My goal is to parallelize a computation using parMap from the parallel package, but I'd also like to add a bit of randomness to my sampling function.

Without the randomness my calculation is simply some number crunching and so it's pure and I could use parMap. In order to get good results, I need to take multiple samples at each step and average the results. The sampling needs to be randomized.

One solution might be to use the random package, call randoms and then consume that list during the computation (by passing the pure lazy list to the computation I would keep it pure). Unfortunately, that's a very slow random number generator and I need a lot of random numbers so I would prefer to use either mwc-random or mersenne-random (although, I don't think mersenne-random is still maintained).

Is it safe to use something like unsafePerformIO with mwc-random to write a function like randoms? Something like this:

randomsMWC :: Variate a => GenST s -> [a]
randomsMWC g = unsafePerformIO $ unsafeSTToIO $ randomsMWC' g
  randomsMWC' g = do
    a  <- uniform g
    as <- unsafeInterleaveST $ randomsMWC' g
    return (a : as)

Do I need to instead reach for a parallel number generator? Or do I need to bite the bullet and admit that my algorithm is simply not pure without using the slow random package?

Suggestions? Thanks!

  • mersenne-random-pure64 is both fast and allows multiple generators - so you can have one per thread. Apr 27, 2013 at 12:07
  • @DonStewart Multiple generators is entirely useless for parallel haskell. There's no facility for using thread-specific resources from parallel code, and there shouldn't be - it would introduce non-determinism. This is really a hard problem.
    – Carl
    Apr 27, 2013 at 18:05
  • 2
    Carl - not so. You can duplicate random gens in a data parallel fashion, avoiding the contention on a shared resource. Think of a tree-structured reduction, for example. Apr 28, 2013 at 9:20

4 Answers 4


If having a single threaded source of randomness isn't a problem for performance, you can get a pure wrapper around mwc-random

import Control.Monad.ST.Lazy
import Control.Monad
import System.Random.MWC

rList :: Variate a => Seed -> [a]
rList s = runST $ do
  g <- strictToLazyST $ restore s
  advance g

advance :: Variate a => Gen s -> ST s [a]
advance g = do
  x <- strictToLazyST $ uniform g
  xs <- x `seq` advance g
  return (x:xs)

here rList takes a seed, and then lazily produces an infinite stream of lazy numbers deterministically. I am not sure that strictToLazyST is really safe, but no one seems to object to it. I have not done any benchmarking, but I suspect this is pretty fast. I assume that mwc-random is thread safe because of the explit data flow encoded with the generator, and that it can be used in the ST monad. Inviting someone to use the hack above. I don't think the seq is necessary, but it makes me less suspicous of strictToLazyST that I know I have deterministic evaluation order (and it is still lazy enough to work).

You still need randomness (that is IO) somewhere to generate a real random seed, but this should let you keep most of the code pure, and let you store the seed to file or reuse it when necessary.


λ: gen <- create
λ: x <- save gen
λ: drop 1 $ take 10 $ rList x :: [Int]

I have a not quite release-ready package hsrandom123 on Github that might be helpful here. I have started implementing this package in order to have a suitable RNG for parallel computations available. It reimplements the Philox and Threefry RNGs from the random123 C library (there's a paper describing the ideas there, too).

There's a reason my library is unreleased, though: while the actual RNG implementation is done and seems to produce the same results as the C version, I've been undecided what Haskell interface to use, and the library is hardly documented. Feel free to contact me if you need more info or help using it, though.

  • Interesting. If it's unreleased, I don't think I want to use it but I do look forward to trying it out in the future. Apr 27, 2013 at 16:56
  • Funnily enough, I've been working on a Haskell port of Random123 too recently, although I swear I did a google search beforehand and could not find any other Haskell implementations. Mine can be found at github.com/Manticore/haskell-random123, and also as Random123 on Hackage (I'm prepared to give up the Hackage entry though, since you clearly have the priority).
    – fjarri
    May 8, 2013 at 5:08
  • Ah, too bad that we didn't coordinate work. My version is on github for some time, but as it's not on Hackage yet, I guess it's easy to overlook. I'll have a look at your version soon. I think I'll stick with the hsrandom123 name. If we come to a clear agreement what the differences are, we should probably include them in the documentation though so that users can make an informed choice.
    – kosmikus
    May 8, 2013 at 8:16

My guess is that mersenne-random isn't thread safe, so using any unsafe... and parallelization will lead you to problems with calling it from multiple threads. (See also the GHC manual Section

Functions that need randomness aren't pure, they need some source of randomness, which is either external (hardware - like a device sampling noise) and hence bound to IO, or pseudorandom, which needs to keep some state during the computation. Either way they can't be pure Haskell functions.

I'd start with separating your requirements to a specific monad type class, for example something like

class Monad m => MonadParRand m where
    random      :: MTRandom a => m a
    parSequence :: [m a] -> m [a]

which will allow you to write your main code without being bound to a specific implementation. Or if you're feeling bold you could use monad-parallel and define something like

class MonadParallel m => MonadParRand m where
    random      :: MTRandom a => m a

Now the tricky part is how to define both random and parSequence (or MonadParallel's bindM2) and making it fast. Since you're in control of bindM2, you can manage how threads are spawned and what state they keep. So you can bind a buffer to each thread from which it draws randomized numbers. If the buffer is empty, it makes a synchronized calls to mersenne-random (or another IO-based number generator), fills the buffer and proceeds.

(If you implement something like that, it'd be very nice to make a standalone library from that.)

Note that randoms from mersenne-random already uses unsafeInterleaveIO to produce a lazy list, but I'd say the list is meant to be consumed only from a single thread. And it has also room for improvements. It uses unsafeInterleaveIO and it has some overhead, as noted in its comment:

There are real overheads here. Consider eagerly filling chunks and extracting elements piecewise.

  • 1
    A function that takes a PRNG and returns a PRNG along with something else is still quite pure.
    – Carl
    Apr 27, 2013 at 18:00
  • @Carl I understand, it's just about the terminology. I used pure in the sense that a function producing a value of type a is pure if it's type is a. You used it probably in the sense that a function producing a value of type a is pure if it doesn't involve IO. A fun and inspiring post about the meaning of pure is Conal Elliots The C language is purely functional.
    – Petr
    Apr 27, 2013 at 18:42
  • 1
    No, I'm using it in the sense "The outputs are determined by only the inputs." That's the actual useful meaning of "pure".
    – Carl
    Apr 27, 2013 at 19:03
  • @Carl Indeed this is a sensible definition, I'd just like to note that all Haskell functions are pure in this sense (and this is why we like Haskell so much), no matter whether they involve IO or not. For example getLine is a true constant - it has no side effects, evaluating it like in const () $! getLine does nothing. Its output is a constant value that describes an action that does something when executed by a Haskell runtime, but not when the function is evaluated. We only perceive it as "impure" because we usually focus on what it does when executed.
    – Petr
    Apr 27, 2013 at 20:31

For completeness of answers, let me explain what I'm doing at the moment to solve this problem.

Instead of trying to make the computation pure, I've opted for using the async package instead of parallel.

If I decide to revise my current solution to be pure, I will first try the solution suggested by Philip JF, so I have marked his answer as the accepted one.

My next challenge is figuring out how to approximate optimal chunking of the work so that threading reduces the amount of time instead of making it take longer :)

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