| Author | Tokens | Token Proportion | Commits | Commit Proportion |
|---|---|---|---|---|
| Danilo Krummrich | 1053 | 95.21% | 14 | 60.87% |
| Zhi Wang | 26 | 2.35% | 2 | 8.70% |
| Alice Ryhl | 13 | 1.18% | 1 | 4.35% |
| Shankari Anand | 5 | 0.45% | 1 | 4.35% |
| Benno Lossin | 4 | 0.36% | 1 | 4.35% |
| Viresh Kumar | 2 | 0.18% | 1 | 4.35% |
| Tamir Duberstein | 1 | 0.09% | 1 | 4.35% |
| Finn Behrens | 1 | 0.09% | 1 | 4.35% |
| Wedson Almeida Filho | 1 | 0.09% | 1 | 4.35% |
| Total | 1106 | 23 |
// SPDX-License-Identifier: GPL-2.0
//! Devres abstraction
//!
//! [`Devres`] represents an abstraction for the kernel devres (device resource management)
//! implementation.
use crate::{
alloc::Flags,
bindings,
device::{
Bound,
Device, //
},
error::to_result,
prelude::*,
revocable::{
Revocable,
RevocableGuard, //
},
sync::{
aref::ARef,
rcu,
Arc, //
},
types::ForeignOwnable,
};
/// This abstraction is meant to be used by subsystems to containerize [`Device`] bound resources to
/// manage their lifetime.
///
/// [`Device`] bound resources should be freed when either the resource goes out of scope or the
/// [`Device`] is unbound respectively, depending on what happens first. In any case, it is always
/// guaranteed that revoking the device resource is completed before the corresponding [`Device`]
/// is unbound.
///
/// To achieve that [`Devres`] registers a devres callback on creation, which is called once the
/// [`Device`] is unbound, revoking access to the encapsulated resource (see also [`Revocable`]).
///
/// After the [`Devres`] has been unbound it is not possible to access the encapsulated resource
/// anymore.
///
/// [`Devres`] users should make sure to simply free the corresponding backing resource in `T`'s
/// [`Drop`] implementation.
///
/// # Examples
///
/// ```no_run
/// use kernel::{
/// bindings,
/// device::{
/// Bound,
/// Device,
/// },
/// devres::Devres,
/// io::{
/// Io,
/// IoKnownSize,
/// Mmio,
/// MmioRaw,
/// PhysAddr, //
/// },
/// prelude::*,
/// };
/// use core::ops::Deref;
///
/// // See also [`pci::Bar`] for a real example.
/// struct IoMem<const SIZE: usize>(MmioRaw<SIZE>);
///
/// impl<const SIZE: usize> IoMem<SIZE> {
/// /// # Safety
/// ///
/// /// [`paddr`, `paddr` + `SIZE`) must be a valid MMIO region that is mappable into the CPUs
/// /// virtual address space.
/// unsafe fn new(paddr: usize) -> Result<Self>{
/// // SAFETY: By the safety requirements of this function [`paddr`, `paddr` + `SIZE`) is
/// // valid for `ioremap`.
/// let addr = unsafe { bindings::ioremap(paddr as PhysAddr, SIZE) };
/// if addr.is_null() {
/// return Err(ENOMEM);
/// }
///
/// Ok(IoMem(MmioRaw::new(addr as usize, SIZE)?))
/// }
/// }
///
/// impl<const SIZE: usize> Drop for IoMem<SIZE> {
/// fn drop(&mut self) {
/// // SAFETY: `self.0.addr()` is guaranteed to be properly mapped by `Self::new`.
/// unsafe { bindings::iounmap(self.0.addr() as *mut c_void); };
/// }
/// }
///
/// impl<const SIZE: usize> Deref for IoMem<SIZE> {
/// type Target = Mmio<SIZE>;
///
/// fn deref(&self) -> &Self::Target {
/// // SAFETY: The memory range stored in `self` has been properly mapped in `Self::new`.
/// unsafe { Mmio::from_raw(&self.0) }
/// }
/// }
/// # fn no_run(dev: &Device<Bound>) -> Result<(), Error> {
/// // SAFETY: Invalid usage for example purposes.
/// let iomem = unsafe { IoMem::<{ core::mem::size_of::<u32>() }>::new(0xBAAAAAAD)? };
/// let devres = Devres::new(dev, iomem)?;
///
/// let res = devres.try_access().ok_or(ENXIO)?;
/// res.write8(0x42, 0x0);
/// # Ok(())
/// # }
/// ```
pub struct Devres<T: Send> {
dev: ARef<Device>,
/// Pointer to [`Self::devres_callback`].
///
/// Has to be stored, since Rust does not guarantee to always return the same address for a
/// function. However, the C API uses the address as a key.
callback: unsafe extern "C" fn(*mut c_void),
data: Arc<Revocable<T>>,
}
impl<T: Send> Devres<T> {
/// Creates a new [`Devres`] instance of the given `data`.
///
/// The `data` encapsulated within the returned `Devres` instance' `data` will be
/// (revoked)[`Revocable`] once the device is detached.
pub fn new<E>(dev: &Device<Bound>, data: impl PinInit<T, E>) -> Result<Self>
where
Error: From<E>,
{
let callback = Self::devres_callback;
let data = Arc::pin_init(Revocable::new(data), GFP_KERNEL)?;
let devres_data = data.clone();
// SAFETY:
// - `dev.as_raw()` is a pointer to a valid bound device.
// - `data` is guaranteed to be a valid for the duration of the lifetime of `Self`.
// - `devm_add_action()` is guaranteed not to call `callback` for the entire lifetime of
// `dev`.
to_result(unsafe {
bindings::devm_add_action(
dev.as_raw(),
Some(callback),
Arc::as_ptr(&data).cast_mut().cast(),
)
})?;
// `devm_add_action()` was successful and has consumed the reference count.
core::mem::forget(devres_data);
Ok(Self {
dev: dev.into(),
callback,
data,
})
}
fn data(&self) -> &Revocable<T> {
&self.data
}
#[allow(clippy::missing_safety_doc)]
unsafe extern "C" fn devres_callback(ptr: *mut kernel::ffi::c_void) {
// SAFETY: In `Self::new` we've passed a valid pointer of `Revocable<T>` to
// `devm_add_action()`, hence `ptr` must be a valid pointer to `Revocable<T>`.
let data = unsafe { Arc::from_raw(ptr.cast::<Revocable<T>>()) };
data.revoke();
}
fn remove_action(&self) -> bool {
// SAFETY:
// - `self.dev` is a valid `Device`,
// - the `action` and `data` pointers are the exact same ones as given to
// `devm_add_action()` previously,
(unsafe {
bindings::devm_remove_action_nowarn(
self.dev.as_raw(),
Some(self.callback),
core::ptr::from_ref(self.data()).cast_mut().cast(),
)
} == 0)
}
/// Return a reference of the [`Device`] this [`Devres`] instance has been created with.
pub fn device(&self) -> &Device {
&self.dev
}
/// Obtain `&'a T`, bypassing the [`Revocable`].
///
/// This method allows to directly obtain a `&'a T`, bypassing the [`Revocable`], by presenting
/// a `&'a Device<Bound>` of the same [`Device`] this [`Devres`] instance has been created with.
///
/// # Errors
///
/// An error is returned if `dev` does not match the same [`Device`] this [`Devres`] instance
/// has been created with.
///
/// # Examples
///
/// ```no_run
/// #![cfg(CONFIG_PCI)]
/// use kernel::{
/// device::Core,
/// devres::Devres,
/// io::{
/// Io,
/// IoKnownSize, //
/// },
/// pci, //
/// };
///
/// fn from_core(dev: &pci::Device<Core>, devres: Devres<pci::Bar<0x4>>) -> Result {
/// let bar = devres.access(dev.as_ref())?;
///
/// let _ = bar.read32(0x0);
///
/// // might_sleep()
///
/// bar.write32(0x42, 0x0);
///
/// Ok(())
/// }
/// ```
pub fn access<'a>(&'a self, dev: &'a Device<Bound>) -> Result<&'a T> {
if self.dev.as_raw() != dev.as_raw() {
return Err(EINVAL);
}
// SAFETY: `dev` being the same device as the device this `Devres` has been created for
// proves that `self.data` hasn't been revoked and is guaranteed to not be revoked as long
// as `dev` lives; `dev` lives at least as long as `self`.
Ok(unsafe { self.data().access() })
}
/// [`Devres`] accessor for [`Revocable::try_access`].
pub fn try_access(&self) -> Option<RevocableGuard<'_, T>> {
self.data().try_access()
}
/// [`Devres`] accessor for [`Revocable::try_access_with`].
pub fn try_access_with<R, F: FnOnce(&T) -> R>(&self, f: F) -> Option<R> {
self.data().try_access_with(f)
}
/// [`Devres`] accessor for [`Revocable::try_access_with_guard`].
pub fn try_access_with_guard<'a>(&'a self, guard: &'a rcu::Guard) -> Option<&'a T> {
self.data().try_access_with_guard(guard)
}
}
// SAFETY: `Devres` can be send to any task, if `T: Send`.
unsafe impl<T: Send> Send for Devres<T> {}
// SAFETY: `Devres` can be shared with any task, if `T: Sync`.
unsafe impl<T: Send + Sync> Sync for Devres<T> {}
impl<T: Send> Drop for Devres<T> {
fn drop(&mut self) {
// SAFETY: When `drop` runs, it is guaranteed that nobody is accessing the revocable data
// anymore, hence it is safe not to wait for the grace period to finish.
if unsafe { self.data().revoke_nosync() } {
// We revoked `self.data` before the devres action did, hence try to remove it.
if self.remove_action() {
// SAFETY: In `Self::new` we have taken an additional reference count of `self.data`
// for `devm_add_action()`. Since `remove_action()` was successful, we have to drop
// this additional reference count.
drop(unsafe { Arc::from_raw(Arc::as_ptr(&self.data)) });
}
}
}
}
/// Consume `data` and [`Drop::drop`] `data` once `dev` is unbound.
fn register_foreign<P>(dev: &Device<Bound>, data: P) -> Result
where
P: ForeignOwnable + Send + 'static,
{
let ptr = data.into_foreign();
#[allow(clippy::missing_safety_doc)]
unsafe extern "C" fn callback<P: ForeignOwnable>(ptr: *mut kernel::ffi::c_void) {
// SAFETY: `ptr` is the pointer to the `ForeignOwnable` leaked above and hence valid.
drop(unsafe { P::from_foreign(ptr.cast()) });
}
// SAFETY:
// - `dev.as_raw()` is a pointer to a valid and bound device.
// - `ptr` is a valid pointer the `ForeignOwnable` devres takes ownership of.
to_result(unsafe {
// `devm_add_action_or_reset()` also calls `callback` on failure, such that the
// `ForeignOwnable` is released eventually.
bindings::devm_add_action_or_reset(dev.as_raw(), Some(callback::<P>), ptr.cast())
})
}
/// Encapsulate `data` in a [`KBox`] and [`Drop::drop`] `data` once `dev` is unbound.
///
/// # Examples
///
/// ```no_run
/// use kernel::{
/// device::{
/// Bound,
/// Device, //
/// },
/// devres, //
/// };
///
/// /// Registration of e.g. a class device, IRQ, etc.
/// struct Registration;
///
/// impl Registration {
/// fn new() -> Self {
/// // register
///
/// Self
/// }
/// }
///
/// impl Drop for Registration {
/// fn drop(&mut self) {
/// // unregister
/// }
/// }
///
/// fn from_bound_context(dev: &Device<Bound>) -> Result {
/// devres::register(dev, Registration::new(), GFP_KERNEL)
/// }
/// ```
pub fn register<T, E>(dev: &Device<Bound>, data: impl PinInit<T, E>, flags: Flags) -> Result
where
T: Send + 'static,
Error: From<E>,
{
let data = KBox::pin_init(data, flags)?;
register_foreign(dev, data)
}
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