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// SPDX-License-Identifier: GPL-2.0
// Copyright (C) 2023 FUJITA Tomonori <fujita.tomonori@gmail.com>
//! Network PHY device.
//!
//! C headers: [`include/linux/phy.h`](srctree/include/linux/phy.h).
use crate::{bindings, error::*, prelude::*, str::CStr, types::Opaque};
use core::marker::PhantomData;
/// PHY state machine states.
///
/// Corresponds to the kernel's [`enum phy_state`].
///
/// Some of PHY drivers access to the state of PHY's software state machine.
///
/// [`enum phy_state`]: srctree/include/linux/phy.h
#[derive(PartialEq, Eq)]
pub enum DeviceState {
/// PHY device and driver are not ready for anything.
Down,
/// PHY is ready to send and receive packets.
Ready,
/// PHY is up, but no polling or interrupts are done.
Halted,
/// PHY is up, but is in an error state.
Error,
/// PHY and attached device are ready to do work.
Up,
/// PHY is currently running.
Running,
/// PHY is up, but not currently plugged in.
NoLink,
/// PHY is performing a cable test.
CableTest,
}
/// A mode of Ethernet communication.
///
/// PHY drivers get duplex information from hardware and update the current state.
pub enum DuplexMode {
/// PHY is in full-duplex mode.
Full,
/// PHY is in half-duplex mode.
Half,
/// PHY is in unknown duplex mode.
Unknown,
}
/// An instance of a PHY device.
///
/// Wraps the kernel's [`struct phy_device`].
///
/// A [`Device`] instance is created when a callback in [`Driver`] is executed. A PHY driver
/// executes [`Driver`]'s methods during the callback.
///
/// # Invariants
///
/// Referencing a `phy_device` using this struct asserts that you are in
/// a context where all methods defined on this struct are safe to call.
///
/// [`struct phy_device`]: srctree/include/linux/phy.h
// During the calls to most functions in [`Driver`], the C side (`PHYLIB`) holds a lock that is
// unique for every instance of [`Device`]. `PHYLIB` uses a different serialization technique for
// [`Driver::resume`] and [`Driver::suspend`]: `PHYLIB` updates `phy_device`'s state with
// the lock held, thus guaranteeing that [`Driver::resume`] has exclusive access to the instance.
// [`Driver::resume`] and [`Driver::suspend`] also are called where only one thread can access
// to the instance.
#[repr(transparent)]
pub struct Device(Opaque<bindings::phy_device>);
impl Device {
/// Creates a new [`Device`] instance from a raw pointer.
///
/// # Safety
///
/// For the duration of 'a, the pointer must point at a valid `phy_device`,
/// and the caller must be in a context where all methods defined on this struct
/// are safe to call.
unsafe fn from_raw<'a>(ptr: *mut bindings::phy_device) -> &'a mut Self {
// CAST: `Self` is a `repr(transparent)` wrapper around `bindings::phy_device`.
let ptr = ptr.cast::<Self>();
// SAFETY: by the function requirements the pointer is valid and we have unique access for
// the duration of `'a`.
unsafe { &mut *ptr }
}
/// Gets the id of the PHY.
pub fn phy_id(&self) -> u32 {
let phydev = self.0.get();
// SAFETY: The struct invariant ensures that we may access
// this field without additional synchronization.
unsafe { (*phydev).phy_id }
}
/// Gets the state of PHY state machine states.
pub fn state(&self) -> DeviceState {
let phydev = self.0.get();
// SAFETY: The struct invariant ensures that we may access
// this field without additional synchronization.
let state = unsafe { (*phydev).state };
// TODO: this conversion code will be replaced with automatically generated code by bindgen
// when it becomes possible.
match state {
bindings::phy_state_PHY_DOWN => DeviceState::Down,
bindings::phy_state_PHY_READY => DeviceState::Ready,
bindings::phy_state_PHY_HALTED => DeviceState::Halted,
bindings::phy_state_PHY_ERROR => DeviceState::Error,
bindings::phy_state_PHY_UP => DeviceState::Up,
bindings::phy_state_PHY_RUNNING => DeviceState::Running,
bindings::phy_state_PHY_NOLINK => DeviceState::NoLink,
bindings::phy_state_PHY_CABLETEST => DeviceState::CableTest,
_ => DeviceState::Error,
}
}
/// Gets the current link state.
///
/// It returns true if the link is up.
pub fn is_link_up(&self) -> bool {
const LINK_IS_UP: u64 = 1;
// TODO: the code to access to the bit field will be replaced with automatically
// generated code by bindgen when it becomes possible.
// SAFETY: The struct invariant ensures that we may access
// this field without additional synchronization.
let bit_field = unsafe { &(*self.0.get())._bitfield_1 };
bit_field.get(14, 1) == LINK_IS_UP
}
/// Gets the current auto-negotiation configuration.
///
/// It returns true if auto-negotiation is enabled.
pub fn is_autoneg_enabled(&self) -> bool {
// TODO: the code to access to the bit field will be replaced with automatically
// generated code by bindgen when it becomes possible.
// SAFETY: The struct invariant ensures that we may access
// this field without additional synchronization.
let bit_field = unsafe { &(*self.0.get())._bitfield_1 };
bit_field.get(13, 1) == bindings::AUTONEG_ENABLE as u64
}
/// Gets the current auto-negotiation state.
///
/// It returns true if auto-negotiation is completed.
pub fn is_autoneg_completed(&self) -> bool {
const AUTONEG_COMPLETED: u64 = 1;
// TODO: the code to access to the bit field will be replaced with automatically
// generated code by bindgen when it becomes possible.
// SAFETY: The struct invariant ensures that we may access
// this field without additional synchronization.
let bit_field = unsafe { &(*self.0.get())._bitfield_1 };
bit_field.get(15, 1) == AUTONEG_COMPLETED
}
/// Sets the speed of the PHY.
pub fn set_speed(&mut self, speed: u32) {
let phydev = self.0.get();
// SAFETY: The struct invariant ensures that we may access
// this field without additional synchronization.
unsafe { (*phydev).speed = speed as i32 };
}
/// Sets duplex mode.
pub fn set_duplex(&mut self, mode: DuplexMode) {
let phydev = self.0.get();
let v = match mode {
DuplexMode::Full => bindings::DUPLEX_FULL as i32,
DuplexMode::Half => bindings::DUPLEX_HALF as i32,
DuplexMode::Unknown => bindings::DUPLEX_UNKNOWN as i32,
};
// SAFETY: The struct invariant ensures that we may access
// this field without additional synchronization.
unsafe { (*phydev).duplex = v };
}
/// Reads a given C22 PHY register.
// This function reads a hardware register and updates the stats so takes `&mut self`.
pub fn read(&mut self, regnum: u16) -> Result<u16> {
let phydev = self.0.get();
// SAFETY: `phydev` is pointing to a valid object by the type invariant of `Self`.
// So it's just an FFI call, open code of `phy_read()` with a valid `phy_device` pointer
// `phydev`.
let ret = unsafe {
bindings::mdiobus_read((*phydev).mdio.bus, (*phydev).mdio.addr, regnum.into())
};
if ret < 0 {
Err(Error::from_errno(ret))
} else {
Ok(ret as u16)
}
}
/// Writes a given C22 PHY register.
pub fn write(&mut self, regnum: u16, val: u16) -> Result {
let phydev = self.0.get();
// SAFETY: `phydev` is pointing to a valid object by the type invariant of `Self`.
// So it's just an FFI call, open code of `phy_write()` with a valid `phy_device` pointer
// `phydev`.
to_result(unsafe {
bindings::mdiobus_write((*phydev).mdio.bus, (*phydev).mdio.addr, regnum.into(), val)
})
}
/// Reads a paged register.
pub fn read_paged(&mut self, page: u16, regnum: u16) -> Result<u16> {
let phydev = self.0.get();
// SAFETY: `phydev` is pointing to a valid object by the type invariant of `Self`.
// So it's just an FFI call.
let ret = unsafe { bindings::phy_read_paged(phydev, page.into(), regnum.into()) };
if ret < 0 {
Err(Error::from_errno(ret))
} else {
Ok(ret as u16)
}
}
/// Resolves the advertisements into PHY settings.
pub fn resolve_aneg_linkmode(&mut self) {
let phydev = self.0.get();
// SAFETY: `phydev` is pointing to a valid object by the type invariant of `Self`.
// So it's just an FFI call.
unsafe { bindings::phy_resolve_aneg_linkmode(phydev) };
}
/// Executes software reset the PHY via `BMCR_RESET` bit.
pub fn genphy_soft_reset(&mut self) -> Result {
let phydev = self.0.get();
// SAFETY: `phydev` is pointing to a valid object by the type invariant of `Self`.
// So it's just an FFI call.
to_result(unsafe { bindings::genphy_soft_reset(phydev) })
}
/// Initializes the PHY.
pub fn init_hw(&mut self) -> Result {
let phydev = self.0.get();
// SAFETY: `phydev` is pointing to a valid object by the type invariant of `Self`.
// So it's just an FFI call.
to_result(unsafe { bindings::phy_init_hw(phydev) })
}
/// Starts auto-negotiation.
pub fn start_aneg(&mut self) -> Result {
let phydev = self.0.get();
// SAFETY: `phydev` is pointing to a valid object by the type invariant of `Self`.
// So it's just an FFI call.
to_result(unsafe { bindings::_phy_start_aneg(phydev) })
}
/// Resumes the PHY via `BMCR_PDOWN` bit.
pub fn genphy_resume(&mut self) -> Result {
let phydev = self.0.get();
// SAFETY: `phydev` is pointing to a valid object by the type invariant of `Self`.
// So it's just an FFI call.
to_result(unsafe { bindings::genphy_resume(phydev) })
}
/// Suspends the PHY via `BMCR_PDOWN` bit.
pub fn genphy_suspend(&mut self) -> Result {
let phydev = self.0.get();
// SAFETY: `phydev` is pointing to a valid object by the type invariant of `Self`.
// So it's just an FFI call.
to_result(unsafe { bindings::genphy_suspend(phydev) })
}
/// Checks the link status and updates current link state.
pub fn genphy_read_status(&mut self) -> Result<u16> {
let phydev = self.0.get();
// SAFETY: `phydev` is pointing to a valid object by the type invariant of `Self`.
// So it's just an FFI call.
let ret = unsafe { bindings::genphy_read_status(phydev) };
if ret < 0 {
Err(Error::from_errno(ret))
} else {
Ok(ret as u16)
}
}
/// Updates the link status.
pub fn genphy_update_link(&mut self) -> Result {
let phydev = self.0.get();
// SAFETY: `phydev` is pointing to a valid object by the type invariant of `Self`.
// So it's just an FFI call.
to_result(unsafe { bindings::genphy_update_link(phydev) })
}
/// Reads link partner ability.
pub fn genphy_read_lpa(&mut self) -> Result {
let phydev = self.0.get();
// SAFETY: `phydev` is pointing to a valid object by the type invariant of `Self`.
// So it's just an FFI call.
to_result(unsafe { bindings::genphy_read_lpa(phydev) })
}
/// Reads PHY abilities.
pub fn genphy_read_abilities(&mut self) -> Result {
let phydev = self.0.get();
// SAFETY: `phydev` is pointing to a valid object by the type invariant of `Self`.
// So it's just an FFI call.
to_result(unsafe { bindings::genphy_read_abilities(phydev) })
}
}
/// Defines certain other features this PHY supports (like interrupts).
///
/// These flag values are used in [`Driver::FLAGS`].
pub mod flags {
/// PHY is internal.
pub const IS_INTERNAL: u32 = bindings::PHY_IS_INTERNAL;
/// PHY needs to be reset after the refclk is enabled.
pub const RST_AFTER_CLK_EN: u32 = bindings::PHY_RST_AFTER_CLK_EN;
/// Polling is used to detect PHY status changes.
pub const POLL_CABLE_TEST: u32 = bindings::PHY_POLL_CABLE_TEST;
/// Don't suspend.
pub const ALWAYS_CALL_SUSPEND: u32 = bindings::PHY_ALWAYS_CALL_SUSPEND;
}
/// An adapter for the registration of a PHY driver.
struct Adapter<T: Driver> {
_p: PhantomData<T>,
}
impl<T: Driver> Adapter<T> {
/// # Safety
///
/// `phydev` must be passed by the corresponding callback in `phy_driver`.
unsafe extern "C" fn soft_reset_callback(
phydev: *mut bindings::phy_device,
) -> core::ffi::c_int {
from_result(|| {
// SAFETY: This callback is called only in contexts
// where we hold `phy_device->lock`, so the accessors on
// `Device` are okay to call.
let dev = unsafe { Device::from_raw(phydev) };
T::soft_reset(dev)?;
Ok(0)
})
}
/// # Safety
///
/// `phydev` must be passed by the corresponding callback in `phy_driver`.
unsafe extern "C" fn get_features_callback(
phydev: *mut bindings::phy_device,
) -> core::ffi::c_int {
from_result(|| {
// SAFETY: This callback is called only in contexts
// where we hold `phy_device->lock`, so the accessors on
// `Device` are okay to call.
let dev = unsafe { Device::from_raw(phydev) };
T::get_features(dev)?;
Ok(0)
})
}
/// # Safety
///
/// `phydev` must be passed by the corresponding callback in `phy_driver`.
unsafe extern "C" fn suspend_callback(phydev: *mut bindings::phy_device) -> core::ffi::c_int {
from_result(|| {
// SAFETY: The C core code ensures that the accessors on
// `Device` are okay to call even though `phy_device->lock`
// might not be held.
let dev = unsafe { Device::from_raw(phydev) };
T::suspend(dev)?;
Ok(0)
})
}
/// # Safety
///
/// `phydev` must be passed by the corresponding callback in `phy_driver`.
unsafe extern "C" fn resume_callback(phydev: *mut bindings::phy_device) -> core::ffi::c_int {
from_result(|| {
// SAFETY: The C core code ensures that the accessors on
// `Device` are okay to call even though `phy_device->lock`
// might not be held.
let dev = unsafe { Device::from_raw(phydev) };
T::resume(dev)?;
Ok(0)
})
}
/// # Safety
///
/// `phydev` must be passed by the corresponding callback in `phy_driver`.
unsafe extern "C" fn config_aneg_callback(
phydev: *mut bindings::phy_device,
) -> core::ffi::c_int {
from_result(|| {
// SAFETY: This callback is called only in contexts
// where we hold `phy_device->lock`, so the accessors on
// `Device` are okay to call.
let dev = unsafe { Device::from_raw(phydev) };
T::config_aneg(dev)?;
Ok(0)
})
}
/// # Safety
///
/// `phydev` must be passed by the corresponding callback in `phy_driver`.
unsafe extern "C" fn read_status_callback(
phydev: *mut bindings::phy_device,
) -> core::ffi::c_int {
from_result(|| {
// SAFETY: This callback is called only in contexts
// where we hold `phy_device->lock`, so the accessors on
// `Device` are okay to call.
let dev = unsafe { Device::from_raw(phydev) };
T::read_status(dev)?;
Ok(0)
})
}
/// # Safety
///
/// `phydev` must be passed by the corresponding callback in `phy_driver`.
unsafe extern "C" fn match_phy_device_callback(
phydev: *mut bindings::phy_device,
) -> core::ffi::c_int {
// SAFETY: This callback is called only in contexts
// where we hold `phy_device->lock`, so the accessors on
// `Device` are okay to call.
let dev = unsafe { Device::from_raw(phydev) };
T::match_phy_device(dev) as i32
}
/// # Safety
///
/// `phydev` must be passed by the corresponding callback in `phy_driver`.
unsafe extern "C" fn read_mmd_callback(
phydev: *mut bindings::phy_device,
devnum: i32,
regnum: u16,
) -> i32 {
from_result(|| {
// SAFETY: This callback is called only in contexts
// where we hold `phy_device->lock`, so the accessors on
// `Device` are okay to call.
let dev = unsafe { Device::from_raw(phydev) };
// CAST: the C side verifies devnum < 32.
let ret = T::read_mmd(dev, devnum as u8, regnum)?;
Ok(ret.into())
})
}
/// # Safety
///
/// `phydev` must be passed by the corresponding callback in `phy_driver`.
unsafe extern "C" fn write_mmd_callback(
phydev: *mut bindings::phy_device,
devnum: i32,
regnum: u16,
val: u16,
) -> i32 {
from_result(|| {
// SAFETY: This callback is called only in contexts
// where we hold `phy_device->lock`, so the accessors on
// `Device` are okay to call.
let dev = unsafe { Device::from_raw(phydev) };
T::write_mmd(dev, devnum as u8, regnum, val)?;
Ok(0)
})
}
/// # Safety
///
/// `phydev` must be passed by the corresponding callback in `phy_driver`.
unsafe extern "C" fn link_change_notify_callback(phydev: *mut bindings::phy_device) {
// SAFETY: This callback is called only in contexts
// where we hold `phy_device->lock`, so the accessors on
// `Device` are okay to call.
let dev = unsafe { Device::from_raw(phydev) };
T::link_change_notify(dev);
}
}
/// Driver structure for a particular PHY type.
///
/// Wraps the kernel's [`struct phy_driver`].
/// This is used to register a driver for a particular PHY type with the kernel.
///
/// # Invariants
///
/// `self.0` is always in a valid state.
///
/// [`struct phy_driver`]: srctree/include/linux/phy.h
#[repr(transparent)]
pub struct DriverVTable(Opaque<bindings::phy_driver>);
// SAFETY: `DriverVTable` doesn't expose any &self method to access internal data, so it's safe to
// share `&DriverVTable` across execution context boundries.
unsafe impl Sync for DriverVTable {}
/// Creates a [`DriverVTable`] instance from [`Driver`].
///
/// This is used by [`module_phy_driver`] macro to create a static array of `phy_driver`.
///
/// [`module_phy_driver`]: crate::module_phy_driver
pub const fn create_phy_driver<T: Driver>() -> DriverVTable {
// INVARIANT: All the fields of `struct phy_driver` are initialized properly.
DriverVTable(Opaque::new(bindings::phy_driver {
name: T::NAME.as_char_ptr().cast_mut(),
flags: T::FLAGS,
phy_id: T::PHY_DEVICE_ID.id,
phy_id_mask: T::PHY_DEVICE_ID.mask_as_int(),
soft_reset: if T::HAS_SOFT_RESET {
Some(Adapter::<T>::soft_reset_callback)
} else {
None
},
get_features: if T::HAS_GET_FEATURES {
Some(Adapter::<T>::get_features_callback)
} else {
None
},
match_phy_device: if T::HAS_MATCH_PHY_DEVICE {
Some(Adapter::<T>::match_phy_device_callback)
} else {
None
},
suspend: if T::HAS_SUSPEND {
Some(Adapter::<T>::suspend_callback)
} else {
None
},
resume: if T::HAS_RESUME {
Some(Adapter::<T>::resume_callback)
} else {
None
},
config_aneg: if T::HAS_CONFIG_ANEG {
Some(Adapter::<T>::config_aneg_callback)
} else {
None
},
read_status: if T::HAS_READ_STATUS {
Some(Adapter::<T>::read_status_callback)
} else {
None
},
read_mmd: if T::HAS_READ_MMD {
Some(Adapter::<T>::read_mmd_callback)
} else {
None
},
write_mmd: if T::HAS_WRITE_MMD {
Some(Adapter::<T>::write_mmd_callback)
} else {
None
},
link_change_notify: if T::HAS_LINK_CHANGE_NOTIFY {
Some(Adapter::<T>::link_change_notify_callback)
} else {
None
},
// SAFETY: The rest is zeroed out to initialize `struct phy_driver`,
// sets `Option<&F>` to be `None`.
..unsafe { core::mem::MaybeUninit::<bindings::phy_driver>::zeroed().assume_init() }
}))
}
/// Driver implementation for a particular PHY type.
///
/// This trait is used to create a [`DriverVTable`].
#[vtable]
pub trait Driver {
/// Defines certain other features this PHY supports.
/// It is a combination of the flags in the [`flags`] module.
const FLAGS: u32 = 0;
/// The friendly name of this PHY type.
const NAME: &'static CStr;
/// This driver only works for PHYs with IDs which match this field.
/// The default id and mask are zero.
const PHY_DEVICE_ID: DeviceId = DeviceId::new_with_custom_mask(0, 0);
/// Issues a PHY software reset.
fn soft_reset(_dev: &mut Device) -> Result {
kernel::build_error(VTABLE_DEFAULT_ERROR)
}
/// Probes the hardware to determine what abilities it has.
fn get_features(_dev: &mut Device) -> Result {
kernel::build_error(VTABLE_DEFAULT_ERROR)
}
/// Returns true if this is a suitable driver for the given phydev.
/// If not implemented, matching is based on [`Driver::PHY_DEVICE_ID`].
fn match_phy_device(_dev: &Device) -> bool {
false
}
/// Configures the advertisement and resets auto-negotiation
/// if auto-negotiation is enabled.
fn config_aneg(_dev: &mut Device) -> Result {
kernel::build_error(VTABLE_DEFAULT_ERROR)
}
/// Determines the negotiated speed and duplex.
fn read_status(_dev: &mut Device) -> Result<u16> {
kernel::build_error(VTABLE_DEFAULT_ERROR)
}
/// Suspends the hardware, saving state if needed.
fn suspend(_dev: &mut Device) -> Result {
kernel::build_error(VTABLE_DEFAULT_ERROR)
}
/// Resumes the hardware, restoring state if needed.
fn resume(_dev: &mut Device) -> Result {
kernel::build_error(VTABLE_DEFAULT_ERROR)
}
/// Overrides the default MMD read function for reading a MMD register.
fn read_mmd(_dev: &mut Device, _devnum: u8, _regnum: u16) -> Result<u16> {
kernel::build_error(VTABLE_DEFAULT_ERROR)
}
/// Overrides the default MMD write function for writing a MMD register.
fn write_mmd(_dev: &mut Device, _devnum: u8, _regnum: u16, _val: u16) -> Result {
kernel::build_error(VTABLE_DEFAULT_ERROR)
}
/// Callback for notification of link change.
fn link_change_notify(_dev: &mut Device) {}
}
/// Registration structure for PHY drivers.
///
/// Registers [`DriverVTable`] instances with the kernel. They will be unregistered when dropped.
///
/// # Invariants
///
/// The `drivers` slice are currently registered to the kernel via `phy_drivers_register`.
pub struct Registration {
drivers: Pin<&'static mut [DriverVTable]>,
}
impl Registration {
/// Registers a PHY driver.
pub fn register(
module: &'static crate::ThisModule,
drivers: Pin<&'static mut [DriverVTable]>,
) -> Result<Self> {
if drivers.is_empty() {
return Err(code::EINVAL);
}
// SAFETY: The type invariants of [`DriverVTable`] ensure that all elements of
// the `drivers` slice are initialized properly. `drivers` will not be moved.
// So it's just an FFI call.
to_result(unsafe {
bindings::phy_drivers_register(drivers[0].0.get(), drivers.len().try_into()?, module.0)
})?;
// INVARIANT: The `drivers` slice is successfully registered to the kernel via `phy_drivers_register`.
Ok(Registration { drivers })
}
}
impl Drop for Registration {
fn drop(&mut self) {
// SAFETY: The type invariants guarantee that `self.drivers` is valid.
// So it's just an FFI call.
unsafe {
bindings::phy_drivers_unregister(self.drivers[0].0.get(), self.drivers.len() as i32)
};
}
}
/// An identifier for PHY devices on an MDIO/MII bus.
///
/// Represents the kernel's `struct mdio_device_id`. This is used to find an appropriate
/// PHY driver.
pub struct DeviceId {
id: u32,
mask: DeviceMask,
}
impl DeviceId {
/// Creates a new instance with the exact match mask.
pub const fn new_with_exact_mask(id: u32) -> Self {
DeviceId {
id,
mask: DeviceMask::Exact,
}
}
/// Creates a new instance with the model match mask.
pub const fn new_with_model_mask(id: u32) -> Self {
DeviceId {
id,
mask: DeviceMask::Model,
}
}
/// Creates a new instance with the vendor match mask.
pub const fn new_with_vendor_mask(id: u32) -> Self {
DeviceId {
id,
mask: DeviceMask::Vendor,
}
}
/// Creates a new instance with a custom match mask.
pub const fn new_with_custom_mask(id: u32, mask: u32) -> Self {
DeviceId {
id,
mask: DeviceMask::Custom(mask),
}
}
/// Creates a new instance from [`Driver`].
pub const fn new_with_driver<T: Driver>() -> Self {
T::PHY_DEVICE_ID
}
/// Get a `mask` as u32.
pub const fn mask_as_int(&self) -> u32 {
self.mask.as_int()
}
// macro use only
#[doc(hidden)]
pub const fn mdio_device_id(&self) -> bindings::mdio_device_id {
bindings::mdio_device_id {
phy_id: self.id,
phy_id_mask: self.mask.as_int(),
}
}
}
enum DeviceMask {
Exact,
Model,
Vendor,
Custom(u32),
}
impl DeviceMask {
const MASK_EXACT: u32 = !0;
const MASK_MODEL: u32 = !0 << 4;
const MASK_VENDOR: u32 = !0 << 10;
const fn as_int(&self) -> u32 {
match self {
DeviceMask::Exact => Self::MASK_EXACT,
DeviceMask::Model => Self::MASK_MODEL,
DeviceMask::Vendor => Self::MASK_VENDOR,
DeviceMask::Custom(mask) => *mask,
}
}
}
/// Declares a kernel module for PHYs drivers.
///
/// This creates a static array of kernel's `struct phy_driver` and registers it.
/// This also corresponds to the kernel's `MODULE_DEVICE_TABLE` macro, which embeds the information
/// for module loading into the module binary file. Every driver needs an entry in `device_table`.
///
/// # Examples
///
/// ```
/// # mod module_phy_driver_sample {
/// use kernel::c_str;
/// use kernel::net::phy::{self, DeviceId};
/// use kernel::prelude::*;
///
/// kernel::module_phy_driver! {
/// drivers: [PhySample],
/// device_table: [
/// DeviceId::new_with_driver::<PhySample>()
/// ],
/// name: "rust_sample_phy",
/// author: "Rust for Linux Contributors",
/// description: "Rust sample PHYs driver",
/// license: "GPL",
/// }
///
/// struct PhySample;
///
/// #[vtable]
/// impl phy::Driver for PhySample {
/// const NAME: &'static CStr = c_str!("PhySample");
/// const PHY_DEVICE_ID: phy::DeviceId = phy::DeviceId::new_with_exact_mask(0x00000001);
/// }
/// # }
/// ```
///
/// This expands to the following code:
///
/// ```ignore
/// use kernel::c_str;
/// use kernel::net::phy::{self, DeviceId};
/// use kernel::prelude::*;
///
/// struct Module {
/// _reg: ::kernel::net::phy::Registration,
/// }
///
/// module! {
/// type: Module,
/// name: "rust_sample_phy",
/// author: "Rust for Linux Contributors",
/// description: "Rust sample PHYs driver",
/// license: "GPL",
/// }
///
/// struct PhySample;
///
/// #[vtable]
/// impl phy::Driver for PhySample {
/// const NAME: &'static CStr = c_str!("PhySample");
/// const PHY_DEVICE_ID: phy::DeviceId = phy::DeviceId::new_with_exact_mask(0x00000001);
/// }
///
/// const _: () = {
/// static mut DRIVERS: [::kernel::net::phy::DriverVTable; 1] =
/// [::kernel::net::phy::create_phy_driver::<PhySample>()];
///
/// impl ::kernel::Module for Module {
/// fn init(module: &'static ThisModule) -> Result<Self> {
/// let drivers = unsafe { &mut DRIVERS };
/// let mut reg = ::kernel::net::phy::Registration::register(
/// module,
/// ::core::pin::Pin::static_mut(drivers),
/// )?;
/// Ok(Module { _reg: reg })
/// }
/// }
/// };
///
/// #[cfg(MODULE)]
/// #[no_mangle]
/// static __mod_mdio__phydev_device_table: [::kernel::bindings::mdio_device_id; 2] = [
/// ::kernel::bindings::mdio_device_id {
/// phy_id: 0x00000001,
/// phy_id_mask: 0xffffffff,
/// },
/// ::kernel::bindings::mdio_device_id {
/// phy_id: 0,
/// phy_id_mask: 0,
/// },
/// ];
/// ```
#[macro_export]
macro_rules! module_phy_driver {
(@replace_expr $_t:tt $sub:expr) => {$sub};
(@count_devices $($x:expr),*) => {
0usize $(+ $crate::module_phy_driver!(@replace_expr $x 1usize))*
};
(@device_table [$($dev:expr),+]) => {
// SAFETY: C will not read off the end of this constant since the last element is zero.
#[cfg(MODULE)]
#[no_mangle]
static __mod_mdio__phydev_device_table: [$crate::bindings::mdio_device_id;
$crate::module_phy_driver!(@count_devices $($dev),+) + 1] = [
$($dev.mdio_device_id()),+,
$crate::bindings::mdio_device_id {
phy_id: 0,
phy_id_mask: 0
}
];
};
(drivers: [$($driver:ident),+ $(,)?], device_table: [$($dev:expr),+ $(,)?], $($f:tt)*) => {
struct Module {
_reg: $crate::net::phy::Registration,
}
$crate::prelude::module! {
type: Module,
$($f)*
}
const _: () = {
static mut DRIVERS: [$crate::net::phy::DriverVTable;
$crate::module_phy_driver!(@count_devices $($driver),+)] =
[$($crate::net::phy::create_phy_driver::<$driver>()),+];
impl $crate::Module for Module {
fn init(module: &'static ThisModule) -> Result<Self> {
// SAFETY: The anonymous constant guarantees that nobody else can access
// the `DRIVERS` static. The array is used only in the C side.
let drivers = unsafe { &mut DRIVERS };
let mut reg = $crate::net::phy::Registration::register(
module,
::core::pin::Pin::static_mut(drivers),
)?;
Ok(Module { _reg: reg })
}
}
};
$crate::module_phy_driver!(@device_table [$($dev),+]);
}
}