Based on Wikipedia's definition of a free object, it seems to me that every Functor is Free in Hask. Conversely, every free object should also be a Functor. Is this correct, or am I misunderstanding?
I'm not sure what you mean. Often times categorical definitions are written in greater generality than one wants in a functional programing contexts. Rather than using the wikipedia definition using concrete categories, consider the definition you get where you treat the kind of thing you want free as a parameter. Definition: free foo. A free foo on type Insert say "monoid" and you get free monoids, groups and you get free groups, etc. Note, this definition uses essentially no category theory and most certainly does not talk about functors. It is less formal than the definition given by wikipedia, but should work intuitively. Given this definition, a free construction is a general way of making free objects. For example I don't think it is the case that all functors are free functors. I also don't think it is the case that all free constructions in Hask are Haskell functors (that all free constructions lead to abstract functors is trivial). My definition of "free" applied only to things of kind You could go all out and do crazy things. For example, you could probably define the free boolean algebra on 


Functor
, by itself, is not an object in Hask, it's an endofunctor on Hask. Are you speaking about a free object in a different category than Hask? – luqui Jan 18 '13 at 1:06F
a Functor, thenF a
should be some free object (we don't know what type) on the "set"a
. – Mike Izbicki Jan 18 '13 at 18:31F
is a Functor,F a
is the free object ona
, then the forgetful functor would takeF a > a
? – Mike Izbicki Jan 18 '13 at 18:33