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denoland-deno/cli/util/sync/value_creator.rs
David Sherret 1b355d8a87
refactor(npm): improve locking around updating npm resolution (#24104) 
Introduces a `SyncReadAsyncWriteLock` to make it harder to write to the
npm resolution without first waiting async in a queue. For the npm
resolution, reading synchronously is fine, but when updating, someone
should wait async, clone the data, then write the data at the end back.
2024-06-05 15:17:35 -04:00

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Rust
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// Copyright 2018-2024 the Deno authors. All rights reserved. MIT license.
use std::sync::Arc;
use deno_core::futures::future::BoxFuture;
use deno_core::futures::future::LocalBoxFuture;
use deno_core::futures::future::Shared;
use deno_core::futures::FutureExt;
use deno_core::parking_lot::Mutex;
use tokio::task::JoinError;
type JoinResult<TResult> = Result<TResult, Arc<JoinError>>;
type CreateFutureFn<TResult> =
Box<dyn Fn() -> LocalBoxFuture<'static, TResult> + Send + Sync>;
#[derive(Debug)]
struct State<TResult> {
retry_index: usize,
future: Option<Shared<BoxFuture<'static, JoinResult<TResult>>>>,
}
/// Attempts to create a shared value asynchronously on one tokio runtime while
/// many runtimes are requesting the value.
///
/// This is only useful when the value needs to get created once across
/// many runtimes.
///
/// This handles the case where the tokio runtime creating the value goes down
/// while another one is waiting on the value.
pub struct MultiRuntimeAsyncValueCreator<TResult: Send + Clone + 'static> {
create_future: CreateFutureFn<TResult>,
state: Mutex<State<TResult>>,
}
impl<TResult: Send + Clone + 'static> std::fmt::Debug
for MultiRuntimeAsyncValueCreator<TResult>
{
fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
f.debug_struct("MultiRuntimeAsyncValueCreator").finish()
}
}
impl<TResult: Send + Clone + 'static> MultiRuntimeAsyncValueCreator<TResult> {
pub fn new(create_future: CreateFutureFn<TResult>) -> Self {
Self {
state: Mutex::new(State {
retry_index: 0,
future: None,
}),
create_future,
}
}
pub async fn get(&self) -> TResult {
let (mut future, mut retry_index) = {
let mut state = self.state.lock();
let future = match &state.future {
Some(future) => future.clone(),
None => {
let future = self.create_shared_future();
state.future = Some(future.clone());
future
}
};
(future, state.retry_index)
};
loop {
let result = future.await;
match result {
Ok(result) => return result,
Err(join_error) => {
if join_error.is_cancelled() {
let mut state = self.state.lock();
if state.retry_index == retry_index {
// we were the first one to retry, so create a new future
// that we'll run from the current runtime
state.retry_index += 1;
state.future = Some(self.create_shared_future());
}
retry_index = state.retry_index;
future = state.future.as_ref().unwrap().clone();
// just in case we're stuck in a loop
if retry_index > 1000 {
panic!("Something went wrong.") // should never happen
}
} else {
panic!("{}", join_error);
}
}
}
}
}
fn create_shared_future(
&self,
) -> Shared<BoxFuture<'static, JoinResult<TResult>>> {
let future = (self.create_future)();
deno_core::unsync::spawn(future)
.map(|result| result.map_err(Arc::new))
.boxed()
.shared()
}
}
#[cfg(test)]
mod test {
use deno_core::unsync::spawn;
use super::*;
#[tokio::test]
async fn single_runtime() {
let value_creator = MultiRuntimeAsyncValueCreator::new(Box::new(|| {
async { 1 }.boxed_local()
}));
let value = value_creator.get().await;
assert_eq!(value, 1);
}
#[test]
fn multi_runtimes() {
let value_creator =
Arc::new(MultiRuntimeAsyncValueCreator::new(Box::new(|| {
async {
tokio::task::yield_now().await;
1
}
.boxed_local()
})));
let handles = (0..3)
.map(|_| {
let value_creator = value_creator.clone();
std::thread::spawn(|| {
create_runtime().block_on(async move { value_creator.get().await })
})
})
.collect::<Vec<_>>();
for handle in handles {
assert_eq!(handle.join().unwrap(), 1);
}
}
#[test]
fn multi_runtimes_first_never_finishes() {
let is_first_run = Arc::new(Mutex::new(true));
let (tx, rx) = std::sync::mpsc::channel::<()>();
let value_creator = Arc::new(MultiRuntimeAsyncValueCreator::new({
let is_first_run = is_first_run.clone();
Box::new(move || {
let is_first_run = is_first_run.clone();
let tx = tx.clone();
async move {
let is_first_run = {
let mut is_first_run = is_first_run.lock();
let initial_value = *is_first_run;
*is_first_run = false;
tx.send(()).unwrap();
initial_value
};
if is_first_run {
tokio::time::sleep(std::time::Duration::from_millis(30_000)).await;
panic!("TIMED OUT"); // should not happen
} else {
tokio::task::yield_now().await;
}
1
}
.boxed_local()
})
}));
std::thread::spawn({
let value_creator = value_creator.clone();
let is_first_run = is_first_run.clone();
move || {
create_runtime().block_on(async {
let value_creator = value_creator.clone();
// spawn a task that will never complete
spawn(async move { value_creator.get().await });
// wait for the task to set is_first_run to false
while *is_first_run.lock() {
tokio::time::sleep(std::time::Duration::from_millis(20)).await;
}
// now exit the runtime while the value_creator is still pending
})
}
});
let handle = {
let value_creator = value_creator.clone();
std::thread::spawn(|| {
create_runtime().block_on(async move {
let value_creator = value_creator.clone();
rx.recv().unwrap();
// even though the other runtime shutdown, this get() should
// recover and still get the value
value_creator.get().await
})
})
};
assert_eq!(handle.join().unwrap(), 1);
}
fn create_runtime() -> tokio::runtime::Runtime {
tokio::runtime::Builder::new_current_thread()
.enable_all()
.build()
.unwrap()
}
}
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