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Assume that I have a type class Vec that implements the theory of, say, vector spaces over the rationals.

class Vec a where
    (+)  :: a -> a -> a
    zero :: a
    -- rest omitted

Now given a natural number n, I can easily construct an instance of Vec whose underlying type is the type of lists of rationals and which implements a vector space of dimension n. We take n = 3 in the following:

newtype RatList3 = RatList3 { list3 :: [Rational] }
instance Vec RatList3 where
    v + w = RatList3 (zipWith (Prelude.+) (list3 v) (list3 w))
    zero  = RatList3 (take 3 (repeat 0))

For another natural number, for example a calculated one, I can write

f :: Int -> Int
f x = x * x -- some complicated function
n :: Int
n = f 2
newtype RatListN = RatListN { listN :: [Rational] }
instance Vec RatListN where
    v + w = RatListN (zipWith (Prelude.+) (listN v) (listN w))
    zero  = RatListN (take n (repeat 0))

Now I have two types, one for vector spaces of dimension 3 and one for vector spaces of dimension n. However, if I want to put my instance declaration of the form instance Vec RatList? in a module where I don't know which n my main program eventually uses, I have a problem as the type RatList? doesn't know which n it belongs to.

To solve the problem, I tried to do something along the following lines:

class HasDim a where
    dim      :: Int

instance (HasDim a, Fractional a) => Vec [a] where
    v + w = ...
    zero  = take dim (repeat (fromRational 0))

-- in the main module
instance HasDim Rational where
    dim = n -- some integer

This doesn't work, of course, because dim in HasDim is independent of the type variable a and in instance (HasDim a) => Vec [a] it is not clear which type's dim to take. I tried to circumvent the first problem by introducing another type:

newtype Dim a = Dim { idim :: Int }

Then I can write

class HasDim a where
    dim      :: Dim a

However, it is not clear to me how to use this in instance (HasDim a) => Vec [a] where. Also my whole "solution" looks rather cumbersome to me, while the posed problem looks simple. (I think it is easy to code this with C++ templates.)


I have excepted ephemient's answer because without the type arithmetic it solved my problem the way I wanted to. Just for information, my final solution is along the following lines:

class Vec a where
    zero :: a
    -- ...

n :: Int
n = 10

newtype RatListN = RatListN [Rational]

instance Vec RatListN where
    zero = RatListN . take n $ repeat 0
    -- ...
share|improve this question
Have you looked at the vector-space package, I think it implements exactly this. – John L Mar 25 '11 at 8:37
@John: I have taken a look at the package you mentioned. I haven't found inside a construction like the one I am looking for. Further, the vector space class above is just for illustration, so I am not looking for a haskell implementation for vector spaces but for a general solution of my problem, namely parametrising instances by values (and not types). – Marc Mar 25 '11 at 15:05
Perhaps there's some value looking at how the REPA library implements shape types: . Is there anything about your problem space requiring the parameterization be by value, rather than specialized types? – Carl Mar 25 '11 at 17:08
up vote 2 down vote accepted

This seems like a case where type arithmetic would get you some of what you want.

data Zero
data Succ a
type One = Succ Zero
type Two = Succ One
type Three = Succ Two
-- ...

class NumericType a where
    toNum :: (Num b) => a -> b
instance NumericType Zero where
    toNum = const 0
instance (NumericType a) => NumericType (Succ a) where
    toNum (Succ a) = toNum a + 1

data RatList a b = RatList { list :: [b] }
instance (NumericType a, Num b) => Vec (RatList a b) where
    zero = RatList . take (toNum (undefined :: a)) $ repeat 0

Now RatList Two Int and RatList Three Int are different types. On the other hand, this does prevent you from instantiating new dimensionalities at runtime…

share|improve this answer
Thanks for your answer. I had also thought about type arithmetic before. However, the n I would like to use is calculated by ordinary Haskell code and I don't want to lift the algorithm on the type level. In any case, your answer is nevertheless helpful to me as you have reminded me of the undefined construct. As soon as I have time to I will check whether the use of this can make my ideas work. – Marc Mar 25 '11 at 18:58

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