A complete set of primitives for concurrency and reactive programming on Swift
A complete set of primitives for concurrency and reactive programming on Swift
- 1.4.0 is the latest and greatest, but only for Swift 4.2 and 5.0
- use 1.3.0 is for Swift 4.0+
- use 1.2.4 for latest release for Swift 3
Features | |
---|---|
? powerful primitives |
Future , Promise , Channel , Producer , Sink , Cache , ... |
? versatile transformations |
map , filter , recover , debounce , distinct , ... |
✌️ convenient combination |
flatMap , merge , zip , sample , scan , reduce , ... |
? improves existing things |
Key-Value Observing, target-action, notifications, bindings |
? less boilerplate code |
neat cancellation, threading, memory manament |
? extendable |
powerful extensions for URLSession , UI controls, CoreData , ... |
? all platforms |
? macOS 10.10+ ? iOS 8.0+ ? tvOS 9.0+ ⌚️ watchOS 2.0+ ? Linux |
? documentation |
100% + sample code, see full documentation |
? simple integration |
SPM, CocoaPods, Carthage |
- Related articles
- Known users
Communication
Reactive Programming
reactive properties
let searchResults = searchBar.rp.text
.debounce(interval: 0.3)
.distinct()
.flatMap(behavior: .keepLatestTransform) { (query) -> Future<[SearchResult]> in
return query.isEmpty
? .just([])
: searchGitHub(query: query).recover([])
}
bindings
- unbinds automatically
- dispatches to a correct queue automatically
- no
.observeOn(MainScheduler.instance)
and.disposed(by: disposeBag)
class MyViewController: UIViewController {
/* ... */
@IBOutlet weak var myLabel: UILabel!
override func viewDidLoad() {
super.viewDidLoad()
UIDevice.current.rp.orientation
.map { $0.description }
.bind(myLabel.rp.text)
}
/* ... */
}
contexts usage
- no
[weak self]
- no
DispatchQueue.main.async { ... }
- no
.observeOn(MainScheduler.instance)
class MyViewController: NSViewController {
let service: MyService
/* ... */
func fetchAndPresentItems(for request: Request) {
service.perform(request: request)
.map(context: self, executor: .primary) { (self, response) in
return self.items(from: response)
}
.onSuccess(context: self) { (self, items) in
self.present(items: items)
}
.onFailure(context: self) { (self, error) in
self.present(error: error)
}
}
func items(from response: Response) throws -> [Items] {
/* ... extract items from response ... */
}
func present(items: [Items]) {
/* ... update UI ... */
}
}
class MyService {
func perform(request: Request) -> Future<Response> {
/* ... */
}
}
In Depth
Let's assume that we have:
Person
is an example of a struct that contains information about the person.MyService
is an example of a class that serves as an entry point to the model. Works in a background.MyViewController
is an example of a class that manages UI-related instances. Works on the main queue.
Code on callbacks
extension MyViewController {
func present(personWithID identifier: String) {
myService.fetch(personWithID: identifier) {
(person, error) in
/* do not forget to dispatch to the main queue */
DispatchQueue.main.async {
/* do not forget the [weak self] */
[weak self] in
guard let strongSelf = self
else { return }
if let person = person {
strongSelf.present(person: person)
} else if let error = error {
strongSelf.present(error: error)
} else {
fatalError("There is neither person nor error. What has happened to this world?")
}
}
}
}
}
extension MyService {
func fetch(personWithID: String, callback: @escaping (Person?, Error?) -> Void) {
/* ... */
}
}
- "do not forget" comment x2
- the block will be retained and called even if MyViewController was already deallocated
Code with other libraries that provide futures
extension MyViewController {
func present(personWithID identifier: String) {
myService.fetch(personWithID: identifier)
/* do not forget to dispatch to the main queue */
.onComplete(executor: .main) {
/* do not forget the [weak self] */
[weak self] (completion) in
if let strongSelf = self {
completion.onSuccess(strongSelf.present(person:))
completion.onFailure(strongSelf.present(error:))
}
}
}
}
extension MyService {
func fetch(personWithID: String) -> Future<Person> {
/* ... */
}
}
- "do not forget" comment x2
- the block will be retained and called even if MyViewController was already deallocated
Code with AsyncNinja
extension MyViewController {
func present(personWithID identifier: String) {
myService.fetch(personWithID: identifier)
.onSuccess(context: self) { (self, person) in
self.present(person: person)
}
.onFailure(context: self) { (self, error) in
self.present(error: error)
}
}
}
extension MyService {
func fetch(personWithID: String) -> Future<Person> {
/* ... */
}
}
- "do not forget" comment NONE
- the block will be retained and called as long as specified context (MyViewController) exists
- Want to see extended explanation?
Using Futures
Let's assume that we have function that finds all prime numbers lesser than n
func primeNumbers(to n: Int) -> [Int] { /* ... */ }
Making future
let futurePrimeNumbers: Future<[Int]> = future { primeNumbers(to: 10_000_000) }
Applying transformation
let futureSquaredPrimeNumbers = futurePrimeNumbers
.map { (primeNumbers) -> [Int] in
return primeNumbers.map { (number) -> Int
return number * number
}
}
Synchronously waiting for completion
if let fallibleNumbers = futurePrimeNumbers.wait(seconds: 1.0) {
print("Number of prime numbers is \(fallibleNumbers.success?.count)")
} else {
print("Did not calculate prime numbers yet")
}
Subscribing for completion
futurePrimeNumbers.onComplete { (falliblePrimeNumbers) in
print("Number of prime numbers is \(falliblePrimeNumbers.success?.count)")
}
Combining futures
let futureA: Future<A> = /* ... */
let futureB: Future<B> = /* ... */
let futureC: Future<C> = /* ... */
let futureABC: Future<(A, B, C)> = zip(futureA, futureB, futureC)
Transition from callbacks-based flow to futures-based flow:
class MyService {
/* implementation */
func fetchPerson(withID personID: Person.Identifier) -> Future<Person> {
let promise = Promise<Person>()
self.fetchPerson(withID: personID, callback: promise.complete)
return promise
}
}
Transition from futures-based flow to callbacks-based flow
class MyService {
/* implementation */
func fetchPerson(withID personID: Person.Identifier,
callback: @escaping (Fallible<Person>) -> Void) {
self.fetchPerson(withID: personID)
.onComplete(callback)
}
}
Using Channels
Let's assume we have function that returns channel of prime numbers: sends prime numbers as finds them and sends number of found numbers as completion
func makeChannelOfPrimeNumbers(to n: Int) -> Channel<Int, Int> { /* ... */ }
Applying transformation
let channelOfSquaredPrimeNumbers = channelOfPrimeNumbers
.map { (number) -> Int in
return number * number
}
Synchronously iterating over update values.
for number in channelOfPrimeNumbers {
print(number)
}
Synchronously waiting for completion
if let fallibleNumberOfPrimes = channelOfPrimeNumbers.wait(seconds: 1.0) {
print("Number of prime numbers is \(fallibleNumberOfPrimes.success)")
} else {
print("Did not calculate prime numbers yet")
}
Synchronously waiting for completion #2
let (primeNumbers, numberOfPrimeNumbers) = channelOfPrimeNumbers.waitForAll()
Subscribing for update
channelOfPrimeNumbers.onUpdate { print("Update: \($0)") }
Subscribing for completion
channelOfPrimeNumbers.onComplete { print("Completed: \($0)") }
Making Channel
func makeChannelOfPrimeNumbers(to n: Int) -> Channel<Int, Int> {
return channel { (update) -> Int in
var numberOfPrimeNumbers = 0
var isPrime = Array(repeating: true, count: n)
for number in 2..<n where isPrime[number] {
numberOfPrimeNumbers += 1
update(number)
// updating seive
var seiveNumber = number + number
while seiveNumber < n {
isPrime[seiveNumber] = false
seiveNumber += number
}
}
return numberOfPrimeNumbers
}
}