My understanding of Sum
and Product
newtypes is that they serve as monoidial wrappers for numeric types. I would understand Functor
instance on them, but why there are also Applicative
, Monad
any many other seemingly useless instances? I understand that they are mathemathically OK (isomorphic to Identity
modad, right?) But what is the use case? If there is an Applicative Sum
instance, for example, I would expect to encounter a value of type Sum (a > b)
somewhere. I can't imagine where this could possibly be useful.
2 Answers
Such instances are convenient for lifting arbitrary functions to work on things that happen to currently be living inside a Sum
or Product
. For example, one might imagine wanting to do some bitwise operations on something that is nevertheless more convenient in a Sum
than bare; then liftA2 (.&.) :: Sum Int > Sum Int > Sum Int
(for example).
One could also provide this operation by giving a Bits
instance for Sum
, but generalizing that technique would require the implementors of Sum
to predict every operation one might ever want to do, which seems like a tall order. Providing Applicative
and Monad
instances give a onceandforall translation for users to lift any function they like  including ones the implementors of Sum
did not predict being useful.

Yes, but that's arguably an abuse of the
Applicative
class. It's much better to useIso
combinators for this purpose. Commented Sep 27, 2016 at 16:57 
1@leftaroundabout Can you say carefully what is better about the
Iso
combinators? Naively, they look like a strange tradeoff: it's a very heavy dependency (certainly not one that should be rolled into base), and the syntax for lifting two or moreargument functions looks verbose compared to a single application ofliftA2
. Commented Sep 27, 2016 at 17:01 
1@leftaroundabout, when I look at
au
andauf
, mine eyes glazeth over.– dfeuerCommented Sep 27, 2016 at 17:02 
@DanielWagner well, I didn't particularly suggest using
lenses
to accomplishliftA2 (.&.)
onSum
. That is certainly not sensible. What I actually meant is that it doesn't do much good to keepSum
wrapped values around at all and combine them like that – these newtypes are intended so you can inject them into a single algorithm that works on monoids but that you want to use with numbers, but not to actually get an result of typeSum Int
. In other words, I understandSum
more as a tag you can pass to functions to explain what to do with numbers, not as an actual type constructor. Commented Sep 27, 2016 at 18:47 
...hence I also don't find it reasonable to give them any instances at all apart from the
Monoid
one which these newtypes are all about. — The iso combinators make it easier to “tagwrap” a number into aSum
in for a single operation, without needing to manually wrap and unwrap again. Iflens
is to much of a dependency you can also use them from the original package. Commented Sep 27, 2016 at 18:48
Values like this typically result from partial application of binary operators. Assuming Functor
and Applicative
instances like
import Control.Applicative
import Data.Monoid
instance Functor Sum where
fmap f (Sum x) = Sum (f x)
instance Applicative Sum where
pure = Sum
(Sum f) <*> (Sum x) = Sum (f x)
then you can see how a value of Sum (a > b)
would arise.
> :t (*) <$> (Sum 5)
(*) <$> (Sum 5) :: Num a => Sum (a > a)
> (*) <$> (Sum 5) <*> (Sum 10)
Sum {getSum = 50}

4
x :: Sum Int; x = do { 1; 2; 3; 4; 5 }
?Sum 5
sinceSum
is the identity monad.x :: Sum Int; x = do {Sum 1; Sum 2}
) and get the actual sum with XRebindableSyntax by saying(>>) = mappend
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