Data.Set captures the mathematical abstraction of a set, but it is not identical. The main difference is that a
Data.Set requires its elements to be ordered, whereas a mathematical set only requires that its elements be comparable for equality.
The reason for requiring
Ord is efficiency. It would be perfectly possible to build a set abstraction by defining
data Set a = Set [a]
i.e. under the hood it is just a list, and we make sure we never insert duplicate elements. The
insert operations would be
elem a (Set as) = any (a ==) as
insert a (Set as) | a `elem` as = Set as
| otherwise = Set (a:as)
However, this means that both
insert are O(n) operations. If we want to do any better than this, the standard approaches are
- Store the elements in a balanced binary tree (which requires an
- Hash the elements and store them in an array (which requires a
The implementation chosen by the authors of
Data.Set was to use a binary tree, which you can see by going to the source. The implementation is more or less
data Set a = Bin a (Set a) (Set a)
Now you can write the
elem function as
elem :: Ord a => a -> Set a -> Bool
elem = go
go _ Tip = False
go x (Bin y l r) = case compare x y of
LT -> go x l
GT -> go x r
EQ -> True
which is an O(log n) operation, rather than O(n). Insertions are trickier (as you need to keep the tree balanced) but similar.
In a hash set, you don't directly compare elements when inserting and removing them. Instead, each element is hashed to an integer, and stored in a location based on that integer.
In theory this doesn't require an
Ord instance. In practice, you need some method of keeping track of multiple elements that hash to the same value, and the method chosen by the developers of
Data.HashSet is to store multiple elements in a regular
Data.Set, so it turns out you do need the
Ord instance after all!
data HashSet a = HashSet (Data.IntMap.IntMap (Data.Set.Set a))
It could have been written instead as
data HashSet a = HashSet (Data.IntMap.IntMap [a])
instead, which removes out the
Ord requirement at the cost of some inefficiency if there are many elements which has to the same value.