# effectOn
Allows you to declare an effect within your model which will execute every time the targeted state changes. Think of it as a thunk that automatically fires when specific state changes.
# API
The effectOn
function is described below.
# Arguments
stateResolvers
(Array<Function>)State resolvers allows you to isolate the specific parts of your state that your effect will track. Each state resolver function receives the following arguments:
state
(Object)The local state against which your effectOn property is bound.
storeState
(Object)The entire store state
handler
(Function, required)The
handler
that will execute the desired effect. It can be asynchronous, and receives the following arguments:actions
(Object)The actions that are local to the thunk. This allows you to dispatch an action to update state should you require.
change
(Object)Represents the change that took place, causing the effect to run. It contains the following properties:
prev
(Array<any>)The previous state that was mapped by your
stateResolvers
.current
(Array<any>)The current state that was mapped by your
stateResolvers
after the change in state occurred.action
(Object)An object representing information about the action that caused the change. It contains the following properties:
type
(string)The action identifer.
payload
(any)The payload, if there was one, that was attached to the action.
helpers
(Object)Helpers which may be useful for more advanced effect implementations. The object contains the following properties:
dispatch
(Function)The Redux dispatch function, allowing you to dispatch "standard" Redux actions.
getState
(Function)When executed it will provide the state that is local to the thunk.
Note: whilst you are able to access the store's state via this API your effect should not perform any mutation of this state. That would be considered an anti-pattern. All state updates must be contained within actions. This API exists within a thunk purely for convenience sake - allowing you to perform logic based on the existing state.
getStoreActions
(Function)When executed it will get the actions across your entire store.
We don't recommend dispatching actions like this, and invite you to consider creating an actionOn or thunkOn listener instead.
getStoreState
(Function)When executed it will provide the entire state of your store.
Note: whilst you are able to access the store's state via this API your thunk should not perform any mutation of this state. That would be considered an anti pattern. All state updates must be contained within actions. This API exists within a thunk purely for convenience sake - allowing you to perform logic based on the existing state.
injections
(Any, default=undefined)Any dependencies that were provided to the
createStore
configuration will be exposed via this argument. See the StoreConfig documentation on how to provide them to your store.meta
(Object)This object contains meta information related to the thunk. Specifically it contains the following properties:
parent (Array)
An array representing the path of the parent against which the thunk was attached within your model.
path (Array)
An array representing the full path to the thunk based on where it was attached within your model.
The
handler
allows you to return adispose
function. Thedispose
function can be asynchronous or synchronous and will be executed prior to the next execution. Please read the docs on this feature.
# Tutorial
# Introduction
Two arguments are provided to effectOn; namely the
stateResolvers
and the handler
. The stateResolvers
are an array of
functions which should resolve the target state that should be tracked. When the
tracked state changes the handler
function is executed..
The handler
can be asynchronous or synchronous. It receives the
store actions, a change
object containing the prev
values for the targeted state and the current
values as well as the action
that caused the change in state. It additionally receives a helper
argument
allowing you to access the store state etc.
The handler
additionally allows you to return a dispose function, which will
be executed prior to the next execution of the handler
. This can be useful in
performing things like API call cancellation etc.
import { effectOn } from 'easy-peasy';
const todosModel = {
items: [],
saving: false,
setSaving: action((state, payload) => {
state.saving = payload;
}),
effectOn(
// Provide an array of "stateResolvers" to resolve the targeted state:
[state => state.items],
// Provide a handler which will execute every time the targeted state changes:
async (actions, change) => {
const [items] = change.current;
actions.setSaving(true);
await todosService.save(items);
actions.setSaving(false);
}
)
};
# Execution behaviour
In regards to the execution of your effect; should the targeted state change multiple times your effect will be executed for each state change. This means that it is possible to have multiple executions of your effect running concurrently, especially in the case of long running asynchronous effects.
Each effect execution will not wait for any prior executions to complete. Should you desire something like this you could look to implement a debounce (opens new window) within your effect handler.
Alternatively, you could make use of the dispose in order to clean up effect executions should a new execution begin. Please read the docs on this feature.
# How state changes are determined
Strict equality checking is used (i.e. prevState === currentState
) when
determining if the targeted state has changed.
It is important you resolve the actual state from your store, and don't create additional wrapper objects/arrays within the state resolvers. If you did so it would break the strict equality checking, causing your effects to run for every change to the store.
This anti-pattern can be illustrated below:
const myModel = {
one: 'one',
two: 'two',
effectOn(
[
(state) => {
// This is an anti-pattern. You are returning a new object instance
// for every execution. This will result in the effect running for
// _every_ state change.
// 👇
return {
one: state.one,
two: state.two
};
}
],
(actions, change) => {
console.log('I run for every change to the store!');
}
)
};
Instead you should resolve each piece of state individually:
const myModel = {
one: 'one',
two: 'two',
effectOn(
[
// 👍
(state) => state.one,
(state) => state.two
],
(actions, change) => {
console.log('I only run when "one" or "two" have changed');
}
)
};
# Utilising a dispose function
An effect can return a dispose
function, which will be executed should a newer
execution of the effect occur due to another state change and the previous
effect execution has not yet completed. This provides a mechanism by which you
can clean up resource hooks or cancel API calls.
import { effectOn } from 'easy-peasy';
const todosModel = {
items: [],
effectOn(
[state => state.items],
(actions, change) => {
const [items] = change.current;
const request = todosService.save(items);
// Return a dispose function to abort the current save call prior to
// executing the handler again.
// 👇
return () => request.abort();
}
)
};
The dispose
function must always be return synchronously from your
effect, whilst the effect can still execution asynchronous code internally.
This restriction allows us to execute your dispose
function as early as
possible should a new effect execution begin. The example below illustrates the
anti-pattern of resolving the dispose
asynchronously.
effectOn(
[(state) => state.items],
// We are using async/await, therefore our dispose is now resolved
// asynchronously via the implicitly returned Promise.
// 👇
async (actions, change) => {
const [items] = change.current;
const request = await todosService.save(items);
return () => request.abort();
},
);
Also note in the above example that as we are awaiting on the
todosService.save
call it will always be resolved prior to the dispose being
returned.
# Limitations
- Effects cannot be dispatched directly - e.g. the
useStoreActions
hook will not include effects. - Effect execution timing is not guaranteed. It's best to consider them as asynchronous operations where you are unable to attach external logic against their resolution.