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There I was, writing a function that takes a value as input, calls a function on that input, and if the result of that is Just x, it should return x; otherwise, it should return the original input.

In other words, this function (that I didn't know what to call):

foo :: (a -> Maybe a) -> a -> a
foo f x = fromMaybe x (f x)

Since it seems like a general-purpose function, I wondered if it wasn't already defined, so I asked on Twitter, and Chris Allen replied that it's ap fromMaybe.

That sounded promising, so I fired up GHCI and started experimenting:

Prelude Control.Monad Data.Maybe> :type ap
ap :: Monad m => m (a -> b) -> m a -> m b
Prelude Control.Monad Data.Maybe> :type fromMaybe
fromMaybe :: a -> Maybe a -> a
Prelude Control.Monad Data.Maybe> :type ap fromMaybe
ap fromMaybe :: (b -> Maybe b) -> b -> b

The type of ap fromMaybe certainly looks correct, and a couple of experiments seem to indicate that it has the desired behaviour as well.

But how does it work?

The fromMaybe function seems clear to me, and in isolation, I think I understand what ap does - at least in the context of Maybe. When m is Maybe, it has the type Maybe (a -> b) -> Maybe a -> Maybe b.

What I don't understand is how ap fromMaybe even compiles. To me, this expression looks like partial application, but I may be getting that wrong. If this is the case, however, I don't understand how the types match up.

The first argument to ap is m (a -> b), but fromMaybe has the type a -> Maybe a -> a. How does that match? Which Monad instance does the compiler infer that m is? How does fromMaybe, which takes two (curried) arguments, turn into a function that takes a single argument?

Can someone help me connect the dots?

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I'm glad you asked because this was driving me crazy too x.x – dcastro Jan 5 at 22:59
By the way, ap fromMaybe is obfuscated code that hopefully no one would ever write in a real program. – Reid Barton Jan 6 at 13:02
up vote 14 down vote accepted

Apologies for laconic and mechanical answer. I don't like cherry-picking things like Applicative or Monad, but I don't know where you're at. This is not my usual approach to teaching Haskell.

First, ap is really (<*>) under the hood.

Prelude> import Control.Monad
Prelude> import Data.Maybe
Prelude> import Control.Applicative
Prelude> :t ap
ap :: Monad m => m (a -> b) -> m a -> m b
Prelude> :t (<*>)
(<*>) :: Applicative f => f (a -> b) -> f a -> f b

What does this mean? It means we don't need something as "strong" as Monad to describe what we're doing. Applicative suffices. Functor doesn't, though.

Prelude> :info Applicative
class Functor f => Applicative (f :: * -> *) where
  pure :: a -> f a
  (<*>) :: f (a -> b) -> f a -> f b
Prelude> :info Functor
class Functor (f :: * -> *) where
  fmap :: (a -> b) -> f a -> f b

Here's ap/(<*>) with the Maybe Monad/Applicative:

Prelude> ap (Just (+1)) (Just 1)
Just 2
Prelude> (<*>) (Just (+1)) (Just 1)
Just 2

First thing to figure out is, which instance of the typeclass Applicative are we talking about?

Prelude> :t fromMaybe
fromMaybe :: a -> Maybe a -> a

Desugaring fromMaybe's type a bit gives us:

(->) a (Maybe a -> a)

So the type constructor we're concerned with here is (->). What does GHCi tell us about (->) also known as function types?

Prelude> :info (->)
data (->) a b   -- Defined in ‘GHC.Prim’
instance Monad ((->) r) -- Defined in ‘GHC.Base’
instance Functor ((->) r) -- Defined in ‘GHC.Base’
instance Applicative ((->) a) -- Defined in ‘GHC.Base’

Hrm. What about Maybe?

Prelude> :info Maybe
data Maybe a = Nothing | Just a     -- Defined in ‘GHC.Base’
instance Monad Maybe -- Defined in ‘GHC.Base’
instance Functor Maybe -- Defined in ‘GHC.Base’
instance Applicative Maybe -- Defined in ‘GHC.Base’

What happened with the use of (<*>) for Maybe was this:

Prelude> (+1) 1
Prelude> (+1) `fmap` Just 1
Just 2
Prelude> Just (+1) <*> Just 1
Just 2
Prelude> :t fmap
fmap :: Functor f => (a -> b) -> f a -> f b
Prelude> let mFmap = fmap :: (a -> b) -> Maybe a -> Maybe b
Prelude> (+1) `mFmap` Just 1
Just 2
Prelude> :t (<*>)
(<*>) :: Applicative f => f (a -> b) -> f a -> f b
Prelude> let mAp = (<*>) :: Maybe (a -> b) -> Maybe a -> Maybe b
Prelude> :t (+1)
(+1) :: Num a => a -> a
Prelude> :t Just (+1)
Just (+1) :: Num a => Maybe (a -> a)
Prelude> Just (+1) `mAp` Just 1
Just 2

Okay, what about the function type's Functor and Applicative? One of the tricky parts here is that (->) has be to be partially applied in the type to be a Functor/Applicative/Monad. So your f becomes (->) a of the overall (->) a b where a is an argument type and b is the result.

Prelude> (fmap (+1) (+2)) 0
Prelude> (fmap (+1) (+2)) 0
Prelude> :t fmap
fmap :: Functor f => (a -> b) -> f a -> f b
Prelude> let funcMap = fmap :: (a -> b) -> (c -> a) -> c -> b
Prelude> -- f ~ (->) c 
Prelude> (funcMap (+1) (+2)) 0

Prelude> :t (<*>)
(<*>) :: Applicative f => f (a -> b) -> f a -> f b
Prelude> let funcAp = (<*>) :: (c -> a -> b) -> (c -> a) -> (c -> b)
Prelude> :t fromMaybe
fromMaybe :: a -> Maybe a -> a
Prelude> :t funcAp fromMaybe
funcAp fromMaybe :: (b -> Maybe b) -> b -> b
Prelude> :t const
const :: a -> b -> a
Prelude> :t funcAp const
funcAp const :: (b -> b1) -> b -> b

Not guaranteed to be useful. You can tell funcAp const isn't interesting just from the type and knowing how parametricity works.

Edit: speaking of compose, the Functor for (->) a is just (.). Applicative is that, but with an extra argument. Monad is the Applicative, but with arguments flipped.

Further whuttery: Applicative <*> for (->) a) is S and pure is K of the SKI combinator calculus. (You can derive I from K and S. Actually you can derive any program from K and S.)

Prelude> :t pure
pure :: Applicative f => a -> f a
Prelude> :t const
const :: a -> b -> a
Prelude> :t const
const :: a -> b -> a
Prelude> let k = pure :: a -> b -> a
Prelude> k 1 2
Prelude> const 1 2
share|improve this answer
This answer is neither laconic nor mechanical. It is lively and detailed! – Ellie Kesselman Jan 5 at 23:55
Thank you, that was very helpful. I particularly found the definitions of mFmap, funcMap and funcAp useful to further my understanding. – Mark Seemann Jan 6 at 20:11

But that use of ap is not in the context of Maybe. We're using it with a function, fromMaybe, so it's in the context of functions, where

ap f g x = f x (g x)

Among the various Monad instances we have

instance Monad ((->) r)

so it is

ap :: Monad m =>    m  (a       -> b)  ->    m  a  ->    m  b
fromMaybe     ::  r -> (Maybe r -> r)
ap            :: (r -> (a       -> b)) -> (r -> a) -> (r -> b)   
ap                   f                        g        x :: b
ap  fromMaybe ::                          (r -> a) -> (r -> b)  , a ~ Maybe r , b ~ r

because -> in types associates to the right: a -> b -> c ~ a -> (b -> c). Trying to plug the types together, we can only end up with that definition above.

And with (<*>) :: Applicative f => f (a -> b) -> f a -> f b, we can write it as (fromMaybe <*>), if you like this kind of graffiti:

 #> :t (fromMaybe <*>)
(fromMaybe <*>) :: (r -> Maybe r) -> r -> r

As is rightfully noted in another answer here, when used with functions, <*> is just your good ole' S combinator. We can't very well have function named S in Haskell, so <*> is just a part of standard repertoire of the point-free style of coding. Monadic bind (more so, flipped), =<<, can be even more mysterious, but a pointfree coder just doesn't care and will happily use it to encode another, similar pattern,

(f =<< g) x = f (g x) x 

in combinatory function calls, mystery or no mystery (zipWith (-) =<< drop 1 comes to mind).

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I'm going to relabel the type arguments, for clarity.

ap :: Monad m => m (a -> b) -> m a -> m b
fromMaybe :: c -> Maybe c -> c

Which Monad instance does the compiler infer that m is?

((->) r) is a Monad. This is all functions that have type r as their argument, for some specific r.

So in the type:

ap :: Monad m => m (a -> b) -> m a -> m b

m ~ (c ->), a ~ Maybe c and b ~ c.

The return type, m a -> m b, expands to (c -> Maybe c) -> c -> c - which is the type of ap fromMaybe.

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The monad you are looking for is (->) r or r -> _ if you prefer infix syntax.

Then the signature of ap expands to:

 m (a -> b) -> m a -> m b =
 r ->(a -> b) -> r -> a -> r -> b = -- now we use the signature of fromMaybe 
 a ->(Maybe a-> a) -> a -> Maybe a -> a -> a

Now if you consider ap fromMaybe as a partially applied function and use clever parethization voila you get the desired result.

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