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Quelle auxiliary.rs
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// SPDX-License-Identifier: GPL-2.0
//! Abstractions for the auxiliary bus.
//!
//! C header: [`include/linux/auxiliary_bus.h`](srctree/include/linux/auxiliary_bus.h)
use crate::{
bindings, container_of, device,
device_id::{RawDeviceId, RawDeviceIdIndex},
driver,
error::{from_result, to_result, Result},
prelude::*,
types::Opaque,
ThisModule,
};
use core::{
marker::PhantomData,
ptr::{addr_of_mut, NonNull},
};
/// An adapter for the registration of auxiliary drivers.
pub struct Adapter<T: Driver>(T);
// SAFETY: A call to `unregister` for a given instance of `RegType` is guaranteed to be valid if
// a preceding call to `register` has been successful.
unsafe impl<T: Driver + 'static> driver::RegistrationOps for Adapter<T> {
type RegType = bindings::auxiliary_driver;
unsafe fn register(
adrv: &Opaque<Self::RegType>,
name: &'static CStr,
module: &'static ThisModule,
) -> Result {
// SAFETY: It's safe to set the fields of `struct auxiliary_driver` on initialization.
unsafe {
(*adrv.get()).name = name.as_char_ptr();
(*adrv.get()).probe = Some(Self::probe_callback);
(*adrv.get()).remove = Some(Self::remove_callback);
(*adrv.get()).id_table = T::ID_TABLE.as_ptr();
}
// SAFETY: `adrv` is guaranteed to be a valid `RegType`.
to_result(unsafe {
bindings::__auxiliary_driver_register(adrv.get(), module.0, name.as_char_ptr())
})
}
unsafe fn unregister(adrv: &Opaque<Self::RegType>) {
// SAFETY: `adrv` is guaranteed to be a valid `RegType`.
unsafe { bindings::auxiliary_driver_unregister(adrv.get()) }
}
}
impl<T: Driver + 'static> Adapter<T> {
extern "C" fn probe_callback(
adev: *mut bindings::auxiliary_device,
id: *const bindings::auxiliary_device_id,
) -> kernel::ffi::c_int {
// SAFETY: The auxiliary bus only ever calls the probe callback with a valid pointer to a
// `struct auxiliary_device`.
//
// INVARIANT: `adev` is valid for the duration of `probe_callback()`.
let adev = unsafe { &*adev.cast::<Device<device::CoreInternal>>() };
// SAFETY: `DeviceId` is a `#[repr(transparent)`] wrapper of `struct auxiliary_device_id`
// and does not add additional invariants, so it's safe to transmute.
let id = unsafe { &*id.cast::<DeviceId>() };
let info = T::ID_TABLE.info(id.index());
from_result(|| {
let data = T::probe(adev, info)?;
adev.as_ref().set_drvdata(data);
Ok(0)
})
}
extern "C" fn remove_callback(adev: *mut bindings::auxiliary_device) {
// SAFETY: The auxiliary bus only ever calls the probe callback with a valid pointer to a
// `struct auxiliary_device`.
//
// INVARIANT: `adev` is valid for the duration of `probe_callback()`.
let adev = unsafe { &*adev.cast::<Device<device::CoreInternal>>() };
// SAFETY: `remove_callback` is only ever called after a successful call to
// `probe_callback`, hence it's guaranteed that `Device::set_drvdata()` has been called
// and stored a `Pin<KBox<T>>`.
drop(unsafe { adev.as_ref().drvdata_obtain::<Pin<KBox<T>>>() });
}
}
/// Declares a kernel module that exposes a single auxiliary driver.
#[macro_export]
macro_rules! module_auxiliary_driver {
($($f:tt)*) => {
$crate::module_driver!(<T>, $crate::auxiliary::Adapter<T>, { $($f)* });
};
}
/// Abstraction for `bindings::auxiliary_device_id`.
#[repr(transparent)]
#[derive(Clone, Copy)]
pub struct DeviceId(bindings::auxiliary_device_id);
impl DeviceId {
/// Create a new [`DeviceId`] from name.
pub const fn new(modname: &'static CStr, name: &'static CStr) -> Self {
let name = name.as_bytes_with_nul();
let modname = modname.as_bytes_with_nul();
// TODO: Replace with `bindings::auxiliary_device_id::default()` once stabilized for
// `const`.
//
// SAFETY: FFI type is valid to be zero-initialized.
let mut id: bindings::auxiliary_device_id = unsafe { core::mem::zeroed() };
let mut i = 0;
while i < modname.len() {
id.name[i] = modname[i];
i += 1;
}
// Reuse the space of the NULL terminator.
id.name[i - 1] = b'.';
let mut j = 0;
while j < name.len() {
id.name[i] = name[j];
i += 1;
j += 1;
}
Self(id)
}
}
// SAFETY: `DeviceId` is a `#[repr(transparent)]` wrapper of `auxiliary_device_id` and does not add
// additional invariants, so it's safe to transmute to `RawType`.
unsafe impl RawDeviceId for DeviceId {
type RawType = bindings::auxiliary_device_id;
}
// SAFETY: `DRIVER_DATA_OFFSET` is the offset to the `driver_data` field.
unsafe impl RawDeviceIdIndex for DeviceId {
const DRIVER_DATA_OFFSET: usize =
core::mem::offset_of!(bindings::auxiliary_device_id, driver_data);
fn index(&self) -> usize {
self.0.driver_data
}
}
/// IdTable type for auxiliary drivers.
pub type IdTable<T> = &'static dyn kernel::device_id::IdTable<DeviceId, T>;
/// Create a auxiliary `IdTable` with its alias for modpost.
#[macro_export]
macro_rules! auxiliary_device_table {
($table_name:ident, $module_table_name:ident, $id_info_type: ty, $table_data: expr) => {
const $table_name: $crate::device_id::IdArray<
$crate::auxiliary::DeviceId,
$id_info_type,
{ $table_data.len() },
> = $crate::device_id::IdArray::new($table_data);
$crate::module_device_table!("auxiliary", $module_table_name, $table_name);
};
}
/// The auxiliary driver trait.
///
/// Drivers must implement this trait in order to get an auxiliary driver registered.
pub trait Driver {
/// The type holding information about each device id supported by the driver.
///
/// TODO: Use associated_type_defaults once stabilized:
///
/// type IdInfo: 'static = ();
type IdInfo: 'static;
/// The table of device ids supported by the driver.
const ID_TABLE: IdTable<Self::IdInfo>;
/// Auxiliary driver probe.
///
/// Called when an auxiliary device is matches a corresponding driver.
fn probe(dev: &Device<device::Core>, id_info: &Self::IdInfo) -> Result<Pin<KBox<Self>>>;
}
/// The auxiliary device representation.
///
/// This structure represents the Rust abstraction for a C `struct auxiliary_device`. The
/// implementation abstracts the usage of an already existing C `struct auxiliary_device` within
/// Rust code that we get passed from the C side.
///
/// # Invariants
///
/// A [`Device`] instance represents a valid `struct auxiliary_device` created by the C portion of
/// the kernel.
#[repr(transparent)]
pub struct Device<Ctx: device::DeviceContext = device::Normal>(
Opaque<bindings::auxiliary_device>,
PhantomData<Ctx>,
);
impl<Ctx: device::DeviceContext> Device<Ctx> {
fn as_raw(&self) -> *mut bindings::auxiliary_device {
self.0.get()
}
/// Returns the auxiliary device' id.
pub fn id(&self) -> u32 {
// SAFETY: By the type invariant `self.as_raw()` is a valid pointer to a
// `struct auxiliary_device`.
unsafe { (*self.as_raw()).id }
}
/// Returns a reference to the parent [`device::Device`], if any.
pub fn parent(&self) -> Option<&device::Device> {
self.as_ref().parent()
}
}
impl Device {
extern "C" fn release(dev: *mut bindings::device) {
// SAFETY: By the type invariant `self.0.as_raw` is a pointer to the `struct device`
// embedded in `struct auxiliary_device`.
let adev = unsafe { container_of!(dev, bindings::auxiliary_device, dev) };
// SAFETY: `adev` points to the memory that has been allocated in `Registration::new`, via
// `KBox::new(Opaque::<bindings::auxiliary_device>::zeroed(), GFP_KERNEL)`.
let _ = unsafe { KBox::<Opaque<bindings::auxiliary_device>>::from_raw(adev.cast()) };
}
}
// SAFETY: `Device` is a transparent wrapper of a type that doesn't depend on `Device`'s generic
// argument.
kernel::impl_device_context_deref!(unsafe { Device });
kernel::impl_device_context_into_aref!(Device);
// SAFETY: Instances of `Device` are always reference-counted.
unsafe impl crate::types::AlwaysRefCounted for Device {
fn inc_ref(&self) {
// SAFETY: The existence of a shared reference guarantees that the refcount is non-zero.
unsafe { bindings::get_device(self.as_ref().as_raw()) };
}
unsafe fn dec_ref(obj: NonNull<Self>) {
// CAST: `Self` a transparent wrapper of `bindings::auxiliary_device`.
let adev: *mut bindings::auxiliary_device = obj.cast().as_ptr();
// SAFETY: By the type invariant of `Self`, `adev` is a pointer to a valid
// `struct auxiliary_device`.
let dev = unsafe { addr_of_mut!((*adev).dev) };
// SAFETY: The safety requirements guarantee that the refcount is non-zero.
unsafe { bindings::put_device(dev) }
}
}
impl<Ctx: device::DeviceContext> AsRef<device::Device<Ctx>> for Device<Ctx> {
fn as_ref(&self) -> &device::Device<Ctx> {
// SAFETY: By the type invariant of `Self`, `self.as_raw()` is a pointer to a valid
// `struct auxiliary_device`.
let dev = unsafe { addr_of_mut!((*self.as_raw()).dev) };
// SAFETY: `dev` points to a valid `struct device`.
unsafe { device::Device::from_raw(dev) }
}
}
// SAFETY: A `Device` is always reference-counted and can be released from any thread.
unsafe impl Send for Device {}
// SAFETY: `Device` can be shared among threads because all methods of `Device`
// (i.e. `Device<Normal>) are thread safe.
unsafe impl Sync for Device {}
/// The registration of an auxiliary device.
///
/// This type represents the registration of a [`struct auxiliary_device`]. When an instance of this
/// type is dropped, its respective auxiliary device will be unregistered from the system.
///
/// # Invariants
///
/// `self.0` always holds a valid pointer to an initialized and registered
/// [`struct auxiliary_device`].
pub struct Registration(NonNull<bindings::auxiliary_device>);
impl Registration {
/// Create and register a new auxiliary device.
pub fn new(parent: &device::Device, name: &CStr, id: u32, modname: &CStr) -> Result<Self> {
let boxed = KBox::new(Opaque::<bindings::auxiliary_device>::zeroed(), GFP_KERNEL)?;
let adev = boxed.get();
// SAFETY: It's safe to set the fields of `struct auxiliary_device` on initialization.
unsafe {
(*adev).dev.parent = parent.as_raw();
(*adev).dev.release = Some(Device::release);
(*adev).name = name.as_char_ptr();
(*adev).id = id;
}
// SAFETY: `adev` is guaranteed to be a valid pointer to a `struct auxiliary_device`,
// which has not been initialized yet.
unsafe { bindings::auxiliary_device_init(adev) };
// Now that `adev` is initialized, leak the `Box`; the corresponding memory will be freed
// by `Device::release` when the last reference to the `struct auxiliary_device` is dropped.
let _ = KBox::into_raw(boxed);
// SAFETY:
// - `adev` is guaranteed to be a valid pointer to a `struct auxiliary_device`, which has
// been initialialized,
// - `modname.as_char_ptr()` is a NULL terminated string.
let ret = unsafe { bindings::__auxiliary_device_add(adev, modname.as_char_ptr()) };
if ret != 0 {
// SAFETY: `adev` is guaranteed to be a valid pointer to a `struct auxiliary_device`,
// which has been initialialized.
unsafe { bindings::auxiliary_device_uninit(adev) };
return Err(Error::from_errno(ret));
}
// SAFETY: `adev` is guaranteed to be non-null, since the `KBox` was allocated successfully.
//
// INVARIANT: The device will remain registered until `auxiliary_device_delete()` is called,
// which happens in `Self::drop()`.
Ok(Self(unsafe { NonNull::new_unchecked(adev) }))
}
}
impl Drop for Registration {
fn drop(&mut self) {
// SAFETY: By the type invariant of `Self`, `self.0.as_ptr()` is a valid registered
// `struct auxiliary_device`.
unsafe { bindings::auxiliary_device_delete(self.0.as_ptr()) };
// This drops the reference we acquired through `auxiliary_device_init()`.
//
// SAFETY: By the type invariant of `Self`, `self.0.as_ptr()` is a valid registered
// `struct auxiliary_device`.
unsafe { bindings::auxiliary_device_uninit(self.0.as_ptr()) };
}
}
// SAFETY: A `Registration` of a `struct auxiliary_device` can be released from any thread.
unsafe impl Send for Registration {}
// SAFETY: `Registration` does not expose any methods or fields that need synchronization.
unsafe impl Sync for Registration {}
[ Dauer der Verarbeitung: 0.29 Sekunden
(vorverarbeitet)
]
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2026-04-04
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