Sprockets: Rack-based asset packaging
Sprockets is a Ruby library for compiling and serving web assets.
It features declarative dependency management for JavaScript and CSS
assets, as well as a powerful preprocessor pipeline that allows you to
write assets in languages like CoffeeScript, Sass and SCSS.
Installation
Install Sprockets from RubyGems:
$ gem install sprockets
Or include it in your project’s Gemfile
with Bundler:
gem 'sprockets', '~> 4.0'
Upgrading to Sprockets 4.x
These are the major features in Sprockets 4.x
- Source Maps
- Manifest.js
- ES6 support
- Deprecated processor interface in 3.x is removed in 4.x
Read more about them by referencing Upgrading document
Guides
For most people interested in using Sprockets, you will want to see the README below.
If you are a framework developer that is using Sprockets, see Building an Asset Processing Framework.
If you are a library developer who is extending the functionality of Sprockets, see Extending Sprockets.
If you want to work on Sprockets or better understand how it works read How Sprockets Works
Behavior Overview
You can interact with Sprockets primarily through directives and file extensions. This section covers how to use each of these things, and the defaults that ship with Sprockets.
Since you are likely using Sprockets through another framework (such as the the Rails asset pipeline), there will be configuration options you can toggle that will change behavior such as what directories or files get compiled. For that documentation you should see your framework’s documentation.
Accessing Assets
Assets in Sprockets are always referenced by their logical path.
The logical path is the path of the asset source file relative to its
containing directory in the load path. For example, if your load path
contains the directory app/assets/javascripts
:
Logical path
Source file on disk
application.js
app/assets/javascripts/application.js
models/project.js
app/assets/javascripts/models/project.js
hello.js
app/assets/javascripts/hello.coffee
> Note: For assets that are compiled or transpiled, you want to specify the extension that you want, not the extension on disk. For example we specified hello.js
even if the file on disk is a coffeescript file, since the asset it will generate is javascript.
Directives
Directives are special comments in your asset file and the main way of interacting with processors. What kind of interactions? You can use these directives to tell Sprockets to load other files, or specify dependencies on other assets.
For example, let’s say you have custom JavaScript that you’ve written. You put this javascript in a file called beta.js
. The javascript makes heavy use of jQuery, so you need to load that before your code executes. You could add a require
directive to the top of beta.js
:
//= require jquery $().ready({ // my custom code here })
The directive processor understands comment blocks in three formats:
/* Multi-line comment blocks (CSS, SCSS, JavaScript) *= require foo */
// Single-line comment blocks (SCSS, JavaScript) //= require foo
# Single-line comment blocks (CoffeeScript) #= require foo
> Note: Directives are only processed if they come before any application code. Once you have a line that does not include a comment or whitespace then Sprockets will stop looking for directives. If you use a directive outside of the “header” of the document it will not do anything, and won’t raise any errors.
Here is a list of the available directives:
require
- Add the contents of a file to currentrequire_self
- Change order of where current contents are concatenated to currentrequire_directory
- Add contents of each file in a folder to currentrequire_tree
- Add contents of all files in all directories in a path to currentlink
- Make target file compile and be publicly available without adding contents to currentlink_directory
- Make target directory compile and be publicly available without adding contents to currentlink_tree
- Make target tree compile and be publicly available without adding contents to currentdepend_on
- Recompile current file if target has changeddepend_on_directory
- Recompile current file if any files in target directory has changedstub
- Ignore target file
You can see what each of these does below.
Specifying Processors through File Extensions
Sprockets uses the filename extensions to determine what processors to run on your file and in what order. For example if you have a file:
application.scss
Then Sprockets will by default run the sass processor (which implements scss). The output file will be converted to css.
You can specify multiple processors by specifying multiple file extensions. For example you can use Ruby’s ERB template language to embed content in your doc before running the sass processor. To accomplish this you would need to name your file
application.scss.erb
Processors are run from right to left (tail to head), so in the above example the processor associated with erb
will be run before the processor associated with scss
extension.
For a description of the processors that Sprockets has by default see the “default processors” section below. Other libraries may register additional processors.
When “asking” for a compiled file, you always ask for the extension you want. For example if you’re using Rails, to get the contents of application.scss.erb
you would use
asset_path("application.css")
Sprockets understands that application.scss.erb
will compile down to a application.css
. Ask for what you need, not what you have.
If this isn’t working like you expect, make sure you didn’t typo an extension, and make sure the file is on a “load path” (see framework docs for adding new load paths).
File Order Processing
By default files are processed in alphabetical order. This behavior can impact your asset compilation when one asset needs to be loaded before another.
For example if you have an application.js
and it loads another directory
//= require_directory my_javascript
The files in that directory will be loaded in alphabetical order. If the directory looks like this:
$ ls -1 my_javascript/ alpha.js beta.js jquery.js
Then alpha.js
will be loaded before either of the other two. This can be a problem if alpha.js
uses jquery. For this reason it is not recommend to use require_directory
with files that are ordering dependent. You can either require individual files manually:
//= require jquery //= require alpha //= require beta
Or you can use index files to proxy your folders.
Index files are proxies for folders
In Sprockets index files such as index.js
or index.css
files inside of a folder will generate a file with the folder’s name. So if you have a foo/index.js
file it will compile down to foo.js
. This is similar to NPM’s behavior of using folders as modules. It is also somewhat similar to the way that a file in public/my_folder/index.html
can be reached by a request to /my_folder
. This means that you cannot directly use an index file. For example this would not work:
<%= asset_path("foo/index.js") %>
Instead you would need to use:
<%= asset_path("foo.js") %>
Why would you want to use this behavior? It is common behavior where you might want to include an entire directory of files in a top level JavaScript. You can do this in Sprockets using require_tree .
//= require_tree .
This has the problem that files are required alphabetically. If your directory has jquery-ui.js
and jquery.min.js
then Sprockets will require jquery-ui.js
before jquery
is required which won’t work (because jquery-ui depends on jquery). Previously the only way to get the correct ordering would be to rename your files, something like 0-jquery-ui.js
. Instead of doing that you can use an index file.
For example, if you have an application.js
and want all the files in the foo/
folder you could do this:
//= require foo.js
Then create a file foo/index.js
that requires all the files in that folder in any order you want using relative references:
//= require ./foo.min.js //= require ./foo-ui.js
Now in your application.js
will correctly load the foo.min.js
before foo-ui.js
. If you used require_tree
it would not work correctly.
Cache
Compiling assets is slow. It requires a lot of disk use to pull assets off of hard drives, a lot of RAM to manipulate those files in memory, and a lot of CPU for compilation operations. Because of this Sprockets has a cache to speed up asset compilation times. That’s the good news. The bad news, is that sprockets has a cache and if you’ve found a bug it’s likely going to involve the cache.
By default Sprockets uses the file system to cache assets. It makes sense that Sprockets does not want to generate assets that already exist on disk in public/assets
, what might not be as intuitive is that Sprockets needs to cache “partial” assets.
For example if you have an application.js
and it is made up of a.js
, b.js
, all the way to z.js
//= require a.js //= require b.js # ... //= require z.js
The first time this file is compiled the application.js
output will be written to disk, but also intermediary compiled files for a.js
etc. will be written to the cache directory (usually tmp/cache/assets
).
So, if b.js
changes it will get recompiled. However instead of having to recompile the other files from a.js
to z.js
since they did not change, we can use the prior intermediary files stored in the cached values . If these files were expensive to generate, then this “partial” asset cache strategy can save a lot of time.
Directives such as require
, link
, depend_on
, and depend_on_directory
tell Sprockets what assets need to be re-compiled when a file changes. Files are considered “fresh” based on their mtime on disk and a combination of cache keys.
On Rails you can force a “clean” install by clearing the public/assets
and tmp/cache/assets
directories.
Default Directives
Directives take a path or a path to a file. Paths for directive can be relative to the current file, for example:
//= require ../foo.js
This would load the file up one directory and named foo.js
. However this isn’t required if foo.js
is on one of Sprocket’s load paths. You can simply use
//= require foo.js
Without any prepended dots and sprockets will search for the asset. If the asset is on a sub-path of the load path, you can specify it without using a relative path as well:
//= require sub/path/foo.js
You can also use an absolute path, but this is discouraged unless you know the directory structure of every machine you plan on running code on.
Below is a section for each of the built in directive types supported by Sprockets.
require
require
path inserts the contents of the asset source file
specified by path. If the file is required multiple times, it will
appear in the bundle only once.
Example:
If you’ve got an a.js
:
var a = "A";
and a b.js
;
var b = "B";
Then you could require both of these in an application.js
//= require a.js //= require b.js
Which would generate one concatenated file:
var a = "A"; var b = "B";
require_self
require_self
tells Sprockets to insert the body of the current
source file before any subsequent require
directives.
Example:
If you’ve got an a.js
:
var a = "A";
And an application.js
//= require_self //= require 'a.js' var app_name = "Sprockets";
Then this will take the contents of application.js
(that come after the last require) and put them at the beginning of the file:
var app_name = "Sprockets"; var a = "A";
require_directory
require_directory
path requires all source files of the same
format in the directory specified by path. Files are required in
alphabetical order.
Example:
If we’ve got a directory called alphabet
with an a.js
and b.js
files like before, then our application.js
//= require_directory alphabet
Would produce:
var a = "A"; var b = "B";
You can also see Index files are proxies for folders for another method of organizing folders that will give you more control.
require_tree
require_tree
path works like require_directory
, but operates
recursively to require all files in all subdirectories of the
directory specified by path.
link
link
path declares a dependency on the target path and adds it to a list
of subdependencies to be compiled when the asset is written out to
disk.
Example:
If you’ve got a manifest.js
file and you want to specify that a admin.js
source file should be
generated and made available to the public you can link it by including this in the manifest.js
file:
//= link admin.js
The argument to link
is a logical path, that is it will be resolved according to the
configured asset load paths. See Accessing Assets above. A path relative to
the current file won’t work, it must be a logical path.
Caution: the “link” directive should always have an explicit extension on the end.
link
can also be used to include manifest files from mounted Rails engines:
//= link my_engine_manifest
This would find a manifest file at my_engine/app/assets/config/my_engine_manifest.js
and include its directives.
link_directory
link_directory
path links all the files inside the directory specified by the path. By “link”, we mean they are specified as compilation targets to be written out to disk, and made available to be served to user-agents.
Files in subdirectories will not be linked (Compare to link_tree).
The path argument to link_directory
is not a logical path (it does not use the asset load paths), but is a path relative to the file the link_directory
directive is found in, and can use ..
to . For instance, you might want:
//= link_directory ../stylesheets
link_directory
can take an optional second argument with an extension or content-type, with the
two arguments separated by a space:
//= link_directory ../stylesheets text/css //= link_directory ../more_stylesheets .css
This will limit the matching files to link to only files recognized as that type. An extension is
just a shortcut for the type referenced, it does not need to match the source file exactly, but
instead identifies the content-type the source file must be recognized as.
link_tree
link_tree
path works like link_directory, but operates
recursively to link all files in all subdirectories of the
directory specified by path.
Example:
//= link_tree ./path/to/folder
Like link_directory
, the argument is path relative to the current file, it is not a ‘logical path’ tresolved against load paths.
As with link_directory
, you can also specify a second argument – separated by a space – so any extra files not matching the content-type specified will be ignored:
//= link_tree ./path/to/folder text/javascript //= link_tree ./path/to/other_folder .js
depend_on
depend_on
path declares a dependency on the given path without
including it in the bundle. This is useful when you need to expire an
asset’s cache in response to a change in another file.
Example:
If you have a file such as bar.data
and you’re using data from that file in another file, then
you need to tell sprockets that it needs to re-compile the file if bar.data
changes:
//= depend_on "bar.data" var bar = '<%= File.read("bar.data") %>'
To depend on an entire directory containing multiple files, use depend_on_directory
depend_on_asset
depend_on_asset
path works like depend_on
, but operates
recursively reading the file and following the directives found. This is automatically implied if you use link
, so consider if it just makes sense using link
instead of depend_on_asset
.
depend_on_directory
depend_on_directory
path declares all files in the given path without
including them in the bundle. This is useful when you need to expire an
asset’s cache in response to a change in multiple files in a single directory.
All paths are relative to your declaration and must begin with ./
Also, your must include these directories in your load path.
Example:
If we’ve got a directory called data
with files a.data
and b.data
// ./data/a.data A
// ./data/b.data B
// ./file.js.erb //= depend_on_directory ./data var a = '<% File.read('data/a.data') %>' var b = '<% File.read('data/b.data') %>'
Would produce:
var a = "A"; var b = "B";
You can also see Index files are proxies for folders for another method of organizing folders that will give you more control.
stub
stub
path excludes that asset and its dependencies from the asset bundle.
The path must be a valid asset and may or may not already be part
of the bundle. stub
should only be used at the top level bundle, not
within any subdependencies.
Invoking Ruby with ERB
Sprockets provides an ERB engine for preprocessing assets using
embedded Ruby code. Append .erb
to a CSS or JavaScript asset’s
filename to enable the ERB engine.
For example if you have an app/application/javascripts/app_name.js.erb
you could have this in the template
var app_name = "<%= ENV['APP_NAME'] %>";
Generated files are cached. If you’re using an ENV
var then
when you change then ENV var the asset will be forced to
recompile. This behavior is only true for environment variables,
if you are pulling a value from somewhere else, such as a database,
you must manually invalidate the cache to see the change.
If you’re using Rails, there are helpers you can use such as asset_url
that will cause a recompile if the value changes.
For example if you have this in your application.css
.logo { background: url(<%= asset_url("logo.png") %>) }
When you modify the logo.png
on disk, it will force application.css
to be
recompiled so that the fingerprint will be correct in the generated asset.
You can manually make sprockets depend on any other file that is generated
by sprockets by using the depend_on
or depend_on_directory
directive. Rails
implements the above feature by auto calling depend_on
on the original asset
when the asset_url
is used inside of an asset.
Styling with Sass and SCSS
Sass is a language that compiles to CSS and
adds features like nested rules, variables, mixins and selector
inheritance.
If the sass
gem is available to your application, you can use Sass
to write CSS assets in Sprockets.
Sprockets supports both Sass syntaxes. For the original
whitespace-sensitive syntax, use the extension .sass
. For the
new SCSS syntax, use the extension .scss
.
In Rails if you have app/application/stylesheets/foo.scss
it can
be referenced with <%= asset_path("foo.css") %>
. When referencing
an asset in Rails, always specify the extension you want. Sprockets will
convert foo.scss
to foo.css
.
Scripting with CoffeeScript
CoffeeScript is a
language that compiles to the “good parts” of JavaScript, featuring a
cleaner syntax with array comprehensions, classes, and function
binding.
If the coffee-script
gem is available to your application, you can
use CoffeeScript to write JavaScript assets in Sprockets. Note that
the CoffeeScript compiler is written in JavaScript, and you will need
an ExecJS-supported runtime
on your system to invoke it.
To write JavaScript assets with CoffeeScript, use the extension
.coffee
.
In Rails if you have app/application/javascripts/foo.coffee
it can
be referenced with <%= asset_path("foo.js") %>
. When referencing
an asset in Rails, always specify the extension you want. Sprockets will
convert foo.coffee
to foo.js
.
ES6 Support
Sprockets 4 ships with a Babel processor. This allows you to transpile ECMAScript6 to JavaScript just like you would transpile CoffeeScript to JavaScript. To use this, modify your Gemfile:
gem 'babel-transpiler'
Any asset with the extension es6
will be treated as an ES6 file:
// app/assets/javascript/application.es6 var square = (n) => n * n console.log(square);
Start a Rails server in development mode and visit localhost:3000/assets/application.js
, and this asset will be transpiled to JavaScript:
var square = function square(n) { return n * n; }; console.log(square);
JavaScript Templating with EJS and Eco
Sprockets supports JavaScript templates for client-side rendering of
strings or markup. JavaScript templates have the special format
extension .jst
and are compiled to JavaScript functions.
When loaded, a JavaScript template function can be accessed by its
logical path as a property on the global JST
object. Invoke a
template function to render the template as a string. The resulting
string can then be inserted into the DOM.
<div>Hello, <span><%= name %></span>!</div> // application.js //= require templates/hello $("#hello").html(JST["templates/hello"]({ name: "Sam" }));
Sprockets supports two JavaScript template languages:
EJS, for embedded
JavaScript, and Eco, for
embedded CoffeeScript. Both languages use the familiar <% … %>
syntax for embedding logic in templates.
If the ejs
gem is available to your application, you can use EJS
templates in Sprockets. EJS templates have the extension .jst.ejs
.
If the eco
gem is available to your application, you can use Eco
templates in Sprockets. Eco
templates have the extension .jst.eco
. Note that the eco
gem
depends on the CoffeeScript compiler, so the same caveats apply as
outlined above for the CoffeeScript engine.
Minifying Assets
Several JavaScript and CSS minifiers are available through shorthand.
In Rails you will specify them with:
config.assets.js_compressor = :terser config.assets.css_compressor = :scss
If you’re not using Rails, configure this directly on the “environment”.
environment.js_compressor = :terser environment.css_compressor = :scss
If you are using Sprockets directly with a Rack app, don’t forget to add
the terser
and sass
gems to your Gemfile when using above options.
Gzip
By default when Sprockets generates a compiled asset file it will also produce a gzipped copy of that file. Sprockets only gzips non-binary files such as CSS, javascript, and SVG files.
For example if Sprockets is generating
application-12345.css
Then it will also generate a compressed copy in
application-12345.css.gz
This behavior can be disabled, refer to your framework specific documentation.
Serving Assets
In production you should generate your assets to a directory on disk and serve them either via Nginx or a feature like Rail’s config.public_file_server.enabled = true
.
On Rails you can generate assets by running:
$ RAILS_ENV=production rake assets:precompile
In development Rails will serve assets from Sprockets::Server
.
Contributing to Sprockets
Sprockets is the work of hundreds of contributors. You’re encouraged to submit pull requests, propose
features and discuss issues.
See CONTRIBUTING.
Version History
Please see the CHANGELOG
License
Sprockets is released under the MIT License.