# How do you prove that a function is unique for its type?

`id` is the only function of type `a -> a`, and `fst` the only function of type `(a,b) -> a`. In these simple cases, this is fairly straightforward to see. But in general, how would you go about proving this? What if there are multiple possible functions of the same type?

Alternatively, given a function's type, how do you derive the unique (if this is true) function of that type?

Edit: I'm particularly interested in what happens when we start adding constraints into the types.

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To be pedantic, I think people would usually say that `id` is the only 'interesting' or 'total' function of type `a->a`. `undefined` can be of any type in Haskell, but it's not a useful function. You might also be interested in Djinn, a program that generates functions from a type when possible, lambda-the-ultimate.org/node/1178 –  John L Nov 27 '12 at 0:39
@JohnL Djinn doesn't actually prove uniqueness, does it? It just finds some function of that type if it exists. –  Mike Izbicki Nov 27 '12 at 0:42
This question may be more suited to cs.stackexchange.com –  Heatsink Nov 27 '12 at 0:47
@MikeIzbicki that's a good point. However, Djinn will find multiple solutions (e.g. `f ? (a,a,b) -> a` will find both answers). If the list is exhaustive (I don't know if it is), then determining uniqueness is trivial. –  John L Nov 27 '12 at 0:52
@JohnL - djinn won't generate all functions; at least not in all cases -- consider `f :: Float -> Float` –  amindfv Nov 27 '12 at 2:45

The result you are looking for derives from Reynolds' parametricity, and was most famously shown by Wadler in theorems for free.

The most elegant way of proving basic parametricity results I have seen use the notion of a "Singleton Type". Essentially, given any ADT

``````data Nat = Zero | Succ Nat
``````

there exists an indexed family (also known as a GADT)

``````data SNat n where
SZero :: SNat Zero
SSucc :: SNat n -> SNat (Succ n)
``````

and we can give a semantics to our language by "erasing" all the types to an untyped language such that `Nat` and `SNat` erase to the same thing. Then, by the typing rules of the language

``````id (x :: SNat n) :: SNat n
``````

`SNat n` has only one inhabitant (its singleton), since the semantics is given by erasure, functions can not use the type of their arguments, so the only value returnable from `id` on any `Nat` is the number you gave it. This basic argument can be extended to prove most of the parametricity results and was used by Karl Crary in A Simple Proof Technique for Parametricity Results although the presentation I have here is inspired by Stone and Harper

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