题意
Given an array of n positive integers and a positive integer s, find the minimal length of a subarray of which the sum ≥ s. If there isn't one, return 0 instead.
For example, given the array [2,3,1,2,4,3] and s = 7,
the subarray [4,3] has the minimal length under the problem constraint.
click to show more practice.
More practice:
If you have figured out the O(n) solution, try coding another solution of which the time complexity is O(n log n).
Credits:
Special thanks to @Freezen for adding this problem and creating all test cases.
这道题给定了我们一个数字,让我们求子数组之和大于等于给定值的最小长度,跟之前那道 Maximum Subarray 最大子数组有些类似,并且题目中要求我们实现O(n)和O(nlgn)两种解法,那么我们先来看O(n)的解法,我们需要定义两个指针left和right,分别记录子数组的左右的边界位置,然后我们让right向右移,直到子数组和大于等于给定值或者right达到数组末尾,此时我们更新最短距离,并且将left像右移一位,然后再sum中减去移去的值,然后重复上面的步骤,直到right到达末尾,且left到达临界位置,即要么到达边界,要么再往右移动,和就会小于给定值。代码如下:
思路
这道题需要比较巧妙的思考,不能直接蛮干,比如说移动窗口,再更新它的窗口最小长度;或者先计算累计和,通过加上给定的值,去得到窗口信息,再更新最小长度。
实现
移动窗口
// O(n)
class Solution {
public:
int minSubArrayLen(int s, vector<int>& nums) {
if (nums.empty()) return 0;
int left = 0, right = 0, sum = 0, len = nums.size(), res = len + 1;
while (right < len) {
while (sum < s && right < len) {
sum += nums[right++];
}
while (sum >= s) {
res = min(res, right - left);
sum -= nums[left++];
}
}
return res == len + 1 ? 0 : res;
}
};
同样的思路,换另外一种写法
class Solution {
public:
int minSubArrayLen(int s, vector<int>& nums) {
int res = INT_MAX, left = 0, sum = 0;
for (int i = 0; i < nums.size(); ++i) {
sum += nums[i];
while (left <= i && sum >= s) {
res = min(res, i - left + 1);
sum -= nums[left++];
}
}
return res == INT_MAX ? 0 : res;
}
};
二分法
// O(nlgn)
class Solution {
public:
int minSubArrayLen(int s, vector<int>& nums) {
int len = nums.size(), sums[len + 1] = {0}, res = len + 1;
for (int i = 1; i < len + 1; ++i) sums[i] = sums[i - 1] + nums[i - 1];
for (int i = 0; i < len + 1; ++i) {
int right = searchRight(i + 1, len, sums[i] + s, sums);
if (right == len + 1) break;
if (res > right - i) res = right - i;
}
return res == len + 1 ? 0 : res;
}
int searchRight(int left, int right, int key, int sums[]) {
while (left <= right) {
int mid = (left + right) / 2;
if (sums[mid] >= key) right = mid - 1;
else left = mid + 1;
}
return left;
}
};
这个解法要用到二分查找法,思路是,我们建立一个比原数组长一位的sums数组,其中sums[i]表示nums数组中[0, i - 1]的和,然后我们对于sums中每一个值sums[i],用二分查找法找到子数组的右边界位置,使该子数组之和大于sums[i] + s,为什么要加上s呢,因为前面我们已经计算出了加上数组前面的和,那么我们只需要判断当前的值加上s等于后面的哪个值,就可以得出后面的值的下标,其实那个s就是前面和后面之间的原数组的值的和,然后我们更新最短长度的距离即可。
或者不需要新加一个函数
class Solution {
public:
int minSubArrayLen(int s, vector<int>& nums) {
int res = INT_MAX, n = nums.size();
vector<int> sums(n + 1, 0);
for (int i = 1; i < n + 1; ++i) sums[i] = sums[i - 1] + nums[i - 1];
for (int i = 0; i < n; ++i) {
int left = i + 1, right = n, t = sums[i] + s;
while (left <= right) {
int mid = left + (right - left) / 2;
if (sums[mid] < t) left = mid + 1;
else right = mid - 1;
}
if (left == n + 1) break;
res = min(res, left - i);
}
return res == INT_MAX ? 0 : res;
}
};
总结
看来并不能直接看别人的说的去实现,还是要自己去理解才行,每个人有每个人自己的理解。