klips/cpp/algorithms/trees/redblack/redblack.h

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/*#############################################################################
## Author: Shaun Reed ##
## Legal: All Content (c) 2021 Shaun Reed, all rights reserved ##
## About: An example of a red black tree implementation ##
## The algorithms in this example are seen in MIT Intro to Algorithms ##
## ##
## Contact: shaunrd0@gmail.com | URL: www.shaunreed.com | GitHub: shaunrd0 ##
##############################################################################
*/
#ifndef REDBLACK_H
#define REDBLACK_H
#include <iostream>
// TODO: Add balance() method to balance overweight branches
class BinarySearchTree {
public:
// BinaryNode Structure
struct BinaryNode{
int element;
BinaryNode *left, *right, *parent;
// Ctor for specific element, lhs, rhs
BinaryNode(const int &el, BinaryNode *lt, BinaryNode *rt, BinaryNode *p)
:element(el), left(lt), right(rt), parent(p) {};
// Ctor for a node and any downstream nodes
explicit BinaryNode(BinaryNode * toCopy);
};
BinarySearchTree() : root(nullptr) {};
BinarySearchTree(const BinarySearchTree &rhs) : root(rhs.clone(rhs.root)) {};
BinarySearchTree& operator=(const BinarySearchTree& rhs);
~BinarySearchTree() { makeEmpty(root);};
inline BinaryNode * getRoot() const { return root;}
// Check if value is within the tree or subtree
inline bool contains(const int &value) const { return contains(value, root);}
bool contains(const int &value, BinaryNode *start) const;
// Empties a given tree or subtree
inline void makeEmpty() { makeEmpty(root);}
void makeEmpty(BinaryNode *&tree);
// Checks if this BST is empty
bool isEmpty() const;
// Insert and remove values from a tree or subtree
inline void insert(const int &x) { insert(x, root, nullptr);}
void insert(const int &newValue, BinaryNode *&start, BinaryNode *prevNode);
inline void remove(const int &x) { remove(search(x, root));}
void remove(BinaryNode *removeNode);
// Traversal functions
inline void printInOrder() const { printInOrder(root);}
inline void printPostOrder() const { printPostOrder(root);}
inline void printPreOrder() const { printPreOrder(root);}
// Overloaded to specify traversal of a subtree
void printInOrder(BinaryNode *start) const;
void printPostOrder(BinaryNode *start) const;
void printPreOrder(BinaryNode *start) const;
// Find a BinaryNode containing value starting at a given tree / subtree node
inline BinaryNode * search(const int &value) const { return search(value, root);}
BinaryNode * search(const int &value, BinaryNode *start) const;
inline BinaryNode * findMin() const { return findMin(root);}
inline BinaryNode * findMax() const { return findMax(root);}
// Find nodes with min / max values starting at a given tree / subtree node
BinaryNode * findMin(BinaryNode *start) const;
BinaryNode * findMax(BinaryNode *start) const;
BinaryNode * predecessor(BinaryNode *startNode) const;
BinaryNode * successor(BinaryNode *startNode) const;
private:
// BST Private Member Functions
static BinaryNode * clone(BinaryNode *start);
void transplant(BinaryNode *oldNode, BinaryNode *newNode);
BinaryNode *root;
};
#endif // REDBLACK_H