use util::time::Time;
use prelude::*;
-use core::fmt;
+use core::{cmp, fmt};
use core::cell::{RefCell, RefMut};
use core::convert::TryInto;
use core::ops::{Deref, DerefMut};
/// use the Persister to persist it.
pub trait WriteableScore<'a>: LockableScore<'a> + Writeable {}
+#[cfg(not(c_bindings))]
impl<'a, T> WriteableScore<'a> for T where T: LockableScore<'a> + Writeable {}
/// (C-not exported)
score: Mutex<S>,
}
#[cfg(c_bindings)]
-/// (C-not exported)
+/// A locked `MultiThreadedLockableScore`.
+pub struct MultiThreadedScoreLock<'a, S: Score>(MutexGuard<'a, S>);
+#[cfg(c_bindings)]
+impl<'a, T: Score + 'a> Score for MultiThreadedScoreLock<'a, T> {
+ fn channel_penalty_msat(&self, scid: u64, source: &NodeId, target: &NodeId, usage: ChannelUsage) -> u64 {
+ self.0.channel_penalty_msat(scid, source, target, usage)
+ }
+ fn payment_path_failed(&mut self, path: &[&RouteHop], short_channel_id: u64) {
+ self.0.payment_path_failed(path, short_channel_id)
+ }
+ fn payment_path_successful(&mut self, path: &[&RouteHop]) {
+ self.0.payment_path_successful(path)
+ }
+ fn probe_failed(&mut self, path: &[&RouteHop], short_channel_id: u64) {
+ self.0.probe_failed(path, short_channel_id)
+ }
+ fn probe_successful(&mut self, path: &[&RouteHop]) {
+ self.0.probe_successful(path)
+ }
+}
+#[cfg(c_bindings)]
+impl<'a, T: Score + 'a> Writeable for MultiThreadedScoreLock<'a, T> {
+ fn write<W: Writer>(&self, writer: &mut W) -> Result<(), io::Error> {
+ self.0.write(writer)
+ }
+}
+
+#[cfg(c_bindings)]
impl<'a, T: Score + 'a> LockableScore<'a> for MultiThreadedLockableScore<T> {
- type Locked = MutexGuard<'a, T>;
+ type Locked = MultiThreadedScoreLock<'a, T>;
- fn lock(&'a self) -> MutexGuard<'a, T> {
- Mutex::lock(&self.score).unwrap()
+ fn lock(&'a self) -> MultiThreadedScoreLock<'a, T> {
+ MultiThreadedScoreLock(Mutex::lock(&self.score).unwrap())
}
}
}
/// Proposed use of a channel passed as a parameter to [`Score::channel_penalty_msat`].
-#[derive(Clone, Copy)]
+#[derive(Clone, Copy, Debug)]
pub struct ChannelUsage {
/// The amount to send through the channel, denominated in millisatoshis.
pub amount_msat: u64,
pub base_penalty_amount_multiplier_msat: u64,
/// A multiplier used in conjunction with the negative `log10` of the channel's success
- /// probability for a payment to determine the liquidity penalty.
+ /// probability for a payment, as determined by our latest estimates of the channel's
+ /// liquidity, to determine the liquidity penalty.
///
/// The penalty is based in part on the knowledge learned from prior successful and unsuccessful
/// payments. This knowledge is decayed over time based on [`liquidity_offset_half_life`]. The
/// uncertainty bounds of the channel liquidity balance. Amounts above the upper bound will
/// result in a `u64::max_value` penalty, however.
///
- /// Default value: 40,000 msat
+ /// Default value: 30,000 msat
///
/// [`liquidity_offset_half_life`]: Self::liquidity_offset_half_life
pub liquidity_penalty_multiplier_msat: u64,
pub liquidity_offset_half_life: Duration,
/// A multiplier used in conjunction with a payment amount and the negative `log10` of the
- /// channel's success probability for the payment to determine the amount penalty.
+ /// channel's success probability for the payment, as determined by our latest estimates of the
+ /// channel's liquidity, to determine the amount penalty.
///
/// The purpose of the amount penalty is to avoid having fees dominate the channel cost (i.e.,
/// fees plus penalty) for large payments. The penalty is computed as the product of this
/// probabilities, the multiplier will have a decreasing effect as the negative `log10` will
/// fall below `1`.
///
- /// Default value: 256 msat
+ /// Default value: 192 msat
pub liquidity_penalty_amount_multiplier_msat: u64,
+ /// A multiplier used in conjunction with the negative `log10` of the channel's success
+ /// probability for the payment, as determined based on the history of our estimates of the
+ /// channel's available liquidity, to determine a penalty.
+ ///
+ /// This penalty is similar to [`liquidity_penalty_multiplier_msat`], however, instead of using
+ /// only our latest estimate for the current liquidity available in the channel, it estimates
+ /// success probability based on the estimated liquidity available in the channel through
+ /// history. Specifically, every time we update our liquidity bounds on a given channel, we
+ /// track which of several buckets those bounds fall into, exponentially decaying the
+ /// probability of each bucket as new samples are added.
+ ///
+ /// Default value: 10,000 msat
+ ///
+ /// [`liquidity_penalty_multiplier_msat`]: Self::liquidity_penalty_multiplier_msat
+ pub historical_liquidity_penalty_multiplier_msat: u64,
+
+ /// A multiplier used in conjunction with the payment amount and the negative `log10` of the
+ /// channel's success probability for the payment, as determined based on the history of our
+ /// estimates of the channel's available liquidity, to determine a penalty.
+ ///
+ /// The purpose of the amount penalty is to avoid having fees dominate the channel cost for
+ /// large payments. The penalty is computed as the product of this multiplier and the `2^20`ths
+ /// of the payment amount, weighted by the negative `log10` of the success probability.
+ ///
+ /// This penalty is similar to [`liquidity_penalty_amount_multiplier_msat`], however, instead
+ /// of using only our latest estimate for the current liquidity available in the channel, it
+ /// estimates success probability based on the estimated liquidity available in the channel
+ /// through history. Specifically, every time we update our liquidity bounds on a given
+ /// channel, we track which of several buckets those bounds fall into, exponentially decaying
+ /// the probability of each bucket as new samples are added.
+ ///
+ /// Default value: 64 msat
+ ///
+ /// [`liquidity_penalty_amount_multiplier_msat`]: Self::liquidity_penalty_amount_multiplier_msat
+ pub historical_liquidity_penalty_amount_multiplier_msat: u64,
+
+ /// If we aren't learning any new datapoints for a channel, the historical liquidity bounds
+ /// tracking can simply live on with increasingly stale data. Instead, when a channel has not
+ /// seen a liquidity estimate update for this amount of time, the historical datapoints are
+ /// decayed by half.
+ ///
+ /// Note that after 16 or more half lives all historical data will be completely gone.
+ ///
+ /// Default value: 14 days
+ pub historical_no_updates_half_life: Duration,
+
/// Manual penalties used for the given nodes. Allows to set a particular penalty for a given
/// node. Note that a manual penalty of `u64::max_value()` means the node would not ever be
/// considered during path finding.
self.buckets[bucket_idx as usize] = self.buckets[bucket_idx as usize].saturating_add(32);
}
}
+ /// Decay all buckets by the given number of half-lives. Used to more aggressively remove old
+ /// datapoints as we receive newer information.
+ fn time_decay_data(&mut self, half_lives: u32) {
+ for e in self.buckets.iter_mut() {
+ *e = e.checked_shr(half_lives).unwrap_or(0);
+ }
+ }
}
impl_writeable_tlv_based!(HistoricalBucketRangeTracker, { (0, buckets, required) });
+struct HistoricalMinMaxBuckets<'a> {
+ min_liquidity_offset_history: &'a HistoricalBucketRangeTracker,
+ max_liquidity_offset_history: &'a HistoricalBucketRangeTracker,
+}
+
+impl HistoricalMinMaxBuckets<'_> {
+ #[inline]
+ fn calculate_success_probability_times_billion(&self, required_decays: u32, payment_amt_64th_bucket: u8) -> Option<u64> {
+ // If historical penalties are enabled, calculate the penalty by walking the set of
+ // historical liquidity bucket (min, max) combinations (where min_idx < max_idx) and, for
+ // each, calculate the probability of success given our payment amount, then total the
+ // weighted average probability of success.
+ //
+ // We use a sliding scale to decide which point within a given bucket will be compared to
+ // the amount being sent - for lower-bounds, the amount being sent is compared to the lower
+ // edge of the first bucket (i.e. zero), but compared to the upper 7/8ths of the last
+ // bucket (i.e. 9 times the index, or 63), with each bucket in between increasing the
+ // comparison point by 1/64th. For upper-bounds, the same applies, however with an offset
+ // of 1/64th (i.e. starting at one and ending at 64). This avoids failing to assign
+ // penalties to channels at the edges.
+ //
+ // If we used the bottom edge of buckets, we'd end up never assigning any penalty at all to
+ // such a channel when sending less than ~0.19% of the channel's capacity (e.g. ~200k sats
+ // for a 1 BTC channel!).
+ //
+ // If we used the middle of each bucket we'd never assign any penalty at all when sending
+ // less than 1/16th of a channel's capacity, or 1/8th if we used the top of the bucket.
+ let mut total_valid_points_tracked = 0;
+
+ // Rather than actually decaying the individual buckets, which would lose precision, we
+ // simply track whether all buckets would be decayed to zero, in which case we treat it as
+ // if we had no data.
+ let mut is_fully_decayed = true;
+ let mut check_track_bucket_contains_undecayed_points =
+ |bucket_val: u16| if bucket_val.checked_shr(required_decays).unwrap_or(0) > 0 { is_fully_decayed = false; };
+
+ for (min_idx, min_bucket) in self.min_liquidity_offset_history.buckets.iter().enumerate() {
+ check_track_bucket_contains_undecayed_points(*min_bucket);
+ for max_bucket in self.max_liquidity_offset_history.buckets.iter().take(8 - min_idx) {
+ total_valid_points_tracked += (*min_bucket as u64) * (*max_bucket as u64);
+ check_track_bucket_contains_undecayed_points(*max_bucket);
+ }
+ }
+ // If the total valid points is smaller than 1.0 (i.e. 32 in our fixed-point scheme), treat
+ // it as if we were fully decayed.
+ if total_valid_points_tracked.checked_shr(required_decays).unwrap_or(0) < 32*32 || is_fully_decayed {
+ return None;
+ }
+
+ let mut cumulative_success_prob_times_billion = 0;
+ for (min_idx, min_bucket) in self.min_liquidity_offset_history.buckets.iter().enumerate() {
+ for (max_idx, max_bucket) in self.max_liquidity_offset_history.buckets.iter().enumerate().take(8 - min_idx) {
+ let bucket_prob_times_million = (*min_bucket as u64) * (*max_bucket as u64)
+ * 1024 * 1024 / total_valid_points_tracked;
+ let min_64th_bucket = min_idx as u8 * 9;
+ let max_64th_bucket = (7 - max_idx as u8) * 9 + 1;
+ if payment_amt_64th_bucket > max_64th_bucket {
+ // Success probability 0, the payment amount is above the max liquidity
+ } else if payment_amt_64th_bucket <= min_64th_bucket {
+ cumulative_success_prob_times_billion += bucket_prob_times_million * 1024;
+ } else {
+ cumulative_success_prob_times_billion += bucket_prob_times_million *
+ ((max_64th_bucket - payment_amt_64th_bucket) as u64) * 1024 /
+ ((max_64th_bucket - min_64th_bucket) as u64);
+ }
+ }
+ }
+
+ Some(cumulative_success_prob_times_billion)
+ }
+}
+
/// Accounting for channel liquidity balance uncertainty.
///
/// Direction is defined in terms of [`NodeId`] partial ordering, where the source node is the
/// A snapshot of [`ChannelLiquidity`] in one direction assuming a certain channel capacity and
/// decayed with a given half life.
-struct DirectedChannelLiquidity<L: Deref<Target = u64>, BRT: Deref<Target = HistoricalBucketRangeTracker>, T: Time, U: Deref<Target = T>> {
+struct DirectedChannelLiquidity<'a, L: Deref<Target = u64>, BRT: Deref<Target = HistoricalBucketRangeTracker>, T: Time, U: Deref<Target = T>> {
min_liquidity_offset_msat: L,
max_liquidity_offset_msat: L,
min_liquidity_offset_history: BRT,
capacity_msat: u64,
last_updated: U,
now: T,
- half_life: Duration,
+ params: &'a ProbabilisticScoringParameters,
}
impl<G: Deref<Target = NetworkGraph<L>>, L: Deref, T: Time> ProbabilisticScorerUsingTime<G, L, T> where L::Target: Logger {
let log_direction = |source, target| {
if let Some((directed_info, _)) = chan_debug.as_directed_to(target) {
let amt = directed_info.effective_capacity().as_msat();
- let dir_liq = liq.as_directed(source, target, amt, self.params.liquidity_offset_half_life);
+ let dir_liq = liq.as_directed(source, target, amt, &self.params);
log_debug!(self.logger, "Liquidity from {:?} to {:?} via {} is in the range ({}, {})",
source, target, scid, dir_liq.min_liquidity_msat(), dir_liq.max_liquidity_msat());
} else {
if let Some(liq) = self.channel_liquidities.get(&scid) {
if let Some((directed_info, source)) = chan.as_directed_to(target) {
let amt = directed_info.effective_capacity().as_msat();
- let dir_liq = liq.as_directed(source, target, amt, self.params.liquidity_offset_half_life);
+ let dir_liq = liq.as_directed(source, target, amt, &self.params);
return Some((dir_liq.min_liquidity_msat(), dir_liq.max_liquidity_msat()));
}
}
liquidity_penalty_multiplier_msat: 0,
liquidity_offset_half_life: Duration::from_secs(3600),
liquidity_penalty_amount_multiplier_msat: 0,
+ historical_liquidity_penalty_multiplier_msat: 0,
+ historical_liquidity_penalty_amount_multiplier_msat: 0,
+ historical_no_updates_half_life: Duration::from_secs(60 * 60 * 24 * 14),
manual_node_penalties: HashMap::new(),
anti_probing_penalty_msat: 0,
considered_impossible_penalty_msat: 0,
Self {
base_penalty_msat: 500,
base_penalty_amount_multiplier_msat: 8192,
- liquidity_penalty_multiplier_msat: 40_000,
+ liquidity_penalty_multiplier_msat: 30_000,
liquidity_offset_half_life: Duration::from_secs(3600),
- liquidity_penalty_amount_multiplier_msat: 256,
+ liquidity_penalty_amount_multiplier_msat: 192,
+ historical_liquidity_penalty_multiplier_msat: 10_000,
+ historical_liquidity_penalty_amount_multiplier_msat: 64,
+ historical_no_updates_half_life: Duration::from_secs(60 * 60 * 24 * 14),
manual_node_penalties: HashMap::new(),
anti_probing_penalty_msat: 250,
considered_impossible_penalty_msat: 1_0000_0000_000,
/// Returns a view of the channel liquidity directed from `source` to `target` assuming
/// `capacity_msat`.
- fn as_directed(
- &self, source: &NodeId, target: &NodeId, capacity_msat: u64, half_life: Duration
- ) -> DirectedChannelLiquidity<&u64, &HistoricalBucketRangeTracker, T, &T> {
+ fn as_directed<'a>(
+ &self, source: &NodeId, target: &NodeId, capacity_msat: u64, params: &'a ProbabilisticScoringParameters
+ ) -> DirectedChannelLiquidity<'a, &u64, &HistoricalBucketRangeTracker, T, &T> {
let (min_liquidity_offset_msat, max_liquidity_offset_msat, min_liquidity_offset_history, max_liquidity_offset_history) =
if source < target {
(&self.min_liquidity_offset_msat, &self.max_liquidity_offset_msat,
capacity_msat,
last_updated: &self.last_updated,
now: T::now(),
- half_life,
+ params,
}
}
/// Returns a mutable view of the channel liquidity directed from `source` to `target` assuming
/// `capacity_msat`.
- fn as_directed_mut(
- &mut self, source: &NodeId, target: &NodeId, capacity_msat: u64, half_life: Duration
- ) -> DirectedChannelLiquidity<&mut u64, &mut HistoricalBucketRangeTracker, T, &mut T> {
+ fn as_directed_mut<'a>(
+ &mut self, source: &NodeId, target: &NodeId, capacity_msat: u64, params: &'a ProbabilisticScoringParameters
+ ) -> DirectedChannelLiquidity<'a, &mut u64, &mut HistoricalBucketRangeTracker, T, &mut T> {
let (min_liquidity_offset_msat, max_liquidity_offset_msat, min_liquidity_offset_history, max_liquidity_offset_history) =
if source < target {
(&mut self.min_liquidity_offset_msat, &mut self.max_liquidity_offset_msat,
capacity_msat,
last_updated: &mut self.last_updated,
now: T::now(),
- half_life,
+ params,
}
}
}
const AMOUNT_PENALTY_DIVISOR: u64 = 1 << 20;
const BASE_AMOUNT_PENALTY_DIVISOR: u64 = 1 << 30;
-impl<L: Deref<Target = u64>, BRT: Deref<Target = HistoricalBucketRangeTracker>, T: Time, U: Deref<Target = T>> DirectedChannelLiquidity<L, BRT, T, U> {
+impl<L: Deref<Target = u64>, BRT: Deref<Target = HistoricalBucketRangeTracker>, T: Time, U: Deref<Target = T>> DirectedChannelLiquidity<'_, L, BRT, T, U> {
/// Returns a liquidity penalty for routing the given HTLC `amount_msat` through the channel in
/// this direction.
fn penalty_msat(&self, amount_msat: u64, params: &ProbabilisticScoringParameters) -> u64 {
let max_liquidity_msat = self.max_liquidity_msat();
let min_liquidity_msat = core::cmp::min(self.min_liquidity_msat(), max_liquidity_msat);
- if amount_msat <= min_liquidity_msat {
+
+ let mut res = if amount_msat <= min_liquidity_msat {
0
} else if amount_msat >= max_liquidity_msat {
// Equivalent to hitting the else clause below with the amount equal to the effective
// capacity and without any certainty on the liquidity upper bound, plus the
// impossibility penalty.
let negative_log10_times_2048 = NEGATIVE_LOG10_UPPER_BOUND * 2048;
- self.combined_penalty_msat(amount_msat, negative_log10_times_2048, params)
+ Self::combined_penalty_msat(amount_msat, negative_log10_times_2048,
+ params.liquidity_penalty_multiplier_msat,
+ params.liquidity_penalty_amount_multiplier_msat)
.saturating_add(params.considered_impossible_penalty_msat)
} else {
let numerator = (max_liquidity_msat - amount_msat).saturating_add(1);
} else {
let negative_log10_times_2048 =
approx::negative_log10_times_2048(numerator, denominator);
- self.combined_penalty_msat(amount_msat, negative_log10_times_2048, params)
+ Self::combined_penalty_msat(amount_msat, negative_log10_times_2048,
+ params.liquidity_penalty_multiplier_msat,
+ params.liquidity_penalty_amount_multiplier_msat)
+ }
+ };
+
+ if params.historical_liquidity_penalty_multiplier_msat != 0 ||
+ params.historical_liquidity_penalty_amount_multiplier_msat != 0 {
+ let required_decays = self.now.duration_since(*self.last_updated).as_secs()
+ .checked_div(params.historical_no_updates_half_life.as_secs())
+ .map_or(u32::max_value(), |decays| cmp::min(decays, u32::max_value() as u64) as u32);
+ let payment_amt_64th_bucket = amount_msat * 64 / self.capacity_msat;
+ debug_assert!(payment_amt_64th_bucket <= 64);
+ if payment_amt_64th_bucket > 64 { return res; }
+
+ let buckets = HistoricalMinMaxBuckets {
+ min_liquidity_offset_history: &self.min_liquidity_offset_history,
+ max_liquidity_offset_history: &self.max_liquidity_offset_history,
+ };
+ if let Some(cumulative_success_prob_times_billion) = buckets
+ .calculate_success_probability_times_billion(required_decays, payment_amt_64th_bucket as u8) {
+ let historical_negative_log10_times_2048 = approx::negative_log10_times_2048(cumulative_success_prob_times_billion + 1, 1024 * 1024 * 1024);
+ res = res.saturating_add(Self::combined_penalty_msat(amount_msat,
+ historical_negative_log10_times_2048, params.historical_liquidity_penalty_multiplier_msat,
+ params.historical_liquidity_penalty_amount_multiplier_msat));
+ } else {
+ // If we don't have any valid points (or, once decayed, we have less than a full
+ // point), redo the non-historical calculation with no liquidity bounds tracked and
+ // the historical penalty multipliers.
+ let max_capacity = self.capacity_msat.saturating_sub(amount_msat).saturating_add(1);
+ let negative_log10_times_2048 =
+ approx::negative_log10_times_2048(max_capacity, self.capacity_msat.saturating_add(1));
+ res = res.saturating_add(Self::combined_penalty_msat(amount_msat, negative_log10_times_2048,
+ params.historical_liquidity_penalty_multiplier_msat,
+ params.historical_liquidity_penalty_amount_multiplier_msat));
+ return res;
}
}
+
+ res
}
/// Computes the liquidity penalty from the penalty multipliers.
#[inline(always)]
- fn combined_penalty_msat(
- &self, amount_msat: u64, negative_log10_times_2048: u64,
- params: &ProbabilisticScoringParameters
+ fn combined_penalty_msat(amount_msat: u64, negative_log10_times_2048: u64,
+ liquidity_penalty_multiplier_msat: u64, liquidity_penalty_amount_multiplier_msat: u64,
) -> u64 {
let liquidity_penalty_msat = {
// Upper bound the liquidity penalty to ensure some channel is selected.
- let multiplier_msat = params.liquidity_penalty_multiplier_msat;
+ let multiplier_msat = liquidity_penalty_multiplier_msat;
let max_penalty_msat = multiplier_msat.saturating_mul(NEGATIVE_LOG10_UPPER_BOUND);
(negative_log10_times_2048.saturating_mul(multiplier_msat) / 2048).min(max_penalty_msat)
};
let amount_penalty_msat = negative_log10_times_2048
- .saturating_mul(params.liquidity_penalty_amount_multiplier_msat)
+ .saturating_mul(liquidity_penalty_amount_multiplier_msat)
.saturating_mul(amount_msat) / 2048 / AMOUNT_PENALTY_DIVISOR;
liquidity_penalty_msat.saturating_add(amount_penalty_msat)
fn decayed_offset_msat(&self, offset_msat: u64) -> u64 {
self.now.duration_since(*self.last_updated).as_secs()
- .checked_div(self.half_life.as_secs())
+ .checked_div(self.params.liquidity_offset_half_life.as_secs())
.and_then(|decays| offset_msat.checked_shr(decays as u32))
.unwrap_or(0)
}
}
-impl<L: DerefMut<Target = u64>, BRT: DerefMut<Target = HistoricalBucketRangeTracker>, T: Time, U: DerefMut<Target = T>> DirectedChannelLiquidity<L, BRT, T, U> {
+impl<L: DerefMut<Target = u64>, BRT: DerefMut<Target = HistoricalBucketRangeTracker>, T: Time, U: DerefMut<Target = T>> DirectedChannelLiquidity<'_, L, BRT, T, U> {
/// Adjusts the channel liquidity balance bounds when failing to route `amount_msat`.
fn failed_at_channel<Log: Deref>(&mut self, amount_msat: u64, chan_descr: fmt::Arguments, logger: &Log) where Log::Target: Logger {
- if amount_msat < self.max_liquidity_msat() {
- log_debug!(logger, "Setting max liquidity of {} to {}", chan_descr, amount_msat);
+ let existing_max_msat = self.max_liquidity_msat();
+ if amount_msat < existing_max_msat {
+ log_debug!(logger, "Setting max liquidity of {} from {} to {}", chan_descr, existing_max_msat, amount_msat);
self.set_max_liquidity_msat(amount_msat);
} else {
- log_trace!(logger, "Max liquidity of {} already more than {}", chan_descr, amount_msat);
+ log_trace!(logger, "Max liquidity of {} is {} (already less than or equal to {})",
+ chan_descr, existing_max_msat, amount_msat);
}
}
/// Adjusts the channel liquidity balance bounds when failing to route `amount_msat` downstream.
fn failed_downstream<Log: Deref>(&mut self, amount_msat: u64, chan_descr: fmt::Arguments, logger: &Log) where Log::Target: Logger {
- if amount_msat > self.min_liquidity_msat() {
- log_debug!(logger, "Setting min liquidity of {} to {}", chan_descr, amount_msat);
+ let existing_min_msat = self.min_liquidity_msat();
+ if amount_msat > existing_min_msat {
+ log_debug!(logger, "Setting min liquidity of {} from {} to {}", existing_min_msat, chan_descr, amount_msat);
self.set_min_liquidity_msat(amount_msat);
} else {
- log_trace!(logger, "Min liquidity of {} already less than {}", chan_descr, amount_msat);
+ log_trace!(logger, "Min liquidity of {} is {} (already greater than or equal to {})",
+ chan_descr, existing_min_msat, amount_msat);
}
}
}
fn update_history_buckets(&mut self) {
+ let half_lives = self.now.duration_since(*self.last_updated).as_secs()
+ .checked_div(self.params.historical_no_updates_half_life.as_secs())
+ .map(|v| v.try_into().unwrap_or(u32::max_value())).unwrap_or(u32::max_value());
+ self.min_liquidity_offset_history.time_decay_data(half_lives);
+ self.max_liquidity_offset_history.time_decay_data(half_lives);
+
debug_assert!(*self.min_liquidity_offset_msat <= self.capacity_msat);
self.min_liquidity_offset_history.track_datapoint(
// Ensure the bucket index we pass is in the range [0, 7], even if the liquidity offset
} else {
self.decayed_offset_msat(*self.max_liquidity_offset_msat)
};
- *self.last_updated = self.now;
self.update_history_buckets();
+ *self.last_updated = self.now;
}
/// Adjusts the upper bound of the channel liquidity balance in this direction.
} else {
self.decayed_offset_msat(*self.min_liquidity_offset_msat)
};
- *self.last_updated = self.now;
self.update_history_buckets();
+ *self.last_updated = self.now;
}
}
_ => {},
}
- let liquidity_offset_half_life = self.params.liquidity_offset_half_life;
let amount_msat = usage.amount_msat;
let capacity_msat = usage.effective_capacity.as_msat()
.saturating_sub(usage.inflight_htlc_msat);
self.channel_liquidities
.get(&short_channel_id)
.unwrap_or(&ChannelLiquidity::new())
- .as_directed(source, target, capacity_msat, liquidity_offset_half_life)
+ .as_directed(source, target, capacity_msat, &self.params)
.penalty_msat(amount_msat, &self.params)
.saturating_add(anti_probing_penalty_msat)
.saturating_add(base_penalty_msat)
fn payment_path_failed(&mut self, path: &[&RouteHop], short_channel_id: u64) {
let amount_msat = path.split_last().map(|(hop, _)| hop.fee_msat).unwrap_or(0);
- let liquidity_offset_half_life = self.params.liquidity_offset_half_life;
log_trace!(self.logger, "Scoring path through to SCID {} as having failed at {} msat", short_channel_id, amount_msat);
let network_graph = self.network_graph.read_only();
for (hop_idx, hop) in path.iter().enumerate() {
self.channel_liquidities
.entry(hop.short_channel_id)
.or_insert_with(ChannelLiquidity::new)
- .as_directed_mut(source, &target, capacity_msat, liquidity_offset_half_life)
+ .as_directed_mut(source, &target, capacity_msat, &self.params)
.failed_at_channel(amount_msat, format_args!("SCID {}, towards {:?}", hop.short_channel_id, target), &self.logger);
break;
}
self.channel_liquidities
.entry(hop.short_channel_id)
.or_insert_with(ChannelLiquidity::new)
- .as_directed_mut(source, &target, capacity_msat, liquidity_offset_half_life)
+ .as_directed_mut(source, &target, capacity_msat, &self.params)
.failed_downstream(amount_msat, format_args!("SCID {}, towards {:?}", hop.short_channel_id, target), &self.logger);
} else {
log_debug!(self.logger, "Not able to penalize channel with SCID {} as we do not have graph info for it (likely a route-hint last-hop).",
fn payment_path_successful(&mut self, path: &[&RouteHop]) {
let amount_msat = path.split_last().map(|(hop, _)| hop.fee_msat).unwrap_or(0);
- let liquidity_offset_half_life = self.params.liquidity_offset_half_life;
log_trace!(self.logger, "Scoring path through SCID {} as having succeeded at {} msat.",
path.split_last().map(|(hop, _)| hop.short_channel_id).unwrap_or(0), amount_msat);
let network_graph = self.network_graph.read_only();
self.channel_liquidities
.entry(hop.short_channel_id)
.or_insert_with(ChannelLiquidity::new)
- .as_directed_mut(source, &target, capacity_msat, liquidity_offset_half_life)
+ .as_directed_mut(source, &target, capacity_msat, &self.params)
.successful(amount_msat, format_args!("SCID {}, towards {:?}", hop.short_channel_id, target), &self.logger);
} else {
log_debug!(self.logger, "Not able to learn for channel with SCID {} as we do not have graph info for it (likely a route-hint last-hop).",
use util::time::Time;
use util::time::tests::SinceEpoch;
- use ln::features::{ChannelFeatures, NodeFeatures};
+ use ln::channelmanager;
use ln::msgs::{ChannelAnnouncement, ChannelUpdate, UnsignedChannelAnnouncement, UnsignedChannelUpdate};
use routing::gossip::{EffectiveCapacity, NetworkGraph, NodeId};
use routing::router::RouteHop;
let node_2_secret = &SecretKey::from_slice(&[40; 32]).unwrap();
let secp_ctx = Secp256k1::new();
let unsigned_announcement = UnsignedChannelAnnouncement {
- features: ChannelFeatures::known(),
+ features: channelmanager::provided_channel_features(),
chain_hash: genesis_hash,
short_channel_id,
node_id_1: PublicKey::from_secret_key(&secp_ctx, &node_1_key),
vec![
RouteHop {
pubkey: source_pubkey(),
- node_features: NodeFeatures::known(),
+ node_features: channelmanager::provided_node_features(),
short_channel_id: 41,
- channel_features: ChannelFeatures::known(),
+ channel_features: channelmanager::provided_channel_features(),
fee_msat: 1,
cltv_expiry_delta: 18,
},
RouteHop {
pubkey: target_pubkey(),
- node_features: NodeFeatures::known(),
+ node_features: channelmanager::provided_node_features(),
short_channel_id: 42,
- channel_features: ChannelFeatures::known(),
+ channel_features: channelmanager::provided_channel_features(),
fee_msat: 2,
cltv_expiry_delta: 18,
},
RouteHop {
pubkey: recipient_pubkey(),
- node_features: NodeFeatures::known(),
+ node_features: channelmanager::provided_node_features(),
short_channel_id: 43,
- channel_features: ChannelFeatures::known(),
+ channel_features: channelmanager::provided_channel_features(),
fee_msat: amount_msat,
cltv_expiry_delta: 18,
},
// Update minimum liquidity.
- let liquidity_offset_half_life = scorer.params.liquidity_offset_half_life;
let liquidity = scorer.channel_liquidities.get(&42).unwrap()
- .as_directed(&source, &target, 1_000, liquidity_offset_half_life);
+ .as_directed(&source, &target, 1_000, &scorer.params);
assert_eq!(liquidity.min_liquidity_msat(), 100);
assert_eq!(liquidity.max_liquidity_msat(), 300);
let liquidity = scorer.channel_liquidities.get(&42).unwrap()
- .as_directed(&target, &source, 1_000, liquidity_offset_half_life);
+ .as_directed(&target, &source, 1_000, &scorer.params);
assert_eq!(liquidity.min_liquidity_msat(), 700);
assert_eq!(liquidity.max_liquidity_msat(), 900);
scorer.channel_liquidities.get_mut(&42).unwrap()
- .as_directed_mut(&source, &target, 1_000, liquidity_offset_half_life)
+ .as_directed_mut(&source, &target, 1_000, &scorer.params)
.set_min_liquidity_msat(200);
let liquidity = scorer.channel_liquidities.get(&42).unwrap()
- .as_directed(&source, &target, 1_000, liquidity_offset_half_life);
+ .as_directed(&source, &target, 1_000, &scorer.params);
assert_eq!(liquidity.min_liquidity_msat(), 200);
assert_eq!(liquidity.max_liquidity_msat(), 300);
let liquidity = scorer.channel_liquidities.get(&42).unwrap()
- .as_directed(&target, &source, 1_000, liquidity_offset_half_life);
+ .as_directed(&target, &source, 1_000, &scorer.params);
assert_eq!(liquidity.min_liquidity_msat(), 700);
assert_eq!(liquidity.max_liquidity_msat(), 800);
// Update maximum liquidity.
let liquidity = scorer.channel_liquidities.get(&43).unwrap()
- .as_directed(&target, &recipient, 1_000, liquidity_offset_half_life);
+ .as_directed(&target, &recipient, 1_000, &scorer.params);
assert_eq!(liquidity.min_liquidity_msat(), 700);
assert_eq!(liquidity.max_liquidity_msat(), 900);
let liquidity = scorer.channel_liquidities.get(&43).unwrap()
- .as_directed(&recipient, &target, 1_000, liquidity_offset_half_life);
+ .as_directed(&recipient, &target, 1_000, &scorer.params);
assert_eq!(liquidity.min_liquidity_msat(), 100);
assert_eq!(liquidity.max_liquidity_msat(), 300);
scorer.channel_liquidities.get_mut(&43).unwrap()
- .as_directed_mut(&target, &recipient, 1_000, liquidity_offset_half_life)
+ .as_directed_mut(&target, &recipient, 1_000, &scorer.params)
.set_max_liquidity_msat(200);
let liquidity = scorer.channel_liquidities.get(&43).unwrap()
- .as_directed(&target, &recipient, 1_000, liquidity_offset_half_life);
+ .as_directed(&target, &recipient, 1_000, &scorer.params);
assert_eq!(liquidity.min_liquidity_msat(), 0);
assert_eq!(liquidity.max_liquidity_msat(), 200);
let liquidity = scorer.channel_liquidities.get(&43).unwrap()
- .as_directed(&recipient, &target, 1_000, liquidity_offset_half_life);
+ .as_directed(&recipient, &target, 1_000, &scorer.params);
assert_eq!(liquidity.min_liquidity_msat(), 800);
assert_eq!(liquidity.max_liquidity_msat(), 1000);
}
assert!(source > target);
// Check initial bounds.
- let liquidity_offset_half_life = scorer.params.liquidity_offset_half_life;
let liquidity = scorer.channel_liquidities.get(&42).unwrap()
- .as_directed(&source, &target, 1_000, liquidity_offset_half_life);
+ .as_directed(&source, &target, 1_000, &scorer.params);
assert_eq!(liquidity.min_liquidity_msat(), 400);
assert_eq!(liquidity.max_liquidity_msat(), 800);
let liquidity = scorer.channel_liquidities.get(&42).unwrap()
- .as_directed(&target, &source, 1_000, liquidity_offset_half_life);
+ .as_directed(&target, &source, 1_000, &scorer.params);
assert_eq!(liquidity.min_liquidity_msat(), 200);
assert_eq!(liquidity.max_liquidity_msat(), 600);
// Reset from source to target.
scorer.channel_liquidities.get_mut(&42).unwrap()
- .as_directed_mut(&source, &target, 1_000, liquidity_offset_half_life)
+ .as_directed_mut(&source, &target, 1_000, &scorer.params)
.set_min_liquidity_msat(900);
let liquidity = scorer.channel_liquidities.get(&42).unwrap()
- .as_directed(&source, &target, 1_000, liquidity_offset_half_life);
+ .as_directed(&source, &target, 1_000, &scorer.params);
assert_eq!(liquidity.min_liquidity_msat(), 900);
assert_eq!(liquidity.max_liquidity_msat(), 1_000);
let liquidity = scorer.channel_liquidities.get(&42).unwrap()
- .as_directed(&target, &source, 1_000, liquidity_offset_half_life);
+ .as_directed(&target, &source, 1_000, &scorer.params);
assert_eq!(liquidity.min_liquidity_msat(), 0);
assert_eq!(liquidity.max_liquidity_msat(), 100);
// Reset from target to source.
scorer.channel_liquidities.get_mut(&42).unwrap()
- .as_directed_mut(&target, &source, 1_000, liquidity_offset_half_life)
+ .as_directed_mut(&target, &source, 1_000, &scorer.params)
.set_min_liquidity_msat(400);
let liquidity = scorer.channel_liquidities.get(&42).unwrap()
- .as_directed(&source, &target, 1_000, liquidity_offset_half_life);
+ .as_directed(&source, &target, 1_000, &scorer.params);
assert_eq!(liquidity.min_liquidity_msat(), 0);
assert_eq!(liquidity.max_liquidity_msat(), 600);
let liquidity = scorer.channel_liquidities.get(&42).unwrap()
- .as_directed(&target, &source, 1_000, liquidity_offset_half_life);
+ .as_directed(&target, &source, 1_000, &scorer.params);
assert_eq!(liquidity.min_liquidity_msat(), 400);
assert_eq!(liquidity.max_liquidity_msat(), 1_000);
}
assert!(source > target);
// Check initial bounds.
- let liquidity_offset_half_life = scorer.params.liquidity_offset_half_life;
let liquidity = scorer.channel_liquidities.get(&42).unwrap()
- .as_directed(&source, &target, 1_000, liquidity_offset_half_life);
+ .as_directed(&source, &target, 1_000, &scorer.params);
assert_eq!(liquidity.min_liquidity_msat(), 400);
assert_eq!(liquidity.max_liquidity_msat(), 800);
let liquidity = scorer.channel_liquidities.get(&42).unwrap()
- .as_directed(&target, &source, 1_000, liquidity_offset_half_life);
+ .as_directed(&target, &source, 1_000, &scorer.params);
assert_eq!(liquidity.min_liquidity_msat(), 200);
assert_eq!(liquidity.max_liquidity_msat(), 600);
// Reset from source to target.
scorer.channel_liquidities.get_mut(&42).unwrap()
- .as_directed_mut(&source, &target, 1_000, liquidity_offset_half_life)
+ .as_directed_mut(&source, &target, 1_000, &scorer.params)
.set_max_liquidity_msat(300);
let liquidity = scorer.channel_liquidities.get(&42).unwrap()
- .as_directed(&source, &target, 1_000, liquidity_offset_half_life);
+ .as_directed(&source, &target, 1_000, &scorer.params);
assert_eq!(liquidity.min_liquidity_msat(), 0);
assert_eq!(liquidity.max_liquidity_msat(), 300);
let liquidity = scorer.channel_liquidities.get(&42).unwrap()
- .as_directed(&target, &source, 1_000, liquidity_offset_half_life);
+ .as_directed(&target, &source, 1_000, &scorer.params);
assert_eq!(liquidity.min_liquidity_msat(), 700);
assert_eq!(liquidity.max_liquidity_msat(), 1_000);
// Reset from target to source.
scorer.channel_liquidities.get_mut(&42).unwrap()
- .as_directed_mut(&target, &source, 1_000, liquidity_offset_half_life)
+ .as_directed_mut(&target, &source, 1_000, &scorer.params)
.set_max_liquidity_msat(600);
let liquidity = scorer.channel_liquidities.get(&42).unwrap()
- .as_directed(&source, &target, 1_000, liquidity_offset_half_life);
+ .as_directed(&source, &target, 1_000, &scorer.params);
assert_eq!(liquidity.min_liquidity_msat(), 400);
assert_eq!(liquidity.max_liquidity_msat(), 1_000);
let liquidity = scorer.channel_liquidities.get(&42).unwrap()
- .as_directed(&target, &source, 1_000, liquidity_offset_half_life);
+ .as_directed(&target, &source, 1_000, &scorer.params);
assert_eq!(liquidity.min_liquidity_msat(), 0);
assert_eq!(liquidity.max_liquidity_msat(), 600);
}
let usage = ChannelUsage {
effective_capacity: EffectiveCapacity::Total { capacity_msat: 3_950_000_000, htlc_maximum_msat: Some(1_000) }, ..usage
};
- assert_eq!(scorer.channel_penalty_msat(42, &source, &target, usage), 1985);
+ assert_eq!(scorer.channel_penalty_msat(42, &source, &target, usage), 1983);
let usage = ChannelUsage {
effective_capacity: EffectiveCapacity::Total { capacity_msat: 4_950_000_000, htlc_maximum_msat: Some(1_000) }, ..usage
};
- assert_eq!(scorer.channel_penalty_msat(42, &source, &target, usage), 1639);
+ assert_eq!(scorer.channel_penalty_msat(42, &source, &target, usage), 1637);
let usage = ChannelUsage {
effective_capacity: EffectiveCapacity::Total { capacity_msat: 5_950_000_000, htlc_maximum_msat: Some(1_000) }, ..usage
};
- assert_eq!(scorer.channel_penalty_msat(42, &source, &target, usage), 1607);
+ assert_eq!(scorer.channel_penalty_msat(42, &source, &target, usage), 1606);
let usage = ChannelUsage {
effective_capacity: EffectiveCapacity::Total { capacity_msat: 6_950_000_000, htlc_maximum_msat: Some(1_000) }, ..usage
};
- assert_eq!(scorer.channel_penalty_msat(42, &source, &target, usage), 1262);
+ assert_eq!(scorer.channel_penalty_msat(42, &source, &target, usage), 1331);
let usage = ChannelUsage {
effective_capacity: EffectiveCapacity::Total { capacity_msat: 7_450_000_000, htlc_maximum_msat: Some(1_000) }, ..usage
};
- assert_eq!(scorer.channel_penalty_msat(42, &source, &target, usage), 1262);
+ assert_eq!(scorer.channel_penalty_msat(42, &source, &target, usage), 1387);
let usage = ChannelUsage {
effective_capacity: EffectiveCapacity::Total { capacity_msat: 7_950_000_000, htlc_maximum_msat: Some(1_000) }, ..usage
};
- assert_eq!(scorer.channel_penalty_msat(42, &source, &target, usage), 1262);
+ assert_eq!(scorer.channel_penalty_msat(42, &source, &target, usage), 1379);
let usage = ChannelUsage {
effective_capacity: EffectiveCapacity::Total { capacity_msat: 8_950_000_000, htlc_maximum_msat: Some(1_000) }, ..usage
};
- assert_eq!(scorer.channel_penalty_msat(42, &source, &target, usage), 1262);
+ assert_eq!(scorer.channel_penalty_msat(42, &source, &target, usage), 1363);
let usage = ChannelUsage {
effective_capacity: EffectiveCapacity::Total { capacity_msat: 9_950_000_000, htlc_maximum_msat: Some(1_000) }, ..usage
};
- assert_eq!(scorer.channel_penalty_msat(42, &source, &target, usage), 1262);
+ assert_eq!(scorer.channel_penalty_msat(42, &source, &target, usage), 1355);
}
#[test]
let params = ProbabilisticScoringParameters {
base_penalty_msat: 500, liquidity_penalty_multiplier_msat: 1_000,
- anti_probing_penalty_msat: 0, ..Default::default()
+ anti_probing_penalty_msat: 0, ..ProbabilisticScoringParameters::zero_penalty()
};
let scorer = ProbabilisticScorer::new(params, &network_graph, &logger);
assert_eq!(scorer.channel_penalty_msat(42, &source, &target, usage), 558);
let params = ProbabilisticScoringParameters {
base_penalty_msat: 500, liquidity_penalty_multiplier_msat: 1_000,
base_penalty_amount_multiplier_msat: (1 << 30),
- anti_probing_penalty_msat: 0, ..Default::default()
+ anti_probing_penalty_msat: 0, ..ProbabilisticScoringParameters::zero_penalty()
};
let scorer = ProbabilisticScorer::new(params, &network_graph, &logger);
assert_eq!(scorer.channel_penalty_msat(42, &source, &target, usage), u64::max_value());
}
+ #[test]
+ fn remembers_historical_failures() {
+ let logger = TestLogger::new();
+ let network_graph = network_graph(&logger);
+ let params = ProbabilisticScoringParameters {
+ historical_liquidity_penalty_multiplier_msat: 1024,
+ historical_liquidity_penalty_amount_multiplier_msat: 1024,
+ historical_no_updates_half_life: Duration::from_secs(10),
+ ..ProbabilisticScoringParameters::zero_penalty()
+ };
+ let mut scorer = ProbabilisticScorer::new(params, &network_graph, &logger);
+ let source = source_node_id();
+ let target = target_node_id();
+
+ let usage = ChannelUsage {
+ amount_msat: 100,
+ inflight_htlc_msat: 0,
+ effective_capacity: EffectiveCapacity::Total { capacity_msat: 1_024, htlc_maximum_msat: Some(1_024) },
+ };
+ // With no historical data the normal liquidity penalty calculation is used.
+ assert_eq!(scorer.channel_penalty_msat(42, &source, &target, usage), 47);
+
+ scorer.payment_path_failed(&payment_path_for_amount(1).iter().collect::<Vec<_>>(), 42);
+ assert_eq!(scorer.channel_penalty_msat(42, &source, &target, usage), 2048);
+
+ // Even after we tell the scorer we definitely have enough available liquidity, it will
+ // still remember that there was some failure in the past, and assign a non-0 penalty.
+ scorer.payment_path_failed(&payment_path_for_amount(1000).iter().collect::<Vec<_>>(), 43);
+ assert_eq!(scorer.channel_penalty_msat(42, &source, &target, usage), 198);
+
+ // Advance the time forward 16 half-lives (which the docs claim will ensure all data is
+ // gone), and check that we're back to where we started.
+ SinceEpoch::advance(Duration::from_secs(10 * 16));
+ assert_eq!(scorer.channel_penalty_msat(42, &source, &target, usage), 47);
+ }
+
#[test]
fn adds_anti_probing_penalty() {
let logger = TestLogger::new();
projects / rust-lightning / blobdiff