2018-10-31 13:25:33 +00:00
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# [101. Symmetric Tree](https://leetcode.com/problems/symmetric-tree/description/)
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# 思路
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## 思路一: 递归
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最简单的思路就是递归。若一个非空树是对称树,那么其左右子树是互为镜像的。类似[判断两颗树是否相等的题解](https://github.com/ShusenTang/LeetCode/blob/master/100.%20Same%20Tree.md),
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两棵非空树互为镜像的充要条件是:
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* 根的值相同;
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* 且树一的左子树和树二的右子树互为镜像,树一的右子树和树二的左子树互为镜像。
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## 思路二: 非递归
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2020-02-05 09:00:42 +00:00
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采用类似层次遍历的方法。对于左子树从上往下**从左往右**层次遍历,对于右子树从上往下**从右往左**层次遍历,遍历过程中进行比较。注意遍历过程中如果某个节点的孩子为空也应将其孩子入队。
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2020-06-26 04:31:32 +00:00
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层次遍历用的队列,其实用栈也是可以的,代码几乎一样,这样就是分别用**根右左**和**根左右**来遍历左右子树,同理空孩子也需要入栈。
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2020-02-05 09:00:42 +00:00
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两种思路都相当于遍历一遍树,所以两种思路的时空复杂度均为O(n)。
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2018-10-31 13:25:33 +00:00
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# C++
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## 思路一
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``` C++
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class Solution {
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private:
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bool isSymmetricSameTree(TreeNode* p, TreeNode* q) { // 判断两棵树是否互为镜像
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2020-02-05 09:00:42 +00:00
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if(!p && !q) return true;
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if(!p || !q || p->val != q->val) return false;
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return isSymmetricSameTree(p -> left, q -> right) && \
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isSymmetricSameTree(p -> right, q -> left);
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2018-10-31 13:25:33 +00:00
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}
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public:
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bool isSymmetric(TreeNode* root) {
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2020-02-05 09:00:42 +00:00
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if(!root) return true;
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2018-10-31 13:25:33 +00:00
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return isSymmetricSameTree(root -> left, root -> right);
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}
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};
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```
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## 思路二
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``` C++
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class Solution {
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public:
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2020-06-26 04:31:32 +00:00
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bool isSymmetric(TreeNode* root) {
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if(!root) return true;
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queue<TreeNode *>container1, container2; // use queue
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// stack<TreeNode *>container1, container2; // use stack
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2020-02-05 09:00:42 +00:00
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2020-06-26 04:31:32 +00:00
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container1.push(root -> left);
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container2.push(root -> right);
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TreeNode *p1, *p2;
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while(!container1.empty() && !container2.empty()){
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p1 = container1.front(); p2 = container2.front(); // use queue
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// p1 = container1.top(); p2 = container2.top(); // use stack
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container1.pop(); container2.pop();
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if(p1 && p2){
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if(p1 -> val != p2 -> val) return false;
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container1.push(p1 -> left);
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container1.push(p1 -> right);
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container2.push(p2 -> right);
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container2.push(p2 -> left);
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}
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else if(!p1 && !p2) continue;
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else return false;
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2018-10-31 13:25:33 +00:00
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}
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return true;
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}
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};
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```
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