Crates.io | calloop |
lib.rs | calloop |
version | |
source | src |
created_at | 2018-08-24 16:57:45.869464 |
updated_at | 2024-12-12 03:37:16.414405 |
description | A callback-based event loop |
homepage | |
repository | https://github.com/Smithay/calloop |
max_upload_size | |
id | 81116 |
Cargo.toml error: | TOML parse error at line 19, column 1 | 19 | autolib = false | ^^^^^^^ unknown field `autolib`, expected one of `name`, `version`, `edition`, `authors`, `description`, `readme`, `license`, `repository`, `homepage`, `documentation`, `build`, `resolver`, `links`, `default-run`, `default_dash_run`, `rust-version`, `rust_dash_version`, `rust_version`, `license-file`, `license_dash_file`, `license_file`, `licenseFile`, `license_capital_file`, `forced-target`, `forced_dash_target`, `autobins`, `autotests`, `autoexamples`, `autobenches`, `publish`, `metadata`, `keywords`, `categories`, `exclude`, `include` |
size | 0 |
Calloop, a Callback-based Event Loop
This crate provides an EventLoop
type, which is a small abstraction
over a polling system. The main difference between this crate
and other traditional rust event loops is that it is based on callbacks:
you can register several event sources, each being associated with a callback
closure that will be invoked whenever the associated event source generates
events.
The main target use of this event loop is thus for apps that expect to spend most of their time waiting for events and wishes to do so in a cheap and convenient way. It is not meant for large scale high performance IO.
Below is a quick usage example of calloop. For a more in-depth tutorial, see the calloop book.
For simple uses, you can just add event sources with callbacks to the event loop. For example, here's a runnable program that exits after five seconds:
use calloop::{timer::{Timer, TimeoutAction}, EventLoop, LoopSignal};
fn main() {
// Create the event loop. The loop is parameterised by the kind of shared
// data you want the callbacks to use. In this case, we want to be able to
// stop the loop when the timer fires, so we provide the loop with a
// LoopSignal, which has the ability to stop the loop from within events. We
// just annotate the type here; the actual data is provided later in the
// run() call.
let mut event_loop: EventLoop<LoopSignal> =
EventLoop::try_new().expect("Failed to initialize the event loop!");
// Retrieve a handle. It is used to insert new sources into the event loop
// It can be cloned, allowing you to insert sources from within source
// callbacks.
let handle = event_loop.handle();
// Create our event source, a timer, that will expire in 2 seconds
let source = Timer::from_duration(std::time::Duration::from_secs(2));
// Inserting an event source takes this general form. It can also be done
// from within the callback of another event source.
handle
.insert_source(
// a type which implements the EventSource trait
source,
// a callback that is invoked whenever this source generates an event
|event, _metadata, shared_data| {
// This callback is given 3 values:
// - the event generated by the source (in our case, timer events are the Instant
// representing the deadline for which it has fired)
// - &mut access to some metadata, specific to the event source (in our case, a
// timer handle)
// - &mut access to the global shared data that was passed to EventLoop::run or
// EventLoop::dispatch (in our case, a LoopSignal object to stop the loop)
//
// The return type is just () because nothing uses it. Some
// sources will expect a Result of some kind instead.
println!("Timeout for {:?} expired!", event);
// notify the event loop to stop running using the signal in the shared data
// (see below)
shared_data.stop();
// The timer event source requires us to return a TimeoutAction to
// specify if the timer should be rescheduled. In our case we just drop it.
TimeoutAction::Drop
},
)
.expect("Failed to insert event source!");
// Create the shared data for our loop.
let mut shared_data = event_loop.get_signal();
// Actually run the event loop. This will dispatch received events to their
// callbacks, waiting at most 20ms for new events between each invocation of
// the provided callback (pass None for the timeout argument if you want to
// wait indefinitely between events).
//
// This is where we pass the *value* of the shared data, as a mutable
// reference that will be forwarded to all your callbacks, allowing them to
// share some state
event_loop
.run(
std::time::Duration::from_millis(20),
&mut shared_data,
|_shared_data| {
// Finally, this is where you can insert the processing you need
// to do do between each waiting event eg. drawing logic if
// you're doing a GUI app.
},
)
.expect("Error during event loop!");
}
The event loop is backed by an OS provided polling selector (epoll on Linux).
This crate also provide some adapters for common event sources such as:
As well as generic objects backed by file descriptors.
It is also possible to insert "idle" callbacks. These callbacks represent computations that
need to be done at some point, but are not as urgent as processing the events. These callbacks
are stored and then executed during EventLoop::dispatch
, once all events from the sources
have been processed.
calloop
can be used with futures, both as an executor and for monitoring Async IO.
Activating the executor
cargo feature will add the futures
module, which provides
a future executor that can be inserted into an EventLoop
as yet another EventSource
.
IO objects can be made Async-aware via the LoopHandle::adapt_io
method. Waking up the
futures using these objects is handled by the associated EventLoop
directly.
You can create custom event sources can will be inserted in the event loop by
implementing the EventSource
trait. This can be done either directly from the file
descriptors of your source of interest, or by wrapping an other event source and further
processing its events. An EventSource
can register more than one file descriptor and
aggregate them.
Currently, calloop is tested on Linux, FreeBSD and macOS.
The following platforms are also enabled at compile time but not tested: Android, NetBSD, OpenBSD, DragonFlyBSD.
Those platforms should work based on the fact that they have the same polling mechanism as tested platforms, but some subtle bugs might still occur.
The current MSRV (Minimum Safe Rust Version) for this crate is Rust 1.63.
When the signals
feature is enabled, however, it will be bumped to nix
's
MSRV. At the time of writing this is Rust 1.69.
Prior to calloop
v1.0, bumps in the MSRV will result in bumps to the patch version. Once calloop
v1.0 is release, bumps in the MSRV will result in bumps to the minor version. In short, MSRV bumps are not considered breaking changes.
As a tentative policy, the base MSRV will not advance past the current Rust version provided by Debian Stable. At the time of writing, this version of Rust is 1.63. However, the MSRV may be advanced further in the event of a major ecosystem shift or a security vulnerability.
License: MIT