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
```

`Typeable`

on a rank-N type (?) but I'm really unsure about that.`ImpredicativeTypes`

in GHC 9.0.1, but I don't think that helps.`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.7more comments