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.
You can find detailed instructions to install Lean, mathlib, and supporting tools on our website. Alternatively, click on the button below to open a Gitpod workspace containing the project.
Please refer to https://github.com/leanprover-community/mathlib4/wiki/Using-mathlib4-as-a-dependency
Got everything installed? Why not start with the tutorial project?
For more pointers, see Learning Lean.
Besides the installation guides above and Lean's general documentation, the documentation of mathlib consists of:
- The mathlib4 docs: documentation generated
automatically from the source
.lean
files. - A description of currently covered theories, as well as an overview for mathematicians.
- 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, and you are welcome to join, or read along without signing up. Questions from users at all levels of expertise are welcome! We also provide an archive of the public discussions, which is useful for quick reference.
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.
You may want to subscribe to the mathlib4
stream
-
To obtain precompiled
olean
files, runlake exe cache get
. (Skipping this step means the next step will be very slow.) -
To build
mathlib4
runlake build
. -
To build and run all tests, run
lake test
. -
You can use
lake build Mathlib.Import.Path
to build a particular file, e.g.lake build Mathlib.Algebra.Group.Defs
. -
If you added a new file, run the following command to update
Mathlib.lean
lake exe mk_all
Mathlib has the following guidelines and conventions that must be followed
- The style guide
- A guide on the naming convention
- The documentation style
You can run lake exe cache get
to download cached build files that are computed by mathlib4
's automated workflow.
If something goes mysteriously wrong,
you can try one of lake clean
or rm -rf .lake
before trying lake exe cache get
again.
In some circumstances you might try lake exe cache get!
which re-downloads cached build files even if they are available locally.
Call lake exe cache
to see its help menu.
Building HTML documentation locally is straightforward, but it may take a while (>20 minutes):
lake -R -Kdoc=on update doc-gen4
lake build Mathlib:docs
The HTML files can then be found in build/doc
.
Warning: these commands will make a change to lake-manifest.json
which should not be committed to Mathlib.
For users familiar with Lean 3 who want to get up to speed in Lean 4 and migrate their existing Lean 3 code we have:
- A survival guide for Lean 3 users
- Instructions to run
mathport
on a project other than mathlib.mathport
is the tool the community used to port the entirety ofmathlib
from Lean 3 to Lean 4.
If you are a mathlib contributor and want to update dependencies, use lake update
,
or lake update batteries aesop
(or similar) to update a subset of the dependencies.
This will update the lake-manifest.json
file correctly.
You will need to make a PR after committing the changes to this file.
Please do not run lake update -Kdoc=on
as previously advised, as the documentation related
dependencies should only be included when CI is building documentation.
For a list containing more detailed information, see https://leanprover-community.github.io/teams/maintainers.html
- Anne Baanen (@Vierkantor): algebra, number theory, tactics
- Matthew Robert Ballard (@mattrobball): algebra, algebraic geometry, category theory, performance
- Reid Barton (@rwbarton): category theory, topology
- Riccardo Brasca (@riccardobrasca): algebra, number theory, algebraic geometry, category theory
- Kevin Buzzard (@kbuzzard): 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
- Anatole Dedecker (@ADedecker): topology, functional analysis, calculus
- 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
- Yury G. Kudryashov (@urkud): analysis, topology, measure theory
- Robert Y. Lewis (@robertylewis): tactics, documentation
- Jireh Loreaux (@j-loreaux): analysis, topology, operator algebras
- Heather Macbeth (@hrmacbeth): geometry, analysis
- Patrick Massot (@patrickmassot): documentation, topology, geometry
- Bhavik Mehta (@b-mehta): category theory, combinatorics
- Kyle Miller (@kmill): combinatorics, tactics, metaprogramming
- Kim Morrison (@semorrison): category theory, tactics
- Oliver Nash (@ocfnash): algebra, geometry, topology
- Joël Riou (@joelriou): category theory, homology, algebraic geometry
- Damiano Testa (@adomani): algebra, algebraic geometry, number theory, tactics
- Adam Topaz (@adamtopaz): algebra, category theory, algebraic geometry
- Eric Wieser (@eric-wieser): algebra, infrastructure
- Jeremy Avigad (@avigad): analysis
- Johannes Hölzl (@johoelzl): measure theory, topology
- Simon Hudon (@cipher1024): tactics
- Chris Hughes (@ChrisHughes24): algebra