Crates.io | frost-secp256k1 |
lib.rs | frost-secp256k1 |
version | 2.0.0 |
source | src |
created_at | 2023-03-10 00:58:19.258613 |
updated_at | 2024-10-23 13:49:14.85711 |
description | A Schnorr signature scheme over the secp256k1 curve that supports FROST. |
homepage | |
repository | https://github.com/ZcashFoundation/frost |
max_upload_size | |
id | 806000 |
size | 148,282 |
An implementation of Schnorr signatures on the secp256k1 curve for both single and threshold numbers of signers (FROST).
Creating a key with a trusted dealer and splitting into shares; then signing a message and aggregating the signature. Note that the example just simulates a distributed scenario in a single thread and it abstracts away any communication between peers.
# // ANCHOR: tkg_gen
use frost_secp256k1 as frost;
use rand::thread_rng;
use std::collections::BTreeMap;
let mut rng = thread_rng();
let max_signers = 5;
let min_signers = 3;
let (shares, pubkey_package) = frost::keys::generate_with_dealer(
max_signers,
min_signers,
frost::keys::IdentifierList::Default,
&mut rng,
)?;
# // ANCHOR_END: tkg_gen
// Verifies the secret shares from the dealer and store them in a BTreeMap.
// In practice, the KeyPackages must be sent to its respective participants
// through a confidential and authenticated channel.
let mut key_packages: BTreeMap<_, _> = BTreeMap::new();
for (identifier, secret_share) in shares {
# // ANCHOR: tkg_verify
let key_package = frost::keys::KeyPackage::try_from(secret_share)?;
# // ANCHOR_END: tkg_verify
key_packages.insert(identifier, key_package);
}
let mut nonces_map = BTreeMap::new();
let mut commitments_map = BTreeMap::new();
////////////////////////////////////////////////////////////////////////////
// Round 1: generating nonces and signing commitments for each participant
////////////////////////////////////////////////////////////////////////////
// In practice, each iteration of this loop will be executed by its respective participant.
for participant_index in 1..=min_signers {
let participant_identifier = participant_index.try_into().expect("should be nonzero");
let key_package = &key_packages[&participant_identifier];
// Generate one (1) nonce and one SigningCommitments instance for each
// participant, up to _threshold_.
# // ANCHOR: round1_commit
let (nonces, commitments) = frost::round1::commit(
key_package.signing_share(),
&mut rng,
);
# // ANCHOR_END: round1_commit
// In practice, the nonces must be kept by the participant to use in the
// next round, while the commitment must be sent to the coordinator
// (or to every other participant if there is no coordinator) using
// an authenticated channel.
nonces_map.insert(participant_identifier, nonces);
commitments_map.insert(participant_identifier, commitments);
}
// This is what the signature aggregator / coordinator needs to do:
// - decide what message to sign
// - take one (unused) commitment per signing participant
let mut signature_shares = BTreeMap::new();
# // ANCHOR: round2_package
let message = "message to sign".as_bytes();
# // In practice, the SigningPackage must be sent to all participants
# // involved in the current signing (at least min_signers participants),
# // using an authenticate channel (and confidential if the message is secret).
let signing_package = frost::SigningPackage::new(commitments_map, message);
# // ANCHOR_END: round2_package
////////////////////////////////////////////////////////////////////////////
// Round 2: each participant generates their signature share
////////////////////////////////////////////////////////////////////////////
// In practice, each iteration of this loop will be executed by its respective participant.
for participant_identifier in nonces_map.keys() {
let key_package = &key_packages[participant_identifier];
let nonces = &nonces_map[participant_identifier];
// Each participant generates their signature share.
# // ANCHOR: round2_sign
let signature_share = frost::round2::sign(&signing_package, nonces, key_package)?;
# // ANCHOR_END: round2_sign
// In practice, the signature share must be sent to the Coordinator
// using an authenticated channel.
signature_shares.insert(*participant_identifier, signature_share);
}
////////////////////////////////////////////////////////////////////////////
// Aggregation: collects the signing shares from all participants,
// generates the final signature.
////////////////////////////////////////////////////////////////////////////
// Aggregate (also verifies the signature shares)
# // ANCHOR: aggregate
let group_signature = frost::aggregate(&signing_package, &signature_shares, &pubkey_package)?;
# // ANCHOR_END: aggregate
// Check that the threshold signature can be verified by the group public
// key (the verification key).
# // ANCHOR: verify
let is_signature_valid = pubkey_package
.verifying_key()
.verify(message, &group_signature)
.is_ok();
# // ANCHOR_END: verify
assert!(is_signature_valid);
# Ok::<(), frost::Error>(())