lighthouse/consensus/fork_choice/tests/tests.rs
2023-02-14 13:33:38 +01:00

1302 lines
41 KiB
Rust

#![cfg(not(debug_assertions))]
use std::fmt;
use std::sync::Mutex;
use std::time::Duration;
use beacon_chain::test_utils::{
AttestationStrategy, BeaconChainHarness, BlockStrategy, EphemeralHarnessType,
};
use beacon_chain::{
BeaconChain, BeaconChainError, BeaconForkChoiceStore, ChainConfig, ForkChoiceError,
StateSkipConfig, WhenSlotSkipped,
};
use fork_choice::{
CountUnrealized, ForkChoiceStore, InvalidAttestation, InvalidBlock, PayloadVerificationStatus,
QueuedAttestation,
};
use store::MemoryStore;
use types::{
test_utils::generate_deterministic_keypair, BeaconBlockRef, BeaconState, ChainSpec, Checkpoint,
Epoch, EthSpec, Hash256, IndexedAttestation, MainnetEthSpec, SignedBeaconBlock, Slot, SubnetId,
};
pub type E = MainnetEthSpec;
pub const VALIDATOR_COUNT: usize = 32;
/// Defines some delay between when an attestation is created and when it is mutated.
pub enum MutationDelay {
/// No delay between creation and mutation.
NoDelay,
/// Create `n` blocks before mutating the attestation.
Blocks(usize),
}
/// A helper struct to make testing fork choice more ergonomic and less repetitive.
struct ForkChoiceTest {
harness: BeaconChainHarness<EphemeralHarnessType<E>>,
}
/// Allows us to use `unwrap` in some cases.
impl fmt::Debug for ForkChoiceTest {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
f.debug_struct("ForkChoiceTest").finish()
}
}
impl ForkChoiceTest {
/// Creates a new tester.
pub fn new() -> Self {
let harness = BeaconChainHarness::builder(MainnetEthSpec)
.default_spec()
.deterministic_keypairs(VALIDATOR_COUNT)
.fresh_ephemeral_store()
.build();
Self { harness }
}
/// Creates a new tester with a custom chain config.
pub fn new_with_chain_config(chain_config: ChainConfig) -> Self {
let harness = BeaconChainHarness::builder(MainnetEthSpec)
.default_spec()
.chain_config(chain_config)
.deterministic_keypairs(VALIDATOR_COUNT)
.fresh_ephemeral_store()
.build();
Self { harness }
}
/// Get a value from the `ForkChoice` instantiation.
fn get<T, U>(&self, func: T) -> U
where
T: Fn(&BeaconForkChoiceStore<E, MemoryStore<E>, MemoryStore<E>>) -> U,
{
func(
&self
.harness
.chain
.canonical_head
.fork_choice_read_lock()
.fc_store(),
)
}
/// Assert the epochs match.
pub fn assert_finalized_epoch(self, epoch: u64) -> Self {
assert_eq!(
self.get(|fc_store| fc_store.finalized_checkpoint().epoch),
Epoch::new(epoch),
"finalized_epoch"
);
self
}
/// Assert the epochs match.
pub fn assert_justified_epoch(self, epoch: u64) -> Self {
assert_eq!(
self.get(|fc_store| fc_store.justified_checkpoint().epoch),
Epoch::new(epoch),
"justified_epoch"
);
self
}
/// Assert the epochs match.
pub fn assert_best_justified_epoch(self, epoch: u64) -> Self {
assert_eq!(
self.get(|fc_store| fc_store.best_justified_checkpoint().epoch),
Epoch::new(epoch),
"best_justified_epoch"
);
self
}
/// Assert the given slot is greater than the head slot.
pub fn assert_finalized_epoch_is_less_than(self, epoch: Epoch) -> Self {
assert!(self.harness.finalized_checkpoint().epoch < epoch);
self
}
/// Assert there was a shutdown signal sent by the beacon chain.
pub fn shutdown_signal_sent(&self) -> bool {
let mutex = self.harness.shutdown_receiver.clone();
let mut shutdown_receiver = mutex.lock();
shutdown_receiver.close();
let msg = shutdown_receiver.try_next().unwrap();
msg.is_some()
}
/// Assert there was a shutdown signal sent by the beacon chain.
pub fn assert_shutdown_signal_sent(self) -> Self {
assert!(self.shutdown_signal_sent());
self
}
/// Assert no shutdown was signal sent by the beacon chain.
pub fn assert_shutdown_signal_not_sent(self) -> Self {
assert!(!self.shutdown_signal_sent());
self
}
/// Inspect the queued attestations in fork choice.
pub fn inspect_queued_attestations<F>(self, mut func: F) -> Self
where
F: FnMut(&[QueuedAttestation]),
{
self.harness
.chain
.canonical_head
.fork_choice_write_lock()
.update_time(self.harness.chain.slot().unwrap(), &self.harness.spec)
.unwrap();
func(
self.harness
.chain
.canonical_head
.fork_choice_read_lock()
.queued_attestations(),
);
self
}
/// Skip a slot, without producing a block.
pub fn skip_slot(self) -> Self {
self.harness.advance_slot();
self
}
/// Skips `count` slots, without producing a block.
pub fn skip_slots(self, count: usize) -> Self {
for _ in 0..count {
self.harness.advance_slot();
}
self
}
/// Build the chain whilst `predicate` returns `true` and `process_block_result` does not error.
pub async fn apply_blocks_while<F>(self, mut predicate: F) -> Result<Self, Self>
where
F: FnMut(BeaconBlockRef<'_, E>, &BeaconState<E>) -> bool,
{
self.harness.advance_slot();
let mut state = self.harness.get_current_state();
let validators = self.harness.get_all_validators();
loop {
let slot = self.harness.get_current_slot();
let (block, state_) = self.harness.make_block(state, slot).await;
state = state_;
if !predicate(block.message(), &state) {
break;
}
if let Ok(block_hash) = self.harness.process_block_result(block.clone()).await {
self.harness.attest_block(
&state,
block.state_root(),
block_hash,
&block,
&validators,
);
self.harness.advance_slot();
} else {
return Err(self);
}
}
Ok(self)
}
/// Apply `count` blocks to the chain (with attestations).
pub async fn apply_blocks(self, count: usize) -> Self {
self.harness.advance_slot();
self.harness
.extend_chain(
count,
BlockStrategy::OnCanonicalHead,
AttestationStrategy::AllValidators,
)
.await;
self
}
/// Apply `count` blocks to the chain (without attestations).
pub async fn apply_blocks_without_new_attestations(self, count: usize) -> Self {
self.harness.advance_slot();
self.harness
.extend_chain(
count,
BlockStrategy::OnCanonicalHead,
AttestationStrategy::SomeValidators(vec![]),
)
.await;
self
}
/// Moves to the next slot that is *outside* the `SAFE_SLOTS_TO_UPDATE_JUSTIFIED` range.
///
/// If the chain is presently in an unsafe period, transition through it and the following safe
/// period.
pub fn move_to_next_unsafe_period(self) -> Self {
self.move_inside_safe_to_update()
.move_outside_safe_to_update()
}
/// Moves to the next slot that is *outside* the `SAFE_SLOTS_TO_UPDATE_JUSTIFIED` range.
pub fn move_outside_safe_to_update(self) -> Self {
while is_safe_to_update(self.harness.chain.slot().unwrap(), &self.harness.chain.spec) {
self.harness.advance_slot()
}
self
}
/// Moves to the next slot that is *inside* the `SAFE_SLOTS_TO_UPDATE_JUSTIFIED` range.
pub fn move_inside_safe_to_update(self) -> Self {
while !is_safe_to_update(self.harness.chain.slot().unwrap(), &self.harness.chain.spec) {
self.harness.advance_slot()
}
self
}
/// Applies a block directly to fork choice, bypassing the beacon chain.
///
/// Asserts the block was applied successfully.
pub async fn apply_block_directly_to_fork_choice<F>(self, mut func: F) -> Self
where
F: FnMut(&mut SignedBeaconBlock<E>, &mut BeaconState<E>),
{
let state = self
.harness
.chain
.state_at_slot(
self.harness.get_current_slot() - 1,
StateSkipConfig::WithStateRoots,
)
.unwrap();
let slot = self.harness.get_current_slot();
let (mut signed_block, mut state) = self.harness.make_block(state, slot).await;
func(&mut signed_block, &mut state);
let current_slot = self.harness.get_current_slot();
self.harness
.chain
.canonical_head
.fork_choice_write_lock()
.on_block(
current_slot,
signed_block.message(),
signed_block.canonical_root(),
Duration::from_secs(0),
&state,
PayloadVerificationStatus::Verified,
&self.harness.chain.spec,
CountUnrealized::True,
)
.unwrap();
self
}
/// Applies a block directly to fork choice, bypassing the beacon chain.
///
/// Asserts that an error occurred and allows inspecting it via `comparison_func`.
pub async fn apply_invalid_block_directly_to_fork_choice<F, G>(
self,
mut mutation_func: F,
mut comparison_func: G,
) -> Self
where
F: FnMut(&mut SignedBeaconBlock<E>, &mut BeaconState<E>),
G: FnMut(ForkChoiceError),
{
let state = self
.harness
.chain
.state_at_slot(
self.harness.get_current_slot() - 1,
StateSkipConfig::WithStateRoots,
)
.unwrap();
let slot = self.harness.get_current_slot();
let (mut signed_block, mut state) = self.harness.make_block(state, slot).await;
mutation_func(&mut signed_block, &mut state);
let current_slot = self.harness.get_current_slot();
let err = self
.harness
.chain
.canonical_head
.fork_choice_write_lock()
.on_block(
current_slot,
signed_block.message(),
signed_block.canonical_root(),
Duration::from_secs(0),
&state,
PayloadVerificationStatus::Verified,
&self.harness.chain.spec,
CountUnrealized::True,
)
.err()
.expect("on_block did not return an error");
comparison_func(err);
self
}
/// Compares the justified balances in the `ForkChoiceStore` verses a direct lookup from the
/// database.
fn check_justified_balances(&self) {
let harness = &self.harness;
let fc = self.harness.chain.canonical_head.fork_choice_read_lock();
let state_root = harness
.chain
.store
.get_blinded_block(&fc.fc_store().justified_checkpoint().root)
.unwrap()
.unwrap()
.message()
.state_root();
let state = harness
.chain
.store
.get_state(&state_root, None)
.unwrap()
.unwrap();
let balances = state
.validators()
.into_iter()
.map(|v| {
if v.is_active_at(state.current_epoch()) {
v.effective_balance
} else {
0
}
})
.collect::<Vec<_>>();
assert_eq!(
&balances[..],
&fc.fc_store().justified_balances().effective_balances,
"balances should match"
);
assert_eq!(
balances.iter().sum::<u64>(),
fc.fc_store().justified_balances().total_effective_balance
);
}
/// Returns an attestation that is valid for some slot in the given `chain`.
///
/// Also returns some info about who created it.
async fn apply_attestation_to_chain<F, G>(
self,
delay: MutationDelay,
mut mutation_func: F,
mut comparison_func: G,
) -> Self
where
F: FnMut(&mut IndexedAttestation<E>, &BeaconChain<EphemeralHarnessType<E>>),
G: FnMut(Result<(), BeaconChainError>),
{
let head = self.harness.chain.head_snapshot();
let current_slot = self.harness.chain.slot().expect("should get slot");
let mut attestation = self
.harness
.chain
.produce_unaggregated_attestation(current_slot, 0)
.expect("should not error while producing attestation");
let validator_committee_index = 0;
let validator_index = *head
.beacon_state
.get_beacon_committee(current_slot, attestation.data.index)
.expect("should get committees")
.committee
.get(validator_committee_index)
.expect("there should be an attesting validator");
let committee_count = head
.beacon_state
.get_committee_count_at_slot(current_slot)
.expect("should not error while getting committee count");
let subnet_id = SubnetId::compute_subnet::<E>(
current_slot,
0,
committee_count,
&self.harness.chain.spec,
)
.expect("should compute subnet id");
let validator_sk = generate_deterministic_keypair(validator_index).sk;
attestation
.sign(
&validator_sk,
validator_committee_index,
&head.beacon_state.fork(),
self.harness.chain.genesis_validators_root,
&self.harness.chain.spec,
)
.expect("should sign attestation");
let mut verified_attestation = self
.harness
.chain
.verify_unaggregated_attestation_for_gossip(&attestation, Some(subnet_id))
.expect("precondition: should gossip verify attestation");
if let MutationDelay::Blocks(slots) = delay {
self.harness.advance_slot();
self.harness
.extend_chain(
slots,
BlockStrategy::OnCanonicalHead,
AttestationStrategy::SomeValidators(vec![]),
)
.await;
}
mutation_func(
verified_attestation.__indexed_attestation_mut(),
&self.harness.chain,
);
let result = self
.harness
.chain
.apply_attestation_to_fork_choice(&verified_attestation);
comparison_func(result);
self
}
/// Check to ensure that we can read the finalized block. This is a regression test.
pub fn check_finalized_block_is_accessible(self) -> Self {
self.harness
.chain
.canonical_head
.fork_choice_read_lock()
.get_block(&self.harness.finalized_checkpoint().root)
.unwrap();
self
}
}
fn is_safe_to_update(slot: Slot, spec: &ChainSpec) -> bool {
slot % E::slots_per_epoch() < spec.safe_slots_to_update_justified
}
#[test]
fn justified_and_finalized_blocks() {
let tester = ForkChoiceTest::new();
let fork_choice = tester.harness.chain.canonical_head.fork_choice_read_lock();
let justified_checkpoint = fork_choice.justified_checkpoint();
assert_eq!(justified_checkpoint.epoch, 0);
assert!(justified_checkpoint.root != Hash256::zero());
assert!(fork_choice.get_justified_block().is_ok());
let finalized_checkpoint = fork_choice.finalized_checkpoint();
assert_eq!(finalized_checkpoint.epoch, 0);
assert!(finalized_checkpoint.root != Hash256::zero());
assert!(fork_choice.get_finalized_block().is_ok());
}
/// - The new justified checkpoint descends from the current.
/// - Current slot is within `SAFE_SLOTS_TO_UPDATE_JUSTIFIED`
#[tokio::test]
async fn justified_checkpoint_updates_with_descendent_inside_safe_slots() {
ForkChoiceTest::new()
.apply_blocks_while(|_, state| state.current_justified_checkpoint().epoch == 0)
.await
.unwrap()
.move_inside_safe_to_update()
.assert_justified_epoch(0)
.apply_blocks(1)
.await
.assert_justified_epoch(2);
}
/// - The new justified checkpoint descends from the current.
/// - Current slot is **not** within `SAFE_SLOTS_TO_UPDATE_JUSTIFIED`
/// - This is **not** the first justification since genesis
#[tokio::test]
async fn justified_checkpoint_updates_with_descendent_outside_safe_slots() {
ForkChoiceTest::new()
.apply_blocks_while(|_, state| state.current_justified_checkpoint().epoch <= 2)
.await
.unwrap()
.move_outside_safe_to_update()
.assert_justified_epoch(2)
.assert_best_justified_epoch(2)
.apply_blocks(1)
.await
.assert_justified_epoch(3);
}
/// - The new justified checkpoint descends from the current.
/// - Current slot is **not** within `SAFE_SLOTS_TO_UPDATE_JUSTIFIED`
/// - This is the first justification since genesis
#[tokio::test]
async fn justified_checkpoint_updates_first_justification_outside_safe_to_update() {
ForkChoiceTest::new()
.apply_blocks_while(|_, state| state.current_justified_checkpoint().epoch == 0)
.await
.unwrap()
.move_to_next_unsafe_period()
.assert_justified_epoch(0)
.assert_best_justified_epoch(0)
.apply_blocks(1)
.await
.assert_justified_epoch(2)
.assert_best_justified_epoch(2);
}
/// - The new justified checkpoint **does not** descend from the current.
/// - Current slot is within `SAFE_SLOTS_TO_UPDATE_JUSTIFIED`
/// - Finalized epoch has **not** increased.
#[tokio::test]
async fn justified_checkpoint_updates_with_non_descendent_inside_safe_slots_without_finality() {
ForkChoiceTest::new()
.apply_blocks_while(|_, state| state.current_justified_checkpoint().epoch == 0)
.await
.unwrap()
.apply_blocks(1)
.await
.move_inside_safe_to_update()
.assert_justified_epoch(2)
.apply_block_directly_to_fork_choice(|_, state| {
// The finalized checkpoint should not change.
state.finalized_checkpoint().epoch = Epoch::new(0);
// The justified checkpoint has changed.
state.current_justified_checkpoint_mut().epoch = Epoch::new(3);
// The new block should **not** include the current justified block as an ancestor.
state.current_justified_checkpoint_mut().root = *state
.get_block_root(Epoch::new(1).start_slot(E::slots_per_epoch()))
.unwrap();
})
.await
.assert_justified_epoch(3)
.assert_best_justified_epoch(3);
}
/// - The new justified checkpoint **does not** descend from the current.
/// - Current slot is **not** within `SAFE_SLOTS_TO_UPDATE_JUSTIFIED`.
/// - Finalized epoch has **not** increased.
#[tokio::test]
async fn justified_checkpoint_updates_with_non_descendent_outside_safe_slots_without_finality() {
ForkChoiceTest::new()
.apply_blocks_while(|_, state| state.current_justified_checkpoint().epoch == 0)
.await
.unwrap()
.apply_blocks(1)
.await
.move_to_next_unsafe_period()
.assert_justified_epoch(2)
.apply_block_directly_to_fork_choice(|_, state| {
// The finalized checkpoint should not change.
state.finalized_checkpoint().epoch = Epoch::new(0);
// The justified checkpoint has changed.
state.current_justified_checkpoint_mut().epoch = Epoch::new(3);
// The new block should **not** include the current justified block as an ancestor.
state.current_justified_checkpoint_mut().root = *state
.get_block_root(Epoch::new(1).start_slot(E::slots_per_epoch()))
.unwrap();
})
.await
.assert_justified_epoch(2)
.assert_best_justified_epoch(3);
}
/// - The new justified checkpoint **does not** descend from the current.
/// - Current slot is **not** within `SAFE_SLOTS_TO_UPDATE_JUSTIFIED`
/// - Finalized epoch has increased.
#[tokio::test]
async fn justified_checkpoint_updates_with_non_descendent_outside_safe_slots_with_finality() {
ForkChoiceTest::new()
.apply_blocks_while(|_, state| state.current_justified_checkpoint().epoch == 0)
.await
.unwrap()
.apply_blocks(1)
.await
.move_to_next_unsafe_period()
.assert_justified_epoch(2)
.apply_block_directly_to_fork_choice(|_, state| {
// The finalized checkpoint should change.
state.finalized_checkpoint_mut().epoch = Epoch::new(1);
// The justified checkpoint has changed.
state.current_justified_checkpoint_mut().epoch = Epoch::new(3);
// The new block should **not** include the current justified block as an ancestor.
state.current_justified_checkpoint_mut().root = *state
.get_block_root(Epoch::new(1).start_slot(E::slots_per_epoch()))
.unwrap();
})
.await
.assert_justified_epoch(3)
.assert_best_justified_epoch(3);
}
/// Check that the balances are obtained correctly.
#[tokio::test]
async fn justified_balances() {
ForkChoiceTest::new()
.apply_blocks_while(|_, state| state.current_justified_checkpoint().epoch == 0)
.await
.unwrap()
.apply_blocks(1)
.await
.assert_justified_epoch(2)
.check_justified_balances()
}
macro_rules! assert_invalid_block {
($err: tt, $($error: pat_param) |+ $( if $guard: expr )?) => {
assert!(
matches!(
$err,
$( ForkChoiceError::InvalidBlock($error) ) |+ $( if $guard )?
),
)
};
}
/// Specification v0.12.1
///
/// assert block.parent_root in store.block_states
#[tokio::test]
async fn invalid_block_unknown_parent() {
let junk = Hash256::from_low_u64_be(42);
ForkChoiceTest::new()
.apply_blocks(2)
.await
.apply_invalid_block_directly_to_fork_choice(
|block, _| {
*block.message_mut().parent_root_mut() = junk;
},
|err| {
assert_invalid_block!(
err,
InvalidBlock::UnknownParent(parent)
if parent == junk
)
},
)
.await;
}
/// Specification v0.12.1
///
/// assert get_current_slot(store) >= block.slot
#[tokio::test]
async fn invalid_block_future_slot() {
ForkChoiceTest::new()
.apply_blocks(2)
.await
.apply_invalid_block_directly_to_fork_choice(
|block, _| {
*block.message_mut().slot_mut() += 1;
},
|err| assert_invalid_block!(err, InvalidBlock::FutureSlot { .. }),
)
.await;
}
/// Specification v0.12.1
///
/// assert block.slot > finalized_slot
#[tokio::test]
async fn invalid_block_finalized_slot() {
ForkChoiceTest::new()
.apply_blocks_while(|_, state| state.finalized_checkpoint().epoch == 0)
.await
.unwrap()
.apply_blocks(1)
.await
.apply_invalid_block_directly_to_fork_choice(
|block, _| {
*block.message_mut().slot_mut() =
Epoch::new(2).start_slot(E::slots_per_epoch()) - 1;
},
|err| {
assert_invalid_block!(
err,
InvalidBlock::FinalizedSlot { finalized_slot, .. }
if finalized_slot == Epoch::new(2).start_slot(E::slots_per_epoch())
)
},
)
.await;
}
/// Specification v0.12.1
///
/// assert get_ancestor(store, hash_tree_root(block), finalized_slot) ==
/// store.finalized_checkpoint().root
///
/// Note: we technically don't do this exact check, but an equivalent check. Reference:
///
/// https://github.com/ethereum/eth2.0-specs/pull/1884
#[tokio::test]
async fn invalid_block_finalized_descendant() {
let invalid_ancestor = Mutex::new(Hash256::zero());
ForkChoiceTest::new()
.apply_blocks_while(|_, state| state.finalized_checkpoint().epoch == 0)
.await
.unwrap()
.apply_blocks(1)
.await
.assert_finalized_epoch(2)
.apply_invalid_block_directly_to_fork_choice(
|block, state| {
*block.message_mut().parent_root_mut() = *state
.get_block_root(Epoch::new(1).start_slot(E::slots_per_epoch()))
.unwrap();
*invalid_ancestor.lock().unwrap() = block.parent_root();
},
|err| {
assert_invalid_block!(
err,
InvalidBlock::NotFinalizedDescendant { block_ancestor, .. }
if block_ancestor == Some(*invalid_ancestor.lock().unwrap())
)
},
)
.await;
}
macro_rules! assert_invalid_attestation {
($err: tt, $($error: pat_param) |+ $( if $guard: expr )?) => {
assert!(
matches!(
$err,
$( Err(BeaconChainError::ForkChoiceError(ForkChoiceError::InvalidAttestation($error))) ) |+ $( if $guard )?
),
"{:?}",
$err
)
};
}
/// Ensure we can process a valid attestation.
#[tokio::test]
async fn valid_attestation() {
ForkChoiceTest::new()
.apply_blocks_without_new_attestations(1)
.await
.apply_attestation_to_chain(
MutationDelay::NoDelay,
|_, _| {},
|result| assert_eq!(result.unwrap(), ()),
)
.await;
}
/// This test is not in the specification, however we reject an attestation with an empty
/// aggregation bitfield since it has no purpose beyond wasting our time.
#[tokio::test]
async fn invalid_attestation_empty_bitfield() {
ForkChoiceTest::new()
.apply_blocks_without_new_attestations(1)
.await
.apply_attestation_to_chain(
MutationDelay::NoDelay,
|attestation, _| {
attestation.attesting_indices = vec![].into();
},
|result| {
assert_invalid_attestation!(result, InvalidAttestation::EmptyAggregationBitfield)
},
)
.await;
}
/// Specification v0.12.1:
///
/// assert target.epoch in [expected_current_epoch, previous_epoch]
///
/// (tests epoch after current epoch)
#[tokio::test]
async fn invalid_attestation_future_epoch() {
ForkChoiceTest::new()
.apply_blocks_without_new_attestations(1)
.await
.apply_attestation_to_chain(
MutationDelay::NoDelay,
|attestation, _| {
attestation.data.target.epoch = Epoch::new(2);
},
|result| {
assert_invalid_attestation!(
result,
InvalidAttestation::FutureEpoch { attestation_epoch, current_epoch }
if attestation_epoch == Epoch::new(2) && current_epoch == Epoch::new(0)
)
},
)
.await;
}
/// Specification v0.12.1:
///
/// assert target.epoch in [expected_current_epoch, previous_epoch]
///
/// (tests epoch prior to previous epoch)
#[tokio::test]
async fn invalid_attestation_past_epoch() {
ForkChoiceTest::new()
.apply_blocks_without_new_attestations(E::slots_per_epoch() as usize * 3 + 1)
.await
.apply_attestation_to_chain(
MutationDelay::NoDelay,
|attestation, _| {
attestation.data.target.epoch = Epoch::new(0);
},
|result| {
assert_invalid_attestation!(
result,
InvalidAttestation::PastEpoch { attestation_epoch, current_epoch }
if attestation_epoch == Epoch::new(0) && current_epoch == Epoch::new(3)
)
},
)
.await;
}
/// Specification v0.12.1:
///
/// assert target.epoch == compute_epoch_at_slot(attestation.data.slot)
#[tokio::test]
async fn invalid_attestation_target_epoch() {
ForkChoiceTest::new()
.apply_blocks_without_new_attestations(E::slots_per_epoch() as usize + 1)
.await
.apply_attestation_to_chain(
MutationDelay::NoDelay,
|attestation, _| {
attestation.data.slot = Slot::new(1);
},
|result| {
assert_invalid_attestation!(
result,
InvalidAttestation::BadTargetEpoch { target, slot }
if target == Epoch::new(1) && slot == Slot::new(1)
)
},
)
.await;
}
/// Specification v0.12.1:
///
/// assert target.root in store.blocks
#[tokio::test]
async fn invalid_attestation_unknown_target_root() {
let junk = Hash256::from_low_u64_be(42);
ForkChoiceTest::new()
.apply_blocks_without_new_attestations(1)
.await
.apply_attestation_to_chain(
MutationDelay::NoDelay,
|attestation, _| {
attestation.data.target.root = junk;
},
|result| {
assert_invalid_attestation!(
result,
InvalidAttestation::UnknownTargetRoot(root)
if root == junk
)
},
)
.await;
}
/// Specification v0.12.1:
///
/// assert attestation.data.beacon_block_root in store.blocks
#[tokio::test]
async fn invalid_attestation_unknown_beacon_block_root() {
let junk = Hash256::from_low_u64_be(42);
ForkChoiceTest::new()
.apply_blocks_without_new_attestations(1)
.await
.apply_attestation_to_chain(
MutationDelay::NoDelay,
|attestation, _| {
attestation.data.beacon_block_root = junk;
},
|result| {
assert_invalid_attestation!(
result,
InvalidAttestation::UnknownHeadBlock { beacon_block_root }
if beacon_block_root == junk
)
},
)
.await;
}
/// Specification v0.12.1:
///
/// assert store.blocks[attestation.data.beacon_block_root].slot <= attestation.data.slot
#[tokio::test]
async fn invalid_attestation_future_block() {
ForkChoiceTest::new()
.apply_blocks_without_new_attestations(1)
.await
.apply_attestation_to_chain(
MutationDelay::Blocks(1),
|attestation, chain| {
attestation.data.beacon_block_root = chain
.block_at_slot(chain.slot().unwrap(), WhenSlotSkipped::Prev)
.unwrap()
.unwrap()
.canonical_root();
},
|result| {
assert_invalid_attestation!(
result,
InvalidAttestation::AttestsToFutureBlock { block, attestation }
if block == 2 && attestation == 1
)
},
)
.await;
}
/// Specification v0.12.1:
///
/// assert target.root == get_ancestor(store, attestation.data.beacon_block_root, target_slot)
#[tokio::test]
async fn invalid_attestation_inconsistent_ffg_vote() {
let local_opt = Mutex::new(None);
let attestation_opt = Mutex::new(None);
ForkChoiceTest::new()
.apply_blocks_without_new_attestations(1)
.await
.apply_attestation_to_chain(
MutationDelay::NoDelay,
|attestation, chain| {
attestation.data.target.root = chain
.block_at_slot(Slot::new(1), WhenSlotSkipped::Prev)
.unwrap()
.unwrap()
.canonical_root();
*attestation_opt.lock().unwrap() = Some(attestation.data.target.root);
*local_opt.lock().unwrap() = Some(
chain
.block_at_slot(Slot::new(0), WhenSlotSkipped::Prev)
.unwrap()
.unwrap()
.canonical_root(),
);
},
|result| {
assert_invalid_attestation!(
result,
InvalidAttestation::InvalidTarget { attestation, local }
if attestation == attestation_opt.lock().unwrap().unwrap()
&& local == local_opt.lock().unwrap().unwrap()
)
},
)
.await;
}
/// Specification v0.12.1:
///
/// assert get_current_slot(store) >= attestation.data.slot + 1
#[tokio::test]
async fn invalid_attestation_delayed_slot() {
ForkChoiceTest::new()
.apply_blocks_without_new_attestations(1)
.await
.inspect_queued_attestations(|queue| assert_eq!(queue.len(), 0))
.apply_attestation_to_chain(
MutationDelay::NoDelay,
|_, _| {},
|result| assert_eq!(result.unwrap(), ()),
)
.await
.inspect_queued_attestations(|queue| assert_eq!(queue.len(), 1))
.skip_slot()
.inspect_queued_attestations(|queue| assert_eq!(queue.len(), 0));
}
/// Tests that the correct target root is used when the attested-to block is in a prior epoch to
/// the attestation.
#[tokio::test]
async fn valid_attestation_skip_across_epoch() {
ForkChoiceTest::new()
.apply_blocks(E::slots_per_epoch() as usize - 1)
.await
.skip_slots(2)
.apply_attestation_to_chain(
MutationDelay::NoDelay,
|attestation, _chain| {
assert_eq!(
attestation.data.target.root,
attestation.data.beacon_block_root
)
},
|result| result.unwrap(),
)
.await;
}
#[tokio::test]
async fn can_read_finalized_block() {
ForkChoiceTest::new()
.apply_blocks_while(|_, state| state.finalized_checkpoint().epoch == 0)
.await
.unwrap()
.apply_blocks(1)
.await
.check_finalized_block_is_accessible();
}
#[test]
#[should_panic]
fn weak_subjectivity_fail_on_startup() {
let epoch = Epoch::new(0);
let root = Hash256::from_low_u64_le(1);
let chain_config = ChainConfig {
weak_subjectivity_checkpoint: Some(Checkpoint { epoch, root }),
..ChainConfig::default()
};
ForkChoiceTest::new_with_chain_config(chain_config);
}
#[tokio::test]
async fn weak_subjectivity_pass_on_startup() {
let epoch = Epoch::new(0);
let root = Hash256::zero();
let chain_config = ChainConfig {
weak_subjectivity_checkpoint: Some(Checkpoint { epoch, root }),
..ChainConfig::default()
};
ForkChoiceTest::new_with_chain_config(chain_config)
.apply_blocks(E::slots_per_epoch() as usize)
.await
.assert_shutdown_signal_not_sent();
}
#[tokio::test]
async fn weak_subjectivity_check_passes() {
let setup_harness = ForkChoiceTest::new()
.apply_blocks_while(|_, state| state.finalized_checkpoint().epoch == 0)
.await
.unwrap()
.apply_blocks(1)
.await
.assert_finalized_epoch(2);
let checkpoint = setup_harness.harness.finalized_checkpoint();
let chain_config = ChainConfig {
weak_subjectivity_checkpoint: Some(checkpoint),
..ChainConfig::default()
};
ForkChoiceTest::new_with_chain_config(chain_config.clone())
.apply_blocks_while(|_, state| state.finalized_checkpoint().epoch == 0)
.await
.unwrap()
.apply_blocks(1)
.await
.assert_finalized_epoch(2)
.assert_shutdown_signal_not_sent();
}
#[tokio::test]
async fn weak_subjectivity_check_fails_early_epoch() {
let setup_harness = ForkChoiceTest::new()
.apply_blocks_while(|_, state| state.finalized_checkpoint().epoch == 0)
.await
.unwrap()
.apply_blocks(1)
.await
.assert_finalized_epoch(2);
let mut checkpoint = setup_harness.harness.finalized_checkpoint();
checkpoint.epoch = checkpoint.epoch - 1;
let chain_config = ChainConfig {
weak_subjectivity_checkpoint: Some(checkpoint),
..ChainConfig::default()
};
ForkChoiceTest::new_with_chain_config(chain_config.clone())
.apply_blocks_while(|_, state| state.finalized_checkpoint().epoch < 3)
.await
.unwrap_err()
.assert_finalized_epoch_is_less_than(checkpoint.epoch)
.assert_shutdown_signal_sent();
}
#[tokio::test]
async fn weak_subjectivity_check_fails_late_epoch() {
let setup_harness = ForkChoiceTest::new()
.apply_blocks_while(|_, state| state.finalized_checkpoint().epoch == 0)
.await
.unwrap()
.apply_blocks(1)
.await
.assert_finalized_epoch(2);
let mut checkpoint = setup_harness.harness.finalized_checkpoint();
checkpoint.epoch = checkpoint.epoch + 1;
let chain_config = ChainConfig {
weak_subjectivity_checkpoint: Some(checkpoint),
..ChainConfig::default()
};
ForkChoiceTest::new_with_chain_config(chain_config.clone())
.apply_blocks_while(|_, state| state.finalized_checkpoint().epoch < 4)
.await
.unwrap_err()
.assert_finalized_epoch_is_less_than(checkpoint.epoch)
.assert_shutdown_signal_sent();
}
#[tokio::test]
async fn weak_subjectivity_check_fails_incorrect_root() {
let setup_harness = ForkChoiceTest::new()
.apply_blocks_while(|_, state| state.finalized_checkpoint().epoch == 0)
.await
.unwrap()
.apply_blocks(1)
.await
.assert_finalized_epoch(2);
let mut checkpoint = setup_harness.harness.finalized_checkpoint();
checkpoint.root = Hash256::zero();
let chain_config = ChainConfig {
weak_subjectivity_checkpoint: Some(checkpoint),
..ChainConfig::default()
};
ForkChoiceTest::new_with_chain_config(chain_config.clone())
.apply_blocks_while(|_, state| state.finalized_checkpoint().epoch < 3)
.await
.unwrap_err()
.assert_finalized_epoch_is_less_than(checkpoint.epoch)
.assert_shutdown_signal_sent();
}
#[tokio::test]
async fn weak_subjectivity_check_epoch_boundary_is_skip_slot() {
let setup_harness = ForkChoiceTest::new()
// first two epochs
.apply_blocks_while(|_, state| state.finalized_checkpoint().epoch == 0)
.await
.unwrap();
// get the head, it will become the finalized root of epoch 4
let checkpoint_root = setup_harness.harness.head_block_root();
setup_harness
// epoch 3 will be entirely skip slots
.skip_slots(E::slots_per_epoch() as usize)
.apply_blocks_while(|_, state| state.finalized_checkpoint().epoch < 5)
.await
.unwrap()
.apply_blocks(1)
.await
.assert_finalized_epoch(5);
// the checkpoint at epoch 4 should become the root of last block of epoch 2
let checkpoint = Checkpoint {
epoch: Epoch::new(4),
root: checkpoint_root,
};
let chain_config = ChainConfig {
weak_subjectivity_checkpoint: Some(checkpoint),
..ChainConfig::default()
};
// recreate the chain exactly
ForkChoiceTest::new_with_chain_config(chain_config.clone())
.apply_blocks_while(|_, state| state.finalized_checkpoint().epoch == 0)
.await
.unwrap()
.skip_slots(E::slots_per_epoch() as usize)
.apply_blocks_while(|_, state| state.finalized_checkpoint().epoch < 5)
.await
.unwrap()
.apply_blocks(1)
.await
.assert_finalized_epoch(5)
.assert_shutdown_signal_not_sent();
}
#[tokio::test]
async fn weak_subjectivity_check_epoch_boundary_is_skip_slot_failure() {
let setup_harness = ForkChoiceTest::new()
// first two epochs
.apply_blocks_while(|_, state| state.finalized_checkpoint().epoch == 0)
.await
.unwrap();
// get the head, it will become the finalized root of epoch 4
let checkpoint_root = setup_harness.harness.head_block_root();
setup_harness
// epoch 3 will be entirely skip slots
.skip_slots(E::slots_per_epoch() as usize)
.apply_blocks_while(|_, state| state.finalized_checkpoint().epoch < 5)
.await
.unwrap()
.apply_blocks(1)
.await
.assert_finalized_epoch(5);
// Invalid checkpoint (epoch too early)
let checkpoint = Checkpoint {
epoch: Epoch::new(1),
root: checkpoint_root,
};
let chain_config = ChainConfig {
weak_subjectivity_checkpoint: Some(checkpoint),
..ChainConfig::default()
};
// recreate the chain exactly
ForkChoiceTest::new_with_chain_config(chain_config.clone())
.apply_blocks_while(|_, state| state.finalized_checkpoint().epoch == 0)
.await
.unwrap()
.skip_slots(E::slots_per_epoch() as usize)
.apply_blocks_while(|_, state| state.finalized_checkpoint().epoch < 6)
.await
.unwrap_err()
.assert_finalized_epoch_is_less_than(checkpoint.epoch)
.assert_shutdown_signal_sent();
}