linux/drivers/cpufreq/cppc_cpufreq.c
Lizhe b4b1ddc9df cpufreq: Make cpufreq_driver->exit() return void
The cpufreq core doesn't check the return type of the exit() callback
and there is not much the core can do on failures at that point. Just
drop the returned value and make it return void.

Signed-off-by: Lizhe <sensor1010@163.com>
[ Viresh: Reworked the patches to fix all missing changes together. ]
Signed-off-by: Viresh Kumar <viresh.kumar@linaro.org>
Reviewed-by: AngeloGioacchino Del Regno <angelogioacchino.delregno@collabora.com> # Mediatek
Acked-by: Sudeep Holla <sudeep.holla@arm.com> # scpi, scmi, vexpress
Acked-by: Mario Limonciello <mario.limonciello@amd.com> # amd
Reviewed-by: Florian Fainelli <florian.fainelli@broadcom.com> # bmips
Acked-by: Rafael J. Wysocki <rafael@kernel.org>
Acked-by: Kevin Hilman <khilman@baylibre.com> # omap
2024-07-09 08:45:30 +05:30

917 lines
24 KiB
C

// SPDX-License-Identifier: GPL-2.0-only
/*
* CPPC (Collaborative Processor Performance Control) driver for
* interfacing with the CPUfreq layer and governors. See
* cppc_acpi.c for CPPC specific methods.
*
* (C) Copyright 2014, 2015 Linaro Ltd.
* Author: Ashwin Chaugule <ashwin.chaugule@linaro.org>
*/
#define pr_fmt(fmt) "CPPC Cpufreq:" fmt
#include <linux/arch_topology.h>
#include <linux/kernel.h>
#include <linux/module.h>
#include <linux/delay.h>
#include <linux/cpu.h>
#include <linux/cpufreq.h>
#include <linux/irq_work.h>
#include <linux/kthread.h>
#include <linux/time.h>
#include <linux/vmalloc.h>
#include <uapi/linux/sched/types.h>
#include <asm/unaligned.h>
#include <acpi/cppc_acpi.h>
/*
* This list contains information parsed from per CPU ACPI _CPC and _PSD
* structures: e.g. the highest and lowest supported performance, capabilities,
* desired performance, level requested etc. Depending on the share_type, not
* all CPUs will have an entry in the list.
*/
static LIST_HEAD(cpu_data_list);
static bool boost_supported;
struct cppc_workaround_oem_info {
char oem_id[ACPI_OEM_ID_SIZE + 1];
char oem_table_id[ACPI_OEM_TABLE_ID_SIZE + 1];
u32 oem_revision;
};
static struct cppc_workaround_oem_info wa_info[] = {
{
.oem_id = "HISI ",
.oem_table_id = "HIP07 ",
.oem_revision = 0,
}, {
.oem_id = "HISI ",
.oem_table_id = "HIP08 ",
.oem_revision = 0,
}
};
static struct cpufreq_driver cppc_cpufreq_driver;
static enum {
FIE_UNSET = -1,
FIE_ENABLED,
FIE_DISABLED
} fie_disabled = FIE_UNSET;
#ifdef CONFIG_ACPI_CPPC_CPUFREQ_FIE
module_param(fie_disabled, int, 0444);
MODULE_PARM_DESC(fie_disabled, "Disable Frequency Invariance Engine (FIE)");
/* Frequency invariance support */
struct cppc_freq_invariance {
int cpu;
struct irq_work irq_work;
struct kthread_work work;
struct cppc_perf_fb_ctrs prev_perf_fb_ctrs;
struct cppc_cpudata *cpu_data;
};
static DEFINE_PER_CPU(struct cppc_freq_invariance, cppc_freq_inv);
static struct kthread_worker *kworker_fie;
static unsigned int hisi_cppc_cpufreq_get_rate(unsigned int cpu);
static int cppc_perf_from_fbctrs(struct cppc_cpudata *cpu_data,
struct cppc_perf_fb_ctrs *fb_ctrs_t0,
struct cppc_perf_fb_ctrs *fb_ctrs_t1);
/**
* cppc_scale_freq_workfn - CPPC arch_freq_scale updater for frequency invariance
* @work: The work item.
*
* The CPPC driver register itself with the topology core to provide its own
* implementation (cppc_scale_freq_tick()) of topology_scale_freq_tick() which
* gets called by the scheduler on every tick.
*
* Note that the arch specific counters have higher priority than CPPC counters,
* if available, though the CPPC driver doesn't need to have any special
* handling for that.
*
* On an invocation of cppc_scale_freq_tick(), we schedule an irq work (since we
* reach here from hard-irq context), which then schedules a normal work item
* and cppc_scale_freq_workfn() updates the per_cpu arch_freq_scale variable
* based on the counter updates since the last tick.
*/
static void cppc_scale_freq_workfn(struct kthread_work *work)
{
struct cppc_freq_invariance *cppc_fi;
struct cppc_perf_fb_ctrs fb_ctrs = {0};
struct cppc_cpudata *cpu_data;
unsigned long local_freq_scale;
u64 perf;
cppc_fi = container_of(work, struct cppc_freq_invariance, work);
cpu_data = cppc_fi->cpu_data;
if (cppc_get_perf_ctrs(cppc_fi->cpu, &fb_ctrs)) {
pr_warn("%s: failed to read perf counters\n", __func__);
return;
}
perf = cppc_perf_from_fbctrs(cpu_data, &cppc_fi->prev_perf_fb_ctrs,
&fb_ctrs);
cppc_fi->prev_perf_fb_ctrs = fb_ctrs;
perf <<= SCHED_CAPACITY_SHIFT;
local_freq_scale = div64_u64(perf, cpu_data->perf_caps.highest_perf);
/* This can happen due to counter's overflow */
if (unlikely(local_freq_scale > 1024))
local_freq_scale = 1024;
per_cpu(arch_freq_scale, cppc_fi->cpu) = local_freq_scale;
}
static void cppc_irq_work(struct irq_work *irq_work)
{
struct cppc_freq_invariance *cppc_fi;
cppc_fi = container_of(irq_work, struct cppc_freq_invariance, irq_work);
kthread_queue_work(kworker_fie, &cppc_fi->work);
}
static void cppc_scale_freq_tick(void)
{
struct cppc_freq_invariance *cppc_fi = &per_cpu(cppc_freq_inv, smp_processor_id());
/*
* cppc_get_perf_ctrs() can potentially sleep, call that from the right
* context.
*/
irq_work_queue(&cppc_fi->irq_work);
}
static struct scale_freq_data cppc_sftd = {
.source = SCALE_FREQ_SOURCE_CPPC,
.set_freq_scale = cppc_scale_freq_tick,
};
static void cppc_cpufreq_cpu_fie_init(struct cpufreq_policy *policy)
{
struct cppc_freq_invariance *cppc_fi;
int cpu, ret;
if (fie_disabled)
return;
for_each_cpu(cpu, policy->cpus) {
cppc_fi = &per_cpu(cppc_freq_inv, cpu);
cppc_fi->cpu = cpu;
cppc_fi->cpu_data = policy->driver_data;
kthread_init_work(&cppc_fi->work, cppc_scale_freq_workfn);
init_irq_work(&cppc_fi->irq_work, cppc_irq_work);
ret = cppc_get_perf_ctrs(cpu, &cppc_fi->prev_perf_fb_ctrs);
if (ret) {
pr_warn("%s: failed to read perf counters for cpu:%d: %d\n",
__func__, cpu, ret);
/*
* Don't abort if the CPU was offline while the driver
* was getting registered.
*/
if (cpu_online(cpu))
return;
}
}
/* Register for freq-invariance */
topology_set_scale_freq_source(&cppc_sftd, policy->cpus);
}
/*
* We free all the resources on policy's removal and not on CPU removal as the
* irq-work are per-cpu and the hotplug core takes care of flushing the pending
* irq-works (hint: smpcfd_dying_cpu()) on CPU hotplug. Even if the kthread-work
* fires on another CPU after the concerned CPU is removed, it won't harm.
*
* We just need to make sure to remove them all on policy->exit().
*/
static void cppc_cpufreq_cpu_fie_exit(struct cpufreq_policy *policy)
{
struct cppc_freq_invariance *cppc_fi;
int cpu;
if (fie_disabled)
return;
/* policy->cpus will be empty here, use related_cpus instead */
topology_clear_scale_freq_source(SCALE_FREQ_SOURCE_CPPC, policy->related_cpus);
for_each_cpu(cpu, policy->related_cpus) {
cppc_fi = &per_cpu(cppc_freq_inv, cpu);
irq_work_sync(&cppc_fi->irq_work);
kthread_cancel_work_sync(&cppc_fi->work);
}
}
static void __init cppc_freq_invariance_init(void)
{
struct sched_attr attr = {
.size = sizeof(struct sched_attr),
.sched_policy = SCHED_DEADLINE,
.sched_nice = 0,
.sched_priority = 0,
/*
* Fake (unused) bandwidth; workaround to "fix"
* priority inheritance.
*/
.sched_runtime = 1000000,
.sched_deadline = 10000000,
.sched_period = 10000000,
};
int ret;
if (fie_disabled != FIE_ENABLED && fie_disabled != FIE_DISABLED) {
fie_disabled = FIE_ENABLED;
if (cppc_perf_ctrs_in_pcc()) {
pr_info("FIE not enabled on systems with registers in PCC\n");
fie_disabled = FIE_DISABLED;
}
}
if (fie_disabled)
return;
kworker_fie = kthread_create_worker(0, "cppc_fie");
if (IS_ERR(kworker_fie)) {
pr_warn("%s: failed to create kworker_fie: %ld\n", __func__,
PTR_ERR(kworker_fie));
fie_disabled = FIE_DISABLED;
return;
}
ret = sched_setattr_nocheck(kworker_fie->task, &attr);
if (ret) {
pr_warn("%s: failed to set SCHED_DEADLINE: %d\n", __func__,
ret);
kthread_destroy_worker(kworker_fie);
fie_disabled = FIE_DISABLED;
}
}
static void cppc_freq_invariance_exit(void)
{
if (fie_disabled)
return;
kthread_destroy_worker(kworker_fie);
}
#else
static inline void cppc_cpufreq_cpu_fie_init(struct cpufreq_policy *policy)
{
}
static inline void cppc_cpufreq_cpu_fie_exit(struct cpufreq_policy *policy)
{
}
static inline void cppc_freq_invariance_init(void)
{
}
static inline void cppc_freq_invariance_exit(void)
{
}
#endif /* CONFIG_ACPI_CPPC_CPUFREQ_FIE */
static int cppc_cpufreq_set_target(struct cpufreq_policy *policy,
unsigned int target_freq,
unsigned int relation)
{
struct cppc_cpudata *cpu_data = policy->driver_data;
unsigned int cpu = policy->cpu;
struct cpufreq_freqs freqs;
int ret = 0;
cpu_data->perf_ctrls.desired_perf =
cppc_khz_to_perf(&cpu_data->perf_caps, target_freq);
freqs.old = policy->cur;
freqs.new = target_freq;
cpufreq_freq_transition_begin(policy, &freqs);
ret = cppc_set_perf(cpu, &cpu_data->perf_ctrls);
cpufreq_freq_transition_end(policy, &freqs, ret != 0);
if (ret)
pr_debug("Failed to set target on CPU:%d. ret:%d\n",
cpu, ret);
return ret;
}
static unsigned int cppc_cpufreq_fast_switch(struct cpufreq_policy *policy,
unsigned int target_freq)
{
struct cppc_cpudata *cpu_data = policy->driver_data;
unsigned int cpu = policy->cpu;
u32 desired_perf;
int ret;
desired_perf = cppc_khz_to_perf(&cpu_data->perf_caps, target_freq);
cpu_data->perf_ctrls.desired_perf = desired_perf;
ret = cppc_set_perf(cpu, &cpu_data->perf_ctrls);
if (ret) {
pr_debug("Failed to set target on CPU:%d. ret:%d\n",
cpu, ret);
return 0;
}
return target_freq;
}
static int cppc_verify_policy(struct cpufreq_policy_data *policy)
{
cpufreq_verify_within_cpu_limits(policy);
return 0;
}
/*
* The PCC subspace describes the rate at which platform can accept commands
* on the shared PCC channel (including READs which do not count towards freq
* transition requests), so ideally we need to use the PCC values as a fallback
* if we don't have a platform specific transition_delay_us
*/
#ifdef CONFIG_ARM64
#include <asm/cputype.h>
static unsigned int cppc_cpufreq_get_transition_delay_us(unsigned int cpu)
{
unsigned long implementor = read_cpuid_implementor();
unsigned long part_num = read_cpuid_part_number();
switch (implementor) {
case ARM_CPU_IMP_QCOM:
switch (part_num) {
case QCOM_CPU_PART_FALKOR_V1:
case QCOM_CPU_PART_FALKOR:
return 10000;
}
}
return cppc_get_transition_latency(cpu) / NSEC_PER_USEC;
}
#else
static unsigned int cppc_cpufreq_get_transition_delay_us(unsigned int cpu)
{
return cppc_get_transition_latency(cpu) / NSEC_PER_USEC;
}
#endif
#if defined(CONFIG_ARM64) && defined(CONFIG_ENERGY_MODEL)
static DEFINE_PER_CPU(unsigned int, efficiency_class);
static void cppc_cpufreq_register_em(struct cpufreq_policy *policy);
/* Create an artificial performance state every CPPC_EM_CAP_STEP capacity unit. */
#define CPPC_EM_CAP_STEP (20)
/* Increase the cost value by CPPC_EM_COST_STEP every performance state. */
#define CPPC_EM_COST_STEP (1)
/* Add a cost gap correspnding to the energy of 4 CPUs. */
#define CPPC_EM_COST_GAP (4 * SCHED_CAPACITY_SCALE * CPPC_EM_COST_STEP \
/ CPPC_EM_CAP_STEP)
static unsigned int get_perf_level_count(struct cpufreq_policy *policy)
{
struct cppc_perf_caps *perf_caps;
unsigned int min_cap, max_cap;
struct cppc_cpudata *cpu_data;
int cpu = policy->cpu;
cpu_data = policy->driver_data;
perf_caps = &cpu_data->perf_caps;
max_cap = arch_scale_cpu_capacity(cpu);
min_cap = div_u64((u64)max_cap * perf_caps->lowest_perf,
perf_caps->highest_perf);
if ((min_cap == 0) || (max_cap < min_cap))
return 0;
return 1 + max_cap / CPPC_EM_CAP_STEP - min_cap / CPPC_EM_CAP_STEP;
}
/*
* The cost is defined as:
* cost = power * max_frequency / frequency
*/
static inline unsigned long compute_cost(int cpu, int step)
{
return CPPC_EM_COST_GAP * per_cpu(efficiency_class, cpu) +
step * CPPC_EM_COST_STEP;
}
static int cppc_get_cpu_power(struct device *cpu_dev,
unsigned long *power, unsigned long *KHz)
{
unsigned long perf_step, perf_prev, perf, perf_check;
unsigned int min_step, max_step, step, step_check;
unsigned long prev_freq = *KHz;
unsigned int min_cap, max_cap;
struct cpufreq_policy *policy;
struct cppc_perf_caps *perf_caps;
struct cppc_cpudata *cpu_data;
policy = cpufreq_cpu_get_raw(cpu_dev->id);
cpu_data = policy->driver_data;
perf_caps = &cpu_data->perf_caps;
max_cap = arch_scale_cpu_capacity(cpu_dev->id);
min_cap = div_u64((u64)max_cap * perf_caps->lowest_perf,
perf_caps->highest_perf);
perf_step = div_u64((u64)CPPC_EM_CAP_STEP * perf_caps->highest_perf,
max_cap);
min_step = min_cap / CPPC_EM_CAP_STEP;
max_step = max_cap / CPPC_EM_CAP_STEP;
perf_prev = cppc_khz_to_perf(perf_caps, *KHz);
step = perf_prev / perf_step;
if (step > max_step)
return -EINVAL;
if (min_step == max_step) {
step = max_step;
perf = perf_caps->highest_perf;
} else if (step < min_step) {
step = min_step;
perf = perf_caps->lowest_perf;
} else {
step++;
if (step == max_step)
perf = perf_caps->highest_perf;
else
perf = step * perf_step;
}
*KHz = cppc_perf_to_khz(perf_caps, perf);
perf_check = cppc_khz_to_perf(perf_caps, *KHz);
step_check = perf_check / perf_step;
/*
* To avoid bad integer approximation, check that new frequency value
* increased and that the new frequency will be converted to the
* desired step value.
*/
while ((*KHz == prev_freq) || (step_check != step)) {
perf++;
*KHz = cppc_perf_to_khz(perf_caps, perf);
perf_check = cppc_khz_to_perf(perf_caps, *KHz);
step_check = perf_check / perf_step;
}
/*
* With an artificial EM, only the cost value is used. Still the power
* is populated such as 0 < power < EM_MAX_POWER. This allows to add
* more sense to the artificial performance states.
*/
*power = compute_cost(cpu_dev->id, step);
return 0;
}
static int cppc_get_cpu_cost(struct device *cpu_dev, unsigned long KHz,
unsigned long *cost)
{
unsigned long perf_step, perf_prev;
struct cppc_perf_caps *perf_caps;
struct cpufreq_policy *policy;
struct cppc_cpudata *cpu_data;
unsigned int max_cap;
int step;
policy = cpufreq_cpu_get_raw(cpu_dev->id);
cpu_data = policy->driver_data;
perf_caps = &cpu_data->perf_caps;
max_cap = arch_scale_cpu_capacity(cpu_dev->id);
perf_prev = cppc_khz_to_perf(perf_caps, KHz);
perf_step = CPPC_EM_CAP_STEP * perf_caps->highest_perf / max_cap;
step = perf_prev / perf_step;
*cost = compute_cost(cpu_dev->id, step);
return 0;
}
static int populate_efficiency_class(void)
{
struct acpi_madt_generic_interrupt *gicc;
DECLARE_BITMAP(used_classes, 256) = {};
int class, cpu, index;
for_each_possible_cpu(cpu) {
gicc = acpi_cpu_get_madt_gicc(cpu);
class = gicc->efficiency_class;
bitmap_set(used_classes, class, 1);
}
if (bitmap_weight(used_classes, 256) <= 1) {
pr_debug("Efficiency classes are all equal (=%d). "
"No EM registered", class);
return -EINVAL;
}
/*
* Squeeze efficiency class values on [0:#efficiency_class-1].
* Values are per spec in [0:255].
*/
index = 0;
for_each_set_bit(class, used_classes, 256) {
for_each_possible_cpu(cpu) {
gicc = acpi_cpu_get_madt_gicc(cpu);
if (gicc->efficiency_class == class)
per_cpu(efficiency_class, cpu) = index;
}
index++;
}
cppc_cpufreq_driver.register_em = cppc_cpufreq_register_em;
return 0;
}
static void cppc_cpufreq_register_em(struct cpufreq_policy *policy)
{
struct cppc_cpudata *cpu_data;
struct em_data_callback em_cb =
EM_ADV_DATA_CB(cppc_get_cpu_power, cppc_get_cpu_cost);
cpu_data = policy->driver_data;
em_dev_register_perf_domain(get_cpu_device(policy->cpu),
get_perf_level_count(policy), &em_cb,
cpu_data->shared_cpu_map, 0);
}
#else
static int populate_efficiency_class(void)
{
return 0;
}
#endif
static struct cppc_cpudata *cppc_cpufreq_get_cpu_data(unsigned int cpu)
{
struct cppc_cpudata *cpu_data;
int ret;
cpu_data = kzalloc(sizeof(struct cppc_cpudata), GFP_KERNEL);
if (!cpu_data)
goto out;
if (!zalloc_cpumask_var(&cpu_data->shared_cpu_map, GFP_KERNEL))
goto free_cpu;
ret = acpi_get_psd_map(cpu, cpu_data);
if (ret) {
pr_debug("Err parsing CPU%d PSD data: ret:%d\n", cpu, ret);
goto free_mask;
}
ret = cppc_get_perf_caps(cpu, &cpu_data->perf_caps);
if (ret) {
pr_debug("Err reading CPU%d perf caps: ret:%d\n", cpu, ret);
goto free_mask;
}
list_add(&cpu_data->node, &cpu_data_list);
return cpu_data;
free_mask:
free_cpumask_var(cpu_data->shared_cpu_map);
free_cpu:
kfree(cpu_data);
out:
return NULL;
}
static void cppc_cpufreq_put_cpu_data(struct cpufreq_policy *policy)
{
struct cppc_cpudata *cpu_data = policy->driver_data;
list_del(&cpu_data->node);
free_cpumask_var(cpu_data->shared_cpu_map);
kfree(cpu_data);
policy->driver_data = NULL;
}
static int cppc_cpufreq_cpu_init(struct cpufreq_policy *policy)
{
unsigned int cpu = policy->cpu;
struct cppc_cpudata *cpu_data;
struct cppc_perf_caps *caps;
int ret;
cpu_data = cppc_cpufreq_get_cpu_data(cpu);
if (!cpu_data) {
pr_err("Error in acquiring _CPC/_PSD data for CPU%d.\n", cpu);
return -ENODEV;
}
caps = &cpu_data->perf_caps;
policy->driver_data = cpu_data;
/*
* Set min to lowest nonlinear perf to avoid any efficiency penalty (see
* Section 8.4.7.1.1.5 of ACPI 6.1 spec)
*/
policy->min = cppc_perf_to_khz(caps, caps->lowest_nonlinear_perf);
policy->max = cppc_perf_to_khz(caps, caps->nominal_perf);
/*
* Set cpuinfo.min_freq to Lowest to make the full range of performance
* available if userspace wants to use any perf between lowest & lowest
* nonlinear perf
*/
policy->cpuinfo.min_freq = cppc_perf_to_khz(caps, caps->lowest_perf);
policy->cpuinfo.max_freq = cppc_perf_to_khz(caps, caps->nominal_perf);
policy->transition_delay_us = cppc_cpufreq_get_transition_delay_us(cpu);
policy->shared_type = cpu_data->shared_type;
switch (policy->shared_type) {
case CPUFREQ_SHARED_TYPE_HW:
case CPUFREQ_SHARED_TYPE_NONE:
/* Nothing to be done - we'll have a policy for each CPU */
break;
case CPUFREQ_SHARED_TYPE_ANY:
/*
* All CPUs in the domain will share a policy and all cpufreq
* operations will use a single cppc_cpudata structure stored
* in policy->driver_data.
*/
cpumask_copy(policy->cpus, cpu_data->shared_cpu_map);
break;
default:
pr_debug("Unsupported CPU co-ord type: %d\n",
policy->shared_type);
ret = -EFAULT;
goto out;
}
policy->fast_switch_possible = cppc_allow_fast_switch();
policy->dvfs_possible_from_any_cpu = true;
/*
* If 'highest_perf' is greater than 'nominal_perf', we assume CPU Boost
* is supported.
*/
if (caps->highest_perf > caps->nominal_perf)
boost_supported = true;
/* Set policy->cur to max now. The governors will adjust later. */
policy->cur = cppc_perf_to_khz(caps, caps->highest_perf);
cpu_data->perf_ctrls.desired_perf = caps->highest_perf;
ret = cppc_set_perf(cpu, &cpu_data->perf_ctrls);
if (ret) {
pr_debug("Err setting perf value:%d on CPU:%d. ret:%d\n",
caps->highest_perf, cpu, ret);
goto out;
}
cppc_cpufreq_cpu_fie_init(policy);
return 0;
out:
cppc_cpufreq_put_cpu_data(policy);
return ret;
}
static void cppc_cpufreq_cpu_exit(struct cpufreq_policy *policy)
{
struct cppc_cpudata *cpu_data = policy->driver_data;
struct cppc_perf_caps *caps = &cpu_data->perf_caps;
unsigned int cpu = policy->cpu;
int ret;
cppc_cpufreq_cpu_fie_exit(policy);
cpu_data->perf_ctrls.desired_perf = caps->lowest_perf;
ret = cppc_set_perf(cpu, &cpu_data->perf_ctrls);
if (ret)
pr_debug("Err setting perf value:%d on CPU:%d. ret:%d\n",
caps->lowest_perf, cpu, ret);
cppc_cpufreq_put_cpu_data(policy);
}
static inline u64 get_delta(u64 t1, u64 t0)
{
if (t1 > t0 || t0 > ~(u32)0)
return t1 - t0;
return (u32)t1 - (u32)t0;
}
static int cppc_perf_from_fbctrs(struct cppc_cpudata *cpu_data,
struct cppc_perf_fb_ctrs *fb_ctrs_t0,
struct cppc_perf_fb_ctrs *fb_ctrs_t1)
{
u64 delta_reference, delta_delivered;
u64 reference_perf;
reference_perf = fb_ctrs_t0->reference_perf;
delta_reference = get_delta(fb_ctrs_t1->reference,
fb_ctrs_t0->reference);
delta_delivered = get_delta(fb_ctrs_t1->delivered,
fb_ctrs_t0->delivered);
/* Check to avoid divide-by zero and invalid delivered_perf */
if (!delta_reference || !delta_delivered)
return cpu_data->perf_ctrls.desired_perf;
return (reference_perf * delta_delivered) / delta_reference;
}
static unsigned int cppc_cpufreq_get_rate(unsigned int cpu)
{
struct cppc_perf_fb_ctrs fb_ctrs_t0 = {0}, fb_ctrs_t1 = {0};
struct cpufreq_policy *policy = cpufreq_cpu_get(cpu);
struct cppc_cpudata *cpu_data;
u64 delivered_perf;
int ret;
if (!policy)
return -ENODEV;
cpu_data = policy->driver_data;
cpufreq_cpu_put(policy);
ret = cppc_get_perf_ctrs(cpu, &fb_ctrs_t0);
if (ret)
return 0;
udelay(2); /* 2usec delay between sampling */
ret = cppc_get_perf_ctrs(cpu, &fb_ctrs_t1);
if (ret)
return 0;
delivered_perf = cppc_perf_from_fbctrs(cpu_data, &fb_ctrs_t0,
&fb_ctrs_t1);
return cppc_perf_to_khz(&cpu_data->perf_caps, delivered_perf);
}
static int cppc_cpufreq_set_boost(struct cpufreq_policy *policy, int state)
{
struct cppc_cpudata *cpu_data = policy->driver_data;
struct cppc_perf_caps *caps = &cpu_data->perf_caps;
int ret;
if (!boost_supported) {
pr_err("BOOST not supported by CPU or firmware\n");
return -EINVAL;
}
if (state)
policy->max = cppc_perf_to_khz(caps, caps->highest_perf);
else
policy->max = cppc_perf_to_khz(caps, caps->nominal_perf);
policy->cpuinfo.max_freq = policy->max;
ret = freq_qos_update_request(policy->max_freq_req, policy->max);
if (ret < 0)
return ret;
return 0;
}
static ssize_t show_freqdomain_cpus(struct cpufreq_policy *policy, char *buf)
{
struct cppc_cpudata *cpu_data = policy->driver_data;
return cpufreq_show_cpus(cpu_data->shared_cpu_map, buf);
}
cpufreq_freq_attr_ro(freqdomain_cpus);
static struct freq_attr *cppc_cpufreq_attr[] = {
&freqdomain_cpus,
NULL,
};
static struct cpufreq_driver cppc_cpufreq_driver = {
.flags = CPUFREQ_CONST_LOOPS,
.verify = cppc_verify_policy,
.target = cppc_cpufreq_set_target,
.get = cppc_cpufreq_get_rate,
.fast_switch = cppc_cpufreq_fast_switch,
.init = cppc_cpufreq_cpu_init,
.exit = cppc_cpufreq_cpu_exit,
.set_boost = cppc_cpufreq_set_boost,
.attr = cppc_cpufreq_attr,
.name = "cppc_cpufreq",
};
/*
* HISI platform does not support delivered performance counter and
* reference performance counter. It can calculate the performance using the
* platform specific mechanism. We reuse the desired performance register to
* store the real performance calculated by the platform.
*/
static unsigned int hisi_cppc_cpufreq_get_rate(unsigned int cpu)
{
struct cpufreq_policy *policy = cpufreq_cpu_get(cpu);
struct cppc_cpudata *cpu_data;
u64 desired_perf;
int ret;
if (!policy)
return -ENODEV;
cpu_data = policy->driver_data;
cpufreq_cpu_put(policy);
ret = cppc_get_desired_perf(cpu, &desired_perf);
if (ret < 0)
return -EIO;
return cppc_perf_to_khz(&cpu_data->perf_caps, desired_perf);
}
static void cppc_check_hisi_workaround(void)
{
struct acpi_table_header *tbl;
acpi_status status = AE_OK;
int i;
status = acpi_get_table(ACPI_SIG_PCCT, 0, &tbl);
if (ACPI_FAILURE(status) || !tbl)
return;
for (i = 0; i < ARRAY_SIZE(wa_info); i++) {
if (!memcmp(wa_info[i].oem_id, tbl->oem_id, ACPI_OEM_ID_SIZE) &&
!memcmp(wa_info[i].oem_table_id, tbl->oem_table_id, ACPI_OEM_TABLE_ID_SIZE) &&
wa_info[i].oem_revision == tbl->oem_revision) {
/* Overwrite the get() callback */
cppc_cpufreq_driver.get = hisi_cppc_cpufreq_get_rate;
fie_disabled = FIE_DISABLED;
break;
}
}
acpi_put_table(tbl);
}
static int __init cppc_cpufreq_init(void)
{
int ret;
if (!acpi_cpc_valid())
return -ENODEV;
cppc_check_hisi_workaround();
cppc_freq_invariance_init();
populate_efficiency_class();
ret = cpufreq_register_driver(&cppc_cpufreq_driver);
if (ret)
cppc_freq_invariance_exit();
return ret;
}
static inline void free_cpu_data(void)
{
struct cppc_cpudata *iter, *tmp;
list_for_each_entry_safe(iter, tmp, &cpu_data_list, node) {
free_cpumask_var(iter->shared_cpu_map);
list_del(&iter->node);
kfree(iter);
}
}
static void __exit cppc_cpufreq_exit(void)
{
cpufreq_unregister_driver(&cppc_cpufreq_driver);
cppc_freq_invariance_exit();
free_cpu_data();
}
module_exit(cppc_cpufreq_exit);
MODULE_AUTHOR("Ashwin Chaugule");
MODULE_DESCRIPTION("CPUFreq driver based on the ACPI CPPC v5.0+ spec");
MODULE_LICENSE("GPL");
late_initcall(cppc_cpufreq_init);
static const struct acpi_device_id cppc_acpi_ids[] __used = {
{ACPI_PROCESSOR_DEVICE_HID, },
{}
};
MODULE_DEVICE_TABLE(acpi, cppc_acpi_ids);