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98.validate-binary-search-tree.md

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题目地址

https://leetcode.com/problems/validate-binary-search-tree/description/

题目描述

Given a binary tree, determine if it is a valid binary search tree (BST).

Assume a BST is defined as follows:

The left subtree of a node contains only nodes with keys less than the node's key.
The right subtree of a node contains only nodes with keys greater than the node's key.
Both the left and right subtrees must also be binary search trees.
 

Example 1:

    2
   / \
  1   3

Input: [2,1,3]
Output: true
Example 2:

    5
   / \
  1   4
     / \
    3   6

Input: [5,1,4,null,null,3,6]
Output: false
Explanation: The root node's value is 5 but its right child's value is 4.


思路

中序遍历

这道题是让你验证一棵树是否为二叉查找树(BST)。 由于中序遍历的性质如果一个树遍历的结果是有序数组,那么他也是一个二叉查找树(BST), 我们只需要中序遍历,然后两两判断是否有逆序的元素对即可,如果有,则不是BST,否则即为一个BST。

定义法

根据定义,一个结点若是在根的左子树上,那它应该小于根结点的值而大于左子树最大值;若是在根的右子树上,那它应该大于根结点的值而小于右子树最小值。也就是说,每一个结点必须落在某个取值范围:

  1. 根结点的取值范围为(考虑某个结点为最大或最小整数的情况):(long_min, long_max)
  2. 左子树的取值范围为:(current_min, root.value)
  3. 右子树的取值范围为:(root.value, current_max)

关键点解析

  • 二叉树的基本操作(遍历)
  • 中序遍历一个二叉查找树(BST)的结果是一个有序数组
  • 如果一个树遍历的结果是有序数组,那么他也是一个二叉查找树(BST)

代码

中序遍历

  • 语言支持:JS,C++

JavaScript Code:

/*
 * @lc app=leetcode id=98 lang=javascript
 *
 * [98] Validate Binary Search Tree
 */
/**
 * Definition for a binary tree node.
 * function TreeNode(val) {
 *     this.val = val;
 *     this.left = this.right = null;
 * }
 */
/**
 * @param {TreeNode} root
 * @return {boolean}
 */
var isValidBST = function(root) {
    if (root === null) return true;
    if (root.left === null && root.right === null) return true;
    const stack = [root];
    let cur = root;
    let pre = null;

    function insertAllLefts(cur) {
        while(cur && cur.left) {
            const l = cur.left;
            stack.push(l);
            cur = l;
        }
    }
    insertAllLefts(cur);

    while(cur = stack.pop()) {
        if (pre && cur.val <= pre.val) return false;
        const r = cur.right;

        if (r) {
            stack.push(r);
            insertAllLefts(r);
        }
        pre = cur;
    }

    return true;
};

C++ Code:

// 递归
class Solution {
public:
    bool isValidBST(TreeNode* root) {
        TreeNode* prev = nullptr;
        return validateBstInorder(root, prev);
    }
    
private:
    bool validateBstInorder(TreeNode* root, TreeNode*& prev) {
        if (root == nullptr) return true;
        if (!validateBstInorder(root->left, prev)) return false;
        if (prev != nullptr && prev->val >= root->val) return false;
        prev = root;
        return validateBstInorder(root->right, prev);
    }
};

// 迭代
class Solution {
public:
    bool isValidBST(TreeNode* root) {
        auto s = vector<TreeNode*>();
        TreeNode* prev = nullptr;
        while (root != nullptr || !s.empty()) {
            while (root != nullptr) {
                s.push_back(root);
                root = root->left;
            }
            root = s.back();
            s.pop_back();
            if (prev != nullptr && prev->val >= root->val) return false;
            prev = root;
            root = root->right;
        }
        return true;
    }
};

定义法

  • 语言支持:C++

C++ Code:

/**
 * Definition for a binary tree node.
 * struct TreeNode {
 *     int val;
 *     TreeNode *left;
 *     TreeNode *right;
 *     TreeNode(int x) : val(x), left(NULL), right(NULL) {}
 * };
 */
// 递归
class Solution {
public:
    bool isValidBST(TreeNode* root) {
        return helper(root, LONG_MIN, LONG_MAX);
    }
private:
    bool helper(const TreeNode* root, long min, long max) {
        if (root == nullptr) return true;
        if (root->val >= max || root->val <= min) return false;
        return helper(root->left, min, root->val) && helper(root->right, root->val, max);
    }
};

// 循环
class Solution {
public:
    bool isValidBST(TreeNode* root) {
        if (root == nullptr) return true;
        auto ranges = queue<pair<long, long>>();
        ranges.push(make_pair(LONG_MIN, LONG_MAX));
        auto nodes = queue<const TreeNode*>();
        nodes.push(root);
        while (!nodes.empty()) {
            auto sz = nodes.size();
            for (auto i = 0; i < sz; ++i) {
                auto range = ranges.front();
                ranges.pop();
                auto n = nodes.front();
                nodes.pop();
                if (n->val >= range.second || n->val <= range.first) {
                    return false;
                }
                if (n->left != nullptr) {
                    ranges.push(make_pair(range.first, n->val));
                    nodes.push(n->left);
                }
                if (n->right != nullptr) {
                    ranges.push(make_pair(n->val, range.second));
                    nodes.push(n->right);
                }
            }
        }
        return true;
    }
};

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