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Code example of TreeMap in Java collection

黄舟
Release: 2017-03-13 14:37:08
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The relationship between TreeMap and Map is as follows:



##TreeMap introduction:

(1) TreeMap is an ordered key-value set, which is implemented through red-black trees.

(2) TreeMap inherits from AbstractMap, so it is a Map and a key-value set.

(3) TreeMap implements the Navigable interface and supports a series of navigation methods. TreeMap is an ordered collection

(4) It implements the Cloneable interface and can be cloned

(5) TreeMap implements the Serializable interface, which supports serialization

(6) TreeMap is based on red-black tree digital display, and the mapping is sorted according to the natural ordering of its keys


TreeMap main API:


Entry<>                ceilingEntry(K key)
K                          ceilingKey(K key)
clear()
Object                     clone()
Comparator<? K>      comparator()
containsKey(Object key)
NavigableSet<>            descendingKeySet()
NavigableMap<>         descendingMap()
Set<<>>           entrySet()
Entry<>                firstEntry()
K                          firstKey()
Entry<>                floorEntry(K key)
K                          floorKey(K key)
V                          get(Object key)
NavigableMap<>         headMap(K toinclusive)
SortedMap<>            headMap(K toExclusive)
Entry<>                higherEntry(K key)
K                          higherKey(K key)
isEmpty()
Set<>                     keySet()
Entry<>                lastEntry()
K                          lastKey()
Entry<>                lowerEntry(K key)
K                          lowerKey(K key)
NavigableSet<>            navigableKeySet()
Entry<>                pollFirstEntry()
Entry<>                pollLastEntry()
V                          put(K keyV value)
V                          remove(Object key)
size()
SortedMap<>            subMap(K fromInclusiveK toExclusive)
NavigableMap<>         subMap(K fromfromInclusiveK totoInclusive)
NavigableMap<>         tailMap(K frominclusive)
SortedMap<>            tailMap(K fromInclusive)
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TreeMap traversal method

(1) Traverse the key-value pairs of TreeMap: obtain the TreeMap according to entrySet() A collection of "key-value pairs", which is iteratively traversed through an Iterator.

String key=Integer value=Iterator iterator=map.entrySet().iterator()(iterator.hasNext())
{
    Map.Entry entry=(Map.Entry)iterator.next()    key=(String) entry.getKey()    value=(Integer)entry.getValue()}
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(2) Traverse the keys of TreeMap: Obtain the "key" collection according to keySet(), and traverse the key collection through the iterator.


String key = Integer integ = Iterator iter = map.keySet().iterator()(iter.hasNext()) {
   key = (String)iter.next()  integ = (Integer)map.get(key)}
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(3) Traverse the values ​​of TreeMap: Obtain the set of values ​​according to values, and traverse the set of values ​​through the iterator.


Integer value = Collection c = map.values()Iterator iter= c.iterator()(iter.hasNext()) 
{
    value = (Integer)iter.next()}
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TreeMap sample code:


public class Hello {
    
    public static void main(String[] args) {
        testTreeMapOridinaryAPIs();
        testSubMapAPIs();
    }
    private static void testTreeMapOridinaryAPIs() {
        // 初始化随机种子
        Random r = new Random();
        // 新建TreeMap
        TreeMap tmap = new TreeMap();
        // 添加操作
        tmap.put("one", r.nextInt(10));
        tmap.put("two", r.nextInt(10));
        tmap.put("three", r.nextInt(10));
        tmap.put("four", r.nextInt(10));
        tmap.put("five", r.nextInt(10));
        tmap.put("six", r.nextInt(10));
        System.out.printf("\n ---- testTreeMapOridinaryAPIs ----\n");
        // 打印出TreeMap
        System.out.printf("%s\n",tmap );
        // 通过Iterator遍历key-value
        Iterator iter = tmap.entrySet().iterator();
        while(iter.hasNext()) {
            Map.Entry entry = (Map.Entry)iter.next();
            System.out.printf("next : %s - %s\n", entry.getKey(), entry.getValue());
        }
        // TreeMap的键值对个数        
        System.out.printf("size: %s\n", tmap.size());
        // containsKey(Object key) :是否包含键key
        System.out.printf("contains key two : %s\n",tmap.containsKey("two"));
        System.out.printf("contains key five : %s\n",tmap.containsKey("five"));
        // containsValue(Object value) :是否包含值value
        System.out.printf("contains value 0 : %s\n",tmap.containsValue(new Integer(0)));
        // remove(Object key) : 删除键key对应的键值对
        tmap.remove("three");
        System.out.printf("tmap:%s\n",tmap );
        // clear() : 清空TreeMap
        tmap.clear();
        // isEmpty() : TreeMap是否为空
        System.out.printf("%s\n", (tmap.isEmpty()?"tmap is empty":"tmap is not empty") );
    }
    public static void testSubMapAPIs() {
        // 新建TreeMap
        TreeMap tmap = new TreeMap();
        // 添加“键值对”
        tmap.put("a", 101);
        tmap.put("b", 102);
        tmap.put("c", 103);
        tmap.put("d", 104);
        tmap.put("e", 105);
        System.out.printf("\n ---- testSubMapAPIs ----\n");
        // 打印出TreeMap
        System.out.printf("tmap:\n\t%s\n", tmap);
        // 测试 headMap(K toKey)
        System.out.printf("tmap.headMap(\"c\"):\n\t%s\n", tmap.headMap("c"));
        // 测试 headMap(K toKey, boolean inclusive) 
        System.out.printf("tmap.headMap(\"c\", true):\n\t%s\n", tmap.headMap("c", true));
        System.out.printf("tmap.headMap(\"c\", false):\n\t%s\n", tmap.headMap("c", false));
        // 测试 tailMap(K fromKey)
        System.out.printf("tmap.tailMap(\"c\"):\n\t%s\n", tmap.tailMap("c"));
        // 测试 tailMap(K fromKey, boolean inclusive)
        System.out.printf("tmap.tailMap(\"c\", true):\n\t%s\n", tmap.tailMap("c", true));
        System.out.printf("tmap.tailMap(\"c\", false):\n\t%s\n", tmap.tailMap("c", false));
        // 测试 subMap(K fromKey, K toKey)
        System.out.printf("tmap.subMap(\"a\", \"c\"):\n\t%s\n", tmap.subMap("a", "c"));
        // 测试 
        System.out.printf("tmap.subMap(\"a\", true, \"c\", true):\n\t%s\n",
                tmap.subMap("a", true, "c", true));
        System.out.printf("tmap.subMap(\"a\", true, \"c\", false):\n\t%s\n",
                tmap.subMap("a", true, "c", false));
        System.out.printf("tmap.subMap(\"a\", false, \"c\", true):\n\t%s\n",
                tmap.subMap("a", false, "c", true));
        System.out.printf("tmap.subMap(\"a\", false, \"c\", false):\n\t%s\n",
                tmap.subMap("a", false, "c", false));

        // 测试 navigableKeySet()
        System.out.printf("tmap.navigableKeySet():\n\t%s\n", tmap.navigableKeySet());
        // 测试 descendingKeySet()
        System.out.printf("tmap.descendingKeySet():\n\t%s\n", tmap.descendingKeySet());
    }
    public static void testNavigableMapAPIs() {
        // 新建TreeMap
        NavigableMap nav = new TreeMap();
        // 添加“键值对”
        nav.put("aaa", 111);
        nav.put("bbb", 222);
        nav.put("eee", 333);
        nav.put("ccc", 555);
        nav.put("ddd", 444);

        System.out.printf("\n ---- testNavigableMapAPIs ----\n");
        // 打印出TreeMap
        System.out.printf("Whole list:%s%n", nav);

        // 获取第一个key、第一个Entry
        System.out.printf("First key: %s\tFirst entry: %s%n",nav.firstKey(), nav.firstEntry());

        // 获取最后一个key、最后一个Entry
        System.out.printf("Last key: %s\tLast entry: %s%n",nav.lastKey(), nav.lastEntry());

        // 获取“小于/等于bbb”的最大键值对
        System.out.printf("Key floor before bbb: %s%n",nav.floorKey("bbb"));

        // 获取“小于bbb”的最大键值对
        System.out.printf("Key lower before bbb: %s%n", nav.lowerKey("bbb"));

        // 获取“大于/等于bbb”的最小键值对
        System.out.printf("Key ceiling after ccc: %s%n",nav.ceilingKey("ccc"));

        // 获取“大于bbb”的最小键值对
        System.out.printf("Key higher after ccc: %s%n\n",nav.higherKey("ccc"));
    }

}
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Running results:

---- testTreeMapOridinaryAPIs ----
{five=5, four=5, one=3, six=8, three=1, two=0}
next : five - 5
next : four - 5
next : one - 3
next : six - 8
next : three - 1
next : two - 0
size: 6
contains key two : true
contains key five : true
contains value 0 : true
tmap:{five=5, four=5, one=3, six=8, two=0}
tmap is empty
 ---- testSubMapAPIs ----
tmap:
 {a=101, b=102, c=103, d=104, e=105}
tmap.headMap("c"):
 {a=101, b=102}
tmap.headMap("c", true):
 {a=101, b=102, c=103}
tmap.headMap("c", false):
 {a=101, b=102}
tmap.tailMap("c"):
 {c=103, d=104, e=105}
tmap.tailMap("c", true):
 {c=103, d=104, e=105}
tmap.tailMap("c", false):
 {d=104, e=105}
tmap.subMap("a", "c"):
 {a=101, b=102}
tmap.subMap("a", true, "c", true):
 {a=101, b=102, c=103}
tmap.subMap("a", true, "c", false):
 {a=101, b=102}
tmap.subMap("a", false, "c", true):
 {b=102, c=103}
tmap.subMap("a", false, "c", false):
 {b=102}
tmap.navigableKeySet():
 [a, b, c, d, e]
tmap.descendingKeySet():
 [e, d, c, b, a]
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SortedMap based on Java8 Interface source code:

public interface SortedMap<K,V> extends Map<K,V> {
    Comparator<? super K> comparator();
    SortedMap<K,V> subMap(K fromKey, K toKey);
    SortedMap<K,V> headMap(K toKey);
    SortedMap<K,V> tailMap(K fromKey);
    K firstKey();
    K lastKey();
    Set<K> keySet();
    Collection<V> values();
    Set<Map.Entry<K, V>> entrySet();
}
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Navigable interface source code based on Java8:


public interface NavigableMap<K,V> extends SortedMap<K,V> {
    Map.Entry<K,V> lowerEntry(K key);
    K lowerKey(K key);
    Map.Entry<K,V> floorEntry(K key);
    K floorKey(K key);
    Map.Entry<K,V> ceilingEntry(K key);
    K ceilingKey(K key);
    Map.Entry<K,V> higherEntry(K key);
    K higherKey(K key);
    Map.Entry<K,V> firstEntry();
    Map.Entry<K,V> lastEntry();
    Map.Entry<K,V> pollFirstEntry();
    Map.Entry<K,V> pollLastEntry();
    NavigableMap<K,V> descendingMap();
    NavigableSet<K> navigableKeySet();
    NavigableSet<K> descendingKeySet();
    NavigableMap<K,V> subMap(K fromKey, boolean fromInclusive,
                             K toKey,   boolean toInclusive);
    NavigableMap<K,V> headMap(K toKey, boolean inclusive);
    NavigableMap<K,V> tailMap(K fromKey, boolean inclusive);
    SortedMap<K,V> subMap(K fromKey, K toKey);
    SortedMap<K,V> headMap(K toKey);
    SortedMap<K,V> tailMap(K fromKey);
}
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TreeMap source code based on Java8:



public class TreeMap<K,V>extends AbstractMap<K,V>
        implements NavigableMap<K,V>, Cloneable, java.io.Serializable
{
    private final Comparator<? super K> comparator;//比较器
    private transient Entry<K,V> root;//根节点        
    private transient int size = 0;//起始个数
    private transient int modCount = 0;//tree改变次数
    public TreeMap() {
        comparator = null;
    }
    public TreeMap(Comparator<? super K> comparator) {
        this.comparator = comparator;
    }
    public TreeMap(Map<? extends K, ? extends V> m) {
        comparator = null;
        putAll(m);
    }
    public TreeMap(SortedMap<K, ? extends V> m) {
        comparator = m.comparator();
        try {
            buildFromSorted(m.size(), m.entrySet().iterator(), null, null);
        } catch (java.io.IOException cannotHappen) {
        } catch (ClassNotFoundException cannotHappen) {
        }
    }
    //获得个数
    public int size() {
        return size;
    }
    //是否含有某个key
    public boolean containsKey(Object key) {
        return getEntry(key) != null;
    }
    //是否还有某个值
    public boolean containsValue(Object value) {
        for (Entry<K,V> e = getFirstEntry(); e != null; e = successor(e))
            if (valEquals(value, e.value))
                return true;
        return false;
    }
    //通过key获得值
    public V get(Object key) {
        Entry<K,V> p = getEntry(key);
        return (p==null ? null : p.value);
    }
    //比较器
    public Comparator<? super K> comparator() {
        return comparator;
    }
    //获得第一个key
    public K firstKey() {
        return key(getFirstEntry());
    }
    //获得最后一个key
    public K lastKey() {
        return key(getLastEntry());
    }

    /**
     * Copies all of the mappings from the specified map to this map.
     * These mappings replace any mappings that this map had for any
     * of the keys currently in the specified map.
     *
     * @param  map mappings to be stored in this map
     * @throws ClassCastException if the class of a key or value in
     *         the specified map prevents it from being stored in this map
     * @throws NullPointerException if the specified map is null or
     *         the specified map contains a null key and this map does not
     *         permit null keys
     */
    //拷贝某个特定的map到这个map
    public void putAll(Map<? extends K, ? extends V> map) {
        int mapSize = map.size();
        if (size==0 && mapSize!=0 && map instanceof SortedMap) {
            Comparator<?> c = ((SortedMap<?,?>)map).comparator();
            if (c == comparator || (c != null && c.equals(comparator))) {
                ++modCount;
                try {
                    buildFromSorted(mapSize, map.entrySet().iterator(),
                            null, null);
                } catch (java.io.IOException cannotHappen) {
                } catch (ClassNotFoundException cannotHappen) {
                }
                return;
            }
        }
        super.putAll(map);
    }

    /**
     * Returns this map&#39;s entry for the given key, or {@code null} if the map
     * does not contain an entry for the key.
     *
     * @return this map&#39;s entry for the given key, or {@code null} if the map
     *         does not contain an entry for the key
     * @throws ClassCastException if the specified key cannot be compared
     *         with the keys currently in the map
     * @throws NullPointerException if the specified key is null
     *         and this map uses natural ordering, or its comparator
     *         does not permit null keys
     */
    //根据某个key获得entry
    final Entry<K,V> getEntry(Object key) {
        // Offload comparator-based version for sake of performance
        if (comparator != null)
            return getEntryUsingComparator(key);
        if (key == null)
            throw new NullPointerException();
        @SuppressWarnings("unchecked")
        Comparable<? super K> k = (Comparable<? super K>) key;
        Entry<K,V> p = root;
        while (p != null) {
            int cmp = k.compareTo(p.key);
            if (cmp < 0)
                p = p.left;
            else if (cmp > 0)
                p = p.right;
            else
                return p;
        }
        return null;
    }

    /**
     * Version of getEntry using comparator. Split off from getEntry
     * for performance. (This is not worth doing for most methods,
     * that are less dependent on comparator performance, but is
     * worthwhile here.)
     */
    //通过比较器来比较key,返回entry
    final Entry<K,V> getEntryUsingComparator(Object key) {
        @SuppressWarnings("unchecked")
        K k = (K) key;
        Comparator<? super K> cpr = comparator;
        if (cpr != null) {
            Entry<K,V> p = root;
            while (p != null) {
                int cmp = cpr.compare(k, p.key);
                if (cmp < 0)
                    p = p.left;
                else if (cmp > 0)
                    p = p.right;
                else
                    return p;
            }
        }
        return null;
    }

    /**
     * Gets the entry corresponding to the specified key; if no such entry
     * exists, returns the entry for the least key greater than the specified
     * key; if no such entry exists (i.e., the greatest key in the Tree is less
     * than the specified key), returns {@code null}.
     */
    //获得与key关系最近的entry,上限
    final Entry<K,V> getCeilingEntry(K key) {
        Entry<K,V> p = root;
        while (p != null) {
            int cmp = compare(key, p.key);
            if (cmp < 0) {
                if (p.left != null)
                    p = p.left;
                else
                    return p;
            } else if (cmp > 0) {
                if (p.right != null) {
                    p = p.right;
                } else {
                    Entry<K,V> parent = p.parent;
                    Entry<K,V> ch = p;
                    while (parent != null && ch == parent.right) {
                        ch = parent;
                        parent = parent.parent;
                    }
                    return parent;
                }
            } else
                return p;
        }
        return null;
    }

    /**
     * Gets the entry corresponding to the specified key; if no such entry
     * exists, returns the entry for the greatest key less than the specified
     * key; if no such entry exists, returns {@code null}.
     */
    //获得与key关系最近的entry,下限
    final Entry<K,V> getFloorEntry(K key) {
        Entry<K,V> p = root;
        while (p != null) {
            int cmp = compare(key, p.key);
            if (cmp > 0) {
                if (p.right != null)
                    p = p.right;
                else
                    return p;
            } else if (cmp < 0) {
                if (p.left != null) {
                    p = p.left;
                } else {
                    Entry<K,V> parent = p.parent;
                    Entry<K,V> ch = p;
                    while (parent != null && ch == parent.left) {
                        ch = parent;
                        parent = parent.parent;
                    }
                    return parent;
                }
            } else
                return p;

        }
        return null;
    }

    /**
     * Gets the entry for the least key greater than the specified
     * key; if no such entry exists, returns the entry for the least
     * key greater than the specified key; if no such entry exists
     * returns {@code null}.
     */
    //比某个key大的entry
    final Entry<K,V> getHigherEntry(K key) {
        Entry<K,V> p = root;
        while (p != null) {
            int cmp = compare(key, p.key);
            if (cmp < 0) {
                if (p.left != null)
                    p = p.left;
                else
                    return p;
            } else {
                if (p.right != null) {
                    p = p.right;
                } else {
                    Entry<K,V> parent = p.parent;
                    Entry<K,V> ch = p;
                    while (parent != null && ch == parent.right) {
                        ch = parent;
                        parent = parent.parent;
                    }
                    return parent;
                }
            }
        }
        return null;
    }

    /**
     * Returns the entry for the greatest key less than the specified key; if
     * no such entry exists (i.e., the least key in the Tree is greater than
     * the specified key), returns {@code null}.
     */
//获得某个key小于最接近的entry
    final Entry<K,V> getLowerEntry(K key) {
        Entry<K,V> p = root;
        while (p != null) {
            int cmp = compare(key, p.key);
            if (cmp > 0) {
                if (p.right != null)
                    p = p.right;
                else
                    return p;
            } else {
                if (p.left != null) {
                    p = p.left;
                } else {
                    Entry<K,V> parent = p.parent;
                    Entry<K,V> ch = p;
                    while (parent != null && ch == parent.left) {
                        ch = parent;
                        parent = parent.parent;
                    }
                    return parent;
                }
            }
        }
        return null;
    }

    /**
     * Associates the specified value with the specified key in this map.
     * If the map previously contained a mapping for the key, the old
     * value is replaced.
     *
     * @param key key with which the specified value is to be associated
     * @param value value to be associated with the specified key
     *
     * @return the previous value associated with {@code key}, or
     *         {@code null} if there was no mapping for {@code key}.
     *         (A {@code null} return can also indicate that the map
     *         previously associated {@code null} with {@code key}.)
     * @throws ClassCastException if the specified key cannot be compared
     *         with the keys currently in the map
     * @throws NullPointerException if the specified key is null
     *         and this map uses natural ordering, or its comparator
     *         does not permit null keys
     */
//插入key-value值
    public V put(K key, V value) {
        Entry<K,V> t = root;
        if (t == null) {
            compare(key, key); // type (and possibly null) check

            root = new Entry<>(key, value, null);
            size = 1;
            modCount++;
            return null;
        }
        int cmp;
        Entry<K,V> parent;
// split comparator and comparable paths
        Comparator<? super K> cpr = comparator;
        if (cpr != null) {
            do {
                parent = t;
                cmp = cpr.compare(key, t.key);
                if (cmp < 0)
                    t = t.left;
                else if (cmp > 0)
                    t = t.right;
                else
                    return t.setValue(value);
            } while (t != null);
        }
        else {
            if (key == null)
                throw new NullPointerException();
            @SuppressWarnings("unchecked")
            Comparable<? super K> k = (Comparable<? super K>) key;
            do {
                parent = t;
                cmp = k.compareTo(t.key);
                if (cmp < 0)
                    t = t.left;
                else if (cmp > 0)
                    t = t.right;
                else
                    return t.setValue(value);
            } while (t != null);
        }
        Entry<K,V> e = new Entry<>(key, value, parent);
        if (cmp < 0)
            parent.left = e;
        else
            parent.right = e;
        fixAfterInsertion(e);
        size++;
        modCount++;
        return null;
    }

    /**
     * Removes the mapping for this key from this TreeMap if present.
     *
     * @param  key key for which mapping should be removed
     * @return the previous value associated with {@code key}, or
     *         {@code null} if there was no mapping for {@code key}.
     *         (A {@code null} return can also indicate that the map
     *         previously associated {@code null} with {@code key}.)
     * @throws ClassCastException if the specified key cannot be compared
     *         with the keys currently in the map
     * @throws NullPointerException if the specified key is null
     *         and this map uses natural ordering, or its comparator
     *         does not permit null keys
     */
//删掉某个key,并返回value
    public V remove(Object key) {
        Entry<K,V> p = getEntry(key);
        if (p == null)
            return null;

        V oldValue = p.value;
        deleteEntry(p);
        return oldValue;
    }

    /**
     * Removes all of the mappings from this map.
     * The map will be empty after this call returns.
     */
//清空
    public void clear() {
        modCount++;
        size = 0;
        root = null;
    }

    /**
     * Returns a shallow copy of this {@code TreeMap} instance. (The keys and
     * values themselves are not cloned.)
     *
     * @return a shallow copy of this map
     */
//进行克隆,深拷贝
    public Object clone() {
        TreeMap<?,?> clone;
        try {
            clone = (TreeMap<?,?>) super.clone();
        } catch (CloneNotSupportedException e) {
            throw new InternalError(e);
        }

// Put clone into "virgin" state (except for comparator)
        clone.root = null;
        clone.size = 0;
        clone.modCount = 0;
        clone.entrySet = null;
        clone.navigableKeySet = null;
        clone.descendingMap = null;

// Initialize clone with our mappings
        try {
            clone.buildFromSorted(size, entrySet().iterator(), null, null);
        } catch (java.io.IOException cannotHappen) {
        } catch (ClassNotFoundException cannotHappen) {
        }

        return clone;
    }

// NavigableMap API methods

    /**
     * @since 1.6
     */
//获得第一个entry
    public Map.Entry<K,V> firstEntry() {
        return exportEntry(getFirstEntry());
    }

    /**
     * @since 1.6
     */
//最后一个entry
    public Map.Entry<K,V> lastEntry() {
        return exportEntry(getLastEntry());
    }

    /**
     * @since 1.6
     */
//弹出第一个entry,并删除
    public Map.Entry<K,V> pollFirstEntry() {
        Entry<K,V> p = getFirstEntry();
        Map.Entry<K,V> result = exportEntry(p);
        if (p != null)
            deleteEntry(p);
        return result;
    }

    /**
     * @since 1.6
     */
//弹出最后一个entry,并删除
    public Map.Entry<K,V> pollLastEntry() {
        Entry<K,V> p = getLastEntry();
        Map.Entry<K,V> result = exportEntry(p);
        if (p != null)
            deleteEntry(p);
        return result;
    }

    /**
     * @throws ClassCastException {@inheritDoc}
     * @throws NullPointerException if the specified key is null
     *         and this map uses natural ordering, or its comparator
     *         does not permit null keys
     * @since 1.6
     */
    public Map.Entry<K,V> lowerEntry(K key) {
        return exportEntry(getLowerEntry(key));
    }

    /**
     * @throws ClassCastException {@inheritDoc}
     * @throws NullPointerException if the specified key is null
     *         and this map uses natural ordering, or its comparator
     *         does not permit null keys
     * @since 1.6
     */
    public K lowerKey(K key) {
        return keyOrNull(getLowerEntry(key));
    }

    /**
     * @throws ClassCastException {@inheritDoc}
     * @throws NullPointerException if the specified key is null
     *         and this map uses natural ordering, or its comparator
     *         does not permit null keys
     * @since 1.6
     */
    public Map.Entry<K,V> floorEntry(K key) {
        return exportEntry(getFloorEntry(key));
    }

    /**
     * @throws ClassCastException {@inheritDoc}
     * @throws NullPointerException if the specified key is null
     *         and this map uses natural ordering, or its comparator
     *         does not permit null keys
     * @since 1.6
     */
    public K floorKey(K key) {
        return keyOrNull(getFloorEntry(key));
    }

    /**
     * @throws ClassCastException {@inheritDoc}
     * @throws NullPointerException if the specified key is null
     *         and this map uses natural ordering, or its comparator
     *         does not permit null keys
     * @since 1.6
     */
    public Map.Entry<K,V> ceilingEntry(K key) {
        return exportEntry(getCeilingEntry(key));
    }

    /**
     * @throws ClassCastException {@inheritDoc}
     * @throws NullPointerException if the specified key is null
     *         and this map uses natural ordering, or its comparator
     *         does not permit null keys
     * @since 1.6
     */
    public K ceilingKey(K key) {
        return keyOrNull(getCeilingEntry(key));
    }

    /**
     * @throws ClassCastException {@inheritDoc}
     * @throws NullPointerException if the specified key is null
     *         and this map uses natural ordering, or its comparator
     *         does not permit null keys
     * @since 1.6
     */
    public Map.Entry<K,V> higherEntry(K key) {
        return exportEntry(getHigherEntry(key));
    }

    /**
     * @throws ClassCastException {@inheritDoc}
     * @throws NullPointerException if the specified key is null
     *         and this map uses natural ordering, or its comparator
     *         does not permit null keys
     * @since 1.6
     */
    public K higherKey(K key) {
        return keyOrNull(getHigherEntry(key));
    }

// Views

    /**
     * Fields initialized to contain an instance of the entry set view
     * the first time this view is requested.  Views are stateless, so
     * there&#39;s no reason to create more than one.
     */
    private transient EntrySet entrySet;
    private transient KeySet<K> navigableKeySet;
    private transient NavigableMap<K,V> descendingMap;

    /**
     * Returns a {@link Set} view of the keys contained in this map.
     *
     * <p>The set&#39;s iterator returns the keys in ascending order.
     * The set&#39;s spliterator is
     * <em><a href="Spliterator.html#binding">late-binding</a></em>,
     * <em>fail-fast</em>, and additionally reports {@link Spliterator#SORTED}
     * and {@link Spliterator#ORDERED} with an encounter order that is ascending
     * key order.  The spliterator&#39;s comparator (see
     * {@link java.util.Spliterator#getComparator()}) is {@code null} if
     * the tree map&#39;s comparator (see {@link #comparator()}) is {@code null}.
     * Otherwise, the spliterator&#39;s comparator is the same as or imposes the
     * same total ordering as the tree map&#39;s comparator.
     *
     * <p>The set is backed by the map, so changes to the map are
     * reflected in the set, and vice-versa.  If the map is modified
     * while an iteration over the set is in progress (except through
     * the iterator&#39;s own {@code remove} operation), the results of
     * the iteration are undefined.  The set supports element removal,
     * which removes the corresponding mapping from the map, via the
     * {@code Iterator.remove}, {@code Set.remove},
     * {@code removeAll}, {@code retainAll}, and {@code clear}
     * operations.  It does not support the {@code add} or {@code addAll}
     * operations.
     */
    public Set<K> keySet() {
        return navigableKeySet();
    }

    /**
     * @since 1.6
     */
    public NavigableSet<K> navigableKeySet() {
        KeySet<K> nks = navigableKeySet;
        return (nks != null) ? nks : (navigableKeySet = new KeySet<>(this));
    }

    /**
     * @since 1.6
     */
    public NavigableSet<K> descendingKeySet() {
        return descendingMap().navigableKeySet();
    }

    /**
     * Returns a {@link Collection} view of the values contained in this map.
     *
     * <p>The collection&#39;s iterator returns the values in ascending order
     * of the corresponding keys. The collection&#39;s spliterator is
     * <em><a href="Spliterator.html#binding">late-binding</a></em>,
     * <em>fail-fast</em>, and additionally reports {@link Spliterator#ORDERED}
     * with an encounter order that is ascending order of the corresponding
     * keys.
     *
     * <p>The collection is backed by the map, so changes to the map are
     * reflected in the collection, and vice-versa.  If the map is
     * modified while an iteration over the collection is in progress
     * (except through the iterator&#39;s own {@code remove} operation),
     * the results of the iteration are undefined.  The collection
     * supports element removal, which removes the corresponding
     * mapping from the map, via the {@code Iterator.remove},
     * {@code Collection.remove}, {@code removeAll},
     * {@code retainAll} and {@code clear} operations.  It does not
     * support the {@code add} or {@code addAll} operations.
     */
    public Collection<V> values() {
        Collection<V> vs = values;
        return (vs != null) ? vs : (values = new Values());
    }

    /**
     * Returns a {@link Set} view of the mappings contained in this map.
     *
     * <p>The set&#39;s iterator returns the entries in ascending key order. The
     * sets&#39;s spliterator is
     * <em><a href="Spliterator.html#binding">late-binding</a></em>,
     * <em>fail-fast</em>, and additionally reports {@link Spliterator#SORTED} and
     * {@link Spliterator#ORDERED} with an encounter order that is ascending key
     * order.
     *
     * <p>The set is backed by the map, so changes to the map are
     * reflected in the set, and vice-versa.  If the map is modified
     * while an iteration over the set is in progress (except through
     * the iterator&#39;s own {@code remove} operation, or through the
     * {@code setValue} operation on a map entry returned by the
     * iterator) the results of the iteration are undefined.  The set
     * supports element removal, which removes the corresponding
     * mapping from the map, via the {@code Iterator.remove},
     * {@code Set.remove}, {@code removeAll}, {@code retainAll} and
     * {@code clear} operations.  It does not support the
     * {@code add} or {@code addAll} operations.
     */
    public Set<Map.Entry<K,V>> entrySet() {
        EntrySet es = entrySet;
        return (es != null) ? es : (entrySet = new EntrySet());
    }

    /**
     * @since 1.6
     */
    public NavigableMap<K, V> descendingMap() {
        NavigableMap<K, V> km = descendingMap;
        return (km != null) ? km :
                (descendingMap = new DescendingSubMap<>(this,
                        true, null, true,
                        true, null, true));
    }

    /**
     * @throws ClassCastException       {@inheritDoc}
     * @throws NullPointerException if {@code fromKey} or {@code toKey} is
     *         null and this map uses natural ordering, or its comparator
     *         does not permit null keys
     * @throws IllegalArgumentException {@inheritDoc}
     * @since 1.6
     */
    public NavigableMap<K,V> subMap(K fromKey, boolean fromInclusive,
                                    K toKey,   boolean toInclusive) {
        return new AscendingSubMap<>(this,
                false, fromKey, fromInclusive,
                false, toKey,   toInclusive);
    }

    /**
     * @throws ClassCastException       {@inheritDoc}
     * @throws NullPointerException if {@code toKey} is null
     *         and this map uses natural ordering, or its comparator
     *         does not permit null keys
     * @throws IllegalArgumentException {@inheritDoc}
     * @since 1.6
     */
    public NavigableMap<K,V> headMap(K toKey, boolean inclusive) {
        return new AscendingSubMap<>(this,
                true,  null,  true,
                false, toKey, inclusive);
    }

    /**
     * @throws ClassCastException       {@inheritDoc}
     * @throws NullPointerException if {@code fromKey} is null
     *         and this map uses natural ordering, or its comparator
     *         does not permit null keys
     * @throws IllegalArgumentException {@inheritDoc}
     * @since 1.6
     */
    public NavigableMap<K,V> tailMap(K fromKey, boolean inclusive) {
        return new AscendingSubMap<>(this,
                false, fromKey, inclusive,
                true,  null,    true);
    }

    /**
     * @throws ClassCastException       {@inheritDoc}
     * @throws NullPointerException if {@code fromKey} or {@code toKey} is
     *         null and this map uses natural ordering, or its comparator
     *         does not permit null keys
     * @throws IllegalArgumentException {@inheritDoc}
     */
    public SortedMap<K,V> subMap(K fromKey, K toKey) {
        return subMap(fromKey, true, toKey, false);
    }

    /**
     * @throws ClassCastException       {@inheritDoc}
     * @throws NullPointerException if {@code toKey} is null
     *         and this map uses natural ordering, or its comparator
     *         does not permit null keys
     * @throws IllegalArgumentException {@inheritDoc}
     */
    public SortedMap<K,V> headMap(K toKey) {
        return headMap(toKey, false);
    }

    /**
     * @throws ClassCastException       {@inheritDoc}
     * @throws NullPointerException if {@code fromKey} is null
     *         and this map uses natural ordering, or its comparator
     *         does not permit null keys
     * @throws IllegalArgumentException {@inheritDoc}
     */
    public SortedMap<K,V> tailMap(K fromKey) {
        return tailMap(fromKey, true);
    }

    @Override
    public boolean replace(K key, V oldValue, V newValue) {
        Entry<K,V> p = getEntry(key);
        if (p!=null && Objects.equals(oldValue, p.value)) {
            p.value = newValue;
            return true;
        }
        return false;
    }

    @Override
    public V replace(K key, V value) {
        Entry<K,V> p = getEntry(key);
        if (p!=null) {
            V oldValue = p.value;
            p.value = value;
            return oldValue;
        }
        return null;
    }

    @Override
    public void forEach(BiConsumer<? super K, ? super V> action) {
        Objects.requireNonNull(action);
        int expectedModCount = modCount;
        for (Entry<K, V> e = getFirstEntry(); e != null; e = successor(e)) {
            action.accept(e.key, e.value);

            if (expectedModCount != modCount) {
                throw new ConcurrentModificationException();
            }
        }
    }

    @Override
    public void replaceAll(BiFunction<? super K, ? super V, ? extends V> function) {
        Objects.requireNonNull(function);
        int expectedModCount = modCount;

        for (Entry<K, V> e = getFirstEntry(); e != null; e = successor(e)) {
            e.value = function.apply(e.key, e.value);

            if (expectedModCount != modCount) {
                throw new ConcurrentModificationException();
            }
        }
    }

// View class support

    class Values extends AbstractCollection<V> {
        public Iterator<V> iterator() {
            return new ValueIterator(getFirstEntry());
        }

        public int size() {
            return TreeMap.this.size();
        }

        public boolean contains(Object o) {
            return TreeMap.this.containsValue(o);
        }

        public boolean remove(Object o) {
            for (Entry<K,V> e = getFirstEntry(); e != null; e = successor(e)) {
                if (valEquals(e.getValue(), o)) {
                    deleteEntry(e);
                    return true;
                }
            }
            return false;
        }

        public void clear() {
            TreeMap.this.clear();
        }

        public Spliterator<V> spliterator() {
            return new ValueSpliterator<K,V>(TreeMap.this, null, null, 0, -1, 0);
        }
    }

    class EntrySet extends AbstractSet<Map.Entry<K,V>> {
        public Iterator<Map.Entry<K,V>> iterator() {
            return new EntryIterator(getFirstEntry());
        }

        public boolean contains(Object o) {
            if (!(o instanceof Map.Entry))
                return false;
            Map.Entry<?,?> entry = (Map.Entry<?,?>) o;
            Object value = entry.getValue();
            Entry<K,V> p = getEntry(entry.getKey());
            return p != null && valEquals(p.getValue(), value);
        }

        public boolean remove(Object o) {
            if (!(o instanceof Map.Entry))
                return false;
            Map.Entry<?,?> entry = (Map.Entry<?,?>) o;
            Object value = entry.getValue();
            Entry<K,V> p = getEntry(entry.getKey());
            if (p != null && valEquals(p.getValue(), value)) {
                deleteEntry(p);
                return true;
            }
            return false;
        }

        public int size() {
            return TreeMap.this.size();
        }

        public void clear() {
            TreeMap.this.clear();
        }

        public Spliterator<Map.Entry<K,V>> spliterator() {
            return new EntrySpliterator<K,V>(TreeMap.this, null, null, 0, -1, 0);
        }
    }

/*
     * Unlike Values and EntrySet, the KeySet class is static,
     * delegating to a NavigableMap to allow use by SubMaps, which
     * outweighs the ugliness of needing type-tests for the following
     * Iterator methods that are defined appropriately in main versus
     * submap classes.
     */

    Iterator<K> keyIterator() {
        return new KeyIterator(getFirstEntry());
    }

    Iterator<K> descendingKeyIterator() {
        return new DescendingKeyIterator(getLastEntry());
    }

    static final class KeySet<E> extends AbstractSet<E> implements NavigableSet<E> {
        private final NavigableMap<E, ?> m;
        KeySet(NavigableMap<E,?> map) { m = map; }

        public Iterator<E> iterator() {
            if (m instanceof TreeMap)
                return ((TreeMap<E,?>)m).keyIterator();
            else
                return ((TreeMap.NavigableSubMap<E,?>)m).keyIterator();
        }

        public Iterator<E> descendingIterator() {
            if (m instanceof TreeMap)
                return ((TreeMap<E,?>)m).descendingKeyIterator();
            else
                return ((TreeMap.NavigableSubMap<E,?>)m).descendingKeyIterator();
        }

        public int size() { return m.size(); }
        public boolean isEmpty() { return m.isEmpty(); }
        public boolean contains(Object o) { return m.containsKey(o); }
        public void clear() { m.clear(); }
        public E lower(E e) { return m.lowerKey(e); }
        public E floor(E e) { return m.floorKey(e); }
        public E ceiling(E e) { return m.ceilingKey(e); }
        public E higher(E e) { return m.higherKey(e); }
        public E first() { return m.firstKey(); }
        public E last() { return m.lastKey(); }
        public Comparator<? super E> comparator() { return m.comparator(); }
        public E pollFirst() {
            Map.Entry<E,?> e = m.pollFirstEntry();
            return (e == null) ? null : e.getKey();
        }
        public E pollLast() {
            Map.Entry<E,?> e = m.pollLastEntry();
            return (e == null) ? null : e.getKey();
        }
        public boolean remove(Object o) {
            int oldSize = size();
            m.remove(o);
            return size() != oldSize;
        }
        public NavigableSet<E> subSet(E fromElement, boolean fromInclusive,
                                      E toElement,   boolean toInclusive) {
            return new KeySet<>(m.subMap(fromElement, fromInclusive,
                    toElement,   toInclusive));
        }
        public NavigableSet<E> headSet(E toElement, boolean inclusive) {
            return new KeySet<>(m.headMap(toElement, inclusive));
        }
        public NavigableSet<E> tailSet(E fromElement, boolean inclusive) {
            return new KeySet<>(m.tailMap(fromElement, inclusive));
        }
        public SortedSet<E> subSet(E fromElement, E toElement) {
            return subSet(fromElement, true, toElement, false);
        }
        public SortedSet<E> headSet(E toElement) {
            return headSet(toElement, false);
        }
        public SortedSet<E> tailSet(E fromElement) {
            return tailSet(fromElement, true);
        }
        public NavigableSet<E> descendingSet() {
            return new KeySet<>(m.descendingMap());
        }

        public Spliterator<E> spliterator() {
            return keySpliteratorFor(m);
        }
    }

    /**
     * Base class for TreeMap Iterators
     */
    abstract class PrivateEntryIterator<T> implements Iterator<T> {
        Entry<K,V> next;
        Entry<K,V> lastReturned;
        int expectedModCount;

        PrivateEntryIterator(Entry<K,V> first) {
            expectedModCount = modCount;
            lastReturned = null;
            next = first;
        }

        public final boolean hasNext() {
            return next != null;
        }

        final Entry<K,V> nextEntry() {
            Entry<K,V> e = next;
            if (e == null)
                throw new NoSuchElementException();
            if (modCount != expectedModCount)
                throw new ConcurrentModificationException();
            next = successor(e);
            lastReturned = e;
            return e;
        }

        final Entry<K,V> prevEntry() {
            Entry<K,V> e = next;
            if (e == null)
                throw new NoSuchElementException();
            if (modCount != expectedModCount)
                throw new ConcurrentModificationException();
            next = predecessor(e);
            lastReturned = e;
            return e;
        }

        public void remove() {
            if (lastReturned == null)
                throw new IllegalStateException();
            if (modCount != expectedModCount)
                throw new ConcurrentModificationException();
// deleted entries are replaced by their successors
            if (lastReturned.left != null && lastReturned.right != null)
                next = lastReturned;
            deleteEntry(lastReturned);
            expectedModCount = modCount;
            lastReturned = null;
        }
    }

    final class EntryIterator extends PrivateEntryIterator<Map.Entry<K,V>> {
        EntryIterator(Entry<K,V> first) {
            super(first);
        }
        public Map.Entry<K,V> next() {
            return nextEntry();
        }
    }

    final class ValueIterator extends PrivateEntryIterator<V> {
        ValueIterator(Entry<K,V> first) {
            super(first);
        }
        public V next() {
            return nextEntry().value;
        }
    }

    final class KeyIterator extends PrivateEntryIterator<K> {
        KeyIterator(Entry<K,V> first) {
            super(first);
        }
        public K next() {
            return nextEntry().key;
        }
    }

    final class DescendingKeyIterator extends PrivateEntryIterator<K> {
        DescendingKeyIterator(Entry<K,V> first) {
            super(first);
        }
        public K next() {
            return prevEntry().key;
        }
        public void remove() {
            if (lastReturned == null)
                throw new IllegalStateException();
            if (modCount != expectedModCount)
                throw new ConcurrentModificationException();
            deleteEntry(lastReturned);
            lastReturned = null;
            expectedModCount = modCount;
        }
    }

// Little utilities

    /**
     * Compares two keys using the correct comparison method for this TreeMap.
     */
    @SuppressWarnings("unchecked")
    final int compare(Object k1, Object k2) {
        return comparator==null ? ((Comparable<? super K>)k1).compareTo((K)k2)
                : comparator.compare((K)k1, (K)k2);
    }

    /**
     * Test two values for equality.  Differs from o1.equals(o2) only in
     * that it copes with {@code null} o1 properly.
     */
    static final boolean valEquals(Object o1, Object o2) {
        return (o1==null ? o2==null : o1.equals(o2));
    }

    /**
     * Return SimpleImmutableEntry for entry, or null if null
     */
    static <K,V> Map.Entry<K,V> exportEntry(TreeMap.Entry<K,V> e) {
        return (e == null) ? null :
                new AbstractMap.SimpleImmutableEntry<>(e);
    }

    /**
     * Return key for entry, or null if null
     */
    static <K,V> K keyOrNull(TreeMap.Entry<K,V> e) {
        return (e == null) ? null : e.key;
    }

    /**
     * Returns the key corresponding to the specified Entry.
     * @throws NoSuchElementException if the Entry is null
     */
    static <K> K key(Entry<K,?> e) {
        if (e==null)
            throw new NoSuchElementException();
        return e.key;
    }


// SubMaps

    /**
     * Dummy value serving as unmatchable fence key for unbounded
     * SubMapIterators
     */
    private static final Object UNBOUNDED = new Object();

    /**
     * @serial include
     */
    abstract static class NavigableSubMap<K,V> extends AbstractMap<K,V>
            implements NavigableMap<K,V>, java.io.Serializable {
        private static final long serialVersionUID = -2102997345730753016L;
        /**
         * The backing map.
         */
        final TreeMap<K,V> m;

        /**
         * Endpoints are represented as triples (fromStart, lo,
         * loInclusive) and (toEnd, hi, hiInclusive). If fromStart is
         * true, then the low (absolute) bound is the start of the
         * backing map, and the other values are ignored. Otherwise,
         * if loInclusive is true, lo is the inclusive bound, else lo
         * is the exclusive bound. Similarly for the upper bound.
         */
        final K lo, hi;
        final boolean fromStart, toEnd;
        final boolean loInclusive, hiInclusive;

        NavigableSubMap(TreeMap<K,V> m,
                        boolean fromStart, K lo, boolean loInclusive,
                        boolean toEnd,     K hi, boolean hiInclusive) {
            if (!fromStart && !toEnd) {
                if (m.compare(lo, hi) > 0)
                    throw new IllegalArgumentException("fromKey > toKey");
            } else {
                if (!fromStart) // type check
                    m.compare(lo, lo);
                if (!toEnd)
                    m.compare(hi, hi);
            }

            this.m = m;
            this.fromStart = fromStart;
            this.lo = lo;
            this.loInclusive = loInclusive;
            this.toEnd = toEnd;
            this.hi = hi;
            this.hiInclusive = hiInclusive;
        }

// internal utilities

        final boolean tooLow(Object key) {
            if (!fromStart) {
                int c = m.compare(key, lo);
                if (c < 0 || (c == 0 && !loInclusive))
                    return true;
            }
            return false;
        }

        final boolean tooHigh(Object key) {
            if (!toEnd) {
                int c = m.compare(key, hi);
                if (c > 0 || (c == 0 && !hiInclusive))
                    return true;
            }
            return false;
        }

        final boolean inRange(Object key) {
            return !tooLow(key) && !tooHigh(key);
        }

        final boolean inClosedRange(Object key) {
            return (fromStart || m.compare(key, lo) >= 0)
                    && (toEnd || m.compare(hi, key) >= 0);
        }

        final boolean inRange(Object key, boolean inclusive) {
            return inclusive ? inRange(key) : inClosedRange(key);
        }

/*
         * Absolute versions of relation operations.
         * Subclasses map to these using like-named "sub"
         * versions that invert senses for descending maps
         */

        final TreeMap.Entry<K,V> absLowest() {
            TreeMap.Entry<K,V> e =
                    (fromStart ?  m.getFirstEntry() :
                            (loInclusive ? m.getCeilingEntry(lo) :
                                    m.getHigherEntry(lo)));
            return (e == null || tooHigh(e.key)) ? null : e;
        }

        final TreeMap.Entry<K,V> absHighest() {
            TreeMap.Entry<K,V> e =
                    (toEnd ?  m.getLastEntry() :
                            (hiInclusive ?  m.getFloorEntry(hi) :
                                    m.getLowerEntry(hi)));
            return (e == null || tooLow(e.key)) ? null : e;
        }

        final TreeMap.Entry<K,V> absCeiling(K key) {
            if (tooLow(key))
                return absLowest();
            TreeMap.Entry<K,V> e = m.getCeilingEntry(key);
            return (e == null || tooHigh(e.key)) ? null : e;
        }

        final TreeMap.Entry<K,V> absHigher(K key) {
            if (tooLow(key))
                return absLowest();
            TreeMap.Entry<K,V> e = m.getHigherEntry(key);
            return (e == null || tooHigh(e.key)) ? null : e;
        }

        final TreeMap.Entry<K,V> absFloor(K key) {
            if (tooHigh(key))
                return absHighest();
            TreeMap.Entry<K,V> e = m.getFloorEntry(key);
            return (e == null || tooLow(e.key)) ? null : e;
        }

        final TreeMap.Entry<K,V> absLower(K key) {
            if (tooHigh(key))
                return absHighest();
            TreeMap.Entry<K,V> e = m.getLowerEntry(key);
            return (e == null || tooLow(e.key)) ? null : e;
        }

        /** Returns the absolute high fence for ascending traversal */
        final TreeMap.Entry<K,V> absHighFence() {
            return (toEnd ? null : (hiInclusive ?
                    m.getHigherEntry(hi) :
                    m.getCeilingEntry(hi)));
        }

        /** Return the absolute low fence for descending traversal  */
        final TreeMap.Entry<K,V> absLowFence() {
            return (fromStart ? null : (loInclusive ?
                    m.getLowerEntry(lo) :
                    m.getFloorEntry(lo)));
        }

// Abstract methods defined in ascending vs descending classes
        // These relay to the appropriate absolute versions

        abstract TreeMap.Entry<K,V> subLowest();
        abstract TreeMap.Entry<K,V> subHighest();
        abstract TreeMap.Entry<K,V> subCeiling(K key);
        abstract TreeMap.Entry<K,V> subHigher(K key);
        abstract TreeMap.Entry<K,V> subFloor(K key);
        abstract TreeMap.Entry<K,V> subLower(K key);

        /** Returns ascending iterator from the perspective of this submap */
        abstract Iterator<K> keyIterator();

        abstract Spliterator<K> keySpliterator();

        /** Returns descending iterator from the perspective of this submap */
        abstract Iterator<K> descendingKeyIterator();

// public methods

        public boolean isEmpty() {
            return (fromStart && toEnd) ? m.isEmpty() : entrySet().isEmpty();
        }

        public int size() {
            return (fromStart && toEnd) ? m.size() : entrySet().size();
        }

        public final boolean containsKey(Object key) {
            return inRange(key) && m.containsKey(key);
        }

        public final V put(K key, V value) {
            if (!inRange(key))
                throw new IllegalArgumentException("key out of range");
            return m.put(key, value);
        }

        public final V get(Object key) {
            return !inRange(key) ? null :  m.get(key);
        }

        public final V remove(Object key) {
            return !inRange(key) ? null : m.remove(key);
        }

        public final Map.Entry<K,V> ceilingEntry(K key) {
            return exportEntry(subCeiling(key));
        }

        public final K ceilingKey(K key) {
            return keyOrNull(subCeiling(key));
        }

        public final Map.Entry<K,V> higherEntry(K key) {
            return exportEntry(subHigher(key));
        }

        public final K higherKey(K key) {
            return keyOrNull(subHigher(key));
        }

        public final Map.Entry<K,V> floorEntry(K key) {
            return exportEntry(subFloor(key));
        }

        public final K floorKey(K key) {
            return keyOrNull(subFloor(key));
        }

        public final Map.Entry<K,V> lowerEntry(K key) {
            return exportEntry(subLower(key));
        }

        public final K lowerKey(K key) {
            return keyOrNull(subLower(key));
        }

        public final K firstKey() {
            return key(subLowest());
        }

        public final K lastKey() {
            return key(subHighest());
        }

        public final Map.Entry<K,V> firstEntry() {
            return exportEntry(subLowest());
        }

        public final Map.Entry<K,V> lastEntry() {
            return exportEntry(subHighest());
        }

        public final Map.Entry<K,V> pollFirstEntry() {
            TreeMap.Entry<K,V> e = subLowest();
            Map.Entry<K,V> result = exportEntry(e);
            if (e != null)
                m.deleteEntry(e);
            return result;
        }

        public final Map.Entry<K,V> pollLastEntry() {
            TreeMap.Entry<K,V> e = subHighest();
            Map.Entry<K,V> result = exportEntry(e);
            if (e != null)
                m.deleteEntry(e);
            return result;
        }

        // Views
        transient NavigableMap<K,V> descendingMapView;
        transient EntrySetView entrySetView;
        transient KeySet<K> navigableKeySetView;

        public final NavigableSet<K> navigableKeySet() {
            KeySet<K> nksv = navigableKeySetView;
            return (nksv != null) ? nksv :
                    (navigableKeySetView = new TreeMap.KeySet<>(this));
        }

        public final Set<K> keySet() {
            return navigableKeySet();
        }

        public NavigableSet<K> descendingKeySet() {
            return descendingMap().navigableKeySet();
        }

        public final SortedMap<K,V> subMap(K fromKey, K toKey) {
            return subMap(fromKey, true, toKey, false);
        }

        public final SortedMap<K,V> headMap(K toKey) {
            return headMap(toKey, false);
        }

        public final SortedMap<K,V> tailMap(K fromKey) {
            return tailMap(fromKey, true);
        }

// View classes

        abstract class EntrySetView extends AbstractSet<Map.Entry<K,V>> {
            private transient int size = -1, sizeModCount;

            public int size() {
                if (fromStart && toEnd)
                    return m.size();
                if (size == -1 || sizeModCount != m.modCount) {
                    sizeModCount = m.modCount;
                    size = 0;
                    Iterator<?> i = iterator();
                    while (i.hasNext()) {
                        size++;
                        i.next();
                    }
                }
                return size;
            }

            public boolean isEmpty() {
                TreeMap.Entry<K,V> n = absLowest();
                return n == null || tooHigh(n.key);
            }

            public boolean contains(Object o) {
                if (!(o instanceof Map.Entry))
                    return false;
                Map.Entry<?,?> entry = (Map.Entry<?,?>) o;
                Object key = entry.getKey();
                if (!inRange(key))
                    return false;
                TreeMap.Entry<?,?> node = m.getEntry(key);
                return node != null &&
                        valEquals(node.getValue(), entry.getValue());
            }

            public boolean remove(Object o) {
                if (!(o instanceof Map.Entry))
                    return false;
                Map.Entry<?,?> entry = (Map.Entry<?,?>) o;
                Object key = entry.getKey();
                if (!inRange(key))
                    return false;
                TreeMap.Entry<K,V> node = m.getEntry(key);
                if (node!=null && valEquals(node.getValue(),
                        entry.getValue())) {
                    m.deleteEntry(node);
                    return true;
                }
                return false;
            }
        }

        /**
         * Iterators for SubMaps
         */
        abstract class SubMapIterator<T> implements Iterator<T> {
            TreeMap.Entry<K,V> lastReturned;
            TreeMap.Entry<K,V> next;
            final Object fenceKey;
            int expectedModCount;

            SubMapIterator(TreeMap.Entry<K,V> first,
                           TreeMap.Entry<K,V> fence) {
                expectedModCount = m.modCount;
                lastReturned = null;
                next = first;
                fenceKey = fence == null ? UNBOUNDED : fence.key;
            }

            public final boolean hasNext() {
                return next != null && next.key != fenceKey;
            }

            final TreeMap.Entry<K,V> nextEntry() {
                TreeMap.Entry<K,V> e = next;
                if (e == null || e.key == fenceKey)
                    throw new NoSuchElementException();
                if (m.modCount != expectedModCount)
                    throw new ConcurrentModificationException();
                next = successor(e);
                lastReturned = e;
                return e;
            }

            final TreeMap.Entry<K,V> prevEntry() {
                TreeMap.Entry<K,V> e = next;
                if (e == null || e.key == fenceKey)
                    throw new NoSuchElementException();
                if (m.modCount != expectedModCount)
                    throw new ConcurrentModificationException();
                next = predecessor(e);
                lastReturned = e;
                return e;
            }

            final void removeAscending() {
                if (lastReturned == null)
                    throw new IllegalStateException();
                if (m.modCount != expectedModCount)
                    throw new ConcurrentModificationException();
// deleted entries are replaced by their successors
                if (lastReturned.left != null && lastReturned.right != null)
                    next = lastReturned;
                m.deleteEntry(lastReturned);
                lastReturned = null;
                expectedModCount = m.modCount;
            }

            final void removeDescending() {
                if (lastReturned == null)
                    throw new IllegalStateException();
                if (m.modCount != expectedModCount)
                    throw new ConcurrentModificationException();
                m.deleteEntry(lastReturned);
                lastReturned = null;
                expectedModCount = m.modCount;
            }

        }

        final class SubMapEntryIterator extends SubMapIterator<Map.Entry<K,V>> {
            SubMapEntryIterator(TreeMap.Entry<K,V> first,
                                TreeMap.Entry<K,V> fence) {
                super(first, fence);
            }
            public Map.Entry<K,V> next() {
                return nextEntry();
            }
            public void remove() {
                removeAscending();
            }
        }

        final class DescendingSubMapEntryIterator extends SubMapIterator<Map.Entry<K,V>> {
            DescendingSubMapEntryIterator(TreeMap.Entry<K,V> last,
                                          TreeMap.Entry<K,V> fence) {
                super(last, fence);
            }

            public Map.Entry<K,V> next() {
                return prevEntry();
            }
            public void remove() {
                removeDescending();
            }
        }

        // Implement minimal Spliterator as KeySpliterator backup
        final class SubMapKeyIterator extends SubMapIterator<K>
                implements Spliterator<K> {
            SubMapKeyIterator(TreeMap.Entry<K,V> first,
                              TreeMap.Entry<K,V> fence) {
                super(first, fence);
            }
            public K next() {
                return nextEntry().key;
            }
            public void remove() {
                removeAscending();
            }
            public Spliterator<K> trySplit() {
                return null;
            }
            public void forEachRemaining(Consumer<? super K> action) {
                while (hasNext())
                    action.accept(next());
            }
            public boolean tryAdvance(Consumer<? super K> action) {
                if (hasNext()) {
                    action.accept(next());
                    return true;
                }
                return false;
            }
            public long estimateSize() {
                return Long.MAX_VALUE;
            }
            public int characteristics() {
                return Spliterator.DISTINCT | Spliterator.ORDERED |
                        Spliterator.SORTED;
            }
            public final Comparator<? super K>  getComparator() {
                return NavigableSubMap.this.comparator();
            }
        }

        final class DescendingSubMapKeyIterator extends SubMapIterator<K>
                implements Spliterator<K> {
            DescendingSubMapKeyIterator(TreeMap.Entry<K,V> last,
                                        TreeMap.Entry<K,V> fence) {
                super(last, fence);
            }
            public K next() {
                return prevEntry().key;
            }
            public void remove() {
                removeDescending();
            }
            public Spliterator<K> trySplit() {
                return null;
            }
            public void forEachRemaining(Consumer<? super K> action) {
                while (hasNext())
                    action.accept(next());
            }
            public boolean tryAdvance(Consumer<? super K> action) {
                if (hasNext()) {
                    action.accept(next());
                    return true;
                }
                return false;
            }
            public long estimateSize() {
                return Long.MAX_VALUE;
            }
            public int characteristics() {
                return Spliterator.DISTINCT | Spliterator.ORDERED;
            }
        }
    }

    /**
     * @serial include
     */
    static final class AscendingSubMap<K,V> extends NavigableSubMap<K,V> {
        private static final long serialVersionUID = 912986545866124060L;

        AscendingSubMap(TreeMap<K,V> m,
                        boolean fromStart, K lo, boolean loInclusive,
                        boolean toEnd,     K hi, boolean hiInclusive) {
            super(m, fromStart, lo, loInclusive, toEnd, hi, hiInclusive);
        }

        public Comparator<? super K> comparator() {
            return m.comparator();
        }

        public NavigableMap<K,V> subMap(K fromKey, boolean fromInclusive,
                                        K toKey,   boolean toInclusive) {
            if (!inRange(fromKey, fromInclusive))
                throw new IllegalArgumentException("fromKey out of range");
            if (!inRange(toKey, toInclusive))
                throw new IllegalArgumentException("toKey out of range");
            return new AscendingSubMap<>(m,
                    false, fromKey, fromInclusive,
                    false, toKey,   toInclusive);
        }

        public NavigableMap<K,V> headMap(K toKey, boolean inclusive) {
            if (!inRange(toKey, inclusive))
                throw new IllegalArgumentException("toKey out of range");
            return new AscendingSubMap<>(m,
                    fromStart, lo,    loInclusive,
                    false,     toKey, inclusive);
        }

        public NavigableMap<K,V> tailMap(K fromKey, boolean inclusive) {
            if (!inRange(fromKey, inclusive))
                throw new IllegalArgumentException("fromKey out of range");
            return new AscendingSubMap<>(m,
                    false, fromKey, inclusive,
                    toEnd, hi,      hiInclusive);
        }

        public NavigableMap<K,V> descendingMap() {
            NavigableMap<K,V> mv = descendingMapView;
            return (mv != null) ? mv :
                    (descendingMapView =
                            new DescendingSubMap<>(m,
                                    fromStart, lo, loInclusive,
                                    toEnd,     hi, hiInclusive));
        }

        Iterator<K> keyIterator() {
            return new SubMapKeyIterator(absLowest(), absHighFence());
        }

        Spliterator<K> keySpliterator() {
            return new SubMapKeyIterator(absLowest(), absHighFence());
        }

        Iterator<K> descendingKeyIterator() {
            return new DescendingSubMapKeyIterator(absHighest(), absLowFence());
        }

        final class AscendingEntrySetView extends EntrySetView {
            public Iterator<Map.Entry<K,V>> iterator() {
                return new SubMapEntryIterator(absLowest(), absHighFence());
            }
        }

        public Set<Map.Entry<K,V>> entrySet() {
            EntrySetView es = entrySetView;
            return (es != null) ? es : (entrySetView = new AscendingEntrySetView());
        }

        TreeMap.Entry<K,V> subLowest()       { return absLowest(); }
        TreeMap.Entry<K,V> subHighest()      { return absHighest(); }
        TreeMap.Entry<K,V> subCeiling(K key) { return absCeiling(key); }
        TreeMap.Entry<K,V> subHigher(K key)  { return absHigher(key); }
        TreeMap.Entry<K,V> subFloor(K key)   { return absFloor(key); }
        TreeMap.Entry<K,V> subLower(K key)   { return absLower(key); }
    }

    /**
     * @serial include
     */
    static final class DescendingSubMap<K,V>  extends NavigableSubMap<K,V> {
        private static final long serialVersionUID = 912986545866120460L;
        DescendingSubMap(TreeMap<K,V> m,
                         boolean fromStart, K lo, boolean loInclusive,
                         boolean toEnd,     K hi, boolean hiInclusive) {
            super(m, fromStart, lo, loInclusive, toEnd, hi, hiInclusive);
        }

        private final Comparator<? super K> reverseComparator =
                Collections.reverseOrder(m.comparator);

        public Comparator<? super K> comparator() {
            return reverseComparator;
        }

        public NavigableMap<K,V> subMap(K fromKey, boolean fromInclusive,
                                        K toKey,   boolean toInclusive) {
            if (!inRange(fromKey, fromInclusive))
                throw new IllegalArgumentException("fromKey out of range");
            if (!inRange(toKey, toInclusive))
                throw new IllegalArgumentException("toKey out of range");
            return new DescendingSubMap<>(m,
                    false, toKey,   toInclusive,
                    false, fromKey, fromInclusive);
        }

        public NavigableMap<K,V> headMap(K toKey, boolean inclusive) {
            if (!inRange(toKey, inclusive))
                throw new IllegalArgumentException("toKey out of range");
            return new DescendingSubMap<>(m,
                    false, toKey, inclusive,
                    toEnd, hi,    hiInclusive);
        }

        public NavigableMap<K,V> tailMap(K fromKey, boolean inclusive) {
            if (!inRange(fromKey, inclusive))
                throw new IllegalArgumentException("fromKey out of range");
            return new DescendingSubMap<>(m,
                    fromStart, lo, loInclusive,
                    false, fromKey, inclusive);
        }

        public NavigableMap<K,V> descendingMap() {
            NavigableMap<K,V> mv = descendingMapView;
            return (mv != null) ? mv :
                    (descendingMapView =
                            new AscendingSubMap<>(m,
                                    fromStart, lo, loInclusive,
                                    toEnd,     hi, hiInclusive));
        }

        Iterator<K> keyIterator() {
            return new DescendingSubMapKeyIterator(absHighest(), absLowFence());
        }

        Spliterator<K> keySpliterator() {
            return new DescendingSubMapKeyIterator(absHighest(), absLowFence());
        }

        Iterator<K> descendingKeyIterator() {
            return new SubMapKeyIterator(absLowest(), absHighFence());
        }

        final class DescendingEntrySetView extends EntrySetView {
            public Iterator<Map.Entry<K,V>> iterator() {
                return new DescendingSubMapEntryIterator(absHighest(), absLowFence());
            }
        }

        public Set<Map.Entry<K,V>> entrySet() {
            EntrySetView es = entrySetView;
            return (es != null) ? es : (entrySetView = new DescendingEntrySetView());
        }

        TreeMap.Entry<K,V> subLowest()       { return absHighest(); }
        TreeMap.Entry<K,V> subHighest()      { return absLowest(); }
        TreeMap.Entry<K,V> subCeiling(K key) { return absFloor(key); }
        TreeMap.Entry<K,V> subHigher(K key)  { return absLower(key); }
        TreeMap.Entry<K,V> subFloor(K key)   { return absCeiling(key); }
        TreeMap.Entry<K,V> subLower(K key)   { return absHigher(key); }
    }

    /**
     * This class exists solely for the sake of serialization
     * compatibility with previous releases of TreeMap that did not
     * support NavigableMap.  It translates an old-version SubMap into
     * a new-version AscendingSubMap. This class is never otherwise
     * used.
     *
     * @serial include
     */
    private class SubMap extends AbstractMap<K,V>
            implements SortedMap<K,V>, java.io.Serializable {
        private static final long serialVersionUID = -6520786458950516097L;
        private boolean fromStart = false, toEnd = false;
        private K fromKey, toKey;
        private Object readResolve() {
            return new AscendingSubMap<>(TreeMap.this,
                    fromStart, fromKey, true,
                    toEnd, toKey, false);
        }
        public Set<Map.Entry<K,V>> entrySet() { throw new InternalError(); }
        public K lastKey() { throw new InternalError(); }
        public K firstKey() { throw new InternalError(); }
        public SortedMap<K,V> subMap(K fromKey, K toKey) { throw new InternalError(); }
        public SortedMap<K,V> headMap(K toKey) { throw new InternalError(); }
        public SortedMap<K,V> tailMap(K fromKey) { throw new InternalError(); }
        public Comparator<? super K> comparator() { throw new InternalError(); }
    }


// Red-black mechanics

    private static final boolean RED   = false;
    private static final boolean BLACK = true;

    /**
     * Node in the Tree.  Doubles as a means to pass key-value pairs back to
     * user (see Map.Entry).
     */

    static final class Entry<K,V> implements Map.Entry<K,V> {
        K key;
        V value;
        Entry<K,V> left;
        Entry<K,V> right;
        Entry<K,V> parent;
        boolean color = BLACK;

        /**
         * Make a new cell with given key, value, and parent, and with
         * {@code null} child links, and BLACK color.
         */
        Entry(K key, V value, Entry<K,V> parent) {
            this.key = key;
            this.value = value;
            this.parent = parent;
        }

        /**
         * Returns the key.
         *
         * @return the key
         */
        public K getKey() {
            return key;
        }

        /**
         * Returns the value associated with the key.
         *
         * @return the value associated with the key
         */
        public V getValue() {
            return value;
        }

        /**
         * Replaces the value currently associated with the key with the given
         * value.
         *
         * @return the value associated with the key before this method was
         *         called
         */
        public V setValue(V value) {
            V oldValue = this.value;
            this.value = value;
            return oldValue;
        }

        public boolean equals(Object o) {
            if (!(o instanceof Map.Entry))
                return false;
            Map.Entry<?,?> e = (Map.Entry<?,?>)o;

            return valEquals(key,e.getKey()) && valEquals(value,e.getValue());
        }

        public int hashCode() {
            int keyHash = (key==null ? 0 : key.hashCode());
            int valueHash = (value==null ? 0 : value.hashCode());
            return keyHash ^ valueHash;
        }

        public String toString() {
            return key + "=" + value;
        }
    }

    /**
     * Returns the first Entry in the TreeMap (according to the TreeMap&#39;s
     * key-sort function).  Returns null if the TreeMap is empty.
     */
    final Entry<K,V> getFirstEntry() {
        Entry<K,V> p = root;
        if (p != null)
            while (p.left != null)
                p = p.left;
        return p;
    }

    /**
     * Returns the last Entry in the TreeMap (according to the TreeMap&#39;s
     * key-sort function).  Returns null if the TreeMap is empty.
     */
    final Entry<K,V> getLastEntry() {
        Entry<K,V> p = root;
        if (p != null)
            while (p.right != null)
                p = p.right;
        return p;
    }

    /**
     * Returns the successor of the specified Entry, or null if no such.
     */
    static <K,V> TreeMap.Entry<K,V> successor(Entry<K,V> t) {
        if (t == null)
            return null;
        else if (t.right != null) {
            Entry<K,V> p = t.right;
            while (p.left != null)
                p = p.left;
            return p;
        } else {
            Entry<K,V> p = t.parent;
            Entry<K,V> ch = t;
            while (p != null && ch == p.right) {
                ch = p;
                p = p.parent;
            }
            return p;
        }
    }

    /**
     * Returns the predecessor of the specified Entry, or null if no such.
     */
    static <K,V> Entry<K,V> predecessor(Entry<K,V> t) {
        if (t == null)
            return null;
        else if (t.left != null) {
            Entry<K,V> p = t.left;
            while (p.right != null)
                p = p.right;
            return p;
        } else {
            Entry<K,V> p = t.parent;
            Entry<K,V> ch = t;
            while (p != null && ch == p.left) {
                ch = p;
                p = p.parent;
            }
            return p;
        }
    }

    /**
     * Balancing operations.
     *
     * Implementations of rebalancings during insertion and deletion are
     * slightly different than the CLR version.  Rather than using dummy
     * nilnodes, we use a set of accessors that deal properly with null.  They
     * are used to avoid messiness surrounding nullness checks in the main
     * algorithms.
     */

    private static <K,V> boolean colorOf(Entry<K,V> p) {
        return (p == null ? BLACK : p.color);
    }

    private static <K,V> Entry<K,V> parentOf(Entry<K,V> p) {
        return (p == null ? null: p.parent);
    }

    private static <K,V> void setColor(Entry<K,V> p, boolean c) {
        if (p != null)
            p.color = c;
    }

    private static <K,V> Entry<K,V> leftOf(Entry<K,V> p) {
        return (p == null) ? null: p.left;
    }

    private static <K,V> Entry<K,V> rightOf(Entry<K,V> p) {
        return (p == null) ? null: p.right;
    }

    /** From CLR */
    private void rotateLeft(Entry<K,V> p) {
        if (p != null) {
            Entry<K,V> r = p.right;
            p.right = r.left;
            if (r.left != null)
                r.left.parent = p;
            r.parent = p.parent;
            if (p.parent == null)
                root = r;
            else if (p.parent.left == p)
                p.parent.left = r;
            else
                p.parent.right = r;
            r.left = p;
            p.parent = r;
        }
    }

    /** From CLR */
    private void rotateRight(Entry<K,V> p) {
        if (p != null) {
            Entry<K,V> l = p.left;
            p.left = l.right;
            if (l.right != null) l.right.parent = p;
            l.parent = p.parent;
            if (p.parent == null)
                root = l;
            else if (p.parent.right == p)
                p.parent.right = l;
            else p.parent.left = l;
            l.right = p;
            p.parent = l;
        }
    }

    /** From CLR */
    private void fixAfterInsertion(Entry<K,V> x) {
        x.color = RED;

        while (x != null && x != root && x.parent.color == RED) {
            if (parentOf(x) == leftOf(parentOf(parentOf(x)))) {
                Entry<K,V> y = rightOf(parentOf(parentOf(x)));
                if (colorOf(y) == RED) {
                    setColor(parentOf(x), BLACK);
                    setColor(y, BLACK);
                    setColor(parentOf(parentOf(x)), RED);
                    x = parentOf(parentOf(x));
                } else {
                    if (x == rightOf(parentOf(x))) {
                        x = parentOf(x);
                        rotateLeft(x);
                    }
                    setColor(parentOf(x), BLACK);
                    setColor(parentOf(parentOf(x)), RED);
                    rotateRight(parentOf(parentOf(x)));
                }
            } else {
                Entry<K,V> y = leftOf(parentOf(parentOf(x)));
                if (colorOf(y) == RED) {
                    setColor(parentOf(x), BLACK);
                    setColor(y, BLACK);
                    setColor(parentOf(parentOf(x)), RED);
                    x = parentOf(parentOf(x));
                } else {
                    if (x == leftOf(parentOf(x))) {
                        x = parentOf(x);
                        rotateRight(x);
                    }
                    setColor(parentOf(x), BLACK);
                    setColor(parentOf(parentOf(x)), RED);
                    rotateLeft(parentOf(parentOf(x)));
                }
            }
        }
        root.color = BLACK;
    }

    /**
     * Delete node p, and then rebalance the tree.
     */
    private void deleteEntry(Entry<K,V> p) {
        modCount++;
        size--;

// If strictly internal, copy successor&#39;s element to p and then make p
        // point to successor.
        if (p.left != null && p.right != null) {
            Entry<K,V> s = successor(p);
            p.key = s.key;
            p.value = s.value;
            p = s;
        } // p has 2 children

        // Start fixup at replacement node, if it exists.
        Entry<K,V> replacement = (p.left != null ? p.left : p.right);

        if (replacement != null) {
// Link replacement to parent
            replacement.parent = p.parent;
            if (p.parent == null)
                root = replacement;
            else if (p == p.parent.left)
                p.parent.left  = replacement;
            else
                p.parent.right = replacement;

// Null out links so they are OK to use by fixAfterDeletion.
            p.left = p.right = p.parent = null;

// Fix replacement
            if (p.color == BLACK)
                fixAfterDeletion(replacement);
        } else if (p.parent == null) { // return if we are the only node.
            root = null;
        } else { //  No children. Use self as phantom replacement and unlink.
            if (p.color == BLACK)
                fixAfterDeletion(p);

            if (p.parent != null) {
                if (p == p.parent.left)
                    p.parent.left = null;
                else if (p == p.parent.right)
                    p.parent.right = null;
                p.parent = null;
            }
        }
    }

    /** From CLR */
    private void fixAfterDeletion(Entry<K,V> x) {
        while (x != root && colorOf(x) == BLACK) {
            if (x == leftOf(parentOf(x))) {
                Entry<K,V> sib = rightOf(parentOf(x));

                if (colorOf(sib) == RED) {
                    setColor(sib, BLACK);
                    setColor(parentOf(x), RED);
                    rotateLeft(parentOf(x));
                    sib = rightOf(parentOf(x));
                }

                if (colorOf(leftOf(sib))  == BLACK &&
                        colorOf(rightOf(sib)) == BLACK) {
                    setColor(sib, RED);
                    x = parentOf(x);
                } else {
                    if (colorOf(rightOf(sib)) == BLACK) {
                        setColor(leftOf(sib), BLACK);
                        setColor(sib, RED);
                        rotateRight(sib);
                        sib = rightOf(parentOf(x));
                    }
                    setColor(sib, colorOf(parentOf(x)));
                    setColor(parentOf(x), BLACK);
                    setColor(rightOf(sib), BLACK);
                    rotateLeft(parentOf(x));
                    x = root;
                }
            } else { // symmetric
                Entry<K,V> sib = leftOf(parentOf(x));

                if (colorOf(sib) == RED) {
                    setColor(sib, BLACK);
                    setColor(parentOf(x), RED);
                    rotateRight(parentOf(x));
                    sib = leftOf(parentOf(x));
                }

                if (colorOf(rightOf(sib)) == BLACK &&
                        colorOf(leftOf(sib)) == BLACK) {
                    setColor(sib, RED);
                    x = parentOf(x);
                } else {
                    if (colorOf(leftOf(sib)) == BLACK) {
                        setColor(rightOf(sib), BLACK);
                        setColor(sib, RED);
                        rotateLeft(sib);
                        sib = leftOf(parentOf(x));
                    }
                    setColor(sib, colorOf(parentOf(x)));
                    setColor(parentOf(x), BLACK);
                    setColor(leftOf(sib), BLACK);
                    rotateRight(parentOf(x));
                    x = root;
                }
            }
        }

        setColor(x, BLACK);
    }

    private static final long serialVersionUID = 919286545866124006L;

    /**
     * Save the state of the {@code TreeMap} instance to a stream (i.e.,
     * serialize it).
     *
     * @serialData The <em>size</em> of the TreeMap (the number of key-value
     *             mappings) is emitted (int), followed by the key (Object)
     *             and value (Object) for each key-value mapping represented
     *             by the TreeMap. The key-value mappings are emitted in
     *             key-order (as determined by the TreeMap&#39;s Comparator,
     *             or by the keys&#39; natural ordering if the TreeMap has no
     *             Comparator).
     */
    private void writeObject(java.io.ObjectOutputStream s)
            throws java.io.IOException {
// Write out the Comparator and any hidden stuff
        s.defaultWriteObject();

// Write out size (number of Mappings)
        s.writeInt(size);

// Write out keys and values (alternating)
        for (Iterator<Map.Entry<K,V>> i = entrySet().iterator(); i.hasNext(); ) {
            Map.Entry<K,V> e = i.next();
            s.writeObject(e.getKey());
            s.writeObject(e.getValue());
        }
    }

    /**
     * Reconstitute the {@code TreeMap} instance from a stream (i.e.,
     * deserialize it).
     */
    private void readObject(final java.io.ObjectInputStream s)
            throws java.io.IOException, ClassNotFoundException {
// Read in the Comparator and any hidden stuff
        s.defaultReadObject();

// Read in size
        int size = s.readInt();

        buildFromSorted(size, null, s, null);
    }

    /** Intended to be called only from TreeSet.readObject */
    void readTreeSet(int size, java.io.ObjectInputStream s, V defaultVal)
            throws java.io.IOException, ClassNotFoundException {
        buildFromSorted(size, null, s, defaultVal);
    }

    /** Intended to be called only from TreeSet.addAll */
    void addAllForTreeSet(SortedSet<? extends K> set, V defaultVal) {
        try {
            buildFromSorted(set.size(), set.iterator(), null, defaultVal);
        } catch (java.io.IOException cannotHappen) {
        } catch (ClassNotFoundException cannotHappen) {
        }
    }


    /**
     * Linear time tree building algorithm from sorted data.  Can accept keys
     * and/or values from iterator or stream. This leads to too many
     * parameters, but seems better than alternatives.  The four formats
     * that this method accepts are:
     *
     *    1) An iterator of Map.Entries.  (it != null, defaultVal == null).
     *    2) An iterator of keys.         (it != null, defaultVal != null).
     *    3) A stream of alternating serialized keys and values.
     *                                   (it == null, defaultVal == null).
     *    4) A stream of serialized keys. (it == null, defaultVal != null).
     *
     * It is assumed that the comparator of the TreeMap is already set prior
     * to calling this method.
     *
     * @param size the number of keys (or key-value pairs) to be read from
     *        the iterator or stream
     * @param it If non-null, new entries are created from entries
     *        or keys read from this iterator.
     * @param str If non-null, new entries are created from keys and
     *        possibly values read from this stream in serialized form.
     *        Exactly one of it and str should be non-null.
     * @param defaultVal if non-null, this default value is used for
     *        each value in the map.  If null, each value is read from
     *        iterator or stream, as described above.
     * @throws java.io.IOException propagated from stream reads. This cannot
     *         occur if str is null.
     * @throws ClassNotFoundException propagated from readObject.
     *         This cannot occur if str is null.
     */
    private void buildFromSorted(int size, Iterator<?> it,
                                 java.io.ObjectInputStream str,
                                 V defaultVal)
            throws  java.io.IOException, ClassNotFoundException {
        this.size = size;
        root = buildFromSorted(0, 0, size-1, computeRedLevel(size),
                it, str, defaultVal);
    }

    /**
     * Recursive "helper method" that does the real work of the
     * previous method.  Identically named parameters have
     * identical definitions.  Additional parameters are documented below.
     * It is assumed that the comparator and size fields of the TreeMap are
     * already set prior to calling this method.  (It ignores both fields.)
     *
     * @param level the current level of tree. Initial call should be 0.
     * @param lo the first element index of this subtree. Initial should be 0.
     * @param hi the last element index of this subtree.  Initial should be
     *        size-1.
     * @param redLevel the level at which nodes should be red.
     *        Must be equal to computeRedLevel for tree of this size.
     */
    @SuppressWarnings("unchecked")
    private final Entry<K,V> buildFromSorted(int level, int lo, int hi,
                                             int redLevel,
                                             Iterator<?> it,
                                             java.io.ObjectInputStream str,
                                             V defaultVal)
            throws  java.io.IOException, ClassNotFoundException {
/*
         * Strategy: The root is the middlemost element. To get to it, we
         * have to first recursively construct the entire left subtree,
         * so as to grab all of its elements. We can then proceed with right
         * subtree.
         *
         * The lo and hi arguments are the minimum and maximum
         * indices to pull out of the iterator or stream for current subtree.
         * They are not actually indexed, we just proceed sequentially,
         * ensuring that items are extracted in corresponding order.
         */

        if (hi < lo) return null;

        int mid = (lo + hi) >>> 1;

        Entry<K,V> left  = null;
        if (lo < mid)
            left = buildFromSorted(level+1, lo, mid - 1, redLevel,
                    it, str, defaultVal);

// extract key and/or value from iterator or stream
        K key;
        V value;
        if (it != null) {
            if (defaultVal==null) {
                Map.Entry<?,?> entry = (Map.Entry<?,?>)it.next();
                key = (K)entry.getKey();
                value = (V)entry.getValue();
            } else {
                key = (K)it.next();
                value = defaultVal;
            }
        } else { // use stream
            key = (K) str.readObject();
            value = (defaultVal != null ? defaultVal : (V) str.readObject());
        }

        Entry<K,V> middle =  new Entry<>(key, value, null);

// color nodes in non-full bottommost level red
        if (level == redLevel)
            middle.color = RED;

        if (left != null) {
            middle.left = left;
            left.parent = middle;
        }

        if (mid < hi) {
            Entry<K,V> right = buildFromSorted(level+1, mid+1, hi, redLevel,
                    it, str, defaultVal);
            middle.right = right;
            right.parent = middle;
        }

        return middle;
    }

    /**
     * Find the level down to which to assign all nodes BLACK.  This is the
     * last `full&#39; level of the complete binary tree produced by
     * buildTree. The remaining nodes are colored RED. (This makes a `nice&#39;
     * set of color assignments wrt future insertions.) This level number is
     * computed by finding the number of splits needed to reach the zeroeth
     * node.  (The answer is ~lg(N), but in any case must be computed by same
     * quick O(lg(N)) loop.)
     */
    private static int computeRedLevel(int sz) {
        int level = 0;
        for (int m = sz - 1; m >= 0; m = m / 2 - 1)
            level++;
        return level;
    }

    /**
     * Currently, we support Spliterator-based versions only for the
     * full map, in either plain of descending form, otherwise relying
     * on defaults because size estimation for submaps would dominate
     * costs. The type tests needed to check these for key views are
     * not very nice but avoid disrupting existing class
     * structures. Callers must use plain default spliterators if this
     * returns null.
     */
    static <K> Spliterator<K> keySpliteratorFor(NavigableMap<K,?> m) {
        if (m instanceof TreeMap) {
            @SuppressWarnings("unchecked") TreeMap<K,Object> t =
                    (TreeMap<K,Object>) m;
            return t.keySpliterator();
        }
        if (m instanceof DescendingSubMap) {
            @SuppressWarnings("unchecked") DescendingSubMap<K,?> dm =
                    (DescendingSubMap<K,?>) m;
            TreeMap<K,?> tm = dm.m;
            if (dm == tm.descendingMap) {
                @SuppressWarnings("unchecked") TreeMap<K,Object> t =
                        (TreeMap<K,Object>) tm;
                return t.descendingKeySpliterator();
            }
        }
        @SuppressWarnings("unchecked") NavigableSubMap<K,?> sm =
                (NavigableSubMap<K,?>) m;
        return sm.keySpliterator();
    }

    final Spliterator<K> keySpliterator() {
        return new KeySpliterator<K,V>(this, null, null, 0, -1, 0);
    }

    final Spliterator<K> descendingKeySpliterator() {
        return new DescendingKeySpliterator<K,V>(this, null, null, 0, -2, 0);
    }

    /**
     * Base class for spliterators.  Iteration starts at a given
     * origin and continues up to but not including a given fence (or
     * null for end).  At top-level, for ascending cases, the first
     * split uses the root as left-fence/right-origin. From there,
     * right-hand splits replace the current fence with its left
     * child, also serving as origin for the split-off spliterator.
     * Left-hands are symmetric. Descending versions place the origin
     * at the end and invert ascending split rules.  This base class
     * is non-commital about directionality, or whether the top-level
     * spliterator covers the whole tree. This means that the actual
     * split mechanics are located in subclasses. Some of the subclass
     * trySplit methods are identical (except for return types), but
     * not nicely factorable.
     *
     * Currently, subclass versions exist only for the full map
     * (including descending keys via its descendingMap).  Others are
     * possible but currently not worthwhile because submaps require
     * O(n) computations to determine size, which substantially limits
     * potential speed-ups of using custom Spliterators versus default
     * mechanics.
     *
     * To boostrap initialization, external constructors use
     * negative size estimates: -1 for ascend, -2 for descend.
     */
    static class TreeMapSpliterator<K,V> {
        final TreeMap<K,V> tree;
        TreeMap.Entry<K,V> current; // traverser; initially first node in range
        TreeMap.Entry<K,V> fence;   // one past last, or null
        int side;                   // 0: top, -1: is a left split, +1: right
        int est;                    // size estimate (exact only for top-level)
        int expectedModCount;       // for CME checks

        TreeMapSpliterator(TreeMap<K,V> tree,
                           TreeMap.Entry<K,V> origin, TreeMap.Entry<K,V> fence,
                           int side, int est, int expectedModCount) {
            this.tree = tree;
            this.current = origin;
            this.fence = fence;
            this.side = side;
            this.est = est;
            this.expectedModCount = expectedModCount;
        }

        final int getEstimate() { // force initialization
            int s; TreeMap<K,V> t;
            if ((s = est) < 0) {
                if ((t = tree) != null) {
                    current = (s == -1) ? t.getFirstEntry() : t.getLastEntry();
                    s = est = t.size;
                    expectedModCount = t.modCount;
                }
                else
                    s = est = 0;
            }
            return s;
        }

        public final long estimateSize() {
            return (long)getEstimate();
        }
    }

    static final class KeySpliterator<K,V>
            extends TreeMapSpliterator<K,V>
            implements Spliterator<K> {
        KeySpliterator(TreeMap<K,V> tree,
                       TreeMap.Entry<K,V> origin, TreeMap.Entry<K,V> fence,
                       int side, int est, int expectedModCount) {
            super(tree, origin, fence, side, est, expectedModCount);
        }

        public KeySpliterator<K,V> trySplit() {
            if (est < 0)
                getEstimate(); // force initialization
            int d = side;
            TreeMap.Entry<K,V> e = current, f = fence,
                    s = ((e == null || e == f) ? null :      // empty
                            (d == 0)              ? tree.root : // was top
                                    (d >  0)              ? e.right :   // was right
                                            (d <  0 && f != null) ? f.left :    // was left
                                                    null);
            if (s != null && s != e && s != f &&
                    tree.compare(e.key, s.key) < 0) {        // e not already past s
                side = 1;
                return new KeySpliterator<>
                        (tree, e, current = s, -1, est >>>= 1, expectedModCount);
            }
            return null;
        }

        public void forEachRemaining(Consumer<? super K> action) {
            if (action == null)
                throw new NullPointerException();
            if (est < 0)
                getEstimate(); // force initialization
            TreeMap.Entry<K,V> f = fence, e, p, pl;
            if ((e = current) != null && e != f) {
                current = f; // exhaust
                do {
                    action.accept(e.key);
                    if ((p = e.right) != null) {
                        while ((pl = p.left) != null)
                            p = pl;
                    }
                    else {
                        while ((p = e.parent) != null && e == p.right)
                            e = p;
                    }
                } while ((e = p) != null && e != f);
                if (tree.modCount != expectedModCount)
                    throw new ConcurrentModificationException();
            }
        }

        public boolean tryAdvance(Consumer<? super K> action) {
            TreeMap.Entry<K,V> e;
            if (action == null)
                throw new NullPointerException();
            if (est < 0)
                getEstimate(); // force initialization
            if ((e = current) == null || e == fence)
                return false;
            current = successor(e);
            action.accept(e.key);
            if (tree.modCount != expectedModCount)
                throw new ConcurrentModificationException();
            return true;
        }

        public int characteristics() {
            return (side == 0 ? Spliterator.SIZED : 0) |
                    Spliterator.DISTINCT | Spliterator.SORTED | Spliterator.ORDERED;
        }

        public final Comparator<? super K>  getComparator() {
            return tree.comparator;
        }

    }

    static final class DescendingKeySpliterator<K,V>
            extends TreeMapSpliterator<K,V>
            implements Spliterator<K> {
        DescendingKeySpliterator(TreeMap<K,V> tree,
                                 TreeMap.Entry<K,V> origin, TreeMap.Entry<K,V> fence,
                                 int side, int est, int expectedModCount) {
            super(tree, origin, fence, side, est, expectedModCount);
        }

        public DescendingKeySpliterator<K,V> trySplit() {
            if (est < 0)
                getEstimate(); // force initialization
            int d = side;
            TreeMap.Entry<K,V> e = current, f = fence,
                    s = ((e == null || e == f) ? null :      // empty
                            (d == 0)              ? tree.root : // was top
                                    (d <  0)              ? e.left :    // was left
                                            (d >  0 && f != null) ? f.right :   // was right
                                                    null);
            if (s != null && s != e && s != f &&
                    tree.compare(e.key, s.key) > 0) {       // e not already past s
                side = 1;
                return new DescendingKeySpliterator<>
                        (tree, e, current = s, -1, est >>>= 1, expectedModCount);
            }
            return null;
        }

        public void forEachRemaining(Consumer<? super K> action) {
            if (action == null)
                throw new NullPointerException();
            if (est < 0)
                getEstimate(); // force initialization
            TreeMap.Entry<K,V> f = fence, e, p, pr;
            if ((e = current) != null && e != f) {
                current = f; // exhaust
                do {
                    action.accept(e.key);
                    if ((p = e.left) != null) {
                        while ((pr = p.right) != null)
                            p = pr;
                    }
                    else {
                        while ((p = e.parent) != null && e == p.left)
                            e = p;
                    }
                } while ((e = p) != null && e != f);
                if (tree.modCount != expectedModCount)
                    throw new ConcurrentModificationException();
            }
        }

        public boolean tryAdvance(Consumer<? super K> action) {
            TreeMap.Entry<K,V> e;
            if (action == null)
                throw new NullPointerException();
            if (est < 0)
                getEstimate(); // force initialization
            if ((e = current) == null || e == fence)
                return false;
            current = predecessor(e);
            action.accept(e.key);
            if (tree.modCount != expectedModCount)
                throw new ConcurrentModificationException();
            return true;
        }

        public int characteristics() {
            return (side == 0 ? Spliterator.SIZED : 0) |
                    Spliterator.DISTINCT | Spliterator.ORDERED;
        }
    }

    static final class ValueSpliterator<K,V>
            extends TreeMapSpliterator<K,V>
            implements Spliterator<V> {
        ValueSpliterator(TreeMap<K,V> tree,
                         TreeMap.Entry<K,V> origin, TreeMap.Entry<K,V> fence,
                         int side, int est, int expectedModCount) {
            super(tree, origin, fence, side, est, expectedModCount);
        }

        public ValueSpliterator<K,V> trySplit() {
            if (est < 0)
                getEstimate(); // force initialization
            int d = side;
            TreeMap.Entry<K,V> e = current, f = fence,
                    s = ((e == null || e == f) ? null :      // empty
                            (d == 0)              ? tree.root : // was top
                                    (d >  0)              ? e.right :   // was right
                                            (d <  0 && f != null) ? f.left :    // was left
                                                    null);
            if (s != null && s != e && s != f &&
                    tree.compare(e.key, s.key) < 0) {        // e not already past s
                side = 1;
                return new ValueSpliterator<>
                        (tree, e, current = s, -1, est >>>= 1, expectedModCount);
            }
            return null;
        }

        public void forEachRemaining(Consumer<? super V> action) {
            if (action == null)
                throw new NullPointerException();
            if (est < 0)
                getEstimate(); // force initialization
            TreeMap.Entry<K,V> f = fence, e, p, pl;
            if ((e = current) != null && e != f) {
                current = f; // exhaust
                do {
                    action.accept(e.value);
                    if ((p = e.right) != null) {
                        while ((pl = p.left) != null)
                            p = pl;
                    }
                    else {
                        while ((p = e.parent) != null && e == p.right)
                            e = p;
                    }
                } while ((e = p) != null && e != f);
                if (tree.modCount != expectedModCount)
                    throw new ConcurrentModificationException();
            }
        }

        public boolean tryAdvance(Consumer<? super V> action) {
            TreeMap.Entry<K,V> e;
            if (action == null)
                throw new NullPointerException();
            if (est < 0)
                getEstimate(); // force initialization
            if ((e = current) == null || e == fence)
                return false;
            current = successor(e);
            action.accept(e.value);
            if (tree.modCount != expectedModCount)
                throw new ConcurrentModificationException();
            return true;
        }

        public int characteristics() {
            return (side == 0 ? Spliterator.SIZED : 0) | Spliterator.ORDERED;
        }
    }

    static final class EntrySpliterator<K,V>
            extends TreeMapSpliterator<K,V>
            implements Spliterator<Map.Entry<K,V>> {
        EntrySpliterator(TreeMap<K,V> tree,
                         TreeMap.Entry<K,V> origin, TreeMap.Entry<K,V> fence,
                         int side, int est, int expectedModCount) {
            super(tree, origin, fence, side, est, expectedModCount);
        }

        public EntrySpliterator<K,V> trySplit() {
            if (est < 0)
                getEstimate(); // force initialization
            int d = side;
            TreeMap.Entry<K,V> e = current, f = fence,
                    s = ((e == null || e == f) ? null :      // empty
                            (d == 0)              ? tree.root : // was top
                                    (d >  0)              ? e.right :   // was right
                                            (d <  0 && f != null) ? f.left :    // was left
                                                    null);
            if (s != null && s != e && s != f &&
                    tree.compare(e.key, s.key) < 0) {        // e not already past s
                side = 1;
                return new EntrySpliterator<>
                        (tree, e, current = s, -1, est >>>= 1, expectedModCount);
            }
            return null;
        }

        public void forEachRemaining(Consumer<? super Map.Entry<K, V>> action) {
            if (action == null)
                throw new NullPointerException();
            if (est < 0)
                getEstimate(); // force initialization
            TreeMap.Entry<K,V> f = fence, e, p, pl;
            if ((e = current) != null && e != f) {
                current = f; // exhaust
                do {
                    action.accept(e);
                    if ((p = e.right) != null) {
                        while ((pl = p.left) != null)
                            p = pl;
                    }
                    else {
                        while ((p = e.parent) != null && e == p.right)
                            e = p;
                    }
                } while ((e = p) != null && e != f);
                if (tree.modCount != expectedModCount)
                    throw new ConcurrentModificationException();
            }
        }

        public boolean tryAdvance(Consumer<? super Map.Entry<K,V>> action) {
            TreeMap.Entry<K,V> e;
            if (action == null)
                throw new NullPointerException();
            if (est < 0)
                getEstimate(); // force initialization
            if ((e = current) == null || e == fence)
                return false;
            current = successor(e);
            action.accept(e);
            if (tree.modCount != expectedModCount)
                throw new ConcurrentModificationException();
            return true;
        }

        public int characteristics() {
            return (side == 0 ? Spliterator.SIZED : 0) |
                    Spliterator.DISTINCT | Spliterator.SORTED | Spliterator.ORDERED;
        }

        @Override
        public Comparator<Map.Entry<K, V>> getComparator() {
// Adapt or create a key-based comparator
            if (tree.comparator != null) {
                return Map.Entry.comparingByKey(tree.comparator);
            }
            else {
                return (Comparator<Map.Entry<K, V>> & Serializable) (e1, e2) -> {
                    @SuppressWarnings("unchecked")
                    Comparable<? super K> k1 = (Comparable<? super K>) e1.getKey();
                    return k1.compareTo(e2.getKey());
                };
            }
        }
    }
}
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