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// This file is part of Substrate.
// Copyright (C) 2017-2022 Parity Technologies (UK) Ltd.
// SPDX-License-Identifier: Apache-2.0
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
//! # Staking Pallet
//! The Staking pallet is used to manage funds at stake by network maintainers.
//! The Staking pallet is the means by which a set of network maintainers (known as _authorities_ in
//! some contexts and _validators_ in others) are chosen based upon those who voluntarily place
//! funds under deposit. Under deposit, those funds are rewarded under normal operation but are held
//! at pain of _slash_ (expropriation) should the staked maintainer be found not to be discharging
//! its duties properly.
//! ### Terminology
//! <!-- Original author of paragraph: @gavofyork -->
//!
//! - Staking: The process of locking up funds for some time, placing them at risk of slashing
//! (loss) in order to become a rewarded maintainer of the network.
//! - Validating: The process of running a node to actively maintain the network, either by
//! producing blocks or guaranteeing finality of the chain.
//! - Nominating: The process of placing staked funds behind one or more validators in order to
//! share in any reward, and punishment, they take.
//! - Stash account: The account holding an owner's funds used for staking.
//! - Controller account: The account that controls an owner's funds for staking.
//! - Era: A (whole) number of sessions, which is the period that the validator set (and each
//! validator's active nominator set) is recalculated and where rewards are paid out.
//! - Slash: The punishment of a staker by reducing its funds.
//!
//! ### Goals
//! <!-- Original author of paragraph: @gavofyork -->
//!
//! The staking system in Substrate NPoS is designed to make the following possible:
//! - Stake funds that are controlled by a cold wallet.
//! - Withdraw some, or deposit more, funds without interrupting the role of an entity.
//! - Switch between roles (nominator, validator, idle) with minimal overhead.
//!
//! ### Scenarios
//!
//! #### Staking
//!
//! Almost any interaction with the Staking pallet requires a process of _**bonding**_ (also known
//! as being a _staker_). To become *bonded*, a fund-holding register known as the _stash account_,
//! which holds some or all of the funds that become frozen in place as part of the staking process,
//! is paired with an active **controller** account, which issues instructions on how they shall be
//! used.
//! An account pair can become bonded using the [`bond`](Call::bond) call.
//! Stash accounts can change their associated controller using the
//! There are three possible roles that any staked account pair can be in: `Validator`, `Nominator`
//! and `Idle` (defined in [`StakerStatus`]). There are three
//! corresponding instructions to change between roles, namely:
//! [`validate`](Call::validate),
//! [`nominate`](Call::nominate), and [`chill`](Call::chill).
//!
//! #### Validating
//!
//! A **validator** takes the role of either validating blocks or ensuring their finality,
//! maintaining the veracity of the network. A validator should avoid both any sort of malicious
//! misbehavior and going offline. Bonded accounts that state interest in being a validator do NOT
//! get immediately chosen as a validator. Instead, they are declared as a _candidate_ and they
//! _might_ get elected at the _next era_ as a validator. The result of the election is determined
//! by nominators and their votes.
//! An account can become a validator candidate via the
//!
//! #### Nomination
//!
//! A **nominator** does not take any _direct_ role in maintaining the network, instead, it votes on
//! a set of validators to be elected. Once interest in nomination is stated by an account, it
//! takes effect at the next election round. The funds in the nominator's stash account indicate the
//! _weight_ of its vote. Both the rewards and any punishment that a validator earns are shared
//! between the validator and its nominators. This rule incentivizes the nominators to NOT vote for
//! the misbehaving/offline validators as much as possible, simply because the nominators will also
//! lose funds if they vote poorly.
//! An account can become a nominator via the [`nominate`](Call::nominate) call.
//! #### Voting
//!
//! Staking is closely related to elections; actual validators are chosen from among all potential
//! validators via election by the potential validators and nominators. To reduce use of the phrase
//! "potential validators and nominators", we often use the term **voters**, who are simply
//! the union of potential validators and nominators.
//!
//! #### Rewards and Slash
//!
//! The **reward and slashing** procedure is the core of the Staking pallet, attempting to _embrace
//! valid behavior_ while _punishing any misbehavior or lack of availability_.
//! Rewards must be claimed for each era before it gets too old by `$HISTORY_DEPTH` using the
//! `payout_stakers` call. Any account can call `payout_stakers`, which pays the reward to the
//! validator as well as its nominators. Only the [`Config::MaxNominatorRewardedPerValidator`]
//! biggest stakers can claim their reward. This is to limit the i/o cost to mutate storage for each
//! nominator's account.
//! Slashing can occur at any point in time, once misbehavior is reported. Once slashing is
//! determined, a value is deducted from the balance of the validator and all the nominators who
//! voted for this validator (values are deducted from the _stash_ account of the slashed entity).
//! Slashing logic is further described in the documentation of the `slashing` pallet.
//! Similar to slashing, rewards are also shared among a validator and its associated nominators.
//! Yet, the reward funds are not always transferred to the stash account and can be configured. See
//! [Reward Calculation](#reward-calculation) for more details.
//!
//! #### Chilling
//! Finally, any of the roles above can choose to step back temporarily and just chill for a while.
//! This means that if they are a nominator, they will not be considered as voters anymore and if
//! they are validators, they will no longer be a candidate for the next election.
//! An account can step back via the [`chill`](Call::chill) call.
//! The pallet implement the trait `SessionManager`. Which is the only API to query new validator
//! set and allowing these validator set to be rewarded once their era is ended.
//!
//! The dispatchable functions of the Staking pallet enable the steps needed for entities to accept
//! and change their role, alongside some helper functions to get/set the metadata of the pallet.
//! The Staking pallet contains many public storage items and (im)mutable functions.
//! ### Example: Rewarding a validator by id.
//! use pallet_staking::{self as staking};
//! #[frame_support::pallet]
//! pub mod pallet {
//! use super::*;
//! use frame_support::pallet_prelude::*;
//! use frame_system::pallet_prelude::*;
//! #[pallet::pallet]
//! pub struct Pallet<T>(_);
//!
//! #[pallet::config]
//! pub trait Config: frame_system::Config + staking::Config {}
//!
//! #[pallet::call]
//! impl<T: Config> Pallet<T> {
//! #[pallet::weight(0)]
//! pub fn reward_myself(origin: OriginFor<T>) -> DispatchResult {
//! let reported = ensure_signed(origin)?;
//! <staking::Pallet<T>>::reward_by_ids(vec![(reported, 10)]);
//! Ok(())
//! }
//! }
//! }
//! # fn main() { }
//! ```
//!
//! ## Implementation Details
//!
//! ### Era payout
//!
//! The era payout is computed using yearly inflation curve defined at
//!
//! ```nocompile
//! staker_payout = yearly_inflation(npos_token_staked / total_tokens) * total_tokens / era_per_year
//! ```
//! This payout is used to reward stakers as defined in next section
//!
//! ```nocompile
//! remaining_payout = max_yearly_inflation * total_tokens / era_per_year - staker_payout
//! ```
//! The remaining reward is send to the configurable end-point
//! ### Reward Calculation
//!
//! Validators and nominators are rewarded at the end of each era. The total reward of an era is
//! calculated using the era duration and the staking rate (the total amount of tokens staked by
//! nominators and validators, divided by the total token supply). It aims to incentivize toward a
//! defined staking rate. The full specification can be found
//! [here](https://research.web3.foundation/en/latest/polkadot/Token%20Economics.html#inflation-model).
//!
//! Total reward is split among validators and their nominators depending on the number of points
//! they received during the era. Points are added to a validator using
//! [`reward_by_ids`](Pallet::reward_by_ids).
//! [`Pallet`] implements
//! points to block producer and block producer of referenced uncles.
//!
//! The validator and its nominator split their reward as following:
//! The validator can declare an amount, named [`commission`](ValidatorPrefs::commission), that does
//! not get shared with the nominators at each reward payout through its [`ValidatorPrefs`]. This
//! value gets deducted from the total reward that is paid to the validator and its nominators. The
//! remaining portion is split pro rata among the validator and the top
//! [`Config::MaxNominatorRewardedPerValidator`] nominators that nominated the validator,
//! proportional to the value staked behind the validator (_i.e._ dividing the
//! [`own`](Exposure::own) or [`others`](Exposure::others) by [`total`](Exposure::total) in
//! [`Exposure`]). Note that the pro rata division of rewards uses the total exposure behind the
//! validator, *not* just the exposure of the validator and the top
//! [`Config::MaxNominatorRewardedPerValidator`] nominators.
//! All entities who receive a reward have the option to choose their reward destination through the
//! [`Payee`] storage item (see
//! [`set_payee`](Call::set_payee)), to be one of the following:
//!
//! - Controller account, (obviously) not increasing the staked value.
//! - Stash account, not increasing the staked value.
//! - Stash account, also increasing the staked value.
//!
//! ### Additional Fund Management Operations
//!
//! Any funds already placed into stash can be the target of the following operations:
//!
//! The controller account can free a portion (or all) of the funds using the
//! [`unbond`](Call::unbond) call. Note that the funds are not immediately
//! accessible. Instead, a duration denoted by
//! [`Config::BondingDuration`] (in number of eras) must
//! pass until the funds can actually be removed. Once the `BondingDuration` is over, the
//! [`withdraw_unbonded`](Call::withdraw_unbonded) call can be used to actually
//! withdraw the funds.
//! Note that there is a limitation to the number of fund-chunks that can be scheduled to be
//! unlocked in the future via [`unbond`](Call::unbond). In case this maximum
//! (`MAX_UNLOCKING_CHUNKS`) is reached, the bonded account _must_ first wait until a successful
//! call to `withdraw_unbonded` to remove some of the chunks.
//!
//! The current election algorithm is implemented based on Phragmén. The reference implementation
//! can be found [here](https://github.com/w3f/consensus/tree/master/NPoS).
//! The election algorithm, aside from electing the validators with the most stake value and votes,
//! tries to divide the nominator votes among candidates in an equal manner. To further assure this,
//! an optional post-processing can be applied that iteratively normalizes the nominator staked
//! values until the total difference among votes of a particular nominator are less than a
//! threshold.
//!
//! ## GenesisConfig
//!
//! The Staking pallet depends on the [`GenesisConfig`]. The
//! `GenesisConfig` is optional and allow to set some initial stakers.
//!
//! ## Related Modules
//!
//! - [Balances](../pallet_balances/index.html): Used to manage values at stake.
//! - [Session](../pallet_session/index.html): Used to manage sessions. Also, a list of new
//! validators is stored in the Session pallet's `Validators` at the end of each era.
#[cfg(feature = "runtime-benchmarks")]
#[cfg(any(feature = "runtime-benchmarks", test))]
#[cfg(test)]
pub(crate) mod mock;
#[cfg(test)]
mod tests;
pub mod inflation;
pub mod migrations;
mod pallet;
use codec::{Decode, Encode, HasCompact};
traits::{Currency, Defensive, Get},
weights::Weight,
BoundedVec, EqNoBound, PartialEqNoBound, RuntimeDebugNoBound,
traits::{AtLeast32BitUnsigned, Convert, Saturating, Zero},
Perbill, Perquintill, RuntimeDebug,
offence::{Offence, OffenceError, ReportOffence},
use sp_std::{collections::btree_map::BTreeMap, prelude::*};
pub use pallet::{pallet::*, *};
pub(crate) const LOG_TARGET: &str = "runtime::staking";
// syntactic sugar for logging.
#[macro_export]
macro_rules! log {
($level:tt, $patter:expr $(, $values:expr)* $(,)?) => {
log::$level!(
concat!("[{:?}] 💸 ", $patter), <frame_system::Pallet<T>>::block_number() $(, $values)*
)
};
}
/// Counter for the number of "reward" points earned by a given validator.
/// The balance type of this pallet.
pub type BalanceOf<T> = <T as Config>::CurrencyBalance;
type PositiveImbalanceOf<T> = <<T as Config>::Currency as Currency<
<T as frame_system::Config>::AccountId,
>>::PositiveImbalance;
type NegativeImbalanceOf<T> = <<T as Config>::Currency as Currency<
<T as frame_system::Config>::AccountId,
>>::NegativeImbalance;
parameter_types! {
pub MaxUnlockingChunks: u32 = 32;
}
/// Information regarding the active era (era in used in session).
#[derive(Encode, Decode, RuntimeDebug, TypeInfo)]
pub struct ActiveEraInfo {
/// Index of era.
pub index: EraIndex,
/// Moment of start expressed as millisecond from `$UNIX_EPOCH`.
///
/// Start can be none if start hasn't been set for the era yet,
/// Start is set on the first on_finalize of the era to guarantee usage of `Time`.
start: Option<u64>,
}
/// Reward points of an era. Used to split era total payout between validators.
///
/// This points will be used to reward validators and their respective nominators.
#[derive(PartialEq, Encode, Decode, RuntimeDebug, TypeInfo)]
/// Total number of points. Equals the sum of reward points for each validator.
pub individual: BTreeMap<AccountId, RewardPoint>,
impl<AccountId: Ord> Default for EraRewardPoints<AccountId> {
fn default() -> Self {
EraRewardPoints { total: Default::default(), individual: BTreeMap::new() }
}
}
/// Indicates the initial status of the staker.
#[derive(RuntimeDebug, TypeInfo)]
#[cfg_attr(feature = "std", derive(serde::Serialize, serde::Deserialize, Clone))]
pub enum StakerStatus<AccountId> {
/// Chilling.
Idle,
/// Declared desire in validating or already participating in it.
Validator,
/// Nominating for a group of other stakers.
Nominator(Vec<AccountId>),
}
/// A destination account for payment.
#[derive(PartialEq, Eq, Copy, Clone, Encode, Decode, RuntimeDebug, TypeInfo)]
pub enum RewardDestination<AccountId> {
/// Pay into the stash account, increasing the amount at stake accordingly.
Staked,
/// Pay into the stash account, not increasing the amount at stake.
Stash,
/// Pay into the controller account.
Controller,
/// Pay into a specified account.
Account(AccountId),
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/// Receive no reward.
None,
impl<AccountId> Default for RewardDestination<AccountId> {
fn default() -> Self {
RewardDestination::Staked
}
/// Preference of what happens regarding validation.
#[derive(PartialEq, Eq, Clone, Encode, Decode, RuntimeDebug, TypeInfo, Default)]
pub struct ValidatorPrefs {
/// Reward that validator takes up-front; only the rest is split between themselves and
/// nominators.
pub commission: Perbill,
/// Whether or not this validator is accepting more nominations. If `true`, then no nominator
/// who is not already nominating this validator may nominate them. By default, validators
/// are accepting nominations.
pub blocked: bool,
/// Just a Balance/BlockNumber tuple to encode when a chunk of funds will be unlocked.
#[derive(PartialEq, Eq, Clone, Encode, Decode, RuntimeDebug, TypeInfo)]
pub struct UnlockChunk<Balance: HasCompact> {
/// Amount of funds to be unlocked.
#[codec(compact)]
value: Balance,
/// Era number at which point it'll be unlocked.
#[codec(compact)]
}
/// The ledger of a (bonded) stash.
#[derive(PartialEq, Eq, Clone, Encode, Decode, RuntimeDebugNoBound, TypeInfo)]
#[scale_info(skip_type_params(T))]
pub struct StakingLedger<T: Config> {
/// The stash account whose balance is actually locked and at stake.
/// The total amount of the stash's balance that we are currently accounting for.
/// It's just `active` plus all the `unlocking` balances.
#[codec(compact)]
/// The total amount of the stash's balance that will be at stake in any forthcoming
/// rounds.
#[codec(compact)]
/// Any balance that is becoming free, which may eventually be transferred out of the stash
/// (assuming it doesn't get slashed first). It is assumed that this will be treated as a first
/// in, first out queue where the new (higher value) eras get pushed on the back.
pub unlocking: BoundedVec<UnlockChunk<BalanceOf<T>>, MaxUnlockingChunks>,
/// List of eras for which the stakers behind a validator have claimed rewards. Only updated
/// for validators.
pub claimed_rewards: Vec<EraIndex>,
impl<T: Config> StakingLedger<T> {
/// Initializes the default object using the given `validator`.
pub fn default_from(stash: T::AccountId) -> Self {
Self {
stash,
total: Zero::zero(),
active: Zero::zero(),
unlocking: Default::default(),
claimed_rewards: vec![],
}
}
/// Remove entries from `unlocking` that are sufficiently old and reduce the
/// total by the sum of their balances.
fn consolidate_unlocked(self, current_era: EraIndex) -> Self {
let unlocking: BoundedVec<_, _> = self
.unlocking
.into_iter()
.filter(|chunk| {
if chunk.era > current_era {
true
} else {
total = total.saturating_sub(chunk.value);
false
}
.collect::<Vec<_>>()
.try_into()
.expect(
"filtering items from a bounded vec always leaves length less than bounds. qed",
);
Self {
stash: self.stash,
total,
active: self.active,
unlocking,
claimed_rewards: self.claimed_rewards,
/// Re-bond funds that were scheduled for unlocking.
///
/// Returns the updated ledger, and the amount actually rebonded.
fn rebond(mut self, value: BalanceOf<T>) -> (Self, BalanceOf<T>) {
let mut unlocking_balance = BalanceOf::<T>::zero();
while let Some(last) = self.unlocking.last_mut() {
if unlocking_balance + last.value <= value {
unlocking_balance += last.value;
self.active += last.value;
self.unlocking.pop();
} else {
let diff = value - unlocking_balance;
unlocking_balance += diff;
self.active += diff;
last.value -= diff;
}
if unlocking_balance >= value {
break
}
}
/// Slash the staker for a given amount of balance.
/// This implements a proportional slashing system, whereby we set our preference to slash as
/// such:
///
/// - If any unlocking chunks exist that are scheduled to be unlocked at `slash_era +
/// bonding_duration` and onwards, the slash is divided equally between the active ledger and
/// the unlocking chunks.
/// - If no such chunks exist, then only the active balance is slashed.
///
/// Note that the above is only a *preference*. If for any reason the active ledger, with or
/// without some portion of the unlocking chunks that are more justified to be slashed are not
/// enough, then the slashing will continue and will consume as much of the active and unlocking
/// chunks as needed.
/// This will never slash more than the given amount. If any of the chunks become dusted, the
/// last chunk is slashed slightly less to compensate. Returns the amount of funds actually
/// slashed.
///
/// `slash_era` is the era in which the slash (which is being enacted now) actually happened.
/// This calls `Config::OnStakerSlash::on_slash` with information as to how the slash was
/// applied.
fn slash(
&mut self,
slash_amount: BalanceOf<T>,
minimum_balance: BalanceOf<T>,
slash_era: EraIndex,
) -> BalanceOf<T> {
if slash_amount.is_zero() {
return Zero::zero()
}
use sp_staking::OnStakerSlash as _;
let mut remaining_slash = slash_amount;
let pre_slash_total = self.total;
// for a `slash_era = x`, any chunk that is scheduled to be unlocked at era `x + 28`
// (assuming 28 is the bonding duration) onwards should be slashed.
let slashable_chunks_start = slash_era + T::BondingDuration::get();
// `Some(ratio)` if this is proportional, with `ratio`, `None` otherwise. In both cases, we
// slash first the active chunk, and then `slash_chunks_priority`.
let (maybe_proportional, slash_chunks_priority) = {
if let Some(first_slashable_index) =
self.unlocking.iter().position(|c| c.era >= slashable_chunks_start)
// If there exists a chunk who's after the first_slashable_start, then this is a
// proportional slash, because we want to slash active and these chunks
// proportionally.
// The indices of the first chunk after the slash up through the most recent chunk.
// (The most recent chunk is at greatest from this era)
let affected_indices = first_slashable_index..self.unlocking.len();
let unbonding_affected_balance =
affected_indices.clone().fold(BalanceOf::<T>::zero(), |sum, i| {
if let Some(chunk) = self.unlocking.get(i).defensive() {
sum.saturating_add(chunk.value)
} else {
sum
}
});
let affected_balance = self.active.saturating_add(unbonding_affected_balance);
let ratio = Perquintill::from_rational(slash_amount, affected_balance);
Some(ratio),
affected_indices.chain((0..first_slashable_index).rev()).collect::<Vec<_>>(),
// We just slash from the last chunk to the most recent one, if need be.
(None, (0..self.unlocking.len()).rev().collect::<Vec<_>>())
}
};
// Helper to update `target` and the ledgers total after accounting for slashing `target`.
log!(
debug,
"slashing {:?} for era {:?} out of {:?}, priority: {:?}, proportional = {:?}",
slash_amount,
slash_era,
self,
slash_chunks_priority,
maybe_proportional,
);
let mut slash_out_of = |target: &mut BalanceOf<T>, slash_remaining: &mut BalanceOf<T>| {
let mut slash_from_target = if let Some(ratio) = maybe_proportional {
ratio * (*target)
} else {
*slash_remaining
}
// this is the total that that the slash target has. We can't slash more than
// this anyhow!
.min(*target)
// this is the total amount that we would have wanted to slash
// non-proportionally, a proportional slash should never exceed this either!
.min(*slash_remaining);
// slash out from *target exactly `slash_from_target`.
*target = *target - slash_from_target;
if *target < minimum_balance {
// Slash the rest of the target if it's dust. This might cause the last chunk to be
// slightly under-slashed, by at most `MaxUnlockingChunks * ED`, which is not a big
// deal.
slash_from_target =
sp_std::mem::replace(target, Zero::zero()).saturating_add(slash_from_target)
}
self.total = self.total.saturating_sub(slash_from_target);
*slash_remaining = slash_remaining.saturating_sub(slash_from_target);
};
// If this is *not* a proportional slash, the active will always wiped to 0.
slash_out_of(&mut self.active, &mut remaining_slash);
let mut slashed_unlocking = BTreeMap::<_, _>::new();
for i in slash_chunks_priority {
if remaining_slash.is_zero() {
break
}
if let Some(chunk) = self.unlocking.get_mut(i).defensive() {
slash_out_of(&mut chunk.value, &mut remaining_slash);
// write the new slashed value of this chunk to the map.
slashed_unlocking.insert(chunk.era, chunk.value);
} else {
break
}
}
// clean unlocking chunks that are set to zero.
self.unlocking.retain(|c| !c.value.is_zero());
T::OnStakerSlash::on_slash(&self.stash, self.active, &slashed_unlocking);
pre_slash_total.saturating_sub(self.total)
}
}
/// A record of the nominations made by a specific account.
#[derive(PartialEqNoBound, EqNoBound, Clone, Encode, Decode, RuntimeDebugNoBound, TypeInfo)]
#[scale_info(skip_type_params(T))]
pub struct Nominations<T: Config> {
/// The targets of nomination.
pub targets: BoundedVec<T::AccountId, T::MaxNominations>,
/// The era the nominations were submitted.
///
/// Except for initial nominations which are considered submitted at era 0.
/// Whether the nominations have been suppressed. This can happen due to slashing of the
/// validators, or other events that might invalidate the nomination.
///
/// NOTE: this for future proofing and is thus far not used.
}
/// The amount of exposure (to slashing) than an individual nominator has.
#[derive(PartialEq, Eq, PartialOrd, Ord, Clone, Encode, Decode, RuntimeDebug, TypeInfo)]
pub struct IndividualExposure<AccountId, Balance: HasCompact> {
/// The stash account of the nominator in question.
/// Amount of funds exposed.
#[codec(compact)]
}
/// A snapshot of the stake backing a single validator in the system.
#[derive(PartialEq, Eq, PartialOrd, Ord, Clone, Encode, Decode, RuntimeDebug, TypeInfo)]
pub struct Exposure<AccountId, Balance: HasCompact> {
/// The total balance backing this validator.
#[codec(compact)]
pub total: Balance,
/// The validator's own stash that is exposed.
#[codec(compact)]
pub own: Balance,
/// The portions of nominators stashes that are exposed.
pub others: Vec<IndividualExposure<AccountId, Balance>>,
}
impl<AccountId, Balance: Default + HasCompact> Default for Exposure<AccountId, Balance> {
fn default() -> Self {
Self { total: Default::default(), own: Default::default(), others: vec![] }
}
}
/// A pending slash record. The value of the slash has been computed but not applied yet,
/// rather deferred for several eras.
#[derive(Encode, Decode, RuntimeDebug, TypeInfo)]
pub struct UnappliedSlash<AccountId, Balance: HasCompact> {
/// The stash ID of the offending validator.
validator: AccountId,
/// The validator's own slash.
own: Balance,
/// All other slashed stakers and amounts.
others: Vec<(AccountId, Balance)>,
/// Reporters of the offence; bounty payout recipients.
reporters: Vec<AccountId>,
/// The amount of payout.
payout: Balance,
impl<AccountId, Balance: HasCompact + Zero> UnappliedSlash<AccountId, Balance> {
/// Initializes the default object using the given `validator`.
pub fn default_from(validator: AccountId) -> Self {
Self {
validator,
own: Zero::zero(),
others: vec![],
reporters: vec![],
payout: Zero::zero(),
}
}
}
/// Means for interacting with a specialized version of the `session` trait.
///
/// This is needed because `Staking` sets the `ValidatorIdOf` of the `pallet_session::Config`
pub trait SessionInterface<AccountId> {
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/// Disable the validator at the given index, returns `false` if the validator was already
/// disabled or the index is out of bounds.
fn disable_validator(validator_index: u32) -> bool;
/// Get the validators from session.
fn validators() -> Vec<AccountId>;
/// Prune historical session tries up to but not including the given index.
fn prune_historical_up_to(up_to: SessionIndex);
impl<T: Config> SessionInterface<<T as frame_system::Config>::AccountId> for T
where
T: pallet_session::Config<ValidatorId = <T as frame_system::Config>::AccountId>,
T: pallet_session::historical::Config<
FullIdentification = Exposure<<T as frame_system::Config>::AccountId, BalanceOf<T>>,
FullIdentificationOf = ExposureOf<T>,
>,
T::SessionHandler: pallet_session::SessionHandler<<T as frame_system::Config>::AccountId>,
T::SessionManager: pallet_session::SessionManager<<T as frame_system::Config>::AccountId>,
T::ValidatorIdOf: Convert<
<T as frame_system::Config>::AccountId,
Option<<T as frame_system::Config>::AccountId>,
>,
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fn disable_validator(validator_index: u32) -> bool {
<pallet_session::Pallet<T>>::disable_index(validator_index)
fn validators() -> Vec<<T as frame_system::Config>::AccountId> {
<pallet_session::Pallet<T>>::validators()
fn prune_historical_up_to(up_to: SessionIndex) {
<pallet_session::historical::Pallet<T>>::prune_up_to(up_to);
impl<AccountId> SessionInterface<AccountId> for () {
fn disable_validator(_: u32) -> bool {
true
}
fn validators() -> Vec<AccountId> {
Vec::new()
}
fn prune_historical_up_to(_: SessionIndex) {
()
}
}
/// Handler for determining how much of a balance should be paid out on the current era.
pub trait EraPayout<Balance> {
/// Determine the payout for this era.
///
/// Returns the amount to be paid to stakers in this era, as well as whatever else should be
/// paid out ("the rest").
fn era_payout(
total_staked: Balance,
total_issuance: Balance,
era_duration_millis: u64,
) -> (Balance, Balance);
}
impl<Balance: Default> EraPayout<Balance> for () {
fn era_payout(
_total_staked: Balance,
_total_issuance: Balance,
_era_duration_millis: u64,
) -> (Balance, Balance) {
(Default::default(), Default::default())
}
}
/// Adaptor to turn a `PiecewiseLinear` curve definition into an `EraPayout` impl, used for
/// backwards compatibility.
pub struct ConvertCurve<T>(sp_std::marker::PhantomData<T>);
impl<Balance: AtLeast32BitUnsigned + Clone, T: Get<&'static PiecewiseLinear<'static>>>
EraPayout<Balance> for ConvertCurve<T>
{
fn era_payout(
total_staked: Balance,
total_issuance: Balance,
era_duration_millis: u64,
) -> (Balance, Balance) {
let (validator_payout, max_payout) = inflation::compute_total_payout(
total_staked,
total_issuance,
// Duration of era; more than u64::MAX is rewarded as u64::MAX.
era_duration_millis,
);
let rest = max_payout.saturating_sub(validator_payout.clone());
(validator_payout, rest)
}
}
/// Mode of era-forcing.
#[derive(Copy, Clone, PartialEq, Eq, Encode, Decode, RuntimeDebug, TypeInfo)]
#[cfg_attr(feature = "std", derive(serde::Serialize, serde::Deserialize))]
pub enum Forcing {
/// Not forcing anything - just let whatever happen.
NotForcing,
/// Force a new era, then reset to `NotForcing` as soon as it is done.
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/// Note that this will force to trigger an election until a new era is triggered, if the
/// election failed, the next session end will trigger a new election again, until success.
ForceNew,
/// Avoid a new era indefinitely.
ForceNone,
/// Force a new era at the end of all sessions indefinitely.
ForceAlways,
}
impl Default for Forcing {
fn default() -> Self {
Forcing::NotForcing
}
// A value placed in storage that represents the current version of the Staking storage. This value
// is used by the `on_runtime_upgrade` logic to determine whether we run storage migration logic.
// This should match directly with the semantic versions of the Rust crate.
#[derive(Encode, Decode, Clone, Copy, PartialEq, Eq, RuntimeDebug, TypeInfo)]
V5_0_0, // blockable validators.
V6_0_0, // removal of all storage associated with offchain phragmen.
V7_0_0, // keep track of number of nominators / validators in map
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V8_0_0, // populate `VoterList`.
V9_0_0, // inject validators into `VoterList` as well.
}
impl Default for Releases {
fn default() -> Self {
Releases::V8_0_0
/// A `Convert` implementation that finds the stash of the given controller account,
/// if any.
pub struct StashOf<T>(sp_std::marker::PhantomData<T>);
impl<T: Config> Convert<T::AccountId, Option<T::AccountId>> for StashOf<T> {
fn convert(controller: T::AccountId) -> Option<T::AccountId> {
<Pallet<T>>::ledger(&controller).map(|l| l.stash)
/// A typed conversion from stash account ID to the active exposure of nominators
/// on that account.
///
/// Active exposure is the exposure of the validator set currently validating, i.e. in
/// `active_era`. It can differ from the latest planned exposure in `current_era`.
pub struct ExposureOf<T>(sp_std::marker::PhantomData<T>);
impl<T: Config> Convert<T::AccountId, Option<Exposure<T::AccountId, BalanceOf<T>>>>
for ExposureOf<T>
{
fn convert(validator: T::AccountId) -> Option<Exposure<T::AccountId, BalanceOf<T>>> {
<Pallet<T>>::active_era()
.map(|active_era| <Pallet<T>>::eras_stakers(active_era.index, &validator))
/// Filter historical offences out and only allow those from the bonding period.
pub struct FilterHistoricalOffences<T, R> {
_inner: sp_std::marker::PhantomData<(T, R)>,
}
impl<T, Reporter, Offender, R, O> ReportOffence<Reporter, Offender, O>
for FilterHistoricalOffences<Pallet<T>, R>
where
T: Config,
R: ReportOffence<Reporter, Offender, O>,
O: Offence<Offender>,
{
fn report_offence(reporters: Vec<Reporter>, offence: O) -> Result<(), OffenceError> {
// Disallow any slashing from before the current bonding period.
let offence_session = offence.session_index();
let bonded_eras = BondedEras::<T>::get();
if bonded_eras.first().filter(|(_, start)| offence_session >= *start).is_some() {
R::report_offence(reporters, offence)
} else {
<Pallet<T>>::deposit_event(Event::<T>::OldSlashingReportDiscarded(offence_session));
Ok(())
fn is_known_offence(offenders: &[Offender], time_slot: &O::TimeSlot) -> bool {
R::is_known_offence(offenders, time_slot)
/// Configurations of the benchmarking of the pallet.
pub trait BenchmarkingConfig {
/// The maximum number of validators to use.
type MaxValidators: Get<u32>;
/// The maximum number of nominators to use.
type MaxNominators: Get<u32>;
}
/// A mock benchmarking config for pallet-staking.
///
/// Should only be used for testing.
#[cfg(feature = "std")]
pub struct TestBenchmarkingConfig;
#[cfg(feature = "std")]
impl BenchmarkingConfig for TestBenchmarkingConfig {
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type MaxValidators = frame_support::traits::ConstU32<100>;
type MaxNominators = frame_support::traits::ConstU32<100>;