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641 lines
14 KiB
C++
641 lines
14 KiB
C++
#include "RedBlackTree.h"
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#include <limits>
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#include "PtrList.h"
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#ifdef min
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#undef min
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#endif
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#ifdef max
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#undef max
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#endif
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void RedBlackTreeIterator::next()
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{
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if (node)
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node = tree->GetSuccessorOf(node);
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}
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bool RedBlackTreeIterator::get(RedBlackTreeIterator::val_t *val)
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{
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if (node)
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{
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*val = node->GetEntry();
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return true;
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}
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return false;
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}
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RedBlackTreeNode::RedBlackTreeNode()
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{
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}
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RedBlackTreeNode::RedBlackTreeNode(key_t _key, val_t newEntry)
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: storedEntry(newEntry) , key(_key)
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{
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}
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RedBlackTreeNode::~RedBlackTreeNode()
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{
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}
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RedBlackTreeNode::val_t RedBlackTreeNode::GetEntry() const
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{
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return storedEntry;
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}
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RedBlackTree::RedBlackTree()
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{
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nil = new RedBlackTreeNode;
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nil->left = nil->right = nil->parent = nil;
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nil->red = 0;
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nil->key = std::numeric_limits<key_t>::min();
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nil->storedEntry = NULL;
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root = new RedBlackTreeNode;
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root->parent = root->left = root->right = nil;
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root->key = std::numeric_limits<key_t>::max();
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root->red=0;
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root->storedEntry = NULL;
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numElements = 0;
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}
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RedBlackTreeIterator RedBlackTree::end()
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{
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RedBlackTreeIterator temp;
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return temp;
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}
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RedBlackTreeIterator RedBlackTree::begin()
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{
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return RedBlackTreeIterator(root->left, this);
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}
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/***********************************************************************/
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/* FUNCTION: LeftRotate */
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/**/
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/* INPUTS: the node to rotate on */
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/**/
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/* OUTPUT: None */
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/**/
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/* Modifies Input: this, x */
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/**/
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/* EFFECTS: Rotates as described in _Introduction_To_Algorithms by */
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/* Cormen, Leiserson, Rivest (Chapter 14). Basically this */
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/* makes the parent of x be to the left of x, x the parent of */
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/* its parent before the rotation and fixes other pointers */
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/* accordingly. */
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/***********************************************************************/
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void RedBlackTree::LeftRotate(RedBlackTreeNode* x)
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{
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RedBlackTreeNode* y;
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/* I originally wrote this function to use the sentinel for */
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/* nil to avoid checking for nil. However this introduces a */
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/* very subtle bug because sometimes this function modifies */
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/* the parent pointer of nil. This can be a problem if a */
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/* function which calls LeftRotate also uses the nil sentinel */
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/* and expects the nil sentinel's parent pointer to be unchanged */
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/* after calling this function. For example, when DeleteFixUP */
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/* calls LeftRotate it expects the parent pointer of nil to be */
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/* unchanged. */
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y=x->right;
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x->right=y->left;
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if (y->left != nil) y->left->parent=x; /* used to use sentinel here */
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/* and do an unconditional assignment instead of testing for nil */
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y->parent=x->parent;
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/* instead of checking if x->parent is the root as in the book, we */
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/* count on the root sentinel to implicitly take care of this case */
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if (x == x->parent->left)
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{
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x->parent->left=y;
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}
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else
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{
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x->parent->right=y;
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}
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y->left=x;
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x->parent=y;
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#ifdef CHECK_RB_TREE_ASSUMPTIONS
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CheckAssumptions();
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#elif defined(DEBUG_ASSERT)
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Assert(!nil->red,"nil not red in RedBlackTree::LeftRotate");
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#endif
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}
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/***********************************************************************/
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/* FUNCTION: RighttRotate */
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/**/
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/* INPUTS: node to rotate on */
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/**/
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/* OUTPUT: None */
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/**/
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/* Modifies Input?: this, y */
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/**/
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/* EFFECTS: Rotates as described in _Introduction_To_Algorithms by */
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/* Cormen, Leiserson, Rivest (Chapter 14). Basically this */
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/* makes the parent of x be to the left of x, x the parent of */
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/* its parent before the rotation and fixes other pointers */
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/* accordingly. */
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/***********************************************************************/
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void RedBlackTree::RightRotate(RedBlackTreeNode* y)
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{
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RedBlackTreeNode* x;
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/* I originally wrote this function to use the sentinel for */
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/* nil to avoid checking for nil. However this introduces a */
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/* very subtle bug because sometimes this function modifies */
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/* the parent pointer of nil. This can be a problem if a */
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/* function which calls LeftRotate also uses the nil sentinel */
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/* and expects the nil sentinel's parent pointer to be unchanged */
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/* after calling this function. For example, when DeleteFixUP */
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/* calls LeftRotate it expects the parent pointer of nil to be */
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/* unchanged. */
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x=y->left;
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y->left=x->right;
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if (nil != x->right) x->right->parent=y; /*used to use sentinel here */
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/* and do an unconditional assignment instead of testing for nil */
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/* instead of checking if x->parent is the root as in the book, we */
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/* count on the root sentinel to implicitly take care of this case */
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x->parent=y->parent;
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if (y == y->parent->left)
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{
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y->parent->left=x;
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}
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else
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{
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y->parent->right=x;
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}
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x->right=y;
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y->parent=x;
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#ifdef CHECK_RB_TREE_ASSUMPTIONS
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CheckAssumptions();
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#elif defined(DEBUG_ASSERT)
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Assert(!nil->red,"nil not red in RedBlackTree::RightRotate");
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#endif
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}
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/***********************************************************************/
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/* FUNCTION: TreeInsertHelp */
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/**/
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/* INPUTS: z is the node to insert */
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/**/
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/* OUTPUT: none */
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/**/
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/* Modifies Input: this, z */
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/**/
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/* EFFECTS: Inserts z into the tree as if it were a regular binary tree */
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/* using the algorithm described in _Introduction_To_Algorithms_ */
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/* by Cormen et al. This funciton is only intended to be called */
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/* by the Insert function and not by the user */
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/***********************************************************************/
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void RedBlackTree::TreeInsertHelp(RedBlackTreeNode* z)
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{
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/* This function should only be called by RedBlackTree::Insert */
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RedBlackTreeNode* x;
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RedBlackTreeNode* y;
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z->left=z->right=nil;
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y=root;
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x=root->left;
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while (x != nil)
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{
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y=x;
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if (x->key > z->key)
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{
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x=x->left;
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}
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else /* x->key <= z->key */
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{
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x=x->right;
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}
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}
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z->parent=y;
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if ((y == root) ||
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(y->key > z->key))
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{
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y->left=z;
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}
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else
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{
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y->right=z;
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}
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#if defined(DEBUG_ASSERT)
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Assert(!nil->red,"nil not red in RedBlackTree::TreeInsertHelp");
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#endif
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}
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RedBlackTreeIterator RedBlackTree::Search(key_t key)
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{
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RedBlackTreeNode* x;
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x=root->left;
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while (x != nil)
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{
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if (x->key > key)
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{
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x=x->left;
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}
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else if (x->key < key)
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{
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x=x->right;
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}
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else
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{
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return RedBlackTreeIterator(x, this);
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}
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}
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return end();
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}
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/* Before calling InsertNode the node x should have its key set */
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/***********************************************************************/
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/* FUNCTION: InsertNode */
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/**/
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/* INPUTS: newEntry is the entry to insert*/
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/**/
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/* OUTPUT: This function returns a pointer to the newly inserted node */
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/* which is guarunteed to be valid until this node is deleted. */
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/* What this means is if another data structure stores this */
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/* pointer then the tree does not need to be searched when this */
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/* is to be deleted. */
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/**/
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/* Modifies Input: tree */
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/**/
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/* EFFECTS: Creates a node node which contains the appropriate key and */
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/* info pointers and inserts it into the tree. */
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/***********************************************************************/
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RedBlackTreeIterator RedBlackTree::Insert(key_t _key, val_t newEntry)
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{
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RedBlackTreeNode * y;
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RedBlackTreeNode * x;
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RedBlackTreeNode * newNode;
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x = new RedBlackTreeNode(_key, newEntry);
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TreeInsertHelp(x);
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newNode = x;
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x->red=1;
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while (x->parent->red) /* use sentinel instead of checking for root */
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{
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if (x->parent == x->parent->parent->left)
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{
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y=x->parent->parent->right;
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if (y->red)
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{
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x->parent->red=0;
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y->red=0;
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x->parent->parent->red=1;
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x=x->parent->parent;
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}
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else
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{
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if (x == x->parent->right)
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{
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x=x->parent;
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LeftRotate(x);
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}
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x->parent->red=0;
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x->parent->parent->red=1;
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RightRotate(x->parent->parent);
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}
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}
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else /* case for x->parent == x->parent->parent->right */
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{
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/* this part is just like the section above with */
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/* left and right interchanged */
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y=x->parent->parent->left;
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if (y->red)
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{
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x->parent->red=0;
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y->red=0;
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x->parent->parent->red=1;
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x=x->parent->parent;
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}
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else
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{
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if (x == x->parent->left)
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{
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x=x->parent;
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RightRotate(x);
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}
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x->parent->red=0;
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x->parent->parent->red=1;
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LeftRotate(x->parent->parent);
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}
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}
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}
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root->left->red=0;
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numElements++;
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return RedBlackTreeIterator(newNode, this);
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#ifdef CHECK_RB_TREE_ASSUMPTIONS
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CheckAssumptions();
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#elif defined(DEBUG_ASSERT)
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Assert(!nil->red,"nil not red in RedBlackTree::Insert");
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Assert(!root->red,"root not red in RedBlackTree::Insert");
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#endif
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}
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RedBlackTree::~RedBlackTree()
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{
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RedBlackTreeNode * x = root->left;
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nu::PtrList<RedBlackTreeNode> stuffToFree;
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if (x != nil)
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{
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if (x->left != nil)
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{
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stuffToFree.push_back(x->left);
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}
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if (x->right != nil)
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{
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stuffToFree.push_back(x->right);
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}
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// delete x->storedEntry;
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delete x;
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while (!stuffToFree.empty())
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{
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x = stuffToFree.back();
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stuffToFree.pop_back();
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if (x->left != nil)
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{
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stuffToFree.push_back(x->left);
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}
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if (x->right != nil)
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{
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stuffToFree.push_back(x->right);
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}
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// delete x->storedEntry;
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delete x;
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}
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}
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delete nil;
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delete root;
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}
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void RedBlackTree::DeleteFixUp(RedBlackTreeNode* x)
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{
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RedBlackTreeNode * w;
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RedBlackTreeNode * rootLeft = root->left;
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while ((!x->red) && (rootLeft != x))
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{
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if (x == x->parent->left)
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{
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w=x->parent->right;
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if (w->red)
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{
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w->red=0;
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x->parent->red=1;
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LeftRotate(x->parent);
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w=x->parent->right;
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}
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if ((!w->right->red) && (!w->left->red))
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{
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w->red=1;
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x=x->parent;
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}
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else
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{
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if (!w->right->red)
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{
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w->left->red=0;
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w->red=1;
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RightRotate(w);
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w=x->parent->right;
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}
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w->red=x->parent->red;
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x->parent->red=0;
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w->right->red=0;
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LeftRotate(x->parent);
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x=rootLeft; /* this is to exit while loop */
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}
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}
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else /* the code below is has left and right switched from above */
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{
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w=x->parent->left;
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if (w->red)
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{
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w->red=0;
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x->parent->red=1;
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RightRotate(x->parent);
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w=x->parent->left;
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}
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if ((!w->right->red) && (!w->left->red))
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{
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w->red=1;
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x=x->parent;
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}
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else
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{
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if (!w->left->red)
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{
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w->right->red=0;
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w->red=1;
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LeftRotate(w);
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w=x->parent->left;
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}
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w->red=x->parent->red;
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x->parent->red=0;
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w->left->red=0;
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RightRotate(x->parent);
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x=rootLeft; /* this is to exit while loop */
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}
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}
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}
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x->red=0;
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#ifdef CHECK_RB_TREE_ASSUMPTIONS
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CheckAssumptions();
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#elif defined(DEBUG_ASSERT)
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Assert(!nil->red,"nil not black in RedBlackTree::DeleteFixUp");
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#endif
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}
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void RedBlackTree::Delete(RedBlackTree::key_t key)
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{
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RedBlackTreeIterator itr = Search(key);
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DeleteNode(itr.node);
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}
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/***********************************************************************/
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/* FUNCTION: DeleteNode */
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/**/
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/* INPUTS: tree is the tree to delete node z from */
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/**/
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/* OUTPUT: returns the RedBlackEntry stored at deleted node */
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/**/
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/* EFFECT: Deletes z from tree and but don't call destructor */
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/**/
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/* Modifies Input: z */
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/**/
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/* The algorithm from this function is from _Introduction_To_Algorithms_ */
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/***********************************************************************/
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RedBlackTree::val_t RedBlackTree::DeleteNode(RedBlackTreeNode * z)
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{
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RedBlackTreeNode* y;
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RedBlackTreeNode* x;
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val_t returnValue = z->storedEntry;
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y= ((z->left == nil) || (z->right == nil)) ? z : GetSuccessorOf(z);
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x= (y->left == nil) ? y->right : y->left;
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if (root == (x->parent = y->parent)) /* assignment of y->p to x->p is intentional */
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{
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root->left=x;
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}
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else
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{
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if (y == y->parent->left)
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{
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y->parent->left=x;
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}
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else
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{
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y->parent->right=x;
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}
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}
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if (y != z) /* y should not be nil in this case */
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{
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#ifdef DEBUG_ASSERT
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Assert((y!=nil),"y is nil in DeleteNode \n");
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#endif
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/* y is the node to splice out and x is its child */
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y->left=z->left;
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y->right=z->right;
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y->parent=z->parent;
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z->left->parent=z->right->parent=y;
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if (z == z->parent->left)
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{
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z->parent->left=y;
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}
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else
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{
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z->parent->right=y;
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}
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if (!(y->red))
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{
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y->red = z->red;
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DeleteFixUp(x);
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}
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else
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y->red = z->red;
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delete z;
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#ifdef CHECK_RB_TREE_ASSUMPTIONS
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CheckAssumptions();
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#elif defined(DEBUG_ASSERT)
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Assert(!nil->red,"nil not black in RedBlackTree::Delete");
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#endif
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}
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else
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{
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if (!(y->red)) DeleteFixUp(x);
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delete y;
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#ifdef CHECK_RB_TREE_ASSUMPTIONS
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CheckAssumptions();
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#elif defined(DEBUG_ASSERT)
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Assert(!nil->red,"nil not black in RedBlackTree::Delete");
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#endif
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}
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numElements--;
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return returnValue;
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}
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size_t RedBlackTree::size() const
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{
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return numElements;
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}
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/***********************************************************************/
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/* FUNCTION: GetPredecessorOf */
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/**/
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/* INPUTS: x is the node to get predecessor of */
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/**/
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/* OUTPUT: This function returns the predecessor of x or NULL if no */
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/* predecessor exists. */
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/**/
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/* Modifies Input: none */
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/**/
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/* Note: uses the algorithm in _Introduction_To_Algorithms_ */
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/***********************************************************************/
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RedBlackTreeNode *RedBlackTree::GetPredecessorOf(RedBlackTreeNode * x) const
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{
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RedBlackTreeNode* y;
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if (nil != (y = x->left)) /* assignment to y is intentional */
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|
{
|
|
while (y->right != nil) /* returns the maximum of the left subtree of x */
|
|
{
|
|
y=y->right;
|
|
}
|
|
return(y);
|
|
}
|
|
else
|
|
{
|
|
y=x->parent;
|
|
while (x == y->left)
|
|
{
|
|
if (y == root) return(nil);
|
|
x=y;
|
|
y=y->parent;
|
|
}
|
|
return(y);
|
|
}
|
|
}
|
|
|
|
|
|
/***********************************************************************/
|
|
/* FUNCTION: GetSuccessorOf */
|
|
/**/
|
|
/* INPUTS: x is the node we want the succesor of */
|
|
/**/
|
|
/* OUTPUT: This function returns the successor of x or NULL if no */
|
|
/* successor exists. */
|
|
/**/
|
|
/* Modifies Input: none */
|
|
/**/
|
|
/* Note: uses the algorithm in _Introduction_To_Algorithms_ */
|
|
/***********************************************************************/
|
|
|
|
RedBlackTreeNode *RedBlackTree::GetSuccessorOf(RedBlackTreeNode * x) const
|
|
{
|
|
RedBlackTreeNode* y;
|
|
|
|
if (nil != (y = x->right)) /* assignment to y is intentional */
|
|
{
|
|
while (y->left != nil) /* returns the minium of the right subtree of x */
|
|
{
|
|
y=y->left;
|
|
}
|
|
return(y);
|
|
}
|
|
else
|
|
{
|
|
y=x->parent;
|
|
while (x == y->right) /* sentinel used instead of checking for nil */
|
|
{
|
|
x=y;
|
|
y=y->parent;
|
|
}
|
|
if (y == root) return(nil);
|
|
return(y);
|
|
}
|
|
}
|