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I'm mostly a practical guy but I find this interesting.

I have been thinking about monadic sequencing and there are a few things that I need clarified. So at the risk of sounding silly here it is:

The monadic member bind

bind :: m b -> (b -> m c) -> m c

can sequence "actions" giving you explicit access to intermediate values.

How does this give me more than the categorical member (.):

(.) :: cat b c -> cat a b -> cat a c

With this I can sequence and get access to intermediate values. After all (f . g) x = f(g (x)).

Why do I need bind for sequencing if I can sequence with (.)?

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The monadic version of (.) is (>=>) :: Monad m => (a -> m b) -> (b -> m c) -> (a -> m c), Kleisli composition. –  Daniel Fischer Oct 13 '12 at 20:09
This gives you less actually. C(a, b) = a -> m b forms a category with bind as composition and return as identity, the Kleisli category of m. –  Alexandre C. Oct 13 '12 at 20:14
It is also not quite true that in f (g x) the g x must happen first. This would be true only under strict semantics. But, as it stands, it could be before, while or not at all. –  Ingo Oct 13 '12 at 20:24
Cool I think I'm starting to learn how to read the hints types give away a bit better. I need to read Benjamin C. Pierces book Basic CT for CS. –  Eric Oct 13 '12 at 20:24

1 Answer 1

up vote 14 down vote accepted

You're on the right track. Every monad gives rise to so-called Kleisli category. For every monad m its corresponding Kleisli category has arrows a -> m b and they can be composed using >=>, which is defined as

f >=> g     = \x -> f x >>= g

Kleisli type encapsulates this in Haskell type system, you can see that it has instance

instance Monad m => Category (Kleisli m) where
    id = Kleisli return
    (Kleisli f) . (Kleisli g) = Kleisli (g >=> f)

So sequencing computations within this category is just sequencing operations using >=>, which can be expressed equivalently using >>=.

We define monads using return and >>= because it's more convenient, but we could define them as well using return and >=> if we wanted.

(See also my answer to Different ways to see a monad.)

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I was typing away but you beat me to it, so I'll just add that the Monad laws are equivalent to the laws that make Kleisli m a category: left and right absorption of identity, and associativity of composition. Note also that ArrowApply defines the extra structure which an Arrow must have to yield a monad. Kleisli m is not just a category but an Arrow, and of course possesses the extra ArrowApply structure, but not all Arrows do. –  pigworker Oct 13 '12 at 20:30
@pigworker: The laws are not 100% equivalent in that you need to add an extra (g >=> h) . f = (f.g) >=> h law in order to deduce the >>= laws from the >=> ones. I don't remember what this is called but it caught me when doing some exercises. –  hugomg Oct 13 '12 at 21:42

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