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
```

`PrimState`

and`PrimMonad`

in the function signatures. Whatever happened to`System.Random.RandomGen`

?`probable`

? Seems to have some simple examples, works with distributions from statistics, updated recently.`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.)`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?4more comments