rtl8812au-chinawrj/hal/hal_com.c
Hans Ulli Kroll d62c22e76e Add driver from found on aircrack-ng site
filename: rtl8812AU_8821AU_linux_v4.3.22_15054.20150901_beta.tar.gz

Signed-off-by: Hans Ulli Kroll <ulli.kroll@googlemail.com>
2016-03-27 19:56:02 +02:00

7846 lines
219 KiB
C
Executable File

/******************************************************************************
*
* Copyright(c) 2007 - 2011 Realtek Corporation. All rights reserved.
*
* 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.
*
* You should have received a copy of the GNU General Public License along with
* this program; if not, write to the Free Software Foundation, Inc.,
* 51 Franklin Street, Fifth Floor, Boston, MA 02110, USA
*
*
******************************************************************************/
#define _HAL_COM_C_
#include <drv_types.h>
#include "hal_com_h2c.h"
#include "hal_data.h"
//#define CONFIG_GTK_OL_DBG
#ifdef CONFIG_LOAD_PHY_PARA_FROM_FILE
char file_path[PATH_LENGTH_MAX];
#endif
void dump_chip_info(HAL_VERSION ChipVersion)
{
int cnt = 0;
u8 buf[128]={0};
if (IS_8188E(ChipVersion))
cnt += sprintf((buf+cnt), "Chip Version Info: CHIP_8188E_");
else if (IS_8188F(ChipVersion))
cnt += sprintf((buf+cnt), "Chip Version Info: CHIP_8188F_");
else if (IS_8812_SERIES(ChipVersion))
cnt += sprintf((buf+cnt), "Chip Version Info: CHIP_8812_");
else if (IS_8192E(ChipVersion))
cnt += sprintf((buf+cnt), "Chip Version Info: CHIP_8192E_");
else if (IS_8821_SERIES(ChipVersion))
cnt += sprintf((buf+cnt), "Chip Version Info: CHIP_8821_");
else if (IS_8723B_SERIES(ChipVersion))
cnt += sprintf((buf+cnt), "Chip Version Info: CHIP_8723B_");
else if (IS_8703B_SERIES(ChipVersion))
cnt += sprintf((buf+cnt), "Chip Version Info: CHIP_8703B_");
else if (IS_8814A_SERIES(ChipVersion))
cnt += sprintf((buf+cnt), "Chip Version Info: CHIP_8814A_");
else
cnt += sprintf((buf+cnt), "Chip Version Info: CHIP_UNKNOWN_");
cnt += sprintf((buf+cnt), "%s_", IS_NORMAL_CHIP(ChipVersion)?"Normal_Chip":"Test_Chip");
if(IS_CHIP_VENDOR_TSMC(ChipVersion))
cnt += sprintf((buf+cnt), "%s_","TSMC");
else if(IS_CHIP_VENDOR_UMC(ChipVersion))
cnt += sprintf((buf+cnt), "%s_","UMC");
else if(IS_CHIP_VENDOR_SMIC(ChipVersion))
cnt += sprintf((buf+cnt), "%s_","SMIC");
if (IS_A_CUT(ChipVersion))
cnt += sprintf((buf+cnt), "A_CUT_");
else if (IS_B_CUT(ChipVersion))
cnt += sprintf((buf+cnt), "B_CUT_");
else if (IS_C_CUT(ChipVersion))
cnt += sprintf((buf+cnt), "C_CUT_");
else if (IS_D_CUT(ChipVersion))
cnt += sprintf((buf+cnt), "D_CUT_");
else if (IS_E_CUT(ChipVersion))
cnt += sprintf((buf+cnt), "E_CUT_");
else if (IS_F_CUT(ChipVersion))
cnt += sprintf((buf+cnt), "F_CUT_");
else if (IS_I_CUT(ChipVersion))
cnt += sprintf((buf+cnt), "I_CUT_");
else if (IS_J_CUT(ChipVersion))
cnt += sprintf((buf+cnt), "J_CUT_");
else if (IS_K_CUT(ChipVersion))
cnt += sprintf((buf+cnt), "K_CUT_");
else
cnt += sprintf((buf+cnt), "UNKNOWN_CUT(%d)_", ChipVersion.CUTVersion);
if(IS_1T1R(ChipVersion)) cnt += sprintf((buf+cnt), "1T1R_");
else if(IS_1T2R(ChipVersion)) cnt += sprintf((buf+cnt), "1T2R_");
else if(IS_2T2R(ChipVersion)) cnt += sprintf((buf+cnt), "2T2R_");
else if(IS_3T3R(ChipVersion)) cnt += sprintf((buf+cnt), "3T3R_");
else if(IS_3T4R(ChipVersion)) cnt += sprintf((buf+cnt), "3T4R_");
else if(IS_4T4R(ChipVersion)) cnt += sprintf((buf+cnt), "4T4R_");
else cnt += sprintf((buf+cnt), "UNKNOWN_RFTYPE(%d)_", ChipVersion.RFType);
cnt += sprintf((buf+cnt), "RomVer(%d)\n", ChipVersion.ROMVer);
DBG_871X("%s", buf);
}
void rtw_hal_config_rftype(PADAPTER padapter)
{
HAL_DATA_TYPE *pHalData = GET_HAL_DATA(padapter);
if (IS_1T1R(pHalData->VersionID)) {
pHalData->rf_type = RF_1T1R;
pHalData->NumTotalRFPath = 1;
}
else if (IS_2T2R(pHalData->VersionID)) {
pHalData->rf_type = RF_2T2R;
pHalData->NumTotalRFPath = 2;
}
else if (IS_1T2R(pHalData->VersionID)) {
pHalData->rf_type = RF_1T2R;
pHalData->NumTotalRFPath = 2;
}
else if(IS_3T3R(pHalData->VersionID)) {
pHalData->rf_type = RF_3T3R;
pHalData->NumTotalRFPath = 3;
}
else if(IS_4T4R(pHalData->VersionID)) {
pHalData->rf_type = RF_4T4R;
pHalData->NumTotalRFPath = 4;
}
else {
pHalData->rf_type = RF_1T1R;
pHalData->NumTotalRFPath = 1;
}
DBG_871X("%s RF_Type is %d TotalTxPath is %d \n", __FUNCTION__, pHalData->rf_type, pHalData->NumTotalRFPath);
}
#define EEPROM_CHANNEL_PLAN_BY_HW_MASK 0x80
/*
* Description:
* Use hardware(efuse), driver parameter(registry) and default channel plan
* to decide which one should be used.
*
* Parameters:
* padapter pointer of adapter
* hw_channel_plan channel plan from HW (efuse/eeprom)
* BIT[7] software configure mode; 0:Enable, 1:disable
* BIT[6:0] Channel Plan
* sw_channel_plan channel plan from SW (registry/module param)
* def_channel_plan channel plan used when HW/SW both invalid
* AutoLoadFail efuse autoload fail or not
*
* Return:
* Final channel plan decision
*
*/
u8
hal_com_config_channel_plan(
IN PADAPTER padapter,
IN u8 hw_channel_plan,
IN u8 sw_channel_plan,
IN u8 def_channel_plan,
IN BOOLEAN AutoLoadFail
)
{
PHAL_DATA_TYPE pHalData;
u8 hwConfig;
u8 chnlPlan;
pHalData = GET_HAL_DATA(padapter);
pHalData->bDisableSWChannelPlan = _FALSE;
chnlPlan = def_channel_plan;
if (0xFF == hw_channel_plan)
AutoLoadFail = _TRUE;
if (_FALSE == AutoLoadFail)
{
u8 hw_chnlPlan;
hw_chnlPlan = hw_channel_plan & (~EEPROM_CHANNEL_PLAN_BY_HW_MASK);
if (rtw_is_channel_plan_valid(hw_chnlPlan))
{
#ifndef CONFIG_SW_CHANNEL_PLAN
if (hw_channel_plan & EEPROM_CHANNEL_PLAN_BY_HW_MASK)
pHalData->bDisableSWChannelPlan = _TRUE;
#endif // !CONFIG_SW_CHANNEL_PLAN
chnlPlan = hw_chnlPlan;
}
}
if ((_FALSE == pHalData->bDisableSWChannelPlan)
&& rtw_is_channel_plan_valid(sw_channel_plan))
{
chnlPlan = sw_channel_plan;
}
return chnlPlan;
}
BOOLEAN
HAL_IsLegalChannel(
IN PADAPTER Adapter,
IN u32 Channel
)
{
BOOLEAN bLegalChannel = _TRUE;
if (Channel > 14) {
if(IsSupported5G(Adapter->registrypriv.wireless_mode) == _FALSE) {
bLegalChannel = _FALSE;
DBG_871X("Channel > 14 but wireless_mode do not support 5G\n");
}
} else if ((Channel <= 14) && (Channel >=1)){
if(IsSupported24G(Adapter->registrypriv.wireless_mode) == _FALSE) {
bLegalChannel = _FALSE;
DBG_871X("(Channel <= 14) && (Channel >=1) but wireless_mode do not support 2.4G\n");
}
} else {
bLegalChannel = _FALSE;
DBG_871X("Channel is Invalid !!!\n");
}
return bLegalChannel;
}
u8 MRateToHwRate(u8 rate)
{
u8 ret = DESC_RATE1M;
switch(rate)
{
case MGN_1M: ret = DESC_RATE1M; break;
case MGN_2M: ret = DESC_RATE2M; break;
case MGN_5_5M: ret = DESC_RATE5_5M; break;
case MGN_11M: ret = DESC_RATE11M; break;
case MGN_6M: ret = DESC_RATE6M; break;
case MGN_9M: ret = DESC_RATE9M; break;
case MGN_12M: ret = DESC_RATE12M; break;
case MGN_18M: ret = DESC_RATE18M; break;
case MGN_24M: ret = DESC_RATE24M; break;
case MGN_36M: ret = DESC_RATE36M; break;
case MGN_48M: ret = DESC_RATE48M; break;
case MGN_54M: ret = DESC_RATE54M; break;
case MGN_MCS0: ret = DESC_RATEMCS0; break;
case MGN_MCS1: ret = DESC_RATEMCS1; break;
case MGN_MCS2: ret = DESC_RATEMCS2; break;
case MGN_MCS3: ret = DESC_RATEMCS3; break;
case MGN_MCS4: ret = DESC_RATEMCS4; break;
case MGN_MCS5: ret = DESC_RATEMCS5; break;
case MGN_MCS6: ret = DESC_RATEMCS6; break;
case MGN_MCS7: ret = DESC_RATEMCS7; break;
case MGN_MCS8: ret = DESC_RATEMCS8; break;
case MGN_MCS9: ret = DESC_RATEMCS9; break;
case MGN_MCS10: ret = DESC_RATEMCS10; break;
case MGN_MCS11: ret = DESC_RATEMCS11; break;
case MGN_MCS12: ret = DESC_RATEMCS12; break;
case MGN_MCS13: ret = DESC_RATEMCS13; break;
case MGN_MCS14: ret = DESC_RATEMCS14; break;
case MGN_MCS15: ret = DESC_RATEMCS15; break;
case MGN_MCS16: ret = DESC_RATEMCS16; break;
case MGN_MCS17: ret = DESC_RATEMCS17; break;
case MGN_MCS18: ret = DESC_RATEMCS18; break;
case MGN_MCS19: ret = DESC_RATEMCS19; break;
case MGN_MCS20: ret = DESC_RATEMCS20; break;
case MGN_MCS21: ret = DESC_RATEMCS21; break;
case MGN_MCS22: ret = DESC_RATEMCS22; break;
case MGN_MCS23: ret = DESC_RATEMCS23; break;
case MGN_MCS24: ret = DESC_RATEMCS24; break;
case MGN_MCS25: ret = DESC_RATEMCS25; break;
case MGN_MCS26: ret = DESC_RATEMCS26; break;
case MGN_MCS27: ret = DESC_RATEMCS27; break;
case MGN_MCS28: ret = DESC_RATEMCS28; break;
case MGN_MCS29: ret = DESC_RATEMCS29; break;
case MGN_MCS30: ret = DESC_RATEMCS30; break;
case MGN_MCS31: ret = DESC_RATEMCS31; break;
case MGN_VHT1SS_MCS0: ret = DESC_RATEVHTSS1MCS0; break;
case MGN_VHT1SS_MCS1: ret = DESC_RATEVHTSS1MCS1; break;
case MGN_VHT1SS_MCS2: ret = DESC_RATEVHTSS1MCS2; break;
case MGN_VHT1SS_MCS3: ret = DESC_RATEVHTSS1MCS3; break;
case MGN_VHT1SS_MCS4: ret = DESC_RATEVHTSS1MCS4; break;
case MGN_VHT1SS_MCS5: ret = DESC_RATEVHTSS1MCS5; break;
case MGN_VHT1SS_MCS6: ret = DESC_RATEVHTSS1MCS6; break;
case MGN_VHT1SS_MCS7: ret = DESC_RATEVHTSS1MCS7; break;
case MGN_VHT1SS_MCS8: ret = DESC_RATEVHTSS1MCS8; break;
case MGN_VHT1SS_MCS9: ret = DESC_RATEVHTSS1MCS9; break;
case MGN_VHT2SS_MCS0: ret = DESC_RATEVHTSS2MCS0; break;
case MGN_VHT2SS_MCS1: ret = DESC_RATEVHTSS2MCS1; break;
case MGN_VHT2SS_MCS2: ret = DESC_RATEVHTSS2MCS2; break;
case MGN_VHT2SS_MCS3: ret = DESC_RATEVHTSS2MCS3; break;
case MGN_VHT2SS_MCS4: ret = DESC_RATEVHTSS2MCS4; break;
case MGN_VHT2SS_MCS5: ret = DESC_RATEVHTSS2MCS5; break;
case MGN_VHT2SS_MCS6: ret = DESC_RATEVHTSS2MCS6; break;
case MGN_VHT2SS_MCS7: ret = DESC_RATEVHTSS2MCS7; break;
case MGN_VHT2SS_MCS8: ret = DESC_RATEVHTSS2MCS8; break;
case MGN_VHT2SS_MCS9: ret = DESC_RATEVHTSS2MCS9; break;
case MGN_VHT3SS_MCS0: ret = DESC_RATEVHTSS3MCS0; break;
case MGN_VHT3SS_MCS1: ret = DESC_RATEVHTSS3MCS1; break;
case MGN_VHT3SS_MCS2: ret = DESC_RATEVHTSS3MCS2; break;
case MGN_VHT3SS_MCS3: ret = DESC_RATEVHTSS3MCS3; break;
case MGN_VHT3SS_MCS4: ret = DESC_RATEVHTSS3MCS4; break;
case MGN_VHT3SS_MCS5: ret = DESC_RATEVHTSS3MCS5; break;
case MGN_VHT3SS_MCS6: ret = DESC_RATEVHTSS3MCS6; break;
case MGN_VHT3SS_MCS7: ret = DESC_RATEVHTSS3MCS7; break;
case MGN_VHT3SS_MCS8: ret = DESC_RATEVHTSS3MCS8; break;
case MGN_VHT3SS_MCS9: ret = DESC_RATEVHTSS3MCS9; break;
case MGN_VHT4SS_MCS0: ret = DESC_RATEVHTSS4MCS0; break;
case MGN_VHT4SS_MCS1: ret = DESC_RATEVHTSS4MCS1; break;
case MGN_VHT4SS_MCS2: ret = DESC_RATEVHTSS4MCS2; break;
case MGN_VHT4SS_MCS3: ret = DESC_RATEVHTSS4MCS3; break;
case MGN_VHT4SS_MCS4: ret = DESC_RATEVHTSS4MCS4; break;
case MGN_VHT4SS_MCS5: ret = DESC_RATEVHTSS4MCS5; break;
case MGN_VHT4SS_MCS6: ret = DESC_RATEVHTSS4MCS6; break;
case MGN_VHT4SS_MCS7: ret = DESC_RATEVHTSS4MCS7; break;
case MGN_VHT4SS_MCS8: ret = DESC_RATEVHTSS4MCS8; break;
case MGN_VHT4SS_MCS9: ret = DESC_RATEVHTSS4MCS9; break;
default: break;
}
return ret;
}
u8 HwRateToMRate(u8 rate)
{
u8 ret_rate = MGN_1M;
switch(rate)
{
case DESC_RATE1M: ret_rate = MGN_1M; break;
case DESC_RATE2M: ret_rate = MGN_2M; break;
case DESC_RATE5_5M: ret_rate = MGN_5_5M; break;
case DESC_RATE11M: ret_rate = MGN_11M; break;
case DESC_RATE6M: ret_rate = MGN_6M; break;
case DESC_RATE9M: ret_rate = MGN_9M; break;
case DESC_RATE12M: ret_rate = MGN_12M; break;
case DESC_RATE18M: ret_rate = MGN_18M; break;
case DESC_RATE24M: ret_rate = MGN_24M; break;
case DESC_RATE36M: ret_rate = MGN_36M; break;
case DESC_RATE48M: ret_rate = MGN_48M; break;
case DESC_RATE54M: ret_rate = MGN_54M; break;
case DESC_RATEMCS0: ret_rate = MGN_MCS0; break;
case DESC_RATEMCS1: ret_rate = MGN_MCS1; break;
case DESC_RATEMCS2: ret_rate = MGN_MCS2; break;
case DESC_RATEMCS3: ret_rate = MGN_MCS3; break;
case DESC_RATEMCS4: ret_rate = MGN_MCS4; break;
case DESC_RATEMCS5: ret_rate = MGN_MCS5; break;
case DESC_RATEMCS6: ret_rate = MGN_MCS6; break;
case DESC_RATEMCS7: ret_rate = MGN_MCS7; break;
case DESC_RATEMCS8: ret_rate = MGN_MCS8; break;
case DESC_RATEMCS9: ret_rate = MGN_MCS9; break;
case DESC_RATEMCS10: ret_rate = MGN_MCS10; break;
case DESC_RATEMCS11: ret_rate = MGN_MCS11; break;
case DESC_RATEMCS12: ret_rate = MGN_MCS12; break;
case DESC_RATEMCS13: ret_rate = MGN_MCS13; break;
case DESC_RATEMCS14: ret_rate = MGN_MCS14; break;
case DESC_RATEMCS15: ret_rate = MGN_MCS15; break;
case DESC_RATEMCS16: ret_rate = MGN_MCS16; break;
case DESC_RATEMCS17: ret_rate = MGN_MCS17; break;
case DESC_RATEMCS18: ret_rate = MGN_MCS18; break;
case DESC_RATEMCS19: ret_rate = MGN_MCS19; break;
case DESC_RATEMCS20: ret_rate = MGN_MCS20; break;
case DESC_RATEMCS21: ret_rate = MGN_MCS21; break;
case DESC_RATEMCS22: ret_rate = MGN_MCS22; break;
case DESC_RATEMCS23: ret_rate = MGN_MCS23; break;
case DESC_RATEMCS24: ret_rate = MGN_MCS24; break;
case DESC_RATEMCS25: ret_rate = MGN_MCS25; break;
case DESC_RATEMCS26: ret_rate = MGN_MCS26; break;
case DESC_RATEMCS27: ret_rate = MGN_MCS27; break;
case DESC_RATEMCS28: ret_rate = MGN_MCS28; break;
case DESC_RATEMCS29: ret_rate = MGN_MCS29; break;
case DESC_RATEMCS30: ret_rate = MGN_MCS30; break;
case DESC_RATEMCS31: ret_rate = MGN_MCS31; break;
case DESC_RATEVHTSS1MCS0: ret_rate = MGN_VHT1SS_MCS0; break;
case DESC_RATEVHTSS1MCS1: ret_rate = MGN_VHT1SS_MCS1; break;
case DESC_RATEVHTSS1MCS2: ret_rate = MGN_VHT1SS_MCS2; break;
case DESC_RATEVHTSS1MCS3: ret_rate = MGN_VHT1SS_MCS3; break;
case DESC_RATEVHTSS1MCS4: ret_rate = MGN_VHT1SS_MCS4; break;
case DESC_RATEVHTSS1MCS5: ret_rate = MGN_VHT1SS_MCS5; break;
case DESC_RATEVHTSS1MCS6: ret_rate = MGN_VHT1SS_MCS6; break;
case DESC_RATEVHTSS1MCS7: ret_rate = MGN_VHT1SS_MCS7; break;
case DESC_RATEVHTSS1MCS8: ret_rate = MGN_VHT1SS_MCS8; break;
case DESC_RATEVHTSS1MCS9: ret_rate = MGN_VHT1SS_MCS9; break;
case DESC_RATEVHTSS2MCS0: ret_rate = MGN_VHT2SS_MCS0; break;
case DESC_RATEVHTSS2MCS1: ret_rate = MGN_VHT2SS_MCS1; break;
case DESC_RATEVHTSS2MCS2: ret_rate = MGN_VHT2SS_MCS2; break;
case DESC_RATEVHTSS2MCS3: ret_rate = MGN_VHT2SS_MCS3; break;
case DESC_RATEVHTSS2MCS4: ret_rate = MGN_VHT2SS_MCS4; break;
case DESC_RATEVHTSS2MCS5: ret_rate = MGN_VHT2SS_MCS5; break;
case DESC_RATEVHTSS2MCS6: ret_rate = MGN_VHT2SS_MCS6; break;
case DESC_RATEVHTSS2MCS7: ret_rate = MGN_VHT2SS_MCS7; break;
case DESC_RATEVHTSS2MCS8: ret_rate = MGN_VHT2SS_MCS8; break;
case DESC_RATEVHTSS2MCS9: ret_rate = MGN_VHT2SS_MCS9; break;
case DESC_RATEVHTSS3MCS0: ret_rate = MGN_VHT3SS_MCS0; break;
case DESC_RATEVHTSS3MCS1: ret_rate = MGN_VHT3SS_MCS1; break;
case DESC_RATEVHTSS3MCS2: ret_rate = MGN_VHT3SS_MCS2; break;
case DESC_RATEVHTSS3MCS3: ret_rate = MGN_VHT3SS_MCS3; break;
case DESC_RATEVHTSS3MCS4: ret_rate = MGN_VHT3SS_MCS4; break;
case DESC_RATEVHTSS3MCS5: ret_rate = MGN_VHT3SS_MCS5; break;
case DESC_RATEVHTSS3MCS6: ret_rate = MGN_VHT3SS_MCS6; break;
case DESC_RATEVHTSS3MCS7: ret_rate = MGN_VHT3SS_MCS7; break;
case DESC_RATEVHTSS3MCS8: ret_rate = MGN_VHT3SS_MCS8; break;
case DESC_RATEVHTSS3MCS9: ret_rate = MGN_VHT3SS_MCS9; break;
case DESC_RATEVHTSS4MCS0: ret_rate = MGN_VHT4SS_MCS0; break;
case DESC_RATEVHTSS4MCS1: ret_rate = MGN_VHT4SS_MCS1; break;
case DESC_RATEVHTSS4MCS2: ret_rate = MGN_VHT4SS_MCS2; break;
case DESC_RATEVHTSS4MCS3: ret_rate = MGN_VHT4SS_MCS3; break;
case DESC_RATEVHTSS4MCS4: ret_rate = MGN_VHT4SS_MCS4; break;
case DESC_RATEVHTSS4MCS5: ret_rate = MGN_VHT4SS_MCS5; break;
case DESC_RATEVHTSS4MCS6: ret_rate = MGN_VHT4SS_MCS6; break;
case DESC_RATEVHTSS4MCS7: ret_rate = MGN_VHT4SS_MCS7; break;
case DESC_RATEVHTSS4MCS8: ret_rate = MGN_VHT4SS_MCS8; break;
case DESC_RATEVHTSS4MCS9: ret_rate = MGN_VHT4SS_MCS9; break;
default:
DBG_871X("HwRateToMRate(): Non supported Rate [%x]!!!\n",rate );
break;
}
return ret_rate;
}
void HalSetBrateCfg(
IN PADAPTER Adapter,
IN u8 *mBratesOS,
OUT u16 *pBrateCfg)
{
u8 i, is_brate, brate;
for(i=0;i<NDIS_802_11_LENGTH_RATES_EX;i++)
{
is_brate = mBratesOS[i] & IEEE80211_BASIC_RATE_MASK;
brate = mBratesOS[i] & 0x7f;
if( is_brate )
{
switch(brate)
{
case IEEE80211_CCK_RATE_1MB: *pBrateCfg |= RATE_1M; break;
case IEEE80211_CCK_RATE_2MB: *pBrateCfg |= RATE_2M; break;
case IEEE80211_CCK_RATE_5MB: *pBrateCfg |= RATE_5_5M;break;
case IEEE80211_CCK_RATE_11MB: *pBrateCfg |= RATE_11M; break;
case IEEE80211_OFDM_RATE_6MB: *pBrateCfg |= RATE_6M; break;
case IEEE80211_OFDM_RATE_9MB: *pBrateCfg |= RATE_9M; break;
case IEEE80211_OFDM_RATE_12MB: *pBrateCfg |= RATE_12M; break;
case IEEE80211_OFDM_RATE_18MB: *pBrateCfg |= RATE_18M; break;
case IEEE80211_OFDM_RATE_24MB: *pBrateCfg |= RATE_24M; break;
case IEEE80211_OFDM_RATE_36MB: *pBrateCfg |= RATE_36M; break;
case IEEE80211_OFDM_RATE_48MB: *pBrateCfg |= RATE_48M; break;
case IEEE80211_OFDM_RATE_54MB: *pBrateCfg |= RATE_54M; break;
}
}
}
}
static VOID
_OneOutPipeMapping(
IN PADAPTER pAdapter
)
{
struct dvobj_priv *pdvobjpriv = adapter_to_dvobj(pAdapter);
pdvobjpriv->Queue2Pipe[0] = pdvobjpriv->RtOutPipe[0];//VO
pdvobjpriv->Queue2Pipe[1] = pdvobjpriv->RtOutPipe[0];//VI
pdvobjpriv->Queue2Pipe[2] = pdvobjpriv->RtOutPipe[0];//BE
pdvobjpriv->Queue2Pipe[3] = pdvobjpriv->RtOutPipe[0];//BK
pdvobjpriv->Queue2Pipe[4] = pdvobjpriv->RtOutPipe[0];//BCN
pdvobjpriv->Queue2Pipe[5] = pdvobjpriv->RtOutPipe[0];//MGT
pdvobjpriv->Queue2Pipe[6] = pdvobjpriv->RtOutPipe[0];//HIGH
pdvobjpriv->Queue2Pipe[7] = pdvobjpriv->RtOutPipe[0];//TXCMD
}
static VOID
_TwoOutPipeMapping(
IN PADAPTER pAdapter,
IN BOOLEAN bWIFICfg
)
{
struct dvobj_priv *pdvobjpriv = adapter_to_dvobj(pAdapter);
if(bWIFICfg){ //WMM
// BK, BE, VI, VO, BCN, CMD,MGT,HIGH,HCCA
//{ 0, 1, 0, 1, 0, 0, 0, 0, 0 };
//0:ep_0 num, 1:ep_1 num
pdvobjpriv->Queue2Pipe[0] = pdvobjpriv->RtOutPipe[1];//VO
pdvobjpriv->Queue2Pipe[1] = pdvobjpriv->RtOutPipe[0];//VI
pdvobjpriv->Queue2Pipe[2] = pdvobjpriv->RtOutPipe[1];//BE
pdvobjpriv->Queue2Pipe[3] = pdvobjpriv->RtOutPipe[0];//BK
pdvobjpriv->Queue2Pipe[4] = pdvobjpriv->RtOutPipe[0];//BCN
pdvobjpriv->Queue2Pipe[5] = pdvobjpriv->RtOutPipe[0];//MGT
pdvobjpriv->Queue2Pipe[6] = pdvobjpriv->RtOutPipe[0];//HIGH
pdvobjpriv->Queue2Pipe[7] = pdvobjpriv->RtOutPipe[0];//TXCMD
}
else{//typical setting
//BK, BE, VI, VO, BCN, CMD,MGT,HIGH,HCCA
//{ 1, 1, 0, 0, 0, 0, 0, 0, 0 };
//0:ep_0 num, 1:ep_1 num
pdvobjpriv->Queue2Pipe[0] = pdvobjpriv->RtOutPipe[0];//VO
pdvobjpriv->Queue2Pipe[1] = pdvobjpriv->RtOutPipe[0];//VI
pdvobjpriv->Queue2Pipe[2] = pdvobjpriv->RtOutPipe[1];//BE
pdvobjpriv->Queue2Pipe[3] = pdvobjpriv->RtOutPipe[1];//BK
pdvobjpriv->Queue2Pipe[4] = pdvobjpriv->RtOutPipe[0];//BCN
pdvobjpriv->Queue2Pipe[5] = pdvobjpriv->RtOutPipe[0];//MGT
pdvobjpriv->Queue2Pipe[6] = pdvobjpriv->RtOutPipe[0];//HIGH
pdvobjpriv->Queue2Pipe[7] = pdvobjpriv->RtOutPipe[0];//TXCMD
}
}
static VOID _ThreeOutPipeMapping(
IN PADAPTER pAdapter,
IN BOOLEAN bWIFICfg
)
{
struct dvobj_priv *pdvobjpriv = adapter_to_dvobj(pAdapter);
if(bWIFICfg){//for WMM
// BK, BE, VI, VO, BCN, CMD,MGT,HIGH,HCCA
//{ 1, 2, 1, 0, 0, 0, 0, 0, 0 };
//0:H, 1:N, 2:L
pdvobjpriv->Queue2Pipe[0] = pdvobjpriv->RtOutPipe[0];//VO
pdvobjpriv->Queue2Pipe[1] = pdvobjpriv->RtOutPipe[1];//VI
pdvobjpriv->Queue2Pipe[2] = pdvobjpriv->RtOutPipe[2];//BE
pdvobjpriv->Queue2Pipe[3] = pdvobjpriv->RtOutPipe[1];//BK
pdvobjpriv->Queue2Pipe[4] = pdvobjpriv->RtOutPipe[0];//BCN
pdvobjpriv->Queue2Pipe[5] = pdvobjpriv->RtOutPipe[0];//MGT
pdvobjpriv->Queue2Pipe[6] = pdvobjpriv->RtOutPipe[0];//HIGH
pdvobjpriv->Queue2Pipe[7] = pdvobjpriv->RtOutPipe[0];//TXCMD
}
else{//typical setting
// BK, BE, VI, VO, BCN, CMD,MGT,HIGH,HCCA
//{ 2, 2, 1, 0, 0, 0, 0, 0, 0 };
//0:H, 1:N, 2:L
pdvobjpriv->Queue2Pipe[0] = pdvobjpriv->RtOutPipe[0];//VO
pdvobjpriv->Queue2Pipe[1] = pdvobjpriv->RtOutPipe[1];//VI
pdvobjpriv->Queue2Pipe[2] = pdvobjpriv->RtOutPipe[2];//BE
pdvobjpriv->Queue2Pipe[3] = pdvobjpriv->RtOutPipe[2];//BK
pdvobjpriv->Queue2Pipe[4] = pdvobjpriv->RtOutPipe[0];//BCN
pdvobjpriv->Queue2Pipe[5] = pdvobjpriv->RtOutPipe[0];//MGT
pdvobjpriv->Queue2Pipe[6] = pdvobjpriv->RtOutPipe[0];//HIGH
pdvobjpriv->Queue2Pipe[7] = pdvobjpriv->RtOutPipe[0];//TXCMD
}
}
static VOID _FourOutPipeMapping(
IN PADAPTER pAdapter,
IN BOOLEAN bWIFICfg
)
{
struct dvobj_priv *pdvobjpriv = adapter_to_dvobj(pAdapter);
if(bWIFICfg){//for WMM
// BK, BE, VI, VO, BCN, CMD,MGT,HIGH,HCCA
//{ 1, 2, 1, 0, 0, 0, 0, 0, 0 };
//0:H, 1:N, 2:L ,3:E
pdvobjpriv->Queue2Pipe[0] = pdvobjpriv->RtOutPipe[0];//VO
pdvobjpriv->Queue2Pipe[1] = pdvobjpriv->RtOutPipe[1];//VI
pdvobjpriv->Queue2Pipe[2] = pdvobjpriv->RtOutPipe[2];//BE
pdvobjpriv->Queue2Pipe[3] = pdvobjpriv->RtOutPipe[1];//BK
pdvobjpriv->Queue2Pipe[4] = pdvobjpriv->RtOutPipe[0];//BCN
pdvobjpriv->Queue2Pipe[5] = pdvobjpriv->RtOutPipe[0];//MGT
pdvobjpriv->Queue2Pipe[6] = pdvobjpriv->RtOutPipe[3];//HIGH
pdvobjpriv->Queue2Pipe[7] = pdvobjpriv->RtOutPipe[0];//TXCMD
}
else{//typical setting
// BK, BE, VI, VO, BCN, CMD,MGT,HIGH,HCCA
//{ 2, 2, 1, 0, 0, 0, 0, 0, 0 };
//0:H, 1:N, 2:L
pdvobjpriv->Queue2Pipe[0] = pdvobjpriv->RtOutPipe[0];//VO
pdvobjpriv->Queue2Pipe[1] = pdvobjpriv->RtOutPipe[1];//VI
pdvobjpriv->Queue2Pipe[2] = pdvobjpriv->RtOutPipe[2];//BE
pdvobjpriv->Queue2Pipe[3] = pdvobjpriv->RtOutPipe[2];//BK
pdvobjpriv->Queue2Pipe[4] = pdvobjpriv->RtOutPipe[0];//BCN
pdvobjpriv->Queue2Pipe[5] = pdvobjpriv->RtOutPipe[0];//MGT
pdvobjpriv->Queue2Pipe[6] = pdvobjpriv->RtOutPipe[3];//HIGH
pdvobjpriv->Queue2Pipe[7] = pdvobjpriv->RtOutPipe[0];//TXCMD
}
}
BOOLEAN
Hal_MappingOutPipe(
IN PADAPTER pAdapter,
IN u8 NumOutPipe
)
{
struct registry_priv *pregistrypriv = &pAdapter->registrypriv;
BOOLEAN bWIFICfg = (pregistrypriv->wifi_spec) ?_TRUE:_FALSE;
BOOLEAN result = _TRUE;
switch(NumOutPipe)
{
case 2:
_TwoOutPipeMapping(pAdapter, bWIFICfg);
break;
case 3:
case 4:
_ThreeOutPipeMapping(pAdapter, bWIFICfg);
break;
case 1:
_OneOutPipeMapping(pAdapter);
break;
default:
result = _FALSE;
break;
}
return result;
}
void hal_init_macaddr(_adapter *adapter)
{
rtw_hal_set_hwreg(adapter, HW_VAR_MAC_ADDR, adapter_mac_addr(adapter));
#ifdef CONFIG_CONCURRENT_MODE
if (adapter->pbuddy_adapter)
rtw_hal_set_hwreg(adapter->pbuddy_adapter, HW_VAR_MAC_ADDR, adapter_mac_addr(adapter->pbuddy_adapter));
#endif
}
void rtw_init_hal_com_default_value(PADAPTER Adapter)
{
PHAL_DATA_TYPE pHalData = GET_HAL_DATA(Adapter);
pHalData->AntDetection = 1;
}
/*
* C2H event format:
* Field TRIGGER CONTENT CMD_SEQ CMD_LEN CMD_ID
* BITS [127:120] [119:16] [15:8] [7:4] [3:0]
*/
void c2h_evt_clear(_adapter *adapter)
{
rtw_write8(adapter, REG_C2HEVT_CLEAR, C2H_EVT_HOST_CLOSE);
}
s32 c2h_evt_read(_adapter *adapter, u8 *buf)
{
s32 ret = _FAIL;
struct c2h_evt_hdr *c2h_evt;
int i;
u8 trigger;
if (buf == NULL)
goto exit;
#if defined (CONFIG_RTL8188E)
trigger = rtw_read8(adapter, REG_C2HEVT_CLEAR);
if (trigger == C2H_EVT_HOST_CLOSE) {
goto exit; /* Not ready */
} else if (trigger != C2H_EVT_FW_CLOSE) {
goto clear_evt; /* Not a valid value */
}
c2h_evt = (struct c2h_evt_hdr *)buf;
_rtw_memset(c2h_evt, 0, 16);
*buf = rtw_read8(adapter, REG_C2HEVT_MSG_NORMAL);
*(buf+1) = rtw_read8(adapter, REG_C2HEVT_MSG_NORMAL + 1);
RT_PRINT_DATA(_module_hal_init_c_, _drv_info_, "c2h_evt_read(): ",
&c2h_evt , sizeof(c2h_evt));
if (0) {
DBG_871X("%s id:%u, len:%u, seq:%u, trigger:0x%02x\n", __func__
, c2h_evt->id, c2h_evt->plen, c2h_evt->seq, trigger);
}
/* Read the content */
for (i = 0; i < c2h_evt->plen; i++)
c2h_evt->payload[i] = rtw_read8(adapter, REG_C2HEVT_MSG_NORMAL + 2 + i);
RT_PRINT_DATA(_module_hal_init_c_, _drv_info_, "c2h_evt_read(): Command Content:\n",
c2h_evt->payload, c2h_evt->plen);
ret = _SUCCESS;
clear_evt:
/*
* Clear event to notify FW we have read the command.
* If this field isn't clear, the FW won't update the next command message.
*/
c2h_evt_clear(adapter);
#endif
exit:
return ret;
}
/*
* C2H event format:
* Field TRIGGER CMD_LEN CONTENT CMD_SEQ CMD_ID
* BITS [127:120] [119:112] [111:16] [15:8] [7:0]
*/
s32 c2h_evt_read_88xx(_adapter *adapter, u8 *buf)
{
s32 ret = _FAIL;
struct c2h_evt_hdr_88xx *c2h_evt;
int i;
u8 trigger;
if (buf == NULL)
goto exit;
#if defined(CONFIG_RTL8812A) || defined(CONFIG_RTL8821A) || defined(CONFIG_RTL8192E) || defined(CONFIG_RTL8723B) || defined(CONFIG_RTL8703B)
trigger = rtw_read8(adapter, REG_C2HEVT_CLEAR);
if (trigger == C2H_EVT_HOST_CLOSE) {
goto exit; /* Not ready */
} else if (trigger != C2H_EVT_FW_CLOSE) {
goto clear_evt; /* Not a valid value */
}
c2h_evt = (struct c2h_evt_hdr_88xx *)buf;
_rtw_memset(c2h_evt, 0, 16);
c2h_evt->id = rtw_read8(adapter, REG_C2HEVT_MSG_NORMAL);
c2h_evt->seq = rtw_read8(adapter, REG_C2HEVT_CMD_SEQ_88XX);
c2h_evt->plen = rtw_read8(adapter, REG_C2HEVT_CMD_LEN_88XX);
RT_PRINT_DATA(_module_hal_init_c_, _drv_info_, "c2h_evt_read(): ",
&c2h_evt , sizeof(c2h_evt));
if (0) {
DBG_871X("%s id:%u, len:%u, seq:%u, trigger:0x%02x\n", __func__
, c2h_evt->id, c2h_evt->plen, c2h_evt->seq, trigger);
}
/* Read the content */
for (i = 0; i < c2h_evt->plen; i++)
c2h_evt->payload[i] = rtw_read8(adapter, REG_C2HEVT_MSG_NORMAL + 2 + i);
RT_PRINT_DATA(_module_hal_init_c_, _drv_info_, "c2h_evt_read(): Command Content:\n",
c2h_evt->payload, c2h_evt->plen);
ret = _SUCCESS;
clear_evt:
/*
* Clear event to notify FW we have read the command.
* If this field isn't clear, the FW won't update the next command message.
*/
c2h_evt_clear(adapter);
#endif
exit:
return ret;
}
u8 rtw_hal_networktype_to_raid(_adapter *adapter, struct sta_info *psta)
{
if(IS_NEW_GENERATION_IC(adapter)){
return networktype_to_raid_ex(adapter,psta);
}
else{
return networktype_to_raid(adapter,psta);
}
}
u8 rtw_get_mgntframe_raid(_adapter *adapter,unsigned char network_type)
{
u8 raid;
if(IS_NEW_GENERATION_IC(adapter)){
raid = (network_type & WIRELESS_11B) ?RATEID_IDX_B
:RATEID_IDX_G;
}
else{
raid = (network_type & WIRELESS_11B) ?RATR_INX_WIRELESS_B
:RATR_INX_WIRELESS_G;
}
return raid;
}
void rtw_hal_update_sta_rate_mask(PADAPTER padapter, struct sta_info *psta)
{
u8 i, rf_type, limit;
u64 tx_ra_bitmap;
if(psta == NULL)
{
return;
}
tx_ra_bitmap = 0;
//b/g mode ra_bitmap
for (i=0; i<sizeof(psta->bssrateset); i++)
{
if (psta->bssrateset[i])
tx_ra_bitmap |= rtw_get_bit_value_from_ieee_value(psta->bssrateset[i]&0x7f);
}
#ifdef CONFIG_80211N_HT
#ifdef CONFIG_80211AC_VHT
//AC mode ra_bitmap
if(psta->vhtpriv.vht_option)
{
tx_ra_bitmap |= (rtw_vht_rate_to_bitmap(psta->vhtpriv.vht_mcs_map) << 12);
}
else
#endif //CONFIG_80211AC_VHT
{
//n mode ra_bitmap
if(psta->htpriv.ht_option)
{
rf_type = RF_1T1R;
rtw_hal_get_hwreg(padapter, HW_VAR_RF_TYPE, (u8 *)(&rf_type));
if(rf_type == RF_2T2R)
limit=16;// 2R
else if(rf_type == RF_3T3R)
limit=24;// 3R
else
limit=8;// 1R
/* Handling SMPS mode for AP MODE only*/
if (check_fwstate(&padapter->mlmepriv, WIFI_AP_STATE) == _TRUE) {
/*0:static SMPS, 1:dynamic SMPS, 3:SMPS disabled, 2:reserved*/
if (psta->htpriv.smps_cap == 0 || psta->htpriv.smps_cap == 1) {
/*operate with only one active receive chain // 11n-MCS rate <= MSC7*/
limit = 8;/* 1R*/
}
}
for (i=0; i<limit; i++) {
if (psta->htpriv.ht_cap.supp_mcs_set[i/8] & BIT(i%8))
tx_ra_bitmap |= BIT(i+12);
}
}
}
#endif //CONFIG_80211N_HT
DBG_871X("supp_mcs_set = %02x, %02x, %02x, rf_type=%d, tx_ra_bitmap=%016llx\n"
, psta->htpriv.ht_cap.supp_mcs_set[0], psta->htpriv.ht_cap.supp_mcs_set[1], psta->htpriv.ht_cap.supp_mcs_set[2], rf_type, tx_ra_bitmap);
psta->ra_mask = tx_ra_bitmap;
psta->init_rate = get_highest_rate_idx(tx_ra_bitmap)&0x3f;
}
#ifndef SEC_CAM_ACCESS_TIMEOUT_MS
#define SEC_CAM_ACCESS_TIMEOUT_MS 200
#endif
#ifndef DBG_SEC_CAM_ACCESS
#define DBG_SEC_CAM_ACCESS 0
#endif
u32 rtw_sec_read_cam(_adapter *adapter, u8 addr)
{
_mutex *mutex = &adapter_to_dvobj(adapter)->cam_ctl.sec_cam_access_mutex;
u32 rdata;
u32 cnt = 0;
u32 start = 0, end = 0;
u8 timeout = 0;
u8 sr = 0;
_enter_critical_mutex(mutex, NULL);
rtw_write32(adapter, REG_CAMCMD, CAM_POLLINIG | addr);
start = rtw_get_current_time();
while (1) {
if (rtw_is_surprise_removed(adapter)) {
sr = 1;
break;
}
cnt++;
if (0 == (rtw_read32(adapter, REG_CAMCMD) & CAM_POLLINIG))
break;
if (rtw_get_passing_time_ms(start) > SEC_CAM_ACCESS_TIMEOUT_MS) {
timeout = 1;
break;
}
}
end = rtw_get_current_time();
rdata = rtw_read32(adapter, REG_CAMREAD);
_exit_critical_mutex(mutex, NULL);
if (DBG_SEC_CAM_ACCESS || timeout) {
DBG_871X(FUNC_ADPT_FMT" addr:0x%02x, rdata:0x%08x, to:%u, polling:%u, %d ms\n"
, FUNC_ADPT_ARG(adapter), addr, rdata, timeout, cnt, rtw_get_time_interval_ms(start, end));
}
return rdata;
}
void rtw_sec_write_cam(_adapter *adapter, u8 addr, u32 wdata)
{
_mutex *mutex = &adapter_to_dvobj(adapter)->cam_ctl.sec_cam_access_mutex;
u32 cnt = 0;
u32 start = 0, end = 0;
u8 timeout = 0;
u8 sr = 0;
_enter_critical_mutex(mutex, NULL);
rtw_write32(adapter, REG_CAMWRITE, wdata);
rtw_write32(adapter, REG_CAMCMD, CAM_POLLINIG | CAM_WRITE | addr);
start = rtw_get_current_time();
while (1) {
if (rtw_is_surprise_removed(adapter)) {
sr = 1;
break;
}
cnt++;
if (0 == (rtw_read32(adapter, REG_CAMCMD) & CAM_POLLINIG))
break;
if (rtw_get_passing_time_ms(start) > SEC_CAM_ACCESS_TIMEOUT_MS) {
timeout = 1;
break;
}
}
end = rtw_get_current_time();
_exit_critical_mutex(mutex, NULL);
if (DBG_SEC_CAM_ACCESS || timeout) {
DBG_871X(FUNC_ADPT_FMT" addr:0x%02x, wdata:0x%08x, to:%u, polling:%u, %d ms\n"
, FUNC_ADPT_ARG(adapter), addr, wdata, timeout, cnt, rtw_get_time_interval_ms(start, end));
}
}
void rtw_sec_read_cam_ent(_adapter *adapter, u8 id, u8 *ctrl, u8 *mac, u8 *key)
{
unsigned int val, addr;
u8 i;
u32 rdata;
u8 begin = 0;
u8 end = 5; /* TODO: consider other key length accordingly */
if (!ctrl && !mac && !key) {
rtw_warn_on(1);
goto exit;
}
/* TODO: check id range */
if (!ctrl && !mac)
begin = 2; /* read from key */
if (!key && !mac)
end = 0; /* read to ctrl */
else if (!key)
end = 2; /* read to mac */
for (i = begin; i <= end; i++) {
rdata = rtw_sec_read_cam(adapter, (id << 3) | i);
switch (i) {
case 0:
if (ctrl)
_rtw_memcpy(ctrl, (u8 *)(&rdata), 2);
if (mac)
_rtw_memcpy(mac, ((u8 *)(&rdata)) + 2, 2);
break;
case 1:
if (mac)
_rtw_memcpy(mac + 2, (u8 *)(&rdata), 4);
break;
default:
if (key)
_rtw_memcpy(key + (i - 2) * 4, (u8 *)(&rdata), 4);
break;
}
}
exit:
return;
}
void rtw_sec_write_cam_ent(_adapter *adapter, u8 id, u16 ctrl, u8 *mac, u8 *key)
{
unsigned int i;
int j;
u8 addr;
u32 wdata;
/* TODO: consider other key length accordingly */
#if 0
switch ((ctrl & 0x1c) >> 2) {
case _WEP40_:
case _TKIP_
case _AES_
case _WEP104_
}
#else
j = 5;
#endif
for (; j >= 0; j--) {
switch (j) {
case 0:
wdata = (ctrl | (mac[0] << 16) | (mac[1] << 24));
break;
case 1:
wdata = (mac[2] | (mac[3] << 8) | (mac[4] << 16) | (mac[5] << 24));
break;
default:
i = (j - 2) << 2;
wdata = (key[i] | (key[i + 1] << 8) | (key[i + 2] << 16) | (key[i + 3] << 24));
break;
}
addr = (id << 3) + j;
rtw_sec_write_cam(adapter, addr, wdata);
}
}
bool rtw_sec_read_cam_is_gk(_adapter *adapter, u8 id)
{
bool res;
u16 ctrl;
rtw_sec_read_cam_ent(adapter, id, (u8 *)&ctrl, NULL, NULL);
res = (ctrl & BIT6) ? _TRUE : _FALSE;
return res;
}
void hw_var_port_switch(_adapter *adapter)
{
#ifdef CONFIG_CONCURRENT_MODE
#ifdef CONFIG_RUNTIME_PORT_SWITCH
/*
0x102: MSR
0x550: REG_BCN_CTRL
0x551: REG_BCN_CTRL_1
0x55A: REG_ATIMWND
0x560: REG_TSFTR
0x568: REG_TSFTR1
0x570: REG_ATIMWND_1
0x610: REG_MACID
0x618: REG_BSSID
0x700: REG_MACID1
0x708: REG_BSSID1
*/
int i;
u8 msr;
u8 bcn_ctrl;
u8 bcn_ctrl_1;
u8 atimwnd[2];
u8 atimwnd_1[2];
u8 tsftr[8];
u8 tsftr_1[8];
u8 macid[6];
u8 bssid[6];
u8 macid_1[6];
u8 bssid_1[6];
u8 iface_type;
msr = rtw_read8(adapter, MSR);
bcn_ctrl = rtw_read8(adapter, REG_BCN_CTRL);
bcn_ctrl_1 = rtw_read8(adapter, REG_BCN_CTRL_1);
for (i=0; i<2; i++)
atimwnd[i] = rtw_read8(adapter, REG_ATIMWND+i);
for (i=0; i<2; i++)
atimwnd_1[i] = rtw_read8(adapter, REG_ATIMWND_1+i);
for (i=0; i<8; i++)
tsftr[i] = rtw_read8(adapter, REG_TSFTR+i);
for (i=0; i<8; i++)
tsftr_1[i] = rtw_read8(adapter, REG_TSFTR1+i);
for (i=0; i<6; i++)
macid[i] = rtw_read8(adapter, REG_MACID+i);
for (i=0; i<6; i++)
bssid[i] = rtw_read8(adapter, REG_BSSID+i);
for (i=0; i<6; i++)
macid_1[i] = rtw_read8(adapter, REG_MACID1+i);
for (i=0; i<6; i++)
bssid_1[i] = rtw_read8(adapter, REG_BSSID1+i);
#ifdef DBG_RUNTIME_PORT_SWITCH
DBG_871X(FUNC_ADPT_FMT" before switch\n"
"msr:0x%02x\n"
"bcn_ctrl:0x%02x\n"
"bcn_ctrl_1:0x%02x\n"
"atimwnd:0x%04x\n"
"atimwnd_1:0x%04x\n"
"tsftr:%llu\n"
"tsftr1:%llu\n"
"macid:"MAC_FMT"\n"
"bssid:"MAC_FMT"\n"
"macid_1:"MAC_FMT"\n"
"bssid_1:"MAC_FMT"\n"
, FUNC_ADPT_ARG(adapter)
, msr
, bcn_ctrl
, bcn_ctrl_1
, *((u16*)atimwnd)
, *((u16*)atimwnd_1)
, *((u64*)tsftr)
, *((u64*)tsftr_1)
, MAC_ARG(macid)
, MAC_ARG(bssid)
, MAC_ARG(macid_1)
, MAC_ARG(bssid_1)
);
#endif /* DBG_RUNTIME_PORT_SWITCH */
/* disable bcn function, disable update TSF */
rtw_write8(adapter, REG_BCN_CTRL, (bcn_ctrl & (~EN_BCN_FUNCTION)) | DIS_TSF_UDT);
rtw_write8(adapter, REG_BCN_CTRL_1, (bcn_ctrl_1 & (~EN_BCN_FUNCTION)) | DIS_TSF_UDT);
/* switch msr */
msr = (msr&0xf0) |((msr&0x03) << 2) | ((msr&0x0c) >> 2);
rtw_write8(adapter, MSR, msr);
/* write port0 */
rtw_write8(adapter, REG_BCN_CTRL, bcn_ctrl_1 & ~EN_BCN_FUNCTION);
for (i=0; i<2; i++)
rtw_write8(adapter, REG_ATIMWND+i, atimwnd_1[i]);
for (i=0; i<8; i++)
rtw_write8(adapter, REG_TSFTR+i, tsftr_1[i]);
for (i=0; i<6; i++)
rtw_write8(adapter, REG_MACID+i, macid_1[i]);
for (i=0; i<6; i++)
rtw_write8(adapter, REG_BSSID+i, bssid_1[i]);
/* write port1 */
rtw_write8(adapter, REG_BCN_CTRL_1, bcn_ctrl & ~EN_BCN_FUNCTION);
for (i=0; i<2; i++)
rtw_write8(adapter, REG_ATIMWND_1+1, atimwnd[i]);
for (i=0; i<8; i++)
rtw_write8(adapter, REG_TSFTR1+i, tsftr[i]);
for (i=0; i<6; i++)
rtw_write8(adapter, REG_MACID1+i, macid[i]);
for (i=0; i<6; i++)
rtw_write8(adapter, REG_BSSID1+i, bssid[i]);
/* write bcn ctl */
#ifdef CONFIG_BT_COEXIST
#if defined(CONFIG_RTL8723B) || defined(CONFIG_RTL8703B)
// always enable port0 beacon function for PSTDMA
bcn_ctrl_1 |= EN_BCN_FUNCTION;
// always disable port1 beacon function for PSTDMA
bcn_ctrl &= ~EN_BCN_FUNCTION;
#endif
#endif
rtw_write8(adapter, REG_BCN_CTRL, bcn_ctrl_1);
rtw_write8(adapter, REG_BCN_CTRL_1, bcn_ctrl);
if (adapter->iface_type == IFACE_PORT0) {
adapter->iface_type = IFACE_PORT1;
adapter->pbuddy_adapter->iface_type = IFACE_PORT0;
DBG_871X_LEVEL(_drv_always_, "port switch - port0("ADPT_FMT"), port1("ADPT_FMT")\n",
ADPT_ARG(adapter->pbuddy_adapter), ADPT_ARG(adapter));
} else {
adapter->iface_type = IFACE_PORT0;
adapter->pbuddy_adapter->iface_type = IFACE_PORT1;
DBG_871X_LEVEL(_drv_always_, "port switch - port0("ADPT_FMT"), port1("ADPT_FMT")\n",
ADPT_ARG(adapter), ADPT_ARG(adapter->pbuddy_adapter));
}
#ifdef DBG_RUNTIME_PORT_SWITCH
msr = rtw_read8(adapter, MSR);
bcn_ctrl = rtw_read8(adapter, REG_BCN_CTRL);
bcn_ctrl_1 = rtw_read8(adapter, REG_BCN_CTRL_1);
for (i=0; i<2; i++)
atimwnd[i] = rtw_read8(adapter, REG_ATIMWND+i);
for (i=0; i<2; i++)
atimwnd_1[i] = rtw_read8(adapter, REG_ATIMWND_1+i);
for (i=0; i<8; i++)
tsftr[i] = rtw_read8(adapter, REG_TSFTR+i);
for (i=0; i<8; i++)
tsftr_1[i] = rtw_read8(adapter, REG_TSFTR1+i);
for (i=0; i<6; i++)
macid[i] = rtw_read8(adapter, REG_MACID+i);
for (i=0; i<6; i++)
bssid[i] = rtw_read8(adapter, REG_BSSID+i);
for (i=0; i<6; i++)
macid_1[i] = rtw_read8(adapter, REG_MACID1+i);
for (i=0; i<6; i++)
bssid_1[i] = rtw_read8(adapter, REG_BSSID1+i);
DBG_871X(FUNC_ADPT_FMT" after switch\n"
"msr:0x%02x\n"
"bcn_ctrl:0x%02x\n"
"bcn_ctrl_1:0x%02x\n"
"atimwnd:%u\n"
"atimwnd_1:%u\n"
"tsftr:%llu\n"
"tsftr1:%llu\n"
"macid:"MAC_FMT"\n"
"bssid:"MAC_FMT"\n"
"macid_1:"MAC_FMT"\n"
"bssid_1:"MAC_FMT"\n"
, FUNC_ADPT_ARG(adapter)
, msr
, bcn_ctrl
, bcn_ctrl_1
, *((u16*)atimwnd)
, *((u16*)atimwnd_1)
, *((u64*)tsftr)
, *((u64*)tsftr_1)
, MAC_ARG(macid)
, MAC_ARG(bssid)
, MAC_ARG(macid_1)
, MAC_ARG(bssid_1)
);
#endif /* DBG_RUNTIME_PORT_SWITCH */
#endif /* CONFIG_RUNTIME_PORT_SWITCH */
#endif /* CONFIG_CONCURRENT_MODE */
}
void rtw_hal_set_FwRsvdPage_cmd(PADAPTER padapter, PRSVDPAGE_LOC rsvdpageloc)
{
struct hal_ops *pHalFunc = &padapter->HalFunc;
u8 u1H2CRsvdPageParm[H2C_RSVDPAGE_LOC_LEN]={0};
u8 ret = 0;
DBG_871X("RsvdPageLoc: ProbeRsp=%d PsPoll=%d Null=%d QoSNull=%d BTNull=%d\n",
rsvdpageloc->LocProbeRsp, rsvdpageloc->LocPsPoll,
rsvdpageloc->LocNullData, rsvdpageloc->LocQosNull,
rsvdpageloc->LocBTQosNull);
SET_H2CCMD_RSVDPAGE_LOC_PROBE_RSP(u1H2CRsvdPageParm, rsvdpageloc->LocProbeRsp);
SET_H2CCMD_RSVDPAGE_LOC_PSPOLL(u1H2CRsvdPageParm, rsvdpageloc->LocPsPoll);
SET_H2CCMD_RSVDPAGE_LOC_NULL_DATA(u1H2CRsvdPageParm, rsvdpageloc->LocNullData);
SET_H2CCMD_RSVDPAGE_LOC_QOS_NULL_DATA(u1H2CRsvdPageParm, rsvdpageloc->LocQosNull);
SET_H2CCMD_RSVDPAGE_LOC_BT_QOS_NULL_DATA(u1H2CRsvdPageParm, rsvdpageloc->LocBTQosNull);
ret = rtw_hal_fill_h2c_cmd(padapter,
H2C_RSVD_PAGE,
H2C_RSVDPAGE_LOC_LEN,
u1H2CRsvdPageParm);
}
#ifdef CONFIG_GPIO_WAKEUP
/*
* Switch GPIO_13, GPIO_14 to wlan control, or pull GPIO_13,14 MUST fail.
* It happended at 8723B/8192E/8821A. New IC will check multi function GPIO,
* and implement HAL function.
*/
static void rtw_hal_switch_gpio_wl_ctrl(_adapter* padapter, u8 index, u8 enable)
{
if (index !=13 && index != 14) return;
rtw_hal_set_hwreg(padapter, HW_SET_GPIO_WL_CTRL, (u8 *)(&enable));
}
void rtw_hal_set_output_gpio(_adapter *padapter, u8 index, u8 outputval)
{
if ( index <= 7 ) {
/* config GPIO mode */
rtw_write8(padapter, REG_GPIO_PIN_CTRL + 3,
rtw_read8(padapter, REG_GPIO_PIN_CTRL + 3) & ~BIT(index) );
/* config GPIO Sel */
/* 0: input */
/* 1: output */
rtw_write8(padapter, REG_GPIO_PIN_CTRL + 2,
rtw_read8(padapter, REG_GPIO_PIN_CTRL + 2) | BIT(index));
/* set output value */
if ( outputval ) {
rtw_write8(padapter, REG_GPIO_PIN_CTRL + 1,
rtw_read8(padapter, REG_GPIO_PIN_CTRL + 1) | BIT(index));
} else {
rtw_write8(padapter, REG_GPIO_PIN_CTRL + 1,
rtw_read8(padapter, REG_GPIO_PIN_CTRL + 1) & ~BIT(index));
}
} else if (index <= 15){
/* 88C Series: */
/* index: 11~8 transform to 3~0 */
/* 8723 Series: */
/* index: 12~8 transform to 4~0 */
index -= 8;
/* config GPIO mode */
rtw_write8(padapter, REG_GPIO_PIN_CTRL_2 + 3,
rtw_read8(padapter, REG_GPIO_PIN_CTRL_2 + 3) & ~BIT(index) );
/* config GPIO Sel */
/* 0: input */
/* 1: output */
rtw_write8(padapter, REG_GPIO_PIN_CTRL_2 + 2,
rtw_read8(padapter, REG_GPIO_PIN_CTRL_2 + 2) | BIT(index));
/* set output value */
if ( outputval ) {
rtw_write8(padapter, REG_GPIO_PIN_CTRL_2 + 1,
rtw_read8(padapter, REG_GPIO_PIN_CTRL_2 + 1) | BIT(index));
} else {
rtw_write8(padapter, REG_GPIO_PIN_CTRL_2 + 1,
rtw_read8(padapter, REG_GPIO_PIN_CTRL_2 + 1) & ~BIT(index));
}
} else {
DBG_871X("%s: invalid GPIO%d=%d\n",
__FUNCTION__, index, outputval);
}
}
#endif
void rtw_hal_set_FwAoacRsvdPage_cmd(PADAPTER padapter, PRSVDPAGE_LOC rsvdpageloc)
{
struct hal_ops *pHalFunc = &padapter->HalFunc;
struct pwrctrl_priv *pwrpriv = adapter_to_pwrctl(padapter);
struct mlme_priv *pmlmepriv = &padapter->mlmepriv;
u8 res = 0, count = 0, ret = 0;
#ifdef CONFIG_WOWLAN
u8 u1H2CAoacRsvdPageParm[H2C_AOAC_RSVDPAGE_LOC_LEN]={0};
DBG_871X("AOACRsvdPageLoc: RWC=%d ArpRsp=%d NbrAdv=%d GtkRsp=%d GtkInfo=%d ProbeReq=%d NetworkList=%d\n",
rsvdpageloc->LocRemoteCtrlInfo, rsvdpageloc->LocArpRsp,
rsvdpageloc->LocNbrAdv, rsvdpageloc->LocGTKRsp,
rsvdpageloc->LocGTKInfo, rsvdpageloc->LocProbeReq,
rsvdpageloc->LocNetList);
if (check_fwstate(pmlmepriv, _FW_LINKED)) {
SET_H2CCMD_AOAC_RSVDPAGE_LOC_REMOTE_WAKE_CTRL_INFO(u1H2CAoacRsvdPageParm, rsvdpageloc->LocRemoteCtrlInfo);
SET_H2CCMD_AOAC_RSVDPAGE_LOC_ARP_RSP(u1H2CAoacRsvdPageParm, rsvdpageloc->LocArpRsp);
//SET_H2CCMD_AOAC_RSVDPAGE_LOC_NEIGHBOR_ADV(u1H2CAoacRsvdPageParm, rsvdpageloc->LocNbrAdv);
SET_H2CCMD_AOAC_RSVDPAGE_LOC_GTK_RSP(u1H2CAoacRsvdPageParm, rsvdpageloc->LocGTKRsp);
SET_H2CCMD_AOAC_RSVDPAGE_LOC_GTK_INFO(u1H2CAoacRsvdPageParm, rsvdpageloc->LocGTKInfo);
#ifdef CONFIG_GTK_OL
SET_H2CCMD_AOAC_RSVDPAGE_LOC_GTK_EXT_MEM(u1H2CAoacRsvdPageParm, rsvdpageloc->LocGTKEXTMEM);
#endif // CONFIG_GTK_OL
ret = rtw_hal_fill_h2c_cmd(padapter,
H2C_AOAC_RSVD_PAGE,
H2C_AOAC_RSVDPAGE_LOC_LEN,
u1H2CAoacRsvdPageParm);
}
#ifdef CONFIG_PNO_SUPPORT
else
{
if(!pwrpriv->pno_in_resume) {
DBG_871X("NLO_INFO=%d\n", rsvdpageloc->LocPNOInfo);
_rtw_memset(&u1H2CAoacRsvdPageParm, 0,
sizeof(u1H2CAoacRsvdPageParm));
SET_H2CCMD_AOAC_RSVDPAGE_LOC_NLO_INFO(u1H2CAoacRsvdPageParm,
rsvdpageloc->LocPNOInfo);
ret = rtw_hal_fill_h2c_cmd(padapter,
H2C_AOAC_RSVDPAGE3,
H2C_AOAC_RSVDPAGE_LOC_LEN,
u1H2CAoacRsvdPageParm);
}
}
#endif //CONFIG_PNO_SUPPORT
#endif // CONFIG_WOWLAN
}
#if defined(CONFIG_WOWLAN) || defined(CONFIG_AP_WOWLAN)
static void rtw_hal_force_enable_rxdma(_adapter *adapter)
{
DBG_871X("%s: Set 0x690=0x00\n", __func__);
rtw_write8(adapter, REG_WOW_CTRL,
(rtw_read8(adapter, REG_WOW_CTRL)&0xf0));
DBG_871X_LEVEL(_drv_always_, "%s: Release RXDMA\n", __func__);
rtw_write32(adapter, REG_RXPKT_NUM,
(rtw_read32(adapter,REG_RXPKT_NUM)&(~RW_RELEASE_EN)));
}
static void rtw_hal_disable_tx_report(_adapter *adapter)
{
rtw_write8(adapter, REG_TX_RPT_CTRL,
((rtw_read8(adapter, REG_TX_RPT_CTRL)&~BIT(1)))&~BIT(5));
DBG_871X("disable TXRPT:0x%02x\n", rtw_read8(adapter, REG_TX_RPT_CTRL));
}
static void rtw_hal_enable_tx_report(_adapter *adapter)
{
rtw_write8(adapter, REG_TX_RPT_CTRL,
((rtw_read8(adapter, REG_TX_RPT_CTRL)|BIT(1)))|BIT(5));
DBG_871X("enable TX_RPT:0x%02x\n", rtw_read8(adapter, REG_TX_RPT_CTRL));
}
static void rtw_hal_release_rx_dma(_adapter *adapter)
{
u32 val32 = 0;
val32 = rtw_read32(adapter, REG_RXPKT_NUM);
rtw_write32(adapter, REG_RXPKT_NUM, (val32 & (~RW_RELEASE_EN)));
DBG_871X("%s, [0x%04x]: 0x%08x\n",
__func__, REG_RXPKT_NUM, (val32 & (~RW_RELEASE_EN)));
}
static u8 rtw_hal_pause_rx_dma(_adapter *adapter)
{
u8 ret = 0;
s8 trycnt = 100;
u16 len = 0;
u32 tmp = 0;
int res = 0;
//RX DMA stop
DBG_871X_LEVEL(_drv_always_, "Pause DMA\n");
rtw_write32(adapter, REG_RXPKT_NUM,
(rtw_read32(adapter,REG_RXPKT_NUM)|RW_RELEASE_EN));
do{
if((rtw_read32(adapter, REG_RXPKT_NUM)&RXDMA_IDLE)) {
DBG_871X_LEVEL(_drv_always_, "RX_DMA_IDLE is true\n");
ret = _SUCCESS;
break;
}
#if defined(CONFIG_SDIO_HCI) || defined(CONFIG_GSPI_HCI)
else {
// If RX_DMA is not idle, receive one pkt from DMA
res = sdio_local_read(adapter,
SDIO_REG_RX0_REQ_LEN, 4, (u8*)&tmp);
len = le16_to_cpu(tmp);
DBG_871X_LEVEL(_drv_always_, "RX len:%d\n", len);
if (len > 0)
res = RecvOnePkt(adapter, len);
else
DBG_871X_LEVEL(_drv_always_, "read length fail %d\n", len);
DBG_871X_LEVEL(_drv_always_,
"RecvOnePkt Result: %d\n", res);
}
#endif //CONFIG_SDIO_HCI || CONFIG_GSPI_HCI
#ifdef CONFIG_USB_HCI
else {
if (adapter->intf_start)
adapter->intf_start(adapter);
tmp = rtw_read32(adapter, REG_RXPKT_NUM) & RXDMA_IDLE;
if (tmp) {
if (adapter->intf_stop)
adapter->intf_stop(adapter);
RTW_ENABLE_FUNC(adapter, DF_RX_BIT);
RTW_ENABLE_FUNC(adapter, DF_TX_BIT);
}
}
#endif
}while(trycnt--);
if (trycnt < 0) {
tmp = rtw_read16(adapter, REG_RXPKT_NUM + 3);
DBG_871X_LEVEL(_drv_always_, "Stop RX DMA failed......\n");
DBG_871X_LEVEL(_drv_always_, "%s, RXPKT_NUM: 0x%04x\n",
__func__, tmp);
tmp = rtw_read16(adapter, REG_RXPKT_NUM + 2);
if (tmp & BIT(3))
DBG_871X_LEVEL(_drv_always_, "%s, RX DMA has req\n",
__func__);
else
DBG_871X_LEVEL(_drv_always_, "%s, RX DMA no req\n",
__func__);
ret = _FAIL;
}
return ret;
}
#if defined(CONFIG_SDIO_HCI) || defined(CONFIG_GSPI_HCI)
static u8 rtw_hal_enable_cpwm2(_adapter* adapter)
{
u8 ret = 0;
int res = 0;
u32 tmp = 0;
DBG_871X_LEVEL(_drv_always_, "%s\n", __func__);
res = sdio_local_read(adapter, SDIO_REG_HIMR, 4, (u8*)&tmp);
if (!res)
DBG_871X_LEVEL(_drv_info_, "read SDIO_REG_HIMR: 0x%08x\n", tmp);
else
DBG_871X_LEVEL(_drv_info_, "sdio_local_read fail\n");
tmp = SDIO_HIMR_CPWM2_MSK;
res = sdio_local_write(adapter, SDIO_REG_HIMR, 4, (u8*)&tmp);
if (!res){
res = sdio_local_read(adapter, SDIO_REG_HIMR, 4, (u8*)&tmp);
DBG_871X_LEVEL(_drv_info_, "read again SDIO_REG_HIMR: 0x%08x\n", tmp);
ret = _SUCCESS;
}else {
DBG_871X_LEVEL(_drv_info_, "sdio_local_write fail\n");
ret = _FAIL;
}
return ret;
}
#endif /* CONFIG_SDIO_HCI, CONFIG_GSPI_HCI */
#endif /* CONFIG_WOWLAN || CONFIG_AP_WOWLAN */
#ifdef CONFIG_WOWLAN
/*
* rtw_hal_check_wow_ctrl
* chk_type: _TRUE means to check enable, if 0x690 & bit1, WOW enable successful
* _FALSE means to check disable, if 0x690 & bit1, WOW disable fail
*/
static u8 rtw_hal_check_wow_ctrl(_adapter *adapter, u8 chk_type)
{
u8 mstatus = 0;
u8 trycnt = 25;
u8 res = _FALSE;
mstatus = rtw_read8(adapter, REG_WOW_CTRL);
DBG_871X_LEVEL(_drv_info_, "%s mstatus:0x%02x\n", __func__, mstatus);
if (chk_type) {
while (!(mstatus&BIT1) && trycnt > 1) {
mstatus = rtw_read8(adapter, REG_WOW_CTRL);
DBG_871X_LEVEL(_drv_always_,
"Loop index: %d :0x%02x\n",
trycnt, mstatus);
trycnt--;
rtw_msleep_os(20);
}
if (mstatus & BIT1)
res = _TRUE;
else
res = _FALSE;
} else {
while (mstatus&BIT1 && trycnt > 1) {
mstatus = rtw_read8(adapter, REG_WOW_CTRL);
DBG_871X_LEVEL(_drv_always_,
"Loop index: %d :0x%02x\n",
trycnt, mstatus);
trycnt--;
rtw_msleep_os(20);
}
if (mstatus & BIT1)
res = _FALSE;
else
res = _TRUE;
}
DBG_871X_LEVEL(_drv_always_, "%s check_type: %d res: %d trycnt: %d\n",
__func__, chk_type, res, (25 - trycnt));
return res;
}
#ifdef CONFIG_PNO_SUPPORT
static u8 rtw_hal_check_pno_enabled(_adapter *adapter)
{
struct pwrctrl_priv *ppwrpriv = adapter_to_pwrctl(adapter);
u8 res = 0, count = 0;
u8 ret = _FALSE;
if (ppwrpriv->wowlan_pno_enable && ppwrpriv->pno_in_resume == _FALSE) {
res = rtw_read8(adapter, REG_PNO_STATUS);
while (!(res&BIT(7)) && count < 25) {
DBG_871X("[%d] cmd: 0x81 REG_PNO_STATUS: 0x%02x\n",
count, res);
res = rtw_read8(adapter, REG_PNO_STATUS);
count++;
rtw_msleep_os(2);
}
if (res & BIT(7))
ret = _TRUE;
else
ret = _FALSE;
DBG_871X("cmd: 0x81 REG_PNO_STATUS: ret(%d)\n", ret);
}
return ret;
}
#endif
static void rtw_hal_backup_rate(_adapter *adapter)
{
DBG_871X("%s\n", __func__);
/* backup data rate to register 0x8b for wowlan FW */
rtw_write8(adapter, 0x8d, 1);
rtw_write8(adapter, 0x8c, 0);
rtw_write8(adapter, 0x8f, 0x40);
rtw_write8(adapter, 0x8b, rtw_read8(adapter, 0x2f0));
}
#ifdef CONFIG_GTK_OL
static void rtw_hal_fw_sync_cam_id(_adapter *adapter)
{
struct security_priv *psecuritypriv = &adapter->securitypriv;
u8 null_addr[] = {0x0, 0x0, 0x0, 0x0, 0x0, 0x0};
int cam_id;
u32 algorithm = 0;
u16 ctrl = 0;
u8 *addr;
u8 index = 0;
u8 get_key[16];
addr = get_bssid(&adapter->mlmepriv);
if (addr == NULL) {
DBG_871X("%s: get bssid MAC addr fail!!\n", __func__);
return;
}
do{
cam_id = rtw_camid_search(adapter, addr, index, -1);
if (cam_id == -1) {
DBG_871X("%s: cam_id: %d, key_id:%d\n",
__func__, cam_id, index);
} else if (rtw_camid_is_gk(adapter, cam_id) != _TRUE) {
DBG_871X("%s: cam_id: %d key_id(%d) is not GK\n",
__func__, cam_id, index);
} else {
rtw_sec_read_cam_ent(adapter, cam_id, NULL, NULL, get_key);
algorithm = psecuritypriv->dot11PrivacyAlgrthm;
ctrl = BIT(15) | BIT6 |(algorithm << 2) | index;
write_cam(adapter, index, ctrl, addr, get_key);
ctrl = 0;
write_cam(adapter, cam_id, ctrl, null_addr, get_key);
}
index++;
}while(index < 4);
rtw_write8(adapter, REG_SECCFG, 0xcc);
}
static void rtw_hal_update_gtk_offload_info(_adapter *adapter)
{
struct security_priv *psecuritypriv = &adapter->securitypriv;
u8 default_cam_id = 0;
u8 cam_id=5;
u8 *addr;
u8 null_addr[] = {0x0, 0x0, 0x0, 0x0, 0x0, 0x0};
u8 gtk_keyindex=0;
u8 get_key[16];
u8 index = 1;
u16 ctrl = 0;
u32 algorithm = 0;
addr = get_bssid(&adapter->mlmepriv);
if (addr == NULL) {
DBG_871X("%s: get bssid MAC addr fail!!\n", __func__);
return;
}
_rtw_memset(get_key, 0, sizeof(get_key));
algorithm = psecuritypriv->dot11PrivacyAlgrthm;
if(psecuritypriv->binstallKCK_KEK == _TRUE) {
//read gtk key index
gtk_keyindex = rtw_read8(adapter, 0x48c);
do{
/* chech if GK */
if (rtw_sec_read_cam_is_gk(adapter, default_cam_id) == _TRUE) {
rtw_sec_read_cam_ent(adapter, default_cam_id, NULL, NULL, get_key);
algorithm = psecuritypriv->dot11PrivacyAlgrthm;
/* in default cam entry, cam id = key id */
ctrl = BIT(15) | BIT6 | (algorithm << 2) | default_cam_id;
write_cam(adapter, cam_id, ctrl, addr, get_key);
cam_id++;
ctrl = 0;
write_cam(adapter, default_cam_id, ctrl, null_addr, get_key);
}
if (gtk_keyindex < 4 && (default_cam_id == gtk_keyindex)) {
psecuritypriv->dot118021XGrpKeyid = gtk_keyindex;
_rtw_memcpy(psecuritypriv->dot118021XGrpKey[psecuritypriv->dot118021XGrpKeyid].skey,
get_key, 16);
DBG_871X_LEVEL(_drv_always_, "GTK (%d) = 0x%08x, 0x%08x, 0x%08x, 0x%08x\n",
gtk_keyindex,
psecuritypriv->dot118021XGrpKey[psecuritypriv->dot118021XGrpKeyid].lkey[0],
psecuritypriv->dot118021XGrpKey[psecuritypriv->dot118021XGrpKeyid].lkey[1],
psecuritypriv->dot118021XGrpKey[psecuritypriv->dot118021XGrpKeyid].lkey[2],
psecuritypriv->dot118021XGrpKey[psecuritypriv->dot118021XGrpKeyid].lkey[3]);
}
default_cam_id++;
} while (default_cam_id < 4);
rtw_write8(adapter, REG_SECCFG, 0x0c);
#ifdef CONFIG_GTK_OL_DBG
//if (gtk_keyindex != 5)
dump_sec_cam(RTW_DBGDUMP, adapter);
#endif
}
}
#endif
static void rtw_hal_update_tx_iv(_adapter *adapter)
{
struct pwrctrl_priv *pwrctl = adapter_to_pwrctl(adapter);
u64 iv_low = 0, iv_high = 0;
// 3.1 read fw iv
iv_low = rtw_read32(adapter, REG_TXPKTBUF_IV_LOW);
//only low two bytes is PN, check AES_IV macro for detail
iv_low &= 0xffff;
iv_high = rtw_read32(adapter, REG_TXPKTBUF_IV_HIGH);
//get the real packet number
pwrctl->wowlan_fw_iv = iv_high << 16 | iv_low;
DBG_871X_LEVEL(_drv_always_,
"fw_iv: 0x%016llx\n", pwrctl->wowlan_fw_iv);
//Update TX iv data.
rtw_set_sec_pn(adapter);
}
static u8 rtw_hal_set_keep_alive_cmd(_adapter *adapter, u8 enable, u8 pkt_type)
{
struct hal_ops *pHalFunc = &adapter->HalFunc;
u8 u1H2CKeepAliveParm[H2C_KEEP_ALIVE_CTRL_LEN]={0};
u8 adopt = 1, check_period = 5;
u8 ret = _FAIL;
DBG_871X("%s(): enable = %d\n", __func__, enable);
SET_H2CCMD_KEEPALIVE_PARM_ENABLE(u1H2CKeepAliveParm, enable);
SET_H2CCMD_KEEPALIVE_PARM_ADOPT(u1H2CKeepAliveParm, adopt);
SET_H2CCMD_KEEPALIVE_PARM_PKT_TYPE(u1H2CKeepAliveParm, pkt_type);
SET_H2CCMD_KEEPALIVE_PARM_CHECK_PERIOD(u1H2CKeepAliveParm, check_period);
ret = rtw_hal_fill_h2c_cmd(adapter,
H2C_KEEP_ALIVE,
H2C_KEEP_ALIVE_CTRL_LEN,
u1H2CKeepAliveParm);
return ret;
}
static u8 rtw_hal_set_disconnect_decision_cmd(_adapter *adapter, u8 enable)
{
struct hal_ops *pHalFunc = &adapter->HalFunc;
u8 u1H2CDisconDecisionParm[H2C_DISCON_DECISION_LEN]={0};
u8 adopt = 1, check_period = 10, trypkt_num = 0;
u8 ret = _FAIL;
DBG_871X("%s(): enable = %d\n", __func__, enable);
SET_H2CCMD_DISCONDECISION_PARM_ENABLE(u1H2CDisconDecisionParm, enable);
SET_H2CCMD_DISCONDECISION_PARM_ADOPT(u1H2CDisconDecisionParm, adopt);
SET_H2CCMD_DISCONDECISION_PARM_CHECK_PERIOD(u1H2CDisconDecisionParm, check_period);
SET_H2CCMD_DISCONDECISION_PARM_TRY_PKT_NUM(u1H2CDisconDecisionParm, trypkt_num);
ret = rtw_hal_fill_h2c_cmd(adapter,
H2C_DISCON_DECISION,
H2C_DISCON_DECISION_LEN,
u1H2CDisconDecisionParm);
return ret;
}
static u8 rtw_hal_set_wowlan_ctrl_cmd(_adapter *adapter, u8 enable, u8 change_unit)
{
struct security_priv *psecpriv = &adapter->securitypriv;
struct pwrctrl_priv *ppwrpriv = adapter_to_pwrctl(adapter);
struct hal_ops *pHalFunc = &adapter->HalFunc;
u8 u1H2CWoWlanCtrlParm[H2C_WOWLAN_LEN]={0};
u8 discont_wake = 1, gpionum = 0, gpio_dur = 0;
u8 hw_unicast = 0, gpio_pulse_cnt = 0, gpio_pulse_en = 0;
u8 sdio_wakeup_enable = 1;
u8 gpio_high_active = 0;
u8 pattern_en = 0;
u8 magic_pkt = 0;
u8 gpio_unit = 0; /*0: 64ns, 1: 8ms*/
u8 ret = _FAIL;
#ifdef CONFIG_GPIO_WAKEUP
gpio_high_active = ppwrpriv->is_high_active;
gpionum = WAKEUP_GPIO_IDX;
sdio_wakeup_enable = 0;
#endif //CONFIG_GPIO_WAKEUP
if (!ppwrpriv->wowlan_pno_enable)
magic_pkt = enable;
if (psecpriv->dot11PrivacyAlgrthm == _WEP40_ || psecpriv->dot11PrivacyAlgrthm == _WEP104_)
hw_unicast = 1;
else
hw_unicast = 0;
if (ppwrpriv->wowlan_pattern) {
if (enable)
pattern_en = 1;
else
pattern_en = 0;
}
DBG_871X("%s(): enable=%d change_unit=%d\n", __func__,
enable, change_unit);
/* time = (gpio_dur/2) * gpio_unit, default:256 ms */
if (enable && change_unit) {
gpio_dur = 0x40;
gpio_unit = 1;
gpio_pulse_en = 1;
}
#ifdef CONFIG_PLATFORM_ARM_RK3188
if (enable) {
gpio_pulse_en = 1;
gpio_pulse_cnt = 0x04;
}
#endif
SET_H2CCMD_WOWLAN_FUNC_ENABLE(u1H2CWoWlanCtrlParm, enable);
SET_H2CCMD_WOWLAN_PATTERN_MATCH_ENABLE(u1H2CWoWlanCtrlParm, pattern_en);
SET_H2CCMD_WOWLAN_MAGIC_PKT_ENABLE(u1H2CWoWlanCtrlParm, magic_pkt);
SET_H2CCMD_WOWLAN_UNICAST_PKT_ENABLE(u1H2CWoWlanCtrlParm, hw_unicast);
SET_H2CCMD_WOWLAN_ALL_PKT_DROP(u1H2CWoWlanCtrlParm, 0);
SET_H2CCMD_WOWLAN_GPIO_ACTIVE(u1H2CWoWlanCtrlParm, gpio_high_active);
#ifndef CONFIG_GTK_OL
SET_H2CCMD_WOWLAN_REKEY_WAKE_UP(u1H2CWoWlanCtrlParm, enable);
#endif
SET_H2CCMD_WOWLAN_DISCONNECT_WAKE_UP(u1H2CWoWlanCtrlParm, discont_wake);
SET_H2CCMD_WOWLAN_GPIONUM(u1H2CWoWlanCtrlParm, gpionum);
SET_H2CCMD_WOWLAN_DATAPIN_WAKE_UP(u1H2CWoWlanCtrlParm, sdio_wakeup_enable);
SET_H2CCMD_WOWLAN_GPIO_DURATION(u1H2CWoWlanCtrlParm, gpio_dur);
SET_H2CCMD_WOWLAN_CHANGE_UNIT(u1H2CWoWlanCtrlParm, gpio_unit);
SET_H2CCMD_WOWLAN_GPIO_PULSE_EN(u1H2CWoWlanCtrlParm, gpio_pulse_en);
SET_H2CCMD_WOWLAN_GPIO_PULSE_COUNT(u1H2CWoWlanCtrlParm, gpio_pulse_cnt);
ret = rtw_hal_fill_h2c_cmd(adapter,
H2C_WOWLAN,
H2C_WOWLAN_LEN,
u1H2CWoWlanCtrlParm);
return ret;
}
static u8 rtw_hal_set_remote_wake_ctrl_cmd(_adapter *adapter, u8 enable)
{
struct hal_ops *pHalFunc = &adapter->HalFunc;
struct security_priv* psecuritypriv=&(adapter->securitypriv);
struct pwrctrl_priv *ppwrpriv = adapter_to_pwrctl(adapter);
u8 u1H2CRemoteWakeCtrlParm[H2C_REMOTE_WAKE_CTRL_LEN]={0};
u8 ret = _FAIL, count = 0;
DBG_871X("%s(): enable=%d\n", __func__, enable);
if (!ppwrpriv->wowlan_pno_enable) {
SET_H2CCMD_REMOTE_WAKECTRL_ENABLE(
u1H2CRemoteWakeCtrlParm, enable);
SET_H2CCMD_REMOTE_WAKE_CTRL_ARP_OFFLOAD_EN(
u1H2CRemoteWakeCtrlParm, 1);
#ifdef CONFIG_GTK_OL
if (psecuritypriv->binstallKCK_KEK == _TRUE &&
psecuritypriv->dot11PrivacyAlgrthm == _AES_) {
SET_H2CCMD_REMOTE_WAKE_CTRL_GTK_OFFLOAD_EN(
u1H2CRemoteWakeCtrlParm, 1);
} else {
DBG_871X("no kck or security is not AES\n");
SET_H2CCMD_REMOTE_WAKE_CTRL_GTK_OFFLOAD_EN(
u1H2CRemoteWakeCtrlParm, 0);
}
#endif //CONFIG_GTK_OL
SET_H2CCMD_REMOTE_WAKE_CTRL_FW_UNICAST_EN(
u1H2CRemoteWakeCtrlParm,
!ppwrpriv->wowlan_pattern);
/*
* filter NetBios name service pkt to avoid being waked-up
* by this kind of unicast pkt this exceptional modification
* is used for match competitor's behavior
*/
SET_H2CCMD_REMOTE_WAKE_CTRL_NBNS_FILTER_EN(
u1H2CRemoteWakeCtrlParm, !ppwrpriv->wowlan_pattern);
if ((psecuritypriv->dot11PrivacyAlgrthm == _AES_) ||
(psecuritypriv->dot11PrivacyAlgrthm == _NO_PRIVACY_)) {
SET_H2CCMD_REMOTE_WAKE_CTRL_ARP_ACTION(
u1H2CRemoteWakeCtrlParm, 0);
} else {
SET_H2CCMD_REMOTE_WAKE_CTRL_ARP_ACTION(
u1H2CRemoteWakeCtrlParm, 1);
}
SET_H2CCMD_REMOTE_WAKE_CTRL_FW_PARSING_UNTIL_WAKEUP(
u1H2CRemoteWakeCtrlParm, 1);
}
#ifdef CONFIG_PNO_SUPPORT
else {
SET_H2CCMD_REMOTE_WAKECTRL_ENABLE(
u1H2CRemoteWakeCtrlParm, enable);
SET_H2CCMD_REMOTE_WAKE_CTRL_NLO_OFFLOAD_EN(
u1H2CRemoteWakeCtrlParm, enable);
}
#endif
#ifdef CONFIG_P2P_WOWLAN
if (_TRUE == ppwrpriv->wowlan_p2p_mode)
{
DBG_871X("P2P OFFLOAD ENABLE\n");
SET_H2CCMD_REMOTE_WAKE_CTRL_P2P_OFFLAD_EN(u1H2CRemoteWakeCtrlParm,1);
}
else
{
DBG_871X("P2P OFFLOAD DISABLE\n");
SET_H2CCMD_REMOTE_WAKE_CTRL_P2P_OFFLAD_EN(u1H2CRemoteWakeCtrlParm,0);
}
#endif //CONFIG_P2P_WOWLAN
ret = rtw_hal_fill_h2c_cmd(adapter,
H2C_REMOTE_WAKE_CTRL,
H2C_REMOTE_WAKE_CTRL_LEN,
u1H2CRemoteWakeCtrlParm);
return ret;
}
static u8 rtw_hal_set_global_info_cmd(_adapter* adapter, u8 group_alg, u8 pairwise_alg)
{
struct hal_ops *pHalFunc = &adapter->HalFunc;
u8 ret = _FAIL;
u8 u1H2CAOACGlobalInfoParm[H2C_AOAC_GLOBAL_INFO_LEN]={0};
DBG_871X("%s(): group_alg=%d pairwise_alg=%d\n",
__func__, group_alg, pairwise_alg);
SET_H2CCMD_AOAC_GLOBAL_INFO_PAIRWISE_ENC_ALG(u1H2CAOACGlobalInfoParm,
pairwise_alg);
SET_H2CCMD_AOAC_GLOBAL_INFO_GROUP_ENC_ALG(u1H2CAOACGlobalInfoParm,
group_alg);
ret = rtw_hal_fill_h2c_cmd(adapter,
H2C_AOAC_GLOBAL_INFO,
H2C_AOAC_GLOBAL_INFO_LEN,
u1H2CAOACGlobalInfoParm);
return ret;
}
#ifdef CONFIG_PNO_SUPPORT
static u8 rtw_hal_set_scan_offload_info_cmd(_adapter* adapter,
PRSVDPAGE_LOC rsvdpageloc, u8 enable)
{
struct pwrctrl_priv *pwrpriv = adapter_to_pwrctl(adapter);
struct hal_ops *pHalFunc = &adapter->HalFunc;
u8 u1H2CScanOffloadInfoParm[H2C_SCAN_OFFLOAD_CTRL_LEN]={0};
u8 res = 0, count = 0, ret = _FAIL;
DBG_871X("%s: loc_probe_packet:%d, loc_scan_info: %d loc_ssid_info:%d\n",
__func__, rsvdpageloc->LocProbePacket,
rsvdpageloc->LocScanInfo, rsvdpageloc->LocSSIDInfo);
SET_H2CCMD_AOAC_NLO_FUN_EN(u1H2CScanOffloadInfoParm, enable);
SET_H2CCMD_AOAC_NLO_IPS_EN(u1H2CScanOffloadInfoParm, enable);
SET_H2CCMD_AOAC_RSVDPAGE_LOC_SCAN_INFO(u1H2CScanOffloadInfoParm,
rsvdpageloc->LocScanInfo);
SET_H2CCMD_AOAC_RSVDPAGE_LOC_PROBE_PACKET(u1H2CScanOffloadInfoParm,
rsvdpageloc->LocProbePacket);
SET_H2CCMD_AOAC_RSVDPAGE_LOC_SSID_INFO(u1H2CScanOffloadInfoParm,
rsvdpageloc->LocSSIDInfo);
ret = rtw_hal_fill_h2c_cmd(adapter,
H2C_D0_SCAN_OFFLOAD_INFO,
H2C_SCAN_OFFLOAD_CTRL_LEN,
u1H2CScanOffloadInfoParm);
return ret;
}
#endif //CONFIG_PNO_SUPPORT
void rtw_hal_set_fw_wow_related_cmd(_adapter* padapter, u8 enable)
{
struct security_priv *psecpriv = &padapter->securitypriv;
struct pwrctrl_priv *ppwrpriv = adapter_to_pwrctl(padapter);
struct mlme_priv *pmlmepriv = &padapter->mlmepriv;
struct sta_info *psta = NULL;
u16 media_status_rpt;
u8 pkt_type = 0;
u8 ret = _SUCCESS;
DBG_871X_LEVEL(_drv_always_, "+%s()+: enable=%d\n", __func__, enable);
_func_enter_;
rtw_hal_set_wowlan_ctrl_cmd(padapter, enable, _FALSE);
if (enable) {
rtw_hal_set_global_info_cmd(padapter,
psecpriv->dot118021XGrpPrivacy,
psecpriv->dot11PrivacyAlgrthm);
if (!(ppwrpriv->wowlan_pno_enable)) {
rtw_hal_set_disconnect_decision_cmd(padapter, enable);
#ifdef CONFIG_ARP_KEEP_ALIVE
if ((psecpriv->dot11PrivacyAlgrthm == _WEP40_) ||
(psecpriv->dot11PrivacyAlgrthm == _WEP104_))
pkt_type = 0;
else
pkt_type = 1;
#else
pkt_type = 0;
#endif //CONFIG_ARP_KEEP_ALIVE
rtw_hal_set_keep_alive_cmd(padapter, enable, pkt_type);
}
rtw_hal_set_remote_wake_ctrl_cmd(padapter, enable);
#ifdef CONFIG_PNO_SUPPORT
rtw_hal_check_pno_enabled(padapter);
#endif //CONFIG_PNO_SUPPORT
} else {
#if 0
{
u32 PageSize = 0;
rtw_hal_get_def_var(padapter, HAL_DEF_TX_PAGE_SIZE, (u8 *)&PageSize);
dump_TX_FIFO(padapter, 4, PageSize);
}
#endif
rtw_hal_set_remote_wake_ctrl_cmd(padapter, enable);
}
_func_exit_;
DBG_871X_LEVEL(_drv_always_, "-%s()-\n", __func__);
}
#endif //CONFIG_WOWLAN
#ifdef CONFIG_AP_WOWLAN
static u8 rtw_hal_set_ap_wowlan_ctrl_cmd(_adapter *adapter, u8 enable)
{
struct security_priv *psecpriv = &adapter->securitypriv;
struct pwrctrl_priv *ppwrpriv = adapter_to_pwrctl(adapter);
struct hal_ops *pHalFunc = &adapter->HalFunc;
u8 u1H2CAPWoWlanCtrlParm[H2C_AP_WOW_GPIO_CTRL_LEN] = {0};
u8 gpionum = 0, gpio_dur = 0;
u8 gpio_pulse = enable;
u8 sdio_wakeup_enable = 1;
u8 gpio_high_active = 0;
u8 ret = _FAIL;
#ifdef CONFIG_GPIO_WAKEUP
gpio_high_active = ppwrpriv->is_high_active;
gpionum = WAKEUP_GPIO_IDX;
sdio_wakeup_enable = 0;
#endif /*CONFIG_GPIO_WAKEUP*/
DBG_871X("%s(): enable=%d\n", __func__, enable);
SET_H2CCMD_AP_WOW_GPIO_CTRL_INDEX(u1H2CAPWoWlanCtrlParm,
gpionum);
SET_H2CCMD_AP_WOW_GPIO_CTRL_PLUS(u1H2CAPWoWlanCtrlParm,
gpio_pulse);
SET_H2CCMD_AP_WOW_GPIO_CTRL_HIGH_ACTIVE(u1H2CAPWoWlanCtrlParm,
gpio_high_active);
SET_H2CCMD_AP_WOW_GPIO_CTRL_EN(u1H2CAPWoWlanCtrlParm,
enable);
SET_H2CCMD_AP_WOW_GPIO_CTRL_DURATION(u1H2CAPWoWlanCtrlParm,
gpio_dur);
ret = rtw_hal_fill_h2c_cmd(adapter,
H2C_AP_WOW_GPIO_CTRL,
H2C_AP_WOW_GPIO_CTRL_LEN,
u1H2CAPWoWlanCtrlParm);
return ret;
}
static u8 rtw_hal_set_ap_offload_ctrl_cmd(_adapter *adapter, u8 enable)
{
struct hal_ops *pHalFunc = &adapter->HalFunc;
u8 u1H2CAPOffloadCtrlParm[H2C_WOWLAN_LEN] = {0};
u8 ret = _FAIL;
DBG_871X("%s(): bFuncEn=%d\n", __func__, enable);
SET_H2CCMD_AP_WOWLAN_EN(u1H2CAPOffloadCtrlParm, enable);
ret = rtw_hal_fill_h2c_cmd(adapter,
H2C_AP_OFFLOAD,
H2C_AP_OFFLOAD_LEN,
u1H2CAPOffloadCtrlParm);
return ret;
}
static u8 rtw_hal_set_ap_ps_cmd(_adapter *adapter, u8 enable)
{
struct hal_ops *pHalFunc = &adapter->HalFunc;
u8 ap_ps_parm[H2C_AP_PS_LEN] = {0};
u8 ret = _FAIL;
DBG_871X("%s(): enable=%d\n" , __func__ , enable);
SET_H2CCMD_AP_WOW_PS_EN(ap_ps_parm, enable);
#ifndef CONFIG_USB_HCI
SET_H2CCMD_AP_WOW_PS_32K_EN(ap_ps_parm, enable);
#endif /*CONFIG_USB_HCI*/
SET_H2CCMD_AP_WOW_PS_RF(ap_ps_parm, enable);
if (enable)
SET_H2CCMD_AP_WOW_PS_DURATION(ap_ps_parm, 0x32);
else
SET_H2CCMD_AP_WOW_PS_DURATION(ap_ps_parm, 0x0);
ret = rtw_hal_fill_h2c_cmd(adapter, H2C_SAP_PS_,
H2C_AP_PS_LEN, ap_ps_parm);
return ret;
}
static void rtw_hal_set_ap_rsvdpage_loc_cmd(PADAPTER padapter,
PRSVDPAGE_LOC rsvdpageloc)
{
struct hal_ops *pHalFunc = &padapter->HalFunc;
u8 rsvdparm[H2C_AOAC_RSVDPAGE_LOC_LEN] = {0};
u8 ret = _FAIL, header = 0;
if (pHalFunc->fill_h2c_cmd == NULL) {
DBG_871X("%s: Please hook fill_h2c_cmd first!\n", __func__);
return;
}
header = rtw_read8(padapter, REG_BCNQ_BDNY);
DBG_871X("%s: beacon: %d, probeRsp: %d, header:0x%02x\n", __func__,
rsvdpageloc->LocApOffloadBCN,
rsvdpageloc->LocProbeRsp,
header);
SET_H2CCMD_AP_WOWLAN_RSVDPAGE_LOC_BCN(rsvdparm,
rsvdpageloc->LocApOffloadBCN + header);
ret = rtw_hal_fill_h2c_cmd(padapter, H2C_BCN_RSVDPAGE,
H2C_BCN_RSVDPAGE_LEN, rsvdparm);
if (ret == _FAIL)
DBG_871X("%s: H2C_BCN_RSVDPAGE cmd fail\n", __func__);
rtw_msleep_os(10);
_rtw_memset(&rsvdparm, 0, sizeof(rsvdparm));
SET_H2CCMD_AP_WOWLAN_RSVDPAGE_LOC_ProbeRsp(rsvdparm,
rsvdpageloc->LocProbeRsp + header);
ret = rtw_hal_fill_h2c_cmd(padapter, H2C_PROBERSP_RSVDPAGE,
H2C_PROBERSP_RSVDPAGE_LEN, rsvdparm);
if (ret == _FAIL)
DBG_871X("%s: H2C_PROBERSP_RSVDPAGE cmd fail\n", __func__);
rtw_msleep_os(10);
}
static void rtw_hal_set_fw_ap_wow_related_cmd(_adapter *padapter, u8 enable)
{
rtw_hal_set_ap_offload_ctrl_cmd(padapter, enable);
rtw_hal_set_ap_wowlan_ctrl_cmd(padapter, enable);
rtw_hal_set_ap_ps_cmd(padapter, enable);
}
static void rtw_hal_ap_wow_enable(_adapter *padapter)
{
struct pwrctrl_priv *pwrctl = adapter_to_pwrctl(padapter);
struct security_priv *psecuritypriv = &padapter->securitypriv;
struct mlme_priv *pmlmepriv = &padapter->mlmepriv;
struct hal_ops *pHalFunc = &padapter->HalFunc;
struct sta_info *psta = NULL;
#ifdef DBG_CHECK_FW_PS_STATE
struct dvobj_priv *psdpriv = padapter->dvobj;
struct debug_priv *pdbgpriv = &psdpriv->drv_dbg;
#endif /*DBG_CHECK_FW_PS_STATE*/
int res;
u16 media_status_rpt;
DBG_871X("%s, WOWLAN_AP_ENABLE\n", __func__);
#ifdef DBG_CHECK_FW_PS_STATE
if (rtw_fw_ps_state(padapter) == _FAIL) {
pdbgpriv->dbg_enwow_dload_fw_fail_cnt++;
DBG_871X_LEVEL(_drv_always_, "wowlan enable no leave 32k\n");
}
#endif /*DBG_CHECK_FW_PS_STATE*/
/* 1. Download WOWLAN FW*/
if (pHalFunc->hal_set_wowlan_fw != NULL)
pHalFunc->hal_set_wowlan_fw(padapter, _TRUE);
else
DBG_871X("hal_set_wowlan_fw is null\n");
media_status_rpt = RT_MEDIA_CONNECT;
rtw_hal_set_hwreg(padapter, HW_VAR_H2C_FW_JOINBSSRPT,
(u8 *)&media_status_rpt);
issue_beacon(padapter, 0);
rtw_msleep_os(2);
if (IS_HARDWARE_TYPE_8188E(padapter))
rtw_hal_disable_tx_report(padapter);
/* RX DMA stop */
res = rtw_hal_pause_rx_dma(padapter);
if (res == _FAIL)
DBG_871X_LEVEL(_drv_always_, "[WARNING] pause RX DMA fail\n");
#if defined(CONFIG_SDIO_HCI) || defined(CONFIG_GSPI_HCI)
/* Enable CPWM2 only. */
res = rtw_hal_enable_cpwm2(padapter);
if (res == _FAIL)
DBG_871X_LEVEL(_drv_always_, "[WARNING] enable cpwm2 fail\n");
#endif
#ifdef CONFIG_GPIO_WAKEUP
rtw_hal_switch_gpio_wl_ctrl(padapter, WAKEUP_GPIO_IDX, _TRUE);
#endif
/* 5. Set Enable WOWLAN H2C command. */
DBG_871X_LEVEL(_drv_always_, "Set Enable AP WOWLan cmd\n");
rtw_hal_set_fw_ap_wow_related_cmd(padapter, 1);
rtw_write8(padapter, REG_MCUTST_WOWLAN, 0);
#ifdef CONFIG_USB_HCI
if (padapter->intf_stop)
padapter->intf_stop(padapter);
#ifdef CONFIG_CONCURRENT_MODE
if (rtw_buddy_adapter_up(padapter))/*free buddy adapter's resource*/
padapter->pbuddy_adapter->intf_stop(padapter->pbuddy_adapter);
#endif /*CONFIG_CONCURRENT_MODE*/
/* Invoid SE0 reset signal during suspending*/
rtw_write8(padapter, REG_RSV_CTRL, 0x20);
rtw_write8(padapter, REG_RSV_CTRL, 0x60);
#endif /*CONFIG_USB_HCI*/
}
static void rtw_hal_ap_wow_disable(_adapter *padapter)
{
struct pwrctrl_priv *pwrctl = adapter_to_pwrctl(padapter);
struct hal_ops *pHalFunc = &padapter->HalFunc;
#ifdef DBG_CHECK_FW_PS_STATE
struct dvobj_priv *psdpriv = padapter->dvobj;
struct debug_priv *pdbgpriv = &psdpriv->drv_dbg;
#endif /*DBG_CHECK_FW_PS_STATE*/
u16 media_status_rpt;
u8 val8;
DBG_871X("%s, WOWLAN_AP_DISABLE\n", __func__);
/* 1. Read wakeup reason*/
pwrctl->wowlan_wake_reason = rtw_read8(padapter, REG_MCUTST_WOWLAN);
DBG_871X_LEVEL(_drv_always_, "wakeup_reason: 0x%02x\n",
pwrctl->wowlan_wake_reason);
rtw_hal_set_fw_ap_wow_related_cmd(padapter, 0);
rtw_msleep_os(2);
#ifdef DBG_CHECK_FW_PS_STATE
if (rtw_fw_ps_state(padapter) == _FAIL) {
pdbgpriv->dbg_diswow_dload_fw_fail_cnt++;
DBG_871X_LEVEL(_drv_always_, "wowlan enable no leave 32k\n");
}
#endif /*DBG_CHECK_FW_PS_STATE*/
if (IS_HARDWARE_TYPE_8188E(padapter))
rtw_hal_enable_tx_report(padapter);
rtw_hal_force_enable_rxdma(padapter);
if (pHalFunc->hal_set_wowlan_fw != NULL)
pHalFunc->hal_set_wowlan_fw(padapter, _FALSE);
else
DBG_871X("hal_set_wowlan_fw is null\n");
#ifdef CONFIG_GPIO_WAKEUP
val8 = (pwrctl->is_high_active == 0) ? 1 : 0;
DBG_871X_LEVEL(_drv_always_, "Set Wake GPIO to default(%d).\n", val8);
rtw_hal_set_output_gpio(padapter, WAKEUP_GPIO_IDX, val8);
rtw_hal_switch_gpio_wl_ctrl(padapter, WAKEUP_GPIO_IDX, _FALSE);
#endif
media_status_rpt = RT_MEDIA_CONNECT;
rtw_hal_set_hwreg(padapter, HW_VAR_H2C_FW_JOINBSSRPT,
(u8 *)&media_status_rpt);
issue_beacon(padapter, 0);
}
#endif /*CONFIG_AP_WOWLAN*/
#ifdef CONFIG_P2P_WOWLAN
static int update_hidden_ssid(u8 *ies, u32 ies_len, u8 hidden_ssid_mode)
{
u8 *ssid_ie;
sint ssid_len_ori;
int len_diff = 0;
ssid_ie = rtw_get_ie(ies, WLAN_EID_SSID, &ssid_len_ori, ies_len);
//DBG_871X("%s hidden_ssid_mode:%u, ssid_ie:%p, ssid_len_ori:%d\n", __FUNCTION__, hidden_ssid_mode, ssid_ie, ssid_len_ori);
if(ssid_ie && ssid_len_ori>0)
{
switch(hidden_ssid_mode)
{
case 1:
{
u8 *next_ie = ssid_ie + 2 + ssid_len_ori;
u32 remain_len = 0;
remain_len = ies_len -(next_ie-ies);
ssid_ie[1] = 0;
_rtw_memcpy(ssid_ie+2, next_ie, remain_len);
len_diff -= ssid_len_ori;
break;
}
case 2:
_rtw_memset(&ssid_ie[2], 0, ssid_len_ori);
break;
default:
break;
}
}
return len_diff;
}
static void rtw_hal_construct_P2PBeacon(_adapter *padapter, u8 *pframe, u32 *pLength)
{
//struct xmit_frame *pmgntframe;
//struct pkt_attrib *pattrib;
//unsigned char *pframe;
struct rtw_ieee80211_hdr *pwlanhdr;
unsigned short *fctrl;
unsigned int rate_len;
struct xmit_priv *pxmitpriv = &(padapter->xmitpriv);
u32 pktlen;
//#if defined (CONFIG_AP_MODE) && defined (CONFIG_NATIVEAP_MLME)
// _irqL irqL;
// struct mlme_priv *pmlmepriv = &(padapter->mlmepriv);
//#endif //#if defined (CONFIG_AP_MODE) && defined (CONFIG_NATIVEAP_MLME)
struct mlme_priv *pmlmepriv = &(padapter->mlmepriv);
struct mlme_ext_priv *pmlmeext = &(padapter->mlmeextpriv);
struct mlme_ext_info *pmlmeinfo = &(pmlmeext->mlmext_info);
WLAN_BSSID_EX *cur_network = &(pmlmeinfo->network);
u8 bc_addr[] = {0xff, 0xff, 0xff, 0xff, 0xff, 0xff};
#ifdef CONFIG_P2P
struct wifidirect_info *pwdinfo = &(padapter->wdinfo);
#endif //CONFIG_P2P
//for debug
u8 *dbgbuf = pframe;
u8 dbgbufLen = 0, index = 0;
DBG_871X("%s\n", __FUNCTION__);
//#if defined (CONFIG_AP_MODE) && defined (CONFIG_NATIVEAP_MLME)
// _enter_critical_bh(&pmlmepriv->bcn_update_lock, &irqL);
//#endif //#if defined (CONFIG_AP_MODE) && defined (CONFIG_NATIVEAP_MLME)
pwlanhdr = (struct rtw_ieee80211_hdr *)pframe;
fctrl = &(pwlanhdr->frame_ctl);
*(fctrl) = 0;
_rtw_memcpy(pwlanhdr->addr1, bc_addr, ETH_ALEN);
_rtw_memcpy(pwlanhdr->addr2, adapter_mac_addr(padapter), ETH_ALEN);
_rtw_memcpy(pwlanhdr->addr3, get_my_bssid(cur_network), ETH_ALEN);
SetSeqNum(pwlanhdr, 0/*pmlmeext->mgnt_seq*/);
//pmlmeext->mgnt_seq++;
SetFrameSubType(pframe, WIFI_BEACON);
pframe += sizeof(struct rtw_ieee80211_hdr_3addr);
pktlen = sizeof (struct rtw_ieee80211_hdr_3addr);
if( (pmlmeinfo->state&0x03) == WIFI_FW_AP_STATE)
{
//DBG_871X("ie len=%d\n", cur_network->IELength);
#ifdef CONFIG_P2P
// for P2P : Primary Device Type & Device Name
u32 wpsielen=0, insert_len=0;
u8 *wpsie=NULL;
wpsie = rtw_get_wps_ie(cur_network->IEs+_FIXED_IE_LENGTH_, cur_network->IELength-_FIXED_IE_LENGTH_, NULL, &wpsielen);
if(rtw_p2p_chk_role(pwdinfo, P2P_ROLE_GO) && wpsie && wpsielen>0)
{
uint wps_offset, remainder_ielen;
u8 *premainder_ie, *pframe_wscie;
wps_offset = (uint)(wpsie - cur_network->IEs);
premainder_ie = wpsie + wpsielen;
remainder_ielen = cur_network->IELength - wps_offset - wpsielen;
#ifdef CONFIG_IOCTL_CFG80211
if(pwdinfo->driver_interface == DRIVER_CFG80211 )
{
if(pmlmepriv->wps_beacon_ie && pmlmepriv->wps_beacon_ie_len>0)
{
_rtw_memcpy(pframe, cur_network->IEs, wps_offset);
pframe += wps_offset;
pktlen += wps_offset;
_rtw_memcpy(pframe, pmlmepriv->wps_beacon_ie, pmlmepriv->wps_beacon_ie_len);
pframe += pmlmepriv->wps_beacon_ie_len;
pktlen += pmlmepriv->wps_beacon_ie_len;
//copy remainder_ie to pframe
_rtw_memcpy(pframe, premainder_ie, remainder_ielen);
pframe += remainder_ielen;
pktlen += remainder_ielen;
}
else
{
_rtw_memcpy(pframe, cur_network->IEs, cur_network->IELength);
pframe += cur_network->IELength;
pktlen += cur_network->IELength;
}
}
else
#endif //CONFIG_IOCTL_CFG80211
{
pframe_wscie = pframe + wps_offset;
_rtw_memcpy(pframe, cur_network->IEs, wps_offset+wpsielen);
pframe += (wps_offset + wpsielen);
pktlen += (wps_offset + wpsielen);
//now pframe is end of wsc ie, insert Primary Device Type & Device Name
// Primary Device Type
// Type:
*(u16*) ( pframe + insert_len) = cpu_to_be16( WPS_ATTR_PRIMARY_DEV_TYPE );
insert_len += 2;
// Length:
*(u16*) ( pframe + insert_len ) = cpu_to_be16( 0x0008 );
insert_len += 2;
// Value:
// Category ID
*(u16*) ( pframe + insert_len ) = cpu_to_be16( WPS_PDT_CID_MULIT_MEDIA );
insert_len += 2;
// OUI
*(u32*) ( pframe + insert_len ) = cpu_to_be32( WPSOUI );
insert_len += 4;
// Sub Category ID
*(u16*) ( pframe + insert_len ) = cpu_to_be16( WPS_PDT_SCID_MEDIA_SERVER );
insert_len += 2;
// Device Name
// Type:
*(u16*) ( pframe + insert_len ) = cpu_to_be16( WPS_ATTR_DEVICE_NAME );
insert_len += 2;
// Length:
*(u16*) ( pframe + insert_len ) = cpu_to_be16( pwdinfo->device_name_len );
insert_len += 2;
// Value:
_rtw_memcpy( pframe + insert_len, pwdinfo->device_name, pwdinfo->device_name_len );
insert_len += pwdinfo->device_name_len;
//update wsc ie length
*(pframe_wscie+1) = (wpsielen -2) + insert_len;
//pframe move to end
pframe+=insert_len;
pktlen += insert_len;
//copy remainder_ie to pframe
_rtw_memcpy(pframe, premainder_ie, remainder_ielen);
pframe += remainder_ielen;
pktlen += remainder_ielen;
}
}
else
#endif //CONFIG_P2P
{
int len_diff;
_rtw_memcpy(pframe, cur_network->IEs, cur_network->IELength);
len_diff = update_hidden_ssid(
pframe+_BEACON_IE_OFFSET_
, cur_network->IELength-_BEACON_IE_OFFSET_
, pmlmeinfo->hidden_ssid_mode
);
pframe += (cur_network->IELength+len_diff);
pktlen += (cur_network->IELength+len_diff);
}
#if 0
{
u8 *wps_ie;
uint wps_ielen;
u8 sr = 0;
wps_ie = rtw_get_wps_ie(pmgntframe->buf_addr+TXDESC_OFFSET+sizeof (struct rtw_ieee80211_hdr_3addr)+_BEACON_IE_OFFSET_,
pattrib->pktlen-sizeof (struct rtw_ieee80211_hdr_3addr)-_BEACON_IE_OFFSET_, NULL, &wps_ielen);
if (wps_ie && wps_ielen>0) {
rtw_get_wps_attr_content(wps_ie, wps_ielen, WPS_ATTR_SELECTED_REGISTRAR, (u8*)(&sr), NULL);
}
if (sr != 0)
set_fwstate(pmlmepriv, WIFI_UNDER_WPS);
else
_clr_fwstate_(pmlmepriv, WIFI_UNDER_WPS);
}
#endif
#ifdef CONFIG_P2P
if(rtw_p2p_chk_role(pwdinfo, P2P_ROLE_GO))
{
u32 len;
#ifdef CONFIG_IOCTL_CFG80211
if(pwdinfo->driver_interface == DRIVER_CFG80211 )
{
len = pmlmepriv->p2p_beacon_ie_len;
if(pmlmepriv->p2p_beacon_ie && len>0)
_rtw_memcpy(pframe, pmlmepriv->p2p_beacon_ie, len);
}
else
#endif //CONFIG_IOCTL_CFG80211
{
len = build_beacon_p2p_ie(pwdinfo, pframe);
}
pframe += len;
pktlen += len;
#ifdef CONFIG_WFD
#ifdef CONFIG_IOCTL_CFG80211
if(_TRUE == pwdinfo->wfd_info->wfd_enable)
#endif //CONFIG_IOCTL_CFG80211
{
len = build_beacon_wfd_ie( pwdinfo, pframe );
}
#ifdef CONFIG_IOCTL_CFG80211
else
{
len = 0;
if(pmlmepriv->wfd_beacon_ie && pmlmepriv->wfd_beacon_ie_len>0)
{
len = pmlmepriv->wfd_beacon_ie_len;
_rtw_memcpy(pframe, pmlmepriv->wfd_beacon_ie, len);
}
}
#endif //CONFIG_IOCTL_CFG80211
pframe += len;
pktlen += len;
#endif //CONFIG_WFD
}
#endif //CONFIG_P2P
goto _issue_bcn;
}
//below for ad-hoc mode
//timestamp will be inserted by hardware
pframe += 8;
pktlen += 8;
// beacon interval: 2 bytes
_rtw_memcpy(pframe, (unsigned char *)(rtw_get_beacon_interval_from_ie(cur_network->IEs)), 2);
pframe += 2;
pktlen += 2;
// capability info: 2 bytes
_rtw_memcpy(pframe, (unsigned char *)(rtw_get_capability_from_ie(cur_network->IEs)), 2);
pframe += 2;
pktlen += 2;
// SSID
pframe = rtw_set_ie(pframe, _SSID_IE_, cur_network->Ssid.SsidLength, cur_network->Ssid.Ssid, &pktlen);
// supported rates...
rate_len = rtw_get_rateset_len(cur_network->SupportedRates);
pframe = rtw_set_ie(pframe, _SUPPORTEDRATES_IE_, ((rate_len > 8)? 8: rate_len), cur_network->SupportedRates, &pktlen);
// DS parameter set
pframe = rtw_set_ie(pframe, _DSSET_IE_, 1, (unsigned char *)&(cur_network->Configuration.DSConfig), &pktlen);
//if( (pmlmeinfo->state&0x03) == WIFI_FW_ADHOC_STATE)
{
u8 erpinfo=0;
u32 ATIMWindow;
// IBSS Parameter Set...
//ATIMWindow = cur->Configuration.ATIMWindow;
ATIMWindow = 0;
pframe = rtw_set_ie(pframe, _IBSS_PARA_IE_, 2, (unsigned char *)(&ATIMWindow), &pktlen);
//ERP IE
pframe = rtw_set_ie(pframe, _ERPINFO_IE_, 1, &erpinfo, &pktlen);
}
// EXTERNDED SUPPORTED RATE
if (rate_len > 8)
{
pframe = rtw_set_ie(pframe, _EXT_SUPPORTEDRATES_IE_, (rate_len - 8), (cur_network->SupportedRates + 8), &pktlen);
}
//todo:HT for adhoc
_issue_bcn:
//#if defined (CONFIG_AP_MODE) && defined (CONFIG_NATIVEAP_MLME)
// pmlmepriv->update_bcn = _FALSE;
//
// _exit_critical_bh(&pmlmepriv->bcn_update_lock, &irqL);
//#endif //#if defined (CONFIG_AP_MODE) && defined (CONFIG_NATIVEAP_MLME)
*pLength = pktlen;
#if 0
// printf dbg msg
dbgbufLen = pktlen;
DBG_871X("======> DBG MSG FOR CONSTRAUCT P2P BEACON\n");
for(index=0;index<dbgbufLen;index++)
printk("%x ",*(dbgbuf+index));
printk("\n");
DBG_871X("<====== DBG MSG FOR CONSTRAUCT P2P BEACON\n");
#endif
}
static int get_reg_classes_full_count(struct p2p_channels channel_list) {
int cnt = 0;
int i;
for (i = 0; i < channel_list.reg_classes; i++) {
cnt += channel_list.reg_class[i].channels;
}
return cnt;
}
static void rtw_hal_construct_P2PProbeRsp(_adapter *padapter, u8 *pframe, u32 *pLength)
{
//struct xmit_frame *pmgntframe;
//struct pkt_attrib *pattrib;
//unsigned char *pframe;
struct rtw_ieee80211_hdr *pwlanhdr;
unsigned short *fctrl;
unsigned char *mac;
struct xmit_priv *pxmitpriv = &(padapter->xmitpriv);
struct mlme_ext_priv *pmlmeext = &(padapter->mlmeextpriv);
struct mlme_ext_info *pmlmeinfo = &(pmlmeext->mlmext_info);
struct mlme_priv *pmlmepriv = &(padapter->mlmepriv);
//WLAN_BSSID_EX *cur_network = &(pmlmeinfo->network);
u16 beacon_interval = 100;
u16 capInfo = 0;
struct wifidirect_info *pwdinfo = &(padapter->wdinfo);
u8 wpsie[255] = { 0x00 };
u32 wpsielen = 0, p2pielen = 0;
u32 pktlen;
#ifdef CONFIG_WFD
u32 wfdielen = 0;
#endif //CONFIG_WFD
#ifdef CONFIG_INTEL_WIDI
u8 zero_array_check[L2SDTA_SERVICE_VE_LEN] = { 0x00 };
#endif //CONFIG_INTEL_WIDI
//for debug
u8 *dbgbuf = pframe;
u8 dbgbufLen = 0, index = 0;
DBG_871X("%s\n", __FUNCTION__);
pwlanhdr = (struct rtw_ieee80211_hdr *)pframe;
mac = adapter_mac_addr(padapter);
fctrl = &(pwlanhdr->frame_ctl);
*(fctrl) = 0;
//DA filled by FW
_rtw_memset(pwlanhdr->addr1, 0, ETH_ALEN);
_rtw_memcpy(pwlanhdr->addr2, mac, ETH_ALEN);
// Use the device address for BSSID field.
_rtw_memcpy(pwlanhdr->addr3, mac, ETH_ALEN);
SetSeqNum(pwlanhdr, 0);
SetFrameSubType(fctrl, WIFI_PROBERSP);
pktlen = sizeof(struct rtw_ieee80211_hdr_3addr);
pframe += pktlen;
//timestamp will be inserted by hardware
pframe += 8;
pktlen += 8;
// beacon interval: 2 bytes
_rtw_memcpy(pframe, (unsigned char *) &beacon_interval, 2);
pframe += 2;
pktlen += 2;
// capability info: 2 bytes
// ESS and IBSS bits must be 0 (defined in the 3.1.2.1.1 of WiFi Direct Spec)
capInfo |= cap_ShortPremble;
capInfo |= cap_ShortSlot;
_rtw_memcpy(pframe, (unsigned char *) &capInfo, 2);
pframe += 2;
pktlen += 2;
// SSID
pframe = rtw_set_ie(pframe, _SSID_IE_, 7, pwdinfo->p2p_wildcard_ssid, &pktlen);
// supported rates...
// Use the OFDM rate in the P2P probe response frame. ( 6(B), 9(B), 12, 18, 24, 36, 48, 54 )
pframe = rtw_set_ie(pframe, _SUPPORTEDRATES_IE_, 8, pwdinfo->support_rate, &pktlen);
// DS parameter set
pframe = rtw_set_ie(pframe, _DSSET_IE_, 1, (unsigned char *)&pwdinfo->listen_channel, &pktlen);
#ifdef CONFIG_IOCTL_CFG80211
if(pwdinfo->driver_interface == DRIVER_CFG80211 )
{
if( pmlmepriv->wps_probe_resp_ie != NULL && pmlmepriv->p2p_probe_resp_ie != NULL )
{
//WPS IE
_rtw_memcpy(pframe, pmlmepriv->wps_probe_resp_ie, pmlmepriv->wps_probe_resp_ie_len);
pktlen += pmlmepriv->wps_probe_resp_ie_len;
pframe += pmlmepriv->wps_probe_resp_ie_len;
//P2P IE
_rtw_memcpy(pframe, pmlmepriv->p2p_probe_resp_ie, pmlmepriv->p2p_probe_resp_ie_len);
pktlen += pmlmepriv->p2p_probe_resp_ie_len;
pframe += pmlmepriv->p2p_probe_resp_ie_len;
}
}
else
#endif //CONFIG_IOCTL_CFG80211
{
// Todo: WPS IE
// Noted by Albert 20100907
// According to the WPS specification, all the WPS attribute is presented by Big Endian.
wpsielen = 0;
// WPS OUI
*(u32*) ( wpsie ) = cpu_to_be32( WPSOUI );
wpsielen += 4;
// WPS version
// Type:
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( WPS_ATTR_VER1 );
wpsielen += 2;
// Length:
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( 0x0001 );
wpsielen += 2;
// Value:
wpsie[wpsielen++] = WPS_VERSION_1; // Version 1.0
#ifdef CONFIG_INTEL_WIDI
// Commented by Kurt
// Appended WiDi info. only if we did issued_probereq_widi(), and then we saved ven. ext. in pmlmepriv->sa_ext.
if( _rtw_memcmp(pmlmepriv->sa_ext, zero_array_check, L2SDTA_SERVICE_VE_LEN) == _FALSE
|| pmlmepriv->num_p2p_sdt != 0 )
{
//Sec dev type
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( WPS_ATTR_SEC_DEV_TYPE_LIST );
wpsielen += 2;
// Length:
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( 0x0008 );
wpsielen += 2;
// Value:
// Category ID
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( WPS_PDT_CID_DISPLAYS );
wpsielen += 2;
// OUI
*(u32*) ( wpsie + wpsielen ) = cpu_to_be32( INTEL_DEV_TYPE_OUI );
wpsielen += 4;
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( WPS_PDT_SCID_WIDI_CONSUMER_SINK );
wpsielen += 2;
if( _rtw_memcmp(pmlmepriv->sa_ext, zero_array_check, L2SDTA_SERVICE_VE_LEN) == _FALSE )
{
// Vendor Extension
_rtw_memcpy( wpsie + wpsielen, pmlmepriv->sa_ext, L2SDTA_SERVICE_VE_LEN );
wpsielen += L2SDTA_SERVICE_VE_LEN;
}
}
#endif //CONFIG_INTEL_WIDI
// WiFi Simple Config State
// Type:
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( WPS_ATTR_SIMPLE_CONF_STATE );
wpsielen += 2;
// Length:
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( 0x0001 );
wpsielen += 2;
// Value:
wpsie[wpsielen++] = WPS_WSC_STATE_NOT_CONFIG; // Not Configured.
// Response Type
// Type:
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( WPS_ATTR_RESP_TYPE );
wpsielen += 2;
// Length:
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( 0x0001 );
wpsielen += 2;
// Value:
wpsie[wpsielen++] = WPS_RESPONSE_TYPE_8021X;
// UUID-E
// Type:
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( WPS_ATTR_UUID_E );
wpsielen += 2;
// Length:
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( 0x0010 );
wpsielen += 2;
// Value:
if (pwdinfo->external_uuid == 0) {
_rtw_memset( wpsie + wpsielen, 0x0, 16 );
_rtw_memcpy(wpsie + wpsielen, mac, ETH_ALEN);
} else {
_rtw_memcpy( wpsie + wpsielen, pwdinfo->uuid, 0x10 );
}
wpsielen += 0x10;
// Manufacturer
// Type:
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( WPS_ATTR_MANUFACTURER );
wpsielen += 2;
// Length:
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( 0x0007 );
wpsielen += 2;
// Value:
_rtw_memcpy( wpsie + wpsielen, "Realtek", 7 );
wpsielen += 7;
// Model Name
// Type:
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( WPS_ATTR_MODEL_NAME );
wpsielen += 2;
// Length:
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( 0x0006 );
wpsielen += 2;
// Value:
_rtw_memcpy( wpsie + wpsielen, "8192CU", 6 );
wpsielen += 6;
// Model Number
// Type:
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( WPS_ATTR_MODEL_NUMBER );
wpsielen += 2;
// Length:
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( 0x0001 );
wpsielen += 2;
// Value:
wpsie[ wpsielen++ ] = 0x31; // character 1
// Serial Number
// Type:
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( WPS_ATTR_SERIAL_NUMBER );
wpsielen += 2;
// Length:
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( ETH_ALEN );
wpsielen += 2;
// Value:
_rtw_memcpy( wpsie + wpsielen, "123456" , ETH_ALEN );
wpsielen += ETH_ALEN;
// Primary Device Type
// Type:
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( WPS_ATTR_PRIMARY_DEV_TYPE );
wpsielen += 2;
// Length:
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( 0x0008 );
wpsielen += 2;
// Value:
// Category ID
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( WPS_PDT_CID_MULIT_MEDIA );
wpsielen += 2;
// OUI
*(u32*) ( wpsie + wpsielen ) = cpu_to_be32( WPSOUI );
wpsielen += 4;
// Sub Category ID
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( WPS_PDT_SCID_MEDIA_SERVER );
wpsielen += 2;
// Device Name
// Type:
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( WPS_ATTR_DEVICE_NAME );
wpsielen += 2;
// Length:
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( pwdinfo->device_name_len );
wpsielen += 2;
// Value:
_rtw_memcpy( wpsie + wpsielen, pwdinfo->device_name, pwdinfo->device_name_len );
wpsielen += pwdinfo->device_name_len;
// Config Method
// Type:
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( WPS_ATTR_CONF_METHOD );
wpsielen += 2;
// Length:
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( 0x0002 );
wpsielen += 2;
// Value:
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( pwdinfo->supported_wps_cm );
wpsielen += 2;
pframe = rtw_set_ie(pframe, _VENDOR_SPECIFIC_IE_, wpsielen, (unsigned char *) wpsie, &pktlen );
p2pielen = build_probe_resp_p2p_ie(pwdinfo, pframe);
pframe += p2pielen;
pktlen += p2pielen;
}
#ifdef CONFIG_WFD
#ifdef CONFIG_IOCTL_CFG80211
if ( _TRUE == pwdinfo->wfd_info->wfd_enable )
#endif //CONFIG_IOCTL_CFG80211
{
wfdielen = build_probe_resp_wfd_ie(pwdinfo, pframe, 0);
pframe += wfdielen;
pktlen += wfdielen;
}
#ifdef CONFIG_IOCTL_CFG80211
else if (pmlmepriv->wfd_probe_resp_ie != NULL && pmlmepriv->wfd_probe_resp_ie_len>0)
{
//WFD IE
_rtw_memcpy(pframe, pmlmepriv->wfd_probe_resp_ie, pmlmepriv->wfd_probe_resp_ie_len);
pktlen += pmlmepriv->wfd_probe_resp_ie_len;
pframe += pmlmepriv->wfd_probe_resp_ie_len;
}
#endif //CONFIG_IOCTL_CFG80211
#endif //CONFIG_WFD
*pLength = pktlen;
#if 0
// printf dbg msg
dbgbufLen = pktlen;
DBG_871X("======> DBG MSG FOR CONSTRAUCT P2P Probe Rsp\n");
for(index=0;index<dbgbufLen;index++)
printk("%x ",*(dbgbuf+index));
printk("\n");
DBG_871X("<====== DBG MSG FOR CONSTRAUCT P2P Probe Rsp\n");
#endif
}
static void rtw_hal_construct_P2PNegoRsp(_adapter *padapter, u8 *pframe, u32 *pLength)
{
unsigned char category = RTW_WLAN_CATEGORY_PUBLIC;
u8 action = P2P_PUB_ACTION_ACTION;
u32 p2poui = cpu_to_be32(P2POUI);
u8 oui_subtype = P2P_GO_NEGO_RESP;
u8 wpsie[ 255 ] = { 0x00 }, p2pie[ 255 ] = { 0x00 };
u8 p2pielen = 0, i;
uint wpsielen = 0;
u16 wps_devicepassword_id = 0x0000;
uint wps_devicepassword_id_len = 0;
u8 channel_cnt_24g = 0, channel_cnt_5gl = 0, channel_cnt_5gh;
u16 len_channellist_attr = 0;
u32 pktlen;
u8 dialogToken = 0;
//struct xmit_frame *pmgntframe;
//struct pkt_attrib *pattrib;
//unsigned char *pframe;
struct rtw_ieee80211_hdr *pwlanhdr;
unsigned short *fctrl;
struct xmit_priv *pxmitpriv = &(padapter->xmitpriv);
struct mlme_ext_priv *pmlmeext = &(padapter->mlmeextpriv);
struct mlme_ext_info *pmlmeinfo = &(pmlmeext->mlmext_info);
struct wifidirect_info *pwdinfo = &( padapter->wdinfo);
//WLAN_BSSID_EX *cur_network = &(pmlmeinfo->network);
#ifdef CONFIG_WFD
u32 wfdielen = 0;
#endif //CONFIG_WFD
//for debug
u8 *dbgbuf = pframe;
u8 dbgbufLen = 0, index = 0;
DBG_871X( "%s\n", __FUNCTION__);
pwlanhdr = (struct rtw_ieee80211_hdr *)pframe;
fctrl = &(pwlanhdr->frame_ctl);
*(fctrl) = 0;
//RA, filled by FW
_rtw_memset(pwlanhdr->addr1, 0, ETH_ALEN);
_rtw_memcpy(pwlanhdr->addr2, adapter_mac_addr(padapter), ETH_ALEN);
_rtw_memcpy(pwlanhdr->addr3, adapter_mac_addr(padapter), ETH_ALEN);
SetSeqNum(pwlanhdr, 0);
SetFrameSubType(pframe, WIFI_ACTION);
pktlen = sizeof(struct rtw_ieee80211_hdr_3addr);
pframe += pktlen;
pframe = rtw_set_fixed_ie(pframe, 1, &(category), &(pktlen));
pframe = rtw_set_fixed_ie(pframe, 1, &(action), &(pktlen));
pframe = rtw_set_fixed_ie(pframe, 4, (unsigned char *) &(p2poui), &(pktlen));
pframe = rtw_set_fixed_ie(pframe, 1, &(oui_subtype), &(pktlen));
//dialog token, filled by FW
pframe = rtw_set_fixed_ie(pframe, 1, &(dialogToken), &(pktlen));
_rtw_memset( wpsie, 0x00, 255 );
wpsielen = 0;
// WPS Section
wpsielen = 0;
// WPS OUI
*(u32*) ( wpsie ) = cpu_to_be32( WPSOUI );
wpsielen += 4;
// WPS version
// Type:
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( WPS_ATTR_VER1 );
wpsielen += 2;
// Length:
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( 0x0001 );
wpsielen += 2;
// Value:
wpsie[wpsielen++] = WPS_VERSION_1; // Version 1.0
// Device Password ID
// Type:
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( WPS_ATTR_DEVICE_PWID );
wpsielen += 2;
// Length:
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( 0x0002 );
wpsielen += 2;
// Value:
if ( wps_devicepassword_id == WPS_DPID_USER_SPEC )
{
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( WPS_DPID_REGISTRAR_SPEC );
}
else if ( wps_devicepassword_id == WPS_DPID_REGISTRAR_SPEC )
{
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( WPS_DPID_USER_SPEC );
}
else
{
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( WPS_DPID_PBC );
}
wpsielen += 2;
pframe = rtw_set_ie(pframe, _VENDOR_SPECIFIC_IE_, wpsielen, (unsigned char *) wpsie, &pktlen );
// P2P IE Section.
// P2P OUI
p2pielen = 0;
p2pie[ p2pielen++ ] = 0x50;
p2pie[ p2pielen++ ] = 0x6F;
p2pie[ p2pielen++ ] = 0x9A;
p2pie[ p2pielen++ ] = 0x09; // WFA P2P v1.0
// Commented by Albert 20100908
// According to the P2P Specification, the group negoitation response frame should contain 9 P2P attributes
// 1. Status
// 2. P2P Capability
// 3. Group Owner Intent
// 4. Configuration Timeout
// 5. Operating Channel
// 6. Intended P2P Interface Address
// 7. Channel List
// 8. Device Info
// 9. Group ID ( Only GO )
// ToDo:
// P2P Status
// Type:
p2pie[ p2pielen++ ] = P2P_ATTR_STATUS;
// Length:
*(u16*) ( p2pie + p2pielen ) = cpu_to_le16( 0x0001 );
p2pielen += 2;
// Value, filled by FW
p2pie[ p2pielen++ ] = 1;
// P2P Capability
// Type:
p2pie[ p2pielen++ ] = P2P_ATTR_CAPABILITY;
// Length:
*(u16*) ( p2pie + p2pielen ) = cpu_to_le16( 0x0002 );
p2pielen += 2;
// Value:
// Device Capability Bitmap, 1 byte
if ( rtw_p2p_chk_role(pwdinfo, P2P_ROLE_CLIENT) )
{
// Commented by Albert 2011/03/08
// According to the P2P specification
// if the sending device will be client, the P2P Capability should be reserved of group negotation response frame
p2pie[ p2pielen++ ] = 0;
}
else
{
// Be group owner or meet the error case
p2pie[ p2pielen++ ] = DMP_P2P_DEVCAP_SUPPORT;
}
// Group Capability Bitmap, 1 byte
if ( pwdinfo->persistent_supported )
{
p2pie[ p2pielen++ ] = P2P_GRPCAP_CROSS_CONN | P2P_GRPCAP_PERSISTENT_GROUP;
}
else
{
p2pie[ p2pielen++ ] = P2P_GRPCAP_CROSS_CONN;
}
// Group Owner Intent
// Type:
p2pie[ p2pielen++ ] = P2P_ATTR_GO_INTENT;
// Length:
*(u16*) ( p2pie + p2pielen ) = cpu_to_le16( 0x0001 );
p2pielen += 2;
// Value:
if ( pwdinfo->peer_intent & 0x01 )
{
// Peer's tie breaker bit is 1, our tie breaker bit should be 0
p2pie[ p2pielen++ ] = ( pwdinfo->intent << 1 );
}
else
{
// Peer's tie breaker bit is 0, our tie breaker bit should be 1
p2pie[ p2pielen++ ] = ( ( pwdinfo->intent << 1 ) | BIT(0) );
}
// Configuration Timeout
// Type:
p2pie[ p2pielen++ ] = P2P_ATTR_CONF_TIMEOUT;
// Length:
*(u16*) ( p2pie + p2pielen ) = cpu_to_le16( 0x0002 );
p2pielen += 2;
// Value:
p2pie[ p2pielen++ ] = 200; // 2 seconds needed to be the P2P GO
p2pie[ p2pielen++ ] = 200; // 2 seconds needed to be the P2P Client
// Operating Channel
// Type:
p2pie[ p2pielen++ ] = P2P_ATTR_OPERATING_CH;
// Length:
*(u16*) ( p2pie + p2pielen ) = cpu_to_le16( 0x0005 );
p2pielen += 2;
// Value:
// Country String
p2pie[ p2pielen++ ] = 'X';
p2pie[ p2pielen++ ] = 'X';
// The third byte should be set to 0x04.
// Described in the "Operating Channel Attribute" section.
p2pie[ p2pielen++ ] = 0x04;
// Operating Class
if ( pwdinfo->operating_channel <= 14 )
{
// Operating Class
p2pie[ p2pielen++ ] = 0x51;
}
else if ( ( pwdinfo->operating_channel >= 36 ) && ( pwdinfo->operating_channel <= 48 ) )
{
// Operating Class
p2pie[ p2pielen++ ] = 0x73;
}
else
{
// Operating Class
p2pie[ p2pielen++ ] = 0x7c;
}
// Channel Number
p2pie[ p2pielen++ ] = pwdinfo->operating_channel; // operating channel number
// Intended P2P Interface Address
// Type:
p2pie[ p2pielen++ ] = P2P_ATTR_INTENTED_IF_ADDR;
// Length:
*(u16*) ( p2pie + p2pielen ) = cpu_to_le16( ETH_ALEN );
p2pielen += 2;
// Value:
_rtw_memcpy(p2pie + p2pielen, adapter_mac_addr(padapter), ETH_ALEN);
p2pielen += ETH_ALEN;
// Channel List
// Type:
p2pie[ p2pielen++ ] = P2P_ATTR_CH_LIST;
// Country String(3)
// + ( Operating Class (1) + Number of Channels(1) ) * Operation Classes (?)
// + number of channels in all classes
len_channellist_attr = 3
+ (1 + 1) * (u16)pmlmeext->channel_list.reg_classes
+ get_reg_classes_full_count(pmlmeext->channel_list);
#ifdef CONFIG_CONCURRENT_MODE
if ( check_buddy_fwstate(padapter, _FW_LINKED ) )
{
*(u16*) ( p2pie + p2pielen ) = cpu_to_le16( 5 + 1 );
}
else
{
*(u16*) ( p2pie + p2pielen ) = cpu_to_le16( len_channellist_attr );
}
#else
*(u16*) ( p2pie + p2pielen ) = cpu_to_le16( len_channellist_attr );
#endif
p2pielen += 2;
// Value:
// Country String
p2pie[ p2pielen++ ] = 'X';
p2pie[ p2pielen++ ] = 'X';
// The third byte should be set to 0x04.
// Described in the "Operating Channel Attribute" section.
p2pie[ p2pielen++ ] = 0x04;
// Channel Entry List
#ifdef CONFIG_CONCURRENT_MODE
if ( check_buddy_fwstate(padapter, _FW_LINKED ) )
{
_adapter *pbuddy_adapter = padapter->pbuddy_adapter;
struct mlme_ext_priv *pbuddy_mlmeext = &pbuddy_adapter->mlmeextpriv;
// Operating Class
if ( pbuddy_mlmeext->cur_channel > 14 )
{
if ( pbuddy_mlmeext->cur_channel >= 149 )
{
p2pie[ p2pielen++ ] = 0x7c;
}
else
{
p2pie[ p2pielen++ ] = 0x73;
}
}
else
{
p2pie[ p2pielen++ ] = 0x51;
}
// Number of Channels
// Just support 1 channel and this channel is AP's channel
p2pie[ p2pielen++ ] = 1;
// Channel List
p2pie[ p2pielen++ ] = pbuddy_mlmeext->cur_channel;
}
else
{
int i, j;
for (j = 0; j < pmlmeext->channel_list.reg_classes; j++) {
// Operating Class
p2pie[p2pielen++] = pmlmeext->channel_list.reg_class[j].reg_class;
// Number of Channels
p2pie[p2pielen++] = pmlmeext->channel_list.reg_class[j].channels;
// Channel List
for (i = 0; i < pmlmeext->channel_list.reg_class[j].channels; i++) {
p2pie[p2pielen++] = pmlmeext->channel_list.reg_class[j].channel[i];
}
}
}
#else // CONFIG_CONCURRENT_MODE
{
int i, j;
for (j = 0; j < pmlmeext->channel_list.reg_classes; j++) {
// Operating Class
p2pie[p2pielen++] = pmlmeext->channel_list.reg_class[j].reg_class;
// Number of Channels
p2pie[p2pielen++] = pmlmeext->channel_list.reg_class[j].channels;
// Channel List
for (i = 0; i < pmlmeext->channel_list.reg_class[j].channels; i++) {
p2pie[p2pielen++] = pmlmeext->channel_list.reg_class[j].channel[i];
}
}
}
#endif // CONFIG_CONCURRENT_MODE
// Device Info
// Type:
p2pie[ p2pielen++ ] = P2P_ATTR_DEVICE_INFO;
// Length:
// 21 -> P2P Device Address (6bytes) + Config Methods (2bytes) + Primary Device Type (8bytes)
// + NumofSecondDevType (1byte) + WPS Device Name ID field (2bytes) + WPS Device Name Len field (2bytes)
*(u16*) ( p2pie + p2pielen ) = cpu_to_le16( 21 + pwdinfo->device_name_len );
p2pielen += 2;
// Value:
// P2P Device Address
_rtw_memcpy(p2pie + p2pielen, adapter_mac_addr(padapter), ETH_ALEN);
p2pielen += ETH_ALEN;
// Config Method
// This field should be big endian. Noted by P2P specification.
*(u16*) ( p2pie + p2pielen ) = cpu_to_be16( pwdinfo->supported_wps_cm );
p2pielen += 2;
// Primary Device Type
// Category ID
*(u16*) ( p2pie + p2pielen ) = cpu_to_be16( WPS_PDT_CID_MULIT_MEDIA );
p2pielen += 2;
// OUI
*(u32*) ( p2pie + p2pielen ) = cpu_to_be32( WPSOUI );
p2pielen += 4;
// Sub Category ID
*(u16*) ( p2pie + p2pielen ) = cpu_to_be16( WPS_PDT_SCID_MEDIA_SERVER );
p2pielen += 2;
// Number of Secondary Device Types
p2pie[ p2pielen++ ] = 0x00; // No Secondary Device Type List
// Device Name
// Type:
*(u16*) ( p2pie + p2pielen ) = cpu_to_be16( WPS_ATTR_DEVICE_NAME );
p2pielen += 2;
// Length:
*(u16*) ( p2pie + p2pielen ) = cpu_to_be16( pwdinfo->device_name_len );
p2pielen += 2;
// Value:
_rtw_memcpy( p2pie + p2pielen, pwdinfo->device_name , pwdinfo->device_name_len );
p2pielen += pwdinfo->device_name_len;
if ( rtw_p2p_chk_role(pwdinfo, P2P_ROLE_GO) )
{
// Group ID Attribute
// Type:
p2pie[ p2pielen++ ] = P2P_ATTR_GROUP_ID;
// Length:
*(u16*) ( p2pie + p2pielen ) = cpu_to_le16( ETH_ALEN + pwdinfo->nego_ssidlen );
p2pielen += 2;
// Value:
// p2P Device Address
_rtw_memcpy( p2pie + p2pielen , pwdinfo->device_addr, ETH_ALEN );
p2pielen += ETH_ALEN;
// SSID
_rtw_memcpy( p2pie + p2pielen, pwdinfo->nego_ssid, pwdinfo->nego_ssidlen );
p2pielen += pwdinfo->nego_ssidlen;
}
pframe = rtw_set_ie(pframe, _VENDOR_SPECIFIC_IE_, p2pielen, (unsigned char *) p2pie, &pktlen );
#ifdef CONFIG_WFD
wfdielen = build_nego_resp_wfd_ie(pwdinfo, pframe);
pframe += wfdielen;
pktlen += wfdielen;
#endif //CONFIG_WFD
*pLength = pktlen;
#if 0
// printf dbg msg
dbgbufLen = pktlen;
DBG_871X("======> DBG MSG FOR CONSTRAUCT Nego Rsp\n");
for(index=0;index<dbgbufLen;index++)
printk("%x ",*(dbgbuf+index));
printk("\n");
DBG_871X("<====== DBG MSG FOR CONSTRAUCT Nego Rsp\n");
#endif
}
static void rtw_hal_construct_P2PInviteRsp(_adapter * padapter, u8 * pframe, u32 * pLength)
{
unsigned char category = RTW_WLAN_CATEGORY_PUBLIC;
u8 action = P2P_PUB_ACTION_ACTION;
u32 p2poui = cpu_to_be32(P2POUI);
u8 oui_subtype = P2P_INVIT_RESP;
u8 p2pie[ 255 ] = { 0x00 };
u8 p2pielen = 0, i;
u8 channel_cnt_24g = 0, channel_cnt_5gl = 0, channel_cnt_5gh = 0;
u16 len_channellist_attr = 0;
u32 pktlen;
u8 dialogToken = 0;
#ifdef CONFIG_CONCURRENT_MODE
_adapter *pbuddy_adapter = padapter->pbuddy_adapter;
struct wifidirect_info *pbuddy_wdinfo = &pbuddy_adapter->wdinfo;
struct mlme_priv *pbuddy_mlmepriv = &pbuddy_adapter->mlmepriv;
struct mlme_ext_priv *pbuddy_mlmeext = &pbuddy_adapter->mlmeextpriv;
#endif
#ifdef CONFIG_WFD
u32 wfdielen = 0;
#endif //CONFIG_WFD
//struct xmit_frame *pmgntframe;
//struct pkt_attrib *pattrib;
//unsigned char *pframe;
struct rtw_ieee80211_hdr *pwlanhdr;
unsigned short *fctrl;
struct xmit_priv *pxmitpriv = &(padapter->xmitpriv);
struct mlme_ext_priv *pmlmeext = &(padapter->mlmeextpriv);
struct mlme_ext_info *pmlmeinfo = &(pmlmeext->mlmext_info);
struct wifidirect_info *pwdinfo = &( padapter->wdinfo);
//for debug
u8 *dbgbuf = pframe;
u8 dbgbufLen = 0, index = 0;
DBG_871X( "%s\n", __FUNCTION__);
pwlanhdr = (struct rtw_ieee80211_hdr *)pframe;
fctrl = &(pwlanhdr->frame_ctl);
*(fctrl) = 0;
//RA fill by FW
_rtw_memset(pwlanhdr->addr1, 0, ETH_ALEN);
_rtw_memcpy(pwlanhdr->addr2, adapter_mac_addr(padapter), ETH_ALEN);
//BSSID fill by FW
_rtw_memset(pwlanhdr->addr3, 0, ETH_ALEN);
SetSeqNum(pwlanhdr, 0);
SetFrameSubType(pframe, WIFI_ACTION);
pframe += sizeof(struct rtw_ieee80211_hdr_3addr);
pktlen = sizeof(struct rtw_ieee80211_hdr_3addr);
pframe = rtw_set_fixed_ie(pframe, 1, &(category), &(pktlen));
pframe = rtw_set_fixed_ie(pframe, 1, &(action), &(pktlen));
pframe = rtw_set_fixed_ie(pframe, 4, (unsigned char *) &(p2poui), &(pktlen));
pframe = rtw_set_fixed_ie(pframe, 1, &(oui_subtype), &(pktlen));
//dialog token, filled by FW
pframe = rtw_set_fixed_ie(pframe, 1, &(dialogToken), &(pktlen));
// P2P IE Section.
// P2P OUI
p2pielen = 0;
p2pie[ p2pielen++ ] = 0x50;
p2pie[ p2pielen++ ] = 0x6F;
p2pie[ p2pielen++ ] = 0x9A;
p2pie[ p2pielen++ ] = 0x09; // WFA P2P v1.0
// Commented by Albert 20101005
// According to the P2P Specification, the P2P Invitation response frame should contain 5 P2P attributes
// 1. Status
// 2. Configuration Timeout
// 3. Operating Channel ( Only GO )
// 4. P2P Group BSSID ( Only GO )
// 5. Channel List
// P2P Status
// Type:
p2pie[ p2pielen++ ] = P2P_ATTR_STATUS;
// Length:
*(u16*) ( p2pie + p2pielen ) = cpu_to_le16( 0x0001 );
p2pielen += 2;
// Value: filled by FW, defult value is FAIL INFO UNAVAILABLE
p2pie[ p2pielen++ ] = P2P_STATUS_FAIL_INFO_UNAVAILABLE;
// Configuration Timeout
// Type:
p2pie[ p2pielen++ ] = P2P_ATTR_CONF_TIMEOUT;
// Length:
*(u16*) ( p2pie + p2pielen ) = cpu_to_le16( 0x0002 );
p2pielen += 2;
// Value:
p2pie[ p2pielen++ ] = 200; // 2 seconds needed to be the P2P GO
p2pie[ p2pielen++ ] = 200; // 2 seconds needed to be the P2P Client
// due to defult value is FAIL INFO UNAVAILABLE, so the following IE is not needed
#if 0
if( status_code == P2P_STATUS_SUCCESS )
{
if( rtw_p2p_chk_role( pwdinfo, P2P_ROLE_GO ) )
{
// The P2P Invitation request frame asks this Wi-Fi device to be the P2P GO
// In this case, the P2P Invitation response frame should carry the two more P2P attributes.
// First one is operating channel attribute.
// Second one is P2P Group BSSID attribute.
// Operating Channel
// Type:
p2pie[ p2pielen++ ] = P2P_ATTR_OPERATING_CH;
// Length:
*(u16*) ( p2pie + p2pielen ) = cpu_to_le16( 0x0005 );
p2pielen += 2;
// Value:
// Country String
p2pie[ p2pielen++ ] = 'X';
p2pie[ p2pielen++ ] = 'X';
// The third byte should be set to 0x04.
// Described in the "Operating Channel Attribute" section.
p2pie[ p2pielen++ ] = 0x04;
// Operating Class
p2pie[ p2pielen++ ] = 0x51; // Copy from SD7
// Channel Number
p2pie[ p2pielen++ ] = pwdinfo->operating_channel; // operating channel number
// P2P Group BSSID
// Type:
p2pie[ p2pielen++ ] = P2P_ATTR_GROUP_BSSID;
// Length:
*(u16*) ( p2pie + p2pielen ) = cpu_to_le16( ETH_ALEN );
p2pielen += 2;
// Value:
// P2P Device Address for GO
_rtw_memcpy(p2pie + p2pielen, adapter_mac_addr(padapter), ETH_ALEN);
p2pielen += ETH_ALEN;
}
// Channel List
// Type:
p2pie[ p2pielen++ ] = P2P_ATTR_CH_LIST;
// Length:
// Country String(3)
// + ( Operating Class (1) + Number of Channels(1) ) * Operation Classes (?)
// + number of channels in all classes
len_channellist_attr = 3
+ (1 + 1) * (u16)pmlmeext->channel_list.reg_classes
+ get_reg_classes_full_count(pmlmeext->channel_list);
#ifdef CONFIG_CONCURRENT_MODE
if ( check_buddy_fwstate(padapter, _FW_LINKED ) )
{
*(u16*) ( p2pie + p2pielen ) = cpu_to_le16( 5 + 1 );
}
else
{
*(u16*) ( p2pie + p2pielen ) = cpu_to_le16( len_channellist_attr );
}
#else
*(u16*) ( p2pie + p2pielen ) = cpu_to_le16( len_channellist_attr );
#endif
p2pielen += 2;
// Value:
// Country String
p2pie[ p2pielen++ ] = 'X';
p2pie[ p2pielen++ ] = 'X';
// The third byte should be set to 0x04.
// Described in the "Operating Channel Attribute" section.
p2pie[ p2pielen++ ] = 0x04;
// Channel Entry List
#ifdef CONFIG_CONCURRENT_MODE
if ( check_buddy_fwstate(padapter, _FW_LINKED ) )
{
_adapter *pbuddy_adapter = padapter->pbuddy_adapter;
struct mlme_ext_priv *pbuddy_mlmeext = &pbuddy_adapter->mlmeextpriv;
// Operating Class
if ( pbuddy_mlmeext->cur_channel > 14 )
{
if ( pbuddy_mlmeext->cur_channel >= 149 )
{
p2pie[ p2pielen++ ] = 0x7c;
}
else
{
p2pie[ p2pielen++ ] = 0x73;
}
}
else
{
p2pie[ p2pielen++ ] = 0x51;
}
// Number of Channels
// Just support 1 channel and this channel is AP's channel
p2pie[ p2pielen++ ] = 1;
// Channel List
p2pie[ p2pielen++ ] = pbuddy_mlmeext->cur_channel;
}
else
{
int i, j;
for (j = 0; j < pmlmeext->channel_list.reg_classes; j++) {
// Operating Class
p2pie[p2pielen++] = pmlmeext->channel_list.reg_class[j].reg_class;
// Number of Channels
p2pie[p2pielen++] = pmlmeext->channel_list.reg_class[j].channels;
// Channel List
for (i = 0; i < pmlmeext->channel_list.reg_class[j].channels; i++) {
p2pie[p2pielen++] = pmlmeext->channel_list.reg_class[j].channel[i];
}
}
}
#else // CONFIG_CONCURRENT_MODE
{
int i, j;
for (j = 0; j < pmlmeext->channel_list.reg_classes; j++) {
// Operating Class
p2pie[p2pielen++] = pmlmeext->channel_list.reg_class[j].reg_class;
// Number of Channels
p2pie[p2pielen++] = pmlmeext->channel_list.reg_class[j].channels;
// Channel List
for (i = 0; i < pmlmeext->channel_list.reg_class[j].channels; i++) {
p2pie[p2pielen++] = pmlmeext->channel_list.reg_class[j].channel[i];
}
}
}
#endif // CONFIG_CONCURRENT_MODE
}
#endif
pframe = rtw_set_ie(pframe, _VENDOR_SPECIFIC_IE_, p2pielen, (unsigned char *) p2pie, &pktlen );
#ifdef CONFIG_WFD
wfdielen = build_invitation_resp_wfd_ie(pwdinfo, pframe);
pframe += wfdielen;
pktlen += wfdielen;
#endif //CONFIG_WFD
*pLength = pktlen;
#if 0
// printf dbg msg
dbgbufLen = pktlen;
DBG_871X("======> DBG MSG FOR CONSTRAUCT Invite Rsp\n");
for(index=0;index<dbgbufLen;index++)
printk("%x ",*(dbgbuf+index));
printk("\n");
DBG_871X("<====== DBG MSG FOR CONSTRAUCT Invite Rsp\n");
#endif
}
static void rtw_hal_construct_P2PProvisionDisRsp(_adapter * padapter, u8 * pframe, u32 * pLength)
{
unsigned char category = RTW_WLAN_CATEGORY_PUBLIC;
u8 action = P2P_PUB_ACTION_ACTION;
u8 dialogToken = 0;
u32 p2poui = cpu_to_be32(P2POUI);
u8 oui_subtype = P2P_PROVISION_DISC_RESP;
u8 wpsie[ 100 ] = { 0x00 };
u8 wpsielen = 0;
u32 pktlen;
#ifdef CONFIG_WFD
u32 wfdielen = 0;
#endif //CONFIG_WFD
//struct xmit_frame *pmgntframe;
//struct pkt_attrib *pattrib;
//unsigned char *pframe;
struct rtw_ieee80211_hdr *pwlanhdr;
unsigned short *fctrl;
struct xmit_priv *pxmitpriv = &(padapter->xmitpriv);
struct mlme_ext_priv *pmlmeext = &(padapter->mlmeextpriv);
struct mlme_ext_info *pmlmeinfo = &(pmlmeext->mlmext_info);
struct wifidirect_info *pwdinfo = &( padapter->wdinfo);
//for debug
u8 *dbgbuf = pframe;
u8 dbgbufLen = 0, index = 0;
DBG_871X( "%s\n", __FUNCTION__);
pwlanhdr = (struct rtw_ieee80211_hdr *)pframe;
fctrl = &(pwlanhdr->frame_ctl);
*(fctrl) = 0;
//RA filled by FW
_rtw_memset(pwlanhdr->addr1, 0, ETH_ALEN);
_rtw_memcpy(pwlanhdr->addr2, adapter_mac_addr(padapter), ETH_ALEN);
_rtw_memcpy(pwlanhdr->addr3, adapter_mac_addr(padapter), ETH_ALEN);
SetSeqNum(pwlanhdr,0);
SetFrameSubType(pframe, WIFI_ACTION);
pframe += sizeof(struct rtw_ieee80211_hdr_3addr);
pktlen = sizeof(struct rtw_ieee80211_hdr_3addr);
pframe = rtw_set_fixed_ie(pframe, 1, &(category), &(pktlen));
pframe = rtw_set_fixed_ie(pframe, 1, &(action), &(pktlen));
pframe = rtw_set_fixed_ie(pframe, 4, (unsigned char *) &(p2poui), &(pktlen));
pframe = rtw_set_fixed_ie(pframe, 1, &(oui_subtype), &(pktlen));
//dialog token, filled by FW
pframe = rtw_set_fixed_ie(pframe, 1, &(dialogToken), &(pktlen));
wpsielen = 0;
// WPS OUI
//*(u32*) ( wpsie ) = cpu_to_be32( WPSOUI );
RTW_PUT_BE32(wpsie, WPSOUI);
wpsielen += 4;
#if 0
// WPS version
// Type:
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( WPS_ATTR_VER1 );
wpsielen += 2;
// Length:
*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( 0x0001 );
wpsielen += 2;
// Value:
wpsie[wpsielen++] = WPS_VERSION_1; // Version 1.0
#endif
// Config Method
// Type:
//*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( WPS_ATTR_CONF_METHOD );
RTW_PUT_BE16(wpsie + wpsielen, WPS_ATTR_CONF_METHOD);
wpsielen += 2;
// Length:
//*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( 0x0002 );
RTW_PUT_BE16(wpsie + wpsielen, 0x0002);
wpsielen += 2;
// Value: filled by FW, default value is PBC
//*(u16*) ( wpsie + wpsielen ) = cpu_to_be16( config_method );
RTW_PUT_BE16(wpsie + wpsielen, WPS_CM_PUSH_BUTTON);
wpsielen += 2;
pframe = rtw_set_ie(pframe, _VENDOR_SPECIFIC_IE_, wpsielen, (unsigned char *) wpsie, &pktlen );
#ifdef CONFIG_WFD
wfdielen = build_provdisc_resp_wfd_ie(pwdinfo, pframe);
pframe += wfdielen;
pktlen += wfdielen;
#endif //CONFIG_WFD
*pLength = pktlen;
// printf dbg msg
#if 0
dbgbufLen = pktlen;
DBG_871X("======> DBG MSG FOR CONSTRAUCT ProvisionDis Rsp\n");
for(index=0;index<dbgbufLen;index++)
printk("%x ",*(dbgbuf+index));
printk("\n");
DBG_871X("<====== DBG MSG FOR CONSTRAUCT ProvisionDis Rsp\n");
#endif
}
u8 rtw_hal_set_FwP2PRsvdPage_cmd(_adapter* adapter, PRSVDPAGE_LOC rsvdpageloc)
{
u8 u1H2CP2PRsvdPageParm[H2C_P2PRSVDPAGE_LOC_LEN]={0};
struct hal_ops *pHalFunc = &adapter->HalFunc;
u8 ret = _FAIL;
DBG_871X("P2PRsvdPageLoc: P2PBeacon=%d P2PProbeRsp=%d NegoRsp=%d InviteRsp=%d PDRsp=%d\n",
rsvdpageloc->LocP2PBeacon, rsvdpageloc->LocP2PProbeRsp,
rsvdpageloc->LocNegoRsp, rsvdpageloc->LocInviteRsp,
rsvdpageloc->LocPDRsp);
SET_H2CCMD_RSVDPAGE_LOC_P2P_BCN(u1H2CP2PRsvdPageParm, rsvdpageloc->LocProbeRsp);
SET_H2CCMD_RSVDPAGE_LOC_P2P_PROBE_RSP(u1H2CP2PRsvdPageParm, rsvdpageloc->LocPsPoll);
SET_H2CCMD_RSVDPAGE_LOC_P2P_NEGO_RSP(u1H2CP2PRsvdPageParm, rsvdpageloc->LocNullData);
SET_H2CCMD_RSVDPAGE_LOC_P2P_INVITE_RSP(u1H2CP2PRsvdPageParm, rsvdpageloc->LocQosNull);
SET_H2CCMD_RSVDPAGE_LOC_P2P_PD_RSP(u1H2CP2PRsvdPageParm, rsvdpageloc->LocBTQosNull);
//FillH2CCmd8723B(padapter, H2C_8723B_P2P_OFFLOAD_RSVD_PAGE, H2C_P2PRSVDPAGE_LOC_LEN, u1H2CP2PRsvdPageParm);
ret = rtw_hal_fill_h2c_cmd(adapter,
H2C_P2P_OFFLOAD_RSVD_PAGE,
H2C_P2PRSVDPAGE_LOC_LEN,
u1H2CP2PRsvdPageParm);
return ret;
}
u8 rtw_hal_set_p2p_wowlan_offload_cmd(_adapter* adapter)
{
u8 offload_cmd[H2C_P2P_OFFLOAD_LEN] = {0};
struct wifidirect_info *pwdinfo = &(adapter->wdinfo);
struct P2P_WoWlan_Offload_t *p2p_wowlan_offload = (struct P2P_WoWlan_Offload_t *)offload_cmd;
struct hal_ops *pHalFunc = &adapter->HalFunc;
u8 ret = _FAIL;
_rtw_memset(p2p_wowlan_offload,0 ,sizeof(struct P2P_WoWlan_Offload_t));
DBG_871X("%s\n",__func__);
switch(pwdinfo->role)
{
case P2P_ROLE_DEVICE:
DBG_871X("P2P_ROLE_DEVICE\n");
p2p_wowlan_offload->role = 0;
break;
case P2P_ROLE_CLIENT:
DBG_871X("P2P_ROLE_CLIENT\n");
p2p_wowlan_offload->role = 1;
break;
case P2P_ROLE_GO:
DBG_871X("P2P_ROLE_GO\n");
p2p_wowlan_offload->role = 2;
break;
default:
DBG_871X("P2P_ROLE_DISABLE\n");
break;
}
p2p_wowlan_offload->Wps_Config[0] = pwdinfo->supported_wps_cm>>8;
p2p_wowlan_offload->Wps_Config[1] = pwdinfo->supported_wps_cm;
offload_cmd = (u8*)p2p_wowlan_offload;
DBG_871X("p2p_wowlan_offload: %x:%x:%x\n",offload_cmd[0],offload_cmd[1],offload_cmd[2]);
ret = rtw_hal_fill_h2c_cmd(adapter,
H2C_P2P_OFFLOAD,
H2C_P2P_OFFLOAD_LEN,
offload_cmd);
return ret;
//FillH2CCmd8723B(adapter, H2C_8723B_P2P_OFFLOAD, sizeof(struct P2P_WoWlan_Offload_t), (u8 *)p2p_wowlan_offload);
}
#endif //CONFIG_P2P_WOWLAN
static void rtw_hal_construct_beacon(_adapter *padapter,
u8 *pframe, u32 *pLength)
{
struct rtw_ieee80211_hdr *pwlanhdr;
u16 *fctrl;
u32 rate_len, pktlen;
struct mlme_ext_priv *pmlmeext = &(padapter->mlmeextpriv);
struct mlme_ext_info *pmlmeinfo = &(pmlmeext->mlmext_info);
WLAN_BSSID_EX *cur_network = &(pmlmeinfo->network);
u8 bc_addr[] = {0xff, 0xff, 0xff, 0xff, 0xff, 0xff};
//DBG_871X("%s\n", __FUNCTION__);
pwlanhdr = (struct rtw_ieee80211_hdr *)pframe;
fctrl = &(pwlanhdr->frame_ctl);
*(fctrl) = 0;
_rtw_memcpy(pwlanhdr->addr1, bc_addr, ETH_ALEN);
_rtw_memcpy(pwlanhdr->addr2, adapter_mac_addr(padapter), ETH_ALEN);
_rtw_memcpy(pwlanhdr->addr3, get_my_bssid(cur_network), ETH_ALEN);
SetSeqNum(pwlanhdr, 0/*pmlmeext->mgnt_seq*/);
//pmlmeext->mgnt_seq++;
SetFrameSubType(pframe, WIFI_BEACON);
pframe += sizeof(struct rtw_ieee80211_hdr_3addr);
pktlen = sizeof (struct rtw_ieee80211_hdr_3addr);
//timestamp will be inserted by hardware
pframe += 8;
pktlen += 8;
// beacon interval: 2 bytes
_rtw_memcpy(pframe, (unsigned char *)(rtw_get_beacon_interval_from_ie(cur_network->IEs)), 2);
pframe += 2;
pktlen += 2;
// capability info: 2 bytes
_rtw_memcpy(pframe, (unsigned char *)(rtw_get_capability_from_ie(cur_network->IEs)), 2);
pframe += 2;
pktlen += 2;
if( (pmlmeinfo->state&0x03) == WIFI_FW_AP_STATE)
{
//DBG_871X("ie len=%d\n", cur_network->IELength);
pktlen += cur_network->IELength - sizeof(NDIS_802_11_FIXED_IEs);
_rtw_memcpy(pframe, cur_network->IEs+sizeof(NDIS_802_11_FIXED_IEs), pktlen);
goto _ConstructBeacon;
}
//below for ad-hoc mode
// SSID
pframe = rtw_set_ie(pframe, _SSID_IE_, cur_network->Ssid.SsidLength, cur_network->Ssid.Ssid, &pktlen);
// supported rates...
rate_len = rtw_get_rateset_len(cur_network->SupportedRates);
pframe = rtw_set_ie(pframe, _SUPPORTEDRATES_IE_, ((rate_len > 8)? 8: rate_len), cur_network->SupportedRates, &pktlen);
// DS parameter set
pframe = rtw_set_ie(pframe, _DSSET_IE_, 1, (unsigned char *)&(cur_network->Configuration.DSConfig), &pktlen);
if( (pmlmeinfo->state&0x03) == WIFI_FW_ADHOC_STATE)
{
u32 ATIMWindow;
// IBSS Parameter Set...
//ATIMWindow = cur->Configuration.ATIMWindow;
ATIMWindow = 0;
pframe = rtw_set_ie(pframe, _IBSS_PARA_IE_, 2, (unsigned char *)(&ATIMWindow), &pktlen);
}
//todo: ERP IE
// EXTERNDED SUPPORTED RATE
if (rate_len > 8)
{
pframe = rtw_set_ie(pframe, _EXT_SUPPORTEDRATES_IE_, (rate_len - 8), (cur_network->SupportedRates + 8), &pktlen);
}
//todo:HT for adhoc
_ConstructBeacon:
if ((pktlen + TXDESC_SIZE) > 512)
{
DBG_871X("beacon frame too large\n");
return;
}
*pLength = pktlen;
//DBG_871X("%s bcn_sz=%d\n", __FUNCTION__, pktlen);
}
static void rtw_hal_construct_PSPoll(_adapter *padapter,
u8 *pframe, u32 *pLength)
{
struct rtw_ieee80211_hdr *pwlanhdr;
u16 *fctrl;
u32 pktlen;
struct mlme_ext_priv *pmlmeext = &(padapter->mlmeextpriv);
struct mlme_ext_info *pmlmeinfo = &(pmlmeext->mlmext_info);
//DBG_871X("%s\n", __FUNCTION__);
pwlanhdr = (struct rtw_ieee80211_hdr *)pframe;
// Frame control.
fctrl = &(pwlanhdr->frame_ctl);
*(fctrl) = 0;
SetPwrMgt(fctrl);
SetFrameSubType(pframe, WIFI_PSPOLL);
// AID.
SetDuration(pframe, (pmlmeinfo->aid | 0xc000));
// BSSID.
_rtw_memcpy(pwlanhdr->addr1, get_my_bssid(&(pmlmeinfo->network)), ETH_ALEN);
// TA.
_rtw_memcpy(pwlanhdr->addr2, adapter_mac_addr(padapter), ETH_ALEN);
*pLength = 16;
}
static void rtw_hal_construct_NullFunctionData(
PADAPTER padapter,
u8 *pframe,
u32 *pLength,
u8 *StaAddr,
u8 bQoS,
u8 AC,
u8 bEosp,
u8 bForcePowerSave)
{
struct rtw_ieee80211_hdr *pwlanhdr;
u16 *fctrl;
u32 pktlen;
struct mlme_priv *pmlmepriv = &padapter->mlmepriv;
struct wlan_network *cur_network = &pmlmepriv->cur_network;
struct mlme_ext_priv *pmlmeext = &(padapter->mlmeextpriv);
struct mlme_ext_info *pmlmeinfo = &(pmlmeext->mlmext_info);
//DBG_871X("%s:%d\n", __FUNCTION__, bForcePowerSave);
pwlanhdr = (struct rtw_ieee80211_hdr*)pframe;
fctrl = &pwlanhdr->frame_ctl;
*(fctrl) = 0;
if (bForcePowerSave)
{
SetPwrMgt(fctrl);
}
switch(cur_network->network.InfrastructureMode)
{
case Ndis802_11Infrastructure:
SetToDs(fctrl);
_rtw_memcpy(pwlanhdr->addr1, get_my_bssid(&(pmlmeinfo->network)), ETH_ALEN);
_rtw_memcpy(pwlanhdr->addr2, adapter_mac_addr(padapter), ETH_ALEN);
_rtw_memcpy(pwlanhdr->addr3, StaAddr, ETH_ALEN);
break;
case Ndis802_11APMode:
SetFrDs(fctrl);
_rtw_memcpy(pwlanhdr->addr1, StaAddr, ETH_ALEN);
_rtw_memcpy(pwlanhdr->addr2, get_my_bssid(&(pmlmeinfo->network)), ETH_ALEN);
_rtw_memcpy(pwlanhdr->addr3, adapter_mac_addr(padapter), ETH_ALEN);
break;
case Ndis802_11IBSS:
default:
_rtw_memcpy(pwlanhdr->addr1, StaAddr, ETH_ALEN);
_rtw_memcpy(pwlanhdr->addr2, adapter_mac_addr(padapter), ETH_ALEN);
_rtw_memcpy(pwlanhdr->addr3, get_my_bssid(&(pmlmeinfo->network)), ETH_ALEN);
break;
}
SetSeqNum(pwlanhdr, 0);
if (bQoS == _TRUE) {
struct rtw_ieee80211_hdr_3addr_qos *pwlanqoshdr;
SetFrameSubType(pframe, WIFI_QOS_DATA_NULL);
pwlanqoshdr = (struct rtw_ieee80211_hdr_3addr_qos*)pframe;
SetPriority(&pwlanqoshdr->qc, AC);
SetEOSP(&pwlanqoshdr->qc, bEosp);
pktlen = sizeof(struct rtw_ieee80211_hdr_3addr_qos);
} else {
SetFrameSubType(pframe, WIFI_DATA_NULL);
pktlen = sizeof(struct rtw_ieee80211_hdr_3addr);
}
*pLength = pktlen;
}
void rtw_hal_construct_ProbeRsp(_adapter *padapter, u8 *pframe, u32 *pLength,
u8 *StaAddr, BOOLEAN bHideSSID)
{
struct rtw_ieee80211_hdr *pwlanhdr;
u16 *fctrl;
u8 *mac, *bssid;
u32 pktlen;
struct mlme_ext_priv *pmlmeext = &(padapter->mlmeextpriv);
struct mlme_ext_info *pmlmeinfo = &(pmlmeext->mlmext_info);
WLAN_BSSID_EX *cur_network = &(pmlmeinfo->network);
/*DBG_871X("%s\n", __FUNCTION__);*/
pwlanhdr = (struct rtw_ieee80211_hdr *)pframe;
mac = adapter_mac_addr(padapter);
bssid = cur_network->MacAddress;
fctrl = &(pwlanhdr->frame_ctl);
*(fctrl) = 0;
_rtw_memcpy(pwlanhdr->addr1, StaAddr, ETH_ALEN);
_rtw_memcpy(pwlanhdr->addr2, mac, ETH_ALEN);
_rtw_memcpy(pwlanhdr->addr3, bssid, ETH_ALEN);
SetSeqNum(pwlanhdr, 0);
SetFrameSubType(fctrl, WIFI_PROBERSP);
pktlen = sizeof(struct rtw_ieee80211_hdr_3addr);
pframe += pktlen;
if (cur_network->IELength > MAX_IE_SZ)
return;
_rtw_memcpy(pframe, cur_network->IEs, cur_network->IELength);
pframe += cur_network->IELength;
pktlen += cur_network->IELength;
*pLength = pktlen;
}
#ifdef CONFIG_WOWLAN
//
// Description:
// Construct the ARP response packet to support ARP offload.
//
static void rtw_hal_construct_ARPRsp(
PADAPTER padapter,
u8 *pframe,
u32 *pLength,
u8 *pIPAddress
)
{
struct rtw_ieee80211_hdr *pwlanhdr;
u16 *fctrl;
u32 pktlen;
struct mlme_priv *pmlmepriv = &padapter->mlmepriv;
struct wlan_network *cur_network = &pmlmepriv->cur_network;
struct mlme_ext_priv *pmlmeext = &(padapter->mlmeextpriv);
struct mlme_ext_info *pmlmeinfo = &(pmlmeext->mlmext_info);
struct security_priv *psecuritypriv = &padapter->securitypriv;
static u8 ARPLLCHeader[8] = {0xAA, 0xAA, 0x03, 0x00, 0x00, 0x00, 0x08, 0x06};
u8 *pARPRspPkt = pframe;
//for TKIP Cal MIC
u8 *payload = pframe;
u8 EncryptionHeadOverhead = 0;
//DBG_871X("%s:%d\n", __FUNCTION__, bForcePowerSave);
pwlanhdr = (struct rtw_ieee80211_hdr*)pframe;
fctrl = &pwlanhdr->frame_ctl;
*(fctrl) = 0;
//-------------------------------------------------------------------------
// MAC Header.
//-------------------------------------------------------------------------
SetFrameType(fctrl, WIFI_DATA);
//SetFrameSubType(fctrl, 0);
SetToDs(fctrl);
_rtw_memcpy(pwlanhdr->addr1, get_my_bssid(&(pmlmeinfo->network)), ETH_ALEN);
_rtw_memcpy(pwlanhdr->addr2, adapter_mac_addr(padapter), ETH_ALEN);
_rtw_memcpy(pwlanhdr->addr3, get_my_bssid(&(pmlmeinfo->network)), ETH_ALEN);
SetSeqNum(pwlanhdr, 0);
SetDuration(pwlanhdr, 0);
//SET_80211_HDR_FRAME_CONTROL(pARPRspPkt, 0);
//SET_80211_HDR_TYPE_AND_SUBTYPE(pARPRspPkt, Type_Data);
//SET_80211_HDR_TO_DS(pARPRspPkt, 1);
//SET_80211_HDR_ADDRESS1(pARPRspPkt, pMgntInfo->Bssid);
//SET_80211_HDR_ADDRESS2(pARPRspPkt, Adapter->CurrentAddress);
//SET_80211_HDR_ADDRESS3(pARPRspPkt, pMgntInfo->Bssid);
//SET_80211_HDR_DURATION(pARPRspPkt, 0);
//SET_80211_HDR_FRAGMENT_SEQUENCE(pARPRspPkt, 0);
#ifdef CONFIG_WAPI_SUPPORT
*pLength = sMacHdrLng;
#else
*pLength = 24;
#endif
switch (psecuritypriv->dot11PrivacyAlgrthm) {
case _WEP40_:
case _WEP104_:
EncryptionHeadOverhead = 4;
break;
case _TKIP_:
EncryptionHeadOverhead = 8;
break;
case _AES_:
EncryptionHeadOverhead = 8;
break;
#ifdef CONFIG_WAPI_SUPPORT
case _SMS4_:
EncryptionHeadOverhead = 18;
break;
#endif
default:
EncryptionHeadOverhead = 0;
}
if(EncryptionHeadOverhead > 0) {
_rtw_memset(&(pframe[*pLength]), 0,EncryptionHeadOverhead);
*pLength += EncryptionHeadOverhead;
//SET_80211_HDR_WEP(pARPRspPkt, 1); //Suggested by CCW.
SetPrivacy(fctrl);
}
//-------------------------------------------------------------------------
// Frame Body.
//-------------------------------------------------------------------------
pARPRspPkt = (u8*)(pframe+ *pLength);
payload = pARPRspPkt; //Get Payload pointer
// LLC header
_rtw_memcpy(pARPRspPkt, ARPLLCHeader, 8);
*pLength += 8;
// ARP element
pARPRspPkt += 8;
SET_ARP_PKT_HW(pARPRspPkt, 0x0100);
SET_ARP_PKT_PROTOCOL(pARPRspPkt, 0x0008); // IP protocol
SET_ARP_PKT_HW_ADDR_LEN(pARPRspPkt, 6);
SET_ARP_PKT_PROTOCOL_ADDR_LEN(pARPRspPkt, 4);
SET_ARP_PKT_OPERATION(pARPRspPkt, 0x0200); // ARP response
SET_ARP_PKT_SENDER_MAC_ADDR(pARPRspPkt, adapter_mac_addr(padapter));
SET_ARP_PKT_SENDER_IP_ADDR(pARPRspPkt, pIPAddress);
#ifdef CONFIG_ARP_KEEP_ALIVE
if (!is_zero_mac_addr(pmlmepriv->gw_mac_addr)) {
SET_ARP_PKT_TARGET_MAC_ADDR(pARPRspPkt, pmlmepriv->gw_mac_addr);
SET_ARP_PKT_TARGET_IP_ADDR(pARPRspPkt, pmlmepriv->gw_ip);
}
else
#endif
{
SET_ARP_PKT_TARGET_MAC_ADDR(pARPRspPkt,
get_my_bssid(&(pmlmeinfo->network)));
SET_ARP_PKT_TARGET_IP_ADDR(pARPRspPkt,
pIPAddress);
DBG_871X("%s Target Mac Addr:" MAC_FMT "\n", __FUNCTION__,
MAC_ARG(get_my_bssid(&(pmlmeinfo->network))));
DBG_871X("%s Target IP Addr" IP_FMT "\n", __FUNCTION__,
IP_ARG(pIPAddress));
}
*pLength += 28;
if (psecuritypriv->dot11PrivacyAlgrthm == _TKIP_) {
u8 mic[8];
struct mic_data micdata;
struct sta_info *psta = NULL;
u8 priority[4]={0x0,0x0,0x0,0x0};
u8 null_key[16]={0x0,0x0,0x0,0x0,0x0,0x0,0x0,0x0,0x0,0x0,0x0,0x0,0x0,0x0,0x0,0x0};
DBG_871X("%s(): Add MIC\n",__FUNCTION__);
psta = rtw_get_stainfo(&padapter->stapriv,
get_my_bssid(&(pmlmeinfo->network)));
if (psta != NULL) {
if(_rtw_memcmp(&psta->dot11tkiptxmickey.skey[0],
null_key, 16)==_TRUE) {
DBG_871X("%s(): STA dot11tkiptxmickey==0\n",
__func__);
}
//start to calculate the mic code
rtw_secmicsetkey(&micdata,
&psta->dot11tkiptxmickey.skey[0]);
}
rtw_secmicappend(&micdata, pwlanhdr->addr3, 6); //DA
rtw_secmicappend(&micdata, pwlanhdr->addr2, 6); //SA
priority[0]=0;
rtw_secmicappend(&micdata, &priority[0], 4);
rtw_secmicappend(&micdata, payload, 36); //payload length = 8 + 28
rtw_secgetmic(&micdata,&(mic[0]));
pARPRspPkt += 28;
_rtw_memcpy(pARPRspPkt, &(mic[0]),8);
*pLength += 8;
}
}
#ifdef CONFIG_PNO_SUPPORT
static void rtw_hal_construct_ProbeReq(_adapter *padapter, u8 *pframe,
u32 *pLength, pno_ssid_t *ssid)
{
struct rtw_ieee80211_hdr *pwlanhdr;
u16 *fctrl;
u32 pktlen;
unsigned char *mac;
unsigned char bssrate[NumRates];
struct xmit_priv *pxmitpriv = &(padapter->xmitpriv);
struct mlme_priv *pmlmepriv = &(padapter->mlmepriv);
struct mlme_ext_priv *pmlmeext = &(padapter->mlmeextpriv);
struct mlme_ext_info *pmlmeinfo = &(pmlmeext->mlmext_info);
int bssrate_len = 0;
u8 bc_addr[] = {0xff, 0xff, 0xff, 0xff, 0xff, 0xff};
pwlanhdr = (struct rtw_ieee80211_hdr *)pframe;
mac = adapter_mac_addr(padapter);
fctrl = &(pwlanhdr->frame_ctl);
*(fctrl) = 0;
_rtw_memcpy(pwlanhdr->addr1, bc_addr, ETH_ALEN);
_rtw_memcpy(pwlanhdr->addr3, bc_addr, ETH_ALEN);
_rtw_memcpy(pwlanhdr->addr2, mac, ETH_ALEN);
SetSeqNum(pwlanhdr, 0);
SetFrameSubType(pframe, WIFI_PROBEREQ);
pktlen = sizeof(struct rtw_ieee80211_hdr_3addr);
pframe += pktlen;
if (ssid == NULL) {
pframe = rtw_set_ie(pframe, _SSID_IE_, 0, NULL, &pktlen);
} else {
//DBG_871X("%s len:%d\n", ssid->SSID, ssid->SSID_len);
pframe = rtw_set_ie(pframe, _SSID_IE_, ssid->SSID_len, ssid->SSID, &pktlen);
}
get_rate_set(padapter, bssrate, &bssrate_len);
if (bssrate_len > 8)
{
pframe = rtw_set_ie(pframe, _SUPPORTEDRATES_IE_ , 8, bssrate, &pktlen);
pframe = rtw_set_ie(pframe, _EXT_SUPPORTEDRATES_IE_ , (bssrate_len - 8), (bssrate + 8), &pktlen);
}
else
{
pframe = rtw_set_ie(pframe, _SUPPORTEDRATES_IE_ , bssrate_len , bssrate, &pktlen);
}
*pLength = pktlen;
}
static void rtw_hal_construct_PNO_info(_adapter *padapter,
u8 *pframe, u32*pLength)
{
struct pwrctrl_priv *pwrctl = adapter_to_pwrctl(padapter);
u8 *pPnoInfoPkt = pframe;
pPnoInfoPkt = (u8*)(pframe+ *pLength);
_rtw_memcpy(pPnoInfoPkt, &pwrctl->pnlo_info->ssid_num, 1);
*pLength+=1;
pPnoInfoPkt += 1;
_rtw_memcpy(pPnoInfoPkt, &pwrctl->pnlo_info->hidden_ssid_num, 1);
*pLength+=3;
pPnoInfoPkt += 3;
_rtw_memcpy(pPnoInfoPkt, &pwrctl->pnlo_info->fast_scan_period, 1);
*pLength+=4;
pPnoInfoPkt += 4;
_rtw_memcpy(pPnoInfoPkt, &pwrctl->pnlo_info->fast_scan_iterations, 4);
*pLength+=4;
pPnoInfoPkt += 4;
_rtw_memcpy(pPnoInfoPkt, &pwrctl->pnlo_info->slow_scan_period, 4);
*pLength+=4;
pPnoInfoPkt += 4;
_rtw_memcpy(pPnoInfoPkt, &pwrctl->pnlo_info->ssid_length,
MAX_PNO_LIST_COUNT);
*pLength+=MAX_PNO_LIST_COUNT;
pPnoInfoPkt += MAX_PNO_LIST_COUNT;
_rtw_memcpy(pPnoInfoPkt, &pwrctl->pnlo_info->ssid_cipher_info,
MAX_PNO_LIST_COUNT);
*pLength+=MAX_PNO_LIST_COUNT;
pPnoInfoPkt += MAX_PNO_LIST_COUNT;
_rtw_memcpy(pPnoInfoPkt, &pwrctl->pnlo_info->ssid_channel_info,
MAX_PNO_LIST_COUNT);
*pLength+=MAX_PNO_LIST_COUNT;
pPnoInfoPkt += MAX_PNO_LIST_COUNT;
_rtw_memcpy(pPnoInfoPkt, &pwrctl->pnlo_info->loc_probe_req,
MAX_HIDDEN_AP);
*pLength+=MAX_HIDDEN_AP;
pPnoInfoPkt += MAX_HIDDEN_AP;
}
static void rtw_hal_construct_ssid_list(_adapter *padapter,
u8 *pframe, u32 *pLength)
{
struct pwrctrl_priv *pwrctl = adapter_to_pwrctl(padapter);
u8 *pSSIDListPkt = pframe;
int i;
pSSIDListPkt = (u8*)(pframe+ *pLength);
for(i = 0; i < pwrctl->pnlo_info->ssid_num ; i++) {
_rtw_memcpy(pSSIDListPkt, &pwrctl->pno_ssid_list->node[i].SSID,
pwrctl->pnlo_info->ssid_length[i]);
*pLength += WLAN_SSID_MAXLEN;
pSSIDListPkt += WLAN_SSID_MAXLEN;
}
}
static void rtw_hal_construct_scan_info(_adapter *padapter,
u8 *pframe, u32 *pLength)
{
struct pwrctrl_priv *pwrctl = adapter_to_pwrctl(padapter);
u8 *pScanInfoPkt = pframe;
int i;
pScanInfoPkt = (u8*)(pframe+ *pLength);
_rtw_memcpy(pScanInfoPkt, &pwrctl->pscan_info->channel_num, 1);
*pLength+=1;
pScanInfoPkt += 1;
_rtw_memcpy(pScanInfoPkt, &pwrctl->pscan_info->orig_ch, 1);
*pLength+=1;
pScanInfoPkt += 1;
_rtw_memcpy(pScanInfoPkt, &pwrctl->pscan_info->orig_bw, 1);
*pLength+=1;
pScanInfoPkt += 1;
_rtw_memcpy(pScanInfoPkt, &pwrctl->pscan_info->orig_40_offset, 1);
*pLength+=1;
pScanInfoPkt += 1;
_rtw_memcpy(pScanInfoPkt, &pwrctl->pscan_info->orig_80_offset, 1);
*pLength+=1;
pScanInfoPkt += 1;
_rtw_memcpy(pScanInfoPkt, &pwrctl->pscan_info->periodScan, 1);
*pLength+=1;
pScanInfoPkt += 1;
_rtw_memcpy(pScanInfoPkt, &pwrctl->pscan_info->period_scan_time, 1);
*pLength+=1;
pScanInfoPkt += 1;
_rtw_memcpy(pScanInfoPkt, &pwrctl->pscan_info->enableRFE, 1);
*pLength+=1;
pScanInfoPkt += 1;
_rtw_memcpy(pScanInfoPkt, &pwrctl->pscan_info->rfe_type, 8);
*pLength+=8;
pScanInfoPkt += 8;
for(i = 0 ; i < MAX_SCAN_LIST_COUNT ; i ++) {
_rtw_memcpy(pScanInfoPkt,
&pwrctl->pscan_info->ssid_channel_info[i], 4);
*pLength+=4;
pScanInfoPkt += 4;
}
}
#endif //CONFIG_PNO_SUPPORT
#ifdef CONFIG_GTK_OL
static void rtw_hal_construct_GTKRsp(
PADAPTER padapter,
u8 *pframe,
u32 *pLength
)
{
struct rtw_ieee80211_hdr *pwlanhdr;
u16 *fctrl;
u32 pktlen;
struct mlme_priv *pmlmepriv = &padapter->mlmepriv;
struct wlan_network *cur_network = &pmlmepriv->cur_network;
struct mlme_ext_priv *pmlmeext = &(padapter->mlmeextpriv);
struct mlme_ext_info *pmlmeinfo = &(pmlmeext->mlmext_info);
struct security_priv *psecuritypriv = &padapter->securitypriv;
static u8 LLCHeader[8] = {0xAA, 0xAA, 0x03, 0x00, 0x00, 0x00, 0x88, 0x8E};
static u8 GTKbody_a[11] ={0x01, 0x03, 0x00, 0x5F, 0x02, 0x03, 0x12, 0x00, 0x10, 0x42, 0x0B};
u8 *pGTKRspPkt = pframe;
u8 EncryptionHeadOverhead = 0;
//DBG_871X("%s:%d\n", __FUNCTION__, bForcePowerSave);
pwlanhdr = (struct rtw_ieee80211_hdr*)pframe;
fctrl = &pwlanhdr->frame_ctl;
*(fctrl) = 0;
//-------------------------------------------------------------------------
// MAC Header.
//-------------------------------------------------------------------------
SetFrameType(fctrl, WIFI_DATA);
//SetFrameSubType(fctrl, 0);
SetToDs(fctrl);
_rtw_memcpy(pwlanhdr->addr1,
get_my_bssid(&(pmlmeinfo->network)), ETH_ALEN);
_rtw_memcpy(pwlanhdr->addr2,
adapter_mac_addr(padapter), ETH_ALEN);
_rtw_memcpy(pwlanhdr->addr3,
get_my_bssid(&(pmlmeinfo->network)), ETH_ALEN);
SetSeqNum(pwlanhdr, 0);
SetDuration(pwlanhdr, 0);
#ifdef CONFIG_WAPI_SUPPORT
*pLength = sMacHdrLng;
#else
*pLength = 24;
#endif //CONFIG_WAPI_SUPPORT
//-------------------------------------------------------------------------
// Security Header: leave space for it if necessary.
//-------------------------------------------------------------------------
switch (psecuritypriv->dot11PrivacyAlgrthm) {
case _WEP40_:
case _WEP104_:
EncryptionHeadOverhead = 4;
break;
case _TKIP_:
EncryptionHeadOverhead = 8;
break;
case _AES_:
EncryptionHeadOverhead = 8;
break;
#ifdef CONFIG_WAPI_SUPPORT
case _SMS4_:
EncryptionHeadOverhead = 18;
break;
#endif //CONFIG_WAPI_SUPPORT
default:
EncryptionHeadOverhead = 0;
}
if (EncryptionHeadOverhead > 0) {
_rtw_memset(&(pframe[*pLength]), 0,EncryptionHeadOverhead);
*pLength += EncryptionHeadOverhead;
//SET_80211_HDR_WEP(pGTKRspPkt, 1); //Suggested by CCW.
//GTK's privacy bit is done by FW
//SetPrivacy(fctrl);
}
//-------------------------------------------------------------------------
// Frame Body.
//-------------------------------------------------------------------------
pGTKRspPkt = (u8*)(pframe+ *pLength);
// LLC header
_rtw_memcpy(pGTKRspPkt, LLCHeader, 8);
*pLength += 8;
// GTK element
pGTKRspPkt += 8;
//GTK frame body after LLC, part 1
_rtw_memcpy(pGTKRspPkt, GTKbody_a, 11);
*pLength += 11;
pGTKRspPkt += 11;
//GTK frame body after LLC, part 2
_rtw_memset(&(pframe[*pLength]), 0, 88);
*pLength += 88;
pGTKRspPkt += 88;
}
#endif //CONFIG_GTK_OL
void rtw_hal_set_wow_fw_rsvd_page(_adapter *adapter, u8 *pframe, u16 index,
u8 tx_desc, u32 page_size, u8 *page_num, u32 *total_pkt_len,
RSVDPAGE_LOC *rsvd_page_loc)
{
struct security_priv *psecuritypriv = &adapter->securitypriv;
struct mlme_priv *pmlmepriv = &adapter->mlmepriv;
struct pwrctrl_priv *pwrctl = adapter_to_pwrctl(adapter);
struct mlme_ext_priv *pmlmeext;
struct mlme_ext_info *pmlmeinfo;
u32 ARPLegnth = 0, GTKLegnth = 0, PNOLength = 0, ScanInfoLength = 0;
u32 SSIDLegnth = 0, ProbeReqLength = 0;
u8 CurtPktPageNum = 0;
u8 currentip[4];
u8 cur_dot11txpn[8];
#ifdef CONFIG_GTK_OL
struct sta_priv *pstapriv = &adapter->stapriv;
struct sta_info * psta;
u8 kek[RTW_KEK_LEN];
u8 kck[RTW_KCK_LEN];
#endif //CONFIG_GTK_OL
#ifdef CONFIG_PNO_SUPPORT
int pno_index;
u8 ssid_num;
#endif //CONFIG_PNO_SUPPORT
pmlmeext = &adapter->mlmeextpriv;
pmlmeinfo = &pmlmeext->mlmext_info;
if (pwrctl->wowlan_pno_enable == _FALSE) {
//ARP RSP * 1 page
rtw_get_current_ip_address(adapter, currentip);
rsvd_page_loc->LocArpRsp = *page_num;
rtw_hal_construct_ARPRsp( adapter, &pframe[index],
&ARPLegnth, currentip);
rtw_hal_fill_fake_txdesc(adapter,
&pframe[index-tx_desc],
ARPLegnth, _FALSE, _FALSE, _TRUE);
CurtPktPageNum = (u8)PageNum(tx_desc + ARPLegnth, page_size);
*page_num += CurtPktPageNum;
index += (CurtPktPageNum * page_size);
//3 SEC IV * 1 page
rtw_get_sec_iv(adapter, cur_dot11txpn,
get_my_bssid(&pmlmeinfo->network));
rsvd_page_loc->LocRemoteCtrlInfo = *page_num;
_rtw_memcpy(pframe+index-tx_desc, cur_dot11txpn, _AES_IV_LEN_);
CurtPktPageNum = (u8)PageNum(_AES_IV_LEN_, page_size);
*page_num += CurtPktPageNum;
*total_pkt_len = index + _AES_IV_LEN_;
#ifdef CONFIG_GTK_OL
index += (CurtPktPageNum * page_size);
//if the ap staion info. exists, get the kek, kck from staion info.
psta = rtw_get_stainfo(pstapriv, get_bssid(pmlmepriv));
if (psta == NULL) {
_rtw_memset(kek, 0, RTW_KEK_LEN);
_rtw_memset(kck, 0, RTW_KCK_LEN);
DBG_8192C("%s, KEK, KCK download rsvd page all zero \n",
__func__);
} else {
_rtw_memcpy(kek, psta->kek, RTW_KEK_LEN);
_rtw_memcpy(kck, psta->kck, RTW_KCK_LEN);
}
//3 KEK, KCK
rsvd_page_loc->LocGTKInfo = *page_num;
if (IS_HARDWARE_TYPE_8188E(adapter) || IS_HARDWARE_TYPE_8812(adapter)) {
struct security_priv *psecpriv = NULL;
psecpriv = &adapter->securitypriv;
_rtw_memcpy(pframe+index-tx_desc,
&psecpriv->dot11PrivacyAlgrthm, 1);
_rtw_memcpy(pframe+index-tx_desc+1,
&psecpriv->dot118021XGrpPrivacy, 1);
_rtw_memcpy(pframe+index-tx_desc+2,
kck, RTW_KCK_LEN);
_rtw_memcpy(pframe+index-tx_desc+2+RTW_KCK_LEN,
kek, RTW_KEK_LEN);
CurtPktPageNum = (u8)PageNum(tx_desc + 2 + RTW_KCK_LEN + RTW_KEK_LEN, page_size);
} else {
_rtw_memcpy(pframe+index-tx_desc, kck, RTW_KCK_LEN);
_rtw_memcpy(pframe+index-tx_desc+RTW_KCK_LEN, kek, RTW_KEK_LEN);
CurtPktPageNum = (u8)PageNum(tx_desc + RTW_KCK_LEN + RTW_KEK_LEN, page_size);
}
#if 0
{
int i;
printk("\ntoFW KCK: ");
for(i=0;i<16; i++)
printk(" %02x ", kck[i]);
printk("\ntoFW KEK: ");
for(i=0;i<16; i++)
printk(" %02x ", kek[i]);
printk("\n");
}
DBG_871X("%s(): HW_VAR_SET_TX_CMD: KEK KCK %p %d\n",
__FUNCTION__, &pframe[index-tx_desc],
(tx_desc + RTW_KCK_LEN + RTW_KEK_LEN));
#endif
*page_num += CurtPktPageNum;
index += (CurtPktPageNum * page_size);
//3 GTK Response
rsvd_page_loc->LocGTKRsp= *page_num;
rtw_hal_construct_GTKRsp(adapter, &pframe[index], &GTKLegnth);
rtw_hal_fill_fake_txdesc(adapter, &pframe[index-tx_desc],
GTKLegnth, _FALSE, _FALSE, _TRUE);
#if 0
{
int gj;
printk("123GTK pkt=> \n");
for(gj=0; gj < GTKLegnth+tx_desc; gj++) {
printk(" %02x ", pframe[index-tx_desc+gj]);
if ((gj + 1)%16==0)
printk("\n");
}
printk(" <=end\n");
}
DBG_871X("%s(): HW_VAR_SET_TX_CMD: GTK RSP %p %d\n",
__FUNCTION__, &pframe[index-tx_desc],
(tx_desc + GTKLegnth));
#endif
CurtPktPageNum = (u8)PageNum(tx_desc + GTKLegnth, page_size);
*page_num += CurtPktPageNum;
index += (CurtPktPageNum * page_size);
//below page is empty for GTK extension memory
//3(11) GTK EXT MEM
rsvd_page_loc->LocGTKEXTMEM = *page_num;
CurtPktPageNum = 2;
*page_num += CurtPktPageNum;
//extension memory for FW
*total_pkt_len =
index - tx_desc + (page_size * CurtPktPageNum);
#endif //CONFIG_GTK_OL
} else {
#ifdef CONFIG_PNO_SUPPORT
if (pwrctl->pno_in_resume == _FALSE &&
pwrctl->pno_inited == _TRUE) {
//Broadcast Probe Request
rsvd_page_loc->LocProbePacket = *page_num;
DBG_871X("loc_probe_req: %d\n",
rsvd_page_loc->LocProbePacket);
rtw_hal_construct_ProbeReq(
adapter,
&pframe[index],
&ProbeReqLength,
NULL);
rtw_hal_fill_fake_txdesc(adapter,
&pframe[index-tx_desc],
ProbeReqLength, _FALSE, _FALSE, _FALSE);
CurtPktPageNum =
(u8)PageNum(tx_desc + ProbeReqLength, page_size);
*page_num += CurtPktPageNum;
index += (CurtPktPageNum * page_size);
//Hidden SSID Probe Request
ssid_num = pwrctl->pnlo_info->hidden_ssid_num;
for (pno_index = 0 ; pno_index < ssid_num ; pno_index++) {
pwrctl->pnlo_info->loc_probe_req[pno_index] =
*page_num;
rtw_hal_construct_ProbeReq(
adapter,
&pframe[index],
&ProbeReqLength,
&pwrctl->pno_ssid_list->node[pno_index]);
rtw_hal_fill_fake_txdesc(adapter,
&pframe[index - tx_desc],
ProbeReqLength, _FALSE, _FALSE, _FALSE);
CurtPktPageNum =
(u8)PageNum(tx_desc + ProbeReqLength, page_size);
*page_num += CurtPktPageNum;
index += (CurtPktPageNum * page_size);
}
//PNO INFO Page
rsvd_page_loc->LocPNOInfo = *page_num;
rtw_hal_construct_PNO_info(adapter,
&pframe[index - tx_desc],
&PNOLength);
CurtPktPageNum = (u8)PageNum(PNOLength, page_size);
*page_num += CurtPktPageNum;
index += (CurtPktPageNum * page_size);
//SSID List Page
rsvd_page_loc->LocSSIDInfo = *page_num;
rtw_hal_construct_ssid_list(adapter,
&pframe[index - tx_desc],
&SSIDLegnth);
CurtPktPageNum = (u8)PageNum(SSIDLegnth, page_size);
*page_num += CurtPktPageNum;
index += (CurtPktPageNum * page_size);
//Scan Info Page
rsvd_page_loc->LocScanInfo = *page_num;
rtw_hal_construct_scan_info(adapter,
&pframe[index - tx_desc],
&ScanInfoLength);
CurtPktPageNum = (u8)PageNum(ScanInfoLength, page_size);
*page_num += CurtPktPageNum;
index += (CurtPktPageNum * page_size);
*total_pkt_len = index + ScanInfoLength;
}
#endif //CONFIG_PNO_SUPPORT
}
}
static void rtw_hal_gate_bb(_adapter *adapter, bool stop)
{
struct pwrctrl_priv *pwrpriv = adapter_to_pwrctl(adapter);
u8 val8 = 0;
u16 val16 = 0;
if (stop) {
/* Pause TX*/
pwrpriv->wowlan_txpause_status = rtw_read8(adapter, REG_TXPAUSE);
rtw_write8(adapter, REG_TXPAUSE, 0xff);
val8 = rtw_read8(adapter, REG_SYS_FUNC_EN);
val8 &= ~BIT(0);
rtw_write8(adapter, REG_SYS_FUNC_EN, val8);
DBG_871X("%s: BB gated: 0x%02x, store TXPAUSE: %02x\n",
__func__,
rtw_read8(adapter, REG_SYS_FUNC_EN),
pwrpriv->wowlan_txpause_status);
} else {
val8 = rtw_read8(adapter, REG_SYS_FUNC_EN);
val8 |= BIT(0);
rtw_write8(adapter, REG_SYS_FUNC_EN, val8);
DBG_871X("%s: BB release: 0x%02x, recover TXPAUSE:%02x\n",
__func__, rtw_read8(adapter, REG_SYS_FUNC_EN),
pwrpriv->wowlan_txpause_status);
/* release TX*/
rtw_write8(adapter, REG_TXPAUSE, pwrpriv->wowlan_txpause_status);
}
}
static void rtw_hal_reset_mac_rx(_adapter *adapter)
{
u8 val8 = 0;
/* Set REG_CR bit1, bit3, bit7 to 0*/
val8 = rtw_read8(adapter, REG_CR);
val8 &= 0x75;
rtw_write8(adapter, REG_CR, val8);
val8 = rtw_read8(adapter, REG_CR);
/* Set REG_CR bit1, bit3, bit7 to 1*/
val8 |= 0x8a;
rtw_write8(adapter, REG_CR, val8);
DBG_871X("0x%04x: %02x\n", REG_CR, rtw_read8(adapter, REG_CR));
}
static void rtw_hal_set_wow_rxff_boundary(_adapter *adapter, bool wow_mode)
{
u8 val8 = 0;
u16 rxff_bndy = 0;
u32 rx_dma_buff_sz = 0;
val8 = rtw_read8(adapter, REG_FIFOPAGE + 3);
if (val8 != 0)
DBG_871X("%s:[%04x]some PKTs in TXPKTBUF\n",
__func__, (REG_FIFOPAGE + 3));
rtw_hal_reset_mac_rx(adapter);
if (wow_mode) {
rtw_hal_get_def_var(adapter, HAL_DEF_RX_DMA_SZ_WOW,
(u8 *)&rx_dma_buff_sz);
rxff_bndy = rx_dma_buff_sz - 1;
rtw_write16(adapter, (REG_TRXFF_BNDY + 2), rxff_bndy);
DBG_871X("%s: wow mode, 0x%04x: 0x%04x\n", __func__,
REG_TRXFF_BNDY + 2,
rtw_read16(adapter, (REG_TRXFF_BNDY+2)));
} else {
rtw_hal_get_def_var(adapter, HAL_DEF_RX_DMA_SZ,
(u8 *)&rx_dma_buff_sz);
rxff_bndy = rx_dma_buff_sz - 1;
rtw_write16(adapter, (REG_TRXFF_BNDY + 2), rxff_bndy);
DBG_871X("%s: normal mode, 0x%04x: 0x%04x\n", __func__,
REG_TRXFF_BNDY + 2,
rtw_read16(adapter, (REG_TRXFF_BNDY+2)));
}
}
static int rtw_hal_set_pattern(_adapter *adapter, u8 *pattern,
u8 len, u8 *mask)
{
struct pwrctrl_priv *pwrctl = adapter_to_pwrctl(adapter);
struct mlme_ext_priv *pmlmeext = NULL;
struct mlme_ext_info *pmlmeinfo = NULL;
struct rtl_wow_pattern wow_pattern;
u8 mask_hw[MAX_WKFM_SIZE] = {0};
u8 content[MAX_WKFM_PATTERN_SIZE] = {0};
u8 broadcast_addr[6] = {0xff, 0xff, 0xff, 0xff, 0xff, 0xff};
u8 multicast_addr1[2] = {0x33, 0x33};
u8 multicast_addr2[3] = {0x01, 0x00, 0x5e};
u8 res = _FALSE, index = 0, mask_len = 0;
u8 mac_addr[ETH_ALEN] = {0};
u16 count = 0;
int i, j;
if (pwrctl->wowlan_pattern_idx > MAX_WKFM_NUM) {
DBG_871X("%s pattern_idx is more than MAX_FMC_NUM: %d\n",
__func__, MAX_WKFM_NUM);
return _FALSE;
}
pmlmeext = &adapter->mlmeextpriv;
pmlmeinfo = &pmlmeext->mlmext_info;
_rtw_memcpy(mac_addr, adapter_mac_addr(adapter), ETH_ALEN);
_rtw_memset(&wow_pattern, 0, sizeof(struct rtl_wow_pattern));
mask_len = DIV_ROUND_UP(len, 8);
/* 1. setup A1 table */
if (memcmp(pattern, broadcast_addr, ETH_ALEN) == 0)
wow_pattern.type = PATTERN_BROADCAST;
else if (memcmp(pattern, multicast_addr1, 2) == 0)
wow_pattern.type = PATTERN_MULTICAST;
else if (memcmp(pattern, multicast_addr2, 3) == 0)
wow_pattern.type = PATTERN_MULTICAST;
else if (memcmp(pattern, mac_addr, ETH_ALEN) == 0)
wow_pattern.type = PATTERN_UNICAST;
else
wow_pattern.type = PATTERN_INVALID;
/* translate mask from os to mask for hw */
/******************************************************************************
* pattern from OS uses 'ethenet frame', like this:
| 6 | 6 | 2 | 20 | Variable | 4 |
|--------+--------+------+-----------+------------+-----|
| 802.3 Mac Header | IP Header | TCP Packet | FCS |
| DA | SA | Type |
* BUT, packet catched by our HW is in '802.11 frame', begin from LLC,
| 24 or 30 | 6 | 2 | 20 | Variable | 4 |
|-------------------+--------+------+-----------+------------+-----|
| 802.11 MAC Header | LLC | IP Header | TCP Packet | FCS |
| Others | Tpye |
* Therefore, we need translate mask_from_OS to mask_to_hw.
* We should left-shift mask by 6 bits, then set the new bit[0~5] = 0,
* because new mask[0~5] means 'SA', but our HW packet begins from LLC,
* bit[0~5] corresponds to first 6 Bytes in LLC, they just don't match.
******************************************************************************/
/* Shift 6 bits */
for (i = 0; i < mask_len - 1; i++) {
mask_hw[i] = mask[i] >> 6;
mask_hw[i] |= (mask[i + 1] & 0x3F) << 2;
}
mask_hw[i] = (mask[i] >> 6) & 0x3F;
/* Set bit 0-5 to zero */
mask_hw[0] &= 0xC0;
for (i = 0; i < (MAX_WKFM_SIZE/4); i++) {
wow_pattern.mask[i] = mask_hw[i * 4];
wow_pattern.mask[i] |= (mask_hw[i * 4 + 1] << 8);
wow_pattern.mask[i] |= (mask_hw[i * 4 + 2] << 16);
wow_pattern.mask[i] |= (mask_hw[i * 4 + 3] << 24);
}
/* To get the wake up pattern from the mask.
* We do not count first 12 bits which means
* DA[6] and SA[6] in the pattern to match HW design. */
count = 0;
for (i = 12; i < len; i++) {
if ((mask[i / 8] >> (i % 8)) & 0x01) {
content[count] = pattern[i];
count++;
}
}
wow_pattern.crc = rtw_calc_crc(content, count);
if (wow_pattern.crc != 0 && wow_pattern.type == PATTERN_INVALID)
wow_pattern.type = PATTERN_VALID;
index = rtw_read8(adapter, REG_WKFMCAM_NUM);
if (!pwrctl->bInSuspend)
index += 2;
/* write pattern */
res = rtw_write_to_frame_mask(adapter, index, &wow_pattern);
if (res == _TRUE) {
pwrctl->wowlan_pattern_idx++;
rtw_write8(adapter,
REG_WKFMCAM_NUM,
pwrctl->wowlan_pattern_idx);
} else {
DBG_871X("%s: ERROR write_to_frame_mask_cam fail\n", __func__);
}
return res;
}
static void rtw_hal_dl_pattern(_adapter *adapter, u8 clean_all)
{
struct pwrctrl_priv *pwrpriv = adapter_to_pwrctl(adapter);
int i = 0, total = 0;
total = pwrpriv->wowlan_pattern_idx + 1;
rtw_clean_pattern(adapter);
if (!clean_all) {
for (i = 0 ; i < total ; i++) {
rtw_hal_set_pattern(adapter,
pwrpriv->patterns[i].content,
pwrpriv->patterns[i].len,
pwrpriv->patterns[i].mask);
}
DBG_871X("pattern downloaded\n");
} else {
for (i = 0 ; i < MAX_WKFM_NUM ; i++) {
_rtw_memset(pwrpriv->patterns[i].content, '\0',
sizeof(pwrpriv->patterns[i].content));
_rtw_memset(pwrpriv->patterns[i].mask, '\0',
sizeof(pwrpriv->patterns[i].mask));
pwrpriv->patterns[i].len = 0;
}
DBG_871X("clean all pattern\n");
}
}
static void rtw_hal_wow_enable(_adapter *adapter)
{
struct pwrctrl_priv *pwrctl = adapter_to_pwrctl(adapter);
struct security_priv *psecuritypriv = &adapter->securitypriv;
struct mlme_priv *pmlmepriv = &adapter->mlmepriv;
struct hal_ops *pHalFunc = &adapter->HalFunc;
struct sta_info *psta = NULL;
int res;
u16 media_status_rpt;
DBG_871X_LEVEL(_drv_always_, "%s, WOWLAN_ENABLE\n", __func__);
rtw_hal_gate_bb(adapter, _TRUE);
#ifdef CONFIG_GTK_OL
if (psecuritypriv->dot11PrivacyAlgrthm == _AES_)
rtw_hal_fw_sync_cam_id(adapter);
#endif
if (IS_HARDWARE_TYPE_8723B(adapter))
rtw_hal_backup_rate(adapter);
/* RX DMA stop */
if (IS_HARDWARE_TYPE_8188E(adapter))
rtw_hal_disable_tx_report(adapter);
res = rtw_hal_pause_rx_dma(adapter);
if (res == _FAIL)
DBG_871X_LEVEL(_drv_always_, "[WARNING] pause RX DMA fail\n");
/* Reconfig RX_FF Boundary */
rtw_hal_set_wow_rxff_boundary(adapter, _TRUE);
/* redownload pattern match */
if (pwrctl->wowlan_pattern)
rtw_hal_dl_pattern(adapter, _FALSE);
rtw_hal_set_wowlan_fw(adapter, _TRUE);
media_status_rpt = RT_MEDIA_CONNECT;
rtw_hal_set_hwreg(adapter, HW_VAR_H2C_FW_JOINBSSRPT,
(u8 *)&media_status_rpt);
if (!pwrctl->wowlan_pno_enable) {
psta = rtw_get_stainfo(&adapter->stapriv, get_bssid(pmlmepriv));
media_status_rpt = (u16)((psta->mac_id<<8)|RT_MEDIA_CONNECT);
if (psta != NULL) {
rtw_hal_set_hwreg(adapter, HW_VAR_H2C_MEDIA_STATUS_RPT,
(u8 *)&media_status_rpt);
}
}
#if defined(CONFIG_SDIO_HCI) || defined(CONFIG_GSPI_HCI)
/* Enable CPWM2 only. */
res = rtw_hal_enable_cpwm2(adapter);
if (res == _FAIL)
DBG_871X_LEVEL(_drv_always_, "[WARNING] enable cpwm2 fail\n");
#endif
#ifdef CONFIG_GPIO_WAKEUP
rtw_hal_switch_gpio_wl_ctrl(adapter, WAKEUP_GPIO_IDX, _TRUE);
#endif
/* Set WOWLAN H2C command. */
DBG_871X_LEVEL(_drv_always_, "Set WOWLan cmd\n");
rtw_hal_set_fw_wow_related_cmd(adapter, 1);
res = rtw_hal_check_wow_ctrl(adapter, _TRUE);
if (res == _FALSE)
DBG_871X("[Error]%s: set wowlan CMD fail!!\n", __func__);
pwrctl->wowlan_wake_reason =
rtw_read8(adapter, REG_WOWLAN_WAKE_REASON);
DBG_871X_LEVEL(_drv_always_, "wowlan_wake_reason: 0x%02x\n",
pwrctl->wowlan_wake_reason);
#ifdef CONFIG_GTK_OL_DBG
dump_sec_cam(RTW_DBGDUMP, adapter);
#endif
#ifdef CONFIG_USB_HCI
if (adapter->intf_stop) /* free adapter's resource */
adapter->intf_stop(adapter);
#ifdef CONFIG_CONCURRENT_MODE
if (rtw_buddy_adapter_up(adapter)) /*free buddy adapter's resource*/
adapter->pbuddy_adapter->intf_stop(adapter->pbuddy_adapter);
#endif /*CONFIG_CONCURRENT_MODE*/
/* Invoid SE0 reset signal during suspending*/
rtw_write8(adapter, REG_RSV_CTRL, 0x20);
rtw_write8(adapter, REG_RSV_CTRL, 0x60);
#endif /*CONFIG_USB_HCI*/
rtw_hal_gate_bb(adapter, _FALSE);
}
static void rtw_hal_wow_disable(_adapter *adapter)
{
struct pwrctrl_priv *pwrctl = adapter_to_pwrctl(adapter);
struct security_priv *psecuritypriv = &adapter->securitypriv;
struct mlme_priv *pmlmepriv = &adapter->mlmepriv;
struct hal_ops *pHalFunc = &adapter->HalFunc;
struct sta_info *psta = NULL;
int res;
u16 media_status_rpt;
u8 val8;
DBG_871X_LEVEL(_drv_always_, "%s, WOWLAN_DISABLE\n", __func__);
if (!pwrctl->wowlan_pno_enable) {
psta = rtw_get_stainfo(&adapter->stapriv, get_bssid(pmlmepriv));
if (psta != NULL) {
media_status_rpt =
(u16)((psta->mac_id<<8)|RT_MEDIA_DISCONNECT);
rtw_hal_set_hwreg(adapter, HW_VAR_H2C_MEDIA_STATUS_RPT,
(u8 *)&media_status_rpt);
} else {
DBG_871X("%s: psta is null\n", __func__);
}
}
if (0) {
DBG_871X("0x630:0x%02x\n", rtw_read8(adapter, 0x630));
DBG_871X("0x631:0x%02x\n", rtw_read8(adapter, 0x631));
}
pwrctl->wowlan_wake_reason = rtw_read8(adapter, REG_WOWLAN_WAKE_REASON);
DBG_871X_LEVEL(_drv_always_, "wakeup_reason: 0x%02x\n",
pwrctl->wowlan_wake_reason);
rtw_hal_set_fw_wow_related_cmd(adapter, 0);
res = rtw_hal_check_wow_ctrl(adapter, _FALSE);
if (res == _FALSE) {
DBG_871X("[Error]%s: disable WOW cmd fail\n!!", __func__);
rtw_hal_force_enable_rxdma(adapter);
}
rtw_hal_gate_bb(adapter, _TRUE);
res = rtw_hal_pause_rx_dma(adapter);
if (res == _FAIL)
DBG_871X_LEVEL(_drv_always_, "[WARNING] pause RX DMA fail\n");
/* clean pattern match */
if (pwrctl->wowlan_pattern)
rtw_hal_dl_pattern(adapter, _TRUE);
/* config RXFF boundary to original */
rtw_hal_set_wow_rxff_boundary(adapter, _FALSE);
rtw_hal_release_rx_dma(adapter);
if (IS_HARDWARE_TYPE_8188E(adapter))
rtw_hal_enable_tx_report(adapter);
rtw_hal_update_tx_iv(adapter);
#ifdef CONFIG_GTK_OL
if (psecuritypriv->dot11PrivacyAlgrthm == _AES_)
rtw_hal_update_gtk_offload_info(adapter);
#endif /*CONFIG_GTK_OL*/
rtw_hal_set_wowlan_fw(adapter, _FALSE);
#ifdef CONFIG_GPIO_WAKEUP
val8 = (pwrctl->is_high_active == 0) ? 1 : 0;
DBG_871X_LEVEL(_drv_always_, "Set Wake GPIO to default(%d).\n", val8);
rtw_hal_set_output_gpio(adapter, WAKEUP_GPIO_IDX, val8);
rtw_hal_switch_gpio_wl_ctrl(adapter, WAKEUP_GPIO_IDX, _FALSE);
#endif
if ((pwrctl->wowlan_wake_reason != FWDecisionDisconnect) &&
(pwrctl->wowlan_wake_reason != Rx_Pairwisekey) &&
(pwrctl->wowlan_wake_reason != Rx_DisAssoc) &&
(pwrctl->wowlan_wake_reason != Rx_DeAuth)) {
media_status_rpt = RT_MEDIA_CONNECT;
rtw_hal_set_hwreg(adapter, HW_VAR_H2C_FW_JOINBSSRPT,
(u8 *)&media_status_rpt);
if (psta != NULL) {
media_status_rpt = (u16)((psta->mac_id<<8)|RT_MEDIA_CONNECT);
rtw_hal_set_hwreg(adapter, HW_VAR_H2C_MEDIA_STATUS_RPT,
(u8 *)&media_status_rpt);
}
}
rtw_hal_gate_bb(adapter, _FALSE);
}
#endif /*CONFIG_WOWLAN*/
#ifdef CONFIG_P2P_WOWLAN
void rtw_hal_set_p2p_wow_fw_rsvd_page(_adapter* adapter, u8 *pframe, u16 index,
u8 tx_desc, u32 page_size, u8 *page_num, u32 *total_pkt_len,
RSVDPAGE_LOC* rsvd_page_loc)
{
u32 P2PNegoRspLength = 0, P2PInviteRspLength = 0;
u32 P2PPDRspLength = 0, P2PProbeRspLength = 0, P2PBCNLength = 0;
u8 CurtPktPageNum = 0;
/* P2P Beacon */
rsvd_page_loc->LocP2PBeacon = *page_num;
rtw_hal_construct_P2PBeacon(adapter, &pframe[index], &P2PBCNLength);
rtw_hal_fill_fake_txdesc(adapter, &pframe[index-tx_desc],
P2PBCNLength, _FALSE, _FALSE, _FALSE);
#if 0
DBG_871X("%s(): HW_VAR_SET_TX_CMD: PROBE RSP %p %d\n",
__FUNCTION__, &pframe[index-tx_desc], (P2PBCNLength+tx_desc));
#endif
CurtPktPageNum = (u8)PageNum(tx_desc + P2PBCNLength, page_size);
*page_num += CurtPktPageNum;
index += (CurtPktPageNum * page_size);
// P2P Probe rsp
rsvd_page_loc->LocP2PProbeRsp = *page_num;
rtw_hal_construct_P2PProbeRsp(adapter, &pframe[index],
&P2PProbeRspLength);
rtw_hal_fill_fake_txdesc(adapter, &pframe[index-tx_desc],
P2PProbeRspLength, _FALSE, _FALSE, _FALSE);
//DBG_871X("%s(): HW_VAR_SET_TX_CMD: PROBE RSP %p %d\n",
// __FUNCTION__, &pframe[index-tx_desc], (P2PProbeRspLength+tx_desc));
CurtPktPageNum = (u8)PageNum(tx_desc + P2PProbeRspLength, page_size);
*page_num += CurtPktPageNum;
index += (CurtPktPageNum * page_size);
//P2P nego rsp
rsvd_page_loc->LocNegoRsp = *page_num;
rtw_hal_construct_P2PNegoRsp(adapter, &pframe[index],
&P2PNegoRspLength);
rtw_hal_fill_fake_txdesc(adapter, &pframe[index-tx_desc],
P2PNegoRspLength, _FALSE, _FALSE, _FALSE);
//DBG_871X("%s(): HW_VAR_SET_TX_CMD: QOS NULL DATA %p %d\n",
// __FUNCTION__, &pframe[index-tx_desc], (NegoRspLength+tx_desc));
CurtPktPageNum = (u8)PageNum(tx_desc + P2PNegoRspLength, page_size);
*page_num += CurtPktPageNum;
index += (CurtPktPageNum * page_size);
//P2P invite rsp
rsvd_page_loc->LocInviteRsp = *page_num;
rtw_hal_construct_P2PInviteRsp(adapter, &pframe[index],
&P2PInviteRspLength);
rtw_hal_fill_fake_txdesc(adapter, &pframe[index-tx_desc],
P2PInviteRspLength, _FALSE, _FALSE, _FALSE);
//DBG_871X("%s(): HW_VAR_SET_TX_CMD: QOS NULL DATA %p %d\n",
//__FUNCTION__, &pframe[index-tx_desc], (InviteRspLength+tx_desc));
CurtPktPageNum = (u8)PageNum(tx_desc + P2PInviteRspLength, page_size);
*page_num += CurtPktPageNum;
index += (CurtPktPageNum * page_size);
//P2P provision discovery rsp
rsvd_page_loc->LocPDRsp = *page_num;
rtw_hal_construct_P2PProvisionDisRsp( adapter,
&pframe[index], &P2PPDRspLength);
rtw_hal_fill_fake_txdesc(adapter, &pframe[index-tx_desc],
P2PPDRspLength, _FALSE, _FALSE, _FALSE);
//DBG_871X("%s(): HW_VAR_SET_TX_CMD: QOS NULL DATA %p %d\n",
// __FUNCTION__, &pframe[index-tx_desc], (PDRspLength+tx_desc));
CurtPktPageNum = (u8)PageNum(tx_desc + P2PPDRspLength, page_size);
*page_num += CurtPktPageNum;
index += (CurtPktPageNum * page_size);
*total_pkt_len = index + P2PPDRspLength;
}
#endif //CONFIG_P2P_WOWLAN
/*
* Description: Fill the reserved packets that FW will use to RSVD page.
* Now we just send 4 types packet to rsvd page.
* (1)Beacon, (2)Ps-poll, (3)Null data, (4)ProbeRsp.
* Input:
* finished - FALSE:At the first time we will send all the packets as a large packet to Hw,
* so we need to set the packet length to total lengh.
* TRUE: At the second time, we should send the first packet (default:beacon)
* to Hw again and set the lengh in descriptor to the real beacon lengh.
* 2009.10.15 by tynli.
*
* Page Size = 128: 8188e, 8723a/b, 8192c/d,
* Page Size = 256: 8192e, 8821a
* Page Size = 512: 8812a
*/
void rtw_hal_set_fw_rsvd_page(_adapter* adapter, bool finished)
{
PHAL_DATA_TYPE pHalData;
struct xmit_frame *pcmdframe;
struct pkt_attrib *pattrib;
struct xmit_priv *pxmitpriv;
struct mlme_ext_priv *pmlmeext;
struct mlme_ext_info *pmlmeinfo;
struct pwrctrl_priv *pwrctl;
struct mlme_priv *pmlmepriv = &adapter->mlmepriv;
struct hal_ops *pHalFunc = &adapter->HalFunc;
u32 BeaconLength = 0, ProbeRspLength = 0, PSPollLength = 0;
u32 NullDataLength = 0, QosNullLength = 0, BTQosNullLength = 0;
u32 ProbeReqLength = 0, NullFunctionDataLength = 0;
u8 TxDescLen = TXDESC_SIZE, TxDescOffset = TXDESC_OFFSET;
u8 TotalPageNum = 0 , CurtPktPageNum = 0 , RsvdPageNum = 0;
u8 *ReservedPagePacket;
u16 BufIndex = 0;
u32 TotalPacketLen = 0, MaxRsvdPageBufSize = 0, PageSize = 0;
RSVDPAGE_LOC RsvdPageLoc;
#ifdef DBG_CONFIG_ERROR_DETECT
struct sreset_priv *psrtpriv;
#endif /* DBG_CONFIG_ERROR_DETECT */
pHalData = GET_HAL_DATA(adapter);
#ifdef DBG_CONFIG_ERROR_DETECT
psrtpriv = &pHalData->srestpriv;
#endif
pxmitpriv = &adapter->xmitpriv;
pmlmeext = &adapter->mlmeextpriv;
pmlmeinfo = &pmlmeext->mlmext_info;
pwrctl = adapter_to_pwrctl(adapter);
rtw_hal_get_def_var(adapter, HAL_DEF_TX_PAGE_SIZE, (u8 *)&PageSize);
if (PageSize == 0) {
DBG_871X("[Error]: %s, PageSize is zero!!\n", __func__);
return;
}
if (pwrctl->wowlan_mode == _TRUE || pwrctl->wowlan_ap_mode == _TRUE)
RsvdPageNum = rtw_hal_get_txbuff_rsvd_page_num(adapter, _TRUE);
else
RsvdPageNum = rtw_hal_get_txbuff_rsvd_page_num(adapter, _FALSE);
DBG_871X("%s PageSize: %d, RsvdPageNUm: %d\n",__func__, PageSize, RsvdPageNum);
MaxRsvdPageBufSize = RsvdPageNum*PageSize;
if (MaxRsvdPageBufSize > MAX_CMDBUF_SZ) {
DBG_871X("%s MaxRsvdPageBufSize(%d) is larger than MAX_CMDBUF_SZ(%d)",
__func__, MaxRsvdPageBufSize, MAX_CMDBUF_SZ);
rtw_warn_on(1);
return;
}
pcmdframe = rtw_alloc_cmdxmitframe(pxmitpriv);
if (pcmdframe == NULL) {
DBG_871X("%s: alloc ReservedPagePacket fail!\n", __FUNCTION__);
return;
}
ReservedPagePacket = pcmdframe->buf_addr;
_rtw_memset(&RsvdPageLoc, 0, sizeof(RSVDPAGE_LOC));
/* beacon * 2 pages */
BufIndex = TxDescOffset;
rtw_hal_construct_beacon(adapter,
&ReservedPagePacket[BufIndex], &BeaconLength);
/*
* When we count the first page size, we need to reserve description size for the RSVD
* packet, it will be filled in front of the packet in TXPKTBUF.
*/
CurtPktPageNum = (u8)PageNum((TxDescLen + BeaconLength), PageSize);
/* If we don't add 1 more page, ARP offload function will fail at 8723bs.*/
if (CurtPktPageNum == 1)
CurtPktPageNum += 1;
TotalPageNum += CurtPktPageNum;
BufIndex += (CurtPktPageNum*PageSize);
if (pwrctl->wowlan_ap_mode == _TRUE) {
/* (4) probe response*/
RsvdPageLoc.LocProbeRsp = TotalPageNum;
rtw_hal_construct_ProbeRsp(
adapter, &ReservedPagePacket[BufIndex],
&ProbeRspLength,
get_my_bssid(&pmlmeinfo->network), _FALSE);
rtw_hal_fill_fake_txdesc(adapter,
&ReservedPagePacket[BufIndex-TxDescLen],
ProbeRspLength, _FALSE, _FALSE, _FALSE);
CurtPktPageNum = (u8)PageNum(TxDescLen + BeaconLength, PageSize);
TotalPageNum += CurtPktPageNum;
BufIndex += (CurtPktPageNum*PageSize);
TotalPacketLen = BufIndex + ProbeRspLength;
goto download_page;
}
/* ps-poll * 1 page */
RsvdPageLoc.LocPsPoll = TotalPageNum;
DBG_871X("LocPsPoll: %d\n", RsvdPageLoc.LocPsPoll);
rtw_hal_construct_PSPoll(adapter,
&ReservedPagePacket[BufIndex], &PSPollLength);
rtw_hal_fill_fake_txdesc(adapter,
&ReservedPagePacket[BufIndex-TxDescLen],
PSPollLength, _TRUE, _FALSE, _FALSE);
CurtPktPageNum = (u8)PageNum((TxDescLen + PSPollLength), PageSize);
TotalPageNum += CurtPktPageNum;
BufIndex += (CurtPktPageNum*PageSize);
#ifdef CONFIG_BT_COEXIST
/* BT Qos null data * 1 page */
RsvdPageLoc.LocBTQosNull = TotalPageNum;
DBG_871X("LocBTQosNull: %d\n", RsvdPageLoc.LocBTQosNull);
rtw_hal_construct_NullFunctionData(
adapter,
&ReservedPagePacket[BufIndex],
&BTQosNullLength,
get_my_bssid(&pmlmeinfo->network),
_TRUE, 0, 0, _FALSE);
rtw_hal_fill_fake_txdesc(adapter,
&ReservedPagePacket[BufIndex-TxDescLen],
BTQosNullLength, _FALSE, _TRUE, _FALSE);
CurtPktPageNum = (u8)PageNum(TxDescLen + BTQosNullLength, PageSize);
TotalPageNum += CurtPktPageNum;
BufIndex += (CurtPktPageNum*PageSize);
#endif /* CONFIG_BT_COEXIT */
/* null data * 1 page */
RsvdPageLoc.LocNullData = TotalPageNum;
DBG_871X("LocNullData: %d\n", RsvdPageLoc.LocNullData);
rtw_hal_construct_NullFunctionData(
adapter,
&ReservedPagePacket[BufIndex],
&NullDataLength,
get_my_bssid(&pmlmeinfo->network),
_FALSE, 0, 0, _FALSE);
rtw_hal_fill_fake_txdesc(adapter,
&ReservedPagePacket[BufIndex-TxDescLen],
NullDataLength, _FALSE, _FALSE, _FALSE);
CurtPktPageNum = (u8)PageNum(TxDescLen + NullDataLength, PageSize);
TotalPageNum += CurtPktPageNum;
BufIndex += (CurtPktPageNum*PageSize);
//Qos null data * 1 page
RsvdPageLoc.LocQosNull = TotalPageNum;
DBG_871X("LocQosNull: %d\n", RsvdPageLoc.LocQosNull);
rtw_hal_construct_NullFunctionData(
adapter,
&ReservedPagePacket[BufIndex],
&QosNullLength,
get_my_bssid(&pmlmeinfo->network),
_TRUE, 0, 0, _FALSE);
rtw_hal_fill_fake_txdesc(adapter,
&ReservedPagePacket[BufIndex-TxDescLen],
QosNullLength, _FALSE, _FALSE, _FALSE);
CurtPktPageNum = (u8)PageNum(TxDescLen + QosNullLength, PageSize);
TotalPageNum += CurtPktPageNum;
BufIndex += (CurtPktPageNum*PageSize);
TotalPacketLen = BufIndex + QosNullLength;
#ifdef CONFIG_WOWLAN
if (pwrctl->wowlan_mode == _TRUE &&
check_fwstate(pmlmepriv, _FW_LINKED) == _TRUE) {
rtw_hal_set_wow_fw_rsvd_page(adapter, ReservedPagePacket,
BufIndex, TxDescLen, PageSize,
&TotalPageNum, &TotalPacketLen, &RsvdPageLoc);
}
#endif /* CONFIG_WOWLAN */
#ifdef CONFIG_P2P_WOWLAN
if(_TRUE == pwrctl->wowlan_p2p_mode) {
rtw_hal_set_p2p_wow_fw_rsvd_page(adapter, ReservedPagePacket,
BufIndex, TxDescLen, PageSize,
&TotalPageNum, &TotalPacketLen, &RsvdPageLoc);
}
#endif /* CONFIG_P2P_WOWLAN */
download_page:
DBG_871X("%s BufIndex(%d), TxDescLen(%d), PageSize(%d)\n",
__func__, BufIndex, TxDescLen, PageSize);
DBG_871X("%s PageNum(%d), pktlen(%d)\n",
__func__, TotalPageNum, TotalPacketLen);
if (TotalPacketLen > MaxRsvdPageBufSize) {
DBG_871X("%s(ERROR): rsvd page size is not enough!!TotalPacketLen %d, MaxRsvdPageBufSize %d\n",
__FUNCTION__, TotalPacketLen,MaxRsvdPageBufSize);
rtw_warn_on(1);
goto error;
} else {
/* update attribute */
pattrib = &pcmdframe->attrib;
update_mgntframe_attrib(adapter, pattrib);
pattrib->qsel = QSLT_BEACON;
pattrib->pktlen = TotalPacketLen - TxDescOffset;
pattrib->last_txcmdsz = TotalPacketLen - TxDescOffset;
#ifdef CONFIG_PCI_HCI
dump_mgntframe(adapter, pcmdframe);
#else
dump_mgntframe_and_wait(adapter, pcmdframe, 100);
#endif
}
DBG_871X("%s: Set RSVD page location to Fw ,TotalPacketLen(%d), TotalPageNum(%d)\n",
__func__,TotalPacketLen,TotalPageNum);
if(check_fwstate(pmlmepriv, _FW_LINKED) == _TRUE) {
rtw_hal_set_FwRsvdPage_cmd(adapter, &RsvdPageLoc);
if (pwrctl->wowlan_mode == _TRUE)
rtw_hal_set_FwAoacRsvdPage_cmd(adapter, &RsvdPageLoc);
#ifdef CONFIG_AP_WOWLAN
if (pwrctl->wowlan_ap_mode == _TRUE)
rtw_hal_set_ap_rsvdpage_loc_cmd(adapter, &RsvdPageLoc);
#endif /* CONFIG_AP_WOWLAN */
} else if (pwrctl->wowlan_pno_enable) {
#ifdef CONFIG_PNO_SUPPORT
rtw_hal_set_FwAoacRsvdPage_cmd(adapter, &RsvdPageLoc);
if(pwrctl->pno_in_resume)
rtw_hal_set_scan_offload_info_cmd(adapter,
&RsvdPageLoc, 0);
else
rtw_hal_set_scan_offload_info_cmd(adapter,
&RsvdPageLoc, 1);
#endif /* CONFIG_PNO_SUPPORT */
}
#ifdef CONFIG_P2P_WOWLAN
if(_TRUE == pwrctl->wowlan_p2p_mode)
rtw_hal_set_FwP2PRsvdPage_cmd(adapter, &RsvdPageLoc);
#endif /* CONFIG_P2P_WOWLAN */
return;
error:
rtw_free_xmitframe(pxmitpriv, pcmdframe);
}
void SetHwReg(_adapter *adapter, u8 variable, u8 *val)
{
HAL_DATA_TYPE *hal_data = GET_HAL_DATA(adapter);
_func_enter_;
switch (variable) {
case HW_VAR_PORT_SWITCH:
hw_var_port_switch(adapter);
break;
case HW_VAR_INIT_RTS_RATE:
{
u16 brate_cfg = *((u16*)val);
u8 rate_index = 0;
HAL_VERSION *hal_ver = &hal_data->VersionID;
if (IS_8188E(*hal_ver)) {
while (brate_cfg > 0x1) {
brate_cfg = (brate_cfg >> 1);
rate_index++;
}
rtw_write8(adapter, REG_INIRTS_RATE_SEL, rate_index);
} else {
rtw_warn_on(1);
}
}
break;
case HW_VAR_SEC_CFG:
{
#if defined(CONFIG_CONCURRENT_MODE) && !defined(DYNAMIC_CAMID_ALLOC)
// enable tx enc and rx dec engine, and no key search for MC/BC
rtw_write8(adapter, REG_SECCFG, SCR_NoSKMC|SCR_RxDecEnable|SCR_TxEncEnable);
#elif defined(DYNAMIC_CAMID_ALLOC)
u16 reg_scr_ori;
u16 reg_scr;
reg_scr = reg_scr_ori = rtw_read16(adapter, REG_SECCFG);
reg_scr |= (SCR_CHK_KEYID|SCR_RxDecEnable|SCR_TxEncEnable);
if (_rtw_camctl_chk_cap(adapter, SEC_CAP_CHK_BMC))
reg_scr |= SCR_CHK_BMC;
if (_rtw_camctl_chk_flags(adapter, SEC_STATUS_STA_PK_GK_CONFLICT_DIS_BMC_SEARCH))
reg_scr |= SCR_NoSKMC;
if (reg_scr != reg_scr_ori)
rtw_write16(adapter, REG_SECCFG, reg_scr);
#else
rtw_write8(adapter, REG_SECCFG, *((u8*)val));
#endif
}
break;
case HW_VAR_SEC_DK_CFG:
{
struct security_priv *sec = &adapter->securitypriv;
u8 reg_scr = rtw_read8(adapter, REG_SECCFG);
if (val) /* Enable default key related setting */
{
reg_scr |= SCR_TXBCUSEDK;
if (sec->dot11AuthAlgrthm != dot11AuthAlgrthm_8021X)
reg_scr |= (SCR_RxUseDK|SCR_TxUseDK);
}
else /* Disable default key related setting */
{
reg_scr &= ~(SCR_RXBCUSEDK|SCR_TXBCUSEDK|SCR_RxUseDK|SCR_TxUseDK);
}
rtw_write8(adapter, REG_SECCFG, reg_scr);
}
break;
case HW_VAR_ASIX_IOT:
// enable ASIX IOT function
if (*((u8*)val) == _TRUE) {
// 0xa2e[0]=0 (disable rake receiver)
rtw_write8(adapter, rCCK0_FalseAlarmReport+2,
rtw_read8(adapter, rCCK0_FalseAlarmReport+2) & ~(BIT0));
// 0xa1c=0xa0 (reset channel estimation if signal quality is bad)
rtw_write8(adapter, rCCK0_DSPParameter2, 0xa0);
} else {
// restore reg:0xa2e, reg:0xa1c
rtw_write8(adapter, rCCK0_FalseAlarmReport+2,
rtw_read8(adapter, rCCK0_FalseAlarmReport+2)|(BIT0));
rtw_write8(adapter, rCCK0_DSPParameter2, 0x00);
}
break;
#if defined(CONFIG_WOWLAN) || defined(CONFIG_AP_WOWLAN)
case HW_VAR_WOWLAN:
{
struct wowlan_ioctl_param *poidparam;
poidparam = (struct wowlan_ioctl_param *)val;
switch (poidparam->subcode) {
#ifdef CONFIG_WOWLAN
case WOWLAN_PATTERN_CLEAN:
rtw_hal_dl_pattern(adapter, _TRUE);
break;
case WOWLAN_ENABLE:
rtw_hal_wow_enable(adapter);
break;
case WOWLAN_DISABLE:
rtw_hal_wow_disable(adapter);
break;
#endif /*CONFIG_WOWLAN*/
#ifdef CONFIG_AP_WOWLAN
case WOWLAN_AP_ENABLE:
rtw_hal_ap_wow_enable(adapter);
break;
case WOWLAN_AP_DISABLE:
rtw_hal_ap_wow_disable(adapter);
break;
#endif /*CONFIG_AP_WOWLAN*/
default:
break;
}
}
break;
#endif /*defined(CONFIG_WOWLAN) || defined(CONFIG_AP_WOWLAN)*/
default:
if (0)
DBG_871X_LEVEL(_drv_always_, FUNC_ADPT_FMT" variable(%d) not defined!\n",
FUNC_ADPT_ARG(adapter), variable);
break;
}
_func_exit_;
}
void GetHwReg(_adapter *adapter, u8 variable, u8 *val)
{
HAL_DATA_TYPE *hal_data = GET_HAL_DATA(adapter);
_func_enter_;
switch (variable) {
case HW_VAR_BASIC_RATE:
*((u16*)val) = hal_data->BasicRateSet;
break;
case HW_VAR_RF_TYPE:
*((u8*)val) = hal_data->rf_type;
break;
default:
if (0)
DBG_871X_LEVEL(_drv_always_, FUNC_ADPT_FMT" variable(%d) not defined!\n",
FUNC_ADPT_ARG(adapter), variable);
break;
}
_func_exit_;
}
u8
SetHalDefVar(_adapter *adapter, HAL_DEF_VARIABLE variable, void *value)
{
HAL_DATA_TYPE *hal_data = GET_HAL_DATA(adapter);
u8 bResult = _SUCCESS;
switch(variable) {
case HAL_DEF_DBG_DUMP_RXPKT:
hal_data->bDumpRxPkt = *((u8*)value);
break;
case HAL_DEF_DBG_DUMP_TXPKT:
hal_data->bDumpTxPkt = *((u8*)value);
break;
case HAL_DEF_ANT_DETECT:
hal_data->AntDetection = *((u8 *)value);
break;
case HAL_DEF_DBG_DIS_PWT:
hal_data->bDisableTXPowerTraining = *((u8*)value);
break;
default:
DBG_871X_LEVEL(_drv_always_, "%s: [WARNING] HAL_DEF_VARIABLE(%d) not defined!\n", __FUNCTION__, variable);
bResult = _FAIL;
break;
}
return bResult;
}
#ifdef CONFIG_BEAMFORMING
u8 rtw_hal_query_txbfer_rf_num(_adapter *adapter)
{
struct registry_priv *pregistrypriv = &adapter->registrypriv;
HAL_DATA_TYPE *hal_data = GET_HAL_DATA(adapter);
if ((pregistrypriv->beamformer_rf_num) && (IS_HARDWARE_TYPE_8814AE(adapter) || IS_HARDWARE_TYPE_8814AU(adapter) || IS_HARDWARE_TYPE_8822BU(adapter)))
return pregistrypriv->beamformer_rf_num;
else if (IS_HARDWARE_TYPE_8814AE(adapter)
/*
#if defined(CONFIG_USB_HCI)
|| (IS_HARDWARE_TYPE_8814AU(adapter) && (pUsbModeMech->CurUsbMode == 2 || pUsbModeMech->HubUsbMode == 2)) //for USB3.0
#endif
*/
) {
/*BF cap provided by Yu Chen, Sean, 2015, 01 */
if (hal_data->rf_type == RF_3T3R)
return 2;
else if (hal_data->rf_type == RF_4T4R)
return 3;
else
return 1;
} else
return 1;
}
u8 rtw_hal_query_txbfee_rf_num(_adapter *adapter)
{
struct registry_priv *pregistrypriv = &adapter->registrypriv;
struct mlme_ext_priv *pmlmeext = &adapter->mlmeextpriv;
struct mlme_ext_info *pmlmeinfo = &(pmlmeext->mlmext_info);
HAL_DATA_TYPE *hal_data = GET_HAL_DATA(adapter);
if ((pregistrypriv->beamformee_rf_num) && (IS_HARDWARE_TYPE_8814AE(adapter) || IS_HARDWARE_TYPE_8814AU(adapter) || IS_HARDWARE_TYPE_8822BU(adapter)))
return pregistrypriv->beamformee_rf_num;
else if (IS_HARDWARE_TYPE_8814AE(adapter) || IS_HARDWARE_TYPE_8814AU(adapter)) {
if (pmlmeinfo->assoc_AP_vendor == HT_IOT_PEER_BROADCOM)
return 2;
else
return 2;/*TODO: May be 3 in the future, by ChenYu. */
} else
return 1;
}
#endif
u8
GetHalDefVar(_adapter *adapter, HAL_DEF_VARIABLE variable, void *value)
{
HAL_DATA_TYPE *hal_data = GET_HAL_DATA(adapter);
u8 bResult = _SUCCESS;
switch(variable) {
case HAL_DEF_UNDERCORATEDSMOOTHEDPWDB:
{
struct mlme_priv *pmlmepriv;
struct sta_priv *pstapriv;
struct sta_info *psta;
pmlmepriv = &adapter->mlmepriv;
pstapriv = &adapter->stapriv;
psta = rtw_get_stainfo(pstapriv, pmlmepriv->cur_network.network.MacAddress);
if (psta)
{
*((int*)value) = psta->rssi_stat.UndecoratedSmoothedPWDB;
}
}
break;
case HAL_DEF_DBG_DUMP_RXPKT:
*((u8*)value) = hal_data->bDumpRxPkt;
break;
case HAL_DEF_DBG_DUMP_TXPKT:
*((u8*)value) = hal_data->bDumpTxPkt;
break;
case HAL_DEF_ANT_DETECT:
*((u8 *)value) = hal_data->AntDetection;
break;
case HAL_DEF_MACID_SLEEP:
*(u8*)value = _FALSE;
break;
case HAL_DEF_TX_PAGE_SIZE:
*(( u32*)value) = PAGE_SIZE_128;
break;
case HAL_DEF_DBG_DIS_PWT:
*(u8*)value = hal_data->bDisableTXPowerTraining;
break;
#ifdef CONFIG_BEAMFORMING
case HAL_DEF_BEAMFORMER_CAP:
*(u8 *)value = rtw_hal_query_txbfer_rf_num(adapter);
break;
case HAL_DEF_BEAMFORMEE_CAP:
*(u8 *)value = rtw_hal_query_txbfee_rf_num(adapter);
break;
#endif
default:
DBG_871X_LEVEL(_drv_always_, "%s: [WARNING] HAL_DEF_VARIABLE(%d) not defined!\n", __FUNCTION__, variable);
bResult = _FAIL;
break;
}
return bResult;
}
void SetHalODMVar(
PADAPTER Adapter,
HAL_ODM_VARIABLE eVariable,
PVOID pValue1,
BOOLEAN bSet)
{
HAL_DATA_TYPE *pHalData = GET_HAL_DATA(Adapter);
PDM_ODM_T podmpriv = &pHalData->odmpriv;
//_irqL irqL;
switch(eVariable){
case HAL_ODM_STA_INFO:
{
struct sta_info *psta = (struct sta_info *)pValue1;
if(bSet){
DBG_8192C("### Set STA_(%d) info ###\n",psta->mac_id);
ODM_CmnInfoPtrArrayHook(podmpriv, ODM_CMNINFO_STA_STATUS,psta->mac_id,psta);
}
else{
DBG_8192C("### Clean STA_(%d) info ###\n",psta->mac_id);
//_enter_critical_bh(&pHalData->odm_stainfo_lock, &irqL);
ODM_CmnInfoPtrArrayHook(podmpriv, ODM_CMNINFO_STA_STATUS,psta->mac_id,NULL);
//_exit_critical_bh(&pHalData->odm_stainfo_lock, &irqL);
}
}
break;
case HAL_ODM_P2P_STATE:
ODM_CmnInfoUpdate(podmpriv,ODM_CMNINFO_WIFI_DIRECT,bSet);
break;
case HAL_ODM_WIFI_DISPLAY_STATE:
ODM_CmnInfoUpdate(podmpriv,ODM_CMNINFO_WIFI_DISPLAY,bSet);
break;
case HAL_ODM_REGULATION:
ODM_CmnInfoInit(podmpriv, ODM_CMNINFO_DOMAIN_CODE_2G, pHalData->Regulation2_4G);
ODM_CmnInfoInit(podmpriv, ODM_CMNINFO_DOMAIN_CODE_5G, pHalData->Regulation5G);
break;
#if defined(CONFIG_SIGNAL_DISPLAY_DBM) && defined(CONFIG_BACKGROUND_NOISE_MONITOR)
case HAL_ODM_NOISE_MONITOR:
{
struct noise_info *pinfo = (struct noise_info *)pValue1;
#ifdef DBG_NOISE_MONITOR
DBG_8192C("### Noise monitor chan(%d)-bPauseDIG:%d,IGIValue:0x%02x,max_time:%d (ms) ###\n",
pinfo->chan,pinfo->bPauseDIG,pinfo->IGIValue,pinfo->max_time);
#endif
pHalData->noise[pinfo->chan] = ODM_InbandNoise_Monitor(podmpriv,pinfo->bPauseDIG,pinfo->IGIValue,pinfo->max_time);
DBG_871X("chan_%d, noise = %d (dBm)\n",pinfo->chan,pHalData->noise[pinfo->chan]);
#ifdef DBG_NOISE_MONITOR
DBG_871X("noise_a = %d, noise_b = %d noise_all:%d \n",
podmpriv->noise_level.noise[ODM_RF_PATH_A],
podmpriv->noise_level.noise[ODM_RF_PATH_B],
podmpriv->noise_level.noise_all);
#endif
}
break;
#endif/*#ifdef CONFIG_BACKGROUND_NOISE_MONITOR*/
case HAL_ODM_INITIAL_GAIN:
{
u8 rx_gain = *((u8 *)(pValue1));
/*printk("rx_gain:%x\n",rx_gain);*/
if (rx_gain == 0xff) {/*restore rx gain*/
/*ODM_Write_DIG(podmpriv,pDigTable->BackupIGValue);*/
odm_PauseDIG(podmpriv, PHYDM_RESUME, PHYDM_PAUSE_LEVEL_0, rx_gain);
} else {
/*pDigTable->BackupIGValue = pDigTable->CurIGValue;*/
/*ODM_Write_DIG(podmpriv,rx_gain);*/
odm_PauseDIG(podmpriv, PHYDM_PAUSE, PHYDM_PAUSE_LEVEL_0, rx_gain);
}
}
break;
case HAL_ODM_FA_CNT_DUMP:
if (*((u8 *)pValue1))
podmpriv->DebugComponents |= (ODM_COMP_DIG | ODM_COMP_FA_CNT);
else
podmpriv->DebugComponents &= ~(ODM_COMP_DIG | ODM_COMP_FA_CNT);
break;
case HAL_ODM_DBG_FLAG:
ODM_CmnInfoUpdate(podmpriv, ODM_CMNINFO_DBG_COMP, *((u8Byte *)pValue1));
break;
case HAL_ODM_DBG_LEVEL:
ODM_CmnInfoUpdate(podmpriv, ODM_CMNINFO_DBG_LEVEL, *((u4Byte *)pValue1));
break;
case HAL_ODM_RX_INFO_DUMP:
{
PFALSE_ALARM_STATISTICS FalseAlmCnt = (PFALSE_ALARM_STATISTICS)PhyDM_Get_Structure(podmpriv , PHYDM_FALSEALMCNT);
pDIG_T pDM_DigTable = &podmpriv->DM_DigTable;
DBG_871X("============ Rx Info dump ===================\n");
DBG_871X("bLinked = %d, RSSI_Min = %d(%%), CurrentIGI = 0x%x\n",
podmpriv->bLinked, podmpriv->RSSI_Min, pDM_DigTable->CurIGValue);
if (FalseAlmCnt)
DBG_871X("Cnt_Cck_fail = %d, Cnt_Ofdm_fail = %d, Total False Alarm = %d\n",
FalseAlmCnt->Cnt_Cck_fail, FalseAlmCnt->Cnt_Ofdm_fail, FalseAlmCnt->Cnt_all);
if (podmpriv->bLinked) {
DBG_871X("RxRate = %s, RSSI_A = %d(%%), RSSI_B = %d(%%)\n",
HDATA_RATE(podmpriv->RxRate), podmpriv->RSSI_A, podmpriv->RSSI_B);
#ifdef DBG_RX_SIGNAL_DISPLAY_RAW_DATA
rtw_dump_raw_rssi_info(Adapter);
#endif
}
}
break;
#ifdef CONFIG_AUTO_CHNL_SEL_NHM
case HAL_ODM_AUTO_CHNL_SEL:
{
ACS_OP acs_op = *(ACS_OP *)pValue1;
rtw_phydm_func_set(Adapter, ODM_BB_NHM_CNT);
if (ACS_INIT == acs_op) {
#ifdef DBG_AUTO_CHNL_SEL_NHM
DBG_871X("[ACS-"ADPT_FMT"] HAL_ODM_AUTO_CHNL_SEL: ACS_INIT\n", ADPT_ARG(Adapter));
#endif
odm_AutoChannelSelectInit(podmpriv);
} else if (ACS_RESET == acs_op) {
/* Reset statistics for auto channel selection mechanism.*/
#ifdef DBG_AUTO_CHNL_SEL_NHM
DBG_871X("[ACS-"ADPT_FMT"] HAL_ODM_AUTO_CHNL_SEL: ACS_RESET\n", ADPT_ARG(Adapter));
#endif
odm_AutoChannelSelectReset(podmpriv);
} else if (ACS_SELECT == acs_op) {
/* Collect NHM measurement result after current channel */
#ifdef DBG_AUTO_CHNL_SEL_NHM
DBG_871X("[ACS-"ADPT_FMT"] HAL_ODM_AUTO_CHNL_SEL: ACS_SELECT, CH(%d)\n", ADPT_ARG(Adapter), rtw_get_acs_channel(Adapter));
#endif
odm_AutoChannelSelect(podmpriv, rtw_get_acs_channel(Adapter));
} else
DBG_871X("[ACS-"ADPT_FMT"] HAL_ODM_AUTO_CHNL_SEL: Unexpected OP\n", ADPT_ARG(Adapter));
}
break;
#endif
default:
break;
}
}
void GetHalODMVar(
PADAPTER Adapter,
HAL_ODM_VARIABLE eVariable,
PVOID pValue1,
PVOID pValue2)
{
HAL_DATA_TYPE *pHalData = GET_HAL_DATA(Adapter);
PDM_ODM_T podmpriv = &pHalData->odmpriv;
switch (eVariable) {
#if defined(CONFIG_SIGNAL_DISPLAY_DBM) && defined(CONFIG_BACKGROUND_NOISE_MONITOR)
case HAL_ODM_NOISE_MONITOR:
{
u8 chan = *(u8 *)pValue1;
*(s16 *)pValue2 = pHalData->noise[chan];
#ifdef DBG_NOISE_MONITOR
DBG_8192C("### Noise monitor chan(%d)-noise:%d (dBm) ###\n",
chan, pHalData->noise[chan]);
#endif
}
break;
#endif/*#ifdef CONFIG_BACKGROUND_NOISE_MONITOR*/
case HAL_ODM_DBG_FLAG:
*((u8Byte *)pValue1) = podmpriv->DebugComponents;
break;
case HAL_ODM_DBG_LEVEL:
*((u4Byte *)pValue1) = podmpriv->DebugLevel;
break;
#ifdef CONFIG_AUTO_CHNL_SEL_NHM
case HAL_ODM_AUTO_CHNL_SEL:
{
#ifdef DBG_AUTO_CHNL_SEL_NHM
DBG_871X("[ACS-"ADPT_FMT"] HAL_ODM_AUTO_CHNL_SEL: GET_BEST_CHAN\n", ADPT_ARG(Adapter));
#endif
/* Retrieve better channel from NHM mechanism */
if (IsSupported24G(Adapter->registrypriv.wireless_mode))
*((u8 *)(pValue1)) = ODM_GetAutoChannelSelectResult(podmpriv, BAND_ON_2_4G);
if (IsSupported5G(Adapter->registrypriv.wireless_mode))
*((u8 *)(pValue2)) = ODM_GetAutoChannelSelectResult(podmpriv, BAND_ON_5G);
}
break;
#endif
default:
break;
}
}
u32 rtw_phydm_ability_ops(_adapter *adapter, HAL_PHYDM_OPS ops, u32 ability)
{
HAL_DATA_TYPE *pHalData = GET_HAL_DATA(adapter);
PDM_ODM_T podmpriv = &pHalData->odmpriv;
u32 result = 0;
switch (ops) {
case HAL_PHYDM_DIS_ALL_FUNC:
podmpriv->SupportAbility = DYNAMIC_FUNC_DISABLE;
break;
case HAL_PHYDM_FUNC_SET:
podmpriv->SupportAbility |= ability;
break;
case HAL_PHYDM_FUNC_CLR:
podmpriv->SupportAbility &= ~(ability);
break;
case HAL_PHYDM_ABILITY_BK:
/* dm flag backup*/
podmpriv->BK_SupportAbility = podmpriv->SupportAbility;
break;
case HAL_PHYDM_ABILITY_RESTORE:
/* restore dm flag */
podmpriv->SupportAbility = podmpriv->BK_SupportAbility;
break;
case HAL_PHYDM_ABILITY_SET:
podmpriv->SupportAbility = ability;
break;
case HAL_PHYDM_ABILITY_GET:
result = podmpriv->SupportAbility;
break;
}
return result;
}
BOOLEAN
eqNByte(
u8* str1,
u8* str2,
u32 num
)
{
if(num==0)
return _FALSE;
while(num>0)
{
num--;
if(str1[num]!=str2[num])
return _FALSE;
}
return _TRUE;
}
//
// Description:
// Return TRUE if chTmp is represent for hex digit and
// FALSE otherwise.
//
//
BOOLEAN
IsHexDigit(
IN char chTmp
)
{
if( (chTmp >= '0' && chTmp <= '9') ||
(chTmp >= 'a' && chTmp <= 'f') ||
(chTmp >= 'A' && chTmp <= 'F') )
{
return _TRUE;
}
else
{
return _FALSE;
}
}
//
// Description:
// Translate a character to hex digit.
//
u32
MapCharToHexDigit(
IN char chTmp
)
{
if(chTmp >= '0' && chTmp <= '9')
return (chTmp - '0');
else if(chTmp >= 'a' && chTmp <= 'f')
return (10 + (chTmp - 'a'));
else if(chTmp >= 'A' && chTmp <= 'F')
return (10 + (chTmp - 'A'));
else
return 0;
}
//
// Description:
// Parse hex number from the string pucStr.
//
BOOLEAN
GetHexValueFromString(
IN char* szStr,
IN OUT u32* pu4bVal,
IN OUT u32* pu4bMove
)
{
char* szScan = szStr;
// Check input parameter.
if(szStr == NULL || pu4bVal == NULL || pu4bMove == NULL)
{
DBG_871X("GetHexValueFromString(): Invalid inpur argumetns! szStr: %p, pu4bVal: %p, pu4bMove: %p\n", szStr, pu4bVal, pu4bMove);
return _FALSE;
}
// Initialize output.
*pu4bMove = 0;
*pu4bVal = 0;
// Skip leading space.
while( *szScan != '\0' &&
(*szScan == ' ' || *szScan == '\t') )
{
szScan++;
(*pu4bMove)++;
}
// Skip leading '0x' or '0X'.
if(*szScan == '0' && (*(szScan+1) == 'x' || *(szScan+1) == 'X'))
{
szScan += 2;
(*pu4bMove) += 2;
}
// Check if szScan is now pointer to a character for hex digit,
// if not, it means this is not a valid hex number.
if(!IsHexDigit(*szScan))
{
return _FALSE;
}
// Parse each digit.
do
{
(*pu4bVal) <<= 4;
*pu4bVal += MapCharToHexDigit(*szScan);
szScan++;
(*pu4bMove)++;
} while(IsHexDigit(*szScan));
return _TRUE;
}
BOOLEAN
GetFractionValueFromString(
IN char* szStr,
IN OUT u8* pInteger,
IN OUT u8* pFraction,
IN OUT u32* pu4bMove
)
{
char *szScan = szStr;
// Initialize output.
*pu4bMove = 0;
*pInteger = 0;
*pFraction = 0;
// Skip leading space.
while ( *szScan != '\0' && (*szScan == ' ' || *szScan == '\t') ) {
++szScan;
++(*pu4bMove);
}
// Parse each digit.
do {
(*pInteger) *= 10;
*pInteger += ( *szScan - '0' );
++szScan;
++(*pu4bMove);
if ( *szScan == '.' )
{
++szScan;
++(*pu4bMove);
if ( *szScan < '0' || *szScan > '9' )
return _FALSE;
else {
*pFraction = *szScan - '0';
++szScan;
++(*pu4bMove);
return _TRUE;
}
}
} while(*szScan >= '0' && *szScan <= '9');
return _TRUE;
}
//
// Description:
// Return TRUE if szStr is comment out with leading "//".
//
BOOLEAN
IsCommentString(
IN char *szStr
)
{
if(*szStr == '/' && *(szStr+1) == '/')
{
return _TRUE;
}
else
{
return _FALSE;
}
}
BOOLEAN
GetU1ByteIntegerFromStringInDecimal(
IN char* Str,
IN OUT u8* pInt
)
{
u16 i = 0;
*pInt = 0;
while ( Str[i] != '\0' )
{
if ( Str[i] >= '0' && Str[i] <= '9' )
{
*pInt *= 10;
*pInt += ( Str[i] - '0' );
}
else
{
return _FALSE;
}
++i;
}
return _TRUE;
}
// <20121004, Kordan> For example,
// ParseQualifiedString(inString, 0, outString, '[', ']') gets "Kordan" from a string "Hello [Kordan]".
// If RightQualifier does not exist, it will hang on in the while loop
BOOLEAN
ParseQualifiedString(
IN char* In,
IN OUT u32* Start,
OUT char* Out,
IN char LeftQualifier,
IN char RightQualifier
)
{
u32 i = 0, j = 0;
char c = In[(*Start)++];
if (c != LeftQualifier)
return _FALSE;
i = (*Start);
while ((c = In[(*Start)++]) != RightQualifier)
; // find ']'
j = (*Start) - 2;
strncpy((char *)Out, (const char*)(In+i), j-i+1);
return _TRUE;
}
BOOLEAN
isAllSpaceOrTab(
u8* data,
u8 size
)
{
u8 cnt = 0, NumOfSpaceAndTab = 0;
while( size > cnt )
{
if ( data[cnt] == ' ' || data[cnt] == '\t' || data[cnt] == '\0' )
++NumOfSpaceAndTab;
++cnt;
}
return size == NumOfSpaceAndTab;
}
void rtw_hal_check_rxfifo_full(_adapter *adapter)
{
struct dvobj_priv *psdpriv = adapter->dvobj;
struct debug_priv *pdbgpriv = &psdpriv->drv_dbg;
HAL_DATA_TYPE *pHalData = GET_HAL_DATA(adapter);
int save_cnt=_FALSE;
//switch counter to RX fifo
if (IS_8188E(pHalData->VersionID) || IS_8188F(pHalData->VersionID)
|| IS_8812_SERIES(pHalData->VersionID) || IS_8821_SERIES(pHalData->VersionID)
|| IS_8723B_SERIES(pHalData->VersionID) || IS_8192E(pHalData->VersionID) || IS_8703B_SERIES(pHalData->VersionID))
{
rtw_write8(adapter, REG_RXERR_RPT+3, rtw_read8(adapter, REG_RXERR_RPT+3)|0xa0);
save_cnt = _TRUE;
}
else
{
//todo: other chips
}
if (save_cnt) {
pdbgpriv->dbg_rx_fifo_last_overflow = pdbgpriv->dbg_rx_fifo_curr_overflow;
pdbgpriv->dbg_rx_fifo_curr_overflow = rtw_read16(adapter, REG_RXERR_RPT);
pdbgpriv->dbg_rx_fifo_diff_overflow = pdbgpriv->dbg_rx_fifo_curr_overflow-pdbgpriv->dbg_rx_fifo_last_overflow;
} else {
/* special value to indicate no implementation */
pdbgpriv->dbg_rx_fifo_last_overflow = 1;
pdbgpriv->dbg_rx_fifo_curr_overflow = 1;
pdbgpriv->dbg_rx_fifo_diff_overflow = 1;
}
}
void linked_info_dump(_adapter *padapter,u8 benable)
{
struct pwrctrl_priv *pwrctrlpriv = adapter_to_pwrctl(padapter);
if(padapter->bLinkInfoDump == benable)
return;
DBG_871X("%s %s \n",__FUNCTION__,(benable)?"enable":"disable");
if(benable){
#ifdef CONFIG_LPS
pwrctrlpriv->org_power_mgnt = pwrctrlpriv->power_mgnt;//keep org value
rtw_pm_set_lps(padapter,PS_MODE_ACTIVE);
#endif
#ifdef CONFIG_IPS
pwrctrlpriv->ips_org_mode = pwrctrlpriv->ips_mode;//keep org value
rtw_pm_set_ips(padapter,IPS_NONE);
#endif
}
else{
#ifdef CONFIG_IPS
rtw_pm_set_ips(padapter, pwrctrlpriv->ips_org_mode);
#endif // CONFIG_IPS
#ifdef CONFIG_LPS
rtw_pm_set_lps(padapter, pwrctrlpriv->org_power_mgnt );
#endif // CONFIG_LPS
}
padapter->bLinkInfoDump = benable ;
}
#ifdef DBG_RX_SIGNAL_DISPLAY_RAW_DATA
void rtw_get_raw_rssi_info(void *sel, _adapter *padapter)
{
u8 isCCKrate,rf_path;
PHAL_DATA_TYPE pHalData = GET_HAL_DATA(padapter);
struct rx_raw_rssi *psample_pkt_rssi = &padapter->recvpriv.raw_rssi_info;
DBG_871X_SEL_NL(sel,"RxRate = %s, PWDBALL = %d(%%), rx_pwr_all = %d(dBm)\n",
HDATA_RATE(psample_pkt_rssi->data_rate), psample_pkt_rssi->pwdball, psample_pkt_rssi->pwr_all);
isCCKrate = (psample_pkt_rssi->data_rate <= DESC_RATE11M)?TRUE :FALSE;
if(isCCKrate)
psample_pkt_rssi->mimo_signal_strength[0] = psample_pkt_rssi->pwdball;
for(rf_path = 0;rf_path<pHalData->NumTotalRFPath;rf_path++)
{
DBG_871X_SEL_NL(sel, "RF_PATH_%d=>signal_strength:%d(%%),signal_quality:%d(%%)\n"
, rf_path, psample_pkt_rssi->mimo_signal_strength[rf_path], psample_pkt_rssi->mimo_signal_quality[rf_path]);
if(!isCCKrate){
DBG_871X_SEL_NL(sel,"\trx_ofdm_pwr:%d(dBm),rx_ofdm_snr:%d(dB)\n",
psample_pkt_rssi->ofdm_pwr[rf_path],psample_pkt_rssi->ofdm_snr[rf_path]);
}
}
}
void rtw_dump_raw_rssi_info(_adapter *padapter)
{
u8 isCCKrate,rf_path;
PHAL_DATA_TYPE pHalData = GET_HAL_DATA(padapter);
struct rx_raw_rssi *psample_pkt_rssi = &padapter->recvpriv.raw_rssi_info;
DBG_871X("============ RAW Rx Info dump ===================\n");
DBG_871X("RxRate = %s, PWDBALL = %d(%%), rx_pwr_all = %d(dBm)\n",
HDATA_RATE(psample_pkt_rssi->data_rate), psample_pkt_rssi->pwdball, psample_pkt_rssi->pwr_all);
isCCKrate = (psample_pkt_rssi->data_rate <= DESC_RATE11M)?TRUE :FALSE;
if(isCCKrate)
psample_pkt_rssi->mimo_signal_strength[0] = psample_pkt_rssi->pwdball;
for(rf_path = 0;rf_path<pHalData->NumTotalRFPath;rf_path++)
{
DBG_871X("RF_PATH_%d=>signal_strength:%d(%%),signal_quality:%d(%%)"
, rf_path, psample_pkt_rssi->mimo_signal_strength[rf_path], psample_pkt_rssi->mimo_signal_quality[rf_path]);
if(!isCCKrate){
printk(",rx_ofdm_pwr:%d(dBm),rx_ofdm_snr:%d(dB)\n",
psample_pkt_rssi->ofdm_pwr[rf_path],psample_pkt_rssi->ofdm_snr[rf_path]);
}else{
printk("\n");
}
}
}
void rtw_store_phy_info(_adapter *padapter, union recv_frame *prframe)
{
u8 isCCKrate,rf_path;
PHAL_DATA_TYPE pHalData = GET_HAL_DATA(padapter);
struct rx_pkt_attrib *pattrib = &prframe->u.hdr.attrib;
PODM_PHY_INFO_T pPhyInfo = (PODM_PHY_INFO_T)(&pattrib->phy_info);
struct rx_raw_rssi *psample_pkt_rssi = &padapter->recvpriv.raw_rssi_info;
psample_pkt_rssi->data_rate = pattrib->data_rate;
isCCKrate = (pattrib->data_rate <= DESC_RATE11M)?TRUE :FALSE;
psample_pkt_rssi->pwdball = pPhyInfo->RxPWDBAll;
psample_pkt_rssi->pwr_all = pPhyInfo->RecvSignalPower;
for(rf_path = 0;rf_path<pHalData->NumTotalRFPath;rf_path++)
{
psample_pkt_rssi->mimo_signal_strength[rf_path] = pPhyInfo->RxMIMOSignalStrength[rf_path];
psample_pkt_rssi->mimo_signal_quality[rf_path] = pPhyInfo->RxMIMOSignalQuality[rf_path];
if(!isCCKrate){
psample_pkt_rssi->ofdm_pwr[rf_path] = pPhyInfo->RxPwr[rf_path];
psample_pkt_rssi->ofdm_snr[rf_path] = pPhyInfo->RxSNR[rf_path];
}
}
}
#endif
int check_phy_efuse_tx_power_info_valid(PADAPTER padapter) {
PHAL_DATA_TYPE pHalData = GET_HAL_DATA(padapter);
u8* pContent = pHalData->efuse_eeprom_data;
int index = 0;
u16 tx_index_offset = 0x0000;
switch (rtw_get_chip_type(padapter)) {
case RTL8723B:
tx_index_offset = EEPROM_TX_PWR_INX_8723B;
break;
case RTL8703B:
tx_index_offset = EEPROM_TX_PWR_INX_8703B;
break;
case RTL8188E:
tx_index_offset = EEPROM_TX_PWR_INX_88E;
break;
case RTL8188F:
tx_index_offset = EEPROM_TX_PWR_INX_8188F;
break;
case RTL8192E:
tx_index_offset = EEPROM_TX_PWR_INX_8192E;
break;
case RTL8821:
tx_index_offset = EEPROM_TX_PWR_INX_8821;
break;
case RTL8812:
tx_index_offset = EEPROM_TX_PWR_INX_8812;
break;
case RTL8814A:
tx_index_offset = EEPROM_TX_PWR_INX_8814;
break;
default:
tx_index_offset = 0x0010;
break;
}
/* TODO: chacking length by ICs */
for (index = 0 ; index < 11 ; index++) {
if (pContent[tx_index_offset + index] == 0xFF)
return _FALSE;
}
return _TRUE;
}
int hal_efuse_macaddr_offset(_adapter *adapter)
{
u8 interface_type = 0;
int addr_offset = -1;
interface_type = rtw_get_intf_type(adapter);
switch (rtw_get_chip_type(adapter)) {
#ifdef CONFIG_RTL8723B
case RTL8723B:
if (interface_type == RTW_USB)
addr_offset = EEPROM_MAC_ADDR_8723BU;
else if (interface_type == RTW_SDIO)
addr_offset = EEPROM_MAC_ADDR_8723BS;
else if (interface_type == RTW_PCIE)
addr_offset = EEPROM_MAC_ADDR_8723BE;
break;
#endif
#ifdef CONFIG_RTL8703B
case RTL8703B:
if (interface_type == RTW_USB)
addr_offset = EEPROM_MAC_ADDR_8703BU;
else if (interface_type == RTW_SDIO)
addr_offset = EEPROM_MAC_ADDR_8703BS;
break;
#endif
#ifdef CONFIG_RTL8188E
case RTL8188E:
if (interface_type == RTW_USB)
addr_offset = EEPROM_MAC_ADDR_88EU;
else if (interface_type == RTW_SDIO)
addr_offset = EEPROM_MAC_ADDR_88ES;
else if (interface_type == RTW_PCIE)
addr_offset = EEPROM_MAC_ADDR_88EE;
break;
#endif
#ifdef CONFIG_RTL8188F
case RTL8188F:
if (interface_type == RTW_USB)
addr_offset = EEPROM_MAC_ADDR_8188FU;
else if (interface_type == RTW_SDIO)
addr_offset = EEPROM_MAC_ADDR_8188FS;
break;
#endif
#ifdef CONFIG_RTL8812A
case RTL8812:
if (interface_type == RTW_USB)
addr_offset = EEPROM_MAC_ADDR_8812AU;
else if (interface_type == RTW_PCIE)
addr_offset = EEPROM_MAC_ADDR_8812AE;
break;
#endif
#ifdef CONFIG_RTL8821A
case RTL8821:
if (interface_type == RTW_USB)
addr_offset = EEPROM_MAC_ADDR_8821AU;
else if (interface_type == RTW_SDIO)
addr_offset = EEPROM_MAC_ADDR_8821AS;
else if (interface_type == RTW_PCIE)
addr_offset = EEPROM_MAC_ADDR_8821AE;
break;
#endif
#ifdef CONFIG_RTL8192E
case RTL8192E:
if (interface_type == RTW_USB)
addr_offset = EEPROM_MAC_ADDR_8192EU;
else if (interface_type == RTW_SDIO)
addr_offset = EEPROM_MAC_ADDR_8192ES;
else if (interface_type == RTW_PCIE)
addr_offset = EEPROM_MAC_ADDR_8192EE;
break;
#endif
#ifdef CONFIG_RTL8814A
case RTL8814A:
if (interface_type == RTW_USB)
addr_offset = EEPROM_MAC_ADDR_8814AU;
else if (interface_type == RTW_PCIE)
addr_offset = EEPROM_MAC_ADDR_8814AE;
break;
#endif
}
if (addr_offset == -1) {
DBG_871X_LEVEL(_drv_err_, "%s: unknown combination - chip_type:%u, interface:%u\n"
, __func__, rtw_get_chip_type(adapter), rtw_get_intf_type(adapter));
}
return addr_offset;
}
int Hal_GetPhyEfuseMACAddr(PADAPTER padapter, u8 *mac_addr)
{
int ret = _FAIL;
int addr_offset;
addr_offset = hal_efuse_macaddr_offset(padapter);
if (addr_offset == -1)
goto exit;
ret = rtw_efuse_map_read(padapter, addr_offset, ETH_ALEN, mac_addr);
exit:
return ret;
}
#ifdef CONFIG_EFUSE_CONFIG_FILE
u32 Hal_readPGDataFromConfigFile(PADAPTER padapter)
{
HAL_DATA_TYPE *hal_data = GET_HAL_DATA(padapter);
u32 ret;
ret = rtw_read_efuse_from_file(EFUSE_MAP_PATH, hal_data->efuse_eeprom_data);
hal_data->efuse_file_status = ((ret == _FAIL) ? EFUSE_FILE_FAILED : EFUSE_FILE_LOADED);
return ret;
}
u32 Hal_ReadMACAddrFromFile(PADAPTER padapter, u8 *mac_addr)
{
HAL_DATA_TYPE *hal_data = GET_HAL_DATA(padapter);
u32 ret = _FAIL;
if (rtw_read_macaddr_from_file(WIFIMAC_PATH, mac_addr) == _SUCCESS
&& rtw_check_invalid_mac_address(mac_addr, _TRUE) == _FALSE
) {
hal_data->macaddr_file_status = MACADDR_FILE_LOADED;
ret = _SUCCESS;
} else {
hal_data->macaddr_file_status = MACADDR_FILE_FAILED;
}
return ret;
}
#endif /* CONFIG_EFUSE_CONFIG_FILE */
int hal_config_macaddr(_adapter *adapter, bool autoload_fail)
{
HAL_DATA_TYPE *hal_data = GET_HAL_DATA(adapter);
u8 addr[ETH_ALEN];
int addr_offset = hal_efuse_macaddr_offset(adapter);
u8 *hw_addr = NULL;
int ret = _SUCCESS;
if (autoload_fail)
goto bypass_hw_pg;
if (addr_offset != -1)
hw_addr = &hal_data->efuse_eeprom_data[addr_offset];
#ifdef CONFIG_EFUSE_CONFIG_FILE
/* if the hw_addr is written by efuse file, set to NULL */
if (hal_data->efuse_file_status == EFUSE_FILE_LOADED)
hw_addr = NULL;
#endif
if (!hw_addr) {
/* try getting hw pg data */
if (Hal_GetPhyEfuseMACAddr(adapter, addr) == _SUCCESS)
hw_addr = addr;
}
/* check hw pg data */
if (hw_addr && rtw_check_invalid_mac_address(hw_addr, _TRUE) == _FALSE) {
_rtw_memcpy(hal_data->EEPROMMACAddr, hw_addr, ETH_ALEN);
goto exit;
}
bypass_hw_pg:
#ifdef CONFIG_EFUSE_CONFIG_FILE
/* check wifi mac file */
if (Hal_ReadMACAddrFromFile(adapter, addr) == _SUCCESS) {
_rtw_memcpy(hal_data->EEPROMMACAddr, addr, ETH_ALEN);
goto exit;
}
#endif
_rtw_memset(hal_data->EEPROMMACAddr, 0, ETH_ALEN);
ret = _FAIL;
exit:
return ret;
}
#ifdef CONFIG_RF_GAIN_OFFSET
u32 Array_kfreemap[] = {
0x08,0xe,
0x06,0xc,
0x04,0xa,
0x02,0x8,
0x00,0x6,
0x03,0x4,
0x05,0x2,
0x07,0x0,
0x09,0x0,
0x0c,0x0,
};
void rtw_bb_rf_gain_offset(_adapter *padapter)
{
HAL_DATA_TYPE *pHalData = GET_HAL_DATA(padapter);
struct registry_priv *registry_par = &padapter->registrypriv;
struct kfree_data_t *kfree_data = &pHalData->kfree_data;
u8 value = pHalData->EEPROMRFGainOffset;
u8 tmp = 0x3e;
u32 res, i = 0;
u4Byte ArrayLen = sizeof(Array_kfreemap)/sizeof(u32);
pu4Byte Array = Array_kfreemap;
u4Byte v1 = 0, v2 = 0, GainValue = 0, target = 0;
if (registry_par->RegRfKFreeEnable == 2) {
DBG_871X("Registry kfree default force disable.\n");
return;
}
#if defined(CONFIG_RTL8723B)
if (value & BIT4 || (registry_par->RegRfKFreeEnable == 1)) {
DBG_871X("Offset RF Gain.\n");
DBG_871X("Offset RF Gain. pHalData->EEPROMRFGainVal=0x%x\n",pHalData->EEPROMRFGainVal);
if(pHalData->EEPROMRFGainVal != 0xff){
if(pHalData->ant_path == ODM_RF_PATH_A) {
GainValue=(pHalData->EEPROMRFGainVal & 0x0f);
} else {
GainValue=(pHalData->EEPROMRFGainVal & 0xf0)>>4;
}
DBG_871X("Ant PATH_%d GainValue Offset = 0x%x\n",(pHalData->ant_path == ODM_RF_PATH_A) ? (ODM_RF_PATH_A) : (ODM_RF_PATH_B),GainValue);
for (i = 0; i < ArrayLen; i += 2 )
{
//DBG_871X("ArrayLen in =%d ,Array 1 =0x%x ,Array2 =0x%x \n",i,Array[i],Array[i]+1);
v1 = Array[i];
v2 = Array[i+1];
if ( v1 == GainValue ) {
DBG_871X("Offset RF Gain. got v1 =0x%x ,v2 =0x%x \n",v1,v2);
target=v2;
break;
}
}
DBG_871X("pHalData->EEPROMRFGainVal=0x%x ,Gain offset Target Value=0x%x\n",pHalData->EEPROMRFGainVal,target);
res = rtw_hal_read_rfreg(padapter, RF_PATH_A, 0x7f, 0xffffffff);
DBG_871X("Offset RF Gain. before reg 0x7f=0x%08x\n",res);
PHY_SetRFReg(padapter, RF_PATH_A, REG_RF_BB_GAIN_OFFSET, BIT18|BIT17|BIT16|BIT15, target);
res = rtw_hal_read_rfreg(padapter, RF_PATH_A, 0x7f, 0xffffffff);
DBG_871X("Offset RF Gain. After reg 0x7f=0x%08x\n",res);
}else {
DBG_871X("Offset RF Gain. pHalData->EEPROMRFGainVal=0x%x != 0xff, didn't run Kfree\n",pHalData->EEPROMRFGainVal);
}
} else {
DBG_871X("Using the default RF gain.\n");
}
#elif defined(CONFIG_RTL8188E)
if (value & BIT4 || (registry_par->RegRfKFreeEnable == 1)) {
DBG_871X("8188ES Offset RF Gain.\n");
DBG_871X("8188ES Offset RF Gain. EEPROMRFGainVal=0x%x\n",
pHalData->EEPROMRFGainVal);
if (pHalData->EEPROMRFGainVal != 0xff) {
res = rtw_hal_read_rfreg(padapter, RF_PATH_A,
REG_RF_BB_GAIN_OFFSET, 0xffffffff);
DBG_871X("Offset RF Gain. reg 0x55=0x%x\n",res);
res &= 0xfff87fff;
res |= (pHalData->EEPROMRFGainVal & 0x0f) << 15;
DBG_871X("Offset RF Gain. res=0x%x\n",res);
rtw_hal_write_rfreg(padapter, RF_PATH_A,
REG_RF_BB_GAIN_OFFSET,
RF_GAIN_OFFSET_MASK, res);
} else {
DBG_871X("Offset RF Gain. EEPROMRFGainVal=0x%x == 0xff, didn't run Kfree\n",
pHalData->EEPROMRFGainVal);
}
} else {
DBG_871X("Using the default RF gain.\n");
}
#else
/* TODO: call this when channel switch */
if (kfree_data->flag & KFREE_FLAG_ON)
rtw_rf_apply_tx_gain_offset(padapter, 6); /* input ch6 to select BB_GAIN_2G */
#endif
}
#endif //CONFIG_RF_GAIN_OFFSET
bool kfree_data_is_bb_gain_empty(struct kfree_data_t *data)
{
#ifdef CONFIG_RF_GAIN_OFFSET
int i, j;
for (i = 0; i < BB_GAIN_NUM; i++)
for (j = 0; j < RF_PATH_MAX; j++)
if (data->bb_gain[i][j] != 0)
return 0;
#endif
return 1;
}
#ifdef CONFIG_USB_RX_AGGREGATION
void rtw_set_usb_agg_by_mode(_adapter *padapter, u8 cur_wireless_mode)
{
HAL_DATA_TYPE *pHalData = GET_HAL_DATA(padapter);
if(cur_wireless_mode < WIRELESS_11_24N
&& cur_wireless_mode > 0) //ABG mode
{
#ifdef CONFIG_PREALLOC_RX_SKB_BUFFER
u32 remainder = 0;
u8 quotient = 0;
remainder = MAX_RECVBUF_SZ % (4*1024);
quotient = (u8)(MAX_RECVBUF_SZ >> 12);
if (quotient > 5) {
pHalData->RegAcUsbDmaSize = 0x6;
pHalData->RegAcUsbDmaTime = 0x10;
} else {
if (remainder >= 2048) {
pHalData->RegAcUsbDmaSize = quotient;
pHalData->RegAcUsbDmaTime = 0x10;
} else {
pHalData->RegAcUsbDmaSize = (quotient-1);
pHalData->RegAcUsbDmaTime = 0x10;
}
}
#else /* !CONFIG_PREALLOC_RX_SKB_BUFFER */
if(0x6 != pHalData->RegAcUsbDmaSize || 0x10 !=pHalData->RegAcUsbDmaTime)
{
pHalData->RegAcUsbDmaSize = 0x6;
pHalData->RegAcUsbDmaTime = 0x10;
rtw_write16(padapter, REG_RXDMA_AGG_PG_TH,
pHalData->RegAcUsbDmaSize | (pHalData->RegAcUsbDmaTime<<8));
}
#endif /* CONFIG_PREALLOC_RX_SKB_BUFFER */
}
else if(cur_wireless_mode >= WIRELESS_11_24N
&& cur_wireless_mode <= WIRELESS_MODE_MAX)//N AC mode
{
#ifdef CONFIG_PREALLOC_RX_SKB_BUFFER
u32 remainder = 0;
u8 quotient = 0;
remainder = MAX_RECVBUF_SZ % (4*1024);
quotient = (u8)(MAX_RECVBUF_SZ >> 12);
if (quotient > 5) {
pHalData->RegAcUsbDmaSize = 0x5;
pHalData->RegAcUsbDmaTime = 0x20;
} else {
if (remainder >= 2048) {
pHalData->RegAcUsbDmaSize = quotient;
pHalData->RegAcUsbDmaTime = 0x10;
} else {
pHalData->RegAcUsbDmaSize = (quotient-1);
pHalData->RegAcUsbDmaTime = 0x10;
}
}
#else /* !CONFIG_PREALLOC_RX_SKB_BUFFER */
if(0x5 != pHalData->RegAcUsbDmaSize || 0x20 !=pHalData->RegAcUsbDmaTime)
{
pHalData->RegAcUsbDmaSize = 0x5;
pHalData->RegAcUsbDmaTime = 0x20;
rtw_write16(padapter, REG_RXDMA_AGG_PG_TH,
pHalData->RegAcUsbDmaSize | (pHalData->RegAcUsbDmaTime<<8));
}
#endif /* CONFIG_PREALLOC_RX_SKB_BUFFER */
}
else
{
/* DBG_871X("%s: Unknow wireless mode(0x%x)\n",__func__,padapter->mlmeextpriv.cur_wireless_mode); */
}
}
#endif //CONFIG_USB_RX_AGGREGATION
//To avoid RX affect TX throughput
void dm_DynamicUsbTxAgg(_adapter *padapter, u8 from_timer)
{
struct dvobj_priv *pdvobjpriv = adapter_to_dvobj(padapter);
struct mlme_priv *pmlmepriv = &(padapter->mlmepriv);
struct mlme_ext_priv *pmlmeextpriv = &(padapter->mlmeextpriv);
HAL_DATA_TYPE *pHalData = GET_HAL_DATA(padapter);
u8 cur_wireless_mode = pmlmeextpriv->cur_wireless_mode;
#ifdef CONFIG_CONCURRENT_MODE
struct mlme_ext_priv *pbuddymlmeextpriv = &(padapter->pbuddy_adapter->mlmeextpriv);
#endif //CONFIG_CONCURRENT_MODE
#ifdef CONFIG_USB_RX_AGGREGATION
if(IS_HARDWARE_TYPE_8821U(padapter) )//|| IS_HARDWARE_TYPE_8192EU(padapter))
{
//This AGG_PH_TH only for UsbRxAggMode == USB_RX_AGG_USB
if((pHalData->UsbRxAggMode == USB_RX_AGG_USB) && (check_fwstate(pmlmepriv, _FW_LINKED)== _TRUE))
{
if(pdvobjpriv->traffic_stat.cur_tx_tp > 2 && pdvobjpriv->traffic_stat.cur_rx_tp < 30)
rtw_write16(padapter , REG_RXDMA_AGG_PG_TH , 0x1010);
else if (pdvobjpriv->traffic_stat.last_tx_bytes > 220000 && pdvobjpriv->traffic_stat.cur_rx_tp < 30)
rtw_write16(padapter , REG_RXDMA_AGG_PG_TH , 0x1006);
else
rtw_write16(padapter, REG_RXDMA_AGG_PG_TH,0x2005); //dmc agg th 20K
//DBG_871X("TX_TP=%u, RX_TP=%u \n", pdvobjpriv->traffic_stat.cur_tx_tp, pdvobjpriv->traffic_stat.cur_rx_tp);
}
}
else if(IS_HARDWARE_TYPE_8812(padapter))
{
#ifdef CONFIG_CONCURRENT_MODE
if(rtw_linked_check(padapter) == _TRUE && rtw_linked_check(padapter->pbuddy_adapter) == _TRUE)
{
if(pbuddymlmeextpriv->cur_wireless_mode >= pmlmeextpriv->cur_wireless_mode)
cur_wireless_mode = pbuddymlmeextpriv->cur_wireless_mode;
else
cur_wireless_mode = pmlmeextpriv->cur_wireless_mode;
rtw_set_usb_agg_by_mode(padapter,cur_wireless_mode);
}
else if (rtw_linked_check(padapter) == _TRUE && rtw_linked_check(padapter->pbuddy_adapter) == _FALSE)
{
rtw_set_usb_agg_by_mode(padapter,cur_wireless_mode);
}
#else //!CONFIG_CONCURRENT_MODE
rtw_set_usb_agg_by_mode(padapter,cur_wireless_mode);
#endif //CONFIG_CONCURRENT_MODE
}
#endif
}
//bus-agg check for SoftAP mode
inline u8 rtw_hal_busagg_qsel_check(_adapter *padapter,u8 pre_qsel,u8 next_qsel)
{
struct mlme_priv *pmlmepriv = &(padapter->mlmepriv);
u8 chk_rst = _SUCCESS;
if(check_fwstate(pmlmepriv, WIFI_AP_STATE) != _TRUE)
return chk_rst;
//if((pre_qsel == 0xFF)||(next_qsel== 0xFF))
// return chk_rst;
if( ((pre_qsel == QSLT_HIGH)||((next_qsel== QSLT_HIGH)))
&& (pre_qsel != next_qsel )){
//DBG_871X("### bus-agg break cause of qsel misatch, pre_qsel=0x%02x,next_qsel=0x%02x ###\n",
// pre_qsel,next_qsel);
chk_rst = _FAIL;
}
return chk_rst;
}
/*
* Description:
* dump_TX_FIFO: This is only used to dump TX_FIFO for debug WoW mode offload
* contant.
*
* Input:
* adapter: adapter pointer.
* page_num: The max. page number that user want to dump.
* page_size: page size of each page. eg. 128 bytes, 256 bytes, 512byte.
*/
void dump_TX_FIFO(_adapter* padapter, u8 page_num, u16 page_size){
int i;
u8 val = 0;
u8 base = 0;
u32 addr = 0;
u32 count = (page_size / 8);
if (page_num <= 0) {
DBG_871X("!!%s: incorrect input page_num paramter!\n", __func__);
return;
}
if (page_size < 128 || page_size > 512) {
DBG_871X("!!%s: incorrect input page_size paramter!\n", __func__);
return;
}
DBG_871X("+%s+\n", __func__);
val = rtw_read8(padapter, 0x106);
rtw_write8(padapter, 0x106, 0x69);
DBG_871X("0x106: 0x%02x\n", val);
base = rtw_read8(padapter, 0x209);
DBG_871X("0x209: 0x%02x\n", base);
addr = ((base) * page_size)/8;
for (i = 0 ; i < page_num * count ; i+=2) {
rtw_write32(padapter, 0x140, addr + i);
printk(" %08x %08x ", rtw_read32(padapter, 0x144), rtw_read32(padapter, 0x148));
rtw_write32(padapter, 0x140, addr + i + 1);
printk(" %08x %08x \n", rtw_read32(padapter, 0x144), rtw_read32(padapter, 0x148));
}
}
#ifdef CONFIG_GPIO_API
u8 rtw_hal_get_gpio(_adapter* adapter, u8 gpio_num)
{
u8 value;
u8 direction;
struct pwrctrl_priv *pwrpriv = adapter_to_pwrctl(adapter);
rtw_ps_deny(adapter, PS_DENY_IOCTL);
DBG_871X("rf_pwrstate=0x%02x\n", pwrpriv->rf_pwrstate);
LeaveAllPowerSaveModeDirect(adapter);
/* Read GPIO Direction */
direction = (rtw_read8(adapter,REG_GPIO_PIN_CTRL + 2) & BIT(gpio_num)) >> gpio_num;
/* According the direction to read register value */
if( direction )
value = (rtw_read8(adapter, REG_GPIO_PIN_CTRL + 1)& BIT(gpio_num)) >> gpio_num;
else
value = (rtw_read8(adapter, REG_GPIO_PIN_CTRL)& BIT(gpio_num)) >> gpio_num;
rtw_ps_deny_cancel(adapter, PS_DENY_IOCTL);
DBG_871X("%s direction=%d value=%d\n",__FUNCTION__,direction,value);
return value;
}
int rtw_hal_set_gpio_output_value(_adapter* adapter, u8 gpio_num, bool isHigh)
{
u8 direction = 0;
u8 res = -1;
if (IS_HARDWARE_TYPE_8188E(adapter)){
/* Check GPIO is 4~7 */
if( gpio_num > 7 || gpio_num < 4)
{
DBG_871X("%s The gpio number does not included 4~7.\n",__FUNCTION__);
return -1;
}
}
rtw_ps_deny(adapter, PS_DENY_IOCTL);
LeaveAllPowerSaveModeDirect(adapter);
/* Read GPIO direction */
direction = (rtw_read8(adapter,REG_GPIO_PIN_CTRL + 2) & BIT(gpio_num)) >> gpio_num;
/* If GPIO is output direction, setting value. */
if( direction )
{
if(isHigh)
rtw_write8(adapter, REG_GPIO_PIN_CTRL + 1, rtw_read8(adapter, REG_GPIO_PIN_CTRL + 1) | BIT(gpio_num));
else
rtw_write8(adapter, REG_GPIO_PIN_CTRL + 1, rtw_read8(adapter, REG_GPIO_PIN_CTRL + 1) & ~BIT(gpio_num));
DBG_871X("%s Set gpio %x[%d]=%d\n",__FUNCTION__,REG_GPIO_PIN_CTRL+1,gpio_num,isHigh );
res = 0;
}
else
{
DBG_871X("%s The gpio is input,not be set!\n",__FUNCTION__);
res = -1;
}
rtw_ps_deny_cancel(adapter, PS_DENY_IOCTL);
return res;
}
int rtw_hal_config_gpio(_adapter* adapter, u8 gpio_num, bool isOutput)
{
if (IS_HARDWARE_TYPE_8188E(adapter)){
if( gpio_num > 7 || gpio_num < 4)
{
DBG_871X("%s The gpio number does not included 4~7.\n",__FUNCTION__);
return -1;
}
}
DBG_871X("%s gpio_num =%d direction=%d\n",__FUNCTION__,gpio_num,isOutput);
rtw_ps_deny(adapter, PS_DENY_IOCTL);
LeaveAllPowerSaveModeDirect(adapter);
if( isOutput )
{
rtw_write8(adapter, REG_GPIO_PIN_CTRL + 2, rtw_read8(adapter, REG_GPIO_PIN_CTRL + 2) | BIT(gpio_num));
}
else
{
rtw_write8(adapter, REG_GPIO_PIN_CTRL + 2, rtw_read8(adapter, REG_GPIO_PIN_CTRL + 2) & ~BIT(gpio_num));
}
rtw_ps_deny_cancel(adapter, PS_DENY_IOCTL);
return 0;
}
int rtw_hal_register_gpio_interrupt(_adapter* adapter, int gpio_num, void(*callback)(u8 level))
{
u8 value;
u8 direction;
PHAL_DATA_TYPE phal = GET_HAL_DATA(adapter);
if (IS_HARDWARE_TYPE_8188E(adapter)){
if(gpio_num > 7 || gpio_num < 4)
{
DBG_871X_LEVEL(_drv_always_, "%s The gpio number does not included 4~7.\n",__FUNCTION__);
return -1;
}
}
rtw_ps_deny(adapter, PS_DENY_IOCTL);
LeaveAllPowerSaveModeDirect(adapter);
/* Read GPIO direction */
direction = (rtw_read8(adapter,REG_GPIO_PIN_CTRL + 2) & BIT(gpio_num)) >> gpio_num;
if(direction){
DBG_871X_LEVEL(_drv_always_, "%s Can't register output gpio as interrupt.\n",__FUNCTION__);
return -1;
}
/* Config GPIO Mode */
rtw_write8(adapter, REG_GPIO_PIN_CTRL + 3, rtw_read8(adapter, REG_GPIO_PIN_CTRL + 3) | BIT(gpio_num));
/* Register GPIO interrupt handler*/
adapter->gpiointpriv.callback[gpio_num] = callback;
/* Set GPIO interrupt mode, 0:positive edge, 1:negative edge */
value = rtw_read8(adapter, REG_GPIO_PIN_CTRL) & BIT(gpio_num);
adapter->gpiointpriv.interrupt_mode = rtw_read8(adapter, REG_HSIMR + 2)^value;
rtw_write8(adapter, REG_GPIO_INTM, adapter->gpiointpriv.interrupt_mode);
/* Enable GPIO interrupt */
adapter->gpiointpriv.interrupt_enable_mask = rtw_read8(adapter, REG_HSIMR + 2) | BIT(gpio_num);
rtw_write8(adapter, REG_HSIMR + 2, adapter->gpiointpriv.interrupt_enable_mask);
rtw_hal_update_hisr_hsisr_ind(adapter, 1);
rtw_ps_deny_cancel(adapter, PS_DENY_IOCTL);
return 0;
}
int rtw_hal_disable_gpio_interrupt(_adapter* adapter, int gpio_num)
{
u8 value;
u8 direction;
PHAL_DATA_TYPE phal = GET_HAL_DATA(adapter);
if (IS_HARDWARE_TYPE_8188E(adapter)){
if(gpio_num > 7 || gpio_num < 4)
{
DBG_871X("%s The gpio number does not included 4~7.\n",__FUNCTION__);
return -1;
}
}
rtw_ps_deny(adapter, PS_DENY_IOCTL);
LeaveAllPowerSaveModeDirect(adapter);
/* Config GPIO Mode */
rtw_write8(adapter, REG_GPIO_PIN_CTRL + 3, rtw_read8(adapter, REG_GPIO_PIN_CTRL + 3) &~ BIT(gpio_num));
/* Unregister GPIO interrupt handler*/
adapter->gpiointpriv.callback[gpio_num] = NULL;
/* Reset GPIO interrupt mode, 0:positive edge, 1:negative edge */
adapter->gpiointpriv.interrupt_mode = rtw_read8(adapter, REG_GPIO_INTM) &~ BIT(gpio_num);
rtw_write8(adapter, REG_GPIO_INTM, 0x00);
/* Disable GPIO interrupt */
adapter->gpiointpriv.interrupt_enable_mask = rtw_read8(adapter, REG_HSIMR + 2) &~ BIT(gpio_num);
rtw_write8(adapter, REG_HSIMR + 2, adapter->gpiointpriv.interrupt_enable_mask);
if(!adapter->gpiointpriv.interrupt_enable_mask)
rtw_hal_update_hisr_hsisr_ind(adapter, 0);
rtw_ps_deny_cancel(adapter, PS_DENY_IOCTL);
return 0;
}
#endif
void rtw_dump_mac_rx_counters(_adapter* padapter,struct dbg_rx_counter *rx_counter)
{
u32 mac_cck_ok=0, mac_ofdm_ok=0, mac_ht_ok=0, mac_vht_ok=0;
u32 mac_cck_err=0, mac_ofdm_err=0, mac_ht_err=0, mac_vht_err=0;
u32 mac_cck_fa=0, mac_ofdm_fa=0, mac_ht_fa=0;
u32 DropPacket=0;
if(!rx_counter){
rtw_warn_on(1);
return;
}
PHY_SetMacReg(padapter, REG_RXERR_RPT, BIT28|BIT29|BIT30|BIT31, 0x3);
mac_cck_ok = PHY_QueryMacReg(padapter, REG_RXERR_RPT, bMaskLWord);// [15:0]
PHY_SetMacReg(padapter, REG_RXERR_RPT, BIT28|BIT29|BIT30|BIT31, 0x0);
mac_ofdm_ok = PHY_QueryMacReg(padapter, REG_RXERR_RPT, bMaskLWord);// [15:0]
PHY_SetMacReg(padapter, REG_RXERR_RPT, BIT28|BIT29|BIT30|BIT31, 0x6);
mac_ht_ok = PHY_QueryMacReg(padapter, REG_RXERR_RPT, bMaskLWord);// [15:0]
mac_vht_ok = 0;
if (IS_HARDWARE_TYPE_JAGUAR(padapter) || IS_HARDWARE_TYPE_JAGUAR2(padapter)) {
PHY_SetMacReg(padapter, REG_RXERR_RPT, BIT28|BIT29|BIT30|BIT31, 0x0);
PHY_SetMacReg(padapter, REG_RXERR_RPT, BIT26, 0x1);
mac_vht_ok = PHY_QueryMacReg(padapter, REG_RXERR_RPT, bMaskLWord);// [15:0]
}
PHY_SetMacReg(padapter, REG_RXERR_RPT, BIT28|BIT29|BIT30|BIT31, 0x4);
mac_cck_err = PHY_QueryMacReg(padapter, REG_RXERR_RPT, bMaskLWord);// [15:0]
PHY_SetMacReg(padapter, REG_RXERR_RPT, BIT28|BIT29|BIT30|BIT31, 0x1);
mac_ofdm_err = PHY_QueryMacReg(padapter, REG_RXERR_RPT, bMaskLWord);// [15:0]
PHY_SetMacReg(padapter, REG_RXERR_RPT, BIT28|BIT29|BIT30|BIT31, 0x7);
mac_ht_err = PHY_QueryMacReg(padapter, REG_RXERR_RPT, bMaskLWord);// [15:0]
mac_vht_err = 0;
if (IS_HARDWARE_TYPE_JAGUAR(padapter) || IS_HARDWARE_TYPE_JAGUAR2(padapter)) {
PHY_SetMacReg(padapter, REG_RXERR_RPT, BIT28|BIT29|BIT30|BIT31, 0x1);
PHY_SetMacReg(padapter, REG_RXERR_RPT, BIT26, 0x1);
mac_vht_err = PHY_QueryMacReg(padapter, REG_RXERR_RPT, bMaskLWord);// [15:0]
}
PHY_SetMacReg(padapter, REG_RXERR_RPT, BIT28|BIT29|BIT30|BIT31, 0x5);
mac_cck_fa = PHY_QueryMacReg(padapter, REG_RXERR_RPT, bMaskLWord);// [15:0]
PHY_SetMacReg(padapter, REG_RXERR_RPT, BIT28|BIT29|BIT30|BIT31, 0x2);
mac_ofdm_fa = PHY_QueryMacReg(padapter, REG_RXERR_RPT, bMaskLWord);// [15:0]
PHY_SetMacReg(padapter, REG_RXERR_RPT, BIT28|BIT29|BIT30|BIT31, 0x9);
mac_ht_fa = PHY_QueryMacReg(padapter, REG_RXERR_RPT, bMaskLWord);// [15:0]
//Mac_DropPacket
rtw_write32(padapter, REG_RXERR_RPT, (rtw_read32(padapter, REG_RXERR_RPT)& 0x0FFFFFFF)| Mac_DropPacket);
DropPacket = rtw_read32(padapter, REG_RXERR_RPT)& 0x0000FFFF;
rx_counter->rx_pkt_ok = mac_cck_ok+mac_ofdm_ok+mac_ht_ok+mac_vht_ok;
rx_counter->rx_pkt_crc_error = mac_cck_err+mac_ofdm_err+mac_ht_err+mac_vht_err;
rx_counter->rx_cck_fa = mac_cck_fa;
rx_counter->rx_ofdm_fa = mac_ofdm_fa;
rx_counter->rx_ht_fa = mac_ht_fa;
rx_counter->rx_pkt_drop = DropPacket;
}
void rtw_reset_mac_rx_counters(_adapter* padapter)
{
if (IS_HARDWARE_TYPE_8703B(padapter) || IS_HARDWARE_TYPE_8188F(padapter))
PHY_SetMacReg(padapter, 0x608, BIT19, 0x1); /* If no packet rx, MaxRx clock be gating ,BIT_DISGCLK bit19 set 1 for fix*/
//reset mac counter
PHY_SetMacReg(padapter, REG_RXERR_RPT, BIT27, 0x1);
PHY_SetMacReg(padapter, REG_RXERR_RPT, BIT27, 0x0);
}
void rtw_dump_phy_rx_counters(_adapter* padapter,struct dbg_rx_counter *rx_counter)
{
u32 cckok=0,cckcrc=0,ofdmok=0,ofdmcrc=0,htok=0,htcrc=0,OFDM_FA=0,CCK_FA=0,vht_ok=0,vht_err=0;
if(!rx_counter){
rtw_warn_on(1);
return;
}
if (IS_HARDWARE_TYPE_JAGUAR(padapter) || IS_HARDWARE_TYPE_JAGUAR2(padapter)){
cckok = PHY_QueryBBReg(padapter, 0xF04, 0x3FFF); // [13:0]
ofdmok = PHY_QueryBBReg(padapter, 0xF14, 0x3FFF); // [13:0]
htok = PHY_QueryBBReg(padapter, 0xF10, 0x3FFF); // [13:0]
vht_ok = PHY_QueryBBReg(padapter, 0xF0C, 0x3FFF); // [13:0]
cckcrc = PHY_QueryBBReg(padapter, 0xF04, 0x3FFF0000); // [29:16]
ofdmcrc = PHY_QueryBBReg(padapter, 0xF14, 0x3FFF0000); // [29:16]
htcrc = PHY_QueryBBReg(padapter, 0xF10, 0x3FFF0000); // [29:16]
vht_err = PHY_QueryBBReg(padapter, 0xF0C, 0x3FFF0000); // [29:16]
CCK_FA = PHY_QueryBBReg(padapter, 0xA5C, bMaskLWord);
OFDM_FA = PHY_QueryBBReg(padapter, 0xF48, bMaskLWord);
}
else
{
cckok = PHY_QueryBBReg(padapter, 0xF88, bMaskDWord);
ofdmok = PHY_QueryBBReg(padapter, 0xF94, bMaskLWord);
htok = PHY_QueryBBReg(padapter, 0xF90, bMaskLWord);
vht_ok = 0;
cckcrc = PHY_QueryBBReg(padapter, 0xF84, bMaskDWord);
ofdmcrc = PHY_QueryBBReg(padapter, 0xF94, bMaskHWord);
htcrc = PHY_QueryBBReg(padapter, 0xF90, bMaskHWord);
vht_err = 0;
OFDM_FA = PHY_QueryBBReg(padapter, 0xCF0, bMaskLWord) + PHY_QueryBBReg(padapter, 0xCF2, bMaskLWord) +
PHY_QueryBBReg(padapter, 0xDA2, bMaskLWord) + PHY_QueryBBReg(padapter, 0xDA4, bMaskLWord) +
PHY_QueryBBReg(padapter, 0xDA6, bMaskLWord) + PHY_QueryBBReg(padapter, 0xDA8, bMaskLWord);
CCK_FA=(rtw_read8(padapter, 0xA5B )<<8 ) | (rtw_read8(padapter, 0xA5C));
}
rx_counter->rx_pkt_ok = cckok+ofdmok+htok+vht_ok;
rx_counter->rx_pkt_crc_error = cckcrc+ofdmcrc+htcrc+vht_err;
rx_counter->rx_ofdm_fa = OFDM_FA;
rx_counter->rx_cck_fa = CCK_FA;
}
void rtw_reset_phy_rx_counters(_adapter* padapter)
{
//reset phy counter
if (IS_HARDWARE_TYPE_JAGUAR(padapter) || IS_HARDWARE_TYPE_JAGUAR2(padapter))
{
PHY_SetBBReg(padapter, 0xB58, BIT0, 0x1);
PHY_SetBBReg(padapter, 0xB58, BIT0, 0x0);
PHY_SetBBReg(padapter, 0x9A4, BIT17, 0x1);//reset OFDA FA counter
PHY_SetBBReg(padapter, 0x9A4, BIT17, 0x0);
PHY_SetBBReg(padapter, 0xA2C, BIT15, 0x0);//reset CCK FA counter
PHY_SetBBReg(padapter, 0xA2C, BIT15, 0x1);
}
else
{
PHY_SetBBReg(padapter, 0xF14, BIT16, 0x1);
rtw_msleep_os(10);
PHY_SetBBReg(padapter, 0xF14, BIT16, 0x0);
PHY_SetBBReg(padapter, 0xD00, BIT27, 0x1);//reset OFDA FA counter
PHY_SetBBReg(padapter, 0xC0C, BIT31, 0x1);//reset OFDA FA counter
PHY_SetBBReg(padapter, 0xD00, BIT27, 0x0);
PHY_SetBBReg(padapter, 0xC0C, BIT31, 0x0);
PHY_SetBBReg(padapter, 0xA2C, BIT15, 0x0);//reset CCK FA counter
PHY_SetBBReg(padapter, 0xA2C, BIT15, 0x1);
}
}
#ifdef DBG_RX_COUNTER_DUMP
void rtw_dump_drv_rx_counters(_adapter* padapter,struct dbg_rx_counter *rx_counter)
{
struct recv_priv *precvpriv = &padapter->recvpriv;
if(!rx_counter){
rtw_warn_on(1);
return;
}
rx_counter->rx_pkt_ok = padapter->drv_rx_cnt_ok;
rx_counter->rx_pkt_crc_error = padapter->drv_rx_cnt_crcerror;
rx_counter->rx_pkt_drop = precvpriv->rx_drop - padapter->drv_rx_cnt_drop;
}
void rtw_reset_drv_rx_counters(_adapter* padapter)
{
struct recv_priv *precvpriv = &padapter->recvpriv;
padapter->drv_rx_cnt_ok = 0;
padapter->drv_rx_cnt_crcerror = 0;
padapter->drv_rx_cnt_drop = precvpriv->rx_drop;
}
void rtw_dump_phy_rxcnts_preprocess(_adapter* padapter,u8 rx_cnt_mode)
{
u8 initialgain;
HAL_DATA_TYPE *hal_data = GET_HAL_DATA(padapter);
DM_ODM_T *odm = &(hal_data->odmpriv);
DIG_T *pDigTable = &odm->DM_DigTable;
if((!(padapter->dump_rx_cnt_mode& DUMP_PHY_RX_COUNTER)) && (rx_cnt_mode & DUMP_PHY_RX_COUNTER))
{
initialgain = pDigTable->CurIGValue;
DBG_871X("%s CurIGValue:0x%02x\n",__FUNCTION__,initialgain);
rtw_hal_set_odm_var(padapter, HAL_ODM_INITIAL_GAIN, &initialgain, _FALSE);
/*disable dynamic functions, such as high power, DIG*/
rtw_phydm_ability_backup(padapter);
rtw_phydm_func_clr(padapter, (ODM_BB_DIG|ODM_BB_FA_CNT));
}
else if((padapter->dump_rx_cnt_mode& DUMP_PHY_RX_COUNTER) &&(!(rx_cnt_mode & DUMP_PHY_RX_COUNTER )))
{
//turn on phy-dynamic functions
rtw_phydm_ability_restore(padapter);
initialgain = 0xff; //restore RX GAIN
rtw_hal_set_odm_var(padapter, HAL_ODM_INITIAL_GAIN, &initialgain, _FALSE);
}
}
void rtw_dump_rx_counters(_adapter* padapter)
{
struct dbg_rx_counter rx_counter;
if( padapter->dump_rx_cnt_mode & DUMP_DRV_RX_COUNTER ){
_rtw_memset(&rx_counter,0,sizeof(struct dbg_rx_counter));
rtw_dump_drv_rx_counters(padapter,&rx_counter);
DBG_871X( "Drv Received packet OK:%d CRC error:%d Drop Packets: %d\n",
rx_counter.rx_pkt_ok,rx_counter.rx_pkt_crc_error,rx_counter.rx_pkt_drop);
rtw_reset_drv_rx_counters(padapter);
}
if( padapter->dump_rx_cnt_mode & DUMP_MAC_RX_COUNTER ){
_rtw_memset(&rx_counter,0,sizeof(struct dbg_rx_counter));
rtw_dump_mac_rx_counters(padapter,&rx_counter);
DBG_871X( "Mac Received packet OK:%d CRC error:%d FA Counter: %d Drop Packets: %d\n",
rx_counter.rx_pkt_ok,rx_counter.rx_pkt_crc_error,
rx_counter.rx_cck_fa+rx_counter.rx_ofdm_fa+rx_counter.rx_ht_fa,
rx_counter.rx_pkt_drop);
rtw_reset_mac_rx_counters(padapter);
}
if(padapter->dump_rx_cnt_mode & DUMP_PHY_RX_COUNTER ){
_rtw_memset(&rx_counter,0,sizeof(struct dbg_rx_counter));
rtw_dump_phy_rx_counters(padapter,&rx_counter);
//DBG_871X("%s: OFDM_FA =%d\n", __FUNCTION__, rx_counter.rx_ofdm_fa);
//DBG_871X("%s: CCK_FA =%d\n", __FUNCTION__, rx_counter.rx_cck_fa);
DBG_871X("Phy Received packet OK:%d CRC error:%d FA Counter: %d\n",rx_counter.rx_pkt_ok,rx_counter.rx_pkt_crc_error,
rx_counter.rx_ofdm_fa+rx_counter.rx_cck_fa);
rtw_reset_phy_rx_counters(padapter);
}
}
#endif
void rtw_get_noise(_adapter* padapter)
{
#if defined(CONFIG_SIGNAL_DISPLAY_DBM) && defined(CONFIG_BACKGROUND_NOISE_MONITOR)
struct mlme_ext_priv *pmlmeext = &padapter->mlmeextpriv;
struct noise_info info;
if(rtw_linked_check(padapter)){
info.bPauseDIG = _TRUE;
info.IGIValue = 0x1e;
info.max_time = 100;//ms
info.chan = pmlmeext->cur_channel ;//rtw_get_oper_ch(padapter);
rtw_ps_deny(padapter, PS_DENY_IOCTL);
LeaveAllPowerSaveModeDirect(padapter);
rtw_hal_set_odm_var(padapter, HAL_ODM_NOISE_MONITOR,&info, _FALSE);
//ODM_InbandNoise_Monitor(podmpriv,_TRUE,0x20,100);
rtw_ps_deny_cancel(padapter, PS_DENY_IOCTL);
rtw_hal_get_odm_var(padapter, HAL_ODM_NOISE_MONITOR,&(info.chan), &(padapter->recvpriv.noise));
#ifdef DBG_NOISE_MONITOR
DBG_871X("chan:%d,noise_level:%d\n",info.chan,padapter->recvpriv.noise);
#endif
}
#endif
}
#ifdef CONFIG_FW_C2H_DEBUG
/* C2H RX package original is 128.
if enable CONFIG_FW_C2H_DEBUG, it should increase to 256.
C2H FW debug message:
without aggregate:
{C2H_CmdID,Seq,SubID,Len,Content[0~n]}
Content[0~n]={'a','b','c',...,'z','\n'}
with aggregate:
{C2H_CmdID,Seq,SubID,Len,Content[0~n]}
Content[0~n]={'a','b','c',...,'z','\n',Extend C2H pkt 2...}
Extend C2H pkt 2={C2H CmdID,Seq,SubID,Len,Content = {'a','b','c',...,'z','\n'}}
Author: Isaac */
void Debug_FwC2H(PADAPTER padapter, u8 *pdata, u8 len)
{
int i = 0;
int cnt = 0, total_length = 0;
u8 buf[128] = {0};
u8 more_data = _FALSE;
u8 *nextdata = NULL;
u8 test = 0;
u8 data_len;
u8 seq_no;
nextdata = pdata;
do {
data_len = *(nextdata + 1);
seq_no = *(nextdata + 2);
for (i = 0 ; i < data_len - 2 ; i++) {
cnt += sprintf((buf+cnt), "%c", nextdata[3 + i]);
if (nextdata[3 + i] == 0x0a && nextdata[4 + i] == 0xff)
more_data = _TRUE;
else if (nextdata[3 + i] == 0x0a && nextdata[4 + i] != 0xff)
more_data = _FALSE;
}
DBG_871X("[RTKFW, SEQ=%d]: %s", seq_no, buf);
data_len += 3;
total_length += data_len;
if (more_data == _TRUE) {
_rtw_memset(buf, '\0', 128);
cnt = 0;
nextdata = (pdata + total_length);
}
} while (more_data == _TRUE);
}
#endif /*CONFIG_FW_C2H_DEBUG*/
void update_IOT_info(_adapter *padapter)
{
struct mlme_ext_priv *pmlmeext = &padapter->mlmeextpriv;
struct mlme_ext_info *pmlmeinfo = &(pmlmeext->mlmext_info);
switch (pmlmeinfo->assoc_AP_vendor)
{
case HT_IOT_PEER_MARVELL:
pmlmeinfo->turboMode_cts2self = 1;
pmlmeinfo->turboMode_rtsen = 0;
break;
case HT_IOT_PEER_RALINK:
pmlmeinfo->turboMode_cts2self = 0;
pmlmeinfo->turboMode_rtsen = 1;
//disable high power
rtw_phydm_func_clr(padapter, ODM_BB_DYNAMIC_TXPWR);
break;
case HT_IOT_PEER_REALTEK:
//rtw_write16(padapter, 0x4cc, 0xffff);
//rtw_write16(padapter, 0x546, 0x01c0);
//disable high power
rtw_phydm_func_clr(padapter, ODM_BB_DYNAMIC_TXPWR);
break;
default:
pmlmeinfo->turboMode_cts2self = 0;
pmlmeinfo->turboMode_rtsen = 1;
break;
}
}
#ifdef CONFIG_AUTO_CHNL_SEL_NHM
void rtw_acs_start(_adapter *padapter, bool bStart)
{
if (_TRUE == bStart) {
ACS_OP acs_op = ACS_INIT;
rtw_hal_set_odm_var(padapter, HAL_ODM_AUTO_CHNL_SEL, &acs_op, _TRUE);
rtw_set_acs_channel(padapter, 0);
SET_ACS_STATE(padapter, ACS_ENABLE);
} else {
SET_ACS_STATE(padapter, ACS_DISABLE);
#ifdef DBG_AUTO_CHNL_SEL_NHM
if (1) {
u8 best_24g_ch = 0;
u8 best_5g_ch = 0;
rtw_hal_get_odm_var(padapter, HAL_ODM_AUTO_CHNL_SEL, &(best_24g_ch), &(best_5g_ch));
DBG_871X("[ACS-"ADPT_FMT"] Best 2.4G CH:%u\n", ADPT_ARG(padapter), best_24g_ch);
DBG_871X("[ACS-"ADPT_FMT"] Best 5G CH:%u\n", ADPT_ARG(padapter), best_5g_ch);
}
#endif
}
}
#endif
/* TODO: merge with phydm, see odm_SetCrystalCap() */
void hal_set_crystal_cap(_adapter *adapter, u8 crystal_cap)
{
crystal_cap = crystal_cap & 0x3F;
switch (rtw_get_chip_type(adapter)) {
#if defined(CONFIG_RTL8188E) || defined(CONFIG_RTL8188F)
case RTL8188E:
case RTL8188F:
/* write 0x24[16:11] = 0x24[22:17] = CrystalCap */
PHY_SetBBReg(adapter, REG_AFE_XTAL_CTRL, 0x007FF800, (crystal_cap | (crystal_cap << 6)));
break;
#endif
#if defined(CONFIG_RTL8812A)
case RTL8812:
/* write 0x2C[30:25] = 0x2C[24:19] = CrystalCap */
PHY_SetBBReg(adapter, REG_MAC_PHY_CTRL, 0x7FF80000, (crystal_cap | (crystal_cap << 6)));
break;
#endif
#if defined(CONFIG_RTL8723B) || defined(CONFIG_RTL8703B) || defined(CONFIG_RTL8821A) || defined(CONFIG_RTL8192E)
case RTL8723B:
case RTL8703B:
case RTL8821:
case RTL8192E:
/* write 0x2C[23:18] = 0x2C[17:12] = CrystalCap */
PHY_SetBBReg(adapter, REG_MAC_PHY_CTRL, 0x00FFF000, (crystal_cap | (crystal_cap << 6)));
break;
#endif
#if defined(CONFIG_RTL8814A)
case RTL8814A:
/* write 0x2C[26:21] = 0x2C[20:15] = CrystalCap*/
PHY_SetBBReg(adapter, REG_MAC_PHY_CTRL, 0x07FF8000, (crystal_cap | (crystal_cap << 6)));
break;
#endif
#if defined(CONFIG_RTL8821B) || defined(CONFIG_RTL8822B)
case RTL8821B:
case RTL8822B:
/* write 0x28[6:1] = 0x24[30:25] = CrystalCap */
crystal_cap = crystal_cap & 0x3F;
PHY_SetBBReg(adapter, REG_AFE_XTAL_CTRL, 0x7E000000, crystal_cap);
PHY_SetBBReg(adapter, REG_AFE_PLL_CTRL, 0x7E, crystal_cap);
break;
#endif
default:
rtw_warn_on(1);
}
}
int hal_spec_init(_adapter *adapter)
{
u8 interface_type = 0;
int ret = _SUCCESS;
interface_type = rtw_get_intf_type(adapter);
switch (rtw_get_chip_type(adapter)) {
#ifdef CONFIG_RTL8723B
case RTL8723B:
init_hal_spec_8723b(adapter);
break;
#endif
#ifdef CONFIG_RTL8703B
case RTL8703B:
init_hal_spec_8703b(adapter);
break;
#endif
#ifdef CONFIG_RTL8188E
case RTL8188E:
init_hal_spec_8188e(adapter);
break;
#endif
#ifdef CONFIG_RTL8188F
case RTL8188F:
init_hal_spec_8188f(adapter);
break;
#endif
#ifdef CONFIG_RTL8812A
case RTL8812:
init_hal_spec_8812a(adapter);
break;
#endif
#ifdef CONFIG_RTL8821A
case RTL8821:
init_hal_spec_8821a(adapter);
break;
#endif
#ifdef CONFIG_RTL8192E
case RTL8192E:
init_hal_spec_8192e(adapter);
break;
#endif
#ifdef CONFIG_RTL8814A
case RTL8814A:
init_hal_spec_8814a(adapter);
break;
#endif
default:
DBG_871X_LEVEL(_drv_err_, "%s: unknown chip_type:%u\n"
, __func__, rtw_get_chip_type(adapter));
ret = _FAIL;
break;
}
return ret;
}
static const char * const _band_cap_str[] = {
/* BIT0 */"2G",
/* BIT1 */"5G",
};
static const char * const _bw_cap_str[] = {
/* BIT0 */"5M",
/* BIT1 */"10M",
/* BIT2 */"20M",
/* BIT3 */"40M",
/* BIT4 */"80M",
/* BIT5 */"160M",
/* BIT6 */"80_80M",
};
static const char * const _wl_func_str[] = {
/* BIT0 */"P2P",
/* BIT1 */"MIRACAST",
/* BIT2 */"TDLS",
/* BIT3 */"FTM",
};
void dump_hal_spec(void *sel, _adapter *adapter)
{
struct hal_spec_t *hal_spec = GET_HAL_SPEC(adapter);
int i;
DBG_871X_SEL_NL(sel, "macid_num:%u\n", hal_spec->macid_num);
DBG_871X_SEL_NL(sel, "sec_cap:0x%02x\n", hal_spec->sec_cap);
DBG_871X_SEL_NL(sel, "sec_cam_ent_num:%u\n", hal_spec->sec_cam_ent_num);
DBG_871X_SEL_NL(sel, "nss_num:%u\n", hal_spec->nss_num);
DBG_871X_SEL_NL(sel, "band_cap:");
for (i = 0; i < BAND_CAP_BIT_NUM; i++) {
if (((hal_spec->band_cap) >> i) & BIT0 && _band_cap_str[i])
DBG_871X_SEL(sel, "%s ", _band_cap_str[i]);
}
DBG_871X_SEL(sel, "\n");
DBG_871X_SEL_NL(sel, "bw_cap:");
for (i = 0; i < BW_CAP_BIT_NUM; i++) {
if (((hal_spec->bw_cap) >> i) & BIT0 && _bw_cap_str[i])
DBG_871X_SEL(sel, "%s ", _bw_cap_str[i]);
}
DBG_871X_SEL(sel, "\n");
DBG_871X_SEL_NL(sel, "wl_func:");
for (i = 0; i < WL_FUNC_BIT_NUM; i++) {
if (((hal_spec->wl_func) >> i) & BIT0 && _wl_func_str[i])
DBG_871X_SEL(sel, "%s ", _wl_func_str[i]);
}
DBG_871X_SEL(sel, "\n");
}
inline bool hal_chk_band_cap(_adapter *adapter, u8 cap)
{
return (GET_HAL_SPEC(adapter)->band_cap & cap);
}
inline bool hal_chk_bw_cap(_adapter *adapter, u8 cap)
{
return (GET_HAL_SPEC(adapter)->bw_cap & cap);
}
inline bool hal_chk_wl_func(_adapter *adapter, u8 func)
{
return (GET_HAL_SPEC(adapter)->wl_func & func);
}
inline bool hal_is_band_support(_adapter *adapter, u8 band)
{
return (GET_HAL_SPEC(adapter)->band_cap & band_to_band_cap(band));
}
inline bool hal_is_bw_support(_adapter *adapter, u8 bw)
{
return (GET_HAL_SPEC(adapter)->bw_cap & ch_width_to_bw_cap(bw));
}
/*
* hal_largest_bw - starting from in_bw, get largest bw supported by HAL
* @adapter:
* @in_bw: starting bw, value of CHANNEL_WIDTH
*
* Returns: value of CHANNEL_WIDTH
*/
u8 hal_largest_bw(_adapter *adapter, u8 in_bw)
{
for (; in_bw > CHANNEL_WIDTH_20; in_bw--) {
if (hal_is_bw_support(adapter, in_bw))
break;
}
if (!hal_is_bw_support(adapter, in_bw))
rtw_warn_on(1);
return in_bw;
}