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capyCRYPT - A Complete Rust Cryptosystem

Build Status Crates.io License: MIT

A complete Rust cryptosystem implementing:

These primitives form the basis of a platform supporting a wide variety of cryptographic operations, which are detailed below.

Security

This library is built with love as an academic excercise in cryptographic algorithm design. Despite how awesome and cool it is, it probably shouldn't be used for anything serious right now. If you find ways to make it even better, open an issue or PR and we'll gladly engage.

Features

  • AES: NIST-Compliant Advanced Encryption Standard (AES) implementation for encrypting and decrypting data.

  • Edwards Elliptic Curve: High-performance, side-channel resistant instance of the Ed448-Goldilocks curve for asymmetric operations.

  • SHA-3: NIST-Compliant Secure Hash Algorithm 3 (SHA-3) implementation for generating cryptographic hash values, symmetric keystreams, and PRNGs.

  • ML-KEM 768: NIST Initial Public Draft (IPD)-Compliant Module Ring-Learning With Errors Key Encapsulation Mechanism (ML-KEM) for quantum-safe asymmetric key and message exchange.

Supported Operations

  • Message Digest: Computes hash of a given message, with adjustable digest lengths.
  • MACs: Computes message authentication code of a given message, with adjustable bit security.
  • Shared Secret Key: Symmetric message encryption and decryption.
  • Public Key Cryptography: Asymmetric message encryption under public key, decryption with secret key.
  • Signatures Prove and verify knowledge of secret information with Schnorr/ECDHIES signatures.
  • Quantum-Safe Message Exchange: Send and receive arbitrary-length quantum-secure encryptions with ML-KEM + SHA3.

Installation

Add the following line to your Cargo.toml file:

cargo add capycrypt

Quick Start

Quantum-Secure Encrypt/Decrypt:

use capycrypt::{
    kem::{encryptable::KEMEncryptable, keypair::kem_keygen},
    sha3::aux_functions::byte_utils::get_random_bytes,
    Message, SecParam,
};

// Get 5mb random data
let mut msg = Message::new(get_random_bytes(5242880));

// Create a new ML-KEM public/private keypair
let (kem_pub_key, kem_priv_key) = kem_keygen();
// Encrypt the message
msg.kem_encrypt(&kem_pub_key, SecParam::D256);
// Decrypt and verify
assert!(msg.kem_decrypt(&kem_priv_key).is_ok());

Elliptic-Curve Encrypt/Decrypt:

use capycrypt::{
    ecc::{encryptable::KeyEncryptable, keypair::KeyPair},
    sha3::aux_functions::byte_utils::get_random_bytes,
    Message, SecParam,
};

// Get 5mb random data
let mut msg = Message::new(get_random_bytes(5242880));

// Create a new elliptic-curve public/private keypair
let key_pair = KeyPair::new(
    &get_random_bytes(64),   // random password for key
    "test key".to_string(),  // label
    SecParam::D256,         // bit-security for key
);
// Encrypt the message
msg.key_encrypt(&key_pair.pub_key, SecParam::D256);
// Decrypt and verify
assert!(msg.key_decrypt(&key_pair.priv_key).is_ok());

Symmetric Encrypt/Decrypt:

use capycrypt::{
    aes::encryptable::AesEncryptable,
    sha3::{aux_functions::byte_utils::get_random_bytes, 
    encryptable::SpongeEncryptable},
    Message, SecParam,
};
// Get a random password
let pw = get_random_bytes(16);
// Get 5mb random data
let mut msg = Message::new(get_random_bytes(5242880));
// Encrypt the data
msg.aes_encrypt_ctr(&pw);
// Decrypt the data
assert!(msg.aes_decrypt_ctr(&pw).is_ok());
// Encrypt the data
msg.sha3_encrypt(&pw, SecParam::D512);
// Decrypt and verify
assert!(msg.sha3_decrypt(&pw).is_ok());

Schnorr Signatures:

use capycrypt::{
    ecc::{keypair::KeyPair, signable::Signable},
    sha3::aux_functions::byte_utils::get_random_bytes,
    Message, SecParam,
};
// Get random 5mb
let mut msg = Message::new(get_random_bytes(5242880));
// Create a new elliptic-curve public/private keypair
let key_pair = KeyPair::new(
    &get_random_bytes(64),  // random password for key
    "test key".to_string(), // label
    SecParam::D256,        // bit-security for key
);
// Sign with 128 bits of security
msg.sign(&key_pair, SecParam::D256);
// Verify signature
assert!(msg.verify(&key_pair.pub_key).is_ok());

Compute Digest:

use capycrypt::{sha3::hashable::SpongeHashable, Message, SecParam};
// Hash the empty string
let mut data = Message::new(vec![]);
// Obtained from echo -n "" | openssl dgst -sha3-256
let expected = "a7ffc6f8bf1ed76651c14756a061d662f580ff4de43b49fa82d80a4b80f8434a";
// Compute a SHA3 digest with 128 bits of security
data.compute_sha3_hash(SecParam::D256);
assert!(hex::encode(data.digest) == expected);

Performance

This library uses the criterion crate for benches. Running:

cargo bench

conducts benchmarks over parameter sets in order from lowest security to highest.

Symmetric operations compare well to openSSL. On an Intel® Core™ i7-10710U × 12, our adaption of in-place keccak from the XKCP achieves a runtime of approximately 20 ms to digest 5mb of random data, vs approximately 17 ms in openSSL.

(Plausible) Post-Quantum Security

This library pairs ML-KEM-768 to a SHA3-sponge construction for a quantum-safe public-key cryptosystem. It offers theoretic quantum-security through the use of the KEM and sponge primitives, which are both based on problems conjectured to be hard to solve for a quantum adversary. This design seeds the SHA-3 sponge with the secret shared through the KEM + a session nonce, which then faciliates high-performance symmetric encryption/decryption of arbitrary-length messages.

Our construction is non-standard, has not been subject to peer review, and lacks any formal audit. Our ML-KEM library itself is a work in progress and only supports the recommended NIST-II security parameter-set of 768. Furthermore, the current FIPS 203 IPD is, (as the name indicates), a draft, and final details about secure implementation may be subject to change. Our design currently exists in this library purely as an academic curiosity. Use it at your own risk, we provide no guarantee of security, reliability, or efficiency.

Acknowledgements

The authors wish to sincerely thank Dr. Paulo Barreto for the initial design of this library as well as the theoretical backbone of the Edward's curve functionality. We also wish to extend gratitude to the curve-dalek authors here and here for the excellent reference implementations and exemplary instances of rock-solid cryptography.

Our KEM is inspired by the excellent ML-KEM articles and go implementation by Filippo Valsorda and the always wonderful rust-crypto implementation by the great Tony Arcieri here.

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