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I want to apply a function f which needs a RandomGen over a list. I tried to generate me therefore a infinite list of RandomGen as you can see below. (just random values as generated by the function "randoms" isn't sufficient, because the needed range of the value depends on the input for f.)

module Test where
import System.Random (getStdGen, RandomGen, randomR, random)

f :: (RandomGen g, Integral a) => g -> a -> Bool

randomGens :: RandomGen g => g -> [g]
randomGens gen =
  let (i, gen') = (random gen) :: (Int, g1)
  in  gen : (repeatGen gen')

Unfortunately the compiler tells me, that it fails

    Could not deduce (g1 ~ g)
    from the context (RandomGen g)
      bound by the type signature for
             randomGens :: RandomGen g => g -> (g, g)
      at Test.hs:11:14-39
    or from (RandomGen g1)
      bound by an expression type signature: RandomGen g1 => (Int, g1)
      at Test.hs:13:19-55
      `g1' is a rigid type variable bound by
           an expression type signature: RandomGen g1 => (Int, g1)
           at Test.hs:13:19
      `g' is a rigid type variable bound by
      the type signature for randomGens :: RandomGen g => g -> (g, g)
          at Test.hs:11:14
    In the first argument of `random', namely `gen'
    In the expression: random gen :: RandomGen g => (Int, g)
    In a pattern binding:
      (i, gen') = random gen :: RandomGen g => (Int, g)

Just skipping in the let-binding the type annotation (Int, g1) doesn't work. He needs to have the result-type for the application of "random"

share|improve this question
up vote 2 down vote accepted

Quick answer

You can define the function you want as

randomGens :: (RandomGen g) => g -> [g]
randomGens g = let (g0,g1) = split g in g0 : randomGens g1

Slightly longer answer

The above probably isn't the best way to go about applying a function that requires randomness to a list. I might define a helper function to do that

mapRandom :: (RandomGen g) => (g -> a -> b) -> g -> [a] -> (g, [b])
mapRandom _ g []     = (g, [])
mapRandom f g (a:as) = let (_,g1) = next g
                        in f g a : mapRandom f g1 as

You can then write

>> g <- newStdGen
>> mapRandom f g [1..5]
([False,False,True,False,True], 1839473859 293842934)

Best answer

The function mapRandom looks very messy. That's because we have to mess around with the fiddly details of manually updating the generator. Fortunately, you don't have to do that! The package Control.Monad.Random gives you nice combinators to almost completely abstract away the idea of generators. Say you currently have

f :: (RandomGen g) => g -> Int -> Bool
f g n = let (x,_) = random g in x < n

I would rewrite that to be

f :: (RandomGen g) => Int -> Rand g Bool
f n = do
  x <- getRandom
  return (x < n)

and just use mapM to map this function over lists. You can run it with

>> gen <- newStdGen
>> runRand (mapM f [1..10]) gen
([False,True,True,False,True], 1838593757 1838473759)

where the first element of the pair is the result of mapping your random function over the list, and the last element is the current value of the generator. Notice that when defining f you don't have to worry about the generator at all - Haskell takes care of updating the generator and generating new random numbers behind the scenes.

share|improve this answer

Disregarding for a while whether generating an infinite list of random generators is really the way to go, there exists a function called split in System.Random that can be used to create a new generator instead of calling random on a dummy type and throwing the generated value away. Using split you can implement randomGens like this:

import Data.List (unfoldr)
import System.Random

randomGens :: RandomGen g => g -> [g]
randomGens = unfoldr (Just . split)

However, you should probably just use randomRs which generates an infinite stream of values in the given range.

share|improve this answer

The main problem here - compiler can't understand the equality g1 and g (list are always homomorphic!)

It is need to use ScopedTypeVariables extension, like this:

{-# LANGUAGE ScopedTypeVariables #-}

randomGens :: forall g. RandomGen g => g -> [g]
randomGens gen =
  let (i, gen') = (random gen) :: RandomGen g => (Int, g)
  in  gen : (randomGens gen')

We add forall g to point on scope context of g.

As Chris Taylor mention, this function isn't effective, it is need to calculate random number twice - first time to calculate new g and second time to calculate new random number.

So, much nicer to use MonadRand saving new generator numbers in the state.


For simple cases we could use zipWith

randomsMap :: (RandomGen g, Random a) => g -> (a -> b -> c) -> [b] -> [c]
randomsMap g f xs = zipWith f (randoms g) xs
share|improve this answer
Nice information! :-) In fact I didn't understand what the compiler problem was. Put that together with Chris Taylor's answer and you have got the perfect answer to my problem. :-) – user2292040 Jan 3 '14 at 15:01
@user2292040 updated – viorior Jan 3 '14 at 15:28

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