Crates.io | await-tree |
lib.rs | await-tree |
version | 0.2.1 |
source | src |
created_at | 2023-02-28 11:52:17.655336 |
updated_at | 2024-04-01 05:31:32.036128 |
description | Instrument await-tree for actor-based applications. |
homepage | |
repository | https://github.com/risingwavelabs/await-tree |
max_upload_size | |
id | 796959 |
size | 98,687 |
The Future
s in Async Rust can be arbitrarily composited or nested to achieve a variety of control flows.
Assuming that the execution of each Future
is represented as a node,
then the asynchronous execution of an async task can be organized into a logical tree,
which is constantly transformed over the polling, completion, and cancellation of Future
s.
await-tree
allows developers to dump this execution tree at runtime, with the span of each Future
annotated by instrument_await
. A basic example is shown below, and more examples of complex control flows can be found in the examples directory.
async fn bar(i: i32) {
// `&'static str` span
baz(i).instrument_await("baz in bar").await
}
async fn baz(i: i32) {
// runtime `String` span is also supported
pending()
.instrument_await(format!("pending in baz {i}"))
.await
}
async fn foo() {
// spans of joined futures will be siblings in the tree
join(
bar(3).instrument_await("bar"),
baz(2).instrument_await("baz"),
)
.await;
}
let root = register("foo");
tokio::spawn(root.instrument(foo()));
sleep(Duration::from_secs(1)).await;
let tree = get_tree("foo");
// foo [1.006s]
// bar [1.006s]
// baz in bar [1.006s]
// pending in baz 3 [1.006s]
// baz [1.006s]
// pending in baz 2 [1.006s]
println!("{tree}");
async-backtrace
tokio-rs/async-backtrace
is a similar crate that also provides the ability to dump the execution tree of async tasks. Here are some differences between await-tree
and async-backtrace
:
Pros of await-tree
:
await-tree
support customizing the span with runtime String
, while async-backtrace
only supports function name and line number.
This is useful when we want to annotate the span with some dynamic information, such as the identifier of a shared resource (e.g., a lock), to see how the contention happens among different tasks.
await-tree
support almost all kinds of async control flows with arbitrary Future
topology, while async-backtrace
fails to handle some of them.
For example, it's common to use &mut impl Future
as an arm of select
to avoid problems led by cancellation unsafety. To further resolve this Future
after the select
completes, we may move it to another place and await
it there. async-backtrace
fails to track this Future
again due to the change of its parent. See examples/detach.rs
for more details.
await-tree
maintains the tree structure with an arena-based data structure, with zero extra unsafe
code. For comparison, async-backtrace
crafts it by hand and there's potential memory unsafety for unhandled topologies mentioned above.
It's worth pointing out that await-tree
has been applied in the production deployment of RisingWave, a distributed streaming database, for a long time.
await-tree
maintains the tree structure separately from the Future
itself, which enables developers to dump the tree at any time with nearly no contention, no matter the Future
is under active polling or has been pending. For comparison, async-backtrace
has to wait for the polling to complete before dumping the tree, which may cause a long delay.
Pros of async-backtrace
:
async-backtrace
is under the Tokio organization.await-tree
is distributed under the Apache License (Version 2.0). Please refer to LICENSE for more information.