• [Swift]LeetCode872. 叶子相似的树 | Leaf-Similar Trees


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    Consider all the leaves of a binary tree.  From left to right order, the values of those leaves form a leaf value sequence.

    For example, in the given tree above, the leaf value sequence is (6, 7, 4, 9, 8).

    Two binary trees are considered leaf-similar if their leaf value sequence is the same.

    Return true if and only if the two given trees with head nodes root1 and root2 are leaf-similar. 

    Note:

    • Both of the given trees will have between 1 and 100nodes.

    请考虑一颗二叉树上所有的叶子,这些叶子的值按从左到右的顺序排列形成一个 叶值序列 。

    举个例子,如上图所示,给定一颗叶值序列为 (6, 7, 4, 9, 8) 的树。

    如果有两颗二叉树的叶值序列是相同,那么我们就认为它们是 叶相似 的。

    如果给定的两个头结点分别为 root1 和 root2 的树是叶相似的,则返回 true;否则返回 false 。 

    提示:

    • 给定的两颗树可能会有 1 到 100 个结点。

    Runtime: 12 ms
    Memory Usage: 19 MB
     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 leafSimilar(_ root1: TreeNode?, _ root2: TreeNode?) -> Bool {
    16         return traverse(root1) == traverse(root2)
    17     }
    18 
    19     func traverse(_ root: TreeNode?) ->String
    20     {
    21         if root == nil {return String()}
    22         if root?.left == nil && root?.right == nil
    23         {
    24             return String(root!.val) + "-"
    25         }
    26         return traverse(root?.left) + traverse(root?.right)
    27     }
    28 }

    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 leafSimilar(_ root1: TreeNode?, _ root2: TreeNode?) -> Bool {
    16         var leaves1 : [Int] = []
    17         var leaves2 : [Int] = []
    18         getLeaves(root1, &leaves1)
    19         getLeaves(root2, &leaves2)
    20         
    21         return isSame(leaves1, leaves2)
    22     }
    23     
    24     func getLeaves(_ root: TreeNode?, _ leaves: inout [Int]) {
    25         guard let node = root else {
    26             return
    27         }
    28         if node.left == nil && node.right == nil {
    29             leaves.append(node.val)
    30             return
    31         }
    32         getLeaves(node.left, &leaves)
    33         getLeaves(node.right, &leaves)
    34     }
    35     
    36     func isSame(_ leaves1: [Int], _ leaves2: [Int]) -> Bool {
    37         if leaves1.count != leaves2.count {
    38             return false
    39         }
    40         
    41         for i in 0..<leaves1.count {
    42             if leaves1[i] != leaves2[i] {
    43                 return false
    44             }
    45         }
    46         return true
    47     }
    48 }

    Runtime: 16 ms

    Memory Usage: 19.1 MB
     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 leafSimilar(_ root1: TreeNode?, _ root2: TreeNode?) -> Bool {
    16         if root1 == nil {
    17             if root2 == nil {
    18                 return true
    19             }
    20             return false
    21         }
    22         
    23         var roots1: [Int] = [], roots2: [Int] = []
    24         
    25         traversingBTree(root1!, roots: &roots1)
    26         traversingBTree(root2!, roots: &roots2)
    27         
    28         //    遍历并且存储叶节点的值至数组
    29         
    30         guard roots1.count == roots2.count else {
    31             return false
    32         }
    33         
    34         for index in 0..<roots1.count {
    35             if roots1[index] != roots2[index] {
    36                 return false
    37             }
    38         }
    39         
    40         return true
    41     }
    42     
    43     func traversingBTree(_ root: TreeNode, roots: inout [Int]) {
    44         
    45         if root.left == nil && root.right == nil {
    46             roots.append(root.val)
    47             return ;
    48         }
    49         if let left = root.left {
    50             traversingBTree(left, roots: &roots)
    51         }
    52         
    53         if let right = root.right {
    54             traversingBTree(right, roots: &roots)
    55         }
    56     }
    57 }

    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 leafSimilar(_ root1: TreeNode?, _ root2: TreeNode?) -> Bool {
    16 
    17         return getLeaves(root1) == getLeaves(root2)
    18         
    19     }
    20     func getLeaves(_ root:TreeNode?) -> [Int]
    21     {
    22         guard let root = root else
    23         {
    24             return []
    25         }
    26         var result: [Int] = []
    27         if root.left == nil && root.right == nil
    28         {
    29             result += [root.val]
    30         }
    31         result += getLeaves(root.left)
    32         result += getLeaves(root.right)
    33         return result
    34     }
    35 }

    24ms

     1 class Solution {
     2     func leafSimilar(_ root1: TreeNode?, _ root2: TreeNode?) -> Bool {
     3         var arr1 = [Int]()
     4         var arr2 = [Int]()
     5         helper(root1, &arr1)
     6         helper(root2, &arr2)
     7         for i in 0..<min(arr1.count, arr2.count) {
     8             if arr1[i] != arr2[i] {
     9                 return false
    10             }
    11         }
    12         return true
    13     }
    14     
    15     func helper(_ root: TreeNode?, _ arr: inout [Int]) {
    16         guard root?.left != nil || root?.right != nil else {
    17             if root != nil {
    18                 arr.append(root!.val)
    19             }
    20             return
    21         }
    22         helper(root?.left, &arr)
    23         helper(root?.right, &arr)
    24     }
    25 }

    28ms

     1 class Solution {
     2     func leafSimilar(_ root1: TreeNode?, _ root2: TreeNode?) -> Bool {
     3     var arr1 = [Int]()
     4     var arr2 = [Int]()
     5     
     6     getArray(root1, &arr1)
     7     getArray(root2, &arr2)
     8     
     9     return arr1 == arr2
    10 }
    11     func getArray(_ root: TreeNode?, _ arr: inout [Int]) {
    12         guard let r = root else { return }          
    13         if r.left == nil && r.right == nil {             
    14             arr.append(r.val)
    15         } else {
    16             getArray(r.left, &arr)
    17             getArray(r.right, &arr)
    18         }
    19     }
    20 }

    32ms

     1 class Solution {
     2     func leafSimilar(_ root1: TreeNode?, _ root2: TreeNode?) -> Bool {
     3         var array1: [Int] = []
     4         var array2: [Int] = []
     5         dfs(root: root1, result: &array1)
     6         dfs(root: root2, result: &array2)
     7         return array1 == array2
     8     }
     9     
    10     func dfs(root: TreeNode?, result: inout [Int]) -> Void {
    11         if let r = root {
    12             if r.left == nil && r.right == nil {
    13                 result.append(r.val)
    14             }
    15             dfs(root: r.left, result: &result)
    16             dfs(root: r.right, result: &result)
    17         }
    18     }
    19 }
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  • 原文地址:https://www.cnblogs.com/strengthen/p/10600036.html
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