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.)

**EDIT**

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
-- ...
```