*edit:* using `These a b`

type from Data.These (used by `Data.Align`

), with this:

```
ordzipBy :: (Ord t) => (a -> t) -> (b -> t) -> [a] -> [b] -> [These a b]
ordzipBy f g a@(x:t) b@(y:r) = case compare (f x) (g y) of
LT -> This x : ordzipBy f g t b
GT -> That y : ordzipBy f g a r
EQ -> These x y : ordzipBy f g t r
ordzipBy _ _ a [] = map This a
ordzipBy _ _ [] b = map That b
```

we can express three set operations as:

```
diffBy :: (Ord t) => (a -> t) -> (b -> t) -> [a] -> [b] -> [a]
meetBy :: (Ord t) => (a -> t) -> (b -> t) -> [a] -> [b] -> [(a, b)]
joinBy :: (Ord t) => (a -> t) -> (a->a->a) -> [a] -> [a] -> [a]
diffBy f g xs ys = [x | This x <- ordzipBy f g xs ys]
meetBy f g xs ys = [(x,y) | These x y <- ordzipBy f g xs ys]
joinBy f h xs ys = mergeThese h `map` ordzipBy f f xs ys
```

what you describe is `meetBy`

, i.e. set intersection operation, with the two ordered lists seen as sets.

The ability of a compiler to efficiently compile these definitions is another question though. The three set functions hand-coded along the lines of `ordzipBy`

might run faster.

`ordzipBy f g`

is compatible with `align`

, and `[]`

with `nil`

, but the type machinery involved in making it happen is above my pay grade. :) Also, it's not clear to me whether the law `align (f <$> xs) (g <$> ys) = bimap f g <$> align xs ys`

would make sense at all because mapping the functions `f`

and `g`

can very well change the mutual ordering of elements of `xs`

and `ys`

.

The two problems (the types, and the law) are related: the parts of data recovered by selector functions for ordering purposes serve as *positions*, as *shape*, yet are part of the original *data*. (cf. instance Alternative ZipList in Haskell?).

*update:* see if the following works as you expected.

```
{-# LANGUAGE InstanceSigs, DatatypeContexts #-}
import Data.These
import Data.Align
newtype Ord a => ZL a b = ZL {unzl :: [(a,b)]}
deriving (Eq, Show)
instance Ord a => Functor (ZL a) where
fmap f (ZL xs) = ZL [(k, f v) | (k,v)<-xs]
instance Ord a => Align (ZL a) where
nil = ZL []
align :: (ZL a b) -> (ZL a c) -> (ZL a (These b c))
align (ZL a) (ZL b) = ZL (g a b) where
g a@((k,x):t) b@((n,y):r) = case compare k n of
LT -> (k, This x ) : g t b
GT -> (n, That y) : g a r
EQ -> (k, These x y) : g t r
g a [] = [(k, This x) | (k,x) <- a]
g [] b = [(n, That y) | (n,y) <- b]
diffBy :: (Ord t) => (a -> t) -> (b -> t) -> [a] -> [b] -> [a]
meetBy :: (Ord t) => (a -> t) -> (b -> t) -> [a] -> [b] -> [(a, b)]
joinBy :: (Ord t) => (a -> t) -> (a->a->a) -> [a] -> [a] -> [a]
diffBy f g xs ys = catThis . map snd . unzl
$ align (ZL [(f x,x) | x<-xs]) (ZL [(g y,y) | y<-ys])
meetBy f g xs ys = catThese . map snd . unzl
$ align (ZL [(f x,x) | x<-xs]) (ZL [(g y,y) | y<-ys])
joinBy f h xs ys = map (mergeThese h . snd) . unzl
$ align (ZL [(f x,x) | x<-xs]) (ZL [(f y,y) | y<-ys])
```

Infinite lists aren't handled well though, while the hand-coded functions can obviously quite easily be made to handle such cases correctly:

```
*Main> diffBy id id [1..5] [4..9]
[1,2,3]
*Main> diffBy id id [1..5] [4..]
[1,2,3Interrupted.
*Main> meetBy id id [1,3..10] [2,5..20]
[(5,5)]
*Main> joinBy id const [1,3..10] [2,5..20]
[1,2,3,5,7,8,9,11,14,17,20]
```

`>`

case? If you do, it's not possible to express this function in terms of`zip`

, because`zip`

doesn't allow putting elements back. If you only need to drop some non-matching pairs out, there's a simple solution in terms of`zipWith`

and`catMaybes`

from`Data.Maybe`

. – Sergei Lebedev Feb 10 at 14:01`zip`

, correct. – Sven Koschnicke Feb 10 at 14:08