ArraySlice

struct ArraySlice<Element>

A slice of an Array, ContiguousArray, or ArraySlice instance.

The ArraySlice type makes it fast and efficient for you to perform operations on sections of a larger array. Instead of copying over the elements of a slice to new storage, an ArraySlice instance presents a view onto the storage of a larger array. And because ArraySlice presents the same interface as Array, you can generally perform the same operations on a slice as you could on the original array.

For more information about using arrays, see Array and ContiguousArray, with which ArraySlice shares most properties and methods.

Slices Are Views onto Arrays

For example, suppose you have an array holding the number of absences from each class during a session.

let absences = [0, 2, 0, 4, 0, 3, 1, 0]

You want to compare the absences in the first half of the session with those in the second half. To do so, start by creating two slices of the absences array.

let midpoint = absences.count / 2

let firstHalf = absences.prefix(upTo: midpoint)
let secondHalf = absences.suffix(from: midpoint)

Neither the firstHalf nor secondHalf slices allocate any new storage of their own. Instead, each presents a view onto the storage of the absences array.

You can call any method on the slices that you might have called on the absences array. To learn which half had more absences, use the reduce(_:_:) method to calculate each sum.

let firstHalfSum = firstHalf.reduce(0, +)
let secondHalfSum = secondHalf.reduce(0, +)

if firstHalfSum > secondHalfSum {
    print("More absences in the first half.")
} else {
    print("More absences in the second half.")
}
// Prints "More absences in the second half."

Important: Long-term storage of ArraySlice instances is discouraged. A slice holds a reference to the entire storage of a larger array, not just to the portion it presents, even after the original array's lifetime ends. Long-term storage of a slice may therefore prolong the lifetime of elements that are no longer otherwise accessible, which can appear to be memory and object leakage.

Slices Maintain Indices

Unlike Array and ContiguousArray, the starting index for an ArraySlice instance isn't always zero. Slices maintain the same indices of the larger array for the same elements, so the starting index of a slice depends on how it was created, letting you perform index-based operations on either a full array or a slice.

Sharing indices between collections and their subsequences is an important part of the design of Swift's collection algorithms. Suppose you are tasked with finding the first two days with absences in the session. To find the indices of the two days in question, follow these steps:

1) Call index(where:) to find the index of the first element in the absences array that is greater than zero. 2) Create a slice of the absences array starting after the index found in step 1. 3) Call index(where:) again, this time on the slice created in step 2. Where in some languages you might pass a starting index into an indexOf method to find the second day, in Swift you perform the same operation on a slice of the original array. 4) Print the results using the indices found in steps 1 and 3 on the original absences array.

Here's an implementation of those steps:

if let i = absences.index(where: { $0 > 0 }) {                      // 1
    let absencesAfterFirst = absences.suffix(from: i + 1)           // 2
    if let j = absencesAfterFirst.index(where: { $0 > 0 }) {        // 3
        print("The first day with absences had \(absences[i]).")    // 4
        print("The second day with absences had \(absences[j]).")
    }
}
// Prints "The first day with absences had 2."
// Prints "The second day with absences had 4."

In particular, note that j, the index of the second day with absences, was found in a slice of the original array and then used to access a value in the original absences array itself.

Note: To safely reference the starting and ending indices of a slice, always use the startIndex and endIndex properties instead of specific values.

Inheritance BidirectionalCollection, BidirectionalIndexable, Collection, CustomDebugStringConvertible, CustomReflectable, CustomStringConvertible, ExpressibleByArrayLiteral, Indexable, IndexableBase, MutableCollection, MutableIndexable, RandomAccessCollection, RandomAccessIndexable, RangeReplaceableCollection, RangeReplaceableIndexable, Sequence View Protocol Hierarchy →
Associated Types
Index = Int

A type that represents a position in the collection.

Valid indices consist of the position of every element and a "past the end" position that's not valid for use as a subscript argument.

See Also: endIndex

Iterator = IndexingIterator<ArraySlice<Element>>

A type that provides the collection's iteration interface and encapsulates its iteration state.

By default, a collection conforms to the Sequence protocol by supplying a IndexingIterator as its associated Iterator type.

Indices = CountableRange<Int>

A type that can represent the indices that are valid for subscripting the collection, in ascending order.

Element = Element

Type alias inferred.

Index = Int

Type alias inferred.

SubSequence = ArraySlice<Element>

Type alias inferred.

Import import Swift

Initializers

init()

Creates a new, empty array.

This is equivalent to initializing with an empty array literal. For example:

var emptyArray = Array<Int>()
print(emptyArray.isEmpty)
// Prints "true"

emptyArray = []
print(emptyArray.isEmpty)
// Prints "true"

Declaration

init()
init(_:)

Creates an array containing the elements of a sequence.

You can use this initializer to create an array from any other type that conforms to the Sequence protocol. For example, you might want to create an array with the integers from 1 through 7. Use this initializer around a range instead of typing all those numbers in an array literal.

let numbers = Array(1...7)
print(numbers)
// Prints "[1, 2, 3, 4, 5, 6, 7]"

You can also use this initializer to convert a complex sequence or collection type back to an array. For example, the keys property of a dictionary isn't an array with its own storage, it's a collection that maps its elements from the dictionary only when they're accessed, saving the time and space needed to allocate an array. If you need to pass those keys to a method that takes an array, however, use this initializer to convert that list from its type of LazyMapCollection<Dictionary<String, Int>, Int> to a simple [String].

func cacheImagesWithNames(names: [String]) {
    // custom image loading and caching
 }

let namedHues: [String: Int] = ["Vermillion": 18, "Magenta": 302,
        "Gold": 50, "Cerise": 320]
let colorNames = Array(namedHues.keys)
cacheImagesWithNames(colorNames)

print(colorNames)
// Prints "["Gold", "Cerise", "Magenta", "Vermillion"]"

s: The sequence of elements to turn into an array.

Declaration

init<S : Sequence where S.Iterator.Element == Element>(_ s: S)

Declared In

ArraySlice , RangeReplaceableCollection
init(arrayLiteral:)

Creates an array from the given array literal.

Do not call this initializer directly. It is used by the compiler when you use an array literal. Instead, create a new array by using an array literal as its value. To do this, enclose a comma-separated list of values in square brackets.

Here, an array of strings is created from an array literal holding only strings:

let ingredients: ArraySlice =
      ["cocoa beans", "sugar", "cocoa butter", "salt"]

elements: A variadic list of elements of the new array.

Declaration

init(arrayLiteral elements: Element...)
init(repeating:count:)

Creates a new array containing the specified number of a single, repeated value.

Here's an example of creating an array initialized with five strings containing the letter Z.

let fiveZs = Array(repeating: "Z", count: 5)
print(fiveZs)
// Prints "["Z", "Z", "Z", "Z", "Z"]"

Parameters: repeatedValue: The element to repeat. count: The number of times to repeat the value passed in the repeating parameter. count must be zero or greater.

Declaration

init(repeating repeatedValue: Element, count: Int)

Declared In

ArraySlice , RangeReplaceableCollection

Instance Variables

var capacity: Int

The total number of elements that the array can contain using its current storage.

If the array grows larger than its capacity, it discards its current storage and allocates a larger one.

The following example creates an array of integers from an array literal, then appends the elements of another collection. Before appending, the array allocates new storage that is large enough store the resulting elements.

var numbers = [10, 20, 30, 40, 50]
print("Count: \(numbers.count), capacity: \(numbers.capacity)")
// Prints "Count: 5, capacity: 5"

numbers.append(contentsOf: stride(from: 60, through: 100, by: 10))
print("Count: \(numbers.count), capacity: \(numbers.capacity)")
// Prints "Count: 10, capacity: 12"

Declaration

var capacity: Int { get }
var count: Int

The number of elements in the array.

Declaration

var count: Int { get }
var customMirror: Mirror

A mirror that reflects the array.

Declaration

var customMirror: Mirror { get }
var debugDescription: String

A textual representation of the array and its elements, suitable for debugging.

Declaration

var debugDescription: String { get }
var description: String

A textual representation of the array and its elements.

Declaration

var description: String { get }
var endIndex: Int

The array's "past the end" position---that is, the position one greater than the last valid subscript argument.

When you need a range that includes the last element of an array, use the half-open range operator (..<) with endIndex. The ..< operator creates a range that doesn't include the upper bound, so it's always safe to use with endIndex. For example:

let numbers = [10, 20, 30, 40, 50]
if let i = numbers.index(of: 30) {
    print(numbers[i ..< numbers.endIndex])
}
// Prints "[30, 40, 50]"

If the array is empty, endIndex is equal to startIndex.

Declaration

var endIndex: Int { get }
var first: Element?

The first element of the collection.

If the collection is empty, the value of this property is nil.

let numbers = [10, 20, 30, 40, 50]
if let firstNumber = numbers.first {
    print(firstNumber)
}
// Prints "10"

Declaration

var first: Element? { get }

Declared In

Collection
var isEmpty: Bool

A Boolean value indicating whether the collection is empty.

When you need to check whether your collection is empty, use the isEmpty property instead of checking that the count property is equal to zero. For collections that don't conform to RandomAccessCollection, accessing the count property iterates through the elements of the collection.

let horseName = "Silver"
if horseName.characters.isEmpty {
    print("I've been through the desert on a horse with no name.")
} else {
    print("Hi ho, \(horseName)!")
}
// Prints "Hi ho, Silver!")

Complexity: O(1)

Declaration

var isEmpty: Bool { get }

Declared In

Collection
var last: Element?

The last element of the collection.

If the collection is empty, the value of this property is nil.

let numbers = [10, 20, 30, 40, 50]
if let lastNumber = numbers.last {
    print(lastNumber)
}
// Prints "50"

Declaration

var last: Element? { get }

Declared In

BidirectionalCollection
var lazy: LazyRandomAccessCollection<ArraySlice<Element>>

A view onto this collection that provides lazy implementations of normally eager operations, such as map and filter.

Use the lazy property when chaining operations to prevent intermediate operations from allocating storage, or when you only need a part of the final collection to avoid unnecessary computation.

See Also: LazySequenceProtocol, LazyCollectionProtocol.

Declaration

var lazy: LazyRandomAccessCollection<ArraySlice<Element>> { get }

Declared In

RandomAccessCollection
var startIndex: Int

The position of the first element in a nonempty array.

If the array is empty, startIndex is equal to endIndex.

Declaration

var startIndex: Int { get }
var underestimatedCount: Int

A value less than or equal to the number of elements in the collection.

Complexity: O(1) if the collection conforms to RandomAccessCollection; otherwise, O(n), where n is the length of the collection.

Declaration

var underestimatedCount: Int { get }

Declared In

Collection , Sequence

Subscripts

subscript(_: ClosedRange<Int>)

Accesses a contiguous subrange of the collection's elements.

The accessed slice uses the same indices for the same elements as the original collection. Always use the slice's startIndex property instead of assuming that its indices start at a particular value.

This example demonstrates getting a slice of an array of strings, finding the index of one of the strings in the slice, and then using that index in the original array.

let streets = ["Adams", "Bryant", "Channing", "Douglas", "Evarts"]
let streetsSlice = streets[2 ..< streets.endIndex]
print(streetsSlice)
// Prints "["Channing", "Douglas", "Evarts"]"

let index = streetsSlice.index(of: "Evarts")    // 4
streets[index!] = "Eustace"
print(streets[index!])
// Prints "Eustace"

bounds: A range of the collection's indices. The bounds of the range must be valid indices of the collection.

Declaration

subscript(bounds: ClosedRange<Int>) -> ArraySlice<Element>

Declared In

MutableIndexable, Indexable
subscript(_: Int)

Accesses the element at the specified position.

The following example uses indexed subscripting to update an array's second element. After assigning the new value ("Butler") at a specific position, that value is immediately available at that same position.

var streets = ["Adams", "Bryant", "Channing", "Douglas", "Evarts"]
streets[1] = "Butler"
print(streets[1])
// Prints "Butler"

index: The position of the element to access. index must be greater than or equal to startIndex and less than endIndex.

Complexity: Reading an element from an array is O(1). Writing is O(1) unless the array's storage is shared with another array, in which case writing is O(n), where n is the length of the array.

Declaration

subscript(index: Int) -> Element
subscript(_: Range<Int>)

Accesses a contiguous subrange of the array's elements.

The returned ArraySlice instance uses the same indices for the same elements as the original array. In particular, that slice, unlike an array, may have a nonzero startIndex and an endIndex that is not equal to count. Always use the slice's startIndex and endIndex properties instead of assuming that its indices start or end at a particular value.

This example demonstrates getting a slice of an array of strings, finding the index of one of the strings in the slice, and then using that index in the original array.

let streets = ["Adams", "Bryant", "Channing", "Douglas", "Evarts"]
let streetsSlice = streets[2 ..< streets.endIndex]
print(streetsSlice)
// Prints "["Channing", "Douglas", "Evarts"]"

let i = streetsSlice.index(of: "Evarts")    // 4
print(streets[i!])
// Prints "Evarts"

bounds: A range of integers. The bounds of the range must be valid indices of the array.

Declaration

subscript(bounds: Range<Int>) -> ArraySlice<Element>

Declared In

ArraySlice, MutableCollection

Instance Methods

mutating func append(_:)

Adds a new element at the end of the array.

Use this method to append a single element to the end of a mutable array.

var numbers = [1, 2, 3, 4, 5]
numbers.append(100)
print(numbers)
// Prints "[1, 2, 3, 4, 5, 100]"

Because arrays increase their allocated capacity using an exponential strategy, appending a single element to an array is an O(1) operation when averaged over many calls to the append(_:) method. When an array has additional capacity and is not sharing its storage with another instance, appending an element is O(1). When an array needs to reallocate storage before appending or its storage is shared with another copy, appending is O(n), where n is the length of the array.

newElement: The element to append to the array.

Complexity: Amortized O(1) over many additions. If the array uses a bridged NSArray instance as its storage, the efficiency is unspecified.

Declaration

mutating func append(_ newElement: Element)

Declared In

ArraySlice, RangeReplaceableCollection
mutating func append<S : Sequence where S.Iterator.Element == Element>(contentsOf: S)

Adds the elements of a sequence to the end of the array.

Use this method to append the elements of a sequence to the end of an array. This example appends the elements of a Range<Int> instance to an array of integers.

var numbers = [1, 2, 3, 4, 5]
numbers.append(contentsOf: 10...15)
print(numbers)
// Prints "[1, 2, 3, 4, 5, 10, 11, 12, 13, 14, 15]"

newElements: The elements to append to the array.

Complexity: O(n), where n is the length of the resulting array.

Declaration

mutating func append<S : Sequence where S.Iterator.Element == Element>(contentsOf newElements: S)
mutating func append<C : Collection where C.Iterator.Element == Element>(contentsOf: C)

Adds the elements of a collection to the end of the array.

Use this method to append the elements of a collection to the end of this array. This example appends the elements of a Range<Int> instance to an array of integers.

var numbers = [1, 2, 3, 4, 5]
numbers.append(contentsOf: 10...15)
print(numbers)
// Prints "[1, 2, 3, 4, 5, 10, 11, 12, 13, 14, 15]"

newElements: The elements to append to the array.

Complexity: O(n), where n is the length of the resulting array.

Declaration

mutating func append<C : Collection where C.Iterator.Element == Element>(contentsOf newElements: C)
mutating func append(contentsOf:)

Adds the elements of a sequence to the end of this collection.

The collection being appended to allocates any additional necessary storage to hold the new elements.

The following example appends the elements of a Range<Int> instance to an array of integers:

var numbers = [1, 2, 3, 4, 5]
numbers.append(contentsOf: 10...15)
print(numbers)
// Prints "[1, 2, 3, 4, 5, 10, 11, 12, 13, 14, 15]"

newElements: The elements to append to the collection.

Complexity: O(n), where n is the length of the resulting collection.

Declaration

mutating func append<S : Sequence where S.Iterator.Element == Iterator.Element>(contentsOf newElements: S)

Declared In

RangeReplaceableCollection
func contains(where:)

Returns a Boolean value indicating whether the sequence contains an element that satisfies the given predicate.

You can use the predicate to check for an element of a type that doesn't conform to the Equatable protocol, such as the HTTPResponse enumeration in this example.

enum HTTPResponse {
    case ok
    case error(Int)
}

let lastThreeResponses: [HTTPResponse] = [.ok, .ok, .error(404)]
let hadError = lastThreeResponses.contains { element in
    if case .error = element {
        return true
    } else {
        return false
    }
}
// 'hadError' == true

Alternatively, a predicate can be satisfied by a range of Equatable elements or a general condition. This example shows how you can check an array for an expense greater than $100.

let expenses = [21.37, 55.21, 9.32, 10.18, 388.77, 11.41]
let hasBigPurchase = expenses.contains { $0 > 100 }
// 'hasBigPurchase' == true

predicate: A closure that takes an element of the sequence as its argument and returns a Boolean value that indicates whether the passed element represents a match. Returns: true if the sequence contains an element that satisfies predicate; otherwise, false.

Declaration

func contains(where predicate: (Element) throws -> Bool) rethrows -> Bool

Declared In

Sequence
func distance(from:to:)

Returns the distance between two indices.

Parameters: start: A valid index of the collection. end: Another valid index of the collection. If end is equal to start, the result is zero. Returns: The distance between start and end.

Declaration

func distance(from start: Int, to end: Int) -> Int

Declared In

ArraySlice, BidirectionalIndexable, Indexable
func dropFirst()

Returns a subsequence containing all but the first element of the sequence.

The following example drops the first element from an array of integers.

let numbers = [1, 2, 3, 4, 5]
print(numbers.dropFirst())
// Prints "[2, 3, 4, 5]"

If the sequence has no elements, the result is an empty subsequence.

let empty: [Int] = []
print(empty.dropFirst())
// Prints "[]"

Returns: A subsequence starting after the first element of the sequence.

Complexity: O(1)

Declaration

func dropFirst() -> ArraySlice<Element>

Declared In

Sequence
func dropFirst(_:)

Returns a subsequence containing all but the given number of initial elements.

If the number of elements to drop exceeds the number of elements in the collection, the result is an empty subsequence.

let numbers = [1, 2, 3, 4, 5]
print(numbers.dropFirst(2))
// Prints "[3, 4, 5]"
print(numbers.dropFirst(10))
// Prints "[]"

n: The number of elements to drop from the beginning of the collection. n must be greater than or equal to zero. Returns: A subsequence starting after the specified number of elements.

Complexity: O(n), where n is the number of elements to drop from the beginning of the collection.

Declaration

func dropFirst(_ n: Int) -> ArraySlice<Element>

Declared In

Collection, Sequence
func dropLast()

Returns a subsequence containing all but the last element of the sequence.

The sequence must be finite. If the sequence has no elements, the result is an empty subsequence.

let numbers = [1, 2, 3, 4, 5]
print(numbers.dropLast())
// Prints "[1, 2, 3, 4]"

If the sequence has no elements, the result is an empty subsequence.

let empty: [Int] = []
print(empty.dropLast())
// Prints "[]"

Returns: A subsequence leaving off the last element of the sequence.

Complexity: O(n), where n is the length of the sequence.

Declaration

func dropLast() -> ArraySlice<Element>

Declared In

Sequence
func dropLast(_:)

Returns a subsequence containing all but the specified number of final elements.

If the number of elements to drop exceeds the number of elements in the collection, the result is an empty subsequence.

let numbers = [1, 2, 3, 4, 5]
print(numbers.dropLast(2))
// Prints "[1, 2, 3]"
print(numbers.dropLast(10))
// Prints "[]"

n: The number of elements to drop off the end of the collection. n must be greater than or equal to zero. Returns: A subsequence that leaves off n elements from the end.

Complexity: O(n), where n is the number of elements to drop.

Declaration

func dropLast(_ n: Int) -> ArraySlice<Element>

Declared In

BidirectionalCollection, Collection, Sequence
func elementsEqual(_:by:)

Returns a Boolean value indicating whether this sequence and another sequence contain equivalent elements, using the given predicate as the equivalence test.

At least one of the sequences must be finite.

The predicate must be a equivalence relation over the elements. That is, for any elements a, b, and c, the following conditions must hold:

  • areEquivalent(a, a) is always true. (Reflexivity)
  • areEquivalent(a, b) implies areEquivalent(b, a). (Symmetry)
  • If areEquivalent(a, b) and areEquivalent(b, c) are both true, then areEquivalent(a, c) is also true. (Transitivity)

Parameters: other: A sequence to compare to this sequence. areEquivalent: A predicate that returns true if its two arguments are equivalent; otherwise, false. Returns: true if this sequence and other contain equivalent items, using areEquivalent as the equivalence test; otherwise, false.

See Also: elementsEqual(_:)

Declaration

func elementsEqual<OtherSequence where OtherSequence : Sequence, OtherSequence.Iterator.Element == Iterator.Element>(_ other: OtherSequence, by areEquivalent: (Element, Element) throws -> Bool) rethrows -> Bool

Declared In

Sequence
func enumerated()

Returns a sequence of pairs (n, x), where n represents a consecutive integer starting at zero, and x represents an element of the sequence.

This example enumerates the characters of the string "Swift" and prints each character along with its place in the string.

for (n, c) in "Swift".characters.enumerated() {
    print("\(n): '\(c)'")
}
// Prints "0: 'S'"
// Prints "1: 'w'"
// Prints "2: 'i'"
// Prints "3: 'f'"
// Prints "4: 't'"

When enumerating a collection, the integer part of each pair is a counter for the enumeration, not necessarily the index of the paired value. These counters can only be used as indices in instances of zero-based, integer-indexed collections, such as Array and ContiguousArray. For other collections the counters may be out of range or of the wrong type to use as an index. To iterate over the elements of a collection with its indices, use the zip(_:_:) function.

This example iterates over the indices and elements of a set, building a list of indices of names with five or fewer letters.

let names: Set = ["Sofia", "Camilla", "Martina", "Mateo", "Nicolás"]
var shorterIndices: [SetIndex<String>] = []
for (i, name) in zip(names.indices, names) {
    if name.characters.count <= 5 {
        shorterIndices.append(i)
    }
}

Now that the shorterIndices array holds the indices of the shorter names in the names set, you can use those indices to access elements in the set.

for i in shorterIndices {
    print(names[i])
}
// Prints "Sofia"
// Prints "Mateo"

Returns: A sequence of pairs enumerating the sequence.

Declaration

func enumerated() -> EnumeratedSequence<ArraySlice<Element>>

Declared In

Sequence
func filter(_:)

Returns an array containing, in order, the elements of the sequence that satisfy the given predicate.

In this example, filter is used to include only names shorter than five characters.

let cast = ["Vivien", "Marlon", "Kim", "Karl"]
let shortNames = cast.filter { $0.characters.count < 5 }
print(shortNames)
// Prints "["Kim", "Karl"]"

shouldInclude: A closure that takes an element of the sequence as its argument and returns a Boolean value indicating whether the element should be included in the returned array. Returns: An array of the elements that includeElement allowed.

Declaration

func filter(_ isIncluded: (Element) throws -> Bool) rethrows -> [Element]

Declared In

Sequence
func first(where:)

Returns the first element of the sequence that satisfies the given predicate or nil if no such element is found.

predicate: A closure that takes an element of the sequence as its argument and returns a Boolean value indicating whether the element is a match. Returns: The first match or nil if there was no match.

Declaration

func first(where predicate: (Element) throws -> Bool) rethrows -> Element?

Declared In

Sequence
func flatMap<ElementOfResult>(_: (Element) throws -> ElementOfResult?)

Returns an array containing the non-nil results of calling the given transformation with each element of this sequence.

Use this method to receive an array of nonoptional values when your transformation produces an optional value.

In this example, note the difference in the result of using map and flatMap with a transformation that returns an optional Int value.

let possibleNumbers = ["1", "2", "three", "///4///", "5"]

let mapped: [Int?] = numbers.map { str in Int(str) }
// [1, 2, nil, nil, 5]

let flatMapped: [Int] = numbers.flatMap { str in Int(str) }
// [1, 2, 5]

transform: A closure that accepts an element of this sequence as its argument and returns an optional value. Returns: An array of the non-nil results of calling transform with each element of the sequence.

Complexity: O(m + n), where m is the length of this sequence and n is the length of the result.

Declaration

func flatMap<ElementOfResult>(_ transform: (Element) throws -> ElementOfResult?) rethrows -> [ElementOfResult]

Declared In

Sequence
func flatMap<SegmentOfResult : Sequence>(_: (Element) throws -> SegmentOfResult)

Returns an array containing the concatenated results of calling the given transformation with each element of this sequence.

Use this method to receive a single-level collection when your transformation produces a sequence or collection for each element.

In this example, note the difference in the result of using map and flatMap with a transformation that returns an array.

let numbers = [1, 2, 3, 4]

let mapped = numbers.map { Array(count: $0, repeatedValue: $0) }
// [[1], [2, 2], [3, 3, 3], [4, 4, 4, 4]]

let flatMapped = numbers.flatMap { Array(count: $0, repeatedValue: $0) }
// [1, 2, 2, 3, 3, 3, 4, 4, 4, 4]

In fact, s.flatMap(transform) is equivalent to Array(s.map(transform).joined()).

transform: A closure that accepts an element of this sequence as its argument and returns a sequence or collection. Returns: The resulting flattened array.

Complexity: O(m + n), where m is the length of this sequence and n is the length of the result. See Also: joined(), map(_:)

Declaration

func flatMap<SegmentOfResult : Sequence>(_ transform: (Element) throws -> SegmentOfResult) rethrows -> [SegmentOfResult.Iterator.Element]

Declared In

Sequence
func forEach(_:)

Calls the given closure on each element in the sequence in the same order as a for-in loop.

The two loops in the following example produce the same output:

let numberWords = ["one", "two", "three"]
for word in numberWords {
    print(word)
}
// Prints "one"
// Prints "two"
// Prints "three"

numberWords.forEach { word in
    print(word)
}
// Same as above

Using the forEach method is distinct from a for-in loop in two important ways:

  1. You cannot use a break or continue statement to exit the current call of the body closure or skip subsequent calls.
  2. Using the return statement in the body closure will exit only from the current call to body, not from any outer scope, and won't skip subsequent calls.

body: A closure that takes an element of the sequence as a parameter.

Declaration

func forEach(_ body: (Element) throws -> Swift.Void) rethrows

Declared In

Sequence
func formIndex(_:offsetBy:)

Offsets the given index by the specified distance.

The value passed as n must not offset i beyond the endIndex or before the startIndex of this collection.

Parameters: i: A valid index of the collection. n: The distance to offset i. n must not be negative unless the collection conforms to the BidirectionalCollection protocol.

See Also: index(_:offsetBy:), formIndex(_:offsetBy:limitedBy:) Complexity: O(1) if the collection conforms to RandomAccessCollection; otherwise, O(n), where n is the absolute value of n.

Declaration

func formIndex(_ i: inout Int, offsetBy n: IntDistance)

Declared In

Indexable
func formIndex(_:offsetBy:limitedBy:)

Offsets the given index by the specified distance, or so that it equals the given limiting index.

The value passed as n must not offset i beyond the endIndex or before the startIndex of this collection, unless the index passed as limit prevents offsetting beyond those bounds.

Parameters: i: A valid index of the collection. n: The distance to offset i. n must not be negative unless the collection conforms to the BidirectionalCollection protocol. Returns: true if i has been offset by exactly n steps without going beyond limit; otherwise, false. When the return value is false, the value of i is equal to limit.

See Also: index(_:offsetBy:), formIndex(_:offsetBy:limitedBy:) Complexity: O(1) if the collection conforms to RandomAccessCollection; otherwise, O(n), where n is the absolute value of n.

Declaration

func formIndex(_ i: inout Int, offsetBy n: IntDistance, limitedBy limit: Int) -> Bool

Declared In

Indexable
func formIndex(after:)

Replaces the given index with its successor.

i: A valid index of the collection. i must be less than endIndex.

Declaration

func formIndex(after i: inout Int)

Declared In

ArraySlice, Indexable
func formIndex(before:)

Replaces the given index with its predecessor.

i: A valid index of the collection. i must be greater than startIndex.

Declaration

func formIndex(before i: inout Int)

Declared In

ArraySlice, BidirectionalIndexable
func index(_:offsetBy:)

Returns an index that is the specified distance from the given index.

The following example obtains an index advanced four positions from an array's starting index and then prints the element at that position.

let numbers = [10, 20, 30, 40, 50]
let i = numbers.index(numbers.startIndex, offsetBy: 4)
print(numbers[i])
// Prints "50"

Advancing an index beyond a collection's ending index or offsetting it before a collection's starting index may trigger a runtime error. The value passed as n must not result in such an operation.

Parameters: i: A valid index of the array. n: The distance to offset i. Returns: An index offset by n from the index i. If n is positive, this is the same value as the result of n calls to index(after:). If n is negative, this is the same value as the result of -n calls to index(before:).

Complexity: O(1)

Declaration

func index(_ i: Int, offsetBy n: Int) -> Int

Declared In

ArraySlice, BidirectionalIndexable, Indexable
func index(_:offsetBy:limitedBy:)

Returns an index that is the specified distance from the given index, unless that distance is beyond a given limiting index.

The following example obtains an index advanced four positions from an array's starting index and then prints the element at that position. The operation doesn't require going beyond the limiting numbers.endIndex value, so it succeeds.

let numbers = [10, 20, 30, 40, 50]
let i = numbers.index(numbers.startIndex,
                      offsetBy: 4,
                      limitedBy: numbers.endIndex)
print(numbers[i])
// Prints "50"

The next example attempts to retrieve an index ten positions from numbers.startIndex, but fails, because that distance is beyond the index passed as limit.

let j = numbers.index(numbers.startIndex,
                      offsetBy: 10,
                      limitedBy: numbers.endIndex)
print(j)
// Prints "nil"

Advancing an index beyond a collection's ending index or offsetting it before a collection's starting index may trigger a runtime error. The value passed as n must not result in such an operation.

Parameters: i: A valid index of the array. n: The distance to offset i. limit: A valid index of the collection to use as a limit. If n > 0, limit has no effect if it is less than i. Likewise, if n < 0, limit has no effect if it is greater than i. Returns: An index offset by n from the index i, unless that index would be beyond limit in the direction of movement. In that case, the method returns nil.

See Also: index(_:offsetBy:), formIndex(_:offsetBy:limitedBy:) Complexity: O(1)

Declaration

func index(_ i: Int, offsetBy n: Int, limitedBy limit: Int) -> Int?

Declared In

ArraySlice, RandomAccessIndexable, BidirectionalIndexable, Indexable
func index(after:)

Returns the position immediately after the given index.

i: A valid index of the collection. i must be less than endIndex. Returns: The index value immediately after i.

Declaration

func index(after i: Int) -> Int
func index(before:)

Returns the position immediately before the given index.

i: A valid index of the collection. i must be greater than startIndex. Returns: The index value immediately before i.

Declaration

func index(before i: Int) -> Int
func index(where:)

Returns the first index in which an element of the collection satisfies the given predicate.

You can use the predicate to find an element of a type that doesn't conform to the Equatable protocol or to find an element that matches particular criteria. Here's an example that finds a student name that begins with the letter "A":

let students = ["Kofi", "Abena", "Peter", "Kweku", "Akosua"]
if let i = students.index(where: { $0.hasPrefix("A") }) {
    print("\(students[i]) starts with 'A'!")
}
// Prints "Abena starts with 'A'!"

predicate: A closure that takes an element as its argument and returns a Boolean value that indicates whether the passed element represents a match. Returns: The index of the first element for which predicate returns true. If no elements in the collection satisfy the given predicate, returns nil.

See Also: index(of:)

Declaration

func index(where predicate: (Element) throws -> Bool) rethrows -> Int?

Declared In

Collection
mutating func insert(_:at:)

Inserts a new element at the specified position.

The new element is inserted before the element currently at the specified index. If you pass the array's endIndex property as the index parameter, the new element is appended to the array.

var numbers = [1, 2, 3, 4, 5]
numbers.insert(100, at: 3)
numbers.insert(200, at: numbers.endIndex)

print(numbers)
// Prints "[1, 2, 3, 100, 4, 5, 200]"

newElement: The new element to insert into the array.

i: The position at which to insert the new element. index must be a valid index of the array or equal to its endIndex property.

Complexity: O(n), where n is the length of the array.

Declaration

mutating func insert(_ newElement: Element, at i: Int)

Declared In

ArraySlice, RangeReplaceableCollection
mutating func insert(contentsOf:at:)

Inserts the elements of a sequence into the collection at the specified position.

The new elements are inserted before the element currently at the specified index. If you pass the collection's endIndex property as the i parameter, the new elements are appended to the collection.

Here's an example of inserting a range of integers into an array of the same type:

var numbers = [1, 2, 3, 4, 5]
numbers.insert(contentsOf: 100...103, at: 3)
print(numbers)
// Prints "[1, 2, 3, 100, 101, 102, 103, 4, 5]"

Calling this method may invalidate any existing indices for use with this collection.

newElements: The new elements to insert into the collection.

i: The position at which to insert the new elements. i must be a valid index of the collection.

Complexity: O(m), where m is the combined length of the collection and newElements. If i is equal to the collection's endIndex property, the complexity is O(n), where n is the length of newElements.

Declaration

mutating func insert<C : Collection where C.Iterator.Element == Iterator.Element>(contentsOf newElements: C, at i: Int)

Declared In

RangeReplaceableCollection
func lexicographicallyPrecedes(_:by:)

Returns a Boolean value indicating whether the sequence precedes another sequence in a lexicographical (dictionary) ordering, using the given predicate to compare elements.

The predicate must be a strict weak ordering over the elements. That is, for any elements a, b, and c, the following conditions must hold:

  • areInIncreasingOrder(a, a) is always false. (Irreflexivity)
  • If areInIncreasingOrder(a, b) and areInIncreasingOrder(b, c) are both true, then areInIncreasingOrder(a, c) is also true. (Transitive comparability)
  • Two elements are incomparable if neither is ordered before the other according to the predicate. If a and b are incomparable, and b and c are incomparable, then a and c are also incomparable. (Transitive incomparability)

Parameters: other: A sequence to compare to this sequence. areInIncreasingOrder: A predicate that returns true if its first argument should be ordered before its second argument; otherwise, false. Returns: true if this sequence precedes other in a dictionary ordering as ordered by areInIncreasingOrder; otherwise, false.

Note: This method implements the mathematical notion of lexicographical ordering, which has no connection to Unicode. If you are sorting strings to present to the end user, use String APIs that perform localized comparison instead. See Also: lexicographicallyPrecedes(_:)

Declaration

func lexicographicallyPrecedes<OtherSequence where OtherSequence : Sequence, OtherSequence.Iterator.Element == Iterator.Element>(_ other: OtherSequence, by areInIncreasingOrder: (Element, Element) throws -> Bool) rethrows -> Bool

Declared In

Sequence
func map(_:)

Returns an array containing the results of mapping the given closure over the sequence's elements.

In this example, map is used first to convert the names in the array to lowercase strings and then to count their characters.

let cast = ["Vivien", "Marlon", "Kim", "Karl"]
let lowercaseNames = cast.map { $0.lowercaseString }
// 'lowercaseNames' == ["vivien", "marlon", "kim", "karl"]
let letterCounts = cast.map { $0.characters.count }
// 'letterCounts' == [6, 6, 3, 4]

transform: A mapping closure. transform accepts an element of this sequence as its parameter and returns a transformed value of the same or of a different type. Returns: An array containing the transformed elements of this sequence.

Declaration

func map<T>(_ transform: (Element) throws -> T) rethrows -> [T]

Declared In

Collection, Sequence
@warn_unqualified_access func max(by:)

Returns the maximum element in the sequence, using the given predicate as the comparison between elements.

The predicate must be a strict weak ordering over the elements. That is, for any elements a, b, and c, the following conditions must hold:

  • areInIncreasingOrder(a, a) is always false. (Irreflexivity)
  • If areInIncreasingOrder(a, b) and areInIncreasingOrder(b, c) are both true, then areInIncreasingOrder(a, c) is also true. (Transitive comparability)
  • Two elements are incomparable if neither is ordered before the other according to the predicate. If a and b are incomparable, and b and c are incomparable, then a and c are also incomparable. (Transitive incomparability)

This example shows how to use the max(by:) method on a dictionary to find the key-value pair with the highest value.

let hues = ["Heliotrope": 296, "Coral": 16, "Aquamarine": 156]
let greatestHue = hues.max { a, b in a.value < b.value }
print(greatestHue)
// Prints "Optional(("Heliotrope", 296))"

areInIncreasingOrder: A predicate that returns true if its first argument should be ordered before its second argument; otherwise, false. Returns: The sequence's maximum element if the sequence is not empty; otherwise, nil.

See Also: max()

Declaration

@warn_unqualified_access func max(by areInIncreasingOrder: (Element, Element) throws -> Bool) rethrows -> Element?

Declared In

Sequence
@warn_unqualified_access func min(by:)

Returns the minimum element in the sequence, using the given predicate as the comparison between elements.

The predicate must be a strict weak ordering over the elements. That is, for any elements a, b, and c, the following conditions must hold:

  • areInIncreasingOrder(a, a) is always false. (Irreflexivity)
  • If areInIncreasingOrder(a, b) and areInIncreasingOrder(b, c) are both true, then areInIncreasingOrder(a, c) is also true. (Transitive comparability)
  • Two elements are incomparable if neither is ordered before the other according to the predicate. If a and b are incomparable, and b and c are incomparable, then a and c are also incomparable. (Transitive incomparability)

This example shows how to use the min(by:) method on a dictionary to find the key-value pair with the lowest value.

let hues = ["Heliotrope": 296, "Coral": 16, "Aquamarine": 156]
let leastHue = hues.min { a, b in a.value < b.value }
print(leastHue)
// Prints "Optional(("Coral", 16))"

areInIncreasingOrder: A predicate that returns true if its first argument should be ordered before its second argument; otherwise, false. Returns: The sequence's minimum element, according to areInIncreasingOrder. If the sequence has no elements, returns nil.

See Also: min()

Declaration

@warn_unqualified_access func min(by areInIncreasingOrder: (Element, Element) throws -> Bool) rethrows -> Element?

Declared In

Sequence
mutating func partition(by:)

Reorders the elements of the collection such that all the elements that match the given predicate are after all the elements that do not match the predicate.

After partitioning a collection, there is a pivot index p where no element before p satisfies the belongsInSecondPartition predicate and every element at or after p satisfies belongsInSecondPartition.

In the following example, an array of numbers is partitioned by a predicate that matches elements greater than 30.

var numbers = [30, 40, 20, 30, 30, 60, 10]
let p = numbers.partition(by: { $0 > 30 })
// p == 5
// numbers == [30, 10, 20, 30, 30, 60, 40]

The numbers array is now arranged in two partitions. The first partition, numbers.prefix(upTo: p), is made up of the elements that are not greater than 30. The second partition, numbers.suffix(from: p), is made up of the elements that are greater than 30.

let first = numbers.prefix(upTo: p)
// first == [30, 10, 20, 30, 30]
let second = numbers.suffix(from: p)
// second == [60, 40]

belongsInSecondPartition: A predicate used to partition the collection. All elements satisfying this predicate are ordered after all elements not satisfying it. Returns: The index of the first element in the reordered collection that matches belongsInSecondPartition. If no elements in the collection match belongsInSecondPartition, the returned index is equal to the collection's endIndex.

Complexity: O(n)

Declaration

mutating func partition(by belongsInSecondPartition: (Element) throws -> Bool) rethrows -> Int

Declared In

MutableCollection
mutating func popFirst()

Removes and returns the first element of the collection.

Returns: The first element of the collection if the collection is not empty; otherwise, nil.

Complexity: O(1)

Declaration

mutating func popFirst() -> Element?

Declared In

Collection
mutating func popLast()

Removes and returns the last element of the collection.

Returns: The last element of the collection if the collection has one or more elements; otherwise, nil.

Complexity: O(1). See Also: removeLast()

Declaration

mutating func popLast() -> Element?

Declared In

BidirectionalCollection
func prefix(_:)

Returns a subsequence, up to the specified maximum length, containing the initial elements of the collection.

If the maximum length exceeds the number of elements in the collection, the result contains all the elements in the collection.

let numbers = [1, 2, 3, 4, 5]
print(numbers.prefix(2))
// Prints "[1, 2]"
print(numbers.prefix(10))
// Prints "[1, 2, 3, 4, 5]"

maxLength: The maximum number of elements to return. maxLength must be greater than or equal to zero. Returns: A subsequence starting at the beginning of this collection with at most maxLength elements.

Declaration

func prefix(_ maxLength: Int) -> ArraySlice<Element>

Declared In

Collection, Sequence
func prefix(through:)

Returns a subsequence from the start of the collection through the specified position.

The resulting subsequence includes the element at the position end. The following example searches for the index of the number 40 in an array of integers, and then prints the prefix of the array up to, and including, that index:

let numbers = [10, 20, 30, 40, 50, 60]
if let i = numbers.index(of: 40) {
    print(numbers.prefix(through: i))
}
// Prints "[10, 20, 30, 40]"

end: The index of the last element to include in the resulting subsequence. end must be a valid index of the collection that is not equal to the endIndex property. Returns: A subsequence up to, and including, the end position.

Complexity: O(1) See Also: prefix(upTo:)

Declaration

func prefix(through position: Int) -> ArraySlice<Element>

Declared In

Collection
func prefix(upTo:)

Returns a subsequence from the start of the collection up to, but not including, the specified position.

The resulting subsequence does not include the element at the position end. The following example searches for the index of the number 40 in an array of integers, and then prints the prefix of the array up to, but not including, that index:

let numbers = [10, 20, 30, 40, 50, 60]
if let i = numbers.index(of: 40) {
    print(numbers.prefix(upTo: i))
}
// Prints "[10, 20, 30]"

Passing the collection's starting index as the end parameter results in an empty subsequence.

print(numbers.prefix(upTo: numbers.startIndex))
// Prints "[]"

end: The "past the end" index of the resulting subsequence. end must be a valid index of the collection. Returns: A subsequence up to, but not including, the end position.

Complexity: O(1) See Also: prefix(through:)

Declaration

func prefix(upTo end: Int) -> ArraySlice<Element>

Declared In

Collection
func reduce(_:_:)

Returns the result of calling the given combining closure with each element of this sequence and an accumulating value.

The nextPartialResult closure is called sequentially with an accumulating value initialized to initialResult and each element of the sequence. This example shows how to find the sum of an array of numbers.

let numbers = [1, 2, 3, 4]
let addTwo: (Int, Int) -> Int = { x, y in x + y }
let numberSum = numbers.reduce(0, addTwo)
// 'numberSum' == 10

When numbers.reduce(_:_:) is called, the following steps occur:

  1. The nextPartialResult closure is called with the initial result and the first element of numbers, returning the sum: 1.
  2. The closure is called again repeatedly with the previous call's return value and each element of the sequence.
  3. When the sequence is exhausted, the last value returned from the closure is returned to the caller.

Parameters: initialResult: the initial accumulating value. nextPartialResult: A closure that combines an accumulating value and an element of the sequence into a new accumulating value, to be used in the next call of the nextPartialResult closure or returned to the caller. Returns: The final accumulated value.

Declaration

func reduce<Result>(_ initialResult: Result, _ nextPartialResult: (Result, Element) throws -> Result) rethrows -> Result

Declared In

Sequence
mutating func remove(at:)

Removes and returns the element at the specified position.

All the elements following the specified position are moved up to close the gap.

var measurements: [Double] = [1.1, 1.5, 2.9, 1.2, 1.5, 1.3, 1.2]
let removed = measurements.remove(at: 2)
print(measurements)
// Prints "[1.1, 1.5, 1.2, 1.5, 1.3, 1.2]"

index: The position of the element to remove. index must be a valid index of the array. Returns: The element at the specified index.

Complexity: O(n), where n is the length of the array.

Declaration

mutating func remove(at index: Int) -> Element

Declared In

ArraySlice, RangeReplaceableCollection
mutating func removeAll(keepingCapacity:)

Removes all elements from the array.

keepCapacity: Pass true to keep the existing capacity of the array after removing its elements. The default value is false.

Complexity: O(n), where n is the length of the array.

Declaration

mutating func removeAll(keepingCapacity keepCapacity: Bool = default)

Declared In

ArraySlice, RangeReplaceableCollection
mutating func removeFirst()

Removes and returns the first element of the collection.

The collection must not be empty.

var bugs = ["Aphid", "Bumblebee", "Cicada", "Damselfly", "Earwig"]
bugs.removeFirst()
print(bugs)
// Prints "["Bumblebee", "Cicada", "Damselfly", "Earwig"]"

Calling this method may invalidate any existing indices for use with this collection.

Returns: The removed element.

Complexity: O(n), where n is the length of the collection.

Declaration

mutating func removeFirst() -> Element

Declared In

RangeReplaceableCollection, Collection
mutating func removeFirst(_:)

Removes the specified number of elements from the beginning of the collection.

var bugs = ["Aphid", "Bumblebee", "Cicada", "Damselfly", "Earwig"]
bugs.removeFirst(3)
print(bugs)
// Prints "["Damselfly", "Earwig"]"

Calling this method may invalidate any existing indices for use with this collection.

n: The number of elements to remove from the collection. n must be greater than or equal to zero and must not exceed the number of elements in the collection.

Complexity: O(n), where n is the length of the collection.

Declaration

mutating func removeFirst(_ n: Int)

Declared In

RangeReplaceableCollection, Collection
mutating func removeLast()

Removes and returns the last element of the collection.

The collection must not be empty.

Calling this method may invalidate all saved indices of this collection. Don't rely on a previously stored index value after altering a collection with any operation that can change its length.

Returns: The last element of the collection.

Complexity: O(1)

Declaration

mutating func removeLast() -> Element

Declared In

RangeReplaceableCollection, BidirectionalCollection
mutating func removeLast(_:)

Removes the specified number of elements from the end of the collection.

Attempting to remove more elements than exist in the collection triggers a runtime error.

Calling this method may invalidate all saved indices of this collection. Don't rely on a previously stored index value after altering a collection with any operation that can change its length.

n: The number of elements to remove from the collection. n must be greater than or equal to zero and must not exceed the number of elements in the collection.

Complexity: O(n), where n is the specified number of elements.

Declaration

mutating func removeLast(_ n: Int)

Declared In

RangeReplaceableCollection, BidirectionalCollection
mutating func removeSubrange(_: ClosedRange<Int>)

Removes the elements in the specified subrange from the collection.

All the elements following the specified position are moved to close the gap. This example removes two elements from the middle of an array of measurements.

var measurements = [1.2, 1.5, 2.9, 1.2, 1.5]
measurements.removeSubrange(1..<3)
print(measurements)
// Prints "[1.2, 1.5]"

Calling this method may invalidate any existing indices for use with this collection.

bounds: The range of the collection to be removed. The bounds of the range must be valid indices of the collection.

Complexity: O(n), where n is the length of the collection.

Declaration

mutating func removeSubrange(_ bounds: ClosedRange<Int>)

Declared In

RangeReplaceableCollection
mutating func removeSubrange(_: Range<Int>)

Removes the elements in the specified subrange from the collection.

All the elements following the specified position are moved to close the gap. This example removes two elements from the middle of an array of measurements.

var measurements = [1.2, 1.5, 2.9, 1.2, 1.5]
measurements.removeSubrange(1..<3)
print(measurements)
// Prints "[1.2, 1.5]"

Calling this method may invalidate any existing indices for use with this collection.

bounds: The range of the collection to be removed. The bounds of the range must be valid indices of the collection.

Complexity: O(n), where n is the length of the collection.

Declaration

mutating func removeSubrange(_ bounds: Range<Int>)

Declared In

RangeReplaceableCollection
mutating func replaceSubrange(_:with:)

Replaces a range of elements with the elements in the specified collection.

This method has the effect of removing the specified range of elements from the array and inserting the new elements at the same location. The number of new elements need not match the number of elements being removed.

In this example, three elements in the middle of an array of integers are replaced by the five elements of a Repeated<Int> instance.

 var nums = [10, 20, 30, 40, 50]
 nums.replaceSubrange(1...3, with: repeatElement(1, count: 5))
 print(nums)
 // Prints "[10, 1, 1, 1, 1, 1, 50]"

If you pass a zero-length range as the subrange parameter, this method inserts the elements of newElements at subrange.startIndex. Calling the insert(contentsOf:at:) method instead is preferred.

Likewise, if you pass a zero-length collection as the newElements parameter, this method removes the elements in the given subrange without replacement. Calling the removeSubrange(_:) method instead is preferred.

Parameters: subrange: The subrange of the array to replace. The start and end of a subrange must be valid indices of the array. newElements: The new elements to add to the array.

Complexity: O(subrange.count) if you are replacing a suffix of the array with an empty collection; otherwise, O(n), where n is the length of the array.

Declaration

mutating func replaceSubrange<C where C : Collection, C.Iterator.Element == _Buffer.Element>(_ subrange: Range<Int>, with newElements: C)

Declared In

ArraySlice, RangeReplaceableCollection
mutating func reserveCapacity(_:)

Reserves enough space to store the specified number of elements.

If you are adding a known number of elements to an array, use this method to avoid multiple reallocations. This method ensures that the array has unique, mutable, contiguous storage, with space allocated for at least the requested number of elements.

For performance reasons, the newly allocated storage may be larger than the requested capacity. Use the array's capacity property to determine the size of the new storage.

minimumCapacity: The requested number of elements to store.

Complexity: O(n), where n is the count of the array.

Declaration

mutating func reserveCapacity(_ minimumCapacity: Int)

Declared In

ArraySlice, RangeReplaceableCollection
mutating func reverse()

Reverses the elements of the collection in place.

The following example reverses the elements of an array of characters:

var characters: [Character] = ["C", "a", "f", "é"]
characters.reverse()
print(cafe.characters)
// Prints "["é", "f", "a", "C"]

Complexity: O(n), where n is the number of elements in the collection.

Declaration

mutating func reverse()

Declared In

MutableCollection
func reversed()

Returns a view presenting the elements of the collection in reverse order.

You can reverse a collection without allocating new space for its elements by calling this reversed() method. A ReversedRandomAccessCollection instance wraps an underlying collection and provides access to its elements in reverse order. This example prints the elements of an array in reverse order:

let numbers = [3, 5, 7]
for number in numbers.reversed() {
    print(number)
}
// Prints "7"
// Prints "5"
// Prints "3"

If you need a reversed collection of the same type, you may be able to use the collection's sequence-based or collection-based initializer. For example, to get the reversed version of an array, initialize a new Array instance from the result of this reversed() method.

let reversedNumbers = Array(numbers.reversed())
print(reversedNumbers)
// Prints "[7, 5, 3]"

Complexity: O(1)

Declaration

func reversed() -> ReversedRandomAccessCollection<ArraySlice<Element>>

Declared In

RandomAccessCollection, BidirectionalCollection, Sequence
mutating func sort(by:)

Sorts the collection in place, using the given predicate as the comparison between elements.

When you want to sort a collection of elements that doesn't conform to the Comparable protocol, pass a closure to this method that returns true when the first element passed should be ordered before the second.

The predicate must be a strict weak ordering over the elements. That is, for any elements a, b, and c, the following conditions must hold:

  • areInIncreasingOrder(a, a) is always false. (Irreflexivity)
  • If areInIncreasingOrder(a, b) and areInIncreasingOrder(b, c) are both true, then areInIncreasingOrder(a, c) is also true. (Transitive comparability)
  • Two elements are incomparable if neither is ordered before the other according to the predicate. If a and b are incomparable, and b and c are incomparable, then a and c are also incomparable. (Transitive incomparability)

The sorting algorithm is not stable. A nonstable sort may change the relative order of elements for which areInIncreasingOrder does not establish an order.

In the following example, the closure provides an ordering for an array of a custom enumeration that describes an HTTP response. The predicate orders errors before successes and sorts the error responses by their error code.

enum HTTPResponse {
    case ok
    case error(Int)
}

var responses: [HTTPResponse] = [.error(500), .ok, .ok, .error(404), .error(403)]
responses.sort {
    switch ($0, $1) {
    // Order errors by code
    case let (.error(aCode), .error(bCode)):
        return aCode < bCode

    // All successes are equivalent, so none is before any other
    case (.ok, .ok): return false

    // Order errors before successes
    case (.error, .ok): return true
    case (.ok, .error): return false
    }
}
print(responses)
// Prints "[.error(403), .error(404), .error(500), .ok, .ok]"

Alternatively, use this method to sort a collection of elements that do conform to Comparable when you want the sort to be descending instead of ascending. Pass the greater-than operator (>) operator as the predicate.

var students = ["Kofi", "Abena", "Peter", "Kweku", "Akosua"]
students.sort(by: >)
print(students)
// Prints "["Peter", "Kweku", "Kofi", "Akosua", "Abena"]"

areInIncreasingOrder: A predicate that returns true if its first argument should be ordered before its second argument; otherwise, false.

Declaration

mutating func sort(by areInIncreasingOrder: (Element, Element) -> Bool)

Declared In

MutableCollection
func sorted(by:)

Returns the elements of the collection, sorted using the given predicate as the comparison between elements.

When you want to sort a collection of elements that don't conform to the Comparable protocol, pass a predicate to this method that returns true when the first element passed should be ordered before the second. The elements of the resulting array are ordered according to the given predicate.

The predicate must be a strict weak ordering over the elements. That is, for any elements a, b, and c, the following conditions must hold:

  • areInIncreasingOrder(a, a) is always false. (Irreflexivity)
  • If areInIncreasingOrder(a, b) and areInIncreasingOrder(b, c) are both true, then areInIncreasingOrder(a, c) is also true. (Transitive comparability)
  • Two elements are incomparable if neither is ordered before the other according to the predicate. If a and b are incomparable, and b and c are incomparable, then a and c are also incomparable. (Transitive incomparability)

The sorting algorithm is not stable. A nonstable sort may change the relative order of elements for which areInIncreasingOrder does not establish an order.

In the following example, the predicate provides an ordering for an array of a custom HTTPResponse type. The predicate orders errors before successes and sorts the error responses by their error code.

enum HTTPResponse {
    case ok
    case error(Int)
}

let responses: [HTTPResponse] = [.error(500), .ok, .ok, .error(404), .error(403)]
let sortedResponses = responses.sorted {
    switch ($0, $1) {
    // Order errors by code
    case let (.error(aCode), .error(bCode)):
        return aCode < bCode

    // All successes are equivalent, so none is before any other
    case (.ok, .ok): return false

    // Order errors before successes
    case (.error, .ok): return true
    case (.ok, .error): return false
    }
}
print(sortedResponses)
// Prints "[.error(403), .error(404), .error(500), .ok, .ok]"

You also use this method to sort elements that conform to the Comparable protocol in descending order. To sort your collection in descending order, pass the greater-than operator (>) as the areInIncreasingOrder parameter.

let students: Set = ["Kofi", "Abena", "Peter", "Kweku", "Akosua"]
let descendingStudents = students.sorted(by: >)
print(descendingStudents)
// Prints "["Peter", "Kweku", "Kofi", "Akosua", "Abena"]"

Calling the related sorted() method is equivalent to calling this method and passing the less-than operator (<) as the predicate.

print(students.sorted())
// Prints "["Abena", "Akosua", "Kofi", "Kweku", "Peter"]"
print(students.sorted(by: <))
// Prints "["Abena", "Akosua", "Kofi", "Kweku", "Peter"]"

areInIncreasingOrder: A predicate that returns true if its first argument should be ordered before its second argument; otherwise, false. Returns: A sorted array of the collection's elements.

See Also: sorted() MutatingVariant: sort

Declaration

func sorted(by areInIncreasingOrder: (Element, Element) -> Bool) -> [Element]

Declared In

MutableCollection, Sequence
func split(_:omittingEmptySubsequences:whereSeparator:)

Returns the longest possible subsequences of the collection, in order, that don't contain elements satisfying the given predicate.

The resulting array consists of at most maxSplits + 1 subsequences. Elements that are used to split the sequence are not returned as part of any subsequence.

The following examples show the effects of the maxSplits and omittingEmptySubsequences parameters when splitting a string using a closure that matches spaces. The first use of split returns each word that was originally separated by one or more spaces.

let line = "BLANCHE:   I don't want realism. I want magic!"
print(line.characters.split(whereSeparator: { $0 == " " })
                     .map(String.init))
// Prints "["BLANCHE:", "I", "don\'t", "want", "realism.", "I", "want", "magic!"]"

The second example passes 1 for the maxSplits parameter, so the original string is split just once, into two new strings.

print(
    line.characters.split(
        maxSplits: 1, whereSeparator: { $0 == " " }
        ).map(String.init))
// Prints "["BLANCHE:", "  I don\'t want realism. I want magic!"]"

The final example passes false for the omittingEmptySubsequences parameter, so the returned array contains empty strings where spaces were repeated.

print(line.characters.split(omittingEmptySubsequences: false, whereSeparator: { $0 == " " })
                      .map(String.init))
// Prints "["BLANCHE:", "", "", "I", "don\'t", "want", "realism.", "I", "want", "magic!"]"

Parameters: maxSplits: The maximum number of times to split the collection, or one less than the number of subsequences to return. If maxSplits + 1 subsequences are returned, the last one is a suffix of the original collection containing the remaining elements. maxSplits must be greater than or equal to zero. The default value is Int.max. omittingEmptySubsequences: If false, an empty subsequence is returned in the result for each pair of consecutive elements satisfying the isSeparator predicate and for each element at the start or end of the collection satisfying the isSeparator predicate. The default value is true. isSeparator: A closure that takes an element as an argument and returns a Boolean value indicating whether the collection should be split at that element. Returns: An array of subsequences, split from this collection's elements.

Declaration

func split(maxSplits: Int = default, omittingEmptySubsequences: Bool = default, whereSeparator isSeparator: (Element) throws -> Bool) rethrows -> [ArraySlice<Element>]

Declared In

Collection, Sequence
func starts(with:by:)

Returns a Boolean value indicating whether the initial elements of the sequence are equivalent to the elements in another sequence, using the given predicate as the equivalence test.

The predicate must be a equivalence relation over the elements. That is, for any elements a, b, and c, the following conditions must hold:

  • areEquivalent(a, a) is always true. (Reflexivity)
  • areEquivalent(a, b) implies areEquivalent(b, a). (Symmetry)
  • If areEquivalent(a, b) and areEquivalent(b, c) are both true, then areEquivalent(a, c) is also true. (Transitivity)

Parameters: possiblePrefix: A sequence to compare to this sequence. areEquivalent: A predicate that returns true if its two arguments are equivalent; otherwise, false. Returns: true if the initial elements of the sequence are equivalent to the elements of possiblePrefix; otherwise, false. If possiblePrefix has no elements, the return value is true.

See Also: starts(with:)

Declaration

func starts<PossiblePrefix where PossiblePrefix : Sequence, PossiblePrefix.Iterator.Element == Iterator.Element>(with possiblePrefix: PossiblePrefix, by areEquivalent: (Element, Element) throws -> Bool) rethrows -> Bool

Declared In

Sequence
func suffix(_:)

Returns a subsequence, up to the given maximum length, containing the final elements of the collection.

If the maximum length exceeds the number of elements in the collection, the result contains the entire collection.

let numbers = [1, 2, 3, 4, 5]
print(numbers.suffix(2))
// Prints "[4, 5]"
print(numbers.suffix(10))
// Prints "[1, 2, 3, 4, 5]"

maxLength: The maximum number of elements to return. maxLength must be greater than or equal to zero. Returns: A subsequence terminating at the end of the collection with at most maxLength elements.

Complexity: O(n), where n is equal to maxLength.

Declaration

func suffix(_ maxLength: Int) -> ArraySlice<Element>

Declared In

BidirectionalCollection, Collection, Sequence
func suffix(from:)

Returns a subsequence from the specified position to the end of the collection.

The following example searches for the index of the number 40 in an array of integers, and then prints the suffix of the array starting at that index:

let numbers = [10, 20, 30, 40, 50, 60]
if let i = numbers.index(of: 40) {
    print(numbers.suffix(from: i))
}
// Prints "[40, 50, 60]"

Passing the collection's endIndex as the start parameter results in an empty subsequence.

print(numbers.suffix(from: numbers.endIndex))
// Prints "[]"

start: The index at which to start the resulting subsequence. start must be a valid index of the collection. Returns: A subsequence starting at the start position.

Complexity: O(1)

Declaration

func suffix(from start: Int) -> ArraySlice<Element>

Declared In

Collection
func withUnsafeBufferPointer(_:)

Calls a closure with a pointer to the array's contiguous storage.

Often, the optimizer can eliminate bounds checks within an array algorithm, but when that fails, invoking the same algorithm on the buffer pointer passed into your closure lets you trade safety for speed.

The following example shows how you can iterate over the contents of the buffer pointer:

let numbers = [1, 2, 3, 4, 5]
let sum = numbers.withUnsafeBufferPointer { buffer -> Int in
    var result = 0
    for i in stride(from: buffer.startIndex, to: buffer.endIndex, by: 2) {
        result += buffer[i]
    }
    return result
}
// 'sum' == 9

body: A closure with an UnsafeBufferPointer parameter that points to the contiguous storage for the array. If body has a return value, it is used as the return value for the withUnsafeBufferPointer(_:) method. The pointer argument is valid only for the duration of the closure's execution. Returns: The return value of the body closure parameter, if any.

See Also: withUnsafeMutableBufferPointer, UnsafeBufferPointer

Declaration

func withUnsafeBufferPointer<R>(_ body: (UnsafeBufferPointer<Element>) throws -> R) rethrows -> R
func withUnsafeBytes(_:)

Calls a closure with a view of the array's underlying bytes of memory as a Collection of UInt8.

If no such storage exists, it is first created.

Precondition: Pointee is a trivial type.

The following example shows how you copy the contents of an array into a buffer of UInt8:

let numbers = [1, 2, 3] var byteBuffer = UInt8 numbers.withUnsafeBytes { byteBuffer += $0 }

body: A closure with an UnsafeRawBufferPointer parameter that points to the contiguous storage for the array. If body has a return value, it is used as the return value for the withUnsafeBytes(_:) method. The argument is valid only for the duration of the closure's execution. Returns: The return value of the body closure parameter, if any.

See Also: withUnsafeBytes, UnsafeRawBufferPointer

Declaration

func withUnsafeBytes<R>(_ body: (UnsafeRawBufferPointer) throws -> R) rethrows -> R
mutating func withUnsafeMutableBufferPointer(_:)

Calls the given closure with a pointer to the array's mutable contiguous storage.

Often, the optimizer can eliminate bounds checks within an array algorithm, but when that fails, invoking the same algorithm on the buffer pointer passed into your closure lets you trade safety for speed.

The following example shows modifying the contents of the UnsafeMutableBufferPointer argument to body alters the contents of the array:

var numbers = [1, 2, 3, 4, 5]
numbers.withUnsafeMutableBufferPointer { buffer in
    for i in stride(from: buffer.startIndex, to: buffer.endIndex - 1, by: 2) {
        swap(&buffer[i], &buffer[i + 1])
    }
}
print(numbers)
// Prints "[2, 1, 4, 3, 5]"

Warning: Do not rely on anything about self (the array that is the target of this method) during the execution of the body closure: It may not appear to have its correct value. Instead, use only the UnsafeMutableBufferPointer argument to body.

body: A closure with an UnsafeMutableBufferPointer parameter that points to the contiguous storage for the array. If body has a return value, it is used as the return value for the withUnsafeMutableBufferPointer(_:) method. The pointer argument is valid only for the duration of the closure's execution. Returns: The return value of the body closure parameter, if any.

See Also: withUnsafeBufferPointer, UnsafeMutableBufferPointer

Declaration

mutating func withUnsafeMutableBufferPointer<R>(_ body: (inout UnsafeMutableBufferPointer<Element>) throws -> R) rethrows -> R
mutating func withUnsafeMutableBytes(_:)

Calls a closure with a view of the array's underlying bytes of memory as a Collection of UInt8.

If no such storage exists, it is first created.

Precondition: Pointee is a trivial type.

The following example shows how you copy bytes into an array:

var numbers = Int32 var byteValues: [UInt8] = [0x01, 0x00, 0x00, 0x00, 0x02, 0x00, 0x00, 0x00] numbers.withUnsafeMutableBytes { destBytes in byteValues.withUnsafeBytes { srcBytes in destBytes.copyBytes(from: srcBytes) } }

body: A closure with an UnsafeRawBufferPointer parameter that points to the contiguous storage for the array. If body has a return value, it is used as the return value for the withUnsafeMutableBytes(_:) method. The argument is valid only for the duration of the closure's execution. Returns: The return value of the body closure parameter, if any.

See Also: withUnsafeBytes, UnsafeMutableRawBufferPointer

Declaration

mutating func withUnsafeMutableBytes<R>(_ body: (UnsafeMutableRawBufferPointer) throws -> R) rethrows -> R

Conditionally Inherited Items

The initializers, methods, and properties listed below may be available on this type under certain conditions (such as methods that are available on Array when its elements are Equatable) or may not ever be available if that determination is beyond SwiftDoc.org's capabilities. Please open an issue on GitHub if you see something out of place!

Where Index : Strideable, Index.Stride : SignedInteger

subscript(_: CountableClosedRange<Int>)

Accesses a contiguous subrange of the collection's elements.

The accessed slice uses the same indices for the same elements as the original collection. Always use the slice's startIndex property instead of assuming that its indices start at a particular value.

This example demonstrates getting a slice of an array of strings, finding the index of one of the strings in the slice, and then using that index in the original array.

let streets = ["Adams", "Bryant", "Channing", "Douglas", "Evarts"]
let streetsSlice = streets[2 ..< streets.endIndex]
print(streetsSlice)
// Prints "["Channing", "Douglas", "Evarts"]"

let index = streetsSlice.index(of: "Evarts")    // 4
streets[index!] = "Eustace"
print(streets[index!])
// Prints "Eustace"

bounds: A range of the collection's indices. The bounds of the range must be valid indices of the collection.

Declaration

subscript(bounds: CountableClosedRange<Int>) -> ArraySlice<Element>

Declared In

MutableIndexable, Indexable
subscript(_: CountableRange<Int>)

Accesses a contiguous subrange of the collection's elements.

The accessed slice uses the same indices for the same elements as the original collection. Always use the slice's startIndex property instead of assuming that its indices start at a particular value.

This example demonstrates getting a slice of an array of strings, finding the index of one of the strings in the slice, and then using that index in the original array.

let streets = ["Adams", "Bryant", "Channing", "Douglas", "Evarts"]
let streetsSlice = streets[2 ..< streets.endIndex]
print(streetsSlice)
// Prints "["Channing", "Douglas", "Evarts"]"

let index = streetsSlice.index(of: "Evarts")    // 4
streets[index!] = "Eustace"
print(streets[index!])
// Prints "Eustace"

bounds: A range of the collection's indices. The bounds of the range must be valid indices of the collection.

Declaration

subscript(bounds: CountableRange<Int>) -> ArraySlice<Element>

Declared In

MutableIndexable, Indexable
mutating func removeSubrange(_: CountableClosedRange<Int>)

Removes the elements in the specified subrange from the collection.

All the elements following the specified position are moved to close the gap. This example removes two elements from the middle of an array of measurements.

var measurements = [1.2, 1.5, 2.9, 1.2, 1.5]
measurements.removeSubrange(1..<3)
print(measurements)
// Prints "[1.2, 1.5]"

Calling this method may invalidate any existing indices for use with this collection.

bounds: The range of the collection to be removed. The bounds of the range must be valid indices of the collection.

Complexity: O(n), where n is the length of the collection.

Declaration

mutating func removeSubrange(_ bounds: CountableClosedRange<Int>)

Declared In

RangeReplaceableCollection
mutating func removeSubrange(_: CountableRange<Int>)

Removes the elements in the specified subrange from the collection.

All the elements following the specified position are moved to close the gap. This example removes two elements from the middle of an array of measurements.

var measurements = [1.2, 1.5, 2.9, 1.2, 1.5]
measurements.removeSubrange(1..<3)
print(measurements)
// Prints "[1.2, 1.5]"

Calling this method may invalidate any existing indices for use with this collection.

bounds: The range of the collection to be removed. The bounds of the range must be valid indices of the collection.

Complexity: O(n), where n is the length of the collection.

Declaration

mutating func removeSubrange(_ bounds: CountableRange<Int>)

Declared In

RangeReplaceableCollection
mutating func replaceSubrange<C where C : Collection, C.Iterator.Element == Iterator.Element>(_: CountableClosedRange<Int>, with: C)

Replaces the specified subrange of elements with the given collection.

This method has the effect of removing the specified range of elements from the collection and inserting the new elements at the same location. The number of new elements need not match the number of elements being removed.

In this example, three elements in the middle of an array of integers are replaced by the five elements of a Repeated<Int> instance.

 var nums = [10, 20, 30, 40, 50]
 nums.replaceSubrange(1...3, with: repeatElement(1, count: 5))
 print(nums)
 // Prints "[10, 1, 1, 1, 1, 1, 50]"

If you pass a zero-length range as the subrange parameter, this method inserts the elements of newElements at subrange.startIndex. Calling the insert(contentsOf:at:) method instead is preferred.

Likewise, if you pass a zero-length collection as the newElements parameter, this method removes the elements in the given subrange without replacement. Calling the removeSubrange(_:) method instead is preferred.

Calling this method may invalidate any existing indices for use with this collection.

Parameters: subrange: The subrange of the collection to replace. The bounds of the range must be valid indices of the collection. newElements: The new elements to add to the collection.

Complexity: O(m), where m is the combined length of the collection and newElements. If the call to replaceSubrange simply appends the contents of newElements to the collection, the complexity is O(n), where n is the length of newElements.

Declaration

mutating func replaceSubrange<C where C : Collection, C.Iterator.Element == Iterator.Element>(_ subrange: CountableClosedRange<Int>, with newElements: C)

Declared In

RangeReplaceableCollection
mutating func replaceSubrange<C where C : Collection, C.Iterator.Element == Iterator.Element>(_: CountableRange<Int>, with: C)

Replaces the specified subrange of elements with the given collection.

This method has the effect of removing the specified range of elements from the collection and inserting the new elements at the same location. The number of new elements need not match the number of elements being removed.

In this example, three elements in the middle of an array of integers are replaced by the five elements of a Repeated<Int> instance.

 var nums = [10, 20, 30, 40, 50]
 nums.replaceSubrange(1...3, with: repeatElement(1, count: 5))
 print(nums)
 // Prints "[10, 1, 1, 1, 1, 1, 50]"

If you pass a zero-length range as the subrange parameter, this method inserts the elements of newElements at subrange.startIndex. Calling the insert(contentsOf:at:) method instead is preferred.

Likewise, if you pass a zero-length collection as the newElements parameter, this method removes the elements in the given subrange without replacement. Calling the removeSubrange(_:) method instead is preferred.

Calling this method may invalidate any existing indices for use with this collection.

Parameters: subrange: The subrange of the collection to replace. The bounds of the range must be valid indices of the collection. newElements: The new elements to add to the collection.

Complexity: O(m), where m is the combined length of the collection and newElements. If the call to replaceSubrange simply appends the contents of newElements to the collection, the complexity is O(n), where n is the length of newElements.

Declaration

mutating func replaceSubrange<C where C : Collection, C.Iterator.Element == Iterator.Element>(_ subrange: CountableRange<Int>, with newElements: C)

Declared In

RangeReplaceableCollection

Where Index : Strideable, Index.Stride == IndexDistance, Indices == CountableRange

var indices: CountableRange<Int>

The indices that are valid for subscripting the collection, in ascending order.

A collection's indices property can hold a strong reference to the collection itself, causing the collection to be non-uniquely referenced. If you mutate the collection while iterating over its indices, a strong reference can cause an unexpected copy of the collection. To avoid the unexpected copy, use the index(after:) method starting with startIndex to produce indices instead.

var c = MyFancyCollection([10, 20, 30, 40, 50])
var i = c.startIndex
while i != c.endIndex {
    c[i] /= 5
    i = c.index(after: i)
}
// c == MyFancyCollection([2, 4, 6, 8, 10])

Declaration

var indices: CountableRange<Int> { get }

Declared In

RandomAccessCollection
func distance(from:to:)

Returns the distance between two indices.

Parameters: start: A valid index of the collection. end: Another valid index of the collection. If end is equal to start, the result is zero. Returns: The distance between start and end.

Complexity: O(1)

Declaration

func distance(from start: Int, to end: Int) -> IntDistance

Declared In

RandomAccessCollection
func index(_:offsetBy:)

Returns an index that is the specified distance from the given index.

The following example obtains an index advanced four positions from an array's starting index and then prints the element at that position.

let numbers = [10, 20, 30, 40, 50]
let i = numbers.index(numbers.startIndex, offsetBy: 4)
print(numbers[i])
// Prints "50"

The value passed as n must not offset i beyond the endIndex or before the startIndex of this collection.

Parameters: i: A valid index of the collection. n: The distance to offset i. Returns: An index offset by n from the index i. If n is positive, this is the same value as the result of n calls to index(after:). If n is negative, this is the same value as the result of -n calls to index(before:).

Precondition: - If n > 0, n <= self.distance(from: i, to: self.endIndex) - If n < 0, n >= self.distance(from: i, to: self.startIndex) Complexity: O(1)

Declaration

func index(_ i: Int, offsetBy n: IntDistance) -> Int

Declared In

RandomAccessCollection
func index(after:)

Returns the position immediately after the given index.

i: A valid index of the collection. i must be less than endIndex. Returns: The index value immediately after i.

Declaration

func index(after i: Int) -> Int

Declared In

RandomAccessCollection
func index(before:)

Returns the position immediately after the given index.

i: A valid index of the collection. i must be greater than startIndex. Returns: The index value immediately before i.

Declaration

func index(before i: Int) -> Int

Declared In

RandomAccessCollection

Where Indices == DefaultBidirectionalIndices

var indices: DefaultBidirectionalIndices<ArraySlice<Element>>

The indices that are valid for subscripting the collection, in ascending order.

A collection's indices property can hold a strong reference to the collection itself, causing the collection to be non-uniquely referenced. If you mutate the collection while iterating over its indices, a strong reference can cause an unexpected copy of the collection. To avoid the unexpected copy, use the index(after:) method starting with startIndex to produce indices instead.

var c = MyFancyCollection([10, 20, 30, 40, 50])
var i = c.startIndex
while i != c.endIndex {
    c[i] /= 5
    i = c.index(after: i)
}
// c == MyFancyCollection([2, 4, 6, 8, 10])

Declaration

var indices: DefaultBidirectionalIndices<ArraySlice<Element>> { get }

Declared In

BidirectionalCollection

Where Indices == DefaultIndices

var indices: DefaultIndices<ArraySlice<Element>>

The indices that are valid for subscripting the collection, in ascending order.

A collection's indices property can hold a strong reference to the collection itself, causing the collection to be non-uniquely referenced. If you mutate the collection while iterating over its indices, a strong reference can cause an unexpected copy of the collection. To avoid the unexpected copy, use the index(after:) method starting with startIndex to produce indices instead.

var c = MyFancyCollection([10, 20, 30, 40, 50])
var i = c.startIndex
while i != c.endIndex {
    c[i] /= 5
    i = c.index(after: i)
}
// c == MyFancyCollection([2, 4, 6, 8, 10])

Declaration

var indices: DefaultIndices<ArraySlice<Element>> { get }

Declared In

Collection

Where Indices == DefaultRandomAccessIndices

var indices: DefaultRandomAccessIndices<ArraySlice<Element>>

The indices that are valid for subscripting the collection, in ascending order.

A collection's indices property can hold a strong reference to the collection itself, causing the collection to be non-uniquely referenced. If you mutate the collection while iterating over its indices, a strong reference can cause an unexpected copy of the collection. To avoid the unexpected copy, use the index(after:) method starting with startIndex to produce indices instead.

var c = MyFancyCollection([10, 20, 30, 40, 50])
var i = c.startIndex
while i != c.endIndex {
    c[i] /= 5
    i = c.index(after: i)
}
// c == MyFancyCollection([2, 4, 6, 8, 10])

Declaration

var indices: DefaultRandomAccessIndices<ArraySlice<Element>> { get }

Declared In

RandomAccessCollection

Where Iterator == IndexingIterator

func makeIterator()

Returns an iterator over the elements of the collection.

Declaration

func makeIterator() -> IndexingIterator<ArraySlice<Element>>

Declared In

Collection

Where Iterator == Self, Self : IteratorProtocol

func makeIterator()

Returns an iterator over the elements of this sequence.

Declaration

func makeIterator() -> ArraySlice<Element>

Declared In

Sequence

Where Iterator.Element : BidirectionalCollection

func joined()

Returns the elements of this collection of collections, concatenated.

In this example, an array of three ranges is flattened so that the elements of each range can be iterated in turn.

let ranges = [0..<3, 8..<10, 15..<17]

// A for-in loop over 'ranges' accesses each range:
for range in ranges {
  print(range)
}
// Prints "0..<3"
// Prints "8..<10"
// Prints "15..<17"

// Use 'joined()' to access each element of each range:
for index in ranges.joined() {
    print(index, terminator: " ")
}
// Prints: "0 1 2 8 9 15 16"

Returns: A flattened view of the elements of this collection of collections.

See Also: flatMap(_:), joined(separator:)

Declaration

func joined() -> FlattenBidirectionalCollection<ArraySlice<Element>>

Declared In

BidirectionalCollection

Where Iterator.Element : Collection

func joined()

Returns the elements of this collection of collections, concatenated.

In this example, an array of three ranges is flattened so that the elements of each range can be iterated in turn.

let ranges = [0..<3, 8..<10, 15..<17]

// A for-in loop over 'ranges' accesses each range:
for range in ranges {
  print(range)
}
// Prints "0..<3"
// Prints "8..<10"
// Prints "15..<17"

// Use 'joined()' to access each element of each range:
for index in ranges.joined() {
    print(index, terminator: " ")
}
// Prints: "0 1 2 8 9 15 16"

Returns: A flattened view of the elements of this collection of collections.

See Also: flatMap(_:), joined(separator:)

Declaration

func joined() -> FlattenCollection<ArraySlice<Element>>

Declared In

Collection

Where Iterator.Element : Comparable

func lexicographicallyPrecedes(_:)

Returns a Boolean value indicating whether the sequence precedes another sequence in a lexicographical (dictionary) ordering, using the less-than operator (<) to compare elements.

This example uses the lexicographicallyPrecedes method to test which array of integers comes first in a lexicographical ordering.

let a = [1, 2, 2, 2]
let b = [1, 2, 3, 4]

print(a.lexicographicallyPrecedes(b))
// Prints "true"
print(b.lexicographicallyPrecedes(b))
// Prints "false"

other: A sequence to compare to this sequence. Returns: true if this sequence precedes other in a dictionary ordering; otherwise, false.

Note: This method implements the mathematical notion of lexicographical ordering, which has no connection to Unicode. If you are sorting strings to present to the end user, use String APIs that perform localized comparison. See Also: lexicographicallyPrecedes(_:by:)

Declaration

func lexicographicallyPrecedes<OtherSequence where OtherSequence : Sequence, OtherSequence.Iterator.Element == Iterator.Element>(_ other: OtherSequence) -> Bool

Declared In

Sequence
@warn_unqualified_access func max()

Returns the maximum element in the sequence.

This example finds the smallest value in an array of height measurements.

let heights = [67.5, 65.7, 64.3, 61.1, 58.5, 60.3, 64.9]
let greatestHeight = heights.max()
print(greatestHeight)
// Prints "Optional(67.5)"

Returns: The sequence's maximum element. If the sequence has no elements, returns nil.

See Also: max(by:)

Declaration

@warn_unqualified_access func max() -> Element?

Declared In

Sequence
@warn_unqualified_access func min()

Returns the minimum element in the sequence.

This example finds the smallest value in an array of height measurements.

let heights = [67.5, 65.7, 64.3, 61.1, 58.5, 60.3, 64.9]
let lowestHeight = heights.min()
print(lowestHeight)
// Prints "Optional(58.5)"

Returns: The sequence's minimum element. If the sequence has no elements, returns nil.

See Also: min(by:)

Declaration

@warn_unqualified_access func min() -> Element?

Declared In

Sequence
func sorted()

Returns the elements of the collection, sorted.

You can sort any collection of elements that conform to the Comparable protocol by calling this method. Elements are sorted in ascending order.

The sorting algorithm is not stable. A nonstable sort may change the relative order of elements that compare equal.

Here's an example of sorting a list of students' names. Strings in Swift conform to the Comparable protocol, so the names are sorted in ascending order according to the less-than operator (<).

let students: Set = ["Kofi", "Abena", "Peter", "Kweku", "Akosua"]
let sortedStudents = students.sorted()
print(sortedStudents)
// Prints "["Abena", "Akosua", "Kofi", "Kweku", "Peter"]"

To sort the elements of your collection in descending order, pass the greater-than operator (>) to the sorted(by:) method.

let descendingStudents = students.sorted(by: >)
print(descendingStudents)
// Prints "["Peter", "Kweku", "Kofi", "Akosua", "Abena"]"

Returns: A sorted array of the collection's elements.

See Also: sorted(by:) MutatingVariant: sort

Declaration

func sorted() -> [Element]

Declared In

MutableCollection, Sequence

Where Iterator.Element : Equatable

func contains(_:)

Returns a Boolean value indicating whether the sequence contains the given element.

This example checks to see whether a favorite actor is in an array storing a movie's cast.

let cast = ["Vivien", "Marlon", "Kim", "Karl"]
print(cast.contains("Marlon"))
// Prints "true"
print(cast.contains("James"))
// Prints "false"

element: The element to find in the sequence. Returns: true if the element was found in the sequence; otherwise, false.

Declaration

func contains(_ element: Element) -> Bool

Declared In

Sequence
func elementsEqual(_:)

Returns a Boolean value indicating whether this sequence and another sequence contain the same elements in the same order.

At least one of the sequences must be finite.

This example tests whether one countable range shares the same elements as another countable range and an array.

let a = 1...3
let b = 1...10

print(a.elementsEqual(b))
// Prints "false"
print(a.elementsEqual([1, 2, 3]))
// Prints "true"

other: A sequence to compare to this sequence. Returns: true if this sequence and other contain the same elements in the same order.

See Also: elementsEqual(_:by:)

Declaration

func elementsEqual<OtherSequence where OtherSequence : Sequence, OtherSequence.Iterator.Element == Iterator.Element>(_ other: OtherSequence) -> Bool

Declared In

Sequence
func index(of:)

Returns the first index where the specified value appears in the collection.

After using index(of:) to find the position of a particular element in a collection, you can use it to access the element by subscripting. This example shows how you can modify one of the names in an array of students.

var students = ["Ben", "Ivy", "Jordell", "Maxime"]
if let i = students.index(of: "Maxime") {
    students[i] = "Max"
}
print(students)
// Prints "["Ben", "Ivy", "Jordell", "Max"]"

element: An element to search for in the collection. Returns: The first index where element is found. If element is not found in the collection, returns nil.

See Also: index(where:)

Declaration

func index(of element: Element) -> Int?

Declared In

Collection
func split(_:maxSplits:omittingEmptySubsequences:)

Returns the longest possible subsequences of the collection, in order, around elements equal to the given element.

The resulting array consists of at most maxSplits + 1 subsequences. Elements that are used to split the collection are not returned as part of any subsequence.

The following examples show the effects of the maxSplits and omittingEmptySubsequences parameters when splitting a string at each space character (" "). The first use of split returns each word that was originally separated by one or more spaces.

let line = "BLANCHE:   I don't want realism. I want magic!"
print(line.characters.split(separator: " ")
                     .map(String.init))
// Prints "["BLANCHE:", "I", "don\'t", "want", "realism.", "I", "want", "magic!"]"

The second example passes 1 for the maxSplits parameter, so the original string is split just once, into two new strings.

print(line.characters.split(separator: " ", maxSplits: 1)
                      .map(String.init))
// Prints "["BLANCHE:", "  I don\'t want realism. I want magic!"]"

The final example passes false for the omittingEmptySubsequences parameter, so the returned array contains empty strings where spaces were repeated.

print(line.characters.split(separator: " ", omittingEmptySubsequences: false)
                      .map(String.init))
// Prints "["BLANCHE:", "", "", "I", "don\'t", "want", "realism.", "I", "want", "magic!"]"

Parameters: separator: The element that should be split upon. maxSplits: The maximum number of times to split the collection, or one less than the number of subsequences to return. If maxSplits + 1 subsequences are returned, the last one is a suffix of the original collection containing the remaining elements. maxSplits must be greater than or equal to zero. The default value is Int.max. omittingEmptySubsequences: If false, an empty subsequence is returned in the result for each consecutive pair of separator elements in the collection and for each instance of separator at the start or end of the collection. If true, only nonempty subsequences are returned. The default value is true. Returns: An array of subsequences, split from this collection's elements.

Declaration

func split(separator: Element, maxSplits: Int = default, omittingEmptySubsequences: Bool = default) -> [ArraySlice<Element>]

Declared In

Collection, Sequence
func starts(with:)

Returns a Boolean value indicating whether the initial elements of the sequence are the same as the elements in another sequence.

This example tests whether one countable range begins with the elements of another countable range.

let a = 1...3
let b = 1...10

print(b.starts(with: a))
// Prints "true"

Passing an sequence with no elements or an empty collection as possiblePrefix always results in true.

print(b.starts(with: []))
// Prints "true"

possiblePrefix: A sequence to compare to this sequence. Returns: true if the initial elements of the sequence are the same as the elements of possiblePrefix; otherwise, false. If possiblePrefix has no elements, the return value is true.

See Also: starts(with:by:)

Declaration

func starts<PossiblePrefix where PossiblePrefix : Sequence, PossiblePrefix.Iterator.Element == Iterator.Element>(with possiblePrefix: PossiblePrefix) -> Bool

Declared In

Sequence

Where Iterator.Element : Sequence

func joined()

Returns the elements of this sequence of sequences, concatenated.

In this example, an array of three ranges is flattened so that the elements of each range can be iterated in turn.

let ranges = [0..<3, 8..<10, 15..<17]

// A for-in loop over 'ranges' accesses each range:
for range in ranges {
  print(range)
}
// Prints "0..<3"
// Prints "8..<10"
// Prints "15..<17"

// Use 'joined()' to access each element of each range:
for index in ranges.joined() {
    print(index, terminator: " ")
}
// Prints: "0 1 2 8 9 15 16"

Returns: A flattened view of the elements of this sequence of sequences.

See Also: flatMap(_:), joined(separator:)

Declaration

func joined() -> FlattenSequence<ArraySlice<Element>>

Declared In

Sequence
func joined(_:)

Returns the concatenated elements of this sequence of sequences, inserting the given separator between each element.

This example shows how an array of [Int] instances can be joined, using another [Int] instance as the separator:

let nestedNumbers = [[1, 2, 3], [4, 5, 6], [7, 8, 9]]
let joined = nestedNumbers.joined(separator: [-1, -2])
print(Array(joined))
// Prints "[1, 2, 3, -1, -2, 4, 5, 6, -1, -2, 7, 8, 9]"

separator: A sequence to insert between each of this sequence's elements. Returns: The joined sequence of elements.

See Also: joined()

Declaration

func joined<Separator : Sequence where Separator.Iterator.Element == Iterator.Element.Iterator.Element>(separator: Separator) -> JoinedSequence<ArraySlice<Element>>

Declared In

Sequence

Where Iterator.Element == String

func joined(_:)

Returns a new string by concatenating the elements of the sequence, adding the given separator between each element.

The following example shows how an array of strings can be joined to a single, comma-separated string:

let cast = ["Vivien", "Marlon", "Kim", "Karl"]
let list = cast.joined(separator: ", ")
print(list)
// Prints "Vivien, Marlon, Kim, Karl"

separator: A string to insert between each of the elements in this sequence. The default separator is an empty string. Returns: A single, concatenated string.

Declaration

func joined(separator: String = default) -> String

Declared In

Sequence

Where Self : RandomAccessCollection, Iterator.Element : Comparable

mutating func sort()

Sorts the collection in place.

You can sort any mutable collection of elements that conform to the Comparable protocol by calling this method. Elements are sorted in ascending order.

The sorting algorithm is not stable. A nonstable sort may change the relative order of elements that compare equal.

Here's an example of sorting a list of students' names. Strings in Swift conform to the Comparable protocol, so the names are sorted in ascending order according to the less-than operator (<).

var students = ["Kofi", "Abena", "Peter", "Kweku", "Akosua"]
students.sort()
print(students)
// Prints "["Abena", "Akosua", "Kofi", "Kweku", "Peter"]"

To sort the elements of your collection in descending order, pass the greater-than operator (>) to the sort(by:) method.

students.sort(by: >)
print(students)
// Prints "["Peter", "Kweku", "Kofi", "Akosua", "Abena"]"

Declaration

mutating func sort()

Declared In

MutableCollection