Module

Data.Array

Helper functions for working with immutable Javascript arrays.

Note: Depending on your use-case, you may prefer to use Data.List or Data.Sequence instead, which might give better performance for certain use cases. This module is useful when integrating with JavaScript libraries which use arrays, but immutable arrays are not a practical data structure for many use cases due to their poor asymptotics.

In addition to the functions in this module, Arrays have a number of useful instances:

  • Functor, which provides map :: forall a b. (a -> b) -> Array a -> Array b
  • Apply, which provides (<*>) :: forall a b. Array (a -> b) -> Array a -> Array b. This function works a bit like a Cartesian product; the result array is constructed by applying each function in the first array to each value in the second, so that the result array ends up with a length equal to the product of the two arguments' lengths.
  • Bind, which provides (>>=) :: forall a b. (a -> Array b) -> Array a -> Array b (this is the same as concatMap).
  • Semigroup, which provides (<>) :: forall a. Array a -> Array a -> Array a, for concatenating arrays.
  • Foldable, which provides a slew of functions for folding (also known as reducing) arrays down to one value. For example, Data.Foldable.or tests whether an array of Boolean values contains at least one true value.
  • Traversable, which provides the PureScript version of a for-loop, allowing you to STAI.iterate over an array and accumulate effects.

#fromFoldable

fromFoldable :: forall f. Foldable f => f ~> Array

Convert a Foldable structure into an Array.

fromFoldable (Just 1) = [1]
fromFoldable (Nothing) = []

#toUnfoldable

toUnfoldable :: forall f. Unfoldable f => Array ~> f

Convert an Array into an Unfoldable structure.

#singleton

singleton :: forall a. a -> Array a

Create an array of one element

singleton 2 = [2]

#(..)

Operator alias for Data.Array.range (non-associative / precedence 8)

An infix synonym for range.

2 .. 5 = [2, 3, 4, 5]

#range

range :: Int -> Int -> Array Int

Create an array containing a range of integers, including both endpoints.

range 2 5 = [2, 3, 4, 5]

#replicate

replicate :: forall a. Int -> a -> Array a

Create an array containing a value repeated the specified number of times.

replicate 2 "Hi" = ["Hi", "Hi"]

#some

some :: forall f a. Alternative f => Lazy (f (Array a)) => f a -> f (Array a)

Attempt a computation multiple times, requiring at least one success.

The Lazy constraint is used to generate the result lazily, to ensure termination.

#many

many :: forall f a. Alternative f => Lazy (f (Array a)) => f a -> f (Array a)

Attempt a computation multiple times, returning as many successful results as possible (possibly zero).

The Lazy constraint is used to generate the result lazily, to ensure termination.

#null

null :: forall a. Array a -> Boolean

Test whether an array is empty.

null [] = true
null [1, 2] = false

#length

length :: forall a. Array a -> Int

Get the number of elements in an array.

length ["Hello", "World"] = 2

#(:)

Operator alias for Data.Array.cons (right-associative / precedence 6)

An infix alias for cons.

1 : [2, 3, 4] = [1, 2, 3, 4]

Note, the running time of this function is O(n).

#cons

cons :: forall a. a -> Array a -> Array a

Attaches an element to the front of an array, creating a new array.

cons 1 [2, 3, 4] = [1, 2, 3, 4]

Note, the running time of this function is O(n).

#snoc

snoc :: forall a. Array a -> a -> Array a

Append an element to the end of an array, creating a new array.

snoc [1, 2, 3] 4 = [1, 2, 3, 4]

#insert

insert :: forall a. Ord a => a -> Array a -> Array a

Insert an element into a sorted array.

insert 10 [1, 2, 20, 21] = [1, 2, 10, 20, 21]

#insertBy

insertBy :: forall a. (a -> a -> Ordering) -> a -> Array a -> Array a

Insert an element into a sorted array, using the specified function to determine the ordering of elements.

invertCompare a b = invert $ compare a b

insertBy invertCompare 10 [21, 20, 2, 1] = [21, 20, 10, 2, 1]

#head

head :: forall a. Array a -> Maybe a

Get the first element in an array, or Nothing if the array is empty

Running time: O(1).

head [1, 2] = Just 1
head [] = Nothing

#last

last :: forall a. Array a -> Maybe a

Get the last element in an array, or Nothing if the array is empty

Running time: O(1).

last [1, 2] = Just 2
last [] = Nothing

#tail

tail :: forall a. Array a -> Maybe (Array a)

Get all but the first element of an array, creating a new array, or Nothing if the array is empty

tail [1, 2, 3, 4] = Just [2, 3, 4]
tail [] = Nothing

Running time: O(n) where n is the length of the array

#init

init :: forall a. Array a -> Maybe (Array a)

Get all but the last element of an array, creating a new array, or Nothing if the array is empty.

init [1, 2, 3, 4] = Just [1, 2, 3]
init [] = Nothing

Running time: O(n) where n is the length of the array

#uncons

uncons :: forall a. Array a -> Maybe { head :: a, tail :: Array a }

Break an array into its first element and remaining elements.

Using uncons provides a way of writing code that would use cons patterns in Haskell or pre-PureScript 0.7:

f (x : xs) = something
f [] = somethingElse

Becomes:

f arr = case uncons arr of
  Just { head: x, tail: xs } -> something
  Nothing -> somethingElse

#unsnoc

unsnoc :: forall a. Array a -> Maybe { init :: Array a, last :: a }

Break an array into its last element and all preceding elements.

unsnoc [1, 2, 3] = Just {init: [1, 2], last: 3}
unsnoc [] = Nothing

Running time: O(n) where n is the length of the array

#(!!)

Operator alias for Data.Array.index (left-associative / precedence 8)

An infix version of index.

sentence = ["Hello", "World", "!"]

sentence !! 0 = Just "Hello"
sentence !! 7 = Nothing

#index

index :: forall a. Array a -> Int -> Maybe a

This function provides a safe way to read a value at a particular index from an array.

sentence = ["Hello", "World", "!"]

index sentence 0 = Just "Hello"
index sentence 7 = Nothing

#elem

elem :: forall a. Eq a => a -> Array a -> Boolean

Returns true if the array has the given element.

#notElem

notElem :: forall a. Eq a => a -> Array a -> Boolean

Returns true if the array does not have the given element.

#elemIndex

elemIndex :: forall a. Eq a => a -> Array a -> Maybe Int

Find the index of the first element equal to the specified element.

elemIndex "a" ["a", "b", "a", "c"] = Just 0
elemIndex "Earth" ["Hello", "World", "!"] = Nothing

#elemLastIndex

elemLastIndex :: forall a. Eq a => a -> Array a -> Maybe Int

Find the index of the last element equal to the specified element.

elemLastIndex "a" ["a", "b", "a", "c"] = Just 2
elemLastIndex "Earth" ["Hello", "World", "!"] = Nothing

#find

find :: forall a. (a -> Boolean) -> Array a -> Maybe a

Find the first element for which a predicate holds.

find (contains $ Pattern "b") ["a", "bb", "b", "d"] = Just "bb"
find (contains $ Pattern "x") ["a", "bb", "b", "d"] = Nothing

#findMap

findMap :: forall a b. (a -> Maybe b) -> Array a -> Maybe b

Find the first element in a data structure which satisfies a predicate mapping.

#findIndex

findIndex :: forall a. (a -> Boolean) -> Array a -> Maybe Int

Find the first index for which a predicate holds.

findIndex (contains $ Pattern "b") ["a", "bb", "b", "d"] = Just 1
findIndex (contains $ Pattern "x") ["a", "bb", "b", "d"] = Nothing

#findLastIndex

findLastIndex :: forall a. (a -> Boolean) -> Array a -> Maybe Int

Find the last index for which a predicate holds.

findLastIndex (contains $ Pattern "b") ["a", "bb", "b", "d"] = Just 2
findLastIndex (contains $ Pattern "x") ["a", "bb", "b", "d"] = Nothing

#insertAt

insertAt :: forall a. Int -> a -> Array a -> Maybe (Array a)

Insert an element at the specified index, creating a new array, or returning Nothing if the index is out of bounds.

insertAt 2 "!" ["Hello", "World"] = Just ["Hello", "World", "!"]
insertAt 10 "!" ["Hello"] = Nothing

#deleteAt

deleteAt :: forall a. Int -> Array a -> Maybe (Array a)

Delete the element at the specified index, creating a new array, or returning Nothing if the index is out of bounds.

deleteAt 0 ["Hello", "World"] = Just ["World"]
deleteAt 10 ["Hello", "World"] = Nothing

#updateAt

updateAt :: forall a. Int -> a -> Array a -> Maybe (Array a)

Change the element at the specified index, creating a new array, or returning Nothing if the index is out of bounds.

updateAt 1 "World" ["Hello", "Earth"] = Just ["Hello", "World"]
updateAt 10 "World" ["Hello", "Earth"] = Nothing

#updateAtIndices

updateAtIndices :: forall t a. Foldable t => t (Tuple Int a) -> Array a -> Array a

Change the elements at the specified indices in index/value pairs. Out-of-bounds indices will have no effect.

updates = [Tuple 0 "Hi", Tuple 2 "." , Tuple 10 "foobar"]

updateAtIndices updates ["Hello", "World", "!"] = ["Hi", "World", "."]

#modifyAt

modifyAt :: forall a. Int -> (a -> a) -> Array a -> Maybe (Array a)

Apply a function to the element at the specified index, creating a new array, or returning Nothing if the index is out of bounds.

modifyAt 1 toUpper ["Hello", "World"] = Just ["Hello", "WORLD"]
modifyAt 10 toUpper ["Hello", "World"] = Nothing

#modifyAtIndices

modifyAtIndices :: forall t a. Foldable t => t Int -> (a -> a) -> Array a -> Array a

Apply a function to the element at the specified indices, creating a new array. Out-of-bounds indices will have no effect.

indices = [1, 3]
modifyAtIndices indices toUpper ["Hello", "World", "and", "others"]
   = ["Hello", "WORLD", "and", "OTHERS"]

#alterAt

alterAt :: forall a. Int -> (a -> Maybe a) -> Array a -> Maybe (Array a)

Update or delete the element at the specified index by applying a function to the current value, returning a new array or Nothing if the index is out-of-bounds.

alterAt 1 (stripSuffix $ Pattern "!") ["Hello", "World!"]
   = Just ["Hello", "World"]

alterAt 1 (stripSuffix $ Pattern "!!!!!") ["Hello", "World!"]
   = Just ["Hello"]

alterAt 10 (stripSuffix $ Pattern "!") ["Hello", "World!"] = Nothing

#intersperse

intersperse :: forall a. a -> Array a -> Array a

Inserts the given element in between each element in the array. The array must have two or more elements for this operation to take effect.

intersperse " " [ "a", "b" ] == [ "a", " ", "b" ]
intersperse 0 [ 1, 2, 3, 4, 5 ] == [ 1, 0, 2, 0, 3, 0, 4, 0, 5 ]

If the array has less than two elements, the input array is returned.

intersperse " " [] == []
intersperse " " ["a"] == ["a"]

#reverse

reverse :: forall a. Array a -> Array a

Reverse an array, creating a new array.

reverse [] = []
reverse [1, 2, 3] = [3, 2, 1]

#concat

concat :: forall a. Array (Array a) -> Array a

Flatten an array of arrays, creating a new array.

concat [[1, 2, 3], [], [4, 5, 6]] = [1, 2, 3, 4, 5, 6]

#concatMap

concatMap :: forall a b. (a -> Array b) -> Array a -> Array b

Apply a function to each element in an array, and flatten the results into a single, new array.

concatMap (split $ Pattern " ") ["Hello World", "other thing"]
   = ["Hello", "World", "other", "thing"]

#filter

filter :: forall a. (a -> Boolean) -> Array a -> Array a

Filter an array, keeping the elements which satisfy a predicate function, creating a new array.

filter (_ > 0) [-1, 4, -5, 7] = [4, 7]

#partition

partition :: forall a. (a -> Boolean) -> Array a -> { no :: Array a, yes :: Array a }

Partition an array using a predicate function, creating a set of new arrays. One for the values satisfying the predicate function and one for values that don't.

partition (_ > 0) [-1, 4, -5, 7] = { yes: [4, 7], no: [-1, -5] }

#splitAt

splitAt :: forall a. Int -> Array a -> { after :: Array a, before :: Array a }

Splits an array into two subarrays, where before contains the elements up to (but not including) the given index, and after contains the rest of the elements, from that index on.

>>> splitAt 3 [1, 2, 3, 4, 5]
{ before: [1, 2, 3], after: [4, 5] }

Thus, the length of (splitAt i arr).before will equal either i or length arr, if that is shorter. (Or if i is negative the length will be 0.)

splitAt 2 ([] :: Array Int) == { before: [], after: [] }
splitAt 3 [1, 2, 3, 4, 5] == { before: [1, 2, 3], after: [4, 5] }

#filterA

filterA :: forall a f. Applicative f => (a -> f Boolean) -> Array a -> f (Array a)

Filter where the predicate returns a Boolean in some Applicative.

powerSet :: forall a. Array a -> Array (Array a)
powerSet = filterA (const [true, false])

#mapMaybe

mapMaybe :: forall a b. (a -> Maybe b) -> Array a -> Array b

Apply a function to each element in an array, keeping only the results which contain a value, creating a new array.

parseEmail :: String -> Maybe Email
parseEmail = ...

mapMaybe parseEmail ["a.com", "hello@example.com", "--"]
   = [Email {user: "hello", domain: "example.com"}]

#catMaybes

catMaybes :: forall a. Array (Maybe a) -> Array a

Filter an array of optional values, keeping only the elements which contain a value, creating a new array.

catMaybes [Nothing, Just 2, Nothing, Just 4] = [2, 4]

#mapWithIndex

mapWithIndex :: forall a b. (Int -> a -> b) -> Array a -> Array b

Apply a function to each element in an array, supplying a generated zero-based index integer along with the element, creating an array with the new elements.

prefixIndex index element = show index <> element

mapWithIndex prefixIndex ["Hello", "World"] = ["0Hello", "1World"]

#foldl

foldl :: forall a b. (b -> a -> b) -> b -> Array a -> b

#foldr

foldr :: forall a b. (a -> b -> b) -> b -> Array a -> b

#foldMap

foldMap :: forall a m. Monoid m => (a -> m) -> Array a -> m

#fold

fold :: forall m. Monoid m => Array m -> m

#intercalate

intercalate :: forall a. Monoid a => a -> Array a -> a

#transpose

transpose :: forall a. Array (Array a) -> Array (Array a)

The 'transpose' function transposes the rows and columns of its argument. For example,

transpose 
  [ [1, 2, 3]
  , [4, 5, 6]
  ] == 
  [ [1, 4]
  , [2, 5]
  , [3, 6]
  ]

If some of the rows are shorter than the following rows, their elements are skipped:

transpose 
  [ [10, 11]
  , [20]
  , [30, 31, 32]
  ] == 
  [ [10, 20, 30]
  , [11, 31]
  , [32]
  ]

#scanl

scanl :: forall a b. (b -> a -> b) -> b -> Array a -> Array b

Fold a data structure from the left, keeping all intermediate results instead of only the final result. Note that the initial value does not appear in the result (unlike Haskell's Prelude.scanl).

scanl (+) 0  [1,2,3] = [1,3,6]
scanl (-) 10 [1,2,3] = [9,7,4]

#scanr

scanr :: forall a b. (a -> b -> b) -> b -> Array a -> Array b

Fold a data structure from the right, keeping all intermediate results instead of only the final result. Note that the initial value does not appear in the result (unlike Haskell's Prelude.scanr).

scanr (+) 0 [1,2,3] = [6,5,3]
scanr (flip (-)) 10 [1,2,3] = [4,5,7]

#sort

sort :: forall a. Ord a => Array a -> Array a

Sort the elements of an array in increasing order, creating a new array. Sorting is stable: the order of equal elements is preserved.

sort [2, -3, 1] = [-3, 1, 2]

#sortBy

sortBy :: forall a. (a -> a -> Ordering) -> Array a -> Array a

Sort the elements of an array in increasing order, where elements are compared using the specified partial ordering, creating a new array. Sorting is stable: the order of elements is preserved if they are equal according to the specified partial ordering.

compareLength a b = compare (length a) (length b)
sortBy compareLength [[1, 2, 3], [7, 9], [-2]] = [[-2],[7,9],[1,2,3]]

#sortWith

sortWith :: forall a b. Ord b => (a -> b) -> Array a -> Array a

Sort the elements of an array in increasing order, where elements are sorted based on a projection. Sorting is stable: the order of elements is preserved if they are equal according to the projection.

sortWith (_.age) [{name: "Alice", age: 42}, {name: "Bob", age: 21}]
   = [{name: "Bob", age: 21}, {name: "Alice", age: 42}]

#slice

slice :: forall a. Int -> Int -> Array a -> Array a

Extract a subarray by a start and end index.

letters = ["a", "b", "c"]
slice 1 3 letters = ["b", "c"]
slice 5 7 letters = []
slice 4 1 letters = []

#take

take :: forall a. Int -> Array a -> Array a

Keep only a number of elements from the start of an array, creating a new array.

letters = ["a", "b", "c"]

take 2 letters = ["a", "b"]
take 100 letters = ["a", "b", "c"]

#takeEnd

takeEnd :: forall a. Int -> Array a -> Array a

Keep only a number of elements from the end of an array, creating a new array.

letters = ["a", "b", "c"]

takeEnd 2 letters = ["b", "c"]
takeEnd 100 letters = ["a", "b", "c"]

#takeWhile

takeWhile :: forall a. (a -> Boolean) -> Array a -> Array a

Calculate the longest initial subarray for which all element satisfy the specified predicate, creating a new array.

takeWhile (_ > 0) [4, 1, 0, -4, 5] = [4, 1]
takeWhile (_ > 0) [-1, 4] = []

#drop

drop :: forall a. Int -> Array a -> Array a

Drop a number of elements from the start of an array, creating a new array.

letters = ["a", "b", "c", "d"]

drop 2 letters = ["c", "d"]
drop 10 letters = []

#dropEnd

dropEnd :: forall a. Int -> Array a -> Array a

Drop a number of elements from the end of an array, creating a new array.

letters = ["a", "b", "c", "d"]

dropEnd 2 letters = ["a", "b"]
dropEnd 10 letters = []

#dropWhile

dropWhile :: forall a. (a -> Boolean) -> Array a -> Array a

Remove the longest initial subarray for which all element satisfy the specified predicate, creating a new array.

dropWhile (_ < 0) [-3, -1, 0, 4, -6] = [0, 4, -6]

#span

span :: forall a. (a -> Boolean) -> Array a -> { init :: Array a, rest :: Array a }

Split an array into two parts:

  1. the longest initial subarray for which all elements satisfy the specified predicate
  2. the remaining elements
span (\n -> n % 2 == 1) [1,3,2,4,5] == { init: [1,3], rest: [2,4,5] }

Running time: O(n).

#group

group :: forall a. Eq a => Array a -> Array (NonEmptyArray a)

Group equal, consecutive elements of an array into arrays.

group [1, 1, 2, 2, 1] == [NonEmptyArray [1, 1], NonEmptyArray [2, 2], NonEmptyArray [1]]

#groupAll

groupAll :: forall a. Ord a => Array a -> Array (NonEmptyArray a)

Group equal elements of an array into arrays.

groupAll [1, 1, 2, 2, 1] == [NonEmptyArray [1, 1, 1], NonEmptyArray [2, 2]]

#groupBy

groupBy :: forall a. (a -> a -> Boolean) -> Array a -> Array (NonEmptyArray a)

Group equal, consecutive elements of an array into arrays, using the specified equivalence relation to determine equality.

groupBy (\a b -> odd a && odd b) [1, 3, 2, 4, 3, 3]
   = [NonEmptyArray [1, 3], NonEmptyArray [2], NonEmptyArray [4], NonEmptyArray [3, 3]]

#groupAllBy

groupAllBy :: forall a. (a -> a -> Ordering) -> Array a -> Array (NonEmptyArray a)

Group equal elements of an array into arrays, using the specified comparison function to determine equality.

groupAllBy (comparing Down) [1, 3, 2, 4, 3, 3]
   = [NonEmptyArray [4], NonEmptyArray [3, 3, 3], NonEmptyArray [2], NonEmptyArray [1]]

#nub

nub :: forall a. Ord a => Array a -> Array a

Remove the duplicates from an array, creating a new array.

nub [1, 2, 1, 3, 3] = [1, 2, 3]

#nubEq

nubEq :: forall a. Eq a => Array a -> Array a

Remove the duplicates from an array, creating a new array.

This less efficient version of nub only requires an Eq instance.

nubEq [1, 2, 1, 3, 3] = [1, 2, 3]

#nubBy

nubBy :: forall a. (a -> a -> Ordering) -> Array a -> Array a

Remove the duplicates from an array, where element equality is determined by the specified ordering, creating a new array.

nubBy compare [1, 3, 4, 2, 2, 1] == [1, 3, 4, 2]

#nubByEq

nubByEq :: forall a. (a -> a -> Boolean) -> Array a -> Array a

Remove the duplicates from an array, where element equality is determined by the specified equivalence relation, creating a new array.

This less efficient version of nubBy only requires an equivalence relation.

mod3eq a b = a `mod` 3 == b `mod` 3
nubByEq mod3eq [1, 3, 4, 5, 6] = [1, 3, 5]

#union

union :: forall a. Eq a => Array a -> Array a -> Array a

Calculate the union of two arrays. Note that duplicates in the first array are preserved while duplicates in the second array are removed.

Running time: O(n^2)

union [1, 2, 1, 1] [3, 3, 3, 4] = [1, 2, 1, 1, 3, 4]

#unionBy

unionBy :: forall a. (a -> a -> Boolean) -> Array a -> Array a -> Array a

Calculate the union of two arrays, using the specified function to determine equality of elements. Note that duplicates in the first array are preserved while duplicates in the second array are removed.

mod3eq a b = a `mod` 3 == b `mod` 3
unionBy mod3eq [1, 5, 1, 2] [3, 4, 3, 3] = [1, 5, 1, 2, 3]

#delete

delete :: forall a. Eq a => a -> Array a -> Array a

Delete the first element of an array which is equal to the specified value, creating a new array.

delete 7 [1, 7, 3, 7] = [1, 3, 7]
delete 7 [1, 2, 3] = [1, 2, 3]

Running time: O(n)

#deleteBy

deleteBy :: forall a. (a -> a -> Boolean) -> a -> Array a -> Array a

Delete the first element of an array which matches the specified value, under the equivalence relation provided in the first argument, creating a new array.

mod3eq a b = a `mod` 3 == b `mod` 3
deleteBy mod3eq 6 [1, 3, 4, 3] = [1, 4, 3]

#(\\)

Operator alias for Data.Array.difference (non-associative / precedence 5)

#difference

difference :: forall a. Eq a => Array a -> Array a -> Array a

Delete the first occurrence of each element in the second array from the first array, creating a new array.

difference [2, 1] [2, 3] = [1]

Running time: O(n*m), where n is the length of the first array, and m is the length of the second.

#intersect

intersect :: forall a. Eq a => Array a -> Array a -> Array a

Calculate the intersection of two arrays, creating a new array. Note that duplicates in the first array are preserved while duplicates in the second array are removed.

intersect [1, 1, 2] [2, 2, 1] = [1, 1, 2]

#intersectBy

intersectBy :: forall a. (a -> a -> Boolean) -> Array a -> Array a -> Array a

Calculate the intersection of two arrays, using the specified equivalence relation to compare elements, creating a new array. Note that duplicates in the first array are preserved while duplicates in the second array are removed.

mod3eq a b = a `mod` 3 == b `mod` 3
intersectBy mod3eq [1, 2, 3] [4, 6, 7] = [1, 3]

#zipWith

zipWith :: forall a b c. (a -> b -> c) -> Array a -> Array b -> Array c

Apply a function to pairs of elements at the same index in two arrays, collecting the results in a new array.

If one array is longer, elements will be discarded from the longer array.

For example

zipWith (*) [1, 2, 3] [4, 5, 6, 7] == [4, 10, 18]

#zipWithA

zipWithA :: forall m a b c. Applicative m => (a -> b -> m c) -> Array a -> Array b -> m (Array c)

A generalization of zipWith which accumulates results in some Applicative functor.

sndChars = zipWithA (\a b -> charAt 2 (a <> b))
sndChars ["a", "b"] ["A", "B"] = Nothing -- since "aA" has no 3rd char
sndChars ["aa", "b"] ["AA", "BBB"] = Just ['A', 'B']

#zip

zip :: forall a b. Array a -> Array b -> Array (Tuple a b)

Takes two arrays and returns an array of corresponding pairs. If one input array is short, excess elements of the longer array are discarded.

zip [1, 2, 3] ["a", "b"] = [Tuple 1 "a", Tuple 2 "b"]

#unzip

unzip :: forall a b. Array (Tuple a b) -> Tuple (Array a) (Array b)

Transforms an array of pairs into an array of first components and an array of second components.

unzip [Tuple 1 "a", Tuple 2 "b"] = Tuple [1, 2] ["a", "b"]

#any

any :: forall a. (a -> Boolean) -> Array a -> Boolean

Returns true if at least one array element satisfies the given predicate, iterating the array only as necessary and stopping as soon as the predicate yields true.

any (_ > 0) [] = False
any (_ > 0) [-1, 0, 1] = True
any (_ > 0) [-1, -2, -3] = False

#all

all :: forall a. (a -> Boolean) -> Array a -> Boolean

Returns true if all the array elements satisfy the given predicate. iterating the array only as necessary and stopping as soon as the predicate yields false.

all (_ > 0) [] = True
all (_ > 0) [1, 2, 3] = True
all (_ > 0) [-1, -2, -3] = False

#foldM

foldM :: forall m a b. Monad m => (b -> a -> m b) -> b -> Array a -> m b

Perform a fold using a monadic step function.

foldM (\x y -> Just (x + y)) 0 [1, 4] = Just 5

#foldRecM

foldRecM :: forall m a b. MonadRec m => (b -> a -> m b) -> b -> Array a -> m b

#unsafeIndex

unsafeIndex :: forall a. Partial => Array a -> Int -> a

Find the element of an array at the specified index.

unsafePartial $ unsafeIndex ["a", "b", "c"] 1 = "b"

Using unsafeIndex with an out-of-range index will not immediately raise a runtime error. Instead, the result will be undefined. Most attempts to subsequently use the result will cause a runtime error, of course, but this is not guaranteed, and is dependent on the backend; some programs will continue to run as if nothing is wrong. For example, in the JavaScript backend, the expression unsafePartial (unsafeIndex [true] 1) has type Boolean; since this expression evaluates to undefined, attempting to use it in an if statement will cause the else branch to be taken.

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