Mutate a copy of data without changing the original source
Setup via NPM
npm install immutability-helper --save
This is a drop-in replacement for react-addons-update
:
// import update from 'react-addons-update';
import update from 'immutability-helper';
const state1 = ['x'];
const state2 = update(state1, {$push: ['y']}); // ['x', 'y']
Note that this module has nothing to do with React. However, since this module is most commonly used with React, the docs will focus on how it can be used with React.
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 fastshouldComponentUpdate()
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 React’s
Using Immutable Data Structures 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()
provides simple syntactic sugar around this pattern to make writing
this code easier. This code becomes:
import update from 'immutability-helper';
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.
{$push: array}
push()
all the items inarray
on the target.{$unshift: array}
unshift()
all the items inarray
on the target.{$splice: array of arrays}
for each item inarrays
callsplice()
on the target with the parameters provided by the item. Note: The items in the array are applied sequentially, so the order matters. The indices of the target may change during the operation.{$set: any}
replace the target entirely.{$toggle: array of strings}
toggles a list of boolean fields from the target object.{$unset: array of strings}
remove the list of keys inarray
from the target object.{$merge: object}
merge the keys ofobject
with the target.{$apply: function}
passes in the current value to the function and updates it with the new returned value.{$add: array of objects
add a value to aMap
orSet
. When adding to aSet
you pass in an array of objects to add, when adding to a Map, you pass in[key, value]
arrays like so:update(myMap, {$add: [['foo', 'bar'], ['baz', 'boo']]})
{$remove: array of strings
remove the list of keys in array from aMap
orSet
.
const initialArray = [1, 2, 3];
const newArray = update(initialArray, {$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}
Arrays can be indexed into with runtime variables via the ES2015 Computed Property Names feature. An object property name expression may be wrapped in brackets [] which will be evaluated at runtime to form the final property name.
const collection = {children: ['zero', 'one', 'two']};
const index = 1;
const newCollection = update(collection, {children: {[index]: {$set: 1}}});
// => {children: ['zero', 1, 'two']}
Autovivification is the auto creation of new arrays and objects when needed. In the context of javascript that would mean something like this
const state = {}
state.a.b.c = 1; // state would equal { a: { b: { c: 1 } } }
Since javascript doesn't have this "feature", the same applies to
immutability-helper
. The reason why this is practically impossible in
javascript and by extension immutability-helper
is the following:
var state = {}
state.thing[0] = 'foo' // What type should state.thing have? Should it be an object or array?
state.thing2[1] = 'foo2' // What about thing2? This must be an object!
state.thing3 = ['thing3'] // This is regular js, this works without autovivification
state.thing3[1] = 'foo3' // Hmm, notice that state.thing2 is an object, yet this is an array
state.thing2.slice // should be undefined
state.thing2.slice // should be a function
If you need to set something deeply nested and don't want to have to set each layer down the line, consider using this technique which is shown with a contrived example:
var state = {}
var desiredState = {
foo: [
{
bar: ['x', 'y', 'z']
},
],
};
var state2 = update(state, {
foo: {$apply: foo =>
update(foo || [], {
0: {$apply: fooZero =>
update(fooZero || {}, {
bar: {$apply: bar =>
update(bar || [], {$push: ['x', 'y', 'z']})
}
})
}
})
}
})
console.log(JSON.stringify(state2) === JSON.stringify(desiredState)) // true
// note that state could have been declared as any of the following and it would still output true:
// var state = { foo: [] }
// var state = { foo: [ {} ] }
// var state = { foo: [ {bar: []} ] }
You can also choose to use the extend functionality to add an $auto
and
$autoArray
command:
update.extend('$auto', function(value, object) {
return object ?
update(object, value):
update({}, value);
});
update.extend('$autoArray', function(value, object) {
return object ?
update(object, value):
update([], value);
});
var state = {}
var desiredState = {
foo: [
{
bar: ['x', 'y', 'z']
},
],
};
var state2 = update(state, {
foo: {$autoArray: {
0: {$auto: {
bar: {$autoArray: {$push: ['x', 'y', 'z']}}
}}
}}
});
console.log(JSON.stringify(state2) === JSON.stringify(desiredState)) // true
The main difference this module has with react-addons-update
is that
you can extend this to give it more functionality:
update.extend('$addtax', function(tax, original) {
return original + (tax * original);
});
const state = { price: 123 };
const withTax = update(state, {
price: {$addtax: 0.8},
});
assert(JSON.stringify(withTax) === JSON.stringify({ price: 221.4 }));
Note that original
in the function above is the original object, so if you
plan making a mutation, you must first shallow clone the object. Another option
is to use update
to make the change
return update(original, { foo: {$set: 'bar'} })
If you don't want to mess around with the globally exported update
function
you can make a copy and work with that copy:
import { newContext } from 'immutability-helper';
const myUpdate = newContext();
myUpdate.extend('$foo', function(value, original) {
return 'foo!';
});