The `s`

keeps objects inside the `ST`

monad from leaking to the outside of the `ST`

monad.

```
-- This is an error... but let's pretend for a moment...
let a = runST $ newSTRef (15 :: Int)
b = runST $ writeSTRef a 20
c = runST $ readSTRef a
in b `seq` c
```

Okay, this is a type error (which is a good thing! we don't want `STRef`

to leak outside the original computation!). It's a type error because of the extra `s`

. Remember that `runST`

has the signature:

```
runST :: (forall s . ST s a) -> a
```

This means that the `s`

on the computation that you're running has to have no constraints on it. So when you try to evaluate `a`

:

```
a = runST (newSTRef (15 :: Int) :: forall s. ST s (STRef s Int))
```

The result would have type `STRef s Int`

, which is wrong since the `s`

has "escaped" outside of the `forall`

in `runST`

. Type variables always have to appear on the inside of a `forall`

, and Haskell allows implicit `forall`

quantifiers everywhere. There's simply no rule that allows you to to meaningfully figure out the return type of `a`

.

**Another example with **`forall`

: To clearly show why you can't allow things to escape a `forall`

, here is a simpler example:

```
f :: (forall a. [a] -> b) -> Bool -> b
f g flag =
if flag
then g "abcd"
else g [1,2]
> :t f length
f length :: Bool -> Int
> :t f id
-- error --
```

Of course `f id`

is an error, since it would return either a list of `Char`

or a list of `Int`

depending on whether the boolean is true or false. It's simply wrong, just like the example with `ST`

.

**On the other hand,** if you didn't have the `s`

type parameter then everything would type check just fine, even though the code is obviously pretty bogus.

**How ST actually works:** Implementation-wise, the `ST`

monad is actually the same as the `IO`

monad but with a slightly different interface. When you use the `ST`

monad you actually get `unsafePerformIO`

or the equivalent, behind the scenes. The reason you can do this safely is because of the type signature of all `ST`

-related functions, especially the part with the `forall`

.

`ST`

monad as well. Once you understand how rank-2 types can control "who chooses" the type used for a type variable, that should help you understand how`ST`

operations use rank-2 to prevent its computations from being used illicitly.`a :: ST Int Int; a = return 2`

`ST`

is a perfectly ordinary state monad, except it uses an unboxed pair as output of the state function`State# s -> (# State# s, a #)`

which makes it impractical to deal with. The mystery is entirely in`runST`

which has a rank 2 type, though ST itself isnt one.