I want to get the minimum of two maybe values, or if one is nothing get the non-nothing one, or return nothing if both inputs are nothing. I can write a simple function to do this, but I suspect there is a way to do this without writing a custom function. Sorry, if this is a petty question, but is there a simpler way than using this custom function?

minMaybe :: Ord a => Maybe a -> Maybe a -> Maybe a
minMaybe Nothing b = b
minMaybe a Nothing = a
minMaybe (Just a) (Just b) = Just $ min a b
  • before I get downvoted by that pigworker ;) ... what about: let minM a b = maybe a Just $ maybe b Just $ min a b ? – Carsten Sep 10 '14 at 16:00
  • Maybe just this – n. 'pronouns' m. Sep 10 '14 at 16:45
  • n.m, that works, but it's not any simpler that what I'm starting with. – clay Sep 10 '14 at 19:13

You cannot use the Applicative, or Monad instance for this, since any Nothing in those contexts will have your total result being a Nothing. That being said, the term "simpler" is highly opinionated, and your function is fine as it is.

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    Note: Community wiki since "simpler" is highly opinionated. – Zeta Sep 10 '14 at 16:03
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    Since max works as @clay would want it to ("preferring" Just values to Nothings), perhaps if @clay used Data.Ord.Down then they would have the behaviour they want, while still being 'simpler' in the way the other answers want it to. – radomaj Sep 12 '14 at 8:41

It is possible to satisfy the specification using operators from Control.Applicative.

myMin :: Ord x => Maybe x -> Maybe x -> Maybe x
myMin a b = min <$> a <*> b <|> a <|> b

where the <|> for Maybe implements "preference"

Nothing <|> b  = b
a       <|> _  = a

The thing is

min <$> Just a <*> Just b = Just (min a b)


min <$> Just a <*> Nothing = Nothing

which has resulted in some incorrect answers to this question. Using <|> allows you to prefer the computed min value when it's available, but recover with either individual when only one is Just.

But you should ask if it is appropriate to use Maybe in this way. With the inglorious exception of its Monoid instance, Maybe is set up to model failure-prone computations. What you have here is the extension of an existing Ord with a "top" element.

data Topped x = Val x | Top deriving (Show, Eq, Ord)

and you'll find that min for Topped x is just what you need. It's good to think of types as not just the representation of data but the equipment of data with structure. Nothing usually represents some kind of failure, so it might be better to use a different type for your purpose.

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    Topped x has a sensible max, but if you want to add a bottom element instead, then the intended semantics changes, so why should the type stay the same? Of course, we could do the "make a monoid from a semigroup" construction once, then wrap max, min, etc as semigroup structures. – pigworker Sep 10 '14 at 17:07
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    min <$> a <*> b == min a b on Maybes. The latter however does look more "golfed" than "simpler"... – chi Sep 10 '14 at 20:01
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    @chi Huh, that means that if the question had used max instead of min, max would have been a correct answer. Or put differently, Bottomed is just Maybe itself. – Ørjan Johansen Sep 10 '14 at 22:34
  • I know I'm quite late to this question, but what the heck. The monoid-extras package on Hackage offers this type (and the Bottomed variant, too) and a few small utilities for working with it. – Daniel Wagner Jan 18 '17 at 22:24

You can write it using the Alternative instance of Maybe:

minMaybe a b = liftA2 min a b <|> a <|> b

Alternatively, you could use maxBound as default, so it'll always choose the other:

minMaybe a b = liftA2 min (d a) (d b)
  where d x = x <|> Just maxBound

But I don't recommend that.


Question is about lifting function min :: Ord a ⇒ a → a → a to work with Maybes context. It's associative so Semigroup instance does exactly what you want:

min' :: forall a. Ord a => Maybe a -> Maybe a -> Maybe a
min' = coerce ((<>) @(Maybe (Min a)))

This requires ScopedTypeVariables and TypeApplications. coerce comes from Data.Coerce. More old fashioned solution given below. But version above should be more performant: coerce doesn't exist at runtime. Although GHC may eliminate fmaps there's no guarantee:

min'' :: Ord a => Maybe a -> Maybe a -> Maybe a
min'' x y = fmap getMin (fmap Min x <> fmap Min y)

P.S. I would say that your solution is just fine.


I think radomaj had a good idea.

import Data.Ord (Down (..))
import Data.Function (on)

minMaybes mx my =
  getDown <$> (max `on` fmap Down) mx my
getDown (Down x) = x

We use max to prefer Just to Nothing, and then use Down so we actually get the minimum if both are Just.

Here's another, similar approach that seems a bit cleaner. Maybe can be seen a way to tack on an extra minimal value, Nothing, to an arbitrary Ord type. We can write our own type to tack on a maximal value:

data AddMax a = TheMax | Plain a deriving Eq
instance Ord a => Ord (AddMax a) where
  TheMax <= Plain _ = False
  _ <= TheMax = True
  Plain a <= Plain b = a <= b

maybeToAddMax :: Maybe a -> AddMax a
maybeToAddMax = maybe TheMax Plain

addMaxToMaybe :: AddMax a -> Maybe a
addMaxToMaybe TheMax = Nothing
addMaxToMaybe (Plain a) = Just a

Now you can write

minMaybes mx my = addMaxToMaybe $
  (min `on` maybeToAddMax) mx my

You can also pull a little sleight-of-hand:

{-# LANGUAGE ScopedTypeVariables, TypeApplications #-}
import Data.Ord
import Data.Function
import Data.Coerce

newtype AddMax a = AddMax {unAddMax :: Down (Maybe (Down a))}
  deriving (Eq, Ord)


minMaybes :: forall a. Ord a => Maybe a -> Maybe a -> Maybe a
minMaybes = coerce (min @(AddMax a))
  • this breaks the separation of concerns principle -- involves the outer structure in comparisons of carried data (or IOW, can't be changed into maxMaybes by just using min). Down also flips the choice for equals..... – Will Ness Jul 16 '18 at 15:48
  • @WillNess, you can fix the choice for equals by doubling down: wrap it around the outside as well as the inside. I agree it's lousy for separation of concerns. – dfeuer Jul 16 '18 at 15:56
  • I tried double-Down, could't make it work... what I have: data X a = X (a,a) that compares pairs by first element only; then max [Down $ X (1,2)] [Down $ X (1,3)] returns [Down (X (1,3))]. Using Down twice doesn't change this (as max (Down [Down $ X (1,2)]) (Down [Down $ X (1,3)])). How should this be done? – Will Ness Jul 16 '18 at 16:03
  • @WillNess, with double-down, you use min. – dfeuer Jul 16 '18 at 16:11
  • thanks. for some reason, max (X (1,2)) (X (1,3)) returns X (1,3), that's what threw me off. the whole distinguishable equals thing doesn't go quite well with purity anyway. – Will Ness Jul 17 '18 at 0:11

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