I would like to manipulate matrices (full or sparse) efficiently with haskell's vector library.

Here is a matrix type

```
import qualified Data.Vector.Unboxed as U
import qualified Data.Vector as V
data Link a = Full (V.Vector (U.Vector a))
| Sparse (V.Vector (U.Vector (Int,a)))
type Vector a = U.Vector a
```

As you can see, the matrix is a vector of unboxed vectors. Now, I would like to do a dot product between a vector and a matrix. It is fairly simple to do by combining a sum, zip and map.

But if I do that, because I'm mapping through the rows of the matrix, the result is a boxed vector, even though it could be unboxed.

```
propagateS output (Field src) (Full weights) = V.map (sum out) weights
where out = U.map output src
sum s w = U.sum $ zipWithFull (*) w s
propagateS output (Field src) (Sparse weights) = V.map (sum out) weights
where out = U.map output src
sum s w = U.sum $ zipWithSparse (*) w s
zipWithFull = U.zipWith
zipWithSparse f x y = U.map f' x
where f' (i,v) = f v (y U.! i)
```

How can I get an unboxed vector as a result efficiently ?