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&v,
Nominations { targets: t, submitted_in: 0, suppressed: false },
);
});
}
}
/// In this implementation `new_session(session)` must be called before `end_session(session-1)`
/// i.e. the new session must be planned before the ending of the previous session.
///
/// Once the first new_session is planned, all session must start and then end in order, though
/// some session can lag in between the newest session planned and the latest session started.
impl<T: Config> pallet_session::SessionManager<T::AccountId> for Pallet<T> {
fn new_session(new_index: SessionIndex) -> Option<Vec<T::AccountId>> {
log!(trace, "planning new session {}", new_index);
CurrentPlannedSession::<T>::put(new_index);
Self::new_session(new_index, false)
}
fn new_session_genesis(new_index: SessionIndex) -> Option<Vec<T::AccountId>> {
log!(trace, "planning new session {} at genesis", new_index);
CurrentPlannedSession::<T>::put(new_index);
Self::new_session(new_index, true)
}
fn start_session(start_index: SessionIndex) {
log!(trace, "starting session {}", start_index);
Self::start_session(start_index)
}
fn end_session(end_index: SessionIndex) {
log!(trace, "ending session {}", end_index);
Self::end_session(end_index)
}
}
impl<T: Config> historical::SessionManager<T::AccountId, Exposure<T::AccountId, BalanceOf<T>>>
for Pallet<T>
{
fn new_session(
new_index: SessionIndex,
) -> Option<Vec<(T::AccountId, Exposure<T::AccountId, BalanceOf<T>>)>> {
<Self as pallet_session::SessionManager<_>>::new_session(new_index).map(|validators| {
let current_era = Self::current_era()
// Must be some as a new era has been created.
.unwrap_or(0);
validators
.into_iter()
.map(|v| {
let exposure = Self::eras_stakers(current_era, &v);
(v, exposure)
})
.collect()
})
}
fn new_session_genesis(
new_index: SessionIndex,
) -> Option<Vec<(T::AccountId, Exposure<T::AccountId, BalanceOf<T>>)>> {
<Self as pallet_session::SessionManager<_>>::new_session_genesis(new_index).map(
|validators| {
let current_era = Self::current_era()
// Must be some as a new era has been created.
.unwrap_or(0);
validators
.into_iter()
.map(|v| {
let exposure = Self::eras_stakers(current_era, &v);
(v, exposure)
})
.collect()
},
)
}
fn start_session(start_index: SessionIndex) {
<Self as pallet_session::SessionManager<_>>::start_session(start_index)
}
fn end_session(end_index: SessionIndex) {
<Self as pallet_session::SessionManager<_>>::end_session(end_index)
}
}
/// 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<T> pallet_authorship::EventHandler<T::AccountId, T::BlockNumber> for Pallet<T>
where
T: Config + pallet_authorship::Config + pallet_session::Config,
{
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![(<pallet_authorship::Pallet<T>>::author(), 2), (author, 1)])
}
}
/// This is intended to be used with `FilterHistoricalOffences`.
impl<T: Config>
OnOffenceHandler<T::AccountId, pallet_session::historical::IdentificationTuple<T>, Weight>
for Pallet<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>,
>,
{
fn on_offence(
offenders: &[OffenceDetails<
T::AccountId,
pallet_session::historical::IdentificationTuple<T>,
>],
slash_fraction: &[Perbill],
slash_session: SessionIndex,
disable_strategy: DisableStrategy,
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) -> Weight {
let reward_proportion = SlashRewardFraction::<T>::get();
let mut consumed_weight: Weight = 0;
let mut add_db_reads_writes = |reads, writes| {
consumed_weight += T::DbWeight::get().reads_writes(reads, writes);
};
let active_era = {
let active_era = Self::active_era();
add_db_reads_writes(1, 0);
if active_era.is_none() {
// This offence need not be re-submitted.
return consumed_weight
}
active_era.expect("value checked not to be `None`; qed").index
};
let active_era_start_session_index = Self::eras_start_session_index(active_era)
.unwrap_or_else(|| {
frame_support::print("Error: start_session_index must be set for current_era");
0
});
add_db_reads_writes(1, 0);
let window_start = active_era.saturating_sub(T::BondingDuration::get());
// Fast path for active-era report - most likely.
// `slash_session` cannot be in a future active era. It must be in `active_era` or before.
let slash_era = if slash_session >= active_era_start_session_index {
active_era
} else {
let eras = BondedEras::<T>::get();
add_db_reads_writes(1, 0);
// Reverse because it's more likely to find reports from recent eras.
match eras.iter().rev().filter(|&&(_, ref sesh)| sesh <= &slash_session).next() {
Some(&(ref slash_era, _)) => *slash_era,
// Before bonding period. defensive - should be filtered out.
None => return consumed_weight,
}
};
<Self as Store>::EarliestUnappliedSlash::mutate(|earliest| {
if earliest.is_none() {
*earliest = Some(active_era)
}
});
add_db_reads_writes(1, 1);
let slash_defer_duration = T::SlashDeferDuration::get();
let invulnerables = Self::invulnerables();
add_db_reads_writes(1, 0);
for (details, slash_fraction) in offenders.iter().zip(slash_fraction) {
let (stash, exposure) = &details.offender;
// Skip if the validator is invulnerable.
if invulnerables.contains(stash) {
continue
}
let unapplied = slashing::compute_slash::<T>(slashing::SlashParams {
stash,
slash: *slash_fraction,
exposure,
slash_era,
window_start,
now: active_era,
reward_proportion,
disable_strategy,
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});
if let Some(mut unapplied) = unapplied {
let nominators_len = unapplied.others.len() as u64;
let reporters_len = details.reporters.len() as u64;
{
let upper_bound = 1 /* Validator/NominatorSlashInEra */ + 2 /* fetch_spans */;
let rw = upper_bound + nominators_len * upper_bound;
add_db_reads_writes(rw, rw);
}
unapplied.reporters = details.reporters.clone();
if slash_defer_duration == 0 {
// Apply right away.
slashing::apply_slash::<T>(unapplied);
{
let slash_cost = (6, 5);
let reward_cost = (2, 2);
add_db_reads_writes(
(1 + nominators_len) * slash_cost.0 + reward_cost.0 * reporters_len,
(1 + nominators_len) * slash_cost.1 + reward_cost.1 * reporters_len,
);
}
} else {
// Defer to end of some `slash_defer_duration` from now.
<Self as Store>::UnappliedSlashes::mutate(active_era, move |for_later| {
for_later.push(unapplied)
});
add_db_reads_writes(1, 1);
}
} else {
add_db_reads_writes(4 /* fetch_spans */, 5 /* kick_out_if_recent */)
}
}
consumed_weight
}
}
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impl<T: Config> VoteWeightProvider<T::AccountId> for Pallet<T> {
fn vote_weight(who: &T::AccountId) -> VoteWeight {
Self::weight_of(who)
}
#[cfg(feature = "runtime-benchmarks")]
fn set_vote_weight_of(who: &T::AccountId, weight: VoteWeight) {
// this will clearly results in an inconsistent state, but it should not matter for a
// benchmark.
let active: BalanceOf<T> = weight.try_into().map_err(|_| ()).unwrap();
let mut ledger = Self::ledger(who).unwrap_or_default();
ledger.active = active;
<Ledger<T>>::insert(who, ledger);
<Bonded<T>>::insert(who, who);
// also, we play a trick to make sure that a issuance based-`CurrencyToVote` behaves well:
// This will make sure that total issuance is zero, thus the currency to vote will be a 1-1
// conversion.
let imbalance = T::Currency::burn(T::Currency::total_issuance());
// kinda ugly, but gets the job done. The fact that this works here is a HUGE exception.
// Don't try this pattern in other places.
sp_std::mem::forget(imbalance);
}
}
/// A simple voter list implementation that does not require any additional pallets. Note, this
/// does not provided nominators in sorted ordered. If you desire nominators in a sorted order take
/// a look at [`pallet-bags-list].
pub struct UseNominatorsMap<T>(sp_std::marker::PhantomData<T>);
impl<T: Config> SortedListProvider<T::AccountId> for UseNominatorsMap<T> {
type Error = ();
/// Returns iterator over voter list, which can have `take` called on it.
fn iter() -> Box<dyn Iterator<Item = T::AccountId>> {
Box::new(Nominators::<T>::iter().map(|(n, _)| n))
}
fn count() -> u32 {
Nominators::<T>::count()
}
fn contains(id: &T::AccountId) -> bool {
Nominators::<T>::contains_key(id)
}
fn on_insert(_: T::AccountId, _weight: VoteWeight) -> Result<(), Self::Error> {
// nothing to do on insert.
Ok(())
}
fn on_update(_: &T::AccountId, _weight: VoteWeight) {
// nothing to do on update.
}
fn on_remove(_: &T::AccountId) {
// nothing to do on remove.
}
_: impl IntoIterator<Item = T::AccountId>,
_: Box<dyn Fn(&T::AccountId) -> VoteWeight>,
) -> u32 {
// nothing to do upon regenerate.
0
}
fn sanity_check() -> Result<(), &'static str> {
Ok(())
}
fn unsafe_clear() {
// NOTE: Caller must ensure this doesn't lead to too many storage accesses. This is a
// condition of SortedListProvider::unsafe_clear.
Nominators::<T>::remove_all();