I'm trying to get the hang of type level natural numbers with a simple example of implementing a dot product. I represent the dot product like this:

```
data DotP (n::Nat) = DotP [Int]
deriving Show
```

Now, I can create a monoid instance (where `mappend`

is the actual dot product) for each individual size of the dot product like this:

```
instance Monoid (DotP 0) where
mempty = DotP $ replicate 0 0
mappend (DotP xs) (DotP ys) = DotP $ zipWith (*) xs ys
instance Monoid (DotP 1) where
mempty = DotP $ replicate 1 0
mappend (DotP xs) (DotP ys) = DotP $ zipWith (*) xs ys
instance Monoid (DotP 2) where
mempty = DotP $ replicate 2 0
mappend (DotP xs) (DotP ys) = DotP $ zipWith (*) xs ys
```

But I want to define a much more general instance like this:

```
instance Monoid (DotP n) where
mempty = DotP $ replicate n 0
mappend (DotP xs) (DotP ys) = DotP $ zipWith (*) xs ys
```

I'm not sure how to convert the type's number into a regular number that I can work with inside the mempty function.

Edit: It would also be cool to have a function `dotplength :: (DotP n) -> n`

that ran in time O(1) by just looking up what type it is, rather than having to traverse the whole list.