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linux/rust/kernel/opp.rs
Linus Torvalds 784faa8eca Merge tag 'rust-6.19' of git://git.kernel.org/pub/scm/linux/kernel/git/ojeda/linux 
Pull Rust updates from Miguel Ojeda:
 "Toolchain and infrastructure:

   - Add support for 'syn'.

     Syn is a parsing library for parsing a stream of Rust tokens into a
     syntax tree of Rust source code.

     Currently this library is geared toward use in Rust procedural
     macros, but contains some APIs that may be useful more generally.

     'syn' allows us to greatly simplify writing complex macros such as
     'pin-init' (Benno has already prepared the 'syn'-based version). We
     will use it in the 'macros' crate too.

     'syn' is the most downloaded Rust crate (according to crates.io),
     and it is also used by the Rust compiler itself. While the amount
     of code is substantial, there should not be many updates needed for
     these crates, and even if there are, they should not be too big,
     e.g. +7k -3k lines across the 3 crates in the last year.

     'syn' requires two smaller dependencies: 'quote' and 'proc-macro2'.
     I only modified their code to remove a third dependency
     ('unicode-ident') and to add the SPDX identifiers. The code can be
     easily verified to exactly match upstream with the provided
     scripts.

     They are all licensed under "Apache-2.0 OR MIT", like the other
     vendored 'alloc' crate we had for a while.

     Please see the merge commit with the cover letter for more context.

   - Allow 'unreachable_pub' and 'clippy::disallowed_names' for
     doctests.

     Examples (i.e. doctests) may want to do things like show public
     items and use names such as 'foo'.

     Nevertheless, we still try to keep examples as close to real code
     as possible (this is part of why running Clippy on doctests is
     important for us, e.g. for safety comments, which userspace Rust
     does not support yet but we are stricter).

  'kernel' crate:

   - Replace our custom 'CStr' type with 'core::ffi::CStr'.

     Using the standard library type reduces our custom code footprint,
     and we retain needed custom functionality through an extension
     trait and a new 'fmt!' macro which replaces the previous 'core'
     import.

     This started in 6.17 and continued in 6.18, and we finally land the
     replacement now. This required quite some stamina from Tamir, who
     split the changes in steps to prepare for the flag day change here.

   - Replace 'kernel::c_str!' with C string literals.

     C string literals were added in Rust 1.77, which produce '&CStr's
     (the 'core' one), so now we can write:

         c"hi"

     instead of:

         c_str!("hi")

   - Add 'num' module for numerical features.

     It includes the 'Integer' trait, implemented for all primitive
     integer types.

     It also includes the 'Bounded' integer wrapping type: an integer
     value that requires only the 'N' least significant bits of the
     wrapped type to be encoded:

         // An unsigned 8-bit integer, of which only the 4 LSBs are used.
         let v = Bounded::<u8, 4>:🆕:<15>();
         assert_eq!(v.get(), 15);

     'Bounded' is useful to e.g. enforce guarantees when working with
     bitfields that have an arbitrary number of bits.

     Values can also be constructed from simple non-constant expressions
     or, for more complex ones, validated at runtime.

     'Bounded' also comes with comparison and arithmetic operations
     (with both their backing type and other 'Bounded's with a
     compatible backing type), casts to change the backing type,
     extending/shrinking and infallible/fallible conversions from/to
     primitives as applicable.

   - 'rbtree' module: add immutable cursor ('Cursor').

     It enables to use just an immutable tree reference where
     appropriate. The existing fully-featured mutable cursor is renamed
     to 'CursorMut'.

  kallsyms:

   - Fix wrong "big" kernel symbol type read from procfs.

  'pin-init' crate:

   - A couple minor fixes (Benno asked me to pick these patches up for
     him this cycle).

  Documentation:

   - Quick Start guide: add Debian 13 (Trixie).

     Debian Stable is now able to build Linux, since Debian 13 (released
     2025-08-09) packages Rust 1.85.0, which is recent enough.

     We are planning to propose that the minimum supported Rust version
     in Linux follows Debian Stable releases, with Debian 13 being the
     first one we upgrade to, i.e. Rust 1.85.

  MAINTAINERS:

   - Add entry for the new 'num' module.

   - Remove Alex as Rust maintainer: he hasn't had the time to
     contribute for a few years now, so it is a no-op change in
     practice.

  And a few other cleanups and improvements"

* tag 'rust-6.19' of git://git.kernel.org/pub/scm/linux/kernel/git/ojeda/linux: (53 commits)
  rust: macros: support `proc-macro2`, `quote` and `syn`
  rust: syn: enable support in kbuild
  rust: syn: add `README.md`
  rust: syn: remove `unicode-ident` dependency
  rust: syn: add SPDX License Identifiers
  rust: syn: import crate
  rust: quote: enable support in kbuild
  rust: quote: add `README.md`
  rust: quote: add SPDX License Identifiers
  rust: quote: import crate
  rust: proc-macro2: enable support in kbuild
  rust: proc-macro2: add `README.md`
  rust: proc-macro2: remove `unicode_ident` dependency
  rust: proc-macro2: add SPDX License Identifiers
  rust: proc-macro2: import crate
  rust: kbuild: support using libraries in `rustc_procmacro`
  rust: kbuild: support skipping flags in `rustc_test_library`
  rust: kbuild: add proc macro library support
  rust: kbuild: simplify `--cfg` handling
  rust: kbuild: introduce `core-flags` and `core-skip_flags`
  ...
2025-12-03 14:16:49 -08:00

1146 lines
38 KiB
Rust
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// SPDX-License-Identifier: GPL-2.0
//! Operating performance points.
//!
//! This module provides rust abstractions for interacting with the OPP subsystem.
//!
//! C header: [`include/linux/pm_opp.h`](srctree/include/linux/pm_opp.h)
//!
//! Reference: <https://docs.kernel.org/power/opp.html>
use crate::{
clk::Hertz,
cpumask::{Cpumask, CpumaskVar},
device::Device,
error::{code::*, from_err_ptr, from_result, to_result, Result, VTABLE_DEFAULT_ERROR},
ffi::{c_char, c_ulong},
prelude::*,
str::CString,
sync::aref::{ARef, AlwaysRefCounted},
types::Opaque,
};
#[cfg(CONFIG_CPU_FREQ)]
/// Frequency table implementation.
mod freq {
use super::*;
use crate::cpufreq;
use core::ops::Deref;
/// OPP frequency table.
///
/// A [`cpufreq::Table`] created from [`Table`].
pub struct FreqTable {
dev: ARef<Device>,
ptr: *mut bindings::cpufreq_frequency_table,
}
impl FreqTable {
/// Creates a new instance of [`FreqTable`] from [`Table`].
pub(crate) fn new(table: &Table) -> Result<Self> {
let mut ptr: *mut bindings::cpufreq_frequency_table = ptr::null_mut();
// SAFETY: The requirements are satisfied by the existence of [`Device`] and its safety
// requirements.
to_result(unsafe {
bindings::dev_pm_opp_init_cpufreq_table(table.dev.as_raw(), &mut ptr)
})?;
Ok(Self {
dev: table.dev.clone(),
ptr,
})
}
/// Returns a reference to the underlying [`cpufreq::Table`].
#[inline]
fn table(&self) -> &cpufreq::Table {
// SAFETY: The `ptr` is guaranteed by the C code to be valid.
unsafe { cpufreq::Table::from_raw(self.ptr) }
}
}
impl Deref for FreqTable {
type Target = cpufreq::Table;
#[inline]
fn deref(&self) -> &Self::Target {
self.table()
}
}
impl Drop for FreqTable {
fn drop(&mut self) {
// SAFETY: The pointer was created via `dev_pm_opp_init_cpufreq_table`, and is only
// freed here.
unsafe {
bindings::dev_pm_opp_free_cpufreq_table(self.dev.as_raw(), &mut self.as_raw())
};
}
}
}
#[cfg(CONFIG_CPU_FREQ)]
pub use freq::FreqTable;
use core::{marker::PhantomData, ptr};
use macros::vtable;
/// Creates a null-terminated slice of pointers to [`CString`]s.
fn to_c_str_array(names: &[CString]) -> Result<KVec<*const c_char>> {
// Allocated a null-terminated vector of pointers.
let mut list = KVec::with_capacity(names.len() + 1, GFP_KERNEL)?;
for name in names.iter() {
list.push(name.as_char_ptr(), GFP_KERNEL)?;
}
list.push(ptr::null(), GFP_KERNEL)?;
Ok(list)
}
/// The voltage unit.
///
/// Represents voltage in microvolts, wrapping a [`c_ulong`] value.
///
/// # Examples
///
/// ```
/// use kernel::opp::MicroVolt;
///
/// let raw = 90500;
/// let volt = MicroVolt(raw);
///
/// assert_eq!(usize::from(volt), raw);
/// assert_eq!(volt, MicroVolt(raw));
/// ```
#[derive(Copy, Clone, PartialEq, Eq, Debug)]
pub struct MicroVolt(pub c_ulong);
impl From<MicroVolt> for c_ulong {
#[inline]
fn from(volt: MicroVolt) -> Self {
volt.0
}
}
/// The power unit.
///
/// Represents power in microwatts, wrapping a [`c_ulong`] value.
///
/// # Examples
///
/// ```
/// use kernel::opp::MicroWatt;
///
/// let raw = 1000000;
/// let power = MicroWatt(raw);
///
/// assert_eq!(usize::from(power), raw);
/// assert_eq!(power, MicroWatt(raw));
/// ```
#[derive(Copy, Clone, PartialEq, Eq, Debug)]
pub struct MicroWatt(pub c_ulong);
impl From<MicroWatt> for c_ulong {
#[inline]
fn from(power: MicroWatt) -> Self {
power.0
}
}
/// Handle for a dynamically created [`OPP`].
///
/// The associated [`OPP`] is automatically removed when the [`Token`] is dropped.
///
/// # Examples
///
/// The following example demonstrates how to create an [`OPP`] dynamically.
///
/// ```
/// use kernel::clk::Hertz;
/// use kernel::device::Device;
/// use kernel::error::Result;
/// use kernel::opp::{Data, MicroVolt, Token};
/// use kernel::sync::aref::ARef;
///
/// fn create_opp(dev: &ARef<Device>, freq: Hertz, volt: MicroVolt, level: u32) -> Result<Token> {
/// let data = Data::new(freq, volt, level, false);
///
/// // OPP is removed once token goes out of scope.
/// data.add_opp(dev)
/// }
/// ```
pub struct Token {
dev: ARef<Device>,
freq: Hertz,
}
impl Token {
/// Dynamically adds an [`OPP`] and returns a [`Token`] that removes it on drop.
fn new(dev: &ARef<Device>, mut data: Data) -> Result<Self> {
// SAFETY: The requirements are satisfied by the existence of [`Device`] and its safety
// requirements.
to_result(unsafe { bindings::dev_pm_opp_add_dynamic(dev.as_raw(), &mut data.0) })?;
Ok(Self {
dev: dev.clone(),
freq: data.freq(),
})
}
}
impl Drop for Token {
fn drop(&mut self) {
// SAFETY: The requirements are satisfied by the existence of [`Device`] and its safety
// requirements.
unsafe { bindings::dev_pm_opp_remove(self.dev.as_raw(), self.freq.into()) };
}
}
/// OPP data.
///
/// Rust abstraction for the C `struct dev_pm_opp_data`, used to define operating performance
/// points (OPPs) dynamically.
///
/// # Examples
///
/// The following example demonstrates how to create an [`OPP`] with [`Data`].
///
/// ```
/// use kernel::clk::Hertz;
/// use kernel::device::Device;
/// use kernel::error::Result;
/// use kernel::opp::{Data, MicroVolt, Token};
/// use kernel::sync::aref::ARef;
///
/// fn create_opp(dev: &ARef<Device>, freq: Hertz, volt: MicroVolt, level: u32) -> Result<Token> {
/// let data = Data::new(freq, volt, level, false);
///
/// // OPP is removed once token goes out of scope.
/// data.add_opp(dev)
/// }
/// ```
#[repr(transparent)]
pub struct Data(bindings::dev_pm_opp_data);
impl Data {
/// Creates a new instance of [`Data`].
///
/// This can be used to define a dynamic OPP to be added to a device.
pub fn new(freq: Hertz, volt: MicroVolt, level: u32, turbo: bool) -> Self {
Self(bindings::dev_pm_opp_data {
turbo,
freq: freq.into(),
u_volt: volt.into(),
level,
})
}
/// Adds an [`OPP`] dynamically.
///
/// Returns a [`Token`] that ensures the OPP is automatically removed
/// when it goes out of scope.
#[inline]
pub fn add_opp(self, dev: &ARef<Device>) -> Result<Token> {
Token::new(dev, self)
}
/// Returns the frequency associated with this OPP data.
#[inline]
fn freq(&self) -> Hertz {
Hertz(self.0.freq)
}
}
/// [`OPP`] search options.
///
/// # Examples
///
/// Defines how to search for an [`OPP`] in a [`Table`] relative to a frequency.
///
/// ```
/// use kernel::clk::Hertz;
/// use kernel::error::Result;
/// use kernel::opp::{OPP, SearchType, Table};
/// use kernel::sync::aref::ARef;
///
/// fn find_opp(table: &Table, freq: Hertz) -> Result<ARef<OPP>> {
/// let opp = table.opp_from_freq(freq, Some(true), None, SearchType::Exact)?;
///
/// pr_info!("OPP frequency is: {:?}\n", opp.freq(None));
/// pr_info!("OPP voltage is: {:?}\n", opp.voltage());
/// pr_info!("OPP level is: {}\n", opp.level());
/// pr_info!("OPP power is: {:?}\n", opp.power());
///
/// Ok(opp)
/// }
/// ```
#[derive(Copy, Clone, Debug, Eq, PartialEq)]
pub enum SearchType {
/// Match the exact frequency.
Exact,
/// Find the highest frequency less than or equal to the given value.
Floor,
/// Find the lowest frequency greater than or equal to the given value.
Ceil,
}
/// OPP configuration callbacks.
///
/// Implement this trait to customize OPP clock and regulator setup for your device.
#[vtable]
pub trait ConfigOps {
/// This is typically used to scale clocks when transitioning between OPPs.
#[inline]
fn config_clks(_dev: &Device, _table: &Table, _opp: &OPP, _scaling_down: bool) -> Result {
build_error!(VTABLE_DEFAULT_ERROR)
}
/// This provides access to the old and new OPPs, allowing for safe regulator adjustments.
#[inline]
fn config_regulators(
_dev: &Device,
_opp_old: &OPP,
_opp_new: &OPP,
_data: *mut *mut bindings::regulator,
_count: u32,
) -> Result {
build_error!(VTABLE_DEFAULT_ERROR)
}
}
/// OPP configuration token.
///
/// Returned by the OPP core when configuration is applied to a [`Device`]. The associated
/// configuration is automatically cleared when the token is dropped.
pub struct ConfigToken(i32);
impl Drop for ConfigToken {
fn drop(&mut self) {
// SAFETY: This is the same token value returned by the C code via `dev_pm_opp_set_config`.
unsafe { bindings::dev_pm_opp_clear_config(self.0) };
}
}
/// OPP configurations.
///
/// Rust abstraction for the C `struct dev_pm_opp_config`.
///
/// # Examples
///
/// The following example demonstrates how to set OPP property-name configuration for a [`Device`].
///
/// ```
/// use kernel::device::Device;
/// use kernel::error::Result;
/// use kernel::opp::{Config, ConfigOps, ConfigToken};
/// use kernel::str::CString;
/// use kernel::sync::aref::ARef;
/// use kernel::macros::vtable;
///
/// #[derive(Default)]
/// struct Driver;
///
/// #[vtable]
/// impl ConfigOps for Driver {}
///
/// fn configure(dev: &ARef<Device>) -> Result<ConfigToken> {
/// let name = CString::try_from_fmt(fmt!("slow"))?;
///
/// // The OPP configuration is cleared once the [`ConfigToken`] goes out of scope.
/// Config::<Driver>::new()
/// .set_prop_name(name)?
/// .set(dev)
/// }
/// ```
#[derive(Default)]
pub struct Config<T: ConfigOps>
where
T: Default,
{
clk_names: Option<KVec<CString>>,
prop_name: Option<CString>,
regulator_names: Option<KVec<CString>>,
supported_hw: Option<KVec<u32>>,
// Tuple containing (required device, index)
required_dev: Option<(ARef<Device>, u32)>,
_data: PhantomData<T>,
}
impl<T: ConfigOps + Default> Config<T> {
/// Creates a new instance of [`Config`].
#[inline]
pub fn new() -> Self {
Self::default()
}
/// Initializes clock names.
pub fn set_clk_names(mut self, names: KVec<CString>) -> Result<Self> {
if self.clk_names.is_some() {
return Err(EBUSY);
}
if names.is_empty() {
return Err(EINVAL);
}
self.clk_names = Some(names);
Ok(self)
}
/// Initializes property name.
pub fn set_prop_name(mut self, name: CString) -> Result<Self> {
if self.prop_name.is_some() {
return Err(EBUSY);
}
self.prop_name = Some(name);
Ok(self)
}
/// Initializes regulator names.
pub fn set_regulator_names(mut self, names: KVec<CString>) -> Result<Self> {
if self.regulator_names.is_some() {
return Err(EBUSY);
}
if names.is_empty() {
return Err(EINVAL);
}
self.regulator_names = Some(names);
Ok(self)
}
/// Initializes required devices.
pub fn set_required_dev(mut self, dev: ARef<Device>, index: u32) -> Result<Self> {
if self.required_dev.is_some() {
return Err(EBUSY);
}
self.required_dev = Some((dev, index));
Ok(self)
}
/// Initializes supported hardware.
pub fn set_supported_hw(mut self, hw: KVec<u32>) -> Result<Self> {
if self.supported_hw.is_some() {
return Err(EBUSY);
}
if hw.is_empty() {
return Err(EINVAL);
}
self.supported_hw = Some(hw);
Ok(self)
}
/// Sets the configuration with the OPP core.
///
/// The returned [`ConfigToken`] will remove the configuration when dropped.
pub fn set(self, dev: &Device) -> Result<ConfigToken> {
let clk_names = self.clk_names.as_deref().map(to_c_str_array).transpose()?;
let regulator_names = self
.regulator_names
.as_deref()
.map(to_c_str_array)
.transpose()?;
let set_config = || {
let clk_names = clk_names.as_ref().map_or(ptr::null(), |c| c.as_ptr());
let regulator_names = regulator_names.as_ref().map_or(ptr::null(), |c| c.as_ptr());
let prop_name = self
.prop_name
.as_ref()
.map_or(ptr::null(), |p| p.as_char_ptr());
let (supported_hw, supported_hw_count) = self
.supported_hw
.as_ref()
.map_or((ptr::null(), 0), |hw| (hw.as_ptr(), hw.len() as u32));
let (required_dev, required_dev_index) = self
.required_dev
.as_ref()
.map_or((ptr::null_mut(), 0), |(dev, idx)| (dev.as_raw(), *idx));
let mut config = bindings::dev_pm_opp_config {
clk_names,
config_clks: if T::HAS_CONFIG_CLKS {
Some(Self::config_clks)
} else {
None
},
prop_name,
regulator_names,
config_regulators: if T::HAS_CONFIG_REGULATORS {
Some(Self::config_regulators)
} else {
None
},
supported_hw,
supported_hw_count,
required_dev,
required_dev_index,
};
// SAFETY: The requirements are satisfied by the existence of [`Device`] and its safety
// requirements. The OPP core guarantees not to access fields of [`Config`] after this
// call and so we don't need to save a copy of them for future use.
let ret = unsafe { bindings::dev_pm_opp_set_config(dev.as_raw(), &mut config) };
to_result(ret).map(|()| ConfigToken(ret))
};
// Ensure the closure does not accidentally drop owned data; if violated, the compiler
// produces E0525 with e.g.:
//
// ```
// closure is `FnOnce` because it moves the variable `clk_names` out of its environment
// ```
let _: &dyn Fn() -> _ = &set_config;
set_config()
}
/// Config's clk callback.
///
/// SAFETY: Called from C. Inputs must be valid pointers.
extern "C" fn config_clks(
dev: *mut bindings::device,
opp_table: *mut bindings::opp_table,
opp: *mut bindings::dev_pm_opp,
_data: *mut c_void,
scaling_down: bool,
) -> c_int {
from_result(|| {
// SAFETY: 'dev' is guaranteed by the C code to be valid.
let dev = unsafe { Device::get_device(dev) };
T::config_clks(
&dev,
// SAFETY: 'opp_table' is guaranteed by the C code to be valid.
&unsafe { Table::from_raw_table(opp_table, &dev) },
// SAFETY: 'opp' is guaranteed by the C code to be valid.
unsafe { OPP::from_raw_opp(opp)? },
scaling_down,
)
.map(|()| 0)
})
}
/// Config's regulator callback.
///
/// SAFETY: Called from C. Inputs must be valid pointers.
extern "C" fn config_regulators(
dev: *mut bindings::device,
old_opp: *mut bindings::dev_pm_opp,
new_opp: *mut bindings::dev_pm_opp,
regulators: *mut *mut bindings::regulator,
count: c_uint,
) -> c_int {
from_result(|| {
// SAFETY: 'dev' is guaranteed by the C code to be valid.
let dev = unsafe { Device::get_device(dev) };
T::config_regulators(
&dev,
// SAFETY: 'old_opp' is guaranteed by the C code to be valid.
unsafe { OPP::from_raw_opp(old_opp)? },
// SAFETY: 'new_opp' is guaranteed by the C code to be valid.
unsafe { OPP::from_raw_opp(new_opp)? },
regulators,
count,
)
.map(|()| 0)
})
}
}
/// A reference-counted OPP table.
///
/// Rust abstraction for the C `struct opp_table`.
///
/// # Invariants
///
/// The pointer stored in `Self` is non-null and valid for the lifetime of the [`Table`].
///
/// Instances of this type are reference-counted.
///
/// # Examples
///
/// The following example demonstrates how to get OPP [`Table`] for a [`Cpumask`] and set its
/// frequency.
///
/// ```
/// # #![cfg(CONFIG_OF)]
/// use kernel::clk::Hertz;
/// use kernel::cpumask::Cpumask;
/// use kernel::device::Device;
/// use kernel::error::Result;
/// use kernel::opp::Table;
/// use kernel::sync::aref::ARef;
///
/// fn get_table(dev: &ARef<Device>, mask: &mut Cpumask, freq: Hertz) -> Result<Table> {
/// let mut opp_table = Table::from_of_cpumask(dev, mask)?;
///
/// if opp_table.opp_count()? == 0 {
/// return Err(EINVAL);
/// }
///
/// pr_info!("Max transition latency is: {} ns\n", opp_table.max_transition_latency_ns());
/// pr_info!("Suspend frequency is: {:?}\n", opp_table.suspend_freq());
///
/// opp_table.set_rate(freq)?;
/// Ok(opp_table)
/// }
/// ```
pub struct Table {
ptr: *mut bindings::opp_table,
dev: ARef<Device>,
#[allow(dead_code)]
em: bool,
#[allow(dead_code)]
of: bool,
cpus: Option<CpumaskVar>,
}
/// SAFETY: It is okay to send ownership of [`Table`] across thread boundaries.
unsafe impl Send for Table {}
/// SAFETY: It is okay to access [`Table`] through shared references from other threads because
/// we're either accessing properties that don't change or that are properly synchronised by C code.
unsafe impl Sync for Table {}
impl Table {
/// Creates a new reference-counted [`Table`] from a raw pointer.
///
/// # Safety
///
/// Callers must ensure that `ptr` is valid and non-null.
unsafe fn from_raw_table(ptr: *mut bindings::opp_table, dev: &ARef<Device>) -> Self {
// SAFETY: By the safety requirements, ptr is valid and its refcount will be incremented.
//
// INVARIANT: The reference-count is decremented when [`Table`] goes out of scope.
unsafe { bindings::dev_pm_opp_get_opp_table_ref(ptr) };
Self {
ptr,
dev: dev.clone(),
em: false,
of: false,
cpus: None,
}
}
/// Creates a new reference-counted [`Table`] instance for a [`Device`].
pub fn from_dev(dev: &Device) -> Result<Self> {
// SAFETY: The requirements are satisfied by the existence of the [`Device`] and its safety
// requirements.
//
// INVARIANT: The reference-count is incremented by the C code and is decremented when
// [`Table`] goes out of scope.
let ptr = from_err_ptr(unsafe { bindings::dev_pm_opp_get_opp_table(dev.as_raw()) })?;
Ok(Self {
ptr,
dev: dev.into(),
em: false,
of: false,
cpus: None,
})
}
/// Creates a new reference-counted [`Table`] instance for a [`Device`] based on device tree
/// entries.
#[cfg(CONFIG_OF)]
pub fn from_of(dev: &ARef<Device>, index: i32) -> Result<Self> {
// SAFETY: The requirements are satisfied by the existence of the [`Device`] and its safety
// requirements.
//
// INVARIANT: The reference-count is incremented by the C code and is decremented when
// [`Table`] goes out of scope.
to_result(unsafe { bindings::dev_pm_opp_of_add_table_indexed(dev.as_raw(), index) })?;
// Get the newly created [`Table`].
let mut table = Self::from_dev(dev)?;
table.of = true;
Ok(table)
}
/// Remove device tree based [`Table`].
#[cfg(CONFIG_OF)]
#[inline]
fn remove_of(&self) {
// SAFETY: The requirements are satisfied by the existence of the [`Device`] and its safety
// requirements. We took the reference from [`from_of`] earlier, it is safe to drop the
// same now.
unsafe { bindings::dev_pm_opp_of_remove_table(self.dev.as_raw()) };
}
/// Creates a new reference-counted [`Table`] instance for a [`Cpumask`] based on device tree
/// entries.
#[cfg(CONFIG_OF)]
pub fn from_of_cpumask(dev: &Device, cpumask: &mut Cpumask) -> Result<Self> {
// SAFETY: The cpumask is valid and the returned pointer will be owned by the [`Table`]
// instance.
//
// INVARIANT: The reference-count is incremented by the C code and is decremented when
// [`Table`] goes out of scope.
to_result(unsafe { bindings::dev_pm_opp_of_cpumask_add_table(cpumask.as_raw()) })?;
// Fetch the newly created table.
let mut table = Self::from_dev(dev)?;
table.cpus = Some(CpumaskVar::try_clone(cpumask)?);
Ok(table)
}
/// Remove device tree based [`Table`] for a [`Cpumask`].
#[cfg(CONFIG_OF)]
#[inline]
fn remove_of_cpumask(&self, cpumask: &Cpumask) {
// SAFETY: The cpumask is valid and we took the reference from [`from_of_cpumask`] earlier,
// it is safe to drop the same now.
unsafe { bindings::dev_pm_opp_of_cpumask_remove_table(cpumask.as_raw()) };
}
/// Returns the number of [`OPP`]s in the [`Table`].
pub fn opp_count(&self) -> Result<u32> {
// SAFETY: The requirements are satisfied by the existence of [`Device`] and its safety
// requirements.
let ret = unsafe { bindings::dev_pm_opp_get_opp_count(self.dev.as_raw()) };
to_result(ret).map(|()| ret as u32)
}
/// Returns max clock latency (in nanoseconds) of the [`OPP`]s in the [`Table`].
#[inline]
pub fn max_clock_latency_ns(&self) -> usize {
// SAFETY: The requirements are satisfied by the existence of [`Device`] and its safety
// requirements.
unsafe { bindings::dev_pm_opp_get_max_clock_latency(self.dev.as_raw()) }
}
/// Returns max volt latency (in nanoseconds) of the [`OPP`]s in the [`Table`].
#[inline]
pub fn max_volt_latency_ns(&self) -> usize {
// SAFETY: The requirements are satisfied by the existence of [`Device`] and its safety
// requirements.
unsafe { bindings::dev_pm_opp_get_max_volt_latency(self.dev.as_raw()) }
}
/// Returns max transition latency (in nanoseconds) of the [`OPP`]s in the [`Table`].
#[inline]
pub fn max_transition_latency_ns(&self) -> usize {
// SAFETY: The requirements are satisfied by the existence of [`Device`] and its safety
// requirements.
unsafe { bindings::dev_pm_opp_get_max_transition_latency(self.dev.as_raw()) }
}
/// Returns the suspend [`OPP`]'s frequency.
#[inline]
pub fn suspend_freq(&self) -> Hertz {
// SAFETY: The requirements are satisfied by the existence of [`Device`] and its safety
// requirements.
Hertz(unsafe { bindings::dev_pm_opp_get_suspend_opp_freq(self.dev.as_raw()) })
}
/// Synchronizes regulators used by the [`Table`].
#[inline]
pub fn sync_regulators(&self) -> Result {
// SAFETY: The requirements are satisfied by the existence of [`Device`] and its safety
// requirements.
to_result(unsafe { bindings::dev_pm_opp_sync_regulators(self.dev.as_raw()) })
}
/// Gets sharing CPUs.
#[inline]
pub fn sharing_cpus(dev: &Device, cpumask: &mut Cpumask) -> Result {
// SAFETY: The requirements are satisfied by the existence of [`Device`] and its safety
// requirements.
to_result(unsafe { bindings::dev_pm_opp_get_sharing_cpus(dev.as_raw(), cpumask.as_raw()) })
}
/// Sets sharing CPUs.
pub fn set_sharing_cpus(&mut self, cpumask: &mut Cpumask) -> Result {
// SAFETY: The requirements are satisfied by the existence of [`Device`] and its safety
// requirements.
to_result(unsafe {
bindings::dev_pm_opp_set_sharing_cpus(self.dev.as_raw(), cpumask.as_raw())
})?;
if let Some(mask) = self.cpus.as_mut() {
// Update the cpumask as this will be used while removing the table.
cpumask.copy(mask);
}
Ok(())
}
/// Gets sharing CPUs from device tree.
#[cfg(CONFIG_OF)]
#[inline]
pub fn of_sharing_cpus(dev: &Device, cpumask: &mut Cpumask) -> Result {
// SAFETY: The requirements are satisfied by the existence of [`Device`] and its safety
// requirements.
to_result(unsafe {
bindings::dev_pm_opp_of_get_sharing_cpus(dev.as_raw(), cpumask.as_raw())
})
}
/// Updates the voltage value for an [`OPP`].
#[inline]
pub fn adjust_voltage(
&self,
freq: Hertz,
volt: MicroVolt,
volt_min: MicroVolt,
volt_max: MicroVolt,
) -> Result {
// SAFETY: The requirements are satisfied by the existence of [`Device`] and its safety
// requirements.
to_result(unsafe {
bindings::dev_pm_opp_adjust_voltage(
self.dev.as_raw(),
freq.into(),
volt.into(),
volt_min.into(),
volt_max.into(),
)
})
}
/// Creates [`FreqTable`] from [`Table`].
#[cfg(CONFIG_CPU_FREQ)]
#[inline]
pub fn cpufreq_table(&mut self) -> Result<FreqTable> {
FreqTable::new(self)
}
/// Configures device with [`OPP`] matching the frequency value.
#[inline]
pub fn set_rate(&self, freq: Hertz) -> Result {
// SAFETY: The requirements are satisfied by the existence of [`Device`] and its safety
// requirements.
to_result(unsafe { bindings::dev_pm_opp_set_rate(self.dev.as_raw(), freq.into()) })
}
/// Configures device with [`OPP`].
#[inline]
pub fn set_opp(&self, opp: &OPP) -> Result {
// SAFETY: The requirements are satisfied by the existence of [`Device`] and its safety
// requirements.
to_result(unsafe { bindings::dev_pm_opp_set_opp(self.dev.as_raw(), opp.as_raw()) })
}
/// Finds [`OPP`] based on frequency.
pub fn opp_from_freq(
&self,
freq: Hertz,
available: Option<bool>,
index: Option<u32>,
stype: SearchType,
) -> Result<ARef<OPP>> {
let raw_dev = self.dev.as_raw();
let index = index.unwrap_or(0);
let mut rate = freq.into();
let ptr = from_err_ptr(match stype {
SearchType::Exact => {
if let Some(available) = available {
// SAFETY: The requirements are satisfied by the existence of [`Device`] and
// its safety requirements. The returned pointer will be owned by the new
// [`OPP`] instance.
unsafe {
bindings::dev_pm_opp_find_freq_exact_indexed(
raw_dev, rate, index, available,
)
}
} else {
return Err(EINVAL);
}
}
// SAFETY: The requirements are satisfied by the existence of [`Device`] and its safety
// requirements. The returned pointer will be owned by the new [`OPP`] instance.
SearchType::Ceil => unsafe {
bindings::dev_pm_opp_find_freq_ceil_indexed(raw_dev, &mut rate, index)
},
// SAFETY: The requirements are satisfied by the existence of [`Device`] and its safety
// requirements. The returned pointer will be owned by the new [`OPP`] instance.
SearchType::Floor => unsafe {
bindings::dev_pm_opp_find_freq_floor_indexed(raw_dev, &mut rate, index)
},
})?;
// SAFETY: The `ptr` is guaranteed by the C code to be valid.
unsafe { OPP::from_raw_opp_owned(ptr) }
}
/// Finds [`OPP`] based on level.
pub fn opp_from_level(&self, mut level: u32, stype: SearchType) -> Result<ARef<OPP>> {
let raw_dev = self.dev.as_raw();
let ptr = from_err_ptr(match stype {
// SAFETY: The requirements are satisfied by the existence of [`Device`] and its safety
// requirements. The returned pointer will be owned by the new [`OPP`] instance.
SearchType::Exact => unsafe { bindings::dev_pm_opp_find_level_exact(raw_dev, level) },
// SAFETY: The requirements are satisfied by the existence of [`Device`] and its safety
// requirements. The returned pointer will be owned by the new [`OPP`] instance.
SearchType::Ceil => unsafe {
bindings::dev_pm_opp_find_level_ceil(raw_dev, &mut level)
},
// SAFETY: The requirements are satisfied by the existence of [`Device`] and its safety
// requirements. The returned pointer will be owned by the new [`OPP`] instance.
SearchType::Floor => unsafe {
bindings::dev_pm_opp_find_level_floor(raw_dev, &mut level)
},
})?;
// SAFETY: The `ptr` is guaranteed by the C code to be valid.
unsafe { OPP::from_raw_opp_owned(ptr) }
}
/// Finds [`OPP`] based on bandwidth.
pub fn opp_from_bw(&self, mut bw: u32, index: i32, stype: SearchType) -> Result<ARef<OPP>> {
let raw_dev = self.dev.as_raw();
let ptr = from_err_ptr(match stype {
// The OPP core doesn't support this yet.
SearchType::Exact => return Err(EINVAL),
// SAFETY: The requirements are satisfied by the existence of [`Device`] and its safety
// requirements. The returned pointer will be owned by the new [`OPP`] instance.
SearchType::Ceil => unsafe {
bindings::dev_pm_opp_find_bw_ceil(raw_dev, &mut bw, index)
},
// SAFETY: The requirements are satisfied by the existence of [`Device`] and its safety
// requirements. The returned pointer will be owned by the new [`OPP`] instance.
SearchType::Floor => unsafe {
bindings::dev_pm_opp_find_bw_floor(raw_dev, &mut bw, index)
},
})?;
// SAFETY: The `ptr` is guaranteed by the C code to be valid.
unsafe { OPP::from_raw_opp_owned(ptr) }
}
/// Enables the [`OPP`].
#[inline]
pub fn enable_opp(&self, freq: Hertz) -> Result {
// SAFETY: The requirements are satisfied by the existence of [`Device`] and its safety
// requirements.
to_result(unsafe { bindings::dev_pm_opp_enable(self.dev.as_raw(), freq.into()) })
}
/// Disables the [`OPP`].
#[inline]
pub fn disable_opp(&self, freq: Hertz) -> Result {
// SAFETY: The requirements are satisfied by the existence of [`Device`] and its safety
// requirements.
to_result(unsafe { bindings::dev_pm_opp_disable(self.dev.as_raw(), freq.into()) })
}
/// Registers with the Energy model.
#[cfg(CONFIG_OF)]
pub fn of_register_em(&mut self, cpumask: &mut Cpumask) -> Result {
// SAFETY: The requirements are satisfied by the existence of [`Device`] and its safety
// requirements.
to_result(unsafe {
bindings::dev_pm_opp_of_register_em(self.dev.as_raw(), cpumask.as_raw())
})?;
self.em = true;
Ok(())
}
/// Unregisters with the Energy model.
#[cfg(all(CONFIG_OF, CONFIG_ENERGY_MODEL))]
#[inline]
fn of_unregister_em(&self) {
// SAFETY: The requirements are satisfied by the existence of [`Device`] and its safety
// requirements. We registered with the EM framework earlier, it is safe to unregister now.
unsafe { bindings::em_dev_unregister_perf_domain(self.dev.as_raw()) };
}
}
impl Drop for Table {
fn drop(&mut self) {
// SAFETY: By the type invariants, we know that `self` owns a reference, so it is safe
// to relinquish it now.
unsafe { bindings::dev_pm_opp_put_opp_table(self.ptr) };
#[cfg(CONFIG_OF)]
{
#[cfg(CONFIG_ENERGY_MODEL)]
if self.em {
self.of_unregister_em();
}
if self.of {
self.remove_of();
} else if let Some(cpumask) = self.cpus.take() {
self.remove_of_cpumask(&cpumask);
}
}
}
}
/// A reference-counted Operating performance point (OPP).
///
/// Rust abstraction for the C `struct dev_pm_opp`.
///
/// # Invariants
///
/// The pointer stored in `Self` is non-null and valid for the lifetime of the [`OPP`].
///
/// Instances of this type are reference-counted. The reference count is incremented by the
/// `dev_pm_opp_get` function and decremented by `dev_pm_opp_put`. The Rust type `ARef<OPP>`
/// represents a pointer that owns a reference count on the [`OPP`].
///
/// A reference to the [`OPP`], &[`OPP`], isn't refcounted by the Rust code.
///
/// # Examples
///
/// The following example demonstrates how to get [`OPP`] corresponding to a frequency value and
/// configure the device with it.
///
/// ```
/// use kernel::clk::Hertz;
/// use kernel::error::Result;
/// use kernel::opp::{SearchType, Table};
///
/// fn configure_opp(table: &Table, freq: Hertz) -> Result {
/// let opp = table.opp_from_freq(freq, Some(true), None, SearchType::Exact)?;
///
/// if opp.freq(None) != freq {
/// return Err(EINVAL);
/// }
///
/// table.set_opp(&opp)
/// }
/// ```
#[repr(transparent)]
pub struct OPP(Opaque<bindings::dev_pm_opp>);
/// SAFETY: It is okay to send the ownership of [`OPP`] across thread boundaries.
unsafe impl Send for OPP {}
/// SAFETY: It is okay to access [`OPP`] through shared references from other threads because we're
/// either accessing properties that don't change or that are properly synchronised by C code.
unsafe impl Sync for OPP {}
/// SAFETY: The type invariants guarantee that [`OPP`] is always refcounted.
unsafe impl AlwaysRefCounted for OPP {
fn inc_ref(&self) {
// SAFETY: The existence of a shared reference means that the refcount is nonzero.
unsafe { bindings::dev_pm_opp_get(self.0.get()) };
}
unsafe fn dec_ref(obj: ptr::NonNull<Self>) {
// SAFETY: The safety requirements guarantee that the refcount is nonzero.
unsafe { bindings::dev_pm_opp_put(obj.cast().as_ptr()) }
}
}
impl OPP {
/// Creates an owned reference to a [`OPP`] from a valid pointer.
///
/// The refcount is incremented by the C code and will be decremented by `dec_ref` when the
/// [`ARef`] object is dropped.
///
/// # Safety
///
/// The caller must ensure that `ptr` is valid and the refcount of the [`OPP`] is incremented.
/// The caller must also ensure that it doesn't explicitly drop the refcount of the [`OPP`], as
/// the returned [`ARef`] object takes over the refcount increment on the underlying object and
/// the same will be dropped along with it.
pub unsafe fn from_raw_opp_owned(ptr: *mut bindings::dev_pm_opp) -> Result<ARef<Self>> {
let ptr = ptr::NonNull::new(ptr).ok_or(ENODEV)?;
// SAFETY: The safety requirements guarantee the validity of the pointer.
//
// INVARIANT: The reference-count is decremented when [`OPP`] goes out of scope.
Ok(unsafe { ARef::from_raw(ptr.cast()) })
}
/// Creates a reference to a [`OPP`] from a valid pointer.
///
/// The refcount is not updated by the Rust API unless the returned reference is converted to
/// an [`ARef`] object.
///
/// # Safety
///
/// The caller must ensure that `ptr` is valid and remains valid for the duration of `'a`.
#[inline]
pub unsafe fn from_raw_opp<'a>(ptr: *mut bindings::dev_pm_opp) -> Result<&'a Self> {
// SAFETY: The caller guarantees that the pointer is not dangling and stays valid for the
// duration of 'a. The cast is okay because [`OPP`] is `repr(transparent)`.
Ok(unsafe { &*ptr.cast() })
}
#[inline]
fn as_raw(&self) -> *mut bindings::dev_pm_opp {
self.0.get()
}
/// Returns the frequency of an [`OPP`].
pub fn freq(&self, index: Option<u32>) -> Hertz {
let index = index.unwrap_or(0);
// SAFETY: By the type invariants, we know that `self` owns a reference, so it is safe to
// use it.
Hertz(unsafe { bindings::dev_pm_opp_get_freq_indexed(self.as_raw(), index) })
}
/// Returns the voltage of an [`OPP`].
#[inline]
pub fn voltage(&self) -> MicroVolt {
// SAFETY: By the type invariants, we know that `self` owns a reference, so it is safe to
// use it.
MicroVolt(unsafe { bindings::dev_pm_opp_get_voltage(self.as_raw()) })
}
/// Returns the level of an [`OPP`].
#[inline]
pub fn level(&self) -> u32 {
// SAFETY: By the type invariants, we know that `self` owns a reference, so it is safe to
// use it.
unsafe { bindings::dev_pm_opp_get_level(self.as_raw()) }
}
/// Returns the power of an [`OPP`].
#[inline]
pub fn power(&self) -> MicroWatt {
// SAFETY: By the type invariants, we know that `self` owns a reference, so it is safe to
// use it.
MicroWatt(unsafe { bindings::dev_pm_opp_get_power(self.as_raw()) })
}
/// Returns the required pstate of an [`OPP`].
#[inline]
pub fn required_pstate(&self, index: u32) -> u32 {
// SAFETY: By the type invariants, we know that `self` owns a reference, so it is safe to
// use it.
unsafe { bindings::dev_pm_opp_get_required_pstate(self.as_raw(), index) }
}
/// Returns true if the [`OPP`] is turbo.
#[inline]
pub fn is_turbo(&self) -> bool {
// SAFETY: By the type invariants, we know that `self` owns a reference, so it is safe to
// use it.
unsafe { bindings::dev_pm_opp_is_turbo(self.as_raw()) }
}
}
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