• [Swift]LeetCode107. 二叉树的层次遍历 II | Binary Tree Level Order Traversal II


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    Given a binary tree, return the bottom-up level order traversal of its nodes' values. (ie, from left to right, level by level from leaf to root).

    For example:
    Given binary tree [3,9,20,null,null,15,7],

        3
       / 
      9  20
        /  
       15   7
    

    return its bottom-up level order traversal as:

    [
      [15,7],
      [9,20],
      [3]
    ]

    给定一个二叉树,返回其节点值自底向上的层次遍历。 (即按从叶子节点所在层到根节点所在的层,逐层从左向右遍历)

    例如:
    给定二叉树 [3,9,20,null,null,15,7],

        3
       / 
      9  20
        /  
       15   7
    

    返回其自底向上的层次遍历为:

    [
      [15,7],
      [9,20],
      [3]
    ]

    12ms
    /**
     * Definition for a binary tree node.
     * public class TreeNode {
     *     public var val: Int
     *     public var left: TreeNode?
     *     public var right: TreeNode?
     *     public init(_ val: Int) {
     *         self.val = val
     *         self.left = nil
     *         self.right = nil
     *     }
     * }
     */
    class Solution {
        func levelOrderBottom(_ root: TreeNode?) -> [[Int]] {
            //递归方法
            //当depth递归到上一层的个数,新建一个空层,继续往里面加数字。
            var res:[[Int]] =  [[Int]]()
            if root == nil {return res}
            var intList:[Int] = [Int]()
            levelOrder(root , 0 , &res)
            var temp:[Int] = [Int]()
            let num:Int = res.count-1
            //交换第一位和最后一位
            //交换第二位和倒数第二位......
            for i in 0...num
            {
                temp = res[i]
                res[i] = res[num-i]
                res[num-i] = temp
            }
            return res.reversed()
        }
        func levelOrder(_ root: TreeNode?, _ depth:Int,_ re: inout [[Int]] )
        {
            if root == nil {return}
            if (depth + 1) > re.count 
            {
                re.append([Int]())
            }
            re[depth].append(root!.val)
            levelOrder(root!.left,depth+1,&re)
            levelOrder(root!.right,depth+1,&re)    
        }
    }

    12ms

     1 /**
     2  * Definition for a binary tree node.
     3  * public class TreeNode {
     4  *     public var val: Int
     5  *     public var left: TreeNode?
     6  *     public var right: TreeNode?
     7  *     public init(_ val: Int) {
     8  *         self.val = val
     9  *         self.left = nil
    10  *         self.right = nil
    11  *     }
    12  * }
    13  */
    14 class Solution {
    15     func levelOrderBottom (_ root: TreeNode?) -> [[Int]] {
    16         var res = [[Int]]()
    17         checkValuesOnLevel(&res, node: root, level: 0)
    18         return res
    19     }
    20     
    21     func checkValuesOnLevel (_ res: inout [[Int]], node: TreeNode?, level: Int) {
    22         guard let node = node else { return }
    23         if level >= res.count {
    24             res.insert ([], at: 0)
    25         }
    26         checkValuesOnLevel(&res, node: node.left, level: level + 1)
    27         checkValuesOnLevel(&res, node: node.right, level: level + 1)
    28         res[res.count - level - 1].append(node.val)
    29     }
    30 }

     16ms

     1 /**
     2  * Definition for a binary tree node.
     3  * public class TreeNode {
     4  *     public var val: Int
     5  *     public var left: TreeNode?
     6  *     public var right: TreeNode?
     7  *     public init(_ val: Int) {
     8  *         self.val = val
     9  *         self.left = nil
    10  *         self.right = nil
    11  *     }
    12  * }
    13  */
    14 class Solution {
    15     func levelOrderBottom(_ root: TreeNode?) -> [[Int]] {
    16             guard let tNode = root else {
    17         return []
    18     }
    19     var result: [[Int]] = []
    20     var tempNodes: [TreeNode] = [tNode]
    21     while !tempNodes.isEmpty {
    22         let count = tempNodes.count
    23         var data: [Int] = []
    24         for i in 0..<count {
    25             let node = tempNodes[i]
    26             data.append(node.val)
    27             if let lNode = node.left {
    28                 tempNodes.append(lNode)
    29             }
    30             if let rNode = node.right {
    31                 tempNodes.append(rNode)
    32             }
    33         }
    34         tempNodes.removeSubrange(Range.init(NSRange(location: 0, length: count))!)
    35         result.append(data)
    36     }
    37     return result.reversed()
    38     }
    39 }

    16ms

     1 /**
     2  * Definition for a binary tree node.
     3  * public class TreeNode {
     4  *     public var val: Int
     5  *     public var left: TreeNode?
     6  *     public var right: TreeNode?
     7  *     public init(_ val: Int) {
     8  *         self.val = val
     9  *         self.left = nil
    10  *         self.right = nil
    11  *     }
    12  * }
    13  */
    14 class Solution {
    15     func levelOrderBottom(_ root: TreeNode?) -> [[Int]] {
    16         if root == nil {
    17             return []
    18         }
    19         
    20         var result = [[Int]]()
    21         var queue = [TreeNode]()
    22         queue.append(root!)
    23         while !queue.isEmpty {
    24             var count = queue.count
    25             var temp = [Int]()
    26             while count != 0 {
    27                 let node = queue.removeFirst()
    28                 temp.append(node.val)
    29                 if node.left != nil {
    30                     queue.append(node.left!)
    31                 }
    32                 if node.right != nil {
    33                     queue.append(node.right!)
    34                 }
    35                 count -= 1
    36             }
    37             result.append(temp)
    38         }
    39         
    40         return result.reversed()
    41     }
    42 }
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  • 原文地址:https://www.cnblogs.com/strengthen/p/9703035.html
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