#![cfg(not(debug_assertions))] use beacon_chain::attestation_verification::Error as AttnError; use beacon_chain::builder::BeaconChainBuilder; use beacon_chain::test_utils::{ test_spec, AttestationStrategy, BeaconChainHarness, BlockStrategy, DiskHarnessType, }; use beacon_chain::{ historical_blocks::HistoricalBlockError, migrate::MigratorConfig, BeaconChain, BeaconChainError, BeaconChainTypes, BeaconSnapshot, ChainConfig, ServerSentEventHandler, WhenSlotSkipped, }; use lazy_static::lazy_static; use logging::test_logger; use maplit::hashset; use rand::Rng; use std::collections::HashMap; use std::collections::HashSet; use std::convert::TryInto; use std::sync::Arc; use std::time::Duration; use store::{ iter::{BlockRootsIterator, StateRootsIterator}, HotColdDB, LevelDB, StoreConfig, }; use tempfile::{tempdir, TempDir}; use tree_hash::TreeHash; 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; lazy_static! { /// A cached set of keys. static ref KEYPAIRS: Vec = types::test_utils::generate_deterministic_keypairs(HIGH_VALIDATOR_COUNT); } type E = MinimalEthSpec; type TestHarness = BeaconChainHarness>; fn get_store(db_path: &TempDir) -> Arc, LevelDB>> { get_store_with_spec(db_path, test_spec::()) } fn get_store_with_spec( db_path: &TempDir, spec: ChainSpec, ) -> Arc, LevelDB>> { let hot_path = db_path.path().join("hot_db"); let cold_path = db_path.path().join("cold_db"); let config = StoreConfig::default(); let log = test_logger(); HotColdDB::open(&hot_path, &cold_path, |_, _, _| Ok(()), config, spec, log) .expect("disk store should initialize") } fn get_harness( store: Arc, LevelDB>>, validator_count: usize, ) -> TestHarness { let harness = BeaconChainHarness::builder(MinimalEthSpec) .default_spec() .keypairs(KEYPAIRS[0..validator_count].to_vec()) .fresh_disk_store(store) .build(); harness.advance_slot(); harness } #[test] 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, ); check_finalization(&harness, num_blocks_produced); check_split_slot(&harness, store); check_chain_dump(&harness, num_blocks_produced + 1); check_iterators(&harness); } #[test] 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, ); harness.advance_slot(); num_blocks_produced += 1; head_slot = slot; } else { harness.advance_slot(); } } let state = &harness.chain.head().expect("should get head").beacon_state; assert_eq!( state.slot(), num_slots, "head should be at the current slot" ); check_split_slot(&harness, store); check_chain_dump(&harness, num_blocks_produced + 1); check_iterators(&harness); } #[test] 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, ); 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, ); 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 #[test] 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() .expect("should get head") .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, ); // Check that genesis value is still present assert!(harness .chain .head() .expect("should get head") .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, ); assert!(harness .chain .head() .expect("should get head") .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. #[test] 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, ); 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. #[test] 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::>(); let mut late_attestations = vec![]; for _ in 0..num_blocks_produced { harness.extend_chain( 1, BlockStrategy::OnCanonicalHead, AttestationStrategy::SomeValidators(timely_validators.clone()), ); let head = harness.chain.head().expect("head ok"); 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_block(&block_root).unwrap().expect("block exists"); let epoch_boundary_state = store .load_epoch_boundary_state(&block.state_root()) .expect("no error") .expect("epoch boundary state exists"); let ebs_of_ebs = store .load_epoch_boundary_state(&epoch_boundary_state.canonical_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 .chain .head_info() .expect("should get head") .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] fn delete_blocks_and_states() { 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 = BeaconChainHarness::builder(MinimalEthSpec) .default_spec() .keypairs(validators_keypairs) .fresh_disk_store(store.clone()) .build(); let unforked_blocks: u64 = 4 * E::slots_per_epoch(); // Finalize an initial portion of the chain. let initial_slots: Vec = (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); // Create a fork post-finalization. let two_thirds = (LOW_VALIDATOR_COUNT / 3) * 2; let honest_validators: Vec = (0..two_thirds).collect(); let faulty_validators: Vec = (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_u64..(slot_u64 + fork_blocks)) .map(Into::into) .collect(); let fork2_slots: Vec = (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), ]); let honest_head = results[0].2; let faulty_head = results[1].2; assert_ne!(honest_head, faulty_head, "forks should be distinct"); let head_info = harness.chain.head_info().expect("should get head"); assert_eq!(head_info.slot, unforked_blocks + fork_blocks); assert_eq!( head_info.block_root, honest_head.into(), "the honest chain should be the canonical chain", ); let faulty_head_block = store .get_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.clone(), &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.clone(), &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.clone(), &faulty_head_state).map(Result::unwrap) { if slot <= unforked_blocks + 1 { break; } store.delete_block(&block_root).unwrap(); assert_eq!(store.get_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 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 = BeaconChainHarness::builder(MinimalEthSpec) .default_spec() .keypairs(validators_keypairs) .fresh_disk_store(store) .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 = (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); } assert!(num_fork1_validators <= LOW_VALIDATOR_COUNT); let fork1_validators: Vec = (0..num_fork1_validators).collect(); let fork2_validators: Vec = (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_u64..(slot_u64 + num_fork1_blocks)) .map(Into::into) .collect(); let fork2_slots: Vec = (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), ]); 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. #[test] 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, ); } #[test] 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, ); } // Check that the op pool safely includes multiple attestations per block when necessary. // This checks the correctness of the shuffling compatibility memoization. #[test] 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, ); let head = harness.chain.head().unwrap(); 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(); assert_eq!( snapshot .beacon_block .deconstruct() .0 .body() .attestations() .len() as u64, if slot <= 1 { 0 } else { committees_per_slot } ); } } #[test] 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); // Skip the block at the end of the first epoch. let head_block_root = harness.extend_chain( 4 * E::slots_per_epoch() as usize, BlockStrategy::OnCanonicalHead, AttestationStrategy::AllValidators, ); check_shuffling_compatible( &harness, &get_state_for_block(&harness, head_block_root), head_block_root, true, true, None, None, ); } #[test] 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, ); harness.advance_slot(); harness.advance_slot(); let head_block_root = harness.extend_chain( 2 * E::slots_per_epoch() as usize, BlockStrategy::OnCanonicalHead, AttestationStrategy::AllValidators, ); check_shuffling_compatible( &harness, &get_state_for_block(&harness, head_block_root), head_block_root, true, true, Some(E::slots_per_epoch() - 2), Some(E::slots_per_epoch() - 2), ); } #[test] 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, ); 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, true, true, None, None); check_shuffling_compatible(&harness, &head1_state, head2, false, false, None, None); check_shuffling_compatible(&harness, &head2_state, head1, false, false, None, None); check_shuffling_compatible(&harness, &head2_state, head2, true, true, None, None); drop(db_path); } #[test] 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, ); 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, true, true, None, None); check_shuffling_compatible(&harness, &head1_state, head2, false, true, None, None); // NOTE: don't check this case, as block 14 from the first chain appears valid on the second // chain due to it matching the second chain's block 15. // check_shuffling_compatible(&harness, &head2_state, head1, false, true, None, None); check_shuffling_compatible( &harness, &head2_state, head2, true, true, // Required because of the skipped slot. Some(2 * E::slots_per_epoch() - 2), None, ); drop(db_path); } fn get_state_for_block(harness: &TestHarness, block_root: Hash256) -> BeaconState { let head_block = harness.chain.get_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, head_block_root: Hash256, current_epoch_valid: bool, previous_epoch_valid: bool, current_epoch_cutoff_slot: Option, previous_epoch_cutoff_slot: Option, ) { let shuffling_lookahead = harness.chain.spec.min_seed_lookahead.as_u64() + 1; let current_pivot_slot = (head_state.current_epoch() - shuffling_lookahead).end_slot(E::slots_per_epoch()); let previous_pivot_slot = (head_state.previous_epoch() - shuffling_lookahead).end_slot(E::slots_per_epoch()); for maybe_tuple in harness .chain .rev_iter_block_roots_from(head_block_root) .unwrap() { let (block_root, slot) = maybe_tuple.unwrap(); // Shuffling is compatible targeting the current epoch, // if slot is greater than or equal to the current epoch pivot block. assert_eq!( harness.chain.shuffling_is_compatible( &block_root, head_state.current_epoch(), &head_state ), current_epoch_valid && slot >= current_epoch_cutoff_slot.unwrap_or(current_pivot_slot.as_u64()) ); // Similarly for the previous epoch assert_eq!( harness.chain.shuffling_is_compatible( &block_root, head_state.previous_epoch(), &head_state ), previous_epoch_valid && slot >= previous_epoch_cutoff_slot.unwrap_or(previous_pivot_slot.as_u64()) ); // Targeting the next epoch should always return false assert_eq!( harness.chain.shuffling_is_compatible( &block_root, head_state.current_epoch() + 1, &head_state ), false ); // Targeting two epochs before the current epoch should also 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 #[test] fn prunes_abandoned_fork_between_two_finalized_checkpoints() { const HONEST_VALIDATOR_COUNT: usize = 16 + 0; const ADVERSARIAL_VALIDATOR_COUNT: usize = 8 - 0; const VALIDATOR_COUNT: usize = HONEST_VALIDATOR_COUNT + ADVERSARIAL_VALIDATOR_COUNT; let validators_keypairs = types::test_utils::generate_deterministic_keypairs(VALIDATOR_COUNT); let honest_validators: Vec = (0..HONEST_VALIDATOR_COUNT).collect(); let adversarial_validators: Vec = (HONEST_VALIDATOR_COUNT..VALIDATOR_COUNT).collect(); let rig = BeaconChainHarness::builder(MinimalEthSpec) .default_spec() .keypairs(validators_keypairs) .fresh_ephemeral_store() .build(); let slots_per_epoch = rig.slots_per_epoch(); let (mut state, state_root) = rig.get_current_state_and_root(); let canonical_chain_slots: Vec = (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, ); state = new_state; let canonical_chain_slot: u64 = rig.get_current_slot().into(); let stray_slots: Vec = (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, ); // 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 = ((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, ); // 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 {} 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)); } #[test] fn pruning_does_not_touch_abandoned_block_shared_with_canonical_chain() { const HONEST_VALIDATOR_COUNT: usize = 16 + 0; const ADVERSARIAL_VALIDATOR_COUNT: usize = 8 - 0; const VALIDATOR_COUNT: usize = HONEST_VALIDATOR_COUNT + ADVERSARIAL_VALIDATOR_COUNT; let validators_keypairs = types::test_utils::generate_deterministic_keypairs(VALIDATOR_COUNT); let honest_validators: Vec = (0..HONEST_VALIDATOR_COUNT).collect(); let adversarial_validators: Vec = (HONEST_VALIDATOR_COUNT..VALIDATOR_COUNT).collect(); let rig = BeaconChainHarness::builder(MinimalEthSpec) .default_spec() .keypairs(validators_keypairs) .fresh_ephemeral_store() .build(); 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 = (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, ); // Fill up 1st epoch let canonical_chain_slots_first_epoch: Vec = (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, ); let canonical_chain_slot: u64 = rig.get_current_slot().into(); let stray_chain_slots_first_epoch: Vec = (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, ); // 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 = ((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, ); // 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)); } #[test] fn pruning_does_not_touch_blocks_prior_to_finalization() { const HONEST_VALIDATOR_COUNT: usize = 16; const ADVERSARIAL_VALIDATOR_COUNT: usize = 8; const VALIDATOR_COUNT: usize = HONEST_VALIDATOR_COUNT + ADVERSARIAL_VALIDATOR_COUNT; let validators_keypairs = types::test_utils::generate_deterministic_keypairs(VALIDATOR_COUNT); let honest_validators: Vec = (0..HONEST_VALIDATOR_COUNT).collect(); let adversarial_validators: Vec = (HONEST_VALIDATOR_COUNT..VALIDATOR_COUNT).collect(); let rig = BeaconChainHarness::builder(MinimalEthSpec) .default_spec() .keypairs(validators_keypairs) .fresh_ephemeral_store() .build(); 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 = (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, ); 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 = ((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, ); // 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 = ((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); // 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)); } #[test] fn prunes_fork_growing_past_youngest_finalized_checkpoint() { const HONEST_VALIDATOR_COUNT: usize = 16 + 0; const ADVERSARIAL_VALIDATOR_COUNT: usize = 8 - 0; const VALIDATOR_COUNT: usize = HONEST_VALIDATOR_COUNT + ADVERSARIAL_VALIDATOR_COUNT; let validators_keypairs = types::test_utils::generate_deterministic_keypairs(VALIDATOR_COUNT); let honest_validators: Vec = (0..HONEST_VALIDATOR_COUNT).collect(); let adversarial_validators: Vec = (HONEST_VALIDATOR_COUNT..VALIDATOR_COUNT).collect(); let rig = BeaconChainHarness::builder(MinimalEthSpec) .default_spec() .keypairs(validators_keypairs) .fresh_ephemeral_store() .build(); let (state, state_root) = rig.get_current_state_and_root(); // Fill up 0th epoch with canonical chain blocks let zeroth_epoch_slots: Vec = (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, ); // Fill up 1st epoch. Contains a fork. let slots_first_epoch: Vec = (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, ); let (canonical_blocks_first_epoch, _, _, mut canonical_state) = rig.add_attested_blocks_at_slots(state, state_root, &slots_first_epoch, &honest_validators); // Fill up 2nd epoch. Extends both the canonical chain and the fork. let stray_slots_second_epoch: Vec = (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, ); // Precondition: Ensure all stray_blocks blocks are still known let stray_blocks: HashMap = stray_blocks_first_epoch .into_iter() .chain(stray_blocks_second_epoch.into_iter()) .collect(); let stray_states: HashMap = 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 = (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, ); // Postconditions let canonical_blocks: HashMap = 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. #[test] fn prunes_skipped_slots_states() { const HONEST_VALIDATOR_COUNT: usize = 16 + 0; const ADVERSARIAL_VALIDATOR_COUNT: usize = 8 - 0; const VALIDATOR_COUNT: usize = HONEST_VALIDATOR_COUNT + ADVERSARIAL_VALIDATOR_COUNT; let validators_keypairs = types::test_utils::generate_deterministic_keypairs(VALIDATOR_COUNT); let honest_validators: Vec = (0..HONEST_VALIDATOR_COUNT).collect(); let adversarial_validators: Vec = (HONEST_VALIDATOR_COUNT..VALIDATOR_COUNT).collect(); let rig = BeaconChainHarness::builder(MinimalEthSpec) .default_spec() .keypairs(validators_keypairs) .fresh_ephemeral_store() .build(); let (state, state_root) = rig.get_current_state_and_root(); let canonical_slots_zeroth_epoch: Vec = (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, ); let skipped_slot: Slot = (rig.epoch_start_slot(1) + 1).into(); let stray_slots: Vec = ((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, ); // 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 = ((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, ); // Postconditions let canonical_blocks: HashMap = 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. #[test] fn finalizes_non_epoch_start_slot() { const HONEST_VALIDATOR_COUNT: usize = 16 + 0; const ADVERSARIAL_VALIDATOR_COUNT: usize = 8 - 0; const VALIDATOR_COUNT: usize = HONEST_VALIDATOR_COUNT + ADVERSARIAL_VALIDATOR_COUNT; let validators_keypairs = types::test_utils::generate_deterministic_keypairs(VALIDATOR_COUNT); let honest_validators: Vec = (0..HONEST_VALIDATOR_COUNT).collect(); let adversarial_validators: Vec = (HONEST_VALIDATOR_COUNT..VALIDATOR_COUNT).collect(); let rig = BeaconChainHarness::builder(MinimalEthSpec) .default_spec() .keypairs(validators_keypairs) .fresh_ephemeral_store() .build(); let (state, state_root) = rig.get_current_state_and_root(); let canonical_slots_zeroth_epoch: Vec = (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, ); let skipped_slot: Slot = rig.epoch_start_slot(1).into(); let stray_slots: Vec = ((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, ); // 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 = ((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, ); // Postconditions let canonical_blocks: HashMap = 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, ) { for &block_hash in blocks { let block = harness.chain.get_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, ) { 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, ) { 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, ) { for &block_hash in blocks { let block = harness.chain.get_block(&block_hash.into()).unwrap(); assert!( block.is_none(), "did not expect block {:?} to be in the DB", block_hash ); } } #[test] 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); } #[test] 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, ); } #[test] 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, ); } #[test] 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); pruning_test(slots_per_epoch - 1, 2, slots_per_epoch, 1, slots_per_epoch); 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, ); 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, ); pruning_test( 2 * slots_per_epoch - 1, slots_per_epoch as u64, 1, 0, 2 * slots_per_epoch, ); } /// Generic harness for pruning tests. 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 = (0..HONEST_VALIDATOR_COUNT).collect(); let faulty_validators: Vec = (HONEST_VALIDATOR_COUNT..VALIDATOR_COUNT).collect(); let slots = |start: Slot, num_blocks: u64| -> Vec { (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, ); 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, ), ]); 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::>(); 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, ); // Check that finalization has advanced past the divergence slot. assert!( harness .chain .head_info() .unwrap() .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::>(); 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()); } #[test] fn garbage_collect_temp_states_from_failed_block() { let db_path = tempdir().unwrap(); 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); let (mut block, _) = signed_block.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 = 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).unwrap_err(); assert_eq!( store.iter_temporary_state_roots().count(), block_slot.as_usize() - 1 ); drop(harness); drop(store); // 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); } #[test] fn weak_subjectivity_sync() { // Build an initial chain on one harness, representing a synced node with full history. let num_initial_blocks = E::slots_per_epoch() * 11; 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); harness.extend_chain( num_initial_blocks as usize, BlockStrategy::OnCanonicalHead, AttestationStrategy::AllValidators, ); let genesis_state = full_store .get_state(&harness.chain.genesis_state_root, Some(Slot::new(0))) .unwrap() .unwrap(); let wss_checkpoint = harness.chain.head_info().unwrap().finalized_checkpoint; let wss_block = harness.get_block(wss_checkpoint.root.into()).unwrap(); let wss_state = full_store .get_state(&wss_block.state_root(), None) .unwrap() .unwrap(); let wss_slot = wss_block.slot(); // Add more blocks that advance finalization further. harness.advance_slot(); harness.extend_chain( num_final_blocks as usize, BlockStrategy::OnCanonicalHead, AttestationStrategy::AllValidators, ); 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::(); let seconds_per_slot = spec.seconds_per_slot; // Initialise a new beacon chain from the finalized checkpoint let beacon_chain = BeaconChainBuilder::new(MinimalEthSpec) .store(store.clone()) .custom_spec(test_spec::()) .weak_subjectivity_state(wss_state, wss_block.clone(), genesis_state) .unwrap() .logger(log.clone()) .store_migrator_config(MigratorConfig::default().blocking()) .dummy_eth1_backend() .expect("should build dummy backend") .testing_slot_clock(Duration::from_secs(seconds_per_slot)) .expect("should configure testing slot clock") .shutdown_sender(shutdown_tx) .chain_config(ChainConfig::default()) .event_handler(Some(ServerSentEventHandler::new_with_capacity( log.clone(), 1, ))) .monitor_validators(true, vec![], log) .build() .expect("should build"); // Apply blocks forward to reach head. let chain_dump = harness.chain.chain_dump().unwrap(); let new_blocks = &chain_dump[wss_slot.as_usize() + 1..]; assert_eq!(new_blocks[0].beacon_block.slot(), wss_slot + 1); for snapshot in new_blocks { let block = &snapshot.beacon_block; beacon_chain.slot_clock.set_slot(block.slot().as_u64()); beacon_chain.process_block(block.clone()).unwrap(); beacon_chain.fork_choice().unwrap(); // Check that the new block's state can be loaded correctly. let state_root = block.state_root(); let mut state = beacon_chain .store .get_state(&state_root, Some(block.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::>(); beacon_chain .import_historical_block_batch(&historical_blocks) .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(&historical_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::>(); let expected = harness .chain .forwards_iter_block_roots(Slot::new(0)) .unwrap() .map(Result::unwrap) .collect::>(); assert_eq!(forwards, expected); // All blocks can be loaded. for (block_root, slot) in beacon_chain .forwards_iter_block_roots(Slot::new(0)) .unwrap() .map(Result::unwrap) { let block = store.get_block(&block_root).unwrap().unwrap(); assert_eq!(block.slot(), slot); } // 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 state = store.get_state(&state_root, Some(slot)).unwrap().unwrap(); assert_eq!(state.slot(), slot); assert_eq!(state.canonical_root(), state_root); } // Anchor slot is still set to the starting slot. assert_eq!(store.get_anchor_slot(), Some(wss_slot)); // Reconstruct states. store.clone().reconstruct_historic_states().unwrap(); assert_eq!(store.get_anchor_slot(), None); } #[test] 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()) .build(); harness.advance_slot(); harness.extend_chain( first_half as usize, BlockStrategy::OnCanonicalHead, AttestationStrategy::AllValidators, ); assert!( harness .chain .head() .expect("should read head") .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::builder(MinimalEthSpec) .default_spec() .keypairs(KEYPAIRS[0..validator_count].to_vec()) .resumed_disk_store(store) .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, ); let state = &resumed_harness .chain .head() .expect("should read head") .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" ); } #[test] 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::>(); // Chain with no fork epoch configured. let db_path1 = tempdir().unwrap(); let store1 = get_store_with_spec(&db_path1, spec1.clone()); let harness1 = BeaconChainHarness::builder(MinimalEthSpec) .spec(spec1) .keypairs(KEYPAIRS[0..validator_count].to_vec()) .fresh_disk_store(store1) .build(); // Chain with fork epoch configured. let db_path2 = tempdir().unwrap(); let store2 = get_store_with_spec(&db_path2, spec2.clone()); let harness2 = BeaconChainHarness::builder(MinimalEthSpec) .spec(spec2.clone()) .keypairs(KEYPAIRS[0..validator_count].to_vec()) .fresh_disk_store(store2) .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, new_state) = harness1.make_block(state, slot); harness1.process_block(slot, block.clone()).unwrap(); harness2.process_block(slot, block.clone()).unwrap(); state = new_state; block_root = block.canonical_root(); } assert_eq!(harness1.chain.head_info().unwrap().slot, fork_slot - 1); assert_eq!(harness2.chain.head_info().unwrap().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, new_state1) = harness1.make_block(state1, slot); harness1.process_block(slot, block1).unwrap(); state1 = new_state1; // Majority chain block (all attesters). let (block2, new_state2) = harness2.make_block(state2, slot); harness2.process_block(slot, block2.clone()).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.chain.head_info().unwrap().slot, end_slot); assert_eq!(harness2.chain.head_info().unwrap().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_with_spec(&db_path1, spec2.clone()); let resumed_harness = BeaconChainHarness::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 })) .build(); // Head should now be just before the fork. resumed_harness.chain.fork_choice().unwrap(); let head = resumed_harness.chain.head_info().unwrap(); assert_eq!(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(&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()).unwrap(); // The canonical head should be the block from the majority chain. resumed_harness.chain.fork_choice().unwrap(); let head_info = resumed_harness.chain.head_info().unwrap(); assert_eq!(head_info.slot, block.slot()); assert_eq!(head_info.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); } /// 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(a: &BeaconChain, b: &BeaconChain) { assert_eq!(a.spec, b.spec, "spec should be equal"); assert_eq!(a.op_pool, b.op_pool, "op_pool should be equal"); assert_eq!( a.head().unwrap(), b.head().unwrap(), "head() 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.fork_choice.write().get_head(slot, &spec).unwrap() == b.fork_choice.write().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().expect("should get head").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().expect("should get head").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, LevelDB>>) { let split_slot = store.get_split_slot(); assert_eq!( harness .chain .head() .expect("should get head") .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 chain_dump = harness.chain.chain_dump().unwrap(); assert_eq!(chain_dump.len() as u64, expected_len); for checkpoint in &chain_dump { // Check that the tree hash of the stored state is as expected assert_eq!( checkpoint.beacon_state_root(), checkpoint.beacon_state.tree_hash_root(), "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 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::>(); let mut forward_block_roots = harness .chain .forwards_iter_block_roots(Slot::new(0)) .expect("should get iter") .map(Result::unwrap) .collect::>(); // 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.chain.head_info().expect("should get 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.chain.head_info().expect("should get head").slot) ); } fn get_finalized_epoch_boundary_blocks( dump: &[BeaconSnapshot], ) -> HashSet { dump.iter() .cloned() .map(|checkpoint| checkpoint.beacon_state.finalized_checkpoint().root.into()) .collect() } fn get_blocks(dump: &[BeaconSnapshot]) -> HashSet { dump.iter() .cloned() .map(|checkpoint| checkpoint.beacon_block_root.into()) .collect() }