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Description of loop from Control.Arrow:

The loop operator expresses computations in which an output value is fed back as input, although the computation occurs only once. It underlies the rec value recursion construct in arrow notation.

Its source code, and its instantiation for (->):

class Arrow a => ArrowLoop a where
    loop :: a (b,d) (c,d) -> a b c

instance ArrowLoop (->) where
    loop f b = let (c,d) = f (b,d) in c

This immediately reminds me of fix, the fixpoint combinator:

fix :: (a -> a) -> a
fix f = let x = f x in x

So my question is:

  1. Is it possible to implement that particular loop via fix?
  2. How are their functionalities different?
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  1. Well, of course. Every recursive definition can be written with fix:

    loop f b = let (c, d) = f (b, d) in c
    loop f b = fst $ let (c, d) = f (b, d) in (c, d)
    loop f b = fst $ let x = f (b, d) in x
    loop f b = fst $ let x = f' x in x
      where f' (_, d) = f (b, d)
    loop f b = fst $ fix $ f . (b,) . snd
    

    And it works the other way around:

    fix f = loop (join (,) . f . snd) ()
    
  2. The above should convince you that loop and fix are equivalently powerful when talking about (->). Why, then, if arrows are meant to generalize functions, is ArrowLoop not defined like so?

    class Arrow a => ArrowLoop a where
      fix :: a b b -> b
    

    Arrows also generalize the notion of "process": when Arrow a, a b c is a way to calculate a c from a b. If ArrowLoop was defined to directly generalize fix, then it would be severely crippled. fix would have to "execute" the process without any context and directly produce a value of type b, which means the "process" a b b cannot e.g. perform IO. Or, consider the arrow

    newtype LT i o = LT { runLT :: [i] -> [o] }
    

    You’d like it if fix would produce a [b] from a LT b b, but it doesn’t.

    loop is a way around these restrictions. It takes a process as argument and produces a process as result. In a sense, all the context associated with the first process can be survived in the second, which would not be possible if loop were more like fix.

    Note that I can implement an analogue of fix for ArrowLoops:

    -- resulting process ignores its input
    fix' :: ArrowLoop a -- taking an impl of loop as argument
         => a b b -> a u b
    fix' f = loop ((id &&& id) . f . arr snd)
    -- take off the outer application to () (application means (->), after all)
    -- and arrowify: join (,) = id &&& id; snd = arr snd; (Prelude..) = (Control.Category..)
    -- but the RHSs are more general
    

    But I don't believe

    loop' :: Arrow a => (forall x u. a x x -> a u x) -- taking an impl of fix' as argument
          -> a (b, d) (c, d) -> a b c
    

    is implementable, so we can’t base ArrowLoop on fix' either.

  • In the case of something like Kleisli IO, isn't mfix enough? – dfeuer Aug 9 '18 at 14:39
  • @dfeuer Yes, but there are arrows that are not based on monads (which is kind of the point of arrows) that can’t make do with fix. Further, as I was playing around writing this answer, I tried to implement loopy things in terms of fixy things and kept hitting vaguely ArrowApply-shaped roadblocks (and those are related to monads). So, I think that "a fixy thing is enough for arrow a" might even be equivalent to "a is a Kleisli arrow". We don’t want to be restricted to Kleisli arrows, so we need loop. – HTNW Aug 9 '18 at 15:46
  • I just meant that your comment about purity being required was too strong. – dfeuer Aug 9 '18 at 15:48
  • @dfeuer I meant "pure" in the general sense of "without any context", not in the more specific sense of "not IO". I’ll see if I can reword it. – HTNW Aug 9 '18 at 15:50
  • You say the process a b b can't perform IO, but that doesn't seem right. – dfeuer Aug 9 '18 at 16:19

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