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linux-yocto/drivers/net/wireless/realtek/rtw89/sar.c
Zong-Zhe Yang 583e998e20 wifi: rtw89: rename sub_entity to chanctx 
Originally, we planed to fill MAC_0/1 indicators with chanctx and
use sub_entity_xxx for these things. However, there are some reasons
listed below which make us give up this plan after we know our Wi-Fi 7
HW design.
	1. one link is bound to one HW band during its life time
	   but, one link might change chanctx dynamically
	2. in concurrent mode, assume 1st vif is MLD
	   1st vif's 2nd link might use the same chanctx as 2nd vif
	   but, they are not on the same HW band
So, we let sub_entity_xxx stuffs deal with only chanctx now. And, to be
more readable, we rename sub_entity related words to chanctx.

No logic is changed.

Signed-off-by: Zong-Zhe Yang <kevin_yang@realtek.com>
Signed-off-by: Ping-Ke Shih <pkshih@realtek.com>
Link: https://patch.msgid.link/20240727080650.12195-4-pkshih@realtek.com
2024-08-02 09:34:09 +08:00

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// SPDX-License-Identifier: GPL-2.0 OR BSD-3-Clause
/* Copyright(c) 2019-2020 Realtek Corporation
*/
#include "acpi.h"
#include "debug.h"
#include "phy.h"
#include "reg.h"
#include "sar.h"
#define RTW89_TAS_FACTOR 2 /* unit: 0.25 dBm */
#define RTW89_TAS_DPR_GAP (1 << RTW89_TAS_FACTOR)
#define RTW89_TAS_DELTA (2 << RTW89_TAS_FACTOR)
static enum rtw89_sar_subband rtw89_sar_get_subband(struct rtw89_dev *rtwdev,
u32 center_freq)
{
switch (center_freq) {
default:
rtw89_debug(rtwdev, RTW89_DBG_SAR,
"center freq: %u to SAR subband is unhandled\n",
center_freq);
fallthrough;
case 2412 ... 2484:
return RTW89_SAR_2GHZ_SUBBAND;
case 5180 ... 5320:
return RTW89_SAR_5GHZ_SUBBAND_1_2;
case 5500 ... 5720:
return RTW89_SAR_5GHZ_SUBBAND_2_E;
case 5745 ... 5825:
return RTW89_SAR_5GHZ_SUBBAND_3;
case 5955 ... 6155:
return RTW89_SAR_6GHZ_SUBBAND_5_L;
case 6175 ... 6415:
return RTW89_SAR_6GHZ_SUBBAND_5_H;
case 6435 ... 6515:
return RTW89_SAR_6GHZ_SUBBAND_6;
case 6535 ... 6695:
return RTW89_SAR_6GHZ_SUBBAND_7_L;
case 6715 ... 6855:
return RTW89_SAR_6GHZ_SUBBAND_7_H;
/* freq 6875 (ch 185, 20MHz) spans RTW89_SAR_6GHZ_SUBBAND_7_H
* and RTW89_SAR_6GHZ_SUBBAND_8, so directly describe it with
* struct rtw89_sar_span in the following.
*/
case 6895 ... 7115:
return RTW89_SAR_6GHZ_SUBBAND_8;
}
}
struct rtw89_sar_span {
enum rtw89_sar_subband subband_low;
enum rtw89_sar_subband subband_high;
};
#define RTW89_SAR_SPAN_VALID(span) ((span)->subband_high)
#define RTW89_SAR_6GHZ_SPAN_HEAD 6145
#define RTW89_SAR_6GHZ_SPAN_IDX(center_freq) \
((((int)(center_freq) - RTW89_SAR_6GHZ_SPAN_HEAD) / 5) / 2)
#define RTW89_DECL_SAR_6GHZ_SPAN(center_freq, subband_l, subband_h) \
[RTW89_SAR_6GHZ_SPAN_IDX(center_freq)] = { \
.subband_low = RTW89_SAR_6GHZ_ ## subband_l, \
.subband_high = RTW89_SAR_6GHZ_ ## subband_h, \
}
/* Since 6GHz SAR subbands are not edge aligned, some cases span two SAR
* subbands. In the following, we describe each of them with rtw89_sar_span.
*/
static const struct rtw89_sar_span rtw89_sar_overlapping_6ghz[] = {
RTW89_DECL_SAR_6GHZ_SPAN(6145, SUBBAND_5_L, SUBBAND_5_H),
RTW89_DECL_SAR_6GHZ_SPAN(6165, SUBBAND_5_L, SUBBAND_5_H),
RTW89_DECL_SAR_6GHZ_SPAN(6185, SUBBAND_5_L, SUBBAND_5_H),
RTW89_DECL_SAR_6GHZ_SPAN(6505, SUBBAND_6, SUBBAND_7_L),
RTW89_DECL_SAR_6GHZ_SPAN(6525, SUBBAND_6, SUBBAND_7_L),
RTW89_DECL_SAR_6GHZ_SPAN(6545, SUBBAND_6, SUBBAND_7_L),
RTW89_DECL_SAR_6GHZ_SPAN(6665, SUBBAND_7_L, SUBBAND_7_H),
RTW89_DECL_SAR_6GHZ_SPAN(6705, SUBBAND_7_L, SUBBAND_7_H),
RTW89_DECL_SAR_6GHZ_SPAN(6825, SUBBAND_7_H, SUBBAND_8),
RTW89_DECL_SAR_6GHZ_SPAN(6865, SUBBAND_7_H, SUBBAND_8),
RTW89_DECL_SAR_6GHZ_SPAN(6875, SUBBAND_7_H, SUBBAND_8),
RTW89_DECL_SAR_6GHZ_SPAN(6885, SUBBAND_7_H, SUBBAND_8),
};
static int rtw89_query_sar_config_common(struct rtw89_dev *rtwdev,
u32 center_freq, s32 *cfg)
{
struct rtw89_sar_cfg_common *rtwsar = &rtwdev->sar.cfg_common;
const struct rtw89_sar_span *span = NULL;
enum rtw89_sar_subband subband_l, subband_h;
int idx;
if (center_freq >= RTW89_SAR_6GHZ_SPAN_HEAD) {
idx = RTW89_SAR_6GHZ_SPAN_IDX(center_freq);
/* To decrease size of rtw89_sar_overlapping_6ghz[],
* RTW89_SAR_6GHZ_SPAN_IDX() truncates the leading NULLs
* to make first span as index 0 of the table. So, if center
* frequency is less than the first one, it will get netative.
*/
if (idx >= 0 && idx < ARRAY_SIZE(rtw89_sar_overlapping_6ghz))
span = &rtw89_sar_overlapping_6ghz[idx];
}
if (span && RTW89_SAR_SPAN_VALID(span)) {
subband_l = span->subband_low;
subband_h = span->subband_high;
} else {
subband_l = rtw89_sar_get_subband(rtwdev, center_freq);
subband_h = subband_l;
}
rtw89_debug(rtwdev, RTW89_DBG_SAR,
"center_freq %u: SAR subband {%u, %u}\n",
center_freq, subband_l, subband_h);
if (!rtwsar->set[subband_l] && !rtwsar->set[subband_h])
return -ENODATA;
if (!rtwsar->set[subband_l])
*cfg = rtwsar->cfg[subband_h];
else if (!rtwsar->set[subband_h])
*cfg = rtwsar->cfg[subband_l];
else
*cfg = min(rtwsar->cfg[subband_l], rtwsar->cfg[subband_h]);
return 0;
}
static const
struct rtw89_sar_handler rtw89_sar_handlers[RTW89_SAR_SOURCE_NR] = {
[RTW89_SAR_SOURCE_COMMON] = {
.descr_sar_source = "RTW89_SAR_SOURCE_COMMON",
.txpwr_factor_sar = 2,
.query_sar_config = rtw89_query_sar_config_common,
},
};
#define rtw89_sar_set_src(_dev, _src, _cfg_name, _cfg_data) \
do { \
typeof(_src) _s = (_src); \
typeof(_dev) _d = (_dev); \
BUILD_BUG_ON(!rtw89_sar_handlers[_s].descr_sar_source); \
BUILD_BUG_ON(!rtw89_sar_handlers[_s].query_sar_config); \
lockdep_assert_held(&_d->mutex); \
_d->sar._cfg_name = *(_cfg_data); \
_d->sar.src = _s; \
} while (0)
static s8 rtw89_txpwr_sar_to_mac(struct rtw89_dev *rtwdev, u8 fct, s32 cfg)
{
const u8 fct_mac = rtwdev->chip->txpwr_factor_mac;
s32 cfg_mac;
cfg_mac = fct > fct_mac ?
cfg >> (fct - fct_mac) : cfg << (fct_mac - fct);
return (s8)clamp_t(s32, cfg_mac,
RTW89_SAR_TXPWR_MAC_MIN,
RTW89_SAR_TXPWR_MAC_MAX);
}
static s8 rtw89_txpwr_tas_to_sar(const struct rtw89_sar_handler *sar_hdl,
s8 cfg)
{
const u8 fct = sar_hdl->txpwr_factor_sar;
if (fct > RTW89_TAS_FACTOR)
return cfg << (fct - RTW89_TAS_FACTOR);
else
return cfg >> (RTW89_TAS_FACTOR - fct);
}
static s8 rtw89_txpwr_sar_to_tas(const struct rtw89_sar_handler *sar_hdl,
s8 cfg)
{
const u8 fct = sar_hdl->txpwr_factor_sar;
if (fct > RTW89_TAS_FACTOR)
return cfg >> (fct - RTW89_TAS_FACTOR);
else
return cfg << (RTW89_TAS_FACTOR - fct);
}
s8 rtw89_query_sar(struct rtw89_dev *rtwdev, u32 center_freq)
{
const enum rtw89_sar_sources src = rtwdev->sar.src;
/* its members are protected by rtw89_sar_set_src() */
const struct rtw89_sar_handler *sar_hdl = &rtw89_sar_handlers[src];
struct rtw89_tas_info *tas = &rtwdev->tas;
s8 delta;
int ret;
s32 cfg;
u8 fct;
lockdep_assert_held(&rtwdev->mutex);
if (src == RTW89_SAR_SOURCE_NONE)
return RTW89_SAR_TXPWR_MAC_MAX;
ret = sar_hdl->query_sar_config(rtwdev, center_freq, &cfg);
if (ret)
return RTW89_SAR_TXPWR_MAC_MAX;
if (tas->enable) {
switch (tas->state) {
case RTW89_TAS_STATE_DPR_OFF:
return RTW89_SAR_TXPWR_MAC_MAX;
case RTW89_TAS_STATE_DPR_ON:
delta = rtw89_txpwr_tas_to_sar(sar_hdl, tas->delta);
cfg -= delta;
break;
case RTW89_TAS_STATE_DPR_FORBID:
default:
break;
}
}
fct = sar_hdl->txpwr_factor_sar;
return rtw89_txpwr_sar_to_mac(rtwdev, fct, cfg);
}
void rtw89_print_sar(struct seq_file *m, struct rtw89_dev *rtwdev, u32 center_freq)
{
const enum rtw89_sar_sources src = rtwdev->sar.src;
/* its members are protected by rtw89_sar_set_src() */
const struct rtw89_sar_handler *sar_hdl = &rtw89_sar_handlers[src];
const u8 fct_mac = rtwdev->chip->txpwr_factor_mac;
int ret;
s32 cfg;
u8 fct;
lockdep_assert_held(&rtwdev->mutex);
if (src == RTW89_SAR_SOURCE_NONE) {
seq_puts(m, "no SAR is applied\n");
return;
}
seq_printf(m, "source: %d (%s)\n", src, sar_hdl->descr_sar_source);
ret = sar_hdl->query_sar_config(rtwdev, center_freq, &cfg);
if (ret) {
seq_printf(m, "config: return code: %d\n", ret);
seq_printf(m, "assign: max setting: %d (unit: 1/%lu dBm)\n",
RTW89_SAR_TXPWR_MAC_MAX, BIT(fct_mac));
return;
}
fct = sar_hdl->txpwr_factor_sar;
seq_printf(m, "config: %d (unit: 1/%lu dBm)\n", cfg, BIT(fct));
}
void rtw89_print_tas(struct seq_file *m, struct rtw89_dev *rtwdev)
{
struct rtw89_tas_info *tas = &rtwdev->tas;
if (!tas->enable) {
seq_puts(m, "no TAS is applied\n");
return;
}
seq_printf(m, "DPR gap: %d\n", tas->dpr_gap);
seq_printf(m, "TAS delta: %d\n", tas->delta);
}
static int rtw89_apply_sar_common(struct rtw89_dev *rtwdev,
const struct rtw89_sar_cfg_common *sar)
{
enum rtw89_sar_sources src;
int ret = 0;
mutex_lock(&rtwdev->mutex);
src = rtwdev->sar.src;
if (src != RTW89_SAR_SOURCE_NONE && src != RTW89_SAR_SOURCE_COMMON) {
rtw89_warn(rtwdev, "SAR source: %d is in use", src);
ret = -EBUSY;
goto exit;
}
rtw89_sar_set_src(rtwdev, RTW89_SAR_SOURCE_COMMON, cfg_common, sar);
rtw89_core_set_chip_txpwr(rtwdev);
exit:
mutex_unlock(&rtwdev->mutex);
return ret;
}
static const struct cfg80211_sar_freq_ranges rtw89_common_sar_freq_ranges[] = {
{ .start_freq = 2412, .end_freq = 2484, },
{ .start_freq = 5180, .end_freq = 5320, },
{ .start_freq = 5500, .end_freq = 5720, },
{ .start_freq = 5745, .end_freq = 5825, },
{ .start_freq = 5955, .end_freq = 6155, },
{ .start_freq = 6175, .end_freq = 6415, },
{ .start_freq = 6435, .end_freq = 6515, },
{ .start_freq = 6535, .end_freq = 6695, },
{ .start_freq = 6715, .end_freq = 6875, },
{ .start_freq = 6875, .end_freq = 7115, },
};
static_assert(RTW89_SAR_SUBBAND_NR ==
ARRAY_SIZE(rtw89_common_sar_freq_ranges));
const struct cfg80211_sar_capa rtw89_sar_capa = {
.type = NL80211_SAR_TYPE_POWER,
.num_freq_ranges = ARRAY_SIZE(rtw89_common_sar_freq_ranges),
.freq_ranges = rtw89_common_sar_freq_ranges,
};
int rtw89_ops_set_sar_specs(struct ieee80211_hw *hw,
const struct cfg80211_sar_specs *sar)
{
struct rtw89_dev *rtwdev = hw->priv;
struct rtw89_sar_cfg_common sar_common = {0};
u8 fct;
u32 freq_start;
u32 freq_end;
s32 power;
u32 i, idx;
if (sar->type != NL80211_SAR_TYPE_POWER)
return -EINVAL;
fct = rtw89_sar_handlers[RTW89_SAR_SOURCE_COMMON].txpwr_factor_sar;
for (i = 0; i < sar->num_sub_specs; i++) {
idx = sar->sub_specs[i].freq_range_index;
if (idx >= ARRAY_SIZE(rtw89_common_sar_freq_ranges))
return -EINVAL;
freq_start = rtw89_common_sar_freq_ranges[idx].start_freq;
freq_end = rtw89_common_sar_freq_ranges[idx].end_freq;
power = sar->sub_specs[i].power;
rtw89_debug(rtwdev, RTW89_DBG_SAR,
"On freq %u to %u, set SAR limit %d (unit: 1/%lu dBm)\n",
freq_start, freq_end, power, BIT(fct));
sar_common.set[idx] = true;
sar_common.cfg[idx] = power;
}
return rtw89_apply_sar_common(rtwdev, &sar_common);
}
static void rtw89_tas_state_update(struct rtw89_dev *rtwdev)
{
const enum rtw89_sar_sources src = rtwdev->sar.src;
/* its members are protected by rtw89_sar_set_src() */
const struct rtw89_sar_handler *sar_hdl = &rtw89_sar_handlers[src];
struct rtw89_tas_info *tas = &rtwdev->tas;
s32 txpwr_avg = tas->total_txpwr / RTW89_TAS_MAX_WINDOW / PERCENT;
s32 dpr_on_threshold, dpr_off_threshold, cfg;
enum rtw89_tas_state state = tas->state;
const struct rtw89_chan *chan;
int ret;
lockdep_assert_held(&rtwdev->mutex);
if (src == RTW89_SAR_SOURCE_NONE)
return;
chan = rtw89_chan_get(rtwdev, RTW89_CHANCTX_0);
ret = sar_hdl->query_sar_config(rtwdev, chan->freq, &cfg);
if (ret)
return;
cfg = rtw89_txpwr_sar_to_tas(sar_hdl, cfg);
if (tas->delta >= cfg) {
rtw89_debug(rtwdev, RTW89_DBG_SAR,
"TAS delta exceed SAR limit\n");
state = RTW89_TAS_STATE_DPR_FORBID;
goto out;
}
dpr_on_threshold = cfg;
dpr_off_threshold = cfg - tas->dpr_gap;
rtw89_debug(rtwdev, RTW89_DBG_SAR,
"DPR_ON thold: %d, DPR_OFF thold: %d, txpwr_avg: %d\n",
dpr_on_threshold, dpr_off_threshold, txpwr_avg);
if (txpwr_avg >= dpr_on_threshold)
state = RTW89_TAS_STATE_DPR_ON;
else if (txpwr_avg < dpr_off_threshold)
state = RTW89_TAS_STATE_DPR_OFF;
out:
if (tas->state == state)
return;
rtw89_debug(rtwdev, RTW89_DBG_SAR,
"TAS old state: %d, new state: %d\n", tas->state, state);
tas->state = state;
rtw89_core_set_chip_txpwr(rtwdev);
}
void rtw89_tas_init(struct rtw89_dev *rtwdev)
{
struct rtw89_tas_info *tas = &rtwdev->tas;
struct rtw89_acpi_dsm_result res = {};
int ret;
u8 val;
ret = rtw89_acpi_evaluate_dsm(rtwdev, RTW89_ACPI_DSM_FUNC_TAS_EN, &res);
if (ret) {
rtw89_debug(rtwdev, RTW89_DBG_SAR,
"acpi: cannot get TAS: %d\n", ret);
return;
}
val = res.u.value;
switch (val) {
case 0:
tas->enable = false;
break;
case 1:
tas->enable = true;
break;
default:
break;
}
if (!tas->enable) {
rtw89_debug(rtwdev, RTW89_DBG_SAR, "TAS not enable\n");
return;
}
tas->dpr_gap = RTW89_TAS_DPR_GAP;
tas->delta = RTW89_TAS_DELTA;
}
void rtw89_tas_reset(struct rtw89_dev *rtwdev)
{
struct rtw89_tas_info *tas = &rtwdev->tas;
if (!tas->enable)
return;
memset(&tas->txpwr_history, 0, sizeof(tas->txpwr_history));
tas->total_txpwr = 0;
tas->cur_idx = 0;
tas->state = RTW89_TAS_STATE_DPR_OFF;
}
static const struct rtw89_reg_def txpwr_regs[] = {
{R_PATH0_TXPWR, B_PATH0_TXPWR},
{R_PATH1_TXPWR, B_PATH1_TXPWR},
};
void rtw89_tas_track(struct rtw89_dev *rtwdev)
{
struct rtw89_env_monitor_info *env = &rtwdev->env_monitor;
const enum rtw89_sar_sources src = rtwdev->sar.src;
u8 max_nss_num = rtwdev->chip->rf_path_num;
struct rtw89_tas_info *tas = &rtwdev->tas;
s16 tmp, txpwr, instant_txpwr = 0;
u32 val;
int i;
if (!tas->enable || src == RTW89_SAR_SOURCE_NONE)
return;
if (env->ccx_watchdog_result != RTW89_PHY_ENV_MON_IFS_CLM)
return;
for (i = 0; i < max_nss_num; i++) {
val = rtw89_phy_read32_mask(rtwdev, txpwr_regs[i].addr,
txpwr_regs[i].mask);
tmp = sign_extend32(val, 8);
if (tmp <= 0)
return;
instant_txpwr += tmp;
}
instant_txpwr /= max_nss_num;
/* in unit of 0.25 dBm multiply by percentage */
txpwr = instant_txpwr * env->ifs_clm_tx_ratio;
tas->total_txpwr += txpwr - tas->txpwr_history[tas->cur_idx];
tas->txpwr_history[tas->cur_idx] = txpwr;
rtw89_debug(rtwdev, RTW89_DBG_SAR,
"instant_txpwr: %d, tx_ratio: %d, txpwr: %d\n",
instant_txpwr, env->ifs_clm_tx_ratio, txpwr);
tas->cur_idx = (tas->cur_idx + 1) % RTW89_TAS_MAX_WINDOW;
rtw89_tas_state_update(rtwdev);
}
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