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i noticed a common pattern of executing an action until it stops having certain effects, when one knows that this signifies a fixed point (ie, there can be no future effects). is there a typeclass for this?

is this covered by MonadFix? looking at the code, it seems it would be, but i was scared off by the wiki page "It is tempting to see “recursion” and guess it means performing actions recursively or repeatedly. No."

it also seems to me that fixed points are something like the dual of identities. that is, an identity disappears when combined with a non-identity (0 for (+), 1 for (*), [] for append, etc). whereas a fixed point causes any non-fixed point to disappear under the 'relax' operation below. is there a way to formalize this duality, and is it useful to do so? ie, is there a relationship between MonadPlus and/or Monoid and MonadRelax?

lastly, i notice relax is almost an unfold/anamorphism. would it be better to express it as such?

{-# LANGUAGE MultiParamTypeClasses, FunctionalDependencies #-}

import Control.Monad.Loops (iterateUntilM) -- cabal install monad-loops

-- states that relax to a fixed point under step
class Monad m => MonadRelax m s | s -> m where
isFixed :: s -> Bool
step :: s -> m s -- often (not always): step s = return s iff isFixed s

relax :: MonadRelax m s => s -> m s
relax = iterateUntilM isFixed step
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  • step s == s isn't well-typed, you might have step s == return s though, so long as Eq a => Eq (m a). Also, having the fundep as s -> m is quite strange. Commented Feb 5, 2014 at 23:14
  • yeah i meant for that return to be kind of implicit. the fundep is so isFixed can look up its instance even though it doesn't mention type m (thanks to johnw on #haskell). Commented Feb 5, 2014 at 23:24
  • Your relax operation, strictly speaking, doesn't "execut[e] an action until it stops having effects"—what it observes is the results of step, and not necessarily its effects. Are you making some assumption that equates effects and results? If so, you may want to clarify this. Commented Feb 5, 2014 at 23:48
  • yeah i meant "stops having certain effects," which would often, but not necessarily, mean changing the result. i guess in that case, under (Eq s), mfix (or whatever) could find the fixed point automatically, and we wouldn't need isFixed? i don't want to limit it to that case, though. Commented Feb 6, 2014 at 0:00
  • I don't understand why MonadRelax is better than iterateUntilM. In fact it seems worse; is there a reason to believe there is just one good way to step a value once we know its type? Commented Feb 6, 2014 at 4:56

1 Answer 1

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What you are asking for, is actually a plain fix:

cd :: (Monad m) => Int -> Int -> m Int
cd = fix (\f c i -> if i == 0 then return c else f (c+i) (i-1))

This will repeat the computation, until i becomes 0. (I added c to have a meaningful computation; but you could assume s=(Int,Int) with one of them being a rolling sum and the other the counter)

> cd 0 4 :: [Int]
[10]

This is the same as:

relax = fix (\f s -> if isFix s then return s else f (step s))

I believe, this is the definition of iterateUntilM.

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  • i must be misunderstanding -- i want step to be able to have effects, and afaict, these types for isFixed and step look wrong: relax :: Monad m => a -> m a relax = fix (\f s -> if isFixed s then return s else f (step s)) step = undefined isFixed = undefined :t step -> step :: a :t isFixed -> isFixed :: a Commented Feb 7, 2014 at 10:30
  • @user1441998 well, ok, step s >>= f then.
    – Sassa NF
    Commented Feb 7, 2014 at 13:22
  • well that worked, but i don't follow. fix :: (a -> a) -> a, but you pass a function of two args. i can see the types work out that a = b -> mb. but how do we think of your f? some kind of null action, just not quite as null as return? the action of recurring? is this just a trick you know, or is there a way to have reasoned towards this solution? since effects were involved, why wasn't MonadFix necessary, ie, what more would have to be going on for MonadFix to apply? what about the potential duality btw identities and fixed points? can anamorphism always be expressed in terms of fix? Commented Feb 8, 2014 at 9:08
  • @user1441998 :) this deserves a long post of its own. Think of it better as so: cd = fix g means cd = g cd. So the first argument, f, of the lambda I passed to fix is really cd. f is not a null action. The trick here is that recursive calls to cd are tied with >>, which combines the actions of each call. MonadFix is used for a different pattern. Identity is related to fixed points like isomorphism is related to identity. fix is not always a anamorphism, but anamorphism is always a fix.
    – Sassa NF
    Commented Feb 8, 2014 at 10:03
  • @user1441998 re: fixed points there is a very good categorical treatment of the matter by Varmo Vene in his thesis.
    – Sassa NF
    Commented Feb 8, 2014 at 10:04

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