Crate pendulum

Data structures and runtimes for timer management.

This library provides various data structures for managing coarse grain timers.

Data Structures

Overview

We provide various data structures for timer management, each with their own tradeoffs and suited for different application.

• For applications that set shorted lived timeouts, all around the same duration, consider using a HashedWheel, as it will require minimal bookkeeping at runtime for operations such as ticking, or removing expired timers.

  • Network communication
  • Cache for short lived items

• For applications that set long lived timeouts, or timeouts spread across many different durations, considuer using a HierarchicalWheel, as it will accept a variety of different durations, without loss of precision.

  • Cache for long lived items
  • Varied timeouts from user input

Hashed Wheel

Stores all timers in a fixed number of slots (num_slots), where each slot represents some fixed period of time (tick_duration). The slots we maintain are used as a circular buffer, where after each tick, we advance our position in the buffer. Each tick occurrs after approximately tick_duration time has passed.

Note: One slot could have multiple timers of differing durations, these timers will be sorted based on tick expiration. However, if the wheel is configured such that one slot contains timers expiring at different ticks, insertion time will fall back to O(n) instead of O(1). By default, max_timeout is set equal to tick_duration * num_slots - 1 ns, to ensure that all timers inserted will be O(1) inserts, though you can change this if required.

Hierarchical Wheel

Not Implemented Yet

Runtimes

Overview

We provide various runtimes on top of the base data structures for timer management, each being generic over the type of Pendulum that you choose.

Runtimes are useful because they allow you to not care about how the underlying data structure is getting ticked, or when we should check for an expired timer.

Futures

Runs the actual Pendulum in a separate thread that handles accepting requests for new timers, as well as making sure the Pendulum is ticked correctly, and finally notifications for expired timeouts.

Since the futures library is based around the concept of readiness, via Task, we can have callers doing other useful work and make it so that callers aren't continuously checking if a timer is up, only when it is actually up with the background timer thread signal readiness, so that the Futures library will poll the timer again.

Note: Timer bounds (on both the duration and capacity), is checked before returning a Future/Stream from the Timer object, so the only Error being returned from either of those objects is related to timer expiration, which makes it easy to integrate the error handling into your application correctly.

Hashed Wheel Example:

extern crate pendulum;
 
use std::time::Duration;
use std::thread;
 
use pendulum::{Pendulum, HashedWheelBuilder};
 
#[derive(Debug, PartialEq, Eq)]
struct SomeData(usize);
 
fn main() {
    // Create a pendulum with mostly default configration
    let mut wheel = HashedWheelBuilder::default()
        // Tick duration defines the resolution for our timer (all timeouts will be a multiple of this)
        .with_tick_duration(Duration::from_millis(100))
        .build();
 
    // Insert a timeout and store the token, we can use this to cancel the timeout
    let token = wheel.insert_timeout(Duration::from_millis(50), SomeData(5)).unwrap();
 
    // Tick our wheel after the given duration (100 ms)
    thread::sleep(wheel.tick_duration());
 
    // Tell the wheel that it can perform a tick
    wheel.tick();
 
    // Retrieve any expired timeouts
    while let Some(timeout) = wheel.expired_timeout() {
        assert_eq!(SomeData(5), timeout);
    }
     
    // If we tried to remove the timeout using the token, we get None (already expired)
    assert_eq!(None, wheel.remove_timeout(token));
}

Modules

error	Errors that a Pendulum can produce.
future	Futures based runtime for a Pendulum.

Structs

HashedWheel	HashedWheel representing a timer that stores timeouts for type T.
HashedWheelBuilder	Builder for configuring different options for a HashedWheel.
Token	Identifier for objects inserted into a Pendulum.

Traits

Pendulum

Trait for working with generic timer wheel implementations.