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I am trying to write a typed abstract syntax tree datatype that can represent function application.

So far I have

type Expr<'a> =
    | Constant    of 'a
    | Application of Expr<'b -> 'a> * Expr<'b> // error: The type parameter 'b' is not defined

I don't think there is a way in F# to write something like 'for all b' on that last line - am I approaching this problem wrongly?

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1 Answer 1

up vote 9 down vote accepted

In general, the F# type system is not expressive enough to (directly) define a typed abstract syntax tree as the one in your example. This can be done using generalized algebraic data types (GADTs) which are not supported in F# (although they are available in Haskell and OCaml). It would be nice to have this in F#, but I think it makes the language a bit more complex.

Technically speaking, the compiler is complaining because the type variable 'b is not defined. But of course, if you define it, then you get type Expr<'a, 'b> which has a different meaning.

If you wanted to express this in F#, you'd have to use a workaround based on interfaces (an interface can have generic method, which give you a way to express constraint like exists 'b which you need here). This will probably get very ugly very soon, so I do not think it is a good approach, but it would look something like this:

// Represents an application that returns 'a but consists
// of an argument 'b and a function 'b -> 'a
type IApplication<'a> =
  abstract Appl<'b> : Expr<'b -> 'a> * Expr<'b> -> unit

and Expr<'a> = 
  // Constant just stores a value...
  | Constant    of 'a 
  // An application is something that we can call with an 
  // implementation (handler). The function then calls the
  // 'Appl' method of the handler we provide. As this method
  // is generic, it will be called with an appropriate type
  // argument 'b that represents the type of the argument.
  | Application of (IApplication<'a> -> unit) 

To represent an expression tree of (fun (n:int) -> string n) 42, you could write something like:

let expr = 
  Application(fun appl -> 
    appl.Appl(Constant(fun (n:int) -> string n), 

A function to evaluate the expression can be written like this:

let rec eval<'T> : Expr<'T> -> 'T = function
  | Constant(v) -> v   // Just return the constant
  | Application(f) ->
      // We use a bit of dirty mutable state (to keep types simpler for now)
      let res = ref None
      // Call the function with a 'handler' that evaluates function application
      f { new IApplication<'T> with
            member x.Appl<'A>(efunc : Expr<'A -> 'T>, earg : Expr<'A>) = 
              // Here we get function 'efunc' and argument 'earg'
              // The type 'A is the type of the argument (which can be
              // anything, depending on the created AST)
              let f = eval<'A -> 'T> efunc
              let a = eval<'A> earg
              res := Some <| (f a) }

As I said, this is a bit really extreme workaround, so I do not think it is a good idea to actually use it. I suppose the F# way of doing this would be to use untyped Expr type. Can you write a bit more about the overall goal of your project (perhaps there is another good approach)?

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A clear and thorough explanation, thanks! I'll see if I can explain clearly what I'm trying to achieve, but in the mean time thanks for keeping the typed option open. –  TimC Sep 23 '12 at 17:23
@TimC Glad to help. I think this approach will work as long as you need to simulate existential types. If you need real GADTs (where a type of a case differs for different cases - i.e. Lambda will be of some type Expr<'a -> 'b>) then I don't think you'll be able to find as easy workaround. –  Tomas Petricek Sep 23 '12 at 18:03

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