/** * File: binary_search_tree.cpp * Created Time: 2022-11-25 * Author: krahets (krahets@163.com) */ #include "../utils/common.hpp" /* Binary search tree */ class BinarySearchTree { private: TreeNode *root; public: /* Constructor */ BinarySearchTree() { // Initialize empty tree root = nullptr; } /* Destructor */ ~BinarySearchTree() { freeMemoryTree(root); } /* Get binary tree root node */ TreeNode *getRoot() { return root; } /* Search node */ TreeNode *search(int num) { TreeNode *cur = root; // Loop find, break after passing leaf nodes while (cur != nullptr) { // Target node is in cur's right subtree if (cur->val < num) cur = cur->right; // Target node is in cur's left subtree else if (cur->val > num) cur = cur->left; // Found target node, break loop else break; } // Return target node return cur; } /* Insert node */ void insert(int num) { // If tree is empty, initialize root node if (root == nullptr) { root = new TreeNode(num); return; } TreeNode *cur = root, *pre = nullptr; // Loop find, break after passing leaf nodes while (cur != nullptr) { // Found duplicate node, thus return if (cur->val == num) return; pre = cur; // Insertion position is in cur's right subtree if (cur->val < num) cur = cur->right; // Insertion position is in cur's left subtree else cur = cur->left; } // Insert node TreeNode *node = new TreeNode(num); if (pre->val < num) pre->right = node; else pre->left = node; } /* Remove node */ void remove(int num) { // If tree is empty, return if (root == nullptr) return; TreeNode *cur = root, *pre = nullptr; // Loop find, break after passing leaf nodes while (cur != nullptr) { // Found node to be removed, break loop if (cur->val == num) break; pre = cur; // Node to be removed is in cur's right subtree if (cur->val < num) cur = cur->right; // Node to be removed is in cur's left subtree else cur = cur->left; } // If no node to be removed, return if (cur == nullptr) return; // Number of child nodes = 0 or 1 if (cur->left == nullptr || cur->right == nullptr) { // When the number of child nodes = 0 / 1, child = nullptr / that child node TreeNode *child = cur->left != nullptr ? cur->left : cur->right; // Remove node cur if (cur != root) { if (pre->left == cur) pre->left = child; else pre->right = child; } else { // If the removed node is the root, reassign the root root = child; } // Free memory delete cur; } // Number of child nodes = 2 else { // Get the next node in in-order traversal of cur TreeNode *tmp = cur->right; while (tmp->left != nullptr) { tmp = tmp->left; } int tmpVal = tmp->val; // Recursively remove node tmp remove(tmp->val); // Replace cur with tmp cur->val = tmpVal; } } }; /* Driver Code */ int main() { /* Initialize binary search tree */ BinarySearchTree *bst = new BinarySearchTree(); // Note that different insertion orders can result in various tree structures. This particular sequence creates a perfect binary tree vector nums = {8, 4, 12, 2, 6, 10, 14, 1, 3, 5, 7, 9, 11, 13, 15}; for (int num : nums) { bst->insert(num); } cout << endl << "The initialized binary tree is\n" << endl; printTree(bst->getRoot()); /* Search node */ TreeNode *node = bst->search(7); cout << endl << "The found node object is " << node << ", node value =" << node->val << endl; /* Insert node */ bst->insert(16); cout << endl << "After inserting node 16, the binary tree is\n" << endl; printTree(bst->getRoot()); /* Remove node */ bst->remove(1); cout << endl << "After removing node 1, the binary tree is\n" << endl; printTree(bst->getRoot()); bst->remove(2); cout << endl << "After removing node 2, the binary tree is\n" << endl; printTree(bst->getRoot()); bst->remove(4); cout << endl << "After removing node 4, the binary tree is\n" << endl; printTree(bst->getRoot()); // Free memory delete bst; return 0; }