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denoland-deno/cli/util/file_watcher.rs
Nayeem Rahman 3545bff678 fix(watch): preserve ProcState::file_fetcher between restarts (#15466)
This commit changes "ProcState" to store "file_fetcher" field in an "Arc",
allowing it to be preserved between restarts and thus keeping the state
alive between the restarts. File watchers for "deno test" and "deno bench"
now reset "ProcState" between restarts.
2023-01-13 11:20:14 -05:00

382 lines
10 KiB
Rust

// Copyright 2018-2023 the Deno authors. All rights reserved. MIT license.
use crate::colors;
use crate::util::fs::canonicalize_path;
use deno_core::error::AnyError;
use deno_core::error::JsError;
use deno_core::futures::Future;
use deno_runtime::fmt_errors::format_js_error;
use log::info;
use notify::event::Event as NotifyEvent;
use notify::event::EventKind;
use notify::Error as NotifyError;
use notify::RecommendedWatcher;
use notify::RecursiveMode;
use notify::Watcher;
use std::collections::HashSet;
use std::path::PathBuf;
use std::sync::Arc;
use std::time::Duration;
use tokio::select;
use tokio::sync::mpsc;
use tokio::sync::mpsc::UnboundedReceiver;
use tokio::time::sleep;
const CLEAR_SCREEN: &str = "\x1B[2J\x1B[1;1H";
const DEBOUNCE_INTERVAL: Duration = Duration::from_millis(200);
struct DebouncedReceiver {
// The `recv()` call could be used in a tokio `select!` macro,
// and so we store this state on the struct to ensure we don't
// lose items if a `recv()` never completes
received_items: HashSet<PathBuf>,
receiver: UnboundedReceiver<Vec<PathBuf>>,
}
impl DebouncedReceiver {
fn new_with_sender() -> (Arc<mpsc::UnboundedSender<Vec<PathBuf>>>, Self) {
let (sender, receiver) = mpsc::unbounded_channel();
(
Arc::new(sender),
Self {
receiver,
received_items: HashSet::new(),
},
)
}
async fn recv(&mut self) -> Option<Vec<PathBuf>> {
if self.received_items.is_empty() {
self
.received_items
.extend(self.receiver.recv().await?.into_iter());
}
loop {
select! {
items = self.receiver.recv() => {
self.received_items.extend(items?);
}
_ = sleep(DEBOUNCE_INTERVAL) => {
return Some(self.received_items.drain().collect());
}
}
}
}
}
async fn error_handler<F>(watch_future: F)
where
F: Future<Output = Result<(), AnyError>>,
{
let result = watch_future.await;
if let Err(err) = result {
let error_string = match err.downcast_ref::<JsError>() {
Some(e) => format_js_error(e),
None => format!("{:?}", err),
};
eprintln!(
"{}: {}",
colors::red_bold("error"),
error_string.trim_start_matches("error: ")
);
}
}
pub enum ResolutionResult<T> {
Restart {
paths_to_watch: Vec<PathBuf>,
result: Result<T, AnyError>,
},
Ignore,
}
async fn next_restart<R, T, F>(
resolver: &mut R,
debounced_receiver: &mut DebouncedReceiver,
) -> (Vec<PathBuf>, Result<T, AnyError>)
where
R: FnMut(Option<Vec<PathBuf>>) -> F,
F: Future<Output = ResolutionResult<T>>,
{
loop {
let changed = debounced_receiver.recv().await;
match resolver(changed).await {
ResolutionResult::Ignore => {
log::debug!("File change ignored")
}
ResolutionResult::Restart {
mut paths_to_watch,
result,
} => {
// watch the current directory when empty
if paths_to_watch.is_empty() {
paths_to_watch.push(PathBuf::from("."));
}
return (paths_to_watch, result);
}
}
}
}
pub struct PrintConfig {
/// printing watcher status to terminal.
pub job_name: String,
/// determine whether to clear the terminal screen; applicable to TTY environments only.
pub clear_screen: bool,
}
fn create_print_after_restart_fn(clear_screen: bool) -> impl Fn() {
move || {
if clear_screen && atty::is(atty::Stream::Stderr) {
eprint!("{}", CLEAR_SCREEN);
}
info!(
"{} File change detected! Restarting!",
colors::intense_blue("Watcher"),
);
}
}
/// Creates a file watcher, which will call `resolver` with every file change.
///
/// - `resolver` is used for resolving file paths to be watched at every restarting
/// of the watcher, and can also return a value to be passed to `operation`.
/// It returns a [`ResolutionResult`], which can either instruct the watcher to restart or ignore the change.
/// This always contains paths to watch;
///
/// - `operation` is the actual operation we want to run every time the watcher detects file
/// changes. For example, in the case where we would like to bundle, then `operation` would
/// have the logic for it like bundling the code.
pub async fn watch_func<R, O, T, F1, F2>(
mut resolver: R,
mut operation: O,
print_config: PrintConfig,
) -> Result<(), AnyError>
where
R: FnMut(Option<Vec<PathBuf>>) -> F1,
O: FnMut(T) -> F2,
F1: Future<Output = ResolutionResult<T>>,
F2: Future<Output = Result<(), AnyError>>,
{
let (sender, mut receiver) = DebouncedReceiver::new_with_sender();
let PrintConfig {
job_name,
clear_screen,
} = print_config;
// Store previous data. If module resolution fails at some point, the watcher will try to
// continue watching files using these data.
let mut paths_to_watch;
let mut resolution_result;
let print_after_restart = create_print_after_restart_fn(clear_screen);
match resolver(None).await {
ResolutionResult::Ignore => {
// The only situation where it makes sense to ignore the initial 'change'
// is if the command isn't supposed to do anything until something changes,
// e.g. a variant of `deno test` which doesn't run the entire test suite to start with,
// but instead does nothing until you make a change.
//
// In that case, this is probably the correct output.
info!(
"{} Waiting for file changes...",
colors::intense_blue("Watcher"),
);
let (paths, result) = next_restart(&mut resolver, &mut receiver).await;
paths_to_watch = paths;
resolution_result = result;
print_after_restart();
}
ResolutionResult::Restart {
paths_to_watch: mut paths,
result,
} => {
// watch the current directory when empty
if paths.is_empty() {
paths.push(PathBuf::from("."));
}
paths_to_watch = paths;
resolution_result = result;
}
};
info!("{} {} started.", colors::intense_blue("Watcher"), job_name,);
loop {
let mut watcher = new_watcher(sender.clone())?;
add_paths_to_watcher(&mut watcher, &paths_to_watch);
match resolution_result {
Ok(operation_arg) => {
let fut = error_handler(operation(operation_arg));
select! {
(paths, result) = next_restart(&mut resolver, &mut receiver) => {
if result.is_ok() {
paths_to_watch = paths;
}
resolution_result = result;
print_after_restart();
continue;
},
_ = fut => {},
};
info!(
"{} {} finished. Restarting on file change...",
colors::intense_blue("Watcher"),
job_name,
);
}
Err(error) => {
eprintln!("{}: {}", colors::red_bold("error"), error);
info!(
"{} {} failed. Restarting on file change...",
colors::intense_blue("Watcher"),
job_name,
);
}
}
let (paths, result) = next_restart(&mut resolver, &mut receiver).await;
if result.is_ok() {
paths_to_watch = paths;
}
resolution_result = result;
print_after_restart();
drop(watcher);
}
}
/// Creates a file watcher.
///
/// - `operation` is the actual operation we want to run every time the watcher detects file
/// changes. For example, in the case where we would like to bundle, then `operation` would
/// have the logic for it like bundling the code.
pub async fn watch_func2<T: Clone, O, F>(
mut paths_to_watch_receiver: UnboundedReceiver<Vec<PathBuf>>,
mut operation: O,
operation_args: T,
print_config: PrintConfig,
) -> Result<(), AnyError>
where
O: FnMut(T) -> Result<F, AnyError>,
F: Future<Output = Result<(), AnyError>>,
{
let (watcher_sender, mut watcher_receiver) =
DebouncedReceiver::new_with_sender();
let PrintConfig {
job_name,
clear_screen,
} = print_config;
let print_after_restart = create_print_after_restart_fn(clear_screen);
info!("{} {} started.", colors::intense_blue("Watcher"), job_name,);
fn consume_paths_to_watch(
watcher: &mut RecommendedWatcher,
receiver: &mut UnboundedReceiver<Vec<PathBuf>>,
) {
loop {
match receiver.try_recv() {
Ok(paths) => {
add_paths_to_watcher(watcher, &paths);
}
Err(e) => match e {
mpsc::error::TryRecvError::Empty => {
break;
}
// there must be at least one receiver alive
_ => unreachable!(),
},
}
}
}
loop {
let mut watcher = new_watcher(watcher_sender.clone())?;
consume_paths_to_watch(&mut watcher, &mut paths_to_watch_receiver);
let receiver_future = async {
loop {
let maybe_paths = paths_to_watch_receiver.recv().await;
add_paths_to_watcher(&mut watcher, &maybe_paths.unwrap());
}
};
let operation_future = error_handler(operation(operation_args.clone())?);
select! {
_ = receiver_future => {},
_ = watcher_receiver.recv() => {
print_after_restart();
continue;
},
_ = operation_future => {
consume_paths_to_watch(&mut watcher, &mut paths_to_watch_receiver);
// TODO(bartlomieju): print exit code here?
info!(
"{} {} finished. Restarting on file change...",
colors::intense_blue("Watcher"),
job_name,
);
},
};
let receiver_future = async {
loop {
let maybe_paths = paths_to_watch_receiver.recv().await;
add_paths_to_watcher(&mut watcher, &maybe_paths.unwrap());
}
};
select! {
_ = receiver_future => {},
_ = watcher_receiver.recv() => {
print_after_restart();
continue;
},
};
}
}
fn new_watcher(
sender: Arc<mpsc::UnboundedSender<Vec<PathBuf>>>,
) -> Result<RecommendedWatcher, AnyError> {
let watcher = Watcher::new(
move |res: Result<NotifyEvent, NotifyError>| {
if let Ok(event) = res {
if matches!(
event.kind,
EventKind::Create(_) | EventKind::Modify(_) | EventKind::Remove(_)
) {
let paths = event
.paths
.iter()
.filter_map(|path| canonicalize_path(path).ok())
.collect();
sender.send(paths).unwrap();
}
}
},
Default::default(),
)?;
Ok(watcher)
}
fn add_paths_to_watcher(watcher: &mut RecommendedWatcher, paths: &[PathBuf]) {
// Ignore any error e.g. `PathNotFound`
for path in paths {
let _ = watcher.watch(path, RecursiveMode::Recursive);
}
log::debug!("Watching paths: {:?}", paths);
}