We can appeal to Daan Leijen's HMF for a few ideas. (He dealing with binders for 'foralls', which also come across as commutative.

In particular, he rebinds the variables in the occurrence order in the body.

Then comparison of terms involves skolemizing both the same way and comparing the results.

We can do better than that by replacing that skolemization pass with a locally nameless representation.

```
data Bound t a = Bound {-# UNPACK #-} !Int t | Unbound a
instance Functor (Bound t) where ...
instance Bifunctor Bound where ...
data Expr a
= Lambdas {-# UNPACK #-} !Int (Expr (Bound () a))
| Var a
```

So now occurrences of Bound under a lambda are the variables bound directly by the lambda, along with any type information you want to put in the occurence, here I just used ().

Now closed terms are polymorphic in 'a' and, if you sort the elements of the lambda by their use site (and can ensure that you always canonicalize the lambda by removing unused terms) alpha equivalent terms compare simply with (==), and if you need open terms you can work with Expr String or some other representation.

A more anal retentive version of the signature for Expr and Bound would use an existential type and a type level natural to identify the number of variables being bound, and use 'Fin' in the Bound constructor, but since you already have to maintain the invariant that you bind no more variables than the # occurring in the lambda and that the type information agrees across all of `Var (Bound n _)`

with the same `n`

, its not too much of a burden to maintain another.

Update: You can use my `bound`

package to do an improved version of this in a fully self-contained way!

`Lambdas [Name Expr] Expr`

(instead of using a Set), does the`aeq`

function do the Right Thing? – John L Feb 27 '12 at 12:24