# Simplifying nested Maybe pattern matching

I have the following construct in my code:

f :: Maybe A -> X
f a = case a of
Nothing -> x
(Just b) -> case b of
Nothing -> y
(Just c) -> case c of
Nothing -> z
(Just d) -> d

I'm not seeing an obvious way to simplify this instead of using nested maybe functions, which wouldn't make the whole thing look much better. Are there any clever - but still understandable - tricks that would help make this construct more "elegant"?

• You need a better structure for the problem then nested Maybe Commented Oct 29, 2013 at 11:30
• It seems a little odd that you don't care about the values of b and c, just whether or not they have values. This makes them effectively Boolean. Is the layer of Maybes arbitrarily deep or a fixed depth? Commented Oct 29, 2013 at 12:35
• Your model is basically wrong. You need to be chaining (i.e. mapping over) functions/functors, not doing this imperative style. Commented Oct 29, 2013 at 13:20
• @itsbruce: What does that mean, in plain English? (Aka, what’s the translation function?)
– anon
Commented Jan 4, 2018 at 21:15
• The answers here are useless, because they arrogantly imply, that you have merely a nested Maybe, and the given example is not just a simplified idea of a much more complex (set of) function(s) that returns Maybe values too, as is commeon.
– anon
Commented Jan 4, 2018 at 21:17

Why did the code construct a Maybe (Maybe (Maybe X)) value in the first place? Unpacking such a value isn't nice, but the real question is, why there even is such a value. Maybe the code would better avoid all those nested Maybes.

If you really need to have such a value and need to do different things in all the Just/Nothing cases you'll have to write them all down. But instead of several nested case statements you could combine them into one big pattern match:

f Nothing                = x
f (Just Nothing))        = y
f (Just (Just Nothing))  = z
f (Just (Just (Just d))) = d
• I'm parsing a nested JSON value with a lot of "nullable" types, so that's why there are so many arbitrarily nested Maybes. Commented Oct 30, 2013 at 10:06

Despite your constraint about not using maybe, I think this looks quite nice:

f = maybe x (maybe y (maybe z id))

or even better, as @pat suggests in his comment:

f = maybe x . maybe y . maybe z \$ id
• Or f = maybe x . maybe y . maybe z \$ id
– pat
Commented Oct 29, 2013 at 15:44

UPDATED 2

import Data.Maybe (maybe)

maybeE :: e -> Maybe a -> Either e a
maybeE e = maybe (Left e) Right

f :: Maybe (Maybe (Maybe d)) -> Either e d
f a  =   maybeE x a
>>= maybeE y
>>= maybeE z

UPDATED 3

If we want to have not Either type, we could rewrite function:

import Data.Either(either)

either' = either id id

f :: Maybe (Maybe (Maybe d)) -> d
f a = either' \$ maybeE x a
>>= maybeE y
>>= maybeE z
• I'm not sure how the Maybe monad would help here, a has a type of Maybe (Maybe (Maybe ...))), and after every Maybe layer I have to return a different value if it evaluates to Nothing, (x y z in the above example). Commented Oct 29, 2013 at 10:48
• This could be re-written so that f takes an arbitrary-size list of Eitherss as the single parameter. Would be better, I think. But that's a comment aimed at the OP, not you, viorior. Commented Oct 29, 2013 at 13:20
• @itsbruce what would the type of f be if you allowed it to take an arbitrary-size list of Eithers? Oh, you mean instead of the nested Maybes.
– pat
Commented Oct 29, 2013 at 15:50
• Precisely! :) It should be f :: [something] -> d where something can probably just be functors to be mapped over, frankly. This kind of thing doesn't need more complexity than that. Commented Oct 29, 2013 at 16:07
• I ended up using your maybeE combinator for my needs, but the other answers are very informative too! Commented Oct 30, 2013 at 10:07