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#![cfg_attr(not(feature = "rt"), allow(dead_code))]
mod interest;
#[allow(unreachable_pub)]
pub use interest::Interest;
mod ready;
#[allow(unreachable_pub)]
pub use ready::Ready;
mod registration;
pub(crate) use registration::Registration;
mod scheduled_io;
use scheduled_io::ScheduledIo;
use crate::park::{Park, Unpark};
use crate::util::slab::{self, Slab};
use crate::{loom::sync::Mutex, util::bit};
use std::fmt;
use std::io;
use std::sync::{Arc, Weak};
use std::time::Duration;
/// I/O driver, backed by Mio.
pub(crate) struct Driver {
/// Tracks the number of times `turn` is called. It is safe for this to wrap
/// as it is mostly used to determine when to call `compact()`.
tick: u8,
/// Reuse the `mio::Events` value across calls to poll.
events: Option<mio::Events>,
/// Primary slab handle containing the state for each resource registered
/// with this driver. During Drop this is moved into the Inner structure, so
/// this is an Option to allow it to be vacated (until Drop this is always
/// Some).
resources: Option<Slab<ScheduledIo>>,
/// The system event queue.
poll: mio::Poll,
/// State shared between the reactor and the handles.
inner: Arc<Inner>,
}
/// A reference to an I/O driver.
#[derive(Clone)]
pub(crate) struct Handle {
inner: Weak<Inner>,
}
#[derive(Debug)]
pub(crate) struct ReadyEvent {
tick: u8,
pub(crate) ready: Ready,
}
pub(super) struct Inner {
/// Primary slab handle containing the state for each resource registered
/// with this driver.
///
/// The ownership of this slab is moved into this structure during
/// `Driver::drop`, so that `Inner::drop` can notify all outstanding handles
/// without risking new ones being registered in the meantime.
resources: Mutex<Option<Slab<ScheduledIo>>>,
/// Registers I/O resources.
registry: mio::Registry,
/// Allocates `ScheduledIo` handles when creating new resources.
pub(super) io_dispatch: slab::Allocator<ScheduledIo>,
/// Used to wake up the reactor from a call to `turn`.
waker: mio::Waker,
}
#[derive(Debug, Eq, PartialEq, Clone, Copy)]
enum Direction {
Read,
Write,
}
enum Tick {
Set(u8),
Clear(u8),
}
// TODO: Don't use a fake token. Instead, reserve a slot entry for the wakeup
// token.
const TOKEN_WAKEUP: mio::Token = mio::Token(1 << 31);
const ADDRESS: bit::Pack = bit::Pack::least_significant(24);
// Packs the generation value in the `readiness` field.
//
// The generation prevents a race condition where a slab slot is reused for a
// new socket while the I/O driver is about to apply a readiness event. The
// generation value is checked when setting new readiness. If the generation do
// not match, then the readiness event is discarded.
const GENERATION: bit::Pack = ADDRESS.then(7);
fn _assert_kinds() {
fn _assert<T: Send + Sync>() {}
_assert::<Handle>();
}
// ===== impl Driver =====
impl Driver {
/// Creates a new event loop, returning any error that happened during the
/// creation.
pub(crate) fn new() -> io::Result<Driver> {
let poll = mio::Poll::new()?;
let waker = mio::Waker::new(poll.registry(), TOKEN_WAKEUP)?;
let registry = poll.registry().try_clone()?;
let slab = Slab::new();
let allocator = slab.allocator();
Ok(Driver {
tick: 0,
events: Some(mio::Events::with_capacity(1024)),
poll,
resources: Some(slab),
inner: Arc::new(Inner {
resources: Mutex::new(None),
registry,
io_dispatch: allocator,
waker,
}),
})
}
/// Returns a handle to this event loop which can be sent across threads
/// and can be used as a proxy to the event loop itself.
///
/// Handles are cloneable and clones always refer to the same event loop.
/// This handle is typically passed into functions that create I/O objects
/// to bind them to this event loop.
pub(crate) fn handle(&self) -> Handle {
Handle {
inner: Arc::downgrade(&self.inner),
}
}
fn turn(&mut self, max_wait: Option<Duration>) -> io::Result<()> {
// How often to call `compact()` on the resource slab
const COMPACT_INTERVAL: u8 = 255;
self.tick = self.tick.wrapping_add(1);
if self.tick == COMPACT_INTERVAL {
self.resources.as_mut().unwrap().compact()
}
let mut events = self.events.take().expect("i/o driver event store missing");
// Block waiting for an event to happen, peeling out how many events
// happened.
match self.poll.poll(&mut events, max_wait) {
Ok(_) => {}
Err(ref e) if e.kind() == io::ErrorKind::Interrupted => {}
Err(e) => return Err(e),
}
// Process all the events that came in, dispatching appropriately
for event in events.iter() {
let token = event.token();
if token != TOKEN_WAKEUP {
self.dispatch(token, Ready::from_mio(event));
}
}
self.events = Some(events);
Ok(())
}
fn dispatch(&mut self, token: mio::Token, ready: Ready) {
let addr = slab::Address::from_usize(ADDRESS.unpack(token.0));
let resources = self.resources.as_mut().unwrap();
let io = match resources.get(addr) {
Some(io) => io,
None => return,
};
let res = io.set_readiness(Some(token.0), Tick::Set(self.tick), |curr| curr | ready);
if res.is_err() {
// token no longer valid!
return;
}
io.wake(ready);
}
}
impl Drop for Driver {
fn drop(&mut self) {
(*self.inner.resources.lock()) = self.resources.take();
}
}
impl Drop for Inner {
fn drop(&mut self) {
let resources = self.resources.lock().take();
if let Some(mut slab) = resources {
slab.for_each(|io| {
// If a task is waiting on the I/O resource, notify it. The task
// will then attempt to use the I/O resource and fail due to the
// driver being shutdown.
io.shutdown();
});
}
}
}
impl Park for Driver {
type Unpark = Handle;
type Error = io::Error;
fn unpark(&self) -> Self::Unpark {
self.handle()
}
fn park(&mut self) -> io::Result<()> {
self.turn(None)?;
Ok(())
}
fn park_timeout(&mut self, duration: Duration) -> io::Result<()> {
self.turn(Some(duration))?;
Ok(())
}
fn shutdown(&mut self) {}
}
impl fmt::Debug for Driver {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
write!(f, "Driver")
}
}
// ===== impl Handle =====
cfg_rt! {
impl Handle {
/// Returns a handle to the current reactor.
///
/// # Panics
///
/// This function panics if there is no current reactor set and `rt` feature
/// flag is not enabled.
pub(super) fn current() -> Self {
crate::runtime::context::io_handle().expect("A Tokio 1.x context was found, but IO is disabled. Call `enable_io` on the runtime builder to enable IO.")
}
}
}
cfg_not_rt! {
impl Handle {
/// Returns a handle to the current reactor.
///
/// # Panics
///
/// This function panics if there is no current reactor set, or if the `rt`
/// feature flag is not enabled.
pub(super) fn current() -> Self {
panic!("{}", crate::util::error::CONTEXT_MISSING_ERROR)
}
}
}
impl Handle {
/// Forces a reactor blocked in a call to `turn` to wakeup, or otherwise
/// makes the next call to `turn` return immediately.
///
/// This method is intended to be used in situations where a notification
/// needs to otherwise be sent to the main reactor. If the reactor is
/// currently blocked inside of `turn` then it will wake up and soon return
/// after this method has been called. If the reactor is not currently
/// blocked in `turn`, then the next call to `turn` will not block and
/// return immediately.
fn wakeup(&self) {
if let Some(inner) = self.inner() {
inner.waker.wake().expect("failed to wake I/O driver");
}
}
pub(super) fn inner(&self) -> Option<Arc<Inner>> {
self.inner.upgrade()
}
}
impl Unpark for Handle {
fn unpark(&self) {
self.wakeup();
}
}
impl fmt::Debug for Handle {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
write!(f, "Handle")
}
}
// ===== impl Inner =====
impl Inner {
/// Registers an I/O resource with the reactor for a given `mio::Ready` state.
///
/// The registration token is returned.
pub(super) fn add_source(
&self,
source: &mut impl mio::event::Source,
interest: Interest,
) -> io::Result<slab::Ref<ScheduledIo>> {
let (address, shared) = self.io_dispatch.allocate().ok_or_else(|| {
io::Error::new(
io::ErrorKind::Other,
"reactor at max registered I/O resources",
)
})?;
let token = GENERATION.pack(shared.generation(), ADDRESS.pack(address.as_usize(), 0));
self.registry
.register(source, mio::Token(token), interest.to_mio())?;
Ok(shared)
}
/// Deregisters an I/O resource from the reactor.
pub(super) fn deregister_source(&self, source: &mut impl mio::event::Source) -> io::Result<()> {
self.registry.deregister(source)
}
}
impl Direction {
pub(super) fn mask(self) -> Ready {
match self {
Direction::Read => Ready::READABLE | Ready::READ_CLOSED,
Direction::Write => Ready::WRITABLE | Ready::WRITE_CLOSED,
}
}
}
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