Awesome

Lean mathlib

Mathlib is a user maintained library for the Lean theorem prover. It contains both programming infrastructure and mathematics, as well as tactics that use the former and allow to develop the latter.

Installation

You can find detailed instructions to install Lean, mathlib, and supporting tools on our website.

Experimenting

Got everything installed? Why not start with the tutorial project?

For more pointers, see Learning Lean.

Documentation

Besides the installation guides above and Lean's general documentation, the documentation of mathlib consists of:

The mathlib docs: documentation generated automatically from the source .lean files. In addition to the pages generated for each file in the library, the docs also include pages on:
- tactics,
- commands,
- hole commands, and
- attributes.
A description of currently covered theories, as well as an overview for mathematicians.
A couple of tutorial Lean files
Some extra Lean documentation not specific to mathlib (see "Miscellaneous topics")
Documentation for people who would like to contribute to mathlib

Much of the discussion surrounding mathlib occurs in a Zulip chat room. Since this chatroom is only visible to registered users, we provide an openly accessible archive of the public discussions. This is useful for quick reference; for a better browsing interface, and to participate in the discussions, we strongly suggest joining the chat. Questions from users at all levels of expertise are welcomed.

Contributing

The complete documentation for contributing to mathlib is located on the community guide contribute to mathlib

The process is different from other projects where one should not fork the repository. Instead write permission for non-master branches should be requested on Zulip by introducing yourself, providing your GitHub handle and what contribution you are planning on doing.

Guidelines

Mathlib has the following guidelines and conventions that must be followed

Note: the title of a PR should follow the commit naming convention.

Using `leanproject` to contribute

Running the leanproject get -b mathlib:shiny_lemma command will create a new worktree mathlib_shiny_lemma with a local branch called shiny_lemma which has a copy of mathlib to work on.

leanproject build will check that nothing broke. Be warned that this will take some time if a fundamental file was changed.

Maintainers:

Anne Baanen (@Vierkantor): algebra, number theory, tactics
Reid Barton (@rwbarton): category theory, topology
Riccardo Brasca (@riccardobrasca): algebra, number theory, algebraic geometry, category theory
Mario Carneiro (@digama0): lean formalization, tactics, type theory, proof engineering
Bryan Gin-ge Chen (@bryangingechen): documentation, infrastructure
Johan Commelin (@jcommelin): algebra, number theory, category theory, algebraic geometry
Rémy Degenne (@RemyDegenne): probability, measure theory, analysis
Floris van Doorn (@fpvandoorn): measure theory, model theory, tactics
Frédéric Dupuis (@dupuisf): linear algebra, functional analysis
Gabriel Ebner (@gebner): tactics, infrastructure, core, formal languages
Sébastien Gouëzel (@sgouezel): topology, calculus, geometry, analysis, measure theory
Markus Himmel (@TwoFX): category theory
Chris Hughes (@ChrisHughes24): algebra
Yury G. Kudryashov (@urkud): analysis, topology, measure theory
Robert Y. Lewis (@robertylewis): tactics, documentation
Heather Macbeth (@hrmacbeth): geometry, analysis
Patrick Massot (@patrickmassot): documentation, topology, geometry
Bhavik Mehta (@b-mehta): category theory, combinatorics
Kyle Miller (@kmill): combinatorics, documentation
Scott Morrison (@semorrison): category theory, tactics
Oliver Nash (@ocfnash): algebra, geometry, topology
Adam Topaz (@adamtopaz): algebra, category theory, algebraic geometry
Eric Wieser (@eric-wieser): algebra, infrastructure

Emeritus maintainers:

Jeremy Avigad (@avigad): analysis
Johannes Hölzl (@johoelzl): measure theory, topology
Simon Hudon (@cipher1024): tactics