Build and run a Python app in a container

Source: Build and run a Python app in a container

Python in a container

In this tutorial, you will learn how to:

  • Create a Dockerfile file describing a simple Python container.
  • Build, run, and verify the functionality of a DjangoFlask, or General Python app.
  • Debug the app running in a container.

Prerequisites

  • Install Docker on your machine and add it to the system path.

  • On Linux, you should also enable Docker CLI for the non-root user account that will be used to run VS Code.

  • The Docker extension. To install the extension, open the Extensions view (Ctrl+Shift+X), search for docker to filter results and select Docker extension authored by Microsoft.

    Select Docker extension

Create a Python project

If you don’t have a Python project already, follow the tutorial Getting started with Python.

Note: If you want to containerize a complete Django or Flask web app, you can start with one of the following samples:

Note: For this tutorial, be sure to use the tutorial branch of the sample repos.

After verifying your app runs properly, you can now containerize your application.

Add Docker files to the project

  1. Open the project folder in VS Code.

  2. Open the Command Palette (Ctrl+Shift+P) and choose Docker: Add Docker Files to Workspace…:

    Add Dockerfile to a Python project

  3. When prompted for the app type, select Python: DjangoPython: Flask, or Python: General as the app type. For this tutorial, we’ll focus on the Python: General case, but will also include notes for Django and Flask.

  4. Enter the relative path to the app’s entry point. This excludes the workspace folder you start from. If you created a python app with hello.py according to the Getting Started with Python tutorial, choose that.

    Django: Choose manage.py (root folder) or subfolder_name/manage.py. See the official Django documentation.

    Flask: Choose the path to where you create your Flask instance. See the official Flask documentation.

    Tip: You may also enter the path to a folder name as long as this folder includes a __main__.py file.

  5. Select the port number. We recommend selecting port 1024 or above to mitigate security concerns from running as a root user. Any unused will port, but Django and Flask use standard default ports.

    Django: The default port 8000.

    Flask: The default port is 5000.

  6. When prompted to include Docker Compose, select No if you do not want a Docker Compose file. If you select Yes, you will need to verify the path to your wsgi.py file in the Dockerfile to run the Compose Up command successfully. Compose is typically used when running multiple containers at once.

  7. With all this information, the Docker extension creates the following files:

    • Dockerfile. To learn more about IntelliSense in this file, refer to the overview.

    • .dockerignore file to reduce the image size by excluding files and folders that aren’t needed such as .git.vscode, and __pycache__.

    • If you’re using Docker Compose, a docker-compose.yml and docker-compose.debug.yml file.

    • If one does not already exist, a requirements.txt file for capturing all app dependencies.

    Important Note: To use our setup, the Python framework (Django/Flask) and Gunicorn must be included in the requirements.txt file. If the virtual environment/host machine already has these prerequisites installed and is supposed to be identical to the container environment, ensure app dependencies are ported over by running pip freeze > requirements.txt in the terminal. This will overwrite your current requirements.txt file.

(Optional) Add an environment variable to the image

This step is not required, but it is included to help you understand how to add environment variables that need to be set in the container’s environment.

The Docker Extension helps you author Dockerfiles by using IntelliSense to provide auto-completions and contextual help. To see this feature in action:

  1. Open the Dockerfile.

  2. Underneath the EXPOSE statement, type Ctrl+Space to trigger IntelliSense and scroll to ENV.

    Adding environment variable to Dockerfile

  3. Press Tab or Enter to complete the statement, then set the key to the name of the variable, and set the value.

For more information about setting and using environment variables in the Dockerfile, see the ENV instruction and Environment replacement section in the Docker documentation.

Gunicorn modifications for Django and Flask apps

To give Python web developers a great starting point, we chose to use Gunicorn as the default web server. Since it is referenced in the default Dockerfile, it is included as a dependency in the requirements.txt file. If you don’t see it in requirements.txt, run pip install gunicorn and then run pip freeze > requirements.txt to regenerate the requirements.txt file.

  • Django: To use Gunicorn, it must bind to an application callable (what the application server uses to communicate with your code) as an entry point. This callable is declared in the wsgi.py file of a Django application. To accomplish this binding, the final line in the Dockerfile says:

    CMD ["gunicorn", "--bind", "0.0.0.0:8000", "{workspace_folder_name}.wsgi"]
    

    If your project does not follow Django’s default project structure (that is, a workspace folder and a wsgi.py file >within a subfolder named the same as the workspace) you must overwrite the Gunicorn entry point in the Dockerfile to locate the correct wsgi.py file.

    If your wsgi.py file is in the root folder, the final argument in the command above will be "wsgi". Within subfolders, the argument would be "subfolder1_name.subfolder2_name.wsgi".

  • Flask: To use Gunicorn, it must bind to an application callable (what the application server uses to communicate with your code) as an entry point. This callable corresponds with the file location and variable name of your created Flask instance. According to official Flask Documentation, users generally create a Flask instance in the main module or in the __init__.py file of their package in this manner:

    from flask import Flask
    app = Flask(__name__) # Flask instance named app
    

    To accomplish this binding, the final line in the Dockerfile says:

    CMD ["gunicorn", "--bind", "0.0.0.0:5000", "{subfolder}.{module_file}:app"]
    

    During the Docker: Add Docker Files to Workspace… command, you configure the path to the Flask instance, however, the Docker extension assumes your Flask instance variable is named app. If this is not the case, you must change the variable name in the Dockerfile.

    If your main module was in the root folder as a file named main.py and had a Flask instance variable was named myapp, the final argument in the command above will be "main:myapp". Within subfolders, the argument would be "subfolder1_name.subfolder2_name.main:myapp".

Build, run, and debug the container

The Docker: Add Docker Files to Workspace… command automatically creates a Docker launch configuration to build and run your container in debug mode. To debug your Python app container:

  1. Navigate to the file that contains your app’s startup code, and set a breakpoint.

  2. Navigate to Run and Debug and select Docker: Python – GeneralDocker: Python – Django, or Docker: Python – Flask, as appropriate.

    Selected Docker debug configuration

  3. Start debugging using the F5 key.

    • The Docker image builds.
    • The Docker container runs.
    • The python debugger stops at the breakpoint.
  4. Step over this line once.

  5. When ready, press continue.

The Docker extension will launch your browser to a randomly mapped port:

Django website launches

Tip: To modify your Docker build settings, such as changing the image tag, navigate to .vscode -> tasks.json under the dockerBuild attribute in the docker-build task. Use IntelliSense within the file (Ctrl+Space) to display all other valid directives.

Use the Docker Explorer

The Docker Explorer provides an interactive experience to examine and manage Docker assets such as containers, images, and so on. To see an example:

  1. Navigate to the Docker Explorer.

  2. In the Containers tab, right-click on your container and choose View Logs.

    Viewing the logs of a container

  3. The output will be displayed in the terminal.

Build the image in Azure

You can use the command Azure Container Registry: Build Image in Azure to build an image that you can then deploy to Azure App Service or Azure Container Apps.

  1. Install the Azure Resources extension. Open the Command Palette (Ctrl+Shift+P) and search for the command Azure: Sign In. If you don’t have an Azure account, you can sign up for a free trial.

  2. There are two ways to invoke the build in Azure command. You can right-click on the Dockerfile, and choose Build Image in Azure. You can also use the Command Palette (Ctrl+Shift+P) and search for the command Azure Container Registry: Build Image in Azure.

    Invoke the command Build Image in Azure

  3. Choose the name and tag for the built image. You’ll use this to identify it in the container registry.

    Choose the name and tag for the built image.

  4. Choose the Azure subscription you want to use.

  5. Choose an existing Azure Container Registry, or create a new one. When you create a new one, you’re asked to provide the name, resource group, location, and an option for pricing, such as Basic, Standard, or Premium. You can read about the costs of these options at Pricing – Container Registry.

  6. Specify the base OS, Linux or Windows. This choice must be consistent with the Dockerfile.

    Choose the base OS for the built image

The process of building the image might take a few minutes. You can track progress in the terminal. If you encounter an error (Error: failed to download context.), try using the Refresh option on the container registry and then request another build. Before rebuilding, manually delete the old image.

Deploy to Azure App Service or Azure Container Apps

Once the container image is built, it should appear in the Container Registry with the tag you specified. Now that it’s built, you can deploy it to Azure App Service or Azure Container Apps. The Azure App Service extension is recommended for deployments to Azure App Service, and the Azure Container Apps extension is required for deployments to Azure Container Apps. You can obtain both if you install the Azure Tools extension pack, which includes a package of tools for a wide range of Azure development scenarios.

  1. Right-click on the image tag and choose Deploy Image to Azure App Service or Deploy Image to Azure Container Apps.

    Deploy image to Azure App Service

  2. Provide the name of the web site. This must be a unique name, and for Django apps, it must also be listed as a valid host name in the ALLOWED_HOSTS list in the settings.py file.

  3. Provide a resource group, location, and App Service Plan. If you’re just getting started, you can choose the free plan.

  4. The image is deployed; the process might take a few minutes. Once it’s deployed, a notification appears with a button you can use to access the site. You can also use the site’s address, {appname}.azurewebsites.net where {appname} is the name you gave when creating it. If it doesn’t work at first, try again in a few minutes. It’s not uncommon for the first few attempts to time out or return an error. It just means the App Service isn’t ready yet to receive requests.

  5. Make a small change in the application code that’s visible on one of the pages, and save the file.

  6. Use the Azure icon to open the Resources view, and expand the node for your subscription to find the App Service that you deployed in the previous step.

  7. Right-click on the App Service node and look at the available options. Choose Deploy to Web App, and then specify your app folder to deploy it.

    Deploy to Web App

    When warned that this will overwrite the previous deployment, choose Deploy to confirm.

    This might take a few minutes; you can monitor progress in the terminal window. When it finishes, a button with access to the site is given.

    Browse website button

    Use the button and verify that your change is reflected on the site.

Congratulations, you’ve used Python in VS Code to create an deploy a web site that’s hosted in the cloud and live on the internet!

Free up resources

In the Azure portal, delete the Resource Group to free up all resources that you created during this exercise.

Next steps

You’re done! Now that your container is ready, you may want to:

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