This can be done in time O(n·k·m) and space O(n·k) by a method similar to that outlined below. Let S be your set with m elements. By definition of *set* and *subset*, all the elements of S are distinct, as are all the elements of any S-subset.

First, consider the simpler problem where we count S-subsets with any number of elements instead of exactly n elements. Let N(W,r) be the number of W-subsets U such that ΣU (the sum of elements of U) is equal to r mod k. If W is a subset of S, let W' be W + z, where z ∈ S\W; that is, z is an element of S not already in W. Now N(W', (r+z)%k) = N(W, (r+z)%k) + N(W, r) because N(W, (r+z)%k) is the number of W'-subsets U with ΣU≡(r+z)%k) that don't contain z and N(W, r) is the number of W'-subsets U with ΣU≡(r+z)%k) that do contain z. Repeat this construction, treating each element of S in turn until W' = S, at which point the desired answer is N(S,0). Time is O(k·m), space is O(k).

To adapt the above process for exact subset sizes, change N(W,r) to N(W,h,r), where h is a subset size, and adapt the equations for N(W',r) to N(W',h,r) in the obvious way. Time is O(k·n·m), space is O(k·n).