// SPDX-License-Identifier: GPL-2.0
//! Abstractions for the PCI bus.
//!
//! C header: [`include/linux/pci.h`](srctree/include/linux/pci.h)
use crate::{
alloc::flags::*,
bindings, container_of, device,
device_id::RawDeviceId,
devres::Devres,
driver,
error::{to_result, Result},
io::Io,
io::IoRaw,
str::CStr,
types::{ARef, ForeignOwnable, Opaque},
ThisModule,
};
use core::{ops::Deref, ptr::addr_of_mut};
use kernel::prelude::*;
/// An adapter for the registration of PCI 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::pci_driver;
unsafe fn register(
pdrv: &Opaque<Self::RegType>,
name: &'static CStr,
module: &'static ThisModule,
) -> Result {
// SAFETY: It's safe to set the fields of `struct pci_driver` on initialization.
unsafe {
(*pdrv.get()).name = name.as_char_ptr();
(*pdrv.get()).probe = Some(Self::probe_callback);
(*pdrv.get()).remove = Some(Self::remove_callback);
(*pdrv.get()).id_table = T::ID_TABLE.as_ptr();
}
// SAFETY: `pdrv` is guaranteed to be a valid `RegType`.
to_result(unsafe {
bindings::__pci_register_driver(pdrv.get(), module.0, name.as_char_ptr())
})
}
unsafe fn unregister(pdrv: &Opaque<Self::RegType>) {
// SAFETY: `pdrv` is guaranteed to be a valid `RegType`.
unsafe { bindings::pci_unregister_driver(pdrv.get()) }
}
}
impl<T: Driver + 'static> Adapter<T> {
extern "C" fn probe_callback(
pdev: *mut bindings::pci_dev,
id: *const bindings::pci_device_id,
) -> kernel::ffi::c_int {
// SAFETY: The PCI bus only ever calls the probe callback with a valid pointer to a
// `struct pci_dev`.
let dev = unsafe { device::Device::get_device(addr_of_mut!((*pdev).dev)) };
// SAFETY: `dev` is guaranteed to be embedded in a valid `struct pci_dev` by the call
// above.
let mut pdev = unsafe { Device::from_dev(dev) };
// SAFETY: `DeviceId` is a `#[repr(transparent)` wrapper of `struct pci_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());
match T::probe(&mut pdev, info) {
Ok(data) => {
// Let the `struct pci_dev` own a reference of the driver's private data.
// SAFETY: By the type invariant `pdev.as_raw` returns a valid pointer to a
// `struct pci_dev`.
unsafe { bindings::pci_set_drvdata(pdev.as_raw(), data.into_foreign() as _) };
}
Err(err) => return Error::to_errno(err),
}
0
}
extern "C" fn remove_callback(pdev: *mut bindings::pci_dev) {
// SAFETY: The PCI bus only ever calls the remove callback with a valid pointer to a
// `struct pci_dev`.
let ptr = unsafe { bindings::pci_get_drvdata(pdev) };
// SAFETY: `remove_callback` is only ever called after a successful call to
// `probe_callback`, hence it's guaranteed that `ptr` points to a valid and initialized
// `KBox<T>` pointer created through `KBox::into_foreign`.
let _ = unsafe { KBox::<T>::from_foreign(ptr) };
}
}
/// Declares a kernel module that exposes a single PCI driver.
///
/// # Example
///
///```ignore
/// kernel::module_pci_driver! {
/// type: MyDriver,
/// name: "Module name",
/// author: "Author name",
/// description: "Description",
/// license: "GPL v2",
/// }
///```
#[macro_export]
macro_rules! module_pci_driver {
($($f:tt)*) => {
$crate::module_driver!(<T>, $crate::pci::Adapter<T>, { $($f)* });
};
}
/// Abstraction for bindings::pci_device_id.
#[repr(transparent)]
#[derive(Clone, Copy)]
pub struct DeviceId(bindings::pci_device_id);
impl DeviceId {
const PCI_ANY_ID: u32 = !0;
/// Equivalent to C's `PCI_DEVICE` macro.
///
/// Create a new `pci::DeviceId` from a vendor and device ID number.
pub const fn from_id(vendor: u32, device: u32) -> Self {
Self(bindings::pci_device_id {
vendor,
device,
subvendor: DeviceId::PCI_ANY_ID,
subdevice: DeviceId::PCI_ANY_ID,
class: 0,
class_mask: 0,
driver_data: 0,
override_only: 0,
})
}
/// Equivalent to C's `PCI_DEVICE_CLASS` macro.
///
/// Create a new `pci::DeviceId` from a class number and mask.
pub const fn from_class(class: u32, class_mask: u32) -> Self {
Self(bindings::pci_device_id {
vendor: DeviceId::PCI_ANY_ID,
device: DeviceId::PCI_ANY_ID,
subvendor: DeviceId::PCI_ANY_ID,
subdevice: DeviceId::PCI_ANY_ID,
class,
class_mask,
driver_data: 0,
override_only: 0,
})
}
}
// SAFETY:
// * `DeviceId` is a `#[repr(transparent)` wrapper of `pci_device_id` and does not add
// additional invariants, so it's safe to transmute to `RawType`.
// * `DRIVER_DATA_OFFSET` is the offset to the `driver_data` field.
unsafe impl RawDeviceId for DeviceId {
type RawType = bindings::pci_device_id;
const DRIVER_DATA_OFFSET: usize = core::mem::offset_of!(bindings::pci_device_id, driver_data);
fn index(&self) -> usize {
self.0.driver_data as _
}
}
/// IdTable type for PCI
pub type IdTable<T> = &'static dyn kernel::device_id::IdTable<DeviceId, T>;
/// Create a PCI `IdTable` with its alias for modpost.
#[macro_export]
macro_rules! pci_device_table {
($table_name:ident, $module_table_name:ident, $id_info_type: ty, $table_data: expr) => {
const $table_name: $crate::device_id::IdArray<
$crate::pci::DeviceId,
$id_info_type,
{ $table_data.len() },
> = $crate::device_id::IdArray::new($table_data);
$crate::module_device_table!("pci", $module_table_name, $table_name);
};
}
/// The PCI driver trait.
///
/// # Example
///
///```
/// # use kernel::{bindings, pci};
///
/// struct MyDriver;
///
/// kernel::pci_device_table!(
/// PCI_TABLE,
/// MODULE_PCI_TABLE,
/// <MyDriver as pci::Driver>::IdInfo,
/// [
/// (pci::DeviceId::from_id(bindings::PCI_VENDOR_ID_REDHAT, bindings::PCI_ANY_ID as _), ())
/// ]
/// );
///
/// impl pci::Driver for MyDriver {
/// type IdInfo = ();
/// const ID_TABLE: pci::IdTable<Self::IdInfo> = &PCI_TABLE;
///
/// fn probe(
/// _pdev: &mut pci::Device,
/// _id_info: &Self::IdInfo,
/// ) -> Result<Pin<KBox<Self>>> {
/// Err(ENODEV)
/// }
/// }
///```
/// Drivers must implement this trait in order to get a PCI driver registered. Please refer to the
/// `Adapter` documentation for an example.
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>;
/// PCI driver probe.
///
/// Called when a new platform device is added or discovered.
/// Implementers should attempt to initialize the device here.
fn probe(dev: &mut Device, id_info: &Self::IdInfo) -> Result<Pin<KBox<Self>>>;
}
/// The PCI device representation.
///
/// A PCI device is based on an always reference counted `device:Device` instance. Cloning a PCI
/// device, hence, also increments the base device' reference count.
///
/// # Invariants
///
/// `Device` hold a valid reference of `ARef<device::Device>` whose underlying `struct device` is a
/// member of a `struct pci_dev`.
#[derive(Clone)]
pub struct Device(ARef<device::Device>);
/// A PCI BAR to perform I/O-Operations on.
///
/// # Invariants
///
/// `Bar` always holds an `IoRaw` inststance that holds a valid pointer to the start of the I/O
/// memory mapped PCI bar and its size.
pub struct Bar<const SIZE: usize = 0> {
pdev: Device,
io: IoRaw<SIZE>,
num: i32,
}
impl<const SIZE: usize> Bar<SIZE> {
fn new(pdev: Device, num: u32, name: &CStr) -> Result<Self> {
let len = pdev.resource_len(num)?;
if len == 0 {
return Err(ENOMEM);
}
// Convert to `i32`, since that's what all the C bindings use.
let num = i32::try_from(num)?;
// SAFETY:
// `pdev` is valid by the invariants of `Device`.
// `num` is checked for validity by a previous call to `Device::resource_len`.
// `name` is always valid.
let ret = unsafe { bindings::pci_request_region(pdev.as_raw(), num, name.as_char_ptr()) };
if ret != 0 {
return Err(EBUSY);
}
// SAFETY:
// `pdev` is valid by the invariants of `Device`.
// `num` is checked for validity by a previous call to `Device::resource_len`.
// `name` is always valid.
let ioptr: usize = unsafe { bindings::pci_iomap(pdev.as_raw(), num, 0) } as usize;
if ioptr == 0 {
// SAFETY:
// `pdev` valid by the invariants of `Device`.
// `num` is checked for validity by a previous call to `Device::resource_len`.
unsafe { bindings::pci_release_region(pdev.as_raw(), num) };
return Err(ENOMEM);
}
let io = match IoRaw::new(ioptr, len as usize) {
Ok(io) => io,
Err(err) => {
// SAFETY:
// `pdev` is valid by the invariants of `Device`.
// `ioptr` is guaranteed to be the start of a valid I/O mapped memory region.
// `num` is checked for validity by a previous call to `Device::resource_len`.
unsafe { Self::do_release(&pdev, ioptr, num) };
return Err(err);
}
};
Ok(Bar { pdev, io, num })
}
/// # Safety
///
/// `ioptr` must be a valid pointer to the memory mapped PCI bar number `num`.
unsafe fn do_release(pdev: &Device, ioptr: usize, num: i32) {
// SAFETY:
// `pdev` is valid by the invariants of `Device`.
// `ioptr` is valid by the safety requirements.
// `num` is valid by the safety requirements.
unsafe {
bindings::pci_iounmap(pdev.as_raw(), ioptr as _);
bindings::pci_release_region(pdev.as_raw(), num);
}
}
fn release(&self) {
// SAFETY: The safety requirements are guaranteed by the type invariant of `self.pdev`.
unsafe { Self::do_release(&self.pdev, self.io.addr(), self.num) };
}
}
impl Bar {
fn index_is_valid(index: u32) -> bool {
// A `struct pci_dev` owns an array of resources with at most `PCI_NUM_RESOURCES` entries.
index < bindings::PCI_NUM_RESOURCES
}
}
impl<const SIZE: usize> Drop for Bar<SIZE> {
fn drop(&mut self) {
self.release();
}
}
impl<const SIZE: usize> Deref for Bar<SIZE> {
type Target = Io<SIZE>;
fn deref(&self) -> &Self::Target {
// SAFETY: By the type invariant of `Self`, the MMIO range in `self.io` is properly mapped.
unsafe { Io::from_raw(&self.io) }
}
}
impl Device {
/// Create a PCI Device instance from an existing `device::Device`.
///
/// # Safety
///
/// `dev` must be an `ARef<device::Device>` whose underlying `bindings::device` is a member of
/// a `bindings::pci_dev`.
pub unsafe fn from_dev(dev: ARef<device::Device>) -> Self {
Self(dev)
}
fn as_raw(&self) -> *mut bindings::pci_dev {
// SAFETY: By the type invariant `self.0.as_raw` is a pointer to the `struct device`
// embedded in `struct pci_dev`.
unsafe { container_of!(self.0.as_raw(), bindings::pci_dev, dev) as _ }
}
/// Returns the PCI vendor ID.
pub fn vendor_id(&self) -> u16 {
// SAFETY: `self.as_raw` is a valid pointer to a `struct pci_dev`.
unsafe { (*self.as_raw()).vendor }
}
/// Returns the PCI device ID.
pub fn device_id(&self) -> u16 {
// SAFETY: `self.as_raw` is a valid pointer to a `struct pci_dev`.
unsafe { (*self.as_raw()).device }
}
/// Enable memory resources for this device.
pub fn enable_device_mem(&self) -> Result {
// SAFETY: `self.as_raw` is guaranteed to be a pointer to a valid `struct pci_dev`.
let ret = unsafe { bindings::pci_enable_device_mem(self.as_raw()) };
if ret != 0 {
Err(Error::from_errno(ret))
} else {
Ok(())
}
}
/// Enable bus-mastering for this device.
pub fn set_master(&self) {
// SAFETY: `self.as_raw` is guaranteed to be a pointer to a valid `struct pci_dev`.
unsafe { bindings::pci_set_master(self.as_raw()) };
}
/// Returns the size of the given PCI bar resource.
pub fn resource_len(&self, bar: u32) -> Result<bindings::resource_size_t> {
if !Bar::index_is_valid(bar) {
return Err(EINVAL);
}
// SAFETY:
// - `bar` is a valid bar number, as guaranteed by the above call to `Bar::index_is_valid`,
// - by its type invariant `self.as_raw` is always a valid pointer to a `struct pci_dev`.
Ok(unsafe { bindings::pci_resource_len(self.as_raw(), bar.try_into()?) })
}
/// Mapps an entire PCI-BAR after performing a region-request on it. I/O operation bound checks
/// can be performed on compile time for offsets (plus the requested type size) < SIZE.
pub fn iomap_region_sized<const SIZE: usize>(
&self,
bar: u32,
name: &CStr,
) -> Result<Devres<Bar<SIZE>>> {
let bar = Bar::<SIZE>::new(self.clone(), bar, name)?;
let devres = Devres::new(self.as_ref(), bar, GFP_KERNEL)?;
Ok(devres)
}
/// Mapps an entire PCI-BAR after performing a region-request on it.
pub fn iomap_region(&self, bar: u32, name: &CStr) -> Result<Devres<Bar>> {
self.iomap_region_sized::<0>(bar, name)
}
}
impl AsRef<device::Device> for Device {
fn as_ref(&self) -> &device::Device {
&self.0
}
}
