The original dynamic programming algorithm applies, with a slight extension - in addition to remembering partial sums, you also need to remember number of ints used to get the sums.

In the original algorithm, assuming the target sum is `M`

and there are `n`

integers, you fill a boolean `n`

x `M`

array `A`

, where `A[i,m]`

is true iff sum `m`

can be achieved by picking (any number of) from first `i+1`

ints (assuming indexing from 0).

You can extend it to a three dimensional array `n`

x`M`

x`k`

, which has a similar property - `A[i,m,l]`

is true iff, sum `m`

can be achieved by picking exactly `l`

from first `i+1`

ints.

Assuming the ints are in array `j[0..n-1]`

:

The recursive relation is pretty similar - the field `A[0,j[0],1]`

is true (you pick `j[0]`

, getting sum `j[0]`

with 1 int (duh)), other fields in `A[0,*,*]`

are false and deriving fields in `A[i+1,*,*]`

from `A[i,*,*]`

is also similar to the original algorithm: `A[i+1,m,l]`

is true if `A[i,m,l]`

is true (if you can pick `m`

from first `i`

ints, then obviously you can pick `m`

from first `i+1`

ints) or if `A[i, m - j[i+1], l-1]`

is true (if you pick `j[i+1]`

then you increase the sum by `j[i+1]`

and the number of ints by 1).

If `k`

is small then obviously it makes sense to skip all of the above part and just iterate over all combinations of `k`

ints and checking their sums. `k<=4`

indeed seems like a sensible threshold.