Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free.

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?

share|improve this question
No, 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
I'm still puzzling over why your code computes the wrong answer, but 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
@PascalCuoq I think I got it. I was reading (λz.y z) as ((λz.y) z) when in fact it should be read as (λz.(y z)). Thing is, nothing pointed me towards that kind of association. Thank you for the optimisation tip as well! –  rickmeizter Dec 9 '12 at 0:41
Yes, 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
Should we keep the question? –  rickmeizter Dec 9 '12 at 0:46

1 Answer 1

up vote 3 down vote accepted

In the comments to the OP it has been pointed out by the kind @PasqualCuoq that λ in lambda calculus associates the same as fun in OCaml. That is, the term t in λx.t is evaluated greedily (see http://en.wikipedia.org/wiki/Lambda_calculus#Notation).

What this is means is that (λz.y z) is actually (λz.(y z)), and that the function above is correct, but the translation provided for the sample expression (λx.(x (λz.y z))) x isn't, as it should've been

(App(Abs("x", App(Var "x", Abs("z", App(Var "y", Var "z")))), Var "x"))

in place of

(App(Abs ("x", App (Abs ("z", Var "y"), Var "z")), Var "x"))

Here's to this awesome place called Stack Overflow!

share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.