hello-algo/en/codes/cpp/chapter_tree/avl_tree.cpp

/**
 * File: avl_tree.cpp
 * Created Time: 2023-02-03
 * Author: what-is-me (whatisme@outlook.jp)
 */

#include "../utils/common.hpp"

/* AVL tree */
class AVLTree {
  private:
    /* Update node height */
    void updateHeight(TreeNode *node) {
        // Node height equals the height of the tallest subtree + 1
        node->height = max(height(node->left), height(node->right)) + 1;
    }

    /* Right rotation operation */
    TreeNode *rightRotate(TreeNode *node) {
        TreeNode *child = node->left;
        TreeNode *grandChild = child->right;
        // Rotate node to the right around child
        child->right = node;
        node->left = grandChild;
        // Update node height
        updateHeight(node);
        updateHeight(child);
        // Return the root of the subtree after rotation
        return child;
    }

    /* Left rotation operation */
    TreeNode *leftRotate(TreeNode *node) {
        TreeNode *child = node->right;
        TreeNode *grandChild = child->left;
        // Rotate node to the left around child
        child->left = node;
        node->right = grandChild;
        // Update node height
        updateHeight(node);
        updateHeight(child);
        // Return the root of the subtree after rotation
        return child;
    }

    /* Perform rotation operation to restore balance to the subtree */
    TreeNode *rotate(TreeNode *node) {
        // Get the balance factor of node
        int _balanceFactor = balanceFactor(node);
        // Left-leaning tree
        if (_balanceFactor > 1) {
            if (balanceFactor(node->left) >= 0) {
                // Right rotation
                return rightRotate(node);
            } else {
                // First left rotation then right rotation
                node->left = leftRotate(node->left);
                return rightRotate(node);
            }
        }
        // Right-leaning tree
        if (_balanceFactor < -1) {
            if (balanceFactor(node->right) <= 0) {
                // Left rotation
                return leftRotate(node);
            } else {
                // First right rotation then left rotation
                node->right = rightRotate(node->right);
                return leftRotate(node);
            }
        }
        // Balanced tree, no rotation needed, return
        return node;
    }

    /* Recursively insert node (helper method) */
    TreeNode *insertHelper(TreeNode *node, int val) {
        if (node == nullptr)
            return new TreeNode(val);
        /* 1. Find insertion position and insert node */
        if (val < node->val)
            node->left = insertHelper(node->left, val);
        else if (val > node->val)
            node->right = insertHelper(node->right, val);
        else
            return node;    // Do not insert duplicate nodes, return
        updateHeight(node); // Update node height
        /* 2. Perform rotation operation to restore balance to the subtree */
        node = rotate(node);
        // Return the root node of the subtree
        return node;
    }

    /* Recursively remove node (helper method) */
    TreeNode *removeHelper(TreeNode *node, int val) {
        if (node == nullptr)
            return nullptr;
        /* 1. Find and remove the node */
        if (val < node->val)
            node->left = removeHelper(node->left, val);
        else if (val > node->val)
            node->right = removeHelper(node->right, val);
        else {
            if (node->left == nullptr || node->right == nullptr) {
                TreeNode *child = node->left != nullptr ? node->left : node->right;
                // Number of child nodes = 0, remove node and return
                if (child == nullptr) {
                    delete node;
                    return nullptr;
                }
                // Number of child nodes = 1, remove node
                else {
                    delete node;
                    node = child;
                }
            } else {
                // Number of child nodes = 2, remove the next node in in-order traversal and replace the current node with it
                TreeNode *temp = node->right;
                while (temp->left != nullptr) {
                    temp = temp->left;
                }
                int tempVal = temp->val;
                node->right = removeHelper(node->right, temp->val);
                node->val = tempVal;
            }
        }
        updateHeight(node); // Update node height
        /* 2. Perform rotation operation to restore balance to the subtree */
        node = rotate(node);
        // Return the root node of the subtree
        return node;
    }

  public:
    TreeNode *root; // Root node

    /* Get node height */
    int height(TreeNode *node) {
        // Empty node height is -1, leaf node height is 0
        return node == nullptr ? -1 : node->height;
    }

    /* Get balance factor */
    int balanceFactor(TreeNode *node) {
        // Empty node balance factor is 0
        if (node == nullptr)
            return 0;
        // Node balance factor = left subtree height - right subtree height
        return height(node->left) - height(node->right);
    }

    /* Insert node */
    void insert(int val) {
        root = insertHelper(root, val);
    }

    /* Remove node */
    void remove(int val) {
        root = removeHelper(root, val);
    }

    /* Search node */
    TreeNode *search(int val) {
        TreeNode *cur = root;
        // Loop find, break after passing leaf nodes
        while (cur != nullptr) {
            // Target node is in cur's right subtree
            if (cur->val < val)
                cur = cur->right;
            // Target node is in cur's left subtree
            else if (cur->val > val)
                cur = cur->left;
            // Found target node, break loop
            else
                break;
        }
        // Return target node
        return cur;
    }

    /*Constructor*/
    AVLTree() : root(nullptr) {
    }

    /*Destructor*/
    ~AVLTree() {
        freeMemoryTree(root);
    }
};

void testInsert(AVLTree &tree, int val) {
    tree.insert(val);
    cout << "\nAfter inserting node " << val << ", the AVL tree is" << endl;
    printTree(tree.root);
}

void testRemove(AVLTree &tree, int val) {
    tree.remove(val);
    cout << "\nAfter removing node " << val << ", the AVL tree is" << endl;
    printTree(tree.root);
}

/* Driver Code */
int main() {
    /* Initialize empty AVL tree */
    AVLTree avlTree;

    /* Insert node */
    // Notice how the AVL tree maintains balance after inserting nodes
    testInsert(avlTree, 1);
    testInsert(avlTree, 2);
    testInsert(avlTree, 3);
    testInsert(avlTree, 4);
    testInsert(avlTree, 5);
    testInsert(avlTree, 8);
    testInsert(avlTree, 7);
    testInsert(avlTree, 9);
    testInsert(avlTree, 10);
    testInsert(avlTree, 6);

    /* Insert duplicate node */
    testInsert(avlTree, 7);

    /* Remove node */
    // Notice how the AVL tree maintains balance after removing nodes
    testRemove(avlTree, 8); // Remove node with degree 0
    testRemove(avlTree, 5); // Remove node with degree 1
    testRemove(avlTree, 4); // Remove node with degree 2

    /* Search node */
    TreeNode *node = avlTree.search(7);
    cout << "\nThe found node object is " << node << ", node value =" << node->val << endl;
}
Add the initial EN translation for C++ code (#1346) 6 months ago			`/**`
			`* File: avl_tree.cpp`
			`* Created Time: 2023-02-03`
			`* Author: what-is-me (whatisme@outlook.jp)`
			`*/`

			`#include "../utils/common.hpp"`

			`/* AVL tree */`
			`class AVLTree {`
			`private:`
			`/* Update node height */`
			`void updateHeight(TreeNode *node) {`
			`// Node height equals the height of the tallest subtree + 1`
			`node->height = max(height(node->left), height(node->right)) + 1;`
			`}`

			`/* Right rotation operation */`
			`TreeNode rightRotate(TreeNode node) {`
			`TreeNode *child = node->left;`
			`TreeNode *grandChild = child->right;`
			`// Rotate node to the right around child`
			`child->right = node;`
			`node->left = grandChild;`
			`// Update node height`
			`updateHeight(node);`
			`updateHeight(child);`
			`// Return the root of the subtree after rotation`
			`return child;`
			`}`

			`/* Left rotation operation */`
			`TreeNode leftRotate(TreeNode node) {`
			`TreeNode *child = node->right;`
			`TreeNode *grandChild = child->left;`
			`// Rotate node to the left around child`
			`child->left = node;`
			`node->right = grandChild;`
			`// Update node height`
			`updateHeight(node);`
			`updateHeight(child);`
			`// Return the root of the subtree after rotation`
			`return child;`
			`}`

			`/* Perform rotation operation to restore balance to the subtree */`
			`TreeNode rotate(TreeNode node) {`
			`// Get the balance factor of node`
			`int _balanceFactor = balanceFactor(node);`
			`// Left-leaning tree`
			`if (_balanceFactor > 1) {`
			`if (balanceFactor(node->left) >= 0) {`
			`// Right rotation`
			`return rightRotate(node);`
			`} else {`
			`// First left rotation then right rotation`
			`node->left = leftRotate(node->left);`
			`return rightRotate(node);`
			`}`
			`}`
			`// Right-leaning tree`
			`if (_balanceFactor < -1) {`
			`if (balanceFactor(node->right) <= 0) {`
			`// Left rotation`
			`return leftRotate(node);`
			`} else {`
			`// First right rotation then left rotation`
			`node->right = rightRotate(node->right);`
			`return leftRotate(node);`
			`}`
			`}`
			`// Balanced tree, no rotation needed, return`
			`return node;`
			`}`

			`/* Recursively insert node (helper method) */`
			`TreeNode insertHelper(TreeNode node, int val) {`
			`if (node == nullptr)`
			`return new TreeNode(val);`
			`/* 1. Find insertion position and insert node */`
			`if (val < node->val)`
			`node->left = insertHelper(node->left, val);`
			`else if (val > node->val)`
			`node->right = insertHelper(node->right, val);`
			`else`
			`return node; // Do not insert duplicate nodes, return`
			`updateHeight(node); // Update node height`
			`/* 2. Perform rotation operation to restore balance to the subtree */`
			`node = rotate(node);`
			`// Return the root node of the subtree`
			`return node;`
			`}`

			`/* Recursively remove node (helper method) */`
			`TreeNode removeHelper(TreeNode node, int val) {`
			`if (node == nullptr)`
			`return nullptr;`
			`/* 1. Find and remove the node */`
			`if (val < node->val)`
			`node->left = removeHelper(node->left, val);`
			`else if (val > node->val)`
			`node->right = removeHelper(node->right, val);`
			`else {`
			`if (node->left == nullptr \|\| node->right == nullptr) {`
			`TreeNode *child = node->left != nullptr ? node->left : node->right;`
			`// Number of child nodes = 0, remove node and return`
			`if (child == nullptr) {`
			`delete node;`
			`return nullptr;`
			`}`
			`// Number of child nodes = 1, remove node`
			`else {`
			`delete node;`
			`node = child;`
			`}`
			`} else {`
			`// Number of child nodes = 2, remove the next node in in-order traversal and replace the current node with it`
			`TreeNode *temp = node->right;`
			`while (temp->left != nullptr) {`
			`temp = temp->left;`
			`}`
			`int tempVal = temp->val;`
			`node->right = removeHelper(node->right, temp->val);`
			`node->val = tempVal;`
			`}`
			`}`
			`updateHeight(node); // Update node height`
			`/* 2. Perform rotation operation to restore balance to the subtree */`
			`node = rotate(node);`
			`// Return the root node of the subtree`
			`return node;`
			`}`

			`public:`
			`TreeNode *root; // Root node`

			`/* Get node height */`
			`int height(TreeNode *node) {`
			`// Empty node height is -1, leaf node height is 0`
			`return node == nullptr ? -1 : node->height;`
			`}`

			`/* Get balance factor */`
			`int balanceFactor(TreeNode *node) {`
			`// Empty node balance factor is 0`
			`if (node == nullptr)`
			`return 0;`
			`// Node balance factor = left subtree height - right subtree height`
			`return height(node->left) - height(node->right);`
			`}`

			`/* Insert node */`
			`void insert(int val) {`
			`root = insertHelper(root, val);`
			`}`

			`/* Remove node */`
			`void remove(int val) {`
			`root = removeHelper(root, val);`
			`}`

			`/* Search node */`
			`TreeNode *search(int val) {`
			`TreeNode *cur = root;`
			`// Loop find, break after passing leaf nodes`
			`while (cur != nullptr) {`
			`// Target node is in cur's right subtree`
			`if (cur->val < val)`
			`cur = cur->right;`
			`// Target node is in cur's left subtree`
			`else if (cur->val > val)`
			`cur = cur->left;`
			`// Found target node, break loop`
			`else`
			`break;`
			`}`
			`// Return target node`
			`return cur;`
			`}`

			`/Constructor/`
			`AVLTree() : root(nullptr) {`
			`}`

			`/Destructor/`
			`~AVLTree() {`
			`freeMemoryTree(root);`
			`}`
			`};`

			`void testInsert(AVLTree &tree, int val) {`
			`tree.insert(val);`
			`cout << "\nAfter inserting node " << val << ", the AVL tree is" << endl;`
			`printTree(tree.root);`
			`}`

			`void testRemove(AVLTree &tree, int val) {`
			`tree.remove(val);`
			`cout << "\nAfter removing node " << val << ", the AVL tree is" << endl;`
			`printTree(tree.root);`
			`}`

			`/* Driver Code */`
			`int main() {`
			`/* Initialize empty AVL tree */`
			`AVLTree avlTree;`

			`/* Insert node */`
			`// Notice how the AVL tree maintains balance after inserting nodes`
			`testInsert(avlTree, 1);`
			`testInsert(avlTree, 2);`
			`testInsert(avlTree, 3);`
			`testInsert(avlTree, 4);`
			`testInsert(avlTree, 5);`
			`testInsert(avlTree, 8);`
			`testInsert(avlTree, 7);`
			`testInsert(avlTree, 9);`
			`testInsert(avlTree, 10);`
			`testInsert(avlTree, 6);`

			`/* Insert duplicate node */`
			`testInsert(avlTree, 7);`

			`/* Remove node */`
			`// Notice how the AVL tree maintains balance after removing nodes`
			`testRemove(avlTree, 8); // Remove node with degree 0`
			`testRemove(avlTree, 5); // Remove node with degree 1`
			`testRemove(avlTree, 4); // Remove node with degree 2`

			`/* Search node */`
			`TreeNode *node = avlTree.search(7);`
			`cout << "\nThe found node object is " << node << ", node value =" << node->val << endl;`
			`}`