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I'd like to have a function like:

unzipState :: (MonadState s m) => m (a, b) -> (m a, m b)

which would take a (stateful) computation that returns a tuple, and would return two (dependant) computations.

The difficulty is of course in that extracting values from one or the other computation should update the state in the other.

A useful (and motivating) application is the Random monad, expressed as

{-# LANGUAGE Rank2types #-}
import qualified System.Random as SR
import Control.Monad.State

type Random a = forall r. (State RandomGen r) => State r a

and let's say you have:

normal :: Random Double
-- implementation skipped

correlateWith :: Double -> Random (Double, Double) -> Random (Double, Double)
correlateWith rho w = do
                        (u, v) <- w
                        return $ (u, p * u + (1 - p * p) * v)

it would be quite natural to be able to write:

let x = normal
    y = normal
    (u, v) = unzipState $ correlateWith 0.5 $ liftM2 (,) x y
    ... now I am able to perform computation on u and v as correlated random variables

Is there a sensible way to do this ? I struggled a bit, but did not manage to get to anything. Hoogle was of no help either.


Great answers have shown me my problem is ill-defined. Nevertheless, can someone explain me why the following implementation in python (which I believe to be correct, but have not tested much) cannot be translated in Haskell (with the magic of STrefs, closures and other things I admit I don't grasp ;-) ):

def unzipState(p):
    flist, glist = [], []
    def f(state):
        if not flist:
            (fvalue, gvalue), newstate = p(state)
            glist.insert(0, gvalue)
            return (fvalue, newstate)
            fvalue = flist.pop()
            return (fvalue, state)
    def g(state):
        if not glist:
            (fvalue, gvalue), newstate = p(state)
            flist.insert(0, fvalue)
            return (fvalue, newstate)
            gvalue = glist.pop()
            return (gvalue, state)
    return (f, g)

Not that I am saying that stateful code can be translated in Haskell, but I feel like understanding why and when (even on an example) it cannot be done would improve my understanding a lot.


Now it is crystal clear. The functons f and g are obviously not pure, as their output does not only depend on the value of state.

Thanks again !

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3 Answers 3

up vote 4 down vote accepted

It's impossible to construct a general function unzipState that does what you want, if only because you probably can't provide a formal specification for its intended effect. In other words, assume that you have implemented some function unzipState. How do you know that it's correct? You would have to prove that it satisfies certain laws/equations, but the trouble here is to find these laws in the first place.

While I think I understand what you want to do, the Random monad also makes it apparent why it cannot be done. To see that, you have to ditch the concrete implementation type Random a = ... and consider the abstract interpretation given by

v :: Random a means that v is a probability distribution of values of type a

The "bind" operation (>>=) :: Random a -> (a -> Random b) -> Random b is simply a way to construct a new probability distribution from an old probability distribution.

Now, this means that unzipState simply returns a pair of probability distributions, which can be used to construct other probability distributions. The point is that while the do syntax looks very suggestive, but you don't actually sample random variables, you just calculate probability distributions. Random variables can be correlated, but probability distributions cannot.

Note that it is possible to create a different monad RandomVariable a that corresponds to random variables. However, you have to fix the sample space Ω in advance. The implementation is

type RandomVariable a = Ω -> a

If you want both random variables and the ability to enlarge the sample space automatically, you probably need two bind operations

bind1 :: Random Ω a -> (a -> Random Ω b) -> Random Ω b
bind2 :: Random Ω1 a -> (a -> Random Ω2 b) -> Random (Ω1,Ω2) b

and some dependent type magic to deal with the proliferation of products like (Ω1,(Ω2,Ω3)).

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I don't think (Random a) can really be interpreted as probability distributions because in that case, you need to be able to define omega as a probalized space, which is quite difficult. Furthermore, it is not because that two objects of Random a have the same distribution that they are equal (take two u = uniform; v=uniform, you don' have u=v). A more humble interpretation is to understand it as realisations (more specifically, as functions operating on realisations) of random variables, which should be isomorphic to streams, so I believe that the unzip operation is well-defined). –  LeMiz Jan 9 '11 at 1:13
Nope. If u = uniform :: Random A and v = uniform :: Random A, then it is trivially true that u = v = uniform. Keep in mind that there are two different notions here: random variables derived from a sample space Ω, and collections of values of type a weighted with a probability (= probability distribution). Your Random a monad corresponds to the latter, not the former. It is equally possible to implement it as Random a = [(a,Probability)]. [I'm afraid it's a bit tricky to discuss this without a formalization of the Random a monad and the particular effect you are after.] –  Heinrich Apfelmus Jan 9 '11 at 16:07
you are perfectly right on the equality point, I was confused. Thanks ! –  LeMiz Jan 9 '11 at 23:35

I'm not entirely clear on how you'd like this to work--since correlateWith operates on a tuple, what meaning would the correlated variables have independently? Say you do this:

let x = normal
    y = normal
    (u, v) = unzipState $ correlateWith 0.5 $ liftM2 (,) x y
in do u1 <- u
      v1 <- v
      u2 <- u
      u3 <- u
      -- etc...

What relationship should exist between u1, u2, and u3?

Also, a "random variable" like this can be converted into an infinite lazy stream in a straightforward fashion. What would the meaning of the following be?

let x = normal
    y = normal
    (u, v) = unzipState $ correlateWith 0.5 $ liftM2 (,) x y
in do vs <- generateStream v
      u1 <- u
      if someCondition u1 then u else return u1
      -- etc...

Because the number of values sampled from u changes based on u1, this seems to suggest that the non-monadic value bound to vs would retroactively depend somehow on u1 as well, which sounds suspiciously like the sort of spooky action at a distance that Haskell avoids.

I would hazard a guess that what you're trying to accomplish can't simply be retrofitted on top of a simple PRNG state monad, but there may be other options.

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I guess the semantics would be exactly the same as for Streams: data Stream a = a :< Stream a, for which unzip is defined the same way as for lists: foldstream f (x:<xs) = f x (foldStream f xs) and unzipStream = foldStream (\(a,b) ~ (as, bs) -> (a:<as, b:<bs)). In your first example, (u1, u2) are correlated, and each consecutive "drawing" of u stores a corresponding value of a drawing of v which would be drawn if one would write v2 <- v etc... –  LeMiz Jan 8 '11 at 18:09
in the previous comment, please read (u1, v1) are correlated instead of (u1, u2) are correlated. –  LeMiz Jan 8 '11 at 18:16

There's lots of related stuff on Bayesian monads in Haskell. Here's one reference: http://www.randomhacks.net/articles/2007/02/22/bayes-rule-and-drug-tests

See also "Purely functional lazy non-deterministic programming" available from this page: http://www.cs.rutgers.edu/~ccshan/

Edit: I also fail to see why you can't just give correlateWith the following type signature, and run it inside the do block directly rather than try to "push" the random state in within a let binding. correlateWith :: Double -> Random Double -> Random Double -> Random (Double, Double)

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It is interesting material, but can you point me how does it relate to my problem ? –  LeMiz Jan 9 '11 at 1:27
It shows how to do actual probability monads, instead of just overloading random and failing. –  sclv Jan 9 '11 at 16:28

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