wasmtime_fiber/lib.rs
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use anyhow::Error;
use std::any::Any;
use std::cell::Cell;
use std::io;
use std::marker::PhantomData;
use std::ops::Range;
use std::panic::{self, AssertUnwindSafe};
cfg_if::cfg_if! {
if #[cfg(windows)] {
mod windows;
use windows as imp;
} else if #[cfg(unix)] {
mod unix;
use unix as imp;
} else {
compile_error!("fibers are not supported on this platform");
}
}
/// Represents an execution stack to use for a fiber.
pub struct FiberStack(imp::FiberStack);
impl FiberStack {
/// Creates a new fiber stack of the given size.
pub fn new(size: usize) -> io::Result<Self> {
Ok(Self(imp::FiberStack::new(size)?))
}
/// Creates a new fiber stack of the given size.
pub fn from_custom(custom: Box<dyn RuntimeFiberStack>) -> io::Result<Self> {
Ok(Self(imp::FiberStack::from_custom(custom)?))
}
/// Creates a new fiber stack with the given pointer to the bottom of the
/// stack plus how large the guard size and stack size are.
///
/// The bytes from `bottom` to `bottom.add(guard_size)` should all be
/// guaranteed to be unmapped. The bytes from `bottom.add(guard_size)` to
/// `bottom.add(guard_size + len)` should be addressable.
///
/// # Safety
///
/// This is unsafe because there is no validation of the given pointer.
///
/// The caller must properly allocate the stack space with a guard page and
/// make the pages accessible for correct behavior.
pub unsafe fn from_raw_parts(
bottom: *mut u8,
guard_size: usize,
len: usize,
) -> io::Result<Self> {
Ok(Self(imp::FiberStack::from_raw_parts(
bottom, guard_size, len,
)?))
}
/// Gets the top of the stack.
///
/// Returns `None` if the platform does not support getting the top of the
/// stack.
pub fn top(&self) -> Option<*mut u8> {
self.0.top()
}
/// Returns the range of where this stack resides in memory if the platform
/// supports it.
pub fn range(&self) -> Option<Range<usize>> {
self.0.range()
}
/// Is this a manually-managed stack created from raw parts? If so, it is up
/// to whoever created it to manage the stack's memory allocation.
pub fn is_from_raw_parts(&self) -> bool {
self.0.is_from_raw_parts()
}
/// Returns the range of memory that the guard page(s) reside in.
pub fn guard_range(&self) -> Option<Range<*mut u8>> {
self.0.guard_range()
}
}
/// A creator of RuntimeFiberStacks.
pub unsafe trait RuntimeFiberStackCreator: Send + Sync {
/// Creates a new RuntimeFiberStack with the specified size, guard pages should be included,
/// memory should be zeroed.
///
/// This is useful to plugin previously allocated memory instead of mmap'ing a new stack for
/// every instance.
fn new_stack(&self, size: usize) -> Result<Box<dyn RuntimeFiberStack>, Error>;
}
/// A fiber stack backed by custom memory.
pub unsafe trait RuntimeFiberStack: Send + Sync {
/// The top of the allocated stack.
fn top(&self) -> *mut u8;
/// The valid range of the stack without guard pages.
fn range(&self) -> Range<usize>;
/// The range of the guard page(s)
fn guard_range(&self) -> Range<*mut u8>;
}
pub struct Fiber<'a, Resume, Yield, Return> {
stack: Option<FiberStack>,
inner: imp::Fiber,
done: Cell<bool>,
_phantom: PhantomData<&'a (Resume, Yield, Return)>,
}
pub struct Suspend<Resume, Yield, Return> {
inner: imp::Suspend,
_phantom: PhantomData<(Resume, Yield, Return)>,
}
enum RunResult<Resume, Yield, Return> {
Executing,
Resuming(Resume),
Yield(Yield),
Returned(Return),
Panicked(Box<dyn Any + Send>),
}
impl<'a, Resume, Yield, Return> Fiber<'a, Resume, Yield, Return> {
/// Creates a new fiber which will execute `func` on the given stack.
///
/// This function returns a `Fiber` which, when resumed, will execute `func`
/// to completion. When desired the `func` can suspend itself via
/// `Fiber::suspend`.
pub fn new(
stack: FiberStack,
func: impl FnOnce(Resume, &mut Suspend<Resume, Yield, Return>) -> Return + 'a,
) -> io::Result<Self> {
let inner = imp::Fiber::new(&stack.0, func)?;
Ok(Self {
stack: Some(stack),
inner,
done: Cell::new(false),
_phantom: PhantomData,
})
}
/// Resumes execution of this fiber.
///
/// This function will transfer execution to the fiber and resume from where
/// it last left off.
///
/// Returns `true` if the fiber finished or `false` if the fiber was
/// suspended in the middle of execution.
///
/// # Panics
///
/// Panics if the current thread is already executing a fiber or if this
/// fiber has already finished.
///
/// Note that if the fiber itself panics during execution then the panic
/// will be propagated to this caller.
pub fn resume(&self, val: Resume) -> Result<Return, Yield> {
assert!(!self.done.replace(true), "cannot resume a finished fiber");
let result = Cell::new(RunResult::Resuming(val));
self.inner.resume(&self.stack().0, &result);
match result.into_inner() {
RunResult::Resuming(_) | RunResult::Executing => unreachable!(),
RunResult::Yield(y) => {
self.done.set(false);
Err(y)
}
RunResult::Returned(r) => Ok(r),
RunResult::Panicked(payload) => std::panic::resume_unwind(payload),
}
}
/// Returns whether this fiber has finished executing.
pub fn done(&self) -> bool {
self.done.get()
}
/// Gets the stack associated with this fiber.
pub fn stack(&self) -> &FiberStack {
self.stack.as_ref().unwrap()
}
/// When this fiber has finished executing, reclaim its stack.
pub fn into_stack(mut self) -> FiberStack {
assert!(self.done());
self.stack.take().unwrap()
}
}
impl<Resume, Yield, Return> Suspend<Resume, Yield, Return> {
/// Suspend execution of a currently running fiber.
///
/// This function will switch control back to the original caller of
/// `Fiber::resume`. This function will then return once the `Fiber::resume`
/// function is called again.
///
/// # Panics
///
/// Panics if the current thread is not executing a fiber from this library.
pub fn suspend(&mut self, value: Yield) -> Resume {
self.inner
.switch::<Resume, Yield, Return>(RunResult::Yield(value))
}
fn execute(
inner: imp::Suspend,
initial: Resume,
func: impl FnOnce(Resume, &mut Suspend<Resume, Yield, Return>) -> Return,
) {
let mut suspend = Suspend {
inner,
_phantom: PhantomData,
};
let result = panic::catch_unwind(AssertUnwindSafe(|| (func)(initial, &mut suspend)));
suspend.inner.switch::<Resume, Yield, Return>(match result {
Ok(result) => RunResult::Returned(result),
Err(panic) => RunResult::Panicked(panic),
});
}
}
impl<A, B, C> Drop for Fiber<'_, A, B, C> {
fn drop(&mut self) {
debug_assert!(self.done.get(), "fiber dropped without finishing");
}
}
#[cfg(test)]
mod tests {
use super::{Fiber, FiberStack};
use std::cell::Cell;
use std::panic::{self, AssertUnwindSafe};
use std::rc::Rc;
#[test]
fn small_stacks() {
Fiber::<(), (), ()>::new(FiberStack::new(0).unwrap(), |_, _| {})
.unwrap()
.resume(())
.unwrap();
Fiber::<(), (), ()>::new(FiberStack::new(1).unwrap(), |_, _| {})
.unwrap()
.resume(())
.unwrap();
}
#[test]
fn smoke() {
let hit = Rc::new(Cell::new(false));
let hit2 = hit.clone();
let fiber = Fiber::<(), (), ()>::new(FiberStack::new(1024 * 1024).unwrap(), move |_, _| {
hit2.set(true);
})
.unwrap();
assert!(!hit.get());
fiber.resume(()).unwrap();
assert!(hit.get());
}
#[test]
fn suspend_and_resume() {
let hit = Rc::new(Cell::new(false));
let hit2 = hit.clone();
let fiber = Fiber::<(), (), ()>::new(FiberStack::new(1024 * 1024).unwrap(), move |_, s| {
s.suspend(());
hit2.set(true);
s.suspend(());
})
.unwrap();
assert!(!hit.get());
assert!(fiber.resume(()).is_err());
assert!(!hit.get());
assert!(fiber.resume(()).is_err());
assert!(hit.get());
assert!(fiber.resume(()).is_ok());
assert!(hit.get());
}
#[test]
fn backtrace_traces_to_host() {
#[inline(never)] // try to get this to show up in backtraces
fn look_for_me() {
run_test();
}
fn assert_contains_host() {
let trace = backtrace::Backtrace::new();
println!("{trace:?}");
assert!(
trace
.frames()
.iter()
.flat_map(|f| f.symbols())
.filter_map(|s| Some(s.name()?.to_string()))
.any(|s| s.contains("look_for_me"))
// TODO: apparently windows unwind routines don't unwind through fibers, so this will always fail. Is there a way we can fix that?
|| cfg!(windows)
// TODO: the system libunwind is broken (#2808)
|| cfg!(all(target_os = "macos", target_arch = "aarch64"))
// TODO: see comments in `arm.rs` about how this seems to work
// in gdb but not at runtime, unsure why at this time.
|| cfg!(target_arch = "arm")
);
}
fn run_test() {
let fiber =
Fiber::<(), (), ()>::new(FiberStack::new(1024 * 1024).unwrap(), move |(), s| {
assert_contains_host();
s.suspend(());
assert_contains_host();
s.suspend(());
assert_contains_host();
})
.unwrap();
assert!(fiber.resume(()).is_err());
assert!(fiber.resume(()).is_err());
assert!(fiber.resume(()).is_ok());
}
look_for_me();
}
#[test]
fn panics_propagated() {
let a = Rc::new(Cell::new(false));
let b = SetOnDrop(a.clone());
let fiber =
Fiber::<(), (), ()>::new(FiberStack::new(1024 * 1024).unwrap(), move |(), _s| {
let _ = &b;
panic!();
})
.unwrap();
assert!(panic::catch_unwind(AssertUnwindSafe(|| fiber.resume(()))).is_err());
assert!(a.get());
struct SetOnDrop(Rc<Cell<bool>>);
impl Drop for SetOnDrop {
fn drop(&mut self) {
self.0.set(true);
}
}
}
#[test]
fn suspend_and_resume_values() {
let fiber = Fiber::new(FiberStack::new(1024 * 1024).unwrap(), move |first, s| {
assert_eq!(first, 2.0);
assert_eq!(s.suspend(4), 3.0);
"hello".to_string()
})
.unwrap();
assert_eq!(fiber.resume(2.0), Err(4));
assert_eq!(fiber.resume(3.0), Ok("hello".to_string()));
}
}