I'd like to understand the reason for this behavior of OCAML objects. Suppose I have a class
A that calls methods of an object of another class
B. Schematically, A#f calls B#g and B#h. The normal practice in OOP is that I would like to avoid using B as a fixed concrete class, but instead declare only an interface for B. What is the best way to do this in OCAML? I tried several options, and I do not quite understand the reason why some of them work while others don't. Here are the code samples.
# class classA = object method f b = b#g + b#h end ;; Error: Some type variables are unbound in this type: class a : object method f : < g : int; h : int; .. > -> int end The method f has type (< g : int; h : int; .. > as 'a) -> int where 'a is unbound
This behavior is well-known: OCAML correctly infers that
b has the open object type
<g:int;h:int;..> but then complains that my class does not declare any type variables. So it seems that
classA is required to have type variables; I then introduced a type variable explicitly.
# class ['a] classA2 = object method f (b:'a) = b#g + b#h end ;; class ['a] classA2 : object constraint 'a = < g : int; h : int; .. > method f : 'a -> int end
This works, but the class is now explicitly polymorphic with a type constraint, as OCAML shows. It is also confusing that the class type contains a type variable
'a, and yet I can still say
let x = new classA2 without specifying a type value for
'a. Why is that possible?
Another drawback of
classA2 is that an explicit type constraint
(b:'a) contains a type variable. After all, I know that
b must conform to a fixed interface rather than to an unknown type
'a. I want OCAML to verify that this interface is indeed correct.
So in version 3 I first declared an interface
classB as a class type and then declared that
b must be of this type:
# class type classB = object method g:int method h:int end;; class type classB = object method g : int method h : int end # class classA3 = object method f (b:classB) = b#g + b#h end;; class classA3 : object method f : classB -> int end
This works too, but my puzzlement remains: why doesn't
classA3 require explicit polymorphism any more?
Summary of questions:
- Why is it possible to use
new classA2without specifying a type for
classA2is declared with a type variable
- Why does
classA3accept a type constraint
(b:classB)and does not require a bound type variable any more?
- Is the functionality of
classA3different in some subtle way, and if yes, how?