You can write a function, say *makeBernoulliSeq*, that takes the probability and a trial count, and gives you a monadic action returning a list of boolean values.

That way, it is easy to combine this with other computations requiring random numbers.

Sample code:

```
{-# LANGUAGE ScopedTypeVariables #-}
import System.Random
import Control.Monad.Random
makeBernoulliSeq :: MonadRandom mr => Double -> Int -> mr [Bool]
makeBernoulliSeq proba count =
let act1 = getRandom -- get one value between 0.0 and 1.0
actN = sequence (replicate count act1)
in do
xs :: [Double] <- actN -- "count" values inside [0.0 --> 1.0)
return $ map (proba >) xs
main = do
let count = 10000 -- number of trials
proba = 0.25 -- probability of success
randomSeed = 424344 -- ideally passed from command line argument
gen0 = mkStdGen randomSeed -- for reproducibility of random numbers
(bList, gen1) = runRand (makeBernoulliSeq proba count) gen0
-- How many True values did we get ?
successCount = length $ filter id bList
expected = floor $ proba * (fromIntegral count)
putStrLn $ (show successCount) ++ " successes out of " ++
(show expected) ++ " expected"
```

## Program output:

```
2468 successes out of 2500 expected
```

**Note:** I generally avoid calling *getRandoms* or similar functions that return an unlimited supply of random values. This is because they involve a call to *split* the random number generator, and it seems to me that the standard code for *split* is a bit fishy. For the standard generator, the first value returned by `getRandoms`

differs from the single value returned by `getRandom`

.

"How do i a get a true random seed..?"You simply can't inside pure logic. That's the reason why you are expected to do all your random thingies by`randomIO :: System.Random.Random a => IO a`

inside the`IO`

monad.`RandomGen g`

.`list2 = go list where go (x:y:zs) = x&&y : go zs`

since the AND of two uniformly distributed bits gives what you want. This does not generalize too well, though.