题目
翻转二叉树
给你一棵二叉树的根节点
root
,翻转这棵二叉树,并返回其根节点。
示例
1
输入:
root = [4,2,7,1,3,6,9]
输出:
[4,7,2,9,6,3,1]
示例
2
输入:
root = [2,1,3]
输出:
[2,3,1]
示例
3
输入:
root = []
输出:
[]
提示:
树中节点数目范围在
[0, 100]
内
-100 <= Node.val <= 100
代码
输入:
root = [4,2,7,1,3,6,9]
输出:
[4,7,2,9,6,3,1]
输入:
root = [2,1,3]
输出:
[2,3,1]
输入:
root = []
输出:
[]
public class Main {
// 测试样例
public static void main(String[] args) {
Solution solution = new Solution();
// 示例 1
TreeNode root1 = new TreeNode(4);
root1.left = new TreeNode(2);
root1.right = new TreeNode(7);
root1.left.left = new TreeNode(1);
root1.left.right = new TreeNode(3);
root1.right.left = new TreeNode(6);
root1.right.right = new TreeNode(9);
TreeNode result1 = solution.invertTree(root1);
System.out.println("示例 1 输出:");
printTree(result1); // 打印翻转后的结果
// 示例 2
TreeNode root2 = new TreeNode(2);root2.left = new TreeNode(1);
root2.right = new TreeNode(3);
TreeNode result2 = solution.invertTree(root2);
System.out.println("\n示例 2 输出:");
printTree(result2); // 打印翻转后的结果
// 示例 3 - 空树
TreeNode root3 = null;
TreeNode result3 = solution.invertTree(root3);
System.out.println("\n示例 3 输出:");
printTree(result3); // 打印翻转后的结果
}
// 辅助方法:按照层序遍历打印二叉树(仅用于验证翻转结果)
private static void printTree(TreeNode root) {
if (root == null) {
System.out.println("null");
return;
}
Queue<TreeNode> queue = new LinkedList<>();
queue.offer(root);
while (!queue.isEmpty()) {
TreeNode node = queue.poll();
if (node != null) {
System.out.print(node.val + " ");
queue.offer(node.left);
queue.offer(node.right);
} else {
System.out.print("null ");
}
}
System.out.println();
}
}
// 定义二叉树节点类
class TreeNode {
int val;
TreeNode left;
TreeNode right;
TreeNode(int val) {
this.val = val;
}
}
class Solution {
public TreeNode invertTree(TreeNode root) {
// 如果当前节点为空,直接返回null
if (root == null) {
return null;
}// 交换当前节点的左右子节点
TreeNode temp = root.left;
root.left = root.right;
root.right = temp;
// 递归地对左右子树进行翻转
invertTree(root.left);
invertTree(root.right);
// 返回翻转后的根节点
return root;
}
}