This is a Foolish Task
It's rather silly to perform direct translation of C to Haskell. I've done it for pay before and it doesn't go smoothly or quickly. It is much better to describe the task and implement it in an idiomatic style in the target language. You would be more likely to get quality answers by providing an English description of the algorithm.
Please Post Compilable Code
When you post questions, please be sure it compiles!
Learn Haskell not How to write C in Haskell
How things are done in different languages can vary drastically, especially when you cross a divide such as from imperative to functional, or mutable to immutable, or strict to lazy, or implicit casting to explicit, or manually managed memory to garbage collected. You are crossing all these divides.
If your task is to learn Haskell, you are starting at the wrong point. If you're task is to learn mutable vectors/arrays in Haskell then you need to know more of the fundamentals to appreciate the nuances. If your task is to taunt Haskell for having poor support of arrays then you would have had a really easy time of it before Roman came along and made the Vector package - this is my way of saying: don't look at Haskell
Arrays only look at
OK OK, What's the Solution?
We'll use the
Vector package for our Arrays and the
ST monad for mutable operations (your first bullet point):
import qualified Data.Vector.Unboxed.Mutable as M
import qualified Data.Vector.Unboxed as V
You're main function takes two vectors and returns a float. We start by obtaining mutable references to the arrays using
thaw and use a simple fold to allow us to flip our array references.
someFunc :: V.Vector Float -> V.Vector Float -> Float
someFunc arrA arrB = runST $ do
-- Obtain mutable copies of the arrays
mA <- V.thaw arrA
mB <- V.thaw arrB
(mA', mB') <- foldM op (mA, mB) [1..n-1] -- for(i = 1 ; i < n; i++)
M.read mA' 0
n = min (V.length arrA) (V.length arrB)
The inner for loop is contained in
op. It just performs some simple reads from the
arrays and writes a new value. It has to return the two arrays in a tuple; the tuple is flipped on every iteration to obtain the same semantics of your mutable pointers (your second point):
op (mA, mB) i = do
forM_ [0..n-i-1] $ \j -> do
v1 <- M.read mA j
v2 <- M.read mB (j+1)
M.write mB j (someFn i j v1 v2)
return (mB, mA)
Consistent with your third point, the inner loop bound changes based on the outter loop.
Just so we can compile a runable program we'll include main:
someFn i j f1 f2 = f1 + fromIntegral i + fromIntegral j - f2
main = print $ someFunc (V.fromList [1..10]) (V.fromList [0..9])
This is for educational purposes only. I haven't tested this, it should be morally the same as your C but might be off by one in a loop or have other trivial differences.