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Older
PendingAvailabilityCommitments::insert(chain_b, default_candidate.commitments);
run_to_block(5, |_| None);
assert!(<PendingAvailability<Test>>::get(&chain_a).is_some());
assert!(<PendingAvailability<Test>>::get(&chain_b).is_some());
assert!(<PendingAvailabilityCommitments>::get(&chain_a).is_some());
assert!(<PendingAvailabilityCommitments>::get(&chain_b).is_some());
Inclusion::collect_pending(|core, _since| core == CoreIndex::from(0));
assert!(<PendingAvailability<Test>>::get(&chain_a).is_none());
assert!(<PendingAvailability<Test>>::get(&chain_b).is_some());
assert!(<PendingAvailabilityCommitments>::get(&chain_a).is_none());
assert!(<PendingAvailabilityCommitments>::get(&chain_b).is_some());
});
}
#[test]
fn bitfield_checks() {
let chain_a = ParaId::from(1);
let chain_b = ParaId::from(2);
let thread_a = ParaId::from(3);
let paras = vec![(chain_a, true), (chain_b, true), (thread_a, false)];
let validators = vec![
Sr25519Keyring::Alice,
Sr25519Keyring::Bob,
Sr25519Keyring::Charlie,
Sr25519Keyring::Dave,
Sr25519Keyring::Ferdie,
];
let keystore: SyncCryptoStorePtr = Arc::new(LocalKeystore::in_memory());
for validator in validators.iter() {
SyncCryptoStore::sr25519_generate_new(&*keystore, PARACHAIN_KEY_TYPE_ID, Some(&validator.to_seed())).unwrap();
}
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let validator_public = validator_pubkeys(&validators);
new_test_ext(genesis_config(paras)).execute_with(|| {
Validators::set(validator_public.clone());
CurrentSessionIndex::set(5);
let signing_context = SigningContext {
parent_hash: System::parent_hash(),
session_index: 5,
};
let core_lookup = |core| match core {
core if core == CoreIndex::from(0) => Some(chain_a),
core if core == CoreIndex::from(1) => Some(chain_b),
core if core == CoreIndex::from(2) => Some(thread_a),
_ => panic!("Core out of bounds for 2 parachains and 1 parathread core."),
};
// wrong number of bits.
{
let mut bare_bitfield = default_bitfield();
bare_bitfield.0.push(false);
let signed = block_on(sign_bitfield(
&keystore,
&validators[0],
0,
bare_bitfield,
&signing_context,
));
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vec![signed],
&core_lookup,
).is_err());
}
// duplicate.
{
let bare_bitfield = default_bitfield();
let signed = block_on(sign_bitfield(
&keystore,
&validators[0],
0,
bare_bitfield,
&signing_context,
));
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vec![signed.clone(), signed],
&core_lookup,
).is_err());
}
// out of order.
{
let bare_bitfield = default_bitfield();
let signed_0 = block_on(sign_bitfield(
&keystore,
&validators[0],
0,
bare_bitfield.clone(),
&signing_context,
));
let signed_1 = block_on(sign_bitfield(
&keystore,
&validators[1],
1,
bare_bitfield,
&signing_context,
));
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vec![signed_1, signed_0],
&core_lookup,
).is_err());
}
// non-pending bit set.
{
let mut bare_bitfield = default_bitfield();
*bare_bitfield.0.get_mut(0).unwrap() = true;
let signed = block_on(sign_bitfield(
&keystore,
&validators[0],
0,
bare_bitfield,
&signing_context,
));
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vec![signed],
&core_lookup,
).is_err());
}
// empty bitfield signed: always OK, but kind of useless.
{
let bare_bitfield = default_bitfield();
let signed = block_on(sign_bitfield(
&keystore,
&validators[0],
0,
bare_bitfield,
&signing_context,
));
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vec![signed],
&core_lookup,
).is_ok());
}
// bitfield signed with pending bit signed.
{
let mut bare_bitfield = default_bitfield();
assert_eq!(core_lookup(CoreIndex::from(0)), Some(chain_a));
let default_candidate = TestCandidateBuilder::default().build();
<PendingAvailability<Test>>::insert(chain_a, CandidatePendingAvailability {
core: CoreIndex::from(0),
descriptor: default_candidate.descriptor,
availability_votes: default_availability_votes(),
relay_parent_number: 0,
backed_in_number: 0,
});
PendingAvailabilityCommitments::insert(chain_a, default_candidate.commitments);
*bare_bitfield.0.get_mut(0).unwrap() = true;
let signed = block_on(sign_bitfield(
&keystore,
&validators[0],
0,
bare_bitfield,
&signing_context,
));
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vec![signed],
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<PendingAvailability<Test>>::remove(chain_a);
PendingAvailabilityCommitments::remove(chain_a);
}
// bitfield signed with pending bit signed, but no commitments.
{
let mut bare_bitfield = default_bitfield();
assert_eq!(core_lookup(CoreIndex::from(0)), Some(chain_a));
let default_candidate = TestCandidateBuilder::default().build();
<PendingAvailability<Test>>::insert(chain_a, CandidatePendingAvailability {
core: CoreIndex::from(0),
descriptor: default_candidate.descriptor,
availability_votes: default_availability_votes(),
relay_parent_number: 0,
backed_in_number: 0,
});
*bare_bitfield.0.get_mut(0).unwrap() = true;
let signed = block_on(sign_bitfield(
&keystore,
&validators[0],
0,
bare_bitfield,
&signing_context,
));
// no core is freed
assert_eq!(
Inclusion::process_bitfields(
vec![signed],
&core_lookup,
),
Ok(vec![]),
);
}
});
}
#[test]
fn supermajority_bitfields_trigger_availability() {
let chain_a = ParaId::from(1);
let chain_b = ParaId::from(2);
let thread_a = ParaId::from(3);
let paras = vec![(chain_a, true), (chain_b, true), (thread_a, false)];
let validators = vec![
Sr25519Keyring::Alice,
Sr25519Keyring::Bob,
Sr25519Keyring::Charlie,
Sr25519Keyring::Dave,
Sr25519Keyring::Ferdie,
];
let keystore: SyncCryptoStorePtr = Arc::new(LocalKeystore::in_memory());
for validator in validators.iter() {
SyncCryptoStore::sr25519_generate_new(&*keystore, PARACHAIN_KEY_TYPE_ID, Some(&validator.to_seed())).unwrap();
}
let validator_public = validator_pubkeys(&validators);
new_test_ext(genesis_config(paras)).execute_with(|| {
Validators::set(validator_public.clone());
CurrentSessionIndex::set(5);
let signing_context = SigningContext {
parent_hash: System::parent_hash(),
session_index: 5,
};
let core_lookup = |core| match core {
core if core == CoreIndex::from(0) => Some(chain_a),
core if core == CoreIndex::from(1) => Some(chain_b),
core if core == CoreIndex::from(2) => Some(thread_a),
_ => panic!("Core out of bounds for 2 parachains and 1 parathread core."),
};
let candidate_a = TestCandidateBuilder {
para_id: chain_a,
head_data: vec![1, 2, 3, 4].into(),
..Default::default()
}.build();
<PendingAvailability<Test>>::insert(chain_a, CandidatePendingAvailability {
core: CoreIndex::from(0),
descriptor: candidate_a.descriptor,
availability_votes: default_availability_votes(),
relay_parent_number: 0,
backed_in_number: 0,
});
PendingAvailabilityCommitments::insert(chain_a, candidate_a.commitments);
let candidate_b = TestCandidateBuilder {
para_id: chain_b,
head_data: vec![5, 6, 7, 8].into(),
..Default::default()
}.build();
<PendingAvailability<Test>>::insert(chain_b, CandidatePendingAvailability {
core: CoreIndex::from(1),
descriptor: candidate_b.descriptor,
availability_votes: default_availability_votes(),
relay_parent_number: 0,
backed_in_number: 0,
});
PendingAvailabilityCommitments::insert(chain_b, candidate_b.commitments);
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// this bitfield signals that a and b are available.
let a_and_b_available = {
let mut bare_bitfield = default_bitfield();
*bare_bitfield.0.get_mut(0).unwrap() = true;
*bare_bitfield.0.get_mut(1).unwrap() = true;
bare_bitfield
};
// this bitfield signals that only a is available.
let a_available = {
let mut bare_bitfield = default_bitfield();
*bare_bitfield.0.get_mut(0).unwrap() = true;
bare_bitfield
};
let threshold = availability_threshold(validators.len());
// 4 of 5 first value >= 2/3
assert_eq!(threshold, 4);
let signed_bitfields = validators.iter().enumerate().filter_map(|(i, key)| {
let to_sign = if i < 3 {
a_and_b_available.clone()
} else if i < 4 {
a_available.clone()
} else {
// sign nothing.
return None
};
Some(block_on(sign_bitfield(
&keystore,
key,
i as ValidatorIndex,
to_sign,
&signing_context,
)))
}).collect();
assert!(Inclusion::process_bitfields(
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signed_bitfields,
&core_lookup,
).is_ok());
// chain A had 4 signing off, which is >= threshold.
// chain B has 3 signing off, which is < threshold.
assert!(<PendingAvailability<Test>>::get(&chain_a).is_none());
assert!(<PendingAvailabilityCommitments>::get(&chain_a).is_none());
assert!(<PendingAvailabilityCommitments>::get(&chain_b).is_some());
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assert_eq!(
<PendingAvailability<Test>>::get(&chain_b).unwrap().availability_votes,
{
// check that votes from first 3 were tracked.
let mut votes = default_availability_votes();
*votes.get_mut(0).unwrap() = true;
*votes.get_mut(1).unwrap() = true;
*votes.get_mut(2).unwrap() = true;
votes
},
);
// and check that chain head was enacted.
assert_eq!(Paras::para_head(&chain_a), Some(vec![1, 2, 3, 4].into()));
});
}
#[test]
fn candidate_checks() {
let chain_a = ParaId::from(1);
let chain_b = ParaId::from(2);
let thread_a = ParaId::from(3);
let paras = vec![(chain_a, true), (chain_b, true), (thread_a, false)];
let validators = vec![
Sr25519Keyring::Alice,
Sr25519Keyring::Bob,
Sr25519Keyring::Charlie,
Sr25519Keyring::Dave,
Sr25519Keyring::Ferdie,
];
let keystore: SyncCryptoStorePtr = Arc::new(LocalKeystore::in_memory());
for validator in validators.iter() {
SyncCryptoStore::sr25519_generate_new(&*keystore, PARACHAIN_KEY_TYPE_ID, Some(&validator.to_seed())).unwrap();
}
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let validator_public = validator_pubkeys(&validators);
new_test_ext(genesis_config(paras)).execute_with(|| {
Validators::set(validator_public.clone());
CurrentSessionIndex::set(5);
run_to_block(5, |_| None);
let signing_context = SigningContext {
parent_hash: System::parent_hash(),
session_index: 5,
};
let group_validators = |group_index: GroupIndex| match group_index {
group_index if group_index == GroupIndex::from(0) => Some(vec![0, 1]),
group_index if group_index == GroupIndex::from(1) => Some(vec![2, 3]),
group_index if group_index == GroupIndex::from(2) => Some(vec![4]),
_ => panic!("Group index out of bounds for 2 parachains and 1 parathread core"),
};
let thread_collator: CollatorId = Sr25519Keyring::Two.public().into();
let chain_a_assignment = CoreAssignment {
core: CoreIndex::from(0),
para_id: chain_a,
kind: AssignmentKind::Parachain,
group_idx: GroupIndex::from(0),
};
let chain_b_assignment = CoreAssignment {
core: CoreIndex::from(1),
para_id: chain_b,
kind: AssignmentKind::Parachain,
group_idx: GroupIndex::from(1),
};
let thread_a_assignment = CoreAssignment {
core: CoreIndex::from(2),
para_id: thread_a,
kind: AssignmentKind::Parathread(thread_collator.clone(), 0),
group_idx: GroupIndex::from(2),
};
// unscheduled candidate.
{
let mut candidate = TestCandidateBuilder {
para_id: chain_a,
persisted_validation_data_hash: make_vdata_hash(chain_a).unwrap(),
collator_sign_candidate(
Sr25519Keyring::One,
&mut candidate,
);
let backed = block_on(back_candidate(
candidate,
&validators,
group_validators(GroupIndex::from(0)).unwrap().as_ref(),
&keystore,
&signing_context,
BackingKind::Threshold,
));
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assert_eq!(
Inclusion::process_candidates(
vec![backed],
vec![chain_b_assignment.clone()],
&group_validators,
),
Err(Error::<Test>::UnscheduledCandidate.into()),
);
}
// candidates out of order.
{
let mut candidate_a = TestCandidateBuilder {
para_id: chain_a,
persisted_validation_data_hash: make_vdata_hash(chain_a).unwrap(),
}.build();
let mut candidate_b = TestCandidateBuilder {
para_id: chain_b,
persisted_validation_data_hash: make_vdata_hash(chain_b).unwrap(),
collator_sign_candidate(
Sr25519Keyring::One,
&mut candidate_a,
);
collator_sign_candidate(
Sr25519Keyring::Two,
&mut candidate_b,
);
let backed_a = block_on(back_candidate(
candidate_a,
&validators,
group_validators(GroupIndex::from(0)).unwrap().as_ref(),
&keystore,
&signing_context,
BackingKind::Threshold,
));
let backed_b = block_on(back_candidate(
candidate_b,
&validators,
group_validators(GroupIndex::from(1)).unwrap().as_ref(),
&keystore,
&signing_context,
BackingKind::Threshold,
));
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// out-of-order manifests as unscheduled.
assert_eq!(
Inclusion::process_candidates(
vec![backed_b, backed_a],
vec![chain_a_assignment.clone(), chain_b_assignment.clone()],
&group_validators,
),
Err(Error::<Test>::UnscheduledCandidate.into()),
);
}
// candidate not backed.
{
let mut candidate = TestCandidateBuilder {
para_id: chain_a,
persisted_validation_data_hash: make_vdata_hash(chain_a).unwrap(),
collator_sign_candidate(
Sr25519Keyring::One,
&mut candidate,
);
let backed = block_on(back_candidate(
candidate,
&validators,
group_validators(GroupIndex::from(0)).unwrap().as_ref(),
&keystore,
&signing_context,
BackingKind::Lacking,
));
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committed
assert_eq!(
Inclusion::process_candidates(
vec![backed],
vec![chain_a_assignment.clone()],
&group_validators,
),
Err(Error::<Test>::InsufficientBacking.into()),
);
}
// candidate not in parent context.
{
let wrong_parent_hash = Hash::from([222; 32]);
assert!(System::parent_hash() != wrong_parent_hash);
let mut candidate = TestCandidateBuilder {
para_id: chain_a,
persisted_validation_data_hash: make_vdata_hash(chain_a).unwrap(),
collator_sign_candidate(
Sr25519Keyring::One,
&mut candidate,
);
let backed = block_on(back_candidate(
candidate,
&validators,
group_validators(GroupIndex::from(0)).unwrap().as_ref(),
&keystore,
&signing_context,
BackingKind::Threshold,
));
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committed
assert_eq!(
Inclusion::process_candidates(
vec![backed],
vec![chain_a_assignment.clone()],
&group_validators,
),
Err(Error::<Test>::CandidateNotInParentContext.into()),
);
}
// candidate has wrong collator.
{
let mut candidate = TestCandidateBuilder {
para_id: thread_a,
persisted_validation_data_hash: make_vdata_hash(thread_a).unwrap(),
assert!(CollatorId::from(Sr25519Keyring::One.public()) != thread_collator);
collator_sign_candidate(
Sr25519Keyring::One,
&mut candidate,
);
let backed = block_on(back_candidate(
candidate,
&validators,
group_validators(GroupIndex::from(2)).unwrap().as_ref(),
&keystore,
&signing_context,
BackingKind::Threshold,
));
asynchronous rob
committed
assert_eq!(
Inclusion::process_candidates(
vec![backed],
vec![
chain_a_assignment.clone(),
chain_b_assignment.clone(),
thread_a_assignment.clone(),
],
&group_validators,
),
Err(Error::<Test>::WrongCollator.into()),
);
}
// candidate not well-signed by collator.
{
let mut candidate = TestCandidateBuilder {
para_id: thread_a,
persisted_validation_data_hash: make_vdata_hash(thread_a).unwrap(),
assert_eq!(CollatorId::from(Sr25519Keyring::Two.public()), thread_collator);
collator_sign_candidate(
Sr25519Keyring::Two,
&mut candidate,
);
// change the candidate after signing.
candidate.descriptor.pov_hash = Hash::from([2; 32]);
let backed = block_on(back_candidate(
candidate,
&validators,
group_validators(GroupIndex::from(2)).unwrap().as_ref(),
&keystore,
&signing_context,
BackingKind::Threshold,
));
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assert_eq!(
Inclusion::process_candidates(
vec![backed],
vec![thread_a_assignment.clone()],
&group_validators,
),
Err(Error::<Test>::NotCollatorSigned.into()),
);
}
// para occupied - reject.
{
let mut candidate = TestCandidateBuilder {
para_id: chain_a,
persisted_validation_data_hash: make_vdata_hash(chain_a).unwrap(),
collator_sign_candidate(
Sr25519Keyring::One,
&mut candidate,
);
let backed = block_on(back_candidate(
candidate,
&validators,
group_validators(GroupIndex::from(0)).unwrap().as_ref(),
&keystore,
&signing_context,
BackingKind::Threshold,
));
let candidate = TestCandidateBuilder::default().build();
<PendingAvailability<Test>>::insert(&chain_a, CandidatePendingAvailability {
core: CoreIndex::from(0),
descriptor: candidate.descriptor,
availability_votes: default_availability_votes(),
relay_parent_number: 3,
backed_in_number: 4,
});
<PendingAvailabilityCommitments>::insert(&chain_a, candidate.commitments);
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committed
assert_eq!(
Inclusion::process_candidates(
vec![backed],
vec![chain_a_assignment.clone()],
&group_validators,
),
Err(Error::<Test>::CandidateScheduledBeforeParaFree.into()),
);
<PendingAvailability<Test>>::remove(&chain_a);
<PendingAvailabilityCommitments>::remove(&chain_a);
}
// messed up commitments storage - do not panic - reject.
{
let mut candidate = TestCandidateBuilder {
para_id: chain_a,
relay_parent: System::parent_hash(),
pov_hash: Hash::from([1; 32]),
persisted_validation_data_hash: make_vdata_hash(chain_a).unwrap(),
..Default::default()
}.build();
collator_sign_candidate(
Sr25519Keyring::One,
&mut candidate,
);
// this is not supposed to happen
<PendingAvailabilityCommitments>::insert(&chain_a, candidate.commitments.clone());
let backed = block_on(back_candidate(
candidate,
&validators,
group_validators(GroupIndex::from(0)).unwrap().as_ref(),
&keystore,
&signing_context,
BackingKind::Threshold,
));
asynchronous rob
committed
assert_eq!(
Inclusion::process_candidates(
vec![backed],
vec![chain_a_assignment.clone()],
&group_validators,
),
Err(Error::<Test>::CandidateScheduledBeforeParaFree.into()),
);
<PendingAvailabilityCommitments>::remove(&chain_a);
}
// interfering code upgrade - reject
{
let mut candidate = TestCandidateBuilder {
para_id: chain_a,
pov_hash: Hash::from([1; 32]),
new_validation_code: Some(vec![5, 6, 7, 8].into()),
persisted_validation_data_hash: make_vdata_hash(chain_a).unwrap(),
collator_sign_candidate(
Sr25519Keyring::One,
&mut candidate,
);
let backed = block_on(back_candidate(
candidate,
&validators,
group_validators(GroupIndex::from(0)).unwrap().as_ref(),
&keystore,
&signing_context,
BackingKind::Threshold,
));
Paras::schedule_code_upgrade(
chain_a,
vec![1, 2, 3, 4].into(),
10,
);
assert_eq!(Paras::last_code_upgrade(chain_a, true), Some(10));
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assert_eq!(
Inclusion::process_candidates(
vec![backed],
vec![chain_a_assignment.clone()],
&group_validators,
),
Err(Error::<Test>::PrematureCodeUpgrade.into()),
);
}
// Bad validation data hash - reject
{
let mut candidate = TestCandidateBuilder {
para_id: chain_a,
relay_parent: System::parent_hash(),
pov_hash: Hash::from([1; 32]),
persisted_validation_data_hash: [42u8; 32].into(),
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..Default::default()
}.build();
collator_sign_candidate(
Sr25519Keyring::One,
&mut candidate,
);
let backed = block_on(back_candidate(
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committed
candidate,
&validators,
group_validators(GroupIndex::from(0)).unwrap().as_ref(),
&keystore,
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committed
&signing_context,
BackingKind::Threshold,
));
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assert_eq!(
Inclusion::process_candidates(
vec![backed],
vec![chain_a_assignment.clone()],
&group_validators,
),
Err(Error::<Test>::ValidationDataHashMismatch.into()),
);
}
});
}
#[test]
fn backing_works() {
let chain_a = ParaId::from(1);
let chain_b = ParaId::from(2);
let thread_a = ParaId::from(3);
let paras = vec![(chain_a, true), (chain_b, true), (thread_a, false)];
let validators = vec![
Sr25519Keyring::Alice,
Sr25519Keyring::Bob,
Sr25519Keyring::Charlie,
Sr25519Keyring::Dave,
Sr25519Keyring::Ferdie,
];
let keystore: SyncCryptoStorePtr = Arc::new(LocalKeystore::in_memory());
for validator in validators.iter() {
SyncCryptoStore::sr25519_generate_new(&*keystore, PARACHAIN_KEY_TYPE_ID, Some(&validator.to_seed())).unwrap();
}
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let validator_public = validator_pubkeys(&validators);
new_test_ext(genesis_config(paras)).execute_with(|| {
Validators::set(validator_public.clone());
CurrentSessionIndex::set(5);
run_to_block(5, |_| None);
let signing_context = SigningContext {
parent_hash: System::parent_hash(),
session_index: 5,
};
let group_validators = |group_index: GroupIndex| match group_index {
group_index if group_index == GroupIndex::from(0) => Some(vec![0, 1]),
group_index if group_index == GroupIndex::from(1) => Some(vec![2, 3]),
group_index if group_index == GroupIndex::from(2) => Some(vec![4]),
_ => panic!("Group index out of bounds for 2 parachains and 1 parathread core"),
};
let thread_collator: CollatorId = Sr25519Keyring::Two.public().into();
let chain_a_assignment = CoreAssignment {
core: CoreIndex::from(0),
para_id: chain_a,
kind: AssignmentKind::Parachain,
group_idx: GroupIndex::from(0),
};
let chain_b_assignment = CoreAssignment {
core: CoreIndex::from(1),
para_id: chain_b,
kind: AssignmentKind::Parachain,
group_idx: GroupIndex::from(1),
};
let thread_a_assignment = CoreAssignment {
core: CoreIndex::from(2),
para_id: thread_a,
kind: AssignmentKind::Parathread(thread_collator.clone(), 0),
group_idx: GroupIndex::from(2),
};
let mut candidate_a = TestCandidateBuilder {
para_id: chain_a,
persisted_validation_data_hash: make_vdata_hash(chain_a).unwrap(),
collator_sign_candidate(
Sr25519Keyring::One,
&mut candidate_a,
);
let mut candidate_b = TestCandidateBuilder {
para_id: chain_b,
persisted_validation_data_hash: make_vdata_hash(chain_b).unwrap(),
collator_sign_candidate(
Sr25519Keyring::One,
&mut candidate_b,
);
let mut candidate_c = TestCandidateBuilder {
para_id: thread_a,
persisted_validation_data_hash: make_vdata_hash(thread_a).unwrap(),
collator_sign_candidate(
Sr25519Keyring::Two,
&mut candidate_c,
);
let backed_a = block_on(back_candidate(
candidate_a.clone(),
&validators,
group_validators(GroupIndex::from(0)).unwrap().as_ref(),
&keystore,
&signing_context,
BackingKind::Threshold,
));
let backed_b = block_on(back_candidate(
candidate_b.clone(),
&validators,
group_validators(GroupIndex::from(1)).unwrap().as_ref(),
&keystore,
&signing_context,
BackingKind::Threshold,
));
let backed_c = block_on(back_candidate(
candidate_c.clone(),
&validators,
group_validators(GroupIndex::from(2)).unwrap().as_ref(),
&keystore,
&signing_context,
BackingKind::Threshold,
));
let occupied_cores = Inclusion::process_candidates(
vec![backed_a, backed_b, backed_c],
vec![
chain_a_assignment.clone(),
chain_b_assignment.clone(),
thread_a_assignment.clone(),
],
&group_validators,
).expect("candidates scheduled, in order, and backed");
assert_eq!(occupied_cores, vec![CoreIndex::from(0), CoreIndex::from(1), CoreIndex::from(2)]);
assert_eq!(
<PendingAvailability<Test>>::get(&chain_a),
Some(CandidatePendingAvailability {
core: CoreIndex::from(0),
descriptor: candidate_a.descriptor,
availability_votes: default_availability_votes(),
relay_parent_number: System::block_number() - 1,
backed_in_number: System::block_number(),
})
);
assert_eq!(
<PendingAvailabilityCommitments>::get(&chain_a),
Some(candidate_a.commitments),
);
assert_eq!(
<PendingAvailability<Test>>::get(&chain_b),
Some(CandidatePendingAvailability {
core: CoreIndex::from(1),
descriptor: candidate_b.descriptor,
availability_votes: default_availability_votes(),
relay_parent_number: System::block_number() - 1,
backed_in_number: System::block_number(),
})
);
assert_eq!(
<PendingAvailabilityCommitments>::get(&chain_b),
Some(candidate_b.commitments),
);
assert_eq!(
<PendingAvailability<Test>>::get(&thread_a),
Some(CandidatePendingAvailability {
core: CoreIndex::from(2),
descriptor: candidate_c.descriptor,
availability_votes: default_availability_votes(),
relay_parent_number: System::block_number() - 1,
backed_in_number: System::block_number(),
})
);
assert_eq!(
<PendingAvailabilityCommitments>::get(&thread_a),
Some(candidate_c.commitments),
);