Merge pull request #3971 from RalfJung/futex-virtual

store futexes in per-allocation data rather than globally
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Ralf Jung 2024-11-10 10:26:23 +00:00 committed by GitHub
commit 673d9c3e85
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5 changed files with 122 additions and 55 deletions

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@ -1,6 +1,8 @@
use std::cell::RefCell;
use std::collections::VecDeque;
use std::collections::hash_map::Entry;
use std::ops::Not;
use std::rc::Rc;
use std::time::Duration;
use rustc_abi::Size;
@ -121,6 +123,15 @@ struct Futex {
clock: VClock,
}
#[derive(Default, Clone)]
pub struct FutexRef(Rc<RefCell<Futex>>);
impl VisitProvenance for FutexRef {
fn visit_provenance(&self, _visit: &mut VisitWith<'_>) {
// No provenance in `Futex`.
}
}
/// A thread waiting on a futex.
#[derive(Debug)]
struct FutexWaiter {
@ -137,9 +148,6 @@ pub struct SynchronizationObjects {
rwlocks: IndexVec<RwLockId, RwLock>,
condvars: IndexVec<CondvarId, Condvar>,
pub(super) init_onces: IndexVec<InitOnceId, InitOnce>,
/// Futex info for the futex at the given address.
futexes: FxHashMap<u64, Futex>,
}
// Private extension trait for local helper methods
@ -184,7 +192,7 @@ pub fn init_once_create(&mut self) -> InitOnceId {
}
impl<'tcx> AllocExtra<'tcx> {
pub fn get_sync<T: 'static>(&self, offset: Size) -> Option<&T> {
fn get_sync<T: 'static>(&self, offset: Size) -> Option<&T> {
self.sync.get(&offset).and_then(|s| s.downcast_ref::<T>())
}
}
@ -273,27 +281,32 @@ fn lazy_sync_get_data<T: 'static + Copy>(
/// Get the synchronization primitive associated with the given pointer,
/// or initialize a new one.
///
/// Return `None` if this pointer does not point to at least 1 byte of mutable memory.
fn get_sync_or_init<'a, T: 'static>(
&'a mut self,
ptr: Pointer,
new: impl FnOnce(&'a mut MiriMachine<'tcx>) -> InterpResult<'tcx, T>,
) -> InterpResult<'tcx, &'a T>
new: impl FnOnce(&'a mut MiriMachine<'tcx>) -> T,
) -> Option<&'a T>
where
'tcx: 'a,
{
let this = self.eval_context_mut();
// Ensure there is memory behind this pointer, so that this allocation
// is truly the only place where the data could be stored.
this.check_ptr_access(ptr, Size::from_bytes(1), CheckInAllocMsg::InboundsTest)?;
let (alloc, offset, _) = this.ptr_get_alloc_id(ptr, 0)?;
let (alloc_extra, machine) = this.get_alloc_extra_mut(alloc)?;
if !this.ptr_try_get_alloc_id(ptr, 0).ok().is_some_and(|(alloc_id, offset, ..)| {
let info = this.get_alloc_info(alloc_id);
info.kind == AllocKind::LiveData && info.mutbl.is_mut() && offset < info.size
}) {
return None;
}
// This cannot fail now.
let (alloc, offset, _) = this.ptr_get_alloc_id(ptr, 0).unwrap();
let (alloc_extra, machine) = this.get_alloc_extra_mut(alloc).unwrap();
// Due to borrow checker reasons, we have to do the lookup twice.
if alloc_extra.get_sync::<T>(offset).is_none() {
let new = new(machine)?;
let new = new(machine);
alloc_extra.sync.insert(offset, Box::new(new));
}
interp_ok(alloc_extra.get_sync::<T>(offset).unwrap())
Some(alloc_extra.get_sync::<T>(offset).unwrap())
}
#[inline]
@ -690,7 +703,7 @@ fn condvar_signal(&mut self, id: CondvarId) -> InterpResult<'tcx, bool> {
/// On a timeout, `retval_timeout` is written to `dest` and `errno_timeout` is set as the last error.
fn futex_wait(
&mut self,
addr: u64,
futex_ref: FutexRef,
bitset: u32,
timeout: Option<(TimeoutClock, TimeoutAnchor, Duration)>,
retval_succ: Scalar,
@ -700,23 +713,25 @@ fn futex_wait(
) {
let this = self.eval_context_mut();
let thread = this.active_thread();
let futex = &mut this.machine.sync.futexes.entry(addr).or_default();
let mut futex = futex_ref.0.borrow_mut();
let waiters = &mut futex.waiters;
assert!(waiters.iter().all(|waiter| waiter.thread != thread), "thread is already waiting");
waiters.push_back(FutexWaiter { thread, bitset });
drop(futex);
this.block_thread(
BlockReason::Futex { addr },
BlockReason::Futex,
timeout,
callback!(
@capture<'tcx> {
addr: u64,
futex_ref: FutexRef,
retval_succ: Scalar,
retval_timeout: Scalar,
dest: MPlaceTy<'tcx>,
errno_timeout: IoError,
}
@unblock = |this| {
let futex = this.machine.sync.futexes.get(&addr).unwrap();
let futex = futex_ref.0.borrow();
// Acquire the clock of the futex.
if let Some(data_race) = &this.machine.data_race {
data_race.acquire_clock(&futex.clock, &this.machine.threads);
@ -728,7 +743,7 @@ fn futex_wait(
@timeout = |this| {
// Remove the waiter from the futex.
let thread = this.active_thread();
let futex = this.machine.sync.futexes.get_mut(&addr).unwrap();
let mut futex = futex_ref.0.borrow_mut();
futex.waiters.retain(|waiter| waiter.thread != thread);
// Set errno and write return value.
this.set_last_error(errno_timeout)?;
@ -739,12 +754,11 @@ fn futex_wait(
);
}
/// Wake up the first thread in the queue that matches any of the bits in the bitset.
/// Returns whether anything was woken.
fn futex_wake(&mut self, addr: u64, bitset: u32) -> InterpResult<'tcx, bool> {
fn futex_wake(&mut self, futex_ref: &FutexRef, bitset: u32) -> InterpResult<'tcx, bool> {
let this = self.eval_context_mut();
let Some(futex) = this.machine.sync.futexes.get_mut(&addr) else {
return interp_ok(false);
};
let mut futex = futex_ref.0.borrow_mut();
let data_race = &this.machine.data_race;
// Each futex-wake happens-before the end of the futex wait
@ -757,7 +771,8 @@ fn futex_wake(&mut self, addr: u64, bitset: u32) -> InterpResult<'tcx, bool> {
return interp_ok(false);
};
let waiter = futex.waiters.remove(i).unwrap();
this.unblock_thread(waiter.thread, BlockReason::Futex { addr })?;
drop(futex);
this.unblock_thread(waiter.thread, BlockReason::Futex)?;
interp_ok(true)
}
}

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@ -147,7 +147,7 @@ pub enum BlockReason {
/// Blocked on a reader-writer lock.
RwLock(RwLockId),
/// Blocked on a Futex variable.
Futex { addr: u64 },
Futex,
/// Blocked on an InitOnce.
InitOnce(InitOnceId),
/// Blocked on epoll.

View File

@ -1,6 +1,11 @@
use crate::concurrency::sync::FutexRef;
use crate::helpers::check_min_arg_count;
use crate::*;
struct LinuxFutex {
futex: FutexRef,
}
/// Implementation of the SYS_futex syscall.
/// `args` is the arguments *including* the syscall number.
pub fn futex<'tcx>(
@ -27,7 +32,6 @@ pub fn futex<'tcx>(
// This is a vararg function so we have to bring our own type for this pointer.
let addr = this.ptr_to_mplace(addr, this.machine.layouts.i32);
let addr_usize = addr.ptr().addr().bytes();
let futex_private = this.eval_libc_i32("FUTEX_PRIVATE_FLAG");
let futex_wait = this.eval_libc_i32("FUTEX_WAIT");
@ -63,8 +67,7 @@ pub fn futex<'tcx>(
};
if bitset == 0 {
this.set_last_error_and_return(LibcError("EINVAL"), dest)?;
return interp_ok(());
return this.set_last_error_and_return(LibcError("EINVAL"), dest);
}
let timeout = this.deref_pointer_as(timeout, this.libc_ty_layout("timespec"))?;
@ -99,19 +102,18 @@ pub fn futex<'tcx>(
// effects of this and the other thread are correctly observed,
// otherwise we will deadlock.
//
// There are two scenarios to consider:
// 1. If we (FUTEX_WAIT) execute first, we'll push ourselves into
// the waiters queue and go to sleep. They (addr write & FUTEX_WAKE)
// will see us in the queue and wake us up.
// 2. If they (addr write & FUTEX_WAKE) execute first, we must observe
// addr's new value. If we see an outdated value that happens to equal
// the expected val, then we'll put ourselves to sleep with no one to wake us
// up, so we end up with a deadlock. This is prevented by having a SeqCst
// fence inside FUTEX_WAKE syscall, and another SeqCst fence
// below, the atomic read on addr after the SeqCst fence is guaranteed
// not to see any value older than the addr write immediately before
// calling FUTEX_WAKE. We'll see futex_val != val and return without
// sleeping.
// There are two scenarios to consider, depending on whether WAIT or WAKE goes first:
// 1. If we (FUTEX_WAIT) execute first, we'll push ourselves into the waiters queue and
// go to sleep. They (FUTEX_WAKE) will see us in the queue and wake us up. It doesn't
// matter how the addr write is ordered.
// 2. If they (FUTEX_WAKE) execute first, that means the addr write is also before us
// (FUTEX_WAIT). It is crucial that we observe addr's new value. If we see an
// outdated value that happens to equal the expected val, then we'll put ourselves to
// sleep with no one to wake us up, so we end up with a deadlock. This is prevented
// by having a SeqCst fence inside FUTEX_WAKE syscall, and another SeqCst fence here
// in FUTEX_WAIT. The atomic read on addr after the SeqCst fence is guaranteed not to
// see any value older than the addr write immediately before calling FUTEX_WAKE.
// We'll see futex_val != val and return without sleeping.
//
// Note that the fences do not create any happens-before relationship.
// The read sees the write immediately before the fence not because
@ -140,11 +142,22 @@ pub fn futex<'tcx>(
this.atomic_fence(AtomicFenceOrd::SeqCst)?;
// Read an `i32` through the pointer, regardless of any wrapper types.
// It's not uncommon for `addr` to be passed as another type than `*mut i32`, such as `*const AtomicI32`.
let futex_val = this.read_scalar_atomic(&addr, AtomicReadOrd::Relaxed)?.to_i32()?;
// We do an acquire read -- it only seems reasonable that if we observe a value here, we
// actually establish an ordering with that value.
let futex_val = this.read_scalar_atomic(&addr, AtomicReadOrd::Acquire)?.to_i32()?;
if val == futex_val {
// The value still matches, so we block the thread and make it wait for FUTEX_WAKE.
// This cannot fail since we already did an atomic acquire read on that pointer.
// Acquire reads are only allowed on mutable memory.
let futex_ref = this
.get_sync_or_init(addr.ptr(), |_| LinuxFutex { futex: Default::default() })
.unwrap()
.futex
.clone();
this.futex_wait(
addr_usize,
futex_ref,
bitset,
timeout,
Scalar::from_target_isize(0, this), // retval_succ
@ -165,6 +178,17 @@ pub fn futex<'tcx>(
// FUTEX_WAKE_BITSET: (int *addr, int op = FUTEX_WAKE, int val, const timespect *_unused, int *_unused, unsigned int bitset)
// Same as FUTEX_WAKE, but allows you to specify a bitset to select which threads to wake up.
op if op == futex_wake || op == futex_wake_bitset => {
let Some(futex_ref) =
this.get_sync_or_init(addr.ptr(), |_| LinuxFutex { futex: Default::default() })
else {
// No AllocId, or no live allocation at that AllocId.
// Return an error code. (That seems nicer than silently doing something non-intuitive.)
// This means that if an address gets reused by a new allocation,
// we'll use an independent futex queue for this... that seems acceptable.
return this.set_last_error_and_return(LibcError("EFAULT"), dest);
};
let futex_ref = futex_ref.futex.clone();
let bitset = if op == futex_wake_bitset {
let [_, _, _, _, timeout, uaddr2, bitset] =
check_min_arg_count("`syscall(SYS_futex, FUTEX_WAKE_BITSET, ...)`", args)?;
@ -184,7 +208,7 @@ pub fn futex<'tcx>(
let mut n = 0;
#[expect(clippy::arithmetic_side_effects)]
for _ in 0..val {
if this.futex_wake(addr_usize, bitset)? {
if this.futex_wake(&futex_ref, bitset)? {
n += 1;
} else {
break;

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@ -3,6 +3,7 @@
use rustc_abi::Size;
use crate::concurrency::init_once::InitOnceStatus;
use crate::concurrency::sync::FutexRef;
use crate::*;
#[derive(Copy, Clone)]
@ -10,6 +11,10 @@ struct WindowsInitOnce {
id: InitOnceId,
}
struct WindowsFutex {
futex: FutexRef,
}
impl<'tcx> EvalContextExtPriv<'tcx> for crate::MiriInterpCx<'tcx> {}
trait EvalContextExtPriv<'tcx>: crate::MiriInterpCxExt<'tcx> {
// Windows sync primitives are pointer sized.
@ -168,8 +173,6 @@ fn WaitOnAddress(
let size = this.read_target_usize(size_op)?;
let timeout_ms = this.read_scalar(timeout_op)?.to_u32()?;
let addr = ptr.addr().bytes();
if size > 8 || !size.is_power_of_two() {
let invalid_param = this.eval_windows("c", "ERROR_INVALID_PARAMETER");
this.set_last_error(invalid_param)?;
@ -190,13 +193,21 @@ fn WaitOnAddress(
let layout = this.machine.layouts.uint(size).unwrap();
let futex_val =
this.read_scalar_atomic(&this.ptr_to_mplace(ptr, layout), AtomicReadOrd::Relaxed)?;
this.read_scalar_atomic(&this.ptr_to_mplace(ptr, layout), AtomicReadOrd::Acquire)?;
let compare_val = this.read_scalar(&this.ptr_to_mplace(compare, layout))?;
if futex_val == compare_val {
// If the values are the same, we have to block.
// This cannot fail since we already did an atomic acquire read on that pointer.
let futex_ref = this
.get_sync_or_init(ptr, |_| WindowsFutex { futex: Default::default() })
.unwrap()
.futex
.clone();
this.futex_wait(
addr,
futex_ref,
u32::MAX, // bitset
timeout,
Scalar::from_i32(1), // retval_succ
@ -219,8 +230,15 @@ fn WakeByAddressSingle(&mut self, ptr_op: &OpTy<'tcx>) -> InterpResult<'tcx> {
// See the Linux futex implementation for why this fence exists.
this.atomic_fence(AtomicFenceOrd::SeqCst)?;
let addr = ptr.addr().bytes();
this.futex_wake(addr, u32::MAX)?;
let Some(futex_ref) =
this.get_sync_or_init(ptr, |_| WindowsFutex { futex: Default::default() })
else {
// Seems like this cannot return an error, so we just wake nobody.
return interp_ok(());
};
let futex_ref = futex_ref.futex.clone();
this.futex_wake(&futex_ref, u32::MAX)?;
interp_ok(())
}
@ -232,8 +250,15 @@ fn WakeByAddressAll(&mut self, ptr_op: &OpTy<'tcx>) -> InterpResult<'tcx> {
// See the Linux futex implementation for why this fence exists.
this.atomic_fence(AtomicFenceOrd::SeqCst)?;
let addr = ptr.addr().bytes();
while this.futex_wake(addr, u32::MAX)? {}
let Some(futex_ref) =
this.get_sync_or_init(ptr, |_| WindowsFutex { futex: Default::default() })
else {
// Seems like this cannot return an error, so we just wake nobody.
return interp_ok(());
};
let futex_ref = futex_ref.futex.clone();
while this.futex_wake(&futex_ref, u32::MAX)? {}
interp_ok(())
}

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@ -41,9 +41,12 @@ fn wake_dangling() {
let ptr: *const i32 = &*futex;
drop(futex);
// Wake 1 waiter. Expect zero waiters woken up, as nobody is waiting.
// Expect error since this is now "unmapped" memory.
// parking_lot relies on this:
// <https://github.com/Amanieu/parking_lot/blob/ca920b31312839013b4455aba1d53a4aede21b2f/core/src/thread_parker/linux.rs#L138-L145>
unsafe {
assert_eq!(libc::syscall(libc::SYS_futex, ptr, libc::FUTEX_WAKE, 1), 0);
assert_eq!(libc::syscall(libc::SYS_futex, ptr, libc::FUTEX_WAKE, 1), -1);
assert_eq!(io::Error::last_os_error().raw_os_error().unwrap(), libc::EFAULT);
}
}