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  • Language
    Swift
  • License
    MIT License
  • Created over 5 years ago
  • Updated almost 3 years ago

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Repository Details

Unidirectional reactive architecture using new Apple Combine framework https://developer.apple.com/documentation/combine

CombineFeedback

Unidirectional Reactive Architecture. This is a Combine implemetation of ReactiveFeedback and RxFeedback

Diagram

Motivation

Requirements for iOS apps have become huge. Our code has to manage a lot of state e.g. server responses, cached data, UI state, routing etc. Some may say that Reactive Programming can help us a lot but, in the wrong hands, it can do even more harm to your code base.

The goal of this library is to provide a simple and intuitive approach to designing reactive state machines.

Core Concepts

State

State is the single source of truth. It represents a state of your system and is usually a plain Swift type. Your state is immutable. The only way to transition from one State to another is to emit an Event.

Event

Represents all possible events that can happen in your system which can cause a transition to a new State.

Reducer

A Reducer is a pure function with a signature of ( inout State, Event) -> Void. While Event represents an action that results in a State change, it's actually not what causes the change. An Event is just that, a representation of the intention to transition from one state to another. What actually causes the State to change, the embodiment of the corresponding Event, is a Reducer. A Reducer is the only place where a State can be changed.

Feedback

While State represents where the system is at a given time, Event represents a state change, and a Reducer is the pure function that enacts the event causing the state to change, there is not as of yet any type to decide which event should take place given a particular current state. That's the job of the Feedback. It's essentially a "processing engine", listening to changes in the current State and emitting the corresponding next events to take place. Feedbacks don't directly mutate states. Instead, they only emit events which then cause states to change in reducers.

To some extent it's like reactive Middleware in Redux

Dependency

Dependency is the type that holds all services that feature needs, such as API clients, analytics clients, etc.

Store

Store - is a base class responsible for initializing a UI state machine. It provides two ways to interact with it.

  • We can start a state machine by observing var state: AnyPublisher<State, Never>.
  • We can send input events into it via public final func send(event: Event).

This is useful if we want to mutate our state in response to user input. Let's consider a Counter example

struct State {
    var count = 0
}

enum Event {
    case increment
    case decrement
}

When we press + button we want the State of the system to be incremented by 1. To do that somewhere in our UI we can do:

Button(action: {
    store.send(event: .increment)
}) {
    return Text("+").font(.largeTitle)
}

Also, we can use the send(event:) method to initiate side effects. For example, imagine that we are building an infinite list, and we want to trigger the next batch load when a user reaches the end of the list.

enum Event {
    case didLoad(Results)
    case didFail(Error)
    case fetchNext
}

struct State: Builder {
    var batch: Results
    var movies: [Movie]
    var status: Status
}
enum Status {
    case idle
    case loading
    case failed(Error)
}

struct MoviesView: View {
    typealias State = MoviesViewModel.State
    typealias Event = MoviesViewModel.Event
    let context: Context<State, Event>

    var body: some View {
        List {
            ForEach(context.movies.identified(by: \.id)) { movie in
                MovieCell(movie: movie).onAppear {
                // When we reach the end of the list
                // we send `fetchNext` event
                    if self.context.movies.last == movie {
                        self.context.send(event: .fetchNext)
                    }
                }
            }
        }
    }
}

When we send .fetchNext event, it goes to the reducer where we put our system into .loading state, which in response triggers effect in the whenLoading feedback, which is reacting to particular state changes

    static func reducer(state: inout State, event: Event) {
        switch event {
        case .didLoad(let batch):
            state.movies += batch.results
            state.status = .idle
            state.batch = batch
        case .didFail(let error):
            state.status = .failed(error)
        case .retry:
            state.status = .loading
        case .fetchNext:
            state.status = .loading
        }
    }

    static var feedback: Feedback<State, Event> {
        return Feedback(lensing: { $0.nextPage }) { page in
            URLSession.shared
                .fetchMovies(page: page)
                .map(Event.didLoad)
                .replaceError(replace: Event.didFail)
                .receive(on: DispatchQueue.main)
        }
    }

Composition

Taking inspiration from TCA CombineFeedback is build with a composition in mind.

Meaning that we can compose smaller states into bigger states. For more details please see Example App.

ViewContext

ViewContext<State, Event> - is a rendering context that we can use to interact with UI and render information. Via @dynamicMemberLookup it has all of the properties of the State and several conveniences methods for more seamless integration with SwiftUI. (Credits to @andersio)

struct State  {
    var email = ""
    var password = ""
}
enum Event {
	case signIn
}
struct SignInView: View {
    private let store: Store<State, Event>
    
    init(store: Store<State, Event>) {
        self.store = store
    }
    
    var body: some View {
      WithContextView(store: store) { context in
        Form {
            Section {
                TextField(context.binding(for: \.email, event: Event.emailDidChange))
                TextField(context.binding(for: \.password, event: Event.passwordDidCange))
                Button(action: context.action(for: .signIn)) {
                    Text("Sign In")
                }
            }
        }
      }
    }
}

Example

Counter Infinite List SignIn Form Traffic Light

References

Automata theory TCA Finite-state machine Mealy machine