I would like to do some Monte Carlo analysis in Haskell. I would like to be able to write code like this:

do n <- poisson lambda
   xs <- replicateM n $ normal mu sigma
   return $ maximum xs

which corresponds to the stochastic model

n ~ Poisson(lambda)
for (i in 1:n)
  x[i] ~ Normal(mu, sigma)
y = max_{i=1}^n x[i]

I can see how to create the necessary random-sampling monad pretty easily. However, I would prefer not to have to implement samplers for all of the standard probability distributions. Is there a Haskell package that already has these implemented?

I have looked at package random-fu, which has been stalled at version 0.2.7 for three years, but I can't make sense of it; it depends on typeclasses MonadRandom and RandomSource, which aren't well explained.

I've also looked at package mwc-probability, but I can't make sense of it either -- it seems you have to already understand the PrimMonad and PrimState typeclasses.

Both of these packages strike me as having overly complex APIs, and seem to have entirely abandoned the standard random-number-generation framework of Haskell as found in System.Random.

Any advice would be appreciated.

  • How about statistics package?
    – moonGoose
    May 10, 2019 at 21:36
  • Same issue with the statistics package -- I get lost when I get down to the section on random number generation and it starts using PrimState and PrimMonad in the function signatures. Whatever happened to System.Random.RandomGen? May 10, 2019 at 21:43
  • How about probable? Seems to have some simple examples, works with distributions from statistics, updated recently.
    – moonGoose
    May 10, 2019 at 21:47
  • 1
    Q: What happened to System.Random.RandomGen? A: It's slow and not very random, so people use better generators (that are, generally, both faster and less predictable) whenever they can. No sense whining about it; instead, take this as an opportunity to learn more about Haskell as you dig into the complicated API. (Yes, every part of the complication is well-motivated by technical considerations.) May 10, 2019 at 22:21
  • 2
    There are good answers to many of the questions you've raised in comments -- it's not that hard to explain what PrimMonad is (and why it's used), and I believe you can use a RandomGen instance as a random-fu RNG without too much pain. However, these answers won't fit in comments, and they aren't answers to the original question. Perhaps you could post these as additional questions?
    – K. A. Buhr
    May 10, 2019 at 23:53

2 Answers 2


Well, if you want to be able to write code like this:

do n <- poisson lambda
   xs <- replicateM n $ normal mu sigma
   return $ maximum xs

then you presumably want to use random-fu:

import Control.Monad
import Data.Random
import Data.Random.Distribution.Poisson
import Data.Random.Distribution.Normal

foo :: RVar Double
foo = do
  n <- poisson lambda
  xs <- replicateM (n+1) $ normal mu sigma
  return $ maximum xs

  where lambda = 10 :: Double
        mu = 0
        sigma = 6

main :: IO ()
main = print =<< replicateM 10 (sample foo)

I'm not sure that lack of updates over the past three years should be a deciding factor. Have there really been that many exciting advances in the world of gamma distributions?

Actually, it looks like mwc-probability works about the same:

import Control.Monad
import System.Random.MWC.Probability

foo :: Prob IO Double
foo = do
  n <- poisson lambda
  xs <- replicateM (n+1) $ normal mu sigma
  return $ maximum xs

  where lambda = 10 :: Double
        mu = 0
        sigma = 6

main :: IO ()
main = do
  gen <- createSystemRandom
  print =<< replicateM 10 (sample foo gen)
  • Thanks, that's a nice example. But the deciding factor is really that I can't figure out what the underlying source of random bits is in your example, or how to provide the underlying RNG in general. When I look at the documentation for sample, I see that I need to understand the typeclasses Sampleable and MonadRandom. The latter has barely any documentation -- not even a list of required methods! The former requires me to understand RandomSource and, possibly, Lift. The documentation for both of those is quite sparse. May 10, 2019 at 21:57
  • Similar comment with mwc-probability -- it's unclear where the underlying RNG is coming from, and function signatures for random variate generation refer to the mysterious typeclasses PrimState and PrimMonad. What happened to System.Random.RandomGen? May 10, 2019 at 22:02
  • 1
    Ah, in that case the answer is no, there is no (reasonably popular and maintained) Haskell package that includes samplers for a standard set of probability distributions, is well documented, can be understood without reference to a MonadRandom or mechanism of similar complexity, and would also support a monadic syntax similar to what you describe.
    – K. A. Buhr
    May 10, 2019 at 22:33
  • 1
    @KevinS.VanHorn sounds like maybe it's time to level up your haskell-fu? Try to understand despite the sparse documentation. It's all open source after all. Ask questions when you get stuck, we're here to help!
    – luqui
    May 11, 2019 at 0:16

I figured out the packages mwc-random and statistics sufficiently to make them usable for my purposes. To make them easier to use, I defined some wrappers, described below. The complete set of packages my solution uses is transformers, vector, mwc-random, and statistics.

First, here are the needed language extensions and imports:

{-# LANGUAGE RankNTypes #-}
{-# LANGUAGE FlexibleContexts #-}

import Control.Monad (replicateM)
import Control.Monad.ST
import Control.Monad.Trans.Reader
import qualified Data.Vector as V
import Data.Vector.Generic hiding (replicateM, sum, product)
import Data.Word
import System.Random.MWC (Gen)
import qualified System.Random.MWC as R
import Statistics.Distribution
import Statistics.Distribution.Normal

I define a random-sampling monad Rand that hides from the user the need to understand PrimMonad and PrimState, and provides some needed utilities. (If you're interested in the details, Gen s a is a uniform PRNG that returns values of type a, ST s is a state-transformer monad, and the uninstantiated type variable s is part of a type-system hack that prevents state-updating side effects from escaping the monad.) An unfortunate feature of the mwc-random and statistics packages is that the primitive PRNG, based on Marsaglia's MWC256 algorithm, is hardwired-in; you cannot substitute a different PRNG.

type Rand0 s a = ReaderT (Gen s) (ST s) a
type Rand a = (forall s. Rand0 s a)  -- the random-sampling monad

-- A draw from the Uniform(0.0, 1.0) distribution
uniform01 :: Rand Double
uniform01 = ask >>= R.uniform

-- Provide a seed for the PRNG and return a draw from the random sampler
runRandL :: Rand a -> [Word32] -> a
runRandL rand seeds = runRandV rand (V.fromList seeds)

-- Provide a seed for the PRNG and return a draw from the random sampler
runRandV :: Vector v Word32 => Rand a -> v Word32 -> a
runRandV rand seeds =
  runST $ R.initialize seeds >>= runReaderT rand

-- Seed the PRNG with data from the system's fast source of pseudo-random numbers,
-- then return a draw from the random sampler
runRandIO :: Rand a -> IO a
runRandIO rand = do
  gen <- R.createSystemRandom
  seeds <- R.fromSeed <$> R.save gen
  return $ runRandV rand seeds

If you have f :: Rand a and you want n independent draws from f, then use replicateM f :: Rand [a] or V.replicateM f :: Rand (V.Vector a). The following example returns a draw from the sum of n independent uniform random variables:

sumOfUniform :: Int -> Rand Double
sumOfUniform n = do
  xs <- replicateM n uniform01
  return $ sum xs

The statistics package provides various data types that correspond to common statistical distributions. For example, normalDistr mu sigma :: NormalDistribution is an object representing a normal distribution; it contains the parameter values mu for the mean and sigma for the std deviation.

Instances of type class ContDistr d provide density and inverse CDF (quantile) functions for objects of distribution type d.

Instances of type class ContGen d provide a genContVar function for drawing from a continuous distribution, and instances of type class DiscrGen d provide a genDiscrVar function for drawing from a discrete distribution.

To make all of this easy to use with the Rand monad, I define some wrappers:

-- Draw from the continuous distribution d
genContV :: ContGen d => d -> Rand Double
genContV d = ask >>= genContVar d

-- Draw from the discrete distribution d
genDiscrV :: DiscreteGen d => d -> Rand Int
genDiscrV d = ask >>= genDiscreteVar d

-- Draw from the continuous distribution d using the inverse CDF method.
genCont :: ContDistr d => d -> Rand Double
genCont d = ask >>= genContinuous d

-- Draw from the normal distribution with mean mu and std dev sigma
normal :: Double -> Double -> Rand Double
normal mu sigma = genContV $ normalDistr mu sigma

Wrappers for other distributions (exponential, beta, gamma, etc.) follow the same pattern as the wrapper for normal distributions.

As a final example, here is a draw from the product of two normally-distributed random variables:

productOf2Normals :: Double -> Double -> Rand Double
productOf2Normals mu sigma = do
  x1 <- normal mu sigma
  x2 <- normal mu sigma
  return $ x1 * x2

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