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I just reinvented some monad, but I'm not sure which. It lets you model steps of a computation, so you can interleave the steps of numerous computations to find which one finishes first.

{-# LANGUAGE ExistentialQuantification #-}
module Computation where

-- model the steps of a computation
data Computation a = forall b. Step b (b -> Computation a) | Done a

instance Monad Computation where
   (Step b g) >>= f = Step b $ (>>=f) . g
   (Done b) >>= f = Step b f
   return = Done

runComputation :: Computation a -> a
runComputation (Step b g) = runComputation (g b)
runComputation (Done a) = a

isDone :: Computation a -> Bool
isDone (Done _) = True
isDone _ = False

-- an order for a set of computations
data Schedule a = a :> Computation (Schedule a) | Last

toList :: Schedule a -> [a]
toList Last = []
toList (a :> c) = a : (toList . runComputation) c

-- given a set of computations, find a schedule to generate all their results
type Strategy a = [Computation a] -> Computation (Schedule a)

-- schedule all the completed computations, and step the rest, 
-- passing the remaining to the given function
scheduleOrStep :: (Queue (Computation a) -> Computation (Schedule a)) -> Strategy a
scheduleOrStep s cs = scheduleOrStep' id cs
  where scheduleOrStep' q ((Done a):cs) = Done $ a :> scheduleOrStep' q cs
        scheduleOrStep' q ((Step b g):cs) = scheduleOrStep' (q . (g b:)) cs
        scheduleOrStep' q [] = s q

-- schedule all completed compuations, step all the rest once, and repeat
-- (may never complete for infinite lists)
-- checking each row of 
-- [ [ c0s0, c1s0, c2s0, ... ]
-- , [ c0s1, c1s1, c2s1, ... ]
-- , [ c0s2, c1s2, c2s2, ... ]
-- ...
-- ]
-- (where cNsM is computation N stepped M times)
fair :: Strategy a
fair [] = Done Last
fair cs = scheduleOrStep (fair . ($[])) cs

-- schedule more steps for earlier computations rather than later computations
-- (works on infinite lists)
-- checking the sw-ne diagonals of 
-- [ [ c0s0, c1s0, c2s0, ... ]
-- , [ c0s1, c1s1, c2s1, ... ]
-- , [ c0s2, c1s2, c2s2, ... ]
-- ...
-- ]
-- (where cNsM is computation N stepped M times)
diag :: Enqueue (Computation a)-> Strategy a
diag _ [] = Done Last
diag enq cs = diag' cs id
  where diag' (c:cs) q = scheduleOrStep (diag' cs) (enq c q $ [])
        diag' [] q = fair (q [])

-- diagonal downwards : 
-- [ c0s0, 
--   c1s0, c0s1, 
--   c2s0, c1s1, c0s2, 
--   ... 
--   cNs0, c{N-1}s1, ..., c1s{N-1}, c0sN,
--   ...
--  ]
diagd :: Strategy a
diagd = diag prepend

-- diagonal upwards : 
-- [ c0s0, 
--   c0s1, c1s0, 
--   c0s2, c1s1, c2s0, 
--   ... 
--   c0sN, c1s{N-1}, ..., c{s1N-1}, cNs0,
--   ...
--  ]
diagu :: Strategy a
diagu = diag append 

-- a queue type
type Queue a = [a] -> [a]
type Enqueue a = a -> Queue a -> Queue a

append :: Enqueue a
append x q = q . (x:)

prepend :: Enqueue a
prepend x q = (x:) . q

I feel like this is probably some kind of threading monad?

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Haskell is the only language I know of where you can't tell what wheel you just reinvented... – alpha123 Aug 28 '11 at 21:02
I was about to close as too localized, but do people really spend their time knowing they're reinventing stuff in Haskell but not what they're reinventing, making this question kind of legitimate (assuming a lot of people would end up reinventing this exact thing, whatever it is)? – Mat Aug 28 '11 at 21:06
@Mat: Yes, actually. At least in certain ways. People occasionally make not-quite-jokes that in Haskell, given sufficiently generic code, if it type checks it's almost certain to be doing something useful even if you're not sure what. This is sort of along the same lines, in that if you invent something to solve a specific problem and it clearly generalizes easily, chances are it's already been done. When I was first learning Haskell, at least once I generalized a specific solution only to realize I'd reinvented an obscure corner of the standard libraries. – C. A. McCann Aug 29 '11 at 5:04

4 Answers 4

up vote 5 down vote accepted

It looks like a resumption-with-state monad. I think there used to be a resumption monad in MTL around GHC 6.6 but if there was it disappeared. William Harrison at the University of Missouri has a number of papers about resumption monads -

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I don't understand why not

data Computation a = Step (Computation a) | Done a

instance Monad Computation where
   (Step g) >>= f = Step $ g >>= f
   (Done b) >>= f = Step (f b)
   return = Done

I'm not sure what this monad is, but it's definitely simpler and seems to be equivalent in most respects.

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good point. I like it. – rampion Aug 29 '11 at 10:55
That is the plain Resumption monad. Rampion's original monad has a threaded state like the unfoldr function, though I can't really see if the state is necessary for the example given. In one of his papers, William Harrison comments that the Resumption monad is basically "inert" without adding state to it (inert is not his original word but I can't find the quote at the moment). – stephen tetley Aug 29 '11 at 11:47
@stephen tetley: With the existential quantification I've given the state, however, there's nothing that can be done with it, so in effect, it's just delaying computation. Which is what lazy evaluation does anyway, so it's equivalent to the Resumption monad. So that's the answer. – rampion Aug 29 '11 at 16:23

This looks similar to the definition of stream fusion used by Don Stewart did a while ago, and also somewhat related to iteratees (though wihtout the notion of pushing data into the iteratee using an enumerator), but less so than stream fusion I guess.

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I haven't spent too much time understanding your code, but it really sounds like the coroutine monad from the monad-coroutine package, which may be a bit more general.

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I glanced briefly at that - it looked like coroutines were communication based, while these are non-communicative. – rampion Aug 28 '11 at 22:00

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