# Is it possible to get hold of free theorems as propositional equalities?

"Free theorems" in the sense of Wadler's paper "Theorems for Free!" are equations about certain values are derived based only on their type. So that, for example,

``````f : {A : Set} → List A → List A
``````

automatically satisfies

``````f . map g = map g . f
``````

Can I get my hands on an Agda term, then, of the following type:

``````(f : {A : Set} → List A → List A) {B C : Set} (g : B → C) (xs : List B)
→ f (map g xs) ≡ map g (f xs)
``````

or if so/if not, can I do something more/less general?

I'm aware of the existence of the Lightweight Free Theorems library but I don't think it does what I want (or if it does, I don't understand it well enough to do it).

(An example use case is that I have a functor `F : Set → Set` and would like to prove that a polymorphic function `F A × F B → F (A × B)` is automatically a natural transformation.)

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Better suited for Computer Science sites. –  PM 77-1 Jul 13 '14 at 0:48
I disagree – this is a question that is about what is concretely achievable in Agda today, rather than what is abstractly or theoretically possible. –  Ben Millwood Jul 13 '14 at 0:55
Everyone wants to get free theorems off the Internet. That's what's killed the theorem publishing business. ;( –  Hot Licks Jul 13 '14 at 1:45

No, the type theory on which Agda is build is not strong enough to prove this. This would require a feature called "internalized parametricity", see the work by Guilhem:

This would allow you for example to prove that all inhabitants of "(A : Set) → A → A" are equal to the (polymorphic) identity function. As far as I know, this has not been implemented in any language yet.

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Chantal Keller and Marc Lasson developped a tactic for Coq generating the parametricity relation corresponding to a (closed) type and proving that this type's inhabitants satisfy the generated relation. You can find more details about this work on Keller's website.

Now in Agda's case, it is in theory possible to do the same sort of work by implementing the tactic in pure Agda using a technique called reflection.

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Your comment about Agda seems to contradict the other answer – are you sure it is possible? –  Ben Millwood Jul 13 '14 at 14:44
Coq does not internalize parametricity either: it's a tactics that does the job. Similarly, neither Agda nor Coq have `fold` functions for their inductive types but you can write a tactic building these iterators automatically. This is true because (and it's a meta-theorem, just like parametricity is) given the restrictions in their type systems, you know that every inductive type has an initial algebra. –  gallais Jul 13 '14 at 22:13