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b6408805a2
lighthouse/beacon_node/beacon_chain/src/beacon_chain.rs
Age Manning b6408805a2
Stable futures (#879) 
* Port eth1 lib to use stable futures

* Port eth1_test_rig to stable futures

* Port eth1 tests to stable futures

* Port genesis service to stable futures

* Port genesis tests to stable futures

* Port beacon_chain to stable futures

* Port lcli to stable futures

* Fix eth1_test_rig (#1014)

* Fix lcli

* Port timer to stable futures

* Fix timer

* Port websocket_server to stable futures

* Port notifier to stable futures

* Add TODOS

* Update hashmap hashset to stable futures

* Adds panic test to hashset delay

* Port remote_beacon_node to stable futures

* Fix lcli merge conflicts

* Non rpc stuff compiles

* protocol.rs compiles

* Port websockets, timer and notifier to stable futures (#1035)

* Fix lcli

* Port timer to stable futures

* Fix timer

* Port websocket_server to stable futures

* Port notifier to stable futures

* Add TODOS

* Port remote_beacon_node to stable futures

* Partial eth2-libp2p stable future upgrade

* Finished first round of fighting RPC types

* Further progress towards porting eth2-libp2p adds caching to discovery

* Update behaviour

* RPC handler to stable futures

* Update RPC to master libp2p

* Network service additions

* Fix the fallback transport construction (#1102)

* Correct warning

* Remove hashmap delay

* Compiling version of eth2-libp2p

* Update all crates versions

* Fix conversion function and add tests (#1113)

* Port validator_client to stable futures (#1114)

* Add PH & MS slot clock changes

* Account for genesis time

* Add progress on duties refactor

* Add simple is_aggregator bool to val subscription

* Start work on attestation_verification.rs

* Add progress on ObservedAttestations

* Progress with ObservedAttestations

* Fix tests

* Add observed attestations to the beacon chain

* Add attestation observation to processing code

* Add progress on attestation verification

* Add first draft of ObservedAttesters

* Add more tests

* Add observed attesters to beacon chain

* Add observers to attestation processing

* Add more attestation verification

* Create ObservedAggregators map

* Remove commented-out code

* Add observed aggregators into chain

* Add progress

* Finish adding features to attestation verification

* Ensure beacon chain compiles

* Link attn verification into chain

* Integrate new attn verification in chain

* Remove old attestation processing code

* Start trying to fix beacon_chain tests

* Split adding into pools into two functions

* Add aggregation to harness

* Get test harness working again

* Adjust the number of aggregators for test harness

* Fix edge-case in harness

* Integrate new attn processing in network

* Fix compile bug in validator_client

* Update validator API endpoints

* Fix aggreagation in test harness

* Fix enum thing

* Fix attestation observation bug:

* Patch failing API tests

* Start adding comments to attestation verification

* Remove unused attestation field

* Unify "is block known" logic

* Update comments

* Supress fork choice errors for network processing

* Add todos

* Tidy

* Add gossip attn tests

* Disallow test harness to produce old attns

* Comment out in-progress tests

* Partially address pruning tests

* Fix failing store test

* Add aggregate tests

* Add comments about which spec conditions we check

* Dont re-aggregate

* Split apart test harness attn production

* Fix compile error in network

* Make progress on commented-out test

* Fix skipping attestation test

* Add fork choice verification tests

* Tidy attn tests, remove dead code

* Remove some accidentally added code

* Fix clippy lint

* Rename test file

* Add block tests, add cheap block proposer check

* Rename block testing file

* Add observed_block_producers

* Tidy

* Switch around block signature verification

* Finish block testing

* Remove gossip from signature tests

* First pass of self review

* Fix deviation in spec

* Update test spec tags

* Start moving over to hashset

* Finish moving observed attesters to hashmap

* Move aggregation pool over to hashmap

* Make fc attn borrow again

* Fix rest_api compile error

* Fix missing comments

* Fix monster test

* Uncomment increasing slots test

* Address remaining comments

* Remove unsafe, use cfg test

* Remove cfg test flag

* Fix dodgy comment

* Revert "Update hashmap hashset to stable futures"

This reverts commit d432378a3cc5cd67fc29c0b15b96b886c1323554.

* Revert "Adds panic test to hashset delay"

This reverts commit 281502396fc5b90d9c421a309c2c056982c9525b.

* Ported attestation_service

* Ported duties_service

* Ported fork_service

* More ports

* Port block_service

* Minor fixes

* VC compiles

* Update TODOS

* Borrow self where possible

* Ignore aggregates that are already known.

* Unify aggregator modulo logic

* Fix typo in logs

* Refactor validator subscription logic

* Avoid reproducing selection proof

* Skip HTTP call if no subscriptions

* Rename DutyAndState -> DutyAndProof

* Tidy logs

* Print root as dbg

* Fix compile errors in tests

* Fix compile error in test

* Re-Fix attestation and duties service

* Minor fixes

Co-authored-by: Paul Hauner <paul@paulhauner.com>

* Network crate update to stable futures

* Port account_manager to stable futures (#1121)

* Port account_manager to stable futures

* Run async fns in tokio environment

* Port rest_api crate to stable futures (#1118)

* Port rest_api lib to stable futures

* Reduce tokio features

* Update notifier to stable futures

* Builder update

* Further updates

* Convert self referential async functions

* stable futures fixes (#1124)

* Fix eth1 update functions

* Fix genesis and client

* Fix beacon node lib

* Return appropriate runtimes from environment

* Fix test rig

* Refactor eth1 service update

* Upgrade simulator to stable futures

* Lighthouse compiles on stable futures

* Remove println debugging statement

* Update libp2p service, start rpc test upgrade

* Update network crate for new libp2p

* Update tokio::codec to futures_codec (#1128)

* Further work towards RPC corrections

* Correct http timeout and network service select

* Use tokio runtime for libp2p

* Revert "Update tokio::codec to futures_codec (#1128)"

This reverts commit e57aea924acf5cbabdcea18895ac07e38a425ed7.

* Upgrade RPC libp2p tests

* Upgrade secio fallback test

* Upgrade gossipsub examples

* Clean up RPC protocol

* Test fixes (#1133)

* Correct websocket timeout and run on os thread

* Fix network test

* Clean up PR

* Correct tokio tcp move attestation service tests

* Upgrade attestation service tests

* Correct network test

* Correct genesis test

* Test corrections

* Log info when block is received

* Modify logs and update attester service events

* Stable futures: fixes to vc, eth1 and account manager (#1142)

* Add local testnet scripts

* Remove whiteblock script

* Rename local testnet script

* Move spawns onto handle

* Fix VC panic

* Initial fix to block production issue

* Tidy block producer fix

* Tidy further

* Add local testnet clean script

* Run cargo fmt

* Tidy duties service

* Tidy fork service

* Tidy ForkService

* Tidy AttestationService

* Tidy notifier

* Ensure await is not suppressed in eth1

* Ensure await is not suppressed in account_manager

* Use .ok() instead of .unwrap_or(())

* RPC decoding test for proto

* Update discv5 and eth2-libp2p deps

* Fix lcli double runtime issue (#1144)

* Handle stream termination and dialing peer errors

* Correct peer_info variant types

* Remove unnecessary warnings

* Handle subnet unsubscription removal and improve logigng

* Add logs around ping

* Upgrade discv5 and improve logging

* Handle peer connection status for multiple connections

* Improve network service logging

* Improve logging around peer manager

* Upgrade swarm poll centralise peer management

* Identify clients on error

* Fix `remove_peer` in sync (#1150)

* remove_peer removes from all chains

* Remove logs

* Fix early return from loop

* Improved logging, fix panic

* Partially correct tests

* Stable futures: Vc sync (#1149)

* Improve syncing heuristic

* Add comments

* Use safer method for tolerance

* Fix tests

* Stable futures: Fix VC bug, update agg pool, add more metrics (#1151)

* Expose epoch processing summary

* Expose participation metrics to prometheus

* Switch to f64

* Reduce precision

* Change precision

* Expose observed attesters metrics

* Add metrics for agg/unagg attn counts

* Add metrics for gossip rx

* Add metrics for gossip tx

* Adds ignored attns to prom

* Add attestation timing

* Add timer for aggregation pool sig agg

* Add write lock timer for agg pool

* Add more metrics to agg pool

* Change map lock code

* Add extra metric to agg pool

* Change lock handling in agg pool

* Change .write() to .read()

* Add another agg pool timer

* Fix for is_aggregator

* Fix pruning bug

Co-authored-by: pawan <pawandhananjay@gmail.com>
Co-authored-by: Paul Hauner <paul@paulhauner.com>
2020-05-17 11:16:48 +00:00

2149 lines
83 KiB
Rust
Raw Blame History

use crate::attestation_verification::{
Error as AttestationError, ForkChoiceVerifiedAttestation, IntoForkChoiceVerifiedAttestation,
VerifiedAggregatedAttestation, VerifiedUnaggregatedAttestation,
};
use crate::block_verification::{
check_block_relevancy, get_block_root, signature_verify_chain_segment, BlockError,
FullyVerifiedBlock, GossipVerifiedBlock, IntoFullyVerifiedBlock,
};
use crate::errors::{BeaconChainError as Error, BlockProductionError};
use crate::eth1_chain::{Eth1Chain, Eth1ChainBackend};
use crate::events::{EventHandler, EventKind};
use crate::fork_choice::{Error as ForkChoiceError, ForkChoice};
use crate::head_tracker::HeadTracker;
use crate::metrics;
use crate::migrate::Migrate;
use crate::naive_aggregation_pool::{Error as NaiveAggregationError, NaiveAggregationPool};
use crate::observed_attestations::{Error as AttestationObservationError, ObservedAttestations};
use crate::observed_attesters::{ObservedAggregators, ObservedAttesters};
use crate::observed_block_producers::ObservedBlockProducers;
use crate::persisted_beacon_chain::PersistedBeaconChain;
use crate::shuffling_cache::ShufflingCache;
use crate::snapshot_cache::SnapshotCache;
use crate::timeout_rw_lock::TimeoutRwLock;
use crate::validator_pubkey_cache::ValidatorPubkeyCache;
use crate::BeaconSnapshot;
use operation_pool::{OperationPool, PersistedOperationPool};
use slog::{crit, debug, error, info, trace, warn, Logger};
use slot_clock::SlotClock;
use state_processing::per_block_processing::errors::{
AttestationValidationError, AttesterSlashingValidationError, ExitValidationError,
ProposerSlashingValidationError,
};
use state_processing::{per_block_processing, per_slot_processing, BlockSignatureStrategy};
use std::borrow::Cow;
use std::cmp::Ordering;
use std::collections::HashMap;
use std::collections::HashSet;
use std::io::prelude::*;
use std::sync::Arc;
use std::time::{Duration, Instant};
use store::iter::{
BlockRootsIterator, ParentRootBlockIterator, ReverseBlockRootIterator,
ReverseStateRootIterator, StateRootsIterator,
};
use store::{Error as DBError, Store};
use types::*;
// Text included in blocks.
// Must be 32-bytes or panic.
//
// |-------must be this long------|
pub const GRAFFITI: &str = "sigp/lighthouse-0.2.0-prerelease";
/// The time-out before failure during an operation to take a read/write RwLock on the canonical
/// head.
pub const HEAD_LOCK_TIMEOUT: Duration = Duration::from_secs(1);
/// The time-out before failure during an operation to take a read/write RwLock on the block
/// processing cache.
pub const BLOCK_PROCESSING_CACHE_LOCK_TIMEOUT: Duration = Duration::from_secs(1);
/// The time-out before failure during an operation to take a read/write RwLock on the
/// attestation cache.
pub const ATTESTATION_CACHE_LOCK_TIMEOUT: Duration = Duration::from_secs(1);
/// The time-out before failure during an operation to take a read/write RwLock on the
/// validator pubkey cache.
pub const VALIDATOR_PUBKEY_CACHE_LOCK_TIMEOUT: Duration = Duration::from_secs(1);
pub const BEACON_CHAIN_DB_KEY: [u8; 32] = [0; 32];
pub const OP_POOL_DB_KEY: [u8; 32] = [0; 32];
pub const ETH1_CACHE_DB_KEY: [u8; 32] = [0; 32];
pub const FORK_CHOICE_DB_KEY: [u8; 32] = [0; 32];
/// The result of a chain segment processing.
#[derive(Debug)]
pub enum ChainSegmentResult {
/// Processing this chain segment finished successfully.
Successful { imported_blocks: usize },
/// There was an error processing this chain segment. Before the error, some blocks could
/// have been imported.
Failed {
imported_blocks: usize,
error: BlockError,
},
}
/// The accepted clock drift for nodes gossiping blocks and attestations (spec v0.11.0). See:
///
/// https://github.com/ethereum/eth2.0-specs/blob/v0.11.0/specs/phase0/p2p-interface.md#configuration
pub const MAXIMUM_GOSSIP_CLOCK_DISPARITY: Duration = Duration::from_millis(500);
#[derive(Debug, PartialEq)]
pub enum AttestationProcessingOutcome {
Processed,
EmptyAggregationBitfield,
UnknownHeadBlock {
beacon_block_root: Hash256,
},
/// The attestation is attesting to a state that is later than itself. (Viz., attesting to the
/// future).
AttestsToFutureBlock {
block: Slot,
attestation: Slot,
},
/// The slot is finalized, no need to import.
FinalizedSlot {
attestation: Slot,
finalized: Slot,
},
FutureEpoch {
attestation_epoch: Epoch,
current_epoch: Epoch,
},
PastEpoch {
attestation_epoch: Epoch,
current_epoch: Epoch,
},
BadTargetEpoch,
UnknownTargetRoot(Hash256),
InvalidSignature,
NoCommitteeForSlotAndIndex {
slot: Slot,
index: CommitteeIndex,
},
Invalid(AttestationValidationError),
}
/// Defines how a `BeaconState` should be "skipped" through skip-slots.
pub enum StateSkipConfig {
/// Calculate the state root during each skip slot, producing a fully-valid `BeaconState`.
WithStateRoots,
/// Don't calculate the state root at each slot, instead just use the zero hash. This is orders
/// of magnitude faster, however it produces a partially invalid state.
///
/// This state is useful for operations that don't use the state roots; e.g., for calculating
/// the shuffling.
WithoutStateRoots,
}
#[derive(Debug, PartialEq)]
pub struct HeadInfo {
pub slot: Slot,
pub block_root: Hash256,
pub state_root: Hash256,
pub current_justified_checkpoint: types::Checkpoint,
pub finalized_checkpoint: types::Checkpoint,
pub fork: Fork,
pub genesis_time: u64,
pub genesis_validators_root: Hash256,
}
pub trait BeaconChainTypes: Send + Sync + 'static {
type Store: store::Store<Self::EthSpec>;
type StoreMigrator: Migrate<Self::Store, Self::EthSpec>;
type SlotClock: slot_clock::SlotClock;
type Eth1Chain: Eth1ChainBackend<Self::EthSpec, Self::Store>;
type EthSpec: types::EthSpec;
type EventHandler: EventHandler<Self::EthSpec>;
}
/// Represents the "Beacon Chain" component of Ethereum 2.0. Allows import of blocks and block
/// operations and chooses a canonical head.
pub struct BeaconChain<T: BeaconChainTypes> {
pub spec: ChainSpec,
/// Persistent storage for blocks, states, etc. Typically an on-disk store, such as LevelDB.
pub store: Arc<T::Store>,
/// Database migrator for running background maintenance on the store.
pub store_migrator: T::StoreMigrator,
/// Reports the current slot, typically based upon the system clock.
pub slot_clock: T::SlotClock,
/// Stores all operations (e.g., `Attestation`, `Deposit`, etc) that are candidates for
/// inclusion in a block.
pub op_pool: OperationPool<T::EthSpec>,
/// A pool of attestations dedicated to the "naive aggregation strategy" defined in the eth2
/// specs.
///
/// This pool accepts `Attestation` objects that only have one aggregation bit set and provides
/// a method to get an aggregated `Attestation` for some `AttestationData`.
pub naive_aggregation_pool: NaiveAggregationPool<T::EthSpec>,
/// Contains a store of attestations which have been observed by the beacon chain.
pub observed_attestations: ObservedAttestations<T::EthSpec>,
/// Maintains a record of which validators have been seen to attest in recent epochs.
pub observed_attesters: ObservedAttesters<T::EthSpec>,
/// Maintains a record of which validators have been seen to create `SignedAggregateAndProofs`
/// in recent epochs.
pub observed_aggregators: ObservedAggregators<T::EthSpec>,
/// Maintains a record of which validators have proposed blocks for each slot.
pub observed_block_producers: ObservedBlockProducers<T::EthSpec>,
/// Provides information from the Ethereum 1 (PoW) chain.
pub eth1_chain: Option<Eth1Chain<T::Eth1Chain, T::EthSpec, T::Store>>,
/// Stores a "snapshot" of the chain at the time the head-of-the-chain block was received.
pub(crate) canonical_head: TimeoutRwLock<BeaconSnapshot<T::EthSpec>>,
/// The root of the genesis block.
pub genesis_block_root: Hash256,
/// The root of the list of genesis validators, used during syncing.
pub genesis_validators_root: Hash256,
/// A state-machine that is updated with information from the network and chooses a canonical
/// head block.
pub fork_choice: ForkChoice<T>,
/// A handler for events generated by the beacon chain.
pub event_handler: T::EventHandler,
/// Used to track the heads of the beacon chain.
pub(crate) head_tracker: Arc<HeadTracker>,
/// A cache dedicated to block processing.
pub(crate) snapshot_cache: TimeoutRwLock<SnapshotCache<T::EthSpec>>,
/// Caches the shuffling for a given epoch and state root.
pub(crate) shuffling_cache: TimeoutRwLock<ShufflingCache>,
/// Caches a map of `validator_index -> validator_pubkey`.
pub(crate) validator_pubkey_cache: TimeoutRwLock<ValidatorPubkeyCache>,
/// A list of any hard-coded forks that have been disabled.
pub disabled_forks: Vec<String>,
/// Logging to CLI, etc.
pub(crate) log: Logger,
}
type BeaconBlockAndState<T> = (BeaconBlock<T>, BeaconState<T>);
impl<T: BeaconChainTypes> BeaconChain<T> {
/// Persists the core `BeaconChain` components (including the head block) and the fork choice.
///
/// ## Notes:
///
/// In this function we first obtain the head, persist fork choice, then persist the head. We
/// do it in this order to ensure that the persisted head is always from a time prior to fork
/// choice.
///
/// We want to ensure that the head never out dates the fork choice to avoid having references
/// to blocks that do not exist in fork choice.
pub fn persist_head_and_fork_choice(&self) -> Result<(), Error> {
let canonical_head_block_root = self
.canonical_head
.try_read_for(HEAD_LOCK_TIMEOUT)
.ok_or_else(|| Error::CanonicalHeadLockTimeout)?
.beacon_block_root;
let persisted_head = PersistedBeaconChain {
canonical_head_block_root,
genesis_block_root: self.genesis_block_root,
ssz_head_tracker: self.head_tracker.to_ssz_container(),
};
let fork_choice_timer = metrics::start_timer(&metrics::PERSIST_FORK_CHOICE);
self.store.put(
&Hash256::from_slice(&FORK_CHOICE_DB_KEY),
&self.fork_choice.as_ssz_container(),
)?;
metrics::stop_timer(fork_choice_timer);
let head_timer = metrics::start_timer(&metrics::PERSIST_HEAD);
self.store
.put(&Hash256::from_slice(&BEACON_CHAIN_DB_KEY), &persisted_head)?;
metrics::stop_timer(head_timer);
Ok(())
}
/// Persists `self.op_pool` to disk.
///
/// ## Notes
///
/// This operation is typically slow and causes a lot of allocations. It should be used
/// sparingly.
pub fn persist_op_pool(&self) -> Result<(), Error> {
let timer = metrics::start_timer(&metrics::PERSIST_OP_POOL);
self.store.put(
&Hash256::from_slice(&OP_POOL_DB_KEY),
&PersistedOperationPool::from_operation_pool(&self.op_pool),
)?;
metrics::stop_timer(timer);
Ok(())
}
/// Persists `self.eth1_chain` and its caches to disk.
pub fn persist_eth1_cache(&self) -> Result<(), Error> {
let timer = metrics::start_timer(&metrics::PERSIST_OP_POOL);
if let Some(eth1_chain) = self.eth1_chain.as_ref() {
self.store.put(
&Hash256::from_slice(&ETH1_CACHE_DB_KEY),
&eth1_chain.as_ssz_container(),
)?;
}
metrics::stop_timer(timer);
Ok(())
}
/// Returns the slot _right now_ according to `self.slot_clock`. Returns `Err` if the slot is
/// unavailable.
///
/// The slot might be unavailable due to an error with the system clock, or if the present time
/// is before genesis (i.e., a negative slot).
pub fn slot(&self) -> Result<Slot, Error> {
self.slot_clock.now().ok_or_else(|| Error::UnableToReadSlot)
}
/// Returns the epoch _right now_ according to `self.slot_clock`. Returns `Err` if the epoch is
/// unavailable.
///
/// The epoch might be unavailable due to an error with the system clock, or if the present time
/// is before genesis (i.e., a negative epoch).
pub fn epoch(&self) -> Result<Epoch, Error> {
self.slot()
.map(|slot| slot.epoch(T::EthSpec::slots_per_epoch()))
}
/// Iterates across all `(block_root, slot)` pairs from the head of the chain (inclusive) to
/// the earliest reachable ancestor (may or may not be genesis).
///
/// ## Notes
///
/// `slot` always decreases by `1`.
/// - Skipped slots contain the root of the closest prior
/// non-skipped slot (identical to the way they are stored in `state.block_roots`) .
/// - Iterator returns `(Hash256, Slot)`.
/// - As this iterator starts at the `head` of the chain (viz., the best block), the first slot
/// returned may be earlier than the wall-clock slot.
pub fn rev_iter_block_roots(
&self,
) -> Result<ReverseBlockRootIterator<T::EthSpec, T::Store>, Error> {
let head = self.head()?;
let iter = BlockRootsIterator::owned(self.store.clone(), head.beacon_state);
Ok(ReverseBlockRootIterator::new(
(head.beacon_block_root, head.beacon_block.slot()),
iter,
))
}
pub fn forwards_iter_block_roots(
&self,
start_slot: Slot,
) -> Result<<T::Store as Store<T::EthSpec>>::ForwardsBlockRootsIterator, Error> {
let local_head = self.head()?;
Ok(T::Store::forwards_block_roots_iterator(
self.store.clone(),
start_slot,
local_head.beacon_state,
local_head.beacon_block_root,
&self.spec,
))
}
/// Traverse backwards from `block_root` to find the block roots of its ancestors.
///
/// ## Notes
///
/// `slot` always decreases by `1`.
/// - Skipped slots contain the root of the closest prior
/// non-skipped slot (identical to the way they are stored in `state.block_roots`) .
/// - Iterator returns `(Hash256, Slot)`.
/// - The provided `block_root` is included as the first item in the iterator.
pub fn rev_iter_block_roots_from(
&self,
block_root: Hash256,
) -> Result<ReverseBlockRootIterator<T::EthSpec, T::Store>, Error> {
let block = self
.get_block(&block_root)?
.ok_or_else(|| Error::MissingBeaconBlock(block_root))?;
let state = self
.get_state(&block.state_root(), Some(block.slot()))?
.ok_or_else(|| Error::MissingBeaconState(block.state_root()))?;
let iter = BlockRootsIterator::owned(self.store.clone(), state);
Ok(ReverseBlockRootIterator::new(
(block_root, block.slot()),
iter,
))
}
/// Traverse backwards from `block_root` to find the root of the ancestor block at `slot`.
pub fn get_ancestor_block_root(
&self,
block_root: Hash256,
slot: Slot,
) -> Result<Option<Hash256>, Error> {
Ok(self
.rev_iter_block_roots_from(block_root)?
.find(|(_, ancestor_slot)| *ancestor_slot == slot)
.map(|(ancestor_block_root, _)| ancestor_block_root))
}
/// Iterates across all `(state_root, slot)` pairs from the head of the chain (inclusive) to
/// the earliest reachable ancestor (may or may not be genesis).
///
/// ## Notes
///
/// `slot` always decreases by `1`.
/// - Iterator returns `(Hash256, Slot)`.
/// - As this iterator starts at the `head` of the chain (viz., the best block), the first slot
/// returned may be earlier than the wall-clock slot.
pub fn rev_iter_state_roots(
&self,
) -> Result<ReverseStateRootIterator<T::EthSpec, T::Store>, Error> {
let head = self.head()?;
let slot = head.beacon_state.slot;
let iter = StateRootsIterator::owned(self.store.clone(), head.beacon_state);
Ok(ReverseStateRootIterator::new(
(head.beacon_state_root, slot),
iter,
))
}
/// Returns the block at the given slot, if any. Only returns blocks in the canonical chain.
///
/// ## Errors
///
/// May return a database error.
pub fn block_at_slot(
&self,
slot: Slot,
) -> Result<Option<SignedBeaconBlock<T::EthSpec>>, Error> {
let root = self
.rev_iter_block_roots()?
.find(|(_, this_slot)| *this_slot == slot)
.map(|(root, _)| root);
if let Some(block_root) = root {
Ok(self.store.get(&block_root)?)
} else {
Ok(None)
}
}
/// Returns the block at the given root, if any.
///
/// ## Errors
///
/// May return a database error.
pub fn get_block(
&self,
block_root: &Hash256,
) -> Result<Option<SignedBeaconBlock<T::EthSpec>>, Error> {
Ok(self.store.get_block(block_root)?)
}
/// Returns the state at the given root, if any.
///
/// ## Errors
///
/// May return a database error.
pub fn get_state(
&self,
state_root: &Hash256,
slot: Option<Slot>,
) -> Result<Option<BeaconState<T::EthSpec>>, Error> {
Ok(self.store.get_state(state_root, slot)?)
}
/// Returns a `Checkpoint` representing the head block and state. Contains the "best block";
/// the head of the canonical `BeaconChain`.
///
/// It is important to note that the `beacon_state` returned may not match the present slot. It
/// is the state as it was when the head block was received, which could be some slots prior to
/// now.
pub fn head(&self) -> Result<BeaconSnapshot<T::EthSpec>, Error> {
self.canonical_head
.try_read_for(HEAD_LOCK_TIMEOUT)
.ok_or_else(|| Error::CanonicalHeadLockTimeout)
.map(|v| v.clone_with_only_committee_caches())
}
/// Returns info representing the head block and state.
///
/// A summarized version of `Self::head` that involves less cloning.
pub fn head_info(&self) -> Result<HeadInfo, Error> {
let head = self
.canonical_head
.try_read_for(HEAD_LOCK_TIMEOUT)
.ok_or_else(|| Error::CanonicalHeadLockTimeout)?;
Ok(HeadInfo {
slot: head.beacon_block.slot(),
block_root: head.beacon_block_root,
state_root: head.beacon_state_root,
current_justified_checkpoint: head.beacon_state.current_justified_checkpoint.clone(),
finalized_checkpoint: head.beacon_state.finalized_checkpoint.clone(),
fork: head.beacon_state.fork.clone(),
genesis_time: head.beacon_state.genesis_time,
genesis_validators_root: head.beacon_state.genesis_validators_root,
})
}
/// Returns the current heads of the `BeaconChain`. For the canonical head, see `Self::head`.
///
/// Returns `(block_root, block_slot)`.
pub fn heads(&self) -> Vec<(Hash256, Slot)> {
self.head_tracker.heads()
}
pub fn knows_head(&self, block_hash: &SignedBeaconBlockHash) -> bool {
self.head_tracker.contains_head((*block_hash).into())
}
/// Returns the `BeaconState` at the given slot.
///
/// Returns `None` when the state is not found in the database or there is an error skipping
/// to a future state.
pub fn state_at_slot(
&self,
slot: Slot,
config: StateSkipConfig,
) -> Result<BeaconState<T::EthSpec>, Error> {
let head_state = self.head()?.beacon_state;
match slot.cmp(&head_state.slot) {
Ordering::Equal => Ok(head_state),
Ordering::Greater => {
if slot > head_state.slot + T::EthSpec::slots_per_epoch() {
warn!(
self.log,
"Skipping more than an epoch";
"head_slot" => head_state.slot,
"request_slot" => slot
)
}
let start_slot = head_state.slot;
let task_start = Instant::now();
let max_task_runtime = Duration::from_millis(self.spec.milliseconds_per_slot);
let head_state_slot = head_state.slot;
let mut state = head_state;
let skip_state_root = match config {
StateSkipConfig::WithStateRoots => None,
StateSkipConfig::WithoutStateRoots => Some(Hash256::zero()),
};
while state.slot < slot {
// Do not allow and forward state skip that takes longer than the maximum task duration.
//
// This is a protection against nodes doing too much work when they're not synced
// to a chain.
if task_start + max_task_runtime < Instant::now() {
return Err(Error::StateSkipTooLarge {
start_slot,
requested_slot: slot,
max_task_runtime,
});
}
// Note: supplying some `state_root` when it is known would be a cheap and easy
// optimization.
match per_slot_processing(&mut state, skip_state_root, &self.spec) {
Ok(_) => (),
Err(e) => {
warn!(
self.log,
"Unable to load state at slot";
"error" => format!("{:?}", e),
"head_slot" => head_state_slot,
"requested_slot" => slot
);
return Err(Error::NoStateForSlot(slot));
}
};
}
Ok(state)
}
Ordering::Less => {
let state_root = self
.rev_iter_state_roots()?
.take_while(|(_root, current_slot)| *current_slot >= slot)
.find(|(_root, current_slot)| *current_slot == slot)
.map(|(root, _slot)| root)
.ok_or_else(|| Error::NoStateForSlot(slot))?;
Ok(self
.get_state(&state_root, Some(slot))?
.ok_or_else(|| Error::NoStateForSlot(slot))?)
}
}
}
/// Returns the `BeaconState` the current slot (viz., `self.slot()`).
///
/// - A reference to the head state (note: this keeps a read lock on the head, try to use
/// sparingly).
/// - The head state, but with skipped slots (for states later than the head).
///
/// Returns `None` when there is an error skipping to a future state or the slot clock cannot
/// be read.
pub fn wall_clock_state(&self) -> Result<BeaconState<T::EthSpec>, Error> {
self.state_at_slot(self.slot()?, StateSkipConfig::WithStateRoots)
}
/// Returns the slot of the highest block in the canonical chain.
pub fn best_slot(&self) -> Result<Slot, Error> {
self.canonical_head
.try_read_for(HEAD_LOCK_TIMEOUT)
.map(|head| head.beacon_block.slot())
.ok_or_else(|| Error::CanonicalHeadLockTimeout)
}
/// Returns the validator index (if any) for the given public key.
///
/// ## Notes
///
/// This query uses the `validator_pubkey_cache` which contains _all_ validators ever seen,
/// even if those validators aren't included in the head state. It is important to remember
/// that just because a validator exists here, it doesn't necessarily exist in all
/// `BeaconStates`.
///
/// ## Errors
///
/// May return an error if acquiring a read-lock on the `validator_pubkey_cache` times out.
pub fn validator_index(&self, pubkey: &PublicKeyBytes) -> Result<Option<usize>, Error> {
let pubkey_cache = self
.validator_pubkey_cache
.try_read_for(VALIDATOR_PUBKEY_CACHE_LOCK_TIMEOUT)
.ok_or_else(|| Error::ValidatorPubkeyCacheLockTimeout)?;
Ok(pubkey_cache.get_index(pubkey))
}
/// Returns the validator pubkey (if any) for the given validator index.
///
/// ## Notes
///
/// This query uses the `validator_pubkey_cache` which contains _all_ validators ever seen,
/// even if those validators aren't included in the head state. It is important to remember
/// that just because a validator exists here, it doesn't necessarily exist in all
/// `BeaconStates`.
///
/// ## Errors
///
/// May return an error if acquiring a read-lock on the `validator_pubkey_cache` times out.
pub fn validator_pubkey(&self, validator_index: usize) -> Result<Option<PublicKey>, Error> {
let pubkey_cache = self
.validator_pubkey_cache
.try_read_for(VALIDATOR_PUBKEY_CACHE_LOCK_TIMEOUT)
.ok_or_else(|| Error::ValidatorPubkeyCacheLockTimeout)?;
Ok(pubkey_cache.get(validator_index).cloned())
}
/// Returns the block canonical root of the current canonical chain at a given slot.
///
/// Returns None if a block doesn't exist at the slot.
pub fn root_at_slot(&self, target_slot: Slot) -> Result<Option<Hash256>, Error> {
Ok(self
.rev_iter_block_roots()?
.find(|(_root, slot)| *slot == target_slot)
.map(|(root, _slot)| root))
}
/// Returns the block proposer for a given slot.
///
/// Information is read from the present `beacon_state` shuffling, only information from the
/// present epoch is available.
pub fn block_proposer(&self, slot: Slot) -> Result<usize, Error> {
let epoch = |slot: Slot| slot.epoch(T::EthSpec::slots_per_epoch());
let head_state = &self.head()?.beacon_state;
let mut state = if epoch(slot) == epoch(head_state.slot) {
self.head()?.beacon_state
} else {
// The block proposer shuffling is not affected by the state roots, so we don't need to
// calculate them.
self.state_at_slot(slot, StateSkipConfig::WithoutStateRoots)?
};
state.build_committee_cache(RelativeEpoch::Current, &self.spec)?;
if epoch(state.slot) != epoch(slot) {
return Err(Error::InvariantViolated(format!(
"Epochs in consistent in proposer lookup: state: {}, requested: {}",
epoch(state.slot),
epoch(slot)
)));
}
state
.get_beacon_proposer_index(slot, &self.spec)
.map_err(Into::into)
}
/// Returns the attestation slot and committee index for a given validator index.
///
/// Information is read from the current state, so only information from the present and prior
/// epoch is available.
pub fn validator_attestation_slot_and_index(
&self,
validator_index: usize,
epoch: Epoch,
) -> Result<Option<(Slot, u64)>, Error> {
let as_epoch = |slot: Slot| slot.epoch(T::EthSpec::slots_per_epoch());
let head_state = &self.head()?.beacon_state;
let mut state = if epoch == as_epoch(head_state.slot) {
self.head()?.beacon_state
} else {
// The block proposer shuffling is not affected by the state roots, so we don't need to
// calculate them.
self.state_at_slot(
epoch.start_slot(T::EthSpec::slots_per_epoch()),
StateSkipConfig::WithoutStateRoots,
)?
};
state.build_committee_cache(RelativeEpoch::Current, &self.spec)?;
if as_epoch(state.slot) != epoch {
return Err(Error::InvariantViolated(format!(
"Epochs in consistent in attestation duties lookup: state: {}, requested: {}",
as_epoch(state.slot),
epoch
)));
}
if let Some(attestation_duty) =
state.get_attestation_duties(validator_index, RelativeEpoch::Current)?
{
Ok(Some((attestation_duty.slot, attestation_duty.index)))
} else {
Ok(None)
}
}
/// Returns an aggregated `Attestation`, if any, that has a matching `attestation.data`.
///
/// The attestation will be obtained from `self.naive_aggregation_pool`.
pub fn get_aggregated_attestation(
&self,
data: &AttestationData,
) -> Result<Option<Attestation<T::EthSpec>>, Error> {
self.naive_aggregation_pool.get(data).map_err(Into::into)
}
/// Produce an unaggregated `Attestation` that is valid for the given `slot` and `index`.
///
/// The produced `Attestation` will not be valid until it has been signed by exactly one
/// validator that is in the committee for `slot` and `index` in the canonical chain.
///
/// Always attests to the canonical chain.
pub fn produce_unaggregated_attestation(
&self,
slot: Slot,
index: CommitteeIndex,
) -> Result<Attestation<T::EthSpec>, Error> {
// Note: we're taking a lock on the head. The work involved here should be trivial enough
// that the lock should not be held for long.
let head = self
.canonical_head
.try_read_for(HEAD_LOCK_TIMEOUT)
.ok_or_else(|| Error::CanonicalHeadLockTimeout)?;
if slot >= head.beacon_block.slot() {
self.produce_unaggregated_attestation_for_block(
slot,
index,
head.beacon_block_root,
Cow::Borrowed(&head.beacon_state),
)
} else {
// Note: this method will fail if `slot` is more than `state.block_roots.len()` slots
// prior to the head.
//
// This seems reasonable, producing an attestation at a slot so far
// in the past seems useless, definitely in mainnet spec. In minimal spec, when the
// block roots only contain two epochs of history, it's possible that you will fail to
// produce an attestation that would be valid to be included in a block. Given that
// minimal is only for testing, I think this is fine.
//
// It is important to note that what's _not_ allowed here is attesting to a slot in the
// past. You can still attest to a block an arbitrary distance in the past, just not as
// if you are in a slot in the past.
let beacon_block_root = *head.beacon_state.get_block_root(slot)?;
let state_root = *head.beacon_state.get_state_root(slot)?;
// Avoid holding a lock on the head whilst doing database reads. Good boi functions
// don't hog locks.
drop(head);
let mut state = self
.get_state(&state_root, Some(slot))?
.ok_or_else(|| Error::MissingBeaconState(state_root))?;
state.build_committee_cache(RelativeEpoch::Current, &self.spec)?;
self.produce_unaggregated_attestation_for_block(
slot,
index,
beacon_block_root,
Cow::Owned(state),
)
}
}
/// Produces an "unaggregated" attestation for the given `slot` and `index` that attests to
/// `beacon_block_root`. The provided `state` should match the `block.state_root` for the
/// `block` identified by `beacon_block_root`.
///
/// The attestation doesn't _really_ have anything about it that makes it unaggregated per say,
/// however this function is only required in the context of forming an unaggregated
/// attestation. It would be an (undetectable) violation of the protocol to create a
/// `SignedAggregateAndProof` based upon the output of this function.
pub fn produce_unaggregated_attestation_for_block(
&self,
slot: Slot,
index: CommitteeIndex,
beacon_block_root: Hash256,
mut state: Cow<BeaconState<T::EthSpec>>,
) -> Result<Attestation<T::EthSpec>, Error> {
let epoch = slot.epoch(T::EthSpec::slots_per_epoch());
if state.slot > slot {
return Err(Error::CannotAttestToFutureState);
} else if state.current_epoch() + 1 < epoch {
let mut_state = state.to_mut();
while mut_state.current_epoch() + 1 < epoch {
// Note: here we provide `Hash256::zero()` as the root of the current state. This
// has the effect of setting the values of all historic state roots to the zero
// hash. This is an optimization, we don't need the state roots so why calculate
// them?
per_slot_processing(mut_state, Some(Hash256::zero()), &self.spec)?;
}
mut_state.build_committee_cache(RelativeEpoch::Next, &self.spec)?;
}
let committee_len = state.get_beacon_committee(slot, index)?.committee.len();
let target_slot = epoch.start_slot(T::EthSpec::slots_per_epoch());
let target_root = if state.slot <= target_slot {
beacon_block_root
} else {
*state.get_block_root(target_slot)?
};
Ok(Attestation {
aggregation_bits: BitList::with_capacity(committee_len)?,
data: AttestationData {
slot,
index,
beacon_block_root: beacon_block_root,
source: state.current_justified_checkpoint.clone(),
target: Checkpoint {
epoch,
root: target_root,
},
},
signature: AggregateSignature::empty_signature(),
})
}
/// Accepts some `Attestation` from the network and attempts to verify it, returning `Ok(_)` if
/// it is valid to be (re)broadcast on the gossip network.
///
/// The attestation must be "unaggregated", that is it must have exactly one
/// aggregation bit set.
pub fn verify_unaggregated_attestation_for_gossip(
&self,
attestation: Attestation<T::EthSpec>,
) -> Result<VerifiedUnaggregatedAttestation<T>, AttestationError> {
metrics::inc_counter(&metrics::UNAGGREGATED_ATTESTATION_PROCESSING_REQUESTS);
let _timer =
metrics::start_timer(&metrics::UNAGGREGATED_ATTESTATION_GOSSIP_VERIFICATION_TIMES);
VerifiedUnaggregatedAttestation::verify(attestation, self).map(|v| {
metrics::inc_counter(&metrics::UNAGGREGATED_ATTESTATION_PROCESSING_SUCCESSES);
v
})
}
/// Accepts some `SignedAggregateAndProof` from the network and attempts to verify it,
/// returning `Ok(_)` if it is valid to be (re)broadcast on the gossip network.
pub fn verify_aggregated_attestation_for_gossip(
&self,
signed_aggregate: SignedAggregateAndProof<T::EthSpec>,
) -> Result<VerifiedAggregatedAttestation<T>, AttestationError> {
metrics::inc_counter(&metrics::AGGREGATED_ATTESTATION_PROCESSING_REQUESTS);
let _timer =
metrics::start_timer(&metrics::AGGREGATED_ATTESTATION_GOSSIP_VERIFICATION_TIMES);
VerifiedAggregatedAttestation::verify(signed_aggregate, self).map(|v| {
metrics::inc_counter(&metrics::AGGREGATED_ATTESTATION_PROCESSING_SUCCESSES);
v
})
}
/// Accepts some attestation-type object and attempts to verify it in the context of fork
/// choice. If it is valid it is applied to `self.fork_choice`.
///
/// Common items that implement `IntoForkChoiceVerifiedAttestation`:
///
/// - `VerifiedUnaggregatedAttestation`
/// - `VerifiedAggregatedAttestation`
/// - `ForkChoiceVerifiedAttestation`
pub fn apply_attestation_to_fork_choice<'a>(
&self,
unverified_attestation: &'a impl IntoForkChoiceVerifiedAttestation<'a, T>,
) -> Result<ForkChoiceVerifiedAttestation<'a, T>, AttestationError> {
let _timer = metrics::start_timer(&metrics::ATTESTATION_PROCESSING_APPLY_TO_FORK_CHOICE);
let verified = unverified_attestation.into_fork_choice_verified_attestation(self)?;
let indexed_attestation = verified.indexed_attestation();
self.fork_choice
.process_indexed_attestation(indexed_attestation)
.map_err(|e| Error::from(e))?;
Ok(verified)
}
/// Accepts an `VerifiedUnaggregatedAttestation` and attempts to apply it to the "naive
/// aggregation pool".
///
/// The naive aggregation pool is used by local validators to produce
/// `SignedAggregateAndProof`.
///
/// If the attestation is too old (low slot) to be included in the pool it is simply dropped
/// and no error is returned.
pub fn add_to_naive_aggregation_pool(
&self,
unaggregated_attestation: VerifiedUnaggregatedAttestation<T>,
) -> Result<VerifiedUnaggregatedAttestation<T>, AttestationError> {
let _timer = metrics::start_timer(&metrics::ATTESTATION_PROCESSING_APPLY_TO_AGG_POOL);
let attestation = unaggregated_attestation.attestation();
match self.naive_aggregation_pool.insert(attestation) {
Ok(outcome) => trace!(
self.log,
"Stored unaggregated attestation";
"outcome" => format!("{:?}", outcome),
"index" => attestation.data.index,
"slot" => attestation.data.slot.as_u64(),
),
Err(NaiveAggregationError::SlotTooLow {
slot,
lowest_permissible_slot,
}) => {
trace!(
self.log,
"Refused to store unaggregated attestation";
"lowest_permissible_slot" => lowest_permissible_slot.as_u64(),
"slot" => slot.as_u64(),
);
}
Err(e) => {
error!(
self.log,
"Failed to store unaggregated attestation";
"error" => format!("{:?}", e),
"index" => attestation.data.index,
"slot" => attestation.data.slot.as_u64(),
);
return Err(Error::from(e).into());
}
};
Ok(unaggregated_attestation)
}
/// Accepts a `VerifiedAggregatedAttestation` and attempts to apply it to `self.op_pool`.
///
/// The op pool is used by local block producers to pack blocks with operations.
pub fn add_to_block_inclusion_pool(
&self,
signed_aggregate: VerifiedAggregatedAttestation<T>,
) -> Result<VerifiedAggregatedAttestation<T>, AttestationError> {
let _timer = metrics::start_timer(&metrics::ATTESTATION_PROCESSING_APPLY_TO_OP_POOL);
// If there's no eth1 chain then it's impossible to produce blocks and therefore
// useless to put things in the op pool.
if self.eth1_chain.is_some() {
let fork = self
.canonical_head
.try_read_for(HEAD_LOCK_TIMEOUT)
.ok_or_else(|| Error::CanonicalHeadLockTimeout)?
.beacon_state
.fork
.clone();
self.op_pool
.insert_attestation(
// TODO: address this clone.
signed_aggregate.attestation().clone(),
&fork,
self.genesis_validators_root,
&self.spec,
)
.map_err(Error::from)?;
}
Ok(signed_aggregate)
}
/// Check that the shuffling at `block_root` is equal to one of the shufflings of `state`.
///
/// The `target_epoch` argument determines which shuffling to check compatibility with, it
/// should be equal to the current or previous epoch of `state`, or else `false` will be
/// returned.
///
/// The compatibility check is designed to be fast: we check that the block that
/// determined the RANDAO mix for the `target_epoch` matches the ancestor of the block
/// identified by `block_root` (at that slot).
pub fn shuffling_is_compatible(
&self,
block_root: &Hash256,
target_epoch: Epoch,
state: &BeaconState<T::EthSpec>,
) -> bool {
let slots_per_epoch = T::EthSpec::slots_per_epoch();
let shuffling_lookahead = 1 + self.spec.min_seed_lookahead.as_u64();
// Shuffling can't have changed if we're in the first few epochs
if state.current_epoch() < shuffling_lookahead {
return true;
}
// Otherwise the shuffling is determined by the block at the end of the target epoch
// minus the shuffling lookahead (usually 2). We call this the "pivot".
let pivot_slot =
if target_epoch == state.previous_epoch() || target_epoch == state.current_epoch() {
(target_epoch - shuffling_lookahead).end_slot(slots_per_epoch)
} else {
return false;
};
let state_pivot_block_root = match state.get_block_root(pivot_slot) {
Ok(root) => *root,
Err(e) => {
warn!(
&self.log,
"Missing pivot block root for attestation";
"slot" => pivot_slot,
"error" => format!("{:?}", e),
);
return false;
}
};
// Use fork choice's view of the block DAG to quickly evaluate whether the attestation's
// pivot block is the same as the current state's pivot block. If it is, then the
// attestation's shuffling is the same as the current state's.
// To account for skipped slots, find the first block at *or before* the pivot slot.
let fork_choice_lock = self.fork_choice.core_proto_array();
let pivot_block_root = fork_choice_lock
.iter_block_roots(block_root)
.find(|(_, slot)| *slot <= pivot_slot)
.map(|(block_root, _)| block_root);
drop(fork_choice_lock);
match pivot_block_root {
Some(root) => root == state_pivot_block_root,
None => {
debug!(
&self.log,
"Discarding attestation because of missing ancestor";
"pivot_slot" => pivot_slot.as_u64(),
"block_root" => format!("{:?}", block_root),
);
false
}
}
}
/// Accept some exit and queue it for inclusion in an appropriate block.
pub fn process_voluntary_exit(
&self,
exit: SignedVoluntaryExit,
) -> Result<(), ExitValidationError> {
match self.wall_clock_state() {
Ok(state) => {
if self.eth1_chain.is_some() {
self.op_pool.insert_voluntary_exit(exit, &state, &self.spec)
} else {
Ok(())
}
}
Err(e) => {
error!(
&self.log,
"Unable to process voluntary exit";
"error" => format!("{:?}", e),
"reason" => "no state"
);
Ok(())
}
}
}
/// Accept some proposer slashing and queue it for inclusion in an appropriate block.
pub fn process_proposer_slashing(
&self,
proposer_slashing: ProposerSlashing,
) -> Result<(), ProposerSlashingValidationError> {
match self.wall_clock_state() {
Ok(state) => {
if self.eth1_chain.is_some() {
self.op_pool
.insert_proposer_slashing(proposer_slashing, &state, &self.spec)
} else {
Ok(())
}
}
Err(e) => {
error!(
&self.log,
"Unable to process proposer slashing";
"error" => format!("{:?}", e),
"reason" => "no state"
);
Ok(())
}
}
}
/// Accept some attester slashing and queue it for inclusion in an appropriate block.
pub fn process_attester_slashing(
&self,
attester_slashing: AttesterSlashing<T::EthSpec>,
) -> Result<(), AttesterSlashingValidationError> {
match self.wall_clock_state() {
Ok(state) => {
if self.eth1_chain.is_some() {
self.op_pool
.insert_attester_slashing(attester_slashing, &state, &self.spec)
} else {
Ok(())
}
}
Err(e) => {
error!(
&self.log,
"Unable to process attester slashing";
"error" => format!("{:?}", e),
"reason" => "no state"
);
Ok(())
}
}
}
/// Attempt to verify and import a chain of blocks to `self`.
///
/// The provided blocks _must_ each reference the previous block via `block.parent_root` (i.e.,
/// be a chain). An error will be returned if this is not the case.
///
/// This operation is not atomic; if one of the blocks in the chain is invalid then some prior
/// blocks might be imported.
///
/// This method is generally much more efficient than importing each block using
/// `Self::process_block`.
pub fn process_chain_segment(
&self,
chain_segment: Vec<SignedBeaconBlock<T::EthSpec>>,
) -> ChainSegmentResult {
let mut filtered_chain_segment = Vec::with_capacity(chain_segment.len());
let mut imported_blocks = 0;
// Produce a list of the parent root and slot of the child of each block.
//
// E.g., `children[0] == (chain_segment[1].parent_root(), chain_segment[1].slot())`
let children = chain_segment
.iter()
.skip(1)
.map(|block| (block.parent_root(), block.slot()))
.collect::<Vec<_>>();
for (i, block) in chain_segment.into_iter().enumerate() {
let block_root = get_block_root(&block);
if let Some((child_parent_root, child_slot)) = children.get(i) {
// If this block has a child in this chain segment, ensure that its parent root matches
// the root of this block.
//
// Without this check it would be possible to have a block verified using the
// incorrect shuffling. That would be bad, mmkay.
if block_root != *child_parent_root {
return ChainSegmentResult::Failed {
imported_blocks,
error: BlockError::NonLinearParentRoots,
};
}
// Ensure that the slots are strictly increasing throughout the chain segment.
if *child_slot <= block.slot() {
return ChainSegmentResult::Failed {
imported_blocks,
error: BlockError::NonLinearSlots,
};
}
}
match check_block_relevancy(&block, Some(block_root), self) {
// If the block is relevant, add it to the filtered chain segment.
Ok(_) => filtered_chain_segment.push((block_root, block)),
// If the block is already known, simply ignore this block.
Err(BlockError::BlockIsAlreadyKnown) => continue,
// If the block is the genesis block, simply ignore this block.
Err(BlockError::GenesisBlock) => continue,
// If the block is is for a finalized slot, simply ignore this block.
//
// The block is either:
//
// 1. In the canonical finalized chain.
// 2. In some non-canonical chain at a slot that has been finalized already.
//
// In the case of (1), there's no need to re-import and later blocks in this
// segement might be useful.
//
// In the case of (2), skipping the block is valid since we should never import it.
// However, we will potentially get a `ParentUnknown` on a later block. The sync
// protocol will need to ensure this is handled gracefully.
Err(BlockError::WouldRevertFinalizedSlot { .. }) => continue,
// If there was an error whilst determining if the block was invalid, return that
// error.
Err(BlockError::BeaconChainError(e)) => {
return ChainSegmentResult::Failed {
imported_blocks,
error: BlockError::BeaconChainError(e),
}
}
// If the block was decided to be irrelevant for any other reason, don't include
// this block or any of it's children in the filtered chain segment.
_ => break,
}
}
while !filtered_chain_segment.is_empty() {
// Determine the epoch of the first block in the remaining segment.
let start_epoch = filtered_chain_segment
.first()
.map(|(_root, block)| block)
.expect("chain_segment cannot be empty")
.slot()
.epoch(T::EthSpec::slots_per_epoch());
// The `last_index` indicates the position of the last block that is in the current
// epoch of `start_epoch`.
let last_index = filtered_chain_segment
.iter()
.position(|(_root, block)| {
block.slot().epoch(T::EthSpec::slots_per_epoch()) > start_epoch
})
.unwrap_or_else(|| filtered_chain_segment.len());
// Split off the first section blocks that are all either within the current epoch of
// the first block. These blocks can all be signature-verified with the same
// `BeaconState`.
let mut blocks = filtered_chain_segment.split_off(last_index);
std::mem::swap(&mut blocks, &mut filtered_chain_segment);
// Verify the signature of the blocks, returning early if the signature is invalid.
let signature_verified_blocks = match signature_verify_chain_segment(blocks, self) {
Ok(blocks) => blocks,
Err(error) => {
return ChainSegmentResult::Failed {
imported_blocks,
error,
}
}
};
// Import the blocks into the chain.
for signature_verified_block in signature_verified_blocks {
match self.process_block(signature_verified_block) {
Ok(_) => imported_blocks += 1,
Err(error) => {
return ChainSegmentResult::Failed {
imported_blocks,
error,
}
}
}
}
}
ChainSegmentResult::Successful { imported_blocks }
}
/// Returns `Ok(GossipVerifiedBlock)` if the supplied `block` should be forwarded onto the
/// gossip network. The block is not imported into the chain, it is just partially verified.
///
/// The returned `GossipVerifiedBlock` should be provided to `Self::process_block` immediately
/// after it is returned, unless some other circumstance decides it should not be imported at
/// all.
///
/// ## Errors
///
/// Returns an `Err` if the given block was invalid, or an error was encountered during
pub fn verify_block_for_gossip(
&self,
block: SignedBeaconBlock<T::EthSpec>,
) -> Result<GossipVerifiedBlock<T>, BlockError> {
let slot = block.message.slot;
let graffiti_string = String::from_utf8(block.message.body.graffiti[..].to_vec())
.unwrap_or_else(|_| format!("{:?}", &block.message.body.graffiti[..]));
match GossipVerifiedBlock::new(block, self) {
Ok(verified) => {
debug!(
self.log,
"Successfully processed gossip block";
"graffiti" => graffiti_string,
"slot" => slot,
"root" => format!("{:?}", verified.block_root()),
);
Ok(verified)
}
Err(e) => {
debug!(
self.log,
"Rejected gossip block";
"error" => format!("{:?}", e),
"graffiti" => graffiti_string,
"slot" => slot,
);
Err(e)
}
}
}
/// Returns `Ok(block_root)` if the given `unverified_block` was successfully verified and
/// imported into the chain.
///
/// Items that implement `IntoFullyVerifiedBlock` include:
///
/// - `SignedBeaconBlock`
/// - `GossipVerifiedBlock`
///
/// ## Errors
///
/// Returns an `Err` if the given block was invalid, or an error was encountered during
/// verification.
pub fn process_block<B: IntoFullyVerifiedBlock<T>>(
&self,
unverified_block: B,
) -> Result<Hash256, BlockError> {
// Start the Prometheus timer.
let full_timer = metrics::start_timer(&metrics::BLOCK_PROCESSING_TIMES);
// Increment the Prometheus counter for block processing requests.
metrics::inc_counter(&metrics::BLOCK_PROCESSING_REQUESTS);
// Clone the block so we can provide it to the event handler.
let block = unverified_block.block().clone();
// A small closure to group the verification and import errors.
let import_block = |unverified_block: B| -> Result<Hash256, BlockError> {
let fully_verified = unverified_block.into_fully_verified_block(self)?;
self.import_block(fully_verified)
};
// Verify and import the block.
let result = match import_block(unverified_block) {
// The block was successfully verified and imported. Yay.
Ok(block_root) => {
trace!(
self.log,
"Beacon block imported";
"block_root" => format!("{:?}", block_root),
"block_slot" => format!("{:?}", block.slot().as_u64()),
);
// Increment the Prometheus counter for block processing successes.
metrics::inc_counter(&metrics::BLOCK_PROCESSING_SUCCESSES);
let _ = self.event_handler.register(EventKind::BeaconBlockImported {
block_root: block_root,
block: Box::new(block),
});
Ok(block_root)
}
// There was an error whilst attempting to verify and import the block. The block might
// be partially verified or partially imported.
Err(BlockError::BeaconChainError(e)) => {
crit!(
self.log,
"Beacon block processing error";
"error" => format!("{:?}", e),
);
let _ = self.event_handler.register(EventKind::BeaconBlockRejected {
reason: format!("Internal error: {:?}", e),
block: Box::new(block),
});
Err(BlockError::BeaconChainError(e))
}
// The block failed verification.
Err(other) => {
trace!(
self.log,
"Beacon block rejected";
"reason" => format!("{:?}", other),
);
let _ = self.event_handler.register(EventKind::BeaconBlockRejected {
reason: format!("Invalid block: {:?}", other),
block: Box::new(block),
});
Err(other)
}
};
// Stop the Prometheus timer.
metrics::stop_timer(full_timer);
result
}
/// Accepts a fully-verified block and imports it into the chain without performing any
/// additional verification.
///
/// An error is returned if the block was unable to be imported. It may be partially imported
/// (i.e., this function is not atomic).
fn import_block(
&self,
fully_verified_block: FullyVerifiedBlock<T>,
) -> Result<Hash256, BlockError> {
let signed_block = fully_verified_block.block;
let block = &signed_block.message;
let block_root = fully_verified_block.block_root;
let state = fully_verified_block.state;
let parent_block = fully_verified_block.parent_block;
let intermediate_states = fully_verified_block.intermediate_states;
let attestation_observation_timer =
metrics::start_timer(&metrics::BLOCK_PROCESSING_ATTESTATION_OBSERVATION);
// Iterate through the attestations in the block and register them as an "observed
// attestation". This will stop us from propagating them on the gossip network.
for a in &block.body.attestations {
match self.observed_attestations.observe_attestation(a, None) {
// If the observation was successful or if the slot for the attestation was too
// low, continue.
//
// We ignore `SlotTooLow` since this will be very common whilst syncing.
Ok(_) | Err(AttestationObservationError::SlotTooLow { .. }) => {}
Err(e) => return Err(BlockError::BeaconChainError(e.into())),
}
}
metrics::stop_timer(attestation_observation_timer);
let fork_choice_register_timer =
metrics::start_timer(&metrics::BLOCK_PROCESSING_FORK_CHOICE_REGISTER);
// If there are new validators in this block, update our pubkey cache.
//
// We perform this _before_ adding the block to fork choice because the pubkey cache is
// used by attestation processing which will only process an attestation if the block is
// known to fork choice. This ordering ensure that the pubkey cache is always up-to-date.
self.validator_pubkey_cache
.try_write_for(VALIDATOR_PUBKEY_CACHE_LOCK_TIMEOUT)
.ok_or_else(|| Error::ValidatorPubkeyCacheLockTimeout)?
.import_new_pubkeys(&state)?;
// If the imported block is in the previous or current epochs (according to the
// wall-clock), check to see if this is the first block of the epoch. If so, add the
// committee to the shuffling cache.
if state.current_epoch() + 1 >= self.epoch()?
&& parent_block.slot().epoch(T::EthSpec::slots_per_epoch()) != state.current_epoch()
{
let mut shuffling_cache = self
.shuffling_cache
.try_write_for(ATTESTATION_CACHE_LOCK_TIMEOUT)
.ok_or_else(|| Error::AttestationCacheLockTimeout)?;
let committee_cache = state.committee_cache(RelativeEpoch::Current)?;
let epoch_start_slot = state
.current_epoch()
.start_slot(T::EthSpec::slots_per_epoch());
let target_root = if state.slot == epoch_start_slot {
block_root
} else {
*state.get_block_root(epoch_start_slot)?
};
shuffling_cache.insert(state.current_epoch(), target_root, committee_cache);
}
// Register the new block with the fork choice service.
if let Err(e) = self
.fork_choice
.process_block(self, &state, block, block_root)
{
error!(
self.log,
"Add block to fork choice failed";
"block_root" => format!("{}", block_root),
"error" => format!("{:?}", e),
)
}
metrics::stop_timer(fork_choice_register_timer);
metrics::observe(
&metrics::OPERATIONS_PER_BLOCK_ATTESTATION,
block.body.attestations.len() as f64,
);
let db_write_timer = metrics::start_timer(&metrics::BLOCK_PROCESSING_DB_WRITE);
// Store all the states between the parent block state and this block's slot before storing
// the final state.
intermediate_states.commit(&*self.store)?;
// Store the block and state.
// NOTE: we store the block *after* the state to guard against inconsistency in the event of
// a crash, as states are usually looked up from blocks, not the other way around. A better
// solution would be to use a database transaction (once our choice of database and API
// settles down).
// See: https://github.com/sigp/lighthouse/issues/692
self.store.put_state(&block.state_root, &state)?;
self.store.put_block(&block_root, signed_block.clone())?;
let parent_root = block.parent_root;
let slot = block.slot;
self.snapshot_cache
.try_write_for(BLOCK_PROCESSING_CACHE_LOCK_TIMEOUT)
.map(|mut snapshot_cache| {
snapshot_cache.insert(BeaconSnapshot {
beacon_state: state,
beacon_state_root: signed_block.state_root(),
beacon_block: signed_block,
beacon_block_root: block_root,
});
})
.unwrap_or_else(|| {
error!(
self.log,
"Failed to obtain cache write lock";
"lock" => "snapshot_cache",
"task" => "process block"
);
});
self.head_tracker
.register_block(block_root, parent_root, slot);
metrics::stop_timer(db_write_timer);
metrics::inc_counter(&metrics::BLOCK_PROCESSING_SUCCESSES);
Ok(block_root)
}
/// Produce a new block at the given `slot`.
///
/// The produced block will not be inherently valid, it must be signed by a block producer.
/// Block signing is out of the scope of this function and should be done by a separate program.
pub fn produce_block(
&self,
randao_reveal: Signature,
slot: Slot,
) -> Result<BeaconBlockAndState<T::EthSpec>, BlockProductionError> {
let state = self
.state_at_slot(slot - 1, StateSkipConfig::WithStateRoots)
.map_err(|_| BlockProductionError::UnableToProduceAtSlot(slot))?;
self.produce_block_on_state(state, slot, randao_reveal)
}
/// Produce a block for some `slot` upon the given `state`.
///
/// Typically the `self.produce_block()` function should be used, instead of calling this
/// function directly. This function is useful for purposefully creating forks or blocks at
/// non-current slots.
///
/// The given state will be advanced to the given `produce_at_slot`, then a block will be
/// produced at that slot height.
pub fn produce_block_on_state(
&self,
mut state: BeaconState<T::EthSpec>,
produce_at_slot: Slot,
randao_reveal: Signature,
) -> Result<BeaconBlockAndState<T::EthSpec>, BlockProductionError> {
metrics::inc_counter(&metrics::BLOCK_PRODUCTION_REQUESTS);
let timer = metrics::start_timer(&metrics::BLOCK_PRODUCTION_TIMES);
let eth1_chain = self
.eth1_chain
.as_ref()
.ok_or_else(|| BlockProductionError::NoEth1ChainConnection)?;
// If required, transition the new state to the present slot.
//
// Note: supplying some `state_root` when it it is known would be a cheap and easy
// optimization.
while state.slot < produce_at_slot {
per_slot_processing(&mut state, None, &self.spec)?;
}
state.build_committee_cache(RelativeEpoch::Current, &self.spec)?;
let parent_root = if state.slot > 0 {
*state
.get_block_root(state.slot - 1)
.map_err(|_| BlockProductionError::UnableToGetBlockRootFromState)?
} else {
state.latest_block_header.canonical_root()
};
let mut graffiti: [u8; 32] = [0; 32];
graffiti.copy_from_slice(GRAFFITI.as_bytes());
let (proposer_slashings, attester_slashings) =
self.op_pool.get_slashings(&state, &self.spec);
let eth1_data = eth1_chain.eth1_data_for_block_production(&state, &self.spec)?;
let deposits = eth1_chain
.deposits_for_block_inclusion(&state, &eth1_data, &self.spec)?
.into();
// Map from attestation head block root to shuffling compatibility.
// Used to memoize the `attestation_shuffling_is_compatible` function.
let mut shuffling_filter_cache = HashMap::new();
let attestation_filter = |att: &&Attestation<T::EthSpec>| -> bool {
*shuffling_filter_cache
.entry((att.data.beacon_block_root, att.data.target.epoch))
.or_insert_with(|| {
self.shuffling_is_compatible(
&att.data.beacon_block_root,
att.data.target.epoch,
&state,
)
})
};
let mut block = SignedBeaconBlock {
message: BeaconBlock {
slot: state.slot,
proposer_index: state.get_beacon_proposer_index(state.slot, &self.spec)? as u64,
parent_root,
state_root: Hash256::zero(),
body: BeaconBlockBody {
randao_reveal,
eth1_data,
graffiti,
proposer_slashings: proposer_slashings.into(),
attester_slashings: attester_slashings.into(),
attestations: self
.op_pool
.get_attestations(&state, attestation_filter, &self.spec)
.map_err(BlockProductionError::OpPoolError)?
.into(),
deposits,
voluntary_exits: self.op_pool.get_voluntary_exits(&state, &self.spec).into(),
},
},
// The block is not signed here, that is the task of a validator client.
signature: Signature::empty_signature(),
};
per_block_processing(
&mut state,
&block,
None,
BlockSignatureStrategy::NoVerification,
&self.spec,
)?;
let state_root = state.update_tree_hash_cache()?;
block.message.state_root = state_root;
metrics::inc_counter(&metrics::BLOCK_PRODUCTION_SUCCESSES);
metrics::stop_timer(timer);
trace!(
self.log,
"Produced beacon block";
"parent" => format!("{}", block.message.parent_root),
"attestations" => block.message.body.attestations.len(),
"slot" => block.message.slot
);
Ok((block.message, state))
}
/// Execute the fork choice algorithm and enthrone the result as the canonical head.
pub fn fork_choice(&self) -> Result<(), Error> {
metrics::inc_counter(&metrics::FORK_CHOICE_REQUESTS);
let overall_timer = metrics::start_timer(&metrics::FORK_CHOICE_TIMES);
let result = self.fork_choice_internal();
if result.is_err() {
metrics::inc_counter(&metrics::FORK_CHOICE_ERRORS);
}
metrics::stop_timer(overall_timer);
result
}
fn fork_choice_internal(&self) -> Result<(), Error> {
// Determine the root of the block that is the head of the chain.
let beacon_block_root = self.fork_choice.find_head(&self)?;
let current_head = self.head_info()?;
let old_finalized_root = current_head.finalized_checkpoint.root;
if beacon_block_root == current_head.block_root {
return Ok(());
}
// At this point we know that the new head block is not the same as the previous one
metrics::inc_counter(&metrics::FORK_CHOICE_CHANGED_HEAD);
// Try and obtain the snapshot for `beacon_block_root` from the snapshot cache, falling
// back to a database read if that fails.
let new_head = self
.snapshot_cache
.try_read_for(BLOCK_PROCESSING_CACHE_LOCK_TIMEOUT)
.and_then(|snapshot_cache| snapshot_cache.get_cloned(beacon_block_root))
.map::<Result<_, Error>, _>(|snapshot| Ok(snapshot))
.unwrap_or_else(|| {
let beacon_block = self
.get_block(&beacon_block_root)?
.ok_or_else(|| Error::MissingBeaconBlock(beacon_block_root))?;
let beacon_state_root = beacon_block.state_root();
let beacon_state: BeaconState<T::EthSpec> = self
.get_state(&beacon_state_root, Some(beacon_block.slot()))?
.ok_or_else(|| Error::MissingBeaconState(beacon_state_root))?;
Ok(BeaconSnapshot {
beacon_block,
beacon_block_root,
beacon_state,
beacon_state_root,
})
})
.and_then(|mut snapshot| {
// Regardless of where we got the state from, attempt to build the committee
// caches.
snapshot
.beacon_state
.build_all_committee_caches(&self.spec)
.map_err(Into::into)
.map(|()| snapshot)
})?;
// Attempt to detect if the new head is not on the same chain as the previous block
// (i.e., a re-org).
//
// Note: this will declare a re-org if we skip `SLOTS_PER_HISTORICAL_ROOT` blocks
// between calls to fork choice without swapping between chains. This seems like an
// extreme-enough scenario that a warning is fine.
let is_reorg = current_head.block_root
!= new_head
.beacon_state
.get_block_root(current_head.slot)
.map(|root| *root)
.unwrap_or_else(|_| Hash256::random());
if is_reorg {
metrics::inc_counter(&metrics::FORK_CHOICE_REORG_COUNT);
warn!(
self.log,
"Beacon chain re-org";
"previous_head" => format!("{}", current_head.block_root),
"previous_slot" => current_head.slot,
"new_head_parent" => format!("{}", new_head.beacon_block.parent_root()),
"new_head" => format!("{}", beacon_block_root),
"new_slot" => new_head.beacon_block.slot()
);
} else {
debug!(
self.log,
"Head beacon block";
"justified_root" => format!("{}", new_head.beacon_state.current_justified_checkpoint.root),
"justified_epoch" => new_head.beacon_state.current_justified_checkpoint.epoch,
"finalized_root" => format!("{}", new_head.beacon_state.finalized_checkpoint.root),
"finalized_epoch" => new_head.beacon_state.finalized_checkpoint.epoch,
"root" => format!("{}", beacon_block_root),
"slot" => new_head.beacon_block.slot(),
);
};
let old_finalized_epoch = current_head.finalized_checkpoint.epoch;
let new_finalized_epoch = new_head.beacon_state.finalized_checkpoint.epoch;
let finalized_root = new_head.beacon_state.finalized_checkpoint.root;
// It is an error to try to update to a head with a lesser finalized epoch.
if new_finalized_epoch < old_finalized_epoch {
return Err(Error::RevertedFinalizedEpoch {
previous_epoch: old_finalized_epoch,
new_epoch: new_finalized_epoch,
});
}
if current_head.slot.epoch(T::EthSpec::slots_per_epoch())
< new_head
.beacon_state
.slot
.epoch(T::EthSpec::slots_per_epoch())
|| is_reorg
{
self.persist_head_and_fork_choice()?;
}
let update_head_timer = metrics::start_timer(&metrics::UPDATE_HEAD_TIMES);
// Update the snapshot that stores the head of the chain at the time it received the
// block.
*self
.canonical_head
.try_write_for(HEAD_LOCK_TIMEOUT)
.ok_or_else(|| Error::CanonicalHeadLockTimeout)? = new_head;
metrics::stop_timer(update_head_timer);
self.snapshot_cache
.try_write_for(BLOCK_PROCESSING_CACHE_LOCK_TIMEOUT)
.map(|mut snapshot_cache| {
snapshot_cache.update_head(beacon_block_root);
})
.unwrap_or_else(|| {
error!(
self.log,
"Failed to obtain cache write lock";
"lock" => "snapshot_cache",
"task" => "update head"
);
});
if new_finalized_epoch != old_finalized_epoch {
self.after_finalization(
old_finalized_epoch,
finalized_root,
old_finalized_root.into(),
)?;
}
let _ = self.event_handler.register(EventKind::BeaconHeadChanged {
reorg: is_reorg,
previous_head_beacon_block_root: current_head.block_root,
current_head_beacon_block_root: beacon_block_root,
});
Ok(())
}
/// Called by the timer on every slot.
///
/// Performs slot-based pruning.
pub fn per_slot_task(&self) {
trace!(self.log, "Running beacon chain per slot tasks");
if let Some(slot) = self.slot_clock.now() {
self.naive_aggregation_pool.prune(slot);
}
}
/// Called after `self` has had a new block finalized.
///
/// Performs pruning and finality-based optimizations.
fn after_finalization(
&self,
old_finalized_epoch: Epoch,
finalized_block_root: Hash256,
old_finalized_root: SignedBeaconBlockHash,
) -> Result<(), Error> {
let finalized_block = self
.store
.get_block(&finalized_block_root)?
.ok_or_else(|| Error::MissingBeaconBlock(finalized_block_root))?
.message;
let new_finalized_epoch = finalized_block.slot.epoch(T::EthSpec::slots_per_epoch());
if new_finalized_epoch < old_finalized_epoch {
Err(Error::RevertedFinalizedEpoch {
previous_epoch: old_finalized_epoch,
new_epoch: new_finalized_epoch,
})
} else {
self.fork_choice.prune()?;
self.observed_block_producers
.prune(new_finalized_epoch.start_slot(T::EthSpec::slots_per_epoch()));
self.snapshot_cache
.try_write_for(BLOCK_PROCESSING_CACHE_LOCK_TIMEOUT)
.map(|mut snapshot_cache| {
snapshot_cache.prune(new_finalized_epoch);
})
.unwrap_or_else(|| {
error!(
self.log,
"Failed to obtain cache write lock";
"lock" => "snapshot_cache",
"task" => "prune"
);
});
let finalized_state = self
.get_state(&finalized_block.state_root, Some(finalized_block.slot))?
.ok_or_else(|| Error::MissingBeaconState(finalized_block.state_root))?;
self.op_pool.prune_all(&finalized_state, &self.spec);
// TODO: configurable max finality distance
let max_finality_distance = 0;
self.store_migrator.process_finalization(
finalized_block.state_root,
finalized_state,
max_finality_distance,
Arc::clone(&self.head_tracker),
old_finalized_root,
finalized_block_root.into(),
);
let _ = self.event_handler.register(EventKind::BeaconFinalization {
epoch: new_finalized_epoch,
root: finalized_block_root,
});
Ok(())
}
}
/// Returns `true` if the given block root has not been processed.
pub fn is_new_block_root(&self, beacon_block_root: &Hash256) -> Result<bool, Error> {
Ok(!self
.store
.exists::<SignedBeaconBlock<T::EthSpec>>(beacon_block_root)?)
}
/// Dumps the entire canonical chain, from the head to genesis to a vector for analysis.
///
/// This could be a very expensive operation and should only be done in testing/analysis
/// activities.
pub fn chain_dump(&self) -> Result<Vec<BeaconSnapshot<T::EthSpec>>, Error> {
let mut dump = vec![];
let mut last_slot = BeaconSnapshot {
beacon_block: self.head()?.beacon_block,
beacon_block_root: self.head()?.beacon_block_root,
beacon_state: self.head()?.beacon_state,
beacon_state_root: self.head()?.beacon_state_root,
};
dump.push(last_slot.clone());
loop {
let beacon_block_root = last_slot.beacon_block.parent_root();
if beacon_block_root == Hash256::zero() {
break; // Genesis has been reached.
}
let beacon_block = self.store.get_block(&beacon_block_root)?.ok_or_else(|| {
Error::DBInconsistent(format!("Missing block {}", beacon_block_root))
})?;
let beacon_state_root = beacon_block.state_root();
let beacon_state = self
.store
.get_state(&beacon_state_root, Some(beacon_block.slot()))?
.ok_or_else(|| {
Error::DBInconsistent(format!("Missing state {:?}", beacon_state_root))
})?;
let slot = BeaconSnapshot {
beacon_block,
beacon_block_root,
beacon_state,
beacon_state_root,
};
dump.push(slot.clone());
last_slot = slot;
}
dump.reverse();
Ok(dump)
}
/// Gets the current `EnrForkId`.
pub fn enr_fork_id(&self) -> EnrForkId {
// If we are unable to read the slot clock we assume that it is prior to genesis and
// therefore use the genesis slot.
let slot = self.slot().unwrap_or_else(|_| self.spec.genesis_slot);
self.spec.enr_fork_id(slot, self.genesis_validators_root)
}
/// Calculates the `Duration` to the next fork, if one exists.
pub fn duration_to_next_fork(&self) -> Option<Duration> {
let epoch = self.spec.next_fork_epoch()?;
self.slot_clock
.duration_to_slot(epoch.start_slot(T::EthSpec::slots_per_epoch()))
}
pub fn dump_as_dot<W: Write>(&self, output: &mut W) {
let canonical_head_hash = self
.canonical_head
.try_read_for(HEAD_LOCK_TIMEOUT)
.ok_or_else(|| Error::CanonicalHeadLockTimeout)
.unwrap()
.beacon_block_root;
let mut visited: HashSet<Hash256> = HashSet::new();
let mut finalized_blocks: HashSet<Hash256> = HashSet::new();
let genesis_block_hash = Hash256::zero();
write!(output, "digraph beacon {{\n").unwrap();
write!(output, "\t_{:?}[label=\"genesis\"];\n", genesis_block_hash).unwrap();
// Canonical head needs to be processed first as otherwise finalized blocks aren't detected
// properly.
let heads = {
let mut heads = self.heads();
let canonical_head_index = heads
.iter()
.position(|(block_hash, _)| *block_hash == canonical_head_hash)
.unwrap();
let (canonical_head_hash, canonical_head_slot) =
heads.swap_remove(canonical_head_index);
heads.insert(0, (canonical_head_hash, canonical_head_slot));
heads
};
for (head_hash, _head_slot) in heads {
for maybe_pair in ParentRootBlockIterator::new(&*self.store, head_hash) {
let (block_hash, signed_beacon_block) = maybe_pair.unwrap();
if visited.contains(&block_hash) {
break;
}
visited.insert(block_hash);
if signed_beacon_block.slot() % T::EthSpec::slots_per_epoch() == 0 {
let block = self.get_block(&block_hash).unwrap().unwrap();
let state = self
.get_state(&block.state_root(), Some(block.slot()))
.unwrap()
.unwrap();
finalized_blocks.insert(state.finalized_checkpoint.root);
}
if block_hash == canonical_head_hash {
write!(
output,
"\t_{:?}[label=\"{} ({})\" shape=box3d];\n",
block_hash,
block_hash,
signed_beacon_block.slot()
)
.unwrap();
} else if finalized_blocks.contains(&block_hash) {
write!(
output,
"\t_{:?}[label=\"{} ({})\" shape=Msquare];\n",
block_hash,
block_hash,
signed_beacon_block.slot()
)
.unwrap();
} else {
write!(
output,
"\t_{:?}[label=\"{} ({})\" shape=box];\n",
block_hash,
block_hash,
signed_beacon_block.slot()
)
.unwrap();
}
write!(
output,
"\t_{:?} -> _{:?};\n",
block_hash,
signed_beacon_block.parent_root()
)
.unwrap();
}
}
write!(output, "}}\n").unwrap();
}
// Used for debugging
#[allow(dead_code)]
pub fn dump_dot_file(&self, file_name: &str) {
let mut file = std::fs::File::create(file_name).unwrap();
self.dump_as_dot(&mut file);
}
}
impl<T: BeaconChainTypes> Drop for BeaconChain<T> {
fn drop(&mut self) {
let drop = || -> Result<(), Error> {
self.persist_head_and_fork_choice()?;
self.persist_op_pool()?;
self.persist_eth1_cache()
};
if let Err(e) = drop() {
error!(
self.log,
"Failed to persist on BeaconChain drop";
"error" => format!("{:?}", e)
)
} else {
info!(
self.log,
"Saved beacon chain to disk";
)
}
}
}
impl From<DBError> for Error {
fn from(e: DBError) -> Error {
Error::DBError(e)
}
}
impl From<ForkChoiceError> for Error {
fn from(e: ForkChoiceError) -> Error {
Error::ForkChoiceError(e)
}
}
impl From<BeaconStateError> for Error {
fn from(e: BeaconStateError) -> Error {
Error::BeaconStateError(e)
}
}
impl ChainSegmentResult {
pub fn to_block_error(self) -> Result<(), BlockError> {
match self {
ChainSegmentResult::Failed { error, .. } => Err(error),
ChainSegmentResult::Successful { .. } => Ok(()),
}
}
}
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