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I can't seem to find any explanation of what lenses are used for in practical examples. This short paragraph from the Hackage page is the closest I've found:

This modules provides a convienient way to access and update the elements of a structure. It is very similar to Data.Accessors, but a bit more generic and has fewer dependencies. I particularly like how cleanly it handles nested structures in state monads.

So, what are they used for? What benefits and disadvantages do they have over other methods? Why are they needed?

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You might enjoy watching Edward Kmett's Lenses: A Functional Imperative talk. It's presented in Scala, but the translation to the usefulness of lenses in Haskell should be clear. –  Dan Burton May 29 '12 at 5:11

4 Answers 4

up vote 41 down vote accepted

They offer a clean abstraction over data updates, and are never really "needed." They just let you reason about a problem in a different way.

In some imperative/"object-oriented" programming languages like C, you have the familiar concept of some collection of values (let's call them "structs") and ways to label each value in the collection (the labels are typically called "fields"). This leads to a definition like this:

typedef struct { /* defining a new struct type */
  float x; /* field */
  float y; /* field */
} Vec2;

typedef struct {
  Vec2 col1; /* nested structs */
  Vec2 col2;
} Mat2;

You can then create values of this newly defined type like so:

Vec2 vec = { 2.0f, 3.0f };
/* Reading the components of vec */
float foo = vec.x;
/* Writing to the components of vec */
vec.y = foo;

Mat2 mat = { vec, vec };
/* Changing a nested field in the matrix */
mat.col2.x = 4.0f;

Similarly in Haskell, we have data types:

data Vec2 =
  { vecX :: Float
  , vecY :: Float

data Mat2 =
  { matCol1 :: Vec2
  , matCol2 :: Vec2

This data type is then used like this:

let vec  = Vec2 2 3
    -- Reading the components of vec
    foo  = vecX vec
    -- Creating a new vector with some component changed.
    vec2 = vec { vecY = foo }

    mat = Mat2 vec2 vec2

However, in Haskell, there's no easy way of changing nested fields in a data structure. This is because you need to re-create all of the wrapping objects around the value that you are changing, because Haskell values are immutable. If you have a matrix like the above in Haskell, and want to change the upper right cell in the matrix, you have to write this:

    mat2 = mat { matCol2 = (matCol2 mat) { vecX = 4 } }

It works, but it looks clumsy. So, what someone came up with, is basically this: If you group two things together: the "getter" of a value (like vecX and matCol2 above) with a corresponding function that, given the data structure that the getter belongs to, can create a new data structure with that value changed, you are able to do a lot of neat stuff. For example:

data Data = Data { member :: Int }

-- The "getter" of the member variable
getMember :: Data -> Int
getMember d = member d

-- The "setter" or more accurately "updater" of the member variable
setMember :: Data -> Int -> Data
setMember d m = d { member = m }

memberLens :: (Data -> Int, Data -> Int -> Data)
memberLens = (getMember, setMember)

There are many ways of implementing lenses; for this text, let's say that a lens is like the above:

type Lens a b = (a -> b, a -> b -> a)

I.e. it is the combination of a getter and a setter for some type a which has a field of type b, so memberLens above would be a Lens Data Int. What does this let us do?

Well, let's first make two simple functions that extract the getters and setters from a lens:

getL :: Lens a b -> a -> b
getL (getter, setter) = getter

setL :: Lens a b -> a -> b -> a
setL (getter, setter) = setter

Now, we can start abstracting over stuff. Let's take the situation above again, that we want to modify a value "two stories deep." We add a data structure with another lens:

data Foo = Foo { subData :: Data }

subDataLens :: Lens Foo Data
subDataLens = (subData, \ f s -> f { subData = s }) -- short lens definition

Now, let's add a function that composes two lenses:

(#) :: Lens a b -> Lens b c -> Lens a c
(#) (getter1, setter1) (getter2, setter2) =
    (getter2 . getter1, combinedSetter)
      combinedSetter a x =
        let oldInner = getter1 a
            newInner = setter2 oldInner x
        in setter1 a newInner

The code is kind of quickly written, but I think it's clear what it does: the getters are simply composed; you get the inner data value, and then you read its field. The setter, when it is supposed to alter some value a with the new inner field value of x, first retrieves the old inner data structure, sets its inner field, and then updates the outer data structure with the new inner data structure.

Now, let's make a function that simply increments the value of a lens:

increment :: Lens a Int -> a -> a
increment l a = setL l a (getL l a + 1)

If we have this code, it becomes clear what it does:

d = Data 3
print $ increment memberLens d -- Prints "Data 4", the inner field is updated.

Now, because we can compose lenses, we can also do this:

f = Foo (Data 5)
print $ increment (subDataLens#memberLens) f
-- Prints "Foo (Data 6)", the innermost field is updated.

What all of the lens packages do is essentially to wrap this concept of lenses - the grouping of a "setter" and a "getter," into a neat package that makes them easy to use. In a particular lens implementation, one would be able to write:

with (Foo (Data 5)) $ do
  subDataLens . memberLens $= 7

So, you get very close to the C version of the code; it becomes very easy to modify nested values in a tree of data structures.

Lenses are nothing more than this: an easy way of modifying parts of some data. Because it becomes so much easier to reason about certain concepts because of them, they see a wide use in situations where you have huge sets of data structures that have to interact with one another in various ways.

For the pros and cons of lenses, see a recent question here on SO.

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One important point your answer is missing is that lenses are first class, so you can build other abstractions from them. The built-in record syntax fails in that regard. –  jberryman May 29 '12 at 0:59
Also, I wrote a blog post on lenses that might be useful to the OP:… –  Gabriel Gonzalez May 29 '12 at 3:13

Lenses provide convenient ways to edit data structures, in a uniform, compositional way.

Many programs are built around the following operations:

  • viewing a component of a (possibly nested) data structure
  • updating fields of (possibly nested) data structures

Lenses provide language support for viewing and editing structures in a way that ensures your edits are consistent; that edits can be composed easily; and that the same code can be used for viewing parts of a structure, as for updating the parts of the structure.

Lenses thus make it easy to write programs from views onto structures; and from structures back on to views (and editors) for those structures. They clean up a lot of the mess of record accessors and setters.

Pierce et al. popularized lenses, e.g. in their Quotient Lenses paper, and implementations for Haskell are now widely used (e.g. fclabels and data-accessors).

For concrete use cases, consider:

  • graphical user interfaces, where a user is editing information in a structured way
  • parsers and pretty printers
  • compilers
  • synchronizing updating data structures
  • databases and schemas

and many other situations where you have a data structure model of the world, and a editable view onto that data.

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As an additional note it is often overlooked that lenses implement a very generic notion of "field access and update". Lenses can be written for all kinds of things, including function-like objects. It requires a bit of abstract thinking to appreciate this, so let me show you an example of the power of lenses:

at :: (Eq a) => a -> Lens (a -> b) b

Using at you can actually access and manipulate functions with multiple arguments depending on earlier arguments. Just keep in mind that Lens is a category. This is a very useful idiom for locally adjusting functions or other things.

You can also access data by properties or alternate representations:

polar :: (Floating a, RealFloat a) => Lens (Complex a) (a, a)
mag   :: (RealFloat a) => Lens (Complex a) a

You can go further writing lenses to access individual bands of a Fourier-transformed signal and a lot more.

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These lecture notes by Bryan O'Sullivan cover this topic in ample detail.

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