This repository contains a proof of Abel - Galois Theorem (equivalence between being solvable by radicals and having a solvable Galois group) and Abel - Ruffini Theorem (unsolvability of quintic equations) in the Coq proof-assistant and using the Mathematical Components library.
- Author(s):
- Sophie Bernard (initial)
- Cyril Cohen (initial)
- Assia Mahboubi (initial)
- Pierre-Yves Strub (initial)
- License: CeCILL-B
- Compatible Coq versions: Coq 8.10 to 8.16
- Additional dependencies:
- Coq namespace:
Abel
- Related publication(s):
The easiest way to install the latest released version of Abel - Ruffini Theorem as a Mathematical Component is via OPAM:
opam repo add coq-released https://coq.inria.fr/opam/released
opam install coq-mathcomp-abel
To instead build and install manually, do:
git clone https://github.com/math-comp/abel.git
cd abel
make # or make -j <number-of-cores-on-your-machine>
make install
-
abel.v
itself contains the main theorems:galois_solvable_by_radical
(requires explicit roots of unity),ext_solvable_by_radical
(equivalent, and still requires roots of unity),radical_solvable_ext
(no mention of roots of unity),AbelGalois
, (equivalence obtained from the above two, requires roots of unity), and consequences on solvability of polynomial- and their consequence on the example polynomial X⁵ -4X + 2:
example_not_solvable_by_radicals
,
-
xmathcomp/various.v
contains various (rather straightforward) extensions that should be added to various mathcomp packages asap with potential minor modifications, -
xmathcomp/char0.v
contains 0 characteristic specific results, that could use a refactoring for a smoother integration with mathcomp. e.g. ratr could get a canonical structure or rmorphism when the target field is almodType ratr
, and we could provide a wrapperNullCharType
akin toPrimeCharType
(fromfinfield.v
), -
xmathcomp/cyclotomic.v
contains complementary results about cyclotomic polynomials, -
xmathcomp/map_gal.v
contains complementary results about galois groups and galois extensions, including various isomorphisms, minimal galois extensions, solvable extensions, and mapping galois groups and galois extensions from a splitting field to another. This last construction is essential in switching to fields with roots of unity when we do not have them yet, -
xmathcomp/classic_ext.v
contains the theory of classic extensions by arbitrary polynomials, most of the results there are in the classically monad, making the results available either for a boolean goal or a classical goal. This was instrumental in eliminating references to some embarrassing roots of the unity. -
xmathcomp/algR.v
contains a proof that the real subset ofalgC
(isomorphic to{x : algC | x \is Num.real}
) is a real closed field (and archimedean), and endows this typealgR
with appropriate canonical instances. -
xmathcomp/real_closed_ext.v
contains some missing lemmas from the librarymath-comp/real_closed
, in particular bounding the number of real roots of a polynomial by one plus the number of real roots of its derivative,