You can't have a pure function that returns a distinct number each time. Its output depends on its previous invocations, not on its arguments only. But you can create a monad that carries the set of numbers generated so far, and retries generating a random number until it finds one that hasn't been generated so far. For the following example I used the MonadRandom package.

```
import Control.Monad
import Control.Monad.Random
import Control.Monad.State
import Data.IntSet (IntSet)
import qualified Data.IntSet as IS
import System.Random (getStdGen)
type RandDistinct g a = StateT IntSet (Rand g) a
evalDistinct :: RandomGen g => RandDistinct g a -> g -> a
evalDistinct k = evalRand (evalStateT k IS.empty)
```

The above type uses `StateT`

to enhance a random number generator to remember the set of generated numbers so far. When we want to evaluate a computation in this monad, we start with an empty set and evaluate the inside computation with `evalRand`

.

Now we can write a function that returns a distinct number each time:

```
nextDistinct :: RandomGen g => (Int,Int) -> RandDistinct g Int
nextDistinct range = loop
where
-- Loop until we find a number not in the set
loop = do
set <- get
r <- getRandomR range
if IS.member r set
then loop -- repeat
else put (IS.insert r set) >> return r
```

And test how it works:

```
main = getStdGen >>= print . evalDistinct (replicateM 50 $ nextDistinct (10, 99))
```

Note that `nextDistinct`

uses a simple strategy - retry generating a new number if it already exists in the set. This works fine as long as the number of collisions is low.