package bls12-381-gen
Install
Dune Dependency
Authors
Maintainers
Sources
md5=5e550e69578c3b991b661c16f012a644
sha512=593051b6de70b8aa433161e8e49f9067cfafb9bbabc0c979958d0f7e1ebd6dd8f95cbb525343b7182a773e44da8d466e7b192578a579442eb58416855362ab77
README.md.html
OCaml implementation of BLS12-381
Encoding
Scalar
The scalar field is Fr = GF(0x73eda753299d7d483339d80809a1d80553bda402fffe5bfeffffffff00000001)
, encoded on 32 bytes in little endian.
Groups
For G1, the base field is Fq: GF(0x1a0111ea397fe69a4b1ba7b6434bacd764774b84f38512bf6730d2a0f6b0f6241eabfffeb153ffffb9feffffffffaaab
) and E(Fq) := y^2 = x^3 + 4
. An element of the base field can be encoded on 48 bytes (using only 381 bits, leaving 3 bits unused).
For G2, the base field is Fq2 := Fq[Z]/(X^2 + 1)
and E(Fq2) := y^2 = x^3 + 4 (Z + 1)
. An element of the base field can be encoded on 2 * 48 bytes representing each coefficient of the polynomial. 3 bits of each coefficient encoding are unused.
The « uncompressed » form (x, y)
of G1 and G2 is the concatenation of the elements x
and y
encoded in big endian.
The « compressed » form uses the first 3 most significant (and unused) bits of the coordinate x
.
the first most significant bit is always set to
1
to carry the information it is the compressed encoding of a point.the second most significant bit is set to
1
if the element is the identity of the curve.the third most significant bit is the sign of
y
. It is set to1
ify
is lexicographically larger than-y
.
Install
# if you implement a library and you don't need an actual implementation
opam install bls12-381
# to target UNIX
opam insall bls12-381-unix
# to target JavaScript, to be used with jsoo.
opam install bls12-381-js
See below how to use in your project.
Run tests
dune runtest
dune build @test/js/browser/serve # Check _build/default/test/js/browser and run `npm run serve`
To get the coverage (only ok for bls12-381-unix and bls12-381-gen)
dune runtest --instrument-with bisect_ppx --force
bisect-ppx-report html
How to use in my project
If you are developing a library using bls12-381
, you only need to add bls12-381
in the dependency list. However, if you are writing a binary, three packages are relevant:
bls12-381-unix
: to be used for UNIXbls12-381-js
: to be used to target JavaScript. It does rely on the node packages listed here, version >= 0.8.1, and suppose this module is loaded before in the global namespace under the name_RUSTC_BLS12_381
. Seetest/js/browser/
for an example. You need to use the appropriate package depending on the platform you target (Node or a bundler for the browser). For instance, if you target Node (resp. a bundler like webpack for a browser usage), you must use@dannywillems/rustc-bls12-381-node
(resp.@dannywillems/rustc-bls12-381
).bls12-381-js-gen
: if the module is loaded somewhere else than in the global namespace like the previous package supposes, you can use this third library that provides functors. The functors are expecting a module of the signature:sig val rust_module : unit -> Jsoo_lib.ESModule.t val get_wasm_memory_buffer : unit -> Jsoo_lib.Memory.Buffer.t end
(note: functions are not directly evaluated values are required because the module might not already be loaded when loading the JavaScript resulting file and the wasm memory buffer being a view over a ArrayBuffer might be invalid if the buffer size is increased at runtime). You can see an example in the
src/js
.
For more examples, see the test directories.
Run the benchmarks
opam install core_bench
dune exec benchmark/bench_ec.exe
dune exec benchmark/bench_ff.exe
dune exec benchmark/bench_pairing.exe
Documentation
opam install odoc
dune build @doc