I was just doing some homework for my upcoming OCaml test and I got into some trouble whatnot.

*Consider the language of λ-terms defined by the following abstract syntax (where x is a variable):*

```
t ::= x | t t | λx. t
```

*Write a type term to represent λ-terms. Assume that variables are represented as strings.*

Ok, boy.

```
# type t = Var of string | App of (t*t) | Abs of string*t;;
type t = Var of string | App of (t * t) | Abs of (string * t)
```

*The free variables fv(t) of a term t are defined inductively a follows:*

```
fv(x) = {x}
fv(t t') = fv(t) ∪ fv(t')
fv(λx. t) = fv(t) \ {x}
```

Sure thing.

```
# let rec fv term = match term with
Var x -> [x]
| App (t, t') -> (List.filter (fun y -> not (List.mem y (fv t'))) (fv t)) @ (fv t')
| Abs (s, t') -> List.filter (fun y -> y<>s) (fv t');;
val fv : t -> string list = <fun>
```

*For instance,*

```
fv((λx.(x (λz.y z))) x) = {x,y}.
```

Let's check that.

```
# fv (App(Abs ("x", App (Abs ("z", Var "y"), Var "z")), Var "x"));;
- : string list = ["y"; "z"; "x"]
```

I've checked a million times, and I'm sure that the result should include the "z" variable. Can you please reassure me on that?

`z`

is not a free variable of`(λz.y z)`

and therefore not a free variable of`(λx.(x (λz.y z))) x`

. – Pascal Cuoq Dec 9 '12 at 0:30`List.filter (fun y -> not (List.mem y (fv t'))) (fv t)`

, while it seems correct to me so far, computes`fv t'`

way to many times. You should compute it once with`let fv_t' = fv t' in …`

and use`fv_t'`

. – Pascal Cuoq Dec 9 '12 at 0:35`λ`

in the lambda-calculus associates the same as`fun`

in OCaml. The expression`fun x -> st uff`

is the same as`fun x -> (st uff)`

. – Pascal Cuoq Dec 9 '12 at 0:43