| .github/workflows | ||
| src | ||
| tests | ||
| Cargo.toml | ||
| README.md | ||
double-ratchet-2
Implementation of the double ratchet system/encryption as specified by Signal.
The implementation follows the cryptographic recommendations provided by Signal. The AEAD Algorithm uses a constant Nonce. This might be changed in the future.
Example Usage:
Standard:
use double_ratchet_2::ratchet::Ratchet;
let sk = [1; 32]; // Initial Key created by a symmetric key agreement protocol
let (mut bob_ratchet, public_key) = Ratchet::init_bob(sk); // Creating Bobs Ratchet (returns Bobs PublicKey)
let mut alice_ratchet = Ratchet::init_alice(sk, public_key); // Creating Alice Ratchet with Bobs PublicKey
let data = b"Hello World".to_vec(); // Data to be encrypted
let (header, encrypted) = alice_ratchet.ratchet_encrypt(&data); // Encrypting message with Alice Ratchet (Alice always needs to send the first message)
let decrypted = bob_ratchet.ratchet_decrypt(&header, &encrypted); // Decrypt message with Bobs Ratchet
assert_eq!(data, decrypted)
With lost message:
let sk = [1; 32]; // Initial Key created by a symmetric key agreement protocol
let (mut bob_ratchet, public_key) = Ratchet::init_bob(sk); // Creating Bobs Ratchet (returns Bobs PublicKey)
let mut alice_ratchet = Ratchet::init_alice(sk, public_key); // Creating Alice Ratchet with Bobs PublicKey
let data = b"Hello World".to_vec(); // Data to be encrypted
let (header1, encrypted1) = alice_ratchet.ratchet_encrypt(&data); // Lost message
let (header2, encrypted2) = alice_ratchet.ratchet_encrypt(&data); // Successful message
let decrypted2 = bob_ratchet.ratchet_decrypt(&header2, &encrypted2); // Decrypting second message first
let decrypted1 = bob_ratchet.ratchet_decrypt(&header1, &encrypted1); // Decrypting latter message
let comp = decrypted1 == data && decrypted2 == data;
assert!(comp);
Encryption before recieving inital message
use double_ratchet_2::ratchet::Ratchet;
let sk = [1; 32];
let (mut bob_ratchet, _) = Ratchet::init_bob(sk);
let data = b"Hello World".to_vec();
let (_, _) = bob_ratchet.ratchet_encrypt(&data);
Encryption after recieving initial message
However bob can (of course) also encrypt messages. This is possible, after decrypting the first message from alice.
use double_ratchet_2::ratchet::Ratchet;
let sk = [1; 32];
let (mut bob_ratchet, public_key) = Ratchet::init_bob(sk);
let mut alice_ratchet = Ratchet::init_alice(sk, public_key);
let data = b"Hello World".to_vec();
let (header1, encrypted1) = alice_ratchet.ratchet_encrypt(&data);
let _decrypted1 = bob_ratchet.ratchet_decrypt(&header1, &encrypted1);
let (header2, encrypted2) = bob_ratchet.ratchet_encrypt(&data);
let decrypted2 = alice_ratchet.ratchet_decrypt(&header2, &encrypted2);
assert_eq!(data, decrypted2);
Constructing and Deconstructing Headers
let header_bytes: Vec<u8> = header.clone().into();
let header_const = Header::from(header_bytes);
assert_eq!(header, header_const);
Features
Currently the crate only supports one feature: ring. If feature is enabled the crate switches to ring-compat and uses ring as backend for Sha512 Hashing. May result in slightly better performance.
TODO:
- Standard Double Ratchet
- Double Ratchet with encrypted headers