Generally, yes. Oftentimes this is desirable since it allows you to prune away functions that you don't want people to have access to. For instance, giving a user `[Double]`

lets them compute the length and examine it as a linked-list, while `newtype Vector = Vector [Double]`

would let you expose `vectorLength`

if and only if you feel it a good idea.

But that's not the problem at hand. Immediately you want to be able to operate on your `Vector`

type without redefining every useful function you can think of. Fortunately, there are many ways to get past this.

You could define `Vector`

as a `type`

synonym instead of a new concrete type. This lets Haskell transparently interpret `Vector`

as `[Double]`

and use the full complement of list functions automatically

```
type Vector = [Double]
vectorSum :: Vector -> Double
vectorSum = sum
```

You could, though you were trying to avoid it, also just write your own `vectorSum`

directly.

```
vectorSum :: Vector -> Double
vectorSum (Vector list) = sum list
```

Generally, it looks a little different in real code as people tend to abuse record syntax to make an easy "escape hatch" for `Vector`

```
data Vector = Vector { unVector :: [Double] }
vectorSum :: Vector -> Double
vectorSum = sum . unVector
manySums :: [Double]
manySums = map (\v -> sum (unVector v)) makeLotsOfVectors
```

You could define `Vector`

as an instance of `Foldable`

. `Foldable`

is a typeclass and is the primary mechanism by which Haskell achieves polymorphism. In particular, you say that a type `t`

is an instance of `Foldable`

if you can think of it as containing elements in a particular order that can be "smashed" together. That pretty much describes a `Vector`

and a `sum`

, so

```
import Prelude hiding (foldl)
import Data.Foldable (Foldable, foldl, foldMap)
data Vector a = Vector [a] -- note that the type is parametric, this is
-- required for Foldable
foldableSum :: (Foldable t) => t Double -> Double
foldableSum = foldl (+) 0
instance Foldable Vector where
foldMap f (Vector list) = foldMap f list -- it just inherits from the
-- Foldable [] instance
vectorSum :: Vector Double -> Double
vectorSum = foldableSum
```

You can also use a very convenient mechanism of GHC Haskell called `GeneralizedNewtypeDeriving`

to make these tedious instances happen automatically. To do this, we have to take note that `Vector`

is *very* similar to `[]`

---it's actually just a new name for it. That means we can use `newtype`

instead of `data`

.

```
{-# LANGUAGE GeneralizedNewtypeDeriving #-}
newtype Vector a = Vector [a] deriving ( Foldable )
vectorSum :: Vector Double -> Double
vectorSum = foldl (+) 0
```

Funnily enough, there's also an extension to GHC Haskell that lets you derive `Foldable`

even if you don't have a newtype. `GeneralizedNewtypeDeriving`

is more powerful, but for `Foldable`

specifically we don't need to use it.

```
{-# LANGUAGE DeriveFoldable #-}
data Vector a = Vector [a]
vectorSum :: Vector Double -> Double
vectorSum = foldl (+) 0
```

There's also the *very* powerful `vector`

library that others have mentioned which can do all of this and MUCH much more.

`a * b`

gives a`Vector`

, but`sum`

takes a list. You need a converting function, like the`toList`

that jozefg defines. – md2perpe Oct 30 '13 at 22:22