Skip to content

Getting Started

Git Branches

The Nautobot project follows a branching model based on Git-flow. As such, there are three persistent git branches:

  • main - Serves as a snapshot of the current stable release
  • develop - All bug fixes and minor feature development on the upcoming stable release occurs here
  • next - All major new feature development for the next feature release occurs here.

You will always base pull requests off of either the develop branch, for fixes and minor features, or next, if you're working on a feature targeted for a later release. Never target fix or feature pull requests into the main branch, which receives merges only from the develop branch and only for new stable releases of Nautobot.

Forking the Repo

When developing Nautobot, you'll be working on your own fork, so your first step will be to fork the official GitHub repository. You will then clone your GitHub fork locally for development.

Note

It is highly recommended that you use SSH with GitHub. If you haven't already, make sure that you setup Git and add an SSH key to your GitHub account before proceeding.

In this guide, SSH will be used to interact with Git.

git clone git@github.com:yourusername/nautobot.git

Example output:

Cloning into 'nautobot'...
remote: Enumerating objects: 231, done.
remote: Counting objects: 100% (231/231), done.
remote: Compressing objects: 100% (147/147), done.
remote: Total 56705 (delta 134), reused 145 (delta 84), pack-reused 56474
Receiving objects: 100% (56705/56705), 27.96 MiB | 34.92 MiB/s, done.
Resolving deltas: 100% (44177/44177), done.
ls nautobot/

Example output:

CHANGELOG.md     README.md    docs        nautobot.code-workspace  site
CONTRIBUTING.md  contrib      manage.py   poetry.lock              tasks.py
LICENSE.txt      development  mkdocs.yml  pyproject.toml           upgrade.sh
NOTICE           dist         nautobot    scripts

About Remote Repos

Git refers to remote repositories as remotes. When you make your initial clone of your fork, Git defaults to naming this remote origin. Throughout this documentation, the following remote names will be used:

  • origin - The default remote name used to refer to your fork of Nautobot
  • upstream - The main remote used to refer to the official Nautobot repository

Setting up your Remotes

Remote repos are managed using the git remote command.

Upon cloning Nautobot for the first time, you will have only a single remote:

git remote -v

Example output:

origin  git@github.com:yourusername/nautobot.git (fetch)
origin  git@github.com:yourusername/nautobot.git (push)

Add the official Nautobot repo as a the upstream remote:

git remote add upstream git@github.com:nautobot/nautobot.git

View your remotes again to confirm you've got both origin pointing to your fork and upstream pointing to the official repo:

git remote -v

Example output:

origin  git@github.com:yourusername/nautobot.git (fetch)
origin  git@github.com:yourusername/nautobot.git (push)
upstream    git@github.com:nautobot/nautobot.git (fetch)
upstream    git@github.com:nautobot/nautobot.git (push)

You're now ready to proceed to the next steps.

Hint

You will always push changes to origin (your fork) and pull changes from upstream (official repo).

Creating a Branch

Before you make any changes, always create a new branch. Again, for bug fixes and minor features, you'll want to create your branches from the develop branch, while for major new features, you'll branch from next instead.

Before you ever create a new branch, always checkout the appropriate branch and make sure you you've got the latest changes from upstream:

git checkout develop
git pull upstream develop

Warning

If you do not do this, you run the risk of having merge conflicts in your branch, and that's never fun to deal with. Trust us on this one.

Now that you've got the latest upstream changes, create your branch. It's convention to always prefix your branch name with your GitHub username or your initials, and suffix it with the issue number if appropriate, separated by hyphens. For example:

git checkout -b yourusername-myfeature-1234

Enabling Pre-Commit Hooks

Nautobot ships with a Git pre-commit hook script that automatically checks for style compliance and missing database migrations prior to committing changes. This helps avoid erroneous commits that result in CI test failures.

Note

This pre-commit hook currently only supports the Python Virtual Environment Workflow.

You are encouraged to enable it by creating a link to scripts/git-hooks/pre-commit:

cd .git/hooks/
ln -s ../../scripts/git-hooks/pre-commit

Setting up your Development Environment

Getting started with Nautobot development is pretty straightforward, and should feel very familiar to anyone with Django development experience. We can recommend either a Docker Compose workflow (if you don't want to install dependencies such as PostgreSQL and Redis directly onto your system) or a Python virtual environment workflow.

Windows Development

Local development on Windows Subsystem for Linux (WSL) is not currently supported. When developing locally on Windows, we recommend using a virtual machine running an officially supported operating system.

Docker Compose Workflow

This workflow uses Docker and Docker Compose and assumes that you have them installed.

For the Docker Compose workflow, Nautobot uses Invoke as a replacement for Make. Invoke was chosen because it is less arcane than make. Instead of a Makefile, Invoke reads the tasks.py in the project root.

Note

Although the Docker Compose workflow uses containers, it is important to note that the containers are running the local repository code on your machine. Changes you make to your local code will be picked up and executed by the containers.

Install Invoke

Because it is used to execute all common Docker workflow tasks, Invoke must be installed for your user environment. On most systems, if you're installing without root/superuser permissions, the default will install into your local user environment.

pip3 install invoke

If you run into issues, you may also deliberately tell pip3 to install into your user environment by adding the --user flag:

pip3 install --user invoke

Please see the official documentation on Pip user installs for more information.

List Invoke Tasks

Now that you have an invoke command, list the tasks defined in tasks.py:

invoke --list

Example output:

Available tasks:

  black                  Check Python code style with Black.
  build                  Build Nautobot docker image.
  build-and-check-docs   Build docs for use within Nautobot.
  buildx                 Build Nautobot docker image using the experimental buildx docker functionality (multi-arch
                         capablility).
  check-migrations       Check for missing migrations.
  check-schema           Render the REST API schema and check for problems.
  cli                    Launch a bash shell inside the running Nautobot (or other) Docker container.
  createsuperuser        Create a new Nautobot superuser account (default: "admin"), will prompt for password.
  debug                  Start Nautobot and its dependencies in debug mode.
  destroy                Destroy all containers and volumes.
  docker-push            Tags and pushes docker images to the appropriate repos, intended for release use only.
  dumpdata               Dump data from database to db_output file.
  flake8                 Check for PEP8 compliance and other style issues.
  hadolint               Check Dockerfile for hadolint compliance and other style issues.
  integration-test       Run Nautobot integration tests.
  loaddata               Load data from file.
  makemigrations         Perform makemigrations operation in Django.
  markdownlint           Lint Markdown files.
  migrate                Perform migrate operation in Django.
  nbshell                Launch an interactive nbshell session.
  performance-test       Run Nautobot performance specific unit tests.
  post-upgrade           Performs Nautobot common post-upgrade operations using a single entrypoint.
  pylint                 Perform static analysis of Nautobot code.
  restart                Gracefully restart containers.
  start                  Start Nautobot and its dependencies in detached mode.
  stop                   Stop Nautobot and its dependencies.
  tests                  Run all linters and unit tests.
  unittest               Run Nautobot unit tests.
  unittest-coverage      Report on code test coverage as measured by 'invoke unittest'.
  vscode                 Launch Visual Studio Code with the appropriate Environment variables to run in a container.

Using Docker with Invoke

A development environment can be easily started up from the root of the project using the following commands:

  • invoke build - Builds Nautobot docker images
  • invoke migrate - Performs database migration operation in Django
  • invoke createsuperuser - Creates a superuser account for the Nautobot application
  • invoke debug - Starts Docker containers for Nautobot, PostgreSQL, Redis, Celery, and the RQ worker in debug mode and attaches their output to the terminal in the foreground. You may enter Control-C to stop the containers

Additional useful commands for the development environment:

  • invoke start [-s servicename] - Starts Docker containers for Nautobot, PostgreSQL, Redis, Celery, and the RQ worker (or a specific container/service, such as invoke start -s redis) to run in the background with debug disabled
  • invoke cli [-s servicename] - Launch a bash shell inside the specified service container (if none is specified, defaults to the Nautobot container)
  • invoke stop [-s servicename] - Stops all containers (or a specific container/service) created by invoke start

Note

The mkdocs container must be started manually with invoke start -s mkdocs. It will not start automatically with the invoke start or invoke debug commands.

Tip

The Nautobot server uses a Django webservice and worker uses watchdog to provide automatic reload of your web and worker servers in most cases when using invoke start or invoke debug.

Tip

To learn about advanced use cases within the Docker Compose workflow, see the Docker Compose Advanced Use Cases page.

Proceed to the Working in your Development Environment section

Python Virtual Environment Workflow

This workflow uses Python and Poetry to work with your development environment locally. It requires that you install the required system dependencies on your system yourself.

There are a few things you'll need:

  • A Linux system or environment
  • A MySQL or PostgreSQL server, which can be installed locally per the documentation
  • A Redis server, which can also be installed locally
  • A supported version of Python
  • A recent version of Poetry

Install Poetry

Poetry is a tool for dependency management and packaging in Python. It allows you to declare the libraries your project depends on and it will manage (install/update/remove) them for you. It will also manage virtual environments automatically, and allow for publishing packages to the Python Package Index.

You may install Poetry in your user environment by running:

curl -sSL https://install.python-poetry.org | python3 -

Changed in version 1.5.6

Poetry 1.3+ is required to be able to install packages against the latest lockfile.

Danger

Always utilize this documented method to install Poetry for use when developing Nautobot.

Never use pip to install Poetry into your Nautobot virtual environment, as it will result in dependency version conflicts that will very likely break Nautobot. Poetry is used as a package manager for Python packages, so you should not install it into the Nautobot environment, because it relies upon a number of the same dependencies as Nautobot, but with conflicting versions.

While there are certain cases where running pip install poetry is valid, such as in Nautobot's automated release deployments where Nautobot is not actually installed, installing Poetry into Nautobot's runtime development environment is not one of them!

For detailed installation instructions, please see the official Poetry installation guide.

Install Hadolint

Hadolint is a tool used to validate and lint Dockerfiles to ensure we are following best practices. On macOS with Homebrew you can install Hadolint by running:

brew install hadolint

Install markdownlint-cli

markdownlint-cli is a tool used to validate and lint Markdown files, such as Nautobot's documentation, to ensure that they are correctly constructed. On macOS with Homebrew you can install markdownlint-cli by running:

brew install markdownlint-cli

Creating a Python Virtual Environment

A Python virtual environment (or virtualenv) is like a container for a set of Python packages. A virtualenv allow you to build environments suited to specific projects without interfering with system packages or other projects. When installed per the documentation, Nautobot uses a virtual environment in production.

For Nautobot development, we have selected Poetry, which will transparently create a virtualenv for you, automatically install all dependencies required for Nautobot to operate, and will also install the nautobot-server CLI command that you will utilize to interact with Nautobot from here on out.

Bootstrap your virtual environment using poetry install:

poetry install

Hint

If you are doing development or testing using MySQL, you may quickly install the mysqlclient library along with Nautobot by running poetry install --extras mysql.

This will create automatically create a virtualenv in your home directory, which houses a virtual copy of the Python executable and its related libraries and tooling. When running Nautobot for development, it will be run using the Python binary at found within the virtualenv.

Once created, you may activate the virtual environment using poetry shell:

poetry shell

Example output:

Spawning shell within /home/example/.cache/pypoetry/virtualenvs/nautobot-Ams_xyDt-py3.8

. /home/example/.cache/pypoetry/virtualenvs/nautobot-Ams_xyDt-py3.8/bin/activate
(nautobot-Ams_xyDt-py3.8) $

Notice that the console prompt changes to indicate the active environment. This updates the necessary system environment variables to ensure that any Python scripts are run within the virtual environment.

Observe also that the python interpreter is bound within the virtualenv:

which python

Example output:

(nautobot-Ams_xyDt-py3.8) $ /home/example/.cache/pypoetry/virtualenvs/nautobot-Ams_xyDt-py3.8/bin/python

To exit the virtual shell, use exit:

exit

Example output:

$

Working with Poetry

Poetry automatically installs your dependencies. However, if you need to install any additional dependencies this can be done with pip. For example, if you really like using ipython for development:

pip3 install ipython

Example output:

Collecting ipython
  Using cached ipython-7.20.0-py3-none-any.whl (784 kB)
  ...
  • Install verify that you have the proper dependencies installed and are in the virtual environment via Poetry. This also ensures that you have the proper mkdocs themes installed.
poetry shell
poetry install

It may not always be convenient to enter into the virtual shell just to run programs. You may also execute a given command ad hoc within the project's virtual shell by using poetry run:

poetry run mkdocs serve

Check out the Poetry usage guide for more tips.

Configuring Nautobot

Note

Unless otherwise noted, all following commands should be executed inside the virtualenv.

Hint

Use poetry shell to enter the virtualenv.

Nautobot's configuration file is nautobot_config.py.

Initializing a Config

You may also initialize a new configuration using nautobot-server init:

nautobot-server init

Example output:

Configuration file created at '/home/example/.nautobot/nautobot_config.py'

You may also specify alternate file locations. Please refer to Configuring Nautobot for how to do that.

Using the Development Config

A nautobot_config.py suitable for development purposes can be found at development/nautobot_config.py. You may customize the values there or utilize environment variables to override the default values.

If you want to use this file, initialize a config first, then copy this file to the default location Nautobot expects to find its config:

cp development/nautobot_config.py ~/.nautobot/nautobot_config.py
Required Settings

A newly created configuration includes sane defaults. If you need to customize them, edit your nautobot_config.py and update the following settings as required:

  • ALLOWED_HOSTS: This can be set to ["*"] for development purposes and must be set if DEBUG=False
  • DATABASES: Database connection parameters, if different from the defaults
  • Redis settings: Redis configuration requires multiple settings including CACHEOPS_REDIS and RQ_QUEUES. The defaults should be fine for development.
  • DEBUG: Set to True to enable verbose exception logging and, if installed, the Django debug toolbar
  • EXTRA_INSTALLED_APPS: Optionally provide a list of extra Django apps/plugins you may desire to use for development

Working in your Development Environment

Below are common commands for working your development environment.

Creating a Superuser

You'll need to create a administrative superuser account to be able to log into the Nautobot Web UI for the first time. Specifying an email address for the user is not required, but be sure to use a very strong password.

Docker Compose Workflow Virtual Environment Workflow
invoke createsuperuser nautobot-server createsuperuser

Starting the Development Server

Django provides a lightweight HTTP/WSGI server for development use. The development server automatically reloads Python code for each request, as needed. You don’t need to restart the server for code changes to take effect. However, some actions like adding files don’t trigger a restart, so you’ll have to restart the server in these cases.

Danger

DO NOT USE THIS SERVER IN A PRODUCTION SETTING. The development server and watchdog is for development and testing purposes only. It is neither performant nor secure enough for production use.

You can start the Nautobot development server with the invoke start command (if using Docker), or the nautobot-server runserver management command:

Docker Compose Workflow Virtual Environment Workflow
invoke start nautobot-server runserver

For example:

nautobot-server runserver

Example output:

Performing system checks...

System check identified no issues (0 silenced).
November 18, 2020 - 15:52:31
Django version 3.1, using settings 'nautobot.core.settings'
Starting development server at http://127.0.0.1:8080/
Quit the server with CONTROL-C.

Warning

Do not use poetry run nautobot-server runserver as it will crash unless you also pass the --noreload flag, which somewhat defeats the purpose of using the development server. It is recommended to use nautobot-server runserver from within an active virtualenv (e.g. poetry shell). This is a known issue with Django and Poetry.

Please see the official Django documentation on runserver for more information.

You can then log into the development server at localhost:8080 with the superuser you created.

Starting the Worker Server

In order to run Nautobot Jobs or anything that requires a worker you must start a Celery worker.

The worker is started in Docker Workflow with watchdog and can be setup to be started with watchdog in the Virtual Environment Workflow. Watchdog provides a similar experience to the Django lightweight HTTP/WSGI for restarting your application automatically. Watchdog can watch for changes on your filesystem, this is helpful when adjusting existing Python files to not have to restart the celery worker when testing jobs.

Docker Compose Workflow Virtual Environment Workflow
invoke start nautobot-server celery worker

Tip

You can leverage watchdog for your celery worker as described above, with the following watchmedo command in your development environment watchmedo auto-restart --directory './' --pattern '*.py' --recursive -- nautobot-server celery worker -l INFO --events.

Starting the Interactive Shell

Nautobot provides an interactive Python shell that sets up the server environment and gives you direct access to the database models for debugging. Nautobot extends this slightly to automatically import models and other utilities.

Run the Nautobot interactive shell with invoke nbshell (Docker) or the nautobot-server nbshell management command:

Docker Compose Workflow Virtual Environment Workflow
invoke nbshell nautobot-server nbshell

For example:

nautobot-server nbshell

Example output:

### Nautobot interactive shell (localhost)
### Python 3.9.1 | Django 3.1.3 | Nautobot 1.0.0b1
### lsmodels() will show available models. Use help(<model>) for more info.
>>>

Post-upgrade Operations

There will be times where you're working with the bleeding edge of Nautobot from the develop branch or feature branches and will need to pull in database changes or run server operations.

Get into the habit of running nautobot-server post_upgrade (or invoke post-upgrade when using Docker) after you pull in a major set of changes from Nautobot, which performs a handful of common operations (such as migrate) from a single command:

Docker Compose Workflow Virtual Environment Workflow
invoke post-upgrade nautobot-server post_upgrade

Please see the documentation on the nautobot-server post_upgrade command for more information.

Reinstalling Nautobot

Note

This mostly applies to working with Nautobot in a virtualenv, since Docker containers are typically rebuilt when the code changes.

Sometimes when files are renamed, moved, or deleted and you've been working in the same environment for a while, you can encounter weird behavior. If this happens, don't panic and nuke your environment.

First, use pip3 to explicitly uninstall the Nautobot package from the environment:

pip3 uninstall -y nautobot

Example output:

Found existing installation: nautobot 1.0.0b2
Uninstalling nautobot-1.0.0b2:
  Successfully uninstalled nautobot-1.0.0b2

Then try to just have Poetry do the right thing by telling it to install again:

poetry install

Example output:

Installing dependencies from lock file

No dependencies to install or update

Installing the current project: nautobot (1.0.0-beta.2)

Running Tests

Throughout the course of development, it's a good idea to occasionally run Nautobot's test suite to catch any potential errors. Tests come in two primary flavors: Unit tests and integration tests.

For information about writing tests, refer to the testing documentation.

Unit Tests

Unit tests are automated tests written and run to ensure that a section of the Nautobot application (known as the "unit") meets its design and behaves as intended and expected. Most commonly as a developer of or contributor to Nautobot you will be writing unit tests to exercise the code you have written. Unit tests are not meant to test how the application behaves, only the individual blocks of code, therefore use of mock data and phony connections is common in unit test code. As a guiding principle, unit tests should be fast, because they will be executed quite often.

Unit tests are run using the invoke unittest command (if using the Docker development environment) or the nautobot-server test command:

Docker Compose Workflow Virtual Environment Workflow
invoke unittest nautobot-server --config=nautobot/core/tests/nautobot_config.py test nautobot

Info

By default invoke unittest will start and run the unit tests inside the Docker development container; this ensures that PostgreSQL and Redis servers are available during the test. However, if you have your environment configured such that nautobot-server can run locally, outside of the Docker environment, you may wish to set the environment variable INVOKE_NAUTOBOT_LOCAL=True to execute these tests in your local environment instead. See the Invoke configuration for more information.

In cases where you haven't made any changes to the database (which is most of the time), you can append the --keepdb argument to this command to reuse the test database between runs. This cuts down on the time it takes to run the test suite since the database doesn't have to be rebuilt each time.

Docker Compose Workflow Virtual Environment Workflow
invoke unittest --keepdb nautobot-server --config=nautobot/core/tests/nautobot_config.py test --keepdb nautobot

Note

Using the --keepdb argument will raise errors if you've modified any model fields since the previous test run.

Warning

In some cases when tests fail and exit uncleanly it may leave the test database in an inconsistent state. If you encounter errors about missing objects, remove --keepdb and run the tests again.

Integration Tests

Integration tests are automated tests written and run to ensure that the Nautobot application behaves as expected when being used as it would be in practice. By contrast to unit tests, where individual units of code are being tested, integration tests rely upon the server code actually running, and web UI clients or API clients to make real connections to the service to exercise actual workflows, such as navigating to the login page, filling out the username/passwords fields, and clicking the "Log In" button.

Running integrations tests requires the use of Docker at this time. They can be directly invoked using nautobot-server test just as unit tests can, however, a headless Firefox browser provided by Selenium is required. Because Selenium installation and setup is complicated, we have included a configuration for this to work out of the box using Docker.

The Selenium container is running a standalone, headless Firefox "web driver" browser that can be remotely controlled by Nautobot for use in integration testing.

Before running integration tests, the selenium container must be running. If you are using the Docker Compose workflow, it is automatically started for you. For the Virtual Environment workflow, you must start it manually.

Docker Compose Workflow Virtual Environment Workflow
(automatic) invoke start --service selenium

Integration tests are run using the invoke integration-test command. All integration tests must inherit from nautobot.utilities.testing.integration.SeleniumTestCase, which itself is tagged with integration. A custom test runner has been implemented to automatically skip any test case tagged with integration by default, so normal unit tests run without any concern. To run the integration tests the --tag integration argument must be passed to nautobot-server test.

Docker Compose Workflow Virtual Environment Workflow
invoke integration-test nautobot-server --config=nautobot/core/tests/nautobot_config.py test --tag integration nautobot

Info

The same arguments supported by invoke unittest are supported by invoke integration-test. The key difference being the dependency upon the Selenium container, and inclusion of the integration tag.

Tip

You may also use invoke integration-test in the Virtual Environment workflow given that the selenium container is running, and that the INVOKE_NAUTOBOT_LOCAL=True environment variable has been set.

Customizing Integration Test Executions

The following environment variables can be provided when running tests to customize where Nautobot looks for Selenium and where Selenium looks for Nautobot. If using the default setup documented above, there is no need to customize these.

  • NAUTOBOT_SELENIUM_URL - The URL used by the Nautobot test runner to remotely control the headless Selenium Firefox node. You can provide your own, but it must be a Remote WebDriver. (Default: http://localhost:4444/wd/hub; for Docker: http://selenium:4444/wd/hub)
  • NAUTOBOT_SELENIUM_HOST - The hostname used by the Selenium WebDriver to access Nautobot using Firefox. (Default: host.docker.internal; for Docker: nautobot)

Verifying the REST API Schema

If you make changes to the REST API, you should verify that the REST API OpenAPI schema renders correctly without errors. To verify that there are no errors, you can run the invoke check-schema command (if using the Docker development environment) or the nautobot-server spectacular command. In the latter case you should run the command for each supported REST API version that Nautobot provides (e.g. "1.2", "1.3")

Docker Compose Workflow Virtual Environment Workflow
invoke check-schema nautobot-server spectacular --api-version 1.2 --validate --fail-on-warn --file /dev/null

Verifying Code Style and Static Analysis

To enforce best practices around consistent coding style, Nautobot uses Flake8 and Black. Additionally, static analysis of Nautobot code is performed by Pylint. You should run all of these commands and ensure that they pass fully with regard to your code changes before opening a pull request upstream.

Docker Compose Workflow Virtual Environment Workflow
invoke flake8 flake8
invoke black black
invoke pylint nautobot-server pylint nautobot tasks.py && nautobot-server pylint --recursive development/ examples/

Handling Migrations

If you're unsure whether a database schema migration is needed based on your changes, you can run the following command:

Docker Compose Workflow Virtual Environment Workflow
invoke check-migrations nautobot-server --config=nautobot/core/tests/nautobot_config.py makemigrations --dry-run --check

If your branch modifies a Django model (and as a result requires a database schema modification), please be sure to provide a meaningful name to the migration before pushing.

  • If you have yet to run invoke makemigrations, you can pass in a name for the migration with the -n option, example invoke makemigrations -n provider_increase_account_length.
  • If you have already run invoke makemigrations, rename the generated migration files, for example 0004_provider_increase_account_length instead of 0004_auto_20211220_2104.

You’ll also want to run black against the generated migration file as the autogenerated code doesn’t follow our style guide by default.

When modifying model field attributes, modify the test data in the tests too to reflect these changes and also any forms which refer to the model.

Working on Documentation

Some features require documentation updates or new documentation to be written. The documentation files can be found in the docs directory. To preview these changes locally, you can use mkdocs.

For substantial changes to the code (including new features, removal of existing features, or significant changes in behavior) you should always make corresponding documentation updates. Nautobot's documentation pipeline includes a custom plugin for mkdocs that adds a few useful macros for annotating such changes:

  • +++ 1.4.3, on a line by itself, is a shorthand for !!! version-added "Added in version 1.4.3"
  • +/- 1.4.3, on a line by itself, is a shorthand for !!! version-changed "Changed in version 1.4.3"
  • --- 1.4.3, on a line by itself, is a shorthand for !!! version-removed "Removed in version 1.4.3"

These admonitions in turn appear in the rendered documentation as follows:

Added in version 1.4.3

Changed in version 1.4.3

Removed in version 1.4.3

You can also add text to any of these admonitions for further clarity, for example:

+++ 1.4.3
    The custom `mkdocs` plugin was added.

will render as:

Added in version 1.4.3

The custom mkdocs plugin was added.

Caution

While you can use the version-added / version-changed / version-removed admonitions directly to add a custom title to a specific admonition, in general, you should use the macros for consistency across the documentation.

Writing Documentation

You can preview the documentation using the server built into mkdocs, which should start a web server at http://localhost:8001.

Docker Compose Workflow Virtual Environment Workflow
invoke start -s mkdocs mkdocs serve

Documentation is written in Markdown. If you need to add additional pages or sections to the documentation, you can add them to mkdocs.yml at the root of the repository.

Verifying Documentation

Nautobot uses markdownlint-cli to verify correctness of the documentation. You should run this command and ensure that it passes fully with regard to your documentation changes before opening a pull request upstream.

Docker Compose Workflow Virtual Environment Workflow
invoke markdownlint markdownlint --ignore nautobot/project-static --config .markdownlint.yml nautobot examples *.md

Submitting Pull Requests

Once you're happy with your work and have verified that all tests pass, commit your changes and push it upstream to your fork. Always provide descriptive (but not excessively verbose) commit messages. When working on a specific issue, be sure to reference it.

git commit -m "Closes #1234: Add IPv5 support"
git push origin

Once your fork has the new commit, submit a pull request to the Nautobot repo to propose the changes. Be sure to provide a detailed accounting of the changes being made and the reasons for doing so.

Once submitted, a maintainer will review your pull request and either merge it or request changes. If changes are needed, you can make them via new commits to your fork: The pull request will update automatically.

Note

Remember, pull requests are entertained only for accepted issues. If an issue you want to work on hasn't been approved by a maintainer yet, it's best to avoid risking your time and effort on a change that might not be accepted.

Troubleshooting

Below are common issues you might encounter in your development environment and how to address them.

FATAL: sorry, too many clients already

When using nautobot-server runserver to do development you might run into a traceback that looks something like this:

Exception Type: OperationalError at /extras/tags/
Exception Value: FATAL:  sorry, too many clients already

The runserver development server is multi-threaded by default, which means that every request is creating its own connection. If you are doing some local testing or development that is resulting in a lot of connections to the database, pass --nothreading to the runserver command to disable threading:

nautobot-server runserver --nothreading