# Is it possible to normalize affine λ-calculus terms using PHOAS in Agda?

In Agda, one can conveniently represent λ-terms using PHOAS:

``````data Term (V : Set) : Set where
var : V → Term V
abs : (V → Term V) → Term V
app : Term V → Term V → Term V
``````

That approach has several benefits over Bruijn indices, as explained in "Parametric Higher-Order Abstract Syntax for Mechanized Semantics". As far as I know, though, there can't be a `eval : ∀ {V} -> Term V -> Term V` function that, given a λ-term, returns its normal form - after all, Agda is total and the λ-calculus is not. But I wonder if it would be possible to write such `eval` function for affine λ-terms; i.e., those where bound variables occur at most once. That language is obviously total.

• Presumably yes. Translate your argument for why the language is "obviously total" into Agda and you will have your function. – luqui Aug 14 '18 at 16:25
• @MaiaVictor I would first just consider normalization for the first-order syntax, you can always go to and from PHOAS (although this may require to postulate some parametricity theorems). – András Kovács Aug 14 '18 at 16:40
• I'm not sure PHOAS is ideal for this job. I'd want a representation that more explicitly witnesses affinity. Nice problem. – pigworker Aug 14 '18 at 17:17
• You might try first converting the lambda expression to a combinator expression with an “abstraction algorithm” using only Bxyz=x(yz), Cxyz=xzy, Kxy=x, Ix=x—the result is guaranteed by construction to be affine, so it might be easier to formulate the proof that evaluation is terminating – Jon Purdy Aug 15 '18 at 10:32
• At least two strategies occur to me. One is to exploit the fact that every beta reduction guarantees a net loss of at least one lambda. The other (which I think I prefer) is to show that every affine lambda term has a simple type. – pigworker Aug 15 '18 at 18:46