Off-by-one on range boundaries
Wrong move: Loop endpoints miss first/last candidate.
Usually fails on: Fails on minimal arrays and exact-boundary answers.
Fix: Re-derive loops from inclusive/exclusive ranges before coding.
Move from brute-force thinking to an efficient approach using array strategy.
Given an integer array nums and an integer k, return the number of non-empty subarrays that have a sum divisible by k.
A subarray is a contiguous part of an array.
Example 1:
Input: nums = [4,5,0,-2,-3,1], k = 5 Output: 7 Explanation: There are 7 subarrays with a sum divisible by k = 5: [4, 5, 0, -2, -3, 1], [5], [5, 0], [5, 0, -2, -3], [0], [0, -2, -3], [-2, -3]
Example 2:
Input: nums = [5], k = 9 Output: 0
Constraints:
1 <= nums.length <= 3 * 104-104 <= nums[i] <= 1042 <= k <= 104Problem summary: Given an integer array nums and an integer k, return the number of non-empty subarrays that have a sum divisible by k. A subarray is a contiguous part of an array.
Start with the most direct exhaustive search. That gives a correctness anchor before optimizing.
Pattern signal: Array · Hash Map
[4,5,0,-2,-3,1] 5
[5] 9
subarray-sum-equals-k)make-sum-divisible-by-p)count-number-of-bad-pairs)find-the-divisibility-array-of-a-string)count-of-interesting-subarrays)Source-backed implementations are provided below for direct study and interview prep.
// Accepted solution for LeetCode #974: Subarray Sums Divisible by K
class Solution {
public int subarraysDivByK(int[] nums, int k) {
Map<Integer, Integer> cnt = new HashMap<>();
cnt.put(0, 1);
int ans = 0, s = 0;
for (int x : nums) {
s = ((s + x) % k + k) % k;
ans += cnt.getOrDefault(s, 0);
cnt.merge(s, 1, Integer::sum);
}
return ans;
}
}
// Accepted solution for LeetCode #974: Subarray Sums Divisible by K
func subarraysDivByK(nums []int, k int) (ans int) {
cnt := map[int]int{0: 1}
s := 0
for _, x := range nums {
s = ((s+x)%k + k) % k
ans += cnt[s]
cnt[s]++
}
return
}
# Accepted solution for LeetCode #974: Subarray Sums Divisible by K
class Solution:
def subarraysDivByK(self, nums: List[int], k: int) -> int:
cnt = Counter({0: 1})
ans = s = 0
for x in nums:
s = (s + x) % k
ans += cnt[s]
cnt[s] += 1
return ans
// Accepted solution for LeetCode #974: Subarray Sums Divisible by K
struct Solution;
impl Solution {
fn subarrays_div_by_k(a: Vec<i32>, k: i32) -> i32 {
let n = k as usize;
let mut count: Vec<i32> = vec![0; n];
let mut sum = 0;
let mut res = 0;
count[0] = 1;
for x in a {
sum = (sum + x % k + k) % k;
res += count[sum as usize];
count[sum as usize] += 1;
}
res
}
}
#[test]
fn test() {
let a = vec![4, 5, 0, -2, -3, 1];
let k = 5;
let res = 7;
assert_eq!(Solution::subarrays_div_by_k(a, k), res);
}
// Accepted solution for LeetCode #974: Subarray Sums Divisible by K
function subarraysDivByK(nums: number[], k: number): number {
const cnt: { [key: number]: number } = { 0: 1 };
let s = 0;
let ans = 0;
for (const x of nums) {
s = (((s + x) % k) + k) % k;
ans += cnt[s] || 0;
cnt[s] = (cnt[s] || 0) + 1;
}
return ans;
}
Use this to step through a reusable interview workflow for this problem.
Two nested loops check every pair or subarray. The outer loop fixes a starting point, the inner loop extends or searches. For n elements this gives up to n²/2 operations. No extra space, but the quadratic time is prohibitive for large inputs.
Most array problems have an O(n²) brute force (nested loops) and an O(n) optimal (single pass with clever state tracking). The key is identifying what information to maintain as you scan: a running max, a prefix sum, a hash map of seen values, or two pointers.
Review these before coding to avoid predictable interview regressions.
Wrong move: Loop endpoints miss first/last candidate.
Usually fails on: Fails on minimal arrays and exact-boundary answers.
Fix: Re-derive loops from inclusive/exclusive ranges before coding.
Wrong move: Zero-count keys stay in map and break distinct/count constraints.
Usually fails on: Window/map size checks are consistently off by one.
Fix: Delete keys when count reaches zero.