// SPDX-License-Identifier: GPL-2.0
/*
* AMD Platform Management Framework Driver
*
* Copyright (c) 2022, Advanced Micro Devices, Inc.
* All Rights Reserved.
*
* Author: Shyam Sundar S K <Shyam-sundar.S-k@amd.com>
*/
#include <linux/workqueue.h>
#include "pmf.h"
static struct cnqf_config config_store;
static int amd_pmf_set_cnqf(struct amd_pmf_dev *dev, int src, int idx,
struct cnqf_config *table)
{
struct power_table_control *pc;
pc = &config_store.mode_set[src][idx].power_control;
amd_pmf_send_cmd(dev, SET_SPL, false, pc->spl, NULL);
amd_pmf_send_cmd(dev, SET_FPPT, false, pc->fppt, NULL);
amd_pmf_send_cmd(dev, SET_SPPT, false, pc->sppt, NULL);
amd_pmf_send_cmd(dev, SET_SPPT_APU_ONLY, false, pc->sppt_apu_only, NULL);
amd_pmf_send_cmd(dev, SET_STT_MIN_LIMIT, false, pc->stt_min, NULL);
amd_pmf_send_cmd(dev, SET_STT_LIMIT_APU, false, pc->stt_skin_temp[STT_TEMP_APU],
NULL);
amd_pmf_send_cmd(dev, SET_STT_LIMIT_HS2, false, pc->stt_skin_temp[STT_TEMP_HS2],
NULL);
if (is_apmf_func_supported(dev, APMF_FUNC_SET_FAN_IDX))
apmf_update_fan_idx(dev,
config_store.mode_set[src][idx].fan_control.manual,
config_store.mode_set[src][idx].fan_control.fan_id);
return 0;
}
static void amd_pmf_update_power_threshold(int src)
{
struct cnqf_mode_settings *ts;
struct cnqf_tran_params *tp;
tp = &config_store.trans_param[src][CNQF_TRANSITION_TO_QUIET];
ts = &config_store.mode_set[src][CNQF_MODE_BALANCE];
tp->power_threshold = ts->power_floor;
tp = &config_store.trans_param[src][CNQF_TRANSITION_TO_TURBO];
ts = &config_store.mode_set[src][CNQF_MODE_PERFORMANCE];
tp->power_threshold = ts->power_floor;
tp = &config_store.trans_param[src][CNQF_TRANSITION_FROM_BALANCE_TO_PERFORMANCE];
ts = &config_store.mode_set[src][CNQF_MODE_BALANCE];
tp->power_threshold = ts->power_floor;
tp = &config_store.trans_param[src][CNQF_TRANSITION_FROM_PERFORMANCE_TO_BALANCE];
ts = &config_store.mode_set[src][CNQF_MODE_PERFORMANCE];
tp->power_threshold = ts->power_floor;
tp = &config_store.trans_param[src][CNQF_TRANSITION_FROM_QUIET_TO_BALANCE];
ts = &config_store.mode_set[src][CNQF_MODE_QUIET];
tp->power_threshold = ts->power_floor;
tp = &config_store.trans_param[src][CNQF_TRANSITION_FROM_TURBO_TO_PERFORMANCE];
ts = &config_store.mode_set[src][CNQF_MODE_TURBO];
tp->power_threshold = ts->power_floor;
}
static const char *state_as_str(unsigned int state)
{
switch (state) {
case CNQF_MODE_QUIET:
return "QUIET";
case CNQF_MODE_BALANCE:
return "BALANCED";
case CNQF_MODE_TURBO:
return "TURBO";
case CNQF_MODE_PERFORMANCE:
return "PERFORMANCE";
default:
return "Unknown CnQF mode";
}
}
static int amd_pmf_cnqf_get_power_source(struct amd_pmf_dev *dev)
{
if (is_apmf_func_supported(dev, APMF_FUNC_DYN_SLIDER_AC) &&
is_apmf_func_supported(dev, APMF_FUNC_DYN_SLIDER_DC))
return amd_pmf_get_power_source();
else if (is_apmf_func_supported(dev, APMF_FUNC_DYN_SLIDER_DC))
return POWER_SOURCE_DC;
else
return POWER_SOURCE_AC;
}
int amd_pmf_trans_cnqf(struct amd_pmf_dev *dev, int socket_power, ktime_t time_lapsed_ms)
{
struct cnqf_tran_params *tp;
int src, i, j;
u32 avg_power = 0;
src = amd_pmf_cnqf_get_power_source(dev);
if (is_pprof_balanced(dev)) {
amd_pmf_set_cnqf(dev, src, config_store.current_mode, NULL);
} else {
/*
* Return from here if the platform_profile is not balanced
* so that preference is given to user mode selection, rather
* than enforcing CnQF to run all the time (if enabled)
*/
return -EINVAL;
}
for (i = 0; i < CNQF_TRANSITION_MAX; i++) {
config_store.trans_param[src][i].timer += time_lapsed_ms;
config_store.trans_param[src][i].total_power += socket_power;
config_store.trans_param[src][i].count++;
tp = &config_store.trans_param[src][i];
if (tp->timer >= tp->time_constant && tp->count) {
avg_power = tp->total_power / tp->count;
/* Reset the indices */
tp->timer = 0;
tp->total_power = 0;
tp->count = 0;
if ((tp->shifting_up && avg_power >= tp->power_threshold) ||
(!tp->shifting_up && avg_power <= tp->power_threshold)) {
tp->priority = true;
} else {
tp->priority = false;
}
}
}
dev_dbg(dev->dev, "[CNQF] Avg power: %u mW socket power: %u mW mode:%s\n",
avg_power, socket_power, state_as_str(config_store.current_mode));
for (j = 0; j < CNQF_TRANSITION_MAX; j++) {
/* apply the highest priority */
if (config_store.trans_param[src][j].priority) {
if (config_store.current_mode !=
config_store.trans_param[src][j].target_mode) {
config_store.current_mode =
config_store.trans_param[src][j].target_mode;
dev_dbg(dev->dev, "Moving to Mode :%s\n",
state_as_str(config_store.current_mode));
amd_pmf_set_cnqf(dev, src,
config_store.current_mode, NULL);
}
break;
}
}
return 0;
}
static void amd_pmf_update_trans_data(int idx, struct apmf_dyn_slider_output out)
{
struct cnqf_tran_params *tp;
tp = &config_store.trans_param[idx][CNQF_TRANSITION_TO_QUIET];
tp->time_constant = out.t_balanced_to_quiet;
tp->target_mode = CNQF_MODE_QUIET;
tp->shifting_up = false;
tp = &config_store.trans_param[idx][CNQF_TRANSITION_FROM_BALANCE_TO_PERFORMANCE];
tp->time_constant = out.t_balanced_to_perf;
tp->target_mode = CNQF_MODE_PERFORMANCE;
tp->shifting_up = true;
tp = &config_store.trans_param[idx][CNQF_TRANSITION_FROM_QUIET_TO_BALANCE];
tp->time_constant = out.t_quiet_to_balanced;
tp->target_mode = CNQF_MODE_BALANCE;
tp->shifting_up = true;
tp = &config_store.trans_param[idx][CNQF_TRANSITION_FROM_PERFORMANCE_TO_BALANCE];
tp->time_constant = out.t_perf_to_balanced;
tp->target_mode = CNQF_MODE_BALANCE;
tp->shifting_up = false;
tp = &config_store.trans_param[idx][CNQF_TRANSITION_FROM_TURBO_TO_PERFORMANCE];
tp->time_constant = out.t_turbo_to_perf;
tp->target_mode = CNQF_MODE_PERFORMANCE;
tp->shifting_up = false;
tp = &config_store.trans_param[idx][CNQF_TRANSITION_TO_TURBO];
tp->time_constant = out.t_perf_to_turbo;
tp->target_mode = CNQF_MODE_TURBO;
tp->shifting_up = true;
}
static void amd_pmf_update_mode_set(int idx, struct apmf_dyn_slider_output out)
{
struct cnqf_mode_settings *ms;
/* Quiet Mode */
ms = &config_store.mode_set[idx][CNQF_MODE_QUIET];
ms->power_floor = out.ps[APMF_CNQF_QUIET].pfloor;
ms->power_control.fppt = out.ps[APMF_CNQF_QUIET].fppt;
ms->power_control.sppt = out.ps[APMF_CNQF_QUIET].sppt;
ms->power_control.sppt_apu_only = out.ps[APMF_CNQF_QUIET].sppt_apu_only;
ms->power_control.spl = out.ps[APMF_CNQF_QUIET].spl;
ms->power_control.stt_min = out.ps[APMF_CNQF_QUIET].stt_min_limit;
ms->power_control.stt_skin_temp[STT_TEMP_APU] =
out.ps[APMF_CNQF_QUIET].stt_skintemp[STT_TEMP_APU];
ms->power_control.stt_skin_temp[STT_TEMP_HS2] =
out.ps[APMF_CNQF_QUIET].stt_skintemp[STT_TEMP_HS2];
ms->fan_control.fan_id = out.ps[APMF_CNQF_QUIET].fan_id;
/* Balance Mode */
ms = &config_store.mode_set[idx][CNQF_MODE_BALANCE];
ms->power_floor = out.ps[APMF_CNQF_BALANCE].pfloor;
ms->power_control.fppt = out.ps[APMF_CNQF_BALANCE].fppt;
ms->power_control.sppt = out.ps[APMF_CNQF_BALANCE].sppt;
ms->power_control.sppt_apu_only = out.ps[APMF_CNQF_BALANCE].sppt_apu_only;
ms->power_control.spl = out.ps[APMF_CNQF_BALANCE].spl;
ms->power_control.stt_min = out.ps[APMF_CNQF_BALANCE].stt_min_limit;
ms->power_control.stt_skin_temp[STT_TEMP_APU] =
out.ps[APMF_CNQF_BALANCE].stt_skintemp[STT_TEMP_APU];
ms->power_control.stt_skin_temp[STT_TEMP_HS2] =
out.ps[APMF_CNQF_BALANCE].stt_skintemp[STT_TEMP_HS2];
ms->fan_control.fan_id = out.ps[APMF_CNQF_BALANCE].fan_id;
/* Performance Mode */
ms = &config_store.mode_set[idx][CNQF_MODE_PERFORMANCE];
ms->power_floor = out.ps[APMF_CNQF_PERFORMANCE].pfloor;
ms->power_control.fppt = out.ps[APMF_CNQF_PERFORMANCE].fppt;
ms->power_control.sppt = out.ps[APMF_CNQF_PERFORMANCE].sppt;
ms->power_control.sppt_apu_only = out.ps[APMF_CNQF_PERFORMANCE].sppt_apu_only;
ms->power_control.spl = out.ps[APMF_CNQF_PERFORMANCE].spl;
ms->power_control.stt_min = out.ps[APMF_CNQF_PERFORMANCE].stt_min_limit;
ms->power_control.stt_skin_temp[STT_TEMP_APU] =
out.ps[APMF_CNQF_PERFORMANCE].stt_skintemp[STT_TEMP_APU];
ms->power_control.stt_skin_temp[STT_TEMP_HS2] =
out.ps[APMF_CNQF_PERFORMANCE].stt_skintemp[STT_TEMP_HS2];
ms->fan_control.fan_id = out.ps[APMF_CNQF_PERFORMANCE].fan_id;
/* Turbo Mode */
ms = &config_store.mode_set[idx][CNQF_MODE_TURBO];
ms->power_floor = out.ps[APMF_CNQF_TURBO].pfloor;
ms->power_control.fppt = out.ps[APMF_CNQF_TURBO].fppt;
ms->power_control.sppt = out.ps[APMF_CNQF_TURBO].sppt;
ms->power_control.sppt_apu_only = out.ps[APMF_CNQF_TURBO].sppt_apu_only;
ms->power_control.spl = out.ps[APMF_CNQF_TURBO].spl;
ms->power_control.stt_min = out.ps[APMF_CNQF_TURBO].stt_min_limit;
ms->power_control.stt_skin_temp[STT_TEMP_APU] =
out.ps[APMF_CNQF_TURBO].stt_skintemp[STT_TEMP_APU];
ms->power_control.stt_skin_temp[STT_TEMP_HS2] =
out.ps[APMF_CNQF_TURBO].stt_skintemp[STT_TEMP_HS2];
ms->fan_control.fan_id = out.ps[APMF_CNQF_TURBO].fan_id;
}
static int amd_pmf_check_flags(struct amd_pmf_dev *dev)
{
struct apmf_dyn_slider_output out = {};
if (is_apmf_func_supported(dev, APMF_FUNC_DYN_SLIDER_AC))
apmf_get_dyn_slider_def_ac(dev, &out);
else if (is_apmf_func_supported(dev, APMF_FUNC_DYN_SLIDER_DC))
apmf_get_dyn_slider_def_dc(dev, &out);
return out.flags;
}
static int amd_pmf_load_defaults_cnqf(struct amd_pmf_dev *dev)
{
struct apmf_dyn_slider_output out;
int i, j, ret;
for (i = 0; i < POWER_SOURCE_MAX; i++) {
if (!is_apmf_func_supported(dev, APMF_FUNC_DYN_SLIDER_AC + i))
continue;
if (i == POWER_SOURCE_AC)
ret = apmf_get_dyn_slider_def_ac(dev, &out);
else
ret = apmf_get_dyn_slider_def_dc(dev, &out);
if (ret) {
dev_err(dev->dev, "APMF apmf_get_dyn_slider_def_dc failed :%d\n", ret);
return ret;
}
amd_pmf_update_mode_set(i, out);
amd_pmf_update_trans_data(i, out);
amd_pmf_update_power_threshold(i);
for (j = 0; j < CNQF_MODE_MAX; j++) {
if (config_store.mode_set[i][j].fan_control.fan_id == FAN_INDEX_AUTO)
config_store.mode_set[i][j].fan_control.manual = false;
else
config_store.mode_set[i][j].fan_control.manual = true;
}
}
/* set to initial default values */
config_store.current_mode = CNQF_MODE_BALANCE;
return 0;
}
static ssize_t cnqf_enable_store(struct device *dev,
struct device_attribute *attr,
const char *buf, size_t count)
{
struct amd_pmf_dev *pdev = dev_get_drvdata(dev);
int result, src;
bool input;
result = kstrtobool(buf, &input);
if (result)
return result;
src = amd_pmf_cnqf_get_power_source(pdev);
pdev->cnqf_enabled = input;
if (pdev->cnqf_enabled && is_pprof_balanced(pdev)) {
amd_pmf_set_cnqf(pdev, src, config_store.current_mode, NULL);
} else {
if (is_apmf_func_supported(pdev, APMF_FUNC_STATIC_SLIDER_GRANULAR))
amd_pmf_set_sps_power_limits(pdev);
}
dev_dbg(pdev->dev, "Received CnQF %s\n", input ? "on" : "off");
return count;
}
static ssize_t cnqf_enable_show(struct device *dev,
struct device_attribute *attr,
char *buf)
{
struct amd_pmf_dev *pdev = dev_get_drvdata(dev);
return sysfs_emit(buf, "%s\n", pdev->cnqf_enabled ? "on" : "off");
}
static DEVICE_ATTR_RW(cnqf_enable);
static umode_t cnqf_feature_is_visible(struct kobject *kobj,
struct attribute *attr, int n)
{
struct device *dev = kobj_to_dev(kobj);
struct amd_pmf_dev *pdev = dev_get_drvdata(dev);
return pdev->cnqf_supported ? attr->mode : 0;
}
static struct attribute *cnqf_feature_attrs[] = {
&dev_attr_cnqf_enable.attr,
NULL
};
const struct attribute_group cnqf_feature_attribute_group = {
.is_visible = cnqf_feature_is_visible,
.attrs = cnqf_feature_attrs,
};
void amd_pmf_deinit_cnqf(struct amd_pmf_dev *dev)
{
cancel_delayed_work_sync(&dev->work_buffer);
}
int amd_pmf_init_cnqf(struct amd_pmf_dev *dev)
{
int ret, src;
/*
* Note the caller of this function has already checked that both
* APMF_FUNC_DYN_SLIDER_AC and APMF_FUNC_DYN_SLIDER_DC are supported.
*/
ret = amd_pmf_load_defaults_cnqf(dev);
if (ret < 0)
return ret;
amd_pmf_init_metrics_table(dev);
dev->cnqf_supported = true;
dev->cnqf_enabled = amd_pmf_check_flags(dev);
/* update the thermal for CnQF */
if (dev->cnqf_enabled && is_pprof_balanced(dev)) {
src = amd_pmf_cnqf_get_power_source(dev);
amd_pmf_set_cnqf(dev, src, config_store.current_mode, NULL);
}
return 0;
}