# threshold_crypto [![Build Status](https://travis-ci.org/poanetwork/threshold_crypto.svg?branch=master)](https://travis-ci.org/poanetwork/threshold_crypto) A pairing-based threshold cryptosystem for collaborative decryption and signatures. The `threshold_crypto` crate provides constructors for encrypted message handling. It utilizes the [`pairing`](https://crates.io/crates/pairing) elliptic curve library to create and enable reconstruction of public and private key shares. In a network environment, messages are signed and encrypted, and key and signature shares are distributed to network participants. A message can be decrypted and authenticated only with cooperation from at least `threshold + 1` nodes. ## Usage `Cargo.toml`: ```toml [dependencies] rand = "0.4" threshold_crypto = { version = "0.1", git = "https://github.com/poanetwork/threshold_crypto" } ``` `main.rs`: ```rust extern crate rand; extern crate threshold_crypto; use threshold_crypto::SecretKey; /// Very basic secret key usage. fn main() { let sk0: SecretKey = rand::random(); let sk1: SecretKey = rand::random(); let pk0 = sk0.public_key(); let msg0 = b"Real news"; let msg1 = b"Fake news"; assert!(pk0.verify(&sk0.sign(msg0), msg0)); assert!(!pk0.verify(&sk1.sign(msg0), msg0)); // Wrong key. assert!(!pk0.verify(&sk0.sign(msg1), msg0)); // Wrong message. } ``` ### Testing Run tests using the following command: ``` $ cargo test ``` ### Examples Run examples from the [`examples`](examples) directory using: ``` $ cargo run --example ``` Also see the [distributed_key_generation](https://github.com/poanetwork/threshold_crypto/blob/d81953b55d181311c2a4eed2b6c34059fcf3fdae/src/poly.rs#L967) test. ## Application Details The basic usage outline is: * choose a threshold value `t` * create a key set * distribute `N` secret key shares among the participants * publish the public master key A third party can now encrypt a message to the public master key and any set of `t + 1` participants *(but no fewer!)* can collaborate to decrypt it. Also, any set of `t + 1` participants can collaborate to sign a message, producing a signature that is verifiable with the public master key. In this system, a signature is unique and independent of the set of participants that produced it. If `S1` and `S2` are signatures for the same message, produced by two different sets of `t + 1` secret key share holders, both signatures will be valid AND equal. This is useful in some applications, for example a message signature can serve as a pseudorandom number unknown to anyone until `t + 1` participants agree to reveal it. In its simplest form, threshold_crypto requires a trusted dealer to produce and distribute the secret key shares. However, keys can be produced so that only the corresponding participant knows their secret in the end. This crate includes the basic tools to implement such a *Distributed Key Generation* scheme. A major application for this library is within a distributed network that must tolerate up to `t` adversarial (malicious or faulty) nodes. Because `t + 1` nodes are required to sign or reveal information, messages can be trusted by third-parties as representing the consensus of the network. ## Performance Benchmarking functionality is kept in the [`benches` directory](benches). You can run the benchmarks with the following command: ``` $ RUSTFLAGS="-C target_cpu=native" cargo bench ``` We use the [`criterion`](https://crates.io/crates/criterion) benchmarking library. ## License Licensed under either of: * Apache License, Version 2.0, ([LICENSE-APACHE](LICENSE-APACHE) or http://www.apache.org/licenses/LICENSE-2.0) * MIT license ([LICENSE-MIT](LICENSE-MIT) or http://opensource.org/licenses/MIT) at your option. ## Contributing See the [CONTRIBUTING](CONTRIBUTING.md) document for contribution, testing and pull request protocol. Unless you explicitly state otherwise, any contribution intentionally submitted for inclusion in the work by you, as defined in the Apache-2.0 license, shall be dual licensed as above, without any additional terms or conditions.