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denoland-deno/core/async_cell.rs
Bartek Iwańczuk 6984b63f2f
refactor: rewrite ops to use ResourceTable2 (#8512)
This commit migrates all ops to use new resource table
and "AsyncRefCell".

Old implementation of resource table was completely 
removed and all code referencing it was updated to use
new system.
2020-12-16 17:14:12 +01:00

746 lines
20 KiB
Rust

// Copyright 2018-2020 the Deno authors. All rights reserved. MIT license.
use std::any::type_name;
use std::any::Any;
use std::borrow::Borrow;
use std::cell::Cell;
use std::cell::UnsafeCell;
use std::collections::VecDeque;
use std::fmt;
use std::fmt::Debug;
use std::fmt::Formatter;
use std::ops::Deref;
use std::rc::Rc;
use self::internal as i;
pub type AsyncRef<T> = i::AsyncBorrowImpl<T, i::Shared>;
pub type AsyncMut<T> = i::AsyncBorrowImpl<T, i::Exclusive>;
pub type AsyncRefFuture<T> = i::AsyncBorrowFutureImpl<T, i::Shared>;
pub type AsyncMutFuture<T> = i::AsyncBorrowFutureImpl<T, i::Exclusive>;
pub struct AsyncRefCell<T> {
value: UnsafeCell<T>,
borrow_count: Cell<i::BorrowCount>,
waiters: Cell<VecDeque<Option<i::Waiter>>>,
turn: Cell<usize>,
}
impl<T: 'static> AsyncRefCell<T> {
/// Create a new `AsyncRefCell` that encapsulates the specified value.
/// Note that in order to borrow the inner value, the `AsyncRefCell`
/// needs to be wrapped in an `Rc` or an `RcRef`. These can be created
/// either manually, or by using the convenience method
/// `AsyncRefCell::new_rc()`.
pub fn new(value: T) -> Self {
Self {
value: UnsafeCell::new(value),
borrow_count: Default::default(),
waiters: Default::default(),
turn: Default::default(),
}
}
pub fn new_rc(value: T) -> Rc<Self> {
Rc::new(Self::new(value))
}
pub fn as_ptr(&self) -> *mut T {
self.value.get()
}
pub fn into_inner(self) -> T {
assert!(self.borrow_count.get().is_empty());
self.value.into_inner()
}
}
impl<T> Debug for AsyncRefCell<T> {
fn fmt(&self, f: &mut Formatter) -> fmt::Result {
write!(f, "AsyncRefCell<{}>", type_name::<T>())
}
}
impl<T: Default + 'static> Default for AsyncRefCell<T> {
fn default() -> Self {
Self::new(Default::default())
}
}
impl<T: Default + 'static> AsyncRefCell<T> {
pub fn default_rc() -> Rc<Self> {
Rc::new(Default::default())
}
}
impl<T: 'static> From<T> for AsyncRefCell<T> {
fn from(value: T) -> Self {
Self::new(value)
}
}
impl<T> AsyncRefCell<T> {
pub fn borrow(self: &Rc<Self>) -> AsyncRefFuture<T> {
AsyncRefFuture::new(self)
}
pub fn borrow_mut(self: &Rc<Self>) -> AsyncMutFuture<T> {
AsyncMutFuture::new(self)
}
pub fn try_borrow(self: &Rc<Self>) -> Option<AsyncRef<T>> {
Self::borrow_sync(self)
}
pub fn try_borrow_mut(self: &Rc<Self>) -> Option<AsyncMut<T>> {
Self::borrow_sync(self)
}
}
impl<T> RcRef<AsyncRefCell<T>> {
pub fn borrow(&self) -> AsyncRefFuture<T> {
AsyncRefFuture::new(self)
}
pub fn borrow_mut(&self) -> AsyncMutFuture<T> {
AsyncMutFuture::new(self)
}
pub fn try_borrow(&self) -> Option<AsyncRef<T>> {
AsyncRefCell::<T>::borrow_sync(self)
}
pub fn try_borrow_mut(&self) -> Option<AsyncMut<T>> {
AsyncRefCell::<T>::borrow_sync(self)
}
}
/// An `RcRef` encapsulates a reference counted pointer, just like a regular
/// `std::rc::Rc`. However, unlike a regular `Rc`, it can be remapped so that
/// it dereferences to any value that's reachable through the reference-counted
/// pointer. This is achieved through the associated method, `RcRef::map()`,
/// similar to how `std::cell::Ref::map()` works. Example:
///
/// ```rust
/// # use std::rc::Rc;
/// # use deno_core::RcRef;
///
/// struct Stuff {
/// foo: u32,
/// bar: String,
/// }
///
/// let stuff_rc = Rc::new(Stuff {
/// foo: 42,
/// bar: "hello".to_owned(),
/// });
///
/// // `foo_rc` and `bar_rc` dereference to different types, however
/// // they share a reference count.
/// let foo_rc: RcRef<u32> = RcRef::map(stuff_rc.clone(), |v| &v.foo);
/// let bar_rc: RcRef<String> = RcRef::map(stuff_rc, |v| &v.bar);
/// ```
#[derive(Debug)]
pub struct RcRef<T> {
rc: Rc<dyn Any>,
value: *const T,
}
impl<T: 'static> RcRef<T> {
pub fn new(value: T) -> Self {
Self::from(Rc::new(value))
}
pub fn map<S: 'static, R: RcLike<S>, F: FnOnce(&S) -> &T>(
source: R,
map_fn: F,
) -> RcRef<T> {
let RcRef::<S> { rc, value } = source.into();
let value = map_fn(unsafe { &*value });
RcRef { rc, value }
}
pub(crate) fn split(rc_ref: &Self) -> (&T, &Rc<dyn Any>) {
let &Self { ref rc, value } = rc_ref;
(unsafe { &*value }, rc)
}
}
impl<T: Default + 'static> Default for RcRef<T> {
fn default() -> Self {
Self::new(Default::default())
}
}
impl<T> Clone for RcRef<T> {
fn clone(&self) -> Self {
Self {
rc: self.rc.clone(),
value: self.value,
}
}
}
impl<T: 'static> From<&RcRef<T>> for RcRef<T> {
fn from(rc_ref: &RcRef<T>) -> Self {
rc_ref.clone()
}
}
impl<T: 'static> From<Rc<T>> for RcRef<T> {
fn from(rc: Rc<T>) -> Self {
Self {
value: &*rc,
rc: rc as Rc<_>,
}
}
}
impl<T: 'static> From<&Rc<T>> for RcRef<T> {
fn from(rc: &Rc<T>) -> Self {
rc.clone().into()
}
}
impl<T> Deref for RcRef<T> {
type Target = T;
fn deref(&self) -> &Self::Target {
unsafe { &*self.value }
}
}
impl<T> Borrow<T> for RcRef<T> {
fn borrow(&self) -> &T {
&**self
}
}
impl<T> AsRef<T> for RcRef<T> {
fn as_ref(&self) -> &T {
&**self
}
}
/// The `RcLike` trait provides an abstraction over `std::rc::Rc` and `RcRef`,
/// so that applicable methods can operate on either type.
pub trait RcLike<T>: AsRef<T> + Into<RcRef<T>> {}
impl<T: 'static> RcLike<T> for Rc<T> {}
impl<T: 'static> RcLike<T> for RcRef<T> {}
impl<T: 'static> RcLike<T> for &Rc<T> {}
impl<T: 'static> RcLike<T> for &RcRef<T> {}
mod internal {
use super::AsyncRefCell;
use super::RcLike;
use super::RcRef;
use futures::future::Future;
use futures::ready;
use futures::task::Context;
use futures::task::Poll;
use futures::task::Waker;
use std::borrow::Borrow;
use std::borrow::BorrowMut;
use std::fmt::Debug;
use std::marker::PhantomData;
use std::ops::Deref;
use std::ops::DerefMut;
use std::pin::Pin;
impl<T> AsyncRefCell<T> {
/// Borrow the cell's contents synchronouslym without creating an
/// intermediate future. If the cell has already been borrowed and either
/// the existing or the requested borrow is exclusive, this function returns
/// `None`.
pub fn borrow_sync<M: BorrowModeTrait, R: RcLike<AsyncRefCell<T>>>(
cell: R,
) -> Option<AsyncBorrowImpl<T, M>> {
let cell_ref = cell.as_ref();
// Don't allow synchronous borrows to cut in line; if there are any
// enqueued waiters, return `None`, even if the current borrow is a shared
// one and the requested borrow is too.
let waiters = unsafe { &mut *cell_ref.waiters.as_ptr() };
if waiters.is_empty() {
// There are no enqueued waiters, but it is still possible that the cell
// is currently borrowed. If there are no current borrows, or both the
// existing and requested ones are shared, `try_add()` returns the
// adjusted borrow count.
let new_borrow_count =
cell_ref.borrow_count.get().try_add(M::borrow_mode())?;
cell_ref.borrow_count.set(new_borrow_count);
Some(AsyncBorrowImpl::<T, M>::new(cell.into()))
} else {
None
}
}
fn drop_borrow<M: BorrowModeTrait>(&self) {
let new_borrow_count = self.borrow_count.get().remove(M::borrow_mode());
self.borrow_count.set(new_borrow_count);
if new_borrow_count.is_empty() {
self.wake_waiters()
}
}
fn create_waiter<M: BorrowModeTrait>(&self) -> usize {
let waiter = Waiter::new(M::borrow_mode());
let turn = self.turn.get();
let index = {
let waiters = unsafe { &mut *self.waiters.as_ptr() };
waiters.push_back(Some(waiter));
waiters.len() - 1
};
if index == 0 {
// SAFETY: the `waiters` reference used above *must* be dropped here.
self.wake_waiters()
}
// Return the new waiter's id.
turn + index
}
fn poll_waiter<M: BorrowModeTrait>(
&self,
id: usize,
cx: &mut Context,
) -> Poll<()> {
let borrow_count = self.borrow_count.get();
let turn = self.turn.get();
if id < turn {
// This waiter made it to the front of the line; we reserved a borrow
// for it, woke its Waker, and removed the waiter from the queue.
// Assertion: BorrowCount::remove() will panic if `mode` is incorrect.
let _ = borrow_count.remove(M::borrow_mode());
Poll::Ready(())
} else {
// This waiter is still in line and has not yet been woken.
let waiters = unsafe { &mut *self.waiters.as_ptr() };
// Sanity check: id cannot be higher than the last queue element.
assert!(id < turn + waiters.len());
// Sanity check: since we always call wake_waiters() when the queue head
// is updated, it should be impossible to add it to the current borrow.
assert!(id > turn || borrow_count.try_add(M::borrow_mode()).is_none());
// Save or update the waiter's Waker.
// TODO(piscisaureus): Use will_wake() to make this more efficient.
let waiter_mut = waiters[id - turn].as_mut().unwrap();
waiter_mut.set_waker(cx.waker().clone());
Poll::Pending
}
}
fn wake_waiters(&self) {
let mut borrow_count = self.borrow_count.get();
let waiters = unsafe { &mut *self.waiters.as_ptr() };
let mut turn = self.turn.get();
loop {
let waiter_entry = match waiters.front().map(Option::as_ref) {
None => break, // Queue empty.
Some(w) => w,
};
let borrow_mode = match waiter_entry {
None => {
// Queue contains a hole. This happens when a Waiter is dropped
// before it makes it to the front of the queue.
waiters.pop_front();
turn += 1;
continue;
}
Some(waiter) => waiter.borrow_mode(),
};
// See if the waiter at the front of the queue can borrow the cell's
// value now. If it does, `try_add()` returns the new borrow count,
// effectively "reserving" the borrow until the associated
// AsyncBorrowFutureImpl future gets polled and produces the actual
// borrow.
borrow_count = match borrow_count.try_add(borrow_mode) {
None => break, // Can't borrow yet.
Some(b) => b,
};
// Drop from queue.
let mut waiter = waiters.pop_front().unwrap().unwrap();
turn += 1;
// Wake this waiter, so the AsyncBorrowFutureImpl future gets polled.
if let Some(waker) = waiter.take_waker() {
waker.wake()
}
}
// Save updated counters.
self.borrow_count.set(borrow_count);
self.turn.set(turn);
}
fn drop_waiter<M: BorrowModeTrait>(&self, id: usize) {
let turn = self.turn.get();
if id < turn {
// We already made a borrow count reservation for this waiter but the
// borrow will never be picked up and removesequently, never dropped.
// Therefore, call the borrow drop handler here.
self.drop_borrow::<M>();
} else {
// This waiter is still in the queue, take it out and leave a "hole".
let waiters = unsafe { &mut *self.waiters.as_ptr() };
waiters[id - turn].take().unwrap();
}
if id == turn {
// Since the first entry in the waiter queue was touched we have to
// reprocess the waiter queue.
self.wake_waiters()
}
}
}
pub struct AsyncBorrowFutureImpl<T: 'static, M: BorrowModeTrait> {
cell: Option<RcRef<AsyncRefCell<T>>>,
id: usize,
_phantom: PhantomData<M>,
}
impl<T, M: BorrowModeTrait> AsyncBorrowFutureImpl<T, M> {
pub fn new<R: RcLike<AsyncRefCell<T>>>(cell: R) -> Self {
Self {
id: cell.as_ref().create_waiter::<M>(),
cell: Some(cell.into()),
_phantom: PhantomData,
}
}
}
impl<T: 'static, M: BorrowModeTrait> Future for AsyncBorrowFutureImpl<T, M> {
type Output = AsyncBorrowImpl<T, M>;
fn poll(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<Self::Output> {
ready!(self.cell.as_ref().unwrap().poll_waiter::<M>(self.id, cx));
let self_mut = unsafe { Pin::get_unchecked_mut(self) };
let cell = self_mut.cell.take().unwrap();
Poll::Ready(AsyncBorrowImpl::<T, M>::new(cell))
}
}
impl<T, M: BorrowModeTrait> Drop for AsyncBorrowFutureImpl<T, M> {
fn drop(&mut self) {
// The expected mode of operation is that this future gets polled until it
// is ready and yields a value of type `AsyncBorrowImpl`, which has a drop
// handler that adjusts the `AsyncRefCell` borrow counter. However if the
// `cell` field still holds a value at this point, it means that the
// future was never polled to completion and no `AsyncBorrowImpl` was ever
// created, so we have to adjust the borrow count here.
if let Some(cell) = self.cell.take() {
cell.drop_waiter::<M>(self.id)
}
}
}
pub struct AsyncBorrowImpl<T: 'static, M: BorrowModeTrait> {
cell: RcRef<AsyncRefCell<T>>,
_phantom: PhantomData<M>,
}
impl<T, M: BorrowModeTrait> AsyncBorrowImpl<T, M> {
fn new(cell: RcRef<AsyncRefCell<T>>) -> Self {
Self {
cell,
_phantom: PhantomData,
}
}
}
impl<T, M: BorrowModeTrait> Deref for AsyncBorrowImpl<T, M> {
type Target = T;
fn deref(&self) -> &Self::Target {
unsafe { &*self.cell.as_ptr() }
}
}
impl<T, M: BorrowModeTrait> Borrow<T> for AsyncBorrowImpl<T, M> {
fn borrow(&self) -> &T {
&**self
}
}
impl<T, M: BorrowModeTrait> AsRef<T> for AsyncBorrowImpl<T, M> {
fn as_ref(&self) -> &T {
&**self
}
}
impl<T> DerefMut for AsyncBorrowImpl<T, Exclusive> {
fn deref_mut(&mut self) -> &mut Self::Target {
unsafe { &mut *self.cell.as_ptr() }
}
}
impl<T> BorrowMut<T> for AsyncBorrowImpl<T, Exclusive> {
fn borrow_mut(&mut self) -> &mut T {
&mut **self
}
}
impl<T> AsMut<T> for AsyncBorrowImpl<T, Exclusive> {
fn as_mut(&mut self) -> &mut T {
&mut **self
}
}
impl<T, M: BorrowModeTrait> Drop for AsyncBorrowImpl<T, M> {
fn drop(&mut self) {
self.cell.drop_borrow::<M>()
}
}
#[derive(Copy, Clone, Debug, Eq, PartialEq)]
pub enum BorrowMode {
Shared,
Exclusive,
}
pub trait BorrowModeTrait: Copy {
fn borrow_mode() -> BorrowMode;
}
#[derive(Copy, Clone, Debug)]
pub struct Shared;
impl BorrowModeTrait for Shared {
fn borrow_mode() -> BorrowMode {
BorrowMode::Shared
}
}
#[derive(Copy, Clone, Debug)]
pub struct Exclusive;
impl BorrowModeTrait for Exclusive {
fn borrow_mode() -> BorrowMode {
BorrowMode::Exclusive
}
}
#[derive(Copy, Clone, Debug, Eq, PartialEq)]
pub enum BorrowCount {
Shared(usize),
Exclusive,
}
impl Default for BorrowCount {
fn default() -> Self {
Self::Shared(0)
}
}
impl BorrowCount {
pub fn is_empty(self) -> bool {
matches!(self, BorrowCount::Shared(0))
}
pub fn try_add(self, mode: BorrowMode) -> Option<BorrowCount> {
match (self, mode) {
(BorrowCount::Shared(refs), BorrowMode::Shared) => {
Some(BorrowCount::Shared(refs + 1))
}
(BorrowCount::Shared(0), BorrowMode::Exclusive) => {
Some(BorrowCount::Exclusive)
}
_ => None,
}
}
#[allow(dead_code)]
pub fn add(self, mode: BorrowMode) -> BorrowCount {
match self.try_add(mode) {
Some(value) => value,
None => panic!("Can't add {:?} to {:?}", mode, self),
}
}
pub fn try_remove(self, mode: BorrowMode) -> Option<BorrowCount> {
match (self, mode) {
(BorrowCount::Shared(refs), BorrowMode::Shared) if refs > 0 => {
Some(BorrowCount::Shared(refs - 1))
}
(BorrowCount::Exclusive, BorrowMode::Exclusive) => {
Some(BorrowCount::Shared(0))
}
_ => None,
}
}
pub fn remove(self, mode: BorrowMode) -> BorrowCount {
match self.try_remove(mode) {
Some(value) => value,
None => panic!("Can't remove {:?} from {:?}", mode, self),
}
}
}
/// The `waiters` queue that is associated with an individual `AsyncRefCell`
/// contains elements of the `Waiter` type.
pub struct Waiter {
borrow_mode: BorrowMode,
waker: Option<Waker>,
}
impl Waiter {
pub fn new(borrow_mode: BorrowMode) -> Self {
Self {
borrow_mode,
waker: None,
}
}
pub fn borrow_mode(&self) -> BorrowMode {
self.borrow_mode
}
pub fn set_waker(&mut self, waker: Waker) {
self.waker.replace(waker);
}
pub fn take_waker(&mut self) -> Option<Waker> {
self.waker.take()
}
}
}
#[cfg(test)]
mod tests {
use super::*;
#[derive(Default)]
struct Thing {
touch_count: usize,
_private: (),
}
impl Thing {
pub fn look(&self) -> usize {
self.touch_count
}
pub fn touch(&mut self) -> usize {
self.touch_count += 1;
self.touch_count
}
}
#[tokio::test]
async fn async_ref_cell_borrow() {
let cell = AsyncRefCell::<Thing>::default_rc();
let fut1 = cell.borrow();
let fut2 = cell.borrow_mut();
let fut3 = cell.borrow();
let fut4 = cell.borrow();
let fut5 = cell.borrow();
let fut6 = cell.borrow();
let fut7 = cell.borrow_mut();
let fut8 = cell.borrow();
// The `try_borrow` and `try_borrow_mut` methods should always return `None`
// if there's a queue of async borrowers.
assert!(cell.try_borrow().is_none());
assert!(cell.try_borrow_mut().is_none());
assert_eq!(fut1.await.look(), 0);
assert_eq!(fut2.await.touch(), 1);
{
let ref5 = fut5.await;
let ref4 = fut4.await;
let ref3 = fut3.await;
let ref6 = fut6.await;
assert_eq!(ref3.look(), 1);
assert_eq!(ref4.look(), 1);
assert_eq!(ref5.look(), 1);
assert_eq!(ref6.look(), 1);
}
{
let mut ref7 = fut7.await;
assert_eq!(ref7.look(), 1);
assert_eq!(ref7.touch(), 2);
}
{
let ref8 = fut8.await;
assert_eq!(ref8.look(), 2);
}
}
#[test]
fn async_ref_cell_try_borrow() {
let cell = AsyncRefCell::<Thing>::default_rc();
{
let ref1 = cell.try_borrow().unwrap();
assert_eq!(ref1.look(), 0);
assert!(cell.try_borrow_mut().is_none());
}
{
let mut ref2 = cell.try_borrow_mut().unwrap();
assert_eq!(ref2.touch(), 1);
assert!(cell.try_borrow().is_none());
assert!(cell.try_borrow_mut().is_none());
}
{
let ref3 = cell.try_borrow().unwrap();
let ref4 = cell.try_borrow().unwrap();
let ref5 = cell.try_borrow().unwrap();
let ref6 = cell.try_borrow().unwrap();
assert_eq!(ref3.look(), 1);
assert_eq!(ref4.look(), 1);
assert_eq!(ref5.look(), 1);
assert_eq!(ref6.look(), 1);
assert!(cell.try_borrow_mut().is_none());
}
{
let mut ref7 = cell.try_borrow_mut().unwrap();
assert_eq!(ref7.look(), 1);
assert_eq!(ref7.touch(), 2);
assert!(cell.try_borrow().is_none());
assert!(cell.try_borrow_mut().is_none());
}
{
let ref8 = cell.try_borrow().unwrap();
assert_eq!(ref8.look(), 2);
assert!(cell.try_borrow_mut().is_none());
assert!(cell.try_borrow().is_some());
}
}
#[derive(Default)]
struct ThreeThings {
pub thing1: AsyncRefCell<Thing>,
pub thing2: AsyncRefCell<Thing>,
pub thing3: AsyncRefCell<Thing>,
}
#[tokio::test]
async fn rc_ref_map() {
let three_cells = Rc::new(ThreeThings::default());
let rc1 = RcRef::map(three_cells.clone(), |things| &things.thing1);
let rc2 = RcRef::map(three_cells.clone(), |things| &things.thing2);
let rc3 = RcRef::map(three_cells, |things| &things.thing3);
let mut ref1 = rc1.borrow_mut().await;
let ref2 = rc2.borrow().await;
let mut ref3 = rc3.borrow_mut().await;
assert_eq!(ref1.look(), 0);
assert_eq!(ref3.touch(), 1);
assert_eq!(ref1.touch(), 1);
assert_eq!(ref2.look(), 0);
assert_eq!(ref3.touch(), 2);
assert_eq!(ref1.look(), 1);
assert_eq!(ref1.touch(), 2);
assert_eq!(ref3.touch(), 3);
assert_eq!(ref1.touch(), 3);
}
}