I'm assuming that the goal is to implement an algorithm as follows: we have a random generator of some sort which we can think of as somehow producing a stream of random values

```
import Pipes
prng :: Monad m => Producer Int m r
-- produces Ints using the effects of m never stops, thus the
-- return type r is polymorphic
```

We would like to modify this PRNG via a shuffle box. Shuffle boxes have a mutable state `Box`

which is an array of random integers and they modify a stream of random integers in a particular way

```
shuffle :: Monad m => Box -> Pipe Int Int m r
-- given a box, convert a stream of integers into a different
-- stream of integers using the effects of m without stopping
-- (polymorphic r)
```

`shuffle`

works on an integer-by-integer basis by indexing into its `Box`

by the incoming random value modulo the size of the box, storing the incoming value there, and emitting the value which was previously stored there. In some sense it's like a stochastic delay function.

So with that spec let's get to a real implementation. We want to use a mutable array so we'll use the `vector`

library and the `ST`

monad. `ST`

requires that we pass around a phantom `s`

parameter that matches throughout a particular `ST`

monad invocation, so when we write `Box`

it'll need to expose that parameter.

```
import qualified Data.Vector.Mutable as Vm
import Control.Monad.ST
data Box s = Box { sz :: Int, vc :: Vm.STVector s Int }
```

The `sz`

parameter is the size of the `Box`

's memory and the `Vm.STVector s`

is a mutable `ST`

`Vector`

linked to the `s`

`ST`

thread. We can immediately use this to build our shuffle algorithm, now knowing that the `Monad`

`m`

must actually be `ST s`

.

```
import Control.Monad
shuffle :: Box s -> Pipe Int Int (ST s) r
shuffle box = forever $ do -- this pipe runs forever
up <- await -- wait for upstream
next <- lift $ do let index = up `rem` sz box -- perform the shuffle
prior <- Vm.read (vc box) index -- using our mutation
Vm.write (vc box) index up -- primitives in the ST
return prior -- monad
yield next -- then yield the result
```

Now we'd just like to be able to attach this `shuffle`

to some `prng`

`Producer`

. Since we're using `vector`

it's nice to use the high-performance `mwc-random`

library.

```
import qualified System.Random.MWC as MWC
-- | Produce a uniformly distributed positive integer
uniformPos :: MWC.GenST s -> ST s Int
uniformPos gen = liftM abs (MWC.uniform gen)
prng :: MWC.GenST s -> Int -> ST s (Box s)
prng gen = forever $ do
val <- lift (uniformPos gen)
yield val
```

Notice that since we're passing the PRNG seed, `MWC.GenST s`

, along in an `ST s`

thread we don't need to catch modifications and thread them along as well. Instead, `mwc-random`

uses a mutable `STRef s`

behind the scenes. Also notice that we modify `MWC.uniform`

to return positive indices only as this is required for our indexing scheme in `shuffle`

.

We can also use `mwc-random`

to generate our initial box.

```
mkBox :: MWC.GenST s -> Int -> ST s (Box s)
mkBox gen size = do
vec <- Vm.replicateM size (uniformPos gen)
return (Box size vec)
```

The only trick here is the very nice `Vm.replicateM`

function which effectively has the constrained type

```
Vm.replicateM :: Int -> ST s Int -> Vm.STVector s Int
```

where the second argument is an `ST s`

action which generates a new element of the vector.

Finally we have all the pieces. We just need to assemble them. Fortunately, the modularity we get from using `pipes`

makes this trivial.

```
import qualified Pipes.Prelude as P
run10 :: MWC.GenST s -> ST s [Int]
run10 gen = do
box <- mkBox gen 1000
P.toListM (prng gen >-> shuffle box >-> P.take 10)
```

Here we use `(>->)`

to build a production pipeline and `P.toListM`

to run that pipeline and produce a list. Finally we just need to execute this `ST s`

thread in `IO`

which is also where we can create our initial `MWC.GenST s`

seed and feed it to `run10`

using `MWC.withSystemRandom`

which generates the initial seed from, as it says, `SystemRandom`

.

```
main :: IO ()
main = do
result <- MWC.withSystemRandom run10
print result
```

And we have our pipeline.

```
*ShuffleBox> main
[743244324568658487,8970293000346490947,7840610233495392020,6500616573179099831,1849346693432591466,4270856297964802595,3520304355004706754,7475836204488259316,1099932102382049619,7752192194581108062]
```

Note that the actual operations of these pieces is not terrifically complex. Unfortunately, the types in `ST`

, `mwc-random`

, `vector`

, and `pipes`

are all each individually *highly* generalized and thus can be quite burdensome to comprehend at first. Hopefully the above, where I've deliberately weakened and specialized nearly every type to this exact problem, will be much easier to follow and provide a little bit of intuition for how each of these wonderful libraries works individually and together.

`mwc-random`

and`vector`

's mutable Vectors, but that machinery is quite a bit more complex than what you have here. – J. Abrahamson Jan 19 at 4:37`vector`

,`mwc-random`

and`pipes`

. I believe it does what you want and, if you handwave around some of the highly generic types, it's nottoohard to read. – J. Abrahamson Jan 19 at 4:42