I have a large number of in place vector functions of the type

```
f :: (M.MVector v r, PrimMonad m) =>
v (PrimState m) r -> v (PrimState m) r -> m ()
```

These functions mostly work in-place, so it is convenient to have their argument be a mutable vector so that I can compose, iterate, etc. However, at the top level, I only want to work with immutable "Haskell"/pure vectors.

Here is an example of the problem:

```
{-# LANGUAGE TypeFamilies,
ScopedTypeVariables,
MultiParamTypeClasses,
FlexibleInstances #-}
import Data.Vector.Generic as V hiding (eq)
import Data.Vector.Generic.Mutable as M
import Control.Monad.ST
import Control.Monad.Primitive
f :: (M.MVector v r, PrimMonad m) =>
v (PrimState m) r -> v (PrimState m) r -> m ()
f vIn vOut = do val <- M.read vIn 0
M.write vOut 0 val
applyFunc :: (M.MVector v r, PrimMonad m, V.Vector v' r, v ~ Mutable v') =>
(v (PrimState m) r -> v (PrimState m) r -> m ()) -> v' r -> v' r
applyFunc g x = runST $ do
y <- V.thaw x
g y y -- LINE 1
V.unsafeFreeze y
topLevelFun :: (V.Vector v r) => r -> v r
topLevelFun a =
let x = V.replicate 10 a
in applyFunc f x -- LINE 2
```

The code as written results in an error on LINE 1:

```
Could not deduce (m ~ ST s)
Expected type: ST s ()
Actual type: m ()
in the return type of g, LINE 1
```

Commenting out LINE 1 results in the error on LINE 2:

```
Ambiguous type variable `m0' in the constraint:
(PrimMonad m0) arising from a use of `applyFun'
```

I've tried a variety of explicit typing (using ScopedTypeVariables, explicit foralls, etc) but haven't found a way to fix the first error. For the LINE 1 error, it seems that `m`

should simply be inferred to be `ST s`

since I'm in a `runST`

.

For the LINE 2 error (with LINE 1 commented out), the only thing I've come up with that works is

```
class Fake m v where
kindSig :: m a -> v b c
instance Fake m v
topLevelFun :: forall m v v' r . (V.Vector v' r, M.MVector v r, PrimMonad m, Fake m v, v ~ Mutable v') => r -> v' r
topLevelFun a =
let x = V.replicate 10 a
in applyFunc (f::Transform m v r) x -- LINE 2
```

which is obviously unsatisfactory: I have to create a fake class, with an even more pointless method whose only job is to demonstrate the kinds of the class arguments. Then I create a generic instance for everything so that I can have `m`

in scope in `topLevelFun`

, so that I can add a constraint and cast `f`

. There has GOT to be a better way.

I could be doing a wide variety of things wrong here, so any suggestions would be helpful.

`applyFunc`

promises to work for any`PrimMonad m`

thecallerchooses, but then`runST $ do ...`

forces`m`

to be`ST s`

. You can fix that by stating that`g`

works for any`PrimMonad m`

youchoose, or just by restricting`m`

to be`ST s`

. Here's the code. If this indeed does answer your problem, let me know and I'll write down an answer. – Vitus Jan 20 '13 at 1:14`applyFunc`

should be (forall m. (PrimMonad m) => ...) Many thanks! Rank2Types pulled through in the end. – Eric Jan 20 '13 at 1:26`RankNTypes`

in`.ghci`

. By the way, I believe`Rank2Types`

is being deprecated in favour of`RankNTypes`

. – Vitus Jan 20 '13 at 1:39pairor not. The actual type of applyFunc is:`(M.MVector v r, V.Vector v' r, v ~ Mutable v') => (forall m . (PrimMonad m) => ((v (PrimState m) r -> v (PrimState m) r -> m ()), Int)) -> v' r -> v' r`

. However, simply adding this pair (to keep track of size) results in the new error`couldn't match type m0 with 'ST s'`

Why would adding the pair cause this? A GHC issue? – Eric Jan 20 '13 at 1:55`applyFunc`

is:`(M.MVector v r, V.Vector v' r, v ~ Mutable v') => ((forall m . (PrimMonad m) => ((v (PrimState m) r -> v (PrimState m) r -> m ()), Int) -> v' r -> v' r`

. With ImpredicativeTypes, this compiles. Also, if this is a reasonable solution, Rank2/NTypes is no longer needed. – Eric Jan 20 '13 at 2:12