No, it's not possible; `ST`

doesn't have those semantics. The monad is `ST s`

, and not `ST s (STUArray s a)`

. `ST s`

is just a monad for keeping track of mutable state; which structures you choose to allocate and use inside a single `ST`

region are up to you. If you have a bunch of computations which all operate on the same `STUArray`

, you can use `ReaderT`

:

```
type Hasher s = ReaderT (STUArray s Int Word32) (ST s)
padFixed :: Hasher ()
padFixed = do
block <- ask
unsafeWrite block 5 0x80000000
unsafeWrite block 15 160
```

The `Reader r`

monad is just a wrapper around `r ->`

; a value of type `Reader r a`

is just a function `r -> a`

. This is essentially a way to compute `a`

while having access to a value of type `r`

. The `ReaderT r`

monad transformer just allows you to provide access to a variable of type `r`

to an arbitrary monadic computation; thus, `ReaderT (STUArray s Int Word32) (ST s)`

is an `ST s`

computation which has access to some array. Note that you don't need to return the array from `padFixed`

; the monad bind will handle all of that.

This'll be a little bit of a pain to write, since we'll have to keep `ask`

ing for the array. Luckily, we can write some combinators to handle this for us:

```
{-# LANGUAGE RankNTypes, GeneralizedNewtypeDeriving #-}
import Data.Word
import Control.Applicative
import Control.Monad.Reader
import Control.Monad.ST
import Data.Array.ST (STUArray, runSTUArray)
import qualified Data.Array.Base as A
import Data.Array.Unboxed (UArray)
newtype Hasher s a =
Hasher { getHasher :: ReaderT (STUArray s Int Word32) (ST s) a }
deriving (Functor, Applicative, Monad, MonadReader (A.STUArray s Int Word32))
hasherToST :: Hasher s () -> (Int,Int) -> ST s (STUArray s Int Word32)
hasherToST (Hasher r) bounds = do
block <- A.newArray bounds 0
runReaderT r block
return block
runHasher :: (forall s. Hasher s ()) -> (Int,Int) -> UArray Int Word32
runHasher h bounds = runSTUArray $ hasherToST h bounds
-- Perhaps private to this module, perhaps not
liftST :: ST s a -> Hasher s a
liftST = Hasher . lift
----- We can lift the functions which act on an STUArray -----
getBounds :: Hasher s (Int,Int)
getBounds = liftST . A.getBounds =<< ask
-- I'd recommend against removing the `unsafe` from the name; this function
-- could segfault, after all.
unsafeReadBlock :: Int -> Hasher s Word32
unsafeReadBlock i = do
block <- ask
liftST $ A.unsafeRead block i
unsafeWriteBlock :: Int -> Word32 -> Hasher s ()
unsafeWriteBlock i x = do
block <- ask
liftST $ A.unsafeWrite block i x
----- And then, perhaps in a separate module: -----
padFixed :: Hasher s ()
padFixed = do
unsafeWriteBlock 5 0x80000000
unsafeWriteBlock 15 160
```

(Note that I couldn't inline `hasherToST`

inside of `runHasher`

, probably because of the higher-rank types blocking inference.)

Basically, we wrap the `ReaderT (STUArray s Int Word32) (ST s)`

into a `newtype`

instead of a type synonym, and lift some basic array primitives up to work on the always-available block. You don't even need to derive `MonadReader`

for the `Hasher`

type if you don't want, as long as you lift all the necessary functions. But once you've done this, your hashing code can talk about the array implicitly.