Let *A* be our input array with zero-based indexing. We can reduce *A* modulo *M* without changing the result.

First of all, let's reduce the problem to a slightly easier one by computing an array *P* representing the prefix sums of *A*, modulo *M*:

```
A = 6 6 11 2 12 1
P = 6 12 10 12 11 12
```

Now let's process the possible left borders of our solution subarrays in decreasing order. This means that we will first determine the optimal solution that starts at index *n - 1*, then the one that starts at index *n - 2* etc.

In our example, if we chose *i = 3* as our left border, the possible subarray sums are represented by the suffix *P[3..n-1]* plus a constant *a = A[i] - P[i]*:

```
a = A[3] - P[3] = 2 - 12 = 3 (mod 13)
P + a = * * * 2 1 2
```

The global maximum will occur at one point too. Since we can insert the suffix values from right to left, we have now reduced the problem to the following:

Given a set of values *S* and integers *x* and *M*, find the maximum of *S + x* modulo *M*

This one is easy: Just use a balanced binary search tree to manage the elements of *S*. Given a query *x*, we want to find the largest value in *S* that is smaller than *M - x* (that is the case where no overflow occurs when adding *x*). If there is no such value, just use the largest value of *S*. Both can be done in O(log |S|) time.

Total runtime of this solution: O(n log n)

Here's some C++ code to compute the maximum sum. It would need some minor adaptions to also return the borders of the optimal subarray:

```
#include <bits/stdc++.h>
using namespace std;
int max_mod_sum(const vector<int>& A, int M) {
vector<int> P(A.size());
for (int i = 0; i < A.size(); ++i)
P[i] = (A[i] + (i > 0 ? P[i-1] : 0)) % M;
set<int> S;
int res = 0;
for (int i = A.size() - 1; i >= 0; --i) {
S.insert(P[i]);
int a = (A[i] - P[i] + M) % M;
auto it = S.lower_bound(M - a);
if (it != begin(S))
res = max(res, *prev(it) + a);
res = max(res, (*prev(end(S)) + a) % M);
}
return res;
}
int main() {
// random testing to the rescue
for (int i = 0; i < 1000; ++i) {
int M = rand() % 1000 + 1, n = rand() % 1000 + 1;
vector<int> A(n);
for (int i = 0; i< n; ++i)
A[i] = rand() % M;
int should_be = 0;
for (int i = 0; i < n; ++i) {
int sum = 0;
for (int j = i; j < n; ++j) {
sum = (sum + A[j]) % M;
should_be = max(should_be, sum);
}
}
assert(should_be == max_mod_sum(A, M));
}
}
```

`M`

? – Sergey Kalinichenko Jun 29 '15 at 11:04`i`

and sums (in modolus) to`k`

, for each index`i`

and for each`k`

in`[0,M)`

(done in DP) – amit Jun 29 '15 at 11:07