Let's start at the beginning:

```
type Rand a = State StdGen a
```

This line tells you that `Rand a`

is a type synonym for a `State`

type, whose state is given by `StdGen`

and whose eventual value is of type `a`

. This will be used to store the state of the random number generator between each request for a random number.

The code for `getRandom`

can be converted into do notation:

```
getRandom :: (Random a) => Rand a
getRandom = do
r <- get -- get the current state of the generator
let (a,g) = random r in do -- call the function random :: StdGen -> (a, StdGen)
put g -- store the new state of the generator
return a -- return the random number that was generated
```

The `runRand`

function takes an initial seed `n`

and a value `r`

of type `Rand a`

(which, remember, is just a synonym for `State StdGen a`

). It creates a new generator with `mkStdGen n`

and feeds it to `evalState r`

. The function `evalState`

just evaluates the return value of a `State s a`

type, ignoring the state.

Again, we can convert `runRandIO`

into `do`

notation:

```
runRandIO :: Rand a -> IO a
runRandIO r = do
rnd <- randomIO -- generate a new random number using randomIO
return (runRand rnd r) -- use that number as the initial seed for runRand
```

Finally, `getRandoms`

takes a number `n`

representing the number of random values that you want to generate. It builds a list `[1..n]`

and applies `getRandom`

to the list. Note that the actual values in `[1..n]`

aren't used (you can tell because the lambda function starts with `\_ -> ...`

). The list is just there to have something with the correct number of elements. Since `getRandom`

returns a monadic value, we use `mapM`

to map over the list, which causes the state (i.e. `StdGen`

) to be threaded correctly through each of the calls to `getRandom`

.