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Haskell: Am I misunderstanding how Arrows may be used?

I wrote some toy code to play with the concept of Arrows. I wanted to see if I could write an Arrow which encoded the concept of a stateful function - giving a different value after different calls.

``````{-# LANGUAGE Arrows#-}
module StatefulFunc where

import Control.Category
import Control.Arrow

newtype StatefulFunc a b = SF { unSF :: a -> (StatefulFunc a b, b) }

idSF :: StatefulFunc a a
idSF = SF \$ \a -> (idSF, a)

dotSF :: StatefulFunc b c -> StatefulFunc a b -> StatefulFunc a c
dotSF f g = SF \$ \a ->
let (g', b) = unSF g a
(f', c) = unSF f b
in (dotSF f' g', c)

instance Category StatefulFunc where
id = idSF
(.) = dotSF

arrSF :: (a -> b) -> StatefulFunc a b
arrSF f = ret
where ret = SF fun
fun a = (ret, f a)

bothSF :: StatefulFunc a b -> StatefulFunc a' b' -> StatefulFunc (a, a') (b, b')
bothSF f g = SF \$ \(a,a') ->
let (f', b) = unSF f a
(g', b') = unSF g a'
in (bothSF f' g', (b, b'))

splitSF :: StatefulFunc a b -> StatefulFunc a b' -> StatefulFunc a (b, b')
splitSF f g = SF \$ \a ->
let (f', b) = unSF f a
(g', b') = unSF g a
in (splitSF f' g', (b, b'))

instance Arrow StatefulFunc where
arr  = arrSF
first = flip bothSF idSF
second = bothSF idSF
(***) = bothSF
(&&&) = splitSF

eitherSF :: StatefulFunc a b -> StatefulFunc a' b' -> StatefulFunc (Either a a') (Either b b')
eitherSF f g = SF \$ \e -> case e of
Left a -> let (f', b) = unSF f a in (eitherSF f' g, Left b)
Right a' -> let (g', b') = unSF g a' in (eitherSF f g', Right b')

mergeSF :: StatefulFunc a b -> StatefulFunc a' b -> StatefulFunc (Either a a') b
mergeSF f g = SF \$ \e -> case e of
Left a -> let (f', b) = unSF f a in (mergeSF f' g, b)
Right a' -> let (g', b) = unSF g a' in (mergeSF f g', b)

instance ArrowChoice StatefulFunc where
left = flip eitherSF idSF
right = eitherSF idSF
(+++) = eitherSF
(|||) = mergeSF
``````

So after I went through the various type class definitions (not sure whether or how ArrowZero would work for this, so I skipped it), I defined some helper functions

``````evalSF :: (StatefulFunc a b) -> a -> b
evalSF f a = snd (unSF f a)

givenState :: s -> (s -> a -> (s, b)) -> StatefulFunc a b
givenState s f = SF \$ \a -> let (s', b) = f s a in (givenState s' f, b)
``````

And worked out an example of use

``````count :: StatefulFunc a Integer
count = givenState 1 \$ \c _ -> (c+1, c)

countExample :: StatefulFunc a Integer
countExample = proc _ -> do
(count', one) <- count -< ()
(count'', two) <- count' -< ()
(count''', three) <- count'' -< ()
returnA -< three
``````

However, when I try to compile `countExample`, I get "Not in scope" errors for `count'` and `count''`, which I suppose means that I need to go back to the tutorial and read up on what can be used when. I think what I'd really like anyway is something more like

``````countExample :: Integer
countExample =
let (count', one) = unSF count ()
(count'', two) = unSF count' ()
(count''', three) = unSF count'' ()
in three
``````

But that's kind of awkward, and I was hoping for something a bit more natural.

Can anyone explain how I'm misunderstanding how Arrows work, and how they might be used? Is there fundamental philosophy to Arrows that I'm missing?

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Can anyone explain how I'm misunderstanding how Arrows work, and how they might be used? Is there fundamental philosophy to Arrows that I'm missing?

I get the impression that you're treating this `Arrow` like you would a `Monad`. I don't know if this counts as a "fundamental philosophy", but there's a significant difference between the two, despite how often they overlap. In a sense the key thing that defines a `Monad` is the `join` function; how to collapse a nested structure into a single layer. They're useful because of what `join` allows: you can create new monadic layers in a recursive function, alter the `Functor` structure based on its contents, and so on. But this isn't about `Monad`s, so we'll leave it at that.

The essence of an `Arrow`, on the other hand, is a generalized version of a function. The `Category` type class defines generalized versions of function composition and the identity function, while the `Arrow` type class defines how to lift a regular function to an `Arrow` and how to work with `Arrow`s that take multiple arguments (in the form of tuples--`Arrows` can't necessarily be curried!).

When combining `Arrow`s in a basic manner, as in your first `countExample` function, all you're really doing is something like elaborate function composition. Look back at your definition of `(.)`--you're taking two stateful functions and connecting them into a single stateful function, with the state change behavior handled automatically.

So, the main problem with your `countExample` is that it even mentions `count'` and such. That's all done behind the scenes, just like you don't need to explicitly pass the state parameter along when using `do` notation in the `State` monad.

Now, because the `proc` notation just lets you construct large composite `Arrow`s, to actually use your stateful function you'll need to work outside the `Arrow` syntax, just like you need `runState` or such in order to actually run a computation in the `State` monad. Your second `countExample` is along these lines, but too specialized. In the general case, your stateful function maps a stream of inputs to a stream of outputs, making it a finite state transducer, so `runStatefulFunction` would probably take a lazy list of input values and convert them into a lazy list of output values using a right fold with `unSF` to feed each to the transducer in turn.

If you'd like to see an example, the `arrows` package includes an `Arrow` transformer `Automaton` that defines something almost identical to your `StatefulFunction`, except with an arbitrary `Arrow` in place of the plain function you've used.

Oh, and to briefly revisit the relationship between `Arrow`s and `Monad`s:

Plain `Arrows` are only "first-order" function-like things. As I said before, they can't always be curried, and likewise they can't always be "applied" in the same sense that the `(\$)` function applies functions. If you do actually want higher-order `Arrows`, the type class `ArrowApply` defines an application `Arrow`. This adds a great deal of power to an `Arrow` and, among other things, allows the same "collapse nested structure" feature that `Monad` provides, making it possible to define generally a `Monad` instance for any `ArrowApply` instance.

In the other direction, because `Monad`s allow combining functions that create new monadic structure, for any `Monad` `m` you can talk about a "Kleisli arrow", which is a function of type `a -> m b`. Kleisli arrows for a `Monad` can be given an `Arrow` instance in a pretty obvious way.

Other than `ArrowApply` and Kleisli arrows, there's no particularly interesting relationship between the type classes.

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awesome, thank you, exactly what I was looking for. – rampion Sep 11 '10 at 3:08