Use
@avaragado/xstateful
with React, accessing states and activities from multiple statecharts anywhere in your app
See https://codesandbox.io/s/6lyq0yl4rz for a full example, simulating UK-style traffic lights and a pedestrian crossing (the source is in the examples/pelican
directory).
- Provider/consumer model Call a function to create React components from an
XStateful
instance. Add the provider near the app root, and use consumers lower down the tree to access machine state and extended state. - Specialised consumer components Use declarative components that render based on machine activities, machine state, or any function.
- Familiar props Consumer components accept
component
prop,render
prop, function-as-child, or child nodes, very similar toreact-router
. - Lifecycle helper A special component lets you "set up" and "tear down" a machine on mount/unmount if you need to.
- React 16.3+ (uses React's new "context" functionality)
The @avaragado/xstateful
package is a self-contained interpreter for statecharts, wrapping xstate
and adding support for reducers, extended state, and time-based events. xstateful
itself doesn't render anything.
xstateful-react
works with xstateful
to let you render React components based on your statechart, and trigger state transitions.
Terms are as used in xstateful
, plus common terms in React development such as render props, function-as-child, and the provider/consumer pattern of React Context.
$ yarn add xstate @avaragado/xstateful @avaragado/xstateful-react
$ # or
$ npm install xstate @avaragado/xstateful @avaragado/xstateful-react
In summary:
- Use
xstateful
to create anXStateful
instance (either instantiatingXStateful
directly, or by callingcreateStatefulMachine
). - Call the
xstateful-react
functioncreateReactMachine
, passing yourXStateful
instance. This function returns a number of components (a provider and several consumers). - Add the provider component somewhere near the root of your app.
- Add the consumer components as necessary as direct or indirect descendants of the provider.
- Add the control component if needed to set up/tear down your machine at the right places in your app.
Use one module to export an XStateful
instance and the React components generated by xstateful-react
. You can test the XStateful
instance in isolation, without worrying about particular rendering environments.
// my-react-machine.js
import { Machine } from 'xstate';
import { createStatefulMachine } from '@avaragado/xstateful';
import { createReactMachine } from '@avaragado/xstateful-react';
const machine = Machine({
// xstate machine configuration
});
const reducer = ... // if needed
const extstate = ... // if needed
export const xsf = createStatefulMachine({ machine, reducer, extstate });
export default createReactMachine(xsf);
Near the root of the render tree, add the provider component (it accepts no props). It doesn't have to look exactly like this: as long as the provider is an ancestor of all the consumers, it's fine.
The object returned by createReactMachine
is a general-purpose consumer component, described in full below. It has properties for the other, more specialised consumers, plus a property for the provider, and one for the control component. This structure is intended to "read well" to aid understanding when inspecting a component tree.
// my-root.jsx
import React from 'react';
import ReactDOM from 'react-dom';
import MyApp from './my-app';
import MyReactMachine from './my-react-machine';
ReactDOM.render(
<MyReactMachine.Provider>
<MyApp />
</MyReactMachine.Provider>,
document.getElementById('root'),
);
Lower down the render tree, render the consumer components. They all accept component
, render
and children
props that work almost identically to react-router
. They also nest, with predictable results. Full descriptions of each component are below – this example component just shows a few options.
// my-random-component.jsx
import React from 'react';
import MyReactMachine from './my-react-machine';
const MyRandomComponent = () => (
<div>
<p>Blah...</p>
{/* the main component renders according to a function of state and extended state */}
<MyReactMachine
cond={({ state, extstate }) =>
state.value === 'boink' && extstate.foo === 'bar'
}
>
<p>Rendered if cond evaluates to true</p>
</MyReactMachine>
{/* the .Activity component renders according to current machine activities */}
<MyReactMachine.Activity is="pending">
Loading...
</MyReactMachine.Activity>
<MyReactMachine.Activity is={['error', 'timeout']}>
Something went wrong
</MyReactMachine.Activity>
{/* the .State component renders according to current machine state value */}
<MyReactMachine.State is="a.b.c"> ... </MyReactMachine.State>
<MyReactMachine.State is={['a.b.c', 'a.b.d']}>...</MyReactMachine.State>
</div>
);
export default MyRandomComponent;
Some XStateful
machines may need special "set up" and "tear down" behaviour. For example, consider a machine that sends an event on a periodic timer when it's in a particular state. This machine keeps sending that event even when it's not mounted in the component tree, for as long as it remains in this state. (This is because the XStateful
instance is decoupled from React.)
This might be what's needed for an app: every app is different. Some apps might instead want to "power down" a machine when it's not mounted. Use the Control
component to do this.
// my-other-component.jsx
import React from 'react';
import MyReactMachine from './my-react-machine';
const MyOtherComponent = () => (
<MyReactMachine.Control
onDidMount={({ transition }) => transition('POWER_ON');}
onWillUnmount={({ transition }) => transition('POWER_OFF');}
>
...other components, including consumer components from MyReactMachine
</MyReactMachine.Control
);
export default MyOtherComponent;
import { createReactMachine } from '@avaragado/xstateful-react';
Returns a general-purpose React consumer component (let's call it Machine
) tied to the input XStateful
instance. Machine
holds other components, as properties Activity
, State
, Provider
and Control
.
This is a React component that gives access to values from Machine.Provider
rendered higher in the tree. Use these values, through props, to determine whether to render other components.
Machine
props:
cond?: boolean | (({ state, extstate }) => boolean)
component?: React.ComponentType<{ state, extstate, init, transition, setExtState }>
render?: ({ state, extstate, init, transition, setExtState }) => React.Node
children?: React.Node | ({ state, extstate, init, transition, setExtState, match }) => React.Node
The arguments/props state
, extstate
, init
, transition
and setExtState
correspond to the XStateful
instance: state
contains machine state, extstate
contains extended state, init
is a function to initialise or reset the machine, transition
is a function to send an event to the machine, and setExtState
is a function to update extended state.
If more than one of component
, render
and children
are specified, component
takes precedence over render
, and render
takes precedence over children
.
The boolean value from cond
(which defaults to true
if cond
is omitted), combined with component
/render
/children
, define what's rendered.
- With
component
:- When
cond
is true, creates a React element from that component, passing the propsstate
,extstate
,init
,transition
andsetExtState
, and renders that. - When
cond
is false, rendersnull
.
- When
- With
render
:- When
cond
is true, calls the render prop function passing a single object arg{ state, extstate, init, transition, setExtState }
and renders the result. - When
cond
is false, rendersnull
.
- When
- With
children
nodes (not function-as-child form):- When
cond
is true, renders the children. - When
cond
is false, rendersnull
.
- When
- With
children
function:- Calls the function, passing a single object arg
{ state, extstate, init, transition, setExtState, match }
, wherematch
is the boolean result ofcond
, and renders the result.
- Calls the function, passing a single object arg
Examples:
<Machine cond={other_value_in_scope}>
<p>Rendered only if cond value is true</p>
</Machine>
<Machine cond={mc => mc.extstate.foo === 123}>
<p>Rendered only if cond evaluates to true</p>
</Machine>
<Machine cond={mc => mc.extstate.foo === 123}>
{({ match }) => (
<p>Rendered always, cond result is in match</p>
)}
</Machine>
<Machine
cond={mc => mc.state.actions.length === 0}
component={RenderedOnlyIfCondTrue}
/>
<Machine
cond={mc => otherfunction(mc, othervalue)}
render={
({ state }) => (<p>rendered only if cond true</p>)
}
/>
<Machine>
{({ state, extstate, init, transition, setExtState }) => {
// render something!
}}
</Machine>
This is a React component that sprinkles some sugar over Machine
, focusing on the activities emitted by the statechart.
Machine.Activity
props:
is?: string | Array<string> | (({ [activity: string]: boolean }) => boolean)
not?: string | Array<string> | (({ [activity: string]: boolean }) => boolean)
component?: React.ComponentType<{ state, extstate, init, transition, setExtState }>
render?: ({ state, extstate, init, transition, setExtState }) => React.Node
children?: React.Node | ({ state, extstate, init, transition, setExtState, match }) => React.Node
The is
and not
props check against the statechart's current activities.
is="foo"
matches if the string is a current activity.not="foo"
matches if the string is not a current activity.is={['foo', 'bar']}
matches if any of the array members is a current activity.not={['foo', 'bar']}
matches if none of the array members is a current activity.is={myFunction}
matches if the function, when passed an object{ [activity: string]: boolean }
describing the statechart's current activities, returns true.not={myFunction}
matches if the function, when passed an object{ [activity: string]: boolean }
describing the statechart's current activities, returns false.
The boolean result of the match feeds in to the component
, render
and children
props as described above for Machine
.
Examples:
<Machine.Activity is="buzzing">
<p>Power is on!</p>
</Machine.Activity>
<Machine.Activity
not={['fizzing', 'buzzing']}
component={MostlyHarmless}
/>
<Machine.Activity is="open">
{({ match }) => (
<p>match is true if activity "open" is current, false otherwise</p>
)}
</Machine.Activity>
This is a React component that sprinkles some sugar over Machine
, focusing on the current state(s) of the statechart.
Machine.State
props:
is?: string | Array<string> | (({ [activity: string]: boolean }) => boolean)
not?: string | Array<string> | (({ [activity: string]: boolean }) => boolean)
component?: React.ComponentType<{ state, extstate, init, transition, setExtState }>
render?: ({ state, extstate, init, transition, setExtState }) => React.Node
children?: React.Node | ({ state, extstate, init, transition, setExtState, match }) => React.Node
The is
and not
props check against the statechart's current states.
is="foo"
matches if the string is a current state.not="foo"
matches if the string is not a current state.is={['foo', 'bar']}
matches if any of the array members is a current state.not={['foo', 'bar']}
matches if none of the array members is a current state.is={myFunction}
matches if the function, when passed anxstate
state value, returns true.not={myFunction}
matches if the function, when passed anxstate
state value, returns false.
The state check uses the xstate
utility matchesState
, and supports parallel and nested states. For example, if the statechart is currently in states a.b.c
and a.b.d
, then a check is="a.b"
will match.
The boolean result of the match feeds in to the component
, render
and children
props as described above for Machine
.
Examples:
<Machine.State is="idle">
<p>Waiting for input</p>
</Machine.State>
<Machine.State
not={['a.b', 'a.c']}
render={({ exstate }) => (
<Something val={extstate.foo} />
)}
/>
<Machine.State is={someComplexFunctionOfStateValue}>
{({ match }) => (
<p>match is boolean result of function</p>
)}
</Machine.State>
This React component holds the link to the XStateful
instance for the statechart. It provides current machine state and extended state values, and functions to send events, to all related consumer components (Machine
, Machine.Activity
, Machine.State
) rendered as descendants in the render tree.
No props.
This React component includes two props that map to React lifecycle methods. Use these props to initialise and/or send events to the statechart when the React component mounts and/or unmounts. Not all apps need to use it.
Machine.Control
props:
onDidMount?: ({ state, extstate, init, transition, setExtState }) => void
onWillUnmount?: ({ state, extstate, init, transition, setExtState }) => void
children: React.Node
The arguments/props state
, extstate
, init
, transition
and setExtState
correspond to the XStateful
instance: state
contains machine state, extstate
contains extended state, init
is a function to initialise or reset the machine, transition
is a function to send an event to the machine, and setExtState
is a function to update extended state.
The component always renders its children.
The component calls the onDidMount
function in its own componentDidMount
lifecycle method, and onWillUnmount
in its own componentWillUnmount
lifecycle method.
Examples:
<Machine.Control onDidMount={({ init }) => init()}>
...
</Machine.Control>
<Machine.Control
onDidMount={({ transition }) => transition('POWER_ON')}
onWillUnmount={({ transition }) => transition('POWER_OFF')}
>
...
</Machine.Control>
xstate
, by David Khourshidreact-finite-machine
, by Derek Duncanreact-automata
, by Michele Bertoli
David Smith (@avaragado)
Bug reports, feature requests and PRs are gratefully received. Add an issue or submit a PR.
Please note that this project is released with a Contributor Code of Conduct. By participating in this project you agree to abide by its terms.
Thanks goes to these wonderful people (emoji key):
David Smith 📖 💻 |
ShMcK 📖 |
---|
This project follows the all-contributors specification. Contributions of any kind welcome!
The package.json
file contains all the usual scripts for linting, testing, building and releasing.
Buzzwords: prettier, eslint, flow, flow-typed, babel, jest, rollup, react.
When merging to master Squash and Merge.
In the commit message, follow conventional-changelog-standard conventions
When ready to release to npm:
git checkout master
git pull origin master
yarn release:dryrun
yarn release
- Engage pre-publication paranoia
git push --follow-tags origin master
npm publish
- not yarn here as yarn doesn't seem to respect publishConfig
MIT © David Smith