// Copyright 2018-2022 the Deno authors. All rights reserved. MIT license. use crate::colors; use crate::fmt_errors::format_js_error; use crate::fs_util::canonicalize_path; use deno_core::error::AnyError; use deno_core::error::JsError; use deno_core::futures::Future; use log::info; use notify::event::Event as NotifyEvent; use notify::event::EventKind; use notify::Config; 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, receiver: mpsc::UnboundedReceiver>, } impl DebouncedReceiver { fn new_with_sender() -> (Arc>>, Self) { let (sender, receiver) = mpsc::unbounded_channel(); ( Arc::new(sender), Self { receiver, received_items: HashSet::new(), }, ) } async fn recv(&mut self) -> Option> { if self.received_items.is_empty() { self .received_items .extend(self.receiver.recv().await?.into_iter()); } loop { tokio::select! { items = self.receiver.recv() => { self.received_items.extend(items?); } _ = sleep(DEBOUNCE_INTERVAL) => { return Some(self.received_items.drain().collect()); } } } } } async fn error_handler(watch_future: F) where F: Future>, { let result = watch_future.await; if let Err(err) = result { let error_string = match err.downcast_ref::() { Some(e) => format_js_error(e), None => format!("{:?}", err), }; eprintln!( "{}: {}", colors::red_bold("error"), error_string.trim_start_matches("error: ") ); } } pub enum ResolutionResult { Restart { paths_to_watch: Vec, result: Result, }, Ignore, } async fn next_restart( resolver: &mut R, debounced_receiver: &mut DebouncedReceiver, ) -> (Vec, Result) where R: FnMut(Option>) -> F, F: Future>, { loop { let changed = debounced_receiver.recv().await; match resolver(changed).await { ResolutionResult::Ignore => { log::debug!("File change ignored") } ResolutionResult::Restart { paths_to_watch, result, } => { return (paths_to_watch, result); } } } } pub struct PrintConfig { /// printing watcher status to terminal. pub job_name: String, /// determine whether to clear the terminal screen pub clear_screen: bool, } fn create_print_after_restart_fn(clear_screen: bool) -> impl Fn() { move || { if clear_screen { 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( mut resolver: R, mut operation: O, print_config: PrintConfig, ) -> Result<(), AnyError> where R: FnMut(Option>) -> F1, O: FnMut(T) -> F2, F1: Future>, F2: Future>, { 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: paths, result, } => { 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( mut paths_to_watch_receiver: mpsc::UnboundedReceiver>, mut operation: O, operation_args: T, print_config: PrintConfig, ) -> Result<(), AnyError> where O: FnMut(T) -> F, F: Future>, { 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>, ) { 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 => { // TODO(bartlomieju): print exit code here? info!( "{} {} finished. Restarting on file change...", colors::intense_blue("Watcher"), job_name, ); 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()); } }; select! { _ = receiver_future => {}, _ = watcher_receiver.recv() => { print_after_restart(); continue; }, }; } } fn new_watcher( sender: Arc>>, ) -> Result { let mut watcher: RecommendedWatcher = Watcher::new(move |res: Result| { 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(); } } })?; watcher.configure(Config::PreciseEvents(true)).unwrap(); 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); }