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/* __ *\
** ________ ___ / / ___ Scala API **
** / __/ __// _ | / / / _ | (c) 2003-2013, LAMP/EPFL **
** __\ \/ /__/ __ |/ /__/ __ | http://scala-lang.org/ **
** /____/\___/_/ |_/____/_/ | | **
** |/ **
\* */
package scala
package collection
package mutable
/**
* An immutable AVL Tree implementation formerly used by mutable.TreeSet
*
* @author Lucien Pereira
*/
@deprecated("AVLTree and its related classes are being removed from the standard library since they're not different enough from RedBlackTree to justify keeping them.", "2.11.2")
private[mutable] sealed trait AVLTree[+A] extends Serializable {
def balance: Int
def depth: Int
def iterator[B >: A]: Iterator[B] = Iterator.empty
def contains[B >: A](value: B, ordering: Ordering[B]): Boolean = false
/**
* Returns a new tree containing the given element.
* Throws an IllegalArgumentException if element is already present.
*
*/
def insert[B >: A](value: B, ordering: Ordering[B]): AVLTree[B] = Node(value, Leaf, Leaf)
/**
* Return a new tree which not contains given element.
*
*/
def remove[B >: A](value: B, ordering: Ordering[B]): AVLTree[A] =
throw new NoSuchElementException(String.valueOf(value))
/**
* Return a tuple containing the smallest element of the provided tree
* and a new tree from which this element has been extracted.
*
*/
def removeMin[B >: A]: (B, AVLTree[B]) = sys.error("Should not happen.")
/**
* Return a tuple containing the biggest element of the provided tree
* and a new tree from which this element has been extracted.
*
*/
def removeMax[B >: A]: (B, AVLTree[B]) = sys.error("Should not happen.")
def rebalance[B >: A]: AVLTree[B] = this
def leftRotation[B >: A]: Node[B] = sys.error("Should not happen.")
def rightRotation[B >: A]: Node[B] = sys.error("Should not happen.")
def doubleLeftRotation[B >: A]: Node[B] = sys.error("Should not happen.")
def doubleRightRotation[B >: A]: Node[B] = sys.error("Should not happen.")
}
/**
* @deprecated("AVLTree and its related classes are being removed from the standard library since they're not different enough from RedBlackTree to justify keeping them.", "2.11.0")
*/
private case object Leaf extends AVLTree[Nothing] {
override val balance: Int = 0
override val depth: Int = -1
}
/**
* @deprecated("AVLTree and its related classes are being removed from the standard library since they're not different enough from RedBlackTree to justify keeping them.", "2.11.0")
*/
private case class Node[A](data: A, left: AVLTree[A], right: AVLTree[A]) extends AVLTree[A] {
override val balance: Int = right.depth - left.depth
override val depth: Int = math.max(left.depth, right.depth) + 1
override def iterator[B >: A]: Iterator[B] = new AVLIterator(this)
override def contains[B >: A](value: B, ordering: Ordering[B]) = {
val ord = ordering.compare(value, data)
if (0 == ord)
true
else if (ord < 0)
left.contains(value, ordering)
else
right.contains(value, ordering)
}
/**
* Returns a new tree containing the given element.
* Throws an IllegalArgumentException if element is already present.
*
*/
override def insert[B >: A](value: B, ordering: Ordering[B]) = {
val ord = ordering.compare(value, data)
if (0 == ord)
throw new IllegalArgumentException()
else if (ord < 0)
Node(data, left.insert(value, ordering), right).rebalance
else
Node(data, left, right.insert(value, ordering)).rebalance
}
/**
* Return a new tree which not contains given element.
*
*/
override def remove[B >: A](value: B, ordering: Ordering[B]): AVLTree[A] = {
val ord = ordering.compare(value, data)
if(ord == 0) {
if (Leaf == left) {
if (Leaf == right) {
Leaf
} else {
val (min, newRight) = right.removeMin
Node(min, left, newRight).rebalance
}
} else {
val (max, newLeft) = left.removeMax
Node(max, newLeft, right).rebalance
}
} else if (ord < 0) {
Node(data, left.remove(value, ordering), right).rebalance
} else {
Node(data, left, right.remove(value, ordering)).rebalance
}
}
/**
* Return a tuple containing the smallest element of the provided tree
* and a new tree from which this element has been extracted.
*
*/
override def removeMin[B >: A]: (B, AVLTree[B]) = {
if (Leaf == left)
(data, right)
else {
val (min, newLeft) = left.removeMin
(min, Node(data, newLeft, right).rebalance)
}
}
/**
* Return a tuple containing the biggest element of the provided tree
* and a new tree from which this element has been extracted.
*
*/
override def removeMax[B >: A]: (B, AVLTree[B]) = {
if (Leaf == right)
(data, left)
else {
val (max, newRight) = right.removeMax
(max, Node(data, left, newRight).rebalance)
}
}
override def rebalance[B >: A] = {
if (-2 == balance) {
if (1 == left.balance)
doubleRightRotation
else
rightRotation
} else if (2 == balance) {
if (-1 == right.balance)
doubleLeftRotation
else
leftRotation
} else {
this
}
}
override def leftRotation[B >: A] = {
if (Leaf != right) {
val r: Node[A] = right.asInstanceOf[Node[A]]
Node(r.data, Node(data, left, r.left), r.right)
} else sys.error("Should not happen.")
}
override def rightRotation[B >: A] = {
if (Leaf != left) {
val l: Node[A] = left.asInstanceOf[Node[A]]
Node(l.data, l.left, Node(data, l.right, right))
} else sys.error("Should not happen.")
}
override def doubleLeftRotation[B >: A] = {
if (Leaf != right) {
val r: Node[A] = right.asInstanceOf[Node[A]]
// Let's save an instanceOf by 'inlining' the left rotation
val rightRotated = r.rightRotation
Node(rightRotated.data, Node(data, left, rightRotated.left), rightRotated.right)
} else sys.error("Should not happen.")
}
override def doubleRightRotation[B >: A] = {
if (Leaf != left) {
val l: Node[A] = left.asInstanceOf[Node[A]]
// Let's save an instanceOf by 'inlining' the right rotation
val leftRotated = l.leftRotation
Node(leftRotated.data, leftRotated.left, Node(data, leftRotated.right, right))
} else sys.error("Should not happen.")
}
}
/**
* @deprecated("AVLTree and its related classes are being removed from the standard library since they're not different enough from RedBlackTree to justify keeping them.", "2.11.0")
*/
private class AVLIterator[A](root: Node[A]) extends Iterator[A] {
val stack = mutable.ArrayStack[Node[A]](root)
diveLeft()
private def diveLeft(): Unit = {
if (Leaf != stack.head.left) {
val left: Node[A] = stack.head.left.asInstanceOf[Node[A]]
stack.push(left)
diveLeft()
}
}
private def engageRight(): Unit = {
if (Leaf != stack.head.right) {
val right: Node[A] = stack.head.right.asInstanceOf[Node[A]]
stack.pop()
stack.push(right)
diveLeft()
} else
stack.pop()
}
override def hasNext: Boolean = !stack.isEmpty
override def next(): A = {
if (stack.isEmpty)
throw new NoSuchElementException()
else {
val result = stack.head.data
// Let's maintain stack for the next invocation
engageRight()
result
}
}
}
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