# How can I define a filter function for arrows?

I'm currently reading through the paper Programming with Arrows by John Hughes and I'm already stumped on the first exercise, in section 2.5, on pg 20.

We have the `Arrow` and `ArrowChoice` typeclasses at our disposal, as well as instances for functions, stream functions `[a] -> [b]`, and monadic functions `a -> m b` via the `Kleisli` type.

A `mapA` example was given:

``````mapA f = arr listcase >>>
arr (const []) ||| (f *** mapA >>> arr (uncurry (:)))
``````

Here's an attempt:

``````listcase :: [a] -> (Either () (a,[a]))
listcase [] = Left ()
listcase (x:xs) = Right (x,xs)

helper :: (Bool,a) -> [a] -> Either (a,[a]) [a]
helper (True,x)  y = Left (x,y)
helper (False,x) y = Right y

test :: Arrow a => (b -> Bool) -> a (b,c) ((Bool,b), c)
test p = first (arr p &&& arr id)

filterA :: Arrow a => (b -> Bool) -> a [b] [c]
filterA p = f >>> (g ||| (h >>> (j ||| (filterA p))))
where f = arr listcase
g = arr (const [])
h = test p >>> (uncurry helper)
j = (arr id *** (filterA p)) >>> (arr (uncurry (:)))
``````

The (bruteforce) rationale behind this futile attempt is as follows: There are two choices to be made with `filterA`: the `listcase` like `map`, and the result of applying the predicate `p`. It starts off like `map`, checking the list and returning an Either value using `listcase`. In the case of an empty list `g` is applied, otherwise everything to the right of `|||` is applied to a value of type `(a,[a])`, containing the `head` and `tail` respectively. The `h` function is applied first, which applies the predicate while keeping the `head`, returning a value of type `((Bool, head),tail)`. This is passed to `(uncurry helper)`, which decides whether to keep the `head` or not depending on the `Bool` value. It returns the result as an `Either` value so that we may apply the choice method `(|||)` to it. This value is passed to the next choice: `(j ||| (filterA p))` such that if the predicate held `True` then `j` is applied to a pair containing the `head` and `tail`. The `head` is filtered through using `id` while the `filter p` is applied to the `tail`. Both results are returned as a pair. This pair is then reconciled using `arr (uncurry (:))` like `map`. Otherwise the `tail` is passed to `filterA p` alone.

I doubt it's as difficult as I'm making it out to be, I assume I'm missing something quite obvious.

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Sorry I'm not quite following your logic, but let's see what the non-arrow code does. It

• Checks to see if the list is empty, if so returns that
• Otherwise, pulls the head of the list off, call the element `x`
• Recurses on the rest of the list, call the result `ys`
• If the predicate `p` is true on the head, then we append `x` to `ys`.
• Otherwise, we return `ys`

The `listcase` function [to implement the first 2 tasks] looks good, though remember you're returning a list, so might as well return that instead of `unit` and remapping through `const []`.

You have the recursion code for the third bullet buried in the two last cases, whereas I expose it directly, but that's okay.

For the last merging, you write it with a `|||`, but since you don't need to compose any other arrows in your target category, you might as well just lift a function to do all of the work. In my code below, that's `rejoin`.

``````filterA :: forall arr a. ArrowChoice arr => arr a Bool -> arr [a] [a]
filterA p = arr lstcase >>> (filterRest ||| id) where
-- left if has a head, right otherwise
lstcase :: [a] -> (Either (a, [a]) [a])
lstcase (x:xs) = Left (x, xs)
lstcase [] = Right []

-- if we got a head, then
--     for the head ("first" in code), map this to itself and p's result on it
--     recurse on the rest of the list ("second" part)
--     append the element to the recursion result if p's result is true
filterRest :: arr (a, [a]) [a]
filterRest = (first (id &&& p) >>> second (filterA p) >>> arr rejoin)

rejoin :: ((a, Bool), [a]) -> [a]
rejoin ((x, True), rest) = x:rest
rejoin ((x, False), rest) = rest
``````

Certainly it takes time to express your ideas clearly with the likes of `***`, `&&&`, `|||`, `first`, etc.

A little critique.

• Make sure you're implementing the function they're asking for!! If you just take a raw function `p`, then you might as well declare `filterA = arr filter`. You really want to take a lifted arrow `p`. That said, the change would be to simply type `p` instead of `arr p`, so your code has the right idea.
• `(uncurry helper)` is not something in the arrow space, it's just a raw function.

When developing this stuff, I usually write a skeleton, and declare the types. That helps me figure out what's going on. For example, I started with

``````filterA :: ArrowChoice arr => arr a Bool -> arr [a] [a]
filterA p = arr lstcase >>> (filterRest ||| id) where
-- left if has a head, right otherwise
lstcase :: [a] -> (Either (a, [a]) [a])
lstcase = undefined

filterRest :: arr (a, [a]) [a]
filterRest = undefined
``````

When you add `fa` into the `filterRest` declaration however, you need to tell it that `arr` for `filterRest` is the same as the one for `filterA` (type variable scoping), so use the `forall arr a.` as above.

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Thanks, looks good. I had noticed that the predicate was an arrow right after I posted, but since it didn't change things much, as you pointed out, I didn't bother changing it. Not lifting `(uncurry helper)` was a mistake. Perhaps the biggest mistake was not making `filterA p` an `ArrowChoice` instance. That simple change allows my code to work as expected, although I prefer yours. – qubital Jul 19 '11 at 3:10

Here's a slight simplification:

``````test :: Arrow a => (b -> Bool) -> a b ([b] -> [b])
test p = arr \$ \b -> if p b then (b:) else id

filterA :: Arrow a => (b -> Bool) -> a [b] [b]
filterA p = f >>> (g ||| h)
where f = arr listcase
g = arr id
h = (test p *** filterA p) >>> (arr (uncurry (\$)))

filterA' :: Arrow a => a b Bool -> a [b] [b]
filterA' p = f >>> (g ||| h)
where f = arr listcase
g = arr id
h = (i *** filterA p) >>> (arr (uncurry (\$)))
i = proc x -> do
b <- p -< x
returnA -< if b then (x:) else id
``````
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