Safe Haskell | None |
---|---|

Language | Haskell2010 |

A

has the ability to extract some number of elements of type `Fold`

S A`A`

from a container of type `S`

. For example, `toListOf`

can be used to obtain
the contained elements as a list. Unlike a `Traversal`

,
there is no way to set or update elements.

This can be seen as a generalisation of `traverse_`

, where the type `S`

does
not need to be a type constructor with `A`

as the last parameter.

A close relative is the `AffineFold`

, which is a `Fold`

that contains at most one element.

## Synopsis

- type Fold s a = Optic' A_Fold NoIx s a
- foldVL :: (forall f. Applicative f => (a -> f u) -> s -> f v) -> Fold s a
- foldOf :: (Is k A_Fold, Monoid a) => Optic' k is s a -> s -> a
- foldMapOf :: (Is k A_Fold, Monoid m) => Optic' k is s a -> (a -> m) -> s -> m
- foldrOf :: Is k A_Fold => Optic' k is s a -> (a -> r -> r) -> r -> s -> r
- foldlOf' :: Is k A_Fold => Optic' k is s a -> (r -> a -> r) -> r -> s -> r
- toListOf :: Is k A_Fold => Optic' k is s a -> s -> [a]
- sequenceOf_ :: (Is k A_Fold, Applicative f) => Optic' k is s (f a) -> s -> f ()
- traverseOf_ :: (Is k A_Fold, Applicative f) => Optic' k is s a -> (a -> f r) -> s -> f ()
- forOf_ :: (Is k A_Fold, Applicative f) => Optic' k is s a -> s -> (a -> f r) -> f ()
- folded :: Foldable f => Fold (f a) a
- folding :: Foldable f => (s -> f a) -> Fold s a
- foldring :: (forall f. Applicative f => (a -> f u -> f u) -> f v -> s -> f w) -> Fold s a
- unfolded :: (s -> Maybe (a, s)) -> Fold s a
- has :: Is k A_Fold => Optic' k is s a -> s -> Bool
- hasn't :: Is k A_Fold => Optic' k is s a -> s -> Bool
- headOf :: Is k A_Fold => Optic' k is s a -> s -> Maybe a
- lastOf :: Is k A_Fold => Optic' k is s a -> s -> Maybe a
- andOf :: Is k A_Fold => Optic' k is s Bool -> s -> Bool
- orOf :: Is k A_Fold => Optic' k is s Bool -> s -> Bool
- allOf :: Is k A_Fold => Optic' k is s a -> (a -> Bool) -> s -> Bool
- anyOf :: Is k A_Fold => Optic' k is s a -> (a -> Bool) -> s -> Bool
- noneOf :: Is k A_Fold => Optic' k is s a -> (a -> Bool) -> s -> Bool
- productOf :: (Is k A_Fold, Num a) => Optic' k is s a -> s -> a
- sumOf :: (Is k A_Fold, Num a) => Optic' k is s a -> s -> a
- asumOf :: (Is k A_Fold, Alternative f) => Optic' k is s (f a) -> s -> f a
- msumOf :: (Is k A_Fold, MonadPlus m) => Optic' k is s (m a) -> s -> m a
- elemOf :: (Is k A_Fold, Eq a) => Optic' k is s a -> a -> s -> Bool
- notElemOf :: (Is k A_Fold, Eq a) => Optic' k is s a -> a -> s -> Bool
- lengthOf :: Is k A_Fold => Optic' k is s a -> s -> Int
- maximumOf :: (Is k A_Fold, Ord a) => Optic' k is s a -> s -> Maybe a
- minimumOf :: (Is k A_Fold, Ord a) => Optic' k is s a -> s -> Maybe a
- maximumByOf :: Is k A_Fold => Optic' k is s a -> (a -> a -> Ordering) -> s -> Maybe a
- minimumByOf :: Is k A_Fold => Optic' k is s a -> (a -> a -> Ordering) -> s -> Maybe a
- findOf :: Is k A_Fold => Optic' k is s a -> (a -> Bool) -> s -> Maybe a
- findMOf :: (Is k A_Fold, Monad m) => Optic' k is s a -> (a -> m Bool) -> s -> m (Maybe a)
- lookupOf :: (Is k A_Fold, Eq a) => Optic' k is s (a, v) -> a -> s -> Maybe v
- pre :: Is k A_Fold => Optic' k is s a -> AffineFold s a
- backwards_ :: Is k A_Fold => Optic' k is s a -> Fold s a
- summing :: (Is k A_Fold, Is l A_Fold) => Optic' k is s a -> Optic' l js s a -> Fold s a
- failing :: (Is k A_Fold, Is l A_Fold) => Optic' k is s a -> Optic' l js s a -> Fold s a
- data A_Fold :: OpticKind

# Formation

# Introduction

foldVL :: (forall f. Applicative f => (a -> f u) -> s -> f v) -> Fold s a Source #

Obtain a `Fold`

by lifting `traverse_`

like function.

`foldVL`

`.`

`traverseOf_`

≡`id`

`traverseOf_`

`.`

`foldVL`

≡`id`

# Elimination

foldOf :: (Is k A_Fold, Monoid a) => Optic' k is s a -> s -> a Source #

Combine the results of a fold using a monoid.

foldMapOf :: (Is k A_Fold, Monoid m) => Optic' k is s a -> (a -> m) -> s -> m Source #

Fold via embedding into a monoid.

foldrOf :: Is k A_Fold => Optic' k is s a -> (a -> r -> r) -> r -> s -> r Source #

Fold right-associatively.

foldlOf' :: Is k A_Fold => Optic' k is s a -> (r -> a -> r) -> r -> s -> r Source #

Fold left-associatively, and strictly.

sequenceOf_ :: (Is k A_Fold, Applicative f) => Optic' k is s (f a) -> s -> f () Source #

Evaluate each action in a structure observed by a `Fold`

from left to
right, ignoring the results.

`sequenceA_`

≡`sequenceOf_`

`folded`

`>>>`

hello world`sequenceOf_ each (putStrLn "hello",putStrLn "world")`

traverseOf_ :: (Is k A_Fold, Applicative f) => Optic' k is s a -> (a -> f r) -> s -> f () Source #

Traverse over all of the targets of a `Fold`

, computing an
`Applicative`

-based answer, but unlike `traverseOf`

do not
construct a new structure. `traverseOf_`

generalizes
`traverse_`

to work over any `Fold`

.

`>>>`

hello world`traverseOf_ each putStrLn ("hello","world")`

`traverse_`

≡`traverseOf_`

`folded`

forOf_ :: (Is k A_Fold, Applicative f) => Optic' k is s a -> s -> (a -> f r) -> f () Source #

A version of `traverseOf_`

with the arguments flipped.

# Computation

`traverseOf_`

(`foldVL`

f) ≡ f

# Additional introduction forms

foldring :: (forall f. Applicative f => (a -> f u -> f u) -> f v -> s -> f w) -> Fold s a Source #

# Additional elimination forms

lengthOf :: Is k A_Fold => Optic' k is s a -> s -> Int Source #

Calculate the number of targets there are for a `Fold`

in a given
container.

*Note:* This can be rather inefficient for large containers and just like
`length`

, this will not terminate for infinite folds.

`length`

≡`lengthOf`

`folded`

`>>>`

1`lengthOf _1 ("hello",())`

`>>>`

10`lengthOf folded [1..10]`

`>>>`

6`lengthOf (folded % folded) [[1,2],[3,4],[5,6]]`

maximumOf :: (Is k A_Fold, Ord a) => Optic' k is s a -> s -> Maybe a Source #

Obtain the maximum element (if any) targeted by a `Fold`

safely.

Note: `maximumOf`

on a valid `Iso`

, `Lens`

or `Getter`

will always return `Just`

a value.

`>>>`

Just 10`maximumOf folded [1..10]`

`>>>`

Nothing`maximumOf folded []`

`>>>`

Just 6`maximumOf (folded % filtered even) [1,4,3,6,7,9,2]`

`maximum`

≡`fromMaybe`

(`error`

"empty")`.`

`maximumOf`

`folded`

In the interest of efficiency, This operation has semantics more strict than
strictly necessary. `\o -> `

has lazier
semantics but could leak memory.`getMax`

. `foldMapOf`

o `Max`

minimumOf :: (Is k A_Fold, Ord a) => Optic' k is s a -> s -> Maybe a Source #

Obtain the minimum element (if any) targeted by a `Fold`

safely.

Note: `minimumOf`

on a valid `Iso`

, `Lens`

or `Getter`

will always return `Just`

a value.

`>>>`

Just 1`minimumOf folded [1..10]`

`>>>`

Nothing`minimumOf folded []`

`>>>`

Just 2`minimumOf (folded % filtered even) [1,4,3,6,7,9,2]`

`minimum`

≡`fromMaybe`

(`error`

"empty")`.`

`minimumOf`

`folded`

In the interest of efficiency, This operation has semantics more strict than
strictly necessary. `\o -> `

has lazier
semantics but could leak memory.`getMin`

. `foldMapOf`

o `Min`

maximumByOf :: Is k A_Fold => Optic' k is s a -> (a -> a -> Ordering) -> s -> Maybe a Source #

Obtain the maximum element (if any) targeted by a `Fold`

according to a
user supplied `Ordering`

.

`>>>`

Just "mustard"`maximumByOf folded (compare `on` length) ["mustard","relish","ham"]`

In the interest of efficiency, This operation has semantics more strict than strictly necessary.

`maximumBy`

cmp ≡`fromMaybe`

(`error`

"empty")`.`

`maximumByOf`

`folded`

cmp

minimumByOf :: Is k A_Fold => Optic' k is s a -> (a -> a -> Ordering) -> s -> Maybe a Source #

Obtain the minimum element (if any) targeted by a `Fold`

according to a
user supplied `Ordering`

.

In the interest of efficiency, This operation has semantics more strict than strictly necessary.

`>>>`

Just "ham"`minimumByOf folded (compare `on` length) ["mustard","relish","ham"]`

`minimumBy`

cmp ≡`fromMaybe`

(`error`

"empty")`.`

`minimumByOf`

`folded`

cmp

findMOf :: (Is k A_Fold, Monad m) => Optic' k is s a -> (a -> m Bool) -> s -> m (Maybe a) Source #

The `findMOf`

function takes a `Fold`

, a monadic predicate and a structure
and returns in the monad the leftmost element of the structure matching the
predicate, or `Nothing`

if there is no such element.

`>>>`

"Checking 1" "Checking 3" "Checking 4" Just 4`findMOf each (\x -> print ("Checking " ++ show x) >> return (even x)) (1,3,4,6)`

`>>>`

"Checking 1" "Checking 3" "Checking 5" "Checking 7" Nothing`findMOf each (\x -> print ("Checking " ++ show x) >> return (even x)) (1,3,5,7)`

`findMOf`

`folded`

:: (Monad m, Foldable f) => (a -> m Bool) -> f a -> m (Maybe a)

lookupOf :: (Is k A_Fold, Eq a) => Optic' k is s (a, v) -> a -> s -> Maybe v Source #

The `lookupOf`

function takes a `Fold`

, a key, and a structure containing
key/value pairs. It returns the first value corresponding to the given
key. This function generalizes `lookup`

to work on an arbitrary `Fold`

instead of lists.

`>>>`

Just 'b'`lookupOf folded 4 [(2, 'a'), (4, 'b'), (4, 'c')]`

`>>>`

Just 'a'`lookupOf folded 2 [(2, 'a'), (4, 'b'), (4, 'c')]`

# Combinators

pre :: Is k A_Fold => Optic' k is s a -> AffineFold s a Source #

Convert a fold to an `AffineFold`

that visits the first element of the
original fold.

backwards_ :: Is k A_Fold => Optic' k is s a -> Fold s a Source #

This allows you to traverse the elements of a `Fold`

in the opposite order.

# Semigroup structure

summing :: (Is k A_Fold, Is l A_Fold) => Optic' k is s a -> Optic' l js s a -> Fold s a infixr 6 Source #

Return entries of the first `Fold`

, then the second one.

`>>>`

[1,7]`toListOf (_1 % ix 0 `summing` _2 % ix 1) ([1,2], [4,7,1])`

failing :: (Is k A_Fold, Is l A_Fold) => Optic' k is s a -> Optic' l js s a -> Fold s a infixl 3 Source #

Try the first `Fold`

. If it returns no entries, try the second one.

# Subtyping

data A_Fold :: OpticKind Source #

Tag for a fold.