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linux/rust/kernel/time/hrtimer.rs

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// SPDX-License-Identifier: GPL-2.0
//! Intrusive high resolution timers.
//!
//! Allows running timer callbacks without doing allocations at the time of
//! starting the timer. For now, only one timer per type is allowed.
//!
//! # Vocabulary
//!
//! States:
//!
//! - Stopped: initialized but not started, or cancelled, or not restarted.
//! - Started: initialized and started or restarted.
//! - Running: executing the callback.
//!
//! Operations:
//!
//! * Start
//! * Cancel
//! * Restart
//!
//! Events:
//!
//! * Expire
//!
//! ## State Diagram
//!
//! ```text
//! Return NoRestart
//! +---------------------------------------------------------------------+
//! | |
//! | |
//! | |
//! | Return Restart |
//! | +------------------------+ |
//! | | | |
//! | | | |
//! v v | |
//! +-----------------+ Start +------------------+ +--------+-----+--+
//! | +---------------->| | | |
//! Init | | | | Expire | |
//! --------->| Stopped | | Started +---------->| Running |
//! | | Cancel | | | |
//! | |<----------------+ | | |
//! +-----------------+ +---------------+--+ +-----------------+
//! ^ |
//! | |
//! +---------+
//! Restart
//! ```
//!
//!
//! A timer is initialized in the **stopped** state. A stopped timer can be
//! **started** by the `start` operation, with an **expiry** time. After the
//! `start` operation, the timer is in the **started** state. When the timer
//! **expires**, the timer enters the **running** state and the handler is
//! executed. After the handler has returned, the timer may enter the
//! **started* or **stopped** state, depending on the return value of the
//! handler. A timer in the **started** or **running** state may be **canceled**
//! by the `cancel` operation. A timer that is cancelled enters the **stopped**
//! state.
//!
//! A `cancel` or `restart` operation on a timer in the **running** state takes
//! effect after the handler has returned and the timer has transitioned
//! out of the **running** state.
//!
//! A `restart` operation on a timer in the **stopped** state is equivalent to a
//! `start` operation.
use super::{ClockSource, Delta, Instant};
use crate::{prelude::*, types::Opaque};
use core::{marker::PhantomData, ptr::NonNull};
use pin_init::PinInit;
/// A type-alias to refer to the [`Instant<C>`] for a given `T` from [`HrTimer<T>`].
///
/// Where `C` is the [`ClockSource`] of the [`HrTimer`].
pub type HrTimerInstant<T> = Instant<<<T as HasHrTimer<T>>::TimerMode as HrTimerMode>::Clock>;
/// A timer backed by a C `struct hrtimer`.
///
/// # Invariants
///
/// * `self.timer` is initialized by `bindings::hrtimer_setup`.
#[pin_data]
#[repr(C)]
pub struct HrTimer<T> {
#[pin]
timer: Opaque<bindings::hrtimer>,
_t: PhantomData<T>,
}
// SAFETY: Ownership of an `HrTimer` can be moved to other threads and
// used/dropped from there.
unsafe impl<T> Send for HrTimer<T> {}
// SAFETY: Timer operations are locked on the C side, so it is safe to operate
// on a timer from multiple threads.
unsafe impl<T> Sync for HrTimer<T> {}
impl<T> HrTimer<T> {
/// Return an initializer for a new timer instance.
pub fn new() -> impl PinInit<Self>
where
T: HrTimerCallback,
T: HasHrTimer<T>,
{
pin_init!(Self {
// INVARIANT: We initialize `timer` with `hrtimer_setup` below.
timer <- Opaque::ffi_init(move |place: *mut bindings::hrtimer| {
// SAFETY: By design of `pin_init!`, `place` is a pointer to a
// live allocation. hrtimer_setup will initialize `place` and
// does not require `place` to be initialized prior to the call.
unsafe {
bindings::hrtimer_setup(
place,
Some(T::Pointer::run),
<<T as HasHrTimer<T>>::TimerMode as HrTimerMode>::Clock::ID,
<T as HasHrTimer<T>>::TimerMode::C_MODE,
);
}
}),
_t: PhantomData,
})
}
/// Get a pointer to the contained `bindings::hrtimer`.
///
/// This function is useful to get access to the value without creating
/// intermediate references.
///
/// # Safety
///
/// `this` must point to a live allocation of at least the size of `Self`.
unsafe fn raw_get(this: *const Self) -> *mut bindings::hrtimer {
// SAFETY: The field projection to `timer` does not go out of bounds,
// because the caller of this function promises that `this` points to an
// allocation of at least the size of `Self`.
unsafe { Opaque::cast_into(core::ptr::addr_of!((*this).timer)) }
}
/// Cancel an initialized and potentially running timer.
///
/// If the timer handler is running, this function will block until the
/// handler returns.
///
/// Note that the timer might be started by a concurrent start operation. If
/// so, the timer might not be in the **stopped** state when this function
/// returns.
///
/// Users of the `HrTimer` API would not usually call this method directly.
/// Instead they would use the safe [`HrTimerHandle::cancel`] on the handle
/// returned when the timer was started.
///
/// This function is useful to get access to the value without creating
/// intermediate references.
///
/// # Safety
///
/// `this` must point to a valid `Self`.
pub(crate) unsafe fn raw_cancel(this: *const Self) -> bool {
// SAFETY: `this` points to an allocation of at least `HrTimer` size.
let c_timer_ptr = unsafe { HrTimer::raw_get(this) };
// If the handler is running, this will wait for the handler to return
// before returning.
// SAFETY: `c_timer_ptr` is initialized and valid. Synchronization is
// handled on the C side.
unsafe { bindings::hrtimer_cancel(c_timer_ptr) != 0 }
}
/// Forward the timer expiry for a given timer pointer.
///
/// # Safety
///
/// - `self_ptr` must point to a valid `Self`.
/// - The caller must either have exclusive access to the data pointed at by `self_ptr`, or be
/// within the context of the timer callback.
#[inline]
unsafe fn raw_forward(self_ptr: *mut Self, now: HrTimerInstant<T>, interval: Delta) -> u64
where
T: HasHrTimer<T>,
{
// SAFETY:
// * The C API requirements for this function are fulfilled by our safety contract.
// * `self_ptr` is guaranteed to point to a valid `Self` via our safety contract
unsafe {
bindings::hrtimer_forward(Self::raw_get(self_ptr), now.as_nanos(), interval.as_nanos())
}
}
/// Conditionally forward the timer.
///
/// If the timer expires after `now`, this function does nothing and returns 0. If the timer
/// expired at or before `now`, this function forwards the timer by `interval` until the timer
/// expires after `now` and then returns the number of times the timer was forwarded by
/// `interval`.
///
/// This function is mainly useful for timer types which can provide exclusive access to the
/// timer when the timer is not running. For forwarding the timer from within the timer callback
/// context, see [`HrTimerCallbackContext::forward()`].
///
/// Returns the number of overruns that occurred as a result of the timer expiry change.
pub fn forward(self: Pin<&mut Self>, now: HrTimerInstant<T>, interval: Delta) -> u64
where
T: HasHrTimer<T>,
{
// SAFETY: `raw_forward` does not move `Self`
let this = unsafe { self.get_unchecked_mut() };
// SAFETY: By existence of `Pin<&mut Self>`, the pointer passed to `raw_forward` points to a
// valid `Self` that we have exclusive access to.
unsafe { Self::raw_forward(this, now, interval) }
}
/// Conditionally forward the timer.
///
/// This is a variant of [`forward()`](Self::forward) that uses an interval after the current
/// time of the base clock for the [`HrTimer`].
pub fn forward_now(self: Pin<&mut Self>, interval: Delta) -> u64
where
T: HasHrTimer<T>,
{
self.forward(HrTimerInstant::<T>::now(), interval)
}
/// Return the time expiry for this [`HrTimer`].
///
/// This value should only be used as a snapshot, as the actual expiry time could change after
/// this function is called.
pub fn expires(&self) -> HrTimerInstant<T>
where
T: HasHrTimer<T>,
{
// SAFETY: `self` is an immutable reference and thus always points to a valid `HrTimer`.
let c_timer_ptr = unsafe { HrTimer::raw_get(self) };
// SAFETY:
// - Timers cannot have negative ktime_t values as their expiration time.
// - There's no actual locking here, a racy read is fine and expected
unsafe {
Instant::from_ktime(
// This `read_volatile` is intended to correspond to a READ_ONCE call.
// FIXME(read_once): Replace with `read_once` when available on the Rust side.
core::ptr::read_volatile(&raw const ((*c_timer_ptr).node.expires)),
)
}
}
}
/// Implemented by pointer types that point to structs that contain a [`HrTimer`].
///
/// `Self` must be [`Sync`] because it is passed to timer callbacks in another
/// thread of execution (hard or soft interrupt context).
///
/// Starting a timer returns a [`HrTimerHandle`] that can be used to manipulate
/// the timer. Note that it is OK to call the start function repeatedly, and
/// that more than one [`HrTimerHandle`] associated with a [`HrTimerPointer`] may
/// exist. A timer can be manipulated through any of the handles, and a handle
/// may represent a cancelled timer.
pub trait HrTimerPointer: Sync + Sized {
/// The operational mode associated with this timer.
///
/// This defines how the expiration value is interpreted.
type TimerMode: HrTimerMode;
/// A handle representing a started or restarted timer.
///
/// If the timer is running or if the timer callback is executing when the
/// handle is dropped, the drop method of [`HrTimerHandle`] should not return
/// until the timer is stopped and the callback has completed.
///
/// Note: When implementing this trait, consider that it is not unsafe to
/// leak the handle.
type TimerHandle: HrTimerHandle;
/// Start the timer with expiry after `expires` time units. If the timer was
/// already running, it is restarted with the new expiry time.
fn start(self, expires: <Self::TimerMode as HrTimerMode>::Expires) -> Self::TimerHandle;
}
/// Unsafe version of [`HrTimerPointer`] for situations where leaking the
/// [`HrTimerHandle`] returned by `start` would be unsound. This is the case for
/// stack allocated timers.
///
/// Typical implementers are pinned references such as [`Pin<&T>`].
///
/// # Safety
///
/// Implementers of this trait must ensure that instances of types implementing
/// [`UnsafeHrTimerPointer`] outlives any associated [`HrTimerPointer::TimerHandle`]
/// instances.
pub unsafe trait UnsafeHrTimerPointer: Sync + Sized {
/// The operational mode associated with this timer.
///
/// This defines how the expiration value is interpreted.
type TimerMode: HrTimerMode;
/// A handle representing a running timer.
///
/// # Safety
///
/// If the timer is running, or if the timer callback is executing when the
/// handle is dropped, the drop method of [`Self::TimerHandle`] must not return
/// until the timer is stopped and the callback has completed.
type TimerHandle: HrTimerHandle;
/// Start the timer after `expires` time units. If the timer was already
/// running, it is restarted at the new expiry time.
///
/// # Safety
///
/// Caller promises keep the timer structure alive until the timer is dead.
/// Caller can ensure this by not leaking the returned [`Self::TimerHandle`].
unsafe fn start(self, expires: <Self::TimerMode as HrTimerMode>::Expires) -> Self::TimerHandle;
}
/// A trait for stack allocated timers.
///
/// # Safety
///
/// Implementers must ensure that `start_scoped` does not return until the
/// timer is dead and the timer handler is not running.
pub unsafe trait ScopedHrTimerPointer {
/// The operational mode associated with this timer.
///
/// This defines how the expiration value is interpreted.
type TimerMode: HrTimerMode;
/// Start the timer to run after `expires` time units and immediately
/// after call `f`. When `f` returns, the timer is cancelled.
fn start_scoped<T, F>(self, expires: <Self::TimerMode as HrTimerMode>::Expires, f: F) -> T
where
F: FnOnce() -> T;
}
// SAFETY: By the safety requirement of [`UnsafeHrTimerPointer`], dropping the
// handle returned by [`UnsafeHrTimerPointer::start`] ensures that the timer is
// killed.
unsafe impl<T> ScopedHrTimerPointer for T
where
T: UnsafeHrTimerPointer,
{
type TimerMode = T::TimerMode;
fn start_scoped<U, F>(
self,
expires: <<T as UnsafeHrTimerPointer>::TimerMode as HrTimerMode>::Expires,
f: F,
) -> U
where
F: FnOnce() -> U,
{
// SAFETY: We drop the timer handle below before returning.
let handle = unsafe { UnsafeHrTimerPointer::start(self, expires) };
let t = f();
drop(handle);
t
}
}
/// Implemented by [`HrTimerPointer`] implementers to give the C timer callback a
/// function to call.
// This is split from `HrTimerPointer` to make it easier to specify trait bounds.
pub trait RawHrTimerCallback {
/// Type of the parameter passed to [`HrTimerCallback::run`]. It may be
/// [`Self`], or a pointer type derived from [`Self`].
type CallbackTarget<'a>;
/// Callback to be called from C when timer fires.
///
/// # Safety
///
/// Only to be called by C code in the `hrtimer` subsystem. `this` must point
/// to the `bindings::hrtimer` structure that was used to start the timer.
unsafe extern "C" fn run(this: *mut bindings::hrtimer) -> bindings::hrtimer_restart;
}
/// Implemented by structs that can be the target of a timer callback.
pub trait HrTimerCallback {
/// The type whose [`RawHrTimerCallback::run`] method will be invoked when
/// the timer expires.
type Pointer<'a>: RawHrTimerCallback;
/// Called by the timer logic when the timer fires.
fn run(
this: <Self::Pointer<'_> as RawHrTimerCallback>::CallbackTarget<'_>,
ctx: HrTimerCallbackContext<'_, Self>,
) -> HrTimerRestart
where
Self: Sized,
Self: HasHrTimer<Self>;
}
/// A handle representing a potentially running timer.
///
/// More than one handle representing the same timer might exist.
///
/// # Safety
///
/// When dropped, the timer represented by this handle must be cancelled, if it
/// is running. If the timer handler is running when the handle is dropped, the
/// drop method must wait for the handler to return before returning.
///
/// Note: One way to satisfy the safety requirement is to call `Self::cancel` in
/// the drop implementation for `Self.`
pub unsafe trait HrTimerHandle {
/// Cancel the timer. If the timer is in the running state, block till the
/// handler has returned.
///
/// Note that the timer might be started by a concurrent start operation. If
/// so, the timer might not be in the **stopped** state when this function
/// returns.
///
/// Returns `true` if the timer was running.
fn cancel(&mut self) -> bool;
}
/// Implemented by structs that contain timer nodes.
///
/// Clients of the timer API would usually safely implement this trait by using
/// the [`crate::impl_has_hr_timer`] macro.
///
/// # Safety
///
/// Implementers of this trait must ensure that the implementer has a
/// [`HrTimer`] field and that all trait methods are implemented according to
/// their documentation. All the methods of this trait must operate on the same
/// field.
pub unsafe trait HasHrTimer<T> {
/// The operational mode associated with this timer.
///
/// This defines how the expiration value is interpreted.
type TimerMode: HrTimerMode;
/// Return a pointer to the [`HrTimer`] within `Self`.
///
/// This function is useful to get access to the value without creating
/// intermediate references.
///
/// # Safety
///
/// `this` must be a valid pointer.
unsafe fn raw_get_timer(this: *const Self) -> *const HrTimer<T>;
/// Return a pointer to the struct that is containing the [`HrTimer`] pointed
/// to by `ptr`.
///
/// This function is useful to get access to the value without creating
/// intermediate references.
///
/// # Safety
///
/// `ptr` must point to a [`HrTimer<T>`] field in a struct of type `Self`.
unsafe fn timer_container_of(ptr: *mut HrTimer<T>) -> *mut Self
where
Self: Sized;
/// Get pointer to the contained `bindings::hrtimer` struct.
///
/// This function is useful to get access to the value without creating
/// intermediate references.
///
/// # Safety
///
/// `this` must be a valid pointer.
unsafe fn c_timer_ptr(this: *const Self) -> *const bindings::hrtimer {
// SAFETY: `this` is a valid pointer to a `Self`.
let timer_ptr = unsafe { Self::raw_get_timer(this) };
// SAFETY: timer_ptr points to an allocation of at least `HrTimer` size.
unsafe { HrTimer::raw_get(timer_ptr) }
}
/// Start the timer contained in the `Self` pointed to by `self_ptr`. If
/// it is already running it is removed and inserted.
///
/// # Safety
///
/// - `this` must point to a valid `Self`.
/// - Caller must ensure that the pointee of `this` lives until the timer
/// fires or is canceled.
unsafe fn start(this: *const Self, expires: <Self::TimerMode as HrTimerMode>::Expires) {
// SAFETY: By function safety requirement, `this` is a valid `Self`.
unsafe {
bindings::hrtimer_start_range_ns(
Self::c_timer_ptr(this).cast_mut(),
expires.as_nanos(),
0,
<Self::TimerMode as HrTimerMode>::C_MODE,
);
}
}
}
/// Restart policy for timers.
#[derive(Copy, Clone, PartialEq, Eq, Debug)]
#[repr(u32)]
pub enum HrTimerRestart {
/// Timer should not be restarted.
NoRestart = bindings::hrtimer_restart_HRTIMER_NORESTART,
/// Timer should be restarted.
Restart = bindings::hrtimer_restart_HRTIMER_RESTART,
}
impl HrTimerRestart {
fn into_c(self) -> bindings::hrtimer_restart {
self as bindings::hrtimer_restart
}
}
/// Time representations that can be used as expiration values in [`HrTimer`].
pub trait HrTimerExpires {
/// Converts the expiration time into a nanosecond representation.
///
/// This value corresponds to a raw ktime_t value, suitable for passing to kernel
/// timer functions. The interpretation (absolute vs relative) depends on the
/// associated [HrTimerMode] in use.
fn as_nanos(&self) -> i64;
}
impl<C: ClockSource> HrTimerExpires for Instant<C> {
#[inline]
fn as_nanos(&self) -> i64 {
Instant::<C>::as_nanos(self)
}
}
impl HrTimerExpires for Delta {
#[inline]
fn as_nanos(&self) -> i64 {
Delta::as_nanos(*self)
}
}
mod private {
use crate::time::ClockSource;
pub trait Sealed {}
impl<C: ClockSource> Sealed for super::AbsoluteMode<C> {}
impl<C: ClockSource> Sealed for super::RelativeMode<C> {}
impl<C: ClockSource> Sealed for super::AbsolutePinnedMode<C> {}
impl<C: ClockSource> Sealed for super::RelativePinnedMode<C> {}
impl<C: ClockSource> Sealed for super::AbsoluteSoftMode<C> {}
impl<C: ClockSource> Sealed for super::RelativeSoftMode<C> {}
impl<C: ClockSource> Sealed for super::AbsolutePinnedSoftMode<C> {}
impl<C: ClockSource> Sealed for super::RelativePinnedSoftMode<C> {}
impl<C: ClockSource> Sealed for super::AbsoluteHardMode<C> {}
impl<C: ClockSource> Sealed for super::RelativeHardMode<C> {}
impl<C: ClockSource> Sealed for super::AbsolutePinnedHardMode<C> {}
impl<C: ClockSource> Sealed for super::RelativePinnedHardMode<C> {}
}
/// Operational mode of [`HrTimer`].
pub trait HrTimerMode: private::Sealed {
/// The C representation of hrtimer mode.
const C_MODE: bindings::hrtimer_mode;
/// Type representing the clock source.
type Clock: ClockSource;
/// Type representing the expiration specification (absolute or relative time).
type Expires: HrTimerExpires;
}
/// Timer that expires at a fixed point in time.
pub struct AbsoluteMode<C: ClockSource>(PhantomData<C>);
impl<C: ClockSource> HrTimerMode for AbsoluteMode<C> {
const C_MODE: bindings::hrtimer_mode = bindings::hrtimer_mode_HRTIMER_MODE_ABS;
type Clock = C;
type Expires = Instant<C>;
}
/// Timer that expires after a delay from now.
pub struct RelativeMode<C: ClockSource>(PhantomData<C>);
impl<C: ClockSource> HrTimerMode for RelativeMode<C> {
const C_MODE: bindings::hrtimer_mode = bindings::hrtimer_mode_HRTIMER_MODE_REL;
type Clock = C;
type Expires = Delta;
}
/// Timer with absolute expiration time, pinned to its current CPU.
pub struct AbsolutePinnedMode<C: ClockSource>(PhantomData<C>);
impl<C: ClockSource> HrTimerMode for AbsolutePinnedMode<C> {
const C_MODE: bindings::hrtimer_mode = bindings::hrtimer_mode_HRTIMER_MODE_ABS_PINNED;
type Clock = C;
type Expires = Instant<C>;
}
/// Timer with relative expiration time, pinned to its current CPU.
pub struct RelativePinnedMode<C: ClockSource>(PhantomData<C>);
impl<C: ClockSource> HrTimerMode for RelativePinnedMode<C> {
const C_MODE: bindings::hrtimer_mode = bindings::hrtimer_mode_HRTIMER_MODE_REL_PINNED;
type Clock = C;
type Expires = Delta;
}
/// Timer with absolute expiration, handled in soft irq context.
pub struct AbsoluteSoftMode<C: ClockSource>(PhantomData<C>);
impl<C: ClockSource> HrTimerMode for AbsoluteSoftMode<C> {
const C_MODE: bindings::hrtimer_mode = bindings::hrtimer_mode_HRTIMER_MODE_ABS_SOFT;
type Clock = C;
type Expires = Instant<C>;
}
/// Timer with relative expiration, handled in soft irq context.
pub struct RelativeSoftMode<C: ClockSource>(PhantomData<C>);
impl<C: ClockSource> HrTimerMode for RelativeSoftMode<C> {
const C_MODE: bindings::hrtimer_mode = bindings::hrtimer_mode_HRTIMER_MODE_REL_SOFT;
type Clock = C;
type Expires = Delta;
}
/// Timer with absolute expiration, pinned to CPU and handled in soft irq context.
pub struct AbsolutePinnedSoftMode<C: ClockSource>(PhantomData<C>);
impl<C: ClockSource> HrTimerMode for AbsolutePinnedSoftMode<C> {
const C_MODE: bindings::hrtimer_mode = bindings::hrtimer_mode_HRTIMER_MODE_ABS_PINNED_SOFT;
type Clock = C;
type Expires = Instant<C>;
}
/// Timer with absolute expiration, pinned to CPU and handled in soft irq context.
pub struct RelativePinnedSoftMode<C: ClockSource>(PhantomData<C>);
impl<C: ClockSource> HrTimerMode for RelativePinnedSoftMode<C> {
const C_MODE: bindings::hrtimer_mode = bindings::hrtimer_mode_HRTIMER_MODE_REL_PINNED_SOFT;
type Clock = C;
type Expires = Delta;
}
/// Timer with absolute expiration, handled in hard irq context.
pub struct AbsoluteHardMode<C: ClockSource>(PhantomData<C>);
impl<C: ClockSource> HrTimerMode for AbsoluteHardMode<C> {
const C_MODE: bindings::hrtimer_mode = bindings::hrtimer_mode_HRTIMER_MODE_ABS_HARD;
type Clock = C;
type Expires = Instant<C>;
}
/// Timer with relative expiration, handled in hard irq context.
pub struct RelativeHardMode<C: ClockSource>(PhantomData<C>);
impl<C: ClockSource> HrTimerMode for RelativeHardMode<C> {
const C_MODE: bindings::hrtimer_mode = bindings::hrtimer_mode_HRTIMER_MODE_REL_HARD;
type Clock = C;
type Expires = Delta;
}
/// Timer with absolute expiration, pinned to CPU and handled in hard irq context.
pub struct AbsolutePinnedHardMode<C: ClockSource>(PhantomData<C>);
impl<C: ClockSource> HrTimerMode for AbsolutePinnedHardMode<C> {
const C_MODE: bindings::hrtimer_mode = bindings::hrtimer_mode_HRTIMER_MODE_ABS_PINNED_HARD;
type Clock = C;
type Expires = Instant<C>;
}
/// Timer with relative expiration, pinned to CPU and handled in hard irq context.
pub struct RelativePinnedHardMode<C: ClockSource>(PhantomData<C>);
impl<C: ClockSource> HrTimerMode for RelativePinnedHardMode<C> {
const C_MODE: bindings::hrtimer_mode = bindings::hrtimer_mode_HRTIMER_MODE_REL_PINNED_HARD;
type Clock = C;
type Expires = Delta;
}
/// Privileged smart-pointer for a [`HrTimer`] callback context.
///
/// Many [`HrTimer`] methods can only be called in two situations:
///
/// * When the caller has exclusive access to the `HrTimer` and the `HrTimer` is guaranteed not to
/// be running.
/// * From within the context of an `HrTimer`'s callback method.
///
/// This type provides access to said methods from within a timer callback context.
///
/// # Invariants
///
/// * The existence of this type means the caller is currently within the callback for an
/// [`HrTimer`].
/// * `self.0` always points to a live instance of [`HrTimer<T>`].
pub struct HrTimerCallbackContext<'a, T: HasHrTimer<T>>(NonNull<HrTimer<T>>, PhantomData<&'a ()>);
impl<'a, T: HasHrTimer<T>> HrTimerCallbackContext<'a, T> {
/// Create a new [`HrTimerCallbackContext`].
///
/// # Safety
///
/// This function relies on the caller being within the context of a timer callback, so it must
/// not be used anywhere except for within implementations of [`RawHrTimerCallback::run`]. The
/// caller promises that `timer` points to a valid initialized instance of
/// [`bindings::hrtimer`].
///
/// The returned `Self` must not outlive the function context of [`RawHrTimerCallback::run`]
/// where this function is called.
pub(crate) unsafe fn from_raw(timer: *mut HrTimer<T>) -> Self {
// SAFETY: The caller guarantees `timer` is a valid pointer to an initialized
// `bindings::hrtimer`
// INVARIANT: Our safety contract ensures that we're within the context of a timer callback
// and that `timer` points to a live instance of `HrTimer<T>`.
Self(unsafe { NonNull::new_unchecked(timer) }, PhantomData)
}
/// Conditionally forward the timer.
///
/// This function is identical to [`HrTimer::forward()`] except that it may only be used from
/// within the context of a [`HrTimer`] callback.
pub fn forward(&mut self, now: HrTimerInstant<T>, interval: Delta) -> u64 {
// SAFETY:
// - We are guaranteed to be within the context of a timer callback by our type invariants
// - By our type invariants, `self.0` always points to a valid `HrTimer<T>`
unsafe { HrTimer::<T>::raw_forward(self.0.as_ptr(), now, interval) }
}
/// Conditionally forward the timer.
///
/// This is a variant of [`HrTimerCallbackContext::forward()`] that uses an interval after the
/// current time of the base clock for the [`HrTimer`].
pub fn forward_now(&mut self, duration: Delta) -> u64 {
self.forward(HrTimerInstant::<T>::now(), duration)
}
}
/// Use to implement the [`HasHrTimer<T>`] trait.
///
/// See [`module`] documentation for an example.
///
/// [`module`]: crate::time::hrtimer
#[macro_export]
macro_rules! impl_has_hr_timer {
(
impl$({$($generics:tt)*})?
HasHrTimer<$timer_type:ty>
for $self:ty
{
mode : $mode:ty,
field : self.$field:ident $(,)?
}
$($rest:tt)*
) => {
// SAFETY: This implementation of `raw_get_timer` only compiles if the
// field has the right type.
unsafe impl$(<$($generics)*>)? $crate::time::hrtimer::HasHrTimer<$timer_type> for $self {
type TimerMode = $mode;
#[inline]
unsafe fn raw_get_timer(
this: *const Self,
) -> *const $crate::time::hrtimer::HrTimer<$timer_type> {
// SAFETY: The caller promises that the pointer is not dangling.
unsafe { ::core::ptr::addr_of!((*this).$field) }
}
#[inline]
unsafe fn timer_container_of(
ptr: *mut $crate::time::hrtimer::HrTimer<$timer_type>,
) -> *mut Self {
// SAFETY: As per the safety requirement of this function, `ptr`
// is pointing inside a `$timer_type`.
unsafe { ::kernel::container_of!(ptr, $timer_type, $field) }
}
}
}
}
mod arc;
pub use arc::ArcHrTimerHandle;
mod pin;
pub use pin::PinHrTimerHandle;
mod pin_mut;
pub use pin_mut::PinMutHrTimerHandle;
// `box` is a reserved keyword, so prefix with `t` for timer
mod tbox;
pub use tbox::BoxHrTimerHandle;
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