117. Populating Next Right Pointers in Each Node II

时间:2023-03-10 04:28:53
117. Populating Next Right Pointers in Each Node II

题目:

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
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Tree Depth-first Search 

链接: http://leetcode.com/problems/populating-next-right-pointers-in-each-node-ii/

题解:

一样是DFS。跟上题不同在于,给定输入不是完全二叉树了,所以要加入一些条件来判断是否存在一个合理的next值。并且对左节点和右节点的有效性也要验证。最后要先递归连接右节点,再connect左节点。

Time Complexity - O(n), Space Complexity - O(1)。

public class Solution {

    public void connect(TreeLinkNode root) {

        if(root == null)

            return;

        TreeLinkNode node = root.next;

        while(node != null){

            if(node.left != null){

                node = node.left;

                break;

            } else if(node.right != null){

                node = node.right;

                break;

            }

            node = node.next;

        }

        if(root.right != null){

            root.right.next = node;

            if(root.left != null)

                root.left.next = root.right;

        } else {

            if(root.left != null)

                root.left.next = node;

        }

        connect(root.right);

        connect(root.left);

    }

}

Update:

/**

 * 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) {

        if(root == null)

            return;

        TreeLinkNode p = root.next;

        while(p != null) {

            if(p.left != null) {

                p = p.left;

                break;

            } else if (p.right != null) {

                p = p.right;

                break;

            }

            p = p.next;

        }

        if(root.right != null)

            root.right.next = p;

        if(root.left != null)

            root.left.next = (root.right != null) ? root.right : p;

        connect(root.right);

        connect(root.left);

    }

}

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二刷:

依然使用了递归,并没有做到constant space。留给三刷了。

Java:

Time Complexity - O(n), Space Complexity - O(n)。

/**

 * 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) {

        if (root == null) return;

        TreeLinkNode nextNode = root.next;

        while (nextNode != null) {

            if (nextNode.left == null && nextNode.right == null) nextNode = nextNode.next;

            else break;

        }

        if (nextNode != null) nextNode = (nextNode.left != null) ? nextNode.left : nextNode.right;

        if (root.right != null) root.right.next = nextNode;

        if (root.left != null) root.left.next = (root.right != null) ? root.right : nextNode;

        connect(root.right);

        connect(root.left);

    }

}

iterative:

Level order traversal。主要就是类似二叉树层序遍历。这回把顶层看作一个linkedlist,我们只需要继续连接这linkedlist中每个节点的子节点们。当顶层遍历完毕以后,下一层正好也形成了一个新的类linkedlist。我们换到下一层以后继续遍历,直到最后。

Java:

Time Complexity - O(n), Space Complexity - O(1)。

/**

 * 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) {

        TreeLinkNode curLevel = new TreeLinkNode(-1);

        TreeLinkNode newLevel = curLevel;

        while (root != null) {

            if (root.left != null) {

                curLevel.next = root.left;

                curLevel = curLevel.next;

            }

            if (root.right != null) {

                curLevel.next = root.right;

                curLevel = curLevel.next;

            }

            root = root.next;

            if (root == null) {

                curLevel = newLevel;

                root = newLevel.next;

                newLevel.next = null;

            }

        }

    }

}

Update:

/**

 * 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) {

        if (root == null) return;

        TreeLinkNode curLevel = new TreeLinkNode(-1);

        TreeLinkNode newLevel = curLevel;

        while (root != null) {

            if (root.left != null) {

                curLevel.next = root.left;

                curLevel = curLevel.next;

            }

            if (root.right != null) {

                curLevel.next = root.right;

                curLevel = curLevel.next;

            }

            root = root.next;

            if (root == null) {

                root = newLevel.next;

                newLevel.next = null;

                curLevel = newLevel;

            }

         }

    }

}

Reference:

http://www.cnblogs.com/springfor/p/3889327.html

https://leetcode.com/discuss/67291/java-solution-with-constant-space

https://leetcode.com/discuss/60795/o-1-space-o-n-time-java-solution

https://leetcode.com/discuss/24398/simple-solution-using-constant-space

https://leetcode.com/discuss/65526/ac-python-o-1-space-solution-12-lines-and-easy-to-understand

https://leetcode.com/discuss/3339/o-1-space-o-n-complexity-iterative-solution

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