I have a polynomial

``````data Poly a = Poly [a]
``````

I would like to be able to do something like `fmap (take 3) polynomial` but I can't since `Poly` isn't really a functor in that the `f` I use in `fmap` can only be of type `[a] -> [b]`, not `a -> b`.

Is there an idiom or way I can express what I want?

EDIT: here is a function which does what I want

``````myMap :: ([a] ->[b]) -> P a -> P b
myMap f (P x) = P (f x)
``````

usage:

``````*Main> myMap (take 3) (P [1..])
P [1,2,3]
``````

You can see from the type sig that it's almost fmap, but not quite. I'm obviously capable of writing the code for `myMap`, but I just want to know if there's another idiom I should be using instead.

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What would you want `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
@leftaroundabout: I've given some example code. – Xodarap Sep 30 '11 at 23:59
As this is not really a canonical operation (how should the typeclass know it's a list and not e.g. an Array), I wouldn't make it any instance at all. I also wouldn't call it "some-`map`" but rather `coeffsTransform` or something like that. – leftaroundabout Oct 1 '11 at 0:17

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
``````
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+1 Great advice! – luqui Oct 1 '11 at 6:32
Thanks, it looks like numeric prelude uses fmap the way you specified. – Xodarap Oct 2 '11 at 14:53

This doesn't work but I thought it was interesting enough to share anyway:

``````{-#LANGUAGE GADTs #-}

data Poly a where
Poly :: [b] -> Poly [b]
``````

We now have a type Poly that's parameterized on `a`, but effectively `a` has to be a list:

``````~% ghci Poly.hs
GHCi, version 6.8.2: http://www.haskell.org/ghc/  :? for help
[1 of 1] Compiling Main             ( Poly.hs, interpreted )
*Main> :k Poly
Poly :: * -> *
*Main> :t Poly
Poly :: [b] -> Poly [b]
*Main> case Poly [1,2,3] of _ -> 0
0
*Main> case Poly 4 of _ -> 0

<interactive>:1:10:
No instance for (Num [b])
arising from the literal `4' at <interactive>:1:10
Possible fix: add an instance declaration for (Num [b])
In the first argument of `Poly', namely `4'
In the scrutinee of a case expression: Poly 4
In the expression: case Poly 4 of _ -> 0
*Main> case Poly True of _ -> 0

<interactive>:1:10:
Couldn't match expected type `[b]' against inferred type `Bool'
In the first argument of `Poly', namely `True'
In the scrutinee of a case expression: Poly True
In the expression: case Poly True of _ -> 0
``````

Now we can try and write an instance of `Functor` for this type:

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

Couldn't match expected type `[b1]' against inferred type `b2'
`b2' is a rigid type variable bound by
the type signature for `fmap' at <no location info>
In the first argument of `Poly', namely `(f x)'
In the expression: Poly (f x)
In the definition of `fmap': fmap f (Poly x) = Poly (f x)
``````

That's not going to work. Interestingly enough, we can't even really write `myMap`:

``````polymap f (Poly x) = Poly (f x)
``````

If we try this we get

``````GADT pattern match in non-rigid context for `Poly'
Tell GHC HQ if you'd like this to unify the context
In the pattern: Poly x
In the definition of `polymap': polymap f (Poly x) = Poly (f x)
``````

Of course we can fix it with a type annotation:

`````` polymap :: ([a] -> [b]) -> Poly [a] -> Poly [b]
``````

But without it, it's a similar problem to what fmap had. Functor just doesn't have anywhere to out this extra context of "I promise always to use lists", and indeed it can't really. You can always say `undefined :: Poly Int` for example. In short, I don't think there's really an idiom that could express this (actually, someone will probably come along with enough ghc extension magic to do it). Certainly not an existing one.

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