src/event_loop.rs - third_party/github.com/alacritty/alacritty - Git at Google

 //! The main event loop which performs I/O on the pseudoterminal
 use std::borrow::Cow;
 use std::collections::VecDeque;
 use std::io::{self, ErrorKind, Write};
 use std::fs::File;
 use std::os::unix::io::AsRawFd;
 use std::sync::Arc;

 use mio::{self, Events, PollOpt, Ready};
 use mio::unix::EventedFd;

 use ansi;
 use display;
 use event;
 use term::Term;
 use util::thread;
 use sync::FairMutex;

 /// Messages that may be sent to the `EventLoop`
 #[derive(Debug)]
 pub enum Msg {
     /// Data that should be written to the pty
     Input(Cow<'static, [u8]>),

     /// Indicates that the `EventLoop` should shut down, as Alacritty is shutting down
     Shutdown
 }

 /// The main event!.. loop.
 ///
 /// Handles all the pty I/O and runs the pty parser which updates terminal
 /// state.
 pub struct EventLoop<Io> {
     poll: mio::Poll,
     pty: Io,
     rx: mio::channel::Receiver<Msg>,
     tx: mio::channel::Sender<Msg>,
     terminal: Arc<FairMutex<Term>>,
     display: display::Notifier,
     ref_test: bool,
 }

 /// Helper type which tracks how much of a buffer has been written.
 struct Writing {
     source: Cow<'static, [u8]>,
     written: usize,
 }

 /// Indicates the result of draining the mio channel
 #[derive(Debug)]
 enum DrainResult {
     /// At least one new item was received
     ReceivedItem,
     /// Nothing was available to receive
     Empty,
     /// A shutdown message was received
     Shutdown
 }

 impl DrainResult {
     pub fn is_shutdown(&self) -> bool {
         match *self {
             DrainResult::Shutdown => true,
             _ => false
         }
     }

     pub fn is_empty(&self) -> bool {
         match *self {
             DrainResult::Empty => true,
             _ => false
         }
     }
 }

 /// All of the mutable state needed to run the event loop
 ///
 /// Contains list of items to write, current write state, etc. Anything that
 /// would otherwise be mutated on the `EventLoop` goes here.
 pub struct State {
     write_list: VecDeque<Cow<'static, [u8]>>,
     writing: Option<Writing>,
     parser: ansi::Processor,
 }

 pub struct Notifier(pub ::mio::channel::Sender<Msg>);

 impl event::Notify for Notifier {
     fn notify<B>(&mut self, bytes: B)
         where B: Into<Cow<'static, [u8]>>
     {
         let bytes = bytes.into();
         // terminal hangs if we send 0 bytes through.
         if bytes.len() == 0 {
             return
         }
         match self.0.send(Msg::Input(bytes)) {
             Ok(_) => (),
             Err(_) => panic!("expected send event loop msg"),
         }
     }
 }


 impl Default for State {
     fn default() -> State {
         State {
             write_list: VecDeque::new(),
             parser: ansi::Processor::new(),
             writing: None,
         }
     }
 }

 impl State {
     #[inline]
     fn ensure_next(&mut self) {
         if self.writing.is_none() {
             self.goto_next();
         }
     }

     #[inline]
     fn goto_next(&mut self) {
         self.writing = self.write_list
             .pop_front()
             .map(Writing::new);
     }

     #[inline]
     fn take_current(&mut self) -> Option<Writing> {
         self.writing.take()
     }

     #[inline]
     fn needs_write(&self) -> bool {
         self.writing.is_some() || !self.write_list.is_empty()
     }

     #[inline]
     fn set_current(&mut self, new: Option<Writing>) {
         self.writing = new;
     }
 }

 impl Writing {
     #[inline]
     fn new(c: Cow<'static, [u8]>) -> Writing {
         Writing { source: c, written: 0 }
     }

     #[inline]
     fn advance(&mut self, n: usize) {
         self.written += n;
     }

     #[inline]
     fn remaining_bytes(&self) -> &[u8] {
         &self.source[self.written..]
     }

     #[inline]
     fn finished(&self) -> bool {
         self.written >= self.source.len()
     }
 }

 /// `mio::Token` for the event loop channel
 const CHANNEL: mio::Token = mio::Token(0);

 /// `mio::Token` for the pty file descriptor
 const PTY: mio::Token = mio::Token(1);

 impl<Io> EventLoop<Io>
     where Io: io::Read + io::Write + Send + AsRawFd + 'static
 {
     /// Create a new event loop
     pub fn new(
         terminal: Arc<FairMutex<Term>>,
         display: display::Notifier,
         pty: Io,
         ref_test: bool,
     ) -> EventLoop<Io> {
         let (tx, rx) = ::mio::channel::channel();
         EventLoop {
             poll: mio::Poll::new().expect("create mio Poll"),
             pty: pty,
             tx: tx,
             rx: rx,
             terminal: terminal,
             display: display,
             ref_test: ref_test,
         }
     }

     pub fn channel(&self) -> mio::channel::Sender<Msg> {
         self.tx.clone()
     }

     // Drain the channel
     //
     // Returns a `DrainResult` indicating the result of receiving from the channe;
     //
     fn drain_recv_channel(&self, state: &mut State) -> DrainResult {
         let mut received_item = false;
         while let Ok(msg) = self.rx.try_recv() {
             received_item = true;
             match msg {
                 Msg::Input(input) => {
                     state.write_list.push_back(input);
                 },
                 Msg::Shutdown => {
                     return DrainResult::Shutdown;
                 }
             }
         }

         if received_item {
             DrainResult::ReceivedItem
         } else {
             DrainResult::Empty
         }
     }

     // Returns a `bool` indicating whether or not the event loop should continue running
     #[inline]
     fn channel_event(&mut self, state: &mut State) -> bool {
         if self.drain_recv_channel(state).is_shutdown() {
             return false;
         }

         self.poll.reregister(
             &self.rx, CHANNEL,
             Ready::readable(),
             PollOpt::edge() | PollOpt::oneshot()
         ).expect("reregister channel");

         if state.needs_write() {
             self.poll.reregister(
                 &EventedFd(&self.pty.as_raw_fd()),
                 PTY,
                 Ready::readable() | Ready::writable(),
                 PollOpt::edge() | PollOpt::oneshot()
             ).expect("reregister fd after channel recv");
         }

         true
     }

     #[inline]
     fn pty_read<W>(
         &mut self,
         state: &mut State,
         buf: &mut [u8],
         mut writer: Option<&mut W>
     ) -> io::Result<()>
         where W: Write
     {
         loop {
             match self.pty.read(&mut buf[..]) {
                 Ok(0) => break,
                 Ok(got) => {
                     writer = writer.map(|w| {
                         w.write_all(&buf[..got]).unwrap(); w
                     });

                     let mut terminal = self.terminal.lock();
                     for byte in &buf[..got] {
                         state.parser.advance(&mut *terminal, *byte, &mut self.pty);
                     }

                     // Only request a draw if one hasn't already been requested.
                     //
                     // This is a performance optimization even if only for X11
                     // which is very expensive to hammer on the even loop wakeup
                     if !terminal.dirty {
                         self.display.notify();
                         terminal.dirty = true;

                         // Break for writing
                         //
                         // Want to prevent case where reading always returns
                         // data and sequences like `C-c` cannot be sent.
                         //
                         // Doing this check in !terminal.dirty will prevent the
                         // condition from being checked overzealously.
                         //
                         // Break if `drain_recv_channel` signals there is work to do or
                         // shutting down.
                         if state.writing.is_some()
                             || !state.write_list.is_empty()
                             || !self.drain_recv_channel(state).is_empty()
                         {
                             break;
                         }
                     }
                 },
                 Err(err) => {
                     match err.kind() {
                         ErrorKind::Interrupted |
                         ErrorKind::WouldBlock => break,
                         _ => return Err(err),
                     }
                 }
             }
         }

         Ok(())
     }

     #[inline]
     fn pty_write(&mut self, state: &mut State) -> io::Result<()> {
         state.ensure_next();

         'write_many: while let Some(mut current) = state.take_current() {
             'write_one: loop {
                 match self.pty.write(current.remaining_bytes()) {
                     Ok(0) => {
                         state.set_current(Some(current));
                         break 'write_many;
                     },
                     Ok(n) => {
                         current.advance(n);
                         if current.finished() {
                             state.goto_next();
                             break 'write_one;
                         }
                     },
                     Err(err) => {
                         state.set_current(Some(current));
                         match err.kind() {
                             ErrorKind::Interrupted |
                             ErrorKind::WouldBlock => break 'write_many,
                             _ => return Err(err),
                         }
                     }
                 }

             }
         }

         Ok(())
     }

     pub fn spawn(
         mut self,
         state: Option<State>
     ) -> thread::JoinHandle<(EventLoop<Io>, State)> {
         thread::spawn_named("pty reader", move || {
             let mut state = state.unwrap_or_else(Default::default);
             let mut buf = [0u8; 4096];

             let fd = self.pty.as_raw_fd();
             let fd = EventedFd(&fd);

             let poll_opts = PollOpt::edge() | PollOpt::oneshot();

             self.poll.register(&self.rx, CHANNEL, Ready::readable(), poll_opts).unwrap();
             self.poll.register(&fd, PTY, Ready::readable(), poll_opts).unwrap();

             let mut events = Events::with_capacity(1024);

             let mut pipe = if self.ref_test {
                 let file = File::create("./alacritty.recording")
                     .expect("create alacritty recording");
                 Some(file)
             } else {
                 None
             };

             'event_loop: loop {
                 if let Err(err) = self.poll.poll(&mut events, None) {
                     match err.kind() {
                         ErrorKind::Interrupted => continue,
                         _ => panic!("EventLoop polling error: {:?}", err)
                     }
                 }

                 for event in events.iter() {
                     match event.token() {
                         CHANNEL =>  {
                             if !self.channel_event(&mut state) {
                                 break 'event_loop;
                             }
                         },
                         PTY => {
                             let kind = event.kind();

                             if kind.is_hup() {
                                 break 'event_loop;
                             }

                             if kind.is_readable() {
                                 if let Err(err) = self.pty_read(&mut state, &mut buf, pipe.as_mut()) {
                                     error!("Event loop exitting due to error: {} [{}:{}]",
                                            err, file!(), line!());
                                     break 'event_loop;
                                 }

                                 if ::tty::process_should_exit() {
                                     break 'event_loop;
                                 }
                             }

                             if kind.is_writable() {
                                 if let Err(err) = self.pty_write(&mut state) {
                                     error!("Event loop exitting due to error: {} [{}:{}]",
                                            err, file!(), line!());
                                     break 'event_loop;
                                 }
                             }

                             // Figure out pty interest
                             let mut interest = Ready::readable();
                             if state.needs_write() {
                                 interest.insert(Ready::writable());
                             }

                             // Reregister pty
                             self.poll
                                 .reregister(&fd, PTY, interest, poll_opts)
                                 .expect("register fd after read/write");
                         },
                         _ => (),
                     }
                 }
             }

             let _ = self.poll.deregister(&self.rx);
             let _ = self.poll.deregister(&fd);

             (self, state)
         })
     }
 }
	//! The main event loop which performs I/O on the pseudoterminal
	use std::borrow::Cow;
	use std::collections::VecDeque;
	use std::io::{self, ErrorKind, Write};
	use std::fs::File;
	use std::os::unix::io::AsRawFd;
	use std::sync::Arc;

	use mio::{self, Events, PollOpt, Ready};
	use mio::unix::EventedFd;

	use ansi;
	use display;
	use event;
	use term::Term;
	use util::thread;
	use sync::FairMutex;

	/// Messages that may be sent to the `EventLoop`
	#[derive(Debug)]
	pub enum Msg {
	/// Data that should be written to the pty
	Input(Cow<'static, [u8]>),

	/// Indicates that the `EventLoop` should shut down, as Alacritty is shutting down
	Shutdown
	}

	/// The main event!.. loop.
	///
	/// Handles all the pty I/O and runs the pty parser which updates terminal
	/// state.
	pub struct EventLoop<Io> {
	poll: mio::Poll,
	pty: Io,
	rx: mio::channel::Receiver<Msg>,
	tx: mio::channel::Sender<Msg>,
	terminal: Arc<FairMutex<Term>>,
	display: display::Notifier,
	ref_test: bool,
	}

	/// Helper type which tracks how much of a buffer has been written.
	struct Writing {
	source: Cow<'static, [u8]>,
	written: usize,
	}

	/// Indicates the result of draining the mio channel
	#[derive(Debug)]
	enum DrainResult {
	/// At least one new item was received
	ReceivedItem,
	/// Nothing was available to receive
	Empty,
	/// A shutdown message was received
	Shutdown
	}

	impl DrainResult {
	pub fn is_shutdown(&self) -> bool {
	match *self {
	DrainResult::Shutdown => true,
	_ => false
	}
	}

	pub fn is_empty(&self) -> bool {
	match *self {
	DrainResult::Empty => true,
	_ => false
	}
	}
	}

	/// All of the mutable state needed to run the event loop
	///
	/// Contains list of items to write, current write state, etc. Anything that
	/// would otherwise be mutated on the `EventLoop` goes here.
	pub struct State {
	write_list: VecDeque<Cow<'static, [u8]>>,
	writing: Option<Writing>,
	parser: ansi::Processor,
	}

	pub struct Notifier(pub ::mio::channel::Sender<Msg>);

	impl event::Notify for Notifier {
	fn notify<B>(&mut self, bytes: B)
	where B: Into<Cow<'static, [u8]>>
	{
	let bytes = bytes.into();
	// terminal hangs if we send 0 bytes through.
	if bytes.len() == 0 {
	return
	}
	match self.0.send(Msg::Input(bytes)) {
	Ok(_) => (),
	Err(_) => panic!("expected send event loop msg"),
	}
	}
	}


	impl Default for State {
	fn default() -> State {
	State {
	write_list: VecDeque::new(),
	parser: ansi::Processor::new(),
	writing: None,
	}
	}
	}

	impl State {
	#[inline]
	fn ensure_next(&mut self) {
	if self.writing.is_none() {
	self.goto_next();
	}
	}

	#[inline]
	fn goto_next(&mut self) {
	self.writing = self.write_list
	.pop_front()
	.map(Writing::new);
	}

	#[inline]
	fn take_current(&mut self) -> Option<Writing> {
	self.writing.take()
	}

	#[inline]
	fn needs_write(&self) -> bool {
	self.writing.is_some() \|\| !self.write_list.is_empty()
	}

	#[inline]
	fn set_current(&mut self, new: Option<Writing>) {
	self.writing = new;
	}
	}

	impl Writing {
	#[inline]
	fn new(c: Cow<'static, [u8]>) -> Writing {
	Writing { source: c, written: 0 }
	}

	#[inline]
	fn advance(&mut self, n: usize) {
	self.written += n;
	}

	#[inline]
	fn remaining_bytes(&self) -> &[u8] {
	&self.source[self.written..]
	}

	#[inline]
	fn finished(&self) -> bool {
	self.written >= self.source.len()
	}
	}

	/// `mio::Token` for the event loop channel
	const CHANNEL: mio::Token = mio::Token(0);

	/// `mio::Token` for the pty file descriptor
	const PTY: mio::Token = mio::Token(1);

	impl<Io> EventLoop<Io>
	where Io: io::Read + io::Write + Send + AsRawFd + 'static
	{
	/// Create a new event loop
	pub fn new(
	terminal: Arc<FairMutex<Term>>,
	display: display::Notifier,
	pty: Io,
	ref_test: bool,
	) -> EventLoop<Io> {
	let (tx, rx) = ::mio::channel::channel();
	EventLoop {
	poll: mio::Poll::new().expect("create mio Poll"),
	pty: pty,
	tx: tx,
	rx: rx,
	terminal: terminal,
	display: display,
	ref_test: ref_test,
	}
	}

	pub fn channel(&self) -> mio::channel::Sender<Msg> {
	self.tx.clone()
	}

	// Drain the channel
	//
	// Returns a `DrainResult` indicating the result of receiving from the channe;
	//
	fn drain_recv_channel(&self, state: &mut State) -> DrainResult {
	let mut received_item = false;
	while let Ok(msg) = self.rx.try_recv() {
	received_item = true;
	match msg {
	Msg::Input(input) => {
	state.write_list.push_back(input);
	},
	Msg::Shutdown => {
	return DrainResult::Shutdown;
	}
	}
	}

	if received_item {
	DrainResult::ReceivedItem
	} else {
	DrainResult::Empty
	}
	}

	// Returns a `bool` indicating whether or not the event loop should continue running
	#[inline]
	fn channel_event(&mut self, state: &mut State) -> bool {
	if self.drain_recv_channel(state).is_shutdown() {
	return false;
	}

	self.poll.reregister(
	&self.rx, CHANNEL,
	Ready::readable(),
	PollOpt::edge() \| PollOpt::oneshot()
	).expect("reregister channel");

	if state.needs_write() {
	self.poll.reregister(
	&EventedFd(&self.pty.as_raw_fd()),
	PTY,
	Ready::readable() \| Ready::writable(),
	PollOpt::edge() \| PollOpt::oneshot()
	).expect("reregister fd after channel recv");
	}

	true
	}

	#[inline]
	fn pty_read<W>(
	&mut self,
	state: &mut State,
	buf: &mut [u8],
	mut writer: Option<&mut W>
	) -> io::Result<()>
	where W: Write
	{
	loop {
	match self.pty.read(&mut buf[..]) {
	Ok(0) => break,
	Ok(got) => {
	writer = writer.map(\|w\| {
	w.write_all(&buf[..got]).unwrap(); w
	});

	let mut terminal = self.terminal.lock();
	for byte in &buf[..got] {
	state.parser.advance(&mut terminal, byte, &mut self.pty);
	}

	// Only request a draw if one hasn't already been requested.
	//
	// This is a performance optimization even if only for X11
	// which is very expensive to hammer on the even loop wakeup
	if !terminal.dirty {
	self.display.notify();
	terminal.dirty = true;

	// Break for writing
	//
	// Want to prevent case where reading always returns
	// data and sequences like `C-c` cannot be sent.
	//
	// Doing this check in !terminal.dirty will prevent the
	// condition from being checked overzealously.
	//
	// Break if `drain_recv_channel` signals there is work to do or
	// shutting down.
	if state.writing.is_some()
	\|\| !state.write_list.is_empty()
	\|\| !self.drain_recv_channel(state).is_empty()
	{
	break;
	}
	}
	},
	Err(err) => {
	match err.kind() {
	ErrorKind::Interrupted \|
	ErrorKind::WouldBlock => break,
	_ => return Err(err),
	}
	}
	}
	}

	Ok(())
	}

	#[inline]
	fn pty_write(&mut self, state: &mut State) -> io::Result<()> {
	state.ensure_next();

	'write_many: while let Some(mut current) = state.take_current() {
	'write_one: loop {
	match self.pty.write(current.remaining_bytes()) {
	Ok(0) => {
	state.set_current(Some(current));
	break 'write_many;
	},
	Ok(n) => {
	current.advance(n);
	if current.finished() {
	state.goto_next();
	break 'write_one;
	}
	},
	Err(err) => {
	state.set_current(Some(current));
	match err.kind() {
	ErrorKind::Interrupted \|
	ErrorKind::WouldBlock => break 'write_many,
	_ => return Err(err),
	}
	}
	}

	}
	}

	Ok(())
	}

	pub fn spawn(
	mut self,
	state: Option<State>
	) -> thread::JoinHandle<(EventLoop<Io>, State)> {
	thread::spawn_named("pty reader", move \|\| {
	let mut state = state.unwrap_or_else(Default::default);
	let mut buf = [0u8; 4096];

	let fd = self.pty.as_raw_fd();
	let fd = EventedFd(&fd);

	let poll_opts = PollOpt::edge() \| PollOpt::oneshot();

	self.poll.register(&self.rx, CHANNEL, Ready::readable(), poll_opts).unwrap();
	self.poll.register(&fd, PTY, Ready::readable(), poll_opts).unwrap();

	let mut events = Events::with_capacity(1024);

	let mut pipe = if self.ref_test {
	let file = File::create("./alacritty.recording")
	.expect("create alacritty recording");
	Some(file)
	} else {
	None
	};

	'event_loop: loop {
	if let Err(err) = self.poll.poll(&mut events, None) {
	match err.kind() {
	ErrorKind::Interrupted => continue,
	_ => panic!("EventLoop polling error: {:?}", err)
	}
	}

	for event in events.iter() {
	match event.token() {
	CHANNEL => {
	if !self.channel_event(&mut state) {
	break 'event_loop;
	}
	},
	PTY => {
	let kind = event.kind();

	if kind.is_hup() {
	break 'event_loop;
	}

	if kind.is_readable() {
	if let Err(err) = self.pty_read(&mut state, &mut buf, pipe.as_mut()) {
	error!("Event loop exitting due to error: {} [{}:{}]",
	err, file!(), line!());
	break 'event_loop;
	}

	if ::tty::process_should_exit() {
	break 'event_loop;
	}
	}

	if kind.is_writable() {
	if let Err(err) = self.pty_write(&mut state) {
	error!("Event loop exitting due to error: {} [{}:{}]",
	err, file!(), line!());
	break 'event_loop;
	}
	}

	// Figure out pty interest
	let mut interest = Ready::readable();
	if state.needs_write() {
	interest.insert(Ready::writable());
	}

	// Reregister pty
	self.poll
	.reregister(&fd, PTY, interest, poll_opts)
	.expect("register fd after read/write");
	},
	_ => (),
	}
	}
	}

	let _ = self.poll.deregister(&self.rx);
	let _ = self.poll.deregister(&fd);

	(self, state)
	})
	}
	}