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I have haskell code which needs to interface with a c library somewhat like this:

typedef struct MyObject *MyObject;
MyObject newMyObject(void);
void myObjectDoStuff(MyObject myObject);
void freeMyObject(MyObject myObject);

The original ffi code wraps all of these functions as pure functions using unsafePerformIO. This has caused bugs and inconsistencies because the sequencing of the operations is undefined.

What I am looking for is a general way of dealing with objects in haskell without resorting to doing everything in IO. Ie what would be nice is something where I can do something like:

myPureFunction :: String -> Int
-- create object, call methods, call destructor, return results

Is there a nice way to achieve this?

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Well, I guess wrap them as IO functions, chain them together in whatever fashion you need and then do unsafePerformIO on the resulting action? – Joker_vD Nov 19 '13 at 4:37
Is there a different monad other than resorting to IO which I could use which would achieve the same effect? Because the way I see it this isn't IO per se, it's mutable state. I have a feeling I could use a state monad or something but I'm nervous about the order being rearranged... – grasevski Nov 19 '13 at 4:45
@grasevski IO is really a monomorphic state monad. This would work. – jozefg Nov 19 '13 at 4:46
@grasevski This is really what IO was built for. Basically any function that interacts with the computer (i.e. doesn't just calculate something) has to access a platform specific API. Printing to STDOUT means calling the platform specific kernel function that actually prints it, it isn't a Haskell "primitive". The encouraged action is to use IO when accessing the outside world. If you're 110% sure that the functions you access don't have side effects, then go ahead and wrap them in unsafePerformIO, but otherwise stick to the IO monad. That's my $0.02 – bheklilr Nov 19 '13 at 4:57
This is mostly semantics, but the c code doesn't really touch the outside world, it is just functions which change mutable state, given as input. This is like in haskell with STRef etc. I was hoping that, like how one can use STRef rather than IORef for mutable state in haskell, there is some analog in my situation. – grasevski Nov 19 '13 at 5:02

The idea is to keep passing a baton from each component to force each component to be evaluated in sequence. This is basically what the state monad is (IO is really a weird state monad. Kinda).

{-# LANGUAGE GeneralizedNewtypeDeriving #-}
import Control.Monad.State

data Baton = Baton -- Hide the constructor!

newtype CLib a = CLib {runCLib :: State Baton a} deriving Monad

And then you just string operations together. Injecting them into the CLib monad will mean they're sequenced. Essentially, you're faking your own IO, in a more unsafe way since you can escape.

Then you must ensure that you add construct and destruct to the end of all CLib chains. This is easily done by exporting a function like

clib :: CLib a -> a
clib m = runCLib $ construct >> m >> destruct

The last big hoop to jump through is to make sure that when you unsafePerformIO whatever's in construct, it actually gets evaluated.

Frankly, this is all kinda pointless since it already exists, battle proven in IO. Instead of this whole elaborate process, how about just

construct :: IO Object
destruct  :: IO ()
runClib :: (Object -> IO a) -> a
runClib = unsafePerformIO $ construct >>= m >> destruct

If you don't want to use the name IO

newtype CLib a = {runCLib :: IO a} deriving(Functor, Applicative, Monad)
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Would it still work if I replaced IO with ST? So that I can enforce that the IO code is separate from this. Otherwise someone could easily come along and put a bunch of putstrlns etc in my code and make it harder to test. – grasevski Nov 19 '13 at 5:18
@grasevski Not really. You original operations are already inside IO, that's the whole point here. You don't really want ST because you're not trying to offer mutable fields and junk, it's orthogonal. I'd suggest creating a custom wrapper like I showed in my last line of code. Basically you're attempting to avoid unsafePerformIO-ing individual operations and instead doing it to one complete computation. – jozefg Nov 19 '13 at 5:19
@jozefg you may need to use Control.Monad.State.Strict for this. Also, you don't even need a separate baton, you can have the state be Ptr MyObject and pass that in to every function at each step. Although the pointer shouldn't change, so you could instead use a 'Reader'. Of course there are a lot of ways to accomplish this... – John L Nov 19 '13 at 7:08
What I want is to isolate changes to the mutable c state in a monad separate from the rest of IO. This does not achieve this because it is leaky abstraction. What would be good is to have my FFI module export some functions like clib :: CLib a -> a, clibX :: CLib Int, clibY :: Int -> CLib (), etc. I attempted this with unsafeLocalState and Control.Monad.State.Strict but it doesnt work for some reason – grasevski Nov 20 '13 at 3:47
up vote 1 down vote accepted

My final solution. It probably has subtle bugs that I haven't considered, but it is the only solution so far which has met all of the original criteria:

  • Strict - all operations are sequenced correctly
  • Abstract - the library is exported as a stateful monad rather than a leaky set of IO operations
  • Safe - the user can embed this code in pure code without using unsafePerformIO and they can expect the result to be pure

Unfortunately the implementation is a bit complicated.


// Stack.h
typedef struct Stack *Stack;
Stack newStack(void);
void pushStack(Stack, int);
int popStack(Stack);
void freeStack(Stack);

c2hs file:

{-# LANGUAGE ForeignFunctionInterface, GeneralizedNewtypeDeriving #-}
module CStack(StackEnv(), runStack, pushStack, popStack) where
import Foreign.C.Types
import Foreign.Ptr
import Foreign.ForeignPtr
import qualified Foreign.Marshal.Unsafe
import qualified Control.Monad.Reader
#include "Stack.h"
{#pointer Stack foreign newtype#}

newtype StackEnv a = StackEnv
 (Control.Monad.Reader.ReaderT (Ptr Stack) IO a)
 deriving (Functor, Monad)

runStack :: StackEnv a -> a
runStack (StackEnv (Control.Monad.Reader.ReaderT m))
 = Foreign.Marshal.Unsafe.unsafeLocalState $ do
  s <- {#call unsafe newStack#}
  result <- m s
  {#call unsafe freeStack#} s
  return result

pushStack :: Int -> StackEnv ()
pushStack x = StackEnv . Control.Monad.Reader.ReaderT $
 flip {#call unsafe pushStack as _pushStack#} (fromIntegral x)

popStack :: StackEnv Int
popStack = StackEnv . Control.Monad.Reader.ReaderT $
 fmap fromIntegral . {#call unsafe popStack as _popStack#}

test program:

-- Main.hs
module Main where
import qualified CStack
main :: IO ()
main = print $ CStack.runStack x where
 x :: CStack.StackEnv Int
 x = pushStack 42 >> popStack


$ gcc -Wall -Werror -c Stack.c
$ c2hs CStack.chs
$ ghc --make -Wall -Werror Main.hs Stack.o
$ ./Main
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