# Arrows are exactly equivalent to applicative functors?

According to the famous paper Idioms are oblivious, arrows are meticulous, monads are promiscuous, the expressive power of arrows (without any additional typeclasses) should be somewhere strictly between applicative functors and monads: monads are equivalent to ArrowApply, and Applicative should be equivalent to something the paper calls "static arrows". However, it is not clear to me what restriction this "static"-ness means.

Playing around with the three typeclasses in question, I was able to build up an equivalence between applicative functors and arrows, which I present below in the context of the well-known equivalence between Monad and ArrowApply. Is this construction correct? (I've proven most of the arrow laws before getting bored of it). Doesn't that mean that Arrow and Applicative are exactly the same?

{-# LANGUAGE TupleSections, NoImplicitPrelude #-}
import Prelude (($), const, uncurry) -- In the red corner, we have arrows, from the land of * -> * -> * import Control.Category import Control.Arrow hiding (Kleisli) -- In the blue corner, we have applicative functors and monads, -- the pride of * -> * import Control.Applicative import Control.Monad -- Recall the well-known result that every monad yields an ArrowApply: newtype Kleisli m a b = Kleisli{ runKleisli :: a -> m b} instance (Monad m) => Category (Kleisli m) where id = Kleisli return Kleisli g . Kleisli f = Kleisli$ g <=< f

instance (Monad m) => Arrow (Kleisli m) where
arr = Kleisli . (return .)
first (Kleisli f) = Kleisli $\(x, y) -> liftM (,y) (f x) instance (Monad m) => ArrowApply (Kleisli m) where app = Kleisli$ \(Kleisli f, x) -> f x

-- Every arrow arr can be turned into an applicative functor
-- for any choice of origin o
newtype Arrplicative arr o a = Arrplicative{ runArrplicative :: arr o a }

instance (Arrow arr) => Functor (Arrplicative arr o) where
fmap f = Arrplicative . (arr f .) . runArrplicative

instance (Arrow arr) => Applicative (Arrplicative arr o) where
pure = Arrplicative . arr . const

Arrplicative af <*> Arrplicative ax = Arrplicative $arr (uncurry ($)) . (af &&& ax)

-- Arrplicatives over ArrowApply are monads, even
instance (ArrowApply arr) => Monad (Arrplicative arr o) where
return = pure
Arrplicative ax >>= f =
Arrplicative $(ax >>> arr (runArrplicative . f)) &&& id >>> app -- Every applicative functor f can be turned into an arrow?? newtype Applicarrow f a b = Applicarrow{ runApplicarrow :: f (a -> b) } instance (Applicative f) => Category (Applicarrow f) where id = Applicarrow$ pure id
Applicarrow g . Applicarrow f = Applicarrow $(.) <$> g <*> f

instance (Applicative f) => Arrow (Applicarrow f) where
arr = Applicarrow . pure
first (Applicarrow f) = Applicarrow $first <$> f

• What trouble are you having with static arrows? The isomorphism is displayed on the first page of the paper. It says that applicatives are equivalent to arrows arr equipped with an isomorphism between arr a b and arr () (a -> b). Commented Jul 10, 2014 at 8:48
• @TomEllis: Let me try to formulate why I don't understand that. Suppose we had a typeclass class (Arrow arr) => ArrowStatic arr where iso :: arr a b :<->: arr () (a -> b). Now, if Applicative is equivalent to ArrowStatic, shouldn't that mean I can turn any Applicative into ArrowStatic, and thus, Arrow? How does that imply that Arrow is a more expressive interface? Commented Jul 10, 2014 at 10:55
• There is a partial proof that Category + Applicative + a few extra laws for the interaction between the two is the same as Arrow. cdsmith.wordpress.com/2011/08/13/…. The proof doesn't go as far as proving that any Applicative Category is also an Arrow. We had a similar discussion about Arrows and Applicative insprired by this tangentially related answer: stackoverflow.com/a/22875729/414413 Commented Jul 10, 2014 at 17:32
• @ErikAllik, such instances are overlapping evil. With that instance around and without OverlappingInstances, the only way for something that looks like p x to be a Functor is for p to be an Arrow! It breaks all sorts of everything, so Cactus thoughtfully didn't do it. Commented Jan 29, 2016 at 19:54
• @EricAllik, no, not at all, as far as I know. GHC commits to the instance before solving its constraints. Because of OverlappingInstances (blech!), this ends up being a good thing for equality constraints. Otherwise, I think it may be important for efficient resolution--not sure. And I think it's almost certainly important for making things sane without overlapping/incoherence. Commented Jan 29, 2016 at 20:46

Every applicative yields an arrow and every arrow yields an applicative, but they are not equivalent. If you have an arrow arr and a morphism arr a b it does not follow that you can generate a morphism arr o (a \to b) that replicates its functionality. Thus if you round trip through applicative you lose some features.

Applicatives are monoidal functors. Arrows are profunctors that are also categories, or equivalently, monoids in the category of profunctors. There is no natural connection between these two notions. If you will excuse my flippancy: In Hask it turns out that the functor part of the pro-functor in an arrow is a monoidal functor, but that construction necessarily forgets the "pro" part.

When you go from arrows to applicatives you are ignoring the part of an arrow that takes input and only using the part that deals with output. Many interesting arrows use the input part in one way or another and so by turning them into applicatives you are giving up useful stuff.

That said, in practice I find applicative the nicer abstraction to work with and one that almost always does what I want. In theory arrows are more powerfull, but I don't find my self using them in practice.

• Can you give me some example to help build an intuition of what one can do with an arrow that can't be done with an applicative? I am hoping for something comparable to how monads allow the shape of the computation to depend on sideeffects on the left of a bind, whereas applicatives have static shapes. Commented Jul 10, 2014 at 4:56
• Applicatives don't allow you to use the result of one computation as the input to a subsequent computation. Commented Jul 10, 2014 at 8:41
• @Cactus danidiaz's answer gives an example showing that whilst neither vanilla Arrow nor Applicative can shape the future computation, Arrow can use the output of one computation as the input to the next, where Applicative can only purely combine the output of both. In practice, an occasional >>= between applicatives gives this full monadic power whilst keeping the nice pure-feel syntax of Applicative. Commented Jul 10, 2014 at 8:47
• @MrBones: If f is an Applicative then f (a -> b) and f a are two applicative computations. We can run the first, run the second, and combine their results to get f b. However the second computation cannot depend on the first. Commented Jul 10, 2014 at 10:23
• @MrBones: If m is a Monad then m a is a monadic computation. We can run it and apply its result to a function of type a -> m b to get a second monadic computation (which we can run to get a b). The result of combining these two things is a monadic computation of type m b formed from running two smaller computations where the second could depend on the first. Does that help? Commented Jul 10, 2014 at 10:24

Let's compare the IO applicative functor with the Kleisli arrows of the IO monad.

You can have an arrow that prints a value read by a previous arrow:

runKleisli ((Kleisli $\() -> getLine) >>> Kleisli putStrLn) ()  But you can't do that with applicative functors. With applicative functors, all the effects take place before applying the function-in-the-functor to the arguments-in-the-functor. The function-in-the-functor can't use the value inside an argument-in-the-functor to "modulate" its own effect, so to speak. • I'd say this is a bad example/argument, because it addresses something quite different that the OP is asking. The correspondence the OP is referring to is between plain Arrow and Applicative, while you're talking about the Kleisli arrow, which corresponds to a Monad. It is clear, that monads are more powerful than applicatives, but the question was about arrows induced just by applicatives without any Monad constraint as newtype Applicarrow f a b = Applicarrow{ runApplicarrow :: f (a -> b) }. – Petr Commented Jul 10, 2014 at 9:41 • It's a perfectly good example. It only takes advantage of the Monad property "by accident". The point is that one can present three APIs for doing IO: an applicative, an arrow, and a monad based API. These are listed in order of strictly increasing expressive power. Commented Jul 10, 2014 at 10:13 • Alternatively, suppose an Arrow called IOA magically appeared, with combinators getLine :: IOA () String and putStrLn :: IOA String (). Using Arrow combinators we can form their composition getLine >>> putStrLn. There would be no way of doing that with merely an Applicative API. Commented Jul 10, 2014 at 10:15 • OK, I am liking this last example. So if IOA was an instance of just Arrow and not ArrowApply, you could still read from a file and write its contents to another file, but you couldn't read a filename from a file and then read that file. Whereas with an applicative IO type, you couldn't even do the first example. Hmmm. So how exactly is what that first example does problematic? Commented Jul 10, 2014 at 13:22 • @TomEllis OK, that makes sense, I'm getting more inclined towards the example. However, to be convincing, I'd like this to be clarified: The power of Applicative (Arrplicative (Kleisli IO)) could be much stronger than Applicative IO, in particular because in the definition of its instance we indirectly use . from Kleisli. So it should be discussed that even this isn't strong enough. While I'm inclined to believe that it's not possible, there could still be some clever trick, such as passing some monadic/functional values through this applicative etc. – Petr Commented Jul 10, 2014 at 14:17 (I've posted the below to my blog with an extended introduction) Tom Ellis suggested thinking about a concrete example involving file I/O, so let's compare three approaches to it using the three typeclasses. To make things simple, we will only care about two operations: reading a string from a file and writing a string to a file. Files are going to be identified by their file path: type FilePath = String  ## Monadic I/O Our first I/O interface is defined as follows: data IOM ∷ ⋆ → ⋆ instance Monad IOM readFile ∷ FilePath → IOM String writeFile ∷ FilePath → String → IOM ()  Using this interface, we can for example copy a file from one path to another: copy ∷ FilePath → FilePath → IOM () copy from to = readFile from >>= writeFile to  However, we can do much more than that: the choice of files we manipulate can depend on effects upstream. For example, the below function takes an index file which contains a filename, and copies it to the given target directory: copyIndirect ∷ FilePath → FilePath → IOM () copyIndirect index target = do from ← readFile index copy from (target ⟨/⟩ to)  On the flip side, this means there is no way to know upfront the set of filenames that are going to be manipulated by a given value action ∷ IOM α. By "upfront", what I mean is the ability to write a pure function fileNames :: IOM α → [FilePath]. Of course, for non-IO-based monads (such as ones for which we have some kind of extractor function μ α → α), this distinction becomes a bit more fuzzy, but it still makes sense to think about trying to extract information without evaluating the effects of the monad (so for example, we could ask "what can we know about a Reader Γ α without having a value of type Γ at hand?"). The reason we can't really do static analysis in this sense on monads is because the function on the right-hand side of a bind is in the space of Haskell functions, and as such, is completely opaque. So let's try restricting our interface to just an applicative functor. ## Applicative I/O data IOF ∷ ⋆ → ⋆ instance Applicative IOF readFile ∷ FilePath → IOF String writeFile ∷ FilePath → String → IOF ()  Since IOF is not a monad, there's no way to compose readFile and writeFile, so all we can do with this interface is to either read from a file and then postprocess its contents purely, or write to a file; but there's no way to write the contents of a file into another one. How about changing the type of writeFile? writeFile′ ∷ FilePath → IOF (String → ())  The main problem with this interface is that while it would allow writing something like copy ∷ FilePath → FilePath → IOF () copy from to = writeFile′ to ⟨*⟩ readFile from  it leads to all kind of nasty problems because String → () is such a horrible model of writing a string to a file, since it breaks referential transparency. For example, what do you expect the contents of out.txt to be after running this program? (λ write → [write "foo", write "bar", write "foo"]) ⟨$⟩ writeFile′ "out.txt"


## Two approaches to arrowized I/O

First of all, let's get two arrow-based I/O interfaces out of the way that don't (in fact, can't) bring anything new to the table: Kleisli IOM and Applicarrow IOF.

The Kleisli-arrow of IOM, modulo currying, is:

readFile ∷ Kleisli IOM FilePath String
writeFile ∷ Kleisli IOM (FilePath, String) ()


Since writeFile's input still contains both the filename and the contents, we can still write copyIndirect (using arrow notation for simplicity). Note how the ArrowApply instance of Kleisli IOM is not even used.

copyIndirect ∷ Kleisli IOM (FilePath, FilePath) ()
copyIndirect = proc (index, target) → do
writeFile ↢ (to, s)


The Applicarrow of IOF would be:

readFile ∷ FilePath → Applicarrow IOF () String
writeFile ∷ FilePath → String → Applicarrow IOF () ()


which of course still exhibits the same problem of being unable to compose readFile and writeFile.

## A proper arrowized I/O interface

Instead of transforming IOM or IOF into an arrow, what if we start from scratch, and try to create something in between, in terms of where we use Haskell functions and where we make an arrow? Take the following interface:

data IOA ∷ ⋆ → ⋆ → ⋆
instance Arrow IOA
readFile ∷ FilePath → IOA () String
writeFile ∷ FilePath → IOA String ()


Because writeFile takes the content from the input side of the arrow, we can still implement copy:

copy ∷ FilePath → FilePath → IOA () ()
copy from to = readFile from >>> writeFile to


However, the other argument of writeFile is a purely functional one, and so it can't depend on the output of e.g. readFile; so copyIndirect can't be implemented with this Arrow interface.

If we turn this argument around, this also means that while we can't know in advance what will end up being written to a file (before running the full IOA pipeline itself), but we can statically determine the set of filenames that will be modified.

## Conclusion

Monads are opaque to static analysis, and applicative functors are poor at expressing dynamic-time data dependencies. It turns out arrows can provide a sweet spot between the two: by choosing the purely functional and the arrowized inputs carefully, it is possible to create an interface that allows for just the right interplay of dynamic behaviour and amenability to static analysis.

• @StephaneRolland: you're right on both counts. I've fixed the link (it's not my fault I swear, nic.io crapped out on me...), and the IOA example is already using >>> in the blogpost, it was just an editing mistake I guess when I was formatting it for Stack Overflow. Commented Jul 4, 2018 at 1:17
• Thanks :-) Moreover, do you know of any work/paper going your way for an arrowised IO, something more like a possible real life implementation with pros/cons ? I'm currently in the middle of John Hugues paper on arrowized parsers. Next, I'll read the paper on the IO Monad implementation. And I am wondering if someone already tried to implement IO as an arrow entirely, or almost. I want to dig this idea to better understand IO. Commented Jul 4, 2018 at 13:11