| Author | Tokens | Token Proportion | Commits | Commit Proportion |
|---|---|---|---|---|
| Daniel Almeida | 1589 | 88.03% | 3 | 60.00% |
| Alice Ryhl | 215 | 11.91% | 1 | 20.00% |
| Wedson Almeida Filho | 1 | 0.06% | 1 | 20.00% |
| Total | 1805 | 5 |
// SPDX-License-Identifier: GPL-2.0
// SPDX-FileCopyrightText: Copyright 2025 Collabora ltd.
//! This module provides types like [`Registration`] and
//! [`ThreadedRegistration`], which allow users to register handlers for a given
//! IRQ line.
use core::marker::PhantomPinned;
use crate::alloc::Allocator;
use crate::device::{Bound, Device};
use crate::devres::Devres;
use crate::error::to_result;
use crate::irq::flags::Flags;
use crate::prelude::*;
use crate::str::CStr;
use crate::sync::Arc;
/// The value that can be returned from a [`Handler`] or a [`ThreadedHandler`].
#[repr(u32)]
pub enum IrqReturn {
/// The interrupt was not from this device or was not handled.
None = bindings::irqreturn_IRQ_NONE,
/// The interrupt was handled by this device.
Handled = bindings::irqreturn_IRQ_HANDLED,
}
/// Callbacks for an IRQ handler.
pub trait Handler: Sync {
/// The hard IRQ handler.
///
/// This is executed in interrupt context, hence all corresponding
/// limitations do apply.
///
/// All work that does not necessarily need to be executed from
/// interrupt context, should be deferred to a threaded handler.
/// See also [`ThreadedRegistration`].
fn handle(&self, device: &Device<Bound>) -> IrqReturn;
}
impl<T: ?Sized + Handler + Send> Handler for Arc<T> {
fn handle(&self, device: &Device<Bound>) -> IrqReturn {
T::handle(self, device)
}
}
impl<T: ?Sized + Handler, A: Allocator> Handler for Box<T, A> {
fn handle(&self, device: &Device<Bound>) -> IrqReturn {
T::handle(self, device)
}
}
/// # Invariants
///
/// - `self.irq` is the same as the one passed to `request_{threaded}_irq`.
/// - `cookie` was passed to `request_{threaded}_irq` as the cookie. It is guaranteed to be unique
/// by the type system, since each call to `new` will return a different instance of
/// `Registration`.
#[pin_data(PinnedDrop)]
struct RegistrationInner {
irq: u32,
cookie: *mut c_void,
}
impl RegistrationInner {
fn synchronize(&self) {
// SAFETY: safe as per the invariants of `RegistrationInner`
unsafe { bindings::synchronize_irq(self.irq) };
}
}
#[pinned_drop]
impl PinnedDrop for RegistrationInner {
fn drop(self: Pin<&mut Self>) {
// SAFETY:
//
// Safe as per the invariants of `RegistrationInner` and:
//
// - The containing struct is `!Unpin` and was initialized using
// pin-init, so it occupied the same memory location for the entirety of
// its lifetime.
//
// Notice that this will block until all handlers finish executing,
// i.e.: at no point will &self be invalid while the handler is running.
unsafe { bindings::free_irq(self.irq, self.cookie) };
}
}
// SAFETY: We only use `inner` on drop, which called at most once with no
// concurrent access.
unsafe impl Sync for RegistrationInner {}
// SAFETY: It is safe to send `RegistrationInner` across threads.
unsafe impl Send for RegistrationInner {}
/// A request for an IRQ line for a given device.
///
/// # Invariants
///
/// - `ìrq` is the number of an interrupt source of `dev`.
/// - `irq` has not been registered yet.
pub struct IrqRequest<'a> {
dev: &'a Device<Bound>,
irq: u32,
}
impl<'a> IrqRequest<'a> {
/// Creates a new IRQ request for the given device and IRQ number.
///
/// # Safety
///
/// - `irq` should be a valid IRQ number for `dev`.
pub(crate) unsafe fn new(dev: &'a Device<Bound>, irq: u32) -> Self {
// INVARIANT: `irq` is a valid IRQ number for `dev`.
IrqRequest { dev, irq }
}
/// Returns the IRQ number of an [`IrqRequest`].
pub fn irq(&self) -> u32 {
self.irq
}
}
/// A registration of an IRQ handler for a given IRQ line.
///
/// # Examples
///
/// The following is an example of using `Registration`. It uses a
/// [`Completion`] to coordinate between the IRQ
/// handler and process context. [`Completion`] uses interior mutability, so the
/// handler can signal with [`Completion::complete_all()`] and the process
/// context can wait with [`Completion::wait_for_completion()`] even though
/// there is no way to get a mutable reference to the any of the fields in
/// `Data`.
///
/// [`Completion`]: kernel::sync::Completion
/// [`Completion::complete_all()`]: kernel::sync::Completion::complete_all
/// [`Completion::wait_for_completion()`]: kernel::sync::Completion::wait_for_completion
///
/// ```
/// use kernel::c_str;
/// use kernel::device::{Bound, Device};
/// use kernel::irq::{self, Flags, IrqRequest, IrqReturn, Registration};
/// use kernel::prelude::*;
/// use kernel::sync::{Arc, Completion};
///
/// // Data shared between process and IRQ context.
/// #[pin_data]
/// struct Data {
/// #[pin]
/// completion: Completion,
/// }
///
/// impl irq::Handler for Data {
/// // Executed in IRQ context.
/// fn handle(&self, _dev: &Device<Bound>) -> IrqReturn {
/// self.completion.complete_all();
/// IrqReturn::Handled
/// }
/// }
///
/// // Registers an IRQ handler for the given IrqRequest.
/// //
/// // This runs in process context and assumes `request` was previously acquired from a device.
/// fn register_irq(
/// handler: impl PinInit<Data, Error>,
/// request: IrqRequest<'_>,
/// ) -> Result<Arc<Registration<Data>>> {
/// let registration = Registration::new(request, Flags::SHARED, c_str!("my_device"), handler);
///
/// let registration = Arc::pin_init(registration, GFP_KERNEL)?;
///
/// registration.handler().completion.wait_for_completion();
///
/// Ok(registration)
/// }
/// # Ok::<(), Error>(())
/// ```
///
/// # Invariants
///
/// * We own an irq handler whose cookie is a pointer to `Self`.
#[pin_data]
pub struct Registration<T: Handler + 'static> {
#[pin]
inner: Devres<RegistrationInner>,
#[pin]
handler: T,
/// Pinned because we need address stability so that we can pass a pointer
/// to the callback.
#[pin]
_pin: PhantomPinned,
}
impl<T: Handler + 'static> Registration<T> {
/// Registers the IRQ handler with the system for the given IRQ number.
pub fn new<'a>(
request: IrqRequest<'a>,
flags: Flags,
name: &'static CStr,
handler: impl PinInit<T, Error> + 'a,
) -> impl PinInit<Self, Error> + 'a {
try_pin_init!(&this in Self {
handler <- handler,
inner <- Devres::new(
request.dev,
try_pin_init!(RegistrationInner {
// INVARIANT: `this` is a valid pointer to the `Registration` instance
cookie: this.as_ptr().cast::<c_void>(),
irq: {
// SAFETY:
// - The callbacks are valid for use with request_irq.
// - If this succeeds, the slot is guaranteed to be valid until the
// destructor of Self runs, which will deregister the callbacks
// before the memory location becomes invalid.
// - When request_irq is called, everything that handle_irq_callback will
// touch has already been initialized, so it's safe for the callback to
// be called immediately.
to_result(unsafe {
bindings::request_irq(
request.irq,
Some(handle_irq_callback::<T>),
flags.into_inner(),
name.as_char_ptr(),
this.as_ptr().cast::<c_void>(),
)
})?;
request.irq
}
})
),
_pin: PhantomPinned,
})
}
/// Returns a reference to the handler that was registered with the system.
pub fn handler(&self) -> &T {
&self.handler
}
/// Wait for pending IRQ handlers on other CPUs.
///
/// This will attempt to access the inner [`Devres`] container.
pub fn try_synchronize(&self) -> Result {
let inner = self.inner.try_access().ok_or(ENODEV)?;
inner.synchronize();
Ok(())
}
/// Wait for pending IRQ handlers on other CPUs.
pub fn synchronize(&self, dev: &Device<Bound>) -> Result {
let inner = self.inner.access(dev)?;
inner.synchronize();
Ok(())
}
}
/// # Safety
///
/// This function should be only used as the callback in `request_irq`.
unsafe extern "C" fn handle_irq_callback<T: Handler>(_irq: i32, ptr: *mut c_void) -> c_uint {
// SAFETY: `ptr` is a pointer to `Registration<T>` set in `Registration::new`
let registration = unsafe { &*(ptr as *const Registration<T>) };
// SAFETY: The irq callback is removed before the device is unbound, so the fact that the irq
// callback is running implies that the device has not yet been unbound.
let device = unsafe { registration.inner.device().as_bound() };
T::handle(®istration.handler, device) as c_uint
}
/// The value that can be returned from [`ThreadedHandler::handle`].
#[repr(u32)]
pub enum ThreadedIrqReturn {
/// The interrupt was not from this device or was not handled.
None = bindings::irqreturn_IRQ_NONE,
/// The interrupt was handled by this device.
Handled = bindings::irqreturn_IRQ_HANDLED,
/// The handler wants the handler thread to wake up.
WakeThread = bindings::irqreturn_IRQ_WAKE_THREAD,
}
/// Callbacks for a threaded IRQ handler.
pub trait ThreadedHandler: Sync {
/// The hard IRQ handler.
///
/// This is executed in interrupt context, hence all corresponding
/// limitations do apply. All work that does not necessarily need to be
/// executed from interrupt context, should be deferred to the threaded
/// handler, i.e. [`ThreadedHandler::handle_threaded`].
///
/// The default implementation returns [`ThreadedIrqReturn::WakeThread`].
#[expect(unused_variables)]
fn handle(&self, device: &Device<Bound>) -> ThreadedIrqReturn {
ThreadedIrqReturn::WakeThread
}
/// The threaded IRQ handler.
///
/// This is executed in process context. The kernel creates a dedicated
/// `kthread` for this purpose.
fn handle_threaded(&self, device: &Device<Bound>) -> IrqReturn;
}
impl<T: ?Sized + ThreadedHandler + Send> ThreadedHandler for Arc<T> {
fn handle(&self, device: &Device<Bound>) -> ThreadedIrqReturn {
T::handle(self, device)
}
fn handle_threaded(&self, device: &Device<Bound>) -> IrqReturn {
T::handle_threaded(self, device)
}
}
impl<T: ?Sized + ThreadedHandler, A: Allocator> ThreadedHandler for Box<T, A> {
fn handle(&self, device: &Device<Bound>) -> ThreadedIrqReturn {
T::handle(self, device)
}
fn handle_threaded(&self, device: &Device<Bound>) -> IrqReturn {
T::handle_threaded(self, device)
}
}
/// A registration of a threaded IRQ handler for a given IRQ line.
///
/// Two callbacks are required: one to handle the IRQ, and one to handle any
/// other work in a separate thread.
///
/// The thread handler is only called if the IRQ handler returns
/// [`ThreadedIrqReturn::WakeThread`].
///
/// # Examples
///
/// The following is an example of using [`ThreadedRegistration`]. It uses a
/// [`Mutex`](kernel::sync::Mutex) to provide interior mutability.
///
/// ```
/// use kernel::c_str;
/// use kernel::device::{Bound, Device};
/// use kernel::irq::{
/// self, Flags, IrqRequest, IrqReturn, ThreadedHandler, ThreadedIrqReturn,
/// ThreadedRegistration,
/// };
/// use kernel::prelude::*;
/// use kernel::sync::{Arc, Mutex};
///
/// // Declare a struct that will be passed in when the interrupt fires. The u32
/// // merely serves as an example of some internal data.
/// //
/// // [`irq::ThreadedHandler::handle`] takes `&self`. This example
/// // illustrates how interior mutability can be used when sharing the data
/// // between process context and IRQ context.
/// #[pin_data]
/// struct Data {
/// #[pin]
/// value: Mutex<u32>,
/// }
///
/// impl ThreadedHandler for Data {
/// // This will run (in a separate kthread) if and only if
/// // [`ThreadedHandler::handle`] returns [`WakeThread`], which it does by
/// // default.
/// fn handle_threaded(&self, _dev: &Device<Bound>) -> IrqReturn {
/// let mut data = self.value.lock();
/// *data += 1;
/// IrqReturn::Handled
/// }
/// }
///
/// // Registers a threaded IRQ handler for the given [`IrqRequest`].
/// //
/// // This is executing in process context and assumes that `request` was
/// // previously acquired from a device.
/// fn register_threaded_irq(
/// handler: impl PinInit<Data, Error>,
/// request: IrqRequest<'_>,
/// ) -> Result<Arc<ThreadedRegistration<Data>>> {
/// let registration =
/// ThreadedRegistration::new(request, Flags::SHARED, c_str!("my_device"), handler);
///
/// let registration = Arc::pin_init(registration, GFP_KERNEL)?;
///
/// {
/// // The data can be accessed from process context too.
/// let mut data = registration.handler().value.lock();
/// *data += 1;
/// }
///
/// Ok(registration)
/// }
/// # Ok::<(), Error>(())
/// ```
///
/// # Invariants
///
/// * We own an irq handler whose cookie is a pointer to `Self`.
#[pin_data]
pub struct ThreadedRegistration<T: ThreadedHandler + 'static> {
#[pin]
inner: Devres<RegistrationInner>,
#[pin]
handler: T,
/// Pinned because we need address stability so that we can pass a pointer
/// to the callback.
#[pin]
_pin: PhantomPinned,
}
impl<T: ThreadedHandler + 'static> ThreadedRegistration<T> {
/// Registers the IRQ handler with the system for the given IRQ number.
pub fn new<'a>(
request: IrqRequest<'a>,
flags: Flags,
name: &'static CStr,
handler: impl PinInit<T, Error> + 'a,
) -> impl PinInit<Self, Error> + 'a {
try_pin_init!(&this in Self {
handler <- handler,
inner <- Devres::new(
request.dev,
try_pin_init!(RegistrationInner {
// INVARIANT: `this` is a valid pointer to the `ThreadedRegistration` instance.
cookie: this.as_ptr().cast::<c_void>(),
irq: {
// SAFETY:
// - The callbacks are valid for use with request_threaded_irq.
// - If this succeeds, the slot is guaranteed to be valid until the
// destructor of Self runs, which will deregister the callbacks
// before the memory location becomes invalid.
// - When request_threaded_irq is called, everything that the two callbacks
// will touch has already been initialized, so it's safe for the
// callbacks to be called immediately.
to_result(unsafe {
bindings::request_threaded_irq(
request.irq,
Some(handle_threaded_irq_callback::<T>),
Some(thread_fn_callback::<T>),
flags.into_inner(),
name.as_char_ptr(),
this.as_ptr().cast::<c_void>(),
)
})?;
request.irq
}
})
),
_pin: PhantomPinned,
})
}
/// Returns a reference to the handler that was registered with the system.
pub fn handler(&self) -> &T {
&self.handler
}
/// Wait for pending IRQ handlers on other CPUs.
///
/// This will attempt to access the inner [`Devres`] container.
pub fn try_synchronize(&self) -> Result {
let inner = self.inner.try_access().ok_or(ENODEV)?;
inner.synchronize();
Ok(())
}
/// Wait for pending IRQ handlers on other CPUs.
pub fn synchronize(&self, dev: &Device<Bound>) -> Result {
let inner = self.inner.access(dev)?;
inner.synchronize();
Ok(())
}
}
/// # Safety
///
/// This function should be only used as the callback in `request_threaded_irq`.
unsafe extern "C" fn handle_threaded_irq_callback<T: ThreadedHandler>(
_irq: i32,
ptr: *mut c_void,
) -> c_uint {
// SAFETY: `ptr` is a pointer to `ThreadedRegistration<T>` set in `ThreadedRegistration::new`
let registration = unsafe { &*(ptr as *const ThreadedRegistration<T>) };
// SAFETY: The irq callback is removed before the device is unbound, so the fact that the irq
// callback is running implies that the device has not yet been unbound.
let device = unsafe { registration.inner.device().as_bound() };
T::handle(®istration.handler, device) as c_uint
}
/// # Safety
///
/// This function should be only used as the callback in `request_threaded_irq`.
unsafe extern "C" fn thread_fn_callback<T: ThreadedHandler>(_irq: i32, ptr: *mut c_void) -> c_uint {
// SAFETY: `ptr` is a pointer to `ThreadedRegistration<T>` set in `ThreadedRegistration::new`
let registration = unsafe { &*(ptr as *const ThreadedRegistration<T>) };
// SAFETY: The irq callback is removed before the device is unbound, so the fact that the irq
// callback is running implies that the device has not yet been unbound.
let device = unsafe { registration.inner.device().as_bound() };
T::handle_threaded(®istration.handler, device) as c_uint
}
Information contained on this website is for historical information purposes only and does not indicate or represent copyright ownership.
Created with Cregit http://github.com/cregit/cregit
Version 2.0-RC1