lens-3.9.2: Lenses, Folds and Traversals

Portabilitynon-portable
Stabilityexperimental
MaintainerEdward Kmett <ekmett@gmail.com>
Safe HaskellNone

Control.Lens.Operators

Contents

Description

This module exists for users who like to work with qualified imports but want access to the operators from Lens.

 import qualified Control.Lens as L
 import Control.Lens.Operators

Synopsis

General Purpose

(&) :: a -> (a -> b) -> bSource

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")

(<&>) :: Functor f => f a -> (a -> b) -> f bSource

Infix flipped fmap.

 (<&>) = flip fmap

(??) :: Functor f => f (a -> b) -> a -> f bSource

This is convenient to flip argument order of composite functions.

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

Getting

(^.) :: s -> Getting a s a -> aSource

View the value pointed to by a Getter or Lens or the result of folding over all the results of a Fold or Traversal that points at a monoidal values.

This is the same operation as view with the arguments flipped.

The fixity and semantics are such that subsequent field accesses can be performed with (.).

>>> (a,b)^._2
b
>>> ("hello","world")^._2
"world"
>>> import Data.Complex
>>> ((0, 1 :+ 2), 3)^._1._2.to magnitude
2.23606797749979
 (^.) ::             s -> Getter s a     -> a
 (^.) :: Monoid m => s -> Fold s m       -> m
 (^.) ::             s -> Iso' s a       -> a
 (^.) ::             s -> Lens' s a      -> a
 (^.) :: Monoid m => s -> Traversal' s m -> m

(^@.) :: s -> IndexedGetting i (i, a) s a -> (i, a)Source

View the value pointed to by a Getter or Lens.

This is the same operation as iview with the arguments flipped.

The fixity and semantics are such that subsequent field accesses can be performed with (.).

>>> (a,b,c,d)^@._2
(1,b)
>>> ("hello","world","!!!")^@._2
(1,"world")
 (^@.) :: s -> IndexedGetter i s a -> (i, a)
 (^@.) :: s -> IndexedLens' i s a  -> (i, a)

The result probably doesn't have much meaning when applied to an IndexedFold.

Loupes

(^#) :: s -> ALens s t a b -> aSource

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

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

with Effects

(^!) :: Monad m => s -> Acting m a s t a b -> m aSource

Perform an Action.

>>> ["hello","world"]^!folded.act putStrLn
hello
world

(^@!) :: Monad m => s -> IndexedActing i m (i, a) s t a b -> m (i, a)Source

Perform an IndexedAction.

(^!!) :: Monad m => s -> Acting m [a] s t a b -> m [a]Source

Perform a MonadicFold and collect all of the results in a list.

>>> ["ab","cd","ef"]^!!folded.acts
["ace","acf","ade","adf","bce","bcf","bde","bdf"]

(^@!!) :: Monad m => s -> IndexedActing i m [(i, a)] s t a b -> m [(i, a)]Source

Obtain a list of all of the results of an IndexedMonadicFold.

(^!?) :: Monad m => s -> Acting m (Leftmost a) s t a b -> m (Maybe a)Source

Perform a MonadicFold and collect the leftmost result.

Note: this still causes all effects for all elements.

>>> [Just 1, Just 2, Just 3]^!?folded.acts
Just (Just 1)
>>> [Just 1, Nothing]^!?folded.acts
Nothing

(^@!?) :: Monad m => s -> IndexedActing i m (Leftmost (i, a)) s t a b -> m (Maybe (i, a))Source

Perform an IndexedMonadicFold and collect the Leftmost result.

Note: this still causes all effects for all elements.

from Folds

(^..) :: s -> Getting (Endo [a]) s a -> [a]Source

A convenient infix (flipped) version of toListOf.

>>> [[1,2],[3]]^..traverse.traverse
[1,2,3]
>>> (1,2)^..both
[1,2]
 toList xs ≡ xs ^.. folded
 (^..) ≡ flip toListOf
 (^..) :: s -> Getter s a     -> [a]
 (^..) :: s -> Fold s a       -> [a]
 (^..) :: s -> Lens' s a      -> [a]
 (^..) :: s -> Iso' s a       -> [a]
 (^..) :: s -> Traversal' s a -> [a]
 (^..) :: s -> Prism' s a     -> [a]

(^@..) :: s -> IndexedGetting i (Endo [(i, a)]) s a -> [(i, a)]Source

An infix version of itoListOf.

(^?) :: s -> Getting (First a) s a -> Maybe aSource

Perform a safe head of a Fold or Traversal or retrieve Just the result from a Getter or Lens.

When using a Traversal as a partial Lens, or a Fold as a partial Getter this can be a convenient way to extract the optional value.

Note: if you get stack overflows due to this, you may want to use firstOf instead, which can deal more gracefully with heavily left-biased trees.

>>> Left 4 ^?_Left
Just 4
>>> Right 4 ^?_Left
Nothing
>>> "world" ^? ix 3
Just 'l'
>>> "world" ^? ix 20
Nothing
 (^?) ≡ flip preview
 (^?) :: s -> Getter s a     -> Maybe a
 (^?) :: s -> Fold s a       -> Maybe a
 (^?) :: s -> Lens' s a      -> Maybe a
 (^?) :: s -> Iso' s a       -> Maybe a
 (^?) :: s -> Traversal' s a -> Maybe a

(^@?) :: s -> IndexedGetting i (Endo (Maybe (i, a))) s a -> Maybe (i, a)Source

Perform a safe head (with index) of an IndexedFold or IndexedTraversal or retrieve Just the index and result from an IndexedGetter or IndexedLens.

When using a IndexedTraversal as a partial IndexedLens, or an IndexedFold as a partial IndexedGetter this can be a convenient way to extract the optional value.

 (^@?) :: s -> IndexedGetter i s a     -> Maybe (i, a)
 (^@?) :: s -> IndexedFold i s a       -> Maybe (i, a)
 (^@?) :: s -> IndexedLens' i s a      -> Maybe (i, a)
 (^@?) :: s -> IndexedTraversal' i s a -> Maybe (i, a)

(^?!) :: s -> Getting (Endo a) s a -> aSource

Perform an *UNSAFE* head of a Fold or Traversal assuming that it is there.

>>> Left 4 ^?! _Left
4
>>> "world" ^?! ix 3
'l'
 (^?!) :: s -> Getter s a     -> a
 (^?!) :: s -> Fold s a       -> a
 (^?!) :: s -> Lens' s a      -> a
 (^?!) :: s -> Iso' s a       -> a
 (^?!) :: s -> Traversal' s a -> a

(^@?!) :: s -> IndexedGetting i (Endo (i, a)) s a -> (i, a)Source

Perform an *UNSAFE* head (with index) of an IndexedFold or IndexedTraversal assuming that it is there.

 (^@?!) :: s -> IndexedGetter i s a     -> (i, a)
 (^@?!) :: s -> IndexedFold i s a       -> (i, a)
 (^@?!) :: s -> IndexedLens' i s a      -> (i, a)
 (^@?!) :: s -> IndexedTraversal' i s a -> (i, a)

Reviewing

(#) :: AReview s t a b -> b -> tSource

An infix alias for review.

 unto f # x ≡ f x
 l # x ≡ x ^. re l

This is commonly used when using a Prism as a smart constructor.

>>> _Left # 4
Left 4

But it can be used for any Prism

>>> base 16 # 123
"7b"
 (#) :: Iso'      s a -> a -> s
 (#) :: Prism'    s a -> a -> s
 (#) :: Review'   s a -> a -> s
 (#) :: Equality' s a -> a -> s

Common Operators

Setting

(.~) :: ASetter s t a b -> b -> s -> tSource

Replace the target of a Lens or all of the targets of a Setter or Traversal with a constant value.

This is an infix version of set, provided for consistency with (.=).

 f <$ a ≡ mapped .~ f $ a
>>> (a,b,c,d) & _4 .~ e
(a,b,c,e)
>>> (42,"world") & _1 .~ "hello"
("hello","world")
>>> (a,b) & both .~ c
(c,c)
 (.~) :: Setter s t a b    -> b -> s -> t
 (.~) :: Iso s t a b       -> b -> s -> t
 (.~) :: Lens s t a b      -> b -> s -> t
 (.~) :: Traversal s t a b -> b -> s -> t

(.=) :: MonadState s m => ASetter s s a b -> b -> m ()Source

Replace the target of a Lens or all of the targets of a Setter or Traversal in our monadic state with a new value, irrespective of the old.

This is an infix version of assign.

>>> execState (do _1 .= c; _2 .= d) (a,b)
(c,d)
>>> execState (both .= c) (a,b)
(c,c)
 (.=) :: MonadState s m => Iso' s a       -> a -> m ()
 (.=) :: MonadState s m => Lens' s a      -> a -> m ()
 (.=) :: MonadState s m => Traversal' s a -> a -> m ()
 (.=) :: MonadState s m => Setter' s a    -> a -> m ()

It puts the state in the monad or it gets the hose again.

(<.~) :: ASetter s t a b -> b -> s -> (b, t)Source

Set with pass-through.

This is mostly present for consistency, but may be useful for for chaining assignments.

If you do not need a copy of the intermediate result, then using l .~ t directly is a good idea.

>>> (a,b) & _1 <.~ c
(c,(c,b))
>>> ("good","morning","vietnam") & _3 <.~ "world"
("world",("good","morning","world"))
>>> (42,Map.fromList [("goodnight","gracie")]) & _2.at "hello" <.~ Just "world"
(Just "world",(42,fromList [("goodnight","gracie"),("hello","world")]))
 (<.~) :: Setter s t a b    -> b -> s -> (b, t)
 (<.~) :: Iso s t a b       -> b -> s -> (b, t)
 (<.~) :: Lens s t a b      -> b -> s -> (b, t)
 (<.~) :: Traversal s t a b -> b -> s -> (b, t)

(<.=) :: MonadState s m => ASetter s s a b -> b -> m bSource

Set with pass-through

This is useful for chaining assignment without round-tripping through your Monad stack.

 do x <- _2 <.= ninety_nine_bottles_of_beer_on_the_wall

If you do not need a copy of the intermediate result, then using l .= d will avoid unused binding warnings.

 (<.=) :: MonadState s m => Setter s s a b    -> b -> m b
 (<.=) :: MonadState s m => Iso s s a b       -> b -> m b
 (<.=) :: MonadState s m => Lens s s a b      -> b -> m b
 (<.=) :: MonadState s m => Traversal s s a b -> b -> m b

(<<.~) :: Overloading (->) q ((,) a) s t a b -> b -> q s (a, t)Source

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)

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

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 t) => Traversal' s a -> (a -> a) -> m a

(#~) :: ALens s t a b -> b -> s -> tSource

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

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

(#=) :: MonadState s m => ALens s s a b -> b -> m ()Source

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

(<#~) :: ALens s t a b -> b -> s -> (b, t)Source

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

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

(<#=) :: MonadState s m => ALens s s a b -> b -> m bSource

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

Just

(?~) :: ASetter s t a (Maybe b) -> b -> s -> tSource

Set the target of a Lens, Traversal or Setter to Just a value.

 l ?~ t ≡ set l (Just t)
>>> Nothing & id ?~ a
Just a
>>> Map.empty & at 3 ?~ x
fromList [(3,x)]
 (?~) :: Setter s t a (Maybe b)    -> b -> s -> t
 (?~) :: Iso s t a (Maybe b)       -> b -> s -> t
 (?~) :: Lens s t a (Maybe b)      -> b -> s -> t
 (?~) :: Traversal s t a (Maybe b) -> b -> s -> t

(?=) :: MonadState s m => ASetter s s a (Maybe b) -> b -> m ()Source

Replace the target of a Lens or all of the targets of a Setter or Traversal in our monadic state with Just a new value, irrespective of the old.

>>> execState (do at 1 ?= a; at 2 ?= b) Map.empty
fromList [(1,a),(2,b)]
>>> execState (do _1 ?= b; _2 ?= c) (Just a, Nothing)
(Just b,Just c)
 (?=) :: MonadState s m => Iso' s (Maybe a)       -> a -> m ()
 (?=) :: MonadState s m => Lens' s (Maybe a)      -> a -> m ()
 (?=) :: MonadState s m => Traversal' s (Maybe a) -> a -> m ()
 (?=) :: MonadState s m => Setter' s (Maybe a)    -> a -> m ()

(<?~) :: ASetter s t a (Maybe b) -> b -> s -> (b, t)Source

Set to Just a value with pass-through.

This is mostly present for consistency, but may be useful for for chaining assignments.

If you do not need a copy of the intermediate result, then using l ?~ d directly is a good idea.

>>> import Data.Map as Map
>>> _2.at "hello" <?~ "world" $ (42,Map.fromList [("goodnight","gracie")])
("world",(42,fromList [("goodnight","gracie"),("hello","world")]))
 (<?~) :: Setter s t a (Maybe b)    -> b -> s -> (b, t)
 (<?~) :: Iso s t a (Maybe b)       -> b -> s -> (b, t)
 (<?~) :: Lens s t a (Maybe b)      -> b -> s -> (b, t)
 (<?~) :: Traversal s t a (Maybe b) -> b -> s -> (b, t)

(<?=) :: MonadState s m => ASetter s s a (Maybe b) -> b -> m bSource

Set Just a value with pass-through

This is useful for chaining assignment without round-tripping through your Monad stack.

 do x <- at foo <?= ninety_nine_bottles_of_beer_on_the_wall

If you do not need a copy of the intermediate result, then using l ?= d will avoid unused binding warnings.

 (<?=) :: MonadState s m => Setter s s a (Maybe b)    -> b -> m b
 (<?=) :: MonadState s m => Iso s s a (Maybe b)       -> b -> m b
 (<?=) :: MonadState s m => Lens s s a (Maybe b)      -> b -> m b
 (<?=) :: MonadState s m => Traversal s s a (Maybe b) -> b -> m b

Modifying

(%~) :: Profunctor p => Setting p s t a b -> p a b -> s -> tSource

Modifies the target of a Lens or all of the targets of a Setter or Traversal with a user supplied function.

This is an infix version of over.

 fmap f ≡ mapped %~ f
 fmapDefault f ≡ traverse %~ f
>>> (a,b,c) & _3 %~ f
(a,b,f c)
>>> (a,b) & both %~ f
(f a,f b)
>>> _2 %~ length $ (1,"hello")
(1,5)
>>> traverse %~ f $ [a,b,c]
[f a,f b,f c]
>>> traverse %~ even $ [1,2,3]
[False,True,False]
>>> traverse.traverse %~ length $ [["hello","world"],["!!!"]]
[[5,5],[3]]
 (%~) :: Setter s t a b    -> (a -> b) -> s -> t
 (%~) :: Iso s t a b       -> (a -> b) -> s -> t
 (%~) :: Lens s t a b      -> (a -> b) -> s -> t
 (%~) :: Traversal s t a b -> (a -> b) -> s -> t

(%=) :: (Profunctor p, MonadState s m) => Setting p s s a b -> p a b -> m ()Source

Map over the target of a Lens or all of the targets of a Setter or Traversal in our monadic state.

>>> execState (do _1 %= f;_2 %= g) (a,b)
(f a,g b)
>>> execState (do both %= f) (a,b)
(f a,f b)
 (%=) :: MonadState s m => Iso' s a       -> (a -> a) -> m ()
 (%=) :: MonadState s m => Lens' s a      -> (a -> a) -> m ()
 (%=) :: MonadState s m => Traversal' s a -> (a -> a) -> m ()
 (%=) :: MonadState s m => Setter' s a    -> (a -> a) -> m ()
 (%=) :: MonadState s m => ASetter s s a b -> (a -> b) -> m ()

(<%~) :: Profunctor p => Overloading p q ((,) b) s t a b -> p a b -> q s (b, t)Source

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)

(<%=) :: (Profunctor p, MonadState s m) => Overloading p (->) ((,) b) s s a b -> p a b -> m bSource

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

(<<%~) :: Strong p => Overloading p q ((,) a) s t a b -> p a b -> q s (a, t)Source

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)

(<<%=) :: (Strong p, MonadState s m) => Overloading p (->) ((,) a) s s a b -> p a b -> m aSource

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

Loupes

(#%~) :: ALens s t a b -> (a -> b) -> s -> tSource

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

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

(#%=) :: MonadState s m => ALens s s a b -> (a -> b) -> m ()Source

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

(<#%~) :: ALens s t a b -> (a -> b) -> s -> (b, t)Source

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

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

(<#%=) :: MonadState s m => ALens s s a b -> (a -> b) -> m bSource

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

with Indices

(%@~) :: AnIndexedSetter i s t a b -> (i -> a -> b) -> s -> tSource

Adjust every target of an IndexedSetter, IndexedLens or IndexedTraversal with access to the index.

 (%@~) ≡ imapOf

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

 l %~ f ≡ l %@~ const f
 (%@~) :: IndexedSetter i s t a b    -> (i -> a -> b) -> s -> t
 (%@~) :: IndexedLens i s t a b      -> (i -> a -> b) -> s -> t
 (%@~) :: IndexedTraversal i s t a b -> (i -> a -> b) -> s -> t

(%@=) :: MonadState s m => AnIndexedSetter i s s a b -> (i -> a -> b) -> m ()Source

Adjust every target in the current state of an IndexedSetter, IndexedLens or IndexedTraversal with access to the index.

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

 l %= f ≡ l %@= const f
 (%@=) :: MonadState s m => IndexedSetter i s s a b    -> (i -> a -> b) -> m ()
 (%@=) :: MonadState s m => IndexedLens i s s a b      -> (i -> a -> b) -> m ()
 (%@=) :: MonadState s m => IndexedTraversal i s t a b -> (i -> a -> b) -> m ()

(<%@~) :: Overloading (Indexed i) q ((,) b) s t a b -> (i -> a -> b) -> q s (b, t)Source

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)

(<%@=) :: MonadState s m => IndexedLensLike i ((,) b) s s a b -> (i -> a -> b) -> m bSource

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

(<<%@~) :: Overloading (Indexed i) q ((,) a) s t a b -> (i -> a -> b) -> q s (a, t)Source

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)

(<<%@=) :: MonadState s m => IndexedLensLike i ((,) a) s s a b -> (i -> a -> b) -> m aSource

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

Traversing

(%%~) :: Overloading p q f s t a b -> p a (f b) -> q s (f t)Source

(%%~) 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)

(%%=) :: MonadState s m => Overloading p (->) ((,) r) s s a b -> p a (r, b) -> m rSource

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

(#%%~) :: Functor f => ALens s t a b -> (a -> f b) -> s -> f tSource

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

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

(#%%=) :: MonadState s m => ALens s s a b -> (a -> (r, b)) -> m rSource

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

(%%@~) :: IndexedLensLike i f s t a b -> (i -> a -> f b) -> s -> f tSource

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)

(%%@=) :: MonadState s m => IndexedLensLike i ((,) r) s s a b -> (i -> a -> (r, b)) -> m rSource

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

Addition

(+~) :: Num a => ASetter s t a a -> a -> s -> tSource

Increment the target(s) of a numerically valued Lens, Setter or Traversal.

>>> (a,b) & _1 +~ c
(a + c,b)
>>> (a,b) & both +~ c
(a + c,b + c)
>>> (1,2) & _2 +~ 1
(1,3)
>>> [(a,b),(c,d)] & traverse.both +~ e
[(a + e,b + e),(c + e,d + e)]
 (+~) :: Num a => Setter' s a    -> a -> s -> s
 (+~) :: Num a => Iso' s a       -> a -> s -> s
 (+~) :: Num a => Lens' s a      -> a -> s -> s
 (+~) :: Num a => Traversal' s a -> a -> s -> s

(+=) :: (MonadState s m, Num a) => ASetter' s a -> a -> m ()Source

Modify the target(s) of a Lens', Iso, Setter or Traversal by adding a value.

Example:

 fresh :: MonadState Int m => m Int
 fresh = do
   id += 1
   use id
>>> execState (do _1 += c; _2 += d) (a,b)
(a + c,b + d)
>>> execState (do _1.at 1.non 0 += 10) (Map.fromList [(2,100)],"hello")
(fromList [(1,10),(2,100)],"hello")
 (+=) :: (MonadState s m, Num a) => Setter' s a    -> a -> m ()
 (+=) :: (MonadState s m, Num a) => Iso' s a       -> a -> m ()
 (+=) :: (MonadState s m, Num a) => Lens' s a      -> a -> m ()
 (+=) :: (MonadState s m, Num a) => Traversal' s a -> a -> m ()

(<+~) :: Num a => Overloading (->) q ((,) a) s t a a -> a -> q s (a, t)Source

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)

(<+=) :: (MonadState s m, Num a) => LensLike' ((,) a) s a -> a -> m aSource

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

Subtraction

(-~) :: Num a => ASetter s t a a -> a -> s -> tSource

Decrement the target(s) of a numerically valued Lens, Iso, Setter or Traversal.

>>> (a,b) & _1 -~ c
(a - c,b)
>>> (a,b) & both -~ c
(a - c,b - c)
>>> _1 -~ 2 $ (1,2)
(-1,2)
>>> mapped.mapped -~ 1 $ [[4,5],[6,7]]
[[3,4],[5,6]]
 (-~) :: Num a => Setter' s a    -> a -> s -> s
 (-~) :: Num a => Iso' s a       -> a -> s -> s
 (-~) :: Num a => Lens' s a      -> a -> s -> s
 (-~) :: Num a => Traversal' s a -> a -> s -> s

(-=) :: (MonadState s m, Num a) => ASetter' s a -> a -> m ()Source

Modify the target(s) of a Lens', Iso, Setter or Traversal by subtracting a value.

>>> execState (do _1 -= c; _2 -= d) (a,b)
(a - c,b - d)
 (-=) :: (MonadState s m, Num a) => Setter' s a    -> a -> m ()
 (-=) :: (MonadState s m, Num a) => Iso' s a       -> a -> m ()
 (-=) :: (MonadState s m, Num a) => Lens' s a      -> a -> m ()
 (-=) :: (MonadState s m, Num a) => Traversal' s a -> a -> m ()

(<-~) :: Num a => Overloading (->) q ((,) a) s t a a -> a -> q s (a, t)Source

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)

(<-=) :: (MonadState s m, Num a) => LensLike' ((,) a) s a -> a -> m aSource

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

Multiplication

(*~) :: Num a => ASetter s t a a -> a -> s -> tSource

Multiply the target(s) of a numerically valued Lens, Iso, Setter or Traversal.

>>> (a,b) & _1 *~ c
(a * c,b)
>>> (a,b) & both *~ c
(a * c,b * c)
>>> (1,2) & _2 *~ 4
(1,8)
>>> Just 24 & mapped *~ 2
Just 48
 (*~) :: Num a => Setter' s a    -> a -> s -> s
 (*~) :: Num a => Iso' s a       -> a -> s -> s
 (*~) :: Num a => Lens' s a      -> a -> s -> s
 (*~) :: Num a => Traversal' s a -> a -> s -> s

(*=) :: (MonadState s m, Num a) => ASetter' s a -> a -> m ()Source

Modify the target(s) of a Lens', Iso, Setter or Traversal by multiplying by value.

>>> execState (do _1 *= c; _2 *= d) (a,b)
(a * c,b * d)
 (*=) :: (MonadState s m, Num a) => Setter' s a    -> a -> m ()
 (*=) :: (MonadState s m, Num a) => Iso' s a       -> a -> m ()
 (*=) :: (MonadState s m, Num a) => Lens' s a      -> a -> m ()
 (*=) :: (MonadState s m, Num a) => Traversal' s a -> a -> m ()

(<*~) :: Num a => Overloading (->) q ((,) a) s t a a -> a -> q s (a, t)Source

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)

(<*=) :: (MonadState s m, Num a) => LensLike' ((,) a) s a -> a -> m aSource

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

Division

(//~) :: Fractional a => ASetter s t a a -> a -> s -> tSource

Divide the target(s) of a numerically valued Lens, Iso, Setter or Traversal.

>>> (a,b) & _1 //~ c
(a / c,b)
>>> (a,b) & both //~ c
(a / c,b / c)
>>> ("Hawaii",10) & _2 //~ 2
("Hawaii",5.0)
 (//~) :: Fractional a => Setter' s a    -> a -> s -> s
 (//~) :: Fractional a => Iso' s a       -> a -> s -> s
 (//~) :: Fractional a => Lens' s a      -> a -> s -> s
 (//~) :: Fractional a => Traversal' s a -> a -> s -> s

(//=) :: (MonadState s m, Fractional a) => ASetter' s a -> a -> m ()Source

Modify the target(s) of a Lens', Iso, Setter or Traversal by dividing by a value.

>>> execState (do _1 //= c; _2 //= d) (a,b)
(a / c,b / d)
 (//=) :: (MonadState s m, Fractional a) => Setter' s a    -> a -> m ()
 (//=) :: (MonadState s m, Fractional a) => Iso' s a       -> a -> m ()
 (//=) :: (MonadState s m, Fractional a) => Lens' s a      -> a -> m ()
 (//=) :: (MonadState s m, Fractional a) => Traversal' s a -> a -> m ()

(<//~) :: Fractional a => Overloading (->) q ((,) a) s t a a -> a -> q s (a, t)Source

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)

(<//=) :: (MonadState s m, Fractional a) => LensLike' ((,) a) s a -> a -> m aSource

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

Exponentiation

(^~) :: (Num a, Integral e) => ASetter s t a a -> e -> s -> tSource

Raise the target(s) of a numerically valued Lens, Setter or Traversal to a non-negative integral power.

>>> (1,3) & _2 ^~ 2
(1,9)
 (^~) :: (Num a, Integral e) => Setter' s a    -> e -> s -> s
 (^~) :: (Num a, Integral e) => Iso' s a       -> e -> s -> s
 (^~) :: (Num a, Integral e) => Lens' s a      -> e -> s -> s
 (^~) :: (Num a, Integral e) => Traversal' s a -> e -> s -> s

(^=) :: (MonadState s m, Num a, Integral e) => ASetter' s a -> e -> m ()Source

Raise the target(s) of a numerically valued Lens, Setter or Traversal to a non-negative integral power.

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

(<^~) :: (Num a, Integral e) => Overloading (->) q ((,) a) s t a a -> e -> q s (a, t)Source

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 division, (^~) 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)

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

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

(^^~) :: (Fractional a, Integral e) => ASetter s t a a -> e -> s -> tSource

Raise the target(s) of a fractionally valued Lens, Setter or Traversal to an integral power.

>>> (1,2) & _2 ^^~ (-1)
(1,0.5)
 (^^~) :: (Fractional a, Integral e) => Setter' s a    -> e -> s -> s
 (^^~) :: (Fractional a, Integral e) => Iso' s a       -> e -> s -> s
 (^^~) :: (Fractional a, Integral e) => Lens' s a      -> e -> s -> s
 (^^~) :: (Fractional a, Integral e) => Traversal' s a -> e -> s -> s

(^^=) :: (MonadState s m, Fractional a, Integral e) => ASetter' s a -> e -> m ()Source

Raise the target(s) of a numerically valued Lens, Setter or Traversal to an integral power.

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

(<^^~) :: (Fractional a, Integral e) => Overloading (->) q ((,) a) s t a a -> e -> q s (a, t)Source

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 division, (^^~) 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)

(<^^=) :: (MonadState s m, Fractional a, Integral e) => LensLike' ((,) a) s a -> e -> m aSource

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

(**~) :: Floating a => ASetter s t a a -> a -> s -> tSource

Raise the target(s) of a floating-point valued Lens, Setter or Traversal to an arbitrary power.

>>> (a,b) & _1 **~ c
(a**c,b)
>>> (a,b) & both **~ c
(a**c,b**c)
>>> _2 **~ pi $ (1,3)
(1,31.54428070019754)
 (**~) :: Floating a => Setter' s a    -> a -> s -> s
 (**~) :: Floating a => Iso' s a       -> a -> s -> s
 (**~) :: Floating a => Lens' s a      -> a -> s -> s
 (**~) :: Floating a => Traversal' s a -> a -> s -> s

(**=) :: (MonadState s m, Floating a) => ASetter' s a -> a -> m ()Source

Raise the target(s) of a numerically valued Lens, Setter or Traversal to an arbitrary power

>>> execState (do _1 **= c; _2 **= d) (a,b)
(a**c,b**d)
 (**=) ::  (MonadState s m, Floating a) => Setter' s a    -> a -> m ()
 (**=) ::  (MonadState s m, Floating a) => Iso' s a       -> a -> m ()
 (**=) ::  (MonadState s m, Floating a) => Lens' s a      -> a -> m ()
 (**=) ::  (MonadState s m, Floating a) => Traversal' s a -> a -> m ()

(<**~) :: Floating a => Overloading (->) q ((,) a) s t a a -> a -> q s (a, t)Source

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 division, (**~) is more flexible.

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

(<**=) :: (MonadState s m, Floating a) => LensLike' ((,) a) s a -> a -> m aSource

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

Logical Or

(||~) :: ASetter s t Bool Bool -> Bool -> s -> tSource

Logically || the target(s) of a Bool-valued Lens or Setter.

>>> both ||~ True $ (False,True)
(True,True)
>>> both ||~ False $ (False,True)
(False,True)
 (||~) :: Setter' s Bool    -> Bool -> s -> s
 (||~) :: Iso' s Bool       -> Bool -> s -> s
 (||~) :: Lens' s Bool      -> Bool -> s -> s
 (||~) :: Traversal' s Bool -> Bool -> s -> s

(||=) :: MonadState s m => ASetter' s Bool -> Bool -> m ()Source

Modify the target(s) of a Lens', 'Iso, Setter or Traversal by taking their logical || with a value.

>>> execState (do _1 ||= True; _2 ||= False; _3 ||= True; _4 ||= False) (True,True,False,False)
(True,True,True,False)
 (||=) :: MonadState s m => Setter' s Bool    -> Bool -> m ()
 (||=) :: MonadState s m => Iso' s Bool       -> Bool -> m ()
 (||=) :: MonadState s m => Lens' s Bool      -> Bool -> m ()
 (||=) :: MonadState s m => Traversal' s Bool -> Bool -> m ()

(<||~) :: Overloading (->) q ((,) Bool) s t Bool Bool -> Bool -> q s (Bool, t)Source

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)

(<||=) :: MonadState s m => LensLike' ((,) Bool) s Bool -> Bool -> m BoolSource

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

Logical And

(&&~) :: ASetter s t Bool Bool -> Bool -> s -> tSource

Logically && the target(s) of a Bool-valued Lens or Setter.

>>> both &&~ True $ (False, True)
(False,True)
>>> both &&~ False $ (False, True)
(False,False)
 (&&~) :: Setter' s Bool    -> Bool -> s -> s
 (&&~) :: Iso' s Bool       -> Bool -> s -> s
 (&&~) :: Lens' s Bool      -> Bool -> s -> s
 (&&~) :: Traversal' s Bool -> Bool -> s -> s

(&&=) :: MonadState s m => ASetter' s Bool -> Bool -> m ()Source

Modify the target(s) of a Lens', Iso, Setter or Traversal by taking their logical && with a value.

>>> execState (do _1 &&= True; _2 &&= False; _3 &&= True; _4 &&= False) (True,True,False,False)
(True,False,False,False)
 (&&=) :: MonadState s m => Setter' s Bool    -> Bool -> m ()
 (&&=) :: MonadState s m => Iso' s Bool       -> Bool -> m ()
 (&&=) :: MonadState s m => Lens' s Bool      -> Bool -> m ()
 (&&=) :: MonadState s m => Traversal' s Bool -> Bool -> m ()

(<&&~) :: Overloading (->) q ((,) Bool) s t Bool Bool -> Bool -> q s (Bool, t)Source

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)

(<&&=) :: MonadState s m => LensLike' ((,) Bool) s Bool -> Bool -> m BoolSource

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

Monoidal

(<>~) :: Monoid a => ASetter s t a a -> a -> s -> tSource

Modify the target of a monoidally valued by mappending another value.

>>> (Sum a,b) & _1 <>~ Sum c
(Sum {getSum = a + c},b)
>>> (Sum a,Sum b) & both <>~ Sum c
(Sum {getSum = a + c},Sum {getSum = b + c})
>>> both <>~ "!!!" $ ("hello","world")
("hello!!!","world!!!")
 (<>~) :: Monoid a => Setter s t a a    -> a -> s -> t
 (<>~) :: Monoid a => Iso s t a a       -> a -> s -> t
 (<>~) :: Monoid a => Lens s t a a      -> a -> s -> t
 (<>~) :: Monoid a => Traversal s t a a -> a -> s -> t

(<>=) :: (MonadState s m, Monoid a) => ASetter' s a -> a -> m ()Source

Modify the target(s) of a Lens', Iso, Setter or Traversal by mappending a value.

>>> execState (do _1 <>= Sum c; _2 <>= Product d) (Sum a,Product b)
(Sum {getSum = a + c},Product {getProduct = b * d})
>>> execState (both <>= "!!!") ("hello","world")
("hello!!!","world!!!")
 (<>=) :: (MonadState s m, Monoid a) => Setter' s a -> a -> m ()
 (<>=) :: (MonadState s m, Monoid a) => Iso' s a -> a -> m ()
 (<>=) :: (MonadState s m, Monoid a) => Lens' s a -> a -> m ()
 (<>=) :: (MonadState s m, Monoid a) => Traversal' s a -> a -> m ()

(<<>~) :: Monoid m => Overloading (->) q ((,) m) s t m m -> m -> q s (m, t)Source

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.

(<<>=) :: (MonadState s m, Monoid r) => LensLike' ((,) r) s r -> r -> m rSource

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.

Composing Indices

(<.>) :: Indexable (i, j) p => (Indexed i s t -> r) -> (Indexed j a b -> s -> t) -> p a b -> rSource

Composition of Indexed functions.

Mnemonically, the < and > points to the fact that we want to preserve the indices.

(<.) :: Indexable i p => (Indexed i s t -> r) -> ((a -> b) -> s -> t) -> p a b -> rSource

Compose an Indexed function with a non-indexed function.

Mnemonically, the < points to the indexing we want to preserve.

(.>) :: (st -> r) -> (kab -> st) -> kab -> rSource

Compose a non-indexed function with an Indexed function.

Mnemonically, the > points to the indexing we want to preserve.

This is the same as (.).

f . g (and f .> g) gives you the index of g unless g is index-preserving, like a Prism, Iso or Equality, in which case it'll pass through the index of f.

Monadic Assignment

(<~) :: MonadState s m => ASetter s s a b -> m b -> m ()Source

Run a monadic action, and set all of the targets of a Lens, Setter or Traversal to its result.

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

As a reasonable mnemonic, this lets you store the result of a monadic action in a Lens rather than in a local variable.

 do foo <- bar
    ...

will store the result in a variable, while

 do foo <~ bar
    ...

will store the result in a Lens, Setter, or Traversal.

(<<~) :: MonadState s m => ALens s s a b -> m b -> m bSource

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.

Zippers

type family h :> p Source

This type family represents a Zipper with the p variable abstracting over the position and the index, in terms of :@. You can visually see it in type signatures as:

 h :> (a :@ i) = Zipper h i a

type :>> h a = Zipper h Int aSource

Many zippers are indexed by Int keys. This type alias is convenient for reducing syntactic noise for talking about these boring indices.

Cons and Snoc

(<|) :: Cons Reviewed Identity s s a a => a -> s -> sSource

cons an element onto a container.

This is an infix alias for cons.

(|>) :: Snoc Reviewed Identity s s a a => s -> a -> sSource

snoc an element onto the end of a container.

This is an infix alias for snoc.