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I have a type that looks like this:

newtype Canonical Int = Canonical Int

and a function

canonicalize :: Int  -> Canonical  Int
canonicalize =  Canonical . (`mod` 10)  -- or whatever

(The Canonical type may not be important, it just serves to distinguish "raw" values from "canonicalized" values.)

I'd like to create some machinery so that I can canonicalize the results of function applications.

For example: (Edit: fixed bogus definitions)

cmap :: (b->Int) -> (Canonical b) -> (Canonical Int)
cmap f (Canonical x) = canonicalize $ f x

cmap2 :: (b->c->Int) -> (Canonical b) -> (Canonical c) -> (Canonical Int)
cmap2 f (Canonical x) (Canonical y) = canonicalize $ f x y

That's superficially similar to Functor and Applicative, but it isn't quite, because it's too specialized: I can't actually compose functions (as required by the homomorphism laws for Functor/Applicative) unless 'b' is Int.

My goal is to use existing library functions/combinators, instead of writing my own variants like cmap, cmap2. Is that possible? Is there a different typeclass, or a different way to structure Canonical type, to enable my goal?

I've tried other structures, like

newtype Canonical a = Canonical { value :: a, canonicalizer :: a -> a }

but that hits the same non-composability problem, because I can't translate one canonicalizer to another (I just want to use the canonicalizer of the result type, which is always Int (or Integral a)

And I can't force "specialization-only" like so, this isn't valid Haskell:

instance (Functor Int) (Canonical Int) 

(and similar variations)

I also tried

newtype (Integral a) => Canonical a = Canonical a -- -XDatatypeContexts
instance (Integral a) => Functor Canonical where
  fmap f (Canonical x) = canonicalize  $ f x

but GHC says that DatatypeContexts is deprecated, and a bad idea, and more severely, I get:

 `Could not deduce (Integral a1) arising from a use of 'C'   
 from the context (Integral a)
 bound by the instance declaration
 [...] fmap :: (a1 -> b) -> (C a1 -> C b)

which I think is saying that the constraint Integral a can't actually be used to constrain fmap to (Integral -> Integral) the way I wish, which is sort of obvious (since fmap has two type variables) :-(

And of course this isn't valid Haskell either

instance (Integer a) => Functor Canonical where

Is there a similar typeclass I could use, or am I wrong to try to use a typeclass at all for this functionality of "implicitly canonicalize the results of function calls"?

share|improve this question
Let's step back a bit. Are you sure the type signature cmap2 :: (b->c->Int) -> (Canonical Int) -> (Canonical Int) describes what you want? Because it looks pretty senseless. It also has nothing to do with Functor. Here's an example of a valid functor signature: (Int -> Int) -> Canonical Int -> Canonical Int. –  Nikita Volkov Dec 26 '13 at 0:18
My mistake, I made errors when simplifiying my more complicated type down to something to ask on SO. I've (tried to) improve the definitions, made an edit. –  misterbee Dec 26 '13 at 5:55

3 Answers 3

up vote 5 down vote accepted

I think what you're trying to achieve is available in the mono-traversable package, and in this case the MonoFunctor typeclass.

share|improve this answer
Oh, this works :-| google.com/search?q=monomorphic+functor+haskell –  misterbee Dec 26 '13 at 18:27
Ah, the magic of mono-traversable is its use of 'type family'. With that, a concrete type Text can be viewed as a Foo Char. Interesting, in omap, Char is then used as Element Text, and the signature is (Element m -> Element m) -> m -> m which is not exactly (a -> a) -> m a -> m a. In some sense, m is seen as UnElement (Element m), to make the type signature match fmap. –  misterbee Dec 26 '13 at 21:30
Need to get mono-traversable into fpcomplete ;-). haddocks.fpcomplete.com/fp/7.4.2/20130922-179 –  misterbee Dec 27 '13 at 4:57
It's available in the unstable package set. At the time that we created the September stable snapshot, mono-traversable wasn't stabilized enough. –  Michael Snoyman Dec 27 '13 at 10:19
Ah, yesterday I couldn't find the hamburger menu to access settings in the FPComplete IDE. Switching to unstable works great! fpcomplete.com/school/using-fphc/… –  misterbee Dec 27 '13 at 16:29

from your type signatures this looks a bit like the Identity monad

newtype Identity a = Identity a

instance Monad Identity where
         return x = Identity x
         f >>= (Identity x)  = Identity (f x)

then in your example canonicalize = return and cmap f x = f >>= (return x)

hope this is helpful


The other structure that comes to my mind is Automorphisms (I studied math)

so if you have

data Automorphisms a = AMorph (a -> a)

then you can have a Monoid

instance Monoid Automorphism where
         mempty = id
         mappend = (.)
         mconcat = foldr1 (.)

(I hope foldr1 is the right one)

share|improve this answer
ps.: this code is not tested –  epsilonhalbe Dec 26 '13 at 0:26
I agree it looks a bit like Identity, but I think the same type-checking problem applies if I try to put canonicalize into the left-hand side of the definition. Identity and Canonical are parametric-polymorphic, but canonicalize is ad-hoc polymorphic at best. –  misterbee Dec 26 '13 at 0:40
can you explain that a bit - I think I am outsmarted at the moment (the ad-hoc polymorphic makes my head mushy) - maybe tomorrow I'll grok it –  epsilonhalbe Dec 26 '13 at 0:44
I mean that Identity works for any type a->a, but canonicalize is implemented as Int -> Int –  misterbee Dec 26 '13 at 0:45
Your Automorphisms is Endo from Data.Monoid –  Roman Cheplyaka Dec 26 '13 at 1:29

Your cmap is actually implementable via fmap. It's a bit strange at first, but (->) is just a datatype itself, actually equivalent to Reader. We can fmap over the return result.

cmap :: (a -> Int) -> a -> (Canonical Int)
cmap = fmap Can

You can create the other cmap variants using the same pattern

cmap2 :: (a -> b -> Int) -> a -> b -> (Canonical Int)
cmap2 = fmap (fmap Can)

cmap3 :: (a -> b -> c -> Int) -> a -> b -> c -> (Canonical Int)
cmap3 = fmap (fmap (fmap Can))

Now this usually is a bit of a strange thing to see in code, it's more common to see the less general form of fmap on (->)

instance Functor (r ->) where
  fmap = (.)

cmap :: (a -> Int) -> a -> (Canonical Int)
cmap = (.) Can
cmap f = Can . f

cmap2 :: (a -> b -> Int) -> a -> b -> (Canonical Int)
cmap2   = (.) ((.) Can)
cmap2   = (.) (Can .)
cmap2 f = (Can .) . f

cmap3 :: (a -> b -> c -> Int) -> a -> b -> c -> (Canonical Int)
cmap3   = (.) ((.) ((.) Can))
cmap3   = (.) ((.) (Can .))
cmap3   = (.) ((Can .) .)
cmap3 f = ((Can .) .) . f

Obviously this gets a little ridiculous in the higher order combinators. Pointfree style might not be the best choice.

share|improve this answer
That looks encouraging, but note that I am not simply trying to tag a value with the Canonical constructor. I am also trying to add a transformation : canonicalize = Canonical . (`mod` 10) –  misterbee Dec 26 '13 at 6:05

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