#include #include #include #include // Get the height of an AVL node uint8_t get_height(struct AVLNode* node) { if (node == NULL) { return 0; } return node->height; } // Get the Maximum Height between two uint8_t max_height(uint8_t a, uint8_t b) { return (a > b) ? a : b; } // Get the balance factor of a node ssize_t get_balance_factor(struct AVLNode* node) { if (node == NULL) { return 0; } return get_height(node->left) - get_height(node->right); } // Rotate an AVL node right struct AVLNode* right_rotate(struct AVLNode* parent) { struct AVLNode* child1 = parent->left; struct AVLNode* child2 = child1->right; child1->right = parent; parent->left = child2; parent->height = max_height(get_height(parent->left), get_height(parent->right)) + 1; child1->height = max_height(get_height(child1->left), get_height(child1->right)) + 1; return child1; } // Rotate an AVL node left struct AVLNode* left_rotate(struct AVLNode* parent) { struct AVLNode* child1 = parent->right; struct AVLNode* child2 = child1->left; child1->left = parent; parent->right = child2; parent->height = max_height(get_height(parent->left), get_height(parent->right)) + 1; child1->height = max_height(get_height(child1->left), get_height(child1->right)) + 1; return child1; } // Create AVL node struct AVLNode* create_avl_node(void* data, bool_t (*compare)(void*, void*)) { struct AVLNode* node = (struct AVLNode*)malloc(sizeof(struct AVLNode)); if (node == NULL) { return NULL; } node->data = data; node->compare = compare; node->left = NULL; node->right = NULL; node->height = 1; // Leaf initially return node; } // Insert data into AVL tree struct Result avl_insert(struct AVLNode* node, void* data, bool_t (*compare)(void*, void*)) { struct Result result; // 1. Standard BST insertion if (node == NULL) { return (struct Result) {create_avl_node(data, compare), TRUE}; } struct MaskData *node_data = (struct MaskData*)node->data; if (node->compare(data, node_data)) { result = avl_insert(node->left, data, compare); if (!result.success) { fprintf(stderr, "Failed to insert!"); return result; } node->left = (struct AVLNode*)result.data; } else if (node->compare(node->data, data)) { result = avl_insert(node->right, data, compare); if (!result.success) { fprintf(stderr, "Failed to insert!"); return result; } node->right = (struct AVLNode*)result.data; } else { return (struct Result) {node, FALSE}; } // 2. Update height of the ancestor node node->height = 1 + max_height(get_height(node->left), get_height(node->right)); ssize_t balance = get_balance_factor(node); // 4. If the node becomes unbalanced // LeftLeft if ((balance > 1) && node->compare(data, node->left->data)) { return (struct Result) {right_rotate(node), TRUE}; } // RightRight if ((balance < -1) && node->compare(node->right->data, data)) { return (struct Result) {left_rotate(node), TRUE}; } // LeftRight if ((balance > 1) && node->compare(node->left->data, data)) { return (struct Result) {right_rotate(node), TRUE}; } // RightLeft if ((balance < -1) && node->compare(data,node->right->data)) { return (struct Result) {left_rotate(node), TRUE}; } return (struct Result) {node, TRUE}; } // In-order traversal print pointer void print_in_order(struct AVLNode* root) { if (root != NULL) { print_in_order(root->left); printf("%p ", root->data); print_in_order(root->right); } } // Free avl tree nodes starting at root void free_avl_tree(struct AVLNode* root) { if (root != NULL) { free_avl_tree(root->left); free_avl_tree(root->right); free(root); } } // Free avl tree and their data starting at root void free_avl_tree_nodes(struct AVLNode* root) { if (root != NULL) { free_avl_tree_nodes(root->left); free_avl_tree_nodes(root->right); if (root->data != NULL) { free(root->data); } free(root); } }