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|
// SPDX-License-Identifier: GPL-2.0 WITH Linux-syscall-note
/*
*
* (C) COPYRIGHT 2016-2021 ARM Limited. All rights reserved.
*
* This program is free software and is provided to you under the terms of the
* GNU General Public License version 2 as published by the Free Software
* Foundation, and any use by you of this program is subject to the terms
* of such GNU license.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, you can access it online at
* http://www.gnu.org/licenses/gpl-2.0.html.
*
*/
#include <linux/thermal.h>
#include <linux/devfreq_cooling.h>
#include <linux/of.h>
#include "mali_kbase.h"
#include "mali_kbase_ipa.h"
#include "mali_kbase_ipa_debugfs.h"
#include "mali_kbase_ipa_simple.h"
#include "backend/gpu/mali_kbase_pm_internal.h"
#include "backend/gpu/mali_kbase_devfreq.h"
#include <linux/pm_opp.h>
#define KBASE_IPA_FALLBACK_MODEL_NAME "mali-simple-power-model"
/* Polling by thermal governor starts when the temperature exceeds the certain
* trip point. In order to have meaningful value for the counters, when the
* polling starts and first call to kbase_get_real_power() is made, it is
* required to reset the counter values every now and then.
* It is reasonable to do the reset every second if no polling is being done,
* the counter model implementation also assumes max sampling interval of 1 sec.
*/
#define RESET_INTERVAL_MS ((s64)1000)
int kbase_ipa_model_recalculate(struct kbase_ipa_model *model)
{
int err = 0;
lockdep_assert_held(&model->kbdev->ipa.lock);
if (model->ops->recalculate) {
err = model->ops->recalculate(model);
if (err) {
dev_err(model->kbdev->dev,
"recalculation of power model %s returned error %d\n",
model->ops->name, err);
}
}
return err;
}
const struct kbase_ipa_model_ops *kbase_ipa_model_ops_find(struct kbase_device *kbdev,
const char *name)
{
if (!strcmp(name, kbase_simple_ipa_model_ops.name))
return &kbase_simple_ipa_model_ops;
return kbase_ipa_counter_model_ops_find(kbdev, name);
}
KBASE_EXPORT_TEST_API(kbase_ipa_model_ops_find);
const char *kbase_ipa_model_name_from_id(u32 gpu_id)
{
const char* model_name =
kbase_ipa_counter_model_name_from_id(gpu_id);
if (!model_name)
return KBASE_IPA_FALLBACK_MODEL_NAME;
else
return model_name;
}
KBASE_EXPORT_TEST_API(kbase_ipa_model_name_from_id);
static struct device_node *get_model_dt_node(struct kbase_ipa_model *model,
bool dt_required)
{
struct device_node *model_dt_node;
char compat_string[64];
snprintf(compat_string, sizeof(compat_string), "arm,%s",
model->ops->name);
/* of_find_compatible_node() will call of_node_put() on the root node,
* so take a reference on it first.
*/
of_node_get(model->kbdev->dev->of_node);
model_dt_node = of_find_compatible_node(model->kbdev->dev->of_node,
NULL, compat_string);
if (!model_dt_node && !model->missing_dt_node_warning) {
if (dt_required)
dev_warn(model->kbdev->dev,
"Couldn't find power_model DT node matching \'%s\'\n",
compat_string);
model->missing_dt_node_warning = true;
}
return model_dt_node;
}
int kbase_ipa_model_add_param_s32(struct kbase_ipa_model *model,
const char *name, s32 *addr,
size_t num_elems, bool dt_required)
{
int err, i;
struct device_node *model_dt_node = get_model_dt_node(model,
dt_required);
char *origin;
err = of_property_read_u32_array(model_dt_node, name, addr, num_elems);
/* We're done with model_dt_node now, so drop the reference taken in
* get_model_dt_node()/of_find_compatible_node().
*/
of_node_put(model_dt_node);
if (err && dt_required) {
memset(addr, 0, sizeof(s32) * num_elems);
dev_warn(model->kbdev->dev,
"Error %d, no DT entry: %s.%s = %zu*[0]\n",
err, model->ops->name, name, num_elems);
origin = "zero";
} else if (err && !dt_required) {
origin = "default";
} else /* !err */ {
origin = "DT";
}
/* Create a unique debugfs entry for each element */
for (i = 0; i < num_elems; ++i) {
char elem_name[32];
if (num_elems == 1)
snprintf(elem_name, sizeof(elem_name), "%s", name);
else
snprintf(elem_name, sizeof(elem_name), "%s.%d",
name, i);
dev_dbg(model->kbdev->dev, "%s.%s = %d (%s)\n",
model->ops->name, elem_name, addr[i], origin);
err = kbase_ipa_model_param_add(model, elem_name,
&addr[i], sizeof(s32),
PARAM_TYPE_S32);
if (err)
goto exit;
}
exit:
return err;
}
int kbase_ipa_model_add_param_string(struct kbase_ipa_model *model,
const char *name, char *addr,
size_t size, bool dt_required)
{
int err;
struct device_node *model_dt_node = get_model_dt_node(model,
dt_required);
const char *string_prop_value;
char *origin;
err = of_property_read_string(model_dt_node, name,
&string_prop_value);
/* We're done with model_dt_node now, so drop the reference taken in
* get_model_dt_node()/of_find_compatible_node().
*/
of_node_put(model_dt_node);
if (err && dt_required) {
strncpy(addr, "", size - 1);
dev_warn(model->kbdev->dev,
"Error %d, no DT entry: %s.%s = \'%s\'\n",
err, model->ops->name, name, addr);
err = 0;
origin = "zero";
} else if (err && !dt_required) {
origin = "default";
} else /* !err */ {
strncpy(addr, string_prop_value, size - 1);
origin = "DT";
}
addr[size - 1] = '\0';
dev_dbg(model->kbdev->dev, "%s.%s = \'%s\' (%s)\n",
model->ops->name, name, string_prop_value, origin);
err = kbase_ipa_model_param_add(model, name, addr, size,
PARAM_TYPE_STRING);
return err;
}
void kbase_ipa_term_model(struct kbase_ipa_model *model)
{
if (!model)
return;
lockdep_assert_held(&model->kbdev->ipa.lock);
if (model->ops->term)
model->ops->term(model);
kbase_ipa_model_param_free_all(model);
kfree(model);
}
KBASE_EXPORT_TEST_API(kbase_ipa_term_model);
struct kbase_ipa_model *kbase_ipa_init_model(struct kbase_device *kbdev,
const struct kbase_ipa_model_ops *ops)
{
struct kbase_ipa_model *model;
int err;
lockdep_assert_held(&kbdev->ipa.lock);
if (!ops || !ops->name)
return NULL;
model = kzalloc(sizeof(struct kbase_ipa_model), GFP_KERNEL);
if (!model)
return NULL;
model->kbdev = kbdev;
model->ops = ops;
INIT_LIST_HEAD(&model->params);
err = model->ops->init(model);
if (err) {
dev_err(kbdev->dev,
"init of power model \'%s\' returned error %d\n",
ops->name, err);
kfree(model);
return NULL;
}
err = kbase_ipa_model_recalculate(model);
if (err) {
kbase_ipa_term_model(model);
return NULL;
}
return model;
}
KBASE_EXPORT_TEST_API(kbase_ipa_init_model);
static void kbase_ipa_term_locked(struct kbase_device *kbdev)
{
lockdep_assert_held(&kbdev->ipa.lock);
/* Clean up the models */
if (kbdev->ipa.configured_model != kbdev->ipa.fallback_model)
kbase_ipa_term_model(kbdev->ipa.configured_model);
kbase_ipa_term_model(kbdev->ipa.fallback_model);
kbdev->ipa.configured_model = NULL;
kbdev->ipa.fallback_model = NULL;
}
int kbase_ipa_init(struct kbase_device *kbdev)
{
const char *model_name;
const struct kbase_ipa_model_ops *ops;
struct kbase_ipa_model *default_model = NULL;
int err;
mutex_init(&kbdev->ipa.lock);
/*
* Lock during init to avoid warnings from lockdep_assert_held (there
* shouldn't be any concurrent access yet).
*/
mutex_lock(&kbdev->ipa.lock);
/* The simple IPA model must *always* be present.*/
ops = kbase_ipa_model_ops_find(kbdev, KBASE_IPA_FALLBACK_MODEL_NAME);
default_model = kbase_ipa_init_model(kbdev, ops);
if (!default_model) {
err = -EINVAL;
goto end;
}
kbdev->ipa.fallback_model = default_model;
err = of_property_read_string(kbdev->dev->of_node,
"ipa-model",
&model_name);
if (err) {
/* Attempt to load a match from GPU-ID */
u32 gpu_id;
gpu_id = kbdev->gpu_props.props.raw_props.gpu_id;
model_name = kbase_ipa_model_name_from_id(gpu_id);
dev_dbg(kbdev->dev,
"Inferring model from GPU ID 0x%x: \'%s\'\n",
gpu_id, model_name);
err = 0;
} else {
dev_dbg(kbdev->dev,
"Using ipa-model parameter from DT: \'%s\'\n",
model_name);
}
if (strcmp(KBASE_IPA_FALLBACK_MODEL_NAME, model_name) != 0) {
ops = kbase_ipa_model_ops_find(kbdev, model_name);
kbdev->ipa.configured_model = kbase_ipa_init_model(kbdev, ops);
if (!kbdev->ipa.configured_model) {
dev_warn(kbdev->dev,
"Failed to initialize ipa-model: \'%s\'\n"
"Falling back on default model\n",
model_name);
kbdev->ipa.configured_model = default_model;
}
} else {
kbdev->ipa.configured_model = default_model;
}
kbdev->ipa.last_sample_time = ktime_get();
end:
if (err)
kbase_ipa_term_locked(kbdev);
else
dev_info(kbdev->dev,
"Using configured power model %s, and fallback %s\n",
kbdev->ipa.configured_model->ops->name,
kbdev->ipa.fallback_model->ops->name);
mutex_unlock(&kbdev->ipa.lock);
return err;
}
KBASE_EXPORT_TEST_API(kbase_ipa_init);
void kbase_ipa_term(struct kbase_device *kbdev)
{
mutex_lock(&kbdev->ipa.lock);
kbase_ipa_term_locked(kbdev);
mutex_unlock(&kbdev->ipa.lock);
mutex_destroy(&kbdev->ipa.lock);
}
KBASE_EXPORT_TEST_API(kbase_ipa_term);
/**
* kbase_scale_dynamic_power() - Scale a dynamic power coefficient to an OPP
* @c: Dynamic model coefficient, in pW/(Hz V^2). Should be in range
* 0 < c < 2^26 to prevent overflow.
* @freq: Frequency, in Hz. Range: 2^23 < freq < 2^30 (~8MHz to ~1GHz)
* @voltage: Voltage, in mV. Range: 2^9 < voltage < 2^13 (~0.5V to ~8V)
*
* Keep a record of the approximate range of each value at every stage of the
* calculation, to ensure we don't overflow. This makes heavy use of the
* approximations 1000 = 2^10 and 1000000 = 2^20, but does the actual
* calculations in decimal for increased accuracy.
*
* Return: Power consumption, in mW. Range: 0 < p < 2^13 (0W to ~8W)
*/
static u32 kbase_scale_dynamic_power(const u32 c, const u32 freq,
const u32 voltage)
{
/* Range: 2^8 < v2 < 2^16 m(V^2) */
const u32 v2 = (voltage * voltage) / 1000;
/* Range: 2^3 < f_MHz < 2^10 MHz */
const u32 f_MHz = freq / 1000000;
/* Range: 2^11 < v2f_big < 2^26 kHz V^2 */
const u32 v2f_big = v2 * f_MHz;
/* Range: 2^1 < v2f < 2^16 MHz V^2 */
const u32 v2f = v2f_big / 1000;
/* Range (working backwards from next line): 0 < v2fc < 2^23 uW.
* Must be < 2^42 to avoid overflowing the return value.
*/
const u64 v2fc = (u64) c * (u64) v2f;
/* Range: 0 < v2fc / 1000 < 2^13 mW */
return div_u64(v2fc, 1000);
}
/**
* kbase_scale_static_power() - Scale a static power coefficient to an OPP
* @c: Static model coefficient, in uW/V^3. Should be in range
* 0 < c < 2^32 to prevent overflow.
* @voltage: Voltage, in mV. Range: 2^9 < voltage < 2^13 (~0.5V to ~8V)
*
* Return: Power consumption, in mW. Range: 0 < p < 2^13 (0W to ~8W)
*/
u32 kbase_scale_static_power(const u32 c, const u32 voltage)
{
/* Range: 2^8 < v2 < 2^16 m(V^2) */
const u32 v2 = (voltage * voltage) / 1000;
/* Range: 2^17 < v3_big < 2^29 m(V^2) mV */
const u32 v3_big = v2 * voltage;
/* Range: 2^7 < v3 < 2^19 m(V^3) */
const u32 v3 = v3_big / 1000;
/*
* Range (working backwards from next line): 0 < v3c_big < 2^33 nW.
* The result should be < 2^52 to avoid overflowing the return value.
*/
const u64 v3c_big = (u64) c * (u64) v3;
/* Range: 0 < v3c_big / 1000000 < 2^13 mW */
return div_u64(v3c_big, 1000000);
}
void kbase_ipa_protection_mode_switch_event(struct kbase_device *kbdev)
{
lockdep_assert_held(&kbdev->hwaccess_lock);
/* Record the event of GPU entering protected mode. */
kbdev->ipa_protection_mode_switched = true;
}
static struct kbase_ipa_model *get_current_model(struct kbase_device *kbdev)
{
struct kbase_ipa_model *model;
unsigned long flags;
lockdep_assert_held(&kbdev->ipa.lock);
spin_lock_irqsave(&kbdev->hwaccess_lock, flags);
if (kbdev->ipa_protection_mode_switched ||
kbdev->ipa.force_fallback_model)
model = kbdev->ipa.fallback_model;
else
model = kbdev->ipa.configured_model;
/*
* Having taken cognizance of the fact that whether GPU earlier
* protected mode or not, the event can be now reset (if GPU is not
* currently in protected mode) so that configured model is used
* for the next sample.
*/
if (!kbdev->protected_mode)
kbdev->ipa_protection_mode_switched = false;
spin_unlock_irqrestore(&kbdev->hwaccess_lock, flags);
return model;
}
static u32 get_static_power_locked(struct kbase_device *kbdev,
struct kbase_ipa_model *model,
unsigned long voltage)
{
u32 power = 0;
int err;
u32 power_coeff;
lockdep_assert_held(&model->kbdev->ipa.lock);
if (!model->ops->get_static_coeff)
model = kbdev->ipa.fallback_model;
if (model->ops->get_static_coeff) {
err = model->ops->get_static_coeff(model, &power_coeff);
if (!err)
power = kbase_scale_static_power(power_coeff,
(u32) voltage);
}
return power;
}
#if KERNEL_VERSION(5, 10, 0) > LINUX_VERSION_CODE
#if defined(CONFIG_MALI_PWRSOFT_765) || \
KERNEL_VERSION(4, 10, 0) <= LINUX_VERSION_CODE
static unsigned long kbase_get_static_power(struct devfreq *df,
unsigned long voltage)
#else
static unsigned long kbase_get_static_power(unsigned long voltage)
#endif
{
struct kbase_ipa_model *model;
u32 power = 0;
#if defined(CONFIG_MALI_PWRSOFT_765) || \
KERNEL_VERSION(4, 10, 0) <= LINUX_VERSION_CODE
struct kbase_device *kbdev = dev_get_drvdata(&df->dev);
#else
struct kbase_device *kbdev = kbase_find_device(-1);
#endif
if (!kbdev)
return 0ul;
mutex_lock(&kbdev->ipa.lock);
model = get_current_model(kbdev);
power = get_static_power_locked(kbdev, model, voltage);
mutex_unlock(&kbdev->ipa.lock);
#if !(defined(CONFIG_MALI_PWRSOFT_765) || \
KERNEL_VERSION(4, 10, 0) <= LINUX_VERSION_CODE)
kbase_release_device(kbdev);
#endif
return power;
}
#endif /* KERNEL_VERSION(5, 10, 0) > LINUX_VERSION_CODE */
/**
* opp_translate_freq_voltage() - Translate nominal OPP frequency from
* devicetree into the real frequency for
* top-level and shader cores.
* @kbdev: Device pointer
* @nominal_freq: Nominal frequency in Hz.
* @nominal_voltage: Nominal voltage, in mV.
* @freqs: Pointer to array of real frequency values.
* @volts: Pointer to array of voltages.
*
* If there are 2 clock domains, then top-level and shader cores can operate
* at different frequency and voltage level. The nominal frequency ("opp-hz")
* used by devfreq from the devicetree may not be same as the real frequency
* at which top-level and shader cores are operating, so a translation is
* needed.
* Nominal voltage shall always be same as the real voltage for top-level.
*/
static void opp_translate_freq_voltage(struct kbase_device *kbdev,
unsigned long nominal_freq,
unsigned long nominal_voltage,
unsigned long *freqs,
unsigned long *volts)
{
u64 core_mask;
kbase_devfreq_opp_translate(kbdev, nominal_freq, &core_mask,
freqs, volts);
CSTD_UNUSED(core_mask);
if (kbdev->nr_clocks == 1) {
freqs[KBASE_IPA_BLOCK_TYPE_SHADER_CORES] =
freqs[KBASE_IPA_BLOCK_TYPE_TOP_LEVEL];
volts[KBASE_IPA_BLOCK_TYPE_SHADER_CORES] =
volts[KBASE_IPA_BLOCK_TYPE_TOP_LEVEL];
}
}
#if KERNEL_VERSION(5, 10, 0) > LINUX_VERSION_CODE
#if defined(CONFIG_MALI_PWRSOFT_765) || \
KERNEL_VERSION(4, 10, 0) <= LINUX_VERSION_CODE
static unsigned long kbase_get_dynamic_power(struct devfreq *df,
unsigned long freq,
unsigned long voltage)
#else
static unsigned long kbase_get_dynamic_power(unsigned long freq,
unsigned long voltage)
#endif
{
struct kbase_ipa_model *model;
unsigned long freqs[KBASE_IPA_BLOCK_TYPE_NUM] = {0};
unsigned long volts[KBASE_IPA_BLOCK_TYPE_NUM] = {0};
u32 power_coeffs[KBASE_IPA_BLOCK_TYPE_NUM] = {0};
u32 power = 0;
int err = 0;
#if defined(CONFIG_MALI_PWRSOFT_765) || \
KERNEL_VERSION(4, 10, 0) <= LINUX_VERSION_CODE
struct kbase_device *kbdev = dev_get_drvdata(&df->dev);
#else
struct kbase_device *kbdev = kbase_find_device(-1);
#endif
if (!kbdev)
return 0ul;
mutex_lock(&kbdev->ipa.lock);
model = kbdev->ipa.fallback_model;
err = model->ops->get_dynamic_coeff(model, power_coeffs);
if (!err) {
opp_translate_freq_voltage(kbdev, freq, voltage, freqs, volts);
power = kbase_scale_dynamic_power(
power_coeffs[KBASE_IPA_BLOCK_TYPE_TOP_LEVEL],
freqs[KBASE_IPA_BLOCK_TYPE_TOP_LEVEL],
volts[KBASE_IPA_BLOCK_TYPE_TOP_LEVEL]);
/* Here unlike kbase_get_real_power(), shader core frequency is
* used for the scaling as simple power model is used to obtain
* the value of dynamic coefficient (which is is a fixed value
* retrieved from the device tree).
*/
power += kbase_scale_dynamic_power(
power_coeffs[KBASE_IPA_BLOCK_TYPE_SHADER_CORES],
freqs[KBASE_IPA_BLOCK_TYPE_SHADER_CORES],
volts[KBASE_IPA_BLOCK_TYPE_SHADER_CORES]);
} else
dev_err_ratelimited(kbdev->dev,
"Model %s returned error code %d\n",
model->ops->name, err);
mutex_unlock(&kbdev->ipa.lock);
#if !(defined(CONFIG_MALI_PWRSOFT_765) || \
KERNEL_VERSION(4, 10, 0) <= LINUX_VERSION_CODE)
kbase_release_device(kbdev);
#endif
return power;
}
#endif /* KERNEL_VERSION(5, 10, 0) > LINUX_VERSION_CODE */
int kbase_get_real_power_locked(struct kbase_device *kbdev, u32 *power,
unsigned long freq,
unsigned long voltage)
{
struct kbase_ipa_model *model;
unsigned long freqs[KBASE_IPA_BLOCK_TYPE_NUM] = {0};
unsigned long volts[KBASE_IPA_BLOCK_TYPE_NUM] = {0};
u32 power_coeffs[KBASE_IPA_BLOCK_TYPE_NUM] = {0};
struct kbasep_pm_metrics diff;
u64 total_time;
bool skip_utilization_scaling = false;
int err = 0;
lockdep_assert_held(&kbdev->ipa.lock);
kbase_pm_get_dvfs_metrics(kbdev, &kbdev->ipa.last_metrics, &diff);
model = get_current_model(kbdev);
err = model->ops->get_dynamic_coeff(model, power_coeffs);
/* If the counter model returns an error (e.g. switching back to
* protected mode and failing to read counters, or a counter sample
* with too few cycles), revert to the fallback model.
*/
if (err && model != kbdev->ipa.fallback_model) {
/* No meaningful scaling for GPU utilization can be done if
* the sampling interval was too long. This is equivalent to
* assuming GPU was busy throughout (similar to what is done
* during protected mode).
*/
if (err == -EOVERFLOW)
skip_utilization_scaling = true;
model = kbdev->ipa.fallback_model;
err = model->ops->get_dynamic_coeff(model, power_coeffs);
}
if (WARN_ON(err))
return err;
opp_translate_freq_voltage(kbdev, freq, voltage, freqs, volts);
*power = kbase_scale_dynamic_power(
power_coeffs[KBASE_IPA_BLOCK_TYPE_TOP_LEVEL],
freqs[KBASE_IPA_BLOCK_TYPE_TOP_LEVEL],
volts[KBASE_IPA_BLOCK_TYPE_TOP_LEVEL]);
if (power_coeffs[KBASE_IPA_BLOCK_TYPE_SHADER_CORES]) {
unsigned long freq = freqs[KBASE_IPA_BLOCK_TYPE_SHADER_CORES];
/* As per the HW team, the top-level frequency needs to be used
* for the scaling if the counter based model was used as
* counter values are normalized with the GPU_ACTIVE counter
* value, which increments at the rate of top-level frequency.
*/
if (model != kbdev->ipa.fallback_model)
freq = freqs[KBASE_IPA_BLOCK_TYPE_TOP_LEVEL];
*power += kbase_scale_dynamic_power(
power_coeffs[KBASE_IPA_BLOCK_TYPE_SHADER_CORES],
freq, volts[KBASE_IPA_BLOCK_TYPE_SHADER_CORES]);
}
if (!skip_utilization_scaling) {
/* time_busy / total_time cannot be >1, so assigning the 64-bit
* result of div_u64 to *power cannot overflow.
*/
total_time = diff.time_busy + (u64) diff.time_idle;
*power = div_u64(*power * (u64) diff.time_busy,
max(total_time, 1ull));
}
*power += get_static_power_locked(kbdev, model,
volts[KBASE_IPA_BLOCK_TYPE_TOP_LEVEL]);
return err;
}
KBASE_EXPORT_TEST_API(kbase_get_real_power_locked);
int kbase_get_real_power(struct devfreq *df, u32 *power,
unsigned long freq,
unsigned long voltage)
{
int ret;
struct kbase_device *kbdev = dev_get_drvdata(&df->dev);
if (!kbdev)
return -ENODEV;
mutex_lock(&kbdev->ipa.lock);
ret = kbase_get_real_power_locked(kbdev, power, freq, voltage);
mutex_unlock(&kbdev->ipa.lock);
return ret;
}
KBASE_EXPORT_TEST_API(kbase_get_real_power);
struct devfreq_cooling_power kbase_ipa_power_model_ops = {
#if KERNEL_VERSION(5, 10, 0) > LINUX_VERSION_CODE
.get_static_power = &kbase_get_static_power,
.get_dynamic_power = &kbase_get_dynamic_power,
#endif /* KERNEL_VERSION(5, 10, 0) > LINUX_VERSION_CODE */
#if defined(CONFIG_MALI_PWRSOFT_765) || \
KERNEL_VERSION(4, 10, 0) <= LINUX_VERSION_CODE
.get_real_power = &kbase_get_real_power,
#endif
};
KBASE_EXPORT_TEST_API(kbase_ipa_power_model_ops);
void kbase_ipa_reset_data(struct kbase_device *kbdev)
{
ktime_t now, diff;
s64 elapsed_time;
mutex_lock(&kbdev->ipa.lock);
now = ktime_get();
diff = ktime_sub(now, kbdev->ipa.last_sample_time);
elapsed_time = ktime_to_ms(diff);
if (elapsed_time > RESET_INTERVAL_MS) {
struct kbasep_pm_metrics diff;
struct kbase_ipa_model *model;
kbase_pm_get_dvfs_metrics(
kbdev, &kbdev->ipa.last_metrics, &diff);
model = get_current_model(kbdev);
if (model != kbdev->ipa.fallback_model)
model->ops->reset_counter_data(model);
kbdev->ipa.last_sample_time = ktime_get();
}
mutex_unlock(&kbdev->ipa.lock);
}
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