Injectable
Injectable
is an opinionated and declarative Dependency Injection library for ruby.
It is being used in production (under ruby 3.1) in RubiconMD and was extracted from its codebase.
Installation
Add this line to your application's Gemfile:
gem 'injectable', '>= 1.0.0'
And then execute:
$ bundle
Or install it yourself as:
$ gem install injectable
Motivation
The main motivation of Injectable
is to ease compliance with SOLID's*, SRP* and Dependency Inversion principle by providing a declarative and very readable DSL* which avoids lots of bolierplate code and thus encourages good practices.*
*Sorry about the acronyms, but using an Ubiquitous Language is important.
Encapsulate domain logic
Using Ruby on Rails recommended practices as an example, when your application grows enough you usually end up with huge model classes with too many responsibilities.
It's way better (although it requires effort and discipline) to split those models and extract domain logic into Service Objects ("SOs" from now on). You can do this without Injectable
, but Injectable
will make your SOs way more readable and a pleasure not only to write but also to test, while encouraging general good practices.
Avoiding to hardcode dependencies
If you find occurences of SomeClass.any_instance.expects(:method)
in your unit tests, then you are probably hardcoding dependencies:
test "MyClass#call"
Collaborator.any_instance.expects(:submit!) # hardcoded dependency
MyClass.new.call
end
class MyClass
attr_reader :collaborator
def initialize
@collaborator = Collaborator.new
end
def call
collaborator.submit!
end
end
What if you did this instead:
test "MyClass#call"
collaborator = stub('Collaborator')
collaborator.expects(:submit!)
MyClass.new(collaborator: collaborator).call
end
class MyClass
attr_reader :collaborator
def initialize(collaborator: Collaborator.new) # we will just provide a default
@collaborator = collaborator
end
def call
collaborator.submit!
end
end
The benefits are not only for testing, as now your class is more modular and you can swap collaborators as long as they have the proper interface, in this case they have to respond_to :submit!
Injectable
allows you to write the above code like this:
class MyClass
include Injectable
dependency :collaborator
def call
collaborator.submit!
end
end
It might not seem a lot but:
- Imagine that you have 4 dependencies. That's a lot of boilerplate.
-
Injectable
is not only this, it has many more features. Please keep reading.
Usage example
Injectable
is a mixin that you have to include in your class and it will provide several macros.
This is a real world example:
class PdfGenerator
include Injectable
dependency :wicked_pdf
argument :html
argument :render_footer, default: false
def call
wicked_pdf.pdf_from_string(html, options)
end
private
def options
return {} unless render_footer
{
footer: {
left: footer,
}
}
end
def footer
"Copyright ® #{Time.current.year}"
end
end
# And you would use it like this:
PdfGenerator.call(html: '<some html here>')
# Overriding the wicked_pdf dependency:
PdfGenerator.new(wicked_pdf: wicked_pdf_replacement).call(html: '<some html>')
Premises
In order to understand how (and why) Injectable
works, you need to know some principles.
#1 The #call
method
Injectable
classes must define a public #call
method that takes no arguments.
This is the only public method you will be defining in your Injectable
classes.
# Correct ✅
def call
# do stuff
end
# Wrong ❗️
def call(some_argument)
# won't work and will raise an exception at runtime
end
If you want your #call
method to receive arguments, that's what the #argument
macro is for. BTW, we call those runtime arguments.
Why #call
?
Because it's a ruby idiom. Many things in ruby are callable
, like lambdas.
#2 The initialize
method
Injectable classes take their dependencies as keyword arguments on the initialize
method. They can also take configuration arguments on initialize
:
MyClass.new(some_dep: some_dep_instance, some_config: true).call
Injectable
instantiates dependencies that you have declared with the dependency
macro for you and passes them to initialize
, so if you don't want to override those you don't even need to instantiate the class and you can use the provided class method #call
shortcut:
Myclass.call # This is calling `initialize` under the hood
If you need to override dependencies or configuration options, just call new
yourself:
Myclass.new(some_dep: Override.new, some_config: false).call
If you do that, any dependency that you didn't pass will be injected by Injectable
.
Notice that configuration arguments, which are declared with #initialize_with
behave in the exact same way.
#3 Keyword arguments
Both #initialize
and #call
take keyword arguments.
#4 Readers
All Injectable
macros define reader methods for you, that's why you define #call
without arguments, because you access everything you declare via reader methods.
The #dependency
macro
This is the main reason why you want to use this library in the first place.
There are several ways of declaring a #dependency
:
Bare dependency name
class ReportPdfRenderer
include Injectable
dependency :some_dependency
end
-
Injectable
first tries to find theSomeDependency
constant inReportPdfRenderer
namespace. - If it doesn't find it, then tries without namespace (
::SomeDependency
).
Notice that this happens at runtime, not when defining your class.
Explicit, inline class:
class MyInjectable
include Injectable
dependency :client, class: Aws::S3::Client
dependency :parser, class: VeryLongClassNameForMyParser
end
Nothing fancy here, you are explicitly telling Injectable
which class to instantiate for you.
You will want to use this style for example if the class is namespaced somewhere else or if you want a different name other than the class', like for example if it's too long.
Notice that this approach sets the class when ruby interprets the class, not at runtime.
With a block:
dependency :complex_client do
instance = ThirdPartyLib.new(:foo, bar: 'goo')
instance.set_config(:name, 'value')
instance
end
It's important to understand that Injectable
won't call #new
on whatever you return from this block.
You probably want to use this when your dependency has a complex setup. We use it a lot when wrapping third party libraries which aren't reused elsewhere.
If you want to wrap a third party library and you need to reuse it, then we recommend that you write a specific Injectable
class for it, so it adheres to its principles and is easier to use.
#dependency
options
:with
If the dependency takes arguments, you can set them with :with
# Arrays will be splatted: WithNormalArguments.new(1, 2, 3)
dependency :with_normal_arguments, with: [1, 2, 3]
# Hashes will be passed as-is: WithKeywordArguments.new(foo: 'bar)
dependency :with_keyword_arguments, with: { foo: 'bar' }
:depends_on
It allows you to share memoized instances of dependencies and supports both a single dependency or multiples as an Array:
dependency :client # this will be instantiated just once and will be shared
dependency :reporter, depends_on: :client
dependency :mailer, depends_on: %i[client reporter]
Dependencies of dependencies will be passed as keyword arguments using the same name they were declared with. In the example above, Injectable
will instantiate a Mailer
class passing { client: client, reporter: reporter }
to #initialize
.
If you have a dependency that is defined with a block which also depends_on other dependencies, you'll receive those as keyword arguments:
dependency :my_dependency, depends_on: :client do |client:|
MyDependency.new(client)
end
:call
Sometimes you have a class that doesn't adhere to Injectable
principles:
dependency :renderer
def call
renderer.render # this class does not respond to `call`
end
:call
is a way of wrapping such dependency so it behaves like an Injectable
:
dependency :renderer, call: :render
def call
renderer.call
end
It's important to understand that you can mix and match all dependency configurations and options described above.
#initialize_with
macro
This macro is meant for configuration arguments passed to initialize
:
initialize_with :debug, default: false
If you don't pass the :default
option the argument will be required.
#argument
macro
#argument
allows you to define runtime arguments passed to #call
argument :browser, default: 'Unknown'
If you don't pass the :default
option the argument will be required.
Development
After checking out the repo, run bin/setup
to install dependencies. Then, run rake spec
to run the tests. You can also run bin/console
for an interactive prompt that will allow you to experiment.
To install this gem onto your local machine, run bundle exec rake install
. To release a new version, update the version number in version.rb
, and then run bundle exec rake release
, which will create a git tag for the version, push git commits and tags, and push the .gem
file to rubygems.org.
Please consider configuring [https://editorconfig.org/] on your favourite IDE/editor, so basic file formatting is consistent and avoids cross-platform issues. Some editors require a plugin, meanwhile others have it pre-installed.
Contributing
Bug reports and pull requests are welcome on GitHub at https://github.com/rubiconmd/injectable. This project is intended to be a safe, welcoming space for collaboration, and contributors are expected to adhere to the Contributor Covenant code of conduct.
License
The gem is available as open source under the terms of the MIT License.
Code of Conduct
Everyone interacting in the Injectable project’s codebases, issue trackers, chat rooms and mailing lists is expected to follow the code of conduct.
Credits
- RubiconMD allowed extracting this gem from its codebase and release it as open source.
- Durran Jordan allowed the usage of the gem name at rubygems.org.
-
David Marchante brainstormed the
initialize
/call
approach, did all code reviews and provided lots of insightful feedback and suggestions. He also wrote the inline documentation. - Julio Antequera, Jimmi Carney and Anthony Rocco had the patience to use it and report many bugs. Also most of the features in this gem came up when reviewing their usage of it. Anthony also made the effort of extracting the code from RubiconMD's codebase.
- Rodrigo Álvarez had the idea for the DSL and actually wrote the library.