This code works but, as I said, is highly unoptimal.
Doesn't seem so terribly bad to me. The number of subsets of size
k of a set of size
n `choose` k which grows rather fast for
k ~ n/2. So creating all the subsets must scale badly.
Using an intermediate list to avoid the
Set.insert doesn't seem help due to the large cost of later reconverting the list to a Set.
Hmm, I found using lists to give better performance. Not asymptotically, I think, but a not negligible more-or-less constant factor.
But first, there is an inefficiency in your code that is simple to repair:
Set.map (Set.insert firstS) (partialN (n-1))
Set.map must rebuild a tree from scratch. But we know that
firstS is always smaller than any element in any of the sets in
partialN (n-1), so we can use
Set.mapMonotonic that can reuse the spine of the set.
And that principle is also what makes lists attractive, the subsets are generated in lexicographic order, so instead of
Set.fromList we can use the more efficient
Set.fromDistinctAscList. Transcribing the algorithm yields
onlyLists :: Ord a => Int -> Set.Set a -> Set.Set (Set.Set a)
onlyLists n s
| n == 0 = Set.singleton Set.empty
| Set.size s < n || n < 0 = error "onlyLists: out of range n"
| Set.size s == n = Set.singleton s
| otherwise = Set.fromDistinctAscList . map Set.fromDistinctAscList $
go n (Set.size s) (Set.toList s)
go 1 _ xs = map return xs
go k l (x:xs)
| k == l = [x:xs]
| otherwise = map (x:) (go (k-1) (l-1) xs) ++ go k (l-1) xs
which in the few benchmarks I've run is between 1.5 and 2× faster than the amended algorithm using
And that is in turn, in my criterion benchmarks, nearly twice as fast as dave4420's.