// Copyright 2017-2019 Parity Technologies (UK) Ltd.
// This file is part of Substrate.
// Substrate 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.
// Substrate 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 Substrate. If not, see .
//! # Staking Module
//!
//! The Staking module is used to manage funds at stake by network maintainers.
//!
//! - [`staking::Trait`](./trait.Trait.html)
//! - [`Call`](./enum.Call.html)
//! - [`Module`](./struct.Module.html)
//!
//! ## Overview
//!
//! The Staking module 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
//!
//!
//! - 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
//!
//!
//! 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 module requires a process of _**bonding**_ (also known
//! as being a _staker_). To become *bonded*, a fund-holding account 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`](./enum.Call.html#variant.bond) call.
//!
//! Stash accounts can change their associated controller using the
//! [`set_controller`](./enum.Call.html#variant.set_controller) call.
//!
//! There are three possible roles that any staked account pair can be in: `Validator`, `Nominator`
//! and `Idle` (defined in [`StakerStatus`](./enum.StakerStatus.html)). There are three
//! corresponding instructions to change between roles, namely:
//! [`validate`](./enum.Call.html#variant.validate), [`nominate`](./enum.Call.html#variant.nominate),
//! and [`chill`](./enum.Call.html#variant.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
//! [`validate`](./enum.Call.html#variant.validate) call.
//!
//! #### 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`](enum.Call.html#variant.nominate) call.
//!
//! #### Rewards and Slash
//!
//! The **reward and slashing** procedure is the core of the Staking module, attempting to _embrace
//! valid behavior_ while _punishing any misbehavior or lack of availability_.
//!
//! 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).
//!
//! 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`](enum.Call.html#variant.chill) call.
//!
//! ## Interface
//!
//! ### Dispatchable Functions
//!
//! The dispatchable functions of the Staking module enable the steps needed for entities to accept
//! and change their role, alongside some helper functions to get/set the metadata of the module.
//!
//! ### Public Functions
//!
//! The Staking module contains many public storage items and (im)mutable functions.
//!
//! ## Usage
//!
//! ### Example: Rewarding a validator by id.
//!
//! ```
//! use support::{decl_module, dispatch::Result};
//! use system::ensure_signed;
//! use srml_staking::{self as staking};
//!
//! pub trait Trait: staking::Trait {}
//!
//! decl_module! {
//! pub struct Module for enum Call where origin: T::Origin {
//! /// Reward a validator.
//! pub fn reward_myself(origin) -> Result {
//! let reported = ensure_signed(origin)?;
//! >::reward_by_ids(vec![(reported, 10)]);
//! Ok(())
//! }
//! }
//! }
//! # fn main() { }
//! ```
//!
//! ## Implementation Details
//!
//! ### Slot Stake
//!
//! The term [`SlotStake`](./struct.Module.html#method.slot_stake) will be used throughout this
//! section. It refers to a value calculated at the end of each era, containing the _minimum value
//! at stake among all validators._ Note that a validator's value at stake might be a combination
//! of the validator's own stake and the votes it received. See [`Exposure`](./struct.Exposure.html)
//! for more details.
//!
//! ### 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 incentivise toward a
//! defined staking rate. The full specification can be found
//! [here](https://research.web3.foundation/en/latest/polkadot/Token%20Economics/#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`](./enum.Call.html#variant.reward_by_ids) or
//! [`reward_by_indices`](./enum.Call.html#variant.reward_by_indices).
//!
//! [`Module`](./struct.Module.html) implements
//! [`authorship::EventHandler`](../srml_authorship/trait.EventHandler.html) to add reward 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
//! [`validator_payment`](./struct.ValidatorPrefs.html#structfield.validator_payment), that does not
//! get shared with the nominators at each reward payout through its
//! [`ValidatorPrefs`](./struct.ValidatorPrefs.html). This value gets deducted from the total reward
//! that is paid to the validator and its nominators. The remaining portion is split among the
//! validator and all of the nominators that nominated the validator, proportional to the value
//! staked behind this validator (_i.e._ dividing the
//! [`own`](./struct.Exposure.html#structfield.own) or
//! [`others`](./struct.Exposure.html#structfield.others) by
//! [`total`](./struct.Exposure.html#structfield.total) in [`Exposure`](./struct.Exposure.html)).
//!
//! All entities who receive a reward have the option to choose their reward destination
//! through the [`Payee`](./struct.Payee.html) storage item (see
//! [`set_payee`](enum.Call.html#variant.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`](enum.Call.html#variant.unbond) call. Note that the funds are not immediately
//! accessible. Instead, a duration denoted by [`BondingDuration`](./struct.BondingDuration.html)
//! (in number of eras) must pass until the funds can actually be removed. Once the
//! `BondingDuration` is over, the [`withdraw_unbonded`](./enum.Call.html#variant.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`](enum.Call.html#variant.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.
//!
//! ### Election Algorithm
//!
//! 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 module depends on the [`GenesisConfig`](./struct.GenesisConfig.html).
//!
//! ## Related Modules
//!
//! - [Balances](../srml_balances/index.html): Used to manage values at stake.
//! - [Session](../srml_session/index.html): Used to manage sessions. Also, a list of new validators
//! is stored in the Session module's `Validators` at the end of each era.
#![recursion_limit="128"]
#![cfg_attr(not(feature = "std"), no_std)]
#[cfg(test)]
mod mock;
#[cfg(test)]
mod tests;
pub mod inflation;
use rstd::{prelude::*, result};
use codec::{HasCompact, Encode, Decode};
use support::{
StorageValue, StorageMap, StorageLinkedMap, decl_module, decl_event,
decl_storage, ensure, traits::{
Currency, OnFreeBalanceZero, OnDilution, LockIdentifier, LockableCurrency,
WithdrawReasons, OnUnbalanced, Imbalance, Get, Time
}
};
use session::{historical::OnSessionEnding, SelectInitialValidators};
use sr_primitives::Perbill;
use sr_primitives::weights::SimpleDispatchInfo;
use sr_primitives::traits::{
Convert, Zero, One, StaticLookup, CheckedSub, Saturating, Bounded, SimpleArithmetic,
SaturatedConversion,
};
use phragmen::{elect, equalize, Support, SupportMap, ExtendedBalance, ACCURACY};
use sr_staking_primitives::{
SessionIndex,
offence::{OnOffenceHandler, OffenceDetails, Offence, ReportOffence},
};
#[cfg(feature = "std")]
use sr_primitives::{Serialize, Deserialize};
use system::{ensure_signed, ensure_root};
const DEFAULT_MINIMUM_VALIDATOR_COUNT: u32 = 4;
const MAX_NOMINATIONS: usize = 16;
const MAX_UNLOCKING_CHUNKS: usize = 32;
const STAKING_ID: LockIdentifier = *b"staking ";
/// Counter for the number of eras that have passed.
pub type EraIndex = u32;
/// Counter for the number of "reward" points earned by a given validator.
pub type Points = u32;
/// Reward points of an era. Used to split era total payout between validators.
#[derive(Encode, Decode, Default)]
pub struct EraPoints {
/// Total number of points. Equals the sum of reward points for each validator.
total: Points,
/// The reward points earned by a given validator. The index of this vec corresponds to the
/// index into the current validator set.
individual: Vec,
}
impl EraPoints {
/// Add the reward to the validator at the given index. Index must be valid
/// (i.e. `index < current_elected.len()`).
fn add_points_to_index(&mut self, index: u32, points: u32) {
if let Some(new_total) = self.total.checked_add(points) {
self.total = new_total;
self.individual.resize((index as usize + 1).max(self.individual.len()), 0);
self.individual[index as usize] += points; // Addition is less than total
}
}
}
/// Indicates the initial status of the staker.
#[cfg_attr(feature = "std", derive(Debug, Serialize, Deserialize))]
pub enum StakerStatus {
/// Chilling.
Idle,
/// Declared desire in validating or already participating in it.
Validator,
/// Nominating for a group of other stakers.
Nominator(Vec),
}
/// A destination account for payment.
#[derive(PartialEq, Eq, Copy, Clone, Encode, Decode)]
#[cfg_attr(feature = "std", derive(Debug))]
pub enum RewardDestination {
/// 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,
}
impl Default for RewardDestination {
fn default() -> Self {
RewardDestination::Staked
}
}
/// Preference of what happens on a slash event.
#[derive(PartialEq, Eq, Clone, Encode, Decode)]
#[cfg_attr(feature = "std", derive(Debug))]
pub struct ValidatorPrefs {
/// Reward that validator takes up-front; only the rest is split between themselves and
/// nominators.
#[codec(compact)]
pub validator_payment: Balance,
}
impl Default for ValidatorPrefs {
fn default() -> Self {
ValidatorPrefs {
validator_payment: Default::default(),
}
}
}
/// Just a Balance/BlockNumber tuple to encode when a chunk of funds will be unlocked.
#[derive(PartialEq, Eq, Clone, Encode, Decode)]
#[cfg_attr(feature = "std", derive(Debug))]
pub struct UnlockChunk {
/// Amount of funds to be unlocked.
#[codec(compact)]
value: Balance,
/// Era number at which point it'll be unlocked.
#[codec(compact)]
era: EraIndex,
}
/// The ledger of a (bonded) stash.
#[derive(PartialEq, Eq, Clone, Encode, Decode)]
#[cfg_attr(feature = "std", derive(Debug))]
pub struct StakingLedger {
/// The stash account whose balance is actually locked and at stake.
pub stash: AccountId,
/// 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)]
pub total: Balance,
/// The total amount of the stash's balance that will be at stake in any forthcoming
/// rounds.
#[codec(compact)]
pub active: Balance,
/// Any balance that is becoming free, which may eventually be transferred out
/// of the stash (assuming it doesn't get slashed first).
pub unlocking: Vec>,
}
impl<
AccountId,
Balance: HasCompact + Copy + Saturating,
> StakingLedger {
/// 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 mut total = self.total;
let unlocking = self.unlocking.into_iter()
.filter(|chunk| if chunk.era > current_era {
true
} else {
total = total.saturating_sub(chunk.value);
false
})
.collect();
Self { total, active: self.active, stash: self.stash, unlocking }
}
}
/// The amount of exposure (to slashing) than an individual nominator has.
#[derive(PartialEq, Eq, PartialOrd, Ord, Clone, Encode, Decode)]
#[cfg_attr(feature = "std", derive(Debug))]
pub struct IndividualExposure {
/// The stash account of the nominator in question.
who: AccountId,
/// Amount of funds exposed.
#[codec(compact)]
value: Balance,
}
/// A snapshot of the stake backing a single validator in the system.
#[derive(PartialEq, Eq, PartialOrd, Ord, Clone, Encode, Decode, Default)]
#[cfg_attr(feature = "std", derive(Debug))]
pub struct Exposure {
/// 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>,
}
/// A slashing event occurred, slashing a validator for a given amount of balance.
#[derive(PartialEq, Eq, PartialOrd, Ord, Clone, Encode, Decode, Default)]
#[cfg_attr(feature = "std", derive(Debug))]
pub struct SlashJournalEntry {
who: AccountId,
amount: Balance,
own_slash: Balance, // the amount of `who`'s own exposure that was slashed
}
pub type BalanceOf =
<::Currency as Currency<::AccountId>>::Balance;
type PositiveImbalanceOf =
<::Currency as Currency<::AccountId>>::PositiveImbalance;
type NegativeImbalanceOf =
<::Currency as Currency<::AccountId>>::NegativeImbalance;
type MomentOf= <::Time as Time>::Moment;
/// Means for interacting with a specialized version of the `session` trait.
///
/// This is needed because `Staking` sets the `ValidatorIdOf` of the `session::Trait`
pub trait SessionInterface: system::Trait {
/// Disable a given validator by stash ID.
fn disable_validator(validator: &AccountId) -> Result<(), ()>;
/// Get the validators from session.
fn validators() -> Vec;
/// Prune historical session tries up to but not including the given index.
fn prune_historical_up_to(up_to: SessionIndex);
}
impl SessionInterface<::AccountId> for T where
T: session::Trait::AccountId>,
T: session::historical::Trait<
FullIdentification = Exposure<::AccountId, BalanceOf>,
FullIdentificationOf = ExposureOf,
>,
T::SessionHandler: session::SessionHandler<::AccountId>,
T::OnSessionEnding: session::OnSessionEnding<::AccountId>,
T::SelectInitialValidators: session::SelectInitialValidators<::AccountId>,
T::ValidatorIdOf: Convert<::AccountId, Option<::AccountId>>
{
fn disable_validator(validator: &::AccountId) -> Result<(), ()> {
>::disable(validator)
}
fn validators() -> Vec<::AccountId> {
>::validators()
}
fn prune_historical_up_to(up_to: SessionIndex) {
>::prune_up_to(up_to);
}
}
pub trait Trait: system::Trait {
/// The staking balance.
type Currency: LockableCurrency;
/// Time used for computing era duration.
type Time: Time;
/// Convert a balance into a number used for election calculation.
/// This must fit into a `u64` but is allowed to be sensibly lossy.
/// TODO: #1377
/// The backward convert should be removed as the new Phragmen API returns ratio.
/// The post-processing needs it but will be moved to off-chain. TODO: #2908
type CurrencyToVote: Convert, u64> + Convert>;
/// Some tokens minted.
type OnRewardMinted: OnDilution>;
/// The overarching event type.
type Event: From> + Into<::Event>;
/// Handler for the unbalanced reduction when slashing a staker.
type Slash: OnUnbalanced>;
/// Handler for the unbalanced increment when rewarding a staker.
type Reward: OnUnbalanced>;
/// Number of sessions per era.
type SessionsPerEra: Get;
/// Number of eras that staked funds must remain bonded for.
type BondingDuration: Get;
/// Interface for interacting with a session module.
type SessionInterface: self::SessionInterface;
}
/// Mode of era-forcing.
#[derive(Copy, Clone, PartialEq, Eq, Encode, Decode)]
#[cfg_attr(feature = "std", derive(Debug, Serialize, 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.
ForceNew,
/// Avoid a new era indefinitely.
ForceNone,
}
impl Default for Forcing {
fn default() -> Self { Forcing::NotForcing }
}
decl_storage! {
trait Store for Module as Staking {
/// The ideal number of staking participants.
pub ValidatorCount get(validator_count) config(): u32;
/// Minimum number of staking participants before emergency conditions are imposed.
pub MinimumValidatorCount get(minimum_validator_count) config():
u32 = DEFAULT_MINIMUM_VALIDATOR_COUNT;
/// Any validators that may never be slashed or forcibly kicked. It's a Vec since they're
/// easy to initialize and the performance hit is minimal (we expect no more than four
/// invulnerables) and restricted to testnets.
pub Invulnerables get(invulnerables) config(): Vec;
/// Map from all locked "stash" accounts to the controller account.
pub Bonded get(bonded): map T::AccountId => Option;
/// Map from all (unlocked) "controller" accounts to the info regarding the staking.
pub Ledger get(ledger):
map T::AccountId => Option>>;
/// Where the reward payment should be made. Keyed by stash.
pub Payee get(payee): map T::AccountId => RewardDestination;
/// The map from (wannabe) validator stash key to the preferences of that validator.
pub Validators get(validators): linked_map T::AccountId => ValidatorPrefs>;
/// The map from nominator stash key to the set of stash keys of all validators to nominate.
pub Nominators get(nominators): linked_map T::AccountId => Vec;
/// Nominators for a particular account that is in action right now. You can't iterate
/// through validators here, but you can find them in the Session module.
///
/// This is keyed by the stash account.
pub Stakers get(stakers): map T::AccountId => Exposure>;
/// The currently elected validator set keyed by stash account ID.
pub CurrentElected get(current_elected): Vec;
/// The current era index.
pub CurrentEra get(current_era) config(): EraIndex;
/// The start of the current era.
pub CurrentEraStart get(current_era_start): MomentOf;
/// The session index at which the current era started.
pub CurrentEraStartSessionIndex get(current_era_start_session_index): SessionIndex;
/// Rewards for the current era. Using indices of current elected set.
CurrentEraPointsEarned get(current_era_reward): EraPoints;
/// The amount of balance actively at stake for each validator slot, currently.
///
/// This is used to derive rewards and punishments.
pub SlotStake get(slot_stake) build(|config: &GenesisConfig| {
config.stakers.iter().map(|&(_, _, value, _)| value).min().unwrap_or_default()
}): BalanceOf;
/// True if the next session change will be a new era regardless of index.
pub ForceEra get(force_era) config(): Forcing;
/// The percentage of the slash that is distributed to reporters.
///
/// The rest of the slashed value is handled by the `Slash`.
pub SlashRewardFraction get(slash_reward_fraction) config(): Perbill;
/// A mapping from still-bonded eras to the first session index of that era.
BondedEras: Vec<(EraIndex, SessionIndex)>;
/// All slashes that have occurred in a given era.
EraSlashJournal get(era_slash_journal):
map EraIndex => Vec>>;
}
add_extra_genesis {
config(stakers):
Vec<(T::AccountId, T::AccountId, BalanceOf, StakerStatus)>;
build(|config: &GenesisConfig| {
for &(ref stash, ref controller, balance, ref status) in &config.stakers {
assert!(
T::Currency::free_balance(&stash) >= balance,
"Stash does not have enough balance to bond."
);
let _ = >::bond(
T::Origin::from(Some(stash.clone()).into()),
T::Lookup::unlookup(controller.clone()),
balance,
RewardDestination::Staked,
);
let _ = match status {
StakerStatus::Validator => {
>::validate(
T::Origin::from(Some(controller.clone()).into()),
Default::default(),
)
},
StakerStatus::Nominator(votes) => {
>::nominate(
T::Origin::from(Some(controller.clone()).into()),
votes.iter().map(|l| T::Lookup::unlookup(l.clone())).collect(),
)
}, _ => Ok(())
};
}
});
}
}
decl_event!(
pub enum Event where Balance = BalanceOf, ::AccountId {
/// All validators have been rewarded by the given balance.
Reward(Balance),
/// One validator (and its nominators) has been slashed by the given amount.
Slash(AccountId, Balance),
/// An old slashing report from a prior era was discarded because it could
/// not be processed.
OldSlashingReportDiscarded(SessionIndex),
}
);
decl_module! {
pub struct Module for enum Call where origin: T::Origin {
/// Number of sessions per era.
const SessionsPerEra: SessionIndex = T::SessionsPerEra::get();
/// Number of eras that staked funds must remain bonded for.
const BondingDuration: EraIndex = T::BondingDuration::get();
fn deposit_event() = default;
fn on_finalize() {
// Set the start of the first era.
if !>::exists() {
>::put(T::Time::now());
}
}
/// Take the origin account as a stash and lock up `value` of its balance. `controller` will
/// be the account that controls it.
///
/// `value` must be more than the `minimum_balance` specified by `T::Currency`.
///
/// The dispatch origin for this call must be _Signed_ by the stash account.
///
/// #
/// - Independent of the arguments. Moderate complexity.
/// - O(1).
/// - Three extra DB entries.
///
/// NOTE: Two of the storage writes (`Self::bonded`, `Self::payee`) are _never_ cleaned unless
/// the `origin` falls below _existential deposit_ and gets removed as dust.
/// #
#[weight = SimpleDispatchInfo::FixedNormal(500_000)]
fn bond(origin,
controller: ::Source,
#[compact] value: BalanceOf,
payee: RewardDestination
) {
let stash = ensure_signed(origin)?;
if >::exists(&stash) {
return Err("stash already bonded")
}
let controller = T::Lookup::lookup(controller)?;
if >::exists(&controller) {
return Err("controller already paired")
}
// reject a bond which is considered to be _dust_.
if value < T::Currency::minimum_balance() {
return Err("can not bond with value less than minimum balance")
}
// You're auto-bonded forever, here. We might improve this by only bonding when
// you actually validate/nominate and remove once you unbond __everything__.
>::insert(&stash, controller.clone());
>::insert(&stash, payee);
let stash_balance = T::Currency::free_balance(&stash);
let value = value.min(stash_balance);
let item = StakingLedger { stash, total: value, active: value, unlocking: vec![] };
Self::update_ledger(&controller, &item);
}
/// Add some extra amount that have appeared in the stash `free_balance` into the balance up
/// for staking.
///
/// Use this if there are additional funds in your stash account that you wish to bond.
/// Unlike [`bond`] or [`unbond`] this function does not impose any limitation on the amount
/// that can be added.
///
/// The dispatch origin for this call must be _Signed_ by the stash, not the controller.
///
/// #
/// - Independent of the arguments. Insignificant complexity.
/// - O(1).
/// - One DB entry.
/// #
#[weight = SimpleDispatchInfo::FixedNormal(500_000)]
fn bond_extra(origin, #[compact] max_additional: BalanceOf) {
let stash = ensure_signed(origin)?;
let controller = Self::bonded(&stash).ok_or("not a stash")?;
let mut ledger = Self::ledger(&controller).ok_or("not a controller")?;
let stash_balance = T::Currency::free_balance(&stash);
if let Some(extra) = stash_balance.checked_sub(&ledger.total) {
let extra = extra.min(max_additional);
ledger.total += extra;
ledger.active += extra;
Self::update_ledger(&controller, &ledger);
}
}
/// Schedule a portion of the stash to be unlocked ready for transfer out after the bond
/// period ends. If this leaves an amount actively bonded less than
/// T::Currency::minimum_balance(), then it is increased to the full amount.
///
/// Once the unlock period is done, you can call `withdraw_unbonded` to actually move
/// the funds out of management ready for transfer.
///
/// No more than a limited number of unlocking chunks (see `MAX_UNLOCKING_CHUNKS`)
/// can co-exists at the same time. In that case, [`Call::withdraw_unbonded`] need
/// to be called first to remove some of the chunks (if possible).
///
/// The dispatch origin for this call must be _Signed_ by the controller, not the stash.
///
/// See also [`Call::withdraw_unbonded`].
///
/// #
/// - Independent of the arguments. Limited but potentially exploitable complexity.
/// - Contains a limited number of reads.
/// - Each call (requires the remainder of the bonded balance to be above `minimum_balance`)
/// will cause a new entry to be inserted into a vector (`Ledger.unlocking`) kept in storage.
/// The only way to clean the aforementioned storage item is also user-controlled via `withdraw_unbonded`.
/// - One DB entry.
///
#[weight = SimpleDispatchInfo::FixedNormal(400_000)]
fn unbond(origin, #[compact] value: BalanceOf) {
let controller = ensure_signed(origin)?;
let mut ledger = Self::ledger(&controller).ok_or("not a controller")?;
ensure!(
ledger.unlocking.len() < MAX_UNLOCKING_CHUNKS,
"can not schedule more unlock chunks"
);
let mut value = value.min(ledger.active);
if !value.is_zero() {
ledger.active -= value;
// Avoid there being a dust balance left in the staking system.
if ledger.active < T::Currency::minimum_balance() {
value += ledger.active;
ledger.active = Zero::zero();
}
let era = Self::current_era() + T::BondingDuration::get();
ledger.unlocking.push(UnlockChunk { value, era });
Self::update_ledger(&controller, &ledger);
}
}
/// Remove any unlocked chunks from the `unlocking` queue from our management.
///
/// This essentially frees up that balance to be used by the stash account to do
/// whatever it wants.
///
/// The dispatch origin for this call must be _Signed_ by the controller, not the stash.
///
/// See also [`Call::unbond`].
///
/// #
/// - Could be dependent on the `origin` argument and how much `unlocking` chunks exist.
/// It implies `consolidate_unlocked` which loops over `Ledger.unlocking`, which is
/// indirectly user-controlled. See [`unbond`] for more detail.
/// - Contains a limited number of reads, yet the size of which could be large based on `ledger`.
/// - Writes are limited to the `origin` account key.
/// #
#[weight = SimpleDispatchInfo::FixedNormal(400_000)]
fn withdraw_unbonded(origin) {
let controller = ensure_signed(origin)?;
let ledger = Self::ledger(&controller).ok_or("not a controller")?;
let ledger = ledger.consolidate_unlocked(Self::current_era());
if ledger.unlocking.is_empty() && ledger.active.is_zero() {
// This account must have called `unbond()` with some value that caused the active
// portion to fall below existential deposit + will have no more unlocking chunks
// left. We can now safely remove this.
let stash = ledger.stash;
// remove the lock.
T::Currency::remove_lock(STAKING_ID, &stash);
// remove all staking-related information.
Self::kill_stash(&stash);
} else {
// This was the consequence of a partial unbond. just update the ledger and move on.
Self::update_ledger(&controller, &ledger);
}
}
/// Declare the desire to validate for the origin controller.
///
/// Effects will be felt at the beginning of the next era.
///
/// The dispatch origin for this call must be _Signed_ by the controller, not the stash.
///
/// #
/// - Independent of the arguments. Insignificant complexity.
/// - Contains a limited number of reads.
/// - Writes are limited to the `origin` account key.
/// #
#[weight = SimpleDispatchInfo::FixedNormal(750_000)]
fn validate(origin, prefs: ValidatorPrefs>) {
let controller = ensure_signed(origin)?;
let ledger = Self::ledger(&controller).ok_or("not a controller")?;
let stash = &ledger.stash;
>::remove(stash);
>::insert(stash, prefs);
}
/// Declare the desire to nominate `targets` for the origin controller.
///
/// Effects will be felt at the beginning of the next era.
///
/// The dispatch origin for this call must be _Signed_ by the controller, not the stash.
///
/// #
/// - The transaction's complexity is proportional to the size of `targets`,
/// which is capped at `MAX_NOMINATIONS`.
/// - Both the reads and writes follow a similar pattern.
/// #
#[weight = SimpleDispatchInfo::FixedNormal(750_000)]
fn nominate(origin, targets: Vec<::Source>) {
let controller = ensure_signed(origin)?;
let ledger = Self::ledger(&controller).ok_or("not a controller")?;
let stash = &ledger.stash;
ensure!(!targets.is_empty(), "targets cannot be empty");
let targets = targets.into_iter()
.take(MAX_NOMINATIONS)
.map(|t| T::Lookup::lookup(t))
.collect::, _>>()?;
>::remove(stash);
>::insert(stash, targets);
}
/// Declare no desire to either validate or nominate.
///
/// Effects will be felt at the beginning of the next era.
///
/// The dispatch origin for this call must be _Signed_ by the controller, not the stash.
///
/// #
/// - Independent of the arguments. Insignificant complexity.
/// - Contains one read.
/// - Writes are limited to the `origin` account key.
/// #
#[weight = SimpleDispatchInfo::FixedNormal(500_000)]
fn chill(origin) {
let controller = ensure_signed(origin)?;
let ledger = Self::ledger(&controller).ok_or("not a controller")?;
let stash = &ledger.stash;
>::remove(stash);
>::remove(stash);
}
/// (Re-)set the payment target for a controller.
///
/// Effects will be felt at the beginning of the next era.
///
/// The dispatch origin for this call must be _Signed_ by the controller, not the stash.
///
/// #
/// - Independent of the arguments. Insignificant complexity.
/// - Contains a limited number of reads.
/// - Writes are limited to the `origin` account key.
/// #
#[weight = SimpleDispatchInfo::FixedNormal(500_000)]
fn set_payee(origin, payee: RewardDestination) {
let controller = ensure_signed(origin)?;
let ledger = Self::ledger(&controller).ok_or("not a controller")?;
let stash = &ledger.stash;
>::insert(stash, payee);
}
/// (Re-)set the controller of a stash.
///
/// Effects will be felt at the beginning of the next era.
///
/// The dispatch origin for this call must be _Signed_ by the stash, not the controller.
///
/// #
/// - Independent of the arguments. Insignificant complexity.
/// - Contains a limited number of reads.
/// - Writes are limited to the `origin` account key.
/// #
#[weight = SimpleDispatchInfo::FixedNormal(750_000)]
fn set_controller(origin, controller: ::Source) {
let stash = ensure_signed(origin)?;
let old_controller = Self::bonded(&stash).ok_or("not a stash")?;
let controller = T::Lookup::lookup(controller)?;
if >::exists(&controller) {
return Err("controller already paired")
}
if controller != old_controller {
>::insert(&stash, &controller);
if let Some(l) = >::take(&old_controller) {
>::insert(&controller, l);
}
}
}
/// The ideal number of validators.
#[weight = SimpleDispatchInfo::FixedOperational(150_000)]
fn set_validator_count(origin, #[compact] new: u32) {
ensure_root(origin)?;
ValidatorCount::put(new);
}
// ----- Root calls.
/// Force there to be no new eras indefinitely.
///
/// #
/// - No arguments.
/// #
#[weight = SimpleDispatchInfo::FixedOperational(10_000)]
fn force_no_eras(origin) {
ensure_root(origin)?;
ForceEra::put(Forcing::ForceNone);
}
/// Force there to be a new era at the end of the next session. After this, it will be
/// reset to normal (non-forced) behaviour.
///
/// #
/// - No arguments.
/// #
#[weight = SimpleDispatchInfo::FixedOperational(10_000)]
fn force_new_era(origin) {
ensure_root(origin)?;
ForceEra::put(Forcing::ForceNew);
}
/// Set the validators who cannot be slashed (if any).
#[weight = SimpleDispatchInfo::FixedOperational(10_000)]
fn set_invulnerables(origin, validators: Vec) {
ensure_root(origin)?;
>::put(validators);
}
}
}
impl Module {
// PUBLIC IMMUTABLES
/// The total balance that can be slashed from a validator controller account as of
/// right now.
pub fn slashable_balance_of(stash: &T::AccountId) -> BalanceOf {
Self::bonded(stash).and_then(Self::ledger).map(|l| l.active).unwrap_or_default()
}
// MUTABLES (DANGEROUS)
/// Update the ledger for a controller. This will also update the stash lock. The lock will
/// will lock the entire funds except paying for further transactions.
fn update_ledger(
controller: &T::AccountId,
ledger: &StakingLedger>
) {
T::Currency::set_lock(
STAKING_ID,
&ledger.stash,
ledger.total,
T::BlockNumber::max_value(),
WithdrawReasons::all(),
);
>::insert(controller, ledger);
}
/// Slash a given validator by a specific amount with given (historical) exposure.
///
/// Removes the slash from the validator's balance by preference,
/// and reduces the nominators' balance if needed.
///
/// Returns the resulting `NegativeImbalance` to allow distributing the slashed amount and
/// pushes an entry onto the slash journal.
fn slash_validator(
stash: &T::AccountId,
slash: BalanceOf,
exposure: &Exposure>,
journal: &mut Vec>>,
) -> NegativeImbalanceOf {
// The amount we are actually going to slash (can't be bigger than the validator's total
// exposure)
let slash = slash.min(exposure.total);
// limit what we'll slash of the stash's own to only what's in
// the exposure.
//
// note: this is fine only because we limit reports of the current era.
// otherwise, these funds may have already been slashed due to something
// reported from a prior era.
let already_slashed_own = journal.iter()
.filter(|entry| &entry.who == stash)
.map(|entry| entry.own_slash)
.fold(>::zero(), |a, c| a.saturating_add(c));
let own_remaining = exposure.own.saturating_sub(already_slashed_own);
// The amount we'll slash from the validator's stash directly.
let own_slash = own_remaining.min(slash);
let (mut imbalance, missing) = T::Currency::slash(stash, own_slash);
let own_slash = own_slash - missing;
// The amount remaining that we can't slash from the validator,
// that must be taken from the nominators.
let rest_slash = slash - own_slash;
if !rest_slash.is_zero() {
// The total to be slashed from the nominators.
let total = exposure.total - exposure.own;
if !total.is_zero() {
for i in exposure.others.iter() {
let per_u64 = Perbill::from_rational_approximation(i.value, total);
// best effort - not much that can be done on fail.
imbalance.subsume(T::Currency::slash(&i.who, per_u64 * rest_slash).0)
}
}
}
journal.push(SlashJournalEntry {
who: stash.clone(),
own_slash: own_slash.clone(),
amount: slash,
});
// trigger the event
Self::deposit_event(
RawEvent::Slash(stash.clone(), slash)
);
imbalance
}
/// Actually make a payment to a staker. This uses the currency's reward function
/// to pay the right payee for the given staker account.
fn make_payout(stash: &T::AccountId, amount: BalanceOf) -> Option> {
let dest = Self::payee(stash);
match dest {
RewardDestination::Controller => Self::bonded(stash)
.and_then(|controller|
T::Currency::deposit_into_existing(&controller, amount).ok()
),
RewardDestination::Stash =>
T::Currency::deposit_into_existing(stash, amount).ok(),
RewardDestination::Staked => Self::bonded(stash)
.and_then(|c| Self::ledger(&c).map(|l| (c, l)))
.and_then(|(controller, mut l)| {
l.active += amount;
l.total += amount;
let r = T::Currency::deposit_into_existing(stash, amount).ok();
Self::update_ledger(&controller, &l);
r
}),
}
}
/// Reward a given validator by a specific amount. Add the reward to the validator's, and its
/// nominators' balance, pro-rata based on their exposure, after having removed the validator's
/// pre-payout cut.
fn reward_validator(stash: &T::AccountId, reward: BalanceOf) -> PositiveImbalanceOf {
let off_the_table = reward.min(Self::validators(stash).validator_payment);
let reward = reward - off_the_table;
let mut imbalance = >::zero();
let validator_cut = if reward.is_zero() {
Zero::zero()
} else {
let exposure = Self::stakers(stash);
let total = exposure.total.max(One::one());
for i in &exposure.others {
let per_u64 = Perbill::from_rational_approximation(i.value, total);
imbalance.maybe_subsume(Self::make_payout(&i.who, per_u64 * reward));
}
let per_u64 = Perbill::from_rational_approximation(exposure.own, total);
per_u64 * reward
};
imbalance.maybe_subsume(Self::make_payout(stash, validator_cut + off_the_table));
imbalance
}
/// Session has just ended. Provide the validator set for the next session if it's an era-end, along
/// with the exposure of the prior validator set.
fn new_session(session_index: SessionIndex)
-> Option<(Vec, Vec<(T::AccountId, Exposure>)>)>
{
let era_length = session_index.checked_sub(Self::current_era_start_session_index()).unwrap_or(0);
match ForceEra::get() {
Forcing::ForceNew => ForceEra::kill(),
Forcing::NotForcing if era_length >= T::SessionsPerEra::get() => (),
_ => return None,
}
let validators = T::SessionInterface::validators();
let prior = validators.into_iter()
.map(|v| { let e = Self::stakers(&v); (v, e) })
.collect();
Self::new_era(session_index).map(move |new| (new, prior))
}
/// The era has changed - enact new staking set.
///
/// NOTE: This always happens immediately before a session change to ensure that new validators
/// get a chance to set their session keys.
fn new_era(start_session_index: SessionIndex) -> Option> {
// Payout
let points = CurrentEraPointsEarned::take();
let now = T::Time::now();
let previous_era_start = >::mutate(|v| {
rstd::mem::replace(v, now)
});
let era_duration = now - previous_era_start;
if !era_duration.is_zero() {
let validators = Self::current_elected();
let validator_len: BalanceOf = (validators.len() as u32).into();
let total_rewarded_stake = Self::slot_stake() * validator_len;
let total_payout = inflation::compute_total_payout(
total_rewarded_stake.clone(),
T::Currency::total_issuance(),
// Duration of era; more than u64::MAX is rewarded as u64::MAX.
era_duration.saturated_into::(),
);
let mut total_imbalance = >::zero();
for (v, p) in validators.iter().zip(points.individual.into_iter()) {
if p != 0 {
let reward = multiply_by_rational(total_payout, p, points.total);
total_imbalance.subsume(Self::reward_validator(v, reward));
}
}
let total_reward = total_imbalance.peek();
// assert!(total_reward <= total_payout)
Self::deposit_event(RawEvent::Reward(total_reward));
T::Reward::on_unbalanced(total_imbalance);
T::OnRewardMinted::on_dilution(total_reward, total_rewarded_stake);
}
// Increment current era.
let current_era = CurrentEra::mutate(|s| { *s += 1; *s });
// prune journal for last era.
>::remove(current_era - 1);
CurrentEraStartSessionIndex::mutate(|v| {
*v = start_session_index;
});
let bonding_duration = T::BondingDuration::get();
if current_era > bonding_duration {
let first_kept = current_era - bonding_duration;
BondedEras::mutate(|bonded| {
bonded.push((current_era, start_session_index));
// prune out everything that's from before the first-kept index.
let n_to_prune = bonded.iter()
.take_while(|&&(era_idx, _)| era_idx < first_kept)
.count();
bonded.drain(..n_to_prune);
if let Some(&(_, first_session)) = bonded.first() {
T::SessionInterface::prune_historical_up_to(first_session);
}
})
}
// Reassign all Stakers.
let (_slot_stake, maybe_new_validators) = Self::select_validators();
maybe_new_validators
}
/// Select a new validator set from the assembled stakers and their role preferences.
///
/// Returns the new `SlotStake` value and a set of newly selected _stash_ IDs.
fn select_validators() -> (BalanceOf, Option>) {
let maybe_phragmen_result = elect::<_, _, _, T::CurrencyToVote>(
Self::validator_count() as usize,
Self::minimum_validator_count().max(1) as usize,
>::enumerate().map(|(who, _)| who).collect::>(),
>::enumerate().collect(),
Self::slashable_balance_of,
true,
);
if let Some(phragmen_result) = maybe_phragmen_result {
let elected_stashes = phragmen_result.winners.iter().map(|(s, _)| s.clone()).collect::>();
let mut assignments = phragmen_result.assignments;
// helper closure.
let to_balance = |b: ExtendedBalance|
>>::convert(b);
let to_votes = |b: BalanceOf|
, u64>>::convert(b) as ExtendedBalance;
// The return value of this is safe to be converted to u64.
// The original balance, `b` is within the scope of u64. It is just extended to u128
// to be properly multiplied by a ratio, which will lead to another value
// less than u64 for sure. The result can then be safely passed to `to_balance`.
// For now the backward convert is used. A simple `TryFrom` is also safe.
let ratio_of = |b, r: ExtendedBalance| r.saturating_mul(to_votes(b)) / ACCURACY;
// Initialize the support of each candidate.
let mut supports = >::new();
elected_stashes
.iter()
.map(|e| (e, to_votes(Self::slashable_balance_of(e))))
.for_each(|(e, s)| {
let item = Support { own: s, total: s, ..Default::default() };
supports.insert(e.clone(), item);
});
// convert the ratio in-place (and replace) to the balance but still in the extended
// balance type.
for (n, assignment) in assignments.iter_mut() {
for (c, r) in assignment.iter_mut() {
let nominator_stake = Self::slashable_balance_of(n);
let other_stake = ratio_of(nominator_stake, *r);
if let Some(support) = supports.get_mut(c) {
// This for an astronomically rich validator with more astronomically rich
// set of nominators, this might saturate.
support.total = support.total.saturating_add(other_stake);
support.others.push((n.clone(), other_stake));
}
// convert the ratio to extended balance
*r = other_stake;
}
}
#[cfg(feature = "equalize")]
{
let tolerance = 0_u128;
let iterations = 2_usize;
equalize::<_, _, _, T::CurrencyToVote>(
assignments,
&mut supports,
tolerance,
iterations,
Self::slashable_balance_of,
);
}
// Clear Stakers.
for v in Self::current_elected().iter() {
>::remove(v);
}
// Populate Stakers and figure out the minimum stake behind a slot.
let mut slot_stake = BalanceOf::::max_value();
for (c, s) in supports.into_iter() {
// build `struct exposure` from `support`
let exposure = Exposure {
own: to_balance(s.own),
// This might reasonably saturate and we cannot do much about it. The sum of
// someone's stake might exceed the balance type if they have the maximum amount
// of balance and receive some support. This is super unlikely to happen, yet
// we simulate it in some tests.
total: to_balance(s.total),
others: s.others
.into_iter()
.map(|(who, value)| IndividualExposure { who, value: to_balance(value) })
.collect::>>(),
};
if exposure.total < slot_stake {
slot_stake = exposure.total;
}
>::insert(c.clone(), exposure.clone());
}
// Update slot stake.
>::put(&slot_stake);
// Set the new validator set in sessions.
>::put(&elected_stashes);
// In order to keep the property required by `n_session_ending`
// that we must return the new validator set even if it's the same as the old,
// as long as any underlying economic conditions have changed, we don't attempt
// to do any optimization where we compare against the prior set.
(slot_stake, Some(elected_stashes))
} else {
// There were not enough candidates for even our minimal level of functionality.
// This is bad.
// We should probably disable all functionality except for block production
// and let the chain keep producing blocks until we can decide on a sufficiently
// substantial set.
// TODO: #2494
(Self::slot_stake(), None)
}
}
/// Remove all associated data of a stash account from the staking system.
///
/// This is called :
/// - Immediately when an account's balance falls below existential deposit.
/// - after a `withdraw_unbond()` call that frees all of a stash's bonded balance.
fn kill_stash(stash: &T::AccountId) {
if let Some(controller) = >::take(stash) {
>::remove(&controller);
}
>::remove(stash);
>::remove(stash);
>::remove(stash);
}
/// Add reward points to validators using their stash account ID.
///
/// Validators are keyed by stash account ID and must be in the current elected set.
///
/// For each element in the iterator the given number of points in u32 is added to the
/// validator, thus duplicates are handled.
///
/// At the end of the era each the total payout will be distributed among validator
/// relatively to their points.
///
/// COMPLEXITY: Complexity is `number_of_validator_to_reward x current_elected_len`.
/// If you need to reward lots of validator consider using `reward_by_indices`.
pub fn reward_by_ids(validators_points: impl IntoIterator- ) {
CurrentEraPointsEarned::mutate(|rewards| {
let current_elected = >::current_elected();
for (validator, points) in validators_points.into_iter() {
if let Some(index) = current_elected.iter()
.position(|elected| *elected == validator)
{
rewards.add_points_to_index(index as u32, points);
}
}
});
}
/// Add reward points to validators using their validator index.
///
/// For each element in the iterator the given number of points in u32 is added to the
/// validator, thus duplicates are handled.
pub fn reward_by_indices(validators_points: impl IntoIterator
- ) {
// TODO: This can be optimised once #3302 is implemented.
let current_elected_len = >::current_elected().len() as u32;
CurrentEraPointsEarned::mutate(|rewards| {
for (validator_index, points) in validators_points.into_iter() {
if validator_index < current_elected_len {
rewards.add_points_to_index(validator_index, points);
}
}
});
}
}
impl session::OnSessionEnding for Module {
fn on_session_ending(_ending: SessionIndex, start_session: SessionIndex) -> Option> {
Self::new_session(start_session - 1).map(|(new, _old)| new)
}
}
impl OnSessionEnding>> for Module {
fn on_session_ending(_ending: SessionIndex, start_session: SessionIndex)
-> Option<(Vec, Vec<(T::AccountId, Exposure>)>)>
{
Self::new_session(start_session - 1)
}
}
impl OnFreeBalanceZero for Module {
fn on_free_balance_zero(stash: &T::AccountId) {
Self::kill_stash(stash);
}
}
/// Add reward points to block authors:
/// * 20 points to the block producer for producing a (non-uncle) block in the relay chain,
/// * 2 points to the block producer for each reference to a previously unreferenced uncle, and
/// * 1 point to the producer of each referenced uncle block.
impl authorship::EventHandler for Module {
fn note_author(author: T::AccountId) {
Self::reward_by_ids(vec![(author, 20)]);
}
fn note_uncle(author: T::AccountId, _age: T::BlockNumber) {
Self::reward_by_ids(vec![
(>::author(), 2),
(author, 1)
])
}
}
// This is guarantee not to overflow on whatever values.
// `num` must be inferior to `den` otherwise it will be reduce to `den`.
fn multiply_by_rational(value: N, num: u32, den: u32) -> N
where N: SimpleArithmetic + Clone
{
let num = num.min(den);
let result_divisor_part = value.clone() / den.into() * num.into();
let result_remainder_part = {
let rem = value % den.into();
// Fits into u32 because den is u32 and remainder < den
let rem_u32 = rem.saturated_into::();
// Multiplication fits into u64 as both term are u32
let rem_part = rem_u32 as u64 * num as u64 / den as u64;
// Result fits into u32 as num < total_points
(rem_part as u32).into()
};
result_divisor_part + result_remainder_part
}
/// A `Convert` implementation that finds the stash of the given controller account,
/// if any.
pub struct StashOf(rstd::marker::PhantomData);
impl Convert> for StashOf {
fn convert(controller: T::AccountId) -> Option {
>::ledger(&controller).map(|l| l.stash)
}
}
/// A typed conversion from stash account ID to the current exposure of nominators
/// on that account.
pub struct ExposureOf(rstd::marker::PhantomData);
impl Convert>>>
for ExposureOf
{
fn convert(validator: T::AccountId) -> Option>> {
Some(>::stakers(&validator))
}
}
impl SelectInitialValidators for Module {
fn select_initial_validators() -> Option> {
>::select_validators().1
}
}
/// This is intended to be used with `FilterHistoricalOffences`.
impl OnOffenceHandler> for Module where
T: session::Trait::AccountId>,
T: session::historical::Trait<
FullIdentification = Exposure<::AccountId, BalanceOf>,
FullIdentificationOf = ExposureOf,
>,
T::SessionHandler: session::SessionHandler<::AccountId>,
T::OnSessionEnding: session::OnSessionEnding<::AccountId>,
T::SelectInitialValidators: session::SelectInitialValidators<::AccountId>,
T::ValidatorIdOf: Convert<::AccountId, Option<::AccountId>>
{
fn on_offence(
offenders: &[OffenceDetails>],
slash_fraction: &[Perbill],
) {
let mut remaining_imbalance = >::zero();
let slash_reward_fraction = SlashRewardFraction::get();
let era_now = Self::current_era();
let mut journal = Self::era_slash_journal(era_now);
for (details, slash_fraction) in offenders.iter().zip(slash_fraction) {
let stash = &details.offender.0;
let exposure = &details.offender.1;
// Skip if the validator is invulnerable.
if Self::invulnerables().contains(stash) {
continue
}
// calculate the amount to slash
let slash_exposure = exposure.total;
let amount = *slash_fraction * slash_exposure;
// in some cases `slash_fraction` can be just `0`,
// which means we are not slashing this time.
if amount.is_zero() {
continue;
}
// make sure to disable validator in next sessions
let _ = T::SessionInterface::disable_validator(stash);
// force a new era, to select a new validator set
ForceEra::put(Forcing::ForceNew);
// actually slash the validator
let slashed_amount = Self::slash_validator(stash, amount, exposure, &mut journal);
// distribute the rewards according to the slash
let slash_reward = slash_reward_fraction * slashed_amount.peek();
if !slash_reward.is_zero() && !details.reporters.is_empty() {
let (mut reward, rest) = slashed_amount.split(slash_reward);
// split the reward between reporters equally. Division cannot fail because
// we guarded against it in the enclosing if.
let per_reporter = reward.peek() / (details.reporters.len() as u32).into();
for reporter in &details.reporters {
let (reporter_reward, rest) = reward.split(per_reporter);
reward = rest;
T::Currency::resolve_creating(reporter, reporter_reward);
}
// The rest goes to the treasury.
remaining_imbalance.subsume(reward);
remaining_imbalance.subsume(rest);
} else {
remaining_imbalance.subsume(slashed_amount);
}
}
>::insert(era_now, journal);
// Handle the rest of imbalances
T::Slash::on_unbalanced(remaining_imbalance);
}
}
/// Filter historical offences out and only allow those from the current era.
pub struct FilterHistoricalOffences {
_inner: rstd::marker::PhantomData<(T, R)>,
}
impl ReportOffence
for FilterHistoricalOffences, R> where
T: Trait,
R: ReportOffence,
O: Offence,
{
fn report_offence(reporters: Vec, offence: O) {
// disallow any slashing from before the current era.
let offence_session = offence.session_index();
if offence_session >= >::current_era_start_session_index() {
R::report_offence(reporters, offence)
} else {
>::deposit_event(
RawEvent::OldSlashingReportDiscarded(offence_session)
)
}
}
}