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The ML module system stands as a high-water mark of programming language support for data abstraction. However, superficially, it seems that it can easily be encoded in an object-oriented language that supports abstract type members. For example, we can encode the elements of SML module system in Scala as follows:

  • SML signatures: Scala traits with no concrete members
  • SML structures with given signatures: Scala objects extending given traits
  • SML functors parameterised by given signatures: Scala classes taking objects extending given traits as constructor arguments

Are there any significant features such an encoding would miss? Anything that can be expressed in SML modules that encoding can't express? Any guarantees that SML makes that this encoding would not be able to make?

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There are a few fundamental differences that you cannot overcome easily:

  • ML signatures are structural types, Scala traits are nominal: an ML signature can be matched by any appropriate module after the fact, for Scala objects you need to declare the relation at definition time. Likewise, subtyping between ML signatures is fully structural. Scala refinements are closer to structural types, but have some rather severe limitations (e.g., they cannot reference their own local type definitions, nor contain free references to abstract types outside their scope).

  • ML signatures can be composed structurally using include and where. The resulting signature is equivalent to the inline expansion of the respective signature expression or type equation. Scala's mixin composition, while more powerful in many ways, again is nominal, and creates an inequivalent type. Even the order of composition matters for type equivalence.

  • ML functors are parameterised by structures, and thereby by both types and values, Scala's generic classes are only parameterised by types. To encode a functor, you would need to turn it into a generic function, that takes the types and the values separately. In general, this transformation -- called phase-splitting in the ML module literature -- cannot be limited to just definitions and uses of functors, because at their call-sites it has to be applied recursively to nested structure arguments; this ultimately requires that all structures are consistently phase-split, which is not a style you want to program in manually. (Neither is it possible to map functors to plain functions in Scala, since functions cannot express the necessary type dependencies between parameter and result types. Edit: since 2.10, Scala has support for dependent methods, which can encode some examples of SML's first-order generative functors, although it does not seem possible in the general case.)

  • ML has a general theory of refining and propagating "translucent" type information. Scala uses a weaker equational theory of "path-dependent" types, where paths denote objects. Scala thereby trades ML's more expressive type equivalences for the ability to use objects (with type members) as first-class values. You cannot easily have both without quickly running into decidability or soundness issues.

  • Edit: ML can naturally express abstract type constructors (i.e., types of higher kind), which often arise with functors. For Scala, higher kinds have to be activated explicitly, which are more challenging for its type system, and apparently lead to undecidable type checking.

The differences become even more interesting when you move beyond SML, to higher-order, first-class, or recursive modules. We briefly discuss a few issues in Section 10.1 of our MixML paper.

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@copumpkin, e.g. try a trivial toy functor like functor F(X : ORD) = struct fun eq(x, y) = X.leq(x, y) andalso X.leq(y, x) end (for the obvious definition of ORD) -- its direct translation to Scala would be def F(X : ORD) = new { def eq(x : X.T, y : X.T) = X.leq(x, y) && X.leq(y, x) }, which doesn't type-check. –  Andreas Rossberg Aug 2 '14 at 8:42
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@Blaisorblade, note that your gist does not only use nominal typing, it also changes the interface of the functor by reexporting the type. Sometimes this may be what you want, but sometimes it is not. The latter case cannot be expressed in Scala, AFAICT. –  Andreas Rossberg Sep 11 '14 at 17:46
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@Blaisorblade, here is a simple example: trait T { type V; val v : V }; trait U { val a : T; val b : a.V }; def f(x : T) = new U { val a = x; val b = x.v } -- this produces "error: overriding value b in trait U of type this.a.V; value b has incompatible type". Though I can't claim to understand why this doesn't work. –  Andreas Rossberg Sep 11 '14 at 17:48
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@AndreasRossberg: the insight you need to understand the above is that Γ ⊦ A = B is only ever deduced if Γ ⊦ A : B.type, or if A is a type alias to B (see the vObj paper at ECOOP 2003 from the Odersky group, especially rule SINGLE-=). That's because the typechecker doesn't even inline a = b to respect the phase distinction (and because type inference is too dumb in this context). I imagine that might be similar to singleton kinds one level down, but I've not studied singleton kinds fully yet. –  Blaisorblade Sep 11 '14 at 21:22
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@Blaisorblade, I see, thanks for the explanation. Re singletons: I think they are different, because their semantics actually yields an equivalence relation that is reflexive, symmetric, transitive, congruent, and closed under all beta/eta rules -- which was what I was alluding to with my point 4 (although you can actually explain ML module typing without singletons). –  Andreas Rossberg Sep 11 '14 at 21:42

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