Reference implementations of PQC

Henry Case dafff237c2 Merge pull request 'sike' (#1 ) from sike into main Reviewed-on: #1		vor 3 Jahren
.cmake	KEM and Sign C-API	vor 3 Jahren
.github/workflows	Fix testing against KATs	vor 3 Jahren
3rd	update cpu_features submodule	vor 3 Jahren
buid.dbg	add drone.yml	vor 3 Jahren
public/pqc	update sike	vor 3 Jahren
src	check if adox available	vor 3 Jahren
test	SIKE/p434 goes thru KATs	vor 3 Jahren
.astylerc	Disable AStyle line endings formatter	vor 5 Jahren
.drone.yml	Update '.drone.yml'	vor 3 Jahren
.gitattributes	Fix tidy for signing	vor 5 Jahren
.gitignore	Parallel tests (#206)	vor 5 Jahren
.gitmodules	change path to cpu_features submodule	vor 3 Jahren
CMakeLists.txt	use haswell as default arch	vor 3 Jahren
LICENSE	Create LICENSE	vor 3 Jahren
README.md	Merge pull request 'sike' (#1) from sike into main	vor 3 Jahren

README.md

PQ Crypto Catalog

This is a repository of post-quantum schemes copied from either the submission to the NIST Post-Quantum Standardization or PQClean project. The goal of the library is to provide easy to use API which enables quick experimentation with some post-quantum cryptographic schemes.

Users shouldn’t expect any level of security provided by this code. The library is not meant to be used on live production systems.

Schemes support

Name	NIST Round	x86 optimized
Kyber	3	x
NTRU	3	x
SABER	3	x
FrodoKEM	3
NTRU Prime	3	x
HQC-RMRS	3	x
Dilithium	3	x
Falcon	2
Rainbow	3
SPHINCS+ SHA256/SHAKE256	3	x
SIKE/p434	3	x

Building

CMake is used to build the library:

mkdir build
cd build
cmake -DCMAKE_BUILD_TYPE=Release ..
make

Build outputs two libraries, a static libpqc_s.a and dynamic libpqc.so, which can be linked with a project.

API

Library provides simple API, wrapping PQClean. For example to use KEM, one should call the library in following way:

    #include <pqc/pqc.h>

    std::vector<uint8_t> ct(ciphertext_bsz(p));
    std::vector<uint8_t> ss1(shared_secret_bsz(p));
    std::vector<uint8_t> ss2(shared_secret_bsz(p));
    std::vector<uint8_t> sk(private_key_bsz(p));
    std::vector<uint8_t> pk(public_key_bsz(p));

    const params_t *p = pqc_kem_alg_by_id(KYBER512);
    pqc_keygen(p, pk.data(), sk.data());
    pqc_kem_encapsulate(p, ct.data(), ss1.data(), pk.data());
    pqc_kem_decapsulate(p, ss2.data(), ct.data(), sk.data());

    p = pqc_sig_alg_by_id(DILITHIUM2);
    size_t sigsz = sig.capacity();
    pqc_keygen(p, pk.data(), sk.data());
    pqc_sig_create(p, sig.data(), &sigsz, msg.data(), msg.size(), sk.data());
    pqc_sig_verify(p, sig.data(), sig.size(), msg.data(), msg.size(), pk.data());

See test implemetnation in test/ut.cpp for more details.

Rust binding

Rust bindgings are provided in the src/rustapi/pqc-sys and can be regenerated automatically by running cargo build in that directory.

Testing against Known Answer Tests

Algorithms are tested against KATs, by the Rust-based runner implemented in the test/katrunner (only verification/decpaulation). The runner uses katwalk crate for parsing NIST format. To run it:

    cd test/katrunner
    curl http://amongbytes.com/~flowher/permalinks/kat.zip --output kat.zip
    unzip kat.zip
    cargo run -- --katdir KAT