There are two parts to what is going on here. First is how to combine the several different types of monad to run at the same time — and as has been pointed out this can be done with monad transformers — and the second is allowing each of your player types access only to the monads they need. The answer to this latter problem is type classes.
So firstly, lets examine monad transformers. A monad transformer is like a monad with an additional 'internal' monad. If this internal monad is the Identity monad (which basically does nothing) then the behaviour is just like the regular monad. For this reason monad are usually implemented as transformers and wrapped in Identity to export a normal monad. Transformer versions of monads usually append T to the end of the type, so the state monad transformer is called StateT. The only difference in the types is in the addition of the inner monad, State s a
vs Monad m => StateT s m a
. So for an example, an IO monad with an attached list of integers as state could have type StateT [Int] IO
.
Two more points are needed to properly use the transformers. First is that to effect the inner monad, you use the lift
function (which any existing monad transformer will have defined). Each call of lift moves you one down the stack of transformers. liftIO
is a special shortcut for when the IO monad is at the bottom of the stack. (And it can't be anywhere else as there is no IO transformer as you would expect.) So we could make a function that pops the head of our int list from the state part and prints it using the IO part:
popAndPrint :: StateT [Int] IO Int
popAndPrint = do
(x:xs) < get
liftIO $ print x
put xs
return x
The second point is that you need transformer versions of the running functions, one for each monad transformer in the stack. So in this case to demonstrate the effect in GHCi we need
> runStateT popAndPrint [1,2,3]
1
(1,[2,3])
If we wrapped this in an Error monad, we'd need to call runErrorT $ runStateT popAndPrint [1,2,3]
and so on.
That is a quick fire intro to monad transformers, there is plenty more available online.
However, for you this is only half of the story, as ideally you want a separation between which monads your different player types can use. The transformer approach seems to give you everything and you don't really want to give all the players access to IO just because one needs it. So how to proceed?
Each different type of player needs access to a different part of the transformer stack. So make a type class for each player that exposes only what that player needs. Each one could go in a different file. For example:
 IOPlayer.hs
class IOPlayerMonad a where
getMove :: IO Move
doSomethingWithIOPLayer :: IOPlayerMonad m => m ()
doSomethingWithIOPLayer = ...
 StatePlayer.hs
class StatePlayerMonad s a where
get :: Monad m => StateT s m s
put :: Monad m => s > StateT s m ()
doSomethingWithStatePlayer :: StatePlayerMonad s m => m ()
doSomethingWithStatePlayer = ...
 main.hs
instance IOPlayerMonad (StateT [Int] IO) where
getMove = liftIO getMoveIO
instance StatePlayerMonad s (StateT [Int] IO) where
get' = get
put' = put
This gives you control over what part of the app can access what from the overall state, and this control all happens in one file. Each individual part gets to define its interface and logic quite apart from specific implementation of the main state.
PS, you may need these at the top:
{# LANGUAGE FlexibleInstances #}
{# LANGUAGE FunctionalDependencies #}
{# LANGUAGE UndecidableInstances #}
{# LANGUAGE MultiParamTypeClasses #}
import Control.Monad.Trans.State
import Control.Monad.IO.Class
import Control.Monad

UPDATE
There has been some confusion about whether you can do it this way and still have a common interface to all players. I maintain that you can. Haskell is not object oriented and so we need to do a little bit of the dispatch plumbing ourselves, but the results are just as powerful and you get better control of the details and can still achieve full encapsulation. To better show this I have included a fully working toy example.
Here we see that the Play
class provides a single interface to a number of different player types, each with their logic in their own file and only seeing a specific interface onto the transformer stack. This interface is controlled in the Play module, and the game logic need use only this interface.
Adding a new player involves making a new file for them, designing the interface they require, adding this to the AppMonad, and wiring it up with a new tag in the Player type.
Note that all players get access to the board via the AppMonadClass class, which could be expanded to include any required common interface elements.
 Common.hs 
data Board = Board
data Move = Move
data Player = IOPlayer  StackPlayer Int
class Monad m => AppMonadClass m where
board :: m Board
class Monad m => Play m where
play :: Player > m Move
 IOPlayer.hs 
import Common
class AppMonadClass m => IOPLayerMonad m where
doIO :: IO a > m a
play1 :: IOPLayerMonad m => m Move
play1 = do
b < board
move < doIO (return Move)
return move
 StackPlayer.hs 
import Common
class AppMonadClass m => StackPlayerMonad s m  m > s where
pop :: Monad m => m s
peak :: Monad m => m s
push :: Monad m => s > m ()
play2 :: (StackPlayerMonad Int m) => Int > m Move
play2 x = do
b < board
x < peak
push x
return Move
 Play.hs 
import Common
import IOPLayer
import StackPlayer
type AppMonad = StateT [Int] (StateT Board IO)
instance AppMonadClass AppMonad where
board = return Board
instance StackPlayerMonad Int AppMonad where
pop = do (x:xs) < get; put xs; return x;
peak = do (x:xs) < get; return x;
push x = do (xs) < get; put (x:xs);
instance IOPLayerMonad AppMonad where
doIO = liftIO
instance Play AppMonad where
play IOPlayer = play1
play (StackPlayer x) = play2 x
 GameLogic.hs
import Play
updateBoard :: Move > Board > Board
updateBoard _ = id
players :: [Player]
players = [IOPlayer, StackPlayer 4]
oneTurn :: Player > AppMonad ()
oneTurn p = do
move < play p
oldBoard < lift get
newBoard < return $ updateBoard move oldBoard
lift $ put newBoard
liftIO $ print newBoard
oneRound :: AppMonad [()]
oneRound = forM players $ (\player > oneTurn player)
loop :: AppMonad ()
loop = forever oneRound
main = evalStateT (evalStateT loop [1,2,3]) Board
Control.Monad.Trans.*
to combine several Monads – viorior Sep 18 '13 at 8:15