LeetCode-315. Count of Smaller Numbers After Self
目录
题目描述
解题思路
【C++】
【Java】
复杂度分析
LeetCode-315. Count of Smaller Numbers After Self
https://leetcode.com/problems/count-of-smaller-numbers-after-self/description/
题目描述
Given an integer array nums, return an integer array counts where counts[i] is the number of smaller elements to the right of nums[i].
Example 1:
Input: nums = [5,2,6,1] Output: [2,1,1,0] Explanation: To the right of 5 there are 2 smaller elements (2 and 1). To the right of 2 there is only 1 smaller element (1). To the right of 6 there is 1 smaller element (1). To the right of 1 there is 0 smaller element.
Example 2:
Input: nums = [-1] Output: [0]
Example 3:
Input: nums = [-1,-1] Output: [0,0]
Constraints:
1 <= nums.length <= 105-104 <= nums[i] <= 104
解题思路
【C++】
class Solution {
private:
vector<int> index{};
vector<int> tmpIndex{};
vector<int> ans{};
void merge(vector<int>& nums, int start, int mid, int end) {
int p1 = start, p2 = mid + 1, cur = start, len = end - start + 1;
while (p1 <= mid && p2 <= end) {
if (nums[index[p1]] > nums[index[p2]]) {
ans[index[p1]] += end - p2 + 1;
tmpIndex[cur++] = index[p1++];
} else {tmpIndex[cur++] = index[p2++];}
}
while (p1 <= mid) {tmpIndex[cur++] = index[p1++];}
while (p2 <= end) {tmpIndex[cur++] = index[p2++];}
for (int i = start; i <= end; i++) {index[i] = tmpIndex[i];}
}
void mergeSort(vector<int>& nums, int start, int end) {
if (start < end) {
int mid = start + (end - start) / 2;
mergeSort(nums, start, mid);
mergeSort(nums, mid + 1, end);
merge(nums, start, mid, end);
}
}
public:
vector<int> countSmaller(vector<int>& nums) {
index.resize(nums.size());
tmpIndex.resize(nums.size());
ans.resize(nums.size(), 0);
for (int i = 0; i < nums.size(); i++) {index[i] = i;}
mergeSort(nums, 0, nums.size() - 1);
return ans;
}
};【Java】
class Solution {
private int[] index;
private int[] tmpIndex;
private List<Integer> ans;
private void merge(int[] nums, int start, int mid, int end) {
int p1 = start, p2 = mid + 1, cur = start, len = end - start + 1;
while (p1 <= mid && p2 <= end) {
if (nums[index[p1]] > nums[index[p2]]) {
ans.set(index[p1], ans.get(index[p1]) + end - p2 + 1);
tmpIndex[cur++] = index[p1++];
} else {tmpIndex[cur++] = index[p2++];}
}
while (p1 <= mid) {tmpIndex[cur++] = index[p1++];}
while (p2 <= end) {tmpIndex[cur++] = index[p2++];}
for (int i = start; i <= end; i++) {index[i] = tmpIndex[i];}
}
private void mergeSort(int[] nums, int start, int end) {
if (start < end) {
int mid = start + (end - start) / 2;
mergeSort(nums, start, mid);
mergeSort(nums, mid + 1, end);
merge(nums, start, mid, end);
}
}
public List<Integer> countSmaller(int[] nums) {
index = new int[nums.length];
tmpIndex = new int[nums.length];
ans = new ArrayList<Integer>(nums.length);
for (int i = 0; i < nums.length; i++) {
index[i] = i;
ans.add(0);
}
mergeSort(nums, 0, nums.length - 1);
return ans;
}
}复杂度分析
- 时间复杂度:O(nlogn),即归并排序的时间复杂度。
- 空间复杂度:O(n),这里归并排序的下标映射数组、临时下标映射数组以及答案数组的空间代价均为 O(n)。
- 注意:不建议在merge函数内创建临时下标映射数组,那样做会反复申请和销毁资源,消耗较大。