Update datastructs/binarysearchtree example
+ Utilize copy-swap idiom, miscellaneous clean-up of conditions and return values
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@ -8,9 +8,14 @@
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#
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cmake_minimum_required(VERSION 3.15)
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# Define the project name
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project(BinarySearchTree)
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# Define source files
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set(SRC driver.cpp bst.cpp)
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# Build an executable
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add_executable(BSTDriver ${SRC})
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project (
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#[[NAME]] BinaryTree
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VERSION 1.0
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DESCRIPTION "A project for testing a basic implementation of a BST"
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LANGUAGES CXX
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)
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add_library(lib-bst "bst.cpp")
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add_executable(test-bst "driver.cpp")
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target_link_libraries(test-bst lib-bst)
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@ -1,10 +1,10 @@
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/*#############################################################################
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## Author: Shaun Reed ##
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## Legal: All Content (c) 2020 Shaun Reed, all rights reserved ##
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## About: An example of a binary search tree implementation ##
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## ##
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## Contact: shaunrd0@gmail.com | URL: www.shaunreed.com | GitHub: shaunrd0 ##
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##############################################################################
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/*##############################################################################
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## Author: Shaun Reed ##
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## Legal: All Content (c) 2021 Shaun Reed, all rights reserved ##
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## About: An example of a binary search tree implementation ##
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## ##
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## Contact: shaunrd0@gmail.com | URL: www.shaunreed.com | GitHub: shaunrd0 ##
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################################################################################
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## bst.cpp
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*/
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@ -21,27 +21,17 @@
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* @param rhs The BST to copy, beginning from its root BinaryNode
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* @return const BinarySearchTree& The copied BinarySearchTree object
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*/
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const BinarySearchTree& BinarySearchTree::operator=(const BinarySearchTree& rhs)
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BinarySearchTree& BinarySearchTree::operator=(BinarySearchTree rhs)
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{
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// If the objects are already equal, do nothing
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if (this == &rhs) return *this;
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// Empty this->root
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makeEmpty();
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// Copy rhs to this->root
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root = clone(rhs.root);
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std::swap(root, rhs.root);
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return *this;
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}
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/** Default Destructor
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* @brief Destroy the Binary Search Tree:: Binary Search Tree object
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*/
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BinarySearchTree::~BinarySearchTree()
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{
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makeEmpty(root);
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}
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/********************************************************************************
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* Public Member Functions
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*********************************************************************************/
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@ -52,9 +42,9 @@ BinarySearchTree::~BinarySearchTree()
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*
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* @return const int& The element of the BinaryNode that holds the lowest value in our tree
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*/
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const int & BinarySearchTree::findMin() const
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int BinarySearchTree::findMin() const
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{
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return findMin(root)->element;
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return findMin(root) != nullptr ? findMin(root)->element: INT32_MIN;
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}
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/** findMax
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@ -63,9 +53,9 @@ const int & BinarySearchTree::findMin() const
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*
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* @return const int& The element of the BinaryNode that holds the highest value in our tree
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*/
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const int & BinarySearchTree::findMax() const
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int BinarySearchTree::findMax() const
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{
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return findMax(root)->element;
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return findMax(root) != nullptr ? findMax(root)->element: INT32_MIN;
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}
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/** contains
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@ -84,12 +74,12 @@ bool BinarySearchTree::contains(const int &x) const
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/** isEmpty
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* @brief Determine whether or not the calling BST object is empty
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*
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* @return true If this->root node points to an empty tree (NULL)
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* @return true If this->root node points to an empty tree (nullptr)
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* @return false If this->root node points to a constructed BinaryNode
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*/
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bool BinarySearchTree::isEmpty() const
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{
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return root == NULL;
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return root == nullptr;
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}
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/** insert
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@ -167,7 +157,7 @@ void BinarySearchTree::printPreOrder() const
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BinarySearchTree::BinaryNode * BinarySearchTree::clone(BinaryNode *t) const
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{
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// If there is nothing to copy
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if (t == NULL) return NULL;
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if (t == nullptr) return nullptr;
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// Construct all child nodes through recursion, return root node
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return new BinaryNode(t->element, clone(t->left), clone(t->right));
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@ -181,14 +171,10 @@ BinarySearchTree::BinaryNode * BinarySearchTree::clone(BinaryNode *t) const
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*/
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void BinarySearchTree::insert(const int &x, BinarySearchTree::BinaryNode *&t) const
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{
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if (t == NULL)
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t = new BinaryNode(x, NULL, NULL);
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else if (x < t->element)
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insert (x, t->left);
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else if (x > t->element)
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insert (x, t->right);
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else
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return;
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if (t == nullptr) t = new BinaryNode(x, nullptr, nullptr);
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else if (x < t->element) insert (x, t->left);
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else if (x > t->element) insert (x, t->right);
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else return;
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}
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/** remove
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@ -199,14 +185,11 @@ void BinarySearchTree::insert(const int &x, BinarySearchTree::BinaryNode *&t) co
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*/
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void BinarySearchTree::remove(const int &x, BinarySearchTree::BinaryNode *&t) const
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{
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if (t == NULL)
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return;
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if (t == nullptr) return;
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if (x < t->element)
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remove(x, t->left);
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else if (x > t->element)
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remove(x, t->right);
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else if (t->left != NULL && t->right != NULL) {
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if (x < t->element) remove(x, t->left);
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else if (x > t->element) remove(x, t->right);
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else if (t->left != nullptr && t->right != nullptr) {
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// If we found the node and there are two branches
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t->element = findMin(t->right)->element;
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std::cout << "Removing [" << t->element << "]...\n";
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@ -215,7 +198,7 @@ void BinarySearchTree::remove(const int &x, BinarySearchTree::BinaryNode *&t) co
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else {
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// If we found the value and there is only one branch
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BinaryNode *oldNode = t;
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t = (t->left != NULL) ? t->left : t->right;
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t = (t->left != nullptr) ? t->left : t->right;
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std::cout << "Removing [" << oldNode->element << "]...\n";
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delete oldNode;
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}
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@ -225,40 +208,32 @@ void BinarySearchTree::remove(const int &x, BinarySearchTree::BinaryNode *&t) co
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* @brief Find the minimum value within the BST of the given BinaryNode
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*
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* @param t The root BinaryNode to begin checking values
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* @return BinarySearchTree::BinaryNode* The BinaryNode which contains the smallest value (returns NULL if BST is empty)
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* @return BinarySearchTree::BinaryNode* The BinaryNode which contains the smallest value (returns nullptr if BST is empty)
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*/
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BinarySearchTree::BinaryNode * BinarySearchTree::findMin(BinarySearchTree::BinaryNode *t) const
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{
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while (t != NULL)
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t = t->left;
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// If our tree is empty
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if (t == NULL)
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return NULL;
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if (t == nullptr) return nullptr;
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// If current node has no smaller children, it is min
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if (t->left == NULL)
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return t;
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while (t->left != nullptr) t = t->left;
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// Move down the left side of our tree and check again
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return findMin(t->left);
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return t;
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}
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/** findMax
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* @brief Find the maximum value within the BST of the given BinaryNode
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*
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* @param t The root BinaryNode to begin checking values
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* @return BinarySearchTree::BinaryNode* The BinaryNode which contains the largest value (returns NULL if BST is empty)
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* @return BinarySearchTree::BinaryNode* The BinaryNode which contains the largest value (returns nullptr if BST is empty)
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*/
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BinarySearchTree::BinaryNode * BinarySearchTree::findMax(BinarySearchTree::BinaryNode *t) const
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{
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// If our tree is empty
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if (t == NULL)
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return NULL;
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if (t == nullptr) return nullptr;
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// If current node has no larger children, it is max
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if (t->right == NULL)
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return t;
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if (t->right == nullptr) return t;
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// Move down the right side of our tree and check again
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return findMax(t->right);
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@ -274,14 +249,13 @@ BinarySearchTree::BinaryNode * BinarySearchTree::findMax(BinarySearchTree::Binar
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*/
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bool BinarySearchTree::contains(const int &x, BinarySearchTree::BinaryNode *t) const
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{
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if (t == NULL) // If tree is empty
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return false;
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else if (x < t->element) // If x is smaller than our current value
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return contains(x, t->left);// Check left node
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else if (x > t->element) // If x is larger than our current value
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return contains(x, t->right); // Check right node
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else
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return true;
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// If tree is empty
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if (t == nullptr) return false;
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// If x is smaller than our current value
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else if (x < t->element) return contains(x, t->left);
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// If x is larger than our current value, check the right node
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else if (x > t->element) return contains(x, t->right);
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else return true;
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}
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/** makeEmpty
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@ -291,12 +265,12 @@ bool BinarySearchTree::contains(const int &x, BinarySearchTree::BinaryNode *t) c
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*/
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void BinarySearchTree::makeEmpty(BinarySearchTree::BinaryNode * & t)
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{
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if (t != NULL) {
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if (t != nullptr) {
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makeEmpty(t->left);
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makeEmpty(t->right);
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delete t;
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}
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t = NULL;
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t = nullptr;
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}
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/** printInOrder
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*/
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void BinarySearchTree::printInOrder(BinaryNode *t) const
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{
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if(t != NULL) {
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if(t != nullptr) {
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printInOrder(t->left);
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std::cout << t->element << " ";
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printInOrder(t->right);
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@ -320,7 +294,7 @@ void BinarySearchTree::printInOrder(BinaryNode *t) const
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*/
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void BinarySearchTree::printPostOrder(BinaryNode *t) const
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{
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if (t != NULL) {
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if (t != nullptr) {
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printPostOrder(t->left);
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printPostOrder(t->right);
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std::cout << t->element << " ";
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@ -328,13 +302,13 @@ void BinarySearchTree::printPostOrder(BinaryNode *t) const
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}
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/** printPreOrder
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* @brief Output the value of the noot nodes before their subtrees
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* @brief Output the value of the root nodes before their subtrees
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*
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* @param t The root BinaryNode to begin the 'Pre Order' output
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*/
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void BinarySearchTree::printPreOrder(BinaryNode *t) const
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{
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if (t != NULL) {
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if (t != nullptr) {
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std::cout << t->element << " ";
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printPreOrder(t->left);
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printPreOrder(t->right);
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@ -1,10 +1,10 @@
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/*#############################################################################
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## Author: Shaun Reed ##
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## Legal: All Content (c) 2020 Shaun Reed, all rights reserved ##
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## About: An example of a binary search tree implementation ##
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## ##
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## Contact: shaunrd0@gmail.com | URL: www.shaunreed.com | GitHub: shaunrd0 ##
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##############################################################################
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/*##############################################################################
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## Author: Shaun Reed ##
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## Legal: All Content (c) 2021 Shaun Reed, all rights reserved ##
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## About: An example of a binary search tree implementation ##
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## ##
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## Contact: shaunrd0@gmail.com | URL: www.shaunreed.com | GitHub: shaunrd0 ##
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################################################################################
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## bst.h
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*/
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@ -16,41 +16,42 @@
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// TODO: Add balance() method to balance overweight branches
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class BinarySearchTree {
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public:
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BinarySearchTree() : root(NULL) {};
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BinarySearchTree(const BinarySearchTree &rhs) : root(rhs.clone(rhs.root)) {};
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const BinarySearchTree& operator=(const BinarySearchTree& rhs);
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~BinarySearchTree();
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const int & findMin() const;
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const int & findMax() const;
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bool contains(const int &x) const;
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bool isEmpty() const;
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void insert(const int &x);
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void remove(const int &x);
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void makeEmpty();
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void printInOrder() const;
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void printPostOrder() const;
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void printPreOrder() const;
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public:
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BinarySearchTree() : root(nullptr) {};
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BinarySearchTree(const BinarySearchTree &rhs) : root(clone(rhs.root)) {};
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BinarySearchTree& operator=(BinarySearchTree rhs);
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~BinarySearchTree() { makeEmpty(root);};
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int findMin() const;
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int findMax() const;
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bool contains(const int &x) const;
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bool isEmpty() const;
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void insert(const int &x);
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void remove(const int &x);
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void makeEmpty();
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void printInOrder() const;
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void printPostOrder() const;
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void printPreOrder() const;
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private:
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struct BinaryNode{
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int element;
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BinaryNode *left;
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BinaryNode *right;
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BinaryNode(const int &el, BinaryNode *lt, BinaryNode *rt)
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:element(el), left(lt), right(rt) {};
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};
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BinaryNode *root;
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BinaryNode * clone(BinaryNode *t) const;
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void insert(const int &x, BinaryNode *&t) const;
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void remove(const int &x, BinaryNode *&t) const;
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BinaryNode * findMin(BinaryNode *t) const;
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BinaryNode * findMax(BinaryNode *t) const;
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bool contains(const int &x, BinaryNode *t) const;
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void makeEmpty(BinaryNode * & t);
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void printInOrder(BinaryNode *t) const;
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void printPostOrder(BinaryNode *t) const;
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void printPreOrder(BinaryNode *t) const;
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private:
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struct BinaryNode{
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int element;
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BinaryNode *left;
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BinaryNode *right;
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BinaryNode(const int &el, BinaryNode *lt, BinaryNode *rt)
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:element(el), left(lt), right(rt) {};
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};
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BinaryNode *root;
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BinaryNode * clone(BinaryNode *t) const;
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void insert(const int &x, BinaryNode *&t) const;
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void remove(const int &x, BinaryNode *&t) const;
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BinaryNode * findMin(BinaryNode *t) const;
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BinaryNode * findMax(BinaryNode *t) const;
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bool contains(const int &x, BinaryNode *t) const;
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void makeEmpty(BinaryNode * & t);
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void printInOrder(BinaryNode *t) const;
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void printPostOrder(BinaryNode *t) const;
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void printPreOrder(BinaryNode *t) const;
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};
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#endif //BST_H
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@ -1,24 +1,26 @@
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/*#############################################################################
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## Author: Shaun Reed ##
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## Legal: All Content (c) 2020 Shaun Reed, all rights reserved ##
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## About: A driver program to test a binary search tree implementation ##
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## ##
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## Contact: shaunrd0@gmail.com | URL: www.shaunreed.com | GitHub: shaunrd0 ##
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##############################################################################
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/*##############################################################################
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## Author: Shaun Reed ##
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## Legal: All Content (c) 2021 Shaun Reed, all rights reserved ##
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## About: A driver program to test a binary search tree implementation ##
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## ##
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## Contact: shaunrd0@gmail.com | URL: www.shaunreed.com | GitHub: shaunrd0 ##
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################################################################################
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## driver.cpp
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*/
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#include "bst.h"
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#include <iostream>
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enum OPS {
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EXIT, INSERT, REMOVE, CONTAINS, INFIX, PREFIX, POSTFIX, EMPTY, MIN, MAX
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EXIT, INSERT, REMOVE, CONTAINS, INFIX, PREFIX, POSTFIX, EMPTY, MIN, MAX,
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COPY, EQUAL
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};
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int main()
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{
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std::cout << "Driver: \n";
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BinarySearchTree testList;
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BinarySearchTree testTree;
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bool exit = false;
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int choice = -1;
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int val;
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@ -26,65 +28,87 @@ int main()
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while (!exit)
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{
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std::cout << "##### Binary Search Tree Menu #####\n\t0. Exit"
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"\n\t1. Insert\n\t2. Remove\n\t3. Contains\n\t4. Infix\n\t5. Prefix"
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<< "\n\t6. Postfix\n\t7. Empty\n\t8. Min\n\t9. Max\n";
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"\n\t1. Insert\n\t2. Remove\n\t3. Contains\n\t4. In-order\n\t"
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"5. Pre-order\n\t6. Post-order\n\t7. Empty\n\t8. Min\n\t9. Max"
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"\n\t10. Copy BST\n\t11. Equal BST\n";
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std::cin >> choice;
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std::cin.clear();
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switch (choice) {
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case EXIT:
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exit = true;
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break;
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case EXIT:
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exit = true;
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break;
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case INSERT:
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std::cout << "Enter a value to insert to our tree: ";
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std::cin >> val;
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std::cin.clear();
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testList.insert(val);
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break;
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case INSERT:
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std::cout << "Enter a value to insert to our tree: ";
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std::cin >> val;
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std::cin.clear();
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testTree.insert(val);
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break;
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case REMOVE:
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std::cout << "Enter a value to remove from our tree: ";
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std::cin >> val;
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std::cin.clear();
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testList.remove(val);
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break;
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case REMOVE:
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std::cout << "Enter a value to remove from our tree: ";
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std::cin >> val;
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std::cin.clear();
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testTree.remove(val);
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break;
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case CONTAINS:
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std::cout << "Enter a value to search for within our tree: ";
|
||||
std::cin >> val;
|
||||
std::cin.clear();
|
||||
if (testList.contains(val))
|
||||
std::cout << val << " exists within our tree\n";
|
||||
else std::cout << val << " does not exist within our tree\n";
|
||||
break;
|
||||
case CONTAINS:
|
||||
std::cout << "Enter a value to search for within our tree: ";
|
||||
std::cin >> val;
|
||||
std::cin.clear();
|
||||
if (testTree.contains(val)) std::cout << val << " exists in our tree\n";
|
||||
else std::cout << val << " does not exist in our tree\n";
|
||||
break;
|
||||
|
||||
case INFIX:
|
||||
testList.printInOrder();
|
||||
break;
|
||||
case INFIX:
|
||||
testTree.printInOrder();
|
||||
break;
|
||||
|
||||
case PREFIX:
|
||||
testList.printPreOrder();
|
||||
break;
|
||||
case PREFIX:
|
||||
testTree.printPreOrder();
|
||||
break;
|
||||
|
||||
case POSTFIX:
|
||||
testList.printPostOrder();
|
||||
break;
|
||||
case POSTFIX:
|
||||
testTree.printPostOrder();
|
||||
break;
|
||||
|
||||
case EMPTY:
|
||||
testList.makeEmpty();
|
||||
break;
|
||||
case EMPTY:
|
||||
testTree.makeEmpty();
|
||||
std::cout << "The BST is empty: "
|
||||
<< (testTree.isEmpty() ? "true" : "false") << std::endl;
|
||||
break;
|
||||
|
||||
case MIN:
|
||||
std::cout << "Min value within our tree: " << testList.findMin();
|
||||
break;
|
||||
case MIN:
|
||||
std::cout << "Min value within our tree: " << testTree.findMin() << "\n";
|
||||
break;
|
||||
|
||||
case MAX:
|
||||
std::cout << "Max value within our tree: " << testList.findMax();
|
||||
break;
|
||||
case MAX:
|
||||
std::cout << "Max value within our tree: " << testTree.findMax() << "\n";
|
||||
break;
|
||||
|
||||
default:
|
||||
std::cout << "Invalid entry...\n";
|
||||
break;
|
||||
case COPY:
|
||||
{
|
||||
BinarySearchTree copiedTree(testTree);
|
||||
std::cout << "Inorder output from copied tree: ";
|
||||
copiedTree.printInOrder();
|
||||
std::cout << std::endl;
|
||||
// copiedTree calls destructor when leaving this scope
|
||||
break;
|
||||
}
|
||||
|
||||
case EQUAL: {
|
||||
BinarySearchTree equalTree;
|
||||
equalTree = testTree;
|
||||
std::cout << "Inorder output from equal tree: ";
|
||||
equalTree.printInOrder();
|
||||
std::cout << std::endl;
|
||||
// equalTree calls destructor when leaving this scope
|
||||
break;
|
||||
}
|
||||
|
||||
default:
|
||||
std::cout << "Invalid entry...\n";
|
||||
break;
|
||||
}
|
||||
}
|
||||
}
|
||||
|
|
Loading…
Reference in New Issue