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Fluxxan4j

Fluxxan4j is a Pure Java 6 implementation of the Flux Architecture that combines concepts from both Fluxxor and Redux with no external dependencies.

It is a port of the Android implementation Fluxxan.

Current Version: 1.0.0

Fluxxan4j follows Semantic Versioning.

Installation

####Manual Installation Download the jar artifact from the artifacts directory and import it into your project.

##Introduction I won't attempt to teach you the concepts of Flux. There are enough articles on the internet for that. Facebook has a great introduction to flux here to get you started. I will instead focus on showing you how to achieve Flux using Fluxxan4j. In this introduction tutorial, I will walk you through building the sample Todo app included in the source.

Fluxxan4j is composed of the

  1. State
  2. Dispatcher
  3. Actions
  4. Action Creators
  5. Reducers (called stores in traditional Flux)
  6. StateListeners

####How it works You hold your application state in a single State object tree. In order to update the State, you tell an ActionCreator, which creates and dispatches an Action object describing what happened. The Dispatcher calls all registered Reducers with the State and Action and each Reducer specifies how the Action transforms the state tree. StateListeners are passed the returned State and update the UI accordingly.

State

The State is the Single Source of Truth of your application. It a single object tree containing the entire app state.

Unlike Redux, Fluxxan4j does not force you to use an immutable state even though the default implementation assumes you do. It is greatly encouraged you do as it will both improve your code, debugging and increase the overall performance of your application. There is a reason most of the new Flux implementations are going immutable. If you choose not to go Immutable, you will need to override couple of methods to help you short circuit the dispatch process.

I've found Immutables to be a really great way to achieve Immutability. It's quick to setup and understand.

It’s a good idea to think of its shape before writing any code. For our Todo app will hold a list of Todo items and a Filter to define which Todos to show.

    @Value.Immutable
    public abstract class AppState {
    
        @Value.Parameter
        public abstract Map<String, Todo> getTodos();
    
        @Value.Default
        public Filter getFilter() {
            return Filter.ALL;
        }
    
        public enum Filter {
            ALL,
            OPEN,
            CLOSED
        }
    }

We also define our Todo object as an Immutable.

    @Value.Immutable
    public abstract class Todo {
        @Value
        public abstract String getUid();
    
        @Value
        public abstract String getTitle();
    
        @Value
        public abstract Status getStatus();
    
        public enum Status {
            OPEN,
            CLOSED
        }
    }

When we build our project, Immutables will generate concrete immutable versions of our AppState and Todo models prefixed with "Immutable" to give ImmutableAppState and ImmutableTodo.

###Actions Actions are objects that define a Type and a data Payload.

The action Type is a unique string to identify the given action and the Payload is any object that you wish to pass to the Reducer.

Actions are created by ActionCreators and passed to the Dispatcher which in turn passes it to each reducer.

###Action Creators As the name implies, Action Creators are methods that create and dispatch Actions.

Fluxxan does not dictate how you create your Action Creators. You have full freedom in this regard. They can be static methods or instance methods.

We have some guidelines which you can follow.

  1. Create a class to group related action creators. e.g. in our app we will create a TodoActionCreator class.
  2. Use instances of each creator rather than static methods.
  3. Each creator should have a nested Creator class that handles the actual creation of the Actions using static methods. This gives our Action Creators two roles and allows to dispatch multiple actions or async tasks while still ensuring we can test our Actions easily.
  4. Nested creator classes should be composed of pure static methods. They should return the same Action each time when given the same arguments. They should cause no side effects.
  5. Don't limit your creators to only dispatch Actions. They are an opportunity to centralize all actions that are taken from the ui. e.g. In a music player app, you can have a PlayerActionCreator class that has a play() method that tells the media player to start playing and does not dispatch an action. Technically, this is not an Action Creator but it's nice that we can have all interactions with the player in one single place.

Let's see what we have in our Todo app (simplified for brevity).

    public class TodoActionCreator extends BaseActionCreator {
        public static final String ADD_TODO = "ADD_TODO";
    
        public void addTodo(String todo) {
	        //get and dispatch the action from our creator
            dispatch(Creator.addTodo(todo));
        }
        
        public static class Creator {
            public static Action<String> addTodo(String todo) {
                return new Action<>(ADD_TODO, todo);
            }
        }
    }

We extend BaseActionCreator which gives us dispatch(Action). Remember to set the dispatcher on your Action Creator after instantiation using setDispatcher(Dispatcher) or Fluxxan.inject(ActionCreator)

As we can see, when we call addTodo, our creator gets the relevant action from the nested creator and dispatches it. We can do neat things in addTodo if we wanted like post to a web service.

In pseudo code it would look something like this:

    public void addTodo(String todo) {
   	    //save on the server
		postToWebservice(todo)
			.onStarted(c => dispatch(Creator.addTodoStarted(todo)))
			.onSuccess(c => dispatch(Creator.addTodoSuccess(todo)))
			.onFailure(c => dispatch(Creator.addTodoFailed(todo)));
    }

Since we are using a dedicated Creator, this allows us to test the actions without having to mock the dispatcher or the web service. We can simply do anywhere in our code:

    dispatch(TodoActionCreator.Creator.addTodoStarted(todo));
    dispatch(TodoActionCreator.Creator.addTodoSuccess(todo));
    dispatch(TodoActionCreator.Creator.addTodoFailed(todo));

###Reducers Reducers describe how our State changes in response to an Action. Like ActionCreator Creators, Reducers need to be pure. That means, no side effects, no calling of an API etc. They should rely solely on the Action to transform the state. Given the same arguments, Reducers should return the same result each time.

To register a Reducer, you need to call Dispatcher.registerReducer(Reducer) and Dispatcher.unregisterReducer(Reducer) if you wish to remove it.

Reducers implement the Reducer interface. We provide two abstract implementations: BaseReducer and BaseAnnotatedReducer both coupled to the default Dispatcher implementation.

BaseReducer requires you to implement reduce(State, Action) in whuch you can check if you want to handle that action Type.

     @Override
     public DispatchResult<State> reduce(State state, Action action) throws Exception {
    
           if(action.Type.equals(TodoActionCreator.ADD_TODO)) {
               //do your thing here
               
               //return the new state and indicate that we handled this action
               return new DispatchResult<>(newState, true);
           }
    
           return new DispatchResult<>(state, false);
       }

BaseAnnotatedReducer uses reflection to determine handlers for each action and calls them for you. This keeps your code cleaner and more concise. You annotate the method with @BindAction(String) and ensure the method has the signature State methodName(State state, PayloadType payload).

This is what our reducer looks like.

    public class TodoReducer extends BaseAnnotatedReducer<AppState> {
    
        @BindAction(TodoActionCreator.ADD_TODO)
        public AppState addTodo(AppState state, String todo) {
            Todo iTodo = ImmutableTodo.builder()
                    .uid(UUID.randomUUID().toString())
                    .title(todo)
                    .status(Todo.Status.OPEN)
                    .build();
    
            return ImmutableAppState.builder()
                    .from(state)
                    .putTodos(iTodo.getUid(), iTodo)
                    .build();
        }
    }

You can call Dispathcer.waitFor or the convenience method provided by BaseReducer and by extension BaseAnnotatedReducer.
This allows the reducer to ensure that other reducers run before it.

StateListener

A StateListener register's itself with the Dispatcher to be notified each time the State changes. It must implement the StateListener interface. It can be any object including an Activity, Fragment, View or Service (running in the same process) etc.

A listener is added using the Dispatcher.addListener(StateListener) and Dispatcher .removeListener(StateListener) to remove it.

hasStateChanged(State newState, State oldState) is a convenience method to help short-circuit the dispatch process if we aren't using an immutable state. You can localize your checks to certain nodes of the state tree specific to this listener. Since we assume your state is immutable, the default implementations use return newState != oldState. If this returns false, onStateChanged is not called.

onStateChanged(final State state) is called when the state has changed. This is not called on the Main or UI thread but on a dedicated background thread. If you wish to make any changes to any UI element, you will need to post a runnable. We provide you a utility method for this using ThreadUtils.runOnMain(Runnable). This design choice was made intentionally to allow you to be able to do any processing (like loops) you wish off the main thread before updating the UI. This allows the UI to remain responsive all the time.

Dispatcher

We saved the best for last.

The dispatcher is the engine of Fluxxan4j. It manages the state, reducers and listeners, handles the dispatching of actions and the subsequent notifying of listeners.

After we create our dispatcher, we need to keep a reference to it so we can register Reducers and StateListeners as well as dispatch Actions. We need to call start and stop on the dispatcher to start or stop it.

You should have only one instance of this class in your application.

The dispatcher checks if states have changed before notifying listeners, but since it assumes state is immutable, you will need to override it's hasStateChanged(State newState, State oldState) method to provide your own functionality. By default, it uses, return newState != oldState.

The dispatcher allows us to provide the ability for a Reducer to wait for other reducers. This is an important feature in Flux not required in Redux.

####Fluxxan We provide you a coordinator to help manage the dispatcher. It's called Fluxxan. Fluxxan is used in default implementations so instead of dealing with the Dispatcher directly (you can if you choose to) we use Fluxxan. Fluxxan provides proxy methods that call Dispatcher. By default, it uses the DispatcherImpl implementation.

In our app, let's see what this looks like.

    AppState state = ImmutableAppState.builder().build();
    
    Fluxxan = new Fluxxan<AppState>(state);
    Fluxxan.registerReducer(new TodoReducer());
    
    Fluxxan.start();

Contributing

Thank you for taking the time to contribute. But before you do, please read our contribution guidelines. They are simple, we promise.

###Todo

  • Writing Tests

License

MIT