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f75a2cf65b4bc4724bab6c6edd5754e5150eca6d
lighthouse/beacon_node/beacon_chain/tests/store_tests.rs
Lion - dapplion f75a2cf65b PeerDAS implementation (#5683) 
* 1D PeerDAS prototype: Data format and Distribution (#5050)

* Build and publish column sidecars. Add stubs for gossip.

* Add blob column subnets

* Add `BlobColumnSubnetId` and initial compute subnet logic.

* Subscribe to blob column subnets.

* Introduce `BLOB_COLUMN_SUBNET_COUNT` based on DAS configuration parameter changes.

* Fix column sidecar type to use `VariableList` for data.

* Fix lint errors.

* Update types and naming to latest consensus-spec #3574.

* Fix test and some cleanups.

* Merge branch 'unstable' into das

* Merge branch 'unstable' into das

* Merge branch 'unstable' into das

# Conflicts:
#	consensus/types/src/chain_spec.rs

* Add `DataColumnSidecarsByRoot ` req/resp protocol (#5196)

* Add stub for `DataColumnsByRoot`

* Add basic implementation of serving RPC data column from DA checker.

* Store data columns in early attester cache and blobs db.

* Apply suggestions from code review

Co-authored-by: Eitan Seri-Levi <eserilev@gmail.com>
Co-authored-by: Jacob Kaufmann <jacobkaufmann18@gmail.com>

* Fix build.

* Store `DataColumnInfo` in database and various cleanups.

* Update `DataColumnSidecar` ssz max size and remove panic code.

---------

Co-authored-by: Eitan Seri-Levi <eserilev@gmail.com>
Co-authored-by: Jacob Kaufmann <jacobkaufmann18@gmail.com>

* feat: add DAS KZG in data col construction (#5210)

* feat: add DAS KZG in data col construction

* refactor data col sidecar construction

* refactor: add data cols to GossipVerifiedBlockContents

* Disable windows tests for `das` branch. (c-kzg doesn't build on windows)

* Formatting and lint changes only.

* refactor: remove iters in construction of data cols

* Update vec capacity and error handling.

* Add `data_column_sidecar_computation_seconds` metric.

---------

Co-authored-by: Jimmy Chen <jchen.tc@gmail.com>

* Merge branch 'unstable' into das

# Conflicts:
#	.github/workflows/test-suite.yml
#	beacon_node/lighthouse_network/src/types/topics.rs

* fix: update data col subnet count from 64 to 32 (#5413)

* feat: add peerdas custody field to ENR (#5409)

* feat: add peerdas custody field to ENR

* add hash prefix step in subnet computation

* refactor test and fix possible u64 overflow

* default to min custody value if not present in ENR

* Merge branch 'unstable' into das

* Merge branch 'unstable' into das-unstable-merge-0415

# Conflicts:
#	Cargo.lock
#	beacon_node/beacon_chain/src/data_availability_checker.rs
#	beacon_node/beacon_chain/src/data_availability_checker/availability_view.rs
#	beacon_node/beacon_chain/src/data_availability_checker/overflow_lru_cache.rs
#	beacon_node/beacon_chain/src/data_availability_checker/processing_cache.rs
#	beacon_node/lighthouse_network/src/rpc/methods.rs
#	beacon_node/network/src/network_beacon_processor/mod.rs
#	beacon_node/network/src/sync/block_lookups/tests.rs
#	crypto/kzg/Cargo.toml

* Merge remote-tracking branch 'sigp/unstable' into das

* Merge remote-tracking branch 'sigp/unstable' into das

* Fix merge conflicts.

* Send custody data column to `DataAvailabilityChecker` for determining block importability (#5570)

* Only import custody data columns after publishing a block.

* Add `subscribe-all-data-column-subnets` and pass custody column count to `availability_cache`.

* Add custody requirement checks to `availability_cache`.

* Fix config not being passed to DAChecker and add more logging.

* Introduce `peer_das_epoch` and make blobs and columns mutually exclusive.

* Add DA filter for PeerDAS.

* Fix data availability check and use test_logger in tests.

* Fix subscribe to all data column subnets not working correctly.

* Fix tests.

* Only publish column sidecars if PeerDAS is activated. Add `PEER_DAS_EPOCH` chain spec serialization.

* Remove unused data column index in `OverflowKey`.

* Fix column sidecars incorrectly produced when there are no blobs.

* Re-instate index to `OverflowKey::DataColumn` and downgrade noisy debug log to `trace`.

* DAS sampling on sync (#5616)

* Data availability sampling on sync

* Address @jimmygchen review

* Trigger sampling

* Address some review comments and only send `SamplingBlock` sync message after PEER_DAS_EPOCH.

---------

Co-authored-by: Jimmy Chen <jchen.tc@gmail.com>

* Merge branch 'unstable' into das

# Conflicts:
#	Cargo.lock
#	Cargo.toml
#	beacon_node/beacon_chain/src/block_verification.rs
#	beacon_node/http_api/src/publish_blocks.rs
#	beacon_node/lighthouse_network/src/rpc/codec/ssz_snappy.rs
#	beacon_node/lighthouse_network/src/rpc/protocol.rs
#	beacon_node/lighthouse_network/src/types/pubsub.rs
#	beacon_node/network/src/sync/block_lookups/single_block_lookup.rs
#	beacon_node/store/src/hot_cold_store.rs
#	consensus/types/src/beacon_state.rs
#	consensus/types/src/chain_spec.rs
#	consensus/types/src/eth_spec.rs

* Merge branch 'unstable' into das

* Re-process early sampling requests (#5569)

* Re-process early sampling requests

# Conflicts:
#	beacon_node/beacon_processor/src/work_reprocessing_queue.rs
#	beacon_node/lighthouse_network/src/rpc/methods.rs
#	beacon_node/network/src/network_beacon_processor/rpc_methods.rs

* Update beacon_node/beacon_processor/src/work_reprocessing_queue.rs

Co-authored-by: Jimmy Chen <jchen.tc@gmail.com>

* Add missing var

* Beta compiler fixes and small typo fixes.

* Remove duplicate method.

---------

Co-authored-by: Jimmy Chen <jchen.tc@gmail.com>

* Merge remote-tracking branch 'sigp/unstable' into das

* Fix merge conflict.

* Add data columns by root to currently supported protocol list (#5678)

* Add data columns by root to currently supported protocol list.

* Add missing data column by roots handling.

* Merge branch 'unstable' into das

# Conflicts:
#	Cargo.lock
#	Cargo.toml
#	beacon_node/network/src/sync/block_lookups/tests.rs
#	beacon_node/network/src/sync/manager.rs

* Fix simulator tests on `das` branch (#5731)

* Bump genesis delay in sim tests as KZG setup takes longer for DAS.

* Fix incorrect YAML spacing.

* DataColumnByRange boilerplate (#5353)

* add boilerplate

* fmt

* PeerDAS custody lookup sync (#5684)

* Implement custody sync

* Lint

* Fix tests

* Fix rebase issue

* Add data column kzg verification and update `c-kzg`. (#5701)

* Add data column kzg verification and update `c-kzg`.

* Fix incorrect `Cell` size.

* Add kzg verification on rpc blocks.

* Add kzg verification on rpc data columns.

* Rename `PEER_DAS_EPOCH` to `EIP7594_FORK_EPOCH` for client interop. (#5750)

* Fetch custody columns in range sync (#5747)

* Fetch custody columns in range sync

* Clean up todos

* Remove `BlobSidecar` construction and publish after PeerDAS activated (#5759)

* Avoid building and publishing blob sidecars after PeerDAS.

* Ignore gossip blobs with a slot greater than peer das activation epoch.

* Only attempt to verify blob count and import blobs before PeerDAS.

* #5684 review comments (#5748)

* #5684 review comments.

* Doc and message update only.

* Fix incorrect condition when constructing `RpcBlock` with `DataColumn`s

* Make sampling tests deterministic (#5775)

* PeerDAS spec tests (#5772)

* Add get_custody_columns spec tests.

* Add kzg merkle proof spec tests.

* Add SSZ spec tests.

* Add remaining KZG tests

* Load KZG only once per process, exclude electra tests and add missing SSZ tests.

* Fix lint and missing changes.

* Ignore macOS generated file.

* Merge remote branch 'sigp/unstable' into das

* Merge remote tracking branch 'origin/unstable' into das

* Implement unconditional reconstruction for supernodes (#5781)

* Implement unconditional reconstruction for supernodes

* Move code into KzgVerifiedCustodyDataColumn

* Remove expect

* Add test

* Thanks justin

* Add withhold attack mode for interop (#5788)

* Add withhold attack mode

* Update readme

* Drop added readmes

* Undo styling changes

* Add column gossip verification and handle unknown parent block (#5783)

* Add column gossip verification and handle missing parent for columns.

* Review PR

* Fix rebase issue

* more lint issues :)

---------

Co-authored-by: dapplion <35266934+dapplion@users.noreply.github.com>

* Trigger sampling on sync events (#5776)

* Trigger sampling on sync events

* Update beacon_chain.rs

* Fix tests

* Fix tests

* PeerDAS parameter changes for devnet-0 (#5779)

* Update PeerDAS parameters to latest values.

* Lint fix

* Fix lint.

* Update hardcoded subnet count to 64 (#5791)

* Fix incorrect columns per subnet and config cleanup (#5792)

* Tidy up PeerDAS preset and config values.

* Fix broken config

* Fix DAS branch CI (#5793)

* Fix invalid syntax.

* Update cli doc. Ignore get_custody_columns test temporarily.

* Fix failing test and add verify inclusion test.

* Undo accidentally removed code.

* Only attempt reconstruct columns once. (#5794)

* Re-enable precompute table for peerdas kzg (#5795)

* Merge branch 'unstable' into das

* Update subscription filter. (#5797)

* Remove penalty for duplicate columns (expected due to reconstruction) (#5798)

* Revert DAS config for interop testing. Optimise get_custody_columns function. (#5799)

* Don't perform reconstruction for proposer node as it already has all the columns. (#5806)

* Multithread compute_cells_and_proofs (#5805)

* Multi-thread reconstruct data columns

* Multi-thread path for block production

* Merge branch 'unstable' into das

# Conflicts:
#	.github/workflows/test-suite.yml
#	beacon_node/network/src/sync/block_lookups/mod.rs
#	beacon_node/network/src/sync/block_lookups/single_block_lookup.rs
#	beacon_node/network/src/sync/network_context.rs

* Fix CI errors.

* Move PeerDAS type-level config to configurable `ChainSpec` (#5828)

* Move PeerDAS type level config to `ChainSpec`.

* Fix tests

* Misc custody lookup improvements (#5821)

* Improve custody requests

* Type DataColumnsByRootRequestId

* Prioritize peers and load balance

* Update tests

* Address PR review

* Merge branch 'unstable' into das

* Rename deploy_block in network config (`das` branch) (#5852)

* Rename deploy_block.txt to deposit_contract_block.txt

* fmt

---------

Co-authored-by: Pawan Dhananjay <pawandhananjay@gmail.com>

* Merge branch 'unstable' into das

* Fix CI and merge issues.

* Merge branch 'unstable' into das

# Conflicts:
#	beacon_node/beacon_chain/src/data_availability_checker/overflow_lru_cache.rs
#	lcli/src/main.rs

* Store data columns individually in store and caches (#5890)

* Store data columns individually in store and caches

* Implement data column pruning

* Merge branch 'unstable' into das

# Conflicts:
#	Cargo.lock

* Update reconstruction benches to newer criterion version. (#5949)

* Merge branch 'unstable' into das

# Conflicts:
#	.github/workflows/test-suite.yml

* chore: add `recover_cells_and_compute_proofs` method (#5938)

* chore: add recover_cells_and_compute_proofs method

* Introduce type alias `CellsAndKzgProofs` to address type complexity.

---------

Co-authored-by: Jimmy Chen <jchen.tc@gmail.com>

* Update `csc` format in ENR and spec tests for devnet-1 (#5966)

* Update `csc` format in ENR.

* Add spec tests for `recover_cells_and_kzg_proofs`.

* Add tests for ENR.

* Fix failing tests.

* Add protection against invalid csc value in ENR.

* Fix lint

* Fix csc encoding and decoding (#5997)

* Fix data column rpc request not being sent due to incorrect limits set. (#6000)

* Fix incorrect inbound request count causing rate limiting. (#6025)

* Merge branch 'stable' into das

# Conflicts:
#	beacon_node/network/src/sync/block_lookups/tests.rs
#	beacon_node/network/src/sync/block_sidecar_coupling.rs
#	beacon_node/network/src/sync/manager.rs
#	beacon_node/network/src/sync/network_context.rs
#	beacon_node/network/src/sync/network_context/requests.rs

* Merge remote-tracking branch 'unstable' into das

* Add kurtosis config for DAS testing (#5968)

* Add kurtosis config for DAS testing.

* Fix invalid yaml file

* Update network parameter files.

* chore: add rust PeerdasKZG crypto library for peerdas functionality and rollback c-kzg dependency to 4844 version (#5941)

* chore: add recover_cells_and_compute_proofs method

* chore: add rust peerdas crypto library

* chore: integrate peerdaskzg rust library into kzg crate

* chore(multi):

- update `ssz_cell_to_crypto_cell`
- update conversion from the crypto cell type to a Vec<u8>. Since the Rust library defines them as references to an array, the conversion is simply `to_vec`

* chore(multi):

- update rest of code to handle the new crypto `Cell` type
- update test case code to no longer use the Box type

* chore: cleanup of superfluous conversions

* chore: revert c-kzg dependency back to v1

* chore: move dependency into correct order

* chore: update rust dependency

- This version includes a new method `PeerDasContext::with_num_threads`

* chore: remove Default initialization of PeerDasContext and explicitly set the parameters in `new_from_trusted_setup`

* chore: cleanup exports

* chore: commit updated cargo.lock

* Update Cargo.toml

Co-authored-by: Jimmy Chen <jchen.tc@gmail.com>

* chore: rename dependency

* chore: update peerdas lib

- sets the blst version to 0.3 so that it matches whatever lighthouse is using. Although 0.3.12 is latest, lighthouse is pinned to 0.3.3

* chore: fix clippy lifetime

- Rust doesn't allow you to elide the lifetime on type aliases

* chore: cargo clippy fix

* chore: cargo fmt

* chore: update lib to add redundant checks (these will be removed in consensus-specs PR 3819)

* chore: update dependency to ignore proofs

* chore: update peerdas lib to latest

* update lib

* chore: remove empty proof parameter

---------

Co-authored-by: Jimmy Chen <jchen.tc@gmail.com>

* Update PeerDAS interop testnet config (#6069)

* Update interop testnet config.

* Fix typo and remove target peers

* Avoid retrying same sampling peer that previously failed. (#6084)

* Various fixes to custody range sync  (#6004)

* Only start requesting batches when there are good peers across all custody columns to avoid spaming block requests.

* Add custody peer check before mutating `BatchInfo` to avoid inconsistent state.

* Add check to cover a case where batch is not processed while waiting for custody peers to become available.

* Fix lint and logic error

* Fix `good_peers_on_subnet` always returning false for `DataColumnSubnet`.

* Add test for `get_custody_peers_for_column`

* Revert epoch parameter refactor.

* Fall back to default custody requiremnt if peer ENR is not present.

* Add metrics and update code comment.

* Add more debug logs.

* Use subscribed peers on subnet before MetaDataV3 is implemented. Remove peer_id matching when injecting error because multiple peers are used for range requests. Use randomized custodial peer to avoid repeatedly sending requests to failing peers. Batch by range request where possible.

* Remove unused code and update docs.

* Add comment

* chore: update peerdas-kzg library (#6118)

* chore: update peerDAS lib

* chore: update library

* chore: update library to version that include "init context" benchmarks and optional validation checks

* chore: (can remove) -- Add benchmarks for init context

* Prevent continuous searchers for low-peer networks (#6162)

* Merge branch 'unstable' into das

* Fix merge conflicts

* Add cli flag to enable sampling and disable by default. (#6209)

* chore: Use reference to an array representing a blob instead of an owned KzgBlob (#6179)

* add KzgBlobRef type

* modify code to use KzgBlobRef

* clippy

* Remove Deneb blob related changes to maintain compatibility with `c-kzg-4844`.

---------

Co-authored-by: Jimmy Chen <jchen.tc@gmail.com>

* Store computed custody subnets in PeerDB and fix custody lookup test (#6218)

* Fix failing custody lookup tests.

* Store custody subnets in PeerDB, fix custody lookup test and refactor some methods.

* Merge branch 'unstable' into das

# Conflicts:
#	beacon_node/beacon_chain/src/beacon_chain.rs
#	beacon_node/beacon_chain/src/block_verification_types.rs
#	beacon_node/beacon_chain/src/builder.rs
#	beacon_node/beacon_chain/src/data_availability_checker.rs
#	beacon_node/beacon_chain/src/data_availability_checker/overflow_lru_cache.rs
#	beacon_node/beacon_chain/src/data_column_verification.rs
#	beacon_node/beacon_chain/src/early_attester_cache.rs
#	beacon_node/beacon_chain/src/historical_blocks.rs
#	beacon_node/beacon_chain/tests/store_tests.rs
#	beacon_node/lighthouse_network/src/discovery/enr.rs
#	beacon_node/network/src/service.rs
#	beacon_node/src/cli.rs
#	beacon_node/store/src/hot_cold_store.rs
#	beacon_node/store/src/lib.rs
#	lcli/src/generate_bootnode_enr.rs

* Fix CI failures after merge.

* Batch sampling requests by peer (#6256)

* Batch sampling requests by peer

* Fix clippy errors

* Fix tests

* Add column_index to error message for ease of tracing

* Remove outdated comment

* Fix range sync never evaluating request as finished, causing it to get stuck. (#6276)

* Merge branch 'unstable' into das-0821-merge

# Conflicts:
#	Cargo.lock
#	Cargo.toml
#	beacon_node/beacon_chain/src/beacon_chain.rs
#	beacon_node/beacon_chain/src/data_availability_checker.rs
#	beacon_node/beacon_chain/src/data_availability_checker/overflow_lru_cache.rs
#	beacon_node/beacon_chain/src/data_column_verification.rs
#	beacon_node/beacon_chain/src/kzg_utils.rs
#	beacon_node/beacon_chain/src/metrics.rs
#	beacon_node/beacon_processor/src/lib.rs
#	beacon_node/lighthouse_network/src/rpc/codec/ssz_snappy.rs
#	beacon_node/lighthouse_network/src/rpc/config.rs
#	beacon_node/lighthouse_network/src/rpc/methods.rs
#	beacon_node/lighthouse_network/src/rpc/outbound.rs
#	beacon_node/lighthouse_network/src/rpc/rate_limiter.rs
#	beacon_node/lighthouse_network/src/service/api_types.rs
#	beacon_node/lighthouse_network/src/types/globals.rs
#	beacon_node/network/src/network_beacon_processor/mod.rs
#	beacon_node/network/src/network_beacon_processor/rpc_methods.rs
#	beacon_node/network/src/network_beacon_processor/sync_methods.rs
#	beacon_node/network/src/sync/block_lookups/common.rs
#	beacon_node/network/src/sync/block_lookups/mod.rs
#	beacon_node/network/src/sync/block_lookups/single_block_lookup.rs
#	beacon_node/network/src/sync/block_lookups/tests.rs
#	beacon_node/network/src/sync/manager.rs
#	beacon_node/network/src/sync/network_context.rs
#	consensus/types/src/data_column_sidecar.rs
#	crypto/kzg/Cargo.toml
#	crypto/kzg/benches/benchmark.rs
#	crypto/kzg/src/lib.rs

* Fix custody tests and load PeerDAS KZG instead.

* Fix ef tests and bench compilation.

* Fix failing sampling test.

* Merge pull request #6287 from jimmygchen/das-0821-merge

Merge `unstable` into `das` 20240821

* Remove get_block_import_status

* Merge branch 'unstable' into das

* Re-enable Windows release tests.

* Address some review comments.

* Address more review comments and cleanups.

* Comment out peer DAS KZG EF tests for now

* Address more review comments and fix build.

* Merge branch 'das' of github.com:sigp/lighthouse into das

* Unignore Electra tests

* Fix metric name

* Address some of Pawan's review comments

* Merge remote-tracking branch 'origin/unstable' into das

* Update PeerDAS network parameters for peerdas-devnet-2  (#6290)

* update subnet count & custody req

* das network params

* update ef tests

---------

Co-authored-by: Jimmy Chen <jchen.tc@gmail.com>
2024-08-27 04:10:22 +00:00

3956 lines
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#![cfg(not(debug_assertions))]
use beacon_chain::attestation_verification::Error as AttnError;
use beacon_chain::block_verification_types::RpcBlock;
use beacon_chain::builder::BeaconChainBuilder;
use beacon_chain::data_availability_checker::AvailableBlock;
use beacon_chain::schema_change::migrate_schema;
use beacon_chain::test_utils::RelativeSyncCommittee;
use beacon_chain::test_utils::{
mock_execution_layer_from_parts, test_spec, AttestationStrategy, BeaconChainHarness,
BlockStrategy, DiskHarnessType, KZG,
};
use beacon_chain::{
data_availability_checker::MaybeAvailableBlock, historical_blocks::HistoricalBlockError,
migrate::MigratorConfig, BeaconChain, BeaconChainError, BeaconChainTypes, BeaconSnapshot,
BlockError, ChainConfig, NotifyExecutionLayer, ServerSentEventHandler, WhenSlotSkipped,
};
use logging::test_logger;
use maplit::hashset;
use rand::Rng;
use slot_clock::{SlotClock, TestingSlotClock};
use state_processing::{state_advance::complete_state_advance, BlockReplayer};
use std::collections::HashMap;
use std::collections::HashSet;
use std::convert::TryInto;
use std::sync::{Arc, LazyLock};
use std::time::Duration;
use store::chunked_vector::Chunk;
use store::metadata::{SchemaVersion, CURRENT_SCHEMA_VERSION, STATE_UPPER_LIMIT_NO_RETAIN};
use store::{
chunked_vector::{chunk_key, Field},
get_key_for_col,
iter::{BlockRootsIterator, StateRootsIterator},
BlobInfo, DBColumn, HotColdDB, KeyValueStore, KeyValueStoreOp, LevelDB, StoreConfig,
};
use tempfile::{tempdir, TempDir};
use tokio::time::sleep;
use types::test_utils::{SeedableRng, XorShiftRng};
use types::*;
// Should ideally be divisible by 3.
pub const LOW_VALIDATOR_COUNT: usize = 24;
pub const HIGH_VALIDATOR_COUNT: usize = 64;
/// A cached set of keys.
static KEYPAIRS: LazyLock<Vec<Keypair>> =
LazyLock::new(|| types::test_utils::generate_deterministic_keypairs(HIGH_VALIDATOR_COUNT));
type E = MinimalEthSpec;
type TestHarness = BeaconChainHarness<DiskHarnessType<E>>;
fn get_store(db_path: &TempDir) -> Arc<HotColdDB<E, LevelDB<E>, LevelDB<E>>> {
get_store_generic(db_path, StoreConfig::default(), test_spec::<E>())
}
fn get_store_generic(
db_path: &TempDir,
config: StoreConfig,
spec: ChainSpec,
) -> Arc<HotColdDB<E, LevelDB<E>, LevelDB<E>>> {
let hot_path = db_path.path().join("hot_db");
let cold_path = db_path.path().join("cold_db");
let blobs_path = db_path.path().join("blobs_db");
let log = test_logger();
HotColdDB::open(
&hot_path,
&cold_path,
&blobs_path,
|_, _, _| Ok(()),
config,
spec,
log,
)
.expect("disk store should initialize")
}
fn get_harness(
store: Arc<HotColdDB<E, LevelDB<E>, LevelDB<E>>>,
validator_count: usize,
) -> TestHarness {
// Most tests expect to retain historic states, so we use this as the default.
let chain_config = ChainConfig {
reconstruct_historic_states: true,
..ChainConfig::default()
};
get_harness_generic(store, validator_count, chain_config)
}
fn get_harness_generic(
store: Arc<HotColdDB<E, LevelDB<E>, LevelDB<E>>>,
validator_count: usize,
chain_config: ChainConfig,
) -> TestHarness {
let harness = TestHarness::builder(MinimalEthSpec)
.spec(store.get_chain_spec().clone())
.keypairs(KEYPAIRS[0..validator_count].to_vec())
.logger(store.logger().clone())
.fresh_disk_store(store)
.mock_execution_layer()
.chain_config(chain_config)
.build();
harness.advance_slot();
harness
}
#[tokio::test]
async fn light_client_updates_test() {
let spec = test_spec::<E>();
let Some(_) = spec.altair_fork_epoch else {
// No-op prior to Altair.
return;
};
let num_final_blocks = E::slots_per_epoch() * 2;
let checkpoint_slot = Slot::new(E::slots_per_epoch() * 9);
let db_path = tempdir().unwrap();
let log = test_logger();
let seconds_per_slot = spec.seconds_per_slot;
let store = get_store_generic(
&db_path,
StoreConfig {
slots_per_restore_point: 2 * E::slots_per_epoch(),
..Default::default()
},
test_spec::<E>(),
);
let harness = get_harness(store.clone(), LOW_VALIDATOR_COUNT);
let all_validators = (0..LOW_VALIDATOR_COUNT).collect::<Vec<_>>();
let num_initial_slots = E::slots_per_epoch() * 10;
let slots: Vec<Slot> = (1..num_initial_slots).map(Slot::new).collect();
let (genesis_state, genesis_state_root) = harness.get_current_state_and_root();
harness
.add_attested_blocks_at_slots(
genesis_state.clone(),
genesis_state_root,
&slots,
&all_validators,
)
.await;
let wss_block_root = harness
.chain
.block_root_at_slot(checkpoint_slot, WhenSlotSkipped::Prev)
.unwrap()
.unwrap();
let wss_state_root = harness
.chain
.state_root_at_slot(checkpoint_slot)
.unwrap()
.unwrap();
let wss_block = harness
.chain
.store
.get_full_block(&wss_block_root)
.unwrap()
.unwrap();
let wss_blobs_opt = harness.chain.store.get_blobs(&wss_block_root).unwrap();
let wss_state = store
.get_state(&wss_state_root, Some(checkpoint_slot))
.unwrap()
.unwrap();
let kzg = spec.deneb_fork_epoch.map(|_| KZG.clone());
let mock =
mock_execution_layer_from_parts(&harness.spec, harness.runtime.task_executor.clone());
harness.advance_slot();
harness
.extend_chain(
num_final_blocks as usize,
BlockStrategy::OnCanonicalHead,
AttestationStrategy::AllValidators,
)
.await;
// Initialise a new beacon chain from the finalized checkpoint.
// The slot clock must be set to a time ahead of the checkpoint state.
let slot_clock = TestingSlotClock::new(
Slot::new(0),
Duration::from_secs(harness.chain.genesis_time),
Duration::from_secs(seconds_per_slot),
);
slot_clock.set_slot(harness.get_current_slot().as_u64());
let (shutdown_tx, _shutdown_rx) = futures::channel::mpsc::channel(1);
let beacon_chain = BeaconChainBuilder::<DiskHarnessType<E>>::new(MinimalEthSpec)
.store(store.clone())
.custom_spec(test_spec::<E>())
.task_executor(harness.chain.task_executor.clone())
.logger(log.clone())
.weak_subjectivity_state(
wss_state,
wss_block.clone(),
wss_blobs_opt.clone(),
genesis_state,
)
.unwrap()
.store_migrator_config(MigratorConfig::default().blocking())
.dummy_eth1_backend()
.expect("should build dummy backend")
.slot_clock(slot_clock)
.shutdown_sender(shutdown_tx)
.chain_config(ChainConfig::default())
.event_handler(Some(ServerSentEventHandler::new_with_capacity(
log.clone(),
1,
)))
.execution_layer(Some(mock.el))
.kzg(kzg)
.build()
.expect("should build");
let beacon_chain = Arc::new(beacon_chain);
let current_state = harness.get_current_state();
if ForkName::Electra == current_state.fork_name_unchecked() {
// TODO(electra) fix beacon state `compute_merkle_proof`
return;
}
let block_root = *current_state
.get_block_root(current_state.slot() - Slot::new(1))
.unwrap();
let contributions = harness.make_sync_contributions(
&current_state,
block_root,
current_state.slot() - Slot::new(1),
RelativeSyncCommittee::Current,
);
// generate sync aggregates
for (_, contribution_and_proof) in contributions {
let contribution = contribution_and_proof
.expect("contribution exists for committee")
.message
.contribution;
beacon_chain
.op_pool
.insert_sync_contribution(contribution.clone())
.unwrap();
beacon_chain
.op_pool
.insert_sync_contribution(contribution)
.unwrap();
}
// check that we can fetch the newly generated sync aggregate
let sync_aggregate = beacon_chain
.op_pool
.get_sync_aggregate(&current_state)
.unwrap()
.unwrap();
// cache light client data
beacon_chain
.light_client_server_cache
.recompute_and_cache_updates(
store.clone(),
current_state.slot() - Slot::new(1),
&block_root,
&sync_aggregate,
&log,
&spec,
)
.unwrap();
// calculate the sync period from the previous slot
let sync_period = (current_state.slot() - Slot::new(1))
.epoch(E::slots_per_epoch())
.sync_committee_period(&spec)
.unwrap();
// fetch a range of light client updates. right now there should only be one light client update
// in the db.
let lc_updates = beacon_chain
.get_light_client_updates(sync_period, 100)
.unwrap();
assert_eq!(lc_updates.len(), 1);
// Advance to the next sync committee period
for _i in 0..(E::slots_per_epoch() * u64::from(spec.epochs_per_sync_committee_period)) {
harness.advance_slot();
}
harness
.extend_chain(
num_final_blocks as usize,
BlockStrategy::OnCanonicalHead,
AttestationStrategy::AllValidators,
)
.await;
let current_state = harness.get_current_state();
let block_root = *current_state
.get_block_root(current_state.slot() - Slot::new(1))
.unwrap();
let contributions = harness.make_sync_contributions(
&current_state,
block_root,
current_state.slot() - Slot::new(1),
RelativeSyncCommittee::Current,
);
// generate new sync aggregates from this new state
for (_, contribution_and_proof) in contributions {
let contribution = contribution_and_proof
.expect("contribution exists for committee")
.message
.contribution;
beacon_chain
.op_pool
.insert_sync_contribution(contribution.clone())
.unwrap();
beacon_chain
.op_pool
.insert_sync_contribution(contribution)
.unwrap();
}
let sync_aggregate = beacon_chain
.op_pool
.get_sync_aggregate(&current_state)
.unwrap()
.unwrap();
// cache new light client data
beacon_chain
.light_client_server_cache
.recompute_and_cache_updates(
store.clone(),
current_state.slot() - Slot::new(1),
&block_root,
&sync_aggregate,
&log,
&spec,
)
.unwrap();
// we should now have two light client updates in the db
let lc_updates = beacon_chain
.get_light_client_updates(sync_period, 100)
.unwrap();
assert_eq!(lc_updates.len(), 2);
}
/// Tests that `store.heal_freezer_block_roots_at_split` inserts block roots between last restore point
/// slot and the split slot.
#[tokio::test]
async fn heal_freezer_block_roots_at_split() {
// chunk_size is hard-coded to 128
let num_blocks_produced = E::slots_per_epoch() * 20;
let db_path = tempdir().unwrap();
let store = get_store_generic(
&db_path,
StoreConfig {
slots_per_restore_point: 2 * E::slots_per_epoch(),
..Default::default()
},
test_spec::<E>(),
);
let harness = get_harness(store.clone(), LOW_VALIDATOR_COUNT);
harness
.extend_chain(
num_blocks_produced as usize,
BlockStrategy::OnCanonicalHead,
AttestationStrategy::AllValidators,
)
.await;
let split_slot = store.get_split_slot();
assert_eq!(split_slot, 18 * E::slots_per_epoch());
// Do a heal before deleting to make sure that it doesn't break.
let last_restore_point_slot = Slot::new(16 * E::slots_per_epoch());
store.heal_freezer_block_roots_at_split().unwrap();
check_freezer_block_roots(&harness, last_restore_point_slot, split_slot);
// Delete block roots between `last_restore_point_slot` and `split_slot`.
let chunk_index = <store::chunked_vector::BlockRoots as Field<E>>::chunk_index(
last_restore_point_slot.as_usize(),
);
let key_chunk = get_key_for_col(DBColumn::BeaconBlockRoots.as_str(), &chunk_key(chunk_index));
store
.cold_db
.do_atomically(vec![KeyValueStoreOp::DeleteKey(key_chunk)])
.unwrap();
let block_root_err = store
.forwards_block_roots_iterator_until(
last_restore_point_slot,
last_restore_point_slot + 1,
|| unreachable!(),
&harness.chain.spec,
)
.unwrap()
.next()
.unwrap()
.unwrap_err();
assert!(matches!(block_root_err, store::Error::NoContinuationData));
// Re-insert block roots
store.heal_freezer_block_roots_at_split().unwrap();
check_freezer_block_roots(&harness, last_restore_point_slot, split_slot);
// Run for another two epochs to check that the invariant is maintained.
let additional_blocks_produced = 2 * E::slots_per_epoch();
harness
.extend_slots(additional_blocks_produced as usize)
.await;
check_finalization(&harness, num_blocks_produced + additional_blocks_produced);
check_split_slot(&harness, store);
check_chain_dump(
&harness,
num_blocks_produced + additional_blocks_produced + 1,
);
check_iterators(&harness);
}
/// Tests that `store.heal_freezer_block_roots` inserts block roots between last restore point
/// slot and the split slot.
#[tokio::test]
async fn heal_freezer_block_roots_with_skip_slots() {
// chunk_size is hard-coded to 128
let num_blocks_produced = E::slots_per_epoch() * 20;
let db_path = tempdir().unwrap();
let store = get_store_generic(
&db_path,
StoreConfig {
slots_per_restore_point: 2 * E::slots_per_epoch(),
..Default::default()
},
test_spec::<E>(),
);
let harness = get_harness(store.clone(), LOW_VALIDATOR_COUNT);
let mut current_state = harness.get_current_state();
let state_root = current_state.canonical_root().unwrap();
let all_validators = &harness.get_all_validators();
harness
.add_attested_blocks_at_slots(
current_state,
state_root,
&(1..=num_blocks_produced)
.filter(|i| i % 12 != 0)
.map(Slot::new)
.collect::<Vec<_>>(),
all_validators,
)
.await;
// split slot should be 18 here
let split_slot = store.get_split_slot();
assert_eq!(split_slot, 18 * E::slots_per_epoch());
let last_restore_point_slot = Slot::new(16 * E::slots_per_epoch());
let chunk_index = <store::chunked_vector::BlockRoots as Field<E>>::chunk_index(
last_restore_point_slot.as_usize(),
);
let key_chunk = get_key_for_col(DBColumn::BeaconBlockRoots.as_str(), &chunk_key(chunk_index));
store
.cold_db
.do_atomically(vec![KeyValueStoreOp::DeleteKey(key_chunk)])
.unwrap();
let block_root_err = store
.forwards_block_roots_iterator_until(
last_restore_point_slot,
last_restore_point_slot + 1,
|| unreachable!(),
&harness.chain.spec,
)
.unwrap()
.next()
.unwrap()
.unwrap_err();
assert!(matches!(block_root_err, store::Error::NoContinuationData));
// heal function
store.heal_freezer_block_roots_at_split().unwrap();
check_freezer_block_roots(&harness, last_restore_point_slot, split_slot);
// Run for another two epochs to check that the invariant is maintained.
let additional_blocks_produced = 2 * E::slots_per_epoch();
harness
.extend_slots(additional_blocks_produced as usize)
.await;
check_finalization(&harness, num_blocks_produced + additional_blocks_produced);
check_split_slot(&harness, store);
check_iterators(&harness);
}
/// Tests that `store.heal_freezer_block_roots_at_genesis` replaces 0x0 block roots between slot
/// 0 and the first non-skip slot with genesis block root.
#[tokio::test]
async fn heal_freezer_block_roots_at_genesis() {
// Run for a few epochs to ensure we're past finalization.
let num_blocks_produced = E::slots_per_epoch() * 4;
let db_path = tempdir().unwrap();
let store = get_store(&db_path);
let harness = get_harness(store.clone(), LOW_VALIDATOR_COUNT);
// Start with 2 skip slots.
harness.advance_slot();
harness.advance_slot();
harness
.extend_chain(
num_blocks_produced as usize,
BlockStrategy::OnCanonicalHead,
AttestationStrategy::AllValidators,
)
.await;
// Do a heal before deleting to make sure that it doesn't break.
store.heal_freezer_block_roots_at_genesis().unwrap();
check_freezer_block_roots(
&harness,
Slot::new(0),
Epoch::new(1).end_slot(E::slots_per_epoch()),
);
// Write 0x0 block roots at slot 1 and slot 2.
let chunk_index = 0;
let chunk_db_key = chunk_key(chunk_index);
let mut chunk =
Chunk::<Hash256>::load(&store.cold_db, DBColumn::BeaconBlockRoots, &chunk_db_key)
.unwrap()
.unwrap();
chunk.values[1] = Hash256::zero();
chunk.values[2] = Hash256::zero();
let mut ops = vec![];
chunk
.store(DBColumn::BeaconBlockRoots, &chunk_db_key, &mut ops)
.unwrap();
store.cold_db.do_atomically(ops).unwrap();
// Ensure the DB is corrupted
let block_roots = store
.forwards_block_roots_iterator_until(
Slot::new(1),
Slot::new(2),
|| unreachable!(),
&harness.chain.spec,
)
.unwrap()
.map(Result::unwrap)
.take(2)
.collect::<Vec<_>>();
assert_eq!(
block_roots,
vec![
(Hash256::zero(), Slot::new(1)),
(Hash256::zero(), Slot::new(2))
]
);
// Insert genesis block roots at skip slots before first block slot
store.heal_freezer_block_roots_at_genesis().unwrap();
check_freezer_block_roots(
&harness,
Slot::new(0),
Epoch::new(1).end_slot(E::slots_per_epoch()),
);
}
fn check_freezer_block_roots(harness: &TestHarness, start_slot: Slot, end_slot: Slot) {
for slot in (start_slot.as_u64()..end_slot.as_u64()).map(Slot::new) {
let (block_root, result_slot) = harness
.chain
.store
.forwards_block_roots_iterator_until(slot, slot, || unreachable!(), &harness.chain.spec)
.unwrap()
.next()
.unwrap()
.unwrap();
assert_eq!(slot, result_slot);
let expected_block_root = harness
.chain
.block_root_at_slot(slot, WhenSlotSkipped::Prev)
.unwrap()
.unwrap();
assert_eq!(expected_block_root, block_root);
}
}
#[tokio::test]
async fn full_participation_no_skips() {
let num_blocks_produced = E::slots_per_epoch() * 5;
let db_path = tempdir().unwrap();
let store = get_store(&db_path);
let harness = get_harness(store.clone(), LOW_VALIDATOR_COUNT);
harness
.extend_chain(
num_blocks_produced as usize,
BlockStrategy::OnCanonicalHead,
AttestationStrategy::AllValidators,
)
.await;
check_finalization(&harness, num_blocks_produced);
check_split_slot(&harness, store);
check_chain_dump(&harness, num_blocks_produced + 1);
check_iterators(&harness);
}
#[tokio::test]
async fn randomised_skips() {
let num_slots = E::slots_per_epoch() * 5;
let mut num_blocks_produced = 0;
let db_path = tempdir().unwrap();
let store = get_store(&db_path);
let harness = get_harness(store.clone(), LOW_VALIDATOR_COUNT);
let rng = &mut XorShiftRng::from_seed([42; 16]);
let mut head_slot = 0;
for slot in 1..=num_slots {
if rng.gen_bool(0.8) {
harness
.extend_chain(
1,
BlockStrategy::ForkCanonicalChainAt {
previous_slot: Slot::new(head_slot),
first_slot: Slot::new(slot),
},
AttestationStrategy::AllValidators,
)
.await;
harness.advance_slot();
num_blocks_produced += 1;
head_slot = slot;
} else {
harness.advance_slot();
}
}
let state = &harness.chain.head_snapshot().beacon_state;
assert_eq!(
state.slot(),
num_slots,
"head should be at the current slot"
);
check_split_slot(&harness, store.clone());
check_chain_dump(&harness, num_blocks_produced + 1);
check_iterators(&harness);
}
#[tokio::test]
async fn long_skip() {
let db_path = tempdir().unwrap();
let store = get_store(&db_path);
let harness = get_harness(store.clone(), LOW_VALIDATOR_COUNT);
// Number of blocks to create in the first run, intentionally not falling on an epoch
// boundary in order to check that the DB hot -> cold migration is capable of reaching
// back across the skip distance, and correctly migrating those extra non-finalized states.
let initial_blocks = E::slots_per_epoch() * 5 + E::slots_per_epoch() / 2;
let skip_slots = E::slots_per_historical_root() as u64 * 8;
// Create the minimum ~2.5 epochs of extra blocks required to re-finalize the chain.
// Having this set lower ensures that we start justifying and finalizing quickly after a skip.
let final_blocks = 2 * E::slots_per_epoch() + E::slots_per_epoch() / 2;
harness
.extend_chain(
initial_blocks as usize,
BlockStrategy::OnCanonicalHead,
AttestationStrategy::AllValidators,
)
.await;
check_finalization(&harness, initial_blocks);
// 2. Skip slots
for _ in 0..skip_slots {
harness.advance_slot();
}
// 3. Produce more blocks, establish a new finalized epoch
harness
.extend_chain(
final_blocks as usize,
BlockStrategy::ForkCanonicalChainAt {
previous_slot: Slot::new(initial_blocks),
first_slot: Slot::new(initial_blocks + skip_slots as u64 + 1),
},
AttestationStrategy::AllValidators,
)
.await;
check_finalization(&harness, initial_blocks + skip_slots + final_blocks);
check_split_slot(&harness, store);
check_chain_dump(&harness, initial_blocks + final_blocks + 1);
check_iterators(&harness);
}
/// Go forward to the point where the genesis randao value is no longer part of the vector.
///
/// This implicitly checks that:
/// 1. The chunked vector scheme doesn't attempt to store an incorrect genesis value
/// 2. We correctly load the genesis value for all required slots
/// NOTE: this test takes about a minute to run
#[tokio::test]
async fn randao_genesis_storage() {
let validator_count = 8;
let db_path = tempdir().unwrap();
let store = get_store(&db_path);
let harness = get_harness(store.clone(), validator_count);
let num_slots = E::slots_per_epoch() * (E::epochs_per_historical_vector() - 1) as u64;
// Check we have a non-trivial genesis value
let genesis_value = *harness
.chain
.head_snapshot()
.beacon_state
.get_randao_mix(Epoch::new(0))
.expect("randao mix ok");
assert!(!genesis_value.is_zero());
harness
.extend_chain(
num_slots as usize - 1,
BlockStrategy::OnCanonicalHead,
AttestationStrategy::AllValidators,
)
.await;
// Check that genesis value is still present
assert!(harness
.chain
.head_snapshot()
.beacon_state
.randao_mixes()
.iter()
.find(|x| **x == genesis_value)
.is_some());
// Then upon adding one more block, it isn't
harness.advance_slot();
harness
.extend_chain(
1,
BlockStrategy::OnCanonicalHead,
AttestationStrategy::AllValidators,
)
.await;
assert!(harness
.chain
.head_snapshot()
.beacon_state
.randao_mixes()
.iter()
.find(|x| **x == genesis_value)
.is_none());
check_finalization(&harness, num_slots);
check_split_slot(&harness, store);
check_chain_dump(&harness, num_slots + 1);
check_iterators(&harness);
}
// Check that closing and reopening a freezer DB restores the split slot to its correct value.
#[tokio::test]
async fn split_slot_restore() {
let db_path = tempdir().unwrap();
let split_slot = {
let store = get_store(&db_path);
let harness = get_harness(store.clone(), LOW_VALIDATOR_COUNT);
let num_blocks = 4 * E::slots_per_epoch();
harness
.extend_chain(
num_blocks as usize,
BlockStrategy::OnCanonicalHead,
AttestationStrategy::AllValidators,
)
.await;
store.get_split_slot()
};
assert_ne!(split_slot, Slot::new(0));
// Re-open the store
let store = get_store(&db_path);
assert_eq!(store.get_split_slot(), split_slot);
}
// Check attestation processing and `load_epoch_boundary_state` in the presence of a split DB.
// This is a bit of a monster test in that it tests lots of different things, but until they're
// tested elsewhere, this is as good a place as any.
#[tokio::test]
async fn epoch_boundary_state_attestation_processing() {
let num_blocks_produced = E::slots_per_epoch() * 5;
let db_path = tempdir().unwrap();
let store = get_store(&db_path);
let harness = get_harness(store.clone(), LOW_VALIDATOR_COUNT);
let late_validators = vec![0, 1];
let timely_validators = (2..LOW_VALIDATOR_COUNT).collect::<Vec<_>>();
let mut late_attestations = vec![];
for _ in 0..num_blocks_produced {
harness
.extend_chain(
1,
BlockStrategy::OnCanonicalHead,
AttestationStrategy::SomeValidators(timely_validators.clone()),
)
.await;
let head = harness.chain.head_snapshot();
late_attestations.extend(harness.get_unaggregated_attestations(
&AttestationStrategy::SomeValidators(late_validators.clone()),
&head.beacon_state,
head.beacon_state_root(),
head.beacon_block_root,
head.beacon_block.slot(),
));
harness.advance_slot();
}
check_finalization(&harness, num_blocks_produced);
check_split_slot(&harness, store.clone());
check_chain_dump(&harness, num_blocks_produced + 1);
check_iterators(&harness);
let mut checked_pre_fin = false;
for (attestation, subnet_id) in late_attestations.into_iter().flatten() {
// load_epoch_boundary_state is idempotent!
let block_root = attestation.data().beacon_block_root;
let block = store
.get_blinded_block(&block_root)
.unwrap()
.expect("block exists");
let mut epoch_boundary_state = store
.load_epoch_boundary_state(&block.state_root())
.expect("no error")
.expect("epoch boundary state exists");
let ebs_state_root = epoch_boundary_state.canonical_root().unwrap();
let ebs_of_ebs = store
.load_epoch_boundary_state(&ebs_state_root)
.expect("no error")
.expect("ebs of ebs exists");
assert_eq!(epoch_boundary_state, ebs_of_ebs);
// If the attestation is pre-finalization it should be rejected.
let finalized_epoch = harness.finalized_checkpoint().epoch;
let res = harness
.chain
.verify_unaggregated_attestation_for_gossip(&attestation, Some(subnet_id));
let current_slot = harness.chain.slot().expect("should get slot");
let expected_attestation_slot = attestation.data().slot;
// Extra -1 to handle gossip clock disparity.
let expected_earliest_permissible_slot = current_slot - E::slots_per_epoch() - 1;
if expected_attestation_slot <= finalized_epoch.start_slot(E::slots_per_epoch())
|| expected_attestation_slot < expected_earliest_permissible_slot
{
checked_pre_fin = true;
assert!(matches!(
res.err().unwrap(),
AttnError::PastSlot {
attestation_slot,
earliest_permissible_slot,
}
if attestation_slot == expected_attestation_slot && earliest_permissible_slot == expected_earliest_permissible_slot
));
} else {
res.expect("should have verified attetation");
}
}
assert!(checked_pre_fin);
}
// Test that the `end_slot` for forwards block and state root iterators works correctly.
#[tokio::test]
async fn forwards_iter_block_and_state_roots_until() {
let num_blocks_produced = E::slots_per_epoch() * 17;
let db_path = tempdir().unwrap();
let store = get_store(&db_path);
let harness = get_harness(store.clone(), LOW_VALIDATOR_COUNT);
let all_validators = &harness.get_all_validators();
let (mut head_state, mut head_state_root) = harness.get_current_state_and_root();
let head_block_root = harness.head_block_root();
let mut block_roots = vec![head_block_root];
let mut state_roots = vec![head_state_root];
for slot in (1..=num_blocks_produced).map(Slot::from) {
let (block_root, mut state) = harness
.add_attested_block_at_slot(slot, head_state, head_state_root, all_validators)
.await
.unwrap();
head_state_root = state.update_tree_hash_cache().unwrap();
head_state = state;
block_roots.push(block_root.into());
state_roots.push(head_state_root);
}
check_finalization(&harness, num_blocks_produced);
check_split_slot(&harness, store.clone());
// The last restore point slot is the point at which the hybrid forwards iterator behaviour
// changes.
let last_restore_point_slot = store.get_latest_restore_point_slot().unwrap();
assert!(last_restore_point_slot > 0);
let chain = &harness.chain;
let head_state = harness.get_current_state();
let head_slot = head_state.slot();
assert_eq!(head_slot, num_blocks_produced);
let test_range = |start_slot: Slot, end_slot: Slot| {
let mut block_root_iter = chain
.forwards_iter_block_roots_until(start_slot, end_slot)
.unwrap();
let mut state_root_iter = chain
.forwards_iter_state_roots_until(start_slot, end_slot)
.unwrap();
for slot in (start_slot.as_u64()..=end_slot.as_u64()).map(Slot::new) {
let block_root = block_roots[slot.as_usize()];
assert_eq!(block_root_iter.next().unwrap().unwrap(), (block_root, slot));
let state_root = state_roots[slot.as_usize()];
assert_eq!(state_root_iter.next().unwrap().unwrap(), (state_root, slot));
}
};
let split_slot = store.get_split_slot();
assert!(split_slot > last_restore_point_slot);
test_range(Slot::new(0), last_restore_point_slot);
test_range(last_restore_point_slot, last_restore_point_slot);
test_range(last_restore_point_slot - 1, last_restore_point_slot);
test_range(Slot::new(0), last_restore_point_slot - 1);
test_range(Slot::new(0), split_slot);
test_range(last_restore_point_slot - 1, split_slot);
test_range(Slot::new(0), head_state.slot());
}
#[tokio::test]
async fn block_replayer_hooks() {
let db_path = tempdir().unwrap();
let store = get_store(&db_path);
let harness = get_harness(store.clone(), LOW_VALIDATOR_COUNT);
let chain = &harness.chain;
let block_slots = vec![1, 3, 5, 10, 11, 12, 13, 14, 31, 32, 33]
.into_iter()
.map(Slot::new)
.collect::<Vec<_>>();
let max_slot = *block_slots.last().unwrap();
let all_slots = (0..=max_slot.as_u64()).map(Slot::new).collect::<Vec<_>>();
let (state, state_root) = harness.get_current_state_and_root();
let all_validators = harness.get_all_validators();
let (_, _, end_block_root, mut end_state) = harness
.add_attested_blocks_at_slots(state.clone(), state_root, &block_slots, &all_validators)
.await;
let blocks = store
.load_blocks_to_replay(Slot::new(0), max_slot, end_block_root.into())
.unwrap();
let mut pre_slots = vec![];
let mut post_slots = vec![];
let mut pre_block_slots = vec![];
let mut post_block_slots = vec![];
let mut replay_state = BlockReplayer::<MinimalEthSpec>::new(state, &chain.spec)
.pre_slot_hook(Box::new(|_, state| {
pre_slots.push(state.slot());
Ok(())
}))
.post_slot_hook(Box::new(|state, epoch_summary, is_skip_slot| {
if is_skip_slot {
assert!(!block_slots.contains(&state.slot()));
} else {
assert!(block_slots.contains(&state.slot()));
}
if state.slot() % E::slots_per_epoch() == 0 {
assert!(epoch_summary.is_some());
}
post_slots.push(state.slot());
Ok(())
}))
.pre_block_hook(Box::new(|state, block| {
assert_eq!(state.slot(), block.slot());
pre_block_slots.push(block.slot());
Ok(())
}))
.post_block_hook(Box::new(|state, block| {
assert_eq!(state.slot(), block.slot());
post_block_slots.push(block.slot());
Ok(())
}))
.apply_blocks(blocks, None)
.unwrap()
.into_state();
// All but last slot seen by pre-slot hook
assert_eq!(&pre_slots, all_slots.split_last().unwrap().1);
// All but 0th slot seen by post-slot hook
assert_eq!(&post_slots, all_slots.split_first().unwrap().1);
// All blocks seen by both hooks
assert_eq!(pre_block_slots, block_slots);
assert_eq!(post_block_slots, block_slots);
// States match.
end_state.apply_pending_mutations().unwrap();
replay_state.apply_pending_mutations().unwrap();
end_state.drop_all_caches().unwrap();
replay_state.drop_all_caches().unwrap();
assert_eq!(end_state, replay_state);
}
#[tokio::test]
async fn delete_blocks_and_states() {
let db_path = tempdir().unwrap();
let store = get_store(&db_path);
let harness = get_harness(store.clone(), LOW_VALIDATOR_COUNT);
let unforked_blocks: u64 = 4 * E::slots_per_epoch();
// Finalize an initial portion of the chain.
let initial_slots: Vec<Slot> = (1..=unforked_blocks).map(Into::into).collect();
let (state, state_root) = harness.get_current_state_and_root();
let all_validators = harness.get_all_validators();
harness
.add_attested_blocks_at_slots(state, state_root, &initial_slots, &all_validators)
.await;
// Create a fork post-finalization.
let two_thirds = (LOW_VALIDATOR_COUNT / 3) * 2;
let honest_validators: Vec<usize> = (0..two_thirds).collect();
let faulty_validators: Vec<usize> = (two_thirds..LOW_VALIDATOR_COUNT).collect();
let fork_blocks = 2 * E::slots_per_epoch();
let slot_u64: u64 = harness.get_current_slot().as_u64() + 1;
let fork1_slots: Vec<Slot> = (slot_u64..(slot_u64 + fork_blocks))
.map(Into::into)
.collect();
let fork2_slots: Vec<Slot> = (slot_u64 + 1..(slot_u64 + 1 + fork_blocks))
.map(Into::into)
.collect();
let fork1_state = harness.get_current_state();
let fork2_state = fork1_state.clone();
let results = harness
.add_blocks_on_multiple_chains(vec![
(fork1_state, fork1_slots, honest_validators),
(fork2_state, fork2_slots, faulty_validators),
])
.await;
let honest_head = results[0].2;
let faulty_head = results[1].2;
assert_ne!(honest_head, faulty_head, "forks should be distinct");
assert_eq!(harness.head_slot(), unforked_blocks + fork_blocks);
assert_eq!(
harness.head_block_root(),
honest_head.into(),
"the honest chain should be the canonical chain",
);
let faulty_head_block = store
.get_blinded_block(&faulty_head.into())
.expect("no errors")
.expect("faulty head block exists");
let faulty_head_state = store
.get_state(
&faulty_head_block.state_root(),
Some(faulty_head_block.slot()),
)
.expect("no db error")
.expect("faulty head state exists");
// Delete faulty fork
// Attempting to load those states should find them unavailable
for (state_root, slot) in
StateRootsIterator::new(&store, &faulty_head_state).map(Result::unwrap)
{
if slot <= unforked_blocks {
break;
}
store.delete_state(&state_root, slot).unwrap();
assert_eq!(store.get_state(&state_root, Some(slot)).unwrap(), None);
}
// Double-deleting should also be OK (deleting non-existent things is fine)
for (state_root, slot) in
StateRootsIterator::new(&store, &faulty_head_state).map(Result::unwrap)
{
if slot <= unforked_blocks {
break;
}
store.delete_state(&state_root, slot).unwrap();
}
// Deleting the blocks from the fork should remove them completely
for (block_root, slot) in
BlockRootsIterator::new(&store, &faulty_head_state).map(Result::unwrap)
{
if slot <= unforked_blocks + 1 {
break;
}
store.delete_block(&block_root).unwrap();
assert_eq!(store.get_blinded_block(&block_root).unwrap(), None);
}
// Deleting frozen states should do nothing
let split_slot = store.get_split_slot();
let finalized_states = harness
.chain
.forwards_iter_state_roots(Slot::new(0))
.expect("should get iter")
.map(Result::unwrap);
for (state_root, slot) in finalized_states {
if slot < split_slot {
store.delete_state(&state_root, slot).unwrap();
}
}
// After all that, the chain dump should still be OK
check_chain_dump(&harness, unforked_blocks + fork_blocks + 1);
}
// Check that we never produce invalid blocks when there is deep forking that changes the shuffling.
// See https://github.com/sigp/lighthouse/issues/845
async fn multi_epoch_fork_valid_blocks_test(
initial_blocks: usize,
num_fork1_blocks_: usize,
num_fork2_blocks_: usize,
num_fork1_validators: usize,
) -> (TempDir, TestHarness, Hash256, Hash256) {
let db_path = tempdir().unwrap();
let store = get_store(&db_path);
let validators_keypairs =
types::test_utils::generate_deterministic_keypairs(LOW_VALIDATOR_COUNT);
let harness = TestHarness::builder(MinimalEthSpec)
.default_spec()
.keypairs(validators_keypairs)
.fresh_disk_store(store)
.mock_execution_layer()
.build();
let num_fork1_blocks: u64 = num_fork1_blocks_.try_into().unwrap();
let num_fork2_blocks: u64 = num_fork2_blocks_.try_into().unwrap();
// Create the initial portion of the chain
if initial_blocks > 0 {
let initial_slots: Vec<Slot> = (1..=initial_blocks).map(Into::into).collect();
let (state, state_root) = harness.get_current_state_and_root();
let all_validators = harness.get_all_validators();
harness
.add_attested_blocks_at_slots(state, state_root, &initial_slots, &all_validators)
.await;
}
assert!(num_fork1_validators <= LOW_VALIDATOR_COUNT);
let fork1_validators: Vec<usize> = (0..num_fork1_validators).collect();
let fork2_validators: Vec<usize> = (num_fork1_validators..LOW_VALIDATOR_COUNT).collect();
let fork1_state = harness.get_current_state();
let fork2_state = fork1_state.clone();
let slot_u64: u64 = harness.get_current_slot().as_u64() + 1;
let fork1_slots: Vec<Slot> = (slot_u64..(slot_u64 + num_fork1_blocks))
.map(Into::into)
.collect();
let fork2_slots: Vec<Slot> = (slot_u64 + 1..(slot_u64 + 1 + num_fork2_blocks))
.map(Into::into)
.collect();
let results = harness
.add_blocks_on_multiple_chains(vec![
(fork1_state, fork1_slots, fork1_validators),
(fork2_state, fork2_slots, fork2_validators),
])
.await;
let head1 = results[0].2;
let head2 = results[1].2;
(db_path, harness, head1.into(), head2.into())
}
// This is the minimal test of block production with different shufflings.
#[tokio::test]
async fn block_production_different_shuffling_early() {
let slots_per_epoch = E::slots_per_epoch() as usize;
multi_epoch_fork_valid_blocks_test(
slots_per_epoch - 2,
slots_per_epoch + 3,
slots_per_epoch + 3,
LOW_VALIDATOR_COUNT / 2,
)
.await;
}
#[tokio::test]
async fn block_production_different_shuffling_long() {
let slots_per_epoch = E::slots_per_epoch() as usize;
multi_epoch_fork_valid_blocks_test(
2 * slots_per_epoch - 2,
3 * slots_per_epoch,
3 * slots_per_epoch,
LOW_VALIDATOR_COUNT / 2,
)
.await;
}
// Check that the op pool safely includes multiple attestations per block when necessary.
// This checks the correctness of the shuffling compatibility memoization.
#[tokio::test]
async fn multiple_attestations_per_block() {
let db_path = tempdir().unwrap();
let store = get_store(&db_path);
let harness = get_harness(store, HIGH_VALIDATOR_COUNT);
harness
.extend_chain(
E::slots_per_epoch() as usize * 3,
BlockStrategy::OnCanonicalHead,
AttestationStrategy::AllValidators,
)
.await;
let head = harness.chain.head_snapshot();
let committees_per_slot = head
.beacon_state
.get_committee_count_at_slot(head.beacon_state.slot())
.unwrap();
assert!(committees_per_slot > 1);
for snapshot in harness.chain.chain_dump().unwrap() {
let slot = snapshot.beacon_block.slot();
let fork_name = harness.chain.spec.fork_name_at_slot::<E>(slot);
if fork_name.electra_enabled() {
assert_eq!(
snapshot
.beacon_block
.as_ref()
.message()
.body()
.attestations_len() as u64,
if slot <= 1 { 0 } else { 1 }
);
} else {
assert_eq!(
snapshot
.beacon_block
.as_ref()
.message()
.body()
.attestations_len() as u64,
if slot <= 1 { 0 } else { committees_per_slot }
);
}
}
}
#[tokio::test]
async fn shuffling_compatible_linear_chain() {
let db_path = tempdir().unwrap();
let store = get_store(&db_path);
let harness = get_harness(store.clone(), LOW_VALIDATOR_COUNT);
let head_block_root = harness
.extend_chain(
4 * E::slots_per_epoch() as usize,
BlockStrategy::OnCanonicalHead,
AttestationStrategy::AllValidators,
)
.await;
check_shuffling_compatible(
&harness,
&get_state_for_block(&harness, head_block_root),
head_block_root,
);
}
#[tokio::test]
async fn shuffling_compatible_missing_pivot_block() {
let db_path = tempdir().unwrap();
let store = get_store(&db_path);
let harness = get_harness(store.clone(), LOW_VALIDATOR_COUNT);
// Skip the block at the end of the first epoch.
harness
.extend_chain(
E::slots_per_epoch() as usize - 2,
BlockStrategy::OnCanonicalHead,
AttestationStrategy::AllValidators,
)
.await;
harness.advance_slot();
harness.advance_slot();
let head_block_root = harness
.extend_chain(
2 * E::slots_per_epoch() as usize,
BlockStrategy::OnCanonicalHead,
AttestationStrategy::AllValidators,
)
.await;
check_shuffling_compatible(
&harness,
&get_state_for_block(&harness, head_block_root),
head_block_root,
);
}
#[tokio::test]
async fn shuffling_compatible_simple_fork() {
let slots_per_epoch = E::slots_per_epoch() as usize;
let (db_path, harness, head1, head2) = multi_epoch_fork_valid_blocks_test(
2 * slots_per_epoch,
3 * slots_per_epoch,
3 * slots_per_epoch,
LOW_VALIDATOR_COUNT / 2,
)
.await;
let head1_state = get_state_for_block(&harness, head1);
let head2_state = get_state_for_block(&harness, head2);
check_shuffling_compatible(&harness, &head1_state, head1);
check_shuffling_compatible(&harness, &head1_state, head2);
check_shuffling_compatible(&harness, &head2_state, head1);
check_shuffling_compatible(&harness, &head2_state, head2);
drop(db_path);
}
#[tokio::test]
async fn shuffling_compatible_short_fork() {
let slots_per_epoch = E::slots_per_epoch() as usize;
let (db_path, harness, head1, head2) = multi_epoch_fork_valid_blocks_test(
2 * slots_per_epoch - 2,
slots_per_epoch + 2,
slots_per_epoch + 2,
LOW_VALIDATOR_COUNT / 2,
)
.await;
let head1_state = get_state_for_block(&harness, head1);
let head2_state = get_state_for_block(&harness, head2);
check_shuffling_compatible(&harness, &head1_state, head1);
check_shuffling_compatible(&harness, &head1_state, head2);
check_shuffling_compatible(&harness, &head2_state, head1);
check_shuffling_compatible(&harness, &head2_state, head2);
drop(db_path);
}
fn get_state_for_block(harness: &TestHarness, block_root: Hash256) -> BeaconState<E> {
let head_block = harness
.chain
.store
.get_blinded_block(&block_root)
.unwrap()
.unwrap();
harness
.chain
.get_state(&head_block.state_root(), Some(head_block.slot()))
.unwrap()
.unwrap()
}
/// Check the invariants that apply to `shuffling_is_compatible`.
fn check_shuffling_compatible(
harness: &TestHarness,
head_state: &BeaconState<E>,
head_block_root: Hash256,
) {
for maybe_tuple in harness
.chain
.rev_iter_block_roots_from(head_block_root)
.unwrap()
{
let (block_root, slot) = maybe_tuple.unwrap();
// Would an attestation to `block_root` at the current epoch be compatible with the head
// state's shuffling?
let current_epoch_shuffling_is_compatible = harness.chain.shuffling_is_compatible(
&block_root,
head_state.current_epoch(),
&head_state,
);
// Check for consistency with the more expensive shuffling lookup.
harness
.chain
.with_committee_cache(
block_root,
head_state.current_epoch(),
|committee_cache, _| {
let state_cache = head_state.committee_cache(RelativeEpoch::Current).unwrap();
// We used to check for false negatives here, but had to remove that check
// because `shuffling_is_compatible` does not guarantee their absence.
//
// See: https://github.com/sigp/lighthouse/issues/6269
if current_epoch_shuffling_is_compatible {
assert_eq!(
committee_cache,
state_cache.as_ref(),
"block at slot {slot}"
);
}
Ok(())
},
)
.unwrap_or_else(|e| {
// If the lookup fails then the shuffling must be invalid in some way, e.g. the
// block with `block_root` is from a later epoch than `previous_epoch`.
assert!(
!current_epoch_shuffling_is_compatible,
"block at slot {slot} has compatible shuffling at epoch {} \
but should be incompatible due to error: {e:?}",
head_state.current_epoch()
);
});
// Similarly for the previous epoch
let previous_epoch_shuffling_is_compatible = harness.chain.shuffling_is_compatible(
&block_root,
head_state.previous_epoch(),
&head_state,
);
harness
.chain
.with_committee_cache(
block_root,
head_state.previous_epoch(),
|committee_cache, _| {
let state_cache = head_state.committee_cache(RelativeEpoch::Previous).unwrap();
if previous_epoch_shuffling_is_compatible {
assert_eq!(committee_cache, state_cache.as_ref());
}
Ok(())
},
)
.unwrap_or_else(|e| {
// If the lookup fails then the shuffling must be invalid in some way, e.g. the
// block with `block_root` is from a later epoch than `previous_epoch`.
assert!(
!previous_epoch_shuffling_is_compatible,
"block at slot {slot} has compatible shuffling at epoch {} \
but should be incompatible due to error: {e:?}",
head_state.previous_epoch()
);
});
// Targeting two epochs before the current epoch should always return false
if head_state.current_epoch() >= 2 {
assert_eq!(
harness.chain.shuffling_is_compatible(
&block_root,
head_state.current_epoch() - 2,
&head_state
),
false
);
}
}
}
// Ensure blocks from abandoned forks are pruned from the Hot DB
#[tokio::test]
async fn prunes_abandoned_fork_between_two_finalized_checkpoints() {
const HONEST_VALIDATOR_COUNT: usize = 32;
const ADVERSARIAL_VALIDATOR_COUNT: usize = 16;
const VALIDATOR_COUNT: usize = HONEST_VALIDATOR_COUNT + ADVERSARIAL_VALIDATOR_COUNT;
let honest_validators: Vec<usize> = (0..HONEST_VALIDATOR_COUNT).collect();
let adversarial_validators: Vec<usize> = (HONEST_VALIDATOR_COUNT..VALIDATOR_COUNT).collect();
let db_path = tempdir().unwrap();
let store = get_store(&db_path);
let rig = get_harness(store.clone(), VALIDATOR_COUNT);
let slots_per_epoch = rig.slots_per_epoch();
let (mut state, state_root) = rig.get_current_state_and_root();
let canonical_chain_slots: Vec<Slot> = (1..=rig.epoch_start_slot(1)).map(Slot::new).collect();
let (canonical_chain_blocks_pre_finalization, _, _, new_state) = rig
.add_attested_blocks_at_slots(
state,
state_root,
&canonical_chain_slots,
&honest_validators,
)
.await;
state = new_state;
let canonical_chain_slot: u64 = rig.get_current_slot().into();
let stray_slots: Vec<Slot> = (canonical_chain_slot + 1..rig.epoch_start_slot(2))
.map(Slot::new)
.collect();
let (current_state, current_state_root) = rig.get_current_state_and_root();
let (stray_blocks, stray_states, stray_head, _) = rig
.add_attested_blocks_at_slots(
current_state,
current_state_root,
&stray_slots,
&adversarial_validators,
)
.await;
// Precondition: Ensure all stray_blocks blocks are still known
for &block_hash in stray_blocks.values() {
assert!(
rig.block_exists(block_hash),
"stray block {} should be still present",
block_hash
);
}
for (&slot, &state_hash) in &stray_states {
assert!(
rig.hot_state_exists(state_hash),
"stray state {} at slot {} should be still present",
state_hash,
slot
);
}
assert_eq!(rig.get_finalized_checkpoints(), hashset! {});
assert!(rig.chain.knows_head(&stray_head));
// Trigger finalization
let finalization_slots: Vec<Slot> = ((canonical_chain_slot + 1)
..=(canonical_chain_slot + slots_per_epoch * 5))
.map(Slot::new)
.collect();
let state_root = state.update_tree_hash_cache().unwrap();
let (canonical_chain_blocks_post_finalization, _, _, _) = rig
.add_attested_blocks_at_slots(state, state_root, &finalization_slots, &honest_validators)
.await;
// Postcondition: New blocks got finalized
assert_eq!(
rig.get_finalized_checkpoints(),
hashset! {
canonical_chain_blocks_pre_finalization[&rig.epoch_start_slot(1).into()],
canonical_chain_blocks_post_finalization[&rig.epoch_start_slot(2).into()],
},
);
// Postcondition: Ensure all stray_blocks blocks have been pruned
for &block_hash in stray_blocks.values() {
assert!(
!rig.block_exists(block_hash),
"abandoned block {block_hash:?} should have been pruned",
);
assert!(
!rig.chain.store.blobs_exist(&block_hash.into()).unwrap(),
"blobs for abandoned block {block_hash:?} should have been pruned"
);
}
for (&slot, &state_hash) in &stray_states {
assert!(
!rig.hot_state_exists(state_hash),
"stray state {} at slot {} should have been pruned",
state_hash,
slot
);
assert!(
!rig.cold_state_exists(state_hash),
"stray state {} at slot {} should have been pruned",
state_hash,
slot
);
}
assert!(!rig.chain.knows_head(&stray_head));
}
#[tokio::test]
async fn pruning_does_not_touch_abandoned_block_shared_with_canonical_chain() {
const HONEST_VALIDATOR_COUNT: usize = 32;
const ADVERSARIAL_VALIDATOR_COUNT: usize = 16;
const VALIDATOR_COUNT: usize = HONEST_VALIDATOR_COUNT + ADVERSARIAL_VALIDATOR_COUNT;
let honest_validators: Vec<usize> = (0..HONEST_VALIDATOR_COUNT).collect();
let adversarial_validators: Vec<usize> = (HONEST_VALIDATOR_COUNT..VALIDATOR_COUNT).collect();
let db_path = tempdir().unwrap();
let store = get_store(&db_path);
let rig = get_harness(store.clone(), VALIDATOR_COUNT);
let slots_per_epoch = rig.slots_per_epoch();
let (state, state_root) = rig.get_current_state_and_root();
// Fill up 0th epoch
let canonical_chain_slots_zeroth_epoch: Vec<Slot> =
(1..rig.epoch_start_slot(1)).map(Slot::new).collect();
let (_, _, _, mut state) = rig
.add_attested_blocks_at_slots(
state,
state_root,
&canonical_chain_slots_zeroth_epoch,
&honest_validators,
)
.await;
// Fill up 1st epoch
let canonical_chain_slots_first_epoch: Vec<Slot> = (rig.epoch_start_slot(1)
..=rig.epoch_start_slot(1) + 1)
.map(Slot::new)
.collect();
let state_root = state.update_tree_hash_cache().unwrap();
let (canonical_chain_blocks_first_epoch, _, shared_head, mut state) = rig
.add_attested_blocks_at_slots(
state.clone(),
state_root,
&canonical_chain_slots_first_epoch,
&honest_validators,
)
.await;
let canonical_chain_slot: u64 = rig.get_current_slot().into();
let stray_chain_slots_first_epoch: Vec<Slot> = (rig.epoch_start_slot(1) + 2
..=rig.epoch_start_slot(1) + 2)
.map(Slot::new)
.collect();
let state_root = state.update_tree_hash_cache().unwrap();
let (stray_blocks, stray_states, stray_head, _) = rig
.add_attested_blocks_at_slots(
state.clone(),
state_root,
&stray_chain_slots_first_epoch,
&adversarial_validators,
)
.await;
// Preconditions
for &block_hash in stray_blocks.values() {
assert!(
rig.block_exists(block_hash),
"stray block {} should be still present",
block_hash
);
}
for (&slot, &state_hash) in &stray_states {
assert!(
rig.hot_state_exists(state_hash),
"stray state {} at slot {} should be still present",
state_hash,
slot
);
}
let chain_dump = rig.chain.chain_dump().unwrap();
assert_eq!(
get_finalized_epoch_boundary_blocks(&chain_dump),
vec![Hash256::zero().into()].into_iter().collect(),
);
assert!(get_blocks(&chain_dump).contains(&shared_head));
// Trigger finalization
let finalization_slots: Vec<Slot> = ((canonical_chain_slot + 1)
..=(canonical_chain_slot + slots_per_epoch * 5))
.map(Slot::new)
.collect();
let state_root = state.update_tree_hash_cache().unwrap();
let (canonical_chain_blocks, _, _, _) = rig
.add_attested_blocks_at_slots(state, state_root, &finalization_slots, &honest_validators)
.await;
// Postconditions
assert_eq!(
rig.get_finalized_checkpoints(),
hashset! {
canonical_chain_blocks_first_epoch[&rig.epoch_start_slot(1).into()],
canonical_chain_blocks[&rig.epoch_start_slot(2).into()],
},
);
for &block_hash in stray_blocks.values() {
assert!(
!rig.block_exists(block_hash),
"stray block {} should have been pruned",
block_hash,
);
}
for (&slot, &state_hash) in &stray_states {
assert!(
!rig.hot_state_exists(state_hash),
"stray state {} at slot {} should have been pruned",
state_hash,
slot
);
assert!(
!rig.cold_state_exists(state_hash),
"stray state {} at slot {} should have been pruned",
state_hash,
slot
);
}
assert!(!rig.chain.knows_head(&stray_head));
let chain_dump = rig.chain.chain_dump().unwrap();
assert!(get_blocks(&chain_dump).contains(&shared_head));
}
#[tokio::test]
async fn pruning_does_not_touch_blocks_prior_to_finalization() {
const HONEST_VALIDATOR_COUNT: usize = 32;
const ADVERSARIAL_VALIDATOR_COUNT: usize = 16;
const VALIDATOR_COUNT: usize = HONEST_VALIDATOR_COUNT + ADVERSARIAL_VALIDATOR_COUNT;
let honest_validators: Vec<usize> = (0..HONEST_VALIDATOR_COUNT).collect();
let adversarial_validators: Vec<usize> = (HONEST_VALIDATOR_COUNT..VALIDATOR_COUNT).collect();
let db_path = tempdir().unwrap();
let store = get_store(&db_path);
let rig = get_harness(store.clone(), VALIDATOR_COUNT);
let slots_per_epoch = rig.slots_per_epoch();
let (mut state, state_root) = rig.get_current_state_and_root();
// Fill up 0th epoch with canonical chain blocks
let zeroth_epoch_slots: Vec<Slot> = (1..=rig.epoch_start_slot(1)).map(Slot::new).collect();
let (canonical_chain_blocks, _, _, new_state) = rig
.add_attested_blocks_at_slots(state, state_root, &zeroth_epoch_slots, &honest_validators)
.await;
state = new_state;
let canonical_chain_slot: u64 = rig.get_current_slot().into();
// Fill up 1st epoch. Contains a fork.
let first_epoch_slots: Vec<Slot> = ((rig.epoch_start_slot(1) + 1)..(rig.epoch_start_slot(2)))
.map(Slot::new)
.collect();
let state_root = state.update_tree_hash_cache().unwrap();
let (stray_blocks, stray_states, stray_head, _) = rig
.add_attested_blocks_at_slots(
state.clone(),
state_root,
&first_epoch_slots,
&adversarial_validators,
)
.await;
// Preconditions
for &block_hash in stray_blocks.values() {
assert!(
rig.block_exists(block_hash),
"stray block {} should be still present",
block_hash
);
}
for (&slot, &state_hash) in &stray_states {
assert!(
rig.hot_state_exists(state_hash),
"stray state {} at slot {} should be still present",
state_hash,
slot
);
}
assert_eq!(rig.get_finalized_checkpoints(), hashset! {});
// Trigger finalization
let slots: Vec<Slot> = ((canonical_chain_slot + 1)
..=(canonical_chain_slot + slots_per_epoch * 4))
.map(Slot::new)
.collect();
let state_root = state.update_tree_hash_cache().unwrap();
let (_, _, _, _) = rig
.add_attested_blocks_at_slots(state, state_root, &slots, &honest_validators)
.await;
// Postconditions
assert_eq!(
rig.get_finalized_checkpoints(),
hashset! {canonical_chain_blocks[&rig.epoch_start_slot(1).into()]},
);
for &block_hash in stray_blocks.values() {
assert!(
rig.block_exists(block_hash),
"stray block {} should be still present",
block_hash
);
}
for (&slot, &state_hash) in &stray_states {
assert!(
rig.hot_state_exists(state_hash),
"stray state {} at slot {} should be still present",
state_hash,
slot
);
}
assert!(rig.chain.knows_head(&stray_head));
}
#[tokio::test]
async fn prunes_fork_growing_past_youngest_finalized_checkpoint() {
const HONEST_VALIDATOR_COUNT: usize = 32;
const ADVERSARIAL_VALIDATOR_COUNT: usize = 16;
const VALIDATOR_COUNT: usize = HONEST_VALIDATOR_COUNT + ADVERSARIAL_VALIDATOR_COUNT;
let honest_validators: Vec<usize> = (0..HONEST_VALIDATOR_COUNT).collect();
let adversarial_validators: Vec<usize> = (HONEST_VALIDATOR_COUNT..VALIDATOR_COUNT).collect();
let db_path = tempdir().unwrap();
let store = get_store(&db_path);
let rig = get_harness(store.clone(), VALIDATOR_COUNT);
let (state, state_root) = rig.get_current_state_and_root();
// Fill up 0th epoch with canonical chain blocks
let zeroth_epoch_slots: Vec<Slot> = (1..=rig.epoch_start_slot(1)).map(Slot::new).collect();
let (canonical_blocks_zeroth_epoch, _, _, mut state) = rig
.add_attested_blocks_at_slots(state, state_root, &zeroth_epoch_slots, &honest_validators)
.await;
// Fill up 1st epoch. Contains a fork.
let slots_first_epoch: Vec<Slot> = (rig.epoch_start_slot(1) + 1..rig.epoch_start_slot(2))
.map(Into::into)
.collect();
let state_root = state.update_tree_hash_cache().unwrap();
let (stray_blocks_first_epoch, stray_states_first_epoch, _, mut stray_state) = rig
.add_attested_blocks_at_slots(
state.clone(),
state_root,
&slots_first_epoch,
&adversarial_validators,
)
.await;
let (canonical_blocks_first_epoch, _, _, mut canonical_state) = rig
.add_attested_blocks_at_slots(state, state_root, &slots_first_epoch, &honest_validators)
.await;
// Fill up 2nd epoch. Extends both the canonical chain and the fork.
let stray_slots_second_epoch: Vec<Slot> = (rig.epoch_start_slot(2)
..=rig.epoch_start_slot(2) + 1)
.map(Into::into)
.collect();
let stray_state_root = stray_state.update_tree_hash_cache().unwrap();
let (stray_blocks_second_epoch, stray_states_second_epoch, stray_head, _) = rig
.add_attested_blocks_at_slots(
stray_state,
stray_state_root,
&stray_slots_second_epoch,
&adversarial_validators,
)
.await;
// Precondition: Ensure all stray_blocks blocks are still known
let stray_blocks: HashMap<Slot, SignedBeaconBlockHash> = stray_blocks_first_epoch
.into_iter()
.chain(stray_blocks_second_epoch.into_iter())
.collect();
let stray_states: HashMap<Slot, BeaconStateHash> = stray_states_first_epoch
.into_iter()
.chain(stray_states_second_epoch.into_iter())
.collect();
for &block_hash in stray_blocks.values() {
assert!(
rig.block_exists(block_hash),
"stray block {} should be still present",
block_hash
);
}
for (&slot, &state_hash) in &stray_states {
assert!(
rig.hot_state_exists(state_hash),
"stray state {} at slot {} should be still present",
state_hash,
slot
);
}
// Precondition: Nothing is finalized yet
assert_eq!(rig.get_finalized_checkpoints(), hashset! {},);
assert!(rig.chain.knows_head(&stray_head));
// Trigger finalization
let canonical_slots: Vec<Slot> = (rig.epoch_start_slot(2)..=rig.epoch_start_slot(6))
.map(Into::into)
.collect();
let canonical_state_root = canonical_state.update_tree_hash_cache().unwrap();
let (canonical_blocks, _, _, _) = rig
.add_attested_blocks_at_slots(
canonical_state,
canonical_state_root,
&canonical_slots,
&honest_validators,
)
.await;
// Postconditions
let canonical_blocks: HashMap<Slot, SignedBeaconBlockHash> = canonical_blocks_zeroth_epoch
.into_iter()
.chain(canonical_blocks_first_epoch.into_iter())
.chain(canonical_blocks.into_iter())
.collect();
// Postcondition: New blocks got finalized
assert_eq!(
rig.get_finalized_checkpoints(),
hashset! {
canonical_blocks[&rig.epoch_start_slot(1).into()],
canonical_blocks[&rig.epoch_start_slot(2).into()],
},
);
// Postcondition: Ensure all stray_blocks blocks have been pruned
for &block_hash in stray_blocks.values() {
assert!(
!rig.block_exists(block_hash),
"abandoned block {} should have been pruned",
block_hash
);
}
for (&slot, &state_hash) in &stray_states {
assert!(
!rig.hot_state_exists(state_hash),
"stray state {} at slot {} should have been pruned",
state_hash,
slot
);
assert!(
!rig.cold_state_exists(state_hash),
"stray state {} at slot {} should have been pruned",
state_hash,
slot
);
}
assert!(!rig.chain.knows_head(&stray_head));
}
// This is to check if state outside of normal block processing are pruned correctly.
#[tokio::test]
async fn prunes_skipped_slots_states() {
const HONEST_VALIDATOR_COUNT: usize = 32;
const ADVERSARIAL_VALIDATOR_COUNT: usize = 16;
const VALIDATOR_COUNT: usize = HONEST_VALIDATOR_COUNT + ADVERSARIAL_VALIDATOR_COUNT;
let honest_validators: Vec<usize> = (0..HONEST_VALIDATOR_COUNT).collect();
let adversarial_validators: Vec<usize> = (HONEST_VALIDATOR_COUNT..VALIDATOR_COUNT).collect();
let db_path = tempdir().unwrap();
let store = get_store(&db_path);
let rig = get_harness(store.clone(), VALIDATOR_COUNT);
let (state, state_root) = rig.get_current_state_and_root();
let canonical_slots_zeroth_epoch: Vec<Slot> =
(1..=rig.epoch_start_slot(1)).map(Into::into).collect();
let (canonical_blocks_zeroth_epoch, _, _, mut canonical_state) = rig
.add_attested_blocks_at_slots(
state.clone(),
state_root,
&canonical_slots_zeroth_epoch,
&honest_validators,
)
.await;
let skipped_slot: Slot = (rig.epoch_start_slot(1) + 1).into();
let stray_slots: Vec<Slot> = ((skipped_slot + 1).into()..rig.epoch_start_slot(2))
.map(Into::into)
.collect();
let canonical_state_root = canonical_state.update_tree_hash_cache().unwrap();
let (stray_blocks, stray_states, _, stray_state) = rig
.add_attested_blocks_at_slots(
canonical_state.clone(),
canonical_state_root,
&stray_slots,
&adversarial_validators,
)
.await;
// Preconditions
for &block_hash in stray_blocks.values() {
assert!(
rig.block_exists(block_hash),
"stray block {} should be still present",
block_hash
);
}
for (&slot, &state_hash) in &stray_states {
assert!(
rig.hot_state_exists(state_hash),
"stray state {} at slot {} should be still present",
state_hash,
slot
);
}
assert_eq!(rig.get_finalized_checkpoints(), hashset! {},);
// Make sure slots were skipped
assert!(rig.is_skipped_slot(&stray_state, skipped_slot));
{
let state_hash = (*stray_state.get_state_root(skipped_slot).unwrap()).into();
assert!(
rig.hot_state_exists(state_hash),
"skipped slot state {} should be still present",
state_hash
);
}
// Trigger finalization
let canonical_slots: Vec<Slot> = ((skipped_slot + 1).into()..rig.epoch_start_slot(7))
.map(Into::into)
.collect();
let canonical_state_root = canonical_state.update_tree_hash_cache().unwrap();
let (canonical_blocks_post_finalization, _, _, _) = rig
.add_attested_blocks_at_slots(
canonical_state,
canonical_state_root,
&canonical_slots,
&honest_validators,
)
.await;
// Postconditions
let canonical_blocks: HashMap<Slot, SignedBeaconBlockHash> = canonical_blocks_zeroth_epoch
.into_iter()
.chain(canonical_blocks_post_finalization.into_iter())
.collect();
assert_eq!(
rig.get_finalized_checkpoints(),
hashset! {
canonical_blocks[&rig.epoch_start_slot(1).into()],
canonical_blocks[&rig.epoch_start_slot(2).into()],
},
);
for (&slot, &state_hash) in &stray_states {
assert!(
!rig.hot_state_exists(state_hash),
"stray state {} at slot {} should have been pruned",
state_hash,
slot
);
assert!(
!rig.cold_state_exists(state_hash),
"stray state {} at slot {} should have been pruned",
state_hash,
slot
);
}
assert!(rig.is_skipped_slot(&stray_state, skipped_slot));
{
let state_hash: BeaconStateHash =
(*stray_state.get_state_root(skipped_slot).unwrap()).into();
assert!(
!rig.hot_state_exists(state_hash),
"skipped slot {} state {} should have been pruned",
skipped_slot,
state_hash
);
}
}
// This is to check if state outside of normal block processing are pruned correctly.
#[tokio::test]
async fn finalizes_non_epoch_start_slot() {
const HONEST_VALIDATOR_COUNT: usize = 32;
const ADVERSARIAL_VALIDATOR_COUNT: usize = 16;
const VALIDATOR_COUNT: usize = HONEST_VALIDATOR_COUNT + ADVERSARIAL_VALIDATOR_COUNT;
let honest_validators: Vec<usize> = (0..HONEST_VALIDATOR_COUNT).collect();
let adversarial_validators: Vec<usize> = (HONEST_VALIDATOR_COUNT..VALIDATOR_COUNT).collect();
let db_path = tempdir().unwrap();
let store = get_store(&db_path);
let rig = get_harness(store.clone(), VALIDATOR_COUNT);
let (state, state_root) = rig.get_current_state_and_root();
let canonical_slots_zeroth_epoch: Vec<Slot> =
(1..rig.epoch_start_slot(1)).map(Into::into).collect();
let (canonical_blocks_zeroth_epoch, _, _, mut canonical_state) = rig
.add_attested_blocks_at_slots(
state.clone(),
state_root,
&canonical_slots_zeroth_epoch,
&honest_validators,
)
.await;
let skipped_slot: Slot = rig.epoch_start_slot(1).into();
let stray_slots: Vec<Slot> = ((skipped_slot + 1).into()..rig.epoch_start_slot(2))
.map(Into::into)
.collect();
let canonical_state_root = canonical_state.update_tree_hash_cache().unwrap();
let (stray_blocks, stray_states, _, stray_state) = rig
.add_attested_blocks_at_slots(
canonical_state.clone(),
canonical_state_root,
&stray_slots,
&adversarial_validators,
)
.await;
// Preconditions
for &block_hash in stray_blocks.values() {
assert!(
rig.block_exists(block_hash),
"stray block {} should be still present",
block_hash
);
}
for (&slot, &state_hash) in &stray_states {
assert!(
rig.hot_state_exists(state_hash),
"stray state {} at slot {} should be still present",
state_hash,
slot
);
}
assert_eq!(rig.get_finalized_checkpoints(), hashset! {});
// Make sure slots were skipped
assert!(rig.is_skipped_slot(&stray_state, skipped_slot));
{
let state_hash = (*stray_state.get_state_root(skipped_slot).unwrap()).into();
assert!(
rig.hot_state_exists(state_hash),
"skipped slot state {} should be still present",
state_hash
);
}
// Trigger finalization
let canonical_slots: Vec<Slot> = ((skipped_slot + 1).into()..rig.epoch_start_slot(7))
.map(Into::into)
.collect();
let canonical_state_root = canonical_state.update_tree_hash_cache().unwrap();
let (canonical_blocks_post_finalization, _, _, _) = rig
.add_attested_blocks_at_slots(
canonical_state,
canonical_state_root,
&canonical_slots,
&honest_validators,
)
.await;
// Postconditions
let canonical_blocks: HashMap<Slot, SignedBeaconBlockHash> = canonical_blocks_zeroth_epoch
.into_iter()
.chain(canonical_blocks_post_finalization.into_iter())
.collect();
assert_eq!(
rig.get_finalized_checkpoints(),
hashset! {
canonical_blocks[&(rig.epoch_start_slot(1)-1).into()],
canonical_blocks[&rig.epoch_start_slot(2).into()],
},
);
for (&slot, &state_hash) in &stray_states {
assert!(
!rig.hot_state_exists(state_hash),
"stray state {} at slot {} should have been pruned",
state_hash,
slot
);
assert!(
!rig.cold_state_exists(state_hash),
"stray state {} at slot {} should have been pruned",
state_hash,
slot
);
}
assert!(rig.is_skipped_slot(&stray_state, skipped_slot));
{
let state_hash: BeaconStateHash =
(*stray_state.get_state_root(skipped_slot).unwrap()).into();
assert!(
!rig.hot_state_exists(state_hash),
"skipped slot {} state {} should have been pruned",
skipped_slot,
state_hash
);
}
}
fn check_all_blocks_exist<'a>(
harness: &TestHarness,
blocks: impl Iterator<Item = &'a SignedBeaconBlockHash>,
) {
for &block_hash in blocks {
let block = harness.chain.get_blinded_block(&block_hash.into()).unwrap();
assert!(
block.is_some(),
"expected block {:?} to be in DB",
block_hash
);
}
}
fn check_all_states_exist<'a>(
harness: &TestHarness,
states: impl Iterator<Item = &'a BeaconStateHash>,
) {
for &state_hash in states {
let state = harness.chain.get_state(&state_hash.into(), None).unwrap();
assert!(
state.is_some(),
"expected state {:?} to be in DB",
state_hash,
);
}
}
// Check that none of the given states exist in the database.
fn check_no_states_exist<'a>(
harness: &TestHarness,
states: impl Iterator<Item = &'a BeaconStateHash>,
) {
for &state_root in states {
assert!(
harness
.chain
.get_state(&state_root.into(), None)
.unwrap()
.is_none(),
"state {:?} should not be in the DB",
state_root
);
}
}
// Check that none of the given blocks exist in the database.
fn check_no_blocks_exist<'a>(
harness: &TestHarness,
blocks: impl Iterator<Item = &'a SignedBeaconBlockHash>,
) {
for &block_hash in blocks {
let block = harness.chain.get_blinded_block(&block_hash.into()).unwrap();
assert!(
block.is_none(),
"did not expect block {:?} to be in the DB",
block_hash
);
assert!(
!harness.chain.store.blobs_exist(&block_hash.into()).unwrap(),
"blobs for abandoned block {block_hash:?} should have been pruned"
);
}
}
#[tokio::test]
async fn prune_single_block_fork() {
let slots_per_epoch = E::slots_per_epoch();
pruning_test(3 * slots_per_epoch, 1, slots_per_epoch, 0, 1).await;
}
#[tokio::test]
async fn prune_single_block_long_skip() {
let slots_per_epoch = E::slots_per_epoch();
pruning_test(
2 * slots_per_epoch,
1,
2 * slots_per_epoch,
2 * slots_per_epoch as u64,
1,
)
.await;
}
#[tokio::test]
async fn prune_shared_skip_states_mid_epoch() {
let slots_per_epoch = E::slots_per_epoch();
pruning_test(
slots_per_epoch + slots_per_epoch / 2,
1,
slots_per_epoch,
2,
slots_per_epoch - 1,
)
.await;
}
#[tokio::test]
async fn prune_shared_skip_states_epoch_boundaries() {
let slots_per_epoch = E::slots_per_epoch();
pruning_test(slots_per_epoch - 1, 1, slots_per_epoch, 2, slots_per_epoch).await;
pruning_test(slots_per_epoch - 1, 2, slots_per_epoch, 1, slots_per_epoch).await;
pruning_test(
2 * slots_per_epoch + slots_per_epoch / 2,
slots_per_epoch as u64 / 2,
slots_per_epoch,
slots_per_epoch as u64 / 2 + 1,
slots_per_epoch,
)
.await;
pruning_test(
2 * slots_per_epoch + slots_per_epoch / 2,
slots_per_epoch as u64 / 2,
slots_per_epoch,
slots_per_epoch as u64 / 2 + 1,
slots_per_epoch,
)
.await;
pruning_test(
2 * slots_per_epoch - 1,
slots_per_epoch as u64,
1,
0,
2 * slots_per_epoch,
)
.await;
}
/// Generic harness for pruning tests.
async fn pruning_test(
// Number of blocks to start the chain with before forking.
num_initial_blocks: u64,
// Number of skip slots on the main chain after the initial blocks.
num_canonical_skips: u64,
// Number of blocks on the main chain after the skip, but before the finalisation-triggering
// blocks.
num_canonical_middle_blocks: u64,
// Number of skip slots on the fork chain after the initial blocks.
num_fork_skips: u64,
// Number of blocks on the fork chain after the skips.
num_fork_blocks: u64,
) {
const VALIDATOR_COUNT: usize = 24;
const VALIDATOR_SUPERMAJORITY: usize = (VALIDATOR_COUNT / 3) * 2;
const HONEST_VALIDATOR_COUNT: usize = VALIDATOR_SUPERMAJORITY;
let db_path = tempdir().unwrap();
let store = get_store(&db_path);
let harness = get_harness(store.clone(), VALIDATOR_COUNT);
let honest_validators: Vec<usize> = (0..HONEST_VALIDATOR_COUNT).collect();
let faulty_validators: Vec<usize> = (HONEST_VALIDATOR_COUNT..VALIDATOR_COUNT).collect();
let slots = |start: Slot, num_blocks: u64| -> Vec<Slot> {
(start.as_u64()..start.as_u64() + num_blocks)
.map(Slot::new)
.collect()
};
let start_slot = Slot::new(1);
let divergence_slot = start_slot + num_initial_blocks;
let (state, state_root) = harness.get_current_state_and_root();
let (_, _, _, divergence_state) = harness
.add_attested_blocks_at_slots(
state,
state_root,
&slots(start_slot, num_initial_blocks)[..],
&honest_validators,
)
.await;
let mut chains = harness
.add_blocks_on_multiple_chains(vec![
// Canonical chain
(
divergence_state.clone(),
slots(
divergence_slot + num_canonical_skips,
num_canonical_middle_blocks,
),
honest_validators.clone(),
),
// Fork chain
(
divergence_state.clone(),
slots(divergence_slot + num_fork_skips, num_fork_blocks),
faulty_validators,
),
])
.await;
let (_, _, _, mut canonical_state) = chains.remove(0);
let (stray_blocks, stray_states, _, stray_head_state) = chains.remove(0);
let stray_head_slot = divergence_slot + num_fork_skips + num_fork_blocks - 1;
let stray_head_state_root = stray_states[&stray_head_slot];
let stray_states = harness
.chain
.rev_iter_state_roots_from(stray_head_state_root.into(), &stray_head_state)
.map(Result::unwrap)
.map(|(state_root, _)| state_root.into())
.collect::<HashSet<_>>();
check_all_blocks_exist(&harness, stray_blocks.values());
check_all_states_exist(&harness, stray_states.iter());
let chain_dump = harness.chain.chain_dump().unwrap();
assert_eq!(
get_finalized_epoch_boundary_blocks(&chain_dump),
vec![Hash256::zero().into()].into_iter().collect(),
);
// Trigger finalization
let num_finalization_blocks = 4 * E::slots_per_epoch();
let canonical_slot = divergence_slot + num_canonical_skips + num_canonical_middle_blocks;
let canonical_state_root = canonical_state.update_tree_hash_cache().unwrap();
harness
.add_attested_blocks_at_slots(
canonical_state,
canonical_state_root,
&slots(canonical_slot, num_finalization_blocks),
&honest_validators,
)
.await;
// Check that finalization has advanced past the divergence slot.
assert!(
harness
.finalized_checkpoint()
.epoch
.start_slot(E::slots_per_epoch())
> divergence_slot
);
check_chain_dump(
&harness,
(num_initial_blocks + num_canonical_middle_blocks + num_finalization_blocks + 1) as u64,
);
let all_canonical_states = harness
.chain
.forwards_iter_state_roots(Slot::new(0))
.unwrap()
.map(Result::unwrap)
.map(|(state_root, _)| state_root.into())
.collect::<HashSet<BeaconStateHash>>();
check_all_states_exist(&harness, all_canonical_states.iter());
check_no_states_exist(&harness, stray_states.difference(&all_canonical_states));
check_no_blocks_exist(&harness, stray_blocks.values());
}
#[tokio::test]
async fn garbage_collect_temp_states_from_failed_block() {
let db_path = tempdir().unwrap();
// Wrap these functions to ensure the variables are dropped before we try to open another
// instance of the store.
let mut store = {
let store = get_store(&db_path);
let harness = get_harness(store.clone(), LOW_VALIDATOR_COUNT);
let slots_per_epoch = E::slots_per_epoch();
let genesis_state = harness.get_current_state();
let block_slot = Slot::new(2 * slots_per_epoch);
let ((signed_block, _), state) = harness.make_block(genesis_state, block_slot).await;
let (mut block, _) = (*signed_block).clone().deconstruct();
// Mutate the block to make it invalid, and re-sign it.
*block.state_root_mut() = Hash256::repeat_byte(0xff);
let proposer_index = block.proposer_index() as usize;
let block = Arc::new(block.sign(
&harness.validator_keypairs[proposer_index].sk,
&state.fork(),
state.genesis_validators_root(),
&harness.spec,
));
// The block should be rejected, but should store a bunch of temporary states.
harness.set_current_slot(block_slot);
harness
.process_block_result((block, None))
.await
.unwrap_err();
assert_eq!(
store.iter_temporary_state_roots().count(),
block_slot.as_usize() - 1
);
store
};
// Wait until all the references to the store have been dropped, this helps ensure we can
// re-open the store later.
loop {
store = if let Err(store_arc) = Arc::try_unwrap(store) {
sleep(Duration::from_millis(500)).await;
store_arc
} else {
break;
}
}
// On startup, the store should garbage collect all the temporary states.
let store = get_store(&db_path);
assert_eq!(store.iter_temporary_state_roots().count(), 0);
}
#[tokio::test]
async fn weak_subjectivity_sync_easy() {
let num_initial_slots = E::slots_per_epoch() * 11;
let checkpoint_slot = Slot::new(E::slots_per_epoch() * 9);
let slots = (1..num_initial_slots).map(Slot::new).collect();
weak_subjectivity_sync_test(slots, checkpoint_slot).await
}
#[tokio::test]
async fn weak_subjectivity_sync_unaligned_advanced_checkpoint() {
let num_initial_slots = E::slots_per_epoch() * 11;
let checkpoint_slot = Slot::new(E::slots_per_epoch() * 9);
let slots = (1..num_initial_slots)
.map(Slot::new)
.filter(|&slot| {
// Skip 3 slots leading up to the checkpoint slot.
slot <= checkpoint_slot - 3 || slot > checkpoint_slot
})
.collect();
weak_subjectivity_sync_test(slots, checkpoint_slot).await
}
#[tokio::test]
async fn weak_subjectivity_sync_unaligned_unadvanced_checkpoint() {
let num_initial_slots = E::slots_per_epoch() * 11;
let checkpoint_slot = Slot::new(E::slots_per_epoch() * 9 - 3);
let slots = (1..num_initial_slots)
.map(Slot::new)
.filter(|&slot| {
// Skip 3 slots after the checkpoint slot.
slot <= checkpoint_slot || slot > checkpoint_slot + 3
})
.collect();
weak_subjectivity_sync_test(slots, checkpoint_slot).await
}
// Regression test for https://github.com/sigp/lighthouse/issues/4817
// Skip 3 slots immediately after genesis, creating a gap between the genesis block and the first
// real block.
#[tokio::test]
async fn weak_subjectivity_sync_skips_at_genesis() {
let start_slot = 4;
let end_slot = E::slots_per_epoch() * 4;
let slots = (start_slot..end_slot).map(Slot::new).collect();
let checkpoint_slot = Slot::new(E::slots_per_epoch() * 2);
weak_subjectivity_sync_test(slots, checkpoint_slot).await
}
async fn weak_subjectivity_sync_test(slots: Vec<Slot>, checkpoint_slot: Slot) {
// Build an initial chain on one harness, representing a synced node with full history.
let num_final_blocks = E::slots_per_epoch() * 2;
let temp1 = tempdir().unwrap();
let full_store = get_store(&temp1);
let harness = get_harness(full_store.clone(), LOW_VALIDATOR_COUNT);
let all_validators = (0..LOW_VALIDATOR_COUNT).collect::<Vec<_>>();
let (genesis_state, genesis_state_root) = harness.get_current_state_and_root();
harness
.add_attested_blocks_at_slots(
genesis_state.clone(),
genesis_state_root,
&slots,
&all_validators,
)
.await;
let wss_block_root = harness
.chain
.block_root_at_slot(checkpoint_slot, WhenSlotSkipped::Prev)
.unwrap()
.unwrap();
let wss_state_root = harness
.chain
.state_root_at_slot(checkpoint_slot)
.unwrap()
.unwrap();
let wss_block = harness
.chain
.store
.get_full_block(&wss_block_root)
.unwrap()
.unwrap();
let wss_blobs_opt = harness.chain.store.get_blobs(&wss_block_root).unwrap();
let wss_state = full_store
.get_state(&wss_state_root, Some(checkpoint_slot))
.unwrap()
.unwrap();
// Add more blocks that advance finalization further.
harness.advance_slot();
harness
.extend_chain(
num_final_blocks as usize,
BlockStrategy::OnCanonicalHead,
AttestationStrategy::AllValidators,
)
.await;
let (shutdown_tx, _shutdown_rx) = futures::channel::mpsc::channel(1);
let log = test_logger();
let temp2 = tempdir().unwrap();
let store = get_store(&temp2);
let spec = test_spec::<E>();
let seconds_per_slot = spec.seconds_per_slot;
let kzg = spec.deneb_fork_epoch.map(|_| KZG.clone());
let mock =
mock_execution_layer_from_parts(&harness.spec, harness.runtime.task_executor.clone());
// Initialise a new beacon chain from the finalized checkpoint.
// The slot clock must be set to a time ahead of the checkpoint state.
let slot_clock = TestingSlotClock::new(
Slot::new(0),
Duration::from_secs(harness.chain.genesis_time),
Duration::from_secs(seconds_per_slot),
);
slot_clock.set_slot(harness.get_current_slot().as_u64());
let beacon_chain = BeaconChainBuilder::<DiskHarnessType<E>>::new(MinimalEthSpec)
.store(store.clone())
.custom_spec(test_spec::<E>())
.task_executor(harness.chain.task_executor.clone())
.logger(log.clone())
.weak_subjectivity_state(
wss_state,
wss_block.clone(),
wss_blobs_opt.clone(),
genesis_state,
)
.unwrap()
.store_migrator_config(MigratorConfig::default().blocking())
.dummy_eth1_backend()
.expect("should build dummy backend")
.slot_clock(slot_clock)
.shutdown_sender(shutdown_tx)
.chain_config(ChainConfig::default())
.event_handler(Some(ServerSentEventHandler::new_with_capacity(
log.clone(),
1,
)))
.execution_layer(Some(mock.el))
.kzg(kzg)
.build()
.expect("should build");
let beacon_chain = Arc::new(beacon_chain);
let wss_block_root = wss_block.canonical_root();
let store_wss_block = harness
.chain
.get_block(&wss_block_root)
.await
.unwrap()
.unwrap();
let store_wss_blobs_opt = beacon_chain.store.get_blobs(&wss_block_root).unwrap();
assert_eq!(store_wss_block, wss_block);
assert_eq!(store_wss_blobs_opt, wss_blobs_opt);
// Apply blocks forward to reach head.
let chain_dump = harness.chain.chain_dump().unwrap();
let new_blocks = chain_dump
.iter()
.filter(|snapshot| snapshot.beacon_block.slot() > checkpoint_slot);
for snapshot in new_blocks {
let block_root = snapshot.beacon_block_root;
let full_block = harness
.chain
.get_block(&snapshot.beacon_block_root)
.await
.unwrap()
.unwrap();
let blobs = harness.chain.get_blobs(&block_root).expect("blobs");
let slot = full_block.slot();
let state_root = full_block.state_root();
beacon_chain.slot_clock.set_slot(slot.as_u64());
beacon_chain
.process_block(
full_block.canonical_root(),
RpcBlock::new(Some(block_root), Arc::new(full_block), Some(blobs)).unwrap(),
NotifyExecutionLayer::Yes,
BlockImportSource::Lookup,
|| Ok(()),
)
.await
.unwrap();
beacon_chain.recompute_head_at_current_slot().await;
// Check that the new block's state can be loaded correctly.
let mut state = beacon_chain
.store
.get_state(&state_root, Some(slot))
.unwrap()
.unwrap();
assert_eq!(state.update_tree_hash_cache().unwrap(), state_root);
}
// Forwards iterator from 0 should fail as we lack blocks.
assert!(matches!(
beacon_chain.forwards_iter_block_roots(Slot::new(0)),
Err(BeaconChainError::HistoricalBlockError(
HistoricalBlockError::BlockOutOfRange { .. }
))
));
// Simulate processing of a `StatusMessage` with an older finalized epoch by calling
// `block_root_at_slot` with an old slot for which we don't know the block root. It should
// return `None` rather than erroring.
assert_eq!(
beacon_chain
.block_root_at_slot(Slot::new(1), WhenSlotSkipped::None)
.unwrap(),
None
);
// Simulate querying the API for a historic state that is unknown. It should also return
// `None` rather than erroring.
assert_eq!(beacon_chain.state_root_at_slot(Slot::new(1)).unwrap(), None);
// Supply blocks backwards to reach genesis. Omit the genesis block to check genesis handling.
let historical_blocks = chain_dump[..wss_block.slot().as_usize()]
.iter()
.filter(|s| s.beacon_block.slot() != 0)
.map(|s| s.beacon_block.clone())
.collect::<Vec<_>>();
let mut available_blocks = vec![];
for blinded in historical_blocks {
let block_root = blinded.canonical_root();
let full_block = harness
.chain
.get_block(&block_root)
.await
.expect("should get block")
.expect("should get block");
let blobs = harness.chain.get_blobs(&block_root).expect("blobs");
if let MaybeAvailableBlock::Available(block) = harness
.chain
.data_availability_checker
.verify_kzg_for_rpc_block(
RpcBlock::new(Some(block_root), Arc::new(full_block), Some(blobs)).unwrap(),
)
.expect("should verify kzg")
{
available_blocks.push(block);
}
}
// Corrupt the signature on the 1st block to ensure that the backfill processor is checking
// signatures correctly. Regression test for https://github.com/sigp/lighthouse/pull/5120.
let mut batch_with_invalid_first_block = available_blocks.clone();
batch_with_invalid_first_block[0] = {
let (block_root, block, blobs, data_columns) = available_blocks[0].clone().deconstruct();
let mut corrupt_block = (*block).clone();
*corrupt_block.signature_mut() = Signature::empty();
AvailableBlock::__new_for_testing(
block_root,
Arc::new(corrupt_block),
blobs,
data_columns,
Arc::new(spec),
)
};
// Importing the invalid batch should error.
assert!(matches!(
beacon_chain
.import_historical_block_batch(batch_with_invalid_first_block)
.unwrap_err(),
BeaconChainError::HistoricalBlockError(HistoricalBlockError::InvalidSignature)
));
// Importing the batch with valid signatures should succeed.
beacon_chain
.import_historical_block_batch(available_blocks.clone())
.unwrap();
assert_eq!(beacon_chain.store.get_oldest_block_slot(), 0);
// Resupplying the blocks should not fail, they can be safely ignored.
beacon_chain
.import_historical_block_batch(available_blocks)
.unwrap();
// The forwards iterator should now match the original chain
let forwards = beacon_chain
.forwards_iter_block_roots(Slot::new(0))
.unwrap()
.map(Result::unwrap)
.collect::<Vec<_>>();
let expected = harness
.chain
.forwards_iter_block_roots(Slot::new(0))
.unwrap()
.map(Result::unwrap)
.collect::<Vec<_>>();
assert_eq!(forwards, expected);
// All blocks can be loaded.
let mut prev_block_root = Hash256::zero();
for (block_root, slot) in beacon_chain
.forwards_iter_block_roots(Slot::new(0))
.unwrap()
.map(Result::unwrap)
{
let block = store.get_blinded_block(&block_root).unwrap().unwrap();
if block_root != prev_block_root {
assert_eq!(block.slot(), slot);
}
prev_block_root = block_root;
}
// All states from the oldest state slot can be loaded.
let (_, oldest_state_slot) = store.get_historic_state_limits();
for (state_root, slot) in beacon_chain
.forwards_iter_state_roots(oldest_state_slot)
.unwrap()
.map(Result::unwrap)
{
let mut state = store.get_state(&state_root, Some(slot)).unwrap().unwrap();
assert_eq!(state.slot(), slot);
assert_eq!(state.canonical_root().unwrap(), state_root);
}
// Anchor slot is still set to the slot of the checkpoint block.
assert_eq!(store.get_anchor_slot(), Some(wss_block.slot()));
// Reconstruct states.
store.clone().reconstruct_historic_states().unwrap();
assert_eq!(store.get_anchor_slot(), None);
}
/// Test that blocks and attestations that refer to states around an unaligned split state are
/// processed correctly.
#[tokio::test]
async fn process_blocks_and_attestations_for_unaligned_checkpoint() {
let temp = tempdir().unwrap();
let store = get_store(&temp);
let chain_config = ChainConfig {
reconstruct_historic_states: false,
..ChainConfig::default()
};
let harness = get_harness_generic(store.clone(), LOW_VALIDATOR_COUNT, chain_config);
let all_validators = (0..LOW_VALIDATOR_COUNT).collect::<Vec<_>>();
let split_slot = Slot::new(E::slots_per_epoch() * 4);
let pre_skips = 1;
let post_skips = 1;
// Build the chain up to the intended split slot, with 3 skips before the split.
let slots = (1..=split_slot.as_u64() - pre_skips)
.map(Slot::new)
.collect::<Vec<_>>();
let (genesis_state, genesis_state_root) = harness.get_current_state_and_root();
harness
.add_attested_blocks_at_slots(
genesis_state.clone(),
genesis_state_root,
&slots,
&all_validators,
)
.await;
// Before the split slot becomes finalized, create two forking blocks that build on the split
// block:
//
// - one that is invalid because it conflicts with finalization (slot <= finalized_slot)
// - one that is valid because its slot is not finalized (slot > finalized_slot)
let (unadvanced_split_state, unadvanced_split_state_root) =
harness.get_current_state_and_root();
let ((invalid_fork_block, _), _) = harness
.make_block(unadvanced_split_state.clone(), split_slot)
.await;
let ((valid_fork_block, _), _) = harness
.make_block(unadvanced_split_state.clone(), split_slot + 1)
.await;
// Advance the chain so that the intended split slot is finalized.
// Do not attest in the epoch boundary slot, to make attestation production later easier (no
// equivocations).
let finalizing_slot = split_slot + 2 * E::slots_per_epoch();
for _ in 0..pre_skips + post_skips {
harness.advance_slot();
}
harness.extend_to_slot(finalizing_slot - 1).await;
harness
.add_block_at_slot(finalizing_slot, harness.get_current_state())
.await
.unwrap();
// Check that the split slot is as intended.
let split = store.get_split_info();
assert_eq!(split.slot, split_slot);
assert_eq!(split.block_root, valid_fork_block.parent_root());
assert_ne!(split.state_root, unadvanced_split_state_root);
// Applying the invalid block should fail.
let err = harness
.chain
.process_block(
invalid_fork_block.canonical_root(),
invalid_fork_block.clone(),
NotifyExecutionLayer::Yes,
BlockImportSource::Lookup,
|| Ok(()),
)
.await
.unwrap_err();
assert!(matches!(err, BlockError::WouldRevertFinalizedSlot { .. }));
// Applying the valid block should succeed, but it should not become head.
harness
.chain
.process_block(
valid_fork_block.canonical_root(),
valid_fork_block.clone(),
NotifyExecutionLayer::Yes,
BlockImportSource::Lookup,
|| Ok(()),
)
.await
.unwrap();
harness.chain.recompute_head_at_current_slot().await;
assert_ne!(harness.head_block_root(), valid_fork_block.canonical_root());
// Attestations to the split block in the next 2 epochs should be processed successfully.
let attestation_start_slot = harness.get_current_slot();
let attestation_end_slot = attestation_start_slot + 2 * E::slots_per_epoch();
let (split_state_root, mut advanced_split_state) = harness
.chain
.store
.get_advanced_hot_state(split.block_root, split.slot, split.state_root)
.unwrap()
.unwrap();
complete_state_advance(
&mut advanced_split_state,
Some(split_state_root),
attestation_start_slot,
&harness.chain.spec,
)
.unwrap();
advanced_split_state
.build_caches(&harness.chain.spec)
.unwrap();
let advanced_split_state_root = advanced_split_state.update_tree_hash_cache().unwrap();
for slot in (attestation_start_slot.as_u64()..attestation_end_slot.as_u64()).map(Slot::new) {
let attestations = harness.make_attestations(
&all_validators,
&advanced_split_state,
advanced_split_state_root,
split.block_root.into(),
slot,
);
harness.advance_slot();
harness.process_attestations(attestations);
}
}
#[tokio::test]
async fn finalizes_after_resuming_from_db() {
let validator_count = 16;
let num_blocks_produced = MinimalEthSpec::slots_per_epoch() * 8;
let first_half = num_blocks_produced / 2;
let db_path = tempdir().unwrap();
let store = get_store(&db_path);
let harness = BeaconChainHarness::builder(MinimalEthSpec)
.default_spec()
.keypairs(KEYPAIRS[0..validator_count].to_vec())
.fresh_disk_store(store.clone())
.mock_execution_layer()
.build();
harness.advance_slot();
harness
.extend_chain(
first_half as usize,
BlockStrategy::OnCanonicalHead,
AttestationStrategy::AllValidators,
)
.await;
assert!(
harness
.chain
.head_snapshot()
.beacon_state
.finalized_checkpoint()
.epoch
> 0,
"the chain should have already finalized"
);
let latest_slot = harness.chain.slot().expect("should have a slot");
harness
.chain
.persist_head_and_fork_choice()
.expect("should persist the head and fork choice");
harness
.chain
.persist_op_pool()
.expect("should persist the op pool");
harness
.chain
.persist_eth1_cache()
.expect("should persist the eth1 cache");
let original_chain = harness.chain;
let resumed_harness = BeaconChainHarness::<DiskHarnessType<E>>::builder(MinimalEthSpec)
.default_spec()
.keypairs(KEYPAIRS[0..validator_count].to_vec())
.resumed_disk_store(store)
.testing_slot_clock(original_chain.slot_clock.clone())
.execution_layer(original_chain.execution_layer.clone())
.build();
assert_chains_pretty_much_the_same(&original_chain, &resumed_harness.chain);
// Set the slot clock of the resumed harness to be in the slot following the previous harness.
//
// This allows us to produce the block at the next slot.
resumed_harness
.chain
.slot_clock
.set_slot(latest_slot.as_u64() + 1);
resumed_harness
.extend_chain(
(num_blocks_produced - first_half) as usize,
BlockStrategy::OnCanonicalHead,
AttestationStrategy::AllValidators,
)
.await;
let state = &resumed_harness.chain.head_snapshot().beacon_state;
assert_eq!(
state.slot(),
num_blocks_produced,
"head should be at the current slot"
);
assert_eq!(
state.current_epoch(),
num_blocks_produced / MinimalEthSpec::slots_per_epoch(),
"head should be at the expected epoch"
);
assert_eq!(
state.current_justified_checkpoint().epoch,
state.current_epoch() - 1,
"the head should be justified one behind the current epoch"
);
assert_eq!(
state.finalized_checkpoint().epoch,
state.current_epoch() - 2,
"the head should be finalized two behind the current epoch"
);
}
#[tokio::test]
async fn revert_minority_fork_on_resume() {
let validator_count = 16;
let slots_per_epoch = MinimalEthSpec::slots_per_epoch();
let fork_epoch = Epoch::new(4);
let fork_slot = fork_epoch.start_slot(slots_per_epoch);
let initial_blocks = slots_per_epoch * fork_epoch.as_u64() - 1;
let post_fork_blocks = slots_per_epoch * 3;
let mut spec1 = MinimalEthSpec::default_spec();
spec1.altair_fork_epoch = None;
let mut spec2 = MinimalEthSpec::default_spec();
spec2.altair_fork_epoch = Some(fork_epoch);
let seconds_per_slot = spec1.seconds_per_slot;
let all_validators = (0..validator_count).collect::<Vec<usize>>();
// Chain with no fork epoch configured.
let db_path1 = tempdir().unwrap();
let store1 = get_store_generic(&db_path1, StoreConfig::default(), spec1.clone());
let harness1 = BeaconChainHarness::builder(MinimalEthSpec)
.spec(spec1)
.keypairs(KEYPAIRS[0..validator_count].to_vec())
.fresh_disk_store(store1)
.mock_execution_layer()
.build();
// Chain with fork epoch configured.
let db_path2 = tempdir().unwrap();
let store2 = get_store_generic(&db_path2, StoreConfig::default(), spec2.clone());
let harness2 = BeaconChainHarness::builder(MinimalEthSpec)
.spec(spec2.clone())
.keypairs(KEYPAIRS[0..validator_count].to_vec())
.fresh_disk_store(store2)
.mock_execution_layer()
.build();
// Apply the same blocks to both chains initially.
let mut state = harness1.get_current_state();
let mut block_root = harness1.chain.genesis_block_root;
for slot in (1..=initial_blocks).map(Slot::new) {
let state_root = state.update_tree_hash_cache().unwrap();
let attestations = harness1.make_attestations(
&all_validators,
&state,
state_root,
block_root.into(),
slot,
);
harness1.set_current_slot(slot);
harness2.set_current_slot(slot);
harness1.process_attestations(attestations.clone());
harness2.process_attestations(attestations);
let ((block, blobs), new_state) = harness1.make_block(state, slot).await;
harness1
.process_block(slot, block.canonical_root(), (block.clone(), blobs.clone()))
.await
.unwrap();
harness2
.process_block(slot, block.canonical_root(), (block.clone(), blobs.clone()))
.await
.unwrap();
state = new_state;
block_root = block.canonical_root();
}
assert_eq!(harness1.head_slot(), fork_slot - 1);
assert_eq!(harness2.head_slot(), fork_slot - 1);
// Fork the two chains.
let mut state1 = state.clone();
let mut state2 = state.clone();
let mut majority_blocks = vec![];
for i in 0..post_fork_blocks {
let slot = fork_slot + i;
// Attestations on majority chain.
let state_root = state.update_tree_hash_cache().unwrap();
let attestations = harness2.make_attestations(
&all_validators,
&state2,
state_root,
block_root.into(),
slot,
);
harness2.set_current_slot(slot);
harness2.process_attestations(attestations);
// Minority chain block (no attesters).
let ((block1, blobs1), new_state1) = harness1.make_block(state1, slot).await;
harness1
.process_block(slot, block1.canonical_root(), (block1, blobs1))
.await
.unwrap();
state1 = new_state1;
// Majority chain block (all attesters).
let ((block2, blobs2), new_state2) = harness2.make_block(state2, slot).await;
harness2
.process_block(slot, block2.canonical_root(), (block2.clone(), blobs2))
.await
.unwrap();
state2 = new_state2;
block_root = block2.canonical_root();
majority_blocks.push(block2);
}
let end_slot = fork_slot + post_fork_blocks - 1;
assert_eq!(harness1.head_slot(), end_slot);
assert_eq!(harness2.head_slot(), end_slot);
// Resume from disk with the hard-fork activated: this should revert the post-fork blocks.
// We have to do some hackery with the `slot_clock` so that the correct slot is set when
// the beacon chain builder loads the head block.
drop(harness1);
let resume_store = get_store_generic(&db_path1, StoreConfig::default(), spec2.clone());
let resumed_harness = TestHarness::builder(MinimalEthSpec)
.spec(spec2)
.keypairs(KEYPAIRS[0..validator_count].to_vec())
.resumed_disk_store(resume_store)
.override_store_mutator(Box::new(move |mut builder| {
builder = builder
.resume_from_db()
.unwrap()
.testing_slot_clock(Duration::from_secs(seconds_per_slot))
.unwrap();
builder
.get_slot_clock()
.unwrap()
.set_slot(end_slot.as_u64());
builder
}))
.mock_execution_layer()
.build();
// Head should now be just before the fork.
resumed_harness.chain.recompute_head_at_current_slot().await;
assert_eq!(resumed_harness.head_slot(), fork_slot - 1);
// Head track should know the canonical head and the rogue head.
assert_eq!(resumed_harness.chain.heads().len(), 2);
assert!(resumed_harness
.chain
.knows_head(&resumed_harness.head_block_root().into()));
// Apply blocks from the majority chain and trigger finalization.
let initial_split_slot = resumed_harness.chain.store.get_split_slot();
for block in &majority_blocks {
resumed_harness
.process_block_result((block.clone(), None))
.await
.unwrap();
// The canonical head should be the block from the majority chain.
resumed_harness.chain.recompute_head_at_current_slot().await;
assert_eq!(resumed_harness.head_slot(), block.slot());
assert_eq!(resumed_harness.head_block_root(), block.canonical_root());
}
let advanced_split_slot = resumed_harness.chain.store.get_split_slot();
// Check that the migration ran successfully.
assert!(advanced_split_slot > initial_split_slot);
// Check that there is only a single head now matching harness2 (the minority chain is gone).
let heads = resumed_harness.chain.heads();
assert_eq!(heads, harness2.chain.heads());
assert_eq!(heads.len(), 1);
}
// This test checks whether the schema downgrade from the latest version to some minimum supported
// version is correct. This is the easiest schema test to write without historic versions of
// Lighthouse on-hand, but has the disadvantage that the min version needs to be adjusted manually
// as old downgrades are deprecated.
#[tokio::test]
async fn schema_downgrade_to_min_version() {
let num_blocks_produced = E::slots_per_epoch() * 4;
let db_path = tempdir().unwrap();
let store = get_store(&db_path);
let harness = get_harness(store.clone(), LOW_VALIDATOR_COUNT);
let spec = &harness.chain.spec.clone();
harness
.extend_chain(
num_blocks_produced as usize,
BlockStrategy::OnCanonicalHead,
AttestationStrategy::AllValidators,
)
.await;
let min_version = SchemaVersion(19);
// Save the slot clock so that the new harness doesn't revert in time.
let slot_clock = harness.chain.slot_clock.clone();
// Close the database to ensure everything is written to disk.
drop(store);
drop(harness);
// Re-open the store.
let store = get_store(&db_path);
// Downgrade.
let deposit_contract_deploy_block = 0;
migrate_schema::<DiskHarnessType<E>>(
store.clone(),
deposit_contract_deploy_block,
CURRENT_SCHEMA_VERSION,
min_version,
store.logger().clone(),
spec,
)
.expect("schema downgrade to minimum version should work");
// Upgrade back.
migrate_schema::<DiskHarnessType<E>>(
store.clone(),
deposit_contract_deploy_block,
min_version,
CURRENT_SCHEMA_VERSION,
store.logger().clone(),
spec,
)
.expect("schema upgrade from minimum version should work");
// Recreate the harness.
let harness = BeaconChainHarness::builder(MinimalEthSpec)
.default_spec()
.keypairs(KEYPAIRS[0..LOW_VALIDATOR_COUNT].to_vec())
.logger(store.logger().clone())
.testing_slot_clock(slot_clock)
.resumed_disk_store(store.clone())
.mock_execution_layer()
.build();
check_finalization(&harness, num_blocks_produced);
check_split_slot(&harness, store.clone());
check_chain_dump(&harness, num_blocks_produced + 1);
check_iterators(&harness);
// Check that downgrading beyond the minimum version fails (bound is *tight*).
let min_version_sub_1 = SchemaVersion(min_version.as_u64().checked_sub(1).unwrap());
migrate_schema::<DiskHarnessType<E>>(
store.clone(),
deposit_contract_deploy_block,
CURRENT_SCHEMA_VERSION,
min_version_sub_1,
harness.logger().clone(),
spec,
)
.expect_err("should not downgrade below minimum version");
}
/// Check that blob pruning prunes blobs older than the data availability boundary.
#[tokio::test]
async fn deneb_prune_blobs_happy_case() {
let db_path = tempdir().unwrap();
let store = get_store(&db_path);
let Some(deneb_fork_epoch) = store.get_chain_spec().deneb_fork_epoch else {
// No-op prior to Deneb.
return;
};
let deneb_fork_slot = deneb_fork_epoch.start_slot(E::slots_per_epoch());
let num_blocks_produced = E::slots_per_epoch() * 8;
let harness = get_harness(store.clone(), LOW_VALIDATOR_COUNT);
harness
.extend_chain(
num_blocks_produced as usize,
BlockStrategy::OnCanonicalHead,
AttestationStrategy::AllValidators,
)
.await;
// Prior to manual pruning with an artifically low data availability boundary all blobs should
// be stored.
assert_eq!(
store.get_blob_info().oldest_blob_slot,
Some(deneb_fork_slot)
);
check_blob_existence(&harness, Slot::new(1), harness.head_slot(), true);
// Trigger blob pruning of blobs older than epoch 2.
let data_availability_boundary = Epoch::new(2);
store
.try_prune_blobs(true, data_availability_boundary)
.unwrap();
// Check oldest blob slot is updated accordingly and prior blobs have been deleted.
let oldest_blob_slot = store.get_blob_info().oldest_blob_slot.unwrap();
assert_eq!(
oldest_blob_slot,
data_availability_boundary.start_slot(E::slots_per_epoch())
);
check_blob_existence(&harness, Slot::new(0), oldest_blob_slot - 1, false);
check_blob_existence(&harness, oldest_blob_slot, harness.head_slot(), true);
}
/// Check that blob pruning does not prune without finalization.
#[tokio::test]
async fn deneb_prune_blobs_no_finalization() {
let db_path = tempdir().unwrap();
let store = get_store(&db_path);
let Some(deneb_fork_epoch) = store.get_chain_spec().deneb_fork_epoch else {
// No-op prior to Deneb.
return;
};
let deneb_fork_slot = deneb_fork_epoch.start_slot(E::slots_per_epoch());
let initial_num_blocks = E::slots_per_epoch() * 5;
let harness = get_harness(store.clone(), LOW_VALIDATOR_COUNT);
// Finalize to epoch 3.
harness
.extend_chain(
initial_num_blocks as usize,
BlockStrategy::OnCanonicalHead,
AttestationStrategy::AllValidators,
)
.await;
// Extend the chain for another few epochs without attestations.
let unfinalized_num_blocks = E::slots_per_epoch() * 3;
harness.advance_slot();
harness
.extend_chain(
unfinalized_num_blocks as usize,
BlockStrategy::OnCanonicalHead,
AttestationStrategy::SomeValidators(vec![]),
)
.await;
// Finalization should be at epoch 3.
let finalized_slot = Slot::new(E::slots_per_epoch() * 3);
assert_eq!(harness.get_current_state().finalized_checkpoint().epoch, 3);
assert_eq!(store.get_split_slot(), finalized_slot);
// All blobs should still be available.
assert_eq!(
store.get_blob_info().oldest_blob_slot,
Some(deneb_fork_slot)
);
check_blob_existence(&harness, Slot::new(0), harness.head_slot(), true);
// Attempt blob pruning of blobs older than epoch 4, which is newer than finalization.
let data_availability_boundary = Epoch::new(4);
store
.try_prune_blobs(true, data_availability_boundary)
.unwrap();
// Check oldest blob slot is only updated to finalization, and NOT to the DAB.
let oldest_blob_slot = store.get_blob_info().oldest_blob_slot.unwrap();
assert_eq!(oldest_blob_slot, finalized_slot);
check_blob_existence(&harness, Slot::new(0), finalized_slot - 1, false);
check_blob_existence(&harness, finalized_slot, harness.head_slot(), true);
}
/// Check that blob pruning does not fail trying to prune across the fork boundary.
#[tokio::test]
async fn deneb_prune_blobs_fork_boundary() {
let deneb_fork_epoch = Epoch::new(4);
let mut spec = ForkName::Capella.make_genesis_spec(E::default_spec());
spec.deneb_fork_epoch = Some(deneb_fork_epoch);
let deneb_fork_slot = deneb_fork_epoch.start_slot(E::slots_per_epoch());
let db_path = tempdir().unwrap();
let store = get_store_generic(&db_path, StoreConfig::default(), spec);
let harness = get_harness(store.clone(), LOW_VALIDATOR_COUNT);
let num_blocks = E::slots_per_epoch() * 7;
// Finalize to epoch 5.
harness
.extend_chain(
num_blocks as usize,
BlockStrategy::OnCanonicalHead,
AttestationStrategy::AllValidators,
)
.await;
// Finalization should be at epoch 5.
let finalized_epoch = Epoch::new(5);
let finalized_slot = finalized_epoch.start_slot(E::slots_per_epoch());
assert_eq!(
harness.get_current_state().finalized_checkpoint().epoch,
finalized_epoch
);
assert_eq!(store.get_split_slot(), finalized_slot);
// All blobs should still be available.
assert_eq!(
store.get_blob_info().oldest_blob_slot,
Some(deneb_fork_slot)
);
check_blob_existence(&harness, Slot::new(0), harness.head_slot(), true);
// Attempt pruning with data availability epochs that precede the fork epoch.
// No pruning should occur.
assert!(deneb_fork_epoch < finalized_epoch);
for data_availability_boundary in [Epoch::new(0), Epoch::new(3), deneb_fork_epoch] {
store
.try_prune_blobs(true, data_availability_boundary)
.unwrap();
// Check oldest blob slot is not updated.
assert_eq!(
store.get_blob_info().oldest_blob_slot,
Some(deneb_fork_slot)
);
}
// All blobs should still be available.
check_blob_existence(&harness, Slot::new(0), harness.head_slot(), true);
// Prune one epoch past the fork.
let pruned_slot = (deneb_fork_epoch + 1).start_slot(E::slots_per_epoch());
store.try_prune_blobs(true, deneb_fork_epoch + 1).unwrap();
assert_eq!(store.get_blob_info().oldest_blob_slot, Some(pruned_slot));
check_blob_existence(&harness, Slot::new(0), pruned_slot - 1, false);
check_blob_existence(&harness, pruned_slot, harness.head_slot(), true);
}
/// Check that blob pruning prunes blobs older than the data availability boundary with margin
/// applied.
#[tokio::test]
async fn deneb_prune_blobs_margin1() {
deneb_prune_blobs_margin_test(1).await;
}
#[tokio::test]
async fn deneb_prune_blobs_margin3() {
deneb_prune_blobs_margin_test(3).await;
}
#[tokio::test]
async fn deneb_prune_blobs_margin4() {
deneb_prune_blobs_margin_test(4).await;
}
async fn deneb_prune_blobs_margin_test(margin: u64) {
let config = StoreConfig {
blob_prune_margin_epochs: margin,
..StoreConfig::default()
};
let db_path = tempdir().unwrap();
let store = get_store_generic(&db_path, config, test_spec::<E>());
let Some(deneb_fork_epoch) = store.get_chain_spec().deneb_fork_epoch else {
// No-op prior to Deneb.
return;
};
let deneb_fork_slot = deneb_fork_epoch.start_slot(E::slots_per_epoch());
let num_blocks_produced = E::slots_per_epoch() * 8;
let harness = get_harness(store.clone(), LOW_VALIDATOR_COUNT);
harness
.extend_chain(
num_blocks_produced as usize,
BlockStrategy::OnCanonicalHead,
AttestationStrategy::AllValidators,
)
.await;
// Prior to manual pruning with an artifically low data availability boundary all blobs should
// be stored.
assert_eq!(
store.get_blob_info().oldest_blob_slot,
Some(deneb_fork_slot)
);
check_blob_existence(&harness, Slot::new(1), harness.head_slot(), true);
// Trigger blob pruning of blobs older than epoch 6 - margin (6 is the minimum, due to
// finalization).
let data_availability_boundary = Epoch::new(6);
let effective_data_availability_boundary =
data_availability_boundary - store.get_config().blob_prune_margin_epochs;
assert!(
effective_data_availability_boundary > 0,
"must be > 0 because epoch 0 won't get pruned alone"
);
store
.try_prune_blobs(true, data_availability_boundary)
.unwrap();
// Check oldest blob slot is updated accordingly and prior blobs have been deleted.
let oldest_blob_slot = store.get_blob_info().oldest_blob_slot.unwrap();
assert_eq!(
oldest_blob_slot,
effective_data_availability_boundary.start_slot(E::slots_per_epoch())
);
check_blob_existence(&harness, Slot::new(0), oldest_blob_slot - 1, false);
check_blob_existence(&harness, oldest_blob_slot, harness.head_slot(), true);
}
/// Check that a database with `blobs_db=false` can be upgraded to `blobs_db=true` before Deneb.
#[tokio::test]
async fn change_to_separate_blobs_db_before_deneb() {
let db_path = tempdir().unwrap();
let store = get_store(&db_path);
// Only run this test on forks prior to Deneb. If the blobs database already has blobs, we can't
// move it.
if store.get_chain_spec().deneb_fork_epoch.is_some() {
return;
}
let init_blob_info = store.get_blob_info();
assert!(
init_blob_info.blobs_db,
"separate blobs DB should be the default"
);
// Change to `blobs_db=false` to emulate legacy Deneb DB.
let legacy_blob_info = BlobInfo {
blobs_db: false,
..init_blob_info
};
store
.compare_and_set_blob_info_with_write(init_blob_info.clone(), legacy_blob_info.clone())
.unwrap();
assert_eq!(store.get_blob_info(), legacy_blob_info);
// Re-open the DB and check that `blobs_db` gets changed back to true.
drop(store);
let store = get_store(&db_path);
assert_eq!(store.get_blob_info(), init_blob_info);
}
/// Check that there are blob sidecars (or not) at every slot in the range.
fn check_blob_existence(
harness: &TestHarness,
start_slot: Slot,
end_slot: Slot,
should_exist: bool,
) {
let mut blobs_seen = 0;
for (block_root, slot) in harness
.chain
.forwards_iter_block_roots_until(start_slot, end_slot)
.unwrap()
.map(Result::unwrap)
{
if let Some(blobs) = harness.chain.store.get_blobs(&block_root).unwrap() {
assert!(should_exist, "blobs at slot {slot} exist but should not");
blobs_seen += blobs.len();
} else {
// We don't actually store empty blobs, so unfortunately we can't assert anything
// meaningful here (like asserting that the blob should not exist).
}
}
if should_exist {
assert_ne!(blobs_seen, 0, "expected non-zero number of blobs");
}
}
#[tokio::test]
async fn prune_historic_states() {
let num_blocks_produced = E::slots_per_epoch() * 5;
let db_path = tempdir().unwrap();
let store = get_store(&db_path);
let harness = get_harness(store.clone(), LOW_VALIDATOR_COUNT);
let genesis_state_root = harness.chain.genesis_state_root;
let genesis_state = harness
.chain
.get_state(&genesis_state_root, None)
.unwrap()
.unwrap();
harness
.extend_chain(
num_blocks_produced as usize,
BlockStrategy::OnCanonicalHead,
AttestationStrategy::AllValidators,
)
.await;
// Check historical state is present.
let state_roots_iter = harness
.chain
.forwards_iter_state_roots(Slot::new(0))
.unwrap();
for (state_root, slot) in state_roots_iter
.take(E::slots_per_epoch() as usize)
.map(Result::unwrap)
{
assert!(store.get_state(&state_root, Some(slot)).unwrap().is_some());
}
store
.prune_historic_states(genesis_state_root, &genesis_state)
.unwrap();
// Check that anchor info is updated.
let anchor_info = store.get_anchor_info().unwrap();
assert_eq!(anchor_info.state_lower_limit, 0);
assert_eq!(anchor_info.state_upper_limit, STATE_UPPER_LIMIT_NO_RETAIN);
// Historical states should be pruned.
let state_roots_iter = harness
.chain
.forwards_iter_state_roots(Slot::new(1))
.unwrap();
for (state_root, slot) in state_roots_iter
.take(E::slots_per_epoch() as usize)
.map(Result::unwrap)
{
assert!(store.get_state(&state_root, Some(slot)).unwrap().is_none());
}
// Ensure that genesis state is still accessible
let genesis_state_root = harness.chain.genesis_state_root;
assert!(store
.get_state(&genesis_state_root, Some(Slot::new(0)))
.unwrap()
.is_some());
// Run for another two epochs.
let additional_blocks_produced = 2 * E::slots_per_epoch();
harness
.extend_slots(additional_blocks_produced as usize)
.await;
check_finalization(&harness, num_blocks_produced + additional_blocks_produced);
check_split_slot(&harness, store);
}
/// Checks that two chains are the same, for the purpose of these tests.
///
/// Several fields that are hard/impossible to check are ignored (e.g., the store).
fn assert_chains_pretty_much_the_same<T: BeaconChainTypes>(a: &BeaconChain<T>, b: &BeaconChain<T>) {
assert_eq!(a.spec, b.spec, "spec should be equal");
assert_eq!(a.op_pool, b.op_pool, "op_pool should be equal");
let a_head = a.head_snapshot();
let b_head = b.head_snapshot();
assert_eq!(
a_head.beacon_block_root, b_head.beacon_block_root,
"head block roots should be equal"
);
assert_eq!(
a_head.beacon_block, b_head.beacon_block,
"head blocks should be equal"
);
// Drop all caches to prevent them messing with the equality check.
let mut a_head_state = a_head.beacon_state.clone();
a_head_state.drop_all_caches().unwrap();
let mut b_head_state = b_head.beacon_state.clone();
b_head_state.drop_all_caches().unwrap();
assert_eq!(a_head_state, b_head_state, "head states should be equal");
assert_eq!(a.heads(), b.heads(), "heads() should be equal");
assert_eq!(
a.genesis_block_root, b.genesis_block_root,
"genesis_block_root should be equal"
);
let slot = a.slot().unwrap();
let spec = T::EthSpec::default_spec();
assert!(
a.canonical_head
.fork_choice_write_lock()
.get_head(slot, &spec)
.unwrap()
== b.canonical_head
.fork_choice_write_lock()
.get_head(slot, &spec)
.unwrap(),
"fork_choice heads should be equal"
);
}
/// Check that the head state's slot matches `expected_slot`.
fn check_slot(harness: &TestHarness, expected_slot: u64) {
let state = &harness.chain.head_snapshot().beacon_state;
assert_eq!(
state.slot(),
expected_slot,
"head should be at the current slot"
);
}
/// Check that the chain has finalized under best-case assumptions, and check the head slot.
fn check_finalization(harness: &TestHarness, expected_slot: u64) {
let state = &harness.chain.head_snapshot().beacon_state;
check_slot(harness, expected_slot);
assert_eq!(
state.current_justified_checkpoint().epoch,
state.current_epoch() - 1,
"the head should be justified one behind the current epoch"
);
assert_eq!(
state.finalized_checkpoint().epoch,
state.current_epoch() - 2,
"the head should be finalized two behind the current epoch"
);
}
/// Check that the HotColdDB's split_slot is equal to the start slot of the last finalized epoch.
fn check_split_slot(harness: &TestHarness, store: Arc<HotColdDB<E, LevelDB<E>, LevelDB<E>>>) {
let split_slot = store.get_split_slot();
assert_eq!(
harness
.chain
.head_snapshot()
.beacon_state
.finalized_checkpoint()
.epoch
.start_slot(E::slots_per_epoch()),
split_slot
);
assert_ne!(split_slot, 0);
}
/// Check that all the states in a chain dump have the correct tree hash.
fn check_chain_dump(harness: &TestHarness, expected_len: u64) {
let mut chain_dump = harness.chain.chain_dump().unwrap();
let split_slot = harness.chain.store.get_split_slot();
assert_eq!(chain_dump.len() as u64, expected_len);
for checkpoint in &mut chain_dump {
// Check that the tree hash of the stored state is as expected
assert_eq!(
checkpoint.beacon_state_root(),
checkpoint.beacon_state.update_tree_hash_cache().unwrap(),
"tree hash of stored state is incorrect"
);
// Check that looking up the state root with no slot hint succeeds.
// This tests the state root -> slot mapping.
assert_eq!(
harness
.chain
.store
.get_state(&checkpoint.beacon_state_root(), None)
.expect("no error")
.expect("state exists")
.slot(),
checkpoint.beacon_state.slot()
);
// Check presence of execution payload on disk.
if harness.chain.spec.bellatrix_fork_epoch.is_some() {
assert_eq!(
harness
.chain
.store
.execution_payload_exists(&checkpoint.beacon_block_root)
.unwrap(),
checkpoint.beacon_block.slot() >= split_slot,
"incorrect payload storage for block at slot {}: {:?}",
checkpoint.beacon_block.slot(),
checkpoint.beacon_block_root,
);
}
}
// Check the forwards block roots iterator against the chain dump
let chain_dump_block_roots = chain_dump
.iter()
.map(|checkpoint| (checkpoint.beacon_block_root, checkpoint.beacon_block.slot()))
.collect::<Vec<_>>();
let mut forward_block_roots = harness
.chain
.forwards_iter_block_roots(Slot::new(0))
.expect("should get iter")
.map(Result::unwrap)
.collect::<Vec<_>>();
// Drop the block roots for skipped slots.
forward_block_roots.dedup_by_key(|(block_root, _)| *block_root);
for i in 0..std::cmp::max(chain_dump_block_roots.len(), forward_block_roots.len()) {
assert_eq!(
chain_dump_block_roots[i],
forward_block_roots[i],
"split slot is {}",
harness.chain.store.get_split_slot()
);
}
}
/// Check that every state from the canonical chain is in the database, and that the
/// reverse state and block root iterators reach genesis.
fn check_iterators(harness: &TestHarness) {
let mut max_slot = None;
for (state_root, slot) in harness
.chain
.forwards_iter_state_roots(Slot::new(0))
.expect("should get iter")
.map(Result::unwrap)
{
assert!(
harness
.chain
.store
.get_state(&state_root, Some(slot))
.unwrap()
.is_some(),
"state {:?} from canonical chain should be in DB",
state_root
);
max_slot = Some(slot);
}
// Assert that we reached the head.
assert_eq!(max_slot, Some(harness.head_slot()));
// Assert that the block root iterator reaches the head.
assert_eq!(
harness
.chain
.forwards_iter_block_roots(Slot::new(0))
.expect("should get iter")
.last()
.map(Result::unwrap)
.map(|(_, slot)| slot),
Some(harness.head_slot())
);
}
fn get_finalized_epoch_boundary_blocks(
dump: &[BeaconSnapshot<MinimalEthSpec, BlindedPayload<MinimalEthSpec>>],
) -> HashSet<SignedBeaconBlockHash> {
dump.iter()
.cloned()
.map(|checkpoint| checkpoint.beacon_state.finalized_checkpoint().root.into())
.collect()
}
fn get_blocks(
dump: &[BeaconSnapshot<MinimalEthSpec, BlindedPayload<MinimalEthSpec>>],
) -> HashSet<SignedBeaconBlockHash> {
dump.iter()
.cloned()
.map(|checkpoint| checkpoint.beacon_block_root.into())
.collect()
}
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