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While reading the QuickCheck Manual, I came across the following example:

prop_RevRev xs = reverse (reverse xs) == xs
  where types = xs::[Int]

The manual goes on to say:

Properties must have monomorphic types. `Polymorphic' properties, such as the one above, must be restricted to a particular type to be used for testing. It is convenient to do so by stating the types of one or more arguments in a

where types = (x1 :: t1, x2 :: t2, ...)

clause. Note that types is not a keyword; this is just a local declaration which provides a convenient place to restrict the types of x1, x2 etc.

I have never seen such a trick in Haskell before. Here's what I'm really having problems with:

  1. Why does this syntax for type declarations even exist? What can it do for me that the following couldn't?

    prop_RevRev :: [Int] -> Bool
    prop_RevRev xs = reverse (reverse xs) == xs
    
  2. Does this use of where constitute 'special' syntax for type declarations? Or is it consistent and logical (and if so, how?)?

  3. Is this usage standard or conventional Haskell?

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2 Answers 2

up vote 11 down vote accepted

where is not special syntax for type declarations. For example, this works:

prop_RevRev :: [Int] -> Bool
prop_RevRev xs = ys == xs
  where ys = reverse (reverse xs)

and so does this:

prop_RevRev xs = ys == xs
  where ys = reverse (reverse xs)
        ys :: [Int]

The advantage of where type = (xs :: [Int]) over prop_RevRev :: [Int] -> Bool is that in the latter case you have to specify the return type, while in the former case the compiler can infer it for you. This would matter if you had a non-Boolean property, for example:

prop_positiveSum xs = 0 < length xs && all (0 <) xs ==> 0 < sum xs
  where types = (xs :: [Int])
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I'd been wondering about this for a long time as well. Thanks. –  sykora Oct 3 '11 at 13:57
1  
@MattFenwick: You can add a type annotation to any sub-expression at any level, so this trick is useful when you want to just fill in the detail the compiler was unable to infer, without having to specify the full type signature. However, they still have to be consistent, e.g. (x :: Float) + (x :: Int) will result in a type error. –  hammar Oct 3 '11 at 14:15
    
so basically the type or types is a dummy variable that is not used; only to facilitate the type guard on the other expression –  newacct Oct 3 '11 at 19:13
    
@newacct: Yes, although you can't use type as that's a reserved keyword :) –  hammar Oct 3 '11 at 22:44
    
@dave4420 I'd like to accept your answer, but I'm still not sure what the answer is to the third sub-question. –  Matt Fenwick Oct 6 '11 at 13:24

It is no special syntax, and sometime you just need it, like in the following case:

foo :: String -> String
foo s = show (read s)

As it stands, this cannot be typed because the type of the value read s cannot be identified. All that is known is that it must be an instance of Show and of Read. But this type does not appear in the type signature at all, so it is also not possible to leave it at that and infer a constrained type. (There is just no type variable that could be constrained.)

It is interesting to note that what read s does depends entirely on the type signature one gives to read s, for example:

read "Just True" :: (Maybe Bool)

will succeed, while

read "Just True" :: (Maybe Int)

will not.

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