kombo
v0.96.7
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A simple base for client-side application based on React & Rx.JS
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Kombo
Kombo is a simple framework for building rich interactive web applications. It defines a small set of classes and types providing state management for React components. Internals are based on RxJS and Immer.js. Kombo takes some loose inspiration from Flux architecture and Redux library. It is used in production (~thousands user per day) in applications containing tens thousands of lines of TypeScript code with complex interactivity and open/modular architecture. It can be run on both client and server (Node.JS).
See Kombo in action:
git clone https://github.com/tomachalek/kombo.git
make demo
- visit
/your/kombo/location/demo/index.html
to see a TodoMVC example
Contents
Key principles
General
- side-effect as first-class citizens
- multiple models
- no global singletons (like e.g. stores in Flux apps) to keep awareness of components' dependencies
- support for model composition and synchronization
- no boilerplate code (or as few as possible)
- e.g. no action creators (dispatching directly from React components; do you really need to reuse a highly specific state-mapped React component?)
- no need to hate OOP - it can be combined with FP in a pragmatic way
Models
- embrace more traditional "model" as an object which encapsulates a specified subdomain of business logic
(including API calls etc.)
- model should know what to do with its related state (no actionCreator/store dilemma)
- stateless model transforms state provided by a reactive stream; it is quite similar to a Redux reducer function but with native support for producing side effects
- stateful model has direct read access to its state; it can also mix multiple changes state changes and side effect during a single action handling (similar to classic event emitter from Flux)
- flexible model/state configuration
- one model -- one state object
- many models -- one state object
- many models -- many state objects (typically each model handles its state here),
- synchronization of models using
waitForAction()
action where model can suspend itself until a specific action is triggered and data obtained via a respective action payload
Views
- view components are always wrapped inside a function allowing explicit runtime dependency injection:
- models
- additional services like message translation
- React component is bound to a model using simple
Bound
,BoundWithProps
functions
Structure
Stateless models
Stateless model does not control when its related state is changed. It only specifies how the state is changed in response to different actions. This is quite similar to the approach used e.g. by Redux. It also prevents programmer from touching the state of a foreign model and passing it around.
It is expected that the state reduction does not mutate the original state. To achieve this, Kombo uses the great Immer.js library which allows handling state like a mutable object. E.g.:
(state, action) => {
state.data.push(action.payload.data);
}
It is also possible to override StatelessModel.reduce
function in a completely different matter
if needed.
Another great thing about Kombo is that side-effects are treated as first class citizens. The basic "redux" pattern looks pure and cool but without side-effects, it is practically impossible to write a useful application. In Redux, there must be a plug-in installed to achieve that. In Kombo, you just write a handler for a side-effect:
this.addActionHandler(
'FORM_SUBMIT',
(state, action) => { // the "reduce" part
state.isBusy = true;
},
(state, action, dispatch) => { // the "side-effect" part (optional)
ajax$('GET', '/my-service/).subscribe(
(data) => {
dispatch({name: 'DATA_LOAD_DONE', payload: {data});
}
)
}
);
A side-effect is always invoked after the model reduced a respective state based on the action.
Side-effect actions are dispatched at will via a provided function (see SEDispatcher
type).
In this way it is possible to build chains of asynchronous actions with multiple actions dispatched during different stages of the process.
Actions dispatched via SEDispatcher
are internally transformed into SideEffectAction
type which cannot
invoke another action via the internal action/state stream. This prevents user from creating hard to track
cycles of actions.
export interface MyState {
userId:number;
firstname:string;
lastname:string;
memberships:Array<{id:string; type:string}>;
isBusy:boolean;
}
export class MyModel extends StatelessModel<MyState> {
constructor(dispatcher:ActionDispatcher) {
super(
dispatcher,
{ // initial state
userId: -1,
firstname: '',
lastname: '',
memberships:Array<{id:string; type:string}>(),
isBusy: false
}
);
this.addActionHandler(
'REGISTER_USER',
(state, action) => { // reducer, 'state' is already a copy
state.isBusy = true;
},
(state, action, dispatch) => { // side-effect of the action (optional)
dispatch({
type: 'REGISTER_USER_DONE',
payload: {userId: someFetchedInfo['userId']};
});
}
);
this.addActionHandler<MyTypedAction>(
'REGISTER_USER_DONE',
(state, action) => {
newState.isBusy = false;
newState.userId = action.payload.userId;
}
);
}
}
Stateful models
Stateful models provide more low-level and fine-grained control on how an action is processed as they have full access to their state and also to when they emit change or trigger side effect actions (in terms of stateful models, the respective method is called "synchronize").
Stateful models can be great e.g. for legacy code integration or for situations when a respective state does contain non-serializable stuff (functions, dynamically loaded components). Such solutions can be considered ugly or "impure" but sometimes they are quite effective and easy to implement. Kombo does not force any specific approach here - if you want a clean "Redux-like" architecture you can stick with Stateless model. But if you consider a problem hard to implement that way, Stateful model is ready to help you. From the React component's view, both Stateless and Stateful components are the same and can be bound to any model via the Bound wrapper component.
export class MyStatefulModel extends StatefulModel {
constructor(dispatcher:ActionDispatcher) {
this.addActionHandler(
'GET_DATA',
action => {
this.changeState(
state => {
state.isBusy = true;
}
);
ajax('GET', '/get-my-data/').subscribe(
(data) => {
this.changeState(state => {
state.data = data;
state.isBusy = false;
});
},
(err) => {
this.changeState(state => {
state.data = null;
state.error = err;
state.isBusy = false;
});
}
);
}
);
}
}
Model synchronization
Model synchronization is necessary when working with multiple models each handling its own state. Sooner or later we encounter a situation where a model M1 needs some model M2 to be already done with handling action A1. The model M1 may even need some data from M2 (of course without accessing its state).
Let's say the model M1 handles a form which also includes some additional subform (backed by the M2 model) with more or less independent logic. Once submitted, the M2 model validates/submits the subform. But the M1 must wait to M2 to decide whether it should submit the main form.
The has to wait for some other model (B) to perform an action (e.g. to load data via AJAX, 'QUERY_VALIDATION_DONE' in the example below) while both models react to the same initial action ('PERFORM_QUERY'). it is possible to make the model A wait for the action of B:
// side effects of model A
this.addActionHandler(
'PERFORM_QUERY',
(state, action) => {
state.isBusy = true;
},
(state, action, dispatch) => {
this.waitForAction({}, (action:Action, syncData) => { // from now, the function is called on each action
if (action.name === 'QUERY_VALIDATION_DONE') { /* we wait for model B here */
return null; // by returning no synchronization data we say: "stop waiting"
}
// by returning original syncData we say: "not interested in this action"
// (= do not send the action down the stream)
return syncData;
}).pipe(
concatMap((matchingAction) => doSomeAsyncStuff(matchingAction.payload))
).subscribe(
(data) => {
dispatch({
name: 'MY_POSTPONED_ACTION',
payload: {data: data}
});
}
);
}
);
View module
import * as React from 'react';
import {Bound, ActionDispatcher, ViewUtils} from 'kombo';
export function init(dispatcher:ActionDispatcher, ut:ViewUtils, model:TodoModel) {
const TodoText:React.FC<{
text:string;
id:number;
complete:boolean;
}> = (props) => {
const handleInputChange = (evt:React.ChangeEvent<{value:string}>) => {
dispatcher.dispatch({
type: ActionTypes.SET_TEXT_TODO,
payload: {
id: props.id,
value: evt.target.value
}
});
}
return <label>{ut.translate('msg_key1')}
<input type="text" value={props.text} onChange={handleInputChange}
placeholder="my new task" disabled={props.complete} />
</label>;
};
class TodoTable:React.FC<TodoTableProps> {
// ....
};
return {
TodoText: TodoText,
TodoTable: Bound<TodoState>(TodoTable, model) // Bound wrapper passes state to props
}
}
It is also possible to combine props from the bound model with some by-parent injected ones using
BoundWithProps
.
Page initialization
import * as React from 'react';
import * as ReactDOM from 'react-dom';
import {ActionDispatcher, ViewUtils} from 'kombo';
import {init as viewInit} from '../views/todomvc';
import {TodoModel} from '../models/todo';
import { ServerAPI } from '../models/mockapi';
export function init() {
const dispatcher = new ActionDispatcher();
const model = new MyModel(dispatcher);
const viewUtils = new ViewUtils('en_US');
const component = viewInit(dispatcher, viewUtils, model);
ReactDOM.render(
React.createElement(component.TodoTable),
document.getElementById('root-mount')
);
}