What you want is `StateT s IO (String, Bool)`

, where `StateT`

is provided by both `Control.Monad.State`

(from the `mtl`

package) and `Control.Monad.Trans.State`

(from the `transformers`

package).

This general phenomenon is called a monad transformer, and you can read a great introduction to them in Monad Transformers, Step by Step.

There are two approaches to defining them. One of them is found in the `transformers`

package which uses the `MonadTrans`

class to implement them. The second approach is found in the `mtl`

class and uses a separate type-class for each monad.

The advantage of the `transformers`

approach is the use of a single type-class to implement everything (found here):

```
class MonadTrans t where
lift :: Monad m => m a -> t m a
```

`lift`

has two nice properties which any instance of `MonadTrans`

must satisfy:

```
(lift .) return = return
(lift .) f >=> (lift .) g = (lift .) (f >=> g)
```

These are the functor laws in disguise, where `(lift .) = fmap`

, `return = id`

and `(>=>) = (.)`

.

The `mtl`

type-class approach has its benefits, too, and some things can only be cleanly solved using the `mtl`

type-classes, however the disadvantage is then that each `mtl`

type-class has its own set of laws you have to remember when implement instances for it. For example, the `MonadError`

type-class (found here)is defined as:

```
class Monad m => MonadError e m | m -> e where
throwError :: e -> m a
catchError :: m a -> (e -> m a) -> m a
```

This class comes with laws, too:

```
m `catchError` throwError = m
(throwError e) `catchError` f = f e
(m `catchError` f) `catchError` g = m `catchError` (\e -> f e `catchError` g)
```

These are just the monad laws in disguise, where `throwError = return`

and `catchError = (>>=)`

(and the monad laws are the category laws in disguise, where `return = id`

and `(>=>) = (.)`

).

For your specific problem, the way you would write your program would be the same:

```
do
-- get the number of games from the command line (already written)
results <- mapM (\game -> playGame game getStdGen) [1..numberOfGames]
```

... but when you write your `playGame`

function it would look either like:

```
-- transformers approach :: (Num s) => StateT s IO ()
do x <- get
y <- lift $ someIOAction
put $ x + y
-- mtl approach :: (Num s, MonadState s m, MonadIO m) => m ()
do x <- get
y <- liftIO $ someIOAction
put $ x + y
```

There are more differences between the approaches that become more apparent when you start stacking more than one monad transformer, but I think that's a good start for now.

`RandT`

from the MonadRandom package. – Daniel Wagner Jun 6 '12 at 19:35