first,
1631	>	TreeMap.Entry<K,V> fence) {
1632	>	super(first, fence);
1633	>	}
1634	>	public K next() {
1635	>	return nextEntry().key;
1636	>	}
1637	>	public void remove() {
1638	>	removeAscending();
1639	>	}
1640		}
1641
1642	<	public SortedMap<K,V> tailMap(K fromKey) {
1643	<	return navigableTailMap(fromKey);
1644	<	}
1642	>	final class DescendingSubMapEntryIterator extends SubMapIterator<Map.Entry<K,V>> {
1643	>	DescendingSubMapEntryIterator(TreeMap.Entry<K,V> last,
1644	>	TreeMap.Entry<K,V> fence) {
1645	>	super(last, fence);
1646	>	}
1647
1648	<	private boolean inRange(K key) {
1649	<	return (fromStart || compare(key, fromKey) >= 0) &&
1650	<	(toEnd     || compare(key, toKey)   <  0);
1648	>	public Map.Entry<K,V> next() {
1649	>	return prevEntry();
1650	>	}
1651	>	public void remove() {
1652	>	removeDescending();
1653	>	}
1654		}
1655
1656	<	// This form allows the high endpoint (as well as all legit keys)
1657	<	private boolean inRange2(K key) {
1658	<	return (fromStart || compare(key, fromKey) >= 0) &&
1659	<	(toEnd     || compare(key, toKey)   <= 0);
1656	>	final class DescendingSubMapKeyIterator extends SubMapIterator<K> {
1657	>	DescendingSubMapKeyIterator(TreeMap.Entry<K,V> last,
1658	>	TreeMap.Entry<K,V> fence) {
1659	>	super(last, fence);
1660	>	}
1661	>	public K next() {
1662	>	return prevEntry().key;
1663	>	}
1664	>	public void remove() {
1665	>	removeDescending();
1666	>	}
1667		}
1668		}
1669
1670		/**
1671	<	* TreeMap Iterator.
1671	>	* @serial include
1672		*/
1673	<	abstract class PrivateEntryIterator<T> implements Iterator<T> {
1674	<	int expectedModCount = TreeMap.this.modCount;
1371	<	Entry<K,V> lastReturned = null;
1372	<	Entry<K,V> next;
1673	>	static final class AscendingSubMap<K,V> extends NavigableSubMap<K,V> {
1674	>	private static final long serialVersionUID = 912986545866124060L;
1675
1676	<	PrivateEntryIterator(Entry<K,V> first) {
1677	<	next = first;
1676	>	AscendingSubMap(TreeMap<K,V> m,
1677	>	boolean fromStart, K lo, boolean loInclusive,
1678	>	boolean toEnd,     K hi, boolean hiInclusive) {
1679	>	super(m, fromStart, lo, loInclusive, toEnd, hi, hiInclusive);
1680		}
1681
1682	<	public boolean hasNext() {
1683	<	return next != null;
1682	>	public Comparator<? super K> comparator() {
1683	>	return m.comparator();
1684		}
1685
1686	<	Entry<K,V> nextEntry() {
1687	<	if (next == null)
1688	<	throw new NoSuchElementException();
1689	<	if (modCount != expectedModCount)
1690	<	throw new ConcurrentModificationException();
1691	<	lastReturned = next;
1692	<	next = successor(next);
1693	<	return lastReturned;
1686	>	public NavigableMap<K,V> subMap(K fromKey, boolean fromInclusive,
1687	>	K toKey,   boolean toInclusive) {
1688	>	if (!inRange(fromKey, fromInclusive))
1689	>	throw new IllegalArgumentException("fromKey out of range");
1690	>	if (!inRange(toKey, toInclusive))
1691	>	throw new IllegalArgumentException("toKey out of range");
1692	>	return new AscendingSubMap(m,
1693	>	false, fromKey, fromInclusive,
1694	>	false, toKey,   toInclusive);
1695		}
1696
1697	<	public void remove() {
1698	<	if (lastReturned == null)
1699	<	throw new IllegalStateException();
1700	<	if (modCount != expectedModCount)
1701	<	throw new ConcurrentModificationException();
1702	<	if (lastReturned.left != null && lastReturned.right != null)
1398	<	next = lastReturned;
1399	<	deleteEntry(lastReturned);
1400	<	expectedModCount++;
1401	<	lastReturned = null;
1697	>	public NavigableMap<K,V> headMap(K toKey, boolean inclusive) {
1698	>	if (!inRange(toKey, inclusive))
1699	>	throw new IllegalArgumentException("toKey out of range");
1700	>	return new AscendingSubMap(m,
1701	>	fromStart, lo,    loInclusive,
1702	>	false,     toKey, inclusive);
1703		}
1403	–	}
1704
1705	<	class EntryIterator extends PrivateEntryIterator<Map.Entry<K,V>> {
1706	<	EntryIterator(Entry<K,V> first) {
1707	<	super(first);
1708	<	}
1709	<	public Map.Entry<K,V> next() {
1710	<	return nextEntry();
1705	>	public NavigableMap<K,V> tailMap(K fromKey, boolean inclusive){
1706	>	if (!inRange(fromKey, inclusive))
1707	>	throw new IllegalArgumentException("fromKey out of range");
1708	>	return new AscendingSubMap(m,
1709	>	false, fromKey, inclusive,
1710	>	toEnd, hi,      hiInclusive);
1711		}
1412	–	}
1712
1713	<	class KeyIterator extends PrivateEntryIterator<K> {
1714	<	KeyIterator(Entry<K,V> first) {
1715	<	super(first);
1713	>	public NavigableMap<K,V> descendingMap() {
1714	>	NavigableMap<K,V> mv = descendingMapView;
1715	>	return (mv != null) ? mv :
1716	>	(descendingMapView =
1717	>	new DescendingSubMap(m,
1718	>	fromStart, lo, loInclusive,
1719	>	toEnd,     hi, hiInclusive));
1720		}
1418	–	public K next() {
1419	–	return nextEntry().key;
1420	–	}
1421	–	}
1721
1722	<	class ValueIterator extends PrivateEntryIterator<V> {
1723	<	ValueIterator(Entry<K,V> first) {
1425	<	super(first);
1426	<	}
1427	<	public V next() {
1428	<	return nextEntry().value;
1722	>	Iterator<K> keyIterator() {
1723	>	return new SubMapKeyIterator(absLowest(), absHighFence());
1724		}
1430	–	}
1431	–
1432	–	class SubMapEntryIterator extends PrivateEntryIterator<Map.Entry<K,V>> {
1433	–	private final K firstExcludedKey;
1725
1726	<	SubMapEntryIterator(Entry<K,V> first, Entry<K,V> firstExcluded) {
1727	<	super(first);
1437	<	firstExcludedKey = (firstExcluded == null
1438	<	? null
1439	<	: firstExcluded.key);
1726	>	Iterator<K> descendingKeyIterator() {
1727	>	return new DescendingSubMapKeyIterator(absHighest(), absLowFence());
1728		}
1729
1730	<	public boolean hasNext() {
1731	<	return next != null && next.key != firstExcludedKey;
1730	>	final class AscendingEntrySetView extends EntrySetView {
1731	>	public Iterator<Map.Entry<K,V>> iterator() {
1732	>	return new SubMapEntryIterator(absLowest(), absHighFence());
1733	>	}
1734		}
1735
1736	<	public Map.Entry<K,V> next() {
1737	<	if (next == null || next.key == firstExcludedKey)
1738	<	throw new NoSuchElementException();
1449	<	return nextEntry();
1736	>	public Set<Map.Entry<K,V>> entrySet() {
1737	>	EntrySetView es = entrySetView;
1738	>	return (es != null) ? es : new AscendingEntrySetView();
1739		}
1740	+
1741	+	TreeMap.Entry<K,V> subLowest()       { return absLowest(); }
1742	+	TreeMap.Entry<K,V> subHighest()      { return absHighest(); }
1743	+	TreeMap.Entry<K,V> subCeiling(K key) { return absCeiling(key); }
1744	+	TreeMap.Entry<K,V> subHigher(K key)  { return absHigher(key); }
1745	+	TreeMap.Entry<K,V> subFloor(K key)   { return absFloor(key); }
1746	+	TreeMap.Entry<K,V> subLower(K key)   { return absLower(key); }
1747		}
1748
1749		/**
1750	<	* Base for Descending Iterators.
1750	>	* @serial include
1751		*/
1752	<	abstract class DescendingPrivateEntryIterator<T> extends PrivateEntryIterator<T> {
1753	<	DescendingPrivateEntryIterator(Entry<K,V> first) {
1754	<	super(first);
1752	>	static final class DescendingSubMap<K,V>  extends NavigableSubMap<K,V> {
1753	>	private static final long serialVersionUID = 912986545866120460L;
1754	>	DescendingSubMap(TreeMap<K,V> m,
1755	>	boolean fromStart, K lo, boolean loInclusive,
1756	>	boolean toEnd,     K hi, boolean hiInclusive) {
1757	>	super(m, fromStart, lo, loInclusive, toEnd, hi, hiInclusive);
1758		}
1759
1760	<	Entry<K,V> nextEntry() {
1761	<	if (next == null)
1463	<	throw new NoSuchElementException();
1464	<	if (modCount != expectedModCount)
1465	<	throw new ConcurrentModificationException();
1466	<	lastReturned = next;
1467	<	next = predecessor(next);
1468	<	return lastReturned;
1469	<	}
1470	<	}
1760	>	private final Comparator<? super K> reverseComparator =
1761	>	Collections.reverseOrder(m.comparator);
1762
1763	<	class DescendingEntryIterator extends DescendingPrivateEntryIterator<Map.Entry<K,V>> {
1764	<	DescendingEntryIterator(Entry<K,V> first) {
1474	<	super(first);
1763	>	public Comparator<? super K> comparator() {
1764	>	return reverseComparator;
1765		}
1766	<	public Map.Entry<K,V> next() {
1767	<	return nextEntry();
1766	>
1767	>	public NavigableMap<K,V> subMap(K fromKey, boolean fromInclusive,
1768	>	K toKey,   boolean toInclusive) {
1769	>	if (!inRange(fromKey, fromInclusive))
1770	>	throw new IllegalArgumentException("fromKey out of range");
1771	>	if (!inRange(toKey, toInclusive))
1772	>	throw new IllegalArgumentException("toKey out of range");
1773	>	return new DescendingSubMap(m,
1774	>	false, toKey,   toInclusive,
1775	>	false, fromKey, fromInclusive);
1776		}
1479	–	}
1777
1778	<	class DescendingKeyIterator extends DescendingPrivateEntryIterator<K> {
1779	<	DescendingKeyIterator(Entry<K,V> first) {
1780	<	super(first);
1778	>	public NavigableMap<K,V> headMap(K toKey, boolean inclusive) {
1779	>	if (!inRange(toKey, inclusive))
1780	>	throw new IllegalArgumentException("toKey out of range");
1781	>	return new DescendingSubMap(m,
1782	>	false, toKey, inclusive,
1783	>	toEnd, hi,    hiInclusive);
1784		}
1785	<	public K next() {
1786	<	return nextEntry().key;
1785	>
1786	>	public NavigableMap<K,V> tailMap(K fromKey, boolean inclusive){
1787	>	if (!inRange(fromKey, inclusive))
1788	>	throw new IllegalArgumentException("fromKey out of range");
1789	>	return new DescendingSubMap(m,
1790	>	fromStart, lo, loInclusive,
1791	>	false, fromKey, inclusive);
1792		}
1488	–	}
1793
1794	+	public NavigableMap<K,V> descendingMap() {
1795	+	NavigableMap<K,V> mv = descendingMapView;
1796	+	return (mv != null) ? mv :
1797	+	(descendingMapView =
1798	+	new AscendingSubMap(m,
1799	+	fromStart, lo, loInclusive,
1800	+	toEnd,     hi, hiInclusive));
1801	+	}
1802
1803	<	class DescendingSubMapEntryIterator extends DescendingPrivateEntryIterator<Map.Entry<K,V>> {
1804	<	private final K lastExcludedKey;
1803	>	Iterator<K> keyIterator() {
1804	>	return new DescendingSubMapKeyIterator(absHighest(), absLowFence());
1805	>	}
1806
1807	<	DescendingSubMapEntryIterator(Entry<K,V> last, Entry<K,V> lastExcluded) {
1808	<	super(last);
1496	<	lastExcludedKey = (lastExcluded == null
1497	<	? null
1498	<	: lastExcluded.key);
1807	>	Iterator<K> descendingKeyIterator() {
1808	>	return new SubMapKeyIterator(absLowest(), absHighFence());
1809		}
1810
1811	<	public boolean hasNext() {
1812	<	return next != null && next.key != lastExcludedKey;
1811	>	final class DescendingEntrySetView extends EntrySetView {
1812	>	public Iterator<Map.Entry<K,V>> iterator() {
1813	>	return new DescendingSubMapEntryIterator(absHighest(), absLowFence());
1814	>	}
1815		}
1816
1817	<	public Map.Entry<K,V> next() {
1818	<	if (next == null || next.key == lastExcludedKey)
1819	<	throw new NoSuchElementException();
1508	<	return nextEntry();
1817	>	public Set<Map.Entry<K,V>> entrySet() {
1818	>	EntrySetView es = entrySetView;
1819	>	return (es != null) ? es : new DescendingEntrySetView();
1820		}
1821
1822	+	TreeMap.Entry<K,V> subLowest()       { return absHighest(); }
1823	+	TreeMap.Entry<K,V> subHighest()      { return absLowest(); }
1824	+	TreeMap.Entry<K,V> subCeiling(K key) { return absFloor(key); }
1825	+	TreeMap.Entry<K,V> subHigher(K key)  { return absLower(key); }
1826	+	TreeMap.Entry<K,V> subFloor(K key)   { return absCeiling(key); }
1827	+	TreeMap.Entry<K,V> subLower(K key)   { return absHigher(key); }
1828		}
1829
1830		/**
1831	<	* Compares two keys using the correct comparison method for this TreeMap.
1831	>	* This class exists solely for the sake of serialization
1832	>	* compatibility with previous releases of TreeMap that did not
1833	>	* support NavigableMap.  It translates an old-version SubMap into
1834	>	* a new-version AscendingSubMap. This class is never otherwise
1835	>	* used.
1836	>	*
1837	>	* @serial include
1838		*/
1839	<	private int compare(K k1, K k2) {
1840	<	return comparator==null ? ((Comparable<? super K>)k1).compareTo(k2)
1841	<	: comparator.compare(k1, k2);
1839	>	private class SubMap extends AbstractMap<K,V>
1840	>	implements SortedMap<K,V>, java.io.Serializable {
1841	>	private static final long serialVersionUID = -6520786458950516097L;
1842	>	private boolean fromStart = false, toEnd = false;
1843	>	private K fromKey, toKey;
1844	>	private Object readResolve() {
1845	>	return new AscendingSubMap(TreeMap.this,
1846	>	fromStart, fromKey, true,
1847	>	toEnd, toKey, false);
1848	>	}
1849	>	public Set<Map.Entry<K,V>> entrySet() { throw new InternalError(); }
1850	>	public K lastKey() { throw new InternalError(); }
1851	>	public K firstKey() { throw new InternalError(); }
1852	>	public SortedMap<K,V> subMap(K fromKey, K toKey) { throw new InternalError(); }
1853	>	public SortedMap<K,V> headMap(K toKey) { throw new InternalError(); }
1854	>	public SortedMap<K,V> tailMap(K fromKey) { throw new InternalError(); }
1855	>	public Comparator<? super K> comparator() { throw new InternalError(); }
1856		}
1857
1858	<	/**
1859	<	* Test two values  for equality.  Differs from o1.equals(o2) only in
1523	<	* that it copes with <tt>null</tt> o1 properly.
1524	<	*/
1525	<	private static boolean valEquals(Object o1, Object o2) {
1526	<	return (o1==null ? o2==null : o1.equals(o2));
1527	<	}
1858	>
1859	>	// Red-black mechanics
1860
1861		private static final boolean RED   = false;
1862		private static final boolean BLACK = true;
#	Line 1534 | Line 1866 | public class TreeMap<K,V>
1866		* user (see Map.Entry).
1867		*/
1868
1869	<	static class Entry<K,V> implements Map.Entry<K,V> {
1869	>	static final class Entry<K,V> implements Map.Entry<K,V> {
1870		K key;
1871		V value;
1872		Entry<K,V> left = null;
#	Line 1586 | Line 1918 | public class TreeMap<K,V>
1918		public boolean equals(Object o) {
1919		if (!(o instanceof Map.Entry))
1920		return false;
1921	<	Map.Entry e = (Map.Entry)o;
1921	>	Map.Entry<?,?> e = (Map.Entry<?,?>)o;
1922
1923		return valEquals(key,e.getKey()) && valEquals(value,e.getValue());
1924		}
#	Line 1606 | Line 1938 | public class TreeMap<K,V>
1938		* Returns the first Entry in the TreeMap (according to the TreeMap's
1939		* key-sort function).  Returns null if the TreeMap is empty.
1940		*/
1941	<	private Entry<K,V> getFirstEntry() {
1941	>	final Entry<K,V> getFirstEntry() {
1942		Entry<K,V> p = root;
1943		if (p != null)
1944		while (p.left != null)
#	Line 1618 | Line 1950 | public class TreeMap<K,V>
1950		* Returns the last Entry in the TreeMap (according to the TreeMap's
1951		* key-sort function).  Returns null if the TreeMap is empty.
1952		*/
1953	<	private Entry<K,V> getLastEntry() {
1953	>	final Entry<K,V> getLastEntry() {
1954		Entry<K,V> p = root;
1955		if (p != null)
1956		while (p.right != null)
#	Line 1629 | Line 1961 | public class TreeMap<K,V>
1961		/**
1962		* Returns the successor of the specified Entry, or null if no such.
1963		*/
1964	<	private Entry<K,V> successor(Entry<K,V> t) {
1964	>	static <K,V> TreeMap.Entry<K,V> successor(Entry<K,V> t) {
1965		if (t == null)
1966		return null;
1967		else if (t.right != null) {
#	Line 1651 | Line 1983 | public class TreeMap<K,V>
1983		/**
1984		* Returns the predecessor of the specified Entry, or null if no such.
1985		*/
1986	<	private Entry<K,V> predecessor(Entry<K,V> t) {
1986	>	static <K,V> Entry<K,V> predecessor(Entry<K,V> t) {
1987		if (t == null)
1988		return null;
1989		else if (t.left != null) {
#	Line 1701 | Line 2033 | public class TreeMap<K,V>
2033		return (p == null) ? null: p.right;
2034		}
2035
2036	<	/** From CLR **/
2036	>	/** From CLR */
2037		private void rotateLeft(Entry<K,V> p) {
2038	<	Entry<K,V> r = p.right;
2039	<	p.right = r.left;
2040	<	if (r.left != null)
2041	<	r.left.parent = p;
2042	<	r.parent = p.parent;
2043	<	if (p.parent == null)
2044	<	root = r;
2045	<	else if (p.parent.left == p)
2046	<	p.parent.left = r;
2047	<	else
2048	<	p.parent.right = r;
2049	<	r.left = p;
2050	<	p.parent = r;
2038	>	if (p != null) {
2039	>	Entry<K,V> r = p.right;
2040	>	p.right = r.left;
2041	>	if (r.left != null)
2042	>	r.left.parent = p;
2043	>	r.parent = p.parent;
2044	>	if (p.parent == null)
2045	>	root = r;
2046	>	else if (p.parent.left == p)
2047	>	p.parent.left = r;
2048	>	else
2049	>	p.parent.right = r;
2050	>	r.left = p;
2051	>	p.parent = r;
2052	>	}
2053		}
2054
2055	<	/** From CLR **/
2055	>	/** From CLR */
2056		private void rotateRight(Entry<K,V> p) {
2057	<	Entry<K,V> l = p.left;
2058	<	p.left = l.right;
2059	<	if (l.right != null) l.right.parent = p;
2060	<	l.parent = p.parent;
2061	<	if (p.parent == null)
2062	<	root = l;
2063	<	else if (p.parent.right == p)
2064	<	p.parent.right = l;
2065	<	else p.parent.left = l;
2066	<	l.right = p;
2067	<	p.parent = l;
2057	>	if (p != null) {
2058	>	Entry<K,V> l = p.left;
2059	>	p.left = l.right;
2060	>	if (l.right != null) l.right.parent = p;
2061	>	l.parent = p.parent;
2062	>	if (p.parent == null)
2063	>	root = l;
2064	>	else if (p.parent.right == p)
2065	>	p.parent.right = l;
2066	>	else p.parent.left = l;
2067	>	l.right = p;
2068	>	p.parent = l;
2069	>	}
2070		}
2071
2072	<
1737	<	/** From CLR **/
2072	>	/** From CLR */
2073		private void fixAfterInsertion(Entry<K,V> x) {
2074		x.color = RED;
2075
#	Line 1753 | Line 2088 | public class TreeMap<K,V>
2088		}
2089		setColor(parentOf(x), BLACK);
2090		setColor(parentOf(parentOf(x)), RED);
2091	<	if (parentOf(parentOf(x)) != null)
1757	<	rotateRight(parentOf(parentOf(x)));
2091	>	rotateRight(parentOf(parentOf(x)));
2092		}
2093		} else {
2094		Entry<K,V> y = leftOf(parentOf(parentOf(x)));
#	Line 1768 | Line 2102 | public class TreeMap<K,V>
2102		x = parentOf(x);
2103		rotateRight(x);
2104		}
2105	<	setColor(parentOf(x),  BLACK);
2105	>	setColor(parentOf(x), BLACK);
2106		setColor(parentOf(parentOf(x)), RED);
2107	<	if (parentOf(parentOf(x)) != null)
1774	<	rotateLeft(parentOf(parentOf(x)));
2107	>	rotateLeft(parentOf(parentOf(x)));
2108		}
2109		}
2110		}
#	Line 1781 | Line 2114 | public class TreeMap<K,V>
2114		/**
2115		* Delete node p, and then rebalance the tree.
2116		*/
1784	–
2117		private void deleteEntry(Entry<K,V> p) {
2118	<	decrementSize();
2118	>	modCount++;
2119	>	size--;
2120
2121		// If strictly internal, copy successor's element to p and then make p
2122		// point to successor.
#	Line 1829 | Line 2162 | public class TreeMap<K,V>
2162		}
2163		}
2164
2165	<	/** From CLR **/
2165	>	/** From CLR */
2166		private void fixAfterDeletion(Entry<K,V> x) {
2167		while (x != root && colorOf(x) == BLACK) {
2168		if (x == leftOf(parentOf(x))) {
#	Line 1844 | Line 2177 | public class TreeMap<K,V>
2177
2178		if (colorOf(leftOf(sib))  == BLACK &&
2179		colorOf(rightOf(sib)) == BLACK) {
2180	<	setColor(sib,  RED);
2180	>	setColor(sib, RED);
2181		x = parentOf(x);
2182		} else {
2183		if (colorOf(rightOf(sib)) == BLACK) {
#	Line 1871 | Line 2204 | public class TreeMap<K,V>
2204
2205		if (colorOf(rightOf(sib)) == BLACK &&
2206		colorOf(leftOf(sib)) == BLACK) {
2207	<	setColor(sib,  RED);
2207	>	setColor(sib, RED);
2208		x = parentOf(x);
2209		} else {
2210		if (colorOf(leftOf(sib)) == BLACK) {
#	Line 1922 | Line 2255 | public class TreeMap<K,V>
2255		}
2256		}
2257
1925	–
1926	–
2258		/**
2259		* Reconstitute the <tt>TreeMap</tt> instance from a stream (i.e.,
2260		* deserialize it).
#	Line 1939 | Line 2270 | public class TreeMap<K,V>
2270		buildFromSorted(size, null, s, null);
2271		}
2272
2273	<	/** Intended to be called only from TreeSet.readObject **/
2273	>	/** Intended to be called only from TreeSet.readObject */
2274		void readTreeSet(int size, java.io.ObjectInputStream s, V defaultVal)
2275		throws java.io.IOException, ClassNotFoundException {
2276		buildFromSorted(size, null, s, defaultVal);
2277		}
2278
2279	<	/** Intended to be called only from TreeSet.addAll **/
2279	>	/** Intended to be called only from TreeSet.addAll */
2280		void addAllForTreeSet(SortedSet<? extends K> set, V defaultVal) {
2281		try {
2282		buildFromSorted(set.size(), set.iterator(), null, defaultVal);
#	Line 1985 | Line 2316 | public class TreeMap<K,V>
2316		* @throws ClassNotFoundException propagated from readObject.
2317		*         This cannot occur if str is null.
2318		*/
2319	<	private
2320	<	void buildFromSorted(int size, Iterator it,
2321	<	java.io.ObjectInputStream str,
1991	<	V defaultVal)
2319	>	private void buildFromSorted(int size, Iterator it,
2320	>	java.io.ObjectInputStream str,
2321	>	V defaultVal)
2322		throws  java.io.IOException, ClassNotFoundException {
2323		this.size = size;
2324	<	root =
2325	<	buildFromSorted(0, 0, size-1, computeRedLevel(size),
1996	<	it, str, defaultVal);
2324	>	root = buildFromSorted(0, 0, size-1, computeRedLevel(size),
2325	>	it, str, defaultVal);
2326		}
2327
2328		/**
2329		* Recursive "helper method" that does the real work of the
2330	<	* of the previous method.  Identically named parameters have
2330	>	* previous method.  Identically named parameters have
2331		* identical definitions.  Additional parameters are documented below.
2332		* It is assumed that the comparator and size fields of the TreeMap are
2333		* already set prior to calling this method.  (It ignores both fields.)
#	Line 2030 | Line 2359 | public class TreeMap<K,V>
2359
2360		if (hi < lo) return null;
2361
2362	<	int mid = (lo + hi) / 2;
2362	>	int mid = (lo + hi) >>> 1;
2363
2364		Entry<K,V> left  = null;
2365		if (lo < mid)

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