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FawltyDeps

FawltyDeps is a dependency checker for Python that finds undeclared and/or unused 3rd-party dependencies in your Python project. The name is inspired by the Monty Python-adjacent Fawlty Towers sitcom.

FawltyDeps demo

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Table of contents

Key Concepts

Installation

Usage

Configuration

Documentation

Development

Integration tests

FAQ

Key Concepts

Installation

The library is distributed with PyPI, so simply:

pip install fawltydeps

or any other way to install Python packages from PyPI should be enough to make it available in your environment.

Consider adding fawltydeps to your development dependencies, to help you catch undeclared and unused dependencies in your projects.

Usage

To check the project in the current directory run:

fawltydeps

This will find imports in all the Python code under the current directory, extract dependencies declared by your project, and then report undeclared and unused dependencies.

Available Actions

FawltyDeps provides the following options for controlling what actions to perform. Only one of these can be used at a time:

When none of these are specified, the default action is --check.

Where to find code and dependency declarations

By default, FawltyDeps will look for Python code (*.py and *.ipynb) and dependency declarations (see list of supported files below) under the current directory. If you want FawltyDeps to look elsewhere, you can pass a different directory (aka basepath) as a positional argument:

fawltydeps my_project/

If you want to separately declare the source of the code and the source of the dependencies, you may use the --code and --deps options documented in the next section. In short, giving the basepath positional argument is equivalent to passing both the --code and the --deps options, like this:

fawltydeps --code my_project/ --deps my_project/

Where to find Python code

The --code option tells FawltyDeps where to find the Python code to parse for import statements. You can pass any number of these:

If no --code option is passed, FawltyDeps will find all Python code under the basepath, if given, or the current directory (i.e. same as --code=.). To include both code from stdin (import foo) and a file path (file.py), use:

echo "import foo" | fawltydeps --list-imports --code - file.py

At any time, if you want to see where FawltyDeps is looking for Python code, you can use the --list-sources --detailed options.

Where to find declared dependencies

The --deps option tells FawltyDeps where to look for your project's declared dependencies. A number of file formats are supported:

The --deps option accepts a space-separated list of files or directories. Each file will be parsed for declared dependencies; each directory will be searched, parsing all of the supported files (see the above list) found within. You would typically want to pass individual files, if you want to be explicit about where to find the declared dependencies.

If no --deps option is passed, FawltyDeps will look for the above files under the basepath, if given, or the current directory (i.e. same as --deps .).

Resolving dependencies

When FawltyDeps looks for undeclared and unused dependencies, it needs to match import statements in your code with corresponding package dependencies declared in your project configuration.

To solve this, FawltyDeps uses a sequence of resolvers (aka. mapping strategies) to determine which Python packages provide which import names. The diagram below shows the dependencies' flow through the sequence of mappings supported by FawltyDeps (each of which is introduced in the following subsections):

<img src="./images/resolvers_sequence.png" alt="Sequence of resolvers used by FawltyDeps" width="500"/>

The priority of each of these mappings, together with their default values and customization options are summarized in the table below:

PriorityMapping strategyOptions
1User-defined mappingProvide a custom mapping in TOML format via --custom-mapping-file or a [tool.fawltydeps.custom_mapping] section in pyproject.toml. <br /> Default: No custom mapping
2Mapping from installed packages found inside projectPoint to one or more environments with --pyenv.<br />Default: auto-discovery of Python environments under the project’s basepath.
3Mapping from packages installed in sys.pathActive by default. No CLI option. This finds packages installed in the Python environment in which FawltyDeps itself runs.
4aMapping via temporary installation of packagesActivated with the --install-deps option.
4bIdentity mappingActive by default. Deactivated when --install-deps is used.

Local Python environment mapping

Local Python environment mapping refers to using packages already installed in local Python environments on your system to resolve dependencies into the imports they expose. This leverages the functionality provided by the excellent importlib_metadata library.

You can use the --pyenv option (or the pyenvs configuration directive) to point FawltyDeps at one [or more] specific Python environment(s) located within your project or elsewhere. For example:

fawltydeps --code my_package/ --deps pyproject.toml --pyenv /path/to/project/venv

This will tell FawltyDeps:

If --pyenv is not used, FawltyDeps will look for Python environments (virtualenvs or similar directories like .venv or __pypackages__.) inside your project (i.e. under basepath, if given, or the current directory).

You can use --pyenv multiple times to have FawltyDeps look for packages in multiple Python environments. In this case (or when multiple Python environments are found inside your project) FawltyDeps will use the union (superset) of all imports provided by all matching packages across those Python environments as valid import names for that dependency.

Current Python environment

In addition to the local Python environments found above, FawltyDeps will also look at your current Python environment, i.e. the environment in which FawltyDeps itself is installed. This works well when you, for example, pip install fawltydeps into the same virtualenv as your project dependencies, no matter where this virtualenv may be located.

Identity mapping

When unable to find an installed package that corresponds to a declared dependency either via a user-provided mapping or local Python environments, FawltyDeps will fall back to one of two strategies. "Identity mapping", which we present in this section is the default fallback strategy. We discuss the other strategy in the next subsection.

Identity mapping relies on the simplistic assumption that the dependency provides a single import of the same name, i.e. it will expect that when you depend on some_package, then that should correspond to import some_package statements in your code.

This assumption is correct for many packages and it allows FawltyDeps to produce results (albeit sometimes inaccurate ones) when the current Python environment does not contain all of your declared dependencies.

To ensure correctness, however, refer to the next subsection outlining the other fallback strategy.

Mapping by temporarily installing packages

Your local Python environments might not always have all your project's dependencies installed. Assuming that you don’t want to go through the bother of installing packages manually, and you also don't want to rely on the inaccurate identity mapping as your fallback strategy, you can use the --install-deps option. This will automatically install missing dependencies (from PyPI, by default) into a temporary virtualenv, and allow FawltyDeps to use this to come up with the correct mapping.

Since this is a potentially expensive strategy (e.g. downloading packages from PyPI), we have chosen to hide it behind the --install-deps command-line option. If you want to always enable this option, you can set the corresponding install_deps configuration variable to true in the [tool.fawltydeps] section of your pyproject.toml.

FawltyDeps will use uv by default to temporarily install missing dependencies. If uv not available, pip will be used instead. If you want to ensure that the faster uv is available, you can install fawltydeps with the uv extra (e.g. pip install fawltydeps[uv]).

To further customize how this automatic installation is done (e.g. if you need to use a different package index), you can use environment variables to alter uv's or pip’s behavior.

Note that we’re never guaranteed to be able to resolve all dependencies with this method: For example, there could be a typo in your requirements.txt that means a dependency will never be found on PyPI, or there could be other circumstances (e.g. network issues or restrictions in your CI environment) that prevent this strategy from working at all. In this case, FawltyDeps will throw an error and abort.

User-defined mapping

We provide a custom mapping functionality to users wishing to take control over the way FawltyDeps resolves dependencies. You may define your own mapping of dependency names to import names, by providing a TOML file like this:

my-package = ["mpkg"]
scikit-learn = ["sklearn"]
multiple-modules = ["module1", "module2"]

To use your mapping, run:

fawltydeps --custom-mapping-file my_mapping.toml

FawltyDeps will parse your my_mapping.toml file and use the extracted mapping for matching dependencies to imports.

You may also place the custom mapping in the pyproject.toml file of your project, inside a [tool.fawltydeps.custom_mapping] section, like this:

[tool.fawltydeps.custom_mapping]
my-package = ["mpkg"]
scikit-learn = ["sklearn"]
multiple-modules = ["module1", "module2"]

The provided mapping can be complete or partial. When a dependency is not present in the given mapping, FawltyDeps will continue to resolve it using the sequence of resolvers illustrated in the diagram above.

Caution when using your mapping is advised: As illustrated in the diagram, the user-defined mapping takes precedence over the other resolvers documented above. For example, if the mapping file has some stale/incorrect mapping entries, they will not be resolved by the Python environment resolver (which is usually more accurate).

Excluding paths

If you want FawltyDeps to exclude parts of your source tree when loooking for code, dependency declarations, or Python environments, then you can use the --exclude option to specify path patterns to exclude, e.g. the following command will skip everything under tests/:

fawltydeps --exclude tests/

The format of the exclude patterns is the same as used by .gitignore files, see here for a full description.

When the --exclude option is not specified, its default value is ".*", which matches all paths that start with a dot (.), aka. "hidden" paths. In the above example, if you want to exclude both hidden paths, and everything under tests/, then instead use:

fawltydeps --exclude tests/ ".*"

(The extra quotes here are needed to prevent the shell from interpreting and replacing the * wildcard.)

You can also point to exclude patterns stored in a file, with the --exclude-from option. E.g. to read exclude patterns from ./my_excludes.txt:

fawltydeps --exclude-from my_excludes.txt

Exclude patterns have lower priority than any paths you pass directly on the command line, e.g. in this command:

fawltydeps --code my_file.py --exclude my_file.py

the --code options "wins" (i.e. imports in my_file.py will be found); the --exclude option only takes affect when traversing directories to look for more files. E.g. use this to find code inside my_dir, but skip Jupyter notebooks:

fawltydeps --code my_dir --exclude "*.ipynb"

Ignoring irrelevant results

There may be import statements in your code that should not be considered an undeclared dependency. This might happen if you for example do a conditional import with a try: ... except ImportError: ... block (or similar). FawltyDeps is not able to recognize whether these dependencies should have been declared or not, but you can ask for them to be ignored with the --ignore-undeclared option, for example: --ignore-undeclared some_module some_other_module

Conversely, there may be dependencies that you have declared without intending to import them. This is often the case for developer tools like Black or Mypy that are part of your project's development environment. We've introduced a DEFAULT_IGNORE_UNUSED list, which includes various categories of commonly used development tools and dependencies. FawltyDeps can automatically ignore these dependencies when checking for unused imports. For the complete list, please see the DEFAULT_IGNORE_UNUSED variable in the fawltydeps/settings.py file in the repository. If you have additional dependencies that you want to exclude from the check for unused imports, you can use the --ignore-unused option to customize the ignore list. By providing your own list of dependencies with this option, you can effectively overwrite the default list. For example: --ignore-unused black mypy some_other_module

Output formats

The default output from FawltyDeps is a summary outlining the relevant dependencies found (according to the selected actions). However you can also ask for more information from FawltyDeps:

Only one of these options can be used at a time.

More help

Run fawltydeps --help to get the full list of available options.

Configuration

You can use a [tool.fawltydeps] section in pyproject.toml to configure the default behavior of FawltyDeps. Here's a fairly comprehensive example:

[tool.fawltydeps]
code = ["myproject"]  # Only search for imports under ./myproject
deps = ["pyproject.toml"]  # Only look for declared dependencies here
ignore_unused = ["black"]  # We use `black`, but we don't intend to import it
output_format = "human_detailed"  # Detailed report by default

Here is a complete list of configuration directives we support:

Environment variables

In addition to configuring FawltyDeps via pyproject.toml as show above, you may also pass the above configuration directives via the environment, using a fawltydeps_ prefix. For example, to enable JSON output via the environment, set fawltydeps_output_format=json in FawltyDeps' environment.

Configuration cascade

Documentation

This project began with an exploration and design phase, yielding this design document, which lays out the main objective for this project and compares various strategies considered

In the code design section of documentation we lay out rules which we adopt to guide code architecture decisions and maintain code quality as the project evolves.

Development

For details on setting up your development environment, please refer to the contributing guidelines of how to set up your development environment in our CONTRIBUTING.md file.

Integration tests

For details on integration tests, please refer to the Testing section in our CONTRIBUTING.md file.

FAQ

I run fawltydeps and get some undeclared dependencies. What can I do with it?

You can run a detailed report to see the exact location (file and line number), in which the undeclared dependencies were imported:

fawltydeps --detailed

and debug each occurrence. Typically an undeclared dependency can be fixed in a couple of ways:

How not to display tools like black and pylint in unused dependencies?

By default, all packages declared as dependencies by your project are included in the FawltyDeps analysis, even if they only contain tools that were not meant to be imported, but rather meant to be run by, say, in a pre-commit hook or a CI script. In such cases you may use either:

fawltydeps --ignore-unused black pylint

or add an equivalent directive to the FawltyDeps configuration in your pyproject.toml (see below).

How can I store my fawltydeps command line options in a configuration file?

You can run:

fawltydeps --generate-toml-config

to generate a [tool.fawltydeps] section with the current configuration that you can then directly copy into your pyproject.toml. Options that have their default value are commented in this output, so you have quickly see where your settings differ from the FawltyDeps defaults.

This also works together with other command line options, so for example in the previous question, you could add --generate-toml-config to the command line (i.e. run fawltydeps --ignore-unused black pylint --generate-toml-config), to get this:

[tool.fawltydeps]
# Default options are commented...
ignore_unused = ["black", "pylint"]

How to use FawltyDeps in a monorepo?

Running fawltydeps without arguments at the root of a monorepo will most likely not give you a useful result: it will collect dependencies and import statements from across the entire monorepo. The produced report may be overwhelming and at the same time not granular enough.

Instead, you should run FawltyDeps for each package separately. This collects dependencies and import statements for one package at a time.

Having:

├ lib1
| ├ pyproject.toml
| ├ ....
├ lib2
| ├ pyproject.toml
| ├ ....

run for each libX:

fawltydeps libX

Why must FawltyDeps run in the same Python environment as my project dependencies?

(This is no longer true since FawltyDeps v0.11: FawltyDeps should be able to automatically find your project dependencies when they are installed in a Python environment that exists within your project. If your project dependencies are installed elsewhere, you can point FawltyDeps in their direction with --pyenv, as explained above in the section on Python environment mapping)

The reason why FawltyDeps need to find your project dependencies somewhere is that the core logic of FawltyDeps needs to match import statements in your code with dependencies declared in your project configuration. This seems straightforward for many packages: for example you pip install requests and then you can import requests in your code. However, this mapping from the name you install to the name you import is not always self-evident:

To solve this, FawltyDeps looks at the packages installed in your Python environment to correctly map dependencies (package names) into the imports that they provide. This is:

As a final resort, when an installed package is not found for a declared dependency, the identity mapping that FawltyDeps falls back to will still do a good job for the majority of dependencies where the import name is indeed identical to the package name that you depend on.

This is an area of active development in FawltyDeps, and we are working on better solutions, to avoid having to fall back to this identity mapping.

Why does FawltyDeps fail to match sklearn with scikit-learn?

There are cases, where FawltyDeps may not match imports and obviously related dependencies, like sklearn and scikit-learn. It will report sklearn as undeclared and scikit-learn as an unused dependency.

This is very much related to the above question. scikit-learn is an example of a package that exposes a different import name: sklearn. When scikit-learn is not found in the Python environment(s) used by FawltyDeps, then FawltyDeps is unable to make the connection between these two names.

To solve this problem, make sure that scikit-learn is installed in a Python environment that belongs to your project. Alternatively, you can use the --pyenv option to point at a Python environment where scikit-learn and your other dependencies are installed.

How can I pass Python code to FawltyDeps via standard input?

The --code argument accepts a single hyphen (-) as a special value meaning that code should be read from standard input. When using this you may pipe or redirect your Python code into FawltyDeps like this:

cat some/source/of/python/code | fawltydeps --code -
# or
fawltydeps --code - < some/source/of/python/code

You can also use this directly in the terminal to e.g. have FawltyDeps analyze some Python code that is in your clipboard:

fawltydeps --code -
# FawltyDeps waits for code on stdin; paste from your clipboard,
# then press Ctrl+D to signal EOF (end-of-file).

Can I use FawltyDeps as a pre-commit hook?

Yes! Assuming that you already use the pre-commit tool, you can add something like this to your project's .pre-commit-config.yaml:

repos:
  - repo: https://github.com/tweag/FawltyDeps
    rev: v0.17.0
    hooks:
      - id: check-undeclared
      - id: check-unused