13

I'm learning Haskell and started noticing common suffixes in functions like:

debugM
mapM_
mapCE

Which is known as Hungarian Notation. But at the same time I can use type classes to write non-ambiguous code like:

show
return

Since functions like map are so common and used in many contexts, why not let type checker to pick correct polymorphic version of map, fmap, mapM, mapM_ or mapCE?

  • 2
    Hungarian notation isn't the general notion of including type information in variable names; it's specifically about prefixing type information to the variable name. – jamesdlin Nov 10 '14 at 2:16
25

There's a little bit of "Hungarian notation", but it's quite different. In short, Haskell's type system removes the need for most of it.

The map/mapM thing is a neat example. These two functions confer the exact same concept, but cannot be polymorphically represented because abstracting over the difference would be really noisy. So we pick a Hungarian notation instead.

To be clear, the two types are

map  ::            (a ->   b) -> ([a] ->   [b])
mapM :: Monad m => (a -> m b) -> ([a] -> m [b])

These look similar, all mapM does is add the monad, but not the same. The structure is revealed when you make the following synonyms

type Arr    a b = a ->   b
type Klei m a b = a -> m b

and rewrite the types as

map  ::            Arr    a b -> Arr    [a] [b]
mapM :: Monad m => Klei m a b -> Klei m [a] [b]

The thing to note is that Arr and Monad m => Klei m are often extremely similar things. They both form a certain structure known as a "category" which allows us to hoist all kinds of computation inside of it. [0]

What we'd like is to abstract over the choice of category with something like

class Mapping cat where
  map :: cat a b -> cat [a] [b]

instance            Mapping (->)     where map = Prelude.map
instance Monad m => Mapping (Klei m) where map = mapM         -- in spirit anyway

but it turns out that there is way more to be gained by abstracting over the list part with Functor [1]

class Functor f where
  map :: (a -> b) -> (f a -> f b)

instance Functor [] where
  map = Prelude.map

instance Functor Maybe where
  map Nothing  = Nothing
  map (Just a) = Just (f a)

and so for simplicity's sake, we use Hungarian notation to make the difference of category instead of rolling it up into Haskell's polymorphism functionality.

[0] Notably, the fact that Klei m is a category implies m is a monad and the category laws become exactly the monad laws. In particular, that's my favorite way for remembering what the monad laws are.

[1] Technically, the sole method of Functor is called fmap not map, but it could and perhaps should have been called just map. The f was added so that the type signature for map remains simple (specialized to lists) and thus is a little less intimidating to beginners. Whether or not that was the right decision is a debate that continues today.

  • Nice answer. However, it seems to miss one important point: Why did we pick Hungarian Notation? It could have been Control.Monad.map as well (OK, maybe except for the name clashes in base) – Bergi Nov 10 '14 at 5:21
  • I suppose you could use Hungarian notation, use module-qualified names, or use polymorphism. Polymorphism is out, especially in early Haskell where trying to mix Functor-like and Category-like polymorphs would have been nightmarish. Haskell tends to eschew lots of qualified names, so while it wouldn't be a problem to have Control.Monad.map, many modules intend to be imported unqualified. So we're left with Hungarian notation. – J. Abrahamson Nov 10 '14 at 5:38
  • I understand that we pick one abstraction from two available. Is it driven by pragmatism or because of a language limitation? Can instances like Mapping (Klei m) be defined in Haskell (with extensions)? – sevo Nov 10 '14 at 21:38
  • Yep, you could definitely define Mapping (Klei m), but it would require manually annotating which "arrows" are standard versus which are Kleisli. You could even define Functor atop that as class Functor cat f where map :: (cat a b) -> (cat (f a) (f b)) but inference will suffer. Edward Kmett's hask project does a lot of this stuff... but don't say I didn't warn you :) – J. Abrahamson Nov 10 '14 at 23:06
8

Your assumption is that all of these do roughly the same thing - they don't. map and fmap are pretty much the same function - map is just fmap specialized to the [] functor (either for historical reasons, or so that beginners would get less confusing type errors - I'm not sure).

mapM and mapM_ on the other hand are like map followed by sequence or sequence_ respectively - while what they're doing may look related, they're doing different things. Incidentally, the function that behaves like fmap for monads is... fmap (which is also aliased with a specialized signature to liftM, for historical reasons), as Monads are, by definition, also Functors; note that this is, right now, not enforced by the standard library - a historical oversight that should be corrected with GHC 7.10 if I'm not mistaken.

I don't know what to tell you about debugM and mapCE as I haven't seen these before.

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