Is it possible to have a function that takes a foreign function call where some of the foreign function's arguments are CString and return a function that accepts String instead?

Is it possible, you ask?

```
<lambdabot> The answer is: Yes! Haskell can do that.
```

Ok. Good thing we got that cleared up.

Warming up with a few tedious formalities:

```
{-# LANGUAGE FlexibleContexts #-}
{-# LANGUAGE FlexibleInstances #-}
{-# LANGUAGE MultiParamTypeClasses #-}
{-# LANGUAGE TypeFamilies #-}
{-# LANGUAGE UndecidableInstances #-}
```

Ah, it's not so bad though. Look, ma, no overlaps!

The problem seems to be fitting in IO functions, since everything that converts to CStrings such as newCString or withCString are IO.

Right. The thing to observe here is that there are two somewhat interrelated matters with which to concern ourselves: A correspondence between two types, allowing conversions; and any extra context introduced by performing a conversion. To deal with this fully, we'll make both parts explicit and shuffle them around appropriately. We also need to take heed of *variance*; lifting an entire function requires working with types in both covariant and contravariant position, so we'll need conversions going in both directions.

Now, given a function we wish to translate, the plan goes something like this:

- Convert the function's argument, receiving a new type and some context.
- Defer the context onto the function's result, to get the argument how we want it.
- Collapse redundant contexts where possible
- Recursively translate the function's result, to deal with multi-argument functions

Well, that doesn't sound too difficult. First, explicit contexts:

```
class (Functor f, Cxt t ~ f) => Context (f :: * -> *) t where
type Collapse t :: *
type Cxt t :: * -> *
collapse :: t -> Collapse t
```

This says we have a context `f`

, and some type `t`

with that context. The `Cxt`

type function extracts the plain context from `t`

, and `Collapse`

tries to combine contexts if possible. The `collapse`

function lets us use the result of the type function.

For now, we have pure contexts, and `IO`

:

```
newtype PureCxt a = PureCxt { unwrapPure :: a }
instance Context IO (IO (PureCxt a)) where
type Collapse (IO (PureCxt a)) = IO a
type Cxt (IO (PureCxt a)) = IO
collapse = fmap unwrapPure
{- more instances here... -}
```

Simple enough. Handling various combinations of contexts is a bit tedious, but the instances are obvious and easy to write.

We'll also need a way to determine the context given a type to convert. Currently the context is the same going in either direction, but it's certainly conceivable for it to be otherwise, so I've treated them separately. Thus, we have two type families, supplying the new outermost context for an import/export conversion:

```
type family ExpCxt int :: * -> *
type family ImpCxt ext :: * -> *
```

Some example instances:

```
type instance ExpCxt () = PureCxt
type instance ImpCxt () = PureCxt
type instance ExpCxt String = IO
type instance ImpCxt CString = IO
```

Next up, converting individual types. We'll worry about recursion later. Time for another type class:

```
class (Foreign int ~ ext, Native ext ~ int) => Convert ext int where
type Foreign int :: *
type Native ext :: *
toForeign :: int -> ExpCxt int ext
toNative :: ext -> ImpCxt ext int
```

This says that two types `ext`

and `int`

are uniquely convertible to each other. I realize that it might not be desirable to always have only one mapping for each type, but I didn't feel like complicating things further (at least, not right now).

As noted, I've also put off handling recursive conversions here; probably they could be combined, but I felt it would be clearer this way. Non-recursive conversions have simple, well-defined mappings that introduce a corresponding context, while recursive conversions need to propagate and merge contexts and deal with distinguishing recursive steps from the base case.

Oh, and you may have noticed by now the funny wiggly tilde business going on up there in the class contexts. That indicates a constraint that the two types must be equal; in this case it ties each type function to the opposite type parameter, which gives the bidirectional nature mentioned above. Er, you probably want to have a fairly recent GHC, though. On older GHCs, this would need functional dependencies instead, and would be written as something like `class Convert ext int | ext -> int, int -> ext`

.

The term-level conversion functions are pretty simple--note the type function application in their result; application is left-associative as always, so that's just applying the context from the earlier type families. Also note the cross-over in names, in that the *export* context comes from a lookup using the *native* type.

So, we can convert types that don't need `IO`

:

```
instance Convert CDouble Double where
type Foreign Double = CDouble
type Native CDouble = Double
toForeign = pure . realToFrac
toNative = pure . realToFrac
```

...as well as types that do:

```
instance Convert CString String where
type Foreign String = CString
type Native CString = String
toForeign = newCString
toNative = peekCString
```

Now to strike at the heart of the matter, and translate whole functions recursively. It should come as no surprise that I've introduced *yet another* type class. Actually, two, as I've separated import/export conversions this time.

```
class FFImport ext where
type Import ext :: *
ffImport :: ext -> Import ext
class FFExport int where
type Export int :: *
ffExport :: int -> Export int
```

Nothing interesting here. You may be noticing a common pattern by now--we're doing roughly equal amounts of computing at both the term and type level, and we're doing them in tandem, even to the point of mimicking names and expression structure. This is pretty common if you're doing type-level calculation for things involving real values, since GHC gets fussy if it doesn't understand what you're doing. Lining things up like this reduces headaches significantly.

Anyway, for each of these classes, we need one instance for each possible base case, and one for the recursive case. Alas, we can't easily have a generic base case, due to the usual bothersome nonsense with overlapping. It could be done using fundeps and type equality conditionals, but... ugh. Maybe later. Another option would be to parameterize the conversion function by a type-level number giving the desired conversion depth, which has the downside of being less automatic, but gains some benefit from being explicit as well, such as being less likely to stumble on polymorphic or ambiguous types.

For now, I'm going to assume that every function ends with something in `IO`

, since `IO a`

is distinguishable from `a -> b`

without overlap.

First, the base case:

```
instance ( Context IO (IO (ImpCxt a (Native a)))
, Convert a (Native a)
) => FFImport (IO a) where
type Import (IO a) = Collapse (IO (ImpCxt a (Native a)))
ffImport x = collapse $ toNative <$> x
```

The constraints here assert a specific context using a known instance, and that we have some base type with a conversion. Again, note the parallel structure shared by the type function `Import`

and term function `ffImport`

. The actual idea here should be pretty obvious--we map the conversion function over `IO`

, creating a nested context of some sort, then use `Collapse`

/`collapse`

to clean up afterwards.

The recursive case is similar, but more elaborate:

```
instance ( FFImport b, Convert a (Native a)
, Context (ExpCxt (Native a)) (ExpCxt (Native a) (Import b))
) => FFImport (a -> b) where
type Import (a -> b) = Native a -> Collapse (ExpCxt (Native a) (Import b))
ffImport f x = collapse $ ffImport . f <$> toForeign x
```

We've added an `FFImport`

constraint for the recursive call, and the context wrangling has gotten more awkward because we don't know exactly what it is, merely specifying enough to make sure we can deal with it. Note also the contravariance here, in that we're converting the *function* to native types, but converting the *argument* to a foreign type. Other than that, it's still pretty simple.

Now, I've left out some instances at this point, but everything else follows the same patterns as the above, so let's just skip to the end and scope out the goods. Some imaginary foreign functions:

```
foreign_1 :: (CDouble -> CString -> CString -> IO ())
foreign_1 = undefined
foreign_2 :: (CDouble -> SizedArray a -> IO CString)
foreign_2 = undefined
```

And conversions:

```
imported1 = ffImport foreign_1
imported2 = ffImport foreign_2
```

What, no type signatures? Did it work?

```
> :t imported1
imported1 :: Double -> String -> [Char] -> IO ()
> :t imported2
imported2 :: Foreign.Storable.Storable a => Double -> AsArray a -> IO [Char]
```

Yep, that's the *inferred* type. Ah, that's what I like to see.

**Edit**: For anyone who wants to try this out, I've taken the full code for the demonstration here, cleaned it up a bit, and uploaded it to github.

`hsc2hs`

? It's quite powerful, and can generate the sorts of signatures that you'd like as a preprocessing step. – sclv Aug 11 '11 at 18:29