[Swift]LeetCode971.翻转二叉树以匹配先序遍历 | Flip Binary Tree To Match Preorder Traversal
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Given a binary tree with N
nodes, each node has a different value from {1, ..., N}
.
A node in this binary tree can be flipped by swapping the left child and the right child of that node.
Consider the sequence of N
values reported by a preorder traversal starting from the root. Call such a sequence of N
values the voyage of the tree.
(Recall that a preorder traversal of a node means we report the current node's value, then preorder-traverse the left child, then preorder-traverse the right child.)
Our goal is to flip the least number of nodes in the tree so that the voyage of the tree matches the voyage
we are given.
If we can do so, then return a list of the values of all nodes flipped. You may return the answer in any order.
If we cannot do so, then return the list [-1]
.
Example 1:
Input: root = [1,2], voyage = [2,1]
Output: [-1]
Example 2:
Input: root = [1,2,3], voyage = [1,3,2]
Output: [1]
Example 3:
Input: root = [1,2,3], voyage = [1,2,3]
Output: []
Note:
1 <= N <= 100
给定一个有 N
个节点的二叉树,每个节点都有一个不同于其他节点且处于 {1, ..., N}
中的值。
通过交换节点的左子节点和右子节点,可以翻转该二叉树中的节点。
考虑从根节点开始的先序遍历报告的 N
值序列。将这一 N
值序列称为树的行程。
(回想一下,节点的先序遍历意味着我们报告当前节点的值,然后先序遍历左子节点,再先序遍历右子节点。)
我们的目标是翻转最少的树中节点,以便树的行程与给定的行程 voyage
相匹配。
如果可以,则返回翻转的所有节点的值的列表。你可以按任何顺序返回答案。
如果不能,则返回列表 [-1]
。
示例 1:
输入:root = [1,2], voyage = [2,1] 输出:[-1]
示例 2:
输入:root = [1,2,3], voyage = [1,3,2] 输出:[1]
示例 3:
输入:root = [1,2,3], voyage = [1,2,3] 输出:[]
提示:
1 <= N <= 100
20ms
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 var p:Int = 0 16 var fed:[Int] = [Int]() 17 func flipMatchVoyage(_ root: TreeNode?, _ voyage: [Int]) -> [Int] { 18 p = 0 19 if dfs(root, voyage) 20 { 21 return fed 22 } 23 else 24 { 25 fed = [Int]() 26 fed.append(-1); 27 return fed; 28 } 29 } 30 31 func dfs(_ cur: TreeNode?, _ voyage: [Int]) -> Bool 32 { 33 if cur == nil {return true} 34 if voyage[p] != cur!.val {return false} 35 p += 1 36 if cur!.left == nil 37 { 38 return dfs(cur?.right, voyage) 39 } 40 if cur!.right == nil 41 { 42 return dfs(cur?.left, voyage) 43 } 44 45 if voyage[p] == cur!.left!.val 46 { 47 var res:Bool = dfs(cur?.left, voyage) 48 if !res 49 { 50 return false 51 } 52 return dfs(cur?.right, voyage) 53 } 54 else 55 { 56 fed.append(cur!.val) 57 var res:Bool = dfs(cur?.right, voyage) 58 if !res 59 { 60 return false 61 } 62 return dfs(cur?.left, voyage) 63 } 64 } 65 }
20ms
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 var voyage = [Int]() 16 var results = [Int]() 17 var legit = false 18 19 func flipMatchVoyage(_ root: TreeNode?, _ voyage: [Int]) -> [Int] { 20 self.voyage = voyage 21 self.results = [] 22 self.legit = true 23 24 helper(root, 0, voyage.count) 25 26 return legit ? results : [-1] 27 } 28 29 func helper(_ root: TreeNode?, _ start: Int, _ end: Int) -> Int { 30 guard legit else { return 0 } 31 guard let root = root else { 32 legit = end == start 33 return 0 34 } 35 guard root.val == voyage[start] else { 36 legit = false 37 return 0 38 } 39 40 if let l = root.left, let r = root.right { 41 if l.val == voyage[start + 1] { 42 var i = start + 1 43 while voyage[i] != r.val && i < end { 44 i += 1 45 } 46 47 if i == end { 48 legit = false 49 return 0 50 } else { 51 return helper(l, start + 1, i) + helper(r, i, end) + 1 52 } 53 } else if r.val == voyage[start + 1] { 54 results.append(root.val) 55 var i = start + 1 56 while voyage[i] != l.val && i < end { 57 i += 1 58 } 59 60 if i == end { 61 legit = false 62 return 0 63 } else { 64 return helper(r, start + 1, i) + helper(l, i, end) + 1 65 } 66 } else { 67 legit = false 68 } 69 70 } else if let l = root.left { 71 helper(l, start + 1, end) + 1 72 } else if let r = root.right { 73 helper(r, start + 1, end) + 1 74 } else if end == start + 1 { 75 return 1 76 } else { 77 legit = false 78 return 0 79 } 80 81 return 0 82 } 83 }
24ms
1 class Solution { 2 func flipMatchVoyage(_ root: TreeNode?, _ voyage: [Int]) -> [Int] { 3 var res = [Int]() 4 if root == nil && voyage.count == 0 { 5 return [] 6 } else if root == nil && voyage.count != 0 { 7 return [-1] 8 } else if root != nil && voyage.count == 0 { 9 return [-1] 10 } else if root?.val != voyage[0] { 11 return [-1] 12 } else { 13 if root?.left == nil && root?.right == nil { 14 return [] 15 } else if root?.left == nil { 16 let rvalue = root!.right!.val 17 let rvoy = cutArray(voyage, rvalue, -1) 18 let rres = flipMatchVoyage(root!.right, rvoy) 19 if rres == [-1] { 20 res = [-1] 21 } else { 22 res.append(contentsOf: rres) 23 } 24 } else if root?.right == nil { 25 let lvalue = root!.left!.val 26 let lvoy = cutArray(voyage, lvalue, -1) 27 let lres = flipMatchVoyage(root!.left, lvoy) 28 if lres == [-1] { 29 res = [-1] 30 } else { 31 res.append(contentsOf: lres) 32 } 33 } else { 34 var ll = root!.left!.val 35 var rr = root!.right!.val 36 if ll != voyage[1] { 37 if rr == voyage[1] { 38 let node = root?.left 39 root?.left = root?.right 40 root?.right = node 41 res.append(root!.val) 42 } else { 43 res = [-1] 44 return res 45 } 46 } 47 ll = root!.left!.val 48 rr = root!.right!.val 49 let lvoy = cutArray(voyage, ll, rr) 50 let rvoy = cutArray(voyage, rr, -1) 51 let lres = flipMatchVoyage(root!.left!, lvoy) 52 let rres = flipMatchVoyage(root!.right!, rvoy) 53 if lres == [-1] || rres == [-1] { 54 res = [-1] 55 } else { 56 res.append(contentsOf: lres) 57 res.append(contentsOf: rres) 58 } 59 } 60 } 61 return res 62 } 63 64 func cutArray(_ arr: [Int], _ start: Int, _ end: Int) -> [Int] { 65 var res = [Int]() 66 var bb = false 67 for i in arr { 68 if i == start { 69 bb = true 70 } 71 if i == end { 72 bb = false 73 break 74 } 75 if bb { 76 res.append(i) 77 } 78 } 79 return res 80 } 81 }
36ms
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 flipMatchVoyage(_ root: TreeNode?, _ voyage: [Int]) -> [Int] { 16 if voyage[0] != root?.val { 17 return [-1] 18 } 19 var index = -1 20 let ans = tryFilp(root!, &index, voyage) 21 return ans.contains(-1) ? [-1] : ans 22 } 23 24 func tryFilp(_ node: TreeNode?, _ nodeIndex: inout Int, _ voyage: [Int]) -> [Int] { 25 guard let node = node else { 26 return [-1] 27 } 28 nodeIndex += 1 29 if node.val != voyage[nodeIndex] { 30 return [-1] 31 } 32 if node.left == nil && node.right == nil { 33 return [] 34 } 35 if node.left != nil || node.right != nil { 36 if node.left != nil { 37 if node.left?.val != voyage[nodeIndex + 1] { 38 let temp = node.left 39 node.left = node.right 40 node.right = temp 41 var ans = tryFilp(node.left, &nodeIndex, voyage) + [node.val] 42 if node.right != nil { 43 ans += tryFilp(node.right, &nodeIndex, voyage) 44 } 45 return ans 46 } else { 47 var ans = tryFilp(node.left, &nodeIndex, voyage) 48 if node.right != nil { 49 ans += tryFilp(node.right, &nodeIndex, voyage) 50 } 51 return ans 52 } 53 } else { 54 if node.right?.val != voyage[nodeIndex + 1] { 55 return [-1] 56 } else { 57 return tryFilp(node.right, &nodeIndex, voyage) 58 } 59 } 60 } 61 return [] 62 } 63 }
60ms
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 16 func flipMatchVoyage(_ root: TreeNode?, _ voyage: [Int]) -> [Int] { 17 guard !voyage.isEmpty else { return [-1] } 18 guard root?.val == voyage[0] else { return [-1] } 19 var swaps: [Int] = [] 20 var seenDifferentIndices = Set<Int>() 21 22 while true { 23 let preorder = preorderTraversal(of: root) 24 25 if let indexOfDifference = Array(zip(preorder, voyage)).firstIndex(where: { (a, b) in a != b }) { 26 let differentValue = preorder[indexOfDifference] 27 let parent = parentNode(of: differentValue, in: root)! 28 let left = parent.left 29 parent.left = parent.right 30 parent.right = left 31 swaps.append(parent.val) 32 33 if seenDifferentIndices.contains(indexOfDifference) { 34 return [-1] 35 } 36 seenDifferentIndices.insert(indexOfDifference) 37 } else { 38 break 39 } 40 } 41 42 let success = preorderTraversal(of: root) == voyage 43 return success ? swaps : [-1] 44 } 45 46 private func parentNode(of value: Int, in tree: TreeNode?) -> TreeNode? { 47 guard let tree = tree else { return nil } 48 if tree.left?.val == value || tree.right?.val == value { 49 return tree 50 } 51 52 return parentNode(of: value, in: tree.left) ?? parentNode(of: value, in: tree.right) 53 } 54 55 private func preorderTraversal(of tree: TreeNode?) -> [Int] { 56 guard let tree = tree else { return [] } 57 return [tree.val] + preorderTraversal(of: tree.left) + preorderTraversal(of: tree.right) 58 } 59 }