50

I have a threading problem in Swift. I have an array with some objects in it. Over a delegate the class gets new objects about every second. After that I have to check if the objects are already in the array, so I have to update the object, otherwise I have to delete / add the new object.

If I add a new object I have to fetch some data over the network first. This is handelt via a block.

Now my problem is, how to I synchronic this tasks?

I have tried a dispatch_semaphore, but this one blocks the UI, until the block is finished.

I have also tried a simple bool variable, which checks if the block is currently executed and skips the compare method meanwhile.

But both methods are not ideal.

What's the best way to manage the array, I don't wanna have duplicate data in the array.

10 Answers 10

66

Kirsteins is correct, but you don't always need to use dispatch queue. You can use:

objc_sync_enter(array)
// manipulate the array
objc_sync_exit(array)

This ought to do the trick. For added bonus, you can create a function to use whenever you need thread safety:

func sync(lock: NSObject, closure: () -> Void) {
    objc_sync_enter(lock)
    closure()
    objc_sync_exit(lock)
}

...
var list = NSMutableArray()
sync (list) {
   list.addObject("something")
}

Notice that I have changed AnyObject to NSObject. In Swift collection types are implemented as structs and they are passed by value, so I am guessing it would be safer to work with mutable collection classes that are passed by reference when using the convenient sync function.

Update for Swift

The recommended pattern for thread-safe access is using dispatch barrier:

let queue = DispatchQueue(label: "thread-safe-obj", attributes: .concurrent)

// write
queue.async(flags: .barrier) {
    // perform writes on data
}

// read
var value: ValueType!
queue.sync {
    // perform read and assign value
}
return value
  • Thanks, but what are the advantages/disadvantages of objc_sync_enter vs dispatch_queue? – Crashalot Apr 2 '16 at 6:16
  • 1
    objc_sync_enter is what's underneath Objective-C's @synchronized. Since I haven't really looked at what's underneath objc_sync_enter I am sort of trusting that the open source code works as promised. As for using serial queue, you know exactly how that is working (blocks of codes sequentially). I am guessing the downside of creating and managing a serial queue per thread safe collection type instance could be costly. – skim Apr 4 '16 at 5:01
  • 2
    You got me curious, so I found this on objc_sync_enter: rykap.com/objective-c/2015/05/09/synchronized – skim Apr 4 '16 at 5:10
  • 9
    It's not safe/correct to use objc_sync_enter on a value type such as Array. objc_sync_array does pointer comparison and the lifetime of the pointer of a bridged Swift value type is not guaranteed to be stable (and in fact most of the time it is not stable). – Jack Lawrence Aug 31 '16 at 20:37
  • 2
    this not working, reason stackoverflow.com/questions/35084754/… – lbsweek May 3 '18 at 7:30
31

My approach to this problem was using serial dispatch queue, to synchronise access to boxed array. It will block the thread when you try to get the value at index and queue is really busy, but that's the problem with locks as well.

public class SynchronizedArray<T> {
    private var array: [T] = []
    private let accessQueue = dispatch_queue_create("SynchronizedArrayAccess", DISPATCH_QUEUE_SERIAL)

    public func append(newElement: T) {
        dispatch_async(self.accessQueue) {
            self.array.append(newElement)
        }
    }

    public subscript(index: Int) -> T {
        set {
            dispatch_async(self.accessQueue) {
                self.array[index] = newValue
            }
        }
        get {
            var element: T!

            dispatch_sync(self.accessQueue) {
                element = self.array[index]
            }

            return element
        }
    }
}

var a = SynchronizedArray<Int>()
a.append(1)
a.append(2)
a.append(3)

// can be empty as this is non-thread safe access
println(a.array)

// thread-safe synchonized access
println(a[0])
println(a[1])
println(a[2])
  • 20
    You might consider using reader-writer pattern: Use DISPATCH_QUEUE_CONCURRENT; changing writes from dispatch_async to dispatch_barrier_async; but leaving reads as dispatch_sync. This gives you concurrent reading, but writes are still synchronized. – Rob Apr 8 '15 at 15:34
  • 3
    You do dispatch_barrier_async for writes only. But do reads with dispatch_sync. Thus, while writes won't (and shouldn't) happen concurrently with respect to anything else, reads can happen concurrently with respect to other reads. See pattern #6 in the latter part of WWDC 2012 video Asynchronous Design Patterns with Blocks, GCD, and XPC. – Rob Nov 4 '15 at 23:41
  • How would you pass in a sort for custom types? – Fred Faust Jan 24 '16 at 19:06
  • Doesn't a DispatchQueue require the CPU to do a context switch to another thread, thus resulting in a very expensive operation? Or is it sync() that actually solves this problem by not dispatching to the queue if not necessary because it's a read-only resource access? – Lars Blumberg Jan 11 '17 at 14:16
31

Kirsteins's answer is correct, but for convenience, I've updated that answer with Amol Chaudhari and Rob's suggestions for using a concurrent queue with async barrier to allow concurrent reads but block on writes.

I've also wrapped some other array functions that were useful to me.

public class SynchronizedArray<T> {
private var array: [T] = []
private let accessQueue = dispatch_queue_create("SynchronizedArrayAccess", DISPATCH_QUEUE_CONCURRENT)

public func append(newElement: T) {
    dispatch_barrier_async(self.accessQueue) {
        self.array.append(newElement)
    }
}

public func removeAtIndex(index: Int) {
    dispatch_barrier_async(self.accessQueue) {
        self.array.removeAtIndex(index)
    }
}

public var count: Int {
    var count = 0

    dispatch_sync(self.accessQueue) {
        count = self.array.count
    }

    return count
}

public func first() -> T? {
    var element: T?

    dispatch_sync(self.accessQueue) {
        if !self.array.isEmpty {
            element = self.array[0]
        }
    }

    return element
}

public subscript(index: Int) -> T {
    set {
        dispatch_barrier_async(self.accessQueue) {
            self.array[index] = newValue
        }
    }
    get {
        var element: T!

        dispatch_sync(self.accessQueue) {
            element = self.array[index]
        }

        return element
    }
}
}

UPDATE This is the same code, updated for Swift3.

public class SynchronizedArray<T> {
private var array: [T] = []
private let accessQueue = DispatchQueue(label: "SynchronizedArrayAccess", attributes: .concurrent)

public func append(newElement: T) {

    self.accessQueue.async(flags:.barrier) {
        self.array.append(newElement)
    }
}

public func removeAtIndex(index: Int) {

    self.accessQueue.async(flags:.barrier) {
        self.array.remove(at: index)
    }
}

public var count: Int {
    var count = 0

    self.accessQueue.sync {
        count = self.array.count
    }

    return count
}

public func first() -> T? {
    var element: T?

    self.accessQueue.sync {
        if !self.array.isEmpty {
            element = self.array[0]
        }
    }

    return element
}

public subscript(index: Int) -> T {
    set {
        self.accessQueue.async(flags:.barrier) {
            self.array[index] = newValue
        }
    }
    get {
        var element: T!
        self.accessQueue.sync {
            element = self.array[index]
        }

        return element
    }
}
}
  • 3
    removeAtIndex could remove wrong item in this code cause idx cold be changed by other thread 'removeAtIndex' ... – Maxim Kholyavkin Nov 20 '16 at 8:20
  • @Speakus could be wrong but I'm pretty sure it doesn't. It's async, but on the same concurrent queue as other array operations... so the removeAtIndex will happen before any other read or write operation happens. – Jordan Smith Jan 23 '17 at 21:27
  • @JordanSmith The issue will happen when you call removeAtIndex but code will switch to another thread for example in time when you get self.accessQueue but before .async running. – Maxim Kholyavkin Jan 24 '17 at 17:22
  • Can you please explain how to use this SynchronizedArray class in place of normal swift 3 array ([String] or []) ? It's very urgent – Varun Naharia Mar 15 '17 at 11:37
  • 2
    @mooney I think @Speakus is right here: Say the sychronized array has one element, wouldn't this fail? if synchronizedArray.count == 1 { synchronizedArray.remove(at: 0) } It's a race condition, say two threads execute the statement. Both read a count of 1 concurrently, both enqueue a write block concurrently. The write blocks execute sequentially, the second one will fail. Am I wrong? Is this a designer or user error? In either case It's fragile as hell & making me never want to touch multi-threading... How would you even make this safe? Back to exclusive locks for both reading and writing? – tombardey Jun 29 '17 at 12:05
7

A minor detail: In Swift 3 (at least in Xcode 8 Beta 6), the syntax for queues changed significantly. The important changes to @Kirsteins' answer will be:

private let accessQueue = DispatchQueue(label: "SynchronizedArrayAccess")

txAccessQueue.async() {
  // Your async code goes here...
}

txAccessQueue.sync() {
  // Your sync code goes here...
}
3

Details

  • Xcode 10.1 (10B61), Swift 4.2
  • Xcode 10.2.1 (10E1001), Swift 5

Solution

import Foundation

// https://developer.apple.com/documentation/swift/rangereplaceablecollection
struct AtomicArray<T>: RangeReplaceableCollection {

    typealias Element = T
    typealias Index = Int
    typealias SubSequence = AtomicArray<T>
    typealias Indices = Range<Int>
    fileprivate var array: Array<T>
    var startIndex: Int { return array.startIndex }
    var endIndex: Int { return array.endIndex }
    var indices: Range<Int> { return array.indices }

    func index(after i: Int) -> Int { return array.index(after: i) }

    private var semaphore = DispatchSemaphore(value: 1)
    fileprivate func _wait() { semaphore.wait() }
    fileprivate func _signal() { semaphore.signal() }
}

// MARK: - Instance Methods

extension AtomicArray {

    init<S>(_ elements: S) where S : Sequence, AtomicArray.Element == S.Element {
        array = Array<S.Element>(elements)
    }

    init() { self.init([]) }

    init(repeating repeatedValue: AtomicArray.Element, count: Int) {
        let array = Array(repeating: repeatedValue, count: count)
        self.init(array)
    }
}

// MARK: - Instance Methods

extension AtomicArray {

    public mutating func append(_ newElement: AtomicArray.Element) {
        _wait(); defer { _signal() }
        array.append(newElement)
    }

    public mutating func append<S>(contentsOf newElements: S) where S : Sequence, AtomicArray.Element == S.Element {
        _wait(); defer { _signal() }
        array.append(contentsOf: newElements)
    }

    func filter(_ isIncluded: (AtomicArray.Element) throws -> Bool) rethrows -> AtomicArray {
        _wait(); defer { _signal() }
        let subArray = try array.filter(isIncluded)
        return AtomicArray(subArray)
    }

    public mutating func insert(_ newElement: AtomicArray.Element, at i: AtomicArray.Index) {
        _wait(); defer { _signal() }
        array.insert(newElement, at: i)
    }

    mutating func insert<S>(contentsOf newElements: S, at i: AtomicArray.Index) where S : Collection, AtomicArray.Element == S.Element {
        _wait(); defer { _signal() }
        array.insert(contentsOf: newElements, at: i)
    }

    mutating func popLast() -> AtomicArray.Element? {
        _wait(); defer { _signal() }
        return array.popLast()
    }

    @discardableResult mutating func remove(at i: AtomicArray.Index) -> AtomicArray.Element {
        _wait(); defer { _signal() }
        return array.remove(at: i)
    }

    mutating func removeAll() {
        _wait(); defer { _signal() }
        array.removeAll()
    }

    mutating func removeAll(keepingCapacity keepCapacity: Bool) {
        _wait(); defer { _signal() }
        array.removeAll()
    }

    mutating func removeAll(where shouldBeRemoved: (AtomicArray.Element) throws -> Bool) rethrows {
        _wait(); defer { _signal() }
        try array.removeAll(where: shouldBeRemoved)
    }

    @discardableResult mutating func removeFirst() -> AtomicArray.Element {
        _wait(); defer { _signal() }
        return array.removeFirst()
    }

    mutating func removeFirst(_ k: Int) {
        _wait(); defer { _signal() }
        array.removeFirst(k)
    }

    @discardableResult mutating func removeLast() -> AtomicArray.Element {
        _wait(); defer { _signal() }
        return array.removeLast()
    }

    mutating func removeLast(_ k: Int) {
        _wait(); defer { _signal() }
        array.removeLast(k)
    }

    @inlinable public func forEach(_ body: (Element) throws -> Void) rethrows {
        _wait(); defer { _signal() }
        try array.forEach(body)
    }

    mutating func removeFirstIfExist(where shouldBeRemoved: (AtomicArray.Element) throws -> Bool) {
        _wait(); defer { _signal() }
        guard let index = try? array.firstIndex(where: shouldBeRemoved) else { return }
        array.remove(at: index)
    }

    mutating func removeSubrange(_ bounds: Range<Int>) {
        _wait(); defer { _signal() }
        array.removeSubrange(bounds)
    }

    mutating func replaceSubrange<C, R>(_ subrange: R, with newElements: C) where C : Collection, R : RangeExpression, T == C.Element, AtomicArray<Element>.Index == R.Bound {
        _wait(); defer { _signal() }
        array.replaceSubrange(subrange, with: newElements)
    }

    mutating func reserveCapacity(_ n: Int) {
        _wait(); defer { _signal() }
        array.reserveCapacity(n)
    }

    public var count: Int {
        _wait(); defer { _signal() }
        return array.count
    }

    public var isEmpty: Bool {
        _wait(); defer { _signal() }
        return array.isEmpty
    }
}

// MARK: - Get/Set

extension AtomicArray {

    // Single  action

    func get() -> [T] {
        _wait(); defer { _signal() }
        return array
    }

    mutating func set(array: [T]) {
        _wait(); defer { _signal() }
        self.array = array
    }

    // Multy actions

    mutating func get(closure: ([T])->()) {
        _wait(); defer { _signal() }
        closure(array)
    }

    mutating func set(closure: ([T]) -> ([T])) {
        _wait(); defer { _signal() }
        array = closure(array)
    }
}

// MARK: - Subscripts

extension AtomicArray {

    subscript(bounds: Range<AtomicArray.Index>) -> AtomicArray.SubSequence {
        get {
            _wait(); defer { _signal() }
            return AtomicArray(array[bounds])
        }
    }

    subscript(bounds: AtomicArray.Index) -> AtomicArray.Element {
        get {
            _wait(); defer { _signal() }
            return array[bounds]
        }
        set(value) {
            _wait(); defer { _signal() }
            array[bounds] = value
        }
    }
}

// MARK: - Operator Functions

extension AtomicArray {

    static func + <Other>(lhs: Other, rhs: AtomicArray) -> AtomicArray where Other : Sequence, AtomicArray.Element == Other.Element {
        return AtomicArray(lhs + rhs.get())
    }

    static func + <Other>(lhs: AtomicArray, rhs: Other) -> AtomicArray where Other : Sequence, AtomicArray.Element == Other.Element {
        return AtomicArray(lhs.get() + rhs)
    }

    static func + <Other>(lhs: AtomicArray, rhs: Other) -> AtomicArray where Other : RangeReplaceableCollection, AtomicArray.Element == Other.Element {
        return AtomicArray(lhs.get() + rhs)
    }

    static func + (lhs: AtomicArray<Element>, rhs: AtomicArray<Element>) -> AtomicArray {
        return AtomicArray(lhs.get() + rhs.get())
    }

    static func += <Other>(lhs: inout AtomicArray, rhs: Other) where Other : Sequence, AtomicArray.Element == Other.Element {
        lhs._wait(); defer { lhs._signal() }
        lhs.array += rhs
    }
}

// MARK: - CustomStringConvertible

extension AtomicArray: CustomStringConvertible {
    var description: String {
        _wait(); defer { _signal() }
        return "\(array)"
    }
}

// MARK: - Equatable

extension AtomicArray where Element : Equatable {

    func split(separator: Element, maxSplits: Int, omittingEmptySubsequences: Bool) -> [ArraySlice<Element>] {
        _wait(); defer { _signal() }
        return array.split(separator: separator, maxSplits: maxSplits, omittingEmptySubsequences: omittingEmptySubsequences)
    }

    func firstIndex(of element: Element) -> Int? {
        _wait(); defer { _signal() }
        return array.firstIndex(of: element)
    }

    func lastIndex(of element: Element) -> Int? {
        _wait(); defer { _signal() }
        return array.lastIndex(of: element)
    }

    func starts<PossiblePrefix>(with possiblePrefix: PossiblePrefix) -> Bool where PossiblePrefix : Sequence, Element == PossiblePrefix.Element {
        _wait(); defer { _signal() }
        return array.starts(with: possiblePrefix)
    }

    func elementsEqual<OtherSequence>(_ other: OtherSequence) -> Bool where OtherSequence : Sequence, Element == OtherSequence.Element {
        _wait(); defer { _signal() }
        return array.elementsEqual(other)
    }

    func contains(_ element: Element) -> Bool {
        _wait(); defer { _signal() }
        return array.contains(element)
    }

    static func != (lhs: AtomicArray<Element>, rhs: AtomicArray<Element>) -> Bool {
        lhs._wait(); defer { lhs._signal() }
        rhs._wait(); defer { rhs._signal() }
        return lhs.array != rhs.array
    }

    static func == (lhs: AtomicArray<Element>, rhs: AtomicArray<Element>) -> Bool {
        lhs._wait(); defer { lhs._signal() }
        rhs._wait(); defer { rhs._signal() }
        return lhs.array == rhs.array
    }
}

Usage sample 1

import Foundation

// init
var array = AtomicArray<Int>()
print(array)
array = AtomicArray(repeating: 0, count: 5)
print(array)
array = AtomicArray([1,2,3,4,5,6,7,8,9])
print(array)

// add
array.append(0)
print(array)
array.append(contentsOf: [5,5,5])
print(array)

// filter
array = array.filter { $0 < 7 }
print(array)

// map
let strings = array.map { "\($0)" }
print(strings)

// insert
array.insert(99, at: 5)
print(array)
array.insert(contentsOf: [2, 2, 2], at: 0)
print(array)

// pop
_ = array.popLast()
print(array)
_ = array.popFirst()
print(array)

// remove
array.removeFirst()
print(array)
array.removeFirst(3)
print(array)
array.remove(at: 2)
print(array)
array.removeLast()
print(array)
array.removeLast(5)
print(array)
array.removeAll { $0%2 == 0 }
print(array)
array = AtomicArray([1,2,3,4,5,6,7,8,9,0])
array.removeSubrange(0...2)
print(array)
array.replaceSubrange(0...2, with: [0,0,0])
print(array)
array.removeAll()
print(array)

array.set(array: [1,2,3,4,5,6,7,8,9,0])
print(array)

// subscript
print(array[0])
array[0] = 100
print(array)
print(array[1...4])

// operator functions
array = [1,2,3] + AtomicArray([4,5,6])
print(array)
array = AtomicArray([4,5,6]) + [1,2,3]
print(array)
array = AtomicArray([1,2,3]) + AtomicArray([4,5,6])
print(array)

Usage sample 2

import Foundation

var arr = AtomicArray([0,1,2,3,4,5])
for i in 0...1000 {
    // Single actions
    DispatchQueue.global(qos: .background).async {
        usleep(useconds_t(Int.random(in: 100...10000)))
        let num = i*i
        arr.append(num)
        print("arr.append(\(num)), background queue")
    }
    DispatchQueue.global(qos: .default).async {
        usleep(useconds_t(Int.random(in: 100...10000)))
        arr.append(arr.count)
        print("arr.append(\(arr.count)), default queue")
    }

    // multy actions
    DispatchQueue.global(qos: .utility).async {
        arr.set { array -> [Int] in
            var newArray = array
            newArray.sort()
            print("sort(), .utility queue")
            return newArray
        }
    }
}
1

I think dispatch_barriers are worth looking into. Using gcd for synchronicity is more intuitive to me than using synchronize keyword to avoid state mutation from multiple threads.

https://mikeash.com/pyblog/friday-qa-2011-10-14-whats-new-in-gcd.html

1

There's a great answer here which is threadsafe and doesn't block concurrent reads: https://stackoverflow.com/a/15936959/2050665

It's written in Objective C, but porting to Swift is trivial.

@property (nonatomic, readwrite, strong) dispatch_queue_t thingQueue;
@property (nonatomic, strong) NSObject *thing;

- (id)init {
  ...
    _thingQueue = dispatch_queue_create("...", DISPATCH_QUEUE_CONCURRENT);
  ...
}

- (NSObject *)thing {
  __block NSObject *thing;
  dispatch_sync(self.thingQueue, ^{
    thing = _thing;
  });
  return thing;
}

- (void)setThing:(NSObject *)thing {
  dispatch_barrier_async(self.thingQueue, ^{
    _thing = thing;
  });
}

Credit to https://stackoverflow.com/users/97337/rob-napier

1

Approach:

Use DispatchQueue to synchronise

Refer:

http://basememara.com/creating-thread-safe-arrays-in-swift/

Code:

Below is a crude implementation of a thread safe array, you can fine tune it.

public class ThreadSafeArray<Element> {

    private var elements    : [Element]
    private let syncQueue   = DispatchQueue(label: "Sync Queue",
                                            qos: .default,
                                            attributes: .concurrent,
                                            autoreleaseFrequency: .inherit,
                                            target: nil)

    public init() {
        elements = []
    }

    public init(_ newElements: [Element]) {
        elements = newElements
    }

    //MARK: Non-mutating

    public var first : Element? {
        return syncQueue.sync {
            elements.first
        }
    }

    public var last : Element? {
        return syncQueue.sync {
            elements.last
        }
    }

    public var count : Int {

        return syncQueue.sync {
            elements.count
        }
    }

    public subscript(index: Int) -> Element {

        get {
            return syncQueue.sync {
                elements[index]
            }
        }

        set {
            syncQueue.sync(flags: .barrier) {
                elements[index] = newValue
            }
        }
    }

    public func reversed() -> [Element] {

        return syncQueue.sync {

            elements.reversed()
        }
    }

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

        return try syncQueue.sync {

           try elements.flatMap(transform)
        }
    }

    public func filter(_ isIncluded: (Element) -> Bool) -> [Element] {

        return syncQueue.sync {

            elements.filter(isIncluded)
        }
    }

    //MARK: Mutating

    public func append(_ element: Element) {

        syncQueue.sync(flags: .barrier) {

            elements.append(element)
        }
    }

    public func append<S>(contentsOf newElements: S) where Element == S.Element, S : Sequence {

        syncQueue.sync(flags: .barrier) {

            elements.append(contentsOf: newElements)
        }
    }

    public func remove(at index: Int) -> Element? {

        var element : Element?

        syncQueue.sync(flags: .barrier) {

            if elements.startIndex ..< elements.endIndex ~= index {
                element = elements.remove(at: index)
            }
            else {
                element = nil
            }
        }

        return element
    }
}

extension ThreadSafeArray where Element : Equatable {

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

        return syncQueue.sync {
            elements.index(of: element)
        }
    }
}
  • this code won't compile because of array getter – derpoliuk Oct 13 '17 at 8:40
  • Which version of Swift are you using ? – user1046037 Oct 13 '17 at 9:47
  • My bad, I wrote comment without trying to compile the code. I though that return queue.sync { _array } won't compile because sync returns nothing. – derpoliuk Oct 13 '17 at 10:19
  • It returns array and the access to the array is synchronised. – user1046037 Oct 13 '17 at 10:23
  • Access to the array is synchronized, true, but any operations performed on the returned array are not. – Michael Long Nov 17 '17 at 16:14
1

firstly, objc_sync_enter not works

objc_sync_enter(array)
defer {
   objc_sync_exit(array)
}

reason objc_sync_enter / objc_sync_exit not working with DISPATCH_QUEUE_PRIORITY_LOW

objc_sync_enter is an extremely low-level primitive, and isn't intended to be used directly. It's an implementation detail of the old @synchronized system in ObjC.

for swift, should use like this, just as @Kirsteins said, and I suggest sync instead of async:

private let syncQueue = DispatchQueue(label:"com.test.LockQueue") 
func test(){
    self.syncQueue.sync{
        // thread safe code here
    }
}
  • serial queue with sync wont cause deadlock ? – karthik Nov 18 '18 at 13:58
  • thanks @karthik, sync did lead to deadlock in some scenario. but for my project, the queue using it has no resource dependency, so it is fine. – lbsweek Nov 19 '18 at 7:32
0

To improve the accepted answer I would suggest using defer:

objc_sync_enter(array)
defer {
   objc_sync_exit(array)
}
// manipulate the array

and the second one

func sync(lock: NSObject, closure: () -> Void) {
    objc_sync_enter(lock)
    defer {
        objc_sync_exit(lock)
    }
    closure()
}

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.