题目链接 : https://leetcode-cn.com/problems/populating-next-right-pointers-in-each-node/
题目描述:
给定一个完美二叉树,其所有叶子节点都在同一层,每个父节点都有两个子节点。二叉树定义如下:
struct Node {
int val;
Node *left;
Node *right;
Node *next;
}
填充它的每个 next 指针,让这个指针指向其下一个右侧节点。如果找不到下一个右侧节点,则将 next 指针设置为 NULL。
初始状态下,所有 next 指针都被设置为 NULL。
示例
输入:{"$id":"1","left":{"$id":"2","left":{"$id":"3","left":null,"next":null,"right":null,"val":4},"next":null,"right":{"$id":"4","left":null,"next":null,"right":null,"val":5},"val":2},"next":null,"right":{"$id":"5","left":{"$id":"6","left":null,"next":null,"right":null,"val":6},"next":null,"right":{"$id":"7","left":null,"next":null,"right":null,"val":7},"val":3},"val":1}
输出:{"$id":"1","left":{"$id":"2","left":{"$id":"3","left":null,"next":{"$id":"4","left":null,"next":{"$id":"5","left":null,"next":{"$id":"6","left":null,"next":null,"right":null,"val":7},"right":null,"val":6},"right":null,"val":5},"right":null,"val":4},"next":{"$id":"7","left":{"$ref":"5"},"next":null,"right":{"$ref":"6"},"val":3},"right":{"$ref":"4"},"val":2},"next":null,"right":{"$ref":"7"},"val":1}
解释:给定二叉树如图 A 所示,你的函数应该填充它的每个 next 指针,以指向其下一个右侧节点,如图 B 所示。
提示:
你只能使用常量级额外空间。
使用递归解题也符合要求,本题中递归程序占用的栈空间不算做额外的空间复杂度。
思路:
与下一题117. 填充每个节点的下一个右侧节点指针 II都可以用BFS方法,如下:
def connect(self, root: 'Node') -> 'Node':
from collections import deque
if not root: return root
queue = deque()
queue.appendleft(root)
while queue:
p = None
n = len(queue)
for _ in range(n):
tmp = queue.pop()
if p:
p.next = tmp
p = p.next
else:
p = tmp
if tmp.left:
queue.appendleft(tmp.left)
if tmp.right:
queue.appendleft(tmp.right)
p.next = None
return root
但是不符合题意, 要使用常量级额外空间
所以我们用其他空间\(O(1)\)的方法
思路一: 递归
思路二: 迭代
代码:
思路一:
def connect(self, root: 'Node') -> 'Node':
if not root:
return
if root.left:
root.left.next = root.right
if root.next:
root.right.next = root.next.left
self.connect(root.left)
self.connect(root.right)
return root
java
class Solution {
public Node connect(Node root) {
if (root == null) return null;
if (root.left != null) {
root.left.next = root.right;
if (root.next != null) root.right.next = root.next.left;
}
connect(root.left);
connect(root.right);
return root;
}
}
思路二:
class Solution:
def connect(self, root: 'Node') -> 'Node':
pre = root
while pre:
cur = pre
while cur:
if cur.left: cur.left.next = cur.right
if cur.right and cur.next: cur.right.next = cur.next.left
cur = cur.next
pre = pre.left
return root
java
class Solution {
public Node connect(Node root) {
Node pre = root;
while (pre != null) {
Node cur = pre;
while (cur != null) {
if (cur.left != null) cur.left.next = cur.right;
if (cur.right != null && cur.next != null) cur.right.next = cur.next.left;
cur = cur.next;
}
pre = pre.left;
}
return root;
}
}
