Well, I can at least point out what to call some of the patterns you're using currently.

So we have a type representing a reference to some mutable data, and a type representing opaque operations on it. We also have a null op and a composition function, which gives an obvious `Monoid`

instance:

```
instance Monoid (ImageOperation c d) where
mempty = nonOp
mappend = (#>)
```

So that's at least one standard name you could use.

Further, the above `Monoid`

is actually a straightforward result of the properties of two other well-known types:

The `Applicative`

and/or `Monad`

instance for `(->) a`

describes combining functions by applying all of them to a single argument, as with the image in the composition function. Basically a lightweight, in-line version of the `Reader`

monad.

The `Monad`

instance for `IO`

, or rather the monoidal structure it implies. By fixing `IO`

's type parameter to `()`

, the monad laws reduce to a simple monoid, with `return ()`

as unit and `(>>)`

as the monoid operation.

To reconstruct your combination, given two functions (unwrapped `ImageOperation`

s) and imagining that the implied monoid for `IO ()`

is an actual instance, we could write:

```
nonOp = pure mempty
x #> y = mappend <$> x <*> y
```

It's also worth noting that the combination of something like a reader monad and a monad allowing mutable state essentially describes "a surrounding environment with mutable references", a.k.a. mutable global variables, except that "global" here means "within a single computation of the combined monad". I've actually constructed such a monad explicitly, using `ReaderT`

and `STM`

.

That handles combining operations. To actually run an operation, you need an `Image`

and I'm gathering you want to only operate on clones, the creation of which is inefficient. Fortunately, considering how very general the above construction for the `Monoid`

is, there's really nothing you can't cram into an `ImageOperation`

before actually running it. Generating the clone is presumably an `IO`

operation and is what I assume is going on in `operate`

--there's probably not really any other way to do that.

Beyond that, if you're interested in alternate ways to structure the whole thing, one obvious variant would be to wrap `Image`

instead into something representing the process of constructing one, with operators merged in to transform the image being produced using something like `operate`

. I don't know if this would actually gain you anything, though.

In fact, I'm inclined to doubt that there're really any other ways to do this. You're writing an FFI binding to a highly imperative library and there's only so much you can do to disguise that.

I'm not sure, however, why you have an unsafe version of `operate`

. What practical purpose would this serve?

I'm also not sure what kind of binary operators you'd like to generalize this to--there's not much else you can do operating on `ImageOperation`

besides what you have here. Do you mean generalizing `ImageOperation`

to work on more than one mutable reference to an image? Or something involving operations on images that return something other than just `IO ()`

?

**EDIT**: Okay, let's look at how one might decompose `poorMansHighPass`

. Hopefully I'm correctly reading what it's doing here:

First, `gaussian`

is independent and can be factored out as its own operation: `gauss' = ImgOp . gaussian`

.

Next, `subtract`

can also be factored out, parameterized by an additional `Image`

: `subtr' = ImgOp . flip subtract`

.

These two are the core of the function, and they can be combined in the usual manner: `poorMansHP' img = gauss' (5, 5) #> subtr' img`

. The last thing needed to recover the original function is that the `img`

argument given to `poorMansHP'`

must be the *same* image whose clone is passed to the inner function by `operate`

.

First we'll explicitly unwrap the `ImageOperation`

and use that in the reimplementation:

```
poorMansHighPass img =
let (ImgOp op) = gauss' (5, 5) #> subtr' img
in do x <- clone img
op x
return x
```

Substitute `withClone`

for the use of `clone`

here:

```
poorMansHighPass img =
let (ImgOp op) = gauss' (5, 5) #> subtr' img
in withClone img $ \x -> do op x
return x
```

Desugar the `do`

block:

```
poorMansHighPass img =
let (ImgOp op) = gauss' (5, 5) #> subtr' img
in withClone img $ \x -> op x >> return x
```

...which obviously contains a reimplementation of `operate`

, so replace that and simplify:

```
poorMansHighPass img = operate (gauss' (5, 5) #> subtr' img) img
```

More interesting would be implementing `poorMansHighPass`

in a way that modifies the argument instead of the clone, which would allow it to be packaged up as an `ImageOperation`

itself. Possibly that's what it's supposed to be doing, and I misread your code?

Anyway, the basic structure of the refactoring would be the same, but you'd need a different composition operator--instead of applying two operators to the same input in sequence, it would need to create a clone of the input internally before recombining the results. I have a rough idea what kind of structure would make this work smoothly, which I can elaborate on if you'd like but I'll have to work through it a bit to make sure it behaves properly.

`unsafeOperate`

actually unsafe? It uses mutation under the covers, but should appear ref transparent to anyone invokin it. – sclv May 19 '11 at 14:39`poorMansHighPass img = img <# ('subtract' img) 'mplus' gaussian (5,5)`

? (single quotes should be backticks) – sclv May 19 '11 at 19:29