Ths is a perfect use case for DerivingVia
(it was brought to my attention that I didn't read the question carefully enough, you have to use a newtype
one way or the other: this solution is not what you were hoping for but it is idiomatic)
{-# Language DerivingVia #-}
{-# Language StandaloneKindSignatures #-}
import Control.Applicative (Alternative)
import Control.Monad (MonadPlus)
import Control.Monad.Fix (MonadFix)
import Control.Monad.Trans.Maybe
import Control.Monad.Zip (MonadZip)
import Data.Kind (Type)
type Fortunate :: Type -> Type
newtype Fortunate a = Fortunate [Maybe a]
deriving
( Functor, Foldable, Applicative, Alternative
, Monad, MonadPlus, MonadFail, MonadFix, MonadZip
)
via MaybeT []
Some of these instances like (Functor, Foldable, Applicative, Alternative)
can be derived via Compose Maybe []
.
To list what instances can be derived, use the :instances
command
>> :instances MaybeT []
instance [safe] Alternative (MaybeT [])
-- Defined in ‘Control.Monad.Trans.Maybe’
instance [safe] Applicative (MaybeT [])
-- Defined in ‘Control.Monad.Trans.Maybe’
...
>> :instances Compose Maybe []
instance Alternative (Compose Maybe [])
-- Defined in ‘Data.Functor.Compose’
instance Applicative (Compose Maybe [])
-- Defined in ‘Data.Functor.Compose’
...
Because Fortunate
is an applicative you can derive (Semigroup, Monoid, Num, Bounded)
through pointwise (idiomatic, applicative) lifting:
import Data.Monoid (Ap(..))
..
deriving (Semigroup, Monoid, Num, Bounded)
via Ap Fortunate a
where (<>) = liftA2 (<>)
, abs = liftA abs
, mempty = pure mempty
, minBound = pure minBound
.
fmap show (Unfortunate [Just 10, Just 1, Nothing, Just 15])
and see what type you get out?(fmap . fmap) f [Just 10, Nothing])
. If you really want, you can define something likeffmap = fmap . fmap
, and it will work for any pair of nested functors like this. That is, it works for your exampleffmap (+1) [Just 10, Nothing] == [Just 11, Nothing]
and also something likeffmap (+1) (Just [1,2]) == Just [2,3]
.