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// 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 is responsible for storing data on parachains and parathreads.
//!
//! It tracks which paras are parachains, what their current head data is in
//! this fork of the relay chain, what their validation code is, and what their past and upcoming
//! validation code is.
//!
//! A para is not considered live until it is registered and activated in this pallet. Activation can
//! only occur at session boundaries.

use crate::{configuration, initializer::SessionChangeNotification, shared};
use frame_support::pallet_prelude::*;
use frame_system::pallet_prelude::*;
use parity_scale_codec::{Decode, Encode};
use primitives::v1::{
	ConsensusLog, HeadData, Id as ParaId, SessionIndex, UpgradeGoAhead, UpgradeRestriction,
	ValidationCode, ValidationCodeHash,
use sp_core::RuntimeDebug;
use sp_runtime::{traits::One, DispatchResult, SaturatedConversion};
use sp_std::{prelude::*, result};

#[cfg(feature = "std")]
use serde::{Deserialize, Serialize};
pub use crate::Origin as ParachainOrigin;
pub use pallet::*;

// 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>,
}

#[cfg_attr(test, derive(Debug, PartialEq))]
enum UseCodeAt<N> {
	/// Use the current code.
	Current,
	/// Use the code that was replaced at the given block number.
	/// This is an inclusive endpoint - a parablock in the context of a relay-chain block on this fork
	/// with number N should use the code that is replaced at N.
	ReplacedAt(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.
	/// 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,
	/// 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.
	fn note_replacement(&mut self, expected_at: N, activated_at: N) {
		self.upgrade_times.push(ReplacementTimes { expected_at, activated_at })
	}

	// Yields an identifier that should be used for validating a
	// parablock in the context of a particular relay-chain block number in this chain.
	//
	// a return value of `None` means that there is no code we are aware of that
	// should be used to validate at the given height.
	fn code_at(&self, para_at: N) -> Option<UseCodeAt<N>> {
		// Find out
		// a) if there is a point where code was replaced in the current chain after the context
		//    we are finding out code for.
		// b) what the index of that point is.
		//
		// The reason we use `activated_at` instead of `expected_at` is that a gap may occur
		// between expectation and actual activation. Any block executed in a context from
		// `expected_at..activated_at` is expected to activate the code upgrade and therefore should
		// use the previous code.
		//
		// A block executed in the context of `activated_at` should use the new code.
		//
		// Cases where `expected_at` and `activated_at` are the same, that is, zero-delay code upgrades
		// are also handled by this rule correctly.
		let replaced_after_pos = self.upgrade_times.iter().position(|t| {
			// example: code replaced at (5, 5)
			//
			// context #4 should use old code
			// context #5 should use new code
			//
			// example: code replaced at (10, 20)
			// context #9 should use the old code
			// context #10 should use the old code
			// context #19 should use the old code
			// context #20 should use the new code
			para_at < t.activated_at
		});

		if let Some(replaced_after_pos) = replaced_after_pos {
			// The earliest stored code replacement needs to be special-cased, since we need to check
			// against the pruning state to see if this replacement represents the correct code, or
			// is simply after a replacement that actually represents the correct code, but has been pruned.
			let was_pruned =
				replaced_after_pos == 0 && self.last_pruned.map_or(false, |t| t >= para_at);

			if was_pruned {
				None
			} else {
				Some(UseCodeAt::ReplacedAt(self.upgrade_times[replaced_after_pos].expected_at))
			}
		} else {
			// No code replacements after this context.
			// This means either that the current code is valid, or `para_at` is so old that
			// we don't know the code necessary anymore. Compare against `last_pruned` to determine.
			self.last_pruned.as_ref().map_or(
				Some(UseCodeAt::Current), // nothing pruned, use current
				|earliest_activation| {
					if &para_at < earliest_activation {
						None
					} else {
						Some(UseCodeAt::Current)
					}
			)
		}
	}

	// The block at which the most recently tracked code change occurred, from the perspective
	// of the para.
	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,
	/// True if parachain, false if parathread.
	pub parachain: bool,
#[frame_support::pallet]
pub mod pallet {
	use super::*;

	#[pallet::pallet]
	#[pallet::generate_store(pub(super) trait Store)]
	pub struct Pallet<T>(_);

	#[pallet::config]
	pub trait Config: frame_system::Config + configuration::Config + shared::Config {
		/// The outer origin type.
		type Origin: From<Origin>
			+ From<<Self as frame_system::Config>::Origin>
			+ Into<result::Result<Origin, <Self as Config>::Origin>>;

		type Event: From<Event> + IsType<<Self as frame_system::Config>::Event>;
	#[pallet::event]
	#[pallet::generate_deposit(pub(super) fn deposit_event)]
	pub enum Event {
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		/// Current code has been updated for a Para. `para_id`
		CurrentCodeUpdated(ParaId),
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		/// Current head has been updated for a Para. `para_id`
		CurrentHeadUpdated(ParaId),
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		/// A code upgrade has been scheduled for a Para. `para_id`
		CodeUpgradeScheduled(ParaId),
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		/// A new head has been noted for a Para. `para_id`
		NewHeadNoted(ParaId),
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		/// A para has been queued to execute pending actions. `para_id`
		ActionQueued(ParaId, SessionIndex),
	#[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,
	}
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	/// All parachains. Ordered ascending by `ParaId`. Parathreads are not included.
	#[pallet::storage]
	#[pallet::getter(fn parachains)]
	pub(super) 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]
	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.
	#[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: Vec<_> = self
				.paras
				.iter()
				.filter(|(_, args)| args.parachain)
				.map(|&(ref id, _)| id)
				.cloned()
				.collect();

			parachains.sort();
			parachains.dedup();

			Parachains::<T>::put(&parachains);

			for (id, genesis_args) in &self.paras {
				let code_hash = genesis_args.validation_code.hash();
				<Pallet<T>>::increase_code_ref(&code_hash, &genesis_args.validation_code);
				<Pallet<T> as Store>::CurrentCodeHash::insert(&id, &code_hash);
				<Pallet<T> as Store>::Heads::insert(&id, &genesis_args.genesis_head);
				if genesis_args.parachain {
					ParaLifecycles::<T>::insert(&id, ParaLifecycle::Parachain);
				} else {
					ParaLifecycles::<T>::insert(&id, ParaLifecycle::Parathread);
				}
			}
		}
	}
	#[pallet::origin]
	pub type Origin = ParachainOrigin;
	#[pallet::call]
	impl<T: Config> Pallet<T> {
		/// Set the storage for the parachain validation code immediately.
		#[pallet::weight(0)]
		pub fn force_set_current_code(
			origin: OriginFor<T>,
			para: ParaId,
			new_code: ValidationCode,
		) -> DispatchResult {
			ensure_root(origin)?;
			let prior_code_hash = <Self as Store>::CurrentCodeHash::get(&para).unwrap_or_default();
			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();
			Self::note_past_code(para, now, now, prior_code_hash);
			Self::deposit_event(Event::CurrentCodeUpdated(para));
			Ok(())
		}

		/// Set the storage for the current parachain head data immediately.
		#[pallet::weight(0)]
		pub fn force_set_current_head(
			origin: OriginFor<T>,
			para: ParaId,
			new_head: HeadData,
		) -> DispatchResult {
			ensure_root(origin)?;
			<Self as Store>::Heads::insert(&para, new_head);
			Self::deposit_event(Event::CurrentHeadUpdated(para));
			Ok(())
		/// Schedule an upgrade as if it was scheduled in the given relay parent block.
		#[pallet::weight(0)]
		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(0)]
		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(0)]
		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(())
impl<T: Config> Pallet<T> {
	/// Called by the initializer to initialize the configuration 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 configuration pallet.
	pub(crate) fn initializer_finalize() {}

	/// 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);
		outgoing_paras
	/// The validation code of live para.
	pub(crate) fn current_code(para_id: &ParaId) -> Option<ValidationCode> {
		CurrentCodeHash::<T>::get(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 = <Self as Store>::Parachains::get();
		let now = <frame_system::Pallet<T>>::block_number();
		let mut outgoing = Vec::new();

		for para in actions {
			let lifecycle = ParaLifecycles::<T>::get(&para);
				None | Some(ParaLifecycle::Parathread) | Some(ParaLifecycle::Parachain) => { /* Nothing to do... */
				},
				// Onboard a new parathread or parachain.
				Some(ParaLifecycle::Onboarding) => {
					if let Some(genesis_data) = <Self as Store>::UpcomingParasGenesis::take(&para) {
						if genesis_data.parachain {
							if let Err(i) = parachains.binary_search(&para) {
								parachains.insert(i, para);
							}
							ParaLifecycles::<T>::insert(&para, ParaLifecycle::Parachain);
							ParaLifecycles::<T>::insert(&para, ParaLifecycle::Parathread);
						let code_hash = genesis_data.validation_code.hash();
						<Self as Store>::Heads::insert(&para, genesis_data.genesis_head);
						Self::increase_code_ref(&code_hash, &genesis_data.validation_code);
						<Self as Store>::CurrentCodeHash::insert(&para, code_hash);
					}
				},
				// Upgrade a parathread to a parachain
				Some(ParaLifecycle::UpgradingParathread) => {
					if let Err(i) = parachains.binary_search(&para) {
						parachains.insert(i, para);
					}
					ParaLifecycles::<T>::insert(&para, ParaLifecycle::Parachain);
				},
				// Downgrade a parachain to a parathread
				Some(ParaLifecycle::DowngradingParachain) => {
					if let Ok(i) = parachains.binary_search(&para) {
						parachains.remove(i);
					}
					ParaLifecycles::<T>::insert(&para, ParaLifecycle::Parathread);
				},
				// Offboard a parathread or parachain from the system
				Some(ParaLifecycle::OffboardingParachain) |
				Some(ParaLifecycle::OffboardingParathread) => {
					if let Ok(i) = parachains.binary_search(&para) {
						parachains.remove(i);
					}

					<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);
		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 = sp_std::mem::take(upcoming_upgrades)
					.into_iter()
					.filter(|&(ref para, _)| !outgoing.contains(para))
					.collect();
			});
			<Self as Store>::UpgradeCooldowns::mutate(|upgrade_cooldowns| {
				*upgrade_cooldowns = sp_std::mem::take(upgrade_cooldowns)
					.into_iter()
					.filter(|&(ref para, _)| !outgoing.contains(para))
					.collect();
			});
		}

		// Place the new parachains set in storage.
		<Self as Store>::Parachains::set(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(&at, |&(_, 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: "runtime::paras",
									"Missing code for removed hash {:?}",
									removed_code_hash,
								);
							}
						meta.most_recent_change().is_none() && 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.
	///
	/// Takes the current block number and returns the weight consumed.
	fn process_scheduled_upgrade_changes(now: T::BlockNumber) -> Weight {
		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
			},
		);
		let cooldowns_expired = <Self as Store>::UpgradeCooldowns::mutate(
			|upgrade_cooldowns: &mut Vec<(ParaId, T::BlockNumber)>| {
				let num = upgrade_cooldowns.iter().take_while(|&(_, at)| at <= &now).count();
				for (para, _) in upgrade_cooldowns.drain(..num) {
					<Self as Store>::UpgradeRestrictionSignal::remove(&para);
				}
				num
			},
		);

		T::DbWeight::get().reads_writes(2, upgrades_signaled as u64 + cooldowns_expired as u64)
	}

	/// 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, _: &ParaGenesisArgs) -> bool {
		let lifecycle = ParaLifecycles::<T>::get(id);
	/// Schedule a para to be initialized at the start of the next session.
	/// Will return error if para is already registered in the system.
	pub(crate) fn schedule_para_initialize(id: ParaId, genesis: ParaGenesisArgs) -> DispatchResult {
		let scheduled_session = Self::scheduled_session();

		// Make sure parachain isn't already in our system.
		ensure!(Self::can_schedule_para_initialize(&id, &genesis), Error::<T>::CannotOnboard);
		ParaLifecycles::<T>::insert(&id, ParaLifecycle::Onboarding);
		UpcomingParasGenesis::<T>::insert(&id, genesis);
		ActionsQueue::<T>::mutate(scheduled_session, |v| {
			if let Err(i) = v.binary_search(&id) {
				v.insert(i, id);
	}

	/// Schedule a para to be cleaned up at the start of the next session.
	/// Will return error if para is not a stable parachain or parathread.
	///
	/// No-op if para is not registered at all.
	pub(crate) fn schedule_para_cleanup(id: ParaId) -> DispatchResult {
		let lifecycle = ParaLifecycles::<T>::get(&id);
			// 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);
	}

	/// 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);
	}

	/// Schedule a future code upgrade of the given parachain, to be applied after inclusion
	/// of a block of the same parachain executed in the context of a relay-chain block
	/// with number >= `expected_at`
	///
	/// 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 {
		<Self as Store>::FutureCodeUpgrades::mutate(&id, |up| {
			if up.is_some() {
				T::DbWeight::get().reads_writes(1, 0)
			} else {
				let expected_at = relay_parent_number + cfg.validation_upgrade_delay;
				let next_possible_upgrade_at =
					relay_parent_number + cfg.validation_upgrade_frequency;

				*up = Some(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));
				});

				// From the moment of signalling of the upgrade until the cooldown expires, the
				// parachain is disallowed to make further upgrades. Therefore set the upgrade
				// permission signal to disallowed and activate the cooldown timer.
				<Self as Store>::UpgradeRestrictionSignal::insert(&id, UpgradeRestriction::Present);
				<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));
				});

				let new_code_hash = new_code.hash();
				let expected_at_u32 = expected_at.saturated_into();
				let log = ConsensusLog::ParaScheduleUpgradeCode(id, new_code_hash, expected_at_u32);
				<frame_system::Pallet<T>>::deposit_log(log.into());

				let (reads, writes) = Self::increase_code_ref(&new_code_hash, &new_code);
				FutureCodeHash::<T>::insert(&id, new_code_hash);
				T::DbWeight::get().reads_writes(2 + reads, 3 + writes)
			}
		})
	}

	/// 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 = FutureCodeHash::<T>::take(&id).unwrap_or_default();
				let prior_code_hash = CurrentCodeHash::<T>::get(&id).unwrap_or_default();
				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 = Self::note_past_code(id, expected_at, now, prior_code_hash);

				// add 1 to writes due to heads update.
				weight + T::DbWeight::get().reads_writes(3, 1 + 3)