描述:
Follow up for problem “Populating Next Right Pointers in Each Node”.
What if the given tree could be any binary tree? Would your previous solution still work?
Note:
You may only use constant extra space.
For example,
Given the following binary tree,
1
/ \
2 3
/ \ \
4 5 7
After calling your function, the tree should look like:
1 -> NULL
/ \
2 -> 3 -> NULL
/ \ \
4-> 5 -> 7 -> NULL
方法:
前边那个没有限定空间复杂度的时候,我们直接可以采用层次遍历的方法,将每一层连接起来。其实之前采用层次遍历方法的时候,我们采用了vector存储每一层节点,遍历到每一层最后节点时,便将vector储存的节点拿出来,依次连接起来。
其实,这个方法还可以简练,观察这棵树的结构,我们可以发现,每当上一层已经连接起来了,我们利用上一层连接信息,便可以把下一层连接起来。
C++代码:
/**
* Definition for binary tree with next pointer.
* struct TreeLinkNode {
* int val;
* TreeLinkNode *left, *right, *next;
* TreeLinkNode(int x) : val(x), left(NULL), right(NULL), next(NULL) {}
* };
*/
class Solution {
public:
void connect(TreeLinkNode *root) {
TreeLinkNode* mroot = root;
while(mroot)
{
TreeLinkNode* dummy = new TreeLinkNode(0);
TreeLinkNode* pre = dummy;
for(auto p = mroot; p; p = p->next)
{
if(p->left)
{
pre->next = p->left;
pre = pre->next;
}
if(p->right)
{
pre->next = p->right;
pre = pre->next;
}
}
mroot = dummy->next;
}
}
};
Java代码:
/**
* Definition for binary tree with next pointer.
* public class TreeLinkNode {
* int val;
* TreeLinkNode left, right, next;
* TreeLinkNode(int x) { val = x; }
* }
*/
public class Solution {
public void connect(TreeLinkNode root) {
while(root != null){
TreeLinkNode dummy = new TreeLinkNode(0);
TreeLinkNode pre = dummy;
for(TreeLinkNode p = root; p != null; p = p.next){
if(p.left != null){
pre.next = p.left;
pre = pre.next;
}
if(p.right != null){
pre.next = p.right;
pre = pre.next;
}
}
root = dummy.next;
}
}
}
