use apply_rewards::process_rewards_and_penalties; use errors::EpochProcessingError as Error; use process_slashings::process_slashings; use registry_updates::process_registry_updates; use std::collections::HashMap; use tree_hash::TreeHash; use types::*; use validator_statuses::{TotalBalances, ValidatorStatuses}; use winning_root::{winning_root, WinningRoot}; pub mod apply_rewards; pub mod errors; pub mod process_slashings; pub mod registry_updates; pub mod tests; pub mod validator_statuses; pub mod winning_root; /// Maps a shard to a winning root. /// /// It is generated during crosslink processing and later used to reward/penalize validators. pub type WinningRootHashSet = HashMap; /// Performs per-epoch processing on some BeaconState. /// /// Mutates the given `BeaconState`, returning early if an error is encountered. If an error is /// returned, a state might be "half-processed" and therefore in an invalid state. /// /// Spec v0.6.1 pub fn per_epoch_processing( state: &mut BeaconState, spec: &ChainSpec, ) -> Result<(), Error> { // Ensure the previous and next epoch caches are built. state.build_committee_cache(RelativeEpoch::Previous, spec)?; state.build_committee_cache(RelativeEpoch::Current, spec)?; // Load the struct we use to assign validators into sets based on their participation. // // E.g., attestation in the previous epoch, attested to the head, etc. let mut validator_statuses = ValidatorStatuses::new(state, spec)?; validator_statuses.process_attestations(&state, spec)?; // Justification and finalization. process_justification_and_finalization(state, &validator_statuses.total_balances, spec)?; // Crosslinks. let winning_root_for_shards = process_crosslinks(state, spec)?; // Rewards and Penalities. process_rewards_and_penalties( state, &mut validator_statuses, &winning_root_for_shards, spec, )?; // Registry Updates. process_registry_updates(state, spec)?; // Slashings. process_slashings(state, validator_statuses.total_balances.current_epoch, spec)?; // Final updates. process_final_updates(state, spec)?; // Rotate the epoch caches to suit the epoch transition. state.advance_caches(); Ok(()) } /// Update the following fields on the `BeaconState`: /// /// - `justification_bitfield`. /// - `previous_justified_epoch` /// - `previous_justified_root` /// - `current_justified_epoch` /// - `current_justified_root` /// - `finalized_epoch` /// - `finalized_root` /// /// Spec v0.6.1 pub fn process_justification_and_finalization( state: &mut BeaconState, total_balances: &TotalBalances, spec: &ChainSpec, ) -> Result<(), Error> { if state.current_epoch() == spec.genesis_epoch { return Ok(()); } let previous_epoch = state.previous_epoch(); let current_epoch = state.current_epoch(); let old_previous_justified_epoch = state.previous_justified_epoch; let old_current_justified_epoch = state.current_justified_epoch; // Process justifications state.previous_justified_epoch = state.current_justified_epoch; state.previous_justified_root = state.current_justified_root; state.justification_bitfield <<= 1; if total_balances.previous_epoch_target_attesters * 3 >= total_balances.previous_epoch * 2 { state.current_justified_epoch = previous_epoch; state.current_justified_root = *state.get_block_root_at_epoch(state.current_justified_epoch, spec)?; state.justification_bitfield |= 2; } // If the current epoch gets justified, fill the last bit. if total_balances.current_epoch_target_attesters * 3 >= total_balances.current_epoch * 2 { state.current_justified_epoch = current_epoch; state.current_justified_root = *state.get_block_root_at_epoch(state.current_justified_epoch, spec)?; state.justification_bitfield |= 1; } let bitfield = state.justification_bitfield; // The 2nd/3rd/4th most recent epochs are all justified, the 2nd using the 4th as source. if (bitfield >> 1) % 8 == 0b111 && old_previous_justified_epoch == current_epoch - 3 { state.finalized_epoch = old_previous_justified_epoch; state.finalized_root = *state.get_block_root_at_epoch(state.finalized_epoch, spec)?; } // The 2nd/3rd most recent epochs are both justified, the 2nd using the 3rd as source. if (bitfield >> 1) % 4 == 0b11 && state.previous_justified_epoch == current_epoch - 2 { state.finalized_epoch = old_previous_justified_epoch; state.finalized_root = *state.get_block_root_at_epoch(state.finalized_epoch, spec)?; } // The 1st/2nd/3rd most recent epochs are all justified, the 1st using the 2nd as source. if bitfield % 8 == 0b111 && state.current_justified_epoch == current_epoch - 2 { state.finalized_epoch = old_current_justified_epoch; state.finalized_root = *state.get_block_root_at_epoch(state.finalized_epoch, spec)?; } // The 1st/2nd most recent epochs are both justified, the 1st using the 2nd as source. if bitfield % 4 == 0b11 && state.current_justified_epoch == current_epoch - 1 { state.finalized_epoch = old_current_justified_epoch; state.finalized_root = *state.get_block_root_at_epoch(state.finalized_epoch, spec)?; } Ok(()) } /// Updates the following fields on the `BeaconState`: /// /// - `previous_crosslinks` /// - `current_crosslinks` /// /// Also returns a `WinningRootHashSet` for later use during epoch processing. /// /// Spec v0.6.1 pub fn process_crosslinks( state: &mut BeaconState, spec: &ChainSpec, ) -> Result { let mut winning_root_for_shards: WinningRootHashSet = HashMap::new(); state.previous_crosslinks = state.current_crosslinks.clone(); for relative_epoch in vec![RelativeEpoch::Previous, RelativeEpoch::Current] { let epoch = relative_epoch.into_epoch(state.current_epoch()); for offset in 0..state.get_epoch_committee_count(relative_epoch)? { let shard = (state.get_epoch_start_shard(relative_epoch)? + offset) % T::ShardCount::to_u64(); let crosslink_committee = state.get_crosslink_committee_for_shard(shard, relative_epoch)?; let winning_root = winning_root(state, shard, epoch, spec)?; if let Some(winning_root) = winning_root { let total_committee_balance = state.get_total_balance(&crosslink_committee.committee, spec)?; if 3 * winning_root.total_attesting_balance >= 2 * total_committee_balance { state.current_crosslinks[shard as usize] = winning_root.crosslink.clone(); } winning_root_for_shards.insert(shard, winning_root); } } } Ok(winning_root_for_shards) } /// Finish up an epoch update. /// /// Spec v0.6.1 pub fn process_final_updates( state: &mut BeaconState, spec: &ChainSpec, ) -> Result<(), Error> { let current_epoch = state.current_epoch(); let next_epoch = state.next_epoch(); // Reset eth1 data votes. if (state.slot + 1) % spec.slots_per_eth1_voting_period == 0 { state.eth1_data_votes = vec![]; } // Update effective balances with hysteresis (lag). for (index, validator) in state.validator_registry.iter_mut().enumerate() { let balance = state.balances[index]; let half_increment = spec.effective_balance_increment / 2; if balance < validator.effective_balance || validator.effective_balance + 3 * half_increment < balance { validator.effective_balance = std::cmp::min( balance - balance % spec.effective_balance_increment, spec.max_effective_balance, ); } } // Update start shard. state.latest_start_shard = state.next_epoch_start_shard()?; // This is a hack to allow us to update index roots and slashed balances for the next epoch. // // The indentation here is to make it obvious where the weird stuff happens. { state.slot += 1; // Set active index root let active_index_root = Hash256::from_slice( &state .get_active_validator_indices(next_epoch + spec.activation_exit_delay) .tree_hash_root()[..], ); state.set_active_index_root(next_epoch, active_index_root, spec)?; // Set total slashed balances state.set_slashed_balance(next_epoch, state.get_slashed_balance(current_epoch)?)?; // Set randao mix state.set_randao_mix(next_epoch, *state.get_randao_mix(current_epoch)?)?; state.slot -= 1; } if next_epoch.as_u64() % (T::SlotsPerHistoricalRoot::to_u64() / T::slots_per_epoch()) == 0 { let historical_batch = state.historical_batch(); state .historical_roots .push(Hash256::from_slice(&historical_batch.tree_hash_root()[..])); } // Rotate current/previous epoch attestations state.previous_epoch_attestations = std::mem::replace(&mut state.current_epoch_attestations, vec![]); Ok(()) }