A Lens is actually a lens family as described in http://comonad.com/reader/2012/mirrored-lenses/.

With great power comes great responsibility and a Lens is subject to the three common sense Lens laws:

1) You get back what you put in:

 view l (set l v s)  ≡ v

2) Putting back what you got doesn't change anything:

 set l (view l s) s  ≡ s

3) Setting twice is the same as setting once:

 set l v' (set l v s) ≡ set l v' s

These laws are strong enough that the 4 type parameters of a Lens cannot vary fully independently. For more on how they interact, read the "Why is it a Lens Family?" section of http://comonad.com/reader/2012/mirrored-lenses/.

There are some emergent properties of these laws:

1) set l s must be injective for every s This is a consequence of law #1

2) set l must be surjective, because of law #2, which indicates that it is possible to obtain any v from some s such that set s v = s

3) Given just the first two laws you can prove a weaker form of law #3 where the values v that you are setting match:

 set l v (set l v s) ≡ set l v s

Every Lens can be used directly as a Setter or Traversal.

You can also use a Lens for Getting as if it were a Fold or Getter.

Since every Lens is a valid Traversal, the Traversal laws are required of any Lens you create:

 l pure ≡ pure
 fmap (l f) . l g ≡ getCompose . l (Compose . fmap f . g)

 type Lens s t a b = forall f. Functor f => LensLike f s t a b

 type Lens' = Simple Lens

Every IndexedLens is a valid Lens and a valid IndexedTraversal.

 type IndexedLens' i = Simple (IndexedLens i)

When you see this as an argument to a function, it expects a Lens.

This type can also be used when you need to store a Lens in a container, since it is rank-1. You can turn them back into a Lens with cloneLens, or use it directly with combinators like storing and (^#).

 type ALens' = Simple ALens

When you see this as an argument to a function, it expects an IndexedLens

 type AnIndexedLens' = Simple (AnIndexedLens i)

Build a Lens from a getter and a setter.

 lens :: Functor f => (s -> a) -> (s -> b -> t) -> (a -> f b) -> s -> f t

>>> s ^. lens getter setter
getter s

>>> s & lens getter setter .~ b
setter s b

>>> s & lens getter setter %~ f
setter s (f (getter s))

 lens :: (s -> a) -> (s -> a -> s) -> Lens' s a

Build an IndexedLens from a Getter and a Setter.

Build an index-preserving Lens from a Getter and a Setter.

(%%~) can be used in one of two scenarios:

When applied to a Lens, it can edit the target of the Lens in a structure, extracting a functorial result.

When applied to a Traversal, it can edit the targets of the traversals, extracting an applicative summary of its actions.

For all that the definition of this combinator is just:

 (%%~) ≡ id

It may be beneficial to think about it as if it had these even more restricted types, however:

 (%%~) :: Functor f =>     Iso s t a b       -> (a -> f b) -> s -> f t
 (%%~) :: Functor f =>     Lens s t a b      -> (a -> f b) -> s -> f t
 (%%~) :: Applicative f => Traversal s t a b -> (a -> f b) -> s -> f t

When applied to a Traversal, it can edit the targets of the traversals, extracting a supplemental monoidal summary of its actions, by choosing f = ((,) m)

 (%%~) ::             Iso s t a b       -> (a -> (r, b)) -> s -> (r, t)
 (%%~) ::             Lens s t a b      -> (a -> (r, b)) -> s -> (r, t)
 (%%~) :: Monoid m => Traversal s t a b -> (a -> (m, b)) -> s -> (m, t)

Modify the target of a Lens in the current state returning some extra information of type r or modify all targets of a Traversal in the current state, extracting extra information of type r and return a monoidal summary of the changes.

>>> runState (_1 %%= \x -> (f x, g x)) (a,b)
(f a,(g a,b))

 (%%=) ≡ (state .)

It may be useful to think of (%%=), instead, as having either of the following more restricted type signatures:

 (%%=) :: MonadState s m             => Iso s s a b       -> (a -> (r, b)) -> m r
 (%%=) :: MonadState s m             => Lens s s a b      -> (a -> (r, b)) -> m r
 (%%=) :: (MonadState s m, Monoid r) => Traversal s s a b -> (a -> (r, b)) -> m r

Adjust the target of an IndexedLens returning a supplementary result, or adjust all of the targets of an IndexedTraversal and return a monoidal summary of the supplementary results and the answer.

(%%@~) ≡ withIndex

 (%%@~) :: Functor f => IndexedLens i s t a b      -> (i -> a -> f b) -> s -> f t
 (%%@~) :: Applicative f => IndexedTraversal i s t a b -> (i -> a -> f b) -> s -> f t

In particular, it is often useful to think of this function as having one of these even more restricted type signatures:

 (%%@~) ::             IndexedLens i s t a b      -> (i -> a -> (r, b)) -> s -> (r, t)
 (%%@~) :: Monoid r => IndexedTraversal i s t a b -> (i -> a -> (r, b)) -> s -> (r, t)

Adjust the target of an IndexedLens returning a supplementary result, or adjust all of the targets of an IndexedTraversal within the current state, and return a monoidal summary of the supplementary results.

l %%@= f ≡ state (l %%@~ f)

 (%%@=) :: MonadState s m                 => IndexedLens i s s a b      -> (i -> a -> (r, b)) -> s -> m r
 (%%@=) :: (MonadState s m, Monoid r) => IndexedTraversal i s s a b -> (i -> a -> (r, b)) -> s -> m r

Adjust the target of an IndexedLens returning the intermediate result, or adjust all of the targets of an IndexedTraversal and return a monoidal summary along with the answer.

l <%~ f ≡ l <%@~ const f

When you do not need access to the index then (<%~) is more liberal in what it can accept.

If you do not need the intermediate result, you can use (%@~) or even (%~).

 (<%@~) ::             IndexedLens i s t a b      -> (i -> a -> b) -> s -> (b, t)
 (<%@~) :: Monoid b => IndexedTraversal i s t a b -> (i -> a -> b) -> s -> (b, t)

Adjust the target of an IndexedLens returning the intermediate result, or adjust all of the targets of an IndexedTraversal within the current state, and return a monoidal summary of the intermediate results.

 (<%@=) :: MonadState s m                 => IndexedLens i s s a b      -> (i -> a -> b) -> m b
 (<%@=) :: (MonadState s m, Monoid b) => IndexedTraversal i s s a b -> (i -> a -> b) -> m b

Adjust the target of an IndexedLens returning the old value, or adjust all of the targets of an IndexedTraversal and return a monoidal summary of the old values along with the answer.

 (<<%@~) ::             IndexedLens i s t a b      -> (i -> a -> b) -> s -> (a, t)
 (<<%@~) :: Monoid a => IndexedTraversal i s t a b -> (i -> a -> b) -> s -> (a, t)

Adjust the target of an IndexedLens returning the old value, or adjust all of the targets of an IndexedTraversal within the current state, and return a monoidal summary of the old values.

 (<<%@=) :: MonadState s m                 => IndexedLens i s s a b      -> (i -> a -> b) -> m a
 (<<%@=) :: (MonadState s m, Monoid b) => IndexedTraversal i s s a b -> (i -> a -> b) -> m a

Passes the result of the left side to the function on the right side (forward pipe operator).

This is the flipped version of ($), which is more common in languages like F# as (|>) where it is needed for inference. Here it is supplied for notational convenience and given a precedence that allows it to be nested inside uses of ($).

>>> a & f
f a

>>> "hello" & length & succ
6

This combinator is commonly used when applying multiple Lens operations in sequence.

>>> ("hello","world") & _1.element 0 .~ 'j' & _1.element 4 .~ 'y'
("jelly","world")

This reads somewhat similar to:

>>> flip execState ("hello","world") $ do _1.element 0 .= 'j'; _1.element 4 .= 'y'
("jelly","world")

Infix flipped fmap.

 (<&>) = flip fmap

This is convenient to flip argument order of composite functions.

>>> over _2 ?? ("hello","world") $ length
("hello",5)

>>> over ?? length ?? ("hello","world") $ _2
("hello",5)

Merge two lenses, getters, setters, folds or traversals.

 chosen ≡ choosing id id

 choosing :: Getter s a     -> Getter s' a     -> Getter (Either s s') a
 choosing :: Fold s a       -> Fold s' a       -> Fold (Either s s') a
 choosing :: Lens' s a      -> Lens' s' a      -> Lens' (Either s s') a
 choosing :: Traversal' s a -> Traversal' s' a -> Traversal' (Either s s') a
 choosing :: Setter' s a    -> Setter' s' a    -> Setter' (Either s s') a

This is a Lens that updates either side of an Either, where both sides have the same type.

 chosen ≡ choosing id id

>>> Left a^.chosen
a

>>> Right a^.chosen
a

>>> Right "hello"^.chosen
"hello"

>>> Right a & chosen *~ b
Right (a * b)

 chosen :: Lens (Either a a) (Either b b) a b
 chosen f (Left a)  = Left <$> f a
 chosen f (Right a) = Right <$> f a

alongside makes a Lens from two other lenses or a Getter from two other getters by executing them on their respective halves of a product.

>>> (Left a, Right b)^.alongside chosen chosen
(a,b)

>>> (Left a, Right b) & alongside chosen chosen .~ (c,d)
(Left c,Right d)

 alongside :: Lens   s t a b -> Lens   s' t' a' b' -> Lens   (s,s') (t,t') (a,a') (b,b')
 alongside :: Getter s t a b -> Getter s' t' a' b' -> Getter (s,s') (t,t') (a,a') (b,b')

Lift a Lens so it can run under a function (or other corepresentable profunctor).

 inside :: Lens s t a b -> Lens (e -> s) (e -> t) (e -> a) (e -> b)

Modify the target of a Lens and return the result.

When you do not need the result of the addition, (%~) is more flexible.

 (<%~) ::             Lens s t a b      -> (a -> b) -> s -> (b, t)
 (<%~) ::             Iso s t a b       -> (a -> b) -> s -> (b, t)
 (<%~) :: Monoid b => Traversal s t a b -> (a -> b) -> s -> (b, t)

Increment the target of a numerically valued Lens and return the result.

When you do not need the result of the addition, (+~) is more flexible.

 (<+~) :: Num a => Lens' s a -> a -> s -> (a, s)
 (<+~) :: Num a => Iso' s a  -> a -> s -> (a, s)

Decrement the target of a numerically valued Lens and return the result.

When you do not need the result of the subtraction, (-~) is more flexible.

 (<-~) :: Num a => Lens' s a -> a -> s -> (a, s)
 (<-~) :: Num a => Iso' s a  -> a -> s -> (a, s)

Multiply the target of a numerically valued Lens and return the result.

When you do not need the result of the multiplication, (*~) is more flexible.

 (<*~) :: Num a => Lens' s a -> a -> s -> (a, s)
 (<*~) :: Num a => Iso'  s a -> a -> s -> (a, s)

Divide the target of a fractionally valued Lens and return the result.

When you do not need the result of the division, (//~) is more flexible.

 (<//~) :: Fractional a => Lens' s a -> a -> s -> (a, s)
 (<//~) :: Fractional a => Iso'  s a -> a -> s -> (a, s)

Raise the target of a numerically valued Lens to a non-negative Integral power and return the result.

When you do not need the result of the operation, (^~) is more flexible.

 (<^~) :: (Num a, Integral e) => Lens' s a -> e -> s -> (a, s)
 (<^~) :: (Num a, Integral e) => Iso' s a -> e -> s -> (a, s)

Raise the target of a fractionally valued Lens to an Integral power and return the result.

When you do not need the result of the operation, (^^~) is more flexible.

 (<^^~) :: (Fractional a, Integral e) => Lens' s a -> e -> s -> (a, s)
 (<^^~) :: (Fractional a, Integral e) => Iso' s a -> e -> s -> (a, s)

Raise the target of a floating-point valued Lens to an arbitrary power and return the result.

When you do not need the result of the operation, (**~) is more flexible.

 (<**~) :: Floating a => Lens' s a -> a -> s -> (a, s)
 (<**~) :: Floating a => Iso' s a  -> a -> s -> (a, s)

Logically || a Boolean valued Lens and return the result.

When you do not need the result of the operation, (||~) is more flexible.

 (<||~) :: Lens' s Bool -> Bool -> s -> (Bool, s)
 (<||~) :: Iso' s Bool  -> Bool -> s -> (Bool, s)

Logically && a Boolean valued Lens and return the result.

When you do not need the result of the operation, (&&~) is more flexible.

 (<&&~) :: Lens' s Bool -> Bool -> s -> (Bool, s)
 (<&&~) :: Iso' s Bool  -> Bool -> s -> (Bool, s)

mappend a monoidal value onto the end of the target of a Lens and return the result.

When you do not need the result of the operation, (<>~) is more flexible.

Modify the target of a Lens, but return the old value.

When you do not need the result of the addition, (%~) is more flexible.

 (<<%~) ::             Lens s t a b      -> (a -> b) -> s -> (a, t)
 (<<%~) ::             Iso s t a b       -> (a -> b) -> s -> (a, t)
 (<<%~) :: Monoid a => Traversal s t a b -> (a -> b) -> s -> (a, t)

Modify the target of a Lens, but return the old value.

When you do not need the old value, (%~) is more flexible.

 (<<.~) ::             Lens s t a b      -> b -> s -> (a, t)
 (<<.~) ::             Iso s t a b       -> b -> s -> (a, t)
 (<<.~) :: Monoid a => Traversal s t a b -> b -> s -> (a, t)

Modify the target of a Lens into your 'Monad'\'s state by a user supplied function and return the result.

When applied to a Traversal, it this will return a monoidal summary of all of the intermediate results.

When you do not need the result of the operation, (%=) is more flexible.

 (<%=) :: MonadState s m             => Lens' s a      -> (a -> a) -> m a
 (<%=) :: MonadState s m             => Iso' s a       -> (a -> a) -> m a
 (<%=) :: (MonadState s m, Monoid a) => Traversal' s a -> (a -> a) -> m a

Add to the target of a numerically valued Lens into your 'Monad'\'s state and return the result.

When you do not need the result of the addition, (+=) is more flexible.

 (<+=) :: (MonadState s m, Num a) => Lens' s a -> a -> m a
 (<+=) :: (MonadState s m, Num a) => Iso' s a -> a -> m a

Subtract from the target of a numerically valued Lens into your 'Monad'\'s state and return the result.

When you do not need the result of the subtraction, (-=) is more flexible.

 (<-=) :: (MonadState s m, Num a) => Lens' s a -> a -> m a
 (<-=) :: (MonadState s m, Num a) => Iso' s a -> a -> m a

Multiply the target of a numerically valued Lens into your 'Monad'\'s state and return the result.

When you do not need the result of the multiplication, (*=) is more flexible.

 (<*=) :: (MonadState s m, Num a) => Lens' s a -> a -> m a
 (<*=) :: (MonadState s m, Num a) => Iso' s a -> a -> m a

Divide the target of a fractionally valued Lens into your 'Monad'\'s state and return the result.

When you do not need the result of the division, (//=) is more flexible.

 (<//=) :: (MonadState s m, Fractional a) => Lens' s a -> a -> m a
 (<//=) :: (MonadState s m, Fractional a) => Iso' s a -> a -> m a

Raise the target of a numerically valued Lens into your 'Monad'\'s state to a non-negative Integral power and return the result.

When you do not need the result of the operation, (^=) is more flexible.

 (<^=) :: (MonadState s m, Num a, Integral e) => Lens' s a -> e -> m a
 (<^=) :: (MonadState s m, Num a, Integral e) => Iso' s a -> e -> m a

Raise the target of a fractionally valued Lens into your 'Monad'\'s state to an Integral power and return the result.

When you do not need the result of the operation, (^^=) is more flexible.

 (<^^=) :: (MonadState s m, Fractional b, Integral e) => Lens' s a -> e -> m a
 (<^^=) :: (MonadState s m, Fractional b, Integral e) => Iso' s a  -> e -> m a

Raise the target of a floating-point valued Lens into your 'Monad'\'s state to an arbitrary power and return the result.

When you do not need the result of the operation, (**=) is more flexible.

 (<**=) :: (MonadState s m, Floating a) => Lens' s a -> a -> m a
 (<**=) :: (MonadState s m, Floating a) => Iso' s a -> a -> m a

Logically || a Boolean valued Lens into your 'Monad'\'s state and return the result.

When you do not need the result of the operation, (||=) is more flexible.

 (<||=) :: MonadState s m => Lens' s Bool -> Bool -> m Bool
 (<||=) :: MonadState s m => Iso' s Bool  -> Bool -> m Bool

Logically && a Boolean valued Lens into your 'Monad'\'s state and return the result.

When you do not need the result of the operation, (&&=) is more flexible.

 (<&&=) :: MonadState s m => Lens' s Bool -> Bool -> m Bool
 (<&&=) :: MonadState s m => Iso' s Bool  -> Bool -> m Bool

mappend a monoidal value onto the end of the target of a Lens into your 'Monad'\'s state and return the result.

When you do not need the result of the operation, (<>=) is more flexible.

Modify the target of a Lens into your 'Monad'\'s state by a user supplied function and return the old value that was replaced.

When applied to a Traversal, it this will return a monoidal summary of all of the old values present.

When you do not need the result of the operation, (%=) is more flexible.

 (<<%=) :: MonadState s m             => Lens' s a      -> (a -> a) -> m a
 (<<%=) :: MonadState s m             => Iso' s a       -> (a -> a) -> m a
 (<<%=) :: (MonadState s m, Monoid b) => Traversal' s a -> (a -> a) -> m a

(<<%=) :: MonadState s m => LensLike ((,)a) s s a b -> (a -> b) -> m a

Modify the target of a Lens into your 'Monad'\'s state by a user supplied function and return the old value that was replaced.

When applied to a Traversal, it this will return a monoidal summary of all of the old values present.

When you do not need the result of the operation, (.=) is more flexible.

 (<<.=) :: MonadState s m             => Lens' s a      -> a -> m a
 (<<.=) :: MonadState s m             => Iso' s a       -> a -> m a
 (<<.=) :: (MonadState s m, Monoid t) => Traversal' s a -> a -> m a

Run a monadic action, and set the target of Lens to its result.

 (<<~) :: MonadState s m => Iso s s a b   -> m b -> m b
 (<<~) :: MonadState s m => Lens s s a b  -> m b -> m b

NB: This is limited to taking an actual Lens than admitting a Traversal because there are potential loss of state issues otherwise.

Cloning a Lens is one way to make sure you aren't given something weaker, such as a Traversal and can be used as a way to pass around lenses that have to be monomorphic in f.

Note: This only accepts a proper Lens.

>>> let example l x = set (cloneLens l) (x^.cloneLens l + 1) x in example _2 ("hello",1,"you")
("hello",2,"you")

Clone a Lens as an IndexedPreservingLens that just passes through whatever index is on any IndexedLens, IndexedFold, IndexedGetter or IndexedTraversal it is composed with.

Clone an IndexedLens as an IndexedLens with the same index.

over for Arrows.

Unlike over, overA can't accept a simple Setter, but requires a full lens, or close enough.

 overA :: Arrow ar => Lens s t a b -> ar a b -> ar s t

A version of set that works on ALens.

>>> storing _2 "world" ("hello","there")
("hello","world")

A version of (^.) that works on ALens.

>>> ("hello","world")^#_2
"world"

A version of (.~) that works on ALens.

>>> ("hello","there") & _2 #~ "world"
("hello","world")

A version of (%~) that works on ALens.

>>> ("hello","world") & _2 #%~ length
("hello",5)

A version of (%%~) that works on ALens.

>>> ("hello","world") & _2 #%%~ \x -> (length x, x ++ "!")
(5,("hello","world!"))

A version of (<.~) that works on ALens.

>>> ("hello","there") & _2 <#~ "world"
("world",("hello","world"))

A version of (<%~) that works on ALens.

>>> ("hello","world") & _2 <#%~ length
(5,("hello",5))

A version of (.=) that works on ALens.

A version of (%=) that works on ALens.

A version of (%%=) that works on ALens.

A version of (<.=) that works on ALens.

A version of (<%=) that works on ALens.

There is a field for every type in the Void. Very zen.

>>> [] & mapped.devoid +~ 1
[]

>>> Nothing & mapped.devoid %~ abs
Nothing

 devoid :: Lens' Void a

We can always retrieve a () from any type.

>>> "hello"^.united
()

>>> "hello" & united .~ ()
"hello"

The indexed store can be used to characterize a Lens and is used by clone.

Context a b t is isomorphic to newtype Context a b t = Context { runContext :: forall f. Functor f => (a -> f b) -> f t }, and to exists s. (s, Lens s t a b).

A Context is like a Lens that has already been applied to a some structure.

type Context' a s = Context a a s

This Lens lets you view the current pos of any indexed store comonad and seek to a new position. This reduces the API for working these instances to a single Lens.

 ipos w ≡ w ^. locus
 iseek s w ≡ w & locus .~ s
 iseeks f w ≡ w & locus %~ f

 locus :: Lens' (Context' a s) a
 locus :: Conjoined p => Lens' (Pretext' p a s) a
 locus :: Conjoined p => Lens' (PretextT' p g a s) a