// This file is part of Substrate. // Copyright (C) 2018-2020 Parity Technologies (UK) Ltd. // SPDX-License-Identifier: GPL-3.0-or-later WITH Classpath-exception-2.0 // This program is free software: you can redistribute it and/or modify // it under the terms of the GNU General Public License as published by // the Free Software Foundation, either version 3 of the License, or // (at your option) any later version. // This program is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // You should have received a copy of the GNU General Public License // along with this program. If not, see . use std::collections::BTreeMap; use std::iter::FromIterator; use std::pin::Pin; use std::sync::Arc; use std::time::Duration; use log::{debug, warn}; use parity_scale_codec::{Decode, Encode}; use futures::prelude::*; use futures_timer::Delay; use parking_lot::RwLock; use std::marker::PhantomData; use sc_client_api::{backend::{Backend, apply_aux}, utils::is_descendent_of}; use finality_grandpa::{ BlockNumberOps, Error as GrandpaError, round::State as RoundState, voter, voter_set::VoterSet, }; use sp_blockchain::{HeaderBackend, HeaderMetadata, Error as ClientError}; use sp_runtime::generic::BlockId; use sp_runtime::traits::{ Block as BlockT, Header as HeaderT, NumberFor, One, Zero, }; use sc_telemetry::{telemetry, CONSENSUS_INFO}; use crate::{ CommandOrError, Commit, Config, Error, Precommit, Prevote, PrimaryPropose, SignedMessage, NewAuthoritySet, VoterCommand, }; use sp_consensus::SelectChain; use crate::authorities::{AuthoritySet, SharedAuthoritySet}; use crate::communication::Network as NetworkT; use crate::consensus_changes::SharedConsensusChanges; use crate::justification::GrandpaJustification; use crate::until_imported::UntilVoteTargetImported; use crate::voting_rule::VotingRule; use sp_finality_grandpa::{ AuthorityId, AuthoritySignature, Equivocation, EquivocationProof, GrandpaApi, RoundNumber, SetId, }; use prometheus_endpoint::{Gauge, U64, register, PrometheusError}; type HistoricalVotes = finality_grandpa::HistoricalVotes< ::Hash, NumberFor, AuthoritySignature, AuthorityId, >; /// Data about a completed round. The set of votes that is stored must be /// minimal, i.e. at most one equivocation is stored per voter. #[derive(Debug, Clone, Decode, Encode, PartialEq)] pub struct CompletedRound { /// The round number. pub number: RoundNumber, /// The round state (prevote ghost, estimate, finalized, etc.) pub state: RoundState>, /// The target block base used for voting in the round. pub base: (Block::Hash, NumberFor), /// All the votes observed in the round. pub votes: Vec>, } // Data about last completed rounds within a single voter set. Stores // NUM_LAST_COMPLETED_ROUNDS and always contains data about at least one round // (genesis). #[derive(Debug, Clone, PartialEq)] pub struct CompletedRounds { rounds: Vec>, set_id: SetId, voters: Vec, } // NOTE: the current strategy for persisting completed rounds is very naive // (update everything) and we also rely on cloning to do atomic updates, // therefore this value should be kept small for now. const NUM_LAST_COMPLETED_ROUNDS: usize = 2; impl Encode for CompletedRounds { fn encode(&self) -> Vec { let v = Vec::from_iter(&self.rounds); (&v, &self.set_id, &self.voters).encode() } } impl parity_scale_codec::EncodeLike for CompletedRounds {} impl Decode for CompletedRounds { fn decode(value: &mut I) -> Result { <(Vec>, SetId, Vec)>::decode(value) .map(|(rounds, set_id, voters)| CompletedRounds { rounds, set_id, voters, }) } } impl CompletedRounds { /// Create a new completed rounds tracker with NUM_LAST_COMPLETED_ROUNDS capacity. pub(crate) fn new( genesis: CompletedRound, set_id: SetId, voters: &AuthoritySet>, ) -> CompletedRounds { let mut rounds = Vec::with_capacity(NUM_LAST_COMPLETED_ROUNDS); rounds.push(genesis); let voters = voters.current_authorities.iter().map(|(a, _)| a.clone()).collect(); CompletedRounds { rounds, set_id, voters } } /// Get the set-id and voter set of the completed rounds. pub fn set_info(&self) -> (SetId, &[AuthorityId]) { (self.set_id, &self.voters[..]) } /// Iterate over all completed rounds. pub fn iter(&self) -> impl Iterator> { self.rounds.iter().rev() } /// Returns the last (latest) completed round. pub fn last(&self) -> &CompletedRound { self.rounds.first() .expect("inner is never empty; always contains at least genesis; qed") } /// Push a new completed round, oldest round is evicted if number of rounds /// is higher than `NUM_LAST_COMPLETED_ROUNDS`. pub fn push(&mut self, completed_round: CompletedRound) { use std::cmp::Reverse; match self.rounds.binary_search_by_key( &Reverse(completed_round.number), |completed_round| Reverse(completed_round.number), ) { Ok(idx) => self.rounds[idx] = completed_round, Err(idx) => self.rounds.insert(idx, completed_round), }; if self.rounds.len() > NUM_LAST_COMPLETED_ROUNDS { self.rounds.pop(); } } } /// A map with voter status information for currently live rounds, /// which votes have we cast and what are they. pub type CurrentRounds = BTreeMap>; /// The state of the current voter set, whether it is currently active or not /// and information related to the previously completed rounds. Current round /// voting status is used when restarting the voter, i.e. it will re-use the /// previous votes for a given round if appropriate (same round and same local /// key). #[derive(Debug, Decode, Encode, PartialEq)] pub enum VoterSetState { /// The voter is live, i.e. participating in rounds. Live { /// The previously completed rounds. completed_rounds: CompletedRounds, /// Voter status for the currently live rounds. current_rounds: CurrentRounds, }, /// The voter is paused, i.e. not casting or importing any votes. Paused { /// The previously completed rounds. completed_rounds: CompletedRounds, }, } impl VoterSetState { /// Create a new live VoterSetState with round 0 as a completed round using /// the given genesis state and the given authorities. Round 1 is added as a /// current round (with state `HasVoted::No`). pub(crate) fn live( set_id: SetId, authority_set: &AuthoritySet>, genesis_state: (Block::Hash, NumberFor), ) -> VoterSetState { let state = RoundState::genesis((genesis_state.0, genesis_state.1)); let completed_rounds = CompletedRounds::new( CompletedRound { number: 0, state, base: (genesis_state.0, genesis_state.1), votes: Vec::new(), }, set_id, authority_set, ); let mut current_rounds = CurrentRounds::new(); current_rounds.insert(1, HasVoted::No); VoterSetState::Live { completed_rounds, current_rounds, } } /// Returns the last completed rounds. pub(crate) fn completed_rounds(&self) -> CompletedRounds { match self { VoterSetState::Live { completed_rounds, .. } => completed_rounds.clone(), VoterSetState::Paused { completed_rounds } => completed_rounds.clone(), } } /// Returns the last completed round. pub(crate) fn last_completed_round(&self) -> CompletedRound { match self { VoterSetState::Live { completed_rounds, .. } => completed_rounds.last().clone(), VoterSetState::Paused { completed_rounds } => completed_rounds.last().clone(), } } /// Returns the voter set state validating that it includes the given round /// in current rounds and that the voter isn't paused. pub fn with_current_round(&self, round: RoundNumber) -> Result<(&CompletedRounds, &CurrentRounds), Error> { if let VoterSetState::Live { completed_rounds, current_rounds } = self { if current_rounds.contains_key(&round) { Ok((completed_rounds, current_rounds)) } else { let msg = "Voter acting on a live round we are not tracking."; Err(Error::Safety(msg.to_string())) } } else { let msg = "Voter acting while in paused state."; Err(Error::Safety(msg.to_string())) } } } /// Whether we've voted already during a prior run of the program. #[derive(Clone, Debug, Decode, Encode, PartialEq)] pub enum HasVoted { /// Has not voted already in this round. No, /// Has voted in this round. Yes(AuthorityId, Vote), } /// The votes cast by this voter already during a prior run of the program. #[derive(Debug, Clone, Decode, Encode, PartialEq)] pub enum Vote { /// Has cast a proposal. Propose(PrimaryPropose), /// Has cast a prevote. Prevote(Option>, Prevote), /// Has cast a precommit (implies prevote.) Precommit(Option>, Prevote, Precommit), } impl HasVoted { /// Returns the proposal we should vote with (if any.) pub fn propose(&self) -> Option<&PrimaryPropose> { match self { HasVoted::Yes(_, Vote::Propose(propose)) => Some(propose), HasVoted::Yes(_, Vote::Prevote(propose, _)) | HasVoted::Yes(_, Vote::Precommit(propose, _, _)) => propose.as_ref(), _ => None, } } /// Returns the prevote we should vote with (if any.) pub fn prevote(&self) -> Option<&Prevote> { match self { HasVoted::Yes(_, Vote::Prevote(_, prevote)) | HasVoted::Yes(_, Vote::Precommit(_, prevote, _)) => Some(prevote), _ => None, } } /// Returns the precommit we should vote with (if any.) pub fn precommit(&self) -> Option<&Precommit> { match self { HasVoted::Yes(_, Vote::Precommit(_, _, precommit)) => Some(precommit), _ => None, } } /// Returns true if the voter can still propose, false otherwise. pub fn can_propose(&self) -> bool { self.propose().is_none() } /// Returns true if the voter can still prevote, false otherwise. pub fn can_prevote(&self) -> bool { self.prevote().is_none() } /// Returns true if the voter can still precommit, false otherwise. pub fn can_precommit(&self) -> bool { self.precommit().is_none() } } /// A voter set state meant to be shared safely across multiple owners. #[derive(Clone)] pub struct SharedVoterSetState { inner: Arc>>, } impl From> for SharedVoterSetState { fn from(set_state: VoterSetState) -> Self { SharedVoterSetState::new(set_state) } } impl SharedVoterSetState { /// Create a new shared voter set tracker with the given state. pub(crate) fn new(state: VoterSetState) -> Self { SharedVoterSetState { inner: Arc::new(RwLock::new(state)) } } /// Read the inner voter set state. pub(crate) fn read(&self) -> parking_lot::RwLockReadGuard> { self.inner.read() } /// Return vote status information for the current round. pub(crate) fn has_voted(&self, round: RoundNumber) -> HasVoted { match &*self.inner.read() { VoterSetState::Live { current_rounds, .. } => { current_rounds.get(&round).and_then(|has_voted| match has_voted { HasVoted::Yes(id, vote) => Some(HasVoted::Yes(id.clone(), vote.clone())), _ => None, }) .unwrap_or(HasVoted::No) }, _ => HasVoted::No, } } // NOTE: not exposed outside of this module intentionally. fn with(&self, f: F) -> R where F: FnOnce(&mut VoterSetState) -> R { f(&mut *self.inner.write()) } } /// Prometheus metrics for GRANDPA. #[derive(Clone)] pub(crate) struct Metrics { finality_grandpa_round: Gauge, } impl Metrics { pub(crate) fn register(registry: &prometheus_endpoint::Registry) -> Result { Ok(Self { finality_grandpa_round: register( Gauge::new("finality_grandpa_round", "Highest completed GRANDPA round.")?, registry )?, }) } } /// The environment we run GRANDPA in. pub(crate) struct Environment, SC, VR> { pub(crate) client: Arc, pub(crate) select_chain: SC, pub(crate) voters: Arc>, pub(crate) config: Config, pub(crate) authority_set: SharedAuthoritySet>, pub(crate) consensus_changes: SharedConsensusChanges>, pub(crate) network: crate::communication::NetworkBridge, pub(crate) set_id: SetId, pub(crate) voter_set_state: SharedVoterSetState, pub(crate) voting_rule: VR, pub(crate) metrics: Option, pub(crate) _phantom: PhantomData, } impl, SC, VR> Environment { /// Updates the voter set state using the given closure. The write lock is /// held during evaluation of the closure and the environment's voter set /// state is set to its result if successful. pub(crate) fn update_voter_set_state(&self, f: F) -> Result<(), Error> where F: FnOnce(&VoterSetState) -> Result>, Error> { self.voter_set_state.with(|voter_set_state| { if let Some(set_state) = f(&voter_set_state)? { *voter_set_state = set_state; if let Some(metrics) = self.metrics.as_ref() { if let VoterSetState::Live { completed_rounds, .. } = voter_set_state { let highest = completed_rounds.rounds.iter() .map(|round| round.number) .max() .expect("There is always one completed round (genesis); qed"); metrics.finality_grandpa_round.set(highest); } } } Ok(()) }) } } impl Environment where Block: BlockT, BE: Backend, C: crate::ClientForGrandpa, C::Api: GrandpaApi, N: NetworkT, SC: SelectChain + 'static, { /// Report the given equivocation to the GRANDPA runtime module. This method /// generates a session membership proof of the offender and then submits an /// extrinsic to report the equivocation. In particular, the session membership /// proof must be generated at the block at which the given set was active which /// isn't necessarily the best block if there are pending authority set changes. fn report_equivocation( &self, equivocation: Equivocation>, ) -> Result<(), Error> { let is_descendent_of = is_descendent_of(&*self.client, None); let best_header = self.select_chain .best_chain() .map_err(|e| Error::Blockchain(e.to_string()))?; let authority_set = self.authority_set.inner().read(); // block hash and number of the next pending authority set change in the // given best chain. let next_change = authority_set .next_change(&best_header.hash(), &is_descendent_of) .map_err(|e| Error::Safety(e.to_string()))?; // find the hash of the latest block in the current set let current_set_latest_hash = match next_change { Some((_, n)) if n.is_zero() => { return Err(Error::Safety( "Authority set change signalled at genesis.".to_string(), )) } // the next set starts at `n` so the current one lasts until `n - 1`. if // `n` is later than the best block, then the current set is still live // at best block. Some((_, n)) if n > *best_header.number() => best_header.hash(), Some((h, _)) => { // this is the header at which the new set will start let header = self.client.header(BlockId::Hash(h))?.expect( "got block hash from registered pending change; \ pending changes are only registered on block import; qed.", ); // its parent block is the last block in the current set *header.parent_hash() } // there is no pending change, the latest block for the current set is // the best block. None => best_header.hash(), }; // generate key ownership proof at that block let key_owner_proof = match self.client .runtime_api() .generate_key_ownership_proof( &BlockId::Hash(current_set_latest_hash), authority_set.set_id, equivocation.offender().clone(), ) .map_err(Error::Client)? { Some(proof) => proof, None => { debug!(target: "afg", "Equivocation offender is not part of the authority set."); return Ok(()); } }; // submit equivocation report at **best** block let equivocation_proof = EquivocationProof::new( authority_set.set_id, equivocation, ); self.client.runtime_api() .submit_report_equivocation_extrinsic( &BlockId::Hash(best_header.hash()), equivocation_proof, key_owner_proof, ).map_err(Error::Client)?; Ok(()) } } impl finality_grandpa::Chain> for Environment where Block: 'static, BE: Backend, C: crate::ClientForGrandpa, N: NetworkT + 'static + Send, SC: SelectChain + 'static, VR: VotingRule, NumberFor: BlockNumberOps, { fn ancestry(&self, base: Block::Hash, block: Block::Hash) -> Result, GrandpaError> { ancestry(&self.client, base, block) } fn best_chain_containing(&self, block: Block::Hash) -> Option<(Block::Hash, NumberFor)> { // NOTE: when we finalize an authority set change through the sync protocol the voter is // signaled asynchronously. therefore the voter could still vote in the next round // before activating the new set. the `authority_set` is updated immediately thus we // restrict the voter based on that. if self.set_id != self.authority_set.set_id() { return None; } let base_header = match self.client.header(BlockId::Hash(block)).ok()? { Some(h) => h, None => { debug!(target: "afg", "Encountered error finding best chain containing {:?}: couldn't find base block", block); return None; } }; // we refuse to vote beyond the current limit number where transitions are scheduled to // occur. // once blocks are finalized that make that transition irrelevant or activate it, // we will proceed onwards. most of the time there will be no pending transition. // the limit, if any, is guaranteed to be higher than or equal to the given base number. let limit = self.authority_set.current_limit(*base_header.number()); debug!(target: "afg", "Finding best chain containing block {:?} with number limit {:?}", block, limit); match self.select_chain.finality_target(block, None) { Ok(Some(best_hash)) => { let best_header = self.client.header(BlockId::Hash(best_hash)).ok()? .expect("Header known to exist after `finality_target` call; qed"); // check if our vote is currently being limited due to a pending change let limit = limit.filter(|limit| limit < best_header.number()); let target; let target_header = if let Some(target_number) = limit { let mut target_header = best_header.clone(); // walk backwards until we find the target block loop { if *target_header.number() < target_number { unreachable!( "we are traversing backwards from a known block; \ blocks are stored contiguously; \ qed" ); } if *target_header.number() == target_number { break; } target_header = self.client.header(BlockId::Hash(*target_header.parent_hash())).ok()? .expect("Header known to exist after `finality_target` call; qed"); } target = target_header; &target } else { // otherwise just use the given best as the target &best_header }; // restrict vote according to the given voting rule, if the // voting rule doesn't restrict the vote then we keep the // previous target. // // note that we pass the original `best_header`, i.e. before the // authority set limit filter, which can be considered a // mandatory/implicit voting rule. // // we also make sure that the restricted vote is higher than the // round base (i.e. last finalized), otherwise the value // returned by the given voting rule is ignored and the original // target is used instead. self.voting_rule .restrict_vote(&*self.client, &base_header, &best_header, target_header) .filter(|(_, restricted_number)| { // we can only restrict votes within the interval [base, target] restricted_number >= base_header.number() && restricted_number < target_header.number() }) .or_else(|| Some((target_header.hash(), *target_header.number()))) }, Ok(None) => { debug!(target: "afg", "Encountered error finding best chain containing {:?}: couldn't find target block", block); None } Err(e) => { debug!(target: "afg", "Encountered error finding best chain containing {:?}: {:?}", block, e); None } } } } pub(crate) fn ancestry( client: &Arc, base: Block::Hash, block: Block::Hash, ) -> Result, GrandpaError> where Client: HeaderMetadata, { if base == block { return Err(GrandpaError::NotDescendent) } let tree_route_res = sp_blockchain::tree_route(&**client, block, base); let tree_route = match tree_route_res { Ok(tree_route) => tree_route, Err(e) => { debug!(target: "afg", "Encountered error computing ancestry between block {:?} and base {:?}: {:?}", block, base, e); return Err(GrandpaError::NotDescendent); } }; if tree_route.common_block().hash != base { return Err(GrandpaError::NotDescendent); } // skip one because our ancestry is meant to start from the parent of `block`, // and `tree_route` includes it. Ok(tree_route.retracted().iter().skip(1).map(|e| e.hash).collect()) } impl voter::Environment> for Environment where Block: 'static, B: Backend, C: crate::ClientForGrandpa + 'static, C::Api: GrandpaApi, N: NetworkT + 'static + Send + Sync, SC: SelectChain + 'static, VR: VotingRule, NumberFor: BlockNumberOps, { type Timer = Pin> + Send + Sync>>; type Id = AuthorityId; type Signature = AuthoritySignature; // regular round message streams type In = Pin, Self::Signature, Self::Id>, Self::Error> > + Send + Sync>>; type Out = Pin>, Error = Self::Error, > + Send + Sync>>; type Error = CommandOrError>; fn round_data( &self, round: RoundNumber, ) -> voter::RoundData { let prevote_timer = Delay::new(self.config.gossip_duration * 2); let precommit_timer = Delay::new(self.config.gossip_duration * 4); let local_key = crate::is_voter(&self.voters, self.config.keystore.as_ref()); let has_voted = match self.voter_set_state.has_voted(round) { HasVoted::Yes(id, vote) => { if local_key.as_ref().map(|k| k == &id).unwrap_or(false) { HasVoted::Yes(id, vote) } else { HasVoted::No } }, HasVoted::No => HasVoted::No, }; let (incoming, outgoing) = self.network.round_communication( self.config.keystore.clone(), crate::communication::Round(round), crate::communication::SetId(self.set_id), self.voters.clone(), local_key.clone(), has_voted, ); // schedule incoming messages from the network to be held until // corresponding blocks are imported. let incoming = Box::pin(UntilVoteTargetImported::new( self.client.import_notification_stream(), self.network.clone(), self.client.clone(), incoming, "round", None, ).map_err(Into::into)); // schedule network message cleanup when sink drops. let outgoing = Box::pin(outgoing.sink_err_into()); voter::RoundData { voter_id: local_key, prevote_timer: Box::pin(prevote_timer.map(Ok)), precommit_timer: Box::pin(precommit_timer.map(Ok)), incoming, outgoing, } } fn proposed(&self, round: RoundNumber, propose: PrimaryPropose) -> Result<(), Self::Error> { let local_id = crate::is_voter(&self.voters, self.config.keystore.as_ref()); let local_id = match local_id { Some(id) => id, None => return Ok(()), }; self.update_voter_set_state(|voter_set_state| { let (completed_rounds, current_rounds) = voter_set_state.with_current_round(round)?; let current_round = current_rounds.get(&round) .expect("checked in with_current_round that key exists; qed."); if !current_round.can_propose() { // we've already proposed in this round (in a previous run), // ignore the given vote and don't update the voter set // state return Ok(None); } let mut current_rounds = current_rounds.clone(); let current_round = current_rounds.get_mut(&round) .expect("checked previously that key exists; qed."); *current_round = HasVoted::Yes(local_id, Vote::Propose(propose)); let set_state = VoterSetState::::Live { completed_rounds: completed_rounds.clone(), current_rounds, }; crate::aux_schema::write_voter_set_state(&*self.client, &set_state)?; Ok(Some(set_state)) })?; Ok(()) } fn prevoted(&self, round: RoundNumber, prevote: Prevote) -> Result<(), Self::Error> { let local_id = crate::is_voter(&self.voters, self.config.keystore.as_ref()); let local_id = match local_id { Some(id) => id, None => return Ok(()), }; self.update_voter_set_state(|voter_set_state| { let (completed_rounds, current_rounds) = voter_set_state.with_current_round(round)?; let current_round = current_rounds.get(&round) .expect("checked in with_current_round that key exists; qed."); if !current_round.can_prevote() { // we've already prevoted in this round (in a previous run), // ignore the given vote and don't update the voter set // state return Ok(None); } let propose = current_round.propose(); let mut current_rounds = current_rounds.clone(); let current_round = current_rounds.get_mut(&round) .expect("checked previously that key exists; qed."); *current_round = HasVoted::Yes(local_id, Vote::Prevote(propose.cloned(), prevote)); let set_state = VoterSetState::::Live { completed_rounds: completed_rounds.clone(), current_rounds, }; crate::aux_schema::write_voter_set_state(&*self.client, &set_state)?; Ok(Some(set_state)) })?; Ok(()) } fn precommitted(&self, round: RoundNumber, precommit: Precommit) -> Result<(), Self::Error> { let local_id = crate::is_voter(&self.voters, self.config.keystore.as_ref()); let local_id = match local_id { Some(id) => id, None => return Ok(()), }; self.update_voter_set_state(|voter_set_state| { let (completed_rounds, current_rounds) = voter_set_state.with_current_round(round)?; let current_round = current_rounds.get(&round) .expect("checked in with_current_round that key exists; qed."); if !current_round.can_precommit() { // we've already precommitted in this round (in a previous run), // ignore the given vote and don't update the voter set // state return Ok(None); } let propose = current_round.propose(); let prevote = match current_round { HasVoted::Yes(_, Vote::Prevote(_, prevote)) => prevote, _ => { let msg = "Voter precommitting before prevoting."; return Err(Error::Safety(msg.to_string())); }, }; let mut current_rounds = current_rounds.clone(); let current_round = current_rounds.get_mut(&round) .expect("checked previously that key exists; qed."); *current_round = HasVoted::Yes( local_id, Vote::Precommit(propose.cloned(), prevote.clone(), precommit), ); let set_state = VoterSetState::::Live { completed_rounds: completed_rounds.clone(), current_rounds, }; crate::aux_schema::write_voter_set_state(&*self.client, &set_state)?; Ok(Some(set_state)) })?; Ok(()) } fn completed( &self, round: RoundNumber, state: RoundState>, base: (Block::Hash, NumberFor), historical_votes: &HistoricalVotes, ) -> Result<(), Self::Error> { debug!( target: "afg", "Voter {} completed round {} in set {}. Estimate = {:?}, Finalized in round = {:?}", self.config.name(), round, self.set_id, state.estimate.as_ref().map(|e| e.1), state.finalized.as_ref().map(|e| e.1), ); self.update_voter_set_state(|voter_set_state| { // NOTE: we don't use `with_current_round` here, it is possible that // we are not currently tracking this round if it is a round we // caught up to. let (completed_rounds, current_rounds) = if let VoterSetState::Live { completed_rounds, current_rounds } = voter_set_state { (completed_rounds, current_rounds) } else { let msg = "Voter acting while in paused state."; return Err(Error::Safety(msg.to_string())); }; let mut completed_rounds = completed_rounds.clone(); // TODO: Future integration will store the prevote and precommit index. See #2611. let votes = historical_votes.seen().to_vec(); completed_rounds.push(CompletedRound { number: round, state: state.clone(), base, votes, }); // remove the round from live rounds and start tracking the next round let mut current_rounds = current_rounds.clone(); current_rounds.remove(&round); current_rounds.insert(round + 1, HasVoted::No); let set_state = VoterSetState::::Live { completed_rounds, current_rounds, }; crate::aux_schema::write_voter_set_state(&*self.client, &set_state)?; Ok(Some(set_state)) })?; Ok(()) } fn concluded( &self, round: RoundNumber, state: RoundState>, _base: (Block::Hash, NumberFor), historical_votes: &HistoricalVotes, ) -> Result<(), Self::Error> { debug!( target: "afg", "Voter {} concluded round {} in set {}. Estimate = {:?}, Finalized in round = {:?}", self.config.name(), round, self.set_id, state.estimate.as_ref().map(|e| e.1), state.finalized.as_ref().map(|e| e.1), ); self.update_voter_set_state(|voter_set_state| { // NOTE: we don't use `with_current_round` here, because a concluded // round is completed and cannot be current. let (completed_rounds, current_rounds) = if let VoterSetState::Live { completed_rounds, current_rounds } = voter_set_state { (completed_rounds, current_rounds) } else { let msg = "Voter acting while in paused state."; return Err(Error::Safety(msg.to_string())); }; let mut completed_rounds = completed_rounds.clone(); if let Some(already_completed) = completed_rounds.rounds .iter_mut().find(|r| r.number == round) { let n_existing_votes = already_completed.votes.len(); // the interface of Environment guarantees that the previous `historical_votes` // from `completable` is a prefix of what is passed to `concluded`. already_completed.votes.extend( historical_votes.seen().iter().skip(n_existing_votes).cloned() ); already_completed.state = state; crate::aux_schema::write_concluded_round(&*self.client, &already_completed)?; } let set_state = VoterSetState::::Live { completed_rounds, current_rounds: current_rounds.clone(), }; crate::aux_schema::write_voter_set_state(&*self.client, &set_state)?; Ok(Some(set_state)) })?; Ok(()) } fn finalize_block( &self, hash: Block::Hash, number: NumberFor, round: RoundNumber, commit: Commit, ) -> Result<(), Self::Error> { finalize_block( self.client.clone(), &self.authority_set, &self.consensus_changes, Some(self.config.justification_period.into()), hash, number, (round, commit).into(), false, ) } fn round_commit_timer(&self) -> Self::Timer { use rand::{thread_rng, Rng}; //random between 0-1 seconds. let delay: u64 = thread_rng().gen_range(0, 1000); Box::pin(Delay::new(Duration::from_millis(delay)).map(Ok)) } fn prevote_equivocation( &self, _round: RoundNumber, equivocation: finality_grandpa::Equivocation, Self::Signature>, ) { warn!(target: "afg", "Detected prevote equivocation in the finality worker: {:?}", equivocation); if let Err(err) = self.report_equivocation(equivocation.into()) { warn!(target: "afg", "Error reporting prevote equivocation: {:?}", err); } } fn precommit_equivocation( &self, _round: RoundNumber, equivocation: finality_grandpa::Equivocation, Self::Signature>, ) { warn!(target: "afg", "Detected precommit equivocation in the finality worker: {:?}", equivocation); if let Err(err) = self.report_equivocation(equivocation.into()) { warn!(target: "afg", "Error reporting precommit equivocation: {:?}", err); } } } pub(crate) enum JustificationOrCommit { Justification(GrandpaJustification), Commit((RoundNumber, Commit)), } impl From<(RoundNumber, Commit)> for JustificationOrCommit { fn from(commit: (RoundNumber, Commit)) -> JustificationOrCommit { JustificationOrCommit::Commit(commit) } } impl From> for JustificationOrCommit { fn from(justification: GrandpaJustification) -> JustificationOrCommit { JustificationOrCommit::Justification(justification) } } /// Finalize the given block and apply any authority set changes. If an /// authority set change is enacted then a justification is created (if not /// given) and stored with the block when finalizing it. /// This method assumes that the block being finalized has already been imported. pub(crate) fn finalize_block( client: Arc, authority_set: &SharedAuthoritySet>, consensus_changes: &SharedConsensusChanges>, justification_period: Option>, hash: Block::Hash, number: NumberFor, justification_or_commit: JustificationOrCommit, initial_sync: bool, ) -> Result<(), CommandOrError>> where Block: BlockT, BE: Backend, Client: crate::ClientForGrandpa, { // NOTE: lock must be held through writing to DB to avoid race. this lock // also implicitly synchronizes the check for last finalized number // below. let mut authority_set = authority_set.inner().write(); let status = client.info(); if number <= status.finalized_number && client.hash(number)? == Some(hash) { // This can happen after a forced change (triggered by the finality tracker when finality is stalled), since // the voter will be restarted at the median last finalized block, which can be lower than the local best // finalized block. warn!(target: "afg", "Re-finalized block #{:?} ({:?}) in the canonical chain, current best finalized is #{:?}", hash, number, status.finalized_number, ); return Ok(()); } // FIXME #1483: clone only when changed let old_authority_set = authority_set.clone(); // holds the old consensus changes in case it is changed below, needed for // reverting in case of failure let mut old_consensus_changes = None; let mut consensus_changes = consensus_changes.lock(); let canon_at_height = |canon_number| { // "true" because the block is finalized canonical_at_height(&*client, (hash, number), true, canon_number) }; let update_res: Result<_, Error> = client.lock_import_and_run(|import_op| { let status = authority_set.apply_standard_changes( hash, number, &is_descendent_of::(&*client, None), initial_sync, ).map_err(|e| Error::Safety(e.to_string()))?; // check if this is this is the first finalization of some consensus changes let (alters_consensus_changes, finalizes_consensus_changes) = consensus_changes .finalize((number, hash), &canon_at_height)?; if alters_consensus_changes { old_consensus_changes = Some(consensus_changes.clone()); let write_result = crate::aux_schema::update_consensus_changes( &*consensus_changes, |insert| apply_aux(import_op, insert, &[]), ); if let Err(e) = write_result { warn!(target: "afg", "Failed to write updated consensus changes to disk. Bailing."); warn!(target: "afg", "Node is in a potentially inconsistent state."); return Err(e.into()); } } // NOTE: this code assumes that honest voters will never vote past a // transition block, thus we don't have to worry about the case where // we have a transition with `effective_block = N`, but we finalize // `N+1`. this assumption is required to make sure we store // justifications for transition blocks which will be requested by // syncing clients. let justification = match justification_or_commit { JustificationOrCommit::Justification(justification) => Some(justification.encode()), JustificationOrCommit::Commit((round_number, commit)) => { let mut justification_required = // justification is always required when block that enacts new authorities // set is finalized status.new_set_block.is_some() || // justification is required when consensus changes are finalized finalizes_consensus_changes; // justification is required every N blocks to be able to prove blocks // finalization to remote nodes if !justification_required { if let Some(justification_period) = justification_period { let last_finalized_number = client.info().finalized_number; justification_required = (!last_finalized_number.is_zero() || number - last_finalized_number == justification_period) && (last_finalized_number / justification_period != number / justification_period); } } if justification_required { let justification = GrandpaJustification::from_commit( &client, round_number, commit, )?; Some(justification.encode()) } else { None } }, }; debug!(target: "afg", "Finalizing blocks up to ({:?}, {})", number, hash); // ideally some handle to a synchronization oracle would be used // to avoid unconditionally notifying. client.apply_finality(import_op, BlockId::Hash(hash), justification, true).map_err(|e| { warn!(target: "afg", "Error applying finality to block {:?}: {:?}", (hash, number), e); e })?; telemetry!(CONSENSUS_INFO; "afg.finalized_blocks_up_to"; "number" => ?number, "hash" => ?hash, ); let new_authorities = if let Some((canon_hash, canon_number)) = status.new_set_block { // the authority set has changed. let (new_id, set_ref) = authority_set.current(); if set_ref.len() > 16 { afg_log!(initial_sync, "👴 Applying GRANDPA set change to new set with {} authorities", set_ref.len(), ); } else { afg_log!(initial_sync, "👴 Applying GRANDPA set change to new set {:?}", set_ref, ); } telemetry!(CONSENSUS_INFO; "afg.generating_new_authority_set"; "number" => ?canon_number, "hash" => ?canon_hash, "authorities" => ?set_ref.to_vec(), "set_id" => ?new_id, ); Some(NewAuthoritySet { canon_hash, canon_number, set_id: new_id, authorities: set_ref.to_vec(), }) } else { None }; if status.changed { let write_result = crate::aux_schema::update_authority_set::( &authority_set, new_authorities.as_ref(), |insert| apply_aux(import_op, insert, &[]), ); if let Err(e) = write_result { warn!(target: "afg", "Failed to write updated authority set to disk. Bailing."); warn!(target: "afg", "Node is in a potentially inconsistent state."); return Err(e.into()); } } Ok(new_authorities.map(VoterCommand::ChangeAuthorities)) }); match update_res { Ok(Some(command)) => Err(CommandOrError::VoterCommand(command)), Ok(None) => Ok(()), Err(e) => { *authority_set = old_authority_set; if let Some(old_consensus_changes) = old_consensus_changes { *consensus_changes = old_consensus_changes; } Err(CommandOrError::Error(e)) } } } /// Using the given base get the block at the given height on this chain. The /// target block must be an ancestor of base, therefore `height <= base.height`. pub(crate) fn canonical_at_height>( provider: &C, base: (Block::Hash, NumberFor), base_is_canonical: bool, height: NumberFor, ) -> Result, ClientError> { if height > base.1 { return Ok(None); } if height == base.1 { if base_is_canonical { return Ok(Some(base.0)); } else { return Ok(provider.hash(height).unwrap_or(None)); } } else if base_is_canonical { return Ok(provider.hash(height).unwrap_or(None)); } let one = NumberFor::::one(); // start by getting _canonical_ block with number at parent position and then iterating // backwards by hash. let mut current = match provider.header(BlockId::Number(base.1 - one))? { Some(header) => header, _ => return Ok(None), }; // we've already checked that base > height above. let mut steps = base.1 - height - one; while steps > NumberFor::::zero() { current = match provider.header(BlockId::Hash(*current.parent_hash()))? { Some(header) => header, _ => return Ok(None), }; steps -= one; } Ok(Some(current.hash())) }