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Here are a few simple functions:

f1 :: () -> ()
f1 () = ()

f2 :: a -> a
f2 a = a

f3 :: a -> (a, a)
f3 a = (a, a)

f4 :: (a, b) -> a
f4 (a, b) = a

All of f1, f2, and f3 are able to accept () as an input. On the other hand, of course, f4 can't accept (); f4 () is a type error.

Is it possible to type-theoretically characterize what f1, f2, and f3 have in common? Specifically, is it possible to define an acceptsUnit function, such that acceptsUnit f1, acceptsUnit f2, and acceptsUnit f3 are well-typed, but acceptsUnit f4 is a type error -- and which has no other effect?

The following does part of the job, but monomorphizes its input (in Haskell, and I gather in Hindley-Milner), and hence has an effect beyond simply asserting that its input can accept ():

acceptsUnit :: (() -> a) -> (() -> a)
acceptsUnit = id

-- acceptsUnit f4     ~> error 😊
-- acceptsUnit f3 'a' ~> error ☹️

The same monomorphizing, of course, happens in the following. In this case, the annotated type of acceptsUnit' is its principal type.

acceptsUnit' :: (() -> a) -> (() -> a)
acceptsUnit' f = let x = f () in f
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    I don't think this is possible, though I'm not sure I could prove it. Why do you want this? The more context you can give us, the more likely we are to be able to propose alternatives. Jul 27, 2021 at 20:42
  • I don't think you can get a satisfactory answer. In Hindley-Milner, when you take a function as input, it becomes monomorphic (roughly speaking). Haskell goes a little beyond that, but I don't think it helps much also because we don't really have impredicative types as in System F. There might be some partial answer using something like Typeable on a rank-N type (?) but I'm really unsure about that.
    – chi
    Jul 27, 2021 at 20:46
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    @SimonC Why does that determination need to be done from within the language? Why isn't making that determination in the metalanguage good enough? Also: I think it would be helpful to have even more context. Are you trying to sell cat food or go to the moon? What program are you writing to enable that? What is the operation that needs this wacky type that must exist for the program to exist, and why? Jul 27, 2021 at 20:56
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    @chi we have ImpredicativeTypes in GHC 9.0.1, but I don't think that helps.
    – Noughtmare
    Jul 27, 2021 at 21:25
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    "In the metatheory" looks like adding a new kind of term to your DSL's syntax, say, takes_unit, with a typing rule that looks like "if Γ ⊢ e : t and Γ ⊢ e : () -> t' then Γ ⊢ takes_unit e : t". (Can't render premises above conclusion in markdown, hopefully you can understand what I intend here.) Of course you'd have to think about whether there's an algorithm that corresponds with that modified type system, but it seems pretty likely to me that there would be one. Jul 28, 2021 at 2:38

1 Answer 1

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It's easy to type-theoretically characterize what f1, f2, and f3 but not f4 have in common. In the language of Hindley-Milner, the first three have polytypes that can be specialized to a polytype of the form:

forall a1...an. () -> tau

for n >= 0 and tau an arbitrary monotype. The fourth one can't.

Can you write a function that accepts the first three as an argument but rejects the fourth? Well, it depends on the type system you're using and the latitude you have to structure your function. In the usual Hindley-Milner and/or standard Haskell type system, if you have latitude to pass two copies of your candidate function to the acceptance function, the following will work:

acceptsUnit :: (() -> a) -> (b -> c) -> (b -> c)
acceptsUnit = flip const

f1 :: () -> ()
f1 () = ()

f2 :: a -> a
f2 a = a

f3 :: a -> (a, a)
f3 a = (a, a)

f4 :: (a, b) -> a
f4 (a, b) = a

main = do
  print $ acceptsUnit f1 f1 ()
  print $ acceptsUnit f2 f2 10
  print $ acceptsUnit f3 f3 10
  -- print $ acceptsUnit f4 f4  -- type error

That's probably the best you'll be able to do with standard Haskell (and probably the best you can do with Haskell plus GHC type system extensions, or someone would have found something by now).

If you're free to define your own typing system with its own typing rules, then the sky is the limit.

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