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I'm trying to run this code in ghci:

http://www.cs.rutgers.edu/~ccshan/prepose/Prepose.hs

This is the code associated with the paper "Functional Pearl: Implicit Configurations"

http://www.cs.rutgers.edu/~ccshan/prepose/prepose.pdf

I'm sure I'm missing some LANGUAGE pragmas... I am getting the following error:

Prepose.hs:39:1: Parse error in pattern: normalize

Also, are there any hackage packages related to this paper?

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3 Answers 3

You can't apply a type signature to a function definition pattern. This is the syntactically correct way to write it:

normalize :: (Modular s a, Integral a) => a -> M s a
normalize a = M (mod a (modulus (__ :: s))) :: M s a

However, that won't work. What you really want is to refer to the type variable s in the function's type signature. This can be done by using the ScopedTypeVariables extension, which requires explicit quantification:

normalize :: forall a s. (Modular s a, Integral a) => a -> M s a
normalize x = M (Mod x (modulus (__ :: s)))

As a suggestion to improve your code I recommend using the tagged library:

import Data.Proxy

modulus :: (Modular s a) => Proxy s -> a

That allows you to get along without ugly placeholder bottoms. Another way to write it is:

modulus :: (Modular s a) => Tagged s a

This also gives you a nice conceptual benefit: You now have two types, Mod for modular values and Tagged for their moduli. You could define the type yourself, too, giving it a nicer name:

newtype Mod     s a = Mod     { residue :: a } 
newtype Modulus s a = Modulus { modulus :: a }

All this aside, if you want to make actual use of this, I recommend what ocharles said: Use the reflection library.

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I can't help with the code problem, but Edward Kmett's `reflection' library is based on that paper.

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This completes the example from the paper using the reflection library. I'm basing this example off the Monoid example in the library source.

data M a s = M a -- Note the phantom comes *after* the concrete

-- In `normalize` we're tying the knot to get the phantom types to align
-- note that reflect :: Reifies s a => forall proxy. proxy s -> a

normalize :: (Reifies s a, Integral a) => a -> M a s
normalize a = b where b = M (mod a (reflect b)) 

instance (Reifies s a, Integral a) => Num (M a s) where
  M a + M b = normalize (a + b)
  ...

withModulus :: Integral a => a -> (forall s. Reifies s a => M a s) -> a
withModulus m ma = reify m (runM . asProxyOf ma)
  where asProxyOf :: f s -> Proxy s -> f s
        asProxyOf a _ = a
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Clever way to write it, although for clarity I prefer an explicit type signature. I also recommend flipping the Mod type. –  ertes Feb 9 '13 at 20:46
    
This is edwardk's method. I think to avoid ScopedTypeVariables. –  J. Abrahamson Feb 9 '13 at 20:48

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