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I have the following problem:

Given a type data T = T (Maybe Int), how can I filter a list getting the non-Nothing values?


a = [T (Just 3), T Nothing, T (Just 4)]

Desired Output

b = [T (Just 3), T (Just 4)]

I have tried something like :

b = filter (\x-> x@(Just t)) a 

...thinking that I can filter based on a pattern match but i get the error:

Pattern syntax in expression context: x@(Just t)
    Did you mean to enable TypeApplications?

I want to later on be able to unpack the inner value (under Just) and use it accordingly.

marked as duplicate by Shersh, Will Ness haskell Sep 14 at 9:51

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  • 1
    you could use filter (\x -> case x of (Just _) -> True ; _ -> False) a or even filter (\case (Just _) -> True ; _ -> False) (the latter with the LambdaCase extention). – Will Ness Sep 14 at 9:54
up vote 4 down vote accepted

I think here we can better use the pattern-matching semantics of list comprehension:

result = [ e | e@(T (Just _)) <- a]

Here we thus enumerate over the elements e in a, and if the pattern matching with T (Just _) succeeds, we yield it in the result list.

If you however wish to unpack the values encapsulated in the T (Just x), we thus can perform pattern matching, and yield the wrapped element:

result = [ e | T (Just e) <- a]

This will thus not only "filter" the values, but unpack concurrently. So the T Nothings are ignored, and only the wrapped T (Just e)s are retained and the corresponding es end up in the list.

  • 3
    This answers the letter of the question, but I bet [e | T (Just e) <- a] answers the spirit of the question better. – Daniel Wagner Sep 13 at 14:08
  • Yes that is precisely what i wanted to later on be able to unpack the inner value and use it accordingly. – Bercovici Adrian Sep 13 at 14:14
  • 1
    @BercoviciAdrian: see update. – Willem Van Onsem Sep 13 at 14:14
  • Could you please tell me why do i get Pattern bindings not allowed in instance declaration for instance Show File where ; (Dfile ls)=Data.List.intercalate ',' [show e|T (Just e) <- ls].Might deserve a separate question but i am not sure. though. – Bercovici Adrian Sep 13 at 14:49
  • 1
    @BercoviciAdrian You probably mean ... where show (Dfile ls)= ... – chi Sep 13 at 16:01

If you want to get a list of the Int values in your list of Ts (so typed [T] -> [Int]), then mapMaybe from Data.Maybe already does almost exactly what you want. All you need on top of that is a unwrapping function of type T -> Maybe Int

import Data.Maybe ( mapMaybe )

data T = T (Maybe Int)
  deriving (Eq, Show)

unT :: T -> Maybe Int
unT (T x) = x

filterTs = mapMaybe unT


λ a = [T (Just 3), T Nothing, T (Just 4)]
a :: [T]

λ filterTs a
it :: [Int]

In my opinion having this filter operation be of type [T] -> [Int] is more useful than having it return the T values containing non-Nothing values; the reason is that even if you filter a down to [T (Just 3), T (Just 4)], then the code that deals with that later still has to pattern match on the Just to get at the Int values, even though you know there'll never be a Nothing1, because T is still hardcoded to contain Nothing.

As a general rule, if you're filtering (or defaulting, or etc) to guarantee the absence of a case, you should consider transforming to a type that doesn't have the case anymore. It usually makes the resulting data easier to deal with (no need for pattern matches or fmaps to get inside the redundant layers, for example), as well as helping avoid bugs.

There's also catMaybes :: [Maybe a] -> [a], that does this "filtering out Nothings without mapping", but since you're mapping to unwrapp the T constructor mapMaybe is a closer fit.

1 And this "I know there'll never be Nothing here, so I don't have to handle it" situation is a very rich source of bugs, liable to break when something changes that hidden invariant in future. So it's not even a great idea to actually write code that takes advantage of that knowledge that Nothing "cannot" be there; you should still handle both cases!

  • Thank you for your observations, they are very valuable for me as a beginner.I wanted to know as a rules of thumb, whenever i have nested maybe-s in my types like in the example oyu provided with T i should make methods that pattern-match and get the field value ? (in your example unT)? – Bercovici Adrian Sep 14 at 5:32

Pattern matching only works in the argument to the function, not the body. The pattern you need to match on is T, with a catamorphism like maybe to convert the wrapped value to a boolean.

Prelude> a = [T (Just 3), T Nothing, T (Just 4)]
Prelude> filter (\(T x) -> maybe False (const True) x) a
[T (Just 3),T (Just 4)]

Note, however, that maybe False (const True) is already defined as Data.Maybe.isJust.

Prelude> import Data.Maybe
Prelude> filter (\(T x) -> isJust x) a
[T (Just 3),T (Just 4)]

You can simplify the predicate if you have some function of type T -> Maybe Int to compose with isJust. For instance:

Prelude> data T = T { getT :: Maybe Int } deriving Show
Prelude> a = [T (Just 3), T Nothing, T (Just 4)]
Prelude> filter (isJust . getT) a
[T {getT = Just 3},T {getT = Just 4}]

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