index.d.ts

/**
 * An *action* is a plain object that represents an intention to change the
 * state. Actions are the only way to get data into the store. Any data,
 * whether from UI events, network callbacks, or other sources such as
 * WebSockets needs to eventually be dispatched as actions.
 *
 * Actions must have a `type` field that indicates the type of action being
 * performed. Types can be defined as constants and imported from another
 * module. It's better to use strings for `type` than Symbols because strings
 * are serializable.
 *
 * Other than `type`, the structure of an action object is really up to you.
 * If you're interested, check out Flux Standard Action for recommendations on
 * how actions should be constructed.
 */
export interface Action {
  type: any;
}


/* reducers */

/**
 * A *reducer* (also called a *reducing function*) is a function that accepts
 * an accumulation and a value and returns a new accumulation. They are used
 * to reduce a collection of values down to a single value
 *
 * Reducers are not unique to Redux—they are a fundamental concept in
 * functional programming.  Even most non-functional languages, like
 * JavaScript, have a built-in API for reducing. In JavaScript, it's
 * `Array.prototype.reduce()`.
 *
 * In Redux, the accumulated value is the state object, and the values being
 * accumulated are actions. Reducers calculate a new state given the previous
 * state and an action. They must be *pure functions*—functions that return
 * the exact same output for given inputs. They should also be free of
 * side-effects. This is what enables exciting features like hot reloading and
 * time travel.
 *
 * Reducers are the most important concept in Redux.
 *
 * *Do not put API calls into reducers.*
 *
 * @template S State object type.
 */
export type Reducer<S> = <A extends Action>(state: S, action: A) => S;

/**
 * Object whose values correspond to different reducer functions.
 */
export interface ReducersMapObject {
  [key: string]: Reducer<any>;
}

/**
 * Turns an object whose values are different reducer functions, into a single
 * reducer function. It will call every child reducer, and gather their results
 * into a single state object, whose keys correspond to the keys of the passed
 * reducer functions.
 *
 * @template S Combined state object type.
 *
 * @param reducers An object whose values correspond to different reducer
 *   functions that need to be combined into one. One handy way to obtain it
 *   is to use ES6 `import * as reducers` syntax. The reducers may never
 *   return undefined for any action. Instead, they should return their
 *   initial state if the state passed to them was undefined, and the current
 *   state for any unrecognized action.
 *
 * @returns A reducer function that invokes every reducer inside the passed
 *   object, and builds a state object with the same shape.
 */
export function combineReducers<S>(reducers: ReducersMapObject): Reducer<S>;


/* store */

/**
 * A *dispatching function* (or simply *dispatch function*) is a function that
 * accepts an action or an async action; it then may or may not dispatch one
 * or more actions to the store.
 *
 * We must distinguish between dispatching functions in general and the base
 * `dispatch` function provided by the store instance without any middleware.
 *
 * The base dispatch function *always* synchronously sends an action to the
 * store's reducer, along with the previous state returned by the store, to
 * calculate a new state. It expects actions to be plain objects ready to be
 * consumed by the reducer.
 *
 * Middleware wraps the base dispatch function. It allows the dispatch
 * function to handle async actions in addition to actions. Middleware may
 * transform, delay, ignore, or otherwise interpret actions or async actions
 * before passing them to the next middleware.
 */
export interface Dispatch<S> {
    <A extends Action>(action: A): A;
}

/**
 * Function to remove listener added by `Store.subscribe()`.
 */
export interface Unsubscribe {
  (): void;
}

/**
 * A store is an object that holds the application's state tree.
 * There should only be a single store in a Redux app, as the composition
 * happens on the reducer level.
 *
 * @template S State object type.
 */
export interface Store<S> {
  /**
   * Dispatches an action. It is the only way to trigger a state change.
   *
   * The `reducer` function, used to create the store, will be called with the
   * current state tree and the given `action`. Its return value will be
   * considered the **next** state of the tree, and the change listeners will
   * be notified.
   *
   * The base implementation only supports plain object actions. If you want
   * to dispatch a Promise, an Observable, a thunk, or something else, you
   * need to wrap your store creating function into the corresponding
   * middleware. For example, see the documentation for the `redux-thunk`
   * package. Even the middleware will eventually dispatch plain object
   * actions using this method.
   *
   * @param action A plain object representing “what changed”. It is a good
   *   idea to keep actions serializable so you can record and replay user
   *   sessions, or use the time travelling `redux-devtools`. An action must
   *   have a `type` property which may not be `undefined`. It is a good idea
   *   to use string constants for action types.
   *
   * @returns For convenience, the same action object you dispatched.
   *
   * Note that, if you use a custom middleware, it may wrap `dispatch()` to
   * return something else (for example, a Promise you can await).
   */
  dispatch: Dispatch<S>;

  /**
   * Reads the state tree managed by the store.
   *
   * @returns The current state tree of your application.
   */
  getState(): S;

  /**
   * Adds a change listener. It will be called any time an action is
   * dispatched, and some part of the state tree may potentially have changed.
   * You may then call `getState()` to read the current state tree inside the
   * callback.
   *
   * You may call `dispatch()` from a change listener, with the following
   * caveats:
   *
   * 1. The subscriptions are snapshotted just before every `dispatch()` call.
   * If you subscribe or unsubscribe while the listeners are being invoked,
   * this will not have any effect on the `dispatch()` that is currently in
   * progress. However, the next `dispatch()` call, whether nested or not,
   * will use a more recent snapshot of the subscription list.
   *
   * 2. The listener should not expect to see all states changes, as the state
   * might have been updated multiple times during a nested `dispatch()` before
   * the listener is called. It is, however, guaranteed that all subscribers
   * registered before the `dispatch()` started will be called with the latest
   * state by the time it exits.
   *
   * @param listener A callback to be invoked on every dispatch.
   * @returns A function to remove this change listener.
   */
  subscribe(listener: () => void): Unsubscribe;

  /**
   * Replaces the reducer currently used by the store to calculate the state.
   *
   * You might need this if your app implements code splitting and you want to
   * load some of the reducers dynamically. You might also need this if you
   * implement a hot reloading mechanism for Redux.
   *
   * @param nextReducer The reducer for the store to use instead.
   */
  replaceReducer(nextReducer: Reducer<S>): void;
}

/**
 * A store creator is a function that creates a Redux store. Like with
 * dispatching function, we must distinguish the base store creator,
 * `createStore(reducer, preloadedState)` exported from the Redux package, from
 * store creators that are returned from the store enhancers.
 *
 * @template S State object type.
 */
export interface StoreCreator {
  <S>(reducer: Reducer<S>, enhancer?: StoreEnhancer<S>): Store<S>;
  <S>(reducer: Reducer<S>, preloadedState: S, enhancer?: StoreEnhancer<S>): Store<S>;
}

/**
 * A store enhancer is a higher-order function that composes a store creator
 * to return a new, enhanced store creator. This is similar to middleware in
 * that it allows you to alter the store interface in a composable way.
 *
 * Store enhancers are much the same concept as higher-order components in
 * React, which are also occasionally called “component enhancers”.
 *
 * Because a store is not an instance, but rather a plain-object collection of
 * functions, copies can be easily created and modified without mutating the
 * original store. There is an example in `compose` documentation
 * demonstrating that.
 *
 * Most likely you'll never write a store enhancer, but you may use the one
 * provided by the developer tools. It is what makes time travel possible
 * without the app being aware it is happening. Amusingly, the Redux
 * middleware implementation is itself a store enhancer.
 */
export type StoreEnhancer<S> = (next: StoreEnhancerStoreCreator<S>) => StoreEnhancerStoreCreator<S>;
export type GenericStoreEnhancer = <S>(next: StoreEnhancerStoreCreator<S>) => StoreEnhancerStoreCreator<S>;
export type StoreEnhancerStoreCreator<S> = (reducer: Reducer<S>, preloadedState?: S) => Store<S>;

/**
 * Creates a Redux store that holds the state tree.
 * The only way to change the data in the store is to call `dispatch()` on it.
 *
 * There should only be a single store in your app. To specify how different
 * parts of the state tree respond to actions, you may combine several
 * reducers
 * into a single reducer function by using `combineReducers`.
 *
 * @template S State object type.
 *
 * @param reducer A function that returns the next state tree, given the
 *   current state tree and the action to handle.
 *
 * @param [preloadedState] The initial state. You may optionally specify it to
 *   hydrate the state from the server in universal apps, or to restore a
 *   previously serialized user session. If you use `combineReducers` to
 *   produce the root reducer function, this must be an object with the same
 *   shape as `combineReducers` keys.
 *
 * @param [enhancer] The store enhancer. You may optionally specify it to
 *   enhance the store with third-party capabilities such as middleware, time
 *   travel, persistence, etc. The only store enhancer that ships with Redux
 *   is `applyMiddleware()`.
 *
 * @returns A Redux store that lets you read the state, dispatch actions and
 *   subscribe to changes.
 */
export const createStore: StoreCreator;


/* middleware */

export interface MiddlewareAPI<S> {
  dispatch: Dispatch<S>;
  getState(): S;
}

/**
 * A middleware is a higher-order function that composes a dispatch function
 * to return a new dispatch function. It often turns async actions into
 * actions.
 *
 * Middleware is composable using function composition. It is useful for
 * logging actions, performing side effects like routing, or turning an
 * asynchronous API call into a series of synchronous actions.
 */
export interface Middleware {
  <S>(api: MiddlewareAPI<S>): (next: Dispatch<S>) => Dispatch<S>;
}

/**
 * Creates a store enhancer that applies middleware to the dispatch method
 * of the Redux store. This is handy for a variety of tasks, such as
 * expressing asynchronous actions in a concise manner, or logging every
 * action payload.
 *
 * See `redux-thunk` package as an example of the Redux middleware.
 *
 * Because middleware is potentially asynchronous, this should be the first
 * store enhancer in the composition chain.
 *
 * Note that each middleware will be given the `dispatch` and `getState`
 * functions as named arguments.
 *
 * @param middlewares The middleware chain to be applied.
 * @returns A store enhancer applying the middleware.
 */
export function applyMiddleware(...middlewares: Middleware[]): GenericStoreEnhancer;


/* action creators */

/**
 * An *action creator* is, quite simply, a function that creates an action. Do
 * not confuse the two terms—again, an action is a payload of information, and
 * an action creator is a factory that creates an action.
 *
 * Calling an action creator only produces an action, but does not dispatch
 * it. You need to call the store's `dispatch` function to actually cause the
 * mutation. Sometimes we say *bound action creators* to mean functions that
 * call an action creator and immediately dispatch its result to a specific
 * store instance.
 *
 * If an action creator needs to read the current state, perform an API call,
 * or cause a side effect, like a routing transition, it should return an
 * async action instead of an action.
 *
 * @template A Returned action type.
 */
export interface ActionCreator<A> {
  (...args: any[]): A;
}

/**
 * Object whose values are action creator functions.
 */
export interface ActionCreatorsMapObject {
  [key: string]: ActionCreator<any>;
}

/**
 * Turns an object whose values are action creators, into an object with the
 * same keys, but with every function wrapped into a `dispatch` call so they
 * may be invoked directly. This is just a convenience method, as you can call
 * `store.dispatch(MyActionCreators.doSomething())` yourself just fine.
 *
 * For convenience, you can also pass a single function as the first argument,
 * and get a function in return.
 *
 * @param actionCreator An object whose values are action creator functions.
 *   One handy way to obtain it is to use ES6 `import * as` syntax. You may
 *   also pass a single function.
 *
 * @param dispatch The `dispatch` function available on your Redux store.
 *
 * @returns The object mimicking the original object, but with every action
 *   creator wrapped into the `dispatch` call. If you passed a function as
 *   `actionCreator`, the return value will also be a single function.
 */
export function bindActionCreators<A extends ActionCreator<any>>(actionCreator: A, dispatch: Dispatch<any>): A;

export function bindActionCreators<
  A extends ActionCreator<any>,
  B extends ActionCreator<any>
  >(actionCreator: A, dispatch: Dispatch<any>): B;

export function bindActionCreators<M extends ActionCreatorsMapObject>(actionCreators: M, dispatch: Dispatch<any>): M;

export function bindActionCreators<
  M extends ActionCreatorsMapObject,
  N extends ActionCreatorsMapObject
  >(actionCreators: M, dispatch: Dispatch<any>): N;


/* compose */

type Func0<R> = () => R;
type Func1<T1, R> = (a1: T1) => R;
type Func2<T1, T2, R> = (a1: T1, a2: T2) => R;
type Func3<T1, T2, T3, R> = (a1: T1, a2: T2, a3: T3, ...args: any[]) => R;

/**
 * Composes single-argument functions from right to left. The rightmost
 * function can take multiple arguments as it provides the signature for the
 * resulting composite function.
 *
 * @param funcs The functions to compose.
 * @returns R function obtained by composing the argument functions from right
 *   to left. For example, `compose(f, g, h)` is identical to doing
 *   `(...args) => f(g(h(...args)))`.
 */
export function compose(): <R>(a: R) => R;

export function compose<F extends Function>(f: F): F;

/* two functions */
export function compose<A, R>(
  f1: (b: A) => R, f2: Func0<A>
): Func0<R>;
export function compose<A, T1, R>(
  f1: (b: A) => R, f2: Func1<T1, A>
): Func1<T1, R>;
export function compose<A, T1, T2, R>(
  f1: (b: A) => R, f2: Func2<T1, T2, A>
): Func2<T1, T2, R>;
export function compose<A, T1, T2, T3, R>(
  f1: (b: A) => R, f2: Func3<T1, T2, T3, A>
): Func3<T1, T2, T3, R>;

/* three functions */
export function compose<A, B, R>(
  f1: (b: B) => R, f2: (a: A) => B, f3: Func0<A>
): Func0<R>;
export function compose<A, B, T1, R>(
  f1: (b: B) => R, f2: (a: A) => B, f3: Func1<T1, A>
): Func1<T1, R>;
export function compose<A, B, T1, T2, R>(
  f1: (b: B) => R, f2: (a: A) => B, f3: Func2<T1, T2, A>
): Func2<T1, T2, R>;
export function compose<A, B, T1, T2, T3, R>(
  f1: (b: B) => R, f2: (a: A) => B, f3: Func3<T1, T2, T3, A>
): Func3<T1, T2, T3, R>;

/* four functions */
export function compose<A, B, C, R>(
  f1: (b: C) => R, f2: (a: B) => C, f3: (a: A) => B, f4: Func0<A>
): Func0<R>;
export function compose<A, B, C, T1, R>(
  f1: (b: C) => R, f2: (a: B) => C, f3: (a: A) => B, f4: Func1<T1, A>
): Func1<T1, R>;
export function compose<A, B, C, T1, T2, R>(
  f1: (b: C) => R, f2: (a: B) => C, f3: (a: A) => B, f4: Func2<T1, T2, A>
): Func2<T1, T2, R>;
export function compose<A, B, C, T1, T2, T3, R>(
  f1: (b: C) => R, f2: (a: B) => C, f3: (a: A) => B, f4: Func3<T1, T2, T3, A>
): Func3<T1, T2, T3, R>;

/* rest */
export function compose<R>(
  f1: (b: any) => R, ...funcs: Function[]
): (...args: any[]) => R;

export function compose<R>(...funcs: Function[]): (...args: any[]) => R;