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| # Cambridge combinatorics in Lean | ||
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| [](https://github.com/YaelDillies/LeanCamCombi/actions/workflows/push_master.yml) | ||
| [](https://gitpod.io/#https://github.com/YaelDillies/LeanCamCombi) | ||
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| This repository aims at formalising the mathematics courses relevant to combinatorics that are lectured in Cambridge, UK. | ||
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| ## What is formalisation? | ||
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| The purpose of this repository is to *digitise* some mathematical definitions, theorem statements and theorem proofs. Digitisation, or formalisation, is a process where the source material, typically a mathematical textbook or a PDF file is transformed into definitions in a target system consisting of a computer implementation of a logical theory (such as set theory or type theory). | ||
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| ### The source | ||
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| The definitions, theorems and proofs in this repository are (mostly) taken from five Cambridge courses, as well as a course from ETH Zürich: | ||
| * Part II Graph Theory, Michaelmas 2022, lectured by Julian Sahasrabudhe | ||
| * Part III Combinatorics, Michaelmas 2022 & [Michaelmas 2023](https://github.com/YaelDillies/maths-notes/blob/master/combinatorics.pdf), lectured by Béla Bollobás | ||
| * Part III Extremal and Probabilistic Combinatorics, Michaelmas 2023, lectured by Julian Sahasrabudhe | ||
| * Part III [Ramsey Theory on Graphs, Michaelmas 2024](https://github.com/YaelDillies/maths-notes/blob/master/ramsey_theory.pdf), lectured by Julian Sahasrabudhe | ||
| * Part III [Additive Combinatorics, Lent 2024](https://github.com/YaelDillies/maths-notes/blob/master/additive_combinatorics.pdf), lectured by Julia Wolf | ||
| * ETH Math-D [Growth in Groups, Winter 2024](https://sites.google.com/view/simonmachado/teaching), lectured by Simon Machado | ||
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| ### The target | ||
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| The formal system which we are using as a target is [Lean 4](https://lean-lang.org). Lean is a dependently typed theorem prover and programming language based on the Calculus of Inductive Constructions. It is being developed at AWS and Microsoft Research by Leonardo de Moura and his team. | ||
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| Our project is backed by [mathlib](https://leanprover-community.github.io), the major classical maths library written in Lean 4. | ||
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| ## Content | ||
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| The Lean code is located within the `LeanCamCombi` folder. Within it, one can find: | ||
| * One subfolder for each course, containing **formal lecture transcripts** in the files named `Lecture1`, `Lecture2`, etc... and **formal example sheet translations** in the files named `ExampleSheet1`, `ExampleSheet2`, etc... We follow the mathlib philosophy of aiming for the most general result within reach. This means that not all proofs follow the lecture notes, and might instead derive a result proved in the lectures from a general theorem. Those general theorems and prerequisite lemmas are proved in other folders. Read below. | ||
| * A `Mathlib` subfolder for the **prerequisites** to be upstreamed to mathlib. Lemmas that belong in an existing mathlib file `Mathlib.X` will be located in `LeanCamCombi.Mathlib.X`. We aim to preserve the property that `LeanCamCombi.Mathlib.X` only imports `Mathlib.X` and files of the form `LeanCamCombi.Mathlib.Y` where `Mathlib.X` (transitively) imports `Mathlib.Y`. Prerequisites that do not belong in any existing mathlib file are placed in subtheory folders. See below. | ||
| * One folder for each **theory development**. The formal lecture transcripts only contain what was stated in the lectures, but sometimes it makes sense for a theory to be developed as a whole before being incorporated by the prerequisites or imported in the formal lecture transcripts. | ||
| * An `Archive` subfolder for **archived results**. It sometimes happens in mathlib that a long argument gets replaced by a shorter one, with a different proof. When the long argument was proved in a lecture, we salvage it to `LeanCamCombi` for conservation purposes. | ||
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| ### Content under development | ||
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| The following topics are under active development in LeanCamCombi. | ||
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| * The Erdős-Rényi model for random graphs, aka binomial random graph | ||
| * The Littlewood-Offord problem | ||
| * The van den Berg-Kesten-Reimer inequality | ||
| * The impact function of a set | ||
| * Simplicial complexes and Sperner's lemma | ||
| * Discrete calculus | ||
| * The Birkhoff representation theorem, categorical version | ||
| * The Minkowski-Carathéodory theorem | ||
| * Approximate subgroups | ||
| * Chevalley's theorem about constructible sets | ||
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| See the [upstreaming dashboard](https://yaeldillies.github.io/LeanCamCombi/upstreaming) for more information. | ||
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| ### Current content | ||
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| The following topics are covered in LeanCamCombi and could be upstreamed to Mathlib. | ||
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| * Kneser's addition theorem | ||
| * The Sylvester-Chvatal theorem | ||
| * Containment of graphs | ||
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| See the [upstreaming dashboard](https://yaeldillies.github.io/LeanCamCombi/upstreaming) for more information. | ||
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| The following topics are archived because they are already covered by mathlib, but nevertheless display interesting proofs: | ||
| * The Cauchy-Davenport theorem for `ℤ/pℤ` as a corollary of Kneser's theorem. | ||
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| ### Past content | ||
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| The following topics have been upstreamed to mathlib and no longer live in LeanCamCombi. | ||
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| * The Ahlswede-Zhang inequality | ||
| * The four functions theorem and related discrete correlation inequalities: FKG inequality, Holley inequality, Daykin inequality, Marica-Schönheim inequality | ||
| * The Birkhoff representation theorem, non-categorical version | ||
| * The Cauchy-Davenport theorem for general groups, and also for linearly ordered cancellative semigroup | ||
| * The Erdős-Ginzburg-Ziv theorem | ||
| * Shatterings of sets, the Sauer-Shelah lemma and the Vapnik-Chervonenkis dimension | ||
| * Sublattices | ||
| * Incidence algebras | ||
| * Strongly convex functions | ||
| * The Marica-Schönheim proof of the squarefree special case of Graham's conjecture | ||
| * Visibility of a point through a set | ||
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| ## Interacting with the project | ||
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| ### Getting the project | ||
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| To build the Lean files of this project, you need to have a working version of Lean. | ||
| See [the installation instructions](https://leanprover-community.github.io/get_started.html) (under Regular install). | ||
| Alternatively, click on the button below to open a Gitpod workspace containing the project. | ||
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| [](https://gitpod.io/#https://github.com/YaelDillies/LeanAPAP) | ||
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| In either case, run `lake exe cache get` and then `lake build` to build the project. | ||
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| ### Browsing the project | ||
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| With the project opened in VScode, you are all set to start exploring the code. There are two pieces of functionality that help a lot when browsing through Lean code: | ||
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| * "Go to definition": If you right-click on a name of a definition or lemma (such as `ErdosRenyi`, or `Finset.sups`), then you can choose "Go to definition" from the menu, and you will be taken to the relevant location in the source files. This also works by `Ctrl`-clicking on the name. | ||
| * "Goal view": in the event that you would like to read a *proof*, you can step through the proof line-by-line, and see the internals of Lean's "brain" in the Goal window. If the Goal window is not open, you can open it by clicking on the forall icon in the top right hand corner. | ||
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| ### Contributing | ||
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| **This project is open to contribution**. You are in fact encouraged to have a look at the example sheet translations and try your hand at one of the problems. If you manage to prove one of them, please open a PR! | ||
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| If you want to contribute a theorem or theory development, please open a PR! Note however that the standard of code is pretty high and that is not because you have formalised a concept/proved a theorem that it can be included into LeanCamCombi as is. Nonetheless I am willing to review your code and put it in shape for incorporation. |