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mod.rs
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// 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/>.
//! `V6` Primitives.
use bitvec::vec::BitVec;
use parity_scale_codec::{Decode, Encode};
use scale_info::TypeInfo;
use sp_std::{
marker::PhantomData,
prelude::*,
slice::{Iter, IterMut},
vec::IntoIter,
};
use application_crypto::KeyTypeId;
use inherents::InherentIdentifier;
use primitives::RuntimeDebug;
use runtime_primitives::traits::{AppVerify, Header as HeaderT};
use sp_arithmetic::traits::{BaseArithmetic, Saturating};
pub use runtime_primitives::traits::{BlakeTwo256, Hash as HashT};
// Export some core primitives.
pub use polkadot_core_primitives::v2::{
AccountId, AccountIndex, AccountPublic, Balance, Block, BlockId, BlockNumber, CandidateHash,
ChainId, DownwardMessage, Hash, Header, InboundDownwardMessage, InboundHrmpMessage, Moment,
Nonce, OutboundHrmpMessage, Remark, Signature, UncheckedExtrinsic,
};
// Export some polkadot-parachain primitives
pub use polkadot_parachain_primitives::primitives::{
HeadData, HorizontalMessages, HrmpChannelId, Id, UpwardMessage, UpwardMessages, ValidationCode,
ValidationCodeHash, LOWEST_PUBLIC_ID,
};
use serde::{Deserialize, Serialize};
pub use sp_authority_discovery::AuthorityId as AuthorityDiscoveryId;
pub use sp_consensus_slots::Slot;
pub use sp_staking::SessionIndex;
/// Signed data.
mod signed;
pub use signed::{EncodeAs, Signed, UncheckedSigned};
pub mod async_backing;
pub mod executor_params;
pub mod slashing;
pub use async_backing::AsyncBackingParams;
pub use executor_params::{ExecutorParam, ExecutorParamError, ExecutorParams, ExecutorParamsHash};
mod metrics;
pub use metrics::{
metric_definitions, RuntimeMetricLabel, RuntimeMetricLabelValue, RuntimeMetricLabelValues,
RuntimeMetricLabels, RuntimeMetricOp, RuntimeMetricUpdate,
};
/// The key type ID for a collator key.
pub const COLLATOR_KEY_TYPE_ID: KeyTypeId = KeyTypeId(*b"coll");
mod collator_app {
use application_crypto::{app_crypto, sr25519};
app_crypto!(sr25519, super::COLLATOR_KEY_TYPE_ID);
}
/// Identity that collators use.
pub type CollatorId = collator_app::Public;
/// A Parachain collator keypair.
#[cfg(feature = "std")]
pub type CollatorPair = collator_app::Pair;
/// Signature on candidate's block data by a collator.
pub type CollatorSignature = collator_app::Signature;
/// The key type ID for a parachain validator key.
pub const PARACHAIN_KEY_TYPE_ID: KeyTypeId = KeyTypeId(*b"para");
mod validator_app {
use application_crypto::{app_crypto, sr25519};
app_crypto!(sr25519, super::PARACHAIN_KEY_TYPE_ID);
}
/// Identity that parachain validators use when signing validation messages.
///
/// For now we assert that parachain validator set is exactly equivalent to the authority set, and
/// so we define it to be the same type as `SessionKey`. In the future it may have different crypto.
pub type ValidatorId = validator_app::Public;
/// Trait required for type specific indices e.g. `ValidatorIndex` and `GroupIndex`
pub trait TypeIndex {
/// Returns the index associated to this value.
fn type_index(&self) -> usize;
}
/// Index of the validator is used as a lightweight replacement of the `ValidatorId` when
/// appropriate.
#[derive(Eq, Ord, PartialEq, PartialOrd, Copy, Clone, Encode, Decode, TypeInfo, RuntimeDebug)]
#[cfg_attr(feature = "std", derive(Serialize, Deserialize, Hash))]
pub struct ValidatorIndex(pub u32);
// We should really get https://github.com/paritytech/polkadot/issues/2403 going ..
impl From<u32> for ValidatorIndex {
fn from(n: u32) -> Self {
ValidatorIndex(n)
}
}
impl TypeIndex for ValidatorIndex {
fn type_index(&self) -> usize {
self.0 as usize
}
}
application_crypto::with_pair! {
/// A Parachain validator keypair.
pub type ValidatorPair = validator_app::Pair;
}
/// Signature with which parachain validators sign blocks.
///
/// For now we assert that parachain validator set is exactly equivalent to the authority set, and
/// so we define it to be the same type as `SessionKey`. In the future it may have different crypto.
pub type ValidatorSignature = validator_app::Signature;
/// A declarations of storage keys where an external observer can find some interesting data.
pub mod well_known_keys {
use super::{HrmpChannelId, Id, WellKnownKey};
use hex_literal::hex;
use parity_scale_codec::Encode as _;
use sp_io::hashing::twox_64;
use sp_std::prelude::*;
// A note on generating these magic values below:
//
// The `StorageValue`, such as `ACTIVE_CONFIG` was obtained by calling:
//
// ActiveConfig::<T>::hashed_key()
//
// The `StorageMap` values require `prefix`, and for example for `hrmp_egress_channel_index`,
// it could be obtained like:
//
// HrmpEgressChannelsIndex::<T>::prefix_hash();
//
/// The current epoch index.
///
/// The storage item should be access as a `u64` encoded value.
pub const EPOCH_INDEX: &[u8] =
&hex!["1cb6f36e027abb2091cfb5110ab5087f38316cbf8fa0da822a20ac1c55bf1be3"];
/// The current relay chain block randomness
///
/// The storage item should be accessed as a `schnorrkel::Randomness` encoded value.
pub const CURRENT_BLOCK_RANDOMNESS: &[u8] =
&hex!["1cb6f36e027abb2091cfb5110ab5087fd077dfdb8adb10f78f10a5df8742c545"];
/// The randomness for one epoch ago
///
/// The storage item should be accessed as a `schnorrkel::Randomness` encoded value.
pub const ONE_EPOCH_AGO_RANDOMNESS: &[u8] =
&hex!["1cb6f36e027abb2091cfb5110ab5087f7ce678799d3eff024253b90e84927cc6"];
/// The randomness for two epochs ago
///
/// The storage item should be accessed as a `schnorrkel::Randomness` encoded value.
pub const TWO_EPOCHS_AGO_RANDOMNESS: &[u8] =
&hex!["1cb6f36e027abb2091cfb5110ab5087f7a414cb008e0e61e46722aa60abdd672"];
/// The current slot number.
///
/// The storage entry should be accessed as a `Slot` encoded value.
pub const CURRENT_SLOT: &[u8] =
&hex!["1cb6f36e027abb2091cfb5110ab5087f06155b3cd9a8c9e5e9a23fd5dc13a5ed"];
/// The currently active host configuration.
///
/// The storage entry should be accessed as an `AbridgedHostConfiguration` encoded value.
pub const ACTIVE_CONFIG: &[u8] =
&hex!["06de3d8a54d27e44a9d5ce189618f22db4b49d95320d9021994c850f25b8e385"];
/// Hash of the committed head data for a given registered para.
///
/// The storage entry stores wrapped `HeadData(Vec<u8>)`.
pub fn para_head(para_id: Id) -> Vec<u8> {
let prefix = hex!["cd710b30bd2eab0352ddcc26417aa1941b3c252fcb29d88eff4f3de5de4476c3"];
para_id.using_encoded(|para_id: &[u8]| {
prefix
.as_ref()
.iter()
.chain(twox_64(para_id).iter())
.chain(para_id.iter())
.cloned()
.collect()
})
}
/// The upward message dispatch queue for the given para id.
///
/// The storage entry stores a tuple of two values:
///
/// - `count: u32`, the number of messages currently in the queue for given para,
/// - `total_size: u32`, the total size of all messages in the queue.
#[deprecated = "Use `relay_dispatch_queue_remaining_capacity` instead"]
pub fn relay_dispatch_queue_size(para_id: Id) -> Vec<u8> {
let prefix = hex!["f5207f03cfdce586301014700e2c2593fad157e461d71fd4c1f936839a5f1f3e"];
para_id.using_encoded(|para_id: &[u8]| {
prefix
.as_ref()
.iter()
.chain(twox_64(para_id).iter())
.chain(para_id.iter())
.cloned()
.collect()
})
}
/// Type safe version of `relay_dispatch_queue_size`.
#[deprecated = "Use `relay_dispatch_queue_remaining_capacity` instead"]
pub fn relay_dispatch_queue_size_typed(para: Id) -> WellKnownKey<(u32, u32)> {
#[allow(deprecated)]
relay_dispatch_queue_size(para).into()
}
/// The upward message dispatch queue remaining capacity for the given para id.
///
/// The storage entry stores a tuple of two values:
///
/// - `count: u32`, the number of additional messages which may be enqueued for the given para,
/// - `total_size: u32`, the total size of additional messages which may be enqueued for the
/// given para.
pub fn relay_dispatch_queue_remaining_capacity(para_id: Id) -> WellKnownKey<(u32, u32)> {
(b":relay_dispatch_queue_remaining_capacity", para_id).encode().into()
}
/// The HRMP channel for the given identifier.
///
/// The storage entry should be accessed as an `AbridgedHrmpChannel` encoded value.
pub fn hrmp_channels(channel: HrmpChannelId) -> Vec<u8> {
let prefix = hex!["6a0da05ca59913bc38a8630590f2627cb6604cff828a6e3f579ca6c59ace013d"];
channel.using_encoded(|channel: &[u8]| {
prefix
.as_ref()
.iter()
.chain(twox_64(channel).iter())
.chain(channel.iter())
.cloned()
.collect()
})
}
/// The list of inbound channels for the given para.
///
/// The storage entry stores a `Vec<ParaId>`
pub fn hrmp_ingress_channel_index(para_id: Id) -> Vec<u8> {
let prefix = hex!["6a0da05ca59913bc38a8630590f2627c1d3719f5b0b12c7105c073c507445948"];
para_id.using_encoded(|para_id: &[u8]| {
prefix
.as_ref()
.iter()
.chain(twox_64(para_id).iter())
.chain(para_id.iter())
.cloned()
.collect()
})
}
/// The list of outbound channels for the given para.
///
/// The storage entry stores a `Vec<ParaId>`
pub fn hrmp_egress_channel_index(para_id: Id) -> Vec<u8> {
let prefix = hex!["6a0da05ca59913bc38a8630590f2627cf12b746dcf32e843354583c9702cc020"];
para_id.using_encoded(|para_id: &[u8]| {
prefix
.as_ref()
.iter()
.chain(twox_64(para_id).iter())
.chain(para_id.iter())
.cloned()
.collect()
})
}
/// The MQC head for the downward message queue of the given para. See more in the `Dmp` module.
///
/// The storage entry stores a `Hash`. This is polkadot hash which is at the moment
/// `blake2b-256`.
pub fn dmq_mqc_head(para_id: Id) -> Vec<u8> {
let prefix = hex!["63f78c98723ddc9073523ef3beefda0c4d7fefc408aac59dbfe80a72ac8e3ce5"];
para_id.using_encoded(|para_id: &[u8]| {
prefix
.as_ref()
.iter()
.chain(twox_64(para_id).iter())
.chain(para_id.iter())
.cloned()
.collect()
})
}
/// The signal that indicates whether the parachain should go-ahead with the proposed validation
/// code upgrade.
///
/// The storage entry stores a value of `UpgradeGoAhead` type.
pub fn upgrade_go_ahead_signal(para_id: Id) -> Vec<u8> {
let prefix = hex!["cd710b30bd2eab0352ddcc26417aa1949e94c040f5e73d9b7addd6cb603d15d3"];
para_id.using_encoded(|para_id: &[u8]| {
prefix
.as_ref()
.iter()
.chain(twox_64(para_id).iter())
.chain(para_id.iter())
.cloned()
.collect()
})
}
/// The signal that indicates whether the parachain is disallowed to signal an upgrade at this
/// relay-parent.
///
/// The storage entry stores a value of `UpgradeRestriction` type.
pub fn upgrade_restriction_signal(para_id: Id) -> Vec<u8> {
let prefix = hex!["cd710b30bd2eab0352ddcc26417aa194f27bbb460270642b5bcaf032ea04d56a"];
para_id.using_encoded(|para_id: &[u8]| {
prefix
.as_ref()
.iter()
.chain(twox_64(para_id).iter())
.chain(para_id.iter())
.cloned()
.collect()
})
}
}
/// Unique identifier for the Parachains Inherent
pub const PARACHAINS_INHERENT_IDENTIFIER: InherentIdentifier = *b"parachn0";
/// The key type ID for parachain assignment key.
pub const ASSIGNMENT_KEY_TYPE_ID: KeyTypeId = KeyTypeId(*b"asgn");
/// Maximum compressed code size we support right now.
/// At the moment we have runtime upgrade on chain, which restricts scalability severely. If we want
/// to have bigger values, we should fix that first.
///
/// Used for:
/// * initial genesis for the Parachains configuration
/// * checking updates to this stored runtime configuration do not exceed this limit
/// * when detecting a code decompression bomb in the client
// NOTE: This value is used in the runtime so be careful when changing it.
pub const MAX_CODE_SIZE: u32 = 3 * 1024 * 1024;
/// Maximum head data size we support right now.
///
/// Used for:
/// * initial genesis for the Parachains configuration
/// * checking updates to this stored runtime configuration do not exceed this limit
// NOTE: This value is used in the runtime so be careful when changing it.
pub const MAX_HEAD_DATA_SIZE: u32 = 1 * 1024 * 1024;
/// Maximum PoV size we support right now.
///
/// Used for:
/// * initial genesis for the Parachains configuration
/// * checking updates to this stored runtime configuration do not exceed this limit
/// * when detecting a PoV decompression bomb in the client
// NOTE: This value is used in the runtime so be careful when changing it.
pub const MAX_POV_SIZE: u32 = 5 * 1024 * 1024;
/// Default queue size we use for the on-demand order book.
///
/// Can be adjusted in configuration.
pub const ON_DEMAND_DEFAULT_QUEUE_MAX_SIZE: u32 = 10_000;
/// Maximum for maximum queue size.
///
/// Setting `on_demand_queue_max_size` to a value higher than this is unsound. This is more a
/// theoretical limit, just below enough what the target type supports, so comparisons are possible
/// even with indices that are overflowing the underyling type.
pub const ON_DEMAND_MAX_QUEUE_MAX_SIZE: u32 = 1_000_000_000;
/// Backing votes threshold used from the host prior to runtime API version 6 and from the runtime
/// prior to v9 configuration migration.
pub const LEGACY_MIN_BACKING_VOTES: u32 = 2;
// The public key of a keypair used by a validator for determining assignments
/// to approve included parachain candidates.
mod assignment_app {
use application_crypto::{app_crypto, sr25519};
app_crypto!(sr25519, super::ASSIGNMENT_KEY_TYPE_ID);
}
/// The public key of a keypair used by a validator for determining assignments
/// to approve included parachain candidates.
pub type AssignmentId = assignment_app::Public;
application_crypto::with_pair! {
/// The full keypair used by a validator for determining assignments to approve included
/// parachain candidates.
pub type AssignmentPair = assignment_app::Pair;
}
/// The index of the candidate in the list of candidates fully included as-of the block.
pub type CandidateIndex = u32;
/// Get a collator signature payload on a relay-parent, block-data combo.
pub fn collator_signature_payload<H: AsRef<[u8]>>(
relay_parent: &H,
para_id: &Id,
persisted_validation_data_hash: &Hash,
pov_hash: &Hash,
validation_code_hash: &ValidationCodeHash,
) -> [u8; 132] {
// 32-byte hash length is protected in a test below.
let mut payload = [0u8; 132];
payload[0..32].copy_from_slice(relay_parent.as_ref());
u32::from(*para_id).using_encoded(|s| payload[32..32 + s.len()].copy_from_slice(s));
payload[36..68].copy_from_slice(persisted_validation_data_hash.as_ref());
payload[68..100].copy_from_slice(pov_hash.as_ref());
payload[100..132].copy_from_slice(validation_code_hash.as_ref());
payload
}
fn check_collator_signature<H: AsRef<[u8]>>(
relay_parent: &H,
para_id: &Id,
persisted_validation_data_hash: &Hash,
pov_hash: &Hash,
validation_code_hash: &ValidationCodeHash,
collator: &CollatorId,
signature: &CollatorSignature,
) -> Result<(), ()> {
let payload = collator_signature_payload(
relay_parent,
para_id,
persisted_validation_data_hash,
pov_hash,
validation_code_hash,
);
if signature.verify(&payload[..], collator) {
Ok(())
} else {
Err(())
}
}
/// A unique descriptor of the candidate receipt.
#[derive(PartialEq, Eq, Clone, Encode, Decode, TypeInfo, RuntimeDebug)]
#[cfg_attr(feature = "std", derive(Hash))]
pub struct CandidateDescriptor<H = Hash> {
/// The ID of the para this is a candidate for.
pub para_id: Id,
/// The hash of the relay-chain block this is executed in the context of.
pub relay_parent: H,
/// The collator's sr25519 public key.
pub collator: CollatorId,
/// The blake2-256 hash of the persisted validation data. This is extra data derived from
/// relay-chain state which may vary based on bitfields included before the candidate.
/// Thus it cannot be derived entirely from the relay-parent.
pub persisted_validation_data_hash: Hash,
/// The blake2-256 hash of the PoV.
pub pov_hash: Hash,
/// The root of a block's erasure encoding Merkle tree.
pub erasure_root: Hash,
/// Signature on blake2-256 of components of this receipt:
/// The parachain index, the relay parent, the validation data hash, and the `pov_hash`.
pub signature: CollatorSignature,
/// Hash of the para header that is being generated by this candidate.
pub para_head: Hash,
/// The blake2-256 hash of the validation code bytes.
pub validation_code_hash: ValidationCodeHash,
}
impl<H: AsRef<[u8]>> CandidateDescriptor<H> {
/// Check the signature of the collator within this descriptor.
pub fn check_collator_signature(&self) -> Result<(), ()> {
check_collator_signature(
&self.relay_parent,
&self.para_id,
&self.persisted_validation_data_hash,
&self.pov_hash,
&self.validation_code_hash,
&self.collator,
&self.signature,
)
}
}
/// A candidate-receipt.
#[derive(PartialEq, Eq, Clone, Encode, Decode, TypeInfo, RuntimeDebug)]
pub struct CandidateReceipt<H = Hash> {
/// The descriptor of the candidate.
pub descriptor: CandidateDescriptor<H>,
/// The hash of the encoded commitments made as a result of candidate execution.
pub commitments_hash: Hash,
}
impl<H> CandidateReceipt<H> {
/// Get a reference to the candidate descriptor.
pub fn descriptor(&self) -> &CandidateDescriptor<H> {
&self.descriptor
}
/// Computes the blake2-256 hash of the receipt.
pub fn hash(&self) -> CandidateHash
where
H: Encode,
{
CandidateHash(BlakeTwo256::hash_of(self))
}
}
/// All data pertaining to the execution of a para candidate.
#[derive(PartialEq, Eq, Clone, Encode, Decode, TypeInfo, RuntimeDebug)]
pub struct FullCandidateReceipt<H = Hash, N = BlockNumber> {
/// The inner candidate receipt.
pub inner: CandidateReceipt<H>,
/// The validation data derived from the relay-chain state at that
/// point. The hash of the persisted validation data should
/// match the `persisted_validation_data_hash` in the descriptor
/// of the receipt.
pub validation_data: PersistedValidationData<H, N>,
}
/// A candidate-receipt with commitments directly included.
#[derive(PartialEq, Eq, Clone, Encode, Decode, TypeInfo, RuntimeDebug)]
#[cfg_attr(feature = "std", derive(Hash))]
pub struct CommittedCandidateReceipt<H = Hash> {
/// The descriptor of the candidate.
pub descriptor: CandidateDescriptor<H>,
/// The commitments of the candidate receipt.
pub commitments: CandidateCommitments,
}
impl<H> CommittedCandidateReceipt<H> {
/// Get a reference to the candidate descriptor.
pub fn descriptor(&self) -> &CandidateDescriptor<H> {
&self.descriptor
}
}
impl<H: Clone> CommittedCandidateReceipt<H> {
/// Transforms this into a plain `CandidateReceipt`.
pub fn to_plain(&self) -> CandidateReceipt<H> {
CandidateReceipt {
descriptor: self.descriptor.clone(),
commitments_hash: self.commitments.hash(),
}
}
/// Computes the hash of the committed candidate receipt.
///
/// This computes the canonical hash, not the hash of the directly encoded data.
/// Thus this is a shortcut for `candidate.to_plain().hash()`.
pub fn hash(&self) -> CandidateHash
where
H: Encode,
{
self.to_plain().hash()
}
/// Does this committed candidate receipt corresponds to the given [`CandidateReceipt`]?
pub fn corresponds_to(&self, receipt: &CandidateReceipt<H>) -> bool
where
H: PartialEq,
{
receipt.descriptor == self.descriptor && receipt.commitments_hash == self.commitments.hash()
}
}
impl PartialOrd for CommittedCandidateReceipt {
fn partial_cmp(&self, other: &Self) -> Option<sp_std::cmp::Ordering> {
Some(self.cmp(other))
}
}
impl Ord for CommittedCandidateReceipt {
fn cmp(&self, other: &Self) -> sp_std::cmp::Ordering {
// TODO: compare signatures or something more sane
// https://github.com/paritytech/polkadot/issues/222
self.descriptor()
.para_id
.cmp(&other.descriptor().para_id)
.then_with(|| self.commitments.head_data.cmp(&other.commitments.head_data))
}
}
/// The validation data provides information about how to create the inputs for validation of a
/// candidate. This information is derived from the chain state and will vary from para to para,
/// although some fields may be the same for every para.
///
/// Since this data is used to form inputs to the validation function, it needs to be persisted by
/// the availability system to avoid dependence on availability of the relay-chain state.
///
/// Furthermore, the validation data acts as a way to authorize the additional data the collator
/// needs to pass to the validation function. For example, the validation function can check whether
/// the incoming messages (e.g. downward messages) were actually sent by using the data provided in
/// the validation data using so called MQC heads.
///
/// Since the commitments of the validation function are checked by the relay-chain, secondary
/// checkers can rely on the invariant that the relay-chain only includes para-blocks for which
/// these checks have already been done. As such, there is no need for the validation data used to
/// inform validators and collators about the checks the relay-chain will perform to be persisted by
/// the availability system.
///
/// The `PersistedValidationData` should be relatively lightweight primarily because it is
/// constructed during inclusion for each candidate and therefore lies on the critical path of
/// inclusion.
#[derive(PartialEq, Eq, Clone, Encode, Decode, TypeInfo, RuntimeDebug)]
#[cfg_attr(feature = "std", derive(Default))]
pub struct PersistedValidationData<H = Hash, N = BlockNumber> {
/// The parent head-data.
pub parent_head: HeadData,
/// The relay-chain block number this is in the context of.
pub relay_parent_number: N,
/// The relay-chain block storage root this is in the context of.
pub relay_parent_storage_root: H,
/// The maximum legal size of a POV block, in bytes.
pub max_pov_size: u32,
}
impl<H: Encode, N: Encode> PersistedValidationData<H, N> {
/// Compute the blake2-256 hash of the persisted validation data.
pub fn hash(&self) -> Hash {
BlakeTwo256::hash_of(self)
}
}
/// Commitments made in a `CandidateReceipt`. Many of these are outputs of validation.
#[derive(PartialEq, Eq, Clone, Encode, Decode, TypeInfo, RuntimeDebug)]
#[cfg_attr(feature = "std", derive(Default, Hash))]
pub struct CandidateCommitments<N = BlockNumber> {
/// Messages destined to be interpreted by the Relay chain itself.
pub upward_messages: UpwardMessages,
/// Horizontal messages sent by the parachain.
pub horizontal_messages: HorizontalMessages,
/// New validation code.
pub new_validation_code: Option<ValidationCode>,
/// The head-data produced as a result of execution.
pub head_data: HeadData,
/// The number of messages processed from the DMQ.
pub processed_downward_messages: u32,
/// The mark which specifies the block number up to which all inbound HRMP messages are
/// processed.
pub hrmp_watermark: N,
}
impl CandidateCommitments {
/// Compute the blake2-256 hash of the commitments.
pub fn hash(&self) -> Hash {
BlakeTwo256::hash_of(self)
}
}
/// A bitfield concerning availability of backed candidates.
///
/// Every bit refers to an availability core index.
#[derive(PartialEq, Eq, Clone, Encode, Decode, RuntimeDebug, TypeInfo)]
pub struct AvailabilityBitfield(pub BitVec<u8, bitvec::order::Lsb0>);
impl From<BitVec<u8, bitvec::order::Lsb0>> for AvailabilityBitfield {
fn from(inner: BitVec<u8, bitvec::order::Lsb0>) -> Self {
AvailabilityBitfield(inner)
}
}
/// A signed compact statement, suitable to be sent to the chain.
pub type SignedStatement = Signed<CompactStatement>;
/// A signed compact statement, with signature not yet checked.
pub type UncheckedSignedStatement = UncheckedSigned<CompactStatement>;
/// A bitfield signed by a particular validator about the availability of pending candidates.
pub type SignedAvailabilityBitfield = Signed<AvailabilityBitfield>;
/// A signed bitfield with signature not yet checked.
pub type UncheckedSignedAvailabilityBitfield = UncheckedSigned<AvailabilityBitfield>;
/// A set of signed availability bitfields. Should be sorted by validator index, ascending.
pub type SignedAvailabilityBitfields = Vec<SignedAvailabilityBitfield>;
/// A set of unchecked signed availability bitfields. Should be sorted by validator index,
/// ascending.
pub type UncheckedSignedAvailabilityBitfields = Vec<UncheckedSignedAvailabilityBitfield>;
/// A backed (or backable, depending on context) candidate.
#[derive(Encode, Decode, Clone, PartialEq, Eq, RuntimeDebug, TypeInfo)]
pub struct BackedCandidate<H = Hash> {
/// The candidate referred to.
pub candidate: CommittedCandidateReceipt<H>,
/// The validity votes themselves, expressed as signatures.
pub validity_votes: Vec<ValidityAttestation>,
/// The indices of the validators within the group, expressed as a bitfield.
pub validator_indices: BitVec<u8, bitvec::order::Lsb0>,
}
impl<H> BackedCandidate<H> {
/// Get a reference to the descriptor of the para.
pub fn descriptor(&self) -> &CandidateDescriptor<H> {
&self.candidate.descriptor
}
/// Compute this candidate's hash.
pub fn hash(&self) -> CandidateHash
where
H: Clone + Encode,
{
self.candidate.hash()
}
/// Get this candidate's receipt.
pub fn receipt(&self) -> CandidateReceipt<H>
where
H: Clone,
{
self.candidate.to_plain()
}
}
/// Verify the backing of the given candidate.
///
/// Provide a lookup from the index of a validator within the group assigned to this para,
/// as opposed to the index of the validator within the overall validator set, as well as
/// the number of validators in the group.
///
/// Also provide the signing context.
///
/// Returns either an error, indicating that one of the signatures was invalid or that the index
/// was out-of-bounds, or the number of signatures checked.
pub fn check_candidate_backing<H: AsRef<[u8]> + Clone + Encode>(
backed: &BackedCandidate<H>,
signing_context: &SigningContext<H>,
group_len: usize,
validator_lookup: impl Fn(usize) -> Option<ValidatorId>,
) -> Result<usize, ()> {
if backed.validator_indices.len() != group_len {
return Err(())
}
if backed.validity_votes.len() > group_len {
return Err(())
}
// this is known, even in runtime, to be blake2-256.
let hash = backed.candidate.hash();
let mut signed = 0;
for ((val_in_group_idx, _), attestation) in backed
.validator_indices
.iter()
.enumerate()
.filter(|(_, signed)| **signed)
.zip(backed.validity_votes.iter())
{
let validator_id = validator_lookup(val_in_group_idx).ok_or(())?;
let payload = attestation.signed_payload(hash, signing_context);
let sig = attestation.signature();
if sig.verify(&payload[..], &validator_id) {
signed += 1;
} else {
return Err(())
}
}
if signed != backed.validity_votes.len() {
return Err(())
}
Ok(signed)
}
/// The unique (during session) index of a core.
#[derive(
Encode, Decode, Default, PartialOrd, Ord, Eq, PartialEq, Clone, Copy, TypeInfo, RuntimeDebug,
)]
#[cfg_attr(feature = "std", derive(Hash))]
pub struct CoreIndex(pub u32);
impl From<u32> for CoreIndex {
fn from(i: u32) -> CoreIndex {
CoreIndex(i)
}
}
impl TypeIndex for CoreIndex {
fn type_index(&self) -> usize {
self.0 as usize
}
}
/// The unique (during session) index of a validator group.
#[derive(Encode, Decode, Default, Clone, Copy, Debug, PartialEq, Eq, TypeInfo, PartialOrd, Ord)]
#[cfg_attr(feature = "std", derive(Hash))]
pub struct GroupIndex(pub u32);
impl From<u32> for GroupIndex {
fn from(i: u32) -> GroupIndex {
GroupIndex(i)
}
}
impl TypeIndex for GroupIndex {
fn type_index(&self) -> usize {
self.0 as usize
}
}
/// A claim on authoring the next block for a given parathread (on-demand parachain).
#[derive(Clone, Encode, Decode, TypeInfo, PartialEq, RuntimeDebug)]
pub struct ParathreadClaim(pub Id, pub Option<CollatorId>);
/// An entry tracking a claim to ensure it does not pass the maximum number of retries.
#[derive(Clone, Encode, Decode, TypeInfo, PartialEq, RuntimeDebug)]
pub struct ParathreadEntry {
/// The claim.
pub claim: ParathreadClaim,
/// Number of retries
pub retries: u32,
}
/// A helper data-type for tracking validator-group rotations.
#[derive(Clone, Encode, Decode, TypeInfo, RuntimeDebug)]
#[cfg_attr(feature = "std", derive(PartialEq))]
pub struct GroupRotationInfo<N = BlockNumber> {
/// The block number where the session started.
pub session_start_block: N,
/// How often groups rotate. 0 means never.
pub group_rotation_frequency: N,
/// The current block number.
pub now: N,
}
impl GroupRotationInfo {
/// Returns the index of the group needed to validate the core at the given index, assuming
/// the given number of cores.
///
/// `core_index` should be less than `cores`, which is capped at `u32::max()`.
pub fn group_for_core(&self, core_index: CoreIndex, cores: usize) -> GroupIndex {
if self.group_rotation_frequency == 0 {
return GroupIndex(core_index.0)
}
if cores == 0 {
return GroupIndex(0)
}
let cores = sp_std::cmp::min(cores, u32::MAX as usize);
let blocks_since_start = self.now.saturating_sub(self.session_start_block);
let rotations = blocks_since_start / self.group_rotation_frequency;
// g = c + r mod cores
let idx = (core_index.0 as usize + rotations as usize) % cores;
GroupIndex(idx as u32)
}
/// Returns the index of the group assigned to the given core. This does no checking or
/// whether the group index is in-bounds.
///
/// `core_index` should be less than `cores`, which is capped at `u32::max()`.
pub fn core_for_group(&self, group_index: GroupIndex, cores: usize) -> CoreIndex {
if self.group_rotation_frequency == 0 {
return CoreIndex(group_index.0)
}
if cores == 0 {
return CoreIndex(0)
}
let cores = sp_std::cmp::min(cores, u32::MAX as usize);
let blocks_since_start = self.now.saturating_sub(self.session_start_block);
let rotations = blocks_since_start / self.group_rotation_frequency;
let rotations = rotations % cores as u32;
// g = c + r mod cores
// c = g - r mod cores
// x = x + cores mod cores
// c = (g + cores) - r mod cores
let idx = (group_index.0 as usize + cores - rotations as usize) % cores;
CoreIndex(idx as u32)
}
/// Create a new `GroupRotationInfo` with one further rotation applied.
pub fn bump_rotation(&self) -> Self {
GroupRotationInfo {
session_start_block: self.session_start_block,
group_rotation_frequency: self.group_rotation_frequency,
now: self.next_rotation_at(),
}
}
}
impl<N: Saturating + BaseArithmetic + Copy> GroupRotationInfo<N> {
/// Returns the block number of the next rotation after the current block. If the current block
/// is 10 and the rotation frequency is 5, this should return 15.
pub fn next_rotation_at(&self) -> N {
let cycle_once = self.now + self.group_rotation_frequency;
cycle_once -
(cycle_once.saturating_sub(self.session_start_block) % self.group_rotation_frequency)
}
/// Returns the block number of the last rotation before or including the current block. If the
/// current block is 10 and the rotation frequency is 5, this should return 10.
pub fn last_rotation_at(&self) -> N {
self.now -
(self.now.saturating_sub(self.session_start_block) % self.group_rotation_frequency)
}
}
/// Information about a core which is currently occupied.
#[derive(Clone, Encode, Decode, TypeInfo, RuntimeDebug)]
#[cfg_attr(feature = "std", derive(PartialEq))]
pub struct OccupiedCore<H = Hash, N = BlockNumber> {
// NOTE: this has no ParaId as it can be deduced from the candidate descriptor.
/// If this core is freed by availability, this is the assignment that is next up on this
/// core, if any. None if there is nothing queued for this core.
pub next_up_on_available: Option<ScheduledCore>,
/// The relay-chain block number this began occupying the core at.
pub occupied_since: N,
/// The relay-chain block this will time-out at, if any.
pub time_out_at: N,
/// If this core is freed by being timed-out, this is the assignment that is next up on this
/// core. None if there is nothing queued for this core or there is no possibility of timing
/// out.
pub next_up_on_time_out: Option<ScheduledCore>,
/// A bitfield with 1 bit for each validator in the set. `1` bits mean that the corresponding
/// validators has attested to availability on-chain. A 2/3+ majority of `1` bits means that
/// this will be available.
pub availability: BitVec<u8, bitvec::order::Lsb0>,
/// The group assigned to distribute availability pieces of this candidate.
pub group_responsible: GroupIndex,
/// The hash of the candidate occupying the core.
pub candidate_hash: CandidateHash,
/// The descriptor of the candidate occupying the core.
pub candidate_descriptor: CandidateDescriptor<H>,
}
impl<H, N> OccupiedCore<H, N> {
/// Get the Para currently occupying this core.
pub fn para_id(&self) -> Id {
self.candidate_descriptor.para_id
}
}
/// Information about a core which is currently occupied.
#[derive(Clone, Encode, Decode, TypeInfo, RuntimeDebug)]
#[cfg_attr(feature = "std", derive(PartialEq))]
pub struct ScheduledCore {
/// The ID of a para scheduled.
pub para_id: Id,
/// DEPRECATED: see: <https://github.com/paritytech/polkadot/issues/7575>
///
/// Will be removed in a future version.
pub collator: Option<CollatorId>,
}
/// The state of a particular availability core.
#[derive(Clone, Encode, Decode, TypeInfo, RuntimeDebug)]
#[cfg_attr(feature = "std", derive(PartialEq))]
pub enum CoreState<H = Hash, N = BlockNumber> {
/// The core is currently occupied.
#[codec(index = 0)]
Occupied(OccupiedCore<H, N>),
/// The core is currently free, with a para scheduled and given the opportunity
/// to occupy.
///
/// If a particular Collator is required to author this block, that is also present in this
/// variant.
#[codec(index = 1)]
Scheduled(ScheduledCore),
/// The core is currently free and there is nothing scheduled. This can be the case for
/// parathread cores when there are no parathread blocks queued. Parachain cores will never be
/// left idle.
#[codec(index = 2)]
Free,
}