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

/*
 * File: avl_tree.cpp
 * Created Time: 2022-12-2
 * Author: mgisr (maguagua0706@gmail.com)
 */

#include "../include/include.hpp"

class AvlTree {
private:
    TreeNode *root{};
    static bool isBalance(const TreeNode *p);
    static int getBalanceFactor(const TreeNode *p);
    static void updateHeight(TreeNode *p);
    void fixBalance(TreeNode *p);
    static bool isLeftChild(const TreeNode *p);
    static TreeNode *&fromParentTo(TreeNode *node);
public:
    AvlTree() = default;
    AvlTree(const AvlTree &p) = default;
    const TreeNode *search(int val);
    bool insert(int val);
    bool remove(int val);
    void printTree();
};

// 判断该结点是否平衡
bool AvlTree::isBalance(const TreeNode *p) {
    int balance_factor = getBalanceFactor(p);
    if (-1 <= balance_factor && balance_factor <= 1) { return true; }
    else { return false; }
}

// 获取当前结点的平衡因子
int AvlTree::getBalanceFactor(const TreeNode *p) {
    if (p->left == nullptr && p->right == nullptr) { return 0; }
    else if (p->left == nullptr) { return (-p->right->height); }
    else if (p->right == nullptr) { return p->left->height; }
    else { return p->left->height - p->right->height; }
}

// 更新结点高度
void AvlTree::updateHeight(TreeNode *p) {
    if (p->left == nullptr && p->right == nullptr) { p->height = 1; }
    else if (p->left == nullptr) { p->height = p->right->height + 1; }
    else if (p->right == nullptr) { p->height = p->left->height + 1; }
    else { p->height = std::max(p->left->height, p->right->height) + 1; }
}

void AvlTree::fixBalance(TreeNode *p) {
    // 左旋操作
    auto rotate_left = [&](TreeNode *node) -> TreeNode * {
        TreeNode *temp = node->right;
        temp->parent = p->parent;
        node->right = temp->left;
        if (temp->left != nullptr) {
            temp->left->parent = node;
        }
        temp->left = node;
        node->parent = temp;
        updateHeight(node);
        updateHeight(temp);
        return temp;
    };
    // 右旋操作
    auto rotate_right = [&](TreeNode *node) -> TreeNode * {
        TreeNode *temp = node->left;
        temp->parent = p->parent;
        node->left = temp->right;
        if (temp->right != nullptr) {
            temp->right->parent = node;
        }
        temp->right = node;
        node->parent = temp;
        updateHeight(node);
        updateHeight(temp);
        return temp;
    };
    // 根据规则选取旋转方式
    if (getBalanceFactor(p) > 1) {
        if (getBalanceFactor(p->left) > 0) {
            if (p->parent == nullptr) { root = rotate_right(p); }
            else { fromParentTo(p) = rotate_right(p); }
        } else {
            p->left = rotate_left(p->left);
            if (p->parent == nullptr) { root = rotate_right(p); }
            else { fromParentTo(p) = rotate_right(p); }
        }
    } else {
        if (getBalanceFactor(p->right) < 0) {
            if (p->parent == nullptr) { root = rotate_left(p); }
            else { fromParentTo(p) = rotate_left(p); }
        } else {
            p->right = rotate_right(p->right);
            if (p->parent == nullptr) { root = rotate_left(p); }
            else { fromParentTo(p) = rotate_left(p); }
        }
    }
}

// 判断当前结点是否为其父节点的左孩子
bool AvlTree::isLeftChild(const TreeNode *p) {
    if (p->parent == nullptr) { return false; }
    return (p->parent->left == p);
}

// 返回父节点指向当前结点指针的引用
TreeNode *&AvlTree::fromParentTo(TreeNode *node) {
    if (isLeftChild(node)) { return node->parent->left; }
    else { return node->parent->right; }
}

const TreeNode *AvlTree::search(int val) {
    TreeNode *p = root;
    while (p != nullptr) {
        if (p->val == val) { return p; }
        else if (p->val > val) { p = p->left; }
        else { p = p->right; }
    }
    return nullptr;
}

bool AvlTree::insert(int val) {
    TreeNode *p = root;
    if (p == nullptr) {
        root = new TreeNode(val);
        return true;
    }
    for (;;) {
        if (p->val == val) { return false; }
        else if (p->val > val) {
            if (p->left == nullptr) {
                p->left = new TreeNode(val, p);
                break;
            } else {
                p = p->left;
            }
        } else {
            if (p->right == nullptr) {
                p->right = new TreeNode(val, p);
                break;
            } else {
                p = p->right;
            }
        }
    }
    for (; p != nullptr; p = p->parent) {
        if (!isBalance(p)) {
            fixBalance(p);
            break;
        } else { updateHeight(p); }
    }
    return true;
}

bool AvlTree::remove(int val) {
    TreeNode *p = root;
    if (p == nullptr) { return false; }
    while (p != nullptr) {
        if (p->val == val) {
            TreeNode *real_delete_node = p;
            TreeNode *next_node;
            if (p->left == nullptr) {
                next_node = p->right;
                if (p->parent == nullptr) { root = next_node; }
                else { fromParentTo(p) = next_node; }
            } else if (p->right == nullptr) {
                next_node = p->left;
                if (p->parent == nullptr) { root = next_node; }
                else { fromParentTo(p) = next_node; }
            } else {
                while (real_delete_node->left != nullptr) {
                    real_delete_node = real_delete_node->left;
                }
                std::swap(p->val, real_delete_node->val);
                next_node = real_delete_node->right;
                if (real_delete_node->parent == p) { p->right = next_node; }
                else { real_delete_node->parent->left = next_node; }
            }
            if (next_node != nullptr) {
                next_node->parent = real_delete_node->parent;
            }
            for (p = real_delete_node; p != nullptr; p = p->parent) {
                if (!isBalance(p)) { fixBalance(p); }
                updateHeight(p);
            }
            delete real_delete_node;
            return true;
        } else if (p->val > val) {
            p = p->left;
        } else {
            p = p->right;
        }
    }
    return false;
}

void inOrder(const TreeNode *root) {
    if (root == nullptr) return;
    inOrder(root->left);
    cout << root->val << ' ';
    inOrder(root->right);
}

void AvlTree::printTree() {
    inOrder(root);
    cout << endl;
}

int main() {
    AvlTree tree = AvlTree();
    // tree.insert(13);
    // tree.insert(24);
    // tree.insert(37);
    // tree.insert(90);
    // tree.insert(53);

    tree.insert(53);
    tree.insert(90);
    tree.insert(37);
    tree.insert(24);
    tree.insert(13);
    tree.remove(90);
    tree.printTree();
    const TreeNode *p = tree.search(37);
    cout << p->val;
    return 0;
}
feat(codes/cpp/chapter_tree/avl_tree.cpp): create 'avl_tree.cpp' 2022-12-03 09:15:51 +00:00			`/*`
			`* File: avl_tree.cpp`
			`* Created Time: 2022-12-2`
			`* Author: mgisr (maguagua0706@gmail.com)`
			`*/`

			`#include "../include/include.hpp"`

			`class AvlTree {`
			`private:`
			`TreeNode *root{};`
			`static bool isBalance(const TreeNode *p);`
			`static int getBalanceFactor(const TreeNode *p);`
			`static void updateHeight(TreeNode *p);`
			`void fixBalance(TreeNode *p);`
			`static bool isLeftChild(const TreeNode *p);`
			`static TreeNode &fromParentTo(TreeNode node);`
			`public:`
			`AvlTree() = default;`
			`AvlTree(const AvlTree &p) = default;`
			`const TreeNode *search(int val);`
			`bool insert(int val);`
			`bool remove(int val);`
			`void printTree();`
			`};`

			`// 判断该结点是否平衡`
			`bool AvlTree::isBalance(const TreeNode *p) {`
			`int balance_factor = getBalanceFactor(p);`
			`if (-1 <= balance_factor && balance_factor <= 1) { return true; }`
			`else { return false; }`
			`}`

			`// 获取当前结点的平衡因子`
			`int AvlTree::getBalanceFactor(const TreeNode *p) {`
			`if (p->left == nullptr && p->right == nullptr) { return 0; }`
			`else if (p->left == nullptr) { return (-p->right->height); }`
			`else if (p->right == nullptr) { return p->left->height; }`
			`else { return p->left->height - p->right->height; }`
			`}`

			`// 更新结点高度`
			`void AvlTree::updateHeight(TreeNode *p) {`
			`if (p->left == nullptr && p->right == nullptr) { p->height = 1; }`
			`else if (p->left == nullptr) { p->height = p->right->height + 1; }`
			`else if (p->right == nullptr) { p->height = p->left->height + 1; }`
			`else { p->height = std::max(p->left->height, p->right->height) + 1; }`
			`}`

			`void AvlTree::fixBalance(TreeNode *p) {`
			`// 左旋操作`
			`auto rotate_left = [&](TreeNode node) -> TreeNode {`
			`TreeNode *temp = node->right;`
			`temp->parent = p->parent;`
			`node->right = temp->left;`
			`if (temp->left != nullptr) {`
			`temp->left->parent = node;`
			`}`
			`temp->left = node;`
			`node->parent = temp;`
			`updateHeight(node);`
			`updateHeight(temp);`
			`return temp;`
			`};`
			`// 右旋操作`
			`auto rotate_right = [&](TreeNode node) -> TreeNode {`
			`TreeNode *temp = node->left;`
			`temp->parent = p->parent;`
			`node->left = temp->right;`
			`if (temp->right != nullptr) {`
			`temp->right->parent = node;`
			`}`
			`temp->right = node;`
			`node->parent = temp;`
			`updateHeight(node);`
			`updateHeight(temp);`
			`return temp;`
			`};`
			`// 根据规则选取旋转方式`
			`if (getBalanceFactor(p) > 1) {`
			`if (getBalanceFactor(p->left) > 0) {`
			`if (p->parent == nullptr) { root = rotate_right(p); }`
			`else { fromParentTo(p) = rotate_right(p); }`
			`} else {`
			`p->left = rotate_left(p->left);`
			`if (p->parent == nullptr) { root = rotate_right(p); }`
			`else { fromParentTo(p) = rotate_right(p); }`
			`}`
			`} else {`
			`if (getBalanceFactor(p->right) < 0) {`
			`if (p->parent == nullptr) { root = rotate_left(p); }`
			`else { fromParentTo(p) = rotate_left(p); }`
			`} else {`
			`p->right = rotate_right(p->right);`
			`if (p->parent == nullptr) { root = rotate_left(p); }`
			`else { fromParentTo(p) = rotate_left(p); }`
			`}`
			`}`
			`}`

			`// 判断当前结点是否为其父节点的左孩子`
			`bool AvlTree::isLeftChild(const TreeNode *p) {`
			`if (p->parent == nullptr) { return false; }`
			`return (p->parent->left == p);`
			`}`

			`// 返回父节点指向当前结点指针的引用`
			`TreeNode &AvlTree::fromParentTo(TreeNode node) {`
			`if (isLeftChild(node)) { return node->parent->left; }`
			`else { return node->parent->right; }`
			`}`

			`const TreeNode *AvlTree::search(int val) {`
			`TreeNode *p = root;`
			`while (p != nullptr) {`
			`if (p->val == val) { return p; }`
			`else if (p->val > val) { p = p->left; }`
			`else { p = p->right; }`
			`}`
			`return nullptr;`
			`}`

			`bool AvlTree::insert(int val) {`
			`TreeNode *p = root;`
			`if (p == nullptr) {`
			`root = new TreeNode(val);`
			`return true;`
			`}`
			`for (;;) {`
			`if (p->val == val) { return false; }`
			`else if (p->val > val) {`
			`if (p->left == nullptr) {`
			`p->left = new TreeNode(val, p);`
			`break;`
			`} else {`
			`p = p->left;`
			`}`
			`} else {`
			`if (p->right == nullptr) {`
			`p->right = new TreeNode(val, p);`
			`break;`
			`} else {`
			`p = p->right;`
			`}`
			`}`
			`}`
			`for (; p != nullptr; p = p->parent) {`
			`if (!isBalance(p)) {`
			`fixBalance(p);`
			`break;`
			`} else { updateHeight(p); }`
			`}`
			`return true;`
			`}`

			`bool AvlTree::remove(int val) {`
			`TreeNode *p = root;`
			`if (p == nullptr) { return false; }`
			`while (p != nullptr) {`
			`if (p->val == val) {`
			`TreeNode *real_delete_node = p;`
			`TreeNode *next_node;`
			`if (p->left == nullptr) {`
			`next_node = p->right;`
			`if (p->parent == nullptr) { root = next_node; }`
			`else { fromParentTo(p) = next_node; }`
			`} else if (p->right == nullptr) {`
			`next_node = p->left;`
			`if (p->parent == nullptr) { root = next_node; }`
			`else { fromParentTo(p) = next_node; }`
			`} else {`
			`while (real_delete_node->left != nullptr) {`
			`real_delete_node = real_delete_node->left;`
			`}`
			`std::swap(p->val, real_delete_node->val);`
			`next_node = real_delete_node->right;`
			`if (real_delete_node->parent == p) { p->right = next_node; }`
			`else { real_delete_node->parent->left = next_node; }`
			`}`
			`if (next_node != nullptr) {`
			`next_node->parent = real_delete_node->parent;`
			`}`
			`for (p = real_delete_node; p != nullptr; p = p->parent) {`
			`if (!isBalance(p)) { fixBalance(p); }`
			`updateHeight(p);`
			`}`
			`delete real_delete_node;`
			`return true;`
			`} else if (p->val > val) {`
			`p = p->left;`
			`} else {`
			`p = p->right;`
			`}`
			`}`
			`return false;`
			`}`

			`void inOrder(const TreeNode *root) {`
			`if (root == nullptr) return;`
			`inOrder(root->left);`
			`cout << root->val << ' ';`
			`inOrder(root->right);`
			`}`

			`void AvlTree::printTree() {`
			`inOrder(root);`
			`cout << endl;`
			`}`

			`int main() {`
			`AvlTree tree = AvlTree();`
			`// tree.insert(13);`
			`// tree.insert(24);`
			`// tree.insert(37);`
			`// tree.insert(90);`
			`// tree.insert(53);`

			`tree.insert(53);`
			`tree.insert(90);`
			`tree.insert(37);`
			`tree.insert(24);`
			`tree.insert(13);`
			`tree.remove(90);`
			`tree.printTree();`
			`const TreeNode *p = tree.search(37);`
			`cout << p->val;`
			`return 0;`
			`}`