veloren/common/src/clock.rs

143 lines
5.4 KiB
Rust
Raw Normal View History

use crate::span;
use std::{
collections::VecDeque,
time::{Duration, Instant},
};
/// This Clock tries to make this tick a constant time by sleeping the rest of
/// the tick
/// - if we actually took less time than we planned: sleep and return planned
/// time
/// - if we ran behind: don't sleep and return actual time
/// We DON'T do any fancy averaging of the deltas for tick for 2 reasons:
/// - all Systems have to work based on `dt` and we cannot assume that this is
/// const through all ticks
/// - when we have a slow tick, a lag, it doesn't help that we have 10 fast
/// ticks directly afterwards
/// We return a smoothed version for display only!
pub struct Clock {
/// This is the dt that the Clock tries to archive with each call of tick.
target_dt: Duration,
/// last time `tick` was called
last_sys_time: Instant,
/// will be calculated in `tick` returns the dt used by the next iteration
/// of the main loop
last_dt: Duration,
/// summed up `last_dt`
total_tick_time: Duration,
// Stats only
// stored as millis in u16 to save space. if it's more than u16::MAX (16s) we have other
// problems
last_dts_millis: VecDeque<u16>,
last_dts_millis_sorted: Vec<u16>,
stats: ClockStats,
}
pub struct ClockStats {
/// busy_dt is the part of the last tick that we didn't sleep.
/// e.g. the total tick is 33ms, including 25ms sleeping. then this returns
/// 8ms
pub last_busy_dt: Duration,
/// avg over the last NUMBER_OF_OLD_DELTAS_KEPT ticks
pub average_tps: f64,
/// = 50% percentile
pub median_tps: f64,
/// lowest 10% of the frames
pub percentile_90_tps: f64,
/// lowest 5% of the frames
pub percentile_95_tps: f64,
/// lowest 1% of the frames
pub percentile_99_tps: f64,
}
const NUMBER_OF_OLD_DELTAS_KEPT: usize = 100;
impl Clock {
pub fn new(target_dt: Duration) -> Self {
Self {
target_dt,
last_sys_time: Instant::now(),
last_dt: target_dt,
total_tick_time: Duration::default(),
last_dts_millis: VecDeque::with_capacity(NUMBER_OF_OLD_DELTAS_KEPT),
last_dts_millis_sorted: Vec::with_capacity(NUMBER_OF_OLD_DELTAS_KEPT),
stats: ClockStats::new(&Vec::new(), target_dt),
}
}
pub fn set_target_dt(&mut self, target_dt: Duration) { self.target_dt = target_dt; }
pub fn stats(&self) -> &ClockStats { &self.stats }
pub fn dt(&self) -> Duration { self.last_dt }
/// Do not modify without asking @xMAC94x first!
pub fn tick(&mut self) {
span!(_guard, "tick", "Clock::tick");
let current_sys_time = Instant::now();
let busy_delta = current_sys_time.duration_since(self.last_sys_time);
// Maintain TPS
self.last_dts_millis_sorted = self.last_dts_millis.iter().copied().collect();
self.last_dts_millis_sorted.sort_unstable();
self.stats = ClockStats::new(&self.last_dts_millis_sorted, busy_delta);
// Attempt to sleep to fill the gap.
if let Some(sleep_dur) = self.target_dt.checked_sub(busy_delta) {
2020-11-10 21:39:10 +00:00
spin_sleep::sleep(sleep_dur);
}
let after_sleep_sys_time = Instant::now();
self.last_dt = after_sleep_sys_time.duration_since(self.last_sys_time);
if self.last_dts_millis.len() >= NUMBER_OF_OLD_DELTAS_KEPT {
self.last_dts_millis.pop_front();
}
self.last_dts_millis
.push_back((self.last_dt.as_millis() as u16).min(std::u16::MAX));
self.total_tick_time += self.last_dt;
self.last_sys_time = after_sleep_sys_time;
}
}
impl ClockStats {
fn new(sorted: &[u16], last_busy_dt: Duration) -> Self {
const NANOS_PER_SEC: f64 = Duration::from_secs(1).as_nanos() as f64;
const NANOS_PER_MILLI: f64 = Duration::from_millis(1).as_nanos() as f64;
let len = sorted.len();
let average_millis = sorted.iter().fold(0, |a, x| a + *x as u32) / len.max(1) as u32;
let average_tps = NANOS_PER_SEC / (average_millis as f64 * NANOS_PER_MILLI);
let (median_tps, percentile_90_tps, percentile_95_tps, percentile_99_tps) = if len
>= NUMBER_OF_OLD_DELTAS_KEPT
{
let median_millis = sorted[len / 2];
let percentile_90_millis = sorted[(NUMBER_OF_OLD_DELTAS_KEPT as f32 * 0.1) as usize];
let percentile_95_millis = sorted[(NUMBER_OF_OLD_DELTAS_KEPT as f32 * 0.05) as usize];
let percentile_99_millis = sorted[(NUMBER_OF_OLD_DELTAS_KEPT as f32 * 0.01) as usize];
let median_tps = NANOS_PER_SEC / (median_millis as f64 * NANOS_PER_MILLI);
let percentile_90_tps = NANOS_PER_SEC / (percentile_90_millis as f64 * NANOS_PER_MILLI);
let percentile_95_tps = NANOS_PER_SEC / (percentile_95_millis as f64 * NANOS_PER_MILLI);
let percentile_99_tps = NANOS_PER_SEC / (percentile_99_millis as f64 * NANOS_PER_MILLI);
(
median_tps,
percentile_90_tps,
percentile_95_tps,
percentile_99_tps,
)
} else {
let avg_tps = NANOS_PER_SEC / last_busy_dt.as_nanos() as f64;
(avg_tps, avg_tps, avg_tps, avg_tps)
};
Self {
last_busy_dt,
average_tps,
median_tps,
percentile_90_tps,
percentile_95_tps,
percentile_99_tps,
}
}
}