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See my earlier question about composing opencv operators for an explanation of what is going on.

I thought up a new interface that allows to compose destructive binary operations in a kind of composable way:

newtype IOP a b = IOP (a -> IO b)

instance Category IOP where
    id = IOP return
    (IOP f) . (IOP g)  = IOP $ g >=> f

(&#&) :: IOP (Image c d) e -> IOP (Image c d) f 
             -> IOP (Image c d) (Image c d,Image c d)
(IOP f) &#& (IOP g) = IOP $ op
        op i = withClone i $ \cl -> (f i >> g cl >> return (i,cl))

runIOP (IOP f) img = withClone img f 

With this I can easily express the 'subtract the gaussian operator':

subtract  :: IOP (Image c d, Image c1 d1) (Image c d)
mulScalar :: d -> IOP (Image c d) (Image c d)
subtractScalar :: d -> IOP (Image c d) (Image c d)
gaussian  :: (Int, Int) -> IOP (Image GrayScale D32) (Image GrayScale D32)

(gaussian (11,11) &#& id) >>> subtract >>> mulScalar 5

To me this seems like a quite safe alternative, though it is not optimal in the sense, that it probably could re-use also the cloned image if some operation after subtract would require this. But it still seems like an acceptable alternative to the completely pure and unoptimized version:

mulScalar 5 $ gaussian (11,11) img `subtract` img
-- Or with nicer names for the operators
5 * gaussian (11,11) img - img


  1. Is this a reasonable structure in the first place?
  2. Is there a reason to prefer the structure in the previous question?
  3. How would you extend this to implement an operation 'find the minimum value in the image, subtract it from the image and then multiply the image with its range (i.e max-min).'
  4. Should I split these into multiple questions instead?
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Just some comments: f >>= return = f, \ clone -> f clone = f. –  augustss May 20 '11 at 10:15
@augustss Doh. Of course. I'm just not a morning person it seems :) –  aleator May 20 '11 at 10:20
Also, IOP is the same as Kleisli IO, which gets you the Category instance (and others) for free. –  hammar May 20 '11 at 15:47
As a brief follow-up to my answer in the previous question, which ended up poorly organized as I tried to get a sense of what you were aiming for: The alternate structure I mentioned having in mind at the end is pretty close to either Kleisli IO or what @sclv describes, plus using either Arrow combinators or a reader monad to describe some sort of "clone" operator. I wasn't confident that it correctly expressed the performance characteristics, however, and @sclv's simpler approach should get the job done nicely. –  C. A. McCann May 20 '11 at 17:23

1 Answer 1

up vote 2 down vote accepted

Continuing from hammar's comment, you can just use kleisli composition to begin with, avoiding the IOP altogether. I've kept ImageOp as a type synonym for clarity's sake. Also, I specialized it to always return unit, and changed some other type signatures accordingly so that we have a typed difference between mutating functions (returning unit) and cloining functions (returning a new value), and a function apOp that applies a mutating function and returns the mutated value so that we can chain mutations easily.

type ImageOp c d -> Image c d -> IO ()

(&#&) :: ImageOp c d -> ImageOp c d -> (Image c d) -> IO (Image c d, Image c d)
f &#& g = \i -> withClone i $ \cl -> f i >> g cl >> return (i,cl)

apOp :: ImageOp c d -> Image c d -> IO (Image c d)
apOp iop x = fmap x (iop x)

subtract  ::  Image c d ->  ImageOp c1 d1
mulScalar :: d -> ImageOp (Image c d)
subtractScalar :: d -> ImageOp (Image c d)
gaussian  :: (Int, Int) -> ImageOp GrayScale D32

myFun = (gaussian (11,11) &#& id) >=> (\(x,y) -> apOp (subtract x) y) >=> apOp (mulScalar 5) 

myFun = (gaussian (11,11) &#& id) >=> uncurry (apOp . subtract) >=> apOp (mulScalar 5) 

Edit If you feel like it, you can write &#& neatly as follows:

f &#& g = uncurry (liftM2 (,)) . (apOp f &&& withClone (apOp g))

Which, I think, is a good argument for this style being pretty expressive.

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On the other hand, the benefit of using Kleisli IO is getting all the bonus instances, most notably Arrow and company, which may or may not be preferable to the approach you give here. –  C. A. McCann May 20 '11 at 17:02
@camccann -- I don't see Arrow and Category as buying you almost anything in this case. I suppose they lend themselves to a slightly more straightforward pipeline style (&#& can be written without the liftM2 (,) that I provide in my above edit) but the newtyping adds plenty of friction points as well. Generally, I think the kleisli composition operators (<=<, >=>) don't get nearly as much use as they should. –  sclv May 20 '11 at 18:31
That's sort of what I was thinking. In particular, the pipeline style is nice but would work at cross purposes with the typed distinction between mutate/clone operations you have here, which have much more obvious value. It's unfortunate we can't write the instances without a newtype and thereby use both, but there's no way to express functor composition directly. –  C. A. McCann May 20 '11 at 18:40
@camccann Thanks for excellent suggestions for my really vague question. However, I think that dropping the newtype allows the user of the library to make mistakes like (\x -> gaussian (11,11) x >>= \y -> subtract x y) too easily. But I think I have enough clues to carry on now :) –  aleator May 21 '11 at 11:40
@aleator -- the typed distinction between mutating ops (returning unit) and cloning ops (returning an image) means that your above example is ill-typed and will be caught. –  sclv May 21 '11 at 14:11

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