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linux/rust/kernel/io.rs
Alexandre Courbot 9a52a8f5ed rust: io: introduce write_reg and LocatedRegister 
Some I/O types, like fixed address registers, carry their location
alongside their values. For these types, the regular `Io::write` method
can lead into repeating the location information twice: once to provide
the location itself, another time to build the value.

We are also considering supporting making all register values carry
their full location information for convenience and safety.

Add a new `Io::write_reg` method that takes a single argument
implementing `LocatedRegister`, a trait that decomposes implementors
into a `(location, value)` tuple. This allows write operations on fixed
offset registers to be done while specifying their name only once.

Suggested-by: Danilo Krummrich <dakr@kernel.org>
Link: https://lore.kernel.org/all/DH0XBLXZD81K.22SWIZ1ZAOW1@kernel.org/
Signed-off-by: Alexandre Courbot <acourbot@nvidia.com>
Link: https://patch.msgid.link/20260314-register-v9-8-86805b2f7e9d@nvidia.com
[ Replace FIFO with VERSION register in the examples. - Danilo ]
Signed-off-by: Danilo Krummrich <dakr@kernel.org>
2026-03-17 20:04:11 +01:00

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// SPDX-License-Identifier: GPL-2.0
//! Memory-mapped IO.
//!
//! C header: [`include/asm-generic/io.h`](srctree/include/asm-generic/io.h)
use crate::{
bindings,
prelude::*, //
};
pub mod mem;
pub mod poll;
pub mod register;
pub mod resource;
pub use crate::register;
pub use resource::Resource;
use register::LocatedRegister;
/// Physical address type.
///
/// This is a type alias to either `u32` or `u64` depending on the config option
/// `CONFIG_PHYS_ADDR_T_64BIT`, and it can be a u64 even on 32-bit architectures.
pub type PhysAddr = bindings::phys_addr_t;
/// Resource Size type.
///
/// This is a type alias to either `u32` or `u64` depending on the config option
/// `CONFIG_PHYS_ADDR_T_64BIT`, and it can be a u64 even on 32-bit architectures.
pub type ResourceSize = bindings::resource_size_t;
/// Raw representation of an MMIO region.
///
/// By itself, the existence of an instance of this structure does not provide any guarantees that
/// the represented MMIO region does exist or is properly mapped.
///
/// Instead, the bus specific MMIO implementation must convert this raw representation into an
/// `Mmio` instance providing the actual memory accessors. Only by the conversion into an `Mmio`
/// structure any guarantees are given.
pub struct MmioRaw<const SIZE: usize = 0> {
addr: usize,
maxsize: usize,
}
impl<const SIZE: usize> MmioRaw<SIZE> {
/// Returns a new `MmioRaw` instance on success, an error otherwise.
pub fn new(addr: usize, maxsize: usize) -> Result<Self> {
if maxsize < SIZE {
return Err(EINVAL);
}
Ok(Self { addr, maxsize })
}
/// Returns the base address of the MMIO region.
#[inline]
pub fn addr(&self) -> usize {
self.addr
}
/// Returns the maximum size of the MMIO region.
#[inline]
pub fn maxsize(&self) -> usize {
self.maxsize
}
}
/// IO-mapped memory region.
///
/// The creator (usually a subsystem / bus such as PCI) is responsible for creating the
/// mapping, performing an additional region request etc.
///
/// # Invariant
///
/// `addr` is the start and `maxsize` the length of valid I/O mapped memory region of size
/// `maxsize`.
///
/// # Examples
///
/// ```no_run
/// use kernel::{
/// bindings,
/// ffi::c_void,
/// io::{
/// Io,
/// IoKnownSize,
/// Mmio,
/// MmioRaw,
/// PhysAddr,
/// },
/// };
/// 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() -> Result<(), Error> {
/// // SAFETY: Invalid usage for example purposes.
/// let iomem = unsafe { IoMem::<{ core::mem::size_of::<u32>() }>::new(0xBAAAAAAD)? };
/// iomem.write32(0x42, 0x0);
/// assert!(iomem.try_write32(0x42, 0x0).is_ok());
/// assert!(iomem.try_write32(0x42, 0x4).is_err());
/// # Ok(())
/// # }
/// ```
#[repr(transparent)]
pub struct Mmio<const SIZE: usize = 0>(MmioRaw<SIZE>);
/// Checks whether an access of type `U` at the given `offset`
/// is valid within this region.
#[inline]
const fn offset_valid<U>(offset: usize, size: usize) -> bool {
let type_size = core::mem::size_of::<U>();
if let Some(end) = offset.checked_add(type_size) {
end <= size && offset % type_size == 0
} else {
false
}
}
/// Trait indicating that an I/O backend supports operations of a certain type and providing an
/// implementation for these operations.
///
/// Different I/O backends can implement this trait to expose only the operations they support.
///
/// For example, a PCI configuration space may implement `IoCapable<u8>`, `IoCapable<u16>`,
/// and `IoCapable<u32>`, but not `IoCapable<u64>`, while an MMIO region on a 64-bit
/// system might implement all four.
pub trait IoCapable<T> {
/// Performs an I/O read of type `T` at `address` and returns the result.
///
/// # Safety
///
/// The range `[address..address + size_of::<T>()]` must be within the bounds of `Self`.
unsafe fn io_read(&self, address: usize) -> T;
/// Performs an I/O write of `value` at `address`.
///
/// # Safety
///
/// The range `[address..address + size_of::<T>()]` must be within the bounds of `Self`.
unsafe fn io_write(&self, value: T, address: usize);
}
/// Describes a given I/O location: its offset, width, and type to convert the raw value from and
/// into.
///
/// This trait is the key abstraction allowing [`Io::read`], [`Io::write`], and [`Io::update`] (and
/// their fallible [`try_read`](Io::try_read), [`try_write`](Io::try_write) and
/// [`try_update`](Io::try_update) counterparts) to work uniformly with both raw [`usize`] offsets
/// (for primitive types like [`u32`]) and typed ones (like those generated by the [`register!`]
/// macro).
///
/// An `IoLoc<T>` carries three pieces of information:
///
/// - The offset to access (returned by [`IoLoc::offset`]),
/// - The width of the access (determined by [`IoLoc::IoType`]),
/// - The type `T` in which the raw data is returned or provided.
///
/// `T` and `IoLoc::IoType` may differ: for instance, a typed register has `T` = the register type
/// with its bitfields, and `IoType` = its backing primitive (e.g. `u32`).
pub trait IoLoc<T> {
/// Size ([`u8`], [`u16`], etc) of the I/O performed on the returned [`offset`](IoLoc::offset).
type IoType: Into<T> + From<T>;
/// Consumes `self` and returns the offset of this location.
fn offset(self) -> usize;
}
/// Implements [`IoLoc<$ty>`] for [`usize`], allowing [`usize`] to be used as a parameter of
/// [`Io::read`] and [`Io::write`].
macro_rules! impl_usize_ioloc {
($($ty:ty),*) => {
$(
impl IoLoc<$ty> for usize {
type IoType = $ty;
#[inline(always)]
fn offset(self) -> usize {
self
}
}
)*
}
}
// Provide the ability to read any primitive type from a [`usize`].
impl_usize_ioloc!(u8, u16, u32, u64);
/// Types implementing this trait (e.g. MMIO BARs or PCI config regions)
/// can perform I/O operations on regions of memory.
///
/// This is an abstract representation to be implemented by arbitrary I/O
/// backends (e.g. MMIO, PCI config space, etc.).
///
/// The [`Io`] trait provides:
/// - Base address and size information
/// - Helper methods for offset validation and address calculation
/// - Fallible (runtime checked) accessors for different data widths
///
/// Which I/O methods are available depends on which [`IoCapable<T>`] traits
/// are implemented for the type.
///
/// # Examples
///
/// For MMIO regions, all widths (u8, u16, u32, and u64 on 64-bit systems) are typically
/// supported. For PCI configuration space, u8, u16, and u32 are supported but u64 is not.
pub trait Io {
/// Returns the base address of this mapping.
fn addr(&self) -> usize;
/// Returns the maximum size of this mapping.
fn maxsize(&self) -> usize;
/// Returns the absolute I/O address for a given `offset`,
/// performing runtime bound checks.
#[inline]
fn io_addr<U>(&self, offset: usize) -> Result<usize> {
if !offset_valid::<U>(offset, self.maxsize()) {
return Err(EINVAL);
}
// Probably no need to check, since the safety requirements of `Self::new` guarantee that
// this can't overflow.
self.addr().checked_add(offset).ok_or(EINVAL)
}
/// Fallible 8-bit read with runtime bounds check.
#[inline(always)]
fn try_read8(&self, offset: usize) -> Result<u8>
where
Self: IoCapable<u8>,
{
self.try_read(offset)
}
/// Fallible 16-bit read with runtime bounds check.
#[inline(always)]
fn try_read16(&self, offset: usize) -> Result<u16>
where
Self: IoCapable<u16>,
{
self.try_read(offset)
}
/// Fallible 32-bit read with runtime bounds check.
#[inline(always)]
fn try_read32(&self, offset: usize) -> Result<u32>
where
Self: IoCapable<u32>,
{
self.try_read(offset)
}
/// Fallible 64-bit read with runtime bounds check.
#[inline(always)]
fn try_read64(&self, offset: usize) -> Result<u64>
where
Self: IoCapable<u64>,
{
self.try_read(offset)
}
/// Fallible 8-bit write with runtime bounds check.
#[inline(always)]
fn try_write8(&self, value: u8, offset: usize) -> Result
where
Self: IoCapable<u8>,
{
self.try_write(offset, value)
}
/// Fallible 16-bit write with runtime bounds check.
#[inline(always)]
fn try_write16(&self, value: u16, offset: usize) -> Result
where
Self: IoCapable<u16>,
{
self.try_write(offset, value)
}
/// Fallible 32-bit write with runtime bounds check.
#[inline(always)]
fn try_write32(&self, value: u32, offset: usize) -> Result
where
Self: IoCapable<u32>,
{
self.try_write(offset, value)
}
/// Fallible 64-bit write with runtime bounds check.
#[inline(always)]
fn try_write64(&self, value: u64, offset: usize) -> Result
where
Self: IoCapable<u64>,
{
self.try_write(offset, value)
}
/// Infallible 8-bit read with compile-time bounds check.
#[inline(always)]
fn read8(&self, offset: usize) -> u8
where
Self: IoKnownSize + IoCapable<u8>,
{
self.read(offset)
}
/// Infallible 16-bit read with compile-time bounds check.
#[inline(always)]
fn read16(&self, offset: usize) -> u16
where
Self: IoKnownSize + IoCapable<u16>,
{
self.read(offset)
}
/// Infallible 32-bit read with compile-time bounds check.
#[inline(always)]
fn read32(&self, offset: usize) -> u32
where
Self: IoKnownSize + IoCapable<u32>,
{
self.read(offset)
}
/// Infallible 64-bit read with compile-time bounds check.
#[inline(always)]
fn read64(&self, offset: usize) -> u64
where
Self: IoKnownSize + IoCapable<u64>,
{
self.read(offset)
}
/// Infallible 8-bit write with compile-time bounds check.
#[inline(always)]
fn write8(&self, value: u8, offset: usize)
where
Self: IoKnownSize + IoCapable<u8>,
{
self.write(offset, value)
}
/// Infallible 16-bit write with compile-time bounds check.
#[inline(always)]
fn write16(&self, value: u16, offset: usize)
where
Self: IoKnownSize + IoCapable<u16>,
{
self.write(offset, value)
}
/// Infallible 32-bit write with compile-time bounds check.
#[inline(always)]
fn write32(&self, value: u32, offset: usize)
where
Self: IoKnownSize + IoCapable<u32>,
{
self.write(offset, value)
}
/// Infallible 64-bit write with compile-time bounds check.
#[inline(always)]
fn write64(&self, value: u64, offset: usize)
where
Self: IoKnownSize + IoCapable<u64>,
{
self.write(offset, value)
}
/// Generic fallible read with runtime bounds check.
///
/// # Examples
///
/// Read a primitive type from an I/O address:
///
/// ```no_run
/// use kernel::io::{
/// Io,
/// Mmio,
/// };
///
/// fn do_reads(io: &Mmio) -> Result {
/// // 32-bit read from address `0x10`.
/// let v: u32 = io.try_read(0x10)?;
///
/// // 8-bit read from address `0xfff`.
/// let v: u8 = io.try_read(0xfff)?;
///
/// Ok(())
/// }
/// ```
#[inline(always)]
fn try_read<T, L>(&self, location: L) -> Result<T>
where
L: IoLoc<T>,
Self: IoCapable<L::IoType>,
{
let address = self.io_addr::<L::IoType>(location.offset())?;
// SAFETY: `address` has been validated by `io_addr`.
Ok(unsafe { self.io_read(address) }.into())
}
/// Generic fallible write with runtime bounds check.
///
/// # Examples
///
/// Write a primitive type to an I/O address:
///
/// ```no_run
/// use kernel::io::{
/// Io,
/// Mmio,
/// };
///
/// fn do_writes(io: &Mmio) -> Result {
/// // 32-bit write of value `1` at address `0x10`.
/// io.try_write(0x10, 1u32)?;
///
/// // 8-bit write of value `0xff` at address `0xfff`.
/// io.try_write(0xfff, 0xffu8)?;
///
/// Ok(())
/// }
/// ```
#[inline(always)]
fn try_write<T, L>(&self, location: L, value: T) -> Result
where
L: IoLoc<T>,
Self: IoCapable<L::IoType>,
{
let address = self.io_addr::<L::IoType>(location.offset())?;
let io_value = value.into();
// SAFETY: `address` has been validated by `io_addr`.
unsafe { self.io_write(io_value, address) }
Ok(())
}
/// Generic fallible write of a fully-located register value.
///
/// # Examples
///
/// Tuples carrying a location and a value can be used with this method:
///
/// ```no_run
/// use kernel::io::{
/// register,
/// Io,
/// Mmio,
/// };
///
/// register! {
/// VERSION(u32) @ 0x100 {
/// 15:8 major;
/// 7:0 minor;
/// }
/// }
///
/// impl VERSION {
/// fn new(major: u8, minor: u8) -> Self {
/// VERSION::zeroed().with_major(major).with_minor(minor)
/// }
/// }
///
/// fn do_write_reg(io: &Mmio) -> Result {
///
/// io.try_write_reg(VERSION::new(1, 0))
/// }
/// ```
#[inline(always)]
fn try_write_reg<T, L, V>(&self, value: V) -> Result
where
L: IoLoc<T>,
V: LocatedRegister<Location = L, Value = T>,
Self: IoCapable<L::IoType>,
{
let (location, value) = value.into_io_op();
self.try_write(location, value)
}
/// Generic fallible update with runtime bounds check.
///
/// Note: this does not perform any synchronization. The caller is responsible for ensuring
/// exclusive access if required.
///
/// # Examples
///
/// Read the u32 value at address `0x10`, increment it, and store the updated value back:
///
/// ```no_run
/// use kernel::io::{
/// Io,
/// Mmio,
/// };
///
/// fn do_update(io: &Mmio<0x1000>) -> Result {
/// io.try_update(0x10, |v: u32| {
/// v + 1
/// })
/// }
/// ```
#[inline(always)]
fn try_update<T, L, F>(&self, location: L, f: F) -> Result
where
L: IoLoc<T>,
Self: IoCapable<L::IoType>,
F: FnOnce(T) -> T,
{
let address = self.io_addr::<L::IoType>(location.offset())?;
// SAFETY: `address` has been validated by `io_addr`.
let value: T = unsafe { self.io_read(address) }.into();
let io_value = f(value).into();
// SAFETY: `address` has been validated by `io_addr`.
unsafe { self.io_write(io_value, address) }
Ok(())
}
/// Generic infallible read with compile-time bounds check.
///
/// # Examples
///
/// Read a primitive type from an I/O address:
///
/// ```no_run
/// use kernel::io::{
/// Io,
/// Mmio,
/// };
///
/// fn do_reads(io: &Mmio<0x1000>) {
/// // 32-bit read from address `0x10`.
/// let v: u32 = io.read(0x10);
///
/// // 8-bit read from the top of the I/O space.
/// let v: u8 = io.read(0xfff);
/// }
/// ```
#[inline(always)]
fn read<T, L>(&self, location: L) -> T
where
L: IoLoc<T>,
Self: IoKnownSize + IoCapable<L::IoType>,
{
let address = self.io_addr_assert::<L::IoType>(location.offset());
// SAFETY: `address` has been validated by `io_addr_assert`.
unsafe { self.io_read(address) }.into()
}
/// Generic infallible write with compile-time bounds check.
///
/// # Examples
///
/// Write a primitive type to an I/O address:
///
/// ```no_run
/// use kernel::io::{
/// Io,
/// Mmio,
/// };
///
/// fn do_writes(io: &Mmio<0x1000>) {
/// // 32-bit write of value `1` at address `0x10`.
/// io.write(0x10, 1u32);
///
/// // 8-bit write of value `0xff` at the top of the I/O space.
/// io.write(0xfff, 0xffu8);
/// }
/// ```
#[inline(always)]
fn write<T, L>(&self, location: L, value: T)
where
L: IoLoc<T>,
Self: IoKnownSize + IoCapable<L::IoType>,
{
let address = self.io_addr_assert::<L::IoType>(location.offset());
let io_value = value.into();
// SAFETY: `address` has been validated by `io_addr_assert`.
unsafe { self.io_write(io_value, address) }
}
/// Generic infallible write of a fully-located register value.
///
/// # Examples
///
/// Tuples carrying a location and a value can be used with this method:
///
/// ```no_run
/// use kernel::io::{
/// register,
/// Io,
/// Mmio,
/// };
///
/// register! {
/// VERSION(u32) @ 0x100 {
/// 15:8 major;
/// 7:0 minor;
/// }
/// }
///
/// impl VERSION {
/// fn new(major: u8, minor: u8) -> Self {
/// VERSION::zeroed().with_major(major).with_minor(minor)
/// }
/// }
///
/// fn do_write_reg(io: &Mmio<0x1000>) {
/// io.write_reg(VERSION::new(1, 0));
/// }
/// ```
#[inline(always)]
fn write_reg<T, L, V>(&self, value: V)
where
L: IoLoc<T>,
V: LocatedRegister<Location = L, Value = T>,
Self: IoKnownSize + IoCapable<L::IoType>,
{
let (location, value) = value.into_io_op();
self.write(location, value)
}
/// Generic infallible update with compile-time bounds check.
///
/// Note: this does not perform any synchronization. The caller is responsible for ensuring
/// exclusive access if required.
///
/// # Examples
///
/// Read the u32 value at address `0x10`, increment it, and store the updated value back:
///
/// ```no_run
/// use kernel::io::{
/// Io,
/// Mmio,
/// };
///
/// fn do_update(io: &Mmio<0x1000>) {
/// io.update(0x10, |v: u32| {
/// v + 1
/// })
/// }
/// ```
#[inline(always)]
fn update<T, L, F>(&self, location: L, f: F)
where
L: IoLoc<T>,
Self: IoKnownSize + IoCapable<L::IoType> + Sized,
F: FnOnce(T) -> T,
{
let address = self.io_addr_assert::<L::IoType>(location.offset());
// SAFETY: `address` has been validated by `io_addr_assert`.
let value: T = unsafe { self.io_read(address) }.into();
let io_value = f(value).into();
// SAFETY: `address` has been validated by `io_addr_assert`.
unsafe { self.io_write(io_value, address) }
}
}
/// Trait for types with a known size at compile time.
///
/// This trait is implemented by I/O backends that have a compile-time known size,
/// enabling the use of infallible I/O accessors with compile-time bounds checking.
///
/// Types implementing this trait can use the infallible methods in [`Io`] trait
/// (e.g., `read8`, `write32`), which require `Self: IoKnownSize` bound.
pub trait IoKnownSize: Io {
/// Minimum usable size of this region.
const MIN_SIZE: usize;
/// Returns the absolute I/O address for a given `offset`,
/// performing compile-time bound checks.
// Always inline to optimize out error path of `build_assert`.
#[inline(always)]
fn io_addr_assert<U>(&self, offset: usize) -> usize {
build_assert!(offset_valid::<U>(offset, Self::MIN_SIZE));
self.addr() + offset
}
}
/// Implements [`IoCapable`] on `$mmio` for `$ty` using `$read_fn` and `$write_fn`.
macro_rules! impl_mmio_io_capable {
($mmio:ident, $(#[$attr:meta])* $ty:ty, $read_fn:ident, $write_fn:ident) => {
$(#[$attr])*
impl<const SIZE: usize> IoCapable<$ty> for $mmio<SIZE> {
unsafe fn io_read(&self, address: usize) -> $ty {
// SAFETY: By the trait invariant `address` is a valid address for MMIO operations.
unsafe { bindings::$read_fn(address as *const c_void) }
}
unsafe fn io_write(&self, value: $ty, address: usize) {
// SAFETY: By the trait invariant `address` is a valid address for MMIO operations.
unsafe { bindings::$write_fn(value, address as *mut c_void) }
}
}
};
}
// MMIO regions support 8, 16, and 32-bit accesses.
impl_mmio_io_capable!(Mmio, u8, readb, writeb);
impl_mmio_io_capable!(Mmio, u16, readw, writew);
impl_mmio_io_capable!(Mmio, u32, readl, writel);
// MMIO regions on 64-bit systems also support 64-bit accesses.
impl_mmio_io_capable!(
Mmio,
#[cfg(CONFIG_64BIT)]
u64,
readq,
writeq
);
impl<const SIZE: usize> Io for Mmio<SIZE> {
/// Returns the base address of this mapping.
#[inline]
fn addr(&self) -> usize {
self.0.addr()
}
/// Returns the maximum size of this mapping.
#[inline]
fn maxsize(&self) -> usize {
self.0.maxsize()
}
}
impl<const SIZE: usize> IoKnownSize for Mmio<SIZE> {
const MIN_SIZE: usize = SIZE;
}
impl<const SIZE: usize> Mmio<SIZE> {
/// Converts an `MmioRaw` into an `Mmio` instance, providing the accessors to the MMIO mapping.
///
/// # Safety
///
/// Callers must ensure that `addr` is the start of a valid I/O mapped memory region of size
/// `maxsize`.
pub unsafe fn from_raw(raw: &MmioRaw<SIZE>) -> &Self {
// SAFETY: `Mmio` is a transparent wrapper around `MmioRaw`.
unsafe { &*core::ptr::from_ref(raw).cast() }
}
}
/// [`Mmio`] wrapper using relaxed accessors.
///
/// This type provides an implementation of [`Io`] that uses relaxed I/O MMIO operands instead of
/// the regular ones.
///
/// See [`Mmio::relaxed`] for a usage example.
#[repr(transparent)]
pub struct RelaxedMmio<const SIZE: usize = 0>(Mmio<SIZE>);
impl<const SIZE: usize> Io for RelaxedMmio<SIZE> {
#[inline]
fn addr(&self) -> usize {
self.0.addr()
}
#[inline]
fn maxsize(&self) -> usize {
self.0.maxsize()
}
}
impl<const SIZE: usize> IoKnownSize for RelaxedMmio<SIZE> {
const MIN_SIZE: usize = SIZE;
}
impl<const SIZE: usize> Mmio<SIZE> {
/// Returns a [`RelaxedMmio`] reference that performs relaxed I/O operations.
///
/// Relaxed accessors do not provide ordering guarantees with respect to DMA or memory accesses
/// and can be used when such ordering is not required.
///
/// # Examples
///
/// ```no_run
/// use kernel::io::{
/// Io,
/// Mmio,
/// RelaxedMmio,
/// };
///
/// fn do_io(io: &Mmio<0x100>) {
/// // The access is performed using `readl_relaxed` instead of `readl`.
/// let v = io.relaxed().read32(0x10);
/// }
///
/// ```
pub fn relaxed(&self) -> &RelaxedMmio<SIZE> {
// SAFETY: `RelaxedMmio` is `#[repr(transparent)]` over `Mmio`, so `Mmio<SIZE>` and
// `RelaxedMmio<SIZE>` have identical layout.
unsafe { core::mem::transmute(self) }
}
}
// MMIO regions support 8, 16, and 32-bit accesses.
impl_mmio_io_capable!(RelaxedMmio, u8, readb_relaxed, writeb_relaxed);
impl_mmio_io_capable!(RelaxedMmio, u16, readw_relaxed, writew_relaxed);
impl_mmio_io_capable!(RelaxedMmio, u32, readl_relaxed, writel_relaxed);
// MMIO regions on 64-bit systems also support 64-bit accesses.
impl_mmio_io_capable!(
RelaxedMmio,
#[cfg(CONFIG_64BIT)]
u64,
readq_relaxed,
writeq_relaxed
);
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