Crates.io | event-manager |
lib.rs | event-manager |
version | 0.4.0 |
source | src |
created_at | 2020-08-12 15:28:45.5022 |
updated_at | 2024-01-03 09:49:53.221357 |
description | Abstractions for implementing event based systems |
homepage | |
repository | https://github.com/rust-vmm/event-manager |
max_upload_size | |
id | 275841 |
size | 192,673 |
The event-manager
provides abstractions for implementing event based
systems. For now, this crate only works on Linux and uses the
epoll API to provide a
mechanism for handling I/O notifications.
This crate is built around two abstractions:
The subscriber defines and registers an interest list with the event manager. The interest list represents the events that the subscriber wants to monitor.
The Event Manager allows adding and removing subscribers, and provides
APIs through which the subscribers can be updated in terms of events in their
interest list. These actions are abstracted through the SubscriberOps
trait.
To interface with the Event Manager, the Event Subscribers need to provide an
initialization function, and a callback for when events in the
interest list become ready. The subscribers can update their interest list
when handling ready events. These actions are abstracted through the
EventSubscriber
and MutEventSubscriber
traits. They contain the same
methods, but the former only requires immutable self
borrows, whereas the
latter requires mutable borrows. Any type implementing EventSubscriber
automatically implements MutEventSubscriber
as well.
A typical event-based application creates the event manager, registers
subscribers, and then calls into the event manager's run
function in a loop.
Behind the scenes, the event manager calls into epoll::wait
and maps the file
descriptors in the ready list to the subscribers it manages. The event manager
calls the subscriber's process
function (its registered callback). When
dispatching the events, the event manager creates a specialized object and
passes it in the callback function so that the subscribers can use it to alter
their interest list.
Read more in the design document.
The event subscriber has full control over the events that it monitors.
The events need to be added to the event manager's loop as part of the
init
function. Adding events to the loop can return errors, and it is
the responsibility of the subscriber to handle them.
Similarly, the event subscriber is in full control of the ready events.
When an event becomes ready, the event manager will call into the subscriber
process
function. The subscriber SHOULD handle the following events which
are always returned when they occur (they don't need to be registered):
EventSet::ERROR
- an error occurred on the monitor file descriptor.EventSet::HANG_UP
- hang up happened on the associated fd.EventSet::READ_HANG_UP
- hang up when the registered event is edge
triggered.For more details about the error cases, you can check the
epoll_ctl documentation
.
The EventManager
uses a generic type parameter which represents the
subscriber type. The crate provides automatic implementations of
EventSubscriber
for Arc<T>
and Rc<T>
(for any T: EventSubscriber +?Sized
),
together with automatic implementations of MutEventSubscriber
for Mutex<T>
and RefCell<T>
(for any T: MutEventSubscriber + ?Sized
). The generic type
parameter enables either static or dynamic dispatch.
This crate has no default features. The optional remote_endpoint
feature enables interactions with the EventManager
from different threads
without the need of more intrusive synchronization.
For closer to real life use cases, please check the examples in tests.
use event_manager::{EventOps, Events, MutEventSubscriber};
use vmm_sys_util::{eventfd::EventFd, epoll::EventSet};
use std::os::unix::io::AsRawFd;
use std::fmt::{Display, Formatter, Result};
pub struct CounterSubscriber {
event_fd: EventFd,
counter: u64,
}
impl CounterSubscriber {
pub fn new() -> Self {
Self {
event_fd: EventFd::new(0).unwrap(),
counter: 0,
}
}
}
impl MutEventSubscriber for CounterSubscriber {
fn process(&mut self, events: Events, event_ops: &mut EventOps) {
match events.event_set() {
EventSet::IN => {
self.counter += 1;
}
EventSet::ERROR => {
eprintln!("Got error on the monitored event.");
}
EventSet::HANG_UP => {
event_ops.remove(events).unwrap_or(
eprintln!("Encountered error during cleanup")
);
panic!("Cannot continue execution. Associated fd was closed.");
}
_ => {}
}
}
fn init(&mut self, ops: &mut EventOps) {
ops.add(Events::new(&self.event_fd, EventSet::IN)).expect("Cannot register event.");
}
}
struct App {
event_manager: EventManager<CounterSubscriber>,
subscribers_id: Vec<SubscriberId>,
}
impl App {
fn new() -> Self {
Self {
event_manager: EventManager::<CounterSubscriber>::new().unwrap(),
subscribers_id: vec![]
}
}
fn add_subscriber(&mut self) {
let counter_subscriber = CounterSubscriber::default();
let id = self.event_manager.add_subscriber(counter_subscriber);
self.subscribers_id.push(id);
}
fn run(&mut self) {
let _ = self.event_manager.run_with_timeout(100);
}
}
The event-manager
is tested using unit tests, Rust integration tests and
performance benchmarks. It leverages
rust-vmm-ci
for continuous
testing. All tests are run in the rustvmm/dev
container.
More details on running the tests can be found in the development document.
This project is licensed under either of: