My question is if there is any difference between Standard ML's module system and OCaml module system? Has OCaml all the support of functors , ascriptions etc... that SML has?

up vote 50 down vote accepted

There are some differences feature-wise, as well as semantically.

Features SML supports but not OCaml:

  • transparent signature ascription
  • module-level let
  • symmetric sharing constraints
  • syntactic sugar for functors over types and values

Features OCaml 4 has but not SML:

  • higher-order functors
  • recursive modules
  • local modules
  • nested signatures
  • modules as first-class values
  • general module sharing (sig with module A = M)
  • module type of

Several SML implementations provide some of these as extensions, however: e.g. higher-order functors (SML/NJ, Moscow ML, Alice ML), local and first-class modules (Moscow ML, Alice ML), module sharing (SML/NJ, Alice ML), nested signatures (Moscow ML, Alice ML), and recursive modules (Moscow ML).

Semantics-wise, the biggest difference is in the treatment of type equivalence, especially with respect to functors:

  • In SML, functors are generative, which means that applying the same functor twice to the same argument always yields fresh types.

  • In OCaml, functors are applicative, which means that applying the same functor twice to the exact same argument (plus additional syntactic restrictions) reproduces equivalent types. This semantics is more flexible, but can also break abstraction (see e.g. the examples we give in this paper, Section 8).

    Edit: OCaml 4 added the ability to optionally make functors generative.

  • OCaml has a purely syntactic notion of signatures, which means that certain type equivalences cannot be expressed by the type system, and are silently dropped.

    Edit: Consider this example:

    module F (X : sig type t end) = struct type u = X.t -> unit type v = X.t end
    module M = F (struct type t = int end : sig type t end)
    

    The type of M is simply sig type u type v end and has thus lost any information about the relation between its types u and v, because that cannot generally be expressed in the surface syntax.

Another notable difference is that OCaml's module type system is undecidable (i.e, type checking may not terminate), due to its permission of abstract signatures, which SML does not allow.

  • 4
    I think you should take the opportunity to take a bit about future module systems, or more precisely the way these feature sets would change assuming a reasonable inception of the "recent" (mostly yours) research on module systems in a next clean iteration of a ML language. That would turn an very interesting answer into an extremely interesting answer. – gasche Mar 23 '13 at 12:43
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    I felt it inappropriate to piggyback the question for that ;). My personal answer would be pretty much what's in the F-ing modules paper I link above -- it subsumes all of the listed features in a clean and (fairly) simple manner (including both generative and applicative functors), minus recursive modules. For those I'm not so sure. OCaml's recursive modules are far too ad-hoc and limited for my taste, but a comprehensive approach will ultimately lead to abandoning a major part of what makes up ML modules, as we describe in the MixML paper. The jury is still out on whether it's worth that. – Andreas Rossberg Mar 23 '13 at 16:18
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    @fedvasu, yes, traditional modules arise as special cases, but yet, the character of the whole system changes quite severely. Traditional ML modules are very functional in nature (e.g. functors as functions, signatures as a natural notion of type). The MixML approach appears less functional and more object-oriented the closer you look, including some of the problems that entails (e.g. more complex, object-like primitives, the hybrid role of modules as both values and types, and observable side effects in initialisation). Question is, is that a bug or a feature? ;) – Andreas Rossberg Apr 2 '13 at 15:16
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    @fedvasu, depends on what specific statement from Odersky you are referring to. ;) Re good enough: either no recursion at all (which many people believe is preferable anyway), or bite the bullet and go the whole way to something similar to MixML. All ad-hoc notions of recursive modules I have seen introduce even more problems and/or are too limited to carry their weight IMHO. – Andreas Rossberg Apr 3 '13 at 11:44
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    @StevenShaw, to be quite honest, I'm still undecided myself. As for side effects, initialisation requires evaluation of respective module bodies, which can generally be effectful computations. Hence, despite recursion, there is a sequential, left-to-right evaluation order that matters for the order of possible effects. Also, you get runtime exceptions when the recursion turns out to be not well-founded, i.e., some value component is used before its initialisation. (Although that's still better than, say, Java, where you just silently get bogus "default" values.) – Andreas Rossberg Apr 27 '14 at 21:41

As for semantics, a much better and elaborate answer is given by Andreas Rossberg above. However, concerning syntax this site might be what you are looking for.

  • 5
    and that site is also the work of Andreas Rossberg! – fedvasu Apr 2 '13 at 13:22

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