Files
pezkuwi-subxt/polkadot/runtime/parachains/src/builder.rs
T
Alexandru Gheorghe d6f68bb906 primitives: Move out of staging released APIs (#3925)
Runtime release 1.2 includes bumping of the ParachainHost APIs up to
v10, so let's move all the released APIs out of vstaging folder, this PR
does not include any logic changes only renaming of the modules and some
moving around.

Signed-off-by: Alexandru Gheorghe <alexandru.gheorghe@parity.io>
2024-04-01 13:03:26 +00:00

896 lines
31 KiB
Rust

// Copyright (C) Parity Technologies (UK) Ltd.
// This file is part of Polkadot.
// Polkadot is free software: you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
// Polkadot is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
// You should have received a copy of the GNU General Public License
// along with Polkadot. If not, see <http://www.gnu.org/licenses/>.
use crate::{
configuration, inclusion, initializer, paras,
paras::ParaKind,
paras_inherent,
scheduler::{self, common::AssignmentProvider, CoreOccupied, ParasEntry},
session_info, shared,
};
use bitvec::{order::Lsb0 as BitOrderLsb0, vec::BitVec};
use frame_support::pallet_prelude::*;
use frame_system::pallet_prelude::*;
use primitives::{
collator_signature_payload, node_features::FeatureIndex, AvailabilityBitfield, BackedCandidate,
CandidateCommitments, CandidateDescriptor, CandidateHash, CollatorId, CollatorSignature,
CommittedCandidateReceipt, CompactStatement, CoreIndex, DisputeStatement, DisputeStatementSet,
GroupIndex, HeadData, Id as ParaId, IndexedVec, InherentData as ParachainsInherentData,
InvalidDisputeStatementKind, PersistedValidationData, SessionIndex, SigningContext,
UncheckedSigned, ValidDisputeStatementKind, ValidationCode, ValidatorId, ValidatorIndex,
ValidityAttestation,
};
use sp_core::{sr25519, H256};
use sp_runtime::{
generic::Digest,
traits::{Header as HeaderT, One, TrailingZeroInput, Zero},
RuntimeAppPublic,
};
use sp_std::{
collections::{btree_map::BTreeMap, btree_set::BTreeSet, vec_deque::VecDeque},
prelude::Vec,
vec,
};
fn mock_validation_code() -> ValidationCode {
ValidationCode(vec![1, 2, 3])
}
/// Grab an account, seeded by a name and index.
///
/// This is directly from frame-benchmarking. Copy/pasted so we can use it when not compiling with
/// "features = runtime-benchmarks".
fn account<AccountId: Decode>(name: &'static str, index: u32, seed: u32) -> AccountId {
let entropy = (name, index, seed).using_encoded(sp_io::hashing::blake2_256);
AccountId::decode(&mut TrailingZeroInput::new(&entropy[..]))
.expect("infinite input; no invalid input; qed")
}
/// Create a 32 byte slice based on the given number.
fn byte32_slice_from(n: u32) -> [u8; 32] {
let mut slice = [0u8; 32];
slice[31] = (n % (1 << 8)) as u8;
slice[30] = ((n >> 8) % (1 << 8)) as u8;
slice[29] = ((n >> 16) % (1 << 8)) as u8;
slice[28] = ((n >> 24) % (1 << 8)) as u8;
slice
}
/// Paras inherent `enter` benchmark scenario builder.
pub(crate) struct BenchBuilder<T: paras_inherent::Config> {
/// Active validators. Validators should be declared prior to all other setup.
validators: Option<IndexedVec<ValidatorIndex, ValidatorId>>,
/// Starting block number; we expect it to get incremented on session setup.
block_number: BlockNumberFor<T>,
/// Starting session; we expect it to get incremented on session setup.
session: SessionIndex,
/// Session we want the scenario to take place in. We will roll to this session.
target_session: u32,
/// Optionally set the max validators per core; otherwise uses the configuration value.
max_validators_per_core: Option<u32>,
/// Optionally set the max validators; otherwise uses the configuration value.
max_validators: Option<u32>,
/// Optionally set the number of dispute statements for each candidate.
dispute_statements: BTreeMap<u32, u32>,
/// Session index of for each dispute. Index of slice corresponds to a core,
/// which is offset by the number of entries for `backed_and_concluding_paras`. I.E. if
/// `backed_and_concluding_paras` has 3 entries, the first index of `dispute_sessions`
/// will correspond to core index 3. There must be one entry for each core with a dispute
/// statement set.
dispute_sessions: Vec<u32>,
/// Map from para id to number of validity votes. Core indices are generated based on
/// `elastic_paras` configuration. Each para id in `elastic_paras` gets the
/// specified amount of consecutive cores assigned to it. If a para id is not present
/// in `elastic_paras` it get assigned to a single core.
backed_and_concluding_paras: BTreeMap<u32, u32>,
/// Map from para id (seed) to number of chained candidates.
elastic_paras: BTreeMap<u32, u8>,
/// Make every candidate include a code upgrade by setting this to `Some` where the interior
/// value is the byte length of the new code.
code_upgrade: Option<u32>,
/// Specifies whether the claimqueue should be filled.
fill_claimqueue: bool,
/// Cores which should not be available when being populated with pending candidates.
unavailable_cores: Vec<u32>,
_phantom: sp_std::marker::PhantomData<T>,
}
/// Paras inherent `enter` benchmark scenario.
#[cfg(any(feature = "runtime-benchmarks", test))]
pub(crate) struct Bench<T: paras_inherent::Config> {
pub(crate) data: ParachainsInherentData<HeaderFor<T>>,
pub(crate) _session: u32,
pub(crate) _block_number: BlockNumberFor<T>,
}
#[allow(dead_code)]
impl<T: paras_inherent::Config> BenchBuilder<T> {
/// Create a new `BenchBuilder` with some opinionated values that should work with the rest
/// of the functions in this implementation.
pub(crate) fn new() -> Self {
BenchBuilder {
validators: None,
block_number: Zero::zero(),
session: SessionIndex::from(0u32),
target_session: 2u32,
max_validators_per_core: None,
max_validators: None,
dispute_statements: BTreeMap::new(),
dispute_sessions: Default::default(),
backed_and_concluding_paras: Default::default(),
elastic_paras: Default::default(),
code_upgrade: None,
fill_claimqueue: true,
unavailable_cores: vec![],
_phantom: sp_std::marker::PhantomData::<T>,
}
}
/// Set the session index for each dispute statement set (in other words, set the session the
/// the dispute statement set's relay chain block is from). Indexes of `dispute_sessions`
/// correspond to a core, which is offset by the number of entries for
/// `backed_and_concluding_paras`. I.E. if `backed_and_concluding_paras` cores has 3 entries,
/// the first index of `dispute_sessions` will correspond to core index 3.
///
/// Note that there must be an entry for each core with a dispute statement set.
pub(crate) fn set_dispute_sessions(mut self, dispute_sessions: impl AsRef<[u32]>) -> Self {
self.dispute_sessions = dispute_sessions.as_ref().to_vec();
self
}
/// Set the cores which should not be available when being populated with pending candidates.
pub(crate) fn set_unavailable_cores(mut self, unavailable_cores: Vec<u32>) -> Self {
self.unavailable_cores = unavailable_cores;
self
}
/// Set a map from para id seed to number of validity votes.
pub(crate) fn set_backed_and_concluding_paras(
mut self,
backed_and_concluding_paras: BTreeMap<u32, u32>,
) -> Self {
self.backed_and_concluding_paras = backed_and_concluding_paras;
self
}
/// Set a map from para id seed to number of cores assigned to it.
pub(crate) fn set_elastic_paras(mut self, elastic_paras: BTreeMap<u32, u8>) -> Self {
self.elastic_paras = elastic_paras;
self
}
/// Set to include a code upgrade for all backed candidates. The value will be the byte length
/// of the code.
pub(crate) fn set_code_upgrade(mut self, code_upgrade: impl Into<Option<u32>>) -> Self {
self.code_upgrade = code_upgrade.into();
self
}
/// Mock header.
pub(crate) fn header(block_number: BlockNumberFor<T>) -> HeaderFor<T> {
HeaderFor::<T>::new(
block_number, // `block_number`,
Default::default(), // `extrinsics_root`,
Default::default(), // `storage_root`,
Default::default(), // `parent_hash`,
Default::default(), // digest,
)
}
/// Number of the relay parent block.
fn relay_parent_number(&self) -> u32 {
(self.block_number - One::one())
.try_into()
.map_err(|_| ())
.expect("self.block_number is u32")
}
/// Maximum number of validators that may be part of a validator group.
pub(crate) fn fallback_max_validators() -> u32 {
configuration::Pallet::<T>::config().max_validators.unwrap_or(200)
}
/// Maximum number of validators participating in parachains consensus (a.k.a. active
/// validators).
fn max_validators(&self) -> u32 {
self.max_validators.unwrap_or(Self::fallback_max_validators())
}
/// Set the maximum number of active validators.
#[cfg(not(feature = "runtime-benchmarks"))]
pub(crate) fn set_max_validators(mut self, n: u32) -> Self {
self.max_validators = Some(n);
self
}
/// Maximum number of validators per core (a.k.a. max validators per group). This value is used
/// if none is explicitly set on the builder.
pub(crate) fn fallback_max_validators_per_core() -> u32 {
configuration::Pallet::<T>::config()
.scheduler_params
.max_validators_per_core
.unwrap_or(5)
}
/// Specify a mapping of core index/ para id to the number of dispute statements for the
/// corresponding dispute statement set. Note that if the number of disputes is not specified
/// it fallbacks to having a dispute per every validator. Additionally, an entry is not
/// guaranteed to have a dispute - it must line up with the cores marked as disputed as defined
/// in `Self::Build`.
#[cfg(not(feature = "runtime-benchmarks"))]
pub(crate) fn set_dispute_statements(mut self, m: BTreeMap<u32, u32>) -> Self {
self.dispute_statements = m;
self
}
/// Get the maximum number of validators per core.
fn max_validators_per_core(&self) -> u32 {
self.max_validators_per_core.unwrap_or(Self::fallback_max_validators_per_core())
}
/// Set maximum number of validators per core.
#[cfg(not(feature = "runtime-benchmarks"))]
pub(crate) fn set_max_validators_per_core(mut self, n: u32) -> Self {
self.max_validators_per_core = Some(n);
self
}
/// Get the maximum number of cores we expect from this configuration.
pub(crate) fn max_cores(&self) -> u32 {
self.max_validators() / self.max_validators_per_core()
}
/// Set whether the claim queue should be filled.
#[cfg(not(feature = "runtime-benchmarks"))]
pub(crate) fn set_fill_claimqueue(mut self, f: bool) -> Self {
self.fill_claimqueue = f;
self
}
/// Get the minimum number of validity votes in order for a backed candidate to be included.
#[cfg(feature = "runtime-benchmarks")]
pub(crate) fn fallback_min_validity_votes() -> u32 {
(Self::fallback_max_validators() / 2) + 1
}
fn mock_head_data() -> HeadData {
let max_head_size = configuration::Pallet::<T>::config().max_head_data_size;
HeadData(vec![0xFF; max_head_size as usize])
}
fn candidate_descriptor_mock() -> CandidateDescriptor<T::Hash> {
CandidateDescriptor::<T::Hash> {
para_id: 0.into(),
relay_parent: Default::default(),
collator: CollatorId::from(sr25519::Public::from_raw([42u8; 32])),
persisted_validation_data_hash: Default::default(),
pov_hash: Default::default(),
erasure_root: Default::default(),
signature: CollatorSignature::from(sr25519::Signature::from_raw([42u8; 64])),
para_head: Default::default(),
validation_code_hash: mock_validation_code().hash(),
}
}
/// Create a mock of `CandidatePendingAvailability`.
fn candidate_availability_mock(
group_idx: GroupIndex,
core_idx: CoreIndex,
candidate_hash: CandidateHash,
availability_votes: BitVec<u8, BitOrderLsb0>,
commitments: CandidateCommitments,
) -> inclusion::CandidatePendingAvailability<T::Hash, BlockNumberFor<T>> {
inclusion::CandidatePendingAvailability::<T::Hash, BlockNumberFor<T>>::new(
core_idx, // core
candidate_hash, // hash
Self::candidate_descriptor_mock(), // candidate descriptor
commitments, // commitments
availability_votes, // availability votes
Default::default(), // backers
Zero::zero(), // relay parent
One::one(), // relay chain block this was backed in
group_idx, // backing group
)
}
/// Add `CandidatePendingAvailability` and `CandidateCommitments` to the relevant storage items.
///
/// NOTE: the default `CandidateCommitments` used does not include any data that would lead to
/// heavy code paths in `enact_candidate`. But enact_candidates does return a weight which will
/// get taken into account.
fn add_availability(
para_id: ParaId,
core_idx: CoreIndex,
group_idx: GroupIndex,
availability_votes: BitVec<u8, BitOrderLsb0>,
candidate_hash: CandidateHash,
) {
let commitments = CandidateCommitments::<u32> {
upward_messages: Default::default(),
horizontal_messages: Default::default(),
new_validation_code: None,
head_data: Self::mock_head_data(),
processed_downward_messages: 0,
hrmp_watermark: 0u32.into(),
};
let candidate_availability = Self::candidate_availability_mock(
group_idx,
core_idx,
candidate_hash,
availability_votes,
commitments,
);
inclusion::PendingAvailability::<T>::mutate(para_id, |maybe_andidates| {
if let Some(candidates) = maybe_andidates {
candidates.push_back(candidate_availability);
} else {
*maybe_andidates =
Some([candidate_availability].into_iter().collect::<VecDeque<_>>());
}
});
}
/// Create an `AvailabilityBitfield` where `concluding` is a map where each key is a core index
/// that is concluding and `cores` is the total number of cores in the system.
fn availability_bitvec(concluding_cores: &BTreeSet<u32>, cores: usize) -> AvailabilityBitfield {
let mut bitfields = bitvec::bitvec![u8, bitvec::order::Lsb0; 0; 0];
for i in 0..cores {
if concluding_cores.contains(&(i as u32)) {
bitfields.push(true);
} else {
bitfields.push(false)
}
}
bitfields.into()
}
/// Run to block number `to`, calling `initializer` `on_initialize` and `on_finalize` along the
/// way.
fn run_to_block(to: u32) {
let to = to.into();
while frame_system::Pallet::<T>::block_number() < to {
let b = frame_system::Pallet::<T>::block_number();
initializer::Pallet::<T>::on_finalize(b);
let b = b + One::one();
frame_system::Pallet::<T>::set_block_number(b);
initializer::Pallet::<T>::on_initialize(b);
}
}
/// Register `n_paras` count of parachains.
///
/// Note that this must be called at least 2 sessions before the target session as there is a
/// n+2 session delay for the scheduled actions to take effect.
fn setup_para_ids(n_paras: usize) {
// make sure parachains exist prior to session change.
for i in 0..n_paras {
let para_id = ParaId::from(i as u32);
let validation_code = mock_validation_code();
paras::Pallet::<T>::schedule_para_initialize(
para_id,
paras::ParaGenesisArgs {
genesis_head: Self::mock_head_data(),
validation_code: validation_code.clone(),
para_kind: ParaKind::Parachain,
},
)
.unwrap();
paras::Pallet::<T>::add_trusted_validation_code(
frame_system::Origin::<T>::Root.into(),
validation_code,
)
.unwrap();
}
}
/// Generate validator key pairs and account ids.
fn generate_validator_pairs(validator_count: u32) -> Vec<(T::AccountId, ValidatorId)> {
(0..validator_count)
.map(|i| {
let public = ValidatorId::generate_pair(None);
// The account Id is not actually used anywhere, just necessary to fulfill the
// expected type of the `validators` param of `test_trigger_on_new_session`.
let account: T::AccountId = account("validator", i, i);
(account, public)
})
.collect()
}
fn signing_context(&self) -> SigningContext<T::Hash> {
SigningContext {
parent_hash: Self::header(self.block_number).hash(),
session_index: self.session,
}
}
/// Create a bitvec of `validators` length with all yes votes.
fn validator_availability_votes_yes(validators: usize) -> BitVec<u8, bitvec::order::Lsb0> {
// every validator confirms availability.
bitvec::bitvec![u8, bitvec::order::Lsb0; 1; validators as usize]
}
/// Setup session 1 and create `self.validators_map` and `self.validators`.
fn setup_session(
mut self,
target_session: SessionIndex,
validators: Vec<(T::AccountId, ValidatorId)>,
// Total cores used in the scenario
total_cores: usize,
// Additional cores for elastic parachains
extra_cores: usize,
) -> Self {
let mut block = 1;
for session in 0..=target_session {
initializer::Pallet::<T>::test_trigger_on_new_session(
false,
session,
validators.iter().map(|(a, v)| (a, v.clone())),
None,
);
block += 1;
Self::run_to_block(block);
}
let block_number = BlockNumberFor::<T>::from(block);
let header = Self::header(block_number);
frame_system::Pallet::<T>::reset_events();
frame_system::Pallet::<T>::initialize(
&header.number(),
&header.hash(),
&Digest { logs: Vec::new() },
);
assert_eq!(<shared::Pallet<T>>::session_index(), target_session);
// We need to refetch validators since they have been shuffled.
let validators_shuffled = session_info::Pallet::<T>::session_info(target_session)
.unwrap()
.validators
.clone();
self.validators = Some(validators_shuffled);
self.block_number = block_number;
self.session = target_session;
assert_eq!(paras::Pallet::<T>::parachains().len(), total_cores - extra_cores);
self
}
/// Create a `UncheckedSigned<AvailabilityBitfield> for each validator where each core in
/// `concluding_cores` is fully available. Additionally set up storage such that each
/// `concluding_cores`is pending becoming fully available so the generated bitfields will be
/// to the cores successfully being freed from the candidates being marked as available.
fn create_availability_bitfields(
&self,
concluding_paras: &BTreeMap<u32, u32>,
elastic_paras: &BTreeMap<u32, u8>,
total_cores: usize,
) -> Vec<UncheckedSigned<AvailabilityBitfield>> {
let validators =
self.validators.as_ref().expect("must have some validators prior to calling");
let mut current_core_idx = 0u32;
let mut concluding_cores = BTreeSet::new();
for (seed, _) in concluding_paras.iter() {
// make sure the candidates that will be concluding are marked as pending availability.
let para_id = ParaId::from(*seed);
for _chain_idx in 0..elastic_paras.get(&seed).cloned().unwrap_or(1) {
let core_idx = CoreIndex::from(current_core_idx);
let group_idx =
scheduler::Pallet::<T>::group_assigned_to_core(core_idx, self.block_number)
.unwrap();
Self::add_availability(
para_id,
core_idx,
group_idx,
// No validators have made this candidate available yet.
bitvec::bitvec![u8, bitvec::order::Lsb0; 0; validators.len()],
CandidateHash(H256::from(byte32_slice_from(current_core_idx))),
);
if !self.unavailable_cores.contains(&current_core_idx) {
concluding_cores.insert(current_core_idx);
}
current_core_idx += 1;
}
}
let availability_bitvec = Self::availability_bitvec(&concluding_cores, total_cores);
let bitfields: Vec<UncheckedSigned<AvailabilityBitfield>> = validators
.iter()
.enumerate()
.map(|(i, public)| {
let unchecked_signed = UncheckedSigned::<AvailabilityBitfield>::benchmark_sign(
public,
availability_bitvec.clone(),
&self.signing_context(),
ValidatorIndex(i as u32),
);
unchecked_signed
})
.collect();
bitfields
}
/// Create backed candidates for `cores_with_backed_candidates`. You need these cores to be
/// scheduled _within_ paras inherent, which requires marking the available bitfields as fully
/// available.
/// - `cores_with_backed_candidates` Mapping of `para_id` seed to number of
/// validity votes.
fn create_backed_candidates(
&self,
paras_with_backed_candidates: &BTreeMap<u32, u32>,
elastic_paras: &BTreeMap<u32, u8>,
includes_code_upgrade: Option<u32>,
) -> Vec<BackedCandidate<T::Hash>> {
let validators =
self.validators.as_ref().expect("must have some validators prior to calling");
let config = configuration::Pallet::<T>::config();
let mut current_core_idx = 0u32;
paras_with_backed_candidates
.iter()
.flat_map(|(seed, num_votes)| {
assert!(*num_votes <= validators.len() as u32);
let para_id = ParaId::from(*seed);
let mut prev_head = None;
// How many chained candidates we want to build ?
(0..elastic_paras.get(&seed).cloned().unwrap_or(1))
.map(|chain_idx| {
let core_idx = CoreIndex::from(current_core_idx);
// Advance core index.
current_core_idx += 1;
let group_idx = scheduler::Pallet::<T>::group_assigned_to_core(
core_idx,
self.block_number,
)
.unwrap();
// This generates a pair and adds it to the keystore, returning just the
// public.
let collator_public = CollatorId::generate_pair(None);
let header = Self::header(self.block_number);
let relay_parent = header.hash();
// Set the head data so it can be used while validating the signatures on
// the candidate receipt.
let mut head_data = Self::mock_head_data();
if chain_idx == 0 {
// Only first parahead of the chain needs to be set in storage.
paras::Pallet::<T>::heads_insert(&para_id, head_data.clone());
} else {
// Make each candidate head data unique to avoid cycles.
head_data.0[0] = chain_idx;
}
let persisted_validation_data_hash = PersistedValidationData::<H256> {
// To form a chain we set parent head to previous block if any, or
// default to what is in storage already setup.
parent_head: prev_head.take().unwrap_or(head_data.clone()),
relay_parent_number: self.relay_parent_number(),
relay_parent_storage_root: Default::default(),
max_pov_size: config.max_pov_size,
}
.hash();
prev_head = Some(head_data.clone());
let pov_hash = Default::default();
let validation_code_hash = mock_validation_code().hash();
let payload = collator_signature_payload(
&relay_parent,
&para_id,
&persisted_validation_data_hash,
&pov_hash,
&validation_code_hash,
);
let signature = collator_public.sign(&payload).unwrap();
let mut past_code_meta =
paras::ParaPastCodeMeta::<BlockNumberFor<T>>::default();
past_code_meta.note_replacement(0u32.into(), 0u32.into());
let group_validators =
scheduler::Pallet::<T>::group_validators(group_idx).unwrap();
let candidate = CommittedCandidateReceipt::<T::Hash> {
descriptor: CandidateDescriptor::<T::Hash> {
para_id,
relay_parent,
collator: collator_public,
persisted_validation_data_hash,
pov_hash,
erasure_root: Default::default(),
signature,
para_head: head_data.hash(),
validation_code_hash,
},
commitments: CandidateCommitments::<u32> {
upward_messages: Default::default(),
horizontal_messages: Default::default(),
new_validation_code: includes_code_upgrade
.map(|v| ValidationCode(vec![42u8; v as usize])),
head_data,
processed_downward_messages: 0,
hrmp_watermark: self.relay_parent_number(),
},
};
let candidate_hash = candidate.hash();
let validity_votes: Vec<_> = group_validators
.iter()
.take(*num_votes as usize)
.map(|val_idx| {
let public = validators.get(*val_idx).unwrap();
let sig = UncheckedSigned::<CompactStatement>::benchmark_sign(
public,
CompactStatement::Valid(candidate_hash),
&self.signing_context(),
*val_idx,
)
.benchmark_signature();
ValidityAttestation::Explicit(sig.clone())
})
.collect();
// Check if the elastic scaling bit is set, if so we need to supply the core
// index in the generated candidate.
let core_idx = configuration::Pallet::<T>::config()
.node_features
.get(FeatureIndex::ElasticScalingMVP as usize)
.map(|_the_bit| core_idx);
BackedCandidate::<T::Hash>::new(
candidate,
validity_votes,
bitvec::bitvec![u8, bitvec::order::Lsb0; 1; group_validators.len()],
core_idx,
)
})
.collect::<Vec<_>>()
})
.collect()
}
/// Fill cores `start..last` with dispute statement sets. The statement sets will have 3/4th of
/// votes be valid, and 1/4th of votes be invalid.
fn create_disputes(
&self,
start: u32,
last: u32,
dispute_sessions: impl AsRef<[u32]>,
) -> Vec<DisputeStatementSet> {
let validators =
self.validators.as_ref().expect("must have some validators prior to calling");
let dispute_sessions = dispute_sessions.as_ref();
let mut current_core_idx = start;
(start..last)
.map(|seed| {
let dispute_session_idx = (seed - start) as usize;
let session = dispute_sessions
.get(dispute_session_idx)
.cloned()
.unwrap_or(self.target_session);
let para_id = ParaId::from(seed);
let core_idx = CoreIndex::from(current_core_idx);
current_core_idx +=1;
let group_idx =
scheduler::Pallet::<T>::group_assigned_to_core(core_idx, self.block_number)
.unwrap();
let candidate_hash = CandidateHash(H256::from(byte32_slice_from(seed)));
let relay_parent = H256::from(byte32_slice_from(seed));
Self::add_availability(
para_id,
core_idx,
group_idx,
Self::validator_availability_votes_yes(validators.len()),
candidate_hash,
);
let statements_len =
self.dispute_statements.get(&seed).cloned().unwrap_or(validators.len() as u32);
let statements = (0..statements_len)
.map(|validator_index| {
let validator_public = &validators.get(ValidatorIndex::from(validator_index)).expect("Test case is not borked. `ValidatorIndex` out of bounds of `ValidatorId`s.");
// We need dispute statements on each side. And we don't want a revert log
// so we make sure that we have a super majority with valid statements.
let dispute_statement = if validator_index % 4 == 0 {
DisputeStatement::Invalid(InvalidDisputeStatementKind::Explicit)
} else if validator_index < 3 {
// Set two votes as backing for the dispute set to be accepted
DisputeStatement::Valid(
ValidDisputeStatementKind::BackingValid(relay_parent)
)
} else {
DisputeStatement::Valid(ValidDisputeStatementKind::Explicit)
};
let data = dispute_statement.payload_data(candidate_hash, session).unwrap();
let statement_sig = validator_public.sign(&data).unwrap();
(dispute_statement, ValidatorIndex(validator_index), statement_sig)
})
.collect();
DisputeStatementSet { candidate_hash, session, statements }
})
.collect()
}
/// Build a scenario for testing or benchmarks.
///
/// Note that this API only allows building scenarios where the `backed_and_concluding_paras`
/// are mutually exclusive with the cores for disputes. So
/// `backed_and_concluding_paras.len() + dispute_sessions.len()` must be less than the max
/// number of cores.
pub(crate) fn build(self) -> Bench<T> {
// Make sure relevant storage is cleared. This is just to get the asserts to work when
// running tests because it seems the storage is not cleared in between.
#[allow(deprecated)]
inclusion::PendingAvailability::<T>::remove_all(None);
// We don't allow a core to have both disputes and be marked fully available at this block.
let max_cores = self.max_cores() as usize;
let extra_cores = self
.elastic_paras
.values()
.map(|count| *count as usize)
.sum::<usize>()
.saturating_sub(self.elastic_paras.len() as usize);
let used_cores =
self.dispute_sessions.len() + self.backed_and_concluding_paras.len() + extra_cores;
assert!(used_cores <= max_cores);
let fill_claimqueue = self.fill_claimqueue;
// NOTE: there is an n+2 session delay for these actions to take effect.
// We are currently in Session 0, so these changes will take effect in Session 2.
Self::setup_para_ids(used_cores - extra_cores);
configuration::ActiveConfig::<T>::mutate(|c| {
c.scheduler_params.num_cores = used_cores as u32;
});
let validator_ids = Self::generate_validator_pairs(self.max_validators());
let target_session = SessionIndex::from(self.target_session);
let builder = self.setup_session(target_session, validator_ids, used_cores, extra_cores);
let bitfields = builder.create_availability_bitfields(
&builder.backed_and_concluding_paras,
&builder.elastic_paras,
used_cores,
);
let backed_candidates = builder.create_backed_candidates(
&builder.backed_and_concluding_paras,
&builder.elastic_paras,
builder.code_upgrade,
);
let disputes = builder.create_disputes(
builder.backed_and_concluding_paras.len() as u32,
(used_cores - extra_cores) as u32,
builder.dispute_sessions.as_slice(),
);
let mut disputed_cores = (builder.backed_and_concluding_paras.len() as u32..
((used_cores - extra_cores) as u32))
.into_iter()
.map(|idx| (idx, 0))
.collect::<BTreeMap<_, _>>();
let mut all_cores = builder.backed_and_concluding_paras.clone();
all_cores.append(&mut disputed_cores);
assert_eq!(inclusion::PendingAvailability::<T>::iter().count(), used_cores - extra_cores);
// Mark all the used cores as occupied. We expect that there are
// `backed_and_concluding_paras` that are pending availability and that there are
// `used_cores - backed_and_concluding_paras ` which are about to be disputed.
let now = <frame_system::Pallet<T>>::block_number() + One::one();
let mut core_idx = 0u32;
let elastic_paras = &builder.elastic_paras;
// Assign potentially multiple cores to same parachains,
let cores = all_cores
.iter()
.flat_map(|(para_id, _)| {
(0..elastic_paras.get(&para_id).cloned().unwrap_or(1))
.map(|_para_local_core_idx| {
let ttl = configuration::Pallet::<T>::config().scheduler_params.ttl;
// Load an assignment into provider so that one is present to pop
let assignment =
<T as scheduler::Config>::AssignmentProvider::get_mock_assignment(
CoreIndex(core_idx),
ParaId::from(*para_id),
);
core_idx += 1;
CoreOccupied::Paras(ParasEntry::new(assignment, now + ttl))
})
.collect::<Vec<CoreOccupied<_>>>()
})
.collect::<Vec<CoreOccupied<_>>>();
scheduler::AvailabilityCores::<T>::set(cores);
core_idx = 0u32;
if fill_claimqueue {
let cores = all_cores
.keys()
.flat_map(|para_id| {
(0..elastic_paras.get(&para_id).cloned().unwrap_or(1))
.filter_map(|_para_local_core_idx| {
let ttl = configuration::Pallet::<T>::config().scheduler_params.ttl;
// Load an assignment into provider so that one is present to pop
let assignment =
<T as scheduler::Config>::AssignmentProvider::get_mock_assignment(
CoreIndex(core_idx),
ParaId::from(*para_id),
);
let entry = (
CoreIndex(core_idx),
[ParasEntry::new(assignment, now + ttl)].into(),
);
let res = if builder.unavailable_cores.contains(&core_idx) {
None
} else {
Some(entry)
};
core_idx += 1;
res
})
.collect::<Vec<(CoreIndex, VecDeque<ParasEntry<_>>)>>()
})
.collect::<BTreeMap<CoreIndex, VecDeque<ParasEntry<_>>>>();
scheduler::ClaimQueue::<T>::set(cores);
}
Bench::<T> {
data: ParachainsInherentData {
bitfields,
backed_candidates,
disputes,
parent_header: Self::header(builder.block_number),
},
_session: target_session,
_block_number: builder.block_number,
}
}
}