# Every Lens' is a Traversal'... how?

``````type Traversal' a b = forall f . Applicative f => (b -> f b) -> (a -> f a)
type Lens'      a b = forall f . Functor     f => (b -> f b) -> (a -> f a)
``````

Notice that the only difference between a Lens' and a Traversal' is the type class constraint. A Lens' has a Functor constraint and Traversal' has an Applicative constraint. This means that any Lens' is automatically also a valid Traversal' (since Functor is a superclass of Applicative).

I simply don't follow the logical sequence here. We know that every `Applicative` is a `Functor`. From this, should it not follow, if at all, that every `Traversal'` is a `Lens'`? The tutorial however reaches the converse conclusion.

## 3 Answers

A `Lens'` works for all functors, which includes all applicative functors, so if a function `g` is a `Lens'`, then `g` is also a `Traversal'`.

A `Traversal'` works for all applicative functors, but not necessarily all functors. So if a function `h` is a `Traversal'`, it is not necessarily a `Lens'`.

(I'm not the one to describe this formally, but to me at least, it looks like the types are "contravariant" in their constraints. `Lens'` is a subtype of `Traversal'` precisely because `Functor` is a superclass of `Applicative`.)

• Another way of putting it that may help: If a Lens were a Functor and a Traversal were an Applicative, the logic in the question would make sense. But rather, a Lens is something that takes a Functor as an argument, while a Traversal takes an Applicative as an argument. So the more general item is the one with the more general argument. Feb 21 at 20:34
• Honestly, I'd love if someone would (accurately) describe how the `forall f` works. I assume a good answer would explain the difference between `Applicative f => ...` and `forall f . Applicative f => ...`. (I'm correct in assuming this is a necessary `forall`, and not just an explicit `forall`, right?) Feb 21 at 20:41
• (Either in a new answer, or editing this one; I'm fine with changing this to a community wiki in the latter case.) Feb 21 at 20:42
• I'm not sure where you got the names `f` and `g` from (probably just using the common function monikers?), but it's not immediately clear that you are not referring to the type variable `f` from the definitions in the question. Feb 22 at 23:32
• @chepner You might like my answer at Why can a Num act like a Fractional?, which attempts to accurately describe how `forall` works and how it interacts with type classes. Feb 23 at 21:52

I'm not usually a fan of cute "real-world entity" analogies, but this matter probably does become clearer by considering the following example:

``````class Animal a where feed :: a -> ArmouredGlove -> IO String

instance Animal Cat where feed _ _ = print "Miaow"
instance Animal Dog where feed _ _ = print "Woof"
instance Animal Lion where feed _ _ = print "Rwaaar"

class Animal a => Pet a where cuddle :: a -> UnprotectedHand -> IO String

instance Pet Cat where cuddle _ _ = print "Purr"
instance Pet Dog where cuddle _ _ = print "Yawn"

type PetOwner = ∀ a . Pet a => a -> IO String
type ZooWarden = ∀ a . Animal a => a -> IO String

peter :: PetOwner
peter = \pet -> cuddle pet peter'sHand

zoey :: ZooWarden
zoey = \animal -> feed animal zoey'sGlove
``````

Here, `ZooWarden` is a subtype of `PetOwner`. Zoey can handle a pet just fine, she can feed any dog as well as lions. But Peter does not have such qualification, he can only handle harmless pets. So, precisely because he is restricted to a more specific class of animals, he himself is member of a more general type of person than the specialised zoo warden.

• Why are `Peter'sHand` and `Zoey'sGlove` types here? Shouldn't they be concrete instances of `UnprotectedHand` and `ArmouredGlove`? Feb 22 at 17:24
• @A.R. they're constructors. But yeah, maybe that doesn't make so much sense, I'm making them simple values. Feb 22 at 19:55

Consider the dictionary-passing view of type classes. This is how type classes are actually implemented in GHC.

## Background

In this form, type classes like `Functor` and `Applicative` look something like this:

``````data Functor f =
MkFunctor
{ fmap :: (a -> b) -> f a -> f b }

data Applicative f =
MkApplicative
{ appFunctor :: Functor f
, pure :: a -> f a
, (<*>) :: f (a -> b) -> f a -> f b
}
``````

Instances are values of those types, for example like this:

``````listFunctor :: Functor []
listFunctor =
MkFunctor
{ fmap = map }
``````

## Lenses and traversals

Now, let's say we have a lens `someLens :: Lens' A B` and we want to turn it into a traversal. Let's expand the type synonym and use dictionary passing:

``````someLens :: Functor f -> (b -> f b) -> (a -> f a)
``````

In this style, you might use it with the list functor like this `someLens listFunctor`.

We want a traversal `someTraversal :: Traversal' A B`. When we implement this, we will need to provide `someLens` with a `Functor f` value. But we already have an `Applicative f` value:

``````someTraversal :: Applicative f -> (b -> f b) -> (a -> f a)
someTraversal applicativeDict = someLens (appFunctor applicativeDict)
``````

We can just use the field accessor that gets the `Functor` implementation for the `Applicative` instance we were given, and we have a `Traversal`. The field accessor has type `appFunctor :: Applicative f -> Functor f`.