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linux/drivers/cpufreq/rcpufreq_dt.rs
Danilo Krummrich 0242623384 rust: driver: let probe() return impl PinInit<Self, Error> 
The driver model defines the lifetime of the private data stored in (and
owned by) a bus device to be valid from when the driver is bound to a
device (i.e. from successful probe()) until the driver is unbound from
the device.

This is already taken care of by the Rust implementation of the driver
model. However, we still ask drivers to return a Result<Pin<KBox<Self>>>
from probe().

Unlike in C, where we do not have the concept of initializers, but
rather deal with uninitialized memory, drivers can just return an
impl PinInit<Self, Error> instead.

This contributes to more clarity to the fact that a driver returns it's
device private data in probe() and the Rust driver model owns the data,
manages the lifetime and - considering the lifetime - provides (safe)
accessors for the driver.

Hence, let probe() functions return an impl PinInit<Self, Error> instead
of Result<Pin<KBox<Self>>>.

Reviewed-by: Alice Ryhl <aliceryhl@google.com>
Acked-by: Viresh Kumar <viresh.kumar@linaro.org>
Reviewed-by: Alexandre Courbot <acourbot@nvidia.com>
Acked-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
Signed-off-by: Danilo Krummrich <dakr@kernel.org>
2025-10-21 18:40:48 +02:00

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// SPDX-License-Identifier: GPL-2.0
//! Rust based implementation of the cpufreq-dt driver.
use kernel::{
c_str,
clk::Clk,
cpu, cpufreq,
cpumask::CpumaskVar,
device::{Core, Device},
error::code::*,
macros::vtable,
module_platform_driver, of, opp, platform,
prelude::*,
str::CString,
sync::Arc,
};
/// Finds exact supply name from the OF node.
fn find_supply_name_exact(dev: &Device, name: &str) -> Option<CString> {
let prop_name = CString::try_from_fmt(fmt!("{name}-supply")).ok()?;
dev.fwnode()?
.property_present(&prop_name)
.then(|| CString::try_from_fmt(fmt!("{name}")).ok())
.flatten()
}
/// Finds supply name for the CPU from DT.
fn find_supply_names(dev: &Device, cpu: cpu::CpuId) -> Option<KVec<CString>> {
// Try "cpu0" for older DTs, fallback to "cpu".
(cpu.as_u32() == 0)
.then(|| find_supply_name_exact(dev, "cpu0"))
.flatten()
.or_else(|| find_supply_name_exact(dev, "cpu"))
.and_then(|name| kernel::kvec![name].ok())
}
/// Represents the cpufreq dt device.
struct CPUFreqDTDevice {
opp_table: opp::Table,
freq_table: opp::FreqTable,
_mask: CpumaskVar,
_token: Option<opp::ConfigToken>,
_clk: Clk,
}
#[derive(Default)]
struct CPUFreqDTDriver;
#[vtable]
impl opp::ConfigOps for CPUFreqDTDriver {}
#[vtable]
impl cpufreq::Driver for CPUFreqDTDriver {
const NAME: &'static CStr = c_str!("cpufreq-dt");
const FLAGS: u16 = cpufreq::flags::NEED_INITIAL_FREQ_CHECK | cpufreq::flags::IS_COOLING_DEV;
const BOOST_ENABLED: bool = true;
type PData = Arc<CPUFreqDTDevice>;
fn init(policy: &mut cpufreq::Policy) -> Result<Self::PData> {
let cpu = policy.cpu();
// SAFETY: The CPU device is only used during init; it won't get hot-unplugged. The cpufreq
// core registers with CPU notifiers and the cpufreq core/driver won't use the CPU device,
// once the CPU is hot-unplugged.
let dev = unsafe { cpu::from_cpu(cpu)? };
let mut mask = CpumaskVar::new_zero(GFP_KERNEL)?;
mask.set(cpu);
let token = find_supply_names(dev, cpu)
.map(|names| {
opp::Config::<Self>::new()
.set_regulator_names(names)?
.set(dev)
})
.transpose()?;
// Get OPP-sharing information from "operating-points-v2" bindings.
let fallback = match opp::Table::of_sharing_cpus(dev, &mut mask) {
Ok(()) => false,
Err(e) if e == ENOENT => {
// "operating-points-v2" not supported. If the platform hasn't
// set sharing CPUs, fallback to all CPUs share the `Policy`
// for backward compatibility.
opp::Table::sharing_cpus(dev, &mut mask).is_err()
}
Err(e) => return Err(e),
};
// Initialize OPP tables for all policy cpus.
//
// For platforms not using "operating-points-v2" bindings, we do this
// before updating policy cpus. Otherwise, we will end up creating
// duplicate OPPs for the CPUs.
//
// OPPs might be populated at runtime, don't fail for error here unless
// it is -EPROBE_DEFER.
let mut opp_table = match opp::Table::from_of_cpumask(dev, &mut mask) {
Ok(table) => table,
Err(e) => {
if e == EPROBE_DEFER {
return Err(e);
}
// The table is added dynamically ?
opp::Table::from_dev(dev)?
}
};
// The OPP table must be initialized, statically or dynamically, by this point.
opp_table.opp_count()?;
// Set sharing cpus for fallback scenario.
if fallback {
mask.setall();
opp_table.set_sharing_cpus(&mut mask)?;
}
let mut transition_latency = opp_table.max_transition_latency_ns() as u32;
if transition_latency == 0 {
transition_latency = cpufreq::DEFAULT_TRANSITION_LATENCY_NS;
}
policy
.set_dvfs_possible_from_any_cpu(true)
.set_suspend_freq(opp_table.suspend_freq())
.set_transition_latency_ns(transition_latency);
let freq_table = opp_table.cpufreq_table()?;
// SAFETY: The `freq_table` is not dropped while it is getting used by the C code.
unsafe { policy.set_freq_table(&freq_table) };
// SAFETY: The returned `clk` is not dropped while it is getting used by the C code.
let clk = unsafe { policy.set_clk(dev, None)? };
mask.copy(policy.cpus());
Ok(Arc::new(
CPUFreqDTDevice {
opp_table,
freq_table,
_mask: mask,
_token: token,
_clk: clk,
},
GFP_KERNEL,
)?)
}
fn exit(_policy: &mut cpufreq::Policy, _data: Option<Self::PData>) -> Result {
Ok(())
}
fn online(_policy: &mut cpufreq::Policy) -> Result {
// We did light-weight tear down earlier, nothing to do here.
Ok(())
}
fn offline(_policy: &mut cpufreq::Policy) -> Result {
// Preserve policy->data and don't free resources on light-weight
// tear down.
Ok(())
}
fn suspend(policy: &mut cpufreq::Policy) -> Result {
policy.generic_suspend()
}
fn verify(data: &mut cpufreq::PolicyData) -> Result {
data.generic_verify()
}
fn target_index(policy: &mut cpufreq::Policy, index: cpufreq::TableIndex) -> Result {
let Some(data) = policy.data::<Self::PData>() else {
return Err(ENOENT);
};
let freq = data.freq_table.freq(index)?;
data.opp_table.set_rate(freq)
}
fn get(policy: &mut cpufreq::Policy) -> Result<u32> {
policy.generic_get()
}
fn set_boost(_policy: &mut cpufreq::Policy, _state: i32) -> Result {
Ok(())
}
fn register_em(policy: &mut cpufreq::Policy) {
policy.register_em_opp()
}
}
kernel::of_device_table!(
OF_TABLE,
MODULE_OF_TABLE,
<CPUFreqDTDriver as platform::Driver>::IdInfo,
[(of::DeviceId::new(c_str!("operating-points-v2")), ())]
);
impl platform::Driver for CPUFreqDTDriver {
type IdInfo = ();
const OF_ID_TABLE: Option<of::IdTable<Self::IdInfo>> = Some(&OF_TABLE);
fn probe(
pdev: &platform::Device<Core>,
_id_info: Option<&Self::IdInfo>,
) -> impl PinInit<Self, Error> {
cpufreq::Registration::<CPUFreqDTDriver>::new_foreign_owned(pdev.as_ref())?;
Ok(Self {})
}
}
module_platform_driver! {
type: CPUFreqDTDriver,
name: "cpufreq-dt",
authors: ["Viresh Kumar <viresh.kumar@linaro.org>"],
description: "Generic CPUFreq DT driver",
license: "GPL v2",
}
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