I'm trying to write a recursive function that mutates a Data.Vector.Unboxed.Mutable 'Vector', though the question applies to any monadic code, I think.

As a contrived example:

```
import Data.Vector.Unboxed as U
import Data.Vector.Unboxed.Mutable as M
import Control.Monad
import Control.Monad.ST
import Control.Monad.Primitive
f :: U.Vector Int -> U.Vector Int
f x = runST $ do
y <- U.thaw x
add1 y 0
U.freeze y
add1 :: (PrimMonad m) => MVector (PrimState m) Int -> Int -> m()
add1 v i | i == M.length v = return ()
add1 v i = do
c <- M.unsafeRead v i
M.unsafeWrite v i (c + 1)
add1 v (i+1)
```

However, v does not change in each recursive call. I would like to be able to remove v as a parameter to the function and inline 'add1' into f, but I need 'y' to be in scope.

I can get one step closer is by changing add1 (and keeping f the same) so that v is not passed in the recursion:

```
add1 :: (PrimMonad m) => MVector (PrimState m) Int -> m()
add1 v = do add1_ 0
where len = M.length v
add1_ i | i == len = do return ()
add1_ i = do
x <- M.unsafeRead v i
M.unsafeWrite v i (x + 1)
add1_ (i+1)
```

What I would really like is to totally inline add1 though. Here's a solution that doesn't quite compile yet:

```
f x = let len = U.length x
y = U.thaw x
add1 i | i == len = return ()
add1 i = do
y' <- y
c <- M.unsafeRead y' i
M.unsafeWrite y' i (c+1)
add1 (i+1)
in runST $ do
add1 0
y' <- y
U.freeze y'
```

GHC errors:

```
couldn't match type 'm0' with 'ST s'
couldn't match type 's' with 'PrimState m0'
```

Errors aside, this isn't optimal yet: I don't want to have to do (y' <- y) in every do statement (especially when add1 is recursive). I'd really like y' (the 'non-monadic' version of y) to just be in scope. Is there any way to do this?

(I apologize if I am horribly misusing monads in some way)