Async I/O and timers. Experimental
This crate is an experimental fork of the splendid async-io
crate targetting MCUs and ESP-IDF in particular.
async-io-mini
is a drop-in, API-compatible replacement for the Async
and Timer
types from async-io
.
So either:
- Just replace all
use async_io
occurances in your crate withuse async_io_mini
- Or - in your
Cargo.toml
- replace:async-io = "..."
- with
async-io = { package = "async-io-mini", ... }
While async-io
supports a ton of operating systems - including ESP-IDF for the Espressif MCU chips - it does have a non-trivial memory consumption in the hidden thread named async-io
. Since its hidden Reactor
object is initialized lazily, it so happens that it is first allocated on-stack, and then it is moved into the static context. This requires the async-io
thread (as well as any thread from where you are polling sockets) to have at least 8K stack, which - by MCU standards! - is relatively large if you are memory-constrained.
In contrast, async-io-mini
:
- Needs < 3K of stack with ESP-IDF (and that's only because ESP-IDF interrupts are executed on the stack of the interrupted thread, i.e. we need to leave some room for these);
- It's reactor is allocated to the
static
context eagerly as its constructor function isconst
(hence no stack blowups); - The reactor has a smaller memory footprint too (~ 500 bytes), as it is hard-coded to the
select
syscall and does not support timers. MCUs (with lwIP) usually have max file and socket handles in the lower tens (~ 20 in ESP-IDF) so all structures can be limited to that size; - No heap allocations - initially and during polling.
Further, async-io
has a non-trivial set of dependencies (again - for MCUs; for regular OSes it is a dwarf by any meaningful measurement!): rustix
, polling
, async-lock
, event
, tracing
, parking-lot
and more. Nothing wrong with with that per-se, but that's a large implementation surface that e.g. recently is triggering a possible miscompilation on Espressif xtensa targets (NOT that this is a justification not to root-cause and fix the problem!).
async-io-mini
only has the following non-optional dependencies:
libc
(which indirectly comes with Rust STD anyway);heapless
(forheapless::Vec
and nothing else);log
(might become optional);enumset
(not crucial, might remove).
The Timer
type of async_io_mini
is based on the embassy-time
crate, and as such should offer a higher resolution on embedded operating systems like the ESP-IDF than what can be normally achieved by implementing timers using the timeout
parameter of the select
syscall (as async-io
does).
The reason for this is that on the ESP-IDF, the timeout
parameter of select
provides a resolution of 10ms (one FreeRTOS sys-tick), while
embassy-time
is implemented using the ESP-IDF Timer service, which provides resolutions up to 1 microsecond.
With that said, for greenfield code that does not need to be compatible with async-io
, use the native embassy_time::Timer
and embassy_time::Ticker
rather than async_io_mini::Timer
, because the latter has a larger memory footprint (40 bytes on 32bit archs) compared to the embassy-time
types (8 and 16 bytes each).
Implementing socket polling as a shared task between the hidden async-io-mini
thread and the thread calling async_io_mini::block_on
is not trivial and probably not worth it on MCUs. Just use futures_lite::block_on
or the block_on
equivalent for your OS (i.e. esp_idf_svc::hal::task::block_on
for the ESP-IDF).
The first time Async
is used, a thread named async-io-mini
will be spawned.
The purpose of this thread is to wait for I/O events reported by the operating system, and then
wake appropriate futures blocked on I/O when they can be resumed.
To wait for the next I/O event, the "async-io-mini" thread uses the select syscall, and is thus only useful for MCUs (might just be the ESP-IDF) where the number of file or socket handles is very small anyway.
As per above, the Timer
type is a wrapper around the functionality provided by the embassy-time
crate.
Connect to example.com:80
, or time out after 10 seconds.
use async_io_mini::{Async, Timer};
use futures_lite::{future::FutureExt, io};
use std::net::{TcpStream, ToSocketAddrs};
use std::time::Duration;
let addr = "example.com:80".to_socket_addrs()?.next().unwrap();
let stream = Async::<TcpStream>::connect(addr).or(async {
Timer::after(Duration::from_secs(10)).await;
Err(io::ErrorKind::TimedOut.into())
})
.await?;
Licensed under either of
- Apache License, Version 2.0 (LICENSE-APACHE or http://www.apache.org/licenses/LICENSE-2.0)
- MIT license (LICENSE-MIT or http://opensource.org/licenses/MIT)
at your option.
Unless you explicitly state otherwise, any contribution intentionally submitted for inclusion in the work by you, as defined in the Apache-2.0 license, shall be dual licensed as above, without any additional terms or conditions.