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injector 0.4.3

Injector - Python dependency injection framework, inspired by Guice

Package Documentation

Latest Version: 0.11.1


Dependency injection as a formal pattern is less useful in Python than in other languages, primarily due to its support for keyword arguments, the ease with which objects can be mocked, and its dynamic nature.

That said, a framework for assisting in this process can remove a lot of boiler-plate from larger applications. That’s where Injector can help. It automatically and transitively provides keyword arguments with their values. As an added benefit, Injector encourages nicely compartmentalised code through the use of Module s.

While being inspired by Guice, it does not slavishly replicate its API. Providing a Pythonic API trumps faithfulness.

A Full Example

Here’s a full example to give you a taste of how Injector works:

>>> from injector import Module, Key, provides, Injector, inject, singleton

We’ll use an in-memory SQLite database for our example:

>>> import sqlite3

And make up an imaginary RequestHandler class that uses the SQLite connection:

>>> class RequestHandler(object):
...   @inject(db=sqlite3.Connection)
...   def __init__(self, db):
...     self._db = db
...   def get(self):
...     cursor = self._db.cursor()
...     cursor.execute('SELECT key, value FROM data ORDER by key')
...     return cursor.fetchall()

Next, for the sake of the example, we’ll create a “configuration” annotated type:

>>> Configuration = Key('configuration')
>>> class ConfigurationForTestingModule(Module):
...   def configure(self, binder):
...     binder.bind(Configuration, to={'db_connection_string': ':memory:'},
...         scope=singleton)

Next we create our database module that initialises the DB based on the configuration provided by the above module, populates it with some dummy data, and provides a Connection object:

>>> class DatabaseModule(Module):
...   @singleton
...   @provides(sqlite3.Connection)
...   @inject(configuration=Configuration)
...   def provide_sqlite_connection(self, configuration):
...     conn = sqlite3.connect(configuration['db_connection_string'])
...     cursor = conn.cursor()
...     cursor.execute('CREATE TABLE IF NOT EXISTS data (key PRIMARY KEY, value)')
...     cursor.execute('INSERT OR REPLACE INTO data VALUES ("hello", "world")')
...     return conn

(Note how we have decoupled configuration from our database initialisation code.)

Finally, we initialise an Injector and use it to instantiate a RequestHandler instance. This first transitively constructs a sqlite3.Connection object, and the Configuration dictionary that it in turn requires, then instantiates our RequestHandler:

>>> injector = Injector([ConfigurationForTestingModule(), DatabaseModule()])
>>> handler = injector.get(RequestHandler)
>>> handler.get()
[(u'hello', u'world')]

We can also veryify that our Configuration and SQLite connections are indeed singletons within the Injector:

>>> injector.get(Configuration) is injector.get(Configuration)
>>> injector.get(sqlite3.Connection) is injector.get(sqlite3.Connection)

You’re probably thinking something like: “this is a large amount of work just to give me a database connection”, and you are correct; dependency injection is typically not that useful for smaller projects. It comes into its own on large projects where the up-front effort pays for itself in two ways:

  1. Forces decoupling. In our example, this is illustrated by decoupling our configuration and database configuration.
  2. After a type is configured, it can be injected anywhere with no additional effort. Simply @inject and it appears. We don’t really illustrate that here, but you can imagine adding an arbitrary number of RequestHandler subclasses, all of which will automatically have a DB connection provided.


At its heart, Injector is simply a dictionary for mapping types to things that create instances of those types. This could be as simple as:

{str: 'an instance of a string'}

For those new to dependency-injection and/or Guice, though, some of the terminology used may not be obvious.


A means of providing an instance of a type. Built-in providers include ClassProvider (creates a new instance from a class), InstanceProvider (returns an existing instance directly) and CallableProvider (provides an instance by calling a function).


By default, providers are executed each time an instance is required. Scopes allow this behaviour to be customised. For example, SingletonScope (typically used through the class decorator singleton), can be used to always provide the same instance of a class.

Other examples of where scopes might be a threading scope, where instances are provided per-thread, or a request scope, where instances are provided per-HTTP-request.

The default scope is NoScope.

Binding Key

A binding key uniquely identifies a provider of a type. It is effectively a tuple of (type, annotation) where type is the type to be provided and annotation is additional, optional, uniquely identifying information for the type.

For example, the following are all unique binding keys for str:

(str, 'name')
(str, 'description')

For a generic type such as str, annotations are very useful for unique identification.

As an alternative convenience to using annotations, Key may be used to create unique types as necessary:

>>> from injector import Key
>>> Name = Key('name')
>>> Description = Key('description')

Which may then be used as binding keys, without annotations, as they already uniquely identify a particular provider:

(Name, None)
(Description, None)

Though of course, annotations may still be used with these types, like any other type.


An annotation is additional unique information about a type to avoid binding key collisions. It creates a new unique binding key for an existing type.


A binding is the mapping of a unique binding key to a corresponding provider. For example:

>>> from injector import InstanceProvider
>>> bindings = {
...   (Name, None): InstanceProvider('Sherlock'),
...   (Description, None): InstanceProvider('A man of astounding insight')}
... }


The Binder is simply a convenient wrapper around the dictionary that maps types to providers. It provides methods that make declaring bindings easier.


A Module configures bindings. It provides methods that simplify the process of binding a key to a provider. For example the above bindings would be created with:

>>> from injector import Module
>>> class MyModule(Module):
...     def configure(self, binder):
...         binder.bind(Name, to='Sherlock')
...         binder.bind(Description, to='A man of astounding insight')

For more complex instance construction, methods decorated with @provides will be called to resolve binding keys:

>>> from injector import provides
>>> class MyModule(Module):
...     def configure(self, binder):
...         binder.bind(Name, to='Sherlock')
...     @provides(Description)
...     def describe(self):
...         return 'A man of astounding insight (at %s)' % time.time()


Injection is the process of providing an instance of a type, to a method that uses that instance. It is achieved with the inject decorator. Keyword arguments to inject define which arguments in its decorated method should be injected, and with what.

Here is an example of injection on a module provider method, and on the constructor of a normal class:

>>> from injector import inject
>>> class User(object):
...     @inject(name=Name, description=Description)
...     def __init__(self, name, description):
... = name
...         self.description = description

>>> class UserModule(Module):
...     def configure(self, binder):
...        binder.bind(User)

>>> class UserAttributeModule(Module):
...     def configure(self, binder):
...         binder.bind(Name, to='Sherlock')
...     @provides(Description)
...     @inject(name=Name)
...     def describe(self, name):
...         return '%s is a man of astounding insight' % name


The Injector brings everything together. It takes a list of Module s, and configures them with a binder, effectively creating a dependency graph:

>>> from injector import Injector
>>> injector = Injector([UserModule(), UserAttributeModule()])

The injector can then be used to acquire instances of a type, either directly:

>>> injector.get(Name)
>>> injector.get(Description)
'Sherlock is a man of astounding insight'

Or transitively:

>>> user = injector.get(User)
>>> isinstance(user, User)
>>> user.description
'Sherlock is a man of astounding insight'



Singletons are declared by binding them in the SingletonScope. This can be done in three ways:

  1. Decorating the class with @singleton.
  2. Decorating a @provides(X) decorated Module method with @singleton.
  3. Explicitly calling binder.bind(X, scope=singleton).

A (redunant) example showing all three methods:

>>> @singleton
... class Thing(object): pass
>>> class ThingModule(Module):
...   def configure(self, binder):
...     binder.bind(Thing, scope=singleton)
...   @singleton
...   @provides(Thing)
...   def provide_thing(self):
...     return Thing()

Implementing new Scopes

In the above description of scopes, we glossed over a lot of detail. In particular, how one would go about implementing our own scopes.

Basically, there are two steps. First, subclass Scope and implement Scope.get:

>>> from injector import Scope
>>> class CustomScope(Scope):
...   def get(self, key, provider):
...     return provider

Then create a global instance of ScopeDecorator to allow classes to be easily annotated with your scope:

>>> from injector import ScopeDecorator
>>> customscope = ScopeDecorator(CustomScope)

This can be used like so:

>>> @customscope
... class MyClass(object):
...   pass

Scopes are bound in modules with the Binder.bind_scope method:

>>> class MyModule(Module):
...   def configure(self, binder):
...     binder.bind_scope(CustomScope)

Scopes can be retrieved from the injector, as with any other instance. They are singletons across the life of the injector:

>>> injector = Injector([MyModule()])
>>> injector.get(CustomScope) is injector.get(CustomScope)

For scopes with a transient lifetime, such as those tied to HTTP requests, the usual solution is to use a thread or greenlet-local cache inside the scope. The scope is “entered” in some low-level code by calling a method on the scope instance that creates this cache. Once the request is complete, the scope is “left” and the cache cleared.


This framework is similar to snake-guice, but aims for simplification.

  1. 2010 by Alec Thomas


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