pezkuwichain/pezkuwi-subxt
1
0
Fork 0
mirror of https://github.com/pezkuwichain/pezkuwi-subxt.git synced 2026-05-30 19:51:02 +00:00
Code Issues Packages Projects Releases Wiki Activity
Files
6d83525b5057a062d185d963ebbe464de2b844da
pezkuwi-subxt/polkadot/runtime/parachains/src/paras/mod.rs
T
alexgparity 6d83525b50 Replace parachain/parathread boolean by enum (#6198) 
* Replace parachain/parathread boolean by enum

* Address PR comments

* Update dependencies

* ParaType -> ParaKind

* Swap enum field order to avoid migration

* Rename paratype field to parakind

* Manual en-/decocing of Parakind

* Manual TypeInfo for ParaKind

* rename field back to parachain

* minor

* Update runtime/parachains/src/paras/mod.rs

Co-authored-by: Andrei Sandu <54316454+sandreim@users.noreply.github.com>

* Manual serde Serialize and Deserialize for ParaKind

* cargo fmt

* Update runtime/parachains/src/paras/mod.rs

Co-authored-by: Andronik <write@reusable.software>

* Add test for serde_json encoding/decoding

* Move serde_json dep to dev-deps

Co-authored-by: Andrei Sandu <54316454+sandreim@users.noreply.github.com>
Co-authored-by: Andronik <write@reusable.software>
2022-11-01 18:34:16 +01:00

2157 lines
80 KiB
Rust
Raw Blame History

// Copyright 2020 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/>.
//! The paras pallet acts as the main registry of paras.
//!
//! # Tracking State of Paras
//!
//! The most important responsibility of this module is to track which parachains and parathreads
//! are active and what their current state is. The current state of a para consists of the current
//! head data and the current validation code (AKA Parachain Validation Function (PVF)).
//!
//! A para is not considered live until it is registered and activated in this pallet.
//!
//! The set of parachains and parathreads cannot change except at session boundaries. This is
//! primarily to ensure that the number and meaning of bits required for the availability bitfields
//! does not change except at session boundaries.
//!
//! # Validation Code Upgrades
//!
//! When a para signals the validation code upgrade it will be processed by this module. This can
//! be in turn split into more fine grained items:
//!
//! - Part of the acceptance criteria checks if the para can indeed signal an upgrade,
//!
//! - When the candidate is enacted, this module schedules code upgrade, storing the prospective
//! validation code.
//!
//! - Actually assign the prospective validation code to be the current one after all conditions are
//! fulfilled.
//!
//! The conditions that must be met before the para can use the new validation code are:
//!
//! 1. The validation code should have been "soaked" in the storage for a given number of blocks. That
//! is, the validation code should have been stored in on-chain storage for some time, so that in
//! case of a revert with a non-extreme height difference, that validation code can still be
//! found on-chain.
//!
//! 2. The validation code was vetted by the validators and declared as non-malicious in a processes
//! known as PVF pre-checking.
//!
//! # Validation Code Management
//!
//! Potentially, one validation code can be used by several different paras. For example, during
//! initial stages of deployment several paras can use the same "shell" validation code, or
//! there can be shards of the same para that use the same validation code.
//!
//! In case a validation code ceases to have any users it must be pruned from the on-chain storage.
//!
//! # Para Lifecycle Management
//!
//! A para can be in one of the two stable states: it is either a parachain or a parathread.
//!
//! However, in order to get into one of those two states, it must first be onboarded. Onboarding
//! can be only enacted at session boundaries. Onboarding must take at least one full session.
//! Moreover, a brand new validation code should go through the PVF pre-checking process.
//!
//! Once the para is in one of the two stable states, it can switch to the other stable state or to
//! initiate offboarding process. The result of offboarding is removal of all data related to that
//! para.
//!
//! # PVF Pre-checking
//!
//! As was mentioned above, a brand new validation code should go through a process of approval.
//! As part of this process, validators from the active set will take the validation code and
//! check if it is malicious. Once they did that and have their judgement, either accept or reject,
//! they issue a statement in a form of an unsigned extrinsic. This extrinsic is processed by this
//! pallet. Once supermajority is gained for accept, then the process that initiated the check
//! is resumed (as mentioned before this can be either upgrading of validation code or onboarding).
//! If supermajority is gained for reject, then the process is canceled.
//!
//! Below is a state diagram that depicts states of a single PVF pre-checking vote.
//!
//! ```text
//! ┌──────────┐
//! supermajority │ │
//! ┌────────for───────────▶│ accepted │
//! vote────┐ │ │ │
//! │ │ │ └──────────┘
//! │ │ │
//! │ ┌───────┐
//! │ │ │
//! └─▶│ init │────supermajority ┌──────────┐
//! │ │ against │ │
//! └───────┘ └──────────▶│ rejected │
//! ▲ │ │ │
//! │ │ session └──────────┘
//! │ └──change
//! │ │
//! │ ▼
//! ┌─────┐
//! start──────▶│reset│
//! └─────┘
//! ```
//!
use crate::{configuration, initializer::SessionChangeNotification, shared};
use bitvec::{order::Lsb0 as BitOrderLsb0, vec::BitVec};
use frame_support::{pallet_prelude::*, traits::EstimateNextSessionRotation};
use frame_system::pallet_prelude::*;
use parity_scale_codec::{Decode, Encode};
use primitives::v2::{
ConsensusLog, HeadData, Id as ParaId, PvfCheckStatement, SessionIndex, UpgradeGoAhead,
UpgradeRestriction, ValidationCode, ValidationCodeHash, ValidatorSignature,
};
use scale_info::{Type, TypeInfo};
use sp_core::RuntimeDebug;
use sp_runtime::{
traits::{AppVerify, One, Saturating},
DispatchResult, SaturatedConversion,
};
use sp_std::{cmp, mem, prelude::*};
#[cfg(feature = "std")]
use serde::{Deserialize, Serialize};
pub use crate::Origin as ParachainOrigin;
#[cfg(feature = "runtime-benchmarks")]
pub(crate) mod benchmarking;
#[cfg(test)]
pub(crate) mod tests;
pub use pallet::*;
const LOG_TARGET: &str = "runtime::paras";
// the two key times necessary to track for every code replacement.
#[derive(Default, Encode, Decode, TypeInfo)]
#[cfg_attr(test, derive(Debug, Clone, PartialEq))]
pub struct ReplacementTimes<N> {
/// The relay-chain block number that the code upgrade was expected to be activated.
/// This is when the code change occurs from the para's perspective - after the
/// first parablock included with a relay-parent with number >= this value.
expected_at: N,
/// The relay-chain block number at which the parablock activating the code upgrade was
/// actually included. This means considered included and available, so this is the time at which
/// that parablock enters the acceptance period in this fork of the relay-chain.
activated_at: N,
}
/// Metadata used to track previous parachain validation code that we keep in
/// the state.
#[derive(Default, Encode, Decode, TypeInfo)]
#[cfg_attr(test, derive(Debug, Clone, PartialEq))]
pub struct ParaPastCodeMeta<N> {
/// Block numbers where the code was expected to be replaced and where the code
/// was actually replaced, respectively. The first is used to do accurate lookups
/// of historic code in historic contexts, whereas the second is used to do
/// pruning on an accurate timeframe. These can be used as indices
/// into the `PastCodeHash` map along with the `ParaId` to fetch the code itself.
upgrade_times: Vec<ReplacementTimes<N>>,
/// Tracks the highest pruned code-replacement, if any. This is the `activated_at` value,
/// not the `expected_at` value.
last_pruned: Option<N>,
}
/// The possible states of a para, to take into account delayed lifecycle changes.
///
/// If the para is in a "transition state", it is expected that the parachain is
/// queued in the `ActionsQueue` to transition it into a stable state. Its lifecycle
/// state will be used to determine the state transition to apply to the para.
#[derive(PartialEq, Eq, Clone, Encode, Decode, RuntimeDebug, TypeInfo)]
pub enum ParaLifecycle {
/// Para is new and is onboarding as a Parathread or Parachain.
Onboarding,
/// Para is a Parathread.
Parathread,
/// Para is a Parachain.
Parachain,
/// Para is a Parathread which is upgrading to a Parachain.
UpgradingParathread,
/// Para is a Parachain which is downgrading to a Parathread.
DowngradingParachain,
/// Parathread is queued to be offboarded.
OffboardingParathread,
/// Parachain is queued to be offboarded.
OffboardingParachain,
}
impl ParaLifecycle {
/// Returns true if parachain is currently onboarding. To learn if the
/// parachain is onboarding as a parachain or parathread, look at the
/// `UpcomingGenesis` storage item.
pub fn is_onboarding(&self) -> bool {
matches!(self, ParaLifecycle::Onboarding)
}
/// Returns true if para is in a stable state, i.e. it is currently
/// a parachain or parathread, and not in any transition state.
pub fn is_stable(&self) -> bool {
matches!(self, ParaLifecycle::Parathread | ParaLifecycle::Parachain)
}
/// Returns true if para is currently treated as a parachain.
/// This also includes transitioning states, so you may want to combine
/// this check with `is_stable` if you specifically want `Paralifecycle::Parachain`.
pub fn is_parachain(&self) -> bool {
matches!(
self,
ParaLifecycle::Parachain |
ParaLifecycle::DowngradingParachain |
ParaLifecycle::OffboardingParachain
)
}
/// Returns true if para is currently treated as a parathread.
/// This also includes transitioning states, so you may want to combine
/// this check with `is_stable` if you specifically want `Paralifecycle::Parathread`.
pub fn is_parathread(&self) -> bool {
matches!(
self,
ParaLifecycle::Parathread |
ParaLifecycle::UpgradingParathread |
ParaLifecycle::OffboardingParathread
)
}
/// Returns true if para is currently offboarding.
pub fn is_offboarding(&self) -> bool {
matches!(self, ParaLifecycle::OffboardingParathread | ParaLifecycle::OffboardingParachain)
}
/// Returns true if para is in any transitionary state.
pub fn is_transitioning(&self) -> bool {
!Self::is_stable(self)
}
}
impl<N: Ord + Copy + PartialEq> ParaPastCodeMeta<N> {
// note a replacement has occurred at a given block number.
pub(crate) fn note_replacement(&mut self, expected_at: N, activated_at: N) {
self.upgrade_times.push(ReplacementTimes { expected_at, activated_at })
}
/// Returns `true` if the upgrade logs list is empty.
fn is_empty(&self) -> bool {
self.upgrade_times.is_empty()
}
// The block at which the most recently tracked code change occurred, from the perspective
// of the para.
#[cfg(test)]
fn most_recent_change(&self) -> Option<N> {
self.upgrade_times.last().map(|x| x.expected_at.clone())
}
// prunes all code upgrade logs occurring at or before `max`.
// note that code replaced at `x` is the code used to validate all blocks before
// `x`. Thus, `max` should be outside of the slashing window when this is invoked.
//
// Since we don't want to prune anything inside the acceptance period, and the parablock only
// enters the acceptance period after being included, we prune based on the activation height of
// the code change, not the expected height of the code change.
//
// returns an iterator of block numbers at which code was replaced, where the replaced
// code should be now pruned, in ascending order.
fn prune_up_to(&'_ mut self, max: N) -> impl Iterator<Item = N> + '_ {
let to_prune = self.upgrade_times.iter().take_while(|t| t.activated_at <= max).count();
let drained = if to_prune == 0 {
// no-op prune.
self.upgrade_times.drain(self.upgrade_times.len()..)
} else {
// if we are actually pruning something, update the `last_pruned` member.
self.last_pruned = Some(self.upgrade_times[to_prune - 1].activated_at);
self.upgrade_times.drain(..to_prune)
};
drained.map(|times| times.expected_at)
}
}
/// Arguments for initializing a para.
#[derive(PartialEq, Eq, Clone, Encode, Decode, RuntimeDebug, TypeInfo)]
#[cfg_attr(feature = "std", derive(Serialize, Deserialize))]
pub struct ParaGenesisArgs {
/// The initial head data to use.
pub genesis_head: HeadData,
/// The initial validation code to use.
pub validation_code: ValidationCode,
/// Parachain or Parathread.
#[cfg_attr(feature = "std", serde(rename = "parachain"))]
pub para_kind: ParaKind,
}
/// Distinguishes between Parachain and Parathread
#[derive(PartialEq, Eq, Clone, RuntimeDebug)]
pub enum ParaKind {
Parathread,
Parachain,
}
#[cfg(feature = "std")]
impl Serialize for ParaKind {
fn serialize<S>(&self, serializer: S) -> Result<S::Ok, S::Error>
where
S: serde::Serializer,
{
match self {
ParaKind::Parachain => serializer.serialize_bool(true),
ParaKind::Parathread => serializer.serialize_bool(false),
}
}
}
#[cfg(feature = "std")]
impl<'de> Deserialize<'de> for ParaKind {
fn deserialize<D>(deserializer: D) -> Result<Self, D::Error>
where
D: serde::Deserializer<'de>,
{
match serde::de::Deserialize::deserialize(deserializer) {
Ok(true) => Ok(ParaKind::Parachain),
Ok(false) => Ok(ParaKind::Parathread),
_ => Err(serde::de::Error::custom("invalid ParaKind serde representation")),
}
}
}
// Manual encoding, decoding, and TypeInfo as the parakind field in ParaGenesisArgs used to be a bool
impl Encode for ParaKind {
fn size_hint(&self) -> usize {
true.size_hint()
}
fn using_encoded<R, F: FnOnce(&[u8]) -> R>(&self, f: F) -> R {
match self {
ParaKind::Parachain => true.using_encoded(f),
ParaKind::Parathread => false.using_encoded(f),
}
}
}
impl Decode for ParaKind {
fn decode<I: parity_scale_codec::Input>(
input: &mut I,
) -> Result<Self, parity_scale_codec::Error> {
match bool::decode(input) {
Ok(true) => Ok(ParaKind::Parachain),
Ok(false) => Ok(ParaKind::Parathread),
_ => Err("Invalid ParaKind representation".into()),
}
}
}
impl TypeInfo for ParaKind {
type Identity = bool;
fn type_info() -> Type {
bool::type_info()
}
}
/// This enum describes a reason why a particular PVF pre-checking vote was initiated. When the
/// PVF vote in question is concluded, this enum indicates what changes should be performed.
#[derive(Encode, Decode, TypeInfo)]
enum PvfCheckCause<BlockNumber> {
/// PVF vote was initiated by the initial onboarding process of the given para.
Onboarding(ParaId),
/// PVF vote was initiated by signalling of an upgrade by the given para.
Upgrade {
/// The ID of the parachain that initiated or is waiting for the conclusion of pre-checking.
id: ParaId,
/// The relay-chain block number that was used as the relay-parent for the parablock that
/// initiated the upgrade.
relay_parent_number: BlockNumber,
},
}
impl<BlockNumber> PvfCheckCause<BlockNumber> {
/// Returns the ID of the para that initiated or subscribed to the pre-checking vote.
fn para_id(&self) -> ParaId {
match *self {
PvfCheckCause::Onboarding(id) => id,
PvfCheckCause::Upgrade { id, .. } => id,
}
}
}
/// Specifies what was the outcome of a PVF pre-checking vote.
#[derive(Copy, Clone, Encode, Decode, RuntimeDebug, TypeInfo)]
enum PvfCheckOutcome {
Accepted,
Rejected,
}
/// This struct describes the current state of an in-progress PVF pre-checking vote.
#[derive(Encode, Decode, TypeInfo)]
struct PvfCheckActiveVoteState<BlockNumber> {
// The two following vectors have their length equal to the number of validators in the active
// set. They start with all zeroes. A 1 is set at an index when the validator at the that index
// makes a vote. Once a 1 is set for either of the vectors, that validator cannot vote anymore.
// Since the active validator set changes each session, the bit vectors are reinitialized as
// well: zeroed and resized so that each validator gets its own bit.
votes_accept: BitVec<u8, BitOrderLsb0>,
votes_reject: BitVec<u8, BitOrderLsb0>,
/// The number of session changes this PVF vote has observed. Therefore, this number is
/// increased at each session boundary. When created, it is initialized with 0.
age: SessionIndex,
/// The block number at which this PVF vote was created.
created_at: BlockNumber,
/// A list of causes for this PVF pre-checking. Has at least one.
causes: Vec<PvfCheckCause<BlockNumber>>,
}
impl<BlockNumber> PvfCheckActiveVoteState<BlockNumber> {
/// Returns a new instance of vote state, started at the specified block `now`, with the
/// number of validators in the current session `n_validators` and the originating `cause`.
fn new(now: BlockNumber, n_validators: usize, cause: PvfCheckCause<BlockNumber>) -> Self {
let mut causes = Vec::with_capacity(1);
causes.push(cause);
Self {
created_at: now,
votes_accept: bitvec::bitvec![u8, BitOrderLsb0; 0; n_validators],
votes_reject: bitvec::bitvec![u8, BitOrderLsb0; 0; n_validators],
age: 0,
causes,
}
}
/// Resets all votes and resizes the votes vectors corresponding to the number of validators
/// in the new session.
fn reinitialize_ballots(&mut self, n_validators: usize) {
let clear_and_resize = |v: &mut BitVec<_, _>| {
v.clear();
v.resize(n_validators, false);
};
clear_and_resize(&mut self.votes_accept);
clear_and_resize(&mut self.votes_reject);
}
/// Returns `Some(true)` if the validator at the given index has already cast their vote within
/// the ongoing session. Returns `None` in case the index is out of bounds.
fn has_vote(&self, validator_index: usize) -> Option<bool> {
let accept_vote = self.votes_accept.get(validator_index)?;
let reject_vote = self.votes_reject.get(validator_index)?;
Some(*accept_vote || *reject_vote)
}
/// Returns `None` if the quorum is not reached, or the direction of the decision.
fn quorum(&self, n_validators: usize) -> Option<PvfCheckOutcome> {
let q_threshold = primitives::v2::supermajority_threshold(n_validators);
// NOTE: counting the reject votes is deliberately placed first. This is to err on the safe.
if self.votes_reject.count_ones() >= q_threshold {
Some(PvfCheckOutcome::Rejected)
} else if self.votes_accept.count_ones() >= q_threshold {
Some(PvfCheckOutcome::Accepted)
} else {
None
}
}
}
pub trait WeightInfo {
fn force_set_current_code(c: u32) -> Weight;
fn force_set_current_head(s: u32) -> Weight;
fn force_schedule_code_upgrade(c: u32) -> Weight;
fn force_note_new_head(s: u32) -> Weight;
fn force_queue_action() -> Weight;
fn add_trusted_validation_code(c: u32) -> Weight;
fn poke_unused_validation_code() -> Weight;
fn include_pvf_check_statement_finalize_upgrade_accept() -> Weight;
fn include_pvf_check_statement_finalize_upgrade_reject() -> Weight;
fn include_pvf_check_statement_finalize_onboarding_accept() -> Weight;
fn include_pvf_check_statement_finalize_onboarding_reject() -> Weight;
fn include_pvf_check_statement() -> Weight;
}
pub struct TestWeightInfo;
impl WeightInfo for TestWeightInfo {
fn force_set_current_code(_c: u32) -> Weight {
Weight::MAX
}
fn force_set_current_head(_s: u32) -> Weight {
Weight::MAX
}
fn force_schedule_code_upgrade(_c: u32) -> Weight {
Weight::MAX
}
fn force_note_new_head(_s: u32) -> Weight {
Weight::MAX
}
fn force_queue_action() -> Weight {
Weight::MAX
}
fn add_trusted_validation_code(_c: u32) -> Weight {
Weight::MAX
}
fn poke_unused_validation_code() -> Weight {
Weight::MAX
}
fn include_pvf_check_statement_finalize_upgrade_accept() -> Weight {
Weight::MAX
}
fn include_pvf_check_statement_finalize_upgrade_reject() -> Weight {
Weight::MAX
}
fn include_pvf_check_statement_finalize_onboarding_accept() -> Weight {
Weight::MAX
}
fn include_pvf_check_statement_finalize_onboarding_reject() -> Weight {
Weight::MAX
}
fn include_pvf_check_statement() -> Weight {
// This special value is to distinguish from the finalizing variants above in tests.
Weight::MAX - Weight::from_ref_time(1)
}
}
#[frame_support::pallet]
pub mod pallet {
use super::*;
use sp_runtime::transaction_validity::{
InvalidTransaction, TransactionPriority, TransactionSource, TransactionValidity,
ValidTransaction,
};
#[pallet::pallet]
#[pallet::generate_store(pub(super) trait Store)]
#[pallet::without_storage_info]
pub struct Pallet<T>(_);
#[pallet::config]
pub trait Config:
frame_system::Config
+ configuration::Config
+ shared::Config
+ frame_system::offchain::SendTransactionTypes<Call<Self>>
{
type RuntimeEvent: From<Event> + IsType<<Self as frame_system::Config>::RuntimeEvent>;
#[pallet::constant]
type UnsignedPriority: Get<TransactionPriority>;
type NextSessionRotation: EstimateNextSessionRotation<Self::BlockNumber>;
/// Weight information for extrinsics in this pallet.
type WeightInfo: WeightInfo;
}
#[pallet::event]
#[pallet::generate_deposit(pub(super) fn deposit_event)]
pub enum Event {
/// Current code has been updated for a Para. `para_id`
CurrentCodeUpdated(ParaId),
/// Current head has been updated for a Para. `para_id`
CurrentHeadUpdated(ParaId),
/// A code upgrade has been scheduled for a Para. `para_id`
CodeUpgradeScheduled(ParaId),
/// A new head has been noted for a Para. `para_id`
NewHeadNoted(ParaId),
/// A para has been queued to execute pending actions. `para_id`
ActionQueued(ParaId, SessionIndex),
/// The given para either initiated or subscribed to a PVF check for the given validation
/// code. `code_hash` `para_id`
PvfCheckStarted(ValidationCodeHash, ParaId),
/// The given validation code was accepted by the PVF pre-checking vote.
/// `code_hash` `para_id`
PvfCheckAccepted(ValidationCodeHash, ParaId),
/// The given validation code was rejected by the PVF pre-checking vote.
/// `code_hash` `para_id`
PvfCheckRejected(ValidationCodeHash, ParaId),
}
#[pallet::error]
pub enum Error<T> {
/// Para is not registered in our system.
NotRegistered,
/// Para cannot be onboarded because it is already tracked by our system.
CannotOnboard,
/// Para cannot be offboarded at this time.
CannotOffboard,
/// Para cannot be upgraded to a parachain.
CannotUpgrade,
/// Para cannot be downgraded to a parathread.
CannotDowngrade,
/// The statement for PVF pre-checking is stale.
PvfCheckStatementStale,
/// The statement for PVF pre-checking is for a future session.
PvfCheckStatementFuture,
/// Claimed validator index is out of bounds.
PvfCheckValidatorIndexOutOfBounds,
/// The signature for the PVF pre-checking is invalid.
PvfCheckInvalidSignature,
/// The given validator already has cast a vote.
PvfCheckDoubleVote,
/// The given PVF does not exist at the moment of process a vote.
PvfCheckSubjectInvalid,
/// The PVF pre-checking statement cannot be included since the PVF pre-checking mechanism
/// is disabled.
PvfCheckDisabled,
/// Parachain cannot currently schedule a code upgrade.
CannotUpgradeCode,
}
/// All currently active PVF pre-checking votes.
///
/// Invariant:
/// - There are no PVF pre-checking votes that exists in list but not in the set and vice versa.
#[pallet::storage]
pub(super) type PvfActiveVoteMap<T: Config> = StorageMap<
_,
Twox64Concat,
ValidationCodeHash,
PvfCheckActiveVoteState<T::BlockNumber>,
OptionQuery,
>;
/// The list of all currently active PVF votes. Auxiliary to `PvfActiveVoteMap`.
#[pallet::storage]
pub(super) type PvfActiveVoteList<T: Config> =
StorageValue<_, Vec<ValidationCodeHash>, ValueQuery>;
/// All parachains. Ordered ascending by `ParaId`. Parathreads are not included.
///
/// Consider using the [`ParachainsCache`] type of modifying.
#[pallet::storage]
#[pallet::getter(fn parachains)]
pub(crate) type Parachains<T: Config> = StorageValue<_, Vec<ParaId>, ValueQuery>;
/// The current lifecycle of a all known Para IDs.
#[pallet::storage]
pub(super) type ParaLifecycles<T: Config> = StorageMap<_, Twox64Concat, ParaId, ParaLifecycle>;
/// The head-data of every registered para.
#[pallet::storage]
#[pallet::getter(fn para_head)]
pub(super) type Heads<T: Config> = StorageMap<_, Twox64Concat, ParaId, HeadData>;
/// The validation code hash of every live para.
///
/// Corresponding code can be retrieved with [`CodeByHash`].
#[pallet::storage]
#[pallet::getter(fn current_code_hash)]
pub(super) type CurrentCodeHash<T: Config> =
StorageMap<_, Twox64Concat, ParaId, ValidationCodeHash>;
/// Actual past code hash, indicated by the para id as well as the block number at which it
/// became outdated.
///
/// Corresponding code can be retrieved with [`CodeByHash`].
#[pallet::storage]
pub(super) type PastCodeHash<T: Config> =
StorageMap<_, Twox64Concat, (ParaId, T::BlockNumber), ValidationCodeHash>;
/// Past code of parachains. The parachains themselves may not be registered anymore,
/// but we also keep their code on-chain for the same amount of time as outdated code
/// to keep it available for secondary checkers.
#[pallet::storage]
#[pallet::getter(fn past_code_meta)]
pub(super) type PastCodeMeta<T: Config> =
StorageMap<_, Twox64Concat, ParaId, ParaPastCodeMeta<T::BlockNumber>, ValueQuery>;
/// Which paras have past code that needs pruning and the relay-chain block at which the code was replaced.
/// Note that this is the actual height of the included block, not the expected height at which the
/// code upgrade would be applied, although they may be equal.
/// This is to ensure the entire acceptance period is covered, not an offset acceptance period starting
/// from the time at which the parachain perceives a code upgrade as having occurred.
/// Multiple entries for a single para are permitted. Ordered ascending by block number.
#[pallet::storage]
pub(super) type PastCodePruning<T: Config> =
StorageValue<_, Vec<(ParaId, T::BlockNumber)>, ValueQuery>;
/// The block number at which the planned code change is expected for a para.
/// The change will be applied after the first parablock for this ID included which executes
/// in the context of a relay chain block with a number >= `expected_at`.
#[pallet::storage]
#[pallet::getter(fn future_code_upgrade_at)]
pub(super) type FutureCodeUpgrades<T: Config> =
StorageMap<_, Twox64Concat, ParaId, T::BlockNumber>;
/// The actual future code hash of a para.
///
/// Corresponding code can be retrieved with [`CodeByHash`].
#[pallet::storage]
pub(super) type FutureCodeHash<T: Config> =
StorageMap<_, Twox64Concat, ParaId, ValidationCodeHash>;
/// This is used by the relay-chain to communicate to a parachain a go-ahead with in the upgrade procedure.
///
/// This value is absent when there are no upgrades scheduled or during the time the relay chain
/// performs the checks. It is set at the first relay-chain block when the corresponding parachain
/// can switch its upgrade function. As soon as the parachain's block is included, the value
/// gets reset to `None`.
///
/// NOTE that this field is used by parachains via merkle storage proofs, therefore changing
/// the format will require migration of parachains.
#[pallet::storage]
pub(super) type UpgradeGoAheadSignal<T: Config> =
StorageMap<_, Twox64Concat, ParaId, UpgradeGoAhead>;
/// This is used by the relay-chain to communicate that there are restrictions for performing
/// an upgrade for this parachain.
///
/// This may be a because the parachain waits for the upgrade cooldown to expire. Another
/// potential use case is when we want to perform some maintenance (such as storage migration)
/// we could restrict upgrades to make the process simpler.
///
/// NOTE that this field is used by parachains via merkle storage proofs, therefore changing
/// the format will require migration of parachains.
#[pallet::storage]
pub(super) type UpgradeRestrictionSignal<T: Config> =
StorageMap<_, Twox64Concat, ParaId, UpgradeRestriction>;
/// The list of parachains that are awaiting for their upgrade restriction to cooldown.
///
/// Ordered ascending by block number.
#[pallet::storage]
pub(super) type UpgradeCooldowns<T: Config> =
StorageValue<_, Vec<(ParaId, T::BlockNumber)>, ValueQuery>;
/// The list of upcoming code upgrades. Each item is a pair of which para performs a code
/// upgrade and at which relay-chain block it is expected at.
///
/// Ordered ascending by block number.
#[pallet::storage]
pub(super) type UpcomingUpgrades<T: Config> =
StorageValue<_, Vec<(ParaId, T::BlockNumber)>, ValueQuery>;
/// The actions to perform during the start of a specific session index.
#[pallet::storage]
#[pallet::getter(fn actions_queue)]
pub(super) type ActionsQueue<T: Config> =
StorageMap<_, Twox64Concat, SessionIndex, Vec<ParaId>, ValueQuery>;
/// Upcoming paras instantiation arguments.
///
/// NOTE that after PVF pre-checking is enabled the para genesis arg will have it's code set
/// to empty. Instead, the code will be saved into the storage right away via `CodeByHash`.
#[pallet::storage]
pub(super) type UpcomingParasGenesis<T: Config> =
StorageMap<_, Twox64Concat, ParaId, ParaGenesisArgs>;
/// The number of reference on the validation code in [`CodeByHash`] storage.
#[pallet::storage]
pub(super) type CodeByHashRefs<T: Config> =
StorageMap<_, Identity, ValidationCodeHash, u32, ValueQuery>;
/// Validation code stored by its hash.
///
/// This storage is consistent with [`FutureCodeHash`], [`CurrentCodeHash`] and
/// [`PastCodeHash`].
#[pallet::storage]
#[pallet::getter(fn code_by_hash)]
pub(super) type CodeByHash<T: Config> =
StorageMap<_, Identity, ValidationCodeHash, ValidationCode>;
#[pallet::genesis_config]
pub struct GenesisConfig {
pub paras: Vec<(ParaId, ParaGenesisArgs)>,
}
#[cfg(feature = "std")]
impl Default for GenesisConfig {
fn default() -> Self {
GenesisConfig { paras: Default::default() }
}
}
#[pallet::genesis_build]
impl<T: Config> GenesisBuild<T> for GenesisConfig {
fn build(&self) {
let mut parachains = ParachainsCache::new();
for (id, genesis_args) in &self.paras {
if genesis_args.validation_code.0.is_empty() {
panic!("empty validation code is not allowed in genesis");
}
Pallet::<T>::initialize_para_now(&mut parachains, *id, genesis_args);
}
// parachains are flushed on drop
}
}
#[pallet::call]
impl<T: Config> Pallet<T> {
/// Set the storage for the parachain validation code immediately.
#[pallet::weight(<T as Config>::WeightInfo::force_set_current_code(new_code.0.len() as u32))]
pub fn force_set_current_code(
origin: OriginFor<T>,
para: ParaId,
new_code: ValidationCode,
) -> DispatchResult {
ensure_root(origin)?;
let maybe_prior_code_hash = <Self as Store>::CurrentCodeHash::get(&para);
let new_code_hash = new_code.hash();
Self::increase_code_ref(&new_code_hash, &new_code);
<Self as Store>::CurrentCodeHash::insert(&para, new_code_hash);
let now = frame_system::Pallet::<T>::block_number();
if let Some(prior_code_hash) = maybe_prior_code_hash {
Self::note_past_code(para, now, now, prior_code_hash);
} else {
log::error!(
target: LOG_TARGET,
"Pallet paras storage is inconsistent, prior code not found {:?}",
&para
);
}
Self::deposit_event(Event::CurrentCodeUpdated(para));
Ok(())
}
/// Set the storage for the current parachain head data immediately.
#[pallet::weight(<T as Config>::WeightInfo::force_set_current_head(new_head.0.len() as u32))]
pub fn force_set_current_head(
origin: OriginFor<T>,
para: ParaId,
new_head: HeadData,
) -> DispatchResult {
ensure_root(origin)?;
Self::set_current_head(para, new_head);
Ok(())
}
/// Schedule an upgrade as if it was scheduled in the given relay parent block.
#[pallet::weight(<T as Config>::WeightInfo::force_schedule_code_upgrade(new_code.0.len() as u32))]
pub fn force_schedule_code_upgrade(
origin: OriginFor<T>,
para: ParaId,
new_code: ValidationCode,
relay_parent_number: T::BlockNumber,
) -> DispatchResult {
ensure_root(origin)?;
let config = configuration::Pallet::<T>::config();
Self::schedule_code_upgrade(para, new_code, relay_parent_number, &config);
Self::deposit_event(Event::CodeUpgradeScheduled(para));
Ok(())
}
/// Note a new block head for para within the context of the current block.
#[pallet::weight(<T as Config>::WeightInfo::force_note_new_head(new_head.0.len() as u32))]
pub fn force_note_new_head(
origin: OriginFor<T>,
para: ParaId,
new_head: HeadData,
) -> DispatchResult {
ensure_root(origin)?;
let now = frame_system::Pallet::<T>::block_number();
Self::note_new_head(para, new_head, now);
Self::deposit_event(Event::NewHeadNoted(para));
Ok(())
}
/// Put a parachain directly into the next session's action queue.
/// We can't queue it any sooner than this without going into the
/// initializer...
#[pallet::weight(<T as Config>::WeightInfo::force_queue_action())]
pub fn force_queue_action(origin: OriginFor<T>, para: ParaId) -> DispatchResult {
ensure_root(origin)?;
let next_session = shared::Pallet::<T>::session_index().saturating_add(One::one());
ActionsQueue::<T>::mutate(next_session, |v| {
if let Err(i) = v.binary_search(&para) {
v.insert(i, para);
}
});
Self::deposit_event(Event::ActionQueued(para, next_session));
Ok(())
}
/// Adds the validation code to the storage.
///
/// The code will not be added if it is already present. Additionally, if PVF pre-checking
/// is running for that code, it will be instantly accepted.
///
/// Otherwise, the code will be added into the storage. Note that the code will be added
/// into storage with reference count 0. This is to account the fact that there are no users
/// for this code yet. The caller will have to make sure that this code eventually gets
/// used by some parachain or removed from the storage to avoid storage leaks. For the latter
/// prefer to use the `poke_unused_validation_code` dispatchable to raw storage manipulation.
///
/// This function is mainly meant to be used for upgrading parachains that do not follow
/// the go-ahead signal while the PVF pre-checking feature is enabled.
#[pallet::weight(<T as Config>::WeightInfo::add_trusted_validation_code(validation_code.0.len() as u32))]
pub fn add_trusted_validation_code(
origin: OriginFor<T>,
validation_code: ValidationCode,
) -> DispatchResult {
ensure_root(origin)?;
let code_hash = validation_code.hash();
if let Some(vote) = <Self as Store>::PvfActiveVoteMap::get(&code_hash) {
// Remove the existing vote.
PvfActiveVoteMap::<T>::remove(&code_hash);
PvfActiveVoteList::<T>::mutate(|l| {
if let Ok(i) = l.binary_search(&code_hash) {
l.remove(i);
}
});
let cfg = configuration::Pallet::<T>::config();
Self::enact_pvf_accepted(
<frame_system::Pallet<T>>::block_number(),
&code_hash,
&vote.causes,
vote.age,
&cfg,
);
return Ok(())
}
if <Self as Store>::CodeByHash::contains_key(&code_hash) {
// There is no vote, but the code exists. Nothing to do here.
return Ok(())
}
// At this point the code is unknown and there is no PVF pre-checking vote for it, so we
// can just add the code into the storage.
//
// NOTE That we do not use `increase_code_ref` here, because the code is not yet used
// by any parachain.
<Self as Store>::CodeByHash::insert(code_hash, &validation_code);
Ok(())
}
/// Remove the validation code from the storage iff the reference count is 0.
///
/// This is better than removing the storage directly, because it will not remove the code
/// that was suddenly got used by some parachain while this dispatchable was pending
/// dispatching.
#[pallet::weight(<T as Config>::WeightInfo::poke_unused_validation_code())]
pub fn poke_unused_validation_code(
origin: OriginFor<T>,
validation_code_hash: ValidationCodeHash,
) -> DispatchResult {
ensure_root(origin)?;
if <Self as Store>::CodeByHashRefs::get(&validation_code_hash) == 0 {
<Self as Store>::CodeByHash::remove(&validation_code_hash);
}
Ok(())
}
/// Includes a statement for a PVF pre-checking vote. Potentially, finalizes the vote and
/// enacts the results if that was the last vote before achieving the supermajority.
#[pallet::weight(
<T as Config>::WeightInfo::include_pvf_check_statement_finalize_upgrade_accept()
.max(<T as Config>::WeightInfo::include_pvf_check_statement_finalize_upgrade_reject())
.max(<T as Config>::WeightInfo::include_pvf_check_statement_finalize_onboarding_accept()
.max(<T as Config>::WeightInfo::include_pvf_check_statement_finalize_onboarding_reject())
)
)]
pub fn include_pvf_check_statement(
origin: OriginFor<T>,
stmt: PvfCheckStatement,
signature: ValidatorSignature,
) -> DispatchResultWithPostInfo {
ensure_none(origin)?;
// Make sure that PVF pre-checking is enabled.
ensure!(
configuration::Pallet::<T>::config().pvf_checking_enabled,
Error::<T>::PvfCheckDisabled,
);
let validators = shared::Pallet::<T>::active_validator_keys();
let current_session = shared::Pallet::<T>::session_index();
if stmt.session_index < current_session {
return Err(Error::<T>::PvfCheckStatementStale.into())
} else if stmt.session_index > current_session {
return Err(Error::<T>::PvfCheckStatementFuture.into())
}
let validator_index = stmt.validator_index.0 as usize;
let validator_public = validators
.get(validator_index)
.ok_or(Error::<T>::PvfCheckValidatorIndexOutOfBounds)?;
let signing_payload = stmt.signing_payload();
ensure!(
signature.verify(&signing_payload[..], &validator_public),
Error::<T>::PvfCheckInvalidSignature,
);
let mut active_vote = PvfActiveVoteMap::<T>::get(&stmt.subject)
.ok_or(Error::<T>::PvfCheckSubjectInvalid)?;
// Ensure that the validator submitting this statement hasn't voted already.
ensure!(
!active_vote
.has_vote(validator_index)
.ok_or(Error::<T>::PvfCheckValidatorIndexOutOfBounds)?,
Error::<T>::PvfCheckDoubleVote,
);
// Finally, cast the vote and persist.
if stmt.accept {
active_vote.votes_accept.set(validator_index, true);
} else {
active_vote.votes_reject.set(validator_index, true);
}
if let Some(outcome) = active_vote.quorum(validators.len()) {
// The supermajority quorum has been achieved.
//
// Remove the PVF vote from the active map and finalize the PVF checking according
// to the outcome.
PvfActiveVoteMap::<T>::remove(&stmt.subject);
PvfActiveVoteList::<T>::mutate(|l| {
if let Ok(i) = l.binary_search(&stmt.subject) {
l.remove(i);
}
});
match outcome {
PvfCheckOutcome::Accepted => {
let cfg = configuration::Pallet::<T>::config();
Self::enact_pvf_accepted(
<frame_system::Pallet<T>>::block_number(),
&stmt.subject,
&active_vote.causes,
active_vote.age,
&cfg,
);
},
PvfCheckOutcome::Rejected => {
Self::enact_pvf_rejected(&stmt.subject, active_vote.causes);
},
}
// No weight refund since this statement was the last one and lead to finalization.
Ok(().into())
} else {
// No quorum has been achieved.
//
// - So just store the updated state back into the storage.
// - Only charge weight for simple vote inclusion.
PvfActiveVoteMap::<T>::insert(&stmt.subject, active_vote);
Ok(Some(<T as Config>::WeightInfo::include_pvf_check_statement()).into())
}
}
}
#[pallet::validate_unsigned]
impl<T: Config> ValidateUnsigned for Pallet<T> {
type Call = Call<T>;
fn validate_unsigned(_source: TransactionSource, call: &Self::Call) -> TransactionValidity {
let (stmt, signature) = match call {
Call::include_pvf_check_statement { stmt, signature } => (stmt, signature),
_ => return InvalidTransaction::Call.into(),
};
if !configuration::Pallet::<T>::config().pvf_checking_enabled {
return InvalidTransaction::Custom(INVALID_TX_PVF_CHECK_DISABLED).into()
}
let current_session = shared::Pallet::<T>::session_index();
if stmt.session_index < current_session {
return InvalidTransaction::Stale.into()
} else if stmt.session_index > current_session {
return InvalidTransaction::Future.into()
}
let validator_index = stmt.validator_index.0 as usize;
let validators = shared::Pallet::<T>::active_validator_keys();
let validator_public = match validators.get(validator_index) {
Some(pk) => pk,
None => return InvalidTransaction::Custom(INVALID_TX_BAD_VALIDATOR_IDX).into(),
};
let signing_payload = stmt.signing_payload();
if !signature.verify(&signing_payload[..], &validator_public) {
return InvalidTransaction::BadProof.into()
}
let active_vote = match PvfActiveVoteMap::<T>::get(&stmt.subject) {
Some(v) => v,
None => return InvalidTransaction::Custom(INVALID_TX_BAD_SUBJECT).into(),
};
match active_vote.has_vote(validator_index) {
Some(false) => (),
Some(true) => return InvalidTransaction::Custom(INVALID_TX_DOUBLE_VOTE).into(),
None => return InvalidTransaction::Custom(INVALID_TX_BAD_VALIDATOR_IDX).into(),
}
ValidTransaction::with_tag_prefix("PvfPreCheckingVote")
.priority(T::UnsignedPriority::get())
.longevity(
TryInto::<u64>::try_into(
T::NextSessionRotation::average_session_length() / 2u32.into(),
)
.unwrap_or(64_u64),
)
.and_provides((stmt.session_index, stmt.validator_index, stmt.subject))
.propagate(true)
.build()
}
fn pre_dispatch(_call: &Self::Call) -> Result<(), TransactionValidityError> {
// Return `Ok` here meaning that as soon as the transaction got into the block, it will
// always dispatched. This is OK, since the `include_pvf_check_statement` dispatchable
// will perform the same checks anyway, so there is no point doing it here.
//
// On the other hand, if we did not provide the implementation, then the default
// implementation would be used. The default implementation just delegates the
// pre-dispatch validation to `validate_unsigned`.
Ok(())
}
}
}
// custom transaction error codes
const INVALID_TX_BAD_VALIDATOR_IDX: u8 = 1;
const INVALID_TX_BAD_SUBJECT: u8 = 2;
const INVALID_TX_DOUBLE_VOTE: u8 = 3;
const INVALID_TX_PVF_CHECK_DISABLED: u8 = 4;
impl<T: Config> Pallet<T> {
/// This is a call to schedule code upgrades for parachains which is safe to be called
/// outside of this module. That means this function does all checks necessary to ensure
/// that some external code is allowed to trigger a code upgrade. We do not do auth checks,
/// that should be handled by whomever calls this function.
pub(crate) fn schedule_code_upgrade_external(
id: ParaId,
new_code: ValidationCode,
) -> DispatchResult {
// Check that we can schedule an upgrade at all.
ensure!(Self::can_upgrade_validation_code(id), Error::<T>::CannotUpgradeCode);
let config = configuration::Pallet::<T>::config();
let current_block = frame_system::Pallet::<T>::block_number();
// Schedule the upgrade with a delay just like if a parachain triggered the upgrade.
let upgrade_block = current_block.saturating_add(config.validation_upgrade_delay);
Self::schedule_code_upgrade(id, new_code, upgrade_block, &config);
Self::deposit_event(Event::CodeUpgradeScheduled(id));
Ok(())
}
/// Set the current head of a parachain.
pub(crate) fn set_current_head(para: ParaId, new_head: HeadData) {
<Self as Store>::Heads::insert(&para, new_head);
Self::deposit_event(Event::CurrentHeadUpdated(para));
}
/// Called by the initializer to initialize the paras pallet.
pub(crate) fn initializer_initialize(now: T::BlockNumber) -> Weight {
let weight = Self::prune_old_code(now);
weight + Self::process_scheduled_upgrade_changes(now)
}
/// Called by the initializer to finalize the paras pallet.
pub(crate) fn initializer_finalize(now: T::BlockNumber) {
Self::process_scheduled_upgrade_cooldowns(now);
}
/// Called by the initializer to note that a new session has started.
///
/// Returns the list of outgoing paras from the actions queue.
pub(crate) fn initializer_on_new_session(
notification: &SessionChangeNotification<T::BlockNumber>,
) -> Vec<ParaId> {
let outgoing_paras = Self::apply_actions_queue(notification.session_index);
Self::groom_ongoing_pvf_votes(&notification.new_config, notification.validators.len());
outgoing_paras
}
/// The validation code of live para.
pub(crate) fn current_code(para_id: &ParaId) -> Option<ValidationCode> {
Self::current_code_hash(para_id).and_then(|code_hash| {
let code = CodeByHash::<T>::get(&code_hash);
if code.is_none() {
log::error!(
"Pallet paras storage is inconsistent, code not found for hash {}",
code_hash,
);
debug_assert!(false, "inconsistent paras storages");
}
code
})
}
// Apply all para actions queued for the given session index.
//
// The actions to take are based on the lifecycle of of the paras.
//
// The final state of any para after the actions queue should be as a
// parachain, parathread, or not registered. (stable states)
//
// Returns the list of outgoing paras from the actions queue.
fn apply_actions_queue(session: SessionIndex) -> Vec<ParaId> {
let actions = ActionsQueue::<T>::take(session);
let mut parachains = ParachainsCache::new();
let now = <frame_system::Pallet<T>>::block_number();
let mut outgoing = Vec::new();
for para in actions {
let lifecycle = ParaLifecycles::<T>::get(&para);
match lifecycle {
None | Some(ParaLifecycle::Parathread) | Some(ParaLifecycle::Parachain) => { /* Nothing to do... */
},
Some(ParaLifecycle::Onboarding) => {
if let Some(genesis_data) = <Self as Store>::UpcomingParasGenesis::take(&para) {
Self::initialize_para_now(&mut parachains, para, &genesis_data);
}
},
// Upgrade a parathread to a parachain
Some(ParaLifecycle::UpgradingParathread) => {
parachains.add(para);
ParaLifecycles::<T>::insert(&para, ParaLifecycle::Parachain);
},
// Downgrade a parachain to a parathread
Some(ParaLifecycle::DowngradingParachain) => {
parachains.remove(para);
ParaLifecycles::<T>::insert(&para, ParaLifecycle::Parathread);
},
// Offboard a parathread or parachain from the system
Some(ParaLifecycle::OffboardingParachain) |
Some(ParaLifecycle::OffboardingParathread) => {
parachains.remove(para);
<Self as Store>::Heads::remove(&para);
<Self as Store>::FutureCodeUpgrades::remove(&para);
<Self as Store>::UpgradeGoAheadSignal::remove(&para);
<Self as Store>::UpgradeRestrictionSignal::remove(&para);
ParaLifecycles::<T>::remove(&para);
let removed_future_code_hash = <Self as Store>::FutureCodeHash::take(&para);
if let Some(removed_future_code_hash) = removed_future_code_hash {
Self::decrease_code_ref(&removed_future_code_hash);
}
let removed_code_hash = <Self as Store>::CurrentCodeHash::take(&para);
if let Some(removed_code_hash) = removed_code_hash {
Self::note_past_code(para, now, now, removed_code_hash);
}
outgoing.push(para);
},
}
}
if !outgoing.is_empty() {
// Filter offboarded parachains from the upcoming upgrades and upgrade cooldowns list.
//
// We do it after the offboarding to get away with only a single read/write per list.
//
// NOTE both of those iterates over the list and the outgoing. We do not expect either
// of these to be large. Thus should be fine.
<Self as Store>::UpcomingUpgrades::mutate(|upcoming_upgrades| {
*upcoming_upgrades = mem::take(upcoming_upgrades)
.into_iter()
.filter(|&(ref para, _)| !outgoing.contains(para))
.collect();
});
<Self as Store>::UpgradeCooldowns::mutate(|upgrade_cooldowns| {
*upgrade_cooldowns = mem::take(upgrade_cooldowns)
.into_iter()
.filter(|&(ref para, _)| !outgoing.contains(para))
.collect();
});
}
// Persist parachains into the storage explicitly.
drop(parachains);
return outgoing
}
// note replacement of the code of para with given `id`, which occured in the
// context of the given relay-chain block number. provide the replaced code.
//
// `at` for para-triggered replacement is the block number of the relay-chain
// block in whose context the parablock was executed
// (i.e. number of `relay_parent` in the receipt)
fn note_past_code(
id: ParaId,
at: T::BlockNumber,
now: T::BlockNumber,
old_code_hash: ValidationCodeHash,
) -> Weight {
<Self as Store>::PastCodeMeta::mutate(&id, |past_meta| {
past_meta.note_replacement(at, now);
});
<Self as Store>::PastCodeHash::insert(&(id, at), old_code_hash);
// Schedule pruning for this past-code to be removed as soon as it
// exits the slashing window.
<Self as Store>::PastCodePruning::mutate(|pruning| {
let insert_idx =
pruning.binary_search_by_key(&now, |&(_, b)| b).unwrap_or_else(|idx| idx);
pruning.insert(insert_idx, (id, now));
});
T::DbWeight::get().reads_writes(2, 3)
}
// looks at old code metadata, compares them to the current acceptance window, and prunes those
// that are too old.
fn prune_old_code(now: T::BlockNumber) -> Weight {
let config = configuration::Pallet::<T>::config();
let code_retention_period = config.code_retention_period;
if now <= code_retention_period {
let weight = T::DbWeight::get().reads_writes(1, 0);
return weight
}
// The height of any changes we no longer should keep around.
let pruning_height = now - (code_retention_period + One::one());
let pruning_tasks_done = <Self as Store>::PastCodePruning::mutate(
|pruning_tasks: &mut Vec<(_, T::BlockNumber)>| {
let (pruning_tasks_done, pruning_tasks_to_do) = {
// find all past code that has just exited the pruning window.
let up_to_idx =
pruning_tasks.iter().take_while(|&(_, at)| at <= &pruning_height).count();
(up_to_idx, pruning_tasks.drain(..up_to_idx))
};
for (para_id, _) in pruning_tasks_to_do {
let full_deactivate = <Self as Store>::PastCodeMeta::mutate(&para_id, |meta| {
for pruned_repl_at in meta.prune_up_to(pruning_height) {
let removed_code_hash =
<Self as Store>::PastCodeHash::take(&(para_id, pruned_repl_at));
if let Some(removed_code_hash) = removed_code_hash {
Self::decrease_code_ref(&removed_code_hash);
} else {
log::warn!(
target: LOG_TARGET,
"Missing code for removed hash {:?}",
removed_code_hash,
);
}
}
meta.is_empty() && Self::para_head(&para_id).is_none()
});
// This parachain has been removed and now the vestigial code
// has been removed from the state. clean up meta as well.
if full_deactivate {
<Self as Store>::PastCodeMeta::remove(&para_id);
}
}
pruning_tasks_done as u64
},
);
// 1 read for the meta for each pruning task, 1 read for the config
// 2 writes: updating the meta and pruning the code
T::DbWeight::get().reads_writes(1 + pruning_tasks_done, 2 * pruning_tasks_done)
}
/// Process the timers related to upgrades. Specifically, the upgrade go ahead signals toggle
/// and the upgrade cooldown restrictions. However, this function does not actually unset
/// the upgrade restriction, that will happen in the `initializer_finalize` function. However,
/// this function does count the number of cooldown timers expired so that we can reserve weight
/// for the `initializer_finalize` function.
fn process_scheduled_upgrade_changes(now: T::BlockNumber) -> Weight {
// account weight for `UpcomingUpgrades::mutate`.
let mut weight = T::DbWeight::get().reads_writes(1, 1);
let upgrades_signaled = <Self as Store>::UpcomingUpgrades::mutate(
|upcoming_upgrades: &mut Vec<(ParaId, T::BlockNumber)>| {
let num = upcoming_upgrades.iter().take_while(|&(_, at)| at <= &now).count();
for (para, _) in upcoming_upgrades.drain(..num) {
<Self as Store>::UpgradeGoAheadSignal::insert(&para, UpgradeGoAhead::GoAhead);
}
num
},
);
weight += T::DbWeight::get().writes(upgrades_signaled as u64);
// account weight for `UpgradeCooldowns::get`.
weight += T::DbWeight::get().reads(1);
let cooldowns_expired = <Self as Store>::UpgradeCooldowns::get()
.iter()
.take_while(|&(_, at)| at <= &now)
.count();
// reserve weight for `initializer_finalize`:
// - 1 read and 1 write for `UpgradeCooldowns::mutate`.
// - 1 write per expired cooldown.
weight += T::DbWeight::get().reads_writes(1, 1);
weight += T::DbWeight::get().reads(cooldowns_expired as u64);
weight
}
/// Actually perform unsetting the expired upgrade restrictions.
///
/// See `process_scheduled_upgrade_changes` for more details.
fn process_scheduled_upgrade_cooldowns(now: T::BlockNumber) {
<Self as Store>::UpgradeCooldowns::mutate(
|upgrade_cooldowns: &mut Vec<(ParaId, T::BlockNumber)>| {
for &(para, _) in upgrade_cooldowns.iter().take_while(|&(_, at)| at <= &now) {
<Self as Store>::UpgradeRestrictionSignal::remove(&para);
}
},
);
}
/// Goes over all PVF votes in progress, reinitializes ballots, increments ages and prunes the
/// active votes that reached their time-to-live.
fn groom_ongoing_pvf_votes(
cfg: &configuration::HostConfiguration<T::BlockNumber>,
new_n_validators: usize,
) -> Weight {
let mut weight = T::DbWeight::get().reads(1);
let potentially_active_votes = PvfActiveVoteList::<T>::get();
// Initially empty list which contains all the PVF active votes that made it through this
// session change.
//
// **Ordered** as well as `PvfActiveVoteList`.
let mut actually_active_votes = Vec::with_capacity(potentially_active_votes.len());
for vote_subject in potentially_active_votes {
let mut vote_state = match PvfActiveVoteMap::<T>::take(&vote_subject) {
Some(v) => v,
None => {
// This branch should never be reached. This is due to the fact that the set of
// `PvfActiveVoteMap`'s keys is always equal to the set of items found in
// `PvfActiveVoteList`.
log::warn!(
target: LOG_TARGET,
"The PvfActiveVoteMap is out of sync with PvfActiveVoteList!",
);
debug_assert!(false);
continue
},
};
vote_state.age += 1;
if vote_state.age < cfg.pvf_voting_ttl {
weight += T::DbWeight::get().writes(1);
vote_state.reinitialize_ballots(new_n_validators);
PvfActiveVoteMap::<T>::insert(&vote_subject, vote_state);
// push maintaining the original order.
actually_active_votes.push(vote_subject);
} else {
// TTL is reached. Reject.
weight += Self::enact_pvf_rejected(&vote_subject, vote_state.causes);
}
}
weight += T::DbWeight::get().writes(1);
PvfActiveVoteList::<T>::put(actually_active_votes);
weight
}
fn enact_pvf_accepted(
now: T::BlockNumber,
code_hash: &ValidationCodeHash,
causes: &[PvfCheckCause<T::BlockNumber>],
sessions_observed: SessionIndex,
cfg: &configuration::HostConfiguration<T::BlockNumber>,
) -> Weight {
let mut weight = Weight::zero();
for cause in causes {
weight += T::DbWeight::get().reads_writes(3, 2);
Self::deposit_event(Event::PvfCheckAccepted(*code_hash, cause.para_id()));
match cause {
PvfCheckCause::Onboarding(id) => {
weight += Self::proceed_with_onboarding(*id, sessions_observed);
},
PvfCheckCause::Upgrade { id, relay_parent_number } => {
weight +=
Self::proceed_with_upgrade(*id, code_hash, now, *relay_parent_number, cfg);
},
}
}
weight
}
fn proceed_with_onboarding(id: ParaId, sessions_observed: SessionIndex) -> Weight {
let weight = T::DbWeight::get().reads_writes(2, 1);
// we should onboard only after `SESSION_DELAY` sessions but we should take
// into account the number of sessions the PVF pre-checking occupied.
//
// we cannot onboard at the current session, so it must be at least one
// session ahead.
let onboard_at: SessionIndex = shared::Pallet::<T>::session_index() +
cmp::max(shared::SESSION_DELAY.saturating_sub(sessions_observed), 1);
ActionsQueue::<T>::mutate(onboard_at, |v| {
if let Err(i) = v.binary_search(&id) {
v.insert(i, id);
}
});
weight
}
fn proceed_with_upgrade(
id: ParaId,
code_hash: &ValidationCodeHash,
now: T::BlockNumber,
relay_parent_number: T::BlockNumber,
cfg: &configuration::HostConfiguration<T::BlockNumber>,
) -> Weight {
let mut weight = Weight::zero();
// Compute the relay-chain block number starting at which the code upgrade is ready to be
// applied.
//
// The first parablock that has a relay-parent higher or at the same height of `expected_at`
// will trigger the code upgrade. The parablock that comes after that will be validated
// against the new validation code.
//
// Here we are trying to choose the block number that will have `validation_upgrade_delay`
// blocks from the relay-parent of the block that schedule code upgrade but no less than
// `minimum_validation_upgrade_delay`. We want this delay out of caution so that when
// the last vote for pre-checking comes the parachain will have some time until the upgrade
// finally takes place.
let expected_at = cmp::max(
relay_parent_number + cfg.validation_upgrade_delay,
now + cfg.minimum_validation_upgrade_delay,
);
weight += T::DbWeight::get().reads_writes(1, 4);
FutureCodeUpgrades::<T>::insert(&id, expected_at);
<Self as Store>::UpcomingUpgrades::mutate(|upcoming_upgrades| {
let insert_idx = upcoming_upgrades
.binary_search_by_key(&expected_at, |&(_, b)| b)
.unwrap_or_else(|idx| idx);
upcoming_upgrades.insert(insert_idx, (id, expected_at));
});
let expected_at = expected_at.saturated_into();
let log = ConsensusLog::ParaScheduleUpgradeCode(id, *code_hash, expected_at);
<frame_system::Pallet<T>>::deposit_log(log.into());
weight
}
fn enact_pvf_rejected(
code_hash: &ValidationCodeHash,
causes: Vec<PvfCheckCause<T::BlockNumber>>,
) -> Weight {
let mut weight = Weight::zero();
for cause in causes {
// Whenever PVF pre-checking is started or a new cause is added to it, the RC is bumped.
// Now we need to unbump it.
weight += Self::decrease_code_ref(code_hash);
weight += T::DbWeight::get().reads_writes(3, 2);
Self::deposit_event(Event::PvfCheckRejected(*code_hash, cause.para_id()));
match cause {
PvfCheckCause::Onboarding(id) => {
// Here we need to undo everything that was done during `schedule_para_initialize`.
// Essentially, the logic is similar to offboarding, with exception that before
// actual onboarding the parachain did not have a chance to reach to upgrades.
// Therefore we can skip all the upgrade related storage items here.
weight += T::DbWeight::get().writes(3);
UpcomingParasGenesis::<T>::remove(&id);
CurrentCodeHash::<T>::remove(&id);
ParaLifecycles::<T>::remove(&id);
},
PvfCheckCause::Upgrade { id, .. } => {
weight += T::DbWeight::get().writes(2);
UpgradeGoAheadSignal::<T>::insert(&id, UpgradeGoAhead::Abort);
FutureCodeHash::<T>::remove(&id);
},
}
}
weight
}
/// Verify that `schedule_para_initialize` can be called successfully.
///
/// Returns false if para is already registered in the system.
pub fn can_schedule_para_initialize(id: &ParaId) -> bool {
ParaLifecycles::<T>::get(id).is_none()
}
/// Schedule a para to be initialized. If the validation code is not already stored in the
/// code storage, then a PVF pre-checking process will be initiated.
///
/// Only after the PVF pre-checking succeeds can the para be onboarded. Note, that calling this
/// does not guarantee that the parachain will eventually be onboarded. This can happen in case
/// the PVF does not pass PVF pre-checking.
///
/// The Para ID should be not activated in this pallet. The validation code supplied in
/// `genesis_data` should not be empty. If those conditions are not met, then the para cannot
/// be onboarded.
pub(crate) fn schedule_para_initialize(
id: ParaId,
mut genesis_data: ParaGenesisArgs,
) -> DispatchResult {
// Make sure parachain isn't already in our system and that the onboarding parameters are
// valid.
ensure!(Self::can_schedule_para_initialize(&id), Error::<T>::CannotOnboard);
ensure!(!genesis_data.validation_code.0.is_empty(), Error::<T>::CannotOnboard);
ParaLifecycles::<T>::insert(&id, ParaLifecycle::Onboarding);
// HACK: here we are doing something nasty.
//
// In order to fix the [soaking issue] we insert the code eagerly here. When the onboarding
// is finally enacted, we do not need to insert the code anymore. Therefore, there is no
// reason for the validation code to be copied into the `ParaGenesisArgs`. We also do not
// want to risk it by copying the validation code needlessly to not risk adding more
// memory pressure.
//
// That said, we also want to preserve `ParaGenesisArgs` as it is, for now. There are two
// reasons:
//
// - Doing it within the context of the PR that introduces this change is undesirable, since
// it is already a big change, and that change would require a migration. Moreover, if we
// run the new version of the runtime, there will be less things to worry about during
// the eventual proper migration.
//
// - This data type already is used for generating genesis, and changing it will probably
// introduce some unnecessary burden.
//
// So instead of going through it right now, we will do something sneaky. Specifically:
//
// - Insert the `CurrentCodeHash` now, instead during the onboarding. That would allow to
// get rid of hashing of the validation code when onboarding.
//
// - Replace `validation_code` with a sentinel value: an empty vector. This should be fine
// as long we do not allow registering parachains with empty code. At the moment of writing
// this should already be the case.
//
// - Empty value is treated as the current code is already inserted during the onboarding.
//
// This is only an intermediate solution and should be fixed in foreseable future.
//
// [soaking issue]: https://github.com/paritytech/polkadot/issues/3918
let validation_code =
mem::replace(&mut genesis_data.validation_code, ValidationCode(Vec::new()));
UpcomingParasGenesis::<T>::insert(&id, genesis_data);
let validation_code_hash = validation_code.hash();
<Self as Store>::CurrentCodeHash::insert(&id, validation_code_hash);
let cfg = configuration::Pallet::<T>::config();
Self::kick_off_pvf_check(
PvfCheckCause::Onboarding(id),
validation_code_hash,
validation_code,
&cfg,
);
Ok(())
}
/// Schedule a para to be cleaned up at the start of the next session.
///
/// Will return error if either is true:
///
/// - para is not a stable parachain or parathread (i.e. [`ParaLifecycle::is_stable`] is `false`)
/// - para has a pending upgrade.
///
/// No-op if para is not registered at all.
pub(crate) fn schedule_para_cleanup(id: ParaId) -> DispatchResult {
// Disallow offboarding in case there is a PVF pre-checking in progress.
//
// This is not a fundamential limitation but rather simplification: it allows us to get
// away without introducing additional logic for pruning and, more importantly, enacting
// ongoing PVF pre-checking votes. It also removes some nasty edge cases.
//
// However, an upcoming upgrade on its own imposes no restrictions. An upgrade is enacted
// with a new para head, so if a para never progresses we still should be able to offboard it.
//
// This implicitly assumes that the given para exists, i.e. it's lifecycle != None.
if let Some(future_code_hash) = FutureCodeHash::<T>::get(&id) {
let active_prechecking = PvfActiveVoteList::<T>::get();
if active_prechecking.contains(&future_code_hash) {
return Err(Error::<T>::CannotOffboard.into())
}
}
let lifecycle = ParaLifecycles::<T>::get(&id);
match lifecycle {
// If para is not registered, nothing to do!
None => return Ok(()),
Some(ParaLifecycle::Parathread) => {
ParaLifecycles::<T>::insert(&id, ParaLifecycle::OffboardingParathread);
},
Some(ParaLifecycle::Parachain) => {
ParaLifecycles::<T>::insert(&id, ParaLifecycle::OffboardingParachain);
},
_ => return Err(Error::<T>::CannotOffboard)?,
}
let scheduled_session = Self::scheduled_session();
ActionsQueue::<T>::mutate(scheduled_session, |v| {
if let Err(i) = v.binary_search(&id) {
v.insert(i, id);
}
});
Ok(())
}
/// Schedule a parathread to be upgraded to a parachain.
///
/// Will return error if `ParaLifecycle` is not `Parathread`.
pub(crate) fn schedule_parathread_upgrade(id: ParaId) -> DispatchResult {
let scheduled_session = Self::scheduled_session();
let lifecycle = ParaLifecycles::<T>::get(&id).ok_or(Error::<T>::NotRegistered)?;
ensure!(lifecycle == ParaLifecycle::Parathread, Error::<T>::CannotUpgrade);
ParaLifecycles::<T>::insert(&id, ParaLifecycle::UpgradingParathread);
ActionsQueue::<T>::mutate(scheduled_session, |v| {
if let Err(i) = v.binary_search(&id) {
v.insert(i, id);
}
});
Ok(())
}
/// Schedule a parachain to be downgraded to a parathread.
///
/// Noop if `ParaLifecycle` is not `Parachain`.
pub(crate) fn schedule_parachain_downgrade(id: ParaId) -> DispatchResult {
let scheduled_session = Self::scheduled_session();
let lifecycle = ParaLifecycles::<T>::get(&id).ok_or(Error::<T>::NotRegistered)?;
ensure!(lifecycle == ParaLifecycle::Parachain, Error::<T>::CannotDowngrade);
ParaLifecycles::<T>::insert(&id, ParaLifecycle::DowngradingParachain);
ActionsQueue::<T>::mutate(scheduled_session, |v| {
if let Err(i) = v.binary_search(&id) {
v.insert(i, id);
}
});
Ok(())
}
/// Schedule a future code upgrade of the given parachain.
///
/// If the new code is not known, then the PVF pre-checking will be started for that validation
/// code. In case the validation code does not pass the PVF pre-checking process, the
/// upgrade will be aborted.
///
/// Only after the code is approved by the process, the upgrade can be scheduled. Specifically,
/// the relay-chain block number will be determined at which the upgrade will take place. We
/// call that block `expected_at`.
///
/// Once the candidate with the relay-parent >= `expected_at` is enacted, the new validation code
/// will be applied. Therefore, the new code will be used to validate the next candidate.
///
/// The new code should not be equal to the current one, otherwise the upgrade will be aborted.
/// If there is already a scheduled code upgrade for the para, this is a no-op.
pub(crate) fn schedule_code_upgrade(
id: ParaId,
new_code: ValidationCode,
relay_parent_number: T::BlockNumber,
cfg: &configuration::HostConfiguration<T::BlockNumber>,
) -> Weight {
let mut weight = T::DbWeight::get().reads(1);
// Enacting this should be prevented by the `can_schedule_upgrade`
if FutureCodeHash::<T>::contains_key(&id) {
// This branch should never be reached. Signalling an upgrade is disallowed for a para
// that already has one upgrade scheduled.
//
// Any candidate that attempts to do that should be rejected by
// `can_upgrade_validation_code`.
//
// NOTE: we cannot set `UpgradeGoAheadSignal` signal here since this will be reset by
// the following call `note_new_head`
log::warn!(target: LOG_TARGET, "ended up scheduling an upgrade while one is pending",);
return weight
}
let code_hash = new_code.hash();
// para signals an update to the same code? This does not make a lot of sense, so abort the
// process right away.
//
// We do not want to allow this since it will mess with the code reference counting.
weight += T::DbWeight::get().reads(1);
if CurrentCodeHash::<T>::get(&id) == Some(code_hash) {
// NOTE: we cannot set `UpgradeGoAheadSignal` signal here since this will be reset by
// the following call `note_new_head`
log::warn!(
target: LOG_TARGET,
"para tried to upgrade to the same code. Abort the upgrade",
);
return weight
}
// This is the start of the upgrade process. Prevent any further attempts at upgrading.
weight += T::DbWeight::get().writes(2);
FutureCodeHash::<T>::insert(&id, &code_hash);
UpgradeRestrictionSignal::<T>::insert(&id, UpgradeRestriction::Present);
weight += T::DbWeight::get().reads_writes(1, 1);
let next_possible_upgrade_at = relay_parent_number + cfg.validation_upgrade_cooldown;
<Self as Store>::UpgradeCooldowns::mutate(|upgrade_cooldowns| {
let insert_idx = upgrade_cooldowns
.binary_search_by_key(&next_possible_upgrade_at, |&(_, b)| b)
.unwrap_or_else(|idx| idx);
upgrade_cooldowns.insert(insert_idx, (id, next_possible_upgrade_at));
});
weight += Self::kick_off_pvf_check(
PvfCheckCause::Upgrade { id, relay_parent_number },
code_hash,
new_code,
cfg,
);
weight
}
/// Makes sure that the given code hash has passed pre-checking.
///
/// If the given code hash has already passed pre-checking, then the approval happens
/// immediately. Similarly, if the pre-checking is turned off, the update is scheduled immediately
/// as well. In this case, the behavior is similar to the previous, i.e. the upgrade sequence
/// is purely time-based.
///
/// If the code is unknown, but the pre-checking for that PVF is already running then we perform
/// "coalescing". We save the cause for this PVF pre-check request and just add it to the
/// existing active PVF vote.
///
/// And finally, if the code is unknown and pre-checking is not running, we start the
/// pre-checking process anew.
///
/// Unconditionally increases the reference count for the passed `code`.
fn kick_off_pvf_check(
cause: PvfCheckCause<T::BlockNumber>,
code_hash: ValidationCodeHash,
code: ValidationCode,
cfg: &configuration::HostConfiguration<T::BlockNumber>,
) -> Weight {
let mut weight = Weight::zero();
weight += T::DbWeight::get().reads_writes(3, 2);
Self::deposit_event(Event::PvfCheckStarted(code_hash, cause.para_id()));
weight += T::DbWeight::get().reads(1);
match PvfActiveVoteMap::<T>::get(&code_hash) {
None => {
// We deliberately are using `CodeByHash` here instead of the `CodeByHashRefs`. This
// is because the code may have been added by `add_trusted_validation_code`.
let known_code = CodeByHash::<T>::contains_key(&code_hash);
weight += T::DbWeight::get().reads(1);
if !cfg.pvf_checking_enabled || known_code {
// Either:
// - the code is known and there is no active PVF vote for it meaning it is
// already checked, or
// - the PVF checking is diabled
// In any case: fast track the PVF checking into the accepted state
weight += T::DbWeight::get().reads(1);
let now = <frame_system::Pallet<T>>::block_number();
weight += Self::enact_pvf_accepted(now, &code_hash, &[cause], 0, cfg);
} else {
// PVF is not being pre-checked and it is not known. Start a new pre-checking
// process.
weight += T::DbWeight::get().reads_writes(3, 2);
let now = <frame_system::Pallet<T>>::block_number();
let n_validators = shared::Pallet::<T>::active_validator_keys().len();
PvfActiveVoteMap::<T>::insert(
&code_hash,
PvfCheckActiveVoteState::new(now, n_validators, cause),
);
PvfActiveVoteList::<T>::mutate(|l| {
if let Err(idx) = l.binary_search(&code_hash) {
l.insert(idx, code_hash);
}
});
}
},
Some(mut vote_state) => {
// Coalescing: the PVF is already being pre-checked so we just need to piggy back
// on it.
weight += T::DbWeight::get().writes(1);
vote_state.causes.push(cause);
PvfActiveVoteMap::<T>::insert(&code_hash, vote_state);
},
}
// We increase the code RC here in any case. Intuitively the parachain that requested this
// action is now a user of that PVF.
//
// If the result of the pre-checking is reject, then we would decrease the RC for each cause,
// including the current.
//
// If the result of the pre-checking is accept, then we do nothing to the RC because the PVF
// will continue be used by the same users.
//
// If the PVF was fast-tracked (i.e. there is already non zero RC) and there is no
// pre-checking, we also do not change the RC then.
weight += Self::increase_code_ref(&code_hash, &code);
weight
}
/// Note that a para has progressed to a new head, where the new head was executed in the context
/// of a relay-chain block with given number. This will apply pending code upgrades based
/// on the relay-parent block number provided.
pub(crate) fn note_new_head(
id: ParaId,
new_head: HeadData,
execution_context: T::BlockNumber,
) -> Weight {
Heads::<T>::insert(&id, new_head);
if let Some(expected_at) = <Self as Store>::FutureCodeUpgrades::get(&id) {
if expected_at <= execution_context {
<Self as Store>::FutureCodeUpgrades::remove(&id);
<Self as Store>::UpgradeGoAheadSignal::remove(&id);
// Both should always be `Some` in this case, since a code upgrade is scheduled.
let new_code_hash = if let Some(new_code_hash) = FutureCodeHash::<T>::take(&id) {
new_code_hash
} else {
log::error!(target: LOG_TARGET, "Missing future code hash for {:?}", &id);
return T::DbWeight::get().reads_writes(3, 1 + 3)
};
let maybe_prior_code_hash = CurrentCodeHash::<T>::get(&id);
CurrentCodeHash::<T>::insert(&id, &new_code_hash);
let log = ConsensusLog::ParaUpgradeCode(id, new_code_hash);
<frame_system::Pallet<T>>::deposit_log(log.into());
// `now` is only used for registering pruning as part of `fn note_past_code`
let now = <frame_system::Pallet<T>>::block_number();
let weight = if let Some(prior_code_hash) = maybe_prior_code_hash {
Self::note_past_code(id, expected_at, now, prior_code_hash)
} else {
log::error!(target: LOG_TARGET, "Missing prior code hash for para {:?}", &id);
Weight::zero()
};
// add 1 to writes due to heads update.
weight + T::DbWeight::get().reads_writes(3, 1 + 3)
} else {
T::DbWeight::get().reads_writes(1, 1 + 0)
}
} else {
// This means there is no upgrade scheduled.
//
// In case the upgrade was aborted by the relay-chain we should reset
// the `Abort` signal.
UpgradeGoAheadSignal::<T>::remove(&id);
T::DbWeight::get().reads_writes(1, 2)
}
}
/// Returns the list of PVFs (aka validation code) that require casting a vote by a validator in
/// the active validator set.
pub(crate) fn pvfs_require_precheck() -> Vec<ValidationCodeHash> {
PvfActiveVoteList::<T>::get()
}
/// Submits a given PVF check statement with corresponding signature as an unsigned transaction
/// into the memory pool. Ultimately, that disseminates the transaction accross the network.
///
/// This function expects an offchain context and cannot be callable from the on-chain logic.
///
/// The signature assumed to pertain to `stmt`.
pub(crate) fn submit_pvf_check_statement(
stmt: PvfCheckStatement,
signature: ValidatorSignature,
) {
use frame_system::offchain::SubmitTransaction;
if let Err(e) = SubmitTransaction::<T, Call<T>>::submit_unsigned_transaction(
Call::include_pvf_check_statement { stmt, signature }.into(),
) {
log::error!(target: LOG_TARGET, "Error submitting pvf check statement: {:?}", e,);
}
}
/// Returns the current lifecycle state of the para.
pub fn lifecycle(id: ParaId) -> Option<ParaLifecycle> {
ParaLifecycles::<T>::get(&id)
}
/// Returns whether the given ID refers to a valid para.
///
/// Paras that are onboarding or offboarding are not included.
pub fn is_valid_para(id: ParaId) -> bool {
if let Some(state) = ParaLifecycles::<T>::get(&id) {
!state.is_onboarding() && !state.is_offboarding()
} else {
false
}
}
/// Whether a para ID corresponds to any live parachain.
///
/// Includes parachains which will downgrade to a parathread in the future.
pub fn is_parachain(id: ParaId) -> bool {
if let Some(state) = ParaLifecycles::<T>::get(&id) {
state.is_parachain()
} else {
false
}
}
/// Whether a para ID corresponds to any live parathread.
///
/// Includes parathreads which will upgrade to parachains in the future.
pub fn is_parathread(id: ParaId) -> bool {
if let Some(state) = ParaLifecycles::<T>::get(&id) {
state.is_parathread()
} else {
false
}
}
/// If a candidate from the specified parachain were submitted at the current block, this
/// function returns if that candidate passes the acceptance criteria.
pub(crate) fn can_upgrade_validation_code(id: ParaId) -> bool {
FutureCodeHash::<T>::get(&id).is_none() && UpgradeRestrictionSignal::<T>::get(&id).is_none()
}
/// Return the session index that should be used for any future scheduled changes.
fn scheduled_session() -> SessionIndex {
shared::Pallet::<T>::scheduled_session()
}
/// Store the validation code if not already stored, and increase the number of reference.
///
/// Returns the weight consumed.
fn increase_code_ref(code_hash: &ValidationCodeHash, code: &ValidationCode) -> Weight {
let mut weight = T::DbWeight::get().reads_writes(1, 1);
<Self as Store>::CodeByHashRefs::mutate(code_hash, |refs| {
if *refs == 0 {
weight += T::DbWeight::get().writes(1);
<Self as Store>::CodeByHash::insert(code_hash, code);
}
*refs += 1;
});
weight
}
/// Decrease the number of reference of the validation code and remove it from storage if zero
/// is reached.
///
/// Returns the weight consumed.
fn decrease_code_ref(code_hash: &ValidationCodeHash) -> Weight {
let mut weight = T::DbWeight::get().reads(1);
let refs = <Self as Store>::CodeByHashRefs::get(code_hash);
if refs == 0 {
log::error!(target: LOG_TARGET, "Code refs is already zero for {:?}", code_hash);
return weight
}
if refs <= 1 {
weight += T::DbWeight::get().writes(2);
<Self as Store>::CodeByHash::remove(code_hash);
<Self as Store>::CodeByHashRefs::remove(code_hash);
} else {
weight += T::DbWeight::get().writes(1);
<Self as Store>::CodeByHashRefs::insert(code_hash, refs - 1);
}
weight
}
/// Test function for triggering a new session in this pallet.
#[cfg(any(feature = "std", feature = "runtime-benchmarks", test))]
pub fn test_on_new_session() {
Self::initializer_on_new_session(&SessionChangeNotification {
session_index: shared::Pallet::<T>::session_index(),
..Default::default()
});
}
#[cfg(any(feature = "runtime-benchmarks", test))]
pub fn heads_insert(para_id: &ParaId, head_data: HeadData) {
Heads::<T>::insert(para_id, head_data);
}
/// A low-level function to eagerly initialize a given para.
pub(crate) fn initialize_para_now(
parachains: &mut ParachainsCache<T>,
id: ParaId,
genesis_data: &ParaGenesisArgs,
) {
match genesis_data.para_kind {
ParaKind::Parachain => {
parachains.add(id);
ParaLifecycles::<T>::insert(&id, ParaLifecycle::Parachain);
},
ParaKind::Parathread => ParaLifecycles::<T>::insert(&id, ParaLifecycle::Parathread),
}
// HACK: see the notice in `schedule_para_initialize`.
//
// Apparently, this is left over from a prior version of the runtime.
// To handle this we just insert the code and link the current code hash
// to it.
if !genesis_data.validation_code.0.is_empty() {
let code_hash = genesis_data.validation_code.hash();
Self::increase_code_ref(&code_hash, &genesis_data.validation_code);
CurrentCodeHash::<T>::insert(&id, code_hash);
}
Heads::<T>::insert(&id, &genesis_data.genesis_head);
}
}
/// An overlay over the `Parachains` storage entry that provides a convenient interface for adding
/// or removing parachains in bulk.
pub(crate) struct ParachainsCache<T: Config> {
// `None` here means the parachains list has not been accessed yet, nevermind modified.
parachains: Option<Vec<ParaId>>,
_config: PhantomData<T>,
}
impl<T: Config> ParachainsCache<T> {
pub fn new() -> Self {
Self { parachains: None, _config: PhantomData }
}
fn ensure_initialized(&mut self) -> &mut Vec<ParaId> {
self.parachains.get_or_insert_with(|| Parachains::<T>::get())
}
/// Adds the given para id to the list.
pub fn add(&mut self, id: ParaId) {
let parachains = self.ensure_initialized();
if let Err(i) = parachains.binary_search(&id) {
parachains.insert(i, id);
}
}
/// Removes the given para id from the list of parachains. Does nothing if the id is not in the
/// list.
pub fn remove(&mut self, id: ParaId) {
let parachains = self.ensure_initialized();
if let Ok(i) = parachains.binary_search(&id) {
parachains.remove(i);
}
}
}
impl<T: Config> Drop for ParachainsCache<T> {
fn drop(&mut self) {
if let Some(parachains) = self.parachains.take() {
Parachains::<T>::put(&parachains);
}
}
}
Reference in New Issue View Git Blame Copy Permalink