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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?

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A Haskell 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 1:06
Every functor in Hask is adjoint to what forgetful functor? –  n.m. Jan 18 '13 at 9:41
@luqui I think I'm talking about Hask, but I could be wrong. What I mean is that if F a Functor, then F a should be some free object (we don't know what type) on the "set" a. –  Mike Izbicki Jan 18 '13 at 18:31
@n.m. If F is a Functor, F a is the free object on a, then the forgetful functor would take F a -> a? –  Mike Izbicki Jan 18 '13 at 18:33
No, this is all totally wrong. –  n.m. Jan 19 '13 at 8:36

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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 T is an object FT such that F is a foo, and a function i :: T -> FT such that any other foo S and a function f :: T -> S there exists a unique foo morphism f' such that f' . i = f.

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 [] provides a free construction for monoids, in that [a] is the free monoid on a for all a.

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 *, but a more general definition would also apply to other kinds. For example, free monads.

You could go all out and do crazy things. For example, you could probably define the free boolean algebra on Sing k (the singleton types of kind k) where k is enumerable using GADTs. That this involves something "functorial" will be highly non-obvious in Hask.

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What I was thinking is that what you call function f looks a lot like the first argument to fmap. The function i also looks a lot like the function pure, so maybe what I'm thinking about actually applies to applicatives. Also, based on your type signatures for f and i, I don't see how any type for f' could make the equation f' . i = f work. Did you mean to say: f . i = f' and have the type of f' :: FT -> FS? –  Mike Izbicki Jan 18 '13 at 17:36
f' :: FT -> S, so f' . i :: T -> S which is what you want. The naming may not have been the best. Consider the case where foo is replaced with Monoid. Then, my claim is that for any a and function f :: a -> m where m is a monoid, f = mconcat . map f . (:[]), and mconcat . map f is a monoid morphism. I think you are correct that free constructions should tend to be pointed functors. –  Philip JF Jan 18 '13 at 19:31
Not only a pointed functor, but a monad! (>>=) :: m a -> (a -> m b) -> m b, or in the above syntax FT -> (T -> FU) -> FU. Now, choose S to be FU, then we get for every f :: T -> FU a function f' :: FT -> FU, which is the same as flip (>>=). (The adjunction between the free functor and the forgetful functor gives rise to this monad.) I have this packaged up here:… –  Sjoerd Visscher Jan 22 '13 at 21:44

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