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I understand that the ST monad is something like a little brother of IO, which in turn is the state monad with added RealWorld magic. I can picture states, I can picture that RealWorld is somoehow put into IO, but every time I write a type signature, the s of the ST monad confuses me, e.g. ST s (STArray s a b). How does the s work there? Is it just used to build up some artificial data dependency between computations, without actually being referrable (like states in the state monad for example) due to the forall?

I'm just throwing things out there, and would really appreciate someone more knowledgeable explain it to me better.

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If you search for "ST monad", there's an entry that kind of answers my question as a side answer to a question about STArrays. Not sure if my question here's a duplicate now. stackoverflow.com/questions/8197032/… –  David Sep 18 '12 at 0:00
It's so tempting to simply answer "Yes." to your question. :) –  AndrewC Sep 18 '12 at 0:30
I guess adding a link to the question and closing it would a) make searching for this easier in the future, and b) save some answerers some time. –  David Sep 18 '12 at 0:33
I'll point you to my writeup on rank-2 types, which should help you understand the 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. –  Luis Casillas Sep 18 '12 at 0:58
You can write 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. –  applicative Sep 27 '12 at 2:27
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3 Answers

up vote 24 down vote accepted

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.

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Could you "break" the safety of ST by using realWorld# directly in client code, to mimic runSTRep ? It's a bad idea of course, but I'm wondering what the protections are, besides realworld# being an obviously unsafe value to use in a program. hackage.haskell.org/package/base-… –  misterbee Jan 8 at 15:03
@misterbee, no, you can't get realWorld# at all. It's too magical. To be precise, I don't think it exists as a value at all. In any case, what would you be able to do with that that you couldn't do with unsafePerformIO? –  dfeuer Jan 16 at 0:16
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The s is just a hack that makes the type system stop you doing things which would be unsafe. It doesn't "do" anything at run-time; it just makes the type checker reject programs that do dubious things. (It is a so-called phantom type, a thing with only exists in the type checker's head, and doesn't affect anything at run-time.)

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St is kind of confusing in haskell for beginners due to that icky runST stuff. Here it is in python, if it helps.

think of ST = reader + writer.

let's start with writer, it's easiest:

def unit(v): return (v, [])

def bind(mv, mf):
    val, out = mv[0], mv[1]
    r_mv = mf(val)
    r_out = r_mv[1]
    final_out = out + r_out if r_out else out
    return (r_mv[0], final_out)

def addOne(x):
    val = x+1
    logmsg = "x+1==%s" % val 
    return (val, [logmsg])

>>> addThreeLogged = m_chain(addOne, addOne, addOne)
>>> map(addThreeLogged, [10,20,30])
[(13, ['x+1==11', 'x+1==12', 'x+1==13']),
 (23, ['x+1==21', 'x+1==22', 'x+1==23']),
 (33, ['x+1==31', 'x+1==32', 'x+1==33'])]


def unit(v): return lambda env: v

def bind(mv, mf):
    def _(env):
        val = mv(env)
        return mf(val)(env)
    return _

def read(key):
    def _(env):
        return env[key]
    return _

>>> mv = read('a')
<a function of env>
>>> mv({'a': 7})
>>> mv({'a': 10, 'b': 3})

>>> computation = bind( read('a'),  lambda a:
                  bind( read('b'),  lambda b:
                        unit( a+b ))
<a function of env>
>>> computation({'a': 7, 'b': 3}) 
>>> computation({'a': 42, 'b': 1})

finally, ST (aka environment) is the combination of reader and writer:

def unit(self, v):
    return lambda env: (v, env)

def bind(self, mv, mf):
    def _env_mv(env):
        val, newenv = mv(env)
        return mf(val)(newenv)
    return _env_mv

>>> write('a', 2)
<a function of env>
>>> myenv = {'a': 999, 'b': 999} 
>>> write('a', 2)(myenv)
(None, {'a': 2, 'b': 999})
>>> read('a')(myenv)
(999, {'a': 999, 'b': 999})

>>> computation = bind( read('a'),        lambda a:
                  bind( read('b'),        lambda b:
                  bind( write('c', a+b),  lambda _:
                        unit(c+1)         )))
<a function of env>
>>> computation({'a': 7, 'b': 3})
(11, {'a': 7, 'b': 3, 'c': 10})
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-1; state transformers != reader + writer -- since the reader and writer types are independent, you can't implement a type-correct update :: (s -> s) -> ST s (). –  Matt Fenwick Mar 20 '13 at 2:58
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