2022-11-10 22:35:09 -05:00
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use core::{ops::Deref, fmt::Debug};
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2022-07-15 01:26:07 -04:00
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use std::{
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2022-10-25 23:17:25 -05:00
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io::{self, Read, Write},
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2022-07-15 01:26:07 -04:00
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collections::HashMap,
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};
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2022-04-21 21:36:18 -04:00
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2022-12-13 20:25:32 -05:00
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use rand_core::{RngCore, CryptoRng, SeedableRng};
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use rand_chacha::ChaCha20Rng;
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2022-04-21 21:36:18 -04:00
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2023-01-01 01:54:18 -05:00
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use zeroize::{Zeroize, Zeroizing};
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Utilize zeroize (#76)
* Apply Zeroize to nonces used in Bulletproofs
Also makes bit decomposition constant time for a given amount of
outputs.
* Fix nonce reuse for single-signer CLSAG
* Attach Zeroize to most structures in Monero, and ZOnDrop to anything with private data
* Zeroize private keys and nonces
* Merge prepare_outputs and prepare_transactions
* Ensure CLSAG is constant time
* Pass by borrow where needed, bug fixes
The past few commitments have been one in-progress chunk which I've
broken up as best read.
* Add Zeroize to FROST structs
Still needs to zeroize internally, yet next step. Not quite as
aggressive as Monero, partially due to the limitations of HashMaps,
partially due to less concern about metadata, yet does still delete a
few smaller items of metadata (group key, context string...).
* Remove Zeroize from most Monero multisig structs
These structs largely didn't have private data, just fields with private
data, yet those fields implemented ZeroizeOnDrop making them already
covered. While there is still traces of the transaction left in RAM,
fully purging that was never the intent.
* Use Zeroize within dleq
bitvec doesn't offer Zeroize, so a manual zeroing has been implemented.
* Use Zeroize for random_nonce
It isn't perfect, due to the inability to zeroize the digest, and due to
kp256 requiring a few transformations. It does the best it can though.
Does move the per-curve random_nonce to a provided one, which is allowed
as of https://github.com/cfrg/draft-irtf-cfrg-frost/pull/231.
* Use Zeroize on FROST keygen/signing
* Zeroize constant time multiexp.
* Correct when FROST keygen zeroizes
* Move the FROST keys Arc into FrostKeys
Reduces amount of instances in memory.
* Manually implement Debug for FrostCore to not leak the secret share
* Misc bug fixes
* clippy + multiexp test bug fixes
* Correct FROST key gen share summation
It leaked our own share for ourself.
* Fix cross-group DLEq tests
2022-08-03 03:25:18 -05:00
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2022-05-03 07:20:24 -04:00
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use transcript::Transcript;
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2023-03-07 03:46:16 -05:00
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use ciphersuite::group::{ff::PrimeField, GroupEncoding};
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2022-12-13 20:25:32 -05:00
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use multiexp::BatchVerifier;
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2022-07-12 01:28:01 -04:00
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2022-05-24 21:41:14 -04:00
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use crate::{
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2022-10-25 23:17:25 -05:00
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curve::Curve,
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2023-02-23 06:50:45 -05:00
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Participant, FrostError, ThresholdParams, ThresholdKeys, ThresholdView,
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2022-10-29 03:54:42 -05:00
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algorithm::{WriteAddendum, Addendum, Algorithm},
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2022-10-25 23:17:25 -05:00
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validate_map,
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2022-05-24 21:41:14 -04:00
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};
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2022-04-21 21:36:18 -04:00
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2022-10-25 23:17:25 -05:00
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pub(crate) use crate::nonce::*;
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/// Trait enabling writing preprocesses and signature shares.
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pub trait Writable {
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fn write<W: Write>(&self, writer: &mut W) -> io::Result<()>;
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2022-10-29 03:54:42 -05:00
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fn serialize(&self) -> Vec<u8> {
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let mut buf = vec![];
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self.write(&mut buf).unwrap();
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buf
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}
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2022-10-25 23:17:25 -05:00
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}
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impl<T: Writable> Writable for Vec<T> {
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fn write<W: Write>(&self, writer: &mut W) -> io::Result<()> {
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for w in self {
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w.write(writer)?;
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}
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Ok(())
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}
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}
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2022-10-29 03:54:42 -05:00
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/// Pairing of an Algorithm with a ThresholdKeys instance and this specific signing set.
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2022-10-29 05:10:07 -04:00
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#[derive(Clone, Zeroize)]
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2022-04-21 21:36:18 -04:00
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pub struct Params<C: Curve, A: Algorithm<C>> {
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2023-01-01 01:54:18 -05:00
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// Skips the algorithm due to being too large a bound to feasibly enforce on users
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2022-10-29 05:10:07 -04:00
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#[zeroize(skip)]
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2022-04-21 21:36:18 -04:00
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algorithm: A,
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2022-10-29 03:54:42 -05:00
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keys: ThresholdKeys<C>,
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2022-04-21 21:36:18 -04:00
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}
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impl<C: Curve, A: Algorithm<C>> Params<C, A> {
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2023-03-17 23:43:32 -04:00
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pub fn new(algorithm: A, keys: ThresholdKeys<C>) -> Params<C, A> {
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Params { algorithm, keys }
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2022-04-21 21:36:18 -04:00
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}
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2022-10-29 03:54:42 -05:00
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pub fn multisig_params(&self) -> ThresholdParams {
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Utilize zeroize (#76)
* Apply Zeroize to nonces used in Bulletproofs
Also makes bit decomposition constant time for a given amount of
outputs.
* Fix nonce reuse for single-signer CLSAG
* Attach Zeroize to most structures in Monero, and ZOnDrop to anything with private data
* Zeroize private keys and nonces
* Merge prepare_outputs and prepare_transactions
* Ensure CLSAG is constant time
* Pass by borrow where needed, bug fixes
The past few commitments have been one in-progress chunk which I've
broken up as best read.
* Add Zeroize to FROST structs
Still needs to zeroize internally, yet next step. Not quite as
aggressive as Monero, partially due to the limitations of HashMaps,
partially due to less concern about metadata, yet does still delete a
few smaller items of metadata (group key, context string...).
* Remove Zeroize from most Monero multisig structs
These structs largely didn't have private data, just fields with private
data, yet those fields implemented ZeroizeOnDrop making them already
covered. While there is still traces of the transaction left in RAM,
fully purging that was never the intent.
* Use Zeroize within dleq
bitvec doesn't offer Zeroize, so a manual zeroing has been implemented.
* Use Zeroize for random_nonce
It isn't perfect, due to the inability to zeroize the digest, and due to
kp256 requiring a few transformations. It does the best it can though.
Does move the per-curve random_nonce to a provided one, which is allowed
as of https://github.com/cfrg/draft-irtf-cfrg-frost/pull/231.
* Use Zeroize on FROST keygen/signing
* Zeroize constant time multiexp.
* Correct when FROST keygen zeroizes
* Move the FROST keys Arc into FrostKeys
Reduces amount of instances in memory.
* Manually implement Debug for FrostCore to not leak the secret share
* Misc bug fixes
* clippy + multiexp test bug fixes
* Correct FROST key gen share summation
It leaked our own share for ourself.
* Fix cross-group DLEq tests
2022-08-03 03:25:18 -05:00
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self.keys.params()
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2022-04-21 21:36:18 -04:00
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}
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}
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2022-10-25 23:17:25 -05:00
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/// Preprocess for an instance of the FROST signing protocol.
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2022-10-29 03:54:42 -05:00
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#[derive(Clone, PartialEq, Eq)]
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2022-10-25 23:17:25 -05:00
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pub struct Preprocess<C: Curve, A: Addendum> {
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pub(crate) commitments: Commitments<C>,
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pub addendum: A,
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}
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impl<C: Curve, A: Addendum> Writable for Preprocess<C, A> {
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fn write<W: Write>(&self, writer: &mut W) -> io::Result<()> {
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self.commitments.write(writer)?;
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self.addendum.write(writer)
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}
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2022-07-12 01:28:01 -04:00
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}
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2022-12-08 19:04:35 -05:00
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/// A cached preprocess. A preprocess MUST only be used once. Reuse will enable third-party
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/// recovery of your private key share. Additionally, this MUST be handled with the same security
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/// as your private key share, as knowledge of it also enables recovery.
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2023-01-01 01:54:18 -05:00
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// Directly exposes the [u8; 32] member to void needing to route through std::io interfaces.
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// Still uses Zeroizing internally so when users grab it, they have a higher likelihood of
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// appreciating how to handle it and don't immediately start copying it just by grabbing it.
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#[derive(Zeroize)]
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pub struct CachedPreprocess(pub Zeroizing<[u8; 32]>);
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2022-12-08 19:04:35 -05:00
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2022-09-29 07:08:20 -04:00
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/// Trait for the initial state machine of a two-round signing protocol.
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2023-03-07 02:38:47 -05:00
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pub trait PreprocessMachine: Send {
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2022-10-25 23:17:25 -05:00
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/// Preprocess message for this machine.
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type Preprocess: Clone + PartialEq + Writable;
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/// Signature produced by this machine.
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2022-11-10 22:35:09 -05:00
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type Signature: Clone + PartialEq + Debug;
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2022-10-25 23:17:25 -05:00
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/// SignMachine this PreprocessMachine turns into.
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type SignMachine: SignMachine<Self::Signature, Preprocess = Self::Preprocess>;
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2022-04-29 22:36:43 -04:00
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2022-09-29 05:25:29 -04:00
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/// Perform the preprocessing round required in order to sign.
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2022-10-25 23:17:25 -05:00
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/// Returns a preprocess message to be broadcast to all participants, over an authenticated
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/// channel.
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fn preprocess<R: RngCore + CryptoRng>(self, rng: &mut R)
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-> (Self::SignMachine, Self::Preprocess);
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2022-06-24 08:40:14 -04:00
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}
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2022-09-29 05:25:29 -04:00
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/// State machine which manages signing for an arbitrary signature algorithm.
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2022-04-29 22:36:43 -04:00
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pub struct AlgorithmMachine<C: Curve, A: Algorithm<C>> {
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2022-07-15 01:26:07 -04:00
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params: Params<C, A>,
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2022-06-24 08:40:14 -04:00
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}
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2022-04-29 22:36:43 -04:00
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impl<C: Curve, A: Algorithm<C>> AlgorithmMachine<C, A> {
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2022-09-29 05:25:29 -04:00
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/// Creates a new machine to generate a signature with the specified keys.
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2023-03-17 23:43:32 -04:00
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pub fn new(algorithm: A, keys: ThresholdKeys<C>) -> AlgorithmMachine<C, A> {
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AlgorithmMachine { params: Params::new(algorithm, keys) }
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2022-12-08 19:04:35 -05:00
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}
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fn seeded_preprocess(
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self,
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2023-01-01 01:54:18 -05:00
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seed: CachedPreprocess,
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2022-12-08 19:04:35 -05:00
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) -> (AlgorithmSignMachine<C, A>, Preprocess<C, A::Addendum>) {
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let mut params = self.params;
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2023-01-01 01:54:18 -05:00
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let mut rng = ChaCha20Rng::from_seed(*seed.0);
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2022-12-13 19:27:09 -05:00
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// Get a challenge to the existing transcript for use when proving for the commitments
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let commitments_challenge = params.algorithm.transcript().challenge(b"commitments");
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2022-12-08 19:04:35 -05:00
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let (nonces, commitments) = Commitments::new::<_, A::Transcript>(
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&mut rng,
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params.keys.secret_share(),
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¶ms.algorithm.nonces(),
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2022-12-13 19:27:09 -05:00
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commitments_challenge.as_ref(),
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2022-12-08 19:04:35 -05:00
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);
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let addendum = params.algorithm.preprocess_addendum(&mut rng, ¶ms.keys);
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let preprocess = Preprocess { commitments, addendum };
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2022-12-13 15:41:37 -05:00
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// Also obtain entropy to randomly sort the included participants if we need to identify blame
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let mut blame_entropy = [0; 32];
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rng.fill_bytes(&mut blame_entropy);
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(
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2022-12-13 19:27:09 -05:00
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AlgorithmSignMachine {
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params,
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seed,
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commitments_challenge,
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nonces,
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preprocess: preprocess.clone(),
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blame_entropy,
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},
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2022-12-13 15:41:37 -05:00
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preprocess,
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)
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2022-04-21 21:36:18 -04:00
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}
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2022-06-03 01:25:46 -04:00
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2022-10-15 23:46:22 -04:00
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#[cfg(any(test, feature = "tests"))]
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2022-06-24 08:40:14 -04:00
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pub(crate) fn unsafe_override_preprocess(
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2022-12-13 19:27:09 -05:00
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mut self,
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2022-10-29 05:10:07 -04:00
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nonces: Vec<Nonce<C>>,
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preprocess: Preprocess<C, A::Addendum>,
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2022-07-13 02:38:29 -04:00
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) -> AlgorithmSignMachine<C, A> {
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2022-12-08 19:04:35 -05:00
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AlgorithmSignMachine {
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2022-12-13 19:27:09 -05:00
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commitments_challenge: self.params.algorithm.transcript().challenge(b"commitments"),
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2022-12-08 19:04:35 -05:00
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params: self.params,
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2023-01-01 01:54:18 -05:00
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seed: CachedPreprocess(Zeroizing::new([0; 32])),
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2022-12-13 19:27:09 -05:00
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2022-12-08 19:04:35 -05:00
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nonces,
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preprocess,
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2022-12-13 19:27:09 -05:00
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// Uses 0s since this is just used to protect against a malicious participant from
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// deliberately increasing the amount of time needed to identify them (and is accordingly
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// not necessary to function)
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2022-12-13 15:41:37 -05:00
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blame_entropy: [0; 32],
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2022-12-08 19:04:35 -05:00
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}
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2022-06-03 01:25:46 -04:00
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}
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2022-04-29 22:36:43 -04:00
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}
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2022-04-21 21:36:18 -04:00
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2022-06-24 08:40:14 -04:00
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impl<C: Curve, A: Algorithm<C>> PreprocessMachine for AlgorithmMachine<C, A> {
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2022-10-25 23:17:25 -05:00
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type Preprocess = Preprocess<C, A::Addendum>;
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2022-04-29 22:36:43 -04:00
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type Signature = A::Signature;
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2022-06-24 08:40:14 -04:00
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type SignMachine = AlgorithmSignMachine<C, A>;
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2022-04-29 22:36:43 -04:00
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2022-10-25 23:17:25 -05:00
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fn preprocess<R: RngCore + CryptoRng>(
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self,
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rng: &mut R,
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) -> (Self::SignMachine, Preprocess<C, A::Addendum>) {
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2023-01-01 01:54:18 -05:00
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let mut seed = CachedPreprocess(Zeroizing::new([0; 32]));
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2022-12-08 19:04:35 -05:00
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rng.fill_bytes(seed.0.as_mut());
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self.seeded_preprocess(seed)
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2022-10-29 05:10:07 -04:00
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}
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}
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/// Share of a signature produced via FROST.
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#[derive(Clone, PartialEq, Eq)]
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pub struct SignatureShare<C: Curve>(C::F);
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impl<C: Curve> Writable for SignatureShare<C> {
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fn write<W: Write>(&self, writer: &mut W) -> io::Result<()> {
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writer.write_all(self.0.to_repr().as_ref())
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2022-04-21 21:36:18 -04:00
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}
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2022-06-24 08:40:14 -04:00
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}
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2023-01-01 01:54:18 -05:00
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#[cfg(any(test, feature = "tests"))]
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impl<C: Curve> SignatureShare<C> {
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pub(crate) fn invalidate(&mut self) {
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2023-03-07 03:46:16 -05:00
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use ciphersuite::group::ff::Field;
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2023-03-07 03:06:46 -05:00
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2023-01-01 01:54:18 -05:00
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self.0 += C::F::one();
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}
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}
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2022-06-24 08:40:14 -04:00
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2022-10-29 05:10:07 -04:00
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/// Trait for the second machine of a two-round signing protocol.
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Processor (#259)
* Initial work on a message box
* Finish message-box (untested)
* Expand documentation
* Embed the recipient in the signature challenge
Prevents a message from A -> B from being read as from A -> C.
* Update documentation by bifurcating sender/receiver
* Panic on receiving an invalid signature
If we've received an invalid signature in an authenticated system, a
service is malicious, critically faulty (equivalent to malicious), or
the message layer has been compromised (or is otherwise critically
faulty).
Please note a receiver who handles a message they shouldn't will trigger
this. That falls under being critically faulty.
* Documentation and helper methods
SecureMessage::new and SecureMessage::serialize.
Secure Debug for MessageBox.
* Have SecureMessage not be serialized by default
Allows passing around in-memory, if desired, and moves the error from
decrypt to new (which performs deserialization).
Decrypt no longer has an error since it panics if given an invalid
signature, due to this being intranet code.
* Explain and improve nonce handling
Includes a missing zeroize call.
* Rebase to latest develop
Updates to transcript 0.2.0.
* Add a test for the MessageBox
* Export PrivateKey and PublicKey
* Also test serialization
* Add a key_gen binary to message_box
* Have SecureMessage support Serde
* Add encrypt_to_bytes and decrypt_from_bytes
* Support String ser via base64
* Rename encrypt/decrypt to encrypt_bytes/decrypt_to_bytes
* Directly operate with values supporting Borsh
* Use bincode instead of Borsh
By staying inside of serde, we'll support many more structs. While
bincode isn't canonical, we don't need canonicity on an authenticated,
internal system.
* Turn PrivateKey, PublicKey into structs
Uses Zeroizing for the PrivateKey per #150.
* from_string functions intended for loading from an env
* Use &str for PublicKey from_string (now from_str)
The PrivateKey takes the String to take ownership of its memory and
zeroize it. That isn't needed with PublicKeys.
* Finish updating from develop
* Resolve warning
* Use ZeroizingAlloc on the key_gen binary
* Move message-box from crypto/ to common/
* Move key serialization functions to ser
* add/remove functions in MessageBox
* Implement Hash on dalek_ff_group Points
* Make MessageBox generic to its key
Exposes a &'static str variant for internal use and a RistrettoPoint
variant for external use.
* Add Private to_string as deprecated
Stub before more competent tooling is deployed.
* Private to_public
* Test both Internal and External MessageBox, only use PublicKey in the pub API
* Remove panics on invalid signatures
Leftover from when this was solely internal which is now unsafe.
* Chicken scratch a Scanner task
* Add a write function to the DKG library
Enables writing directly to a file.
Also modifies serialize to return Zeroizing<Vec<u8>> instead of just Vec<u8>.
* Make dkg::encryption pub
* Remove encryption from MessageBox
* Use a 64-bit block number in Substrate
We use a 64-bit block number in general since u32 only works for 120 years
(with a 1 second block time). As some chains even push the 1 second threshold,
especially ones based on DAG consensus, this becomes potentially as low as 60
years.
While that should still be plenty, it's not worth wondering/debating. Since
Serai uses 64-bit block numbers elsewhere, this ensures consistency.
* Misc crypto lints
* Get the scanner scratch to compile
* Initial scanner test
* First few lines of scheduler
* Further work on scheduler, solidify API
* Define Scheduler TX format
* Branch creation algorithm
* Document when the branch algorithm isn't perfect
* Only scanned confirmed blocks
* Document Coin
* Remove Canonical/ChainNumber from processor
The processor should be abstracted from canonical numbers thanks to the
coordinator, making this unnecessary.
* Add README documenting processor flow
* Use Zeroize on substrate primitives
* Define messages from/to the processor
* Correct over-specified versioning
* Correct build re: in_instructions::primitives
* Debug/some serde in crypto/
* Use a struct for ValidatorSetInstance
* Add a processor key_gen task
Redos DB handling code.
* Replace trait + impl with wrapper struct
* Add a key confirmation flow to the key gen task
* Document concerns on key_gen
* Start on a signer task
* Add Send to FROST traits
* Move processor lib.rs to main.rs
Adds a dummy main to reduce clippy dead_code warnings.
* Further flesh out main.rs
* Move the DB trait to AsRef<[u8]>
* Signer task
* Remove a panic in bitcoin when there's insufficient funds
Unchecked underflow.
* Have Monero's mine_block mine one block, not 10
It was initially a nicety to deal with the 10 block lock. C::CONFIRMATIONS
should be used for that instead.
* Test signer
* Replace channel expects with log statements
The expects weren't problematic and had nicer code. They just clutter test
output.
* Remove the old wallet file
It predates the coordinator design and shouldn't be used.
* Rename tests/scan.rs to tests/scanner.rs
* Add a wallet test
Complements the recently removed wallet file by adding a test for the scanner,
scheduler, and signer together.
* Work on a run function
Triggers a clippy ICE.
* Resolve clippy ICE
The issue was the non-fully specified lambda in signer.
* Add KeyGenEvent and KeyGenOrder
Needed so we get KeyConfirmed messages from the key gen task.
While we could've read the CoordinatorMessage to see that, routing through the
key gen tasks ensures we only handle it once it's been successfully saved to
disk.
* Expand scanner test
* Clarify processor documentation
* Have the Scanner load keys on boot/save outputs to disk
* Use Vec<u8> for Block ID
Much more flexible.
* Panic if we see the same output multiple times
* Have the Scanner DB mark itself as corrupt when doing a multi-put
This REALLY should be a TX. Since we don't have a TX API right now, this at
least offers detection.
* Have DST'd DB keys accept AsRef<[u8]>
* Restore polling all signers
Writes a custom future to do so.
Also loads signers on boot using what the scanner claims are active keys.
* Schedule OutInstructions
Adds a data field to Payment.
Also cleans some dead code.
* Panic if we create an invalid transaction
Saves the TX once it's successfully signed so if we do panic, we have a copy.
* Route coordinator messages to their respective signer
Requires adding key to the SignId.
* Send SignTransaction orders for all plans
* Add a timer to retry sign_plans when prepare_send fails
* Minor fmt'ing
* Basic Fee API
* Move the change key into Plan
* Properly route activation_number
* Remove ScannerEvent::Block
It's not used under current designs
* Nicen logs
* Add utilities to get a block's number
* Have main issue AckBlock
Also has a few misc lints.
* Parse instructions out of outputs
* Tweak TODOs and remove an unwrap
* Update Bitcoin max input/output quantity
* Only read one piece of data from Monero
Due to output randomization, it's infeasible.
* Embed plan IDs into the TXs they create
We need to stop attempting signing if we've already signed a protocol. Ideally,
any one of the participating signers should be able to provide a proof the TX
was successfully signed. We can't just run a second signing protocol though as
a single malicious signer could complete the TX signature, and publish it,
yet not complete the secondary signature.
The TX itself has to be sufficient to show that the TX matches the plan. This
is done by embedding the ID, so matching addresses/amounts plans are
distinguished, and by allowing verification a TX actually matches a set of
addresses/amounts.
For Monero, this will need augmenting with the ephemeral keys (or usage of a
static seed for them).
* Don't use OP_RETURN to encode the plan ID on Bitcoin
We can use the inputs to distinguih identical-output plans without issue.
* Update OP_RETURN data access
It's not required to be the last output.
* Add Eventualities to Monero
An Eventuality is an effective equivalent to a SignableTransaction. That is
declared not by the inputs it spends, yet the outputs it creates.
Eventualities are also bound to a 32-byte RNG seed, enabling usage of a
hash-based identifier in a SignableTransaction, allowing multiple
SignableTransactions with the same output set to have different Eventualities.
In order to prevent triggering the burning bug, the RNG seed is hashed with
the planned-to-be-used inputs' output keys. While this does bind to them, it's
only loosely bound. The TX actually created may use different inputs entirely
if a forgery is crafted (which requires no brute forcing).
Binding to the key images would provide a strong binding, yet would require
knowing the key images, which requires active communication with the spend
key.
The purpose of this is so a multisig can identify if a Transaction the entire
group planned has been executed by a subset of the group or not. Once a plan
is created, it can have an Eventuality made. The Eventuality's extra is able
to be inserted into a HashMap, so all new on-chain transactions can be
trivially checked as potential candidates. Once a potential candidate is found,
a check involving ECC ops can be performed.
While this is arguably a DoS vector, the underlying Monero blockchain would
need to be spammed with transactions to trigger it. Accordingly, it becomes
a Monero blockchain DoS vector, when this code is written on the premise
of the Monero blockchain functioning. Accordingly, it is considered handled.
If a forgery does match, it must have created the exact same outputs the
multisig would've. Accordingly, it's argued the multisig shouldn't mind.
This entire suite of code is only necessary due to the lack of outgoing
view keys, yet it's able to avoid an interactive protocol to communicate
key images on every single received output.
While this could be locked to the multisig feature, there's no practical
benefit to doing so.
* Add support for encoding Monero address to instructions
* Move Serai's Monero address encoding into serai-client
serai-client is meant to be a single library enabling using Serai. While it was
originally written as an RPC client for Serai, apps actually using Serai will
primarily be sending transactions on connected networks. Sending those
transactions require proper {In, Out}Instructions, including proper address
encoding.
Not only has address encoding been moved, yet the subxt client is now behind
a feature. coin integrations have their own features, which are on by default.
primitives are always exposed.
* Reorganize file layout a bit, add feature flags to processor
* Tidy up ETH Dockerfile
* Add Bitcoin address encoding
* Move Bitcoin::Address to serai-client's
* Comment where tweaking needs to happen
* Add an API to check if a plan was completed in a specific TX
This allows any participating signer to submit the TX ID to prevent further
signing attempts.
Also performs some API cleanup.
* Minimize FROST dependencies
* Use a seeded RNG for key gen
* Tweak keys from Key gen
* Test proper usage of Branch/Change addresses
Adds a more descriptive error to an error case in decoys, and pads Monero
payments as needed.
* Also test spending the change output
* Add queued_plans to the Scheduler
queued_plans is for payments to be issued when an amount appears, yet the
amount is currently pre-fee. One the output is actually created, the
Scheduler should be notified of the amount it was created with, moving from
queued_plans to plans under the actual amount.
Also tightens debug_asserts to asserts for invariants which may are at risk of
being exclusive to prod.
* Add missing tweak_keys call
* Correct decoy selection height handling
* Add a few log statements to the scheduler
* Simplify test's get_block_number
* Simplify, while making more robust, branch address handling in Scheduler
* Have fees deducted from payments
Corrects Monero's handling of fees when there's no change address.
Adds a DUST variable, as needed due to 1_00_000_000 not being enough to pay
its fee on Monero.
* Add comment to Monero
* Consolidate BTC/XMR prepare_send code
These aren't fully consolidated. We'd need a SignableTransaction trait for
that. This is a lot cleaner though.
* Ban integrated addresses
The reasoning why is accordingly documented.
* Tidy TODOs/dust handling
* Update README TODO
* Use a determinisitic protocol version in Monero
* Test rebuilt KeyGen machines function as expected
* Use a more robust KeyGen entropy system
* Add DB TXNs
Also load entropy from env
* Add a loop for processing messages from substrate
Allows detecting if we're behind, and if so, waiting to handle the message
* Set Monero MAX_INPUTS properly
The previous number was based on an old hard fork. With the ring size having
increased, transactions have since got larger.
* Distinguish TODOs into TODO and TODO2s
TODO2s are for after protonet
* Zeroize secret share repr in ThresholdCore write
* Work on Eventualities
Adds serialization and stops signing when an eventuality is proven.
* Use a more robust DB key schema
* Update to {k, p}256 0.12
* cargo +nightly clippy
* cargo update
* Slight message-box tweaks
* Update to recent Monero merge
* Add a Coordinator trait for communication with coordinator
* Remove KeyGenHandle for just KeyGen
While KeyGen previously accepted instructions over a channel, this breaks the
ack flow needed for coordinator communication. Now, KeyGen is the direct object
with a handle() function for messages.
Thankfully, this ended up being rather trivial for KeyGen as it has no
background tasks.
* Add a handle function to Signer
Enables determining when it's finished handling a CoordinatorMessage and
therefore creating an acknowledgement.
* Save transactions used to complete eventualities
* Use a more intelligent sleep in the signer
* Emit SignedTransaction with the first ID *we can still get from our node*
* Move Substrate message handling into the new coordinator recv loop
* Add handle function to Scanner
* Remove the plans timer
Enables ensuring the ordring on the handling of plans.
* Remove the outputs function which panicked if a precondition wasn't met
The new API only returns outputs upon satisfaction of the precondition.
* Convert SignerOrder::SignTransaction to a function
* Remove the key_gen object from sign_plans
* Refactor out get_fee/prepare_send into dedicated functions
* Save plans being signed to the DB
* Reload transactions being signed on boot
* Stop reloading TXs being signed (and report it to peers)
* Remove message-box from the processor branch
We don't use it here yet.
* cargo +nightly fmt
* Move back common/zalloc
* Update subxt to 0.27
* Zeroize ^1.5, not 1
* Update GitHub workflow
* Remove usage of SignId in completed
2023-03-16 22:59:40 -04:00
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pub trait SignMachine<S>: Send + Sync + Sized {
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/// Params used to instantiate this machine which can be used to rebuild from a cache.
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type Params: Clone;
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/// Keys used for signing operations.
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type Keys;
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/// Preprocess message for this machine.
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type Preprocess: Clone + PartialEq + Writable;
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/// SignatureShare message for this machine.
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type SignatureShare: Clone + PartialEq + Writable;
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/// SignatureMachine this SignMachine turns into.
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type SignatureMachine: SignatureMachine<S, SignatureShare = Self::SignatureShare>;
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2022-12-08 19:04:35 -05:00
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/// Cache this preprocess for usage later. This cached preprocess MUST only be used once. Reuse
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/// of it enables recovery of your private key share. Third-party recovery of a cached preprocess
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/// also enables recovery of your private key share, so this MUST be treated with the same
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/// security as your private key share.
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fn cache(self) -> CachedPreprocess;
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2023-03-01 00:35:37 -05:00
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/// Create a sign machine from a cached preprocess. After this, the preprocess must be deleted so
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/// it's never reused. Any reuse would cause the signer to leak their secret share.
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2022-12-08 19:04:35 -05:00
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fn from_cache(
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params: Self::Params,
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keys: Self::Keys,
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cache: CachedPreprocess,
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) -> Result<Self, FrostError>;
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/// Read a Preprocess message. Despite taking self, this does not save the preprocess.
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/// It must be externally cached and passed into sign.
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fn read_preprocess<R: Read>(&self, reader: &mut R) -> io::Result<Self::Preprocess>;
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/// Sign a message.
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/// Takes in the participants' preprocess messages. Returns the signature share to be broadcast
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2022-12-08 19:04:35 -05:00
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/// to all participants, over an authenticated channel. The parties who participate here will
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/// become the signing set for this session.
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fn sign(
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self,
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commitments: HashMap<Participant, Self::Preprocess>,
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msg: &[u8],
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) -> Result<(Self::SignatureMachine, Self::SignatureShare), FrostError>;
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}
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/// Next step of the state machine for the signing process.
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#[derive(Zeroize)]
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pub struct AlgorithmSignMachine<C: Curve, A: Algorithm<C>> {
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params: Params<C, A>,
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seed: CachedPreprocess,
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2022-12-13 19:27:09 -05:00
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commitments_challenge: <A::Transcript as Transcript>::Challenge,
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pub(crate) nonces: Vec<Nonce<C>>,
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// Skips the preprocess due to being too large a bound to feasibly enforce on users
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#[zeroize(skip)]
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pub(crate) preprocess: Preprocess<C, A::Addendum>,
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pub(crate) blame_entropy: [u8; 32],
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}
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impl<C: Curve, A: Algorithm<C>> SignMachine<A::Signature> for AlgorithmSignMachine<C, A> {
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type Params = A;
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type Keys = ThresholdKeys<C>;
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type Preprocess = Preprocess<C, A::Addendum>;
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type SignatureShare = SignatureShare<C>;
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type SignatureMachine = AlgorithmSignatureMachine<C, A>;
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2023-01-01 01:54:18 -05:00
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fn cache(self) -> CachedPreprocess {
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self.seed
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}
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fn from_cache(
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algorithm: A,
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keys: ThresholdKeys<C>,
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cache: CachedPreprocess,
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) -> Result<Self, FrostError> {
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2023-03-17 23:43:32 -04:00
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let (machine, _) = AlgorithmMachine::new(algorithm, keys).seeded_preprocess(cache);
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2022-12-08 19:04:35 -05:00
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Ok(machine)
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}
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2022-10-25 23:17:25 -05:00
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fn read_preprocess<R: Read>(&self, reader: &mut R) -> io::Result<Self::Preprocess> {
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Ok(Preprocess {
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2022-12-13 19:27:09 -05:00
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commitments: Commitments::read::<_, A::Transcript>(
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reader,
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&self.params.algorithm.nonces(),
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self.commitments_challenge.as_ref(),
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)?,
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addendum: self.params.algorithm.read_addendum(reader)?,
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})
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}
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fn sign(
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mut self,
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mut preprocesses: HashMap<Participant, Preprocess<C, A::Addendum>>,
|
2022-07-15 01:26:07 -04:00
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msg: &[u8],
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) -> Result<(Self::SignatureMachine, SignatureShare<C>), FrostError> {
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2022-10-29 05:10:07 -04:00
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let multisig_params = self.params.multisig_params();
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let mut included = Vec::with_capacity(preprocesses.len() + 1);
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included.push(multisig_params.i());
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for l in preprocesses.keys() {
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included.push(*l);
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}
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included.sort_unstable();
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// Included < threshold
|
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if included.len() < usize::from(multisig_params.t()) {
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Err(FrostError::InvalidSigningSet("not enough signers"))?;
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}
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// OOB index
|
2023-02-23 06:50:45 -05:00
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|
if u16::from(included[included.len() - 1]) > multisig_params.n() {
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Err(FrostError::InvalidParticipant(multisig_params.n(), included[included.len() - 1]))?;
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2022-12-08 19:04:35 -05:00
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}
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// Same signer included multiple times
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for i in 0 .. (included.len() - 1) {
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|
if included[i] == included[i + 1] {
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2023-02-23 06:50:45 -05:00
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Err(FrostError::DuplicatedParticipant(included[i]))?;
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2022-12-08 19:04:35 -05:00
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}
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}
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2023-03-01 01:06:13 -05:00
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let view = self.params.keys.view(included.clone()).unwrap();
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2022-12-08 19:04:35 -05:00
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validate_map(&preprocesses, &included, multisig_params.i())?;
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2022-10-29 05:10:07 -04:00
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{
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// Domain separate FROST
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|
|
self.params.algorithm.transcript().domain_separate(b"FROST");
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}
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|
let nonces = self.params.algorithm.nonces();
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|
#[allow(non_snake_case)]
|
2023-02-23 06:50:45 -05:00
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let mut B = BindingFactor(HashMap::<Participant, _>::with_capacity(included.len()));
|
2022-10-29 05:10:07 -04:00
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{
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// Parse the preprocesses
|
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for l in &included {
|
2022-10-29 05:10:07 -04:00
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{
|
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|
self
|
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|
.params
|
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|
.algorithm
|
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|
.transcript()
|
2023-02-23 06:50:45 -05:00
|
|
|
.append_message(b"participant", C::F::from(u64::from(u16::from(*l))).to_repr());
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2022-10-29 05:10:07 -04:00
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|
}
|
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|
|
if *l == self.params.keys.params().i() {
|
|
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|
let commitments = self.preprocess.commitments.clone();
|
|
|
|
|
commitments.transcript(self.params.algorithm.transcript());
|
|
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|
|
|
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|
|
let addendum = self.preprocess.addendum.clone();
|
|
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|
|
{
|
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|
|
let mut buf = vec![];
|
|
|
|
|
addendum.write(&mut buf).unwrap();
|
2022-11-05 18:43:36 -04:00
|
|
|
self.params.algorithm.transcript().append_message(b"addendum", buf);
|
2022-10-29 05:10:07 -04:00
|
|
|
}
|
|
|
|
|
|
|
|
|
|
B.insert(*l, commitments);
|
2022-12-08 19:04:35 -05:00
|
|
|
self.params.algorithm.process_addendum(&view, *l, addendum)?;
|
2022-10-29 05:10:07 -04:00
|
|
|
} else {
|
|
|
|
|
let preprocess = preprocesses.remove(l).unwrap();
|
|
|
|
|
preprocess.commitments.transcript(self.params.algorithm.transcript());
|
|
|
|
|
{
|
|
|
|
|
let mut buf = vec![];
|
|
|
|
|
preprocess.addendum.write(&mut buf).unwrap();
|
2022-11-05 18:43:36 -04:00
|
|
|
self.params.algorithm.transcript().append_message(b"addendum", buf);
|
2022-10-29 05:10:07 -04:00
|
|
|
}
|
|
|
|
|
|
|
|
|
|
B.insert(*l, preprocess.commitments);
|
2022-12-08 19:04:35 -05:00
|
|
|
self.params.algorithm.process_addendum(&view, *l, preprocess.addendum)?;
|
2022-10-29 05:10:07 -04:00
|
|
|
}
|
|
|
|
|
}
|
|
|
|
|
|
|
|
|
|
// Re-format into the FROST-expected rho transcript
|
|
|
|
|
let mut rho_transcript = A::Transcript::new(b"FROST_rho");
|
2022-11-05 18:43:36 -04:00
|
|
|
rho_transcript.append_message(b"message", C::hash_msg(msg));
|
2022-10-29 05:10:07 -04:00
|
|
|
rho_transcript.append_message(
|
|
|
|
|
b"preprocesses",
|
|
|
|
|
&C::hash_commitments(
|
|
|
|
|
self.params.algorithm.transcript().challenge(b"preprocesses").as_ref(),
|
|
|
|
|
),
|
|
|
|
|
);
|
|
|
|
|
|
|
|
|
|
// Include the offset, if one exists
|
|
|
|
|
// While this isn't part of the FROST-expected rho transcript, the offset being here
|
|
|
|
|
// coincides with another specification (despite the transcript format still being distinct)
|
|
|
|
|
if let Some(offset) = self.params.keys.current_offset() {
|
|
|
|
|
// Transcript as a point
|
|
|
|
|
// Under a coordinated model, the coordinater can be the only party to know the discrete
|
|
|
|
|
// log of the offset. This removes the ability for any signer to provide the discrete log,
|
|
|
|
|
// proving a key is related to another, slightly increasing security
|
|
|
|
|
// While further code edits would still be required for such a model (having the offset
|
|
|
|
|
// communicated as a point along with only a single party applying the offset), this means
|
|
|
|
|
// it wouldn't require a transcript change as well
|
2022-11-05 18:43:36 -04:00
|
|
|
rho_transcript.append_message(b"offset", (C::generator() * offset).to_bytes());
|
2022-10-29 05:10:07 -04:00
|
|
|
}
|
|
|
|
|
|
|
|
|
|
// Generate the per-signer binding factors
|
|
|
|
|
B.calculate_binding_factors(&mut rho_transcript);
|
|
|
|
|
|
|
|
|
|
// Merge the rho transcript back into the global one to ensure its advanced, while
|
|
|
|
|
// simultaneously committing to everything
|
|
|
|
|
self
|
|
|
|
|
.params
|
|
|
|
|
.algorithm
|
|
|
|
|
.transcript()
|
2022-11-05 18:43:36 -04:00
|
|
|
.append_message(b"rho_transcript", rho_transcript.challenge(b"merge"));
|
2022-10-29 05:10:07 -04:00
|
|
|
}
|
|
|
|
|
|
|
|
|
|
#[allow(non_snake_case)]
|
|
|
|
|
let Rs = B.nonces(&nonces);
|
|
|
|
|
|
|
|
|
|
let our_binding_factors = B.binding_factors(multisig_params.i());
|
2022-11-10 22:35:09 -05:00
|
|
|
let nonces = self
|
2022-10-29 05:10:07 -04:00
|
|
|
.nonces
|
2022-11-10 22:35:09 -05:00
|
|
|
.drain(..)
|
2022-10-29 05:10:07 -04:00
|
|
|
.enumerate()
|
2022-11-10 22:35:09 -05:00
|
|
|
.map(|(n, nonces)| {
|
|
|
|
|
let [base, mut actual] = nonces.0;
|
|
|
|
|
*actual *= our_binding_factors[n];
|
|
|
|
|
*actual += base.deref();
|
|
|
|
|
actual
|
|
|
|
|
})
|
2022-10-29 05:10:07 -04:00
|
|
|
.collect::<Vec<_>>();
|
|
|
|
|
|
2022-12-08 19:04:35 -05:00
|
|
|
let share = self.params.algorithm.sign_share(&view, &Rs, nonces, msg);
|
2022-10-29 05:10:07 -04:00
|
|
|
|
|
|
|
|
Ok((
|
2022-12-13 15:41:37 -05:00
|
|
|
AlgorithmSignatureMachine {
|
|
|
|
|
params: self.params.clone(),
|
|
|
|
|
view,
|
|
|
|
|
B,
|
|
|
|
|
Rs,
|
|
|
|
|
share,
|
|
|
|
|
blame_entropy: self.blame_entropy,
|
|
|
|
|
},
|
2022-10-29 05:10:07 -04:00
|
|
|
SignatureShare(share),
|
|
|
|
|
))
|
2022-04-21 21:36:18 -04:00
|
|
|
}
|
2022-06-24 08:40:14 -04:00
|
|
|
}
|
2022-04-21 21:36:18 -04:00
|
|
|
|
2022-10-29 05:10:07 -04:00
|
|
|
/// Trait for the final machine of a two-round signing protocol.
|
Processor (#259)
* Initial work on a message box
* Finish message-box (untested)
* Expand documentation
* Embed the recipient in the signature challenge
Prevents a message from A -> B from being read as from A -> C.
* Update documentation by bifurcating sender/receiver
* Panic on receiving an invalid signature
If we've received an invalid signature in an authenticated system, a
service is malicious, critically faulty (equivalent to malicious), or
the message layer has been compromised (or is otherwise critically
faulty).
Please note a receiver who handles a message they shouldn't will trigger
this. That falls under being critically faulty.
* Documentation and helper methods
SecureMessage::new and SecureMessage::serialize.
Secure Debug for MessageBox.
* Have SecureMessage not be serialized by default
Allows passing around in-memory, if desired, and moves the error from
decrypt to new (which performs deserialization).
Decrypt no longer has an error since it panics if given an invalid
signature, due to this being intranet code.
* Explain and improve nonce handling
Includes a missing zeroize call.
* Rebase to latest develop
Updates to transcript 0.2.0.
* Add a test for the MessageBox
* Export PrivateKey and PublicKey
* Also test serialization
* Add a key_gen binary to message_box
* Have SecureMessage support Serde
* Add encrypt_to_bytes and decrypt_from_bytes
* Support String ser via base64
* Rename encrypt/decrypt to encrypt_bytes/decrypt_to_bytes
* Directly operate with values supporting Borsh
* Use bincode instead of Borsh
By staying inside of serde, we'll support many more structs. While
bincode isn't canonical, we don't need canonicity on an authenticated,
internal system.
* Turn PrivateKey, PublicKey into structs
Uses Zeroizing for the PrivateKey per #150.
* from_string functions intended for loading from an env
* Use &str for PublicKey from_string (now from_str)
The PrivateKey takes the String to take ownership of its memory and
zeroize it. That isn't needed with PublicKeys.
* Finish updating from develop
* Resolve warning
* Use ZeroizingAlloc on the key_gen binary
* Move message-box from crypto/ to common/
* Move key serialization functions to ser
* add/remove functions in MessageBox
* Implement Hash on dalek_ff_group Points
* Make MessageBox generic to its key
Exposes a &'static str variant for internal use and a RistrettoPoint
variant for external use.
* Add Private to_string as deprecated
Stub before more competent tooling is deployed.
* Private to_public
* Test both Internal and External MessageBox, only use PublicKey in the pub API
* Remove panics on invalid signatures
Leftover from when this was solely internal which is now unsafe.
* Chicken scratch a Scanner task
* Add a write function to the DKG library
Enables writing directly to a file.
Also modifies serialize to return Zeroizing<Vec<u8>> instead of just Vec<u8>.
* Make dkg::encryption pub
* Remove encryption from MessageBox
* Use a 64-bit block number in Substrate
We use a 64-bit block number in general since u32 only works for 120 years
(with a 1 second block time). As some chains even push the 1 second threshold,
especially ones based on DAG consensus, this becomes potentially as low as 60
years.
While that should still be plenty, it's not worth wondering/debating. Since
Serai uses 64-bit block numbers elsewhere, this ensures consistency.
* Misc crypto lints
* Get the scanner scratch to compile
* Initial scanner test
* First few lines of scheduler
* Further work on scheduler, solidify API
* Define Scheduler TX format
* Branch creation algorithm
* Document when the branch algorithm isn't perfect
* Only scanned confirmed blocks
* Document Coin
* Remove Canonical/ChainNumber from processor
The processor should be abstracted from canonical numbers thanks to the
coordinator, making this unnecessary.
* Add README documenting processor flow
* Use Zeroize on substrate primitives
* Define messages from/to the processor
* Correct over-specified versioning
* Correct build re: in_instructions::primitives
* Debug/some serde in crypto/
* Use a struct for ValidatorSetInstance
* Add a processor key_gen task
Redos DB handling code.
* Replace trait + impl with wrapper struct
* Add a key confirmation flow to the key gen task
* Document concerns on key_gen
* Start on a signer task
* Add Send to FROST traits
* Move processor lib.rs to main.rs
Adds a dummy main to reduce clippy dead_code warnings.
* Further flesh out main.rs
* Move the DB trait to AsRef<[u8]>
* Signer task
* Remove a panic in bitcoin when there's insufficient funds
Unchecked underflow.
* Have Monero's mine_block mine one block, not 10
It was initially a nicety to deal with the 10 block lock. C::CONFIRMATIONS
should be used for that instead.
* Test signer
* Replace channel expects with log statements
The expects weren't problematic and had nicer code. They just clutter test
output.
* Remove the old wallet file
It predates the coordinator design and shouldn't be used.
* Rename tests/scan.rs to tests/scanner.rs
* Add a wallet test
Complements the recently removed wallet file by adding a test for the scanner,
scheduler, and signer together.
* Work on a run function
Triggers a clippy ICE.
* Resolve clippy ICE
The issue was the non-fully specified lambda in signer.
* Add KeyGenEvent and KeyGenOrder
Needed so we get KeyConfirmed messages from the key gen task.
While we could've read the CoordinatorMessage to see that, routing through the
key gen tasks ensures we only handle it once it's been successfully saved to
disk.
* Expand scanner test
* Clarify processor documentation
* Have the Scanner load keys on boot/save outputs to disk
* Use Vec<u8> for Block ID
Much more flexible.
* Panic if we see the same output multiple times
* Have the Scanner DB mark itself as corrupt when doing a multi-put
This REALLY should be a TX. Since we don't have a TX API right now, this at
least offers detection.
* Have DST'd DB keys accept AsRef<[u8]>
* Restore polling all signers
Writes a custom future to do so.
Also loads signers on boot using what the scanner claims are active keys.
* Schedule OutInstructions
Adds a data field to Payment.
Also cleans some dead code.
* Panic if we create an invalid transaction
Saves the TX once it's successfully signed so if we do panic, we have a copy.
* Route coordinator messages to their respective signer
Requires adding key to the SignId.
* Send SignTransaction orders for all plans
* Add a timer to retry sign_plans when prepare_send fails
* Minor fmt'ing
* Basic Fee API
* Move the change key into Plan
* Properly route activation_number
* Remove ScannerEvent::Block
It's not used under current designs
* Nicen logs
* Add utilities to get a block's number
* Have main issue AckBlock
Also has a few misc lints.
* Parse instructions out of outputs
* Tweak TODOs and remove an unwrap
* Update Bitcoin max input/output quantity
* Only read one piece of data from Monero
Due to output randomization, it's infeasible.
* Embed plan IDs into the TXs they create
We need to stop attempting signing if we've already signed a protocol. Ideally,
any one of the participating signers should be able to provide a proof the TX
was successfully signed. We can't just run a second signing protocol though as
a single malicious signer could complete the TX signature, and publish it,
yet not complete the secondary signature.
The TX itself has to be sufficient to show that the TX matches the plan. This
is done by embedding the ID, so matching addresses/amounts plans are
distinguished, and by allowing verification a TX actually matches a set of
addresses/amounts.
For Monero, this will need augmenting with the ephemeral keys (or usage of a
static seed for them).
* Don't use OP_RETURN to encode the plan ID on Bitcoin
We can use the inputs to distinguih identical-output plans without issue.
* Update OP_RETURN data access
It's not required to be the last output.
* Add Eventualities to Monero
An Eventuality is an effective equivalent to a SignableTransaction. That is
declared not by the inputs it spends, yet the outputs it creates.
Eventualities are also bound to a 32-byte RNG seed, enabling usage of a
hash-based identifier in a SignableTransaction, allowing multiple
SignableTransactions with the same output set to have different Eventualities.
In order to prevent triggering the burning bug, the RNG seed is hashed with
the planned-to-be-used inputs' output keys. While this does bind to them, it's
only loosely bound. The TX actually created may use different inputs entirely
if a forgery is crafted (which requires no brute forcing).
Binding to the key images would provide a strong binding, yet would require
knowing the key images, which requires active communication with the spend
key.
The purpose of this is so a multisig can identify if a Transaction the entire
group planned has been executed by a subset of the group or not. Once a plan
is created, it can have an Eventuality made. The Eventuality's extra is able
to be inserted into a HashMap, so all new on-chain transactions can be
trivially checked as potential candidates. Once a potential candidate is found,
a check involving ECC ops can be performed.
While this is arguably a DoS vector, the underlying Monero blockchain would
need to be spammed with transactions to trigger it. Accordingly, it becomes
a Monero blockchain DoS vector, when this code is written on the premise
of the Monero blockchain functioning. Accordingly, it is considered handled.
If a forgery does match, it must have created the exact same outputs the
multisig would've. Accordingly, it's argued the multisig shouldn't mind.
This entire suite of code is only necessary due to the lack of outgoing
view keys, yet it's able to avoid an interactive protocol to communicate
key images on every single received output.
While this could be locked to the multisig feature, there's no practical
benefit to doing so.
* Add support for encoding Monero address to instructions
* Move Serai's Monero address encoding into serai-client
serai-client is meant to be a single library enabling using Serai. While it was
originally written as an RPC client for Serai, apps actually using Serai will
primarily be sending transactions on connected networks. Sending those
transactions require proper {In, Out}Instructions, including proper address
encoding.
Not only has address encoding been moved, yet the subxt client is now behind
a feature. coin integrations have their own features, which are on by default.
primitives are always exposed.
* Reorganize file layout a bit, add feature flags to processor
* Tidy up ETH Dockerfile
* Add Bitcoin address encoding
* Move Bitcoin::Address to serai-client's
* Comment where tweaking needs to happen
* Add an API to check if a plan was completed in a specific TX
This allows any participating signer to submit the TX ID to prevent further
signing attempts.
Also performs some API cleanup.
* Minimize FROST dependencies
* Use a seeded RNG for key gen
* Tweak keys from Key gen
* Test proper usage of Branch/Change addresses
Adds a more descriptive error to an error case in decoys, and pads Monero
payments as needed.
* Also test spending the change output
* Add queued_plans to the Scheduler
queued_plans is for payments to be issued when an amount appears, yet the
amount is currently pre-fee. One the output is actually created, the
Scheduler should be notified of the amount it was created with, moving from
queued_plans to plans under the actual amount.
Also tightens debug_asserts to asserts for invariants which may are at risk of
being exclusive to prod.
* Add missing tweak_keys call
* Correct decoy selection height handling
* Add a few log statements to the scheduler
* Simplify test's get_block_number
* Simplify, while making more robust, branch address handling in Scheduler
* Have fees deducted from payments
Corrects Monero's handling of fees when there's no change address.
Adds a DUST variable, as needed due to 1_00_000_000 not being enough to pay
its fee on Monero.
* Add comment to Monero
* Consolidate BTC/XMR prepare_send code
These aren't fully consolidated. We'd need a SignableTransaction trait for
that. This is a lot cleaner though.
* Ban integrated addresses
The reasoning why is accordingly documented.
* Tidy TODOs/dust handling
* Update README TODO
* Use a determinisitic protocol version in Monero
* Test rebuilt KeyGen machines function as expected
* Use a more robust KeyGen entropy system
* Add DB TXNs
Also load entropy from env
* Add a loop for processing messages from substrate
Allows detecting if we're behind, and if so, waiting to handle the message
* Set Monero MAX_INPUTS properly
The previous number was based on an old hard fork. With the ring size having
increased, transactions have since got larger.
* Distinguish TODOs into TODO and TODO2s
TODO2s are for after protonet
* Zeroize secret share repr in ThresholdCore write
* Work on Eventualities
Adds serialization and stops signing when an eventuality is proven.
* Use a more robust DB key schema
* Update to {k, p}256 0.12
* cargo +nightly clippy
* cargo update
* Slight message-box tweaks
* Update to recent Monero merge
* Add a Coordinator trait for communication with coordinator
* Remove KeyGenHandle for just KeyGen
While KeyGen previously accepted instructions over a channel, this breaks the
ack flow needed for coordinator communication. Now, KeyGen is the direct object
with a handle() function for messages.
Thankfully, this ended up being rather trivial for KeyGen as it has no
background tasks.
* Add a handle function to Signer
Enables determining when it's finished handling a CoordinatorMessage and
therefore creating an acknowledgement.
* Save transactions used to complete eventualities
* Use a more intelligent sleep in the signer
* Emit SignedTransaction with the first ID *we can still get from our node*
* Move Substrate message handling into the new coordinator recv loop
* Add handle function to Scanner
* Remove the plans timer
Enables ensuring the ordring on the handling of plans.
* Remove the outputs function which panicked if a precondition wasn't met
The new API only returns outputs upon satisfaction of the precondition.
* Convert SignerOrder::SignTransaction to a function
* Remove the key_gen object from sign_plans
* Refactor out get_fee/prepare_send into dedicated functions
* Save plans being signed to the DB
* Reload transactions being signed on boot
* Stop reloading TXs being signed (and report it to peers)
* Remove message-box from the processor branch
We don't use it here yet.
* cargo +nightly fmt
* Move back common/zalloc
* Update subxt to 0.27
* Zeroize ^1.5, not 1
* Update GitHub workflow
* Remove usage of SignId in completed
2023-03-16 22:59:40 -04:00
|
|
|
pub trait SignatureMachine<S>: Send + Sync {
|
2022-10-29 05:10:07 -04:00
|
|
|
/// SignatureShare message for this machine.
|
|
|
|
|
type SignatureShare: Clone + PartialEq + Writable;
|
|
|
|
|
|
|
|
|
|
/// Read a Signature Share message.
|
|
|
|
|
fn read_share<R: Read>(&self, reader: &mut R) -> io::Result<Self::SignatureShare>;
|
|
|
|
|
|
|
|
|
|
/// Complete signing.
|
|
|
|
|
/// Takes in everyone elses' shares. Returns the signature.
|
2023-02-23 06:50:45 -05:00
|
|
|
fn complete(self, shares: HashMap<Participant, Self::SignatureShare>) -> Result<S, FrostError>;
|
2022-10-29 05:10:07 -04:00
|
|
|
}
|
|
|
|
|
|
|
|
|
|
/// Final step of the state machine for the signing process.
|
|
|
|
|
#[allow(non_snake_case)]
|
|
|
|
|
pub struct AlgorithmSignatureMachine<C: Curve, A: Algorithm<C>> {
|
|
|
|
|
params: Params<C, A>,
|
2022-12-08 19:04:35 -05:00
|
|
|
view: ThresholdView<C>,
|
2022-10-29 05:10:07 -04:00
|
|
|
B: BindingFactor<C>,
|
|
|
|
|
Rs: Vec<Vec<C::G>>,
|
|
|
|
|
share: C::F,
|
2022-12-13 15:41:37 -05:00
|
|
|
blame_entropy: [u8; 32],
|
2022-10-29 05:10:07 -04:00
|
|
|
}
|
|
|
|
|
|
2022-07-15 01:26:07 -04:00
|
|
|
impl<C: Curve, A: Algorithm<C>> SignatureMachine<A::Signature> for AlgorithmSignatureMachine<C, A> {
|
2022-10-25 23:17:25 -05:00
|
|
|
type SignatureShare = SignatureShare<C>;
|
|
|
|
|
|
|
|
|
|
fn read_share<R: Read>(&self, reader: &mut R) -> io::Result<SignatureShare<C>> {
|
|
|
|
|
Ok(SignatureShare(C::read_F(reader)?))
|
|
|
|
|
}
|
|
|
|
|
|
2022-10-29 05:10:07 -04:00
|
|
|
fn complete(
|
|
|
|
|
self,
|
2023-02-23 06:50:45 -05:00
|
|
|
mut shares: HashMap<Participant, SignatureShare<C>>,
|
2022-10-29 05:10:07 -04:00
|
|
|
) -> Result<A::Signature, FrostError> {
|
|
|
|
|
let params = self.params.multisig_params();
|
2022-12-13 19:40:54 -05:00
|
|
|
validate_map(&shares, self.view.included(), params.i())?;
|
2022-10-29 05:10:07 -04:00
|
|
|
|
|
|
|
|
let mut responses = HashMap::new();
|
|
|
|
|
responses.insert(params.i(), self.share);
|
|
|
|
|
let mut sum = self.share;
|
|
|
|
|
for (l, share) in shares.drain() {
|
|
|
|
|
responses.insert(l, share.0);
|
|
|
|
|
sum += share.0;
|
|
|
|
|
}
|
|
|
|
|
|
|
|
|
|
// Perform signature validation instead of individual share validation
|
|
|
|
|
// For the success route, which should be much more frequent, this should be faster
|
|
|
|
|
// It also acts as an integrity check of this library's signing function
|
2022-12-08 19:04:35 -05:00
|
|
|
if let Some(sig) = self.params.algorithm.verify(self.view.group_key(), &self.Rs, sum) {
|
2022-10-29 05:10:07 -04:00
|
|
|
return Ok(sig);
|
|
|
|
|
}
|
|
|
|
|
|
2022-12-13 20:25:32 -05:00
|
|
|
// We could remove blame_entropy by taking in an RNG here
|
|
|
|
|
// Considering we don't need any RNG for a valid signature, and we only use the RNG here for
|
|
|
|
|
// performance reasons, it doesn't feel worthwhile to include as an argument to every
|
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// implementor of the trait
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let mut rng = ChaCha20Rng::from_seed(self.blame_entropy);
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let mut batch = BatchVerifier::new(self.view.included().len());
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for l in self.view.included() {
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if let Ok(statements) = self.params.algorithm.verify_share(
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self.view.verification_share(*l),
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&self.B.bound(*l),
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responses[l],
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2022-10-29 05:10:07 -04:00
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) {
|
2022-12-13 20:25:32 -05:00
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batch.queue(&mut rng, *l, statements);
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|
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} else {
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Err(FrostError::InvalidShare(*l))?;
|
2022-10-29 05:10:07 -04:00
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|
}
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}
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|
2022-12-13 20:25:32 -05:00
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|
|
if let Err(l) = batch.verify_vartime_with_vartime_blame() {
|
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|
|
|
Err(FrostError::InvalidShare(l))?;
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|
|
|
|
}
|
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|
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// If everyone has a valid share, and there were enough participants, this should've worked
|
2022-10-29 05:10:07 -04:00
|
|
|
Err(FrostError::InternalError("everyone had a valid share yet the signature was still invalid"))
|
2022-04-21 21:36:18 -04:00
|
|
|
}
|
|
|
|
|
}
|