Canonical outer join zip function

If you consider the (implicit) indexes of each element of a list as their keys, then `zipWith` is sort of like a relational inner join. It only processes the keys for which both inputs have values:

``````zipWith (+) [1..5] [10..20] == zipWith (+) [1..11] [10..14] == [11,13,15,17,19]
``````

Is there a canonical corresponding function corresponding to outer join? Something like:

``````outerZipWith :: (a -> b -> c) -> a -> b -> [a] -> [b] -> [c]
outerZipWith _ _ _ [] [] = []
outerZipWith f a' b' [] (b:bs) = f a' b : outerZipWith f a' b' [] bs
outerZipWith f a' b' (a:as) [] = f a b' : outerZipWith f a' b' as []
outerZipWith f a' b' (a:as) (b:bs) = f a b : outerZipWith f a' b' as bs
``````

or maybe

``````outerZipWith' :: (a -> b -> c) -> Maybe a -> Maybe b -> [a] -> [b] -> [c]
outerZipWith' _ _ _ [] [] = []
outerZipWith' _ Nothing _ [] _ = []
outerZipWith' _ _ Nothing _ [] = []
outerZipWith' f a' b' [] (b:bs) = f (fromJust a') b : outerZipWith f a' b' [] bs
outerZipWith' f a' b' (a:as) [] = f a (fromJust b') : outerZipWith f a' b' as []
outerZipWith' f a' b' (a:as) (b:bs) = f a b : outerZipWith f a' b' as bs
``````

So I can do

``````outerZipWith (+) 0 0 [1..5] [10..20]  == [11,13,15,17,19,15,16,17,18,19,20]
outerZipWith (+) 0 0 [1..11] [10..14] == [11,13,15,17,19,6,7,8,9,10,11]
``````

I find myself needing it from time to time, and I'd rather use a common idiom to make my code more writable (and easier to maintain) rather than implementing `outerZipWith`, or doing `if length as < length bs then zipWith f (as ++ repeat a) bs else zipWith f as (bs ++ repeat b)`.

This seems awkward because you're trying to skip to the end rather than deal with the primitive operations.

First of all, `zipWith` is conceptually a `zip` followed by `map (uncurry (\$))`. This is an important point, because (un)currying is why `zipWith` is possible at all. Given lists with types `[a]` and `[b]`, to apply a function `(a -> b -> c)` and get something of type `[c]` you obviously need one of each input. The two ways to do this are precisely the two `Applicative` instances for lists, and `zipWith` is `liftA2` for one of them. (The other instance is the standard one, which gives the cartesian product--a cross join, if you prefer).

The semantics you want don't correspond to any obvious `Applicative` instance, which is why it's much more difficult. Consider first an `outerZip :: [a] -> [b] -> [?? a b]` and what type it would have. The elements of the result list could each be an `a`, `b`, or both. This not only doesn't correspond to any standard data type, it's awkward to express in terms of them because you can't factor anything useful out of the expression `(A + B + A*B)`.

Such a data type has its own uses, which is why I have my own package defining one. I recall there being one on hackage as well (with fewer auxiliary functions than mine, I think) but I can't remember what it was called.

Sticking to just standard stuff, you end up needing a sensible "default value" which roughly translates into having a `Monoid` instance and using the identity value to pad the lists out. Translating to and from an appropriate `Monoid` using `newtype` wrappers or such may not end up being any simpler than your current implementation, however.

As an aside, your remark about list indices as keys can actually be developed further; any `Functor` with a similar notion of a key is isomorphic to the `Reader` monad, a.k.a. an explicit function from keys to values. Edward Kmett has, as always, a bunch of packages encoding these abstract notions, in this case building from the `representable-functors` package. Might be helpful, if you don't mind writing a dozen instances just to get started at least...

• Wouldn't `outerZip :: a -> b -> [a] -> [b] -> [(a,b)]`? – pat Feb 8 '12 at 18:13
• More like `outerZip :: (a -> c) -> (b -> d) -> c -> d -> [a] -> [b] -> [(c, d)]` – Apocalisp Feb 8 '12 at 18:26
• An inclusive-or type (like your `These`) may be the necessary first step. At the very least, it's a good place to start. – rampion Feb 8 '12 at 18:27
• `outerZip f a b as bs = map (f . fromThese a b) \$ zipThese as bs` is very clean. I like it. – rampion Feb 8 '12 at 18:38
• @rampion: Oh, also--since collecting inputs like this as an intermediate step is the obvious use for a type like `These`, I tried to be very comprehensive with projections, case analysis functions, and predicates for `These`, specifically to support cleanly defining things like your `outerZip`. :] – C. A. McCann Feb 8 '12 at 19:02

This kind of thing comes up a lot. It's the `cogroup` operation of the PACT algebra. Where I work, we make use of type classes to differentiate these three operations:

1. `zip`: Structural intersection.
2. `align`: Structural union.
3. `liftA2`: Structural cartesian product.

This is discussed by Paul Chiusano on his blog.

• That Paul Chiusano blog entry is straightforward and insightful. Thanks for linking that. – Luis Casillas Feb 9 '12 at 1:53

Instead of filling out the shorter list with a constant, why not provide a list of values to take until the end of the longer list is reached? This also eliminates the need for a `Maybe` since the list can be empty (or of finite length).

I couldn't find anything standard, but short of a complete re-implementation of `zipWith` along the lines you showed, I developed your `length` test version like this:

``````outerZipWith :: (a -> b -> c) -> [a] -> [b] -> [a] -> [b] -> [c]
outerZipWith f as bs as' bs' = take n \$ zipWith f (as ++ as') (bs ++ bs')
where n = max (length as) (length bs)
``````
• This doesn't compile (for me at least). – Andy Hayden Oct 22 '12 at 18:37
• @hayden oops. fixed – pat Oct 22 '12 at 23:27