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I'd like to express a Data type with a field sType to be anything that is an instance of SType (from zeromq-haskell). SType is the zeromq socket type. In the zeromq-haskell source one example is this:

data Pair = Pair
instance SType Pair where
    zmqSocketType = const pair

Here's what I've got now

data SocketOpts = SocketOpts
 { end :: SocketEnd
 , sType :: SType st => st
 }

But when I use it like so socket ctx $ sType so I get:

Ambiguous type variable `a0' in the constraint:
(SType a0) arising from a use of `sType'

(socket's signature is socket :: SType a => Context -> a -> IO (Socket a)

When I try and create a SocketOpts in ghci I get:

let so = SocketOpts (Bind "some") Pull

<interactive>:1:35:
Could not deduce (st ~ Pull)
from the context (SType st)
  bound by a type expected by the context: SType st => st
  at <interactive>:1:10-38
  `st' is a rigid type variable bound by
       a type expected by the context: SType st => st
       at <interactive>:1:10
In the second argument of `SocketOpts', namely `Pull'
In the expression: SocketOpts (Bind "some") Pull
In an equation for `so': so = SocketOpts (Bind "some") Pull

What I understand from this is that SType is more general that what I've asked for (Pull, which is an instance of SType). How should I express what I want here?


Edit

This:

data SocketOpts st = SocketOpts
     { end :: SocketEnd
     , sType :: st
     }

being used in conjunction with:

zmqSource :: (ResourceIO m, SType st) => Context -> SocketOpts st -> Source m a
zmqSource ctx so = sourceIO
          mkSocket
          recvSock
          (\x -> undefined)
          where
              recvSock = undefined
              mkSocket = socket ctx $ sType so

Seems to be working, but I'll leave the question open in case there's a more elegant way to do this?


Edit 2

Guys, thanks very much for your answers. Based on your feedback I've now got the following (I won't post it here as it's easier to read on github)

https://github.com/boothead/zeromq-conduit/blob/master/Data/Conduit/ZMQ.hs

I've used a GADT (I think) to try and express the difference between setting up a normal socket and a Sub socket, but there's a wrinkle at the moment: I could use the SockOpts type to set up a sub socket it which case subscribe wouldn't be called and it wouldn't work:

SockOpts (Connect "tcp://127.0.0.1:9999") Sub  -- This would be bad

Is there anyway to get the type system to disallow this? Something like what I've got in the angle brackets?

SockOpts :: (SType st, <not SubsType st>) => SocketEnd -> st -> SocketOpts st
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2 Answers 2

I'd like to express a Data type with a field sType to be anything that is an instance of SType (from zeromq-haskell).

There's some ambiguity in what you mean by "anything" here.

Do you want to simply create SocketOpts values with a parametric type, and enforce the requirement for a SType instance when the SocketOpts value is used? Then a normal parameterized type is fine, as in your edit.

Do you want to ensure that any SocketOpts value will have an instance for the specified type, enforcing the constraint when the value is created rather than used? Then a GADT definition will work:

data SocketOpts st where
    SocketOpts :: (SType st) => SocketEnd -> st -> SocketOpts st

Do you want to use any instance to create a SocketOpts value, without parameterizing it by the specific type? That's an existential type will work:

data SocketOpts where
    SocketOpts :: (SType st) => SocketEnd -> st -> SocketOpts

...but be warned that existentials can be awkward, and that all you can do with something like this is pattern match on SocketOpts and then use the methods defined for SType. Knowledge of the specific type is lost.

Or, finally, do you want to select any instance when using a SocketOpts value, giving up the ability to create one with a specific type? That's a universally quantified type:

data SocketOpts where
    SocketOpts :: SocketEnd -> (forall st. SType st => st) -> SocketOpts

...which I believe is what your original version was. In this case, you can't use a monomorphic value to create a SocketOpts value, only a polymorphic value--think of the difference between the Int value 11 and the numeric literal 11 :: Num a => a. Be warned that in this case, GHC still needs to know which instance to select, so when using the contents of a SocketOpts you'll need a specific type before using any SType methods.

The errors you saw both came from the above warnings about universally quantified types: The "ambiguous type" because you applied something that needed to pick an SType instance without giving GHC enough information to do so, and the "could not deduce" error because you tried to construct a SocketOpts with a monomorphic value.

I suspect that the existential version is what you were trying for. However, unless you have a compelling reason to mix different instances of SType, the parametric GADT is probably the better choice.

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Did you tr GADTs?

data SocketOpts where
    SocketOpts :: SType st => SocketEnd -> st -> SocketOpts

You can also try GADTs with existentials:

data SocketOpts where
    SocketOpts :: SocketEnd -> (forall st . SType st => st) -> SocketOpts
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