Is it possible to create a Functor instance for sorted binary trees in Haskell?

Imagine we have a `SortBinTree` type constructor defined as, for example,

``````data SortBinTree a = EmptyNode | Node a (SortBinTree a) (SortBinTree a);
``````

It make sense only when `a` is an instance of `Ord` type class, so most functions have `:: (Ord a) =>` in the beginning of their declaration, especially a function for creating such a tree from list. However to teach Haskell, that `SortBinTree` is an instance of `Functor` type class we have to write something like

``````instance Functor SortBinTree where
fmap g tree = ...
``````

The problem here is that we have to deal with `g :: a->b`, where `b` is not necessarily an instance of `Ord` type class. That makes it problematic to write such function, since we can't use inequalities while creating an element of the type `SortBinTree b`.

Is there a standard workaround here? Any way to define `fmap` only for the case `b` is in `Ord` type class?

-

No, there's no way to do this with the `Functor` type class. As you noted, the Prelude gives us¹

``````class Functor f where
fmap :: (a -> b) -> f a -> f b
``````

which provides no way to hang a restriction on the `b`. We can define an `OrdFunctor` class:

``````class OrdFunctor f where
fmapOrd :: (Ord a, Ord b) => (a -> b) -> f a -> f b
``````

This might get annoying if we had lots of different kinds of `Functor`s (`EqFunctor`, `MonoidFunctor`, etc.) But if we turn on `ConstraintKinds` and `TypeFamilies`, we can generalize this to a restricted functor class:

``````{-# LANGUAGE ConstraintKinds, TypeFamilies #-}
import GHC.Exts (Constraint)
import Data.Set (Set)
import qualified Data.Set as S

class RFunctor f where
type RFunctorConstraint f :: * -> Constraint
fmapR :: (RFunctorConstraint f a, RFunctorConstraint f b) => (a -> b) -> f a -> f b

-- Modulo the issues with unusual `Eq` and `Ord` instances, we might have
instance RFunctor Set where
type RFunctorConstraint f = Ord
fmapR = S.map
``````

Or, as jozefg suggested, you could just write your own `treeMap` function and not put it in a type class. Nothing wrong with that.

Note, however, that you should be careful when making `SortBinTree` a functor; the following is not `fmap`. (It is, however, what `deriving (..., Functor)` will produce, so don't use that.)

``````notFmap :: (Ord a, Ord b) => (a -> b) -> SortBinTree a -> SortBinTree b
notFmap f EmptyNode    = EmptyNode
notFmap f (Node x l r) = Node (f x) (notFmap l) (notFmap r)
``````

Why not? Consider `notFmap negate (Node 2 (Node 1 EmptyNode EmptyNode) EmptyNode)`. That will produce the tree `Node (-2) (Node (-1) EmptyNode EmptyNode) EmptyNode)`, which presumably violates your invariants – it's sorted backwards.² So make sure your `fmap` is invariant-preserving. `Data.Set` splits these into `map`, which makes sure the invariants are preserved, and `mapMonotonic`, which requires you to pass in an order-preserving function. This latter function has the simple implementation, à la `notFmap`, but could produce invalid `Set`s if given uncooperative functions.

¹ The `Data.Functor` module also exposes the `(<\$) :: Functor f => a -> f b -> a` type class method, but that's just there in case `fmap . const` has a faster implementation.

² However, `notFmap` is `fmap` from the subcategory of Hask whose objects are types with an `Ord` instance and whose morphisms are order-preserving maps to a subcategory of Hask whose objects are `SortBinTree`s over types with an `Ord` instance. (Modulo some potential concerns about "uncooperative" `Eq`/`Ord` instances like those that mess with `Set` being a `Functor`.)

-
About footnote 2. Yes, it does form a functor from an ordered subcategory of Hask to a subcategory of `SortBinTree` with ordered `a`s. In essence, `Functor` is a proper endofunctor, `F : Hask -> Hask`, but we want a more refined notion of `RestrictedF : exists C <= Hask, D <= Hask, C -> D` which is a functor between subcategories of `Hask`. The reason we don't have this is purely a historical accident as the provides a strict superset of our current `Functor`. –  jozefg Nov 30 '13 at 7:09
@jozefg Ah, thanks. I fixed the easy-to-fix bit from your comment. –  Antal S-Z Nov 30 '13 at 7:30

There are two choices, if your type satisfies the functor laws then the correct trick is

``````{-# LANGUAGE DeriveFunctor #-}
data SortBinTree a = EmptyNode
| Node a (SortBinTree a) (SortBinTree a)
deriving Functor
-- Or a manual instance if you have some invariants that
``````

And make sure that all it's operations demand an `Ord` instance. If someone decides to put the tree in a useless state, then it's their own job to fix it.

However for this to work than you must satisfy the functor laws

`````` fmap id         === id
fmap f . fmap g === fmap (f . g)
``````

So if you remove duplicates at all from your tree, you're going to be in trouble. This is why `Data.Set` being an instance of `Functor` is dubious, it breaks this law.

If you break the laws, then you're simply not a functor. You cannot specify to Haskell that you only want to deal with a subcategory of `Hask`. In this case you should just define a different function

``````treeMap :: (Ord a, Ord b) => (a -> b) -> SortBinTree a -> SortBinTree b
``````

In a category theoretic sense, this is still a functor, just not the one that `Functor` talks about.

-
What is the standard `Set`? Do you mean `Data.Set`? Then it seems, that it is not a member of Haskell's `Functor` type class. If it is, could you, please, point me to some reference? –  fiktor Nov 30 '13 at 6:11
@fiktor Yes, I've edited to make this clear. –  jozefg Nov 30 '13 at 6:12
@jozefg But as fiktor said, `Set` is not a `Functor`, and the lawlessness is exactly why. –  Antal S-Z Nov 30 '13 at 6:19
@AntalS-Z Sorry, I misread the docs, I've updated my answer to be a bit clearer. –  jozefg Nov 30 '13 at 6:24
@fiktor Sorry I missed your comment edit, I've updated to make it clear. –  jozefg Nov 30 '13 at 6:26