What you're trying to determine is if there is a subgroup H of G such that {g_{1}, ..., g_{n}} is a transversal of the cosets of H. i.e. A set of representatives of the partitioning of G by the cosets of H.

First, by Lagrange's theorem, |G| = |G:H| * |G|, where |G:H| = |G|/|H| is the index of the subgroup H of G. If {g_{1}, ..., g_{n}} is indeed a transversal, then |G:H| = |{g_{1}, ..., g_{n}}|, so the first test in your algorithm should be whether n divides |G|.

Moreover, since g_{i} and g_{j} are in the same right coset only if g_{i}g_{j}^{-1} is in H, you can then check subgroups with index n to see if they avoid g_{i}g_{j}^{-1}. Also, note that (g_{i}g_{j}^{-1})(g_{j}g_{k}^{-1}) = g_{i}g_{k}^{-1}, so you can choose any pairing of the g_{i}s.

This should be sufficient if n is small compared to |G|.

Another approach is to start with H being the trivial group and add elements of the set H^{*} = {h in G : h^{k} != g_{i}g_{j}^{-1}, for all i, j, k; i != j} to the generators of H until you can't add any more (i.e. until it's no longer a subgroup). H is then a maximal subgroup of G such that H is a subset of H^{*}. If you can get all such H (and have them be large enough) then the subgroup you're looking for must be one of them.

This approach would work better for larger n.

Either way a non-exponential-time approach isn't obvious.

**EDIT:** I've just found a discussion of this very topic here: http://en.wikipedia.org/wiki/Wikipedia:Reference_desk/Archives/Mathematics/2009_April_18#Is_a_given_set_of_group_elements_a_set_of_coset_representatives.3F