中序遍历后比较 8056s
import java.util.*;
import java.lang.*;
public class Solution {
/* * @param root: param root: The root of the binary search tree * @param k1: An integer * @param k2: An integer * @return: return: Return all keys that k1<=key<=k2 in ascending order */
public List<Integer> searchRange(TreeNode root, int k1, int k2) {
// write your code here
List<Integer> all=new ArrayList<>();
inOrder(root,all);
List<Integer> result=new ArrayList<>();
for(int i=0;i<all.size();i++){
int temp=all.get(i);
if(temp>=k1&&temp<=k2){
result.add(temp);
}
}
return result;
}
public void inOrder(TreeNode root,List<Integer> list){
if(root!=null){
inOrder(root.left,list);
list.add(root.val);
inOrder(root.right,list);
}
}
}九章解答
4000+s,我就说嘛,之前没有利用二叉搜索树的条件
private ArrayList<Integer> results;
public ArrayList<Integer> searchRange(TreeNode root, int k1, int k2) {
results = new ArrayList<Integer>();
helper(root, k1, k2);
return results;
}
private void helper(TreeNode root, int k1, int k2) {
if (root == null) {
return;
}
//当前值比k1都大,看看他的左儿子的情况,要找更小的数来比较,右边就不看了。
if (root.val > k1) {
helper(root.left, k1, k2);
}
if (root.val >= k1 && root.val <= k2) {
results.add(root.val);
}
//当前的值比k2都小,看看右儿子的情况,要找最接近k2的数,左边就不看了。
if (root.val < k2) {
helper(root.right, k1, k2);
}
}
