Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I find myself needing a data structure that contains maybe an A, maybe a B, and definitely one of them. If I were to hack up a general data type for this thing, it would probably look like:

data OneOrBoth a b = A a | B b | AB a b

maybeA :: OneOrBoth a b -> Maybe a
maybeB :: OneOrBoth a b -> Maybe b
eitherL :: OneOrBoth a b -> Either a b -- Prefers a
eitherR :: OneOrBoth a b -> Either a b -- Prefers b
hasBoth, hasExactlyOne, hasA, hasB :: OneOrBoth a b -> Bool

Does this data structure have a name? Is there a canonical way to handle one-or-both structures in Haskell?

share|improve this question
Why stop at two types? Three, Four, ...? :-) –  Aaron McDaid Oct 16 '13 at 20:49
If you wanted "Zero, One, or Both" you'd have 1 + A + B + A*B = (1 + A) * (1 + B) or (Maybe A, Maybe B). –  rampion Oct 17 '13 at 1:34

3 Answers 3

up vote 39 down vote accepted


This can be useful to represent combinations of two values, where the combination is defined if either input is. Algebraically, the type These A B represents (A + B + AB), which doesn't factor easily into sums and products — a type like Either A (B, Maybe A) is unclear and awkward to use.

share|improve this answer
Not really canonical, but definitely a better choice than rolling your own, although this package does come with a lot of dependencies and extras that may or may not be useful to OP –  bheklilr Oct 16 '13 at 20:49
I'm not sure if this actualy beats rolling your own in all cases. It's sounds like the OP uses this a lot, but if this was a small thing I wouldn't want to pull in dependencies on profunctors, mtl, semigroups etc –  jozefg Oct 16 '13 at 20:55
Amused by how difficult it is to talk about proper nouns that are named after articles, I wrote up Acme.Whose which has the definite advantage of only pulling in strict and bifunctors. Please don't use it. –  J. Abrahamson Oct 16 '13 at 20:57
Precisely the sort of thing I was looking for. Thanks! –  So8res Oct 16 '13 at 21:03

Data.These has been mentioned, and is probably the best choice, but if I were to roll my own, I'd do it as:

import Control.Applicative ((<$>), (<*>))

type These a b = Either (Either a b) (a, b)

maybeA :: These a b -> Maybe a
maybeA (Left (Left a)) = Just a
maybeA (Right (a, _))  = Just a
maybeA _               = Nothing

maybeB :: These a b -> Maybe b
maybeB (Left (Right b)) = Just b
maybeB (Right (_, b))   = Just b
maybeB _                = Nothing

eitherA :: These a b -> Either a b
eitherA (Left (Left a))  = Left a
eitherA (Right (a, _))   = Left a
eitherA (Left (Right b)) = Right b

eitherB :: These a b -> Either a b
eitherB (Left (Right b)) = Right b
eitherB (Right (_, b))   = Right b
eitherB (Left (Left a))  = Left a

hasBoth, hasJustA, hasJustB, hasA, hasB :: These a b -> Bool

hasBoth (Right _) = True
hasBoth _         = False

hasJustA (Left (Left _)) = True
hasJustA _               = False

hasJustB (Left (Right _)) = True
hasJustB _                = False

hasA = (||) <$> hasBoth <*> hasJustA
hasB = (||) <$> hasBoth <*> hasJustB
share|improve this answer

If you wanted "Zero, One, or Both" you'd have 1 + A + B + A*B = (1 + A) * (1 + B) or (Maybe A, Maybe B).

You could do A + B + A*B = (1+A)*(1+B)-1 by wrapping (Maybe A, Maybe B) in a newtype and using smart constructors to remove the (Nothing,Nothing):

module Some (
  this, that, those, some,
  oror, orro, roro, roor,
) where

import Control.Applicative ((<|>))

newtype Some a b = Some (Maybe a, Maybe b) deriving (Show, Eq)

-- smart constructors
this :: a -> Some a b
this a = Some (Just a,Nothing)

that :: b -> Some a b
that b = Some (Nothing, Just b)

those :: a -> b -> Some a b
those a b = Some (Just a, Just b)

-- catamorphism/smart deconstructor
some :: (a -> r) -> (b -> r) -> (a -> b -> r) -> Some a b -> r
some f _ _ (Some (Just a, Nothing)) = f a
some _ g _ (Some (Nothing, Just b)) = g b
some _ _ h (Some (Just a, Just b))  = h a b
some _ _ _ _ = error "this case should be unreachable due to smart constructors"

swap :: Some a b -> Some b a
swap ~(Some ~(ma,mb)) = Some (mb,ma)

-- combining operators
oror, orro, roro, roor :: Some a b -> Some a b -> Some a b

-- prefer the leftmost A and the leftmost B
oror (Some (ma,mb)) (Some (ma',mb')) = Some (ma <|> ma', mb <|> mb')
-- prefer the leftmost A and the rightmost B
orro (Some (ma,mb)) (Some (ma',mb')) = Some (ma <|> ma', mb' <|> mb)
-- prefer the rightmost A and the rightmost B
roro = flip oror
-- prefer the rightmost A and the leftmost B
roor = flip orro

The combining operators are fun:

λ this "red" `oror` that "blue" `oror` those "beige" "yellow"
Some (Just "red",Just "blue")
λ this "red" `orro` that "blue" `orro` those "beige" "yellow"
Some (Just "red",Just "yellow")
λ this "red" `roor` that "blue" `roor` those "beige" "yellow"
Some (Just "beige",Just "blue")
λ this "red" `roro` that "blue" `roro` those "beige" "yellow"
Some (Just "beige",Just "yellow")
share|improve this answer
While the algebraic factoring method is nice, I don't see how this actually provides any advantage over simply rolling your own sum type. Using a newtype is basically isomorphic and now pattern matching is gone. –  jozefg Oct 17 '13 at 5:50

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.