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316 lines
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ReStructuredText
316 lines
11 KiB
ReStructuredText
Dependency injection and inversion of control in Python
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=======================================================
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.. meta::
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:keywords: Python,DI,Dependency injection,IoC,Inversion of Control,Example
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:description: This page describes a usage of the dependency injection and inversion of control
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in Python. It contains Python examples that show how to implement dependency
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injection. It demonstrates a usage of the dependency injection framework
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Dependency Injector, its container, Factory, Singleton and Configuration
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providers. The example show how to use Dependency Injector providers overriding
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feature for testing or configuring project in different environments and explains
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why it's better than monkey-patching.
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Originally dependency injection pattern got popular in languages with static typing like Java.
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Dependency injection is a principle that helps to achieve an inversion of control. A
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dependency injection framework can significantly improve the flexibility of a language
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with static typing. Implementation of a dependency injection framework for a language
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with static typing is not something that one can do quickly. It will be a quite complex thing
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to be done well. And will take time.
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Python is an interpreted language with dynamic typing. There is an opinion that dependency
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injection doesn't work for it as well as it does for Java. A lot of the flexibility is already
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built-in. Also, there is an opinion that a dependency injection framework is something that
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Python developer rarely needs. Python developers say that dependency injection can be implemented
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easily using language fundamentals.
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This page describes the advantages of applying dependency injection in Python. It
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contains Python examples that show how to implement dependency injection. It demonstrates the usage
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of the ``Dependency Injector`` framework, its container, ``Factory``, ``Singleton``,
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and ``Configuration`` providers. The example shows how to use providers' overriding feature
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of ``Dependency Injector`` for testing or re-configuring a project in different environments and
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explains why it's better than monkey-patching.
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What is dependency injection?
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-----------------------------
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Let's see what the dependency injection is.
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Dependency injection is a principle that helps to decrease coupling and increase cohesion.
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.. image:: images/coupling-cohesion.png
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What is coupling and cohesion?
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Coupling and cohesion are about how tough the components are tied.
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- **High coupling**. If the coupling is high it's like using superglue or welding. No easy way
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to disassemble.
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- **High cohesion**. High cohesion is like using screws. Quite easy to disassemble and
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re-assemble in a different way. It is an opposite to high coupling.
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Cohesion often correlates with coupling. Higher cohesion usually leads to lower coupling and vice versa.
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Low coupling brings flexibility. Your code becomes easier to change and test.
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How to implement the dependency injection?
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Objects do not create each other anymore. They provide a way to inject the dependencies instead.
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Before:
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.. code-block:: python
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import os
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class ApiClient:
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def __init__(self) -> None:
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self.api_key = os.getenv("API_KEY") # <-- dependency
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self.timeout = int(os.getenv("TIMEOUT")) # <-- dependency
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class Service:
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def __init__(self) -> None:
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self.api_client = ApiClient() # <-- dependency
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def main() -> None:
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service = Service() # <-- dependency
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...
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if __name__ == "__main__":
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main()
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After:
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.. code-block:: python
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import os
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class ApiClient:
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def __init__(self, api_key: str, timeout: int) -> None:
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self.api_key = api_key # <-- dependency is injected
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self.timeout = timeout # <-- dependency is injected
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class Service:
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def __init__(self, api_client: ApiClient) -> None:
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self.api_client = api_client # <-- dependency is injected
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def main(service: Service) -> None: # <-- dependency is injected
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...
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if __name__ == "__main__":
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main(
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service=Service(
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api_client=ApiClient(
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api_key=os.getenv("API_KEY"),
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timeout=int(os.getenv("TIMEOUT")),
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),
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),
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)
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``ApiClient`` is decoupled from knowing where the options come from. You can read a key and a
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timeout from a configuration file or even get them from a database.
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``Service`` is decoupled from the ``ApiClient``. It does not create it anymore. You can provide a
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stub or other compatible object.
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Function ``main()`` is decoupled from ``Service``. It receives it as an argument.
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Flexibility comes with a price.
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Now you need to assemble and inject the objects like this:
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.. code-block:: python
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main(
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service=Service(
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api_client=ApiClient(
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api_key=os.getenv("API_KEY"),
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timeout=int(os.getenv("TIMEOUT")),
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),
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),
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)
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The assembly code might get duplicated and it'll become harder to change the application structure.
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Here comes the ``Dependency Injector``.
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What does the Dependency Injector do?
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-------------------------------------
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With the dependency injection pattern, objects lose the responsibility of assembling
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the dependencies. The ``Dependency Injector`` absorbs that responsibility.
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``Dependency Injector`` helps to assemble and inject the dependencies.
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It provides a container and providers that help you with the objects assembly.
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When you need an object you place a ``Provide`` marker as a default value of a
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function argument. When you call this function, framework assembles and injects
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the dependency.
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.. code-block:: python
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from dependency_injector import containers, providers
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from dependency_injector.wiring import Provide, inject
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class Container(containers.DeclarativeContainer):
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config = providers.Configuration()
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api_client = providers.Singleton(
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ApiClient,
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api_key=config.api_key,
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timeout=config.timeout,
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)
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service = providers.Factory(
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Service,
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api_client=api_client,
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)
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@inject
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def main(service: Service = Provide[Container.service]) -> None:
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...
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if __name__ == "__main__":
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container = Container()
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container.config.api_key.from_env("API_KEY", required=True)
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container.config.timeout.from_env("TIMEOUT", as_=int, default=5)
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container.wire(modules=[__name__])
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main() # <-- dependency is injected automatically
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with container.api_client.override(mock.Mock()):
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main() # <-- overridden dependency is injected automatically
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When you call the ``main()`` function the ``Service`` dependency is assembled and injected automatically.
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When you do testing, you call the ``container.api_client.override()`` method to replace the real API
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client with a mock. When you call ``main()``, the mock is injected.
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You can override any provider with another provider.
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It also helps you in a re-configuring project for different environments: replace an API client
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with a stub on the dev or stage.
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Objects assembling is consolidated in a container. Dependency injections are defined explicitly.
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This makes it easier to understand and change how an application works.
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Testing, Monkey-patching and dependency injection
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-------------------------------------------------
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The testability benefit is opposed to monkey-patching.
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In Python, you can monkey-patch anything, anytime. The problem with monkey-patching is
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that it's too fragile. The cause of it is that when you monkey-patch you do something that
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wasn't intended to be done. You monkey-patch the implementation details. When implementation
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changes the monkey-patching is broken.
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With dependency injection, you patch the interface, not an implementation. This is a way more
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stable approach.
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Also, monkey-patching is way too dirty to be used outside of the testing code for
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re-configuring the project for the different environments.
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Conclusion
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----------
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Dependency injection provides you with three advantages:
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- **Flexibility**. The components are loosely coupled. You can easily extend or change the
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functionality of a system by combining the components in a different way. You even can do it on
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the fly.
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- **Testability**. Testing is easier because you can easily inject mocks instead of real objects
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that use API or database, etc.
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- **Clearness and maintainability**. Dependency injection helps you reveal the dependencies.
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Implicit becomes explicit. And "Explicit is better than implicit" (PEP 20 - The Zen of Python).
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You have all the components and dependencies defined explicitly in a container. This
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provides an overview and control of the application structure. It is easier to understand and
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change it.
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Is it worth applying dependency injection in Python?
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It depends on what you build. The advantages above are not too important if you use Python as a
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scripting language. The picture is different when you use Python to create an application. The
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larger the application the more significant the benefits.
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Is it worth using a framework for applying dependency injection?
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The complexity of the dependency injection pattern implementation in Python is
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lower than in other languages but it's still in place. It doesn't mean you have to use a
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framework but using a framework is beneficial because the framework is:
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- Already implemented
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- Tested on all platforms and versions of Python
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- Documented
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- Supported
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- Other engineers are familiar with it
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An advice at last:
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- **Give it a try**. Dependency injection is counter-intuitive. Our nature is that
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when we need something the first thought that comes to our mind is to go and get it. Dependency
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injection is just like "Wait, I need to state a need instead of getting something right away".
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It's like a little investment that will pay-off later. The advice is to just give it a try for
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two weeks. This time will be enough for getting your own impression. If you don't like it you
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won't lose too much.
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- **Common sense first**. Use common sense when applying dependency injection. It is a good
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principle, but not a silver bullet. If you do it too much you will reveal too many of the
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implementation details. Experience comes with practice and time.
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What's next?
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------------
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Choose one of the following as a next step:
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- Look at the application examples:
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- :ref:`application-single-container`
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- :ref:`application-multiple-containers`
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- :ref:`decoupled-packages`
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- :ref:`boto3-example`
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- :ref:`django-example`
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- :ref:`flask-example`
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- :ref:`flask-blueprints-example`
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- :ref:`aiohttp-example`
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- :ref:`sanic-example`
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- :ref:`fastapi-example`
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- :ref:`fastapi-redis-example`
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- :ref:`fastapi-sqlalchemy-example`
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- Pass the tutorials:
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- :ref:`flask-tutorial`
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- :ref:`aiohttp-tutorial`
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- :ref:`asyncio-daemon-tutorial`
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- :ref:`cli-tutorial`
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- Know more about the ``Dependency Injector`` :ref:`key-features`
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- Know more about the :ref:`providers`
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- Know more about the :ref:`wiring`
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- Go to the :ref:`contents`
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Useful links
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------------
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A few useful links related to a dependency injection design pattern for further reading:
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+ https://en.wikipedia.org/wiki/Dependency_injection
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+ https://martinfowler.com/articles/injection.html
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+ https://github.com/ets-labs/python-dependency-injector
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+ https://pypi.org/project/dependency-injector/
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.. include:: ../sponsor.rst
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.. disqus::
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