20
Prelude> let myprint = putStrLn . show
Prelude> :t myprint
myprint :: () -> IO ()

OK, nothing too unusual here. Just GHCi type defaulting rules, I guess...

Prelude> let myprint = (putStrLn . show) :: Show x => x -> IO ()
Prelude> :t myprint
myprint :: () -> IO ()

What sorcery is this?? You're point-blank ignoring my type declaration?! O_O

Is there some way I can convince GHCi to do what I actually intended?

  • 1
    Wild guess: the dreaded monomorphism restriction. – jubobs Mar 22 '15 at 10:48
  • @Jubobs That would be my guess as well - except that doesn't an explicit type signature disable that? – MathematicalOrchid Mar 22 '15 at 10:49
  • 1
    Are you using an old version of GHC? I'm on 7.8.3 and I get the type signature you'd generally expect (Show a => a -> IO ()), even without using a signature expression. Getting () -> IO () seems like an actual problem with GHC. – MasterMastic Mar 22 '15 at 16:50
  • 1
    The monomorphism restriction was turned off by default in GHCi 7.8.1 (for GHCi only), see downloads.haskell.org/~ghc/7.8.1/docs/html/users_guide/…. – MvanGeest Mar 22 '15 at 23:27
  • 1
    @MvanGeest Is it because of the number of SO questions? ;-) – MathematicalOrchid Mar 23 '15 at 11:06
17

We can do the following, with monomorphism restriction on:

>let myprint :: Show x => x -> IO (); myprint = putStrLn . show
>:t myprint
myprint :: Show x => x -> IO ()

This is not the same as let myprint = putStrLn . show :: Show x => x -> IO (). In the former case we have a binding with a type signature, in the latter case we a have a let binding with a type annotation inside the right hand side. Monomorphism checks top-level type signatures, but not local annotations.

  • 1
    I always recommend the :set +m flag, which lets you do multi-line input in GHCi. It's really handy for instances like this, although I wish GHCi had smart indentation with multi-line input like IPython (project Jupyter is working on fixing this, though) – bheklilr Mar 22 '15 at 16:59
21

Adding a type annotation to an expression as in

e :: type

makes the compiler check that e has that type, as well as use that type to drive type variables instantiation and instance selection. However, if the type is polymorphic it can still be instantiated later on. Consider e.g.

(id :: a -> a) "hello"

Above, a will be instantiated to String, despite my annotation. Further,

foo :: Int -> Int
foo = (id :: a -> a)

will make a to be instantiated to Int later on. The above id annotation does not give any information to GHC: it already knows that id has that type. We could remove it without affecting the type checking at all. That is, the expressions id and id :: a->a are not only dynamically equivalent, but also statically such.

Similarly, the expressions

putStrLn . show

and

(putStrLn . show) :: Show x => x -> IO ()

are statically equivalent: we are just annotating the code with the type GHC can infer. In other words, we are not providing any information to GHC it does not already know.

After the annotation is type checked, GHC can then instantiate x further. The monomorphism restriction does that in your example. To prevent that, use an annotation for the binding you are introducing, not for the expression:

myprint :: Show x => x -> IO ()
myprint = (putStrLn . show)

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