17

To me it seems that you can always pass function arguments rather than using a typeclass. For example rather than defining equality typeclass:

class Eq a where 
  (==)                  :: a -> a -> Bool

And using it in other functions to indicate type argument must be an instance of Eq:

elem                    :: (Eq a) => a -> [a] -> Bool

Can't we just define our elem function without using a typeclass and instead pass a function argument that does the job?

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  • 2
    that's called dictionary passing. You can think typeclass constraints as implicit arguments.
    – Poscat
    Apr 16, 2020 at 5:31
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    You could do that, but it's obviously much more convenient to not have to pass a function and just have it use a "standard" one depending on the type. Apr 16, 2020 at 5:33
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    You could put it like that, yes. But I'd argue that there is at least one other important advantage: the ability to write polymorphic functions which work on any type which implements a particular "interface" or set of features. I think typeclass constraints express that very clearly in a way that passing extra function arguments doesn't. In particular because of the (sadly implicit) "laws" which many typeclasses have to satisfy. A Monad m constraint says more to me than passing additional function arguments of types a -> m a and m a -> (a -> m b) -> m b. Apr 16, 2020 at 5:51
  • 1
    See also are typeclasses essential?
    – luqui
    Apr 16, 2020 at 5:51
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    The TypeApplications extension lets you make the implicit argument explicit. (==) @Int 3 5 compares 3 and 5 specifically as Int values. You can think of @Int as a key in the dictionary of type-specific equality functions, rather than the Int-specific comparison function itself.
    – chepner
    Apr 16, 2020 at 11:54

2 Answers 2

19

Yes. This is called "dictionary passing style". Sometimes when I am doing some especially tricky things, I need to scrap a typeclass and turn it into a dictionary, because dictionary passing is more powerful1, yet often quite cumbersome, making conceptually simple code look quite complicated. I use dictionary passing style sometimes in languages that aren't Haskell to simulate typeclasses (but have learned that that is usually not as great an idea as it sounds).

Of course, whenever there is a difference in expressive power, there is a trade-off. While you can use a given API in more ways if it is written using DPS, the API gets more information if you can't. One way this shows up in practice is in Data.Set, which relies on the fact that there is only one Ord dictionary per type. The Set stores its elements sorted according to Ord, and if you build a set with one dictionary, and then inserted an element using a different one, as would be possible with DPS, you could break Set's invariant and cause it to crash. This uniqueness problem can be mitigated using a phantom existential type to mark the dictionary, but, again, at the cost of quite a bit of annoying complexity in the API. This also shows up in pretty much the same way in the Typeable API.

The uniqueness bit doesn't come up very often. What typeclasses are great at is writing code for you. For example,

catProcs :: (i -> Maybe String) -> (i -> Maybe String) -> (i -> Maybe String)
catProcs f g = f <> g

which takes two "processors" which take an input and might give an output, and concatenates them, flattening away Nothing, would have to be written in DPS something like this:

catProcs f g = (<>) (funcSemi (maybeSemi listSemi)) f g

We essentially had to spell out the type we're using it at again, even though we already spelled it out in the type signature, and even that was redundant because the compiler already knows all the types. Because there's only one way to construct a given Semigroup at a type, the compiler can do it for you. This has a "compound interest" type effect when you start defining a lot of parametric instances and using the structure of your types to compute for you, as in the Data.Functor.* combinators, and this is used to great effect with deriving via where you can essentially get all the "standard" algebraic structure of your type written for you.

And don't even get me started on MPTC's and fundeps, which feed information back into typechecking and inference. I have never tried converting such a thing to DPS -- I suspect it would involve passing around a lot of type equality proofs -- but in any case I'm sure it would be a lot more work for my brain than I would be comfortable with.

--

1Unless you use reflection in which case they become equivalent in power -- but reflection can also be cumbersome to use.

3
5

Yes. That (called dictionary passing) is basically what the compiler does to typeclasses anyway. For that function, done literally, it would look a bit like this:

elemBy :: (a -> a -> Bool) -> a -> [a] -> Bool
elemBy _ _ [] = False
elemBy eq x (y:ys) = eq x y || elemBy eq x ys

Calling elemBy (==) x xs is now equivalent to elem x xs. And in this specific case, you can go a step further: eq has the same first argument every time, so you can make it the caller's responsibility to apply that, and end up with this:

elemBy2 :: (a -> Bool) -> [a] -> Bool
elemBy2 _ [] = False
elemBy2 eqx (y:ys) = eqx y || elemBy2 eqx ys

Calling elemBy2 (x ==) xs is now equivalent to elem x xs.

...Oh wait. That's just any. (And in fact, in the standard library, elem = any . (==).)

1
  • AFAIU dictionary passing is Scala's approach to encoding type classes. Those extra arguments can be declared as implicit and the compiler would inject them for you from the scope.
    – michid
    Apr 16, 2020 at 22:14

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