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How can I sample without replacement from a set of numbers ([1, 2, 3]) until I hit x? My plan was to shuffle the list [1, 2, 3] and chop it at x:

-- chopAt 3 [2, 3, 1] == [2, 3]
-- chopAt 3 [2, 1, 3] == [2, 1, 3]
-- chopAt 3 [3, 1, 2] == [3]
chopAt _ [] = []
chopAt x (y:ys)
  | x /= y    = y : chopAt x ys
  | otherwise = [y]

However I could not figure out how to shuffle the list (or understand Monads yet).

-- sample without replacement from [1, 2, 3] until one hits a 3
-- x <- shuffle [1, 2, 3]
-- print (chopAt 3 x)
main = do
-- shuffle [1, 2, 3]
  print (chopAt 3 [1, 3, 2])
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4 Answers 4

up vote 29 down vote accepted

Use random and maybe even MonadRandom to implement your shuffles. A few good answers exist here

But that's really operational. Here's what's going on behind the scenes.


Randomness is one of the first places in Haskell that you encounter and have to handle impurity---which seems offensive, because shuffles and samples seem so simple and don't feel like they ought to be bundled up with printing to a physical screen or launching nukes, but often purity == referentially transparent and referentially transparent randomness would be useless.

random = 9 -- a referentially transparent random number

So we need a different idea about randomness to make it pure.


A typical "cheat" in scientific code used to enhance reproducibility—super important—is to fix your random seed of an experiment so that others can verify that they get exactly the same results every time your code is run. This is exactly referential transparency! Let's try it.

type Seed = Int
random :: Seed -> (Int, Seed)
random s = (mersenneTwisterPerturb s, splitSeed s)

where mersenneTwisterPerturb is a pseudorandom mapping from Seeds to Int and splitSeed is a pseudorandom mapping from Seeds to Seeds. Note that both of these functions are totally deterministic (and referentially transparent), so random is as well, but we can create an infinite, lazy pseudorandom stream like so

randomStream :: Seed -> [Int]
randomStram s = mersenneTwisterPerturb s : randomStream (splitSeed s)

Again, this stream is deterministic based on the Seed value, but an observer who sees only the stream and not the seed should be unable to predict its future values.


Can we shuffle a list using a random stream of integers? Sure we can, by using modular arithmetic.

shuffle' :: [Int] -> [a] -> [a]
shuffle' (i:is) xs = let (firsts, rest) = splitAt (i `mod` length xs) xs
                     in (last firsts) : shuffle is (init firsts ++ rest)

Or, to make it more self-contained, we can precompose our stream generating function to get

shuffle :: Seed -> [a] -> [a]
shuffle s xs = shuffle' (randomStream s) xs

another "seed consuming" referentially transparent "random" function.


So this seems to be a repeating trend. In fact, if you browse the module System.Random you'll see lots of functions like what we wrote above (I've specialized some type classes)

random :: (Random a) => StdGen -> (a, StdGen)
randoms :: (Random a) => StdGen -> [a]

where Random is the type class of things which can be generated randomly and StdGen is a kind of Seed. This is already enough actual working code to write the necessary shuffling function.

shuffle :: StdGen -> [a] -> [a]
shuffle g xs = shuffle' (randoms g) xs

and there's an IO function newStdGen :: IO StdGen which will let us build a random seed.

main = do gen <- newStdGen
          return (shuffle gen [1,2,3,4,5])

But you'll notice something annoying: we need to keep varying the gen if we want to make different random permutations

main = do gen1 <- newStdGen
          shuffle gen1 [1,2,3,4,5]
          gen2 <- newStdGen
          shuffle gen2 [1,2,3,4,5]

          -- using `split :: StdGen -> (StdGen, StdGen)`
          gen3 <- newStdGen
          let (_, gen4) = split gen3
          shuffle gen3 [1,2,3,4,5]
          let (_, gen5) = split gen4
          shuffle gen4 [1,2,3,4,5]

This means you'll either have to do lots of StdGen bookkeeping or stay in IO if you want different random numbers. This "makes sense" because of referential transparency again---a set of random numbers have to be random with respect to each other so you need to pass information from each random event on to the next.

It's really annoying, though. Can we do better?


Well, generally what we need is a way to have a function take in a random seed then output some "randomized" result and the next seed.

withSeed :: (Seed -> a) -> Seed -> (a, Seed)
withSeed f s = (f s, splitSeed s)

The result type withSeed s :: Seed -> (a, Seed) is a fairly general result. Let's give it a name

newtype Random a = Random (Seed -> (a, Seed))

And we know that we can create meaningful Seeds in IO, so there's an obvious function to convert Random types to IO

runRandom :: Random a -> IO a
runRandom (Random f) = do seed <- newSeed
                          let (result, _) = f seed
                          return result

And now it feels like we've got something useful---a notion of a random value of type a, Random a is just a function on Seeds which returns the next Seed so that later Random values won't all be identical. We can even make some machinery to compose random values and do this Seed-passing automatically

sequenceRandom :: Random a -> Random b -> Random b
sequenceRandom (Random fa) (Random fb) = 
    Random $ \seed -> let (_aValue, newSeed) = fa seed in fb newSeed

but that's a little silly since we're just throwing away _aValue. Let's compose them such that the second random number actually depends materially on the first random value.

bindRandom :: Random a -> (a -> Random b) -> Random b
bindRandom (Random fa) getRb = 
    Random $ \seed -> let (aValue, newSeed) = fa seed
                          (Random fb)       = getRb aValue
                      in fb newSeed

We also ought to note that we can do "pure" things to Random values, for instance, multiplying a random number by 2:

randomTimesTwo :: Random Int -> Random Int
randomTimesTwo (Random f) = Random $ \seed -> let (value, newSeed) = f seed
                                              in (value*2, newSeed)

which we can abstract out as a Functor instance

instance Functor Random where
  fmap f (Random step) = Random $ \seed -> let (value, newSeed) = step seed
                                           in (f value, newSeed)

and now we can create cool random effects like Brownian motion

brownianMotion :: Random [Int]
brownianMotion = 
   bindRandom random $ \x -> 
       fmap (\rest -> x : map (+x) rest) brownianMotion


And this gets to the heart of the whole matter that I've been writing up to. Randomness can exist in the IO monad perfectly well, but it can also exist on its own as a simpler Random monad. We can write the instance immediately.

instance Monad Random where
  return x = Random (\seed -> (x, seed))
  rx >>= f = bindRandom rx f

And since it's a monad, we get free do notation

brownianMotion' = do x <- random
                     rest <- brownianMotion'
                     return $ x : map (+x) rest

and you could even get fancy and call runRandom a monad homomorphism, but that's a very different topic.

So, to recap

  1. randomness in a referentially transparent language needs Seeds
  2. carting Seeds are is annoying
  3. there's a common pattern to "lifting" and "binding" random values which routes the Seeds around naturally
  4. that pattern forms a monad

And the really short answer is that you probably want to be using random and maybe even MonadRandom to implement your shuffles. They'll come in handy for "sampling" generally.


share|improve this answer
See also random-fu's shuffle function. –  Daniel Wagner Feb 4 '13 at 20:09
random-fu just kicks the shuffling down to random-shuffle's shuffle :: [a] -> [Int] -> [a] which is, to be honest, a muuuch better shuffling algorithm than I have above. There's also shuffle' :: RandomGen gen => [a] -> Int -> gen -> [a] which ties into the System.Random random functionality directly. –  J. Abrahamson Feb 5 '13 at 1:40
So what do you do if you don't want seeds, because you want a hardware RNG instead? –  dfeuer Mar 15 at 3:25
Ultimately you probably do want seeds (it's ultra slow otherwise) so you just need to ensure that you get them from a good entropy source and put them into a good PRNG. If you genuinely want hardware only randomness then there's an easy function to write of type IO Bit. –  J. Abrahamson Mar 15 at 5:31
@J.Abrahamson, what I mean is that it seems tricky to take code that assumes seed splitting and convert it to use an entropy pool. Or is there some monadic magic I'm missing? (Please ping me so I see your response.) –  dfeuer Mar 18 at 3:24

Are you looking for permutations?

Also it seems that cropAt can be implemented via takeWhile. I personally prefer standard combinators over hand-made.

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to explain: hand-made because in order to learn Haskell I gave myself little challenges. –  Micha Wiedenmann Feb 4 '13 at 17:44

Bellow you may find some simple solution from beginning of my Haskell learning. If truth to be told, I'm still at the beginning or just slightly behind ;-)

import System.Random
import Control.Applicative

shuffle :: [a] -> IO [a]
shuffle [] = return []
shuffle lst = do
    (e, rest) <- pickElem <$> getIx
    (e:) <$> shuffle rest
    getIx = getStdRandom $ randomR (1, length lst)
    pickElem n = case splitAt n lst of
        ([], s) -> error $ "failed at index " ++ show n -- should never match
        (r, s)  -> (last r, init r ++ s)
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Everyone seem to have encountered this at one point in time or another. This is my quick solution to a problem:

import System.Random

shuffle :: [a] -> IO [a]
shuffle [] = return []
shuffle xs = do randomPosition <- getStdRandom (randomR (0, length xs - 1))
                let (left, (a:right)) = splitAt randomPosition xs
                fmap (a:) (shuffle (left ++ right))

Note that the complexity is O(N^2), so this is pretty inefficient for larger lists. Other way is to implement Fisher-Yates shuffle by using mutable arrays (linear complexity):

import Data.Array.IO
import System.Random

swapElements_ :: (MArray a e m, Ix i) => a i e -> i -> i -> m ()
swapElements_ arr i j = do a <- readArray arr i
                           b <- readArray arr j
                           writeArray arr i b
                           writeArray arr j a
                           return ()

shuffle :: [a] -> IO [a]
shuffle xs = do let upperBound = length xs
                arr <- (newListArray (1, upperBound) :: [a] -> IO (IOArray Int a)) xs
                mapM_ (shuffleCycle arr) [2..upperBound]
                getElems arr
  where shuffleCycle arr i = do j <- getStdRandom (randomR (1, i))
                                swapElements_ arr i j
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