Note:
update
is a legacy add-on. Use kolodny/immutability-helper instead.
Importing
import update from 'react-addons-update'; // ES6
var update = require('react-addons-update'); // ES5 with npm
var update = React.addons.update; // ES5 with react-with-addons.js
React lets you use whatever style of data management you want, including mutation. However, if you can use immutable data in performance-critical parts of your application it's easy to implement a fast shouldComponentUpdate()
method to significantly speed up your app.
Dealing with immutable data in JavaScript is more difficult than in languages designed for it, like Clojure. However, we've provided a simple immutability helper, update()
, that makes dealing with this type of data much easier, without fundamentally changing how your data is represented. You can also take a look at Facebook's Immutable-js and the Advanced Performance section for more detail on Immutable-js.
If you mutate data like this:
myData.x.y.z = 7;
// or...
myData.a.b.push(9);
You have no way of determining which data has changed since the previous copy has been overwritten. Instead, you need to create a new copy of myData
and change only the parts of it that need to be changed. Then you can compare the old copy of myData
with the new one in shouldComponentUpdate()
using triple-equals:
const newData = deepCopy(myData);
newData.x.y.z = 7;
newData.a.b.push(9);
Unfortunately, deep copies are expensive, and sometimes impossible. You can alleviate this by only copying objects that need to be changed and by reusing the objects that haven't changed. Unfortunately, in today's JavaScript this can be cumbersome:
const newData = extend(myData, {
x: extend(myData.x, {
y: extend(myData.x.y, {z: 7}),
}),
a: extend(myData.a, {b: myData.a.b.concat(9)})
});
While this is fairly performant (since it only makes a shallow copy of log n
objects and reuses the rest), it's a big pain to write. Look at all the repetition! This is not only annoying, but also provides a large surface area for bugs.
update()
update()
provides simple syntactic sugar around this pattern to make writing this code easier. This code becomes:
import update from 'react-addons-update';
const newData = update(myData, {
x: {y: {z: {$set: 7}}},
a: {b: {$push: [9]}}
});
While the syntax takes a little getting used to (though it's inspired by MongoDB's query language) there's no redundancy, it's statically analyzable and it's not much more typing than the mutative version.
The $
-prefixed keys are called commands. The data structure they are "mutating" is called the target.
{$push: array}
push()
all the items in array
on the target.{$unshift: array}
unshift()
all the items in array
on the target.{$splice: array of arrays}
for each item in arrays
call splice()
on the target with the parameters provided by the item.{$set: any}
replace the target entirely.{$merge: object}
merge the keys of object
with the target.{$apply: function}
passes in the current value to the function and updates it with the new returned value.const initialArray = [1, 2, 3];
const newArray = update(initialArray, {$push: [4]}); // => [1, 2, 3, 4]
initialArray
is still [1, 2, 3]
.
const collection = [1, 2, {a: [12, 17, 15]}];
const newCollection = update(collection, {2: {a: {$splice: [[1, 1, 13, 14]]}}});
// => [1, 2, {a: [12, 13, 14, 15]}]
This accesses collection
's index 2
, key a
, and does a splice of one item starting from index 1
(to remove 17
) while inserting 13
and 14
.
const obj = {a: 5, b: 3};
const newObj = update(obj, {b: {$apply: function(x) {return x * 2;}}});
// => {a: 5, b: 6}
// This is equivalent, but gets verbose for deeply nested collections:
const newObj2 = update(obj, {b: {$set: obj.b * 2}});
const obj = {a: 5, b: 3};
const newObj = update(obj, {$merge: {b: 6, c: 7}}); // => {a: 5, b: 6, c: 7}