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if I specify the (I think) correct type for a high order function the OCaml compiler rejects the second usage of that function.

The code

let foo ():string  =
    let f: ('a -> string) -> 'a -> string = fun g v -> g v
    in let h = string_of_int
    in let i = string_of_float
    in let x = f h 23
    in let y = f i 23.0
    in x ^ y

leads to the following error message

File "test.ml", line 6, characters 14-15:
Error: This expression has type float -> string
       but an expression was expected of type int -> string

So the first usage of f seems to fix the type of its first parameter to int -> string. I could understand that. But what I don't get is that omitting the type restriction on f fixes the problem.

let foo ():string  =
    let f g v = g v
    in let h = string_of_int
    in let i = string_of_float
    in let x = f h 23
    in let y = f i 23.0
    in x ^ y

And moving f to global scope fixes the problem, too:

let f: ('a -> string) -> 'a -> string = fun g v -> g v

let foo ():string  =
  let h = string_of_int
  in let i = string_of_float
  in let x = f h 23
  in let y = f i 23.0
  in x ^ y

Why is it that the first example does not compile while the later ones do?

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3  
I am stumped by your question, but a remark I can make is that let f (g: 'a->string) (v: 'a): string = g v does not do what you want: the 'a is not the same in the two type annotations. You'd better write let (f : ('a->string) -> 'a -> string) = fun g v -> g v (which produces the same type error) if you want to constrain g and v with the same 'a. –  Pascal Cuoq Dec 14 '10 at 19:48
2  
I would recommend posting this to the OCaml mailing list. –  Niki Yoshiuchi Dec 14 '10 at 20:03
    
@Pascal: thank you, I edited the question –  copton Dec 14 '10 at 20:34
1  
After reading Gilles's answer, I retract my comment: it is the same 'a in the two annotations, and the mechanism that makes it the same is the mechanism that also causes the confusion. Also confirmed by typing let f (x:'a) (y:'a) = raise Not_found ;; or by reading caml.inria.fr/pub/docs/manual-ocaml/types.html at section "type variables". –  Pascal Cuoq Dec 14 '10 at 22:13
    
Why post the same question both on StackOverflow and the OCaml mailing list? As there are knowledgeable camlers on both, you have two correct, disconnected answers (as most mailing-list reader don't read StackOverflow), so one of them was valuable time wasted by a helper. –  gasche Dec 15 '10 at 13:45
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3 Answers 3

up vote 9 down vote accepted

Let me use a simpler example that illustrates the issue.

# let cons0 (x : 'a) (y : 'a list) = x :: y;;
val cons0 : 'a -> 'a list -> 'a list = <fun>
# let cons1 (x : 'a) (y : 'a list) = x :: y in cons1 1 [];;
- : int list = [1]
# let cons2 (x : 'a) (y : 'a list) = x :: y in (cons2 1 [], cons2 true []);;
This expression has type bool but is here used with type int
# let cons3 x y = x :: y in (cons3 1 [], cons3 true []);;
- : int list * bool list = ([1], [true])

cons0 is a polymorphic function definition, defined at global scope. It's just a trivial wrapper to the :: operator. Unsurprisingly, the definition works. cons1 is almost the same as cons0, except that its scope is limited to the expression in the in body. The change of scope looks innocuous, and sure enough, it typechecks. cons3 is again the same function, with no type annotation, and we can use it polymorphically in the in body.

So what's wrong with cons2? The problem is the scope of 'a: it's the whole toplevel phrase. The semantics of the phrase that defines cons2 is

for some type 'a, (let cons2 (x : 'a) (y : 'a list) = ... in ...)

Since 'a must be compatible with int (due to cons3 1 []) and with bool (due to cons3 true [], there is no possible instantiation of 'a. Therefore the phrase is ill-typed.

If you like to think about ML typing in terms of its usual type inference algorithm, each explicit user variable introduces a set of constraints in the unification algorithm. Here the constraints are 'a = "type of the parameter x" and ' = "type of the parameter y". But the scope of 'a is the whole phrase, it's not generalized in any inner scope. So int and bool both end up unified to the non-generalized 'a.

Recent versions OCaml introduce scoped type variables (as in Niki Yoshiuchi's answer). The same effect could have been achieved with a local module in earlier versions (≥2.0):

let module M = struct
    let cons2 (x : 'a) (y : 'a list) = x :: y
  end in
(M.cons2 1 [], M.cons2 true []);;

(Standard MLers note: this is one place where OCaml and SML differ.)

share|improve this answer
    
What's interesting is how f (x: 'a) differs from f x, as both appear to have the same type signature. The fact that the global scope differs from the in scope makes sense, what doesn't is that annotating the type to a generic resolves that generic to an explicit type. If the behavior was the same for both annotated and non-annotated parameters it would be less weird. –  Niki Yoshiuchi Dec 14 '10 at 20:57
1  
@Niki: The thing is, you're not annotating the type to a generic, you're annotating with a variable. The scope of the variable is the whole phrase. I think this issue would feel natural if you had to declare type variables. (Also remember that they're type variables, not type scheme variables.) –  Gilles Dec 14 '10 at 21:08
    
Thanks for this instructive answer. Do you remember when it was decided that the scope of type variables such as 'a was the phrase? I am almost certain I remember a time around year 2000 when the scope was just the type (at that time, my comment to the question would have been valid. Now, it's not, I guess...) –  Pascal Cuoq Dec 14 '10 at 22:10
    
@Pascal: I don't remember ever seeing an ML implementation where the scope of a type variable was a single type annotation. And AFAIK the scope of 'a has always been the same in OCaml (and probably was in Caml Light too, maybe not in CAML), other than when explicitly delimited through features like local modules and polymorphic records. –  Gilles Dec 14 '10 at 22:32
    
@Gilles: thank you for the answer. Just to state it clear: does this mean that there is no way to get the intended behavior with type annotations? –  copton Dec 15 '10 at 7:04
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This is a real head-scratcher and I wouldn't be surprised if it's a compiler bug. That said, you can do what you want by explicitly naming the type:

let f (type t) (g: t->string) (v: t) = g v in

From the manual: http://caml.inria.fr/pub/docs/manual-ocaml/manual021.html#htoc108

Edit:

This also works:

let f g v:string = g v in

which has the type signature you are looking for: ('a -> string) -> 'a -> string

Strange that it doesn't work when you annotate the type of the arguments.

EDIT:

Polymorphic type annotations have a special syntax:

let f: 'a. ('a -> string)-> 'a -> string = fun g v -> g v in

And the type is required to be polymorphic: http://caml.inria.fr/pub/docs/manual-ocaml/manual021.html#toc79

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1  
Your answer makes me wonder if it's not a regression introduced in OCaml 3.12 (at the same time as the circumvention method, so to speak). I have only 3.12.0. Did someone try with an older version? –  Pascal Cuoq Dec 14 '10 at 19:53
1  
@Pascal Cuoq: same with 3.11.2 –  barti_ddu Dec 14 '10 at 19:55
    
@Pascal Cuoq same with 3.10.2 –  Niki Yoshiuchi Dec 14 '10 at 19:57
1  
Could this be something to do with weak polymorphism? (I tried with 3.11.0). –  nlucaroni Dec 14 '10 at 20:17
1  
@Niki: according to the caml mailing list locally abstract types (let f (type a) (g : a -> string) (v : a) : string = g v) and polymorphic recursion (let f: 'a. ('a -> string) -> 'a -> string = fun g v -> g v) indeed are the two possible solutions. Both are available in OCaml 3.12. –  copton Dec 15 '10 at 9:02
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As a reference point, the equivalent F#

let foo ():string  = 
    let f: ('a -> string) -> 'a -> string = fun g v -> g v 
    let h = string 
    let i = string
    let x = f h 23 
    let y = f i 23.0 
    x ^ y 

compiles.

share|improve this answer
    
One would expect so, since h and i are both the same hat-typed function in F#, right? –  Chuck Dec 14 '10 at 20:56
    
No, since they're not inline, the type inference infers a monomorphic type for each based on usage. So h is int -> string and i is float -> string. (You can always add explicit types or lambdas to make this more obvious.) Only inlines can have hat types; use them outside an inline context, and they must get 'normal' type instantiations based on usage. –  Brian Dec 14 '10 at 22:08
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