7

I just looked up the HasResolution typeclass and it has a single method, resolution that is declared as follows:

class HasResolution a where
   ...
   resolution :: p a -> Integer

I don't understand the p in the above declaration. Where does it come from and what does it mean?

  • 2
    It is universally quantified. The signature could be alternatively written resolution :: forall p. p a -> Integer. It means the caller of resolution can pick any p they wish, as long as a has a HasResolution instance. – Alexis King Feb 15 '18 at 0:40
  • 4
    p is what's often called a proxy type. The argument to resolution serves only to fix a to a particular type, indicating which HasResolution instance you want. The old-fashioned way to do this is to just take an a, but using a proxy is much clearer once you understand the idiom. p will often, but not always, be Data.Proxy.Proxy, an extremely boring type: data Proxy a = Proxy. – dfeuer Feb 15 '18 at 0:53
13

It's just a proxy.

If you had

class HasResolution a where
  resolution :: Integer

you'd get yelled at because there is no way for the compiler to ever infer which instance of HasResolution you want when you call resolution. Specifically, resolution :: HasResolution a => Integer, where a appears on the left but not on the right, so you can never infer a.

So, one solution was

class HasResolution a where
  resolution :: a -> Integer

and resolution's documentation would say that it is not meant to inspect the a; it is just meant to let the compiler figure out which instance to pick. You'd use it as resolution (undefined :: a). Then, another solution emerged:

data Proxy a = Proxy

class HasResolution a where
  resolution :: Proxy a -> Integer

Proxy gives no information to resolution; it exists, again, only for the compiler to infer what a is. It's better than the original in that resolution really can't inspect its argument, so the Integer is really associated with the type and not with the argument to resolution. It's slightly worse (or better, depending on who you ask) in that usage is the more verbose resolution (Proxy :: Proxy a) (you can't just use undefined because the implementation may pattern match on Proxy).

This evolved into

class HasResolution a where
  resolution :: p a -> Integer

This means that you aren't tied down to just Proxy, and it means that if you have, e.g., a [a] lying in scope, you can pass it to resolution without incurring massive verbosity, while maintaining compatibility with code that just used Proxy. Again, resolution's first argument is for the compiler's use only. It means nothing to the actual implementation. You simply use it to select the instance of HasResolution you want.

Proxy eventually became so common that GHC.Exts got a new member: Proxy#. Proxy# has no runtime representation, so it incurs no performance penalty, unlike Proxy (or the above polymorphic p trick). Proxy#, however, suffers from the fact that its kind is forall k. k -> TYPE (TupleRep '[]). By not living in * like all the other "well-behaved" types, it cannot participate in the polymorphic p trick.

class HasResolution a where
  resolution :: Proxy# a -> Integer

The first solution is rather dated, though you see examples sometimes. The second and third are rather common, and the fourth was superseded pretty quickly by the most recent solution, which is to enable -XTypeApplications -XAllowAmbiguousTypes and just have

class HasResolution a where
  resolution :: Integer

again. -XAllowAmbiguousTypes staves off the error and -XTypeApplications lets you specify a at the call site as resolution @a. This can't be used in code that needs to be a certain degree of backwards compatible, but you see it more in libraries that require new GHC anyway and can afford to not have compatibility.

  • Thanks, @HTNW. This is an element of the language I had not seen before and its history is interesting, too. – melston Feb 15 '18 at 1:20
  • I think it's worth a small note that there is a second advantage to using a type variable for the proxy type - it prevents pattern matching. You can still pattern match on Proxy, even if it's a bit silly. But there's no pattern at all that can be used on a polymorphic type. Given this, the user of the code can look at the type and determine immediately that the argument is only be used to pass a type - it can't do anything else. – Carl Feb 17 '18 at 1:09
  • @Carl I don't think that makes much of a difference. You still can't pass undefined as argument for the polymorphic version, because seq (or, as I sometimes call it, pattern matching without the pattern matching) can still ruin your day. Granted, using seq on such an argument is absurd, but.... – HTNW Jan 13 '19 at 21:56

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