So if all you want is a function

```
randomPairs :: IO [(Int, Int)]
```

then we can do something like

```
randomList :: IO [Int]
randomList = randomRs (-10, 10) `fmap` newStdGen
randomPairs = ??? randomList randomList
```

where `???`

takes two `IO [Int]`

and "zips" them together to form a `IO [(Int, Int)]`

. We now turn to hoogle and query for a function `[a] -> [a] -> [(a, a])`

and we find a function `zip :: [a] -> [b] -> [(a, b)]`

we now just need to "lift" `zip`

into the `IO`

monad to work with it across `IO`

lists so we end up with

```
randomPairs = liftM2 zip randomList randomList
```

or if we want to be really fancy, we could use applicatives instead and end up with

```
import Control.Applicative
randomPairs = zip <$> randomList <*> randomList
```

But judging from your `randomNumber`

funciton, you really just want *one* pair. The idea is quite similar. Instead of generating a list, we generate just one random number with `randomRIO (-10, 10)`

and lift `(,) :: a -> b -> (a, b)`

resulting in

```
randomPair = (,) <$> randomRIO (-10, 10) <*> randomRIO (-10, 10)
```

Finally, the `State`

data constructor went away a while ago because the MTL moved from having separate `State`

and `StateT`

types to making `State`

a type synonym. Nowadays you need to use the lowercase `state :: (s -> (s, a)) -> State s a`

To clarify, my final code is

```
import System.Random
import Control.Monad
randomList :: IO [Int]
randomList = randomRs (-10, 10) `fmap` newStdGen
pairs :: IO [(Int, Int)]
pairs = liftM2 zip randomList randomList
somePairs n = take n `fmap` pairs
main = somePairs 10 >>= print
```