Since you allow any function to be applied to the list of coefficients, your data type only really serves two purposes.

- You get extra type safety, since a
`Poly [a]`

is distinct from `[a]`

.
- You can define different instances.

If you don't need either of these, you might as well use a type alias.

```
type Poly a = [a]
```

Now you can apply any list function on it directly.

If, on the other hand, you want a distinct type, you might find the `newtype`

package useful. For example, given this instance.

```
instance Newtype (Poly a) [a] where
pack = Poly
unpack (Poly x) = x
```

You can now write things like

```
foo :: Poly a -> Poly a
foo = over Poly (take 3)
```

although this might be overkill if your `myMap`

is sufficient for your purposes.

All this aside, I think that exposing the representation of your data type in such a way might not be a good idea in the first place, as it can leave the rest of your code intimately dependent on this representation.

This makes it harder to change to a different representation at a later time. For example, you might want to change to a sparse representation like

```
data Poly a = Poly [(a, Int)]
```

where the `Int`

is the power of the term. I suggest thinking about what operations you want to expose, and limiting yourself to those. For example, it might make sense to have a `Functor`

instance that works on a per-element basis.

```
instance Functor Poly where
fmap f (Poly x) = Poly $ map f x
```

Now, the change to the sparse representation leaves client code unchanged. Only the instance (and the handful of other functions that depend on the representation) will have to change.

```
instance Functor Poly where
fmap f (Poly x) = Poly $ map (first f) x
```

`fmap (take 3) polynomial`

to do? It doesn't make sense to me at all. —`polynomial`

is simply a`polynomial :: Poly CoeffType`

`polynomial = Poly [a₁, a₂ ..]`

? – leftaroundabout Sep 30 '11 at 23:15`map`

" but rather`coeffsTransform`

or something like that. – leftaroundabout Oct 1 '11 at 0:17