pqc/README.md

# PQ Crypto Catalog

Implementation of quantum-safe signature and KEM schemes submitted to NIST PQC Standardization Process. 

The goal is to provide an easy-to-use API in C and Rust to enable experimentation. The code is derived from the submission to the NIST Post-Quantum Standardization, either directly or by leveraging [PQClean](https://github.com/PQClean/PQClean) project.

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

## Supported schemes

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

## Building

CMake is used to build the library:

```bash
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:
```c
    #include <pqc/pqc.h>

    const params_t *p = pqc_kem_alg_by_id(KYBER512);
    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));

    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:

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

```
Use CMake 2021-03-03 06:50:25 +00:00			`# PQ Crypto Catalog`
First sketch of the README 2019-01-11 00:05:16 +00:00
Update README.md 2021-05-26 11:15:16 +01:00			`Implementation of quantum-safe signature and KEM schemes submitted to NIST PQC Standardization Process.`
Update README.md 2021-05-15 22:21:09 +01:00
			`The goal is to provide an easy-to-use API in C and Rust to enable experimentation. The code is derived from the submission to the NIST Post-Quantum Standardization, either directly or by leveraging [PQClean](https://github.com/PQClean/PQClean) project.`
putting all badges in the README was a bit too much 2020-10-11 12:20:15 +01:00
Update README.md 2021-03-25 09:32:59 +00:00			`Users shouldn't expect any level of security provided by this code. The library is not meant to be used on live production systems.`
update readme with building instructions 2021-03-25 00:46:19 +00:00
Update README.md 2021-06-23 14:14:25 +01:00			`## Supported schemes`
update readme 2021-03-27 00:00:15 +00:00
			`\| Name \| NIST Round \| x86 optimized \|`
			`\|--------------------------\|------------\|---------------\|`
			`\| Kyber \| 3 \| x \|`
			`\| SABER \| 3 \| x \|`
			`\| FrodoKEM \| 3 \| \|`
			`\| Dilithium \| 3 \| x \|`
Implelments Falcon 512/1024 Round3 * Enable KAT testing for Falcon * Prefix all algorithms with PQC_ALG_SIG/KEM_ 2021-05-25 08:20:31 +01:00			`\| Falcon \| 3 \| \|`
update readme 2021-03-27 00:00:15 +00:00			`\| SPHINCS+ SHA256/SHAKE256 \| 3 \| x \|`
Update README.md 2021-06-23 14:14:25 +01:00			`\| NTRU \| 3 \| x \|`
			`\| NTRU Prime \| 3 \| x \|`
			`\| HQC-RMRS \| 3 \| x \|`
			`\| Rainbow \| 3 \| \|`
SIKE/p434 Pulls SIKE/p434 from CECPQ2 implementation changed to use SHAKE instead of SHA2 2021-04-06 23:41:01 +01:00			`\| SIKE/p434 \| 3 \| x \|`
Update README.md 2021-06-23 14:14:25 +01:00			`\| McEliece \| 3 \| \|`
pqapi.h -> pqc.h 2021-03-24 23:34:34 +00:00
			`## Building`

			`CMake is used to build the library:`

Update README.md 2021-03-27 00:11:37 +00:00			```bash
pqapi.h -> pqc.h 2021-03-24 23:34:34 +00:00			`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.

update readme with building instructions 2021-03-25 00:46:19 +00:00			`## API`

			`Library provides simple API, wrapping PQClean. For example to use KEM, one should call the library in following way:`
			```c
ups 2021-03-25 00:48:05 +00:00			`#include <pqc/pqc.h>`
update readme with building instructions 2021-03-25 00:46:19 +00:00
Update README.md 2021-05-04 07:47:35 +01:00			`const params_t *p = pqc_kem_alg_by_id(KYBER512);`
update readme with building instructions 2021-03-25 00:46:19 +00:00			`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));`

ups 2021-03-25 00:48:05 +00:00			`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());`
update readme 2021-03-27 00:00:15 +00:00
Update README.md 2021-03-28 16:58:13 +01:00			`p = pqc_sig_alg_by_id(DILITHIUM2);`
Update README.md 2021-03-25 07:34:06 +00:00			`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());`
update readme with building instructions 2021-03-25 00:46:19 +00:00			```

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

			`## Rust binding`

update readme 2021-03-27 00:00:15 +00:00			Rust bindgings are provided in the ``src/rustapi/pqc-sys`` and can be regenerated automatically by running ``cargo build`` in that directory.
update readme with building instructions 2021-03-25 00:46:19 +00:00
Update README.md 2021-03-27 00:07:28 +00:00			`## Testing against Known Answer Tests`
update readme with building instructions 2021-03-25 00:46:19 +00:00
Update README.md 2021-03-27 00:07:28 +00:00			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:
update readme 2021-03-27 00:00:15 +00:00
Update README.md 2021-03-27 00:11:37 +00:00			```bash
update readme 2021-03-27 00:00:15 +00:00			`cd test/katrunner`
			`curl http://amongbytes.com/~flowher/permalinks/kat.zip --output kat.zip`
			`unzip kat.zip`
			`cargo run -- --katdir KAT`

			```