If you want to use GHC's lexically scoped type variables, you also have to use explicit universal quantification. That is, you have to add forall declarations to your functions' type signatures:

{-# LANGUAGE ExplicitForAll, ScopedTypeVariables #-}

f :: forall a . [a] -> [a]      -- The `forall` is required here ...
f (x:xs) = xs ++ [x :: a]       -- ... to relate this `a` to the ones above.

Does this actually have anything to do with quantification, or did the extension writers just coopt the forall keyword as a convenient marker for where the new, wider scoping applies?

In other words, why can't we leave out the forall as usual? Wouldn't it be clear that type variables in annotations within the function body refer to variables of the same name in the function signature? Or would the typing be somehow problematic or ambiguous?

  • 1
    I submitted my own answer below, but I wonder whether there are additional subtleties I haven't considered. ... – pash Apr 4 '13 at 1:05
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    Since Haskell-98 doesn't have scoped it's a compromise to only have the scoped variables introduced by forall. That way old code still works when turning on ScopedTypeVariables. (Arguably, Haskell should always have had scoped type variables.) – augustss Apr 4 '13 at 6:53
up vote 25 down vote accepted

Yes, the quantifier is meaningful and is required for the types to make sense.

First note that there's really no such thing as an "unquantified" type signature in Haskell. Signatures without a forall are really implicitly quantified. This code ...

f :: [a] -> [a]                         -- No `forall` here ...
f (x:xs) = xs ++ [x :: a]               -- ... or here.

... really means this:

f :: forall a . [a] -> [a]              -- With a `forall` here ...
f (x:xs) = xs ++ [x :: forall a . a]    -- ... and another one here.

So let's figure out what this says. The important thing is to notice that the type variables named a in the signatures for f and for x are bound by separate quantifiers. This means that they are different variables, despite sharing a name. So the above code is equivalent to this:

f :: forall a . [a] -> [a]
f (x:xs) = xs ++ [x :: forall b . b]    -- I've changed `a` to `b`

With the names differentiated, it's now clear not only that the type variables in the signatures for f and x are unrelated, but that the signature for x claims that x can have any type. But this is impossible, since x must have the particular type bound to a when f is applied to an argument. And indeed the type-checker rejects this code.

On the other hand, with a single forall in the signature for f ...

f :: forall a . [a] -> [a]              -- A `forall` here ...
f (x:xs) = xs ++ [x :: a]               -- ... but not here.

... the a in the signature on x is bound by the quantifier at the beginning of f's type signature, so this a represents the same type as the type represented by the variables called a in f's signature.

  • Apparently according to downloads.haskell.org/~ghc/7.8.2/docs/html/users_guide/… it's possible to do this kind of scoping in expressions and in pattern type signatures as well. but I don't quite understand pattern type signatures. – CMCDragonkai Apr 1 '15 at 15:12
  • What happens if you enable ScopedTypeVariables but don't enable ExplicitForAll? Then you can't write forall. Then what is the effect of ScopedTypeVariables? In a snippet that I wrote, ScopedTypeVariables allowed one to declare that a particular value was of Char type inside a function body. Without ScopedTypeVariables, it did not allow me to write it. Which is strange since I'm not trying to unify any type variables. – CMCDragonkai Apr 1 '15 at 15:21
  • @CMCDragonkai, -XScopedTypeVariables is basically useless without -XExplicitForAll. Half the time I forget to set the latter and end up tearing my hair out for five minutes before I realize that's the problem. – pash Jan 27 '17 at 5:48

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