require('modules')
in the browser
Use a node-style require()
to organize your browser code
and load modules installed by npm.
browserify will recursively analyze all the require()
calls in your app in
order to build a bundle you can serve up to the browser in a single <script>
tag.
Whip up a file, main.js
with some require()s
in it. You can use relative
paths like './foo'
and '../lib/bar'
or module paths like 'gamma'
that will
search node_modules/
using
node's module lookup algorithm.
var foo = require('./foo');
var bar = require('../lib/bar');
var gamma = require('gamma');
var elem = document.getElementById('result');
var x = foo(100) + bar('baz');
elem.textContent = gamma(x);
Now just use the browserify
command to build a bundle starting at main.js
:
$ browserify main.js > bundle.js
All of the modules that entry.js
needs are included in the bundle.js
from a
recursive walk of the require()
graph using
required.
To use this bundle, just toss a <script src="bundle.js"></script>
into your
html!
You can just as easily create bundle that will export a require()
function so
you can require()
modules from another script tag. Here we'll create a
bundle.js
with the through
and duplexer modules.
$ browserify -r through -r duplexer > bundle.js
Then in your page you can do:
<script src="bundle.js"></script>
<script>
var through = require('through');
var duplexer = require('duplexer');
/* ... */
</script>
If browserify finds a require
function already defined in the page scope, it
will fall back to that function if it didn't find any matches in its own set of
bundled modules.
In this way you can use browserify to split up bundles among multiple pages to
get the benefit of caching for shared, infrequently-changing modules, while
still being able to use require()
. Just use a combination of --external
and
--require
to factor out common dependencies.
For example, if a website with 2 pages, beep.js
:
var robot = require('./robot');
console.log(robot('beep'));
and boop.js
:
var robot = require('./robot');
console.log(robot('boop'));
both depend on robot.js
:
module.exports = function (s) { return s.toUpperCase() + '!' };
$ browserify -r ./robot > static/common.js
$ browserify -x ./robot.js beep.js > static/beep.js
$ browserify -x ./robot.js boop.js > static/boop.js
Then on the beep page you can have:
<script src="common.js"></script>
<script src="beep.js"></script>
while the boop page can have:
<script src="common.js"></script>
<script src="boop.js"></script>
Usage: browserify [entry files] {OPTIONS}
Standard Options:
--outfile, -o Write the browserify bundle to this file.
If unspecified, browserify prints to stdout.
--require, -r A module name or file to bundle.require()
Optionally use a colon separator to set the target.
--entry, -e An entry point of your app
--ignore, -i Omit a file from the output bundle.
--external, -x Reference a file from another bundle.
--transform, -t Use a transform module on top-level files.
--command, -c Use a transform command on top-level files.
--help, -h Show this message
Advanced Options:
--insert-globals, --ig, --fast [default: false]
Skip detection and always insert definitions for process, global,
__filename, and __dirname.
benefit: faster builds
cost: extra bytes
--detect-globals, --dg [default: true]
Detect the presence of process, global, __filename, and __dirname and define
these values when present.
benefit: npm modules more likely to work
cost: slower builds
--ignore-missing, --im [default: false]
Ignore `require()` statements that don't resolve to anything.
Specify a parameter.
Many npm modules that don't do IO will just work after being browserified. Others take more work.
Many node built-in modules have been wrapped to work in the browser, but only
when you explicitly require()
or use their functionality.
When you require()
any of these modules, you will get a browser-specific shim:
Additionally if you use any of these variables, they will be defined in the bundled output in a browser-appropriate way:
- process
- global - top-level scope object (window)
- __filename - file path of the currently executing file
- __dirname - directory path of the currently executing file
var browserify = require('browserify')
Create a browserify instance b
from the entry main files
.
files
can be an array of files or a single file.
Add an entry file from file
that will be executed when the bundle loads.
Make name
available from outside the bundle with require(name)
.
The package name
is anything that can be resolved by require.resolve()
.
Bundle the files and their dependencies into a single javascript file.
Return a readable stream with the javascript file contents or
optionally specify a cb(err, src)
to get the buffered results.
When opts.insertGlobals
is true, always insert process
, global
,
__filename
, and __dirname
without analyzing the AST for faster builds but
larger output bundles. Default false.
When opts.detectGlobals
is true, scan all files for process
, global
,
__filename
, and __dirname
, defining as necessary. With this option npm
modules are more likely to work but bundling takes longer. Default true.
Prevent file
from being loaded into the current bundle, instead referencing
from another bundle.
Prevent the module name or file at file
from showing up in the output bundle.
Transform source code before parsing it for require()
calls with the transform
function or module name tr
.
If tr
is a function, it will be called with tr(file)
and it should return a
through-stream
that takes the raw file contents and produces the transformed source.
If tr
is a string, it should be a module name or file path of a
transform module
with a signature of:
var through = require('through');
module.exports = function (file) { return through() };
You don't need to necessarily use the through module, this is just a simple example.
Here's how you might compile coffee script on the fly using .transform()
:
var coffee = require('coffee-script');
var through = require('through');
b.transform(function (file) {
var data = '';
return through(write, end);
function write (buf) { data += buf }
function end () {
this.queue(coffee.compile(data));
this.queue(null);
}
});
Note that on the command-line with the -c
flag you can just do:
$ browserify -c 'coffee -sc' main.coffee > bundle.js
Or better still, use the coffeeify module:
$ npm install coffeeify
$ browserify -t coffeeify main.coffee > bundle.js
browserify uses the package.json
in its module resolution algorithm just like
node, but there is a special
"browsers" field you can set to override file
resolution for browser-specific versions.
You can specify source transforms in the package.json in the browserify.transforms field. There is more information about how source transforms work in package.json on the module-deps readme.
Here is a list of known source transforms:
-
brfs - inline
fs.readFileSync()
calls with file contents -
coffeeify - compile
.coffee
files to javascript automatically
With npm do:
npm install -g browserify
MIT