RTL88x2BU-Linux-Driver/core/rtw_odm.c

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/******************************************************************************
*
* Copyright(c) 2013 - 2017 Realtek Corporation.
*
* This program is free software; you can redistribute it and/or modify it
* under the terms of version 2 of the GNU General Public License as
* published by the Free Software Foundation.
*
* 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.
*
*****************************************************************************/
#include <rtw_odm.h>
#include <hal_data.h>
u32 rtw_phydm_ability_ops(_adapter *adapter, HAL_PHYDM_OPS ops, u32 ability)
{
HAL_DATA_TYPE *pHalData = GET_HAL_DATA(adapter);
struct dm_struct *podmpriv = &pHalData->odmpriv;
u32 result = 0;
switch (ops) {
case HAL_PHYDM_DIS_ALL_FUNC:
podmpriv->support_ability = DYNAMIC_FUNC_DISABLE;
halrf_cmn_info_set(podmpriv, HALRF_CMNINFO_ABILITY, DYNAMIC_FUNC_DISABLE);
break;
case HAL_PHYDM_FUNC_SET:
podmpriv->support_ability |= ability;
break;
case HAL_PHYDM_FUNC_CLR:
podmpriv->support_ability &= ~(ability);
break;
case HAL_PHYDM_ABILITY_BK:
/* dm flag backup*/
podmpriv->bk_support_ability = podmpriv->support_ability;
pHalData->bk_rf_ability = halrf_cmn_info_get(podmpriv, HALRF_CMNINFO_ABILITY);
break;
case HAL_PHYDM_ABILITY_RESTORE:
/* restore dm flag */
podmpriv->support_ability = podmpriv->bk_support_ability;
halrf_cmn_info_set(podmpriv, HALRF_CMNINFO_ABILITY, pHalData->bk_rf_ability);
break;
case HAL_PHYDM_ABILITY_SET:
podmpriv->support_ability = ability;
break;
case HAL_PHYDM_ABILITY_GET:
result = podmpriv->support_ability;
break;
}
return result;
}
/* set ODM_CMNINFO_IC_TYPE based on chip_type */
void rtw_odm_init_ic_type(_adapter *adapter)
{
struct dm_struct *odm = adapter_to_phydm(adapter);
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u32 ic_type = chip_type_to_odm_ic_type(rtw_get_chip_type(adapter));
rtw_warn_on(!ic_type);
odm_cmn_info_init(odm, ODM_CMNINFO_IC_TYPE, ic_type);
}
void rtw_odm_adaptivity_ver_msg(void *sel, _adapter *adapter)
{
RTW_PRINT_SEL(sel, "ADAPTIVITY_VERSION "ADAPTIVITY_VERSION"\n");
}
#define RTW_ADAPTIVITY_EN_DISABLE 0
#define RTW_ADAPTIVITY_EN_ENABLE 1
void rtw_odm_adaptivity_en_msg(void *sel, _adapter *adapter)
{
struct registry_priv *regsty = &adapter->registrypriv;
RTW_PRINT_SEL(sel, "RTW_ADAPTIVITY_EN_");
if (regsty->adaptivity_en == RTW_ADAPTIVITY_EN_DISABLE)
_RTW_PRINT_SEL(sel, "DISABLE\n");
else if (regsty->adaptivity_en == RTW_ADAPTIVITY_EN_ENABLE)
_RTW_PRINT_SEL(sel, "ENABLE\n");
else
_RTW_PRINT_SEL(sel, "INVALID\n");
}
#define RTW_ADAPTIVITY_MODE_NORMAL 0
#define RTW_ADAPTIVITY_MODE_CARRIER_SENSE 1
void rtw_odm_adaptivity_mode_msg(void *sel, _adapter *adapter)
{
struct registry_priv *regsty = &adapter->registrypriv;
RTW_PRINT_SEL(sel, "RTW_ADAPTIVITY_MODE_");
if (regsty->adaptivity_mode == RTW_ADAPTIVITY_MODE_NORMAL)
_RTW_PRINT_SEL(sel, "NORMAL\n");
else if (regsty->adaptivity_mode == RTW_ADAPTIVITY_MODE_CARRIER_SENSE)
_RTW_PRINT_SEL(sel, "CARRIER_SENSE\n");
else
_RTW_PRINT_SEL(sel, "INVALID\n");
}
void rtw_odm_adaptivity_config_msg(void *sel, _adapter *adapter)
{
rtw_odm_adaptivity_ver_msg(sel, adapter);
rtw_odm_adaptivity_en_msg(sel, adapter);
rtw_odm_adaptivity_mode_msg(sel, adapter);
}
bool rtw_odm_adaptivity_needed(_adapter *adapter)
{
struct registry_priv *regsty = &adapter->registrypriv;
bool ret = _FALSE;
if (regsty->adaptivity_en == RTW_ADAPTIVITY_EN_ENABLE)
ret = _TRUE;
return ret;
}
void rtw_odm_adaptivity_parm_msg(void *sel, _adapter *adapter)
{
struct dm_struct *odm = adapter_to_phydm(adapter);
rtw_odm_adaptivity_config_msg(sel, adapter);
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RTW_PRINT_SEL(sel, "%10s %16s\n"
, "th_l2h_ini", "th_edcca_hl_diff");
RTW_PRINT_SEL(sel, "0x%-8x %-16d\n"
, (u8)odm->th_l2h_ini
, odm->th_edcca_hl_diff
);
}
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void rtw_odm_adaptivity_parm_set(_adapter *adapter, s8 th_l2h_ini, s8 th_edcca_hl_diff)
{
struct dm_struct *odm = adapter_to_phydm(adapter);
odm->th_l2h_ini = th_l2h_ini;
odm->th_edcca_hl_diff = th_edcca_hl_diff;
}
void rtw_odm_get_perpkt_rssi(void *sel, _adapter *adapter)
{
struct dm_struct *odm = adapter_to_phydm(adapter);
RTW_PRINT_SEL(sel, "rx_rate = %s, rssi_a = %d(%%), rssi_b = %d(%%)\n",
HDATA_RATE(odm->rx_rate), odm->rssi_a, odm->rssi_b);
}
void rtw_odm_acquirespinlock(_adapter *adapter, enum rt_spinlock_type type)
{
PHAL_DATA_TYPE pHalData = GET_HAL_DATA(adapter);
_irqL irqL;
switch (type) {
case RT_IQK_SPINLOCK:
_enter_critical_bh(&pHalData->IQKSpinLock, &irqL);
default:
break;
}
}
void rtw_odm_releasespinlock(_adapter *adapter, enum rt_spinlock_type type)
{
PHAL_DATA_TYPE pHalData = GET_HAL_DATA(adapter);
_irqL irqL;
switch (type) {
case RT_IQK_SPINLOCK:
_exit_critical_bh(&pHalData->IQKSpinLock, &irqL);
default:
break;
}
}
#ifdef CONFIG_DFS_MASTER
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inline void rtw_odm_radar_detect_reset(_adapter *adapter)
{
phydm_radar_detect_reset(adapter_to_phydm(adapter));
}
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inline void rtw_odm_radar_detect_disable(_adapter *adapter)
{
phydm_radar_detect_disable(adapter_to_phydm(adapter));
}
/* called after ch, bw is set */
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inline void rtw_odm_radar_detect_enable(_adapter *adapter)
{
phydm_radar_detect_enable(adapter_to_phydm(adapter));
}
inline BOOLEAN rtw_odm_radar_detect(_adapter *adapter)
{
return phydm_radar_detect(adapter_to_phydm(adapter));
}
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inline u8 rtw_odm_radar_detect_polling_int_ms(struct dvobj_priv *dvobj)
{
return phydm_dfs_polling_time(dvobj_to_phydm(dvobj));
}
#endif /* CONFIG_DFS_MASTER */
void rtw_odm_parse_rx_phy_status_chinfo(union recv_frame *rframe, u8 *phys)
{
#ifndef DBG_RX_PHYSTATUS_CHINFO
#define DBG_RX_PHYSTATUS_CHINFO 0
#endif
#if (ODM_PHY_STATUS_NEW_TYPE_SUPPORT == 1)
_adapter *adapter = rframe->u.hdr.adapter;
struct dm_struct *phydm = adapter_to_phydm(adapter);
struct rx_pkt_attrib *attrib = &rframe->u.hdr.attrib;
u8 *wlanhdr = get_recvframe_data(rframe);
if (phydm->support_ic_type & PHYSTS_2ND_TYPE_IC) {
/*
* 8723D:
* type_0(CCK)
* l_rxsc
* is filled with primary channel SC, not real rxsc.
* 0:LSC, 1:USC
* type_1(OFDM)
* rf_mode
* RF bandwidth when RX
* l_rxsc(legacy), ht_rxsc
* see below RXSC N-series
* type_2(Not used)
*/
/*
* 8821C, 8822B:
* type_0(CCK)
* l_rxsc
* is filled with primary channel SC, not real rxsc.
* 0:LSC, 1:USC
* type_1(OFDM)
* rf_mode
* RF bandwidth when RX
* l_rxsc(legacy), ht_rxsc
* see below RXSC AC-series
* type_2(Not used)
*/
if ((*phys & 0xf) == 0) {
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struct phy_sts_rpt_jgr2_type0 *phys_t0 = (struct phy_sts_rpt_jgr2_type0 *)phys;
if (DBG_RX_PHYSTATUS_CHINFO) {
RTW_PRINT("phys_t%u ta="MAC_FMT" %s, %s(band:%u, ch:%u, l_rxsc:%u)\n"
, *phys & 0xf
, MAC_ARG(get_ta(wlanhdr))
, is_broadcast_mac_addr(get_ra(wlanhdr)) ? "BC" : is_multicast_mac_addr(get_ra(wlanhdr)) ? "MC" : "UC"
, HDATA_RATE(attrib->data_rate)
, phys_t0->band, phys_t0->channel, phys_t0->rxsc
);
}
} else if ((*phys & 0xf) == 1) {
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struct phy_sts_rpt_jgr2_type1 *phys_t1 = (struct phy_sts_rpt_jgr2_type1 *)phys;
u8 rxsc = (attrib->data_rate > DESC_RATE11M && attrib->data_rate < DESC_RATEMCS0) ? phys_t1->l_rxsc : phys_t1->ht_rxsc;
u8 pkt_cch = 0;
u8 pkt_bw = CHANNEL_WIDTH_20;
#if ODM_IC_11N_SERIES_SUPPORT
if (phydm->support_ic_type & ODM_IC_11N_SERIES) {
/* RXSC N-series */
#define RXSC_DUP 0
#define RXSC_LSC 1
#define RXSC_USC 2
#define RXSC_40M 3
static const s8 cch_offset_by_rxsc[4] = {0, -2, 2, 0};
if (phys_t1->rf_mode == 0) {
pkt_cch = phys_t1->channel;
pkt_bw = CHANNEL_WIDTH_20;
} else if (phys_t1->rf_mode == 1) {
if (rxsc == RXSC_LSC || rxsc == RXSC_USC) {
pkt_cch = phys_t1->channel + cch_offset_by_rxsc[rxsc];
pkt_bw = CHANNEL_WIDTH_20;
} else if (rxsc == RXSC_40M) {
pkt_cch = phys_t1->channel;
pkt_bw = CHANNEL_WIDTH_40;
}
} else
rtw_warn_on(1);
goto type1_end;
}
#endif /* ODM_IC_11N_SERIES_SUPPORT */
#if ODM_IC_11AC_SERIES_SUPPORT
if (phydm->support_ic_type & ODM_IC_11AC_SERIES) {
/* RXSC AC-series */
#define RXSC_DUP 0 /* 0: RX from all SC of current rf_mode */
#define RXSC_LL20M_OF_160M 8 /* 1~8: RX from 20MHz SC */
#define RXSC_L20M_OF_160M 6
#define RXSC_L20M_OF_80M 4
#define RXSC_L20M_OF_40M 2
#define RXSC_U20M_OF_40M 1
#define RXSC_U20M_OF_80M 3
#define RXSC_U20M_OF_160M 5
#define RXSC_UU20M_OF_160M 7
#define RXSC_L40M_OF_160M 12 /* 9~12: RX from 40MHz SC */
#define RXSC_L40M_OF_80M 10
#define RXSC_U40M_OF_80M 9
#define RXSC_U40M_OF_160M 11
#define RXSC_L80M_OF_160M 14 /* 13~14: RX from 80MHz SC */
#define RXSC_U80M_OF_160M 13
static const s8 cch_offset_by_rxsc[15] = {0, 2, -2, 6, -6, 10, -10, 14, -14, 4, -4, 12, -12, 8, -8};
if (phys_t1->rf_mode == 0) {
/* RF 20MHz */
pkt_cch = phys_t1->channel;
pkt_bw = CHANNEL_WIDTH_20;
goto type1_end;
}
if (rxsc == 0) {
/* RF and RX with same BW */
if (attrib->data_rate >= DESC_RATEMCS0) {
pkt_cch = phys_t1->channel;
pkt_bw = phys_t1->rf_mode;
}
goto type1_end;
}
if ((phys_t1->rf_mode == 1 && rxsc >= 1 && rxsc <= 2) /* RF 40MHz, RX 20MHz */
|| (phys_t1->rf_mode == 2 && rxsc >= 1 && rxsc <= 4) /* RF 80MHz, RX 20MHz */
|| (phys_t1->rf_mode == 3 && rxsc >= 1 && rxsc <= 8) /* RF 160MHz, RX 20MHz */
) {
pkt_cch = phys_t1->channel + cch_offset_by_rxsc[rxsc];
pkt_bw = CHANNEL_WIDTH_20;
} else if ((phys_t1->rf_mode == 2 && rxsc >= 9 && rxsc <= 10) /* RF 80MHz, RX 40MHz */
|| (phys_t1->rf_mode == 3 && rxsc >= 9 && rxsc <= 12) /* RF 160MHz, RX 40MHz */
) {
if (attrib->data_rate >= DESC_RATEMCS0) {
pkt_cch = phys_t1->channel + cch_offset_by_rxsc[rxsc];
pkt_bw = CHANNEL_WIDTH_40;
}
} else if ((phys_t1->rf_mode == 3 && rxsc >= 13 && rxsc <= 14) /* RF 160MHz, RX 80MHz */
) {
if (attrib->data_rate >= DESC_RATEMCS0) {
pkt_cch = phys_t1->channel + cch_offset_by_rxsc[rxsc];
pkt_bw = CHANNEL_WIDTH_80;
}
} else
rtw_warn_on(1);
}
#endif /* ODM_IC_11AC_SERIES_SUPPORT */
type1_end:
if (DBG_RX_PHYSTATUS_CHINFO) {
RTW_PRINT("phys_t%u ta="MAC_FMT" %s, %s(band:%u, ch:%u, rf_mode:%u, l_rxsc:%u, ht_rxsc:%u) => %u,%u\n"
, *phys & 0xf
, MAC_ARG(get_ta(wlanhdr))
, is_broadcast_mac_addr(get_ra(wlanhdr)) ? "BC" : is_multicast_mac_addr(get_ra(wlanhdr)) ? "MC" : "UC"
, HDATA_RATE(attrib->data_rate)
, phys_t1->band, phys_t1->channel, phys_t1->rf_mode, phys_t1->l_rxsc, phys_t1->ht_rxsc
, pkt_cch, pkt_bw
);
}
/* for now, only return cneter channel of 20MHz packet */
if (pkt_cch && pkt_bw == CHANNEL_WIDTH_20)
attrib->ch = pkt_cch;
} else {
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struct phy_sts_rpt_jgr2_type2 *phys_t2 = (struct phy_sts_rpt_jgr2_type2 *)phys;
if (DBG_RX_PHYSTATUS_CHINFO) {
RTW_PRINT("phys_t%u ta="MAC_FMT" %s, %s(band:%u, ch:%u, l_rxsc:%u, ht_rxsc:%u)\n"
, *phys & 0xf
, MAC_ARG(get_ta(wlanhdr))
, is_broadcast_mac_addr(get_ra(wlanhdr)) ? "BC" : is_multicast_mac_addr(get_ra(wlanhdr)) ? "MC" : "UC"
, HDATA_RATE(attrib->data_rate)
, phys_t2->band, phys_t2->channel, phys_t2->l_rxsc, phys_t2->ht_rxsc
);
}
}
}
#endif /* (ODM_PHY_STATUS_NEW_TYPE_SUPPORT == 1) */
}
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#if defined(CONFIG_RTL8822C) && defined(CONFIG_LPS_PG)
void
debug_DACK(
struct dm_struct *dm
)
{
//P_PHYDM_FUNC dm;
//dm = &(SysMib.ODM.Phydm);
//PIQK_OFFLOAD_PARM pIQK_info;
//pIQK_info= &(SysMib.ODM.IQKParm);
u8 i;
u32 temp1, temp2, temp3;
temp1 = odm_get_bb_reg(dm, 0x1860, bMaskDWord);
temp2 = odm_get_bb_reg(dm, 0x4160, bMaskDWord);
temp3 = odm_get_bb_reg(dm, 0x9b4, bMaskDWord);
odm_set_bb_reg(dm, 0x9b4, bMaskDWord, 0xdb66db00);
//pathA
odm_set_bb_reg(dm, 0x1830, BIT(30), 0x0);
odm_set_bb_reg(dm, 0x1860, 0xfc000000, 0x3c);
RTW_INFO("path A i\n");
//i
for (i = 0; i < 0xf; i++) {
odm_set_bb_reg(dm, 0x18b0, 0xf0000000, i);
RTW_INFO("[0][0][%d] = 0x%08x\n", i, (u16)odm_get_bb_reg(dm,0x2810,0x7fc0000));
//pIQK_info->msbk_d[0][0][i] = (u16)odm_get_bb_reg(dm,0x2810,0x7fc0000);
}
RTW_INFO("path A q\n");
//q
for (i = 0; i < 0xf; i++) {
odm_set_bb_reg(dm, 0x18cc, 0xf0000000, i);
RTW_INFO("[0][1][%d] = 0x%08x\n", i, (u16)odm_get_bb_reg(dm,0x283c,0x7fc0000));
//pIQK_info->msbk_d[0][1][i] = (u16)odm_get_bb_reg(dm,0x283c,0x7fc0000);
}
//pathB
odm_set_bb_reg(dm, 0x4130, BIT(30), 0x0);
odm_set_bb_reg(dm, 0x4160, 0xfc000000, 0x3c);
RTW_INFO("\npath B i\n");
//i
for (i = 0; i < 0xf; i++) {
odm_set_bb_reg(dm, 0x41b0, 0xf0000000, i);
RTW_INFO("[1][0][%d] = 0x%08x\n", i, (u16)odm_get_bb_reg(dm,0x4510,0x7fc0000));
//pIQK_info->msbk_d[1][0][i] = (u16)odm_get_bb_reg(dm,0x2810,0x7fc0000);
}
RTW_INFO("path B q\n");
//q
for (i = 0; i < 0xf; i++) {
odm_set_bb_reg(dm, 0x41cc, 0xf0000000, i);
RTW_INFO("[1][1][%d] = 0x%08x\n", i, (u16)odm_get_bb_reg(dm,0x453c,0x7fc0000));
//pIQK_info->msbk_d[1][1][i] = (u16)odm_get_bb_reg(dm,0x283c,0x7fc0000);
}
//restore to normal
odm_set_bb_reg(dm, 0x1830, BIT(30), 0x1);
odm_set_bb_reg(dm, 0x4130, BIT(30), 0x1);
odm_set_bb_reg(dm, 0x1860, bMaskDWord, temp1);
odm_set_bb_reg(dm, 0x4160, bMaskDWord, temp2);
odm_set_bb_reg(dm, 0x9b4, bMaskDWord, temp3);
}
void
debug_IQK(
struct dm_struct *dm,
IN u8 idx,
IN u8 path
)
{
u8 i, ch;
u32 tmp;
u32 bit_mask_20_16 = BIT(20) | BIT(19) | BIT(18) | BIT(17) | BIT(16);
RTW_INFO("idx = %d, path = %d\n", idx, path);
odm_set_bb_reg(dm, 0x1b00, MASKDWORD, 0x8 | path << 1);
if (idx == TX_IQK) {//TXCFIR
odm_set_bb_reg(dm, R_0x1b20, BIT(31) | BIT(30), 0x3);
} else {//RXCFIR
odm_set_bb_reg(dm, R_0x1b20, BIT(31) | BIT(30), 0x1);
}
odm_set_bb_reg(dm, R_0x1bd4, BIT(21), 0x1);
odm_set_bb_reg(dm, R_0x1bd4, bit_mask_20_16, 0x10);
for (i = 0; i <= 16; i++) {
odm_set_bb_reg(dm, R_0x1bd8, MASKDWORD, 0xe0000001 | i << 2);
tmp = odm_get_bb_reg(dm, R_0x1bfc, MASKDWORD);
RTW_INFO("iqk_cfir_real[%d][%d][%d] = 0x%x\n", path, idx, i, ((tmp & 0x0fff0000) >> 16));
//iqk_info->iqk_cfir_real[ch][path][idx][i] =
// (tmp & 0x0fff0000) >> 16;
RTW_INFO("iqk_cfir_imag[%d][%d][%d] = 0x%x\n", path, idx, i, (tmp & 0x0fff));
//iqk_info->iqk_cfir_imag[ch][path][idx][i] = tmp & 0x0fff;
}
odm_set_bb_reg(dm, R_0x1b20, BIT(31) | BIT(30), 0x0);
//odm_set_bb_reg(dm, R_0x1bd8, MASKDWORD, 0x0);
}
__odm_func__ void
debug_information_8822c(
struct dm_struct *dm)
{
struct dm_dpk_info *dpk_info = &dm->dpk_info;
u32 reg_rf18;
if (odm_get_bb_reg(dm, R_0x1e7c, BIT(30)))
dpk_info->is_tssi_mode = true;
else
dpk_info->is_tssi_mode = false;
reg_rf18 = odm_get_rf_reg(dm, RF_PATH_A, RF_0x18, RFREG_MASK);
dpk_info->dpk_band = (u8)((reg_rf18 & BIT(16)) >> 16); /*0/1:G/A*/
dpk_info->dpk_ch = (u8)reg_rf18 & 0xff;
dpk_info->dpk_bw = (u8)((reg_rf18 & 0x3000) >> 12); /*3/2/1:20/40/80*/
RTW_INFO("[DPK] TSSI/ Band/ CH/ BW = %d / %s / %d / %s\n",
dpk_info->is_tssi_mode, dpk_info->dpk_band == 0 ? "2G" : "5G",
dpk_info->dpk_ch,
dpk_info->dpk_bw == 3 ? "20M" : (dpk_info->dpk_bw == 2 ? "40M" : "80M"));
}
extern void _dpk_get_coef_8822c(void *dm_void, u8 path);
__odm_func__ void
debug_reload_data_8822c(
void *dm_void)
{
struct dm_struct *dm = (struct dm_struct *)dm_void;
struct dm_dpk_info *dpk_info = &dm->dpk_info;
u8 path;
u32 u32tmp;
debug_information_8822c(dm);
for (path = 0; path < DPK_RF_PATH_NUM_8822C; path++) {
RTW_INFO("[DPK] Reload path: 0x%x\n", path);
odm_set_bb_reg(dm, R_0x1b00, MASKDWORD, 0x8 | (path << 1));
/*txagc bnd*/
if (dpk_info->dpk_band == 0x0)
u32tmp = odm_get_bb_reg(dm, R_0x1b60, MASKDWORD);
else
u32tmp = odm_get_bb_reg(dm, R_0x1b60, MASKDWORD);
RTW_INFO("[DPK] txagc bnd = 0x%08x\n", u32tmp);
u32tmp = odm_get_bb_reg(dm, R_0x1b64, MASKBYTE3);
RTW_INFO("[DPK] dpk_txagc = 0x%08x\n", u32tmp);
//debug_coef_write_8822c(dm, path, dpk_info->dpk_path_ok & BIT(path) >> path);
_dpk_get_coef_8822c(dm, path);
//debug_one_shot_8822c(dm, path, DPK_ON);
odm_set_bb_reg(dm, R_0x1b00, 0x0000000f, 0xc);
if (path == RF_PATH_A)
u32tmp = odm_get_bb_reg(dm, R_0x1b04, 0x0fffffff);
else
u32tmp = odm_get_bb_reg(dm, R_0x1b5c, 0x0fffffff);
RTW_INFO("[DPK] dpk_gs = 0x%08x\n", u32tmp);
}
}
void odm_lps_pg_debug_8822c(void *dm_void)
{
struct dm_struct *dm = (struct dm_struct *)dm_void;
debug_DACK(dm);
debug_IQK(dm, TX_IQK, RF_PATH_A);
debug_IQK(dm, RX_IQK, RF_PATH_A);
debug_IQK(dm, TX_IQK, RF_PATH_B);
debug_IQK(dm, RX_IQK, RF_PATH_B);
debug_reload_data_8822c(dm);
}
#endif /* defined(CONFIG_RTL8822C) && defined(CONFIG_LPS_PG) */