What are the differences between lenses and zippers?

This is an example of using a zipper in Haskell:

``````data Tree a = Fork (Tree a) (Tree a) | Leaf a
data Cxt a = Top | L (Cxt a) (Tree a) | R (Tree a) (Cxt a)
type Loc a = (Tree a, Cxt a)

left :: Loc a -> Loc a
left (Fork l r, c) = (l, L c r)

right :: Loc a -> Loc a
right (Fork l r, c) = (r, R l c)

top :: Tree a -> Loc a
top t = (t, Top)

up :: Loc a -> Loc a
up (t, L c r) = (Fork t r, c)
up (t, R l c) = (Fork l t, c)

upmost :: Loc a -> Loc a
upmost l@(t, Top) = l
upmost l = upmost (up l)

modify :: Loc a -> (Tree a -> Tree a) -> Loc a
modify (t, c) f = (f t, c)
``````

This is an example of using a zipper in Clojure:

``````(use 'clojure.zip)
(require '[clojure.zip :as z])

user> (def z [[1 2 3] [4 [5 6] 7] [8 9]])
#'user/z

user> (def zp (zipper vector? seq (fn [_ c] c) z))
#'user/zp

user> zp
[[[1 2 3] [4 [5 6] 7] [8 9]] nil]

user> (-> zp down)
[[1 2 3] {:l [], :pnodes [[[1 2 3] [4 [5 6] 7] [8 9]]], :ppath nil, :r ([4 [5 6] 7] [8 9])}]

user> (first (-> zp down))
[1 2 3]
``````

This is an example of using a Lens in Haskell:

``````data Person = P { name :: String
}
data Address = A { street :: String
, city :: String
, postcode :: String
}

setPostcode :: String -> Person -> Person
setPostcode pc p = p { addr = addr p { postcode = pc }}
``````

This is an example of using a Lens in Clojure.

``````(use 'lens)

(defrecord Address [street city postcode])
(defrecord Person [name age address])

(def -postcode (mklens :postcode))
(def -city (mklens :city))
(def -street (mklens :street))
(def -age (mklens :age))
(def -name (mklens :name))
(def -uid (mklens :uid))
(def -identity (mklens :identity))

(-get -postcode home)

(-set -postcode home 500)
``````

Now it seems both lenses and zippers are functional ways of traversing nested data structures.

My question is: What are the differences between lenses and zippers? Is one suited to a particular use case?

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You can move around in zippers? In general zippers have 'go left', 'go up', etc primitives; you can't normally move a lens a bit to the left. They are closely related though. –  drquicksilver Feb 28 '14 at 12:18
A lens is just conceptually a getter/setter pair that can go arbitrarily deep into a data structure (it's actually even a little more general than this). A zipper is a specific kind of data structure where you can (at least) move left and right/up and down. –  David Young Feb 28 '14 at 20:14

Zippers are akin to cursors: they allow to traverse trees in an ordered manner. Their usual operations are `up`, `down`, `left`, `right` and `edit`. (names may vary depending on impl)

Lenses are some sort of generalized keys (as in "keys of an associative datastructure"). The structure does not need to be ordered. Their usual operations are `fetch` and `putback` and are very similar to `get` and `assoc`. (names may vary depending on impl)

So as you see zippers are very much concerned about hierarchy (up/down) and order (left/right) while lenses are just about focusing (hence the name) on a piece of data, which may even be a projection (that is something that didn't existed on its own in the original structure).

For example in my ongoing work on Enliven, I have lenses that allow me to focus on a single class or style attribute in a HTML document.

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Zippers are a variant of a datatype which unfolds the type into its local context and its extents in all directions. Atop a Zipper you can implement efficient motion and local update.

Lenses are first class examinations of a particular component of a data type. They focus on 0, 1, or many subparts of a data structure. Notably, your example of a lens in Haskell is not actually a lens—it's not first class.

It's perfectly reasonable to build a lens which focuses on some part of a zipper. For instance, an even simpler zipper than your examples is a Cons list zipper

``````data Cons a = Empty | Cons a (Cons a)

data ConsZ a = ConsZ { lefts :: Cons a; here :: a; rights :: Cons a }

zip :: Cons a -> Maybe (ConsZ a)
zip Empty = Nothing
zip (Cons a as) = ConsZ Empty a as

unzip :: ConsZ a -> Cons a
unzip (ConsZ Empty a as) = Cons a as
unzip (ConsZ (Cons l ls) a as) = unzip (ConsZ ls) l (Cons a as)
``````

We can incrementally modify this structure, moving the focus left or right

``````moveRight :: ConsZ a -> Maybe (ConsZ a)
moveRight (ConsZ _ _ Empty) = Nothing
moveRight (ConsZ ls x (Cons a as)) =  ConsZ (Cons x ls) a as
``````

and modify the current local point

``````modify :: (a -> a) -> ConsZ a -> ConsZ a
modify f (ConsZ ls x rs) = ConsZ ls (f x) rs
``````

We can also build lenses which access each part of the zipper structure

``````type Lens s a = forall f . Functor f => (a -> f a) -> (s -> f s)

_lefts :: Lens (ConsZ a) a
_lenfs inj (ConsZ ls x rs) = (\ls -> ConsZ ls' x rs) <\$> inj ls

_here :: Lens (ConsZ a) a
_here inj (ConsZ ls x rs) = (\x' -> ConsZ ls x' rs) <\$> inj x
``````

And even use them to build our zipper actions effectively

``````over :: ((a -> Identity a) -> s -> Identity s) -> (a -> a) -> (s -> s)
over l f s = runIdentity (l (Identity . f) s)

modify = over _here
``````

Ultimately, however, a lens is always a first class access to a particular point in a data structure. They can be composed which gives the illusion of "motion" in a type, but if you really want that then you ought to make the zipper transform and use a real zipper type.

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