• 【python刷题】二叉树-相关题目


    计算二叉树有多少个节点

    def count(root):
        if not root:
            return 0
       return 1 + count(root.left) + count(root.right)   
    

    计算二叉树的深度

    def count_depth(root):
        if not root:
            return 0
        return max(count_depth(root.left), count_depth(root.right)) + 1
    

    226. 翻转二叉树

    class Solution:
        def invertTree(self, root: TreeNode) -> TreeNode:
            if not root:
                return None
            root.left, root.right = root.right, root.left
            self.invertTree(root.left)
            self.invertTree(root.right)
            return root
    

    114. 二叉树展开为链表

    class Solution:
        def flatten(self, root: TreeNode) -> None:
            """
            Do not return anything, modify root in-place instead.
            """
            if not root:
                return None
            self.flatten(root.left)
            self.flatten(root.right)
            left = root.left
            right = root.right
            root.left = None
            root.right = left
            p = root
            while p.right:
                p = p.right
                
            p.right = right
            return root
    

    116. 填充每个节点的下一个右侧节点指针

    class Solution:
        def connect(self, root: 'Node') -> 'Node':
            if not root:
                return None
            self.connectTwoNode(root.left, root.right)
            return root
        def connectTwoNode(self, node1, node2):
            if (not node1) or (not node2):
                return
            node1.next = node2
            self.connectTwoNode(node1.left, node1.right)
            self.connectTwoNode(node2.left, node2.right)
            self.connectTwoNode(node1.right, node1.left)
    

    654. 最大二叉树

    class Solution:
        def constructMaximumBinaryTree(self, nums: List[int]) -> TreeNode:
            m = max(nums)
            ind = nums.index(m)
            l = nums[:ind]
            r = nums[ind+1:]
            t = TreeNode(m)
            t.left = self.constructMaximumBinaryTree(l) if l else None
            t.right = self.constructMaximumBinaryTree(r) if r else None
            return t
    

    105. 从前序与中序遍历序列构造二叉树

    class Solution(object):
        def buildTree(self, preorder, inorder):
            """
            :type preorder: List[int]
            :type inorder: List[int]
            :rtype: TreeNode
            """
            #先序遍历的列表为[根,左,右],中序遍历的列表为[左,根,右],则中序遍历中根的下标为先序遍历中左的边界
            if not preorder:
                return None
            root = TreeNode(preorder[0])
            #找到根节点在中序遍历中的下标
            n = inorder.index(root.val)
            root.left = self.buildTree(preorder[1:n+1],inorder[:n])
            root.right = self.buildTree(preorder[n+1:],inorder[n+1:])
            return root 
    

    106. 从中序与后序遍历序列构造二叉树

    class Solution:
        def buildTree(self, inorder: List[int], postorder: List[int]) -> TreeNode:
            if not postorder:
                return None
            root = TreeNode(postorder[-1])
            n = inorder.index(root.val)
            root.left = self.buildTree(inorder[:n],postorder[:n])
            root.right = self.buildTree(inorder[n+1:],postorder[n:-1])
            return root
    

    652. 寻找重复的子树

    class Solution:
        def findDuplicateSubtrees(self, root: TreeNode) -> List[TreeNode]:
            res = []
            from collections import defaultdict
            memo = defaultdict(int)
            def traverse(root):
                if not root:
                    return "#"
                left = traverse(root.left)
                right = traverse(root.right)
                subTree = "{},{},{}".format(left, right, root.val)
                memo[subTree] += 1
                if memo[subTree] == 2:
                    res.append(root)
                return subTree
            traverse(root)
            return res
    

    236. 二叉树的最近公共祖先

    class Solution:
        def lowestCommonAncestor(self, root: 'TreeNode', p: 'TreeNode', q: 'TreeNode') -> 'TreeNode':
            if not root:
                return None
            if root == p or root == q:
                return root
            left = self.lowestCommonAncestor(root.left, p, q)
            right = self.lowestCommonAncestor(root.right, p, q)
            if left is not None and right is not None:
                return root
            if left is None and right is None:
                return None
            return right if left is None else left
    

    110. 平衡二叉树

    #自顶向下:
    class Solution:
        def isBalanced(self, root: TreeNode) -> bool:
            def height(root: TreeNode) -> int:
                if not root:
                    return 0
                return max(height(root.left), height(root.right)) + 1
    
            if not root:
                return True
            return abs(height(root.left) - height(root.right)) <= 1 and self.isBalanced(root.left) and self.isBalanced(root.right)
    #自底向上
    class Solution:
        def isBalanced(self, root: TreeNode) -> bool:
            def height(root):
                if not root:
                    return 0
                left = height(root.left)
                right = height(root.right)
                if left == -1 or right == -1 or abs(left - right) >= 2:
                    return -1
                else:
                    return max(left, right) + 1
            res = height(root)
            return res >=0 
    

    589. N叉树的前序遍历

    class Solution:
        def __init__(self):
            self.res = []
        def preorder(self, root: 'Node') -> List[int]:
            if not root:
                return []
            self.res.append(root.val)
            for child in root.children:
                self.preorder(child)
            return self.res
    

    897. 递增顺序查找树

    class Solution:
        def increasingBST(self, root: TreeNode) -> TreeNode:
            self.x = ans = TreeNode(0)
            def traverse(root):
                if root:
                    traverse(root.left)
                    t = TreeNode(root.val)
                    self.x.right = t
                    self.x = t
                    traverse(root.right)
            traverse(root)
            return ans.right
    

    112. 路径总和

    class Solution:
        def hasPathSum(self, root: TreeNode, targetSum: int) -> bool:
            if not root:
                return False
            if not root.left and not root.right:
                return targetSum == root.val
            return self.hasPathSum(root.left, targetSum - root.val) or self.hasPathSum(root.right, targetSum - root.val)
    

    1022. 从根到叶的二进制数之和

    class Solution:
        def __init__(self):
            self.res = 0
        def sumRootToLeaf(self, root: TreeNode) -> int:
            def traverse(root, s):
                if not root:
                    return 0
                s = s * 2 + root.val
                if not root.left and not root.right:
                    self.res += s
                traverse(root.left, s)
                traverse(root.right, s)
            traverse(root, 0)
            return self.res
    

    617. 合并二叉树

    class Solution:
        def mergeTrees(self, t1: TreeNode, t2: TreeNode) -> TreeNode:
            if not t1:
                return t2
            if not t2:
                return t1
            if not t1 and not t2:
                return None
            root = TreeNode(t1.val + t2.val)
            root.left = self.mergeTrees(t1.left, t2.left)
            root.right = self.mergeTrees(t1.right, t2.right)
            return root
    

    107. 二叉树的层序遍历 II

    class Solution:
        def levelOrderBottom(self, root: TreeNode) -> List[List[int]]:
            res = [[]]
            def traverse(root, lev):
                if not root:
                    return 
                res[lev-1].append(root.val)
                if len(res) == lev:
                    res.append([])
                traverse(root.left, lev+1)
                traverse(root.right, lev+1)            
            traverse(root, 1)
            return res[:-1][::-1]
    

    100. 相同的树

    class Solution:
        def isSameTree(self, p: TreeNode, q: TreeNode) -> bool:
            if q is None and p is not None:
                return False
            if p is None and q is not None:
                return False
            if p is None and q is None:
                return True
            return p.val == q.val and self.isSameTree(p.left, q.left) and self.isSameTree(p.right, q.right)
    

    404. 左叶子之和

    class Solution:
        def sumOfLeftLeaves(self, root: TreeNode) -> int:
            if not root:
                return 0
            if root.left is None:
               return self.sumOfLeftLeaves(root.right)
            if root.left.left is None and root.left.right is None:
                return root.left.val + self.sumOfLeftLeaves(root.right)
            return self.sumOfLeftLeaves(root.left) + self.sumOfLeftLeaves(root.right)
    

    965. 单值二叉树

    class Solution:
        def isUnivalTree(self, root: TreeNode) -> bool:
            left = not root.left or root.val == root.left.val and self.isUnivalTree(root.left)
            right = not root.right or root.val == root.right.val and self.isUnivalTree(root.right)
            return left and right
    

    669. 修剪二叉搜索树

    class Solution:
        def trimBST(self, root: TreeNode, low: int, high: int) -> TreeNode:
            def traverse(root, low ,high):
                if not root:
                    return None
                elif root.val < low:
                    return self.trimBST(root.right, low, high)
                elif root.val > high:
                    return self.trimBST(root.left, low ,high)
                else:
                    root.left = traverse(root.left, low ,high)
                    root.right = traverse(root.right, low, high)
                    return root
            return traverse(root, low, high)
    

    993. 二叉树的堂兄弟节点

    class Solution:
        def isCousins(self, root: TreeNode, x: int, y: int) -> bool:
            def traverse(root, parent, target, depth):
                if not root:
                    return (-1, parent)
                if root.val == target:
                    return (depth, parent)
                l = traverse(root.left, root, target, depth + 1)
                r = traverse(root.right, root, target, depth + 1)
                if l[0] != -1:
                    return l
                return r
            dx, px = traverse(root, None, x, 0)
            dy, py = traverse(root, None, y, 0)
            if dx == dy and px != py:
                return True
            else:
                return False
    

    653. 两数之和 IV - 输入 BST

    class Solution:
        def findTarget(self, root: TreeNode, k: int) -> bool:
            def traverse(root, k, tmp):
                if not root:
                    return False
                if k - root.val in tmp:
                    return True
                tmp.add(root.val)
                return traverse(root.left, k, tmp) or traverse(root.right, k, tmp)
            tmp = set()
            return traverse(root, k, tmp)
    

    543. 二叉树的直径

    class Solution:
        def diameterOfBinaryTree(self, root: TreeNode) -> int:
            if not root:
                return 0
            res = float("-inf")
            def traverse(root):
                nonlocal res
                if not root:
                    return 0
                left = traverse(root.left)
                right = traverse(root.right)
                res = max(left + right, res)
                return max(left, right) + 1 
            traverse(root)
            return res
    

    树的子结构

    # -*- coding:utf-8 -*-
    # class TreeNode:
    #     def __init__(self, x):
    #         self.val = x
    #         self.left = None
    #         self.right = None
    class Solution:
        def HasSubtree(self, pRoot1, pRoot2):
            result = False
            if pRoot1 and pRoot2:
                if pRoot1.val == pRoot2.val:
                    result = self.check_structure(pRoot1, pRoot2)
                if not result:
                    result = self.HasSubtree(pRoot1.left, pRoot2)
                if not result:
                    result = self.HasSubtree(pRoot1.right, pRoot2)
            return result
        def check_structure(self, root1, root2):
            if not root2:
                return True
            if not root1:
                return False
            if root1.val != root2.val:
                return False
            left_check = self.check_structure(root1.left, root2.left)
            right_check = self.check_structure(root1.right, root2.right)
            return left_check and right_check    
    
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  • 原文地址:https://www.cnblogs.com/xiximayou/p/14287533.html
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