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Upon trying to use Data.Has, I've been writing code like the following:

data Name = Name; type instance TypeOf Name = Text
type NameRecord = FieldOf Name;

I've found:

instance I NameRecord where
  ...

Throws a compile error, namely:

Illegal type synonym family application in instance

Whereas:

instance (NameRecord ~ a) => I a where
  ...

Compiles fine.

I believe the error is related to this ticket in GHC, marked as invalid.

The response to the ticket says:

I am not sure what you are suggesting. We cannot automatically transform

instance C (Fam Int) -- (1)

into

instance (Fam Int ~ famint) => C famint -- (2)

This works if there is only one instance, but as soon as there are two such instances, they always overlap.

Maybe you are suggesting that we should do it anyway and programmers should just take the implicit transformation into account. I don't think that this is a good idea. It's confusing for very little benefit (as you can always write the transformed instance yourself with little effort).

Can someone elaborate on this explanation, perhaps with some sample code where the (1) fails but (2) does not, and why?

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1 Answer 1

up vote 4 down vote accepted

A case where (1) fails but (2) does not is trivial; because type synonyms (type ExampleOfATypeSynonym = ...) are not allowed in instance declarations, but they are allowed in constraints, any situation where you have only one instance like this:

-- (1)
class Foo a
type Bla = ()
instance Foo Bla

... can be transformed into:

-- (2)
class Foo a
type Bla = ()
instance (a ~ Bla) => Foo a

The only reason why (1) fails is because type synonyms are not allowed in instance declarations, and that's because type synonyms are like type functions: they provide a one-way mapping from a type name to a type name, so if you have a type B = A and an instance Foo B, it is non-obvious that an instance of Foo A is created instead. The rule exists so that you have to write instance Foo A instead to make it clear that that is the type that actually gets the instance.

The use of type families is irrelevant in this context, because the problem is rather that you're using a type synonym, the NameRecord type. You have to also keep in mind that if the type synonym is removed and replaced by FieldOf Name directly, the compile will still fail; that is because a "type family" is just an enhanced version of type synonyms, so FieldOf Name is also a "type synonym" for Name :> Text in this context. You have to use a data family and a data instance instead to get a "bidirectional" association.

More information about data families can be found in the GHC documentation.


I think you mean "... where (2) fails but (1) does not..."

Let's imagine that we have a type class like so:

class Foo a where
  foo :: a

Now, you can write instances like so:

 instance Foo Int where
   foo = 0

 instance Foo Float where
   foo = 0

 main :: IO ()
 main = print (foo :: Float)

This works as one would expect. However, if you transform the code into this:

{-# LANGUAGE FlexibleInstances, TypeFamilies #-}
class Foo a where
  foo :: a

instance (a ~ Int) => Foo a where
  foo = 0

instance (a ~ Float) => Foo a where
  foo = 0

main :: IO ()
main = print (foo :: Float)

It doesn't compile; it displays the error:

test.hs:5:10:
    Duplicate instance declarations:
      instance a ~ Int => Foo a -- Defined at test.hs:5:10-27
      instance a ~ Float => Foo a -- Defined at test.hs:8:10-29

So, this is the example you hopefully were looking for. Now, this only happens if there is more than one instance of Foo that uses this trick. Why is that?

When GHC resolves type classes, it only looks at the instance declaration head; i.e. it ignores everything before the =>. When it has chosen an instance, it "commits" to it, and checks the constraints before the => to see whether they are true. So, at first it sees two instances:

instance Foo a where ...
instance Foo a where ...

It is clearly impossible to decide which instance to use based on this information alone.

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Out of interest, do you happen to know if GHC's method of resolving type classes is an explicit design decision? And if so, the reason for it? (Or maybe the alternative is just too complicated to implement cleanly?) –  dbaupp May 7 '12 at 11:59
3  
The reason for it is that the Haskell Report requires it to behave like this. The reason for that is that if it didn't behave like this, there'd have to be an algorithm that gave a heuristic for "how well a type fits a constraint;" you'd have to argue "Yeah, this type fits this class instance, but that other instance fits much better because {less constraints, shorter reduction distance, ...}." It might be possible to develop such a heuristic, but it would break the Open World Assumption which is a key concept when it comes to type classes. –  dflemstr May 7 '12 at 12:11
    
Imagine instance String ~ a => Foo a and instance a ~ [b] => Foo a. That's an example of instances where you'd need an algorithm to resolve Foo [Char]. –  dflemstr May 7 '12 at 12:14
    
Ah, interesting, thanks! So the reason is basically: it violates OWA and so breaks some of the nice properties of type classes. (On a slightly tangential note, CSS has various rules to explicitly work out which selectors are "more important" and override others, so such a heuristic is possible (and useable).) –  dbaupp May 7 '12 at 13:21
    
@dflemstr: No, I think I meant (1) fails but (2) does not. Did you view the GHC ticket I linked to in the article, and can you refer to it in your answer? –  Clinton May 7 '12 at 14:03

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