2018-03-04 15:24:24 -05:00
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// This file is part of Moonfire NVR, a security camera network video recorder.
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2021-02-17 16:28:48 -05:00
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// Copyright (C) 2018 The Moonfire NVR Authors; see AUTHORS and LICENSE.txt.
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// SPDX-License-Identifier: GPL-v3.0-or-later WITH GPL-3.0-linking-exception.
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2016-12-06 21:41:44 -05:00
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//! Clock interface and implementations for testability.
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2018-03-04 15:24:24 -05:00
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use failure::Error;
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2018-12-28 18:30:33 -05:00
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use log::warn;
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2018-03-04 15:24:24 -05:00
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use parking_lot::Mutex;
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use std::mem;
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use std::sync::{mpsc, Arc};
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use std::thread;
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use std::time::Duration as StdDuration;
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use time::{Duration, Timespec};
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use crate::shutdown::ShutdownError;
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2016-12-30 00:05:57 -05:00
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/// Abstract interface to the system clocks. This is for testability.
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pub trait Clocks: Send + Sync + 'static {
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/// Gets the current time from `CLOCK_REALTIME`.
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fn realtime(&self) -> Timespec;
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2021-09-16 21:21:27 -04:00
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/// Gets the current time from a monotonic clock.
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///
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/// On Linux, this uses `CLOCK_BOOTTIME`, which includes suspended time.
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/// On other systems, it uses `CLOCK_MONOTONIC`.
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fn monotonic(&self) -> Timespec;
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/// Causes the current thread to sleep for the specified time.
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fn sleep(&self, how_long: Duration);
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/// Calls `rcv.recv_timeout` or substitutes a test implementation.
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fn recv_timeout<T>(
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&self,
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rcv: &mpsc::Receiver<T>,
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timeout: StdDuration,
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) -> Result<T, mpsc::RecvTimeoutError>;
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}
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pub fn retry<C, T, E>(
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clocks: &C,
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shutdown_rx: &crate::shutdown::Receiver,
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f: &mut dyn FnMut() -> Result<T, E>,
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) -> Result<T, ShutdownError>
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where
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C: Clocks,
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E: Into<Error>,
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{
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loop {
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let e = match f() {
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Ok(t) => return Ok(t),
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Err(e) => e.into(),
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};
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shutdown_rx.check()?;
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let sleep_time = Duration::seconds(1);
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warn!(
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"sleeping for {} after error: {}",
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sleep_time,
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crate::error::prettify_failure(&e)
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);
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clocks.sleep(sleep_time);
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}
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}
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2018-03-23 16:31:23 -04:00
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#[derive(Copy, Clone)]
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pub struct RealClocks {}
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impl RealClocks {
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fn get(&self, clock: libc::clockid_t) -> Timespec {
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unsafe {
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let mut ts = mem::MaybeUninit::uninit();
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assert_eq!(0, libc::clock_gettime(clock, ts.as_mut_ptr()));
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let ts = ts.assume_init();
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Timespec::new(ts.tv_sec as i64, ts.tv_nsec as i32)
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}
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}
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}
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impl Clocks for RealClocks {
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fn realtime(&self) -> Timespec {
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self.get(libc::CLOCK_REALTIME)
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}
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#[cfg(target_os = "linux")]
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fn monotonic(&self) -> Timespec {
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self.get(libc::CLOCK_BOOTTIME)
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}
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#[cfg(not(target_os = "linux"))]
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fn monotonic(&self) -> Timespec {
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self.get(libc::CLOCK_MONOTONIC)
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}
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fn sleep(&self, how_long: Duration) {
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match how_long.to_std() {
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Ok(d) => thread::sleep(d),
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Err(e) => warn!("Invalid duration {:?}: {}", how_long, e),
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};
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}
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fn recv_timeout<T>(
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&self,
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rcv: &mpsc::Receiver<T>,
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timeout: StdDuration,
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) -> Result<T, mpsc::RecvTimeoutError> {
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rcv.recv_timeout(timeout)
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}
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}
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2018-01-31 17:20:30 -05:00
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/// Logs a warning if the TimerGuard lives "too long", using the label created by a supplied
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/// function.
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pub struct TimerGuard<'a, C: Clocks + ?Sized, S: AsRef<str>, F: FnOnce() -> S + 'a> {
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clocks: &'a C,
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label_f: Option<F>,
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start: Timespec,
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}
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impl<'a, C: Clocks + ?Sized, S: AsRef<str>, F: FnOnce() -> S + 'a> TimerGuard<'a, C, S, F> {
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pub fn new(clocks: &'a C, label_f: F) -> Self {
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TimerGuard {
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clocks,
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label_f: Some(label_f),
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start: clocks.monotonic(),
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}
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}
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}
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impl<'a, C, S, F> Drop for TimerGuard<'a, C, S, F>
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where
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C: Clocks + ?Sized,
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S: AsRef<str>,
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F: FnOnce() -> S + 'a,
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{
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fn drop(&mut self) {
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let elapsed = self.clocks.monotonic() - self.start;
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if elapsed.num_seconds() >= 1 {
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let label_f = self.label_f.take().unwrap();
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warn!("{} took {}!", label_f().as_ref(), elapsed);
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}
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}
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}
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/// Simulated clock for testing.
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#[derive(Clone)]
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pub struct SimulatedClocks(Arc<SimulatedClocksInner>);
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struct SimulatedClocksInner {
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boot: Timespec,
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uptime: Mutex<Duration>,
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}
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impl SimulatedClocks {
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pub fn new(boot: Timespec) -> Self {
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SimulatedClocks(Arc::new(SimulatedClocksInner {
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boot,
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uptime: Mutex::new(Duration::seconds(0)),
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}))
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}
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}
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impl Clocks for SimulatedClocks {
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fn realtime(&self) -> Timespec {
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self.0.boot + *self.0.uptime.lock()
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}
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fn monotonic(&self) -> Timespec {
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Timespec::new(0, 0) + *self.0.uptime.lock()
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}
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/// Advances the clock by the specified amount without actually sleeping.
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fn sleep(&self, how_long: Duration) {
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let mut l = self.0.uptime.lock();
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*l = *l + how_long;
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}
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/// Advances the clock by the specified amount if data is not immediately available.
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fn recv_timeout<T>(
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&self,
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rcv: &mpsc::Receiver<T>,
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timeout: StdDuration,
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) -> Result<T, mpsc::RecvTimeoutError> {
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let r = rcv.recv_timeout(StdDuration::new(0, 0));
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if r.is_err() {
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self.sleep(Duration::from_std(timeout).unwrap());
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}
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r
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}
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}
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