257. Binary Tree Paths

时间:2023-03-09 00:54:22
257. Binary Tree Paths

题目:

Given a binary tree, return all root-to-leaf paths.

For example, given the following binary tree:

   1

 /   \

2     3

 \

  5

All root-to-leaf paths are:

["1->2->5", "1->3"]

链接: http://leetcode.com/problems/binary-tree-paths/

题解:

求Binary Tree所有路径。用Recursive解法会比较容易。逻辑是,假如为current root为leaf node,则在res中加入该节点,返回。否则,递归求解,在左子树和右子树每一个结果中,在String前面insert  root.val + "->"。

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

/**

 * Definition for a binary tree node.

 * public class TreeNode {

 *     int val;

 *     TreeNode left;

 *     TreeNode right;

 *     TreeNode(int x) { val = x; }

 * }

 */

public class Solution {

    public List<String> binaryTreePaths(TreeNode root) {

        List<String> res = new ArrayList<>();

        if(root == null)

            return res;

        if(root.left == null && root.right == null) {

            res.add(String.valueOf(root.val));

        } else {

            for(String s : binaryTreePaths(root.left)) {

                res.add(String.valueOf(root.val) + "->" + s);

            }

            for(String s : binaryTreePaths(root.right)) {

                res.add(String.valueOf(root.val) + "->" + s);

            }

        }

        return res;

    }

}

二刷:

还是使用了最简单的DFS Recursive解法。更好的解法可能是stack DFS和queue BFS。

Java:

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

/**

 * Definition for a binary tree node.

 * public class TreeNode {

 *     int val;

 *     TreeNode left;

 *     TreeNode right;

 *     TreeNode(int x) { val = x; }

 * }

 */

public class Solution {

    public List<String> binaryTreePaths(TreeNode root) {

        List<String> res = new ArrayList<>();

        if (root == null) {

            return res;

        }

        if (root.left == null && root.right == null) {

            res.add(root.val + "");

            return res;

        }

        List<String> left = binaryTreePaths(root.left);

        List<String> right = binaryTreePaths(root.right);

        for (String s : left) {

            res.add(root.val + "->" + s);

        }

        for (String s : right) {

            res.add(root.val + "->" + s);

        }

        return res;

    }

}

三刷:

完全忘了一刷二刷是怎么写的,直接就用dfs + backtracking了。辅助方法里面用的是in-order traversal。 这里使用了一个List<Integer>来辅助计算Path,否则单独使用一个StringBuilder并不十分方便。

Java:

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

/**

 * Definition for a binary tree node.

 * public class TreeNode {

 *     int val;

 *     TreeNode left;

 *     TreeNode right;

 *     TreeNode(int x) { val = x; }

 * }

 */

public class Solution {

    public List<String> binaryTreePaths(TreeNode root) {

        List<String> res = new ArrayList<>();

        List<Integer> path = new ArrayList<>();

        getBinaryTreePaths(res, path, root);

        return res;

    }

    private void getBinaryTreePaths(List<String> res, List<Integer> path, TreeNode root) {

        if (root == null) return;

        path.add(root.val);

        if (root.left == null && root.right == null) {

            StringBuilder sb = new StringBuilder();

            for (int val : path) sb.append(val).append("->");

            sb.setLength(sb.length() - 2);

            res.add(sb.toString());

            path.remove(path.size() - 1);

            return;

        }

        getBinaryTreePaths(res, path, root.left);

        getBinaryTreePaths(res, path, root.right);

        path.remove(path.size() - 1);

    }

}

Update:

/**

 * Definition for a binary tree node.

 * public class TreeNode {

 *     int val;

 *     TreeNode left;

 *     TreeNode right;

 *     TreeNode(int x) { val = x; }

 * }

 */

public class Solution {

    public List<String> binaryTreePaths(TreeNode root) {

        List<String> res = new ArrayList<>();

        binaryTreePaths(res, new ArrayList<Integer>(), root);

        return res;

    }

    private void binaryTreePaths(List<String> res, List<Integer> path, TreeNode root) {

        if (root == null) return;

        path.add(root.val);

        if (root.left == null && root.right == null) {

            StringBuilder sb = new StringBuilder();

            for (int val : path) sb.append(val).append("->");

            sb.setLength(sb.length() - 2);

            res.add(sb.toString());

            path.remove(path.size() - 1);

            return;

        }

        binaryTreePaths(res, path, root.left);

        binaryTreePaths(res, path, root.right);

        path.remove(path.size() - 1);

    }

}

写在一个方法里,仿照一刷二刷的dfs:

这里每次递归都要创建新的ArrayList,并且左右子树都要计算,空间复杂度会比较高。怎么计算清楚,留给下一次了。

/**

 * Definition for a binary tree node.

 * public class TreeNode {

 *     int val;

 *     TreeNode left;

 *     TreeNode right;

 *     TreeNode(int x) { val = x; }

 * }

 */

public class Solution {

    public List<String> binaryTreePaths(TreeNode root) {

        List<String> res = new ArrayList<>();

        if (root == null) return res;

        if (root.left == null && root.right == null) res.add(String.valueOf(root.val));

        List<String> left = binaryTreePaths(root.left);

        for (String leftPath :left) res.add(root.val + "->" + leftPath);

        List<String> right = binaryTreePaths(root.right);

        for (String rightPath :right) res.add(root.val + "->" + rightPath);

        return res;

    }

}

Reference:

https://leetcode.com/discuss/55451/clean-solution-accepted-without-helper-recursive-function

https://leetcode.com/discuss/52072/accepted-java-simple-solution-in-8-lines

https://leetcode.com/discuss/52020/5-lines-recursive-python

https://leetcode.com/discuss/65362/my-concise-java-dfs-solution

https://leetcode.com/discuss/67749/bfs-with-two-queue-java-solution

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