1
0
Fork 0
mirror of https://github.com/denoland/deno.git synced 2024-12-22 07:14:47 -05:00
denoland-deno/cli/util/file_watcher.rs
Nayeem Rahman a635c9700c
refactor: reland "preserve ProcState::file_fetcher between restarts" (#17636)
Just some watcher init step that I thought would be "cloned over" but
needs to be done again on reset.
2023-02-03 20:15:16 +01:00

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);
}