skyfall/rtl8188eu
1
0
Fork 0
mirror of https://github.com/lwfinger/rtl8188eu.git synced 2024-09-19 23:57:07 +00:00
Code Issues Projects Releases Packages Wiki Activity Actions

rtl8188eu: Convert non-standard variable types to regular ones

Browse source 
These include changing s1Byte to s8, etc.

Signed-off-by: Larry Finger <Larry.Finger@lwfinger.net>
This commit is contained in:
Larry Finger 2013-08-14 12:03:28 -05:00
parent 9dd1827027
commit 2db42a3fbf
39 changed files with 1041 additions and 1120 deletions
Show stats Download patch file Download diff file Expand all files Collapse all files

2
core/rtw_mlme.c
View file

@ -631,7 +631,7 @@ void rtw_update_scanned_network(struct adapter *adapter, struct wlan_bssid_ex *t
{
unsigned long irqL;
struct list_head *plist, *phead;
ULONG bssid_ex_sz;
u32 bssid_ex_sz;
struct mlme_priv *pmlmepriv = &(adapter->mlmepriv);
struct __queue *queue = &(pmlmepriv->scanned_queue);
struct wlan_network *pnetwork = NULL;

10
core/rtw_mp.c
View file

@ -270,11 +270,11 @@ s32 MPT_InitializeAdapter(struct adapter *pAdapter, u8 Channel)
dm_CheckTXPowerTracking(&pHalData->odmpriv); /* trigger thermal meter */
PHY_LCCalibrate(pAdapter);
pMptCtx->backup0xc50 = (u1Byte)PHY_QueryBBReg(pAdapter, rOFDM0_XAAGCCore1, bMaskByte0);
pMptCtx->backup0xc58 = (u1Byte)PHY_QueryBBReg(pAdapter, rOFDM0_XBAGCCore1, bMaskByte0);
pMptCtx->backup0xc30 = (u1Byte)PHY_QueryBBReg(pAdapter, rOFDM0_RxDetector1, bMaskByte0);
pMptCtx->backup0x52_RF_A = (u1Byte)PHY_QueryRFReg(pAdapter, RF_PATH_A, RF_0x52, 0x000F0);
pMptCtx->backup0x52_RF_B = (u1Byte)PHY_QueryRFReg(pAdapter, RF_PATH_A, RF_0x52, 0x000F0);
pMptCtx->backup0xc50 = (u8)PHY_QueryBBReg(pAdapter, rOFDM0_XAAGCCore1, bMaskByte0);
pMptCtx->backup0xc58 = (u8)PHY_QueryBBReg(pAdapter, rOFDM0_XBAGCCore1, bMaskByte0);
pMptCtx->backup0xc30 = (u8)PHY_QueryBBReg(pAdapter, rOFDM0_RxDetector1, bMaskByte0);
pMptCtx->backup0x52_RF_A = (u8)PHY_QueryRFReg(pAdapter, RF_PATH_A, RF_0x52, 0x000F0);
pMptCtx->backup0x52_RF_B = (u8)PHY_QueryRFReg(pAdapter, RF_PATH_A, RF_0x52, 0x000F0);
/* set ant to wifi side in mp mode */
rtw_write16(pAdapter, 0x870, 0x300);

26
core/rtw_mp_ioctl.c
View file

@ -481,8 +481,8 @@ _func_enter_;
return status;
}
if (poid_par_priv->information_buf_len == sizeof(ULONG)) {
*(ULONG *)poid_par_priv->information_buf = Adapter->mppriv.tx_pktcount;
if (poid_par_priv->information_buf_len == sizeof(u32)) {
*(u32 *)poid_par_priv->information_buf = Adapter->mppriv.tx_pktcount;
*poid_par_priv->bytes_rw = poid_par_priv->information_buf_len;
} else {
status = NDIS_STATUS_INVALID_LENGTH;
@ -505,8 +505,8 @@ _func_enter_;
return status;
}
RT_TRACE(_module_mp_, _drv_alert_, ("===> oid_rt_pro_query_rx_packet_received_hdl.\n"));
if (poid_par_priv->information_buf_len == sizeof(ULONG)) {
*(ULONG *)poid_par_priv->information_buf = Adapter->mppriv.rx_pktcount;
if (poid_par_priv->information_buf_len == sizeof(u32)) {
*(u32 *)poid_par_priv->information_buf = Adapter->mppriv.rx_pktcount;
*poid_par_priv->bytes_rw = poid_par_priv->information_buf_len;
RT_TRACE(_module_mp_, _drv_alert_, ("recv_ok:%d\n", Adapter->mppriv.rx_pktcount));
} else {
@ -530,8 +530,8 @@ _func_enter_;
return status;
}
RT_TRACE(_module_mp_, _drv_alert_, ("===> oid_rt_pro_query_rx_packet_crc32_error_hdl.\n"));
if (poid_par_priv->information_buf_len == sizeof(ULONG)) {
*(ULONG *)poid_par_priv->information_buf = Adapter->mppriv.rx_crcerrpktcount;
if (poid_par_priv->information_buf_len == sizeof(u32)) {
*(u32 *)poid_par_priv->information_buf = Adapter->mppriv.rx_crcerrpktcount;
*poid_par_priv->bytes_rw = poid_par_priv->information_buf_len;
RT_TRACE(_module_mp_, _drv_alert_, ("recv_err:%d\n", Adapter->mppriv.rx_crcerrpktcount));
} else {
@ -576,7 +576,7 @@ _func_enter_;
return status;
}
if (poid_par_priv->information_buf_len == sizeof(ULONG)) {
if (poid_par_priv->information_buf_len == sizeof(u32)) {
Adapter->mppriv.rx_pktcount = 0;
Adapter->mppriv.rx_crcerrpktcount = 0;
} else {
@ -621,16 +621,16 @@ _func_enter_;
if (poid_par_priv->type_of_oid != QUERY_OID)
return NDIS_STATUS_NOT_ACCEPTED;
if (poid_par_priv->information_buf_len != sizeof(ULONG))
if (poid_par_priv->information_buf_len != sizeof(u32))
return NDIS_STATUS_INVALID_LENGTH;
_irqlevel_changed_(&oldirql, LOWER);
*(ULONG *)poid_par_priv->information_buf = GetPhyRxPktReceived(Adapter);
*(u32 *)poid_par_priv->information_buf = GetPhyRxPktReceived(Adapter);
_irqlevel_changed_(&oldirql, RAISE);
*poid_par_priv->bytes_rw = poid_par_priv->information_buf_len;
RT_TRACE(_module_mp_, _drv_notice_, ("-oid_rt_get_phy_rx_packet_received_hdl: recv_ok=%d\n", *(ULONG *)poid_par_priv->information_buf));
RT_TRACE(_module_mp_, _drv_notice_, ("-oid_rt_get_phy_rx_packet_received_hdl: recv_ok=%d\n", *(u32 *)poid_par_priv->information_buf));
_func_exit_;
@ -650,18 +650,18 @@ _func_enter_;
return NDIS_STATUS_NOT_ACCEPTED;
if (poid_par_priv->information_buf_len != sizeof(ULONG))
if (poid_par_priv->information_buf_len != sizeof(u32))
return NDIS_STATUS_INVALID_LENGTH;
_irqlevel_changed_(&oldirql, LOWER);
*(ULONG *)poid_par_priv->information_buf = GetPhyRxPktCRC32Error(Adapter);
*(u32 *)poid_par_priv->information_buf = GetPhyRxPktCRC32Error(Adapter);
_irqlevel_changed_(&oldirql, RAISE);
*poid_par_priv->bytes_rw = poid_par_priv->information_buf_len;
RT_TRACE(_module_mp_, _drv_info_,
("-oid_rt_get_phy_rx_packet_crc32_error_hdl: recv_err =%d\n",
*(ULONG *)poid_par_priv->information_buf));
*(u32 *)poid_par_priv->information_buf));
_func_exit_;

4
core/rtw_security.c
View file

@ -259,7 +259,7 @@ _func_exit_;
/* 3 ===== TKIP related ===== */
static u32 secmicgetuint32(u8 *p)
/* Convert from Byte[] to Us4Byte32 in a portable way */
/* Convert from Byte[] to Us3232 in a portable way */
{
s32 i;
u32 res = 0;
@ -271,7 +271,7 @@ _func_exit_;
}
static void secmicputuint32(u8 *p, u32 val)
/* Convert from Us4Byte32 to Byte[] in a portable way */
/* Convert from Us3232 to Byte[] in a portable way */
{
long i;
_func_enter_;

108
hal/Hal8188ERateAdaptive.c
View file

@ -17,7 +17,7 @@ Major Change History:
/* Rate adaptive parameters */
static u1Byte RETRY_PENALTY[PERENTRY][RETRYSIZE+1] = {
static u8 RETRY_PENALTY[PERENTRY][RETRYSIZE+1] = {
{5, 4, 3, 2, 0, 3}, /* 92 , idx = 0 */
{6, 5, 4, 3, 0, 4}, /* 86 , idx = 1 */
{6, 5, 4, 2, 0, 4}, /* 81 , idx = 2 */
@ -43,12 +43,12 @@ static u1Byte RETRY_PENALTY[PERENTRY][RETRYSIZE+1] = {
{49, 16, 16, 0, 0, 48}
}; /* 3, idx = 0x16 */
static u1Byte RETRY_PENALTY_UP[RETRYSIZE+1] = {49, 44, 16, 16, 0, 48}; /* 12% for rate up */
static u8 RETRY_PENALTY_UP[RETRYSIZE+1] = {49, 44, 16, 16, 0, 48}; /* 12% for rate up */
static u1Byte PT_PENALTY[RETRYSIZE+1] = {34, 31, 30, 24, 0, 32};
static u8 PT_PENALTY[RETRYSIZE+1] = {34, 31, 30, 24, 0, 32};
/* wilson modify */
static u1Byte RETRY_PENALTY_IDX[2][RATESIZE] = {
static u8 RETRY_PENALTY_IDX[2][RATESIZE] = {
{4, 4, 4, 5, 4, 4, 5, 7, 7, 7, 8, 0x0a, /* SS>TH */
4, 4, 4, 4, 6, 0x0a, 0x0b, 0x0d,
5, 5, 7, 7, 8, 0x0b, 0x0d, 0x0f}, /* 0329 R01 */
@ -58,41 +58,41 @@ static u1Byte RETRY_PENALTY_IDX[2][RATESIZE] = {
9, 9, 9, 9, 0x0c, 0x0e, 0x11, 0x13}
};
static u1Byte RETRY_PENALTY_UP_IDX[RATESIZE] = {
static u8 RETRY_PENALTY_UP_IDX[RATESIZE] = {
0x0c, 0x0d, 0x0d, 0x0f, 0x0d, 0x0e,
0x0f, 0x0f, 0x10, 0x12, 0x13, 0x14, /* SS>TH */
0x0f, 0x10, 0x10, 0x12, 0x12, 0x13, 0x14, 0x15,
0x11, 0x11, 0x12, 0x13, 0x13, 0x13, 0x14, 0x15};
static u1Byte RSSI_THRESHOLD[RATESIZE] = {
static u8 RSSI_THRESHOLD[RATESIZE] = {
0, 0, 0, 0,
0, 0, 0, 0, 0, 0x24, 0x26, 0x2a,
0x18, 0x1a, 0x1d, 0x1f, 0x21, 0x27, 0x29, 0x2a,
0, 0, 0, 0x1f, 0x23, 0x28, 0x2a, 0x2c};
static u2Byte N_THRESHOLD_HIGH[RATESIZE] = {
static u16 N_THRESHOLD_HIGH[RATESIZE] = {
4, 4, 8, 16,
24, 36, 48, 72, 96, 144, 192, 216,
60, 80, 100, 160, 240, 400, 560, 640,
300, 320, 480, 720, 1000, 1200, 1600, 2000};
static u2Byte N_THRESHOLD_LOW[RATESIZE] = {
static u16 N_THRESHOLD_LOW[RATESIZE] = {
2, 2, 4, 8,
12, 18, 24, 36, 48, 72, 96, 108,
30, 40, 50, 80, 120, 200, 280, 320,
150, 160, 240, 360, 500, 600, 800, 1000};
static u1Byte TRYING_NECESSARY[RATESIZE] = {
static u8 TRYING_NECESSARY[RATESIZE] = {
2, 2, 2, 2,
2, 2, 3, 3, 4, 4, 5, 7,
4, 4, 7, 10, 10, 12, 12, 18,
5, 7, 7, 8, 11, 18, 36, 60}; /* 0329 1207 */
static u1Byte DROPING_NECESSARY[RATESIZE] = {
static u8 DROPING_NECESSARY[RATESIZE] = {
1, 1, 1, 1,
1, 2, 3, 4, 5, 6, 7, 8,
1, 2, 3, 4, 5, 6, 7, 8,
5, 6, 7, 8, 9, 10, 11, 12};
static u4Byte INIT_RATE_FALLBACK_TABLE[16] = {
static u32 INIT_RATE_FALLBACK_TABLE[16] = {
0x0f8ff015, /* 0: 40M BGN mode */
0x0f8ff010, /* 1: 40M GN mode */
0x0f8ff005, /* 2: BN mode/ 40M BGN mode */
@ -111,8 +111,8 @@ static u4Byte INIT_RATE_FALLBACK_TABLE[16] = {
0, /* 15: */
};
static u1Byte PendingForRateUpFail[5] = {2, 10, 24, 40, 60};
static u2Byte DynamicTxRPTTiming[6] = {
static u8 PendingForRateUpFail[5] = {2, 10, 24, 40, 60};
static u16 DynamicTxRPTTiming[6] = {
0x186a, 0x30d4, 0x493e, 0x61a8, 0x7a12 , 0x927c}; /* 200ms-1200ms */
/* End Rate adaptive parameters */
@ -120,10 +120,10 @@ static u2Byte DynamicTxRPTTiming[6] = {
static void odm_SetTxRPTTiming_8188E(
struct odm_dm_struct *dm_odm,
struct odm_ra_info *pRaInfo,
u1Byte extend
u8 extend
)
{
u1Byte idx = 0;
u8 idx = 0;
for (idx = 0; idx < 5; idx++)
if (DynamicTxRPTTiming[idx] == pRaInfo->RptTime)
@ -146,8 +146,8 @@ static void odm_SetTxRPTTiming_8188E(
static int odm_RateDown_8188E(struct odm_dm_struct *dm_odm, struct odm_ra_info *pRaInfo)
{
u1Byte RateID, LowestRate, HighestRate;
u1Byte i;
u8 RateID, LowestRate, HighestRate;
u8 i;
ODM_RT_TRACE(dm_odm, ODM_COMP_RATE_ADAPTIVE, ODM_DBG_TRACE, ("=====>odm_RateDown_8188E()\n"));
if (NULL == pRaInfo) {
@ -205,8 +205,8 @@ static int odm_RateUp_8188E(
struct odm_ra_info *pRaInfo
)
{
u1Byte RateID, HighestRate;
u1Byte i;
u8 RateID, HighestRate;
u8 i;
ODM_RT_TRACE(dm_odm, ODM_COMP_RATE_ADAPTIVE, ODM_DBG_TRACE, ("=====>odm_RateUp_8188E()\n"));
if (NULL == pRaInfo) {
@ -258,7 +258,7 @@ RateUpfinish:
static void odm_ResetRaCounter_8188E(struct odm_ra_info *pRaInfo)
{
u1Byte RateID;
u8 RateID;
RateID = pRaInfo->DecisionRate;
pRaInfo->NscUp = (N_THRESHOLD_HIGH[RateID]+N_THRESHOLD_LOW[RateID])>>1;
@ -269,9 +269,9 @@ static void odm_RateDecision_8188E(struct odm_dm_struct *dm_odm,
struct odm_ra_info *pRaInfo
)
{
u1Byte RateID = 0, RtyPtID = 0, PenaltyID1 = 0, PenaltyID2 = 0;
/* u4Byte pool_retry; */
static u1Byte DynamicTxRPTTimingCounter;
u8 RateID = 0, RtyPtID = 0, PenaltyID1 = 0, PenaltyID2 = 0;
/* u32 pool_retry; */
static u8 DynamicTxRPTTimingCounter;
ODM_RT_TRACE(dm_odm, ODM_COMP_RATE_ADAPTIVE, ODM_DBG_TRACE, ("=====>odm_RateDecision_8188E()\n"));
@ -357,8 +357,8 @@ static void odm_RateDecision_8188E(struct odm_dm_struct *dm_odm,
static int odm_ARFBRefresh_8188E(struct odm_dm_struct *dm_odm, struct odm_ra_info *pRaInfo)
{ /* Wilson 2011/10/26 */
u4Byte MaskFromReg;
s1Byte i;
u32 MaskFromReg;
s8 i;
switch (pRaInfo->RateID) {
case RATR_INX_WIRELESS_NGB:
@ -498,11 +498,11 @@ static void odm_PTTryState_8188E(struct odm_ra_info *pRaInfo)
static void odm_PTDecision_8188E(struct odm_ra_info *pRaInfo)
{
u1Byte j;
u1Byte temp_stage;
u4Byte numsc;
u4Byte num_total;
u1Byte stage_id;
u8 j;
u8 temp_stage;
u32 numsc;
u32 num_total;
u8 stage_id;
numsc = 0;
num_total = pRaInfo->TOTAL * PT_PENALTY[5];
@ -534,7 +534,7 @@ static void odm_PTDecision_8188E(struct odm_ra_info *pRaInfo)
static void
odm_RATxRPTTimerSetting(
struct odm_dm_struct *dm_odm,
u2Byte minRptTime
u16 minRptTime
)
{
ODM_RT_TRACE(dm_odm, ODM_COMP_RATE_ADAPTIVE, ODM_DBG_TRACE, (" =====>odm_RATxRPTTimerSetting()\n"));
@ -560,11 +560,11 @@ ODM_RASupport_Init(
dm_odm->RaSupport88E = true;
}
int ODM_RAInfo_Init(struct odm_dm_struct *dm_odm, u1Byte macid)
int ODM_RAInfo_Init(struct odm_dm_struct *dm_odm, u8 macid)
{
struct odm_ra_info *pRaInfo = &dm_odm->RAInfo[macid];
u1Byte WirelessMode = 0xFF; /* invalid value */
u1Byte max_rate_idx = 0x13; /* MCS7 */
u8 WirelessMode = 0xFF; /* invalid value */
u8 max_rate_idx = 0x13; /* MCS7 */
if (dm_odm->pWirelessMode != NULL)
WirelessMode = *(dm_odm->pWirelessMode);
@ -619,7 +619,7 @@ int ODM_RAInfo_Init(struct odm_dm_struct *dm_odm, u1Byte macid)
int ODM_RAInfo_Init_all(struct odm_dm_struct *dm_odm)
{
u1Byte macid = 0;
u8 macid = 0;
ODM_RT_TRACE(dm_odm, ODM_COMP_RATE_ADAPTIVE, ODM_DBG_LOUD, ("=====>\n"));
dm_odm->CurrminRptTime = 0;
@ -630,7 +630,7 @@ int ODM_RAInfo_Init_all(struct odm_dm_struct *dm_odm)
return 0;
}
u1Byte ODM_RA_GetShortGI_8188E(struct odm_dm_struct *dm_odm, u1Byte macid)
u8 ODM_RA_GetShortGI_8188E(struct odm_dm_struct *dm_odm, u8 macid)
{
if ((NULL == dm_odm) || (macid >= ASSOCIATE_ENTRY_NUM))
return 0;
@ -639,9 +639,9 @@ u1Byte ODM_RA_GetShortGI_8188E(struct odm_dm_struct *dm_odm, u1Byte macid)
return dm_odm->RAInfo[macid].RateSGI;
}
u1Byte ODM_RA_GetDecisionRate_8188E(struct odm_dm_struct *dm_odm, u1Byte macid)
u8 ODM_RA_GetDecisionRate_8188E(struct odm_dm_struct *dm_odm, u8 macid)
{
u1Byte DecisionRate = 0;
u8 DecisionRate = 0;
if ((NULL == dm_odm) || (macid >= ASSOCIATE_ENTRY_NUM))
return 0;
@ -651,9 +651,9 @@ u1Byte ODM_RA_GetDecisionRate_8188E(struct odm_dm_struct *dm_odm, u1Byte macid)
return DecisionRate;
}
u1Byte ODM_RA_GetHwPwrStatus_8188E(struct odm_dm_struct *dm_odm, u1Byte macid)
u8 ODM_RA_GetHwPwrStatus_8188E(struct odm_dm_struct *dm_odm, u8 macid)
{
u1Byte PTStage = 5;
u8 PTStage = 5;
if ((NULL == dm_odm) || (macid >= ASSOCIATE_ENTRY_NUM))
return 0;
@ -663,7 +663,7 @@ u1Byte ODM_RA_GetHwPwrStatus_8188E(struct odm_dm_struct *dm_odm, u1Byte macid)
return PTStage;
}
void ODM_RA_UpdateRateInfo_8188E(struct odm_dm_struct *dm_odm, u1Byte macid, u1Byte RateID, u4Byte RateMask, u1Byte SGIEnable)
void ODM_RA_UpdateRateInfo_8188E(struct odm_dm_struct *dm_odm, u8 macid, u8 RateID, u32 RateMask, u8 SGIEnable)
{
struct odm_ra_info *pRaInfo = NULL;
@ -680,7 +680,7 @@ void ODM_RA_UpdateRateInfo_8188E(struct odm_dm_struct *dm_odm, u1Byte macid, u1B
odm_ARFBRefresh_8188E(dm_odm, pRaInfo);
}
void ODM_RA_SetRSSI_8188E(struct odm_dm_struct *dm_odm, u1Byte macid, u1Byte Rssi)
void ODM_RA_SetRSSI_8188E(struct odm_dm_struct *dm_odm, u8 macid, u8 Rssi)
{
struct odm_ra_info *pRaInfo = NULL;
@ -693,18 +693,18 @@ void ODM_RA_SetRSSI_8188E(struct odm_dm_struct *dm_odm, u1Byte macid, u1Byte Rss
pRaInfo->RssiStaRA = Rssi;
}
void ODM_RA_Set_TxRPT_Time(struct odm_dm_struct *dm_odm, u2Byte minRptTime)
void ODM_RA_Set_TxRPT_Time(struct odm_dm_struct *dm_odm, u16 minRptTime)
{
ODM_Write2Byte(dm_odm, REG_TX_RPT_TIME, minRptTime);
}
void ODM_RA_TxRPT2Handle_8188E(struct odm_dm_struct *dm_odm, pu1Byte TxRPT_Buf, u2Byte TxRPT_Len, u4Byte macid_entry0, u4Byte macid_entry1)
void ODM_RA_TxRPT2Handle_8188E(struct odm_dm_struct *dm_odm, u8 *TxRPT_Buf, u16 TxRPT_Len, u32 macid_entry0, u32 macid_entry1)
{
struct odm_ra_info *pRAInfo = NULL;
u1Byte MacId = 0;
pu1Byte pBuffer = NULL;
u4Byte valid = 0, ItemNum = 0;
u2Byte minRptTime = 0x927c;
u8 MacId = 0;
u8 *pBuffer = NULL;
u32 valid = 0, ItemNum = 0;
u16 minRptTime = 0x927c;
ODM_RT_TRACE(dm_odm, ODM_COMP_RATE_ADAPTIVE, ODM_DBG_LOUD,
("=====>ODM_RA_TxRPT2Handle_8188E(): valid0 =%d valid1 =%d BufferLength =%d\n",
@ -723,12 +723,12 @@ void ODM_RA_TxRPT2Handle_8188E(struct odm_dm_struct *dm_odm, pu1Byte TxRPT_Buf,
pRAInfo = &(dm_odm->RAInfo[MacId]);
if (valid) {
pRAInfo->RTY[0] = (u2Byte)GET_TX_REPORT_TYPE1_RERTY_0(pBuffer);
pRAInfo->RTY[1] = (u2Byte)GET_TX_REPORT_TYPE1_RERTY_1(pBuffer);
pRAInfo->RTY[2] = (u2Byte)GET_TX_REPORT_TYPE1_RERTY_2(pBuffer);
pRAInfo->RTY[3] = (u2Byte)GET_TX_REPORT_TYPE1_RERTY_3(pBuffer);
pRAInfo->RTY[4] = (u2Byte)GET_TX_REPORT_TYPE1_RERTY_4(pBuffer);
pRAInfo->DROP = (u2Byte)GET_TX_REPORT_TYPE1_DROP_0(pBuffer);
pRAInfo->RTY[0] = (u16)GET_TX_REPORT_TYPE1_RERTY_0(pBuffer);
pRAInfo->RTY[1] = (u16)GET_TX_REPORT_TYPE1_RERTY_1(pBuffer);
pRAInfo->RTY[2] = (u16)GET_TX_REPORT_TYPE1_RERTY_2(pBuffer);
pRAInfo->RTY[3] = (u16)GET_TX_REPORT_TYPE1_RERTY_3(pBuffer);
pRAInfo->RTY[4] = (u16)GET_TX_REPORT_TYPE1_RERTY_4(pBuffer);
pRAInfo->DROP = (u16)GET_TX_REPORT_TYPE1_DROP_0(pBuffer);
pRAInfo->TOTAL = pRAInfo->RTY[0] + pRAInfo->RTY[1] +
pRAInfo->RTY[2] + pRAInfo->RTY[3] +
pRAInfo->RTY[4] + pRAInfo->DROP;

92
hal/HalHWImg8188E_BB.c
View file

@ -29,12 +29,12 @@
v2 = array[i+1]; \
} while (0)
static bool CheckCondition(const u4Byte condition, const u4Byte hex)
static bool CheckCondition(const u32 condition, const u32 hex)
{
u4Byte _board = (hex & 0x000000FF);
u4Byte _interface = (hex & 0x0000FF00) >> 8;
u4Byte _platform = (hex & 0x00FF0000) >> 16;
u4Byte cond = condition;
u32 _board = (hex & 0x000000FF);
u32 _interface = (hex & 0x0000FF00) >> 8;
u32 _platform = (hex & 0x00FF0000) >> 16;
u32 cond = condition;
if (condition == 0xCDCDCDCD)
return true;
@ -60,7 +60,7 @@ static bool CheckCondition(const u4Byte condition, const u4Byte hex)
* AGC_TAB_1T.TXT
******************************************************************************/
static u4Byte array_agc_tab_1t_8188e[] = {
static u32 array_agc_tab_1t_8188e[] = {
0xC78, 0xFB000001,
0xC78, 0xFB010001,
0xC78, 0xFB020001,
@ -193,15 +193,15 @@ static u4Byte array_agc_tab_1t_8188e[] = {
enum HAL_STATUS ODM_ReadAndConfig_AGC_TAB_1T_8188E(struct odm_dm_struct *dm_odm)
{
u4Byte hex = 0;
u4Byte i = 0;
u2Byte count = 0;
pu4Byte ptr_array = NULL;
u1Byte platform = dm_odm->SupportPlatform;
u1Byte interfaceValue = dm_odm->SupportInterface;
u1Byte board = dm_odm->BoardType;
u4Byte arraylen = sizeof(array_agc_tab_1t_8188e)/sizeof(u4Byte);
pu4Byte array = array_agc_tab_1t_8188e;
u32 hex = 0;
u32 i = 0;
u16 count = 0;
u32 *ptr_array = NULL;
u8 platform = dm_odm->SupportPlatform;
u8 interfaceValue = dm_odm->SupportInterface;
u8 board = dm_odm->BoardType;
u32 arraylen = sizeof(array_agc_tab_1t_8188e)/sizeof(u32);
u32 *array = array_agc_tab_1t_8188e;
bool biol = false;
struct adapter *adapter = dm_odm->Adapter;
struct xmit_frame *pxmit_frame;
@ -223,15 +223,15 @@ enum HAL_STATUS ODM_ReadAndConfig_AGC_TAB_1T_8188E(struct odm_dm_struct *dm_odm)
}
for (i = 0; i < arraylen; i += 2) {
u4Byte v1 = array[i];
u4Byte v2 = array[i+1];
u32 v1 = array[i];
u32 v2 = array[i+1];
/* This (offset, data) pair meets the condition. */
if (v1 < 0xCDCDCDCD) {
if (biol) {
if (rtw_IOL_cmd_boundary_handle(pxmit_frame))
bndy_cnt++;
rtw_IOL_append_WD_cmd(pxmit_frame, (u2Byte)v1, v2, bMaskDWord);
rtw_IOL_append_WD_cmd(pxmit_frame, (u16)v1, v2, bMaskDWord);
} else {
odm_ConfigBB_AGC_8188E(dm_odm, v1, bMaskDWord, v2);
}
@ -254,7 +254,7 @@ enum HAL_STATUS ODM_ReadAndConfig_AGC_TAB_1T_8188E(struct odm_dm_struct *dm_odm)
if (biol) {
if (rtw_IOL_cmd_boundary_handle(pxmit_frame))
bndy_cnt++;
rtw_IOL_append_WD_cmd(pxmit_frame, (u2Byte)v1, v2, bMaskDWord);
rtw_IOL_append_WD_cmd(pxmit_frame, (u16)v1, v2, bMaskDWord);
} else {
odm_ConfigBB_AGC_8188E(dm_odm, v1, bMaskDWord, v2);
}
@ -279,7 +279,7 @@ enum HAL_STATUS ODM_ReadAndConfig_AGC_TAB_1T_8188E(struct odm_dm_struct *dm_odm)
* PHY_REG_1T.TXT
******************************************************************************/
static u4Byte array_phy_reg_1t_8188e[] = {
static u32 array_phy_reg_1t_8188e[] = {
0x800, 0x80040000,
0x804, 0x00000003,
0x808, 0x0000FC00,
@ -475,15 +475,15 @@ static u4Byte array_phy_reg_1t_8188e[] = {
enum HAL_STATUS ODM_ReadAndConfig_PHY_REG_1T_8188E(struct odm_dm_struct *dm_odm)
{
u4Byte hex = 0;
u4Byte i = 0;
u2Byte count = 0;
pu4Byte ptr_array = NULL;
u1Byte platform = dm_odm->SupportPlatform;
u1Byte interfaceValue = dm_odm->SupportInterface;
u1Byte board = dm_odm->BoardType;
u4Byte arraylen = sizeof(array_phy_reg_1t_8188e)/sizeof(u4Byte);
pu4Byte array = array_phy_reg_1t_8188e;
u32 hex = 0;
u32 i = 0;
u16 count = 0;
u32 *ptr_array = NULL;
u8 platform = dm_odm->SupportPlatform;
u8 interfaceValue = dm_odm->SupportInterface;
u8 board = dm_odm->BoardType;
u32 arraylen = sizeof(array_phy_reg_1t_8188e)/sizeof(u32);
u32 *array = array_phy_reg_1t_8188e;
bool biol = false;
struct adapter *adapter = dm_odm->Adapter;
struct xmit_frame *pxmit_frame;
@ -504,8 +504,8 @@ enum HAL_STATUS ODM_ReadAndConfig_PHY_REG_1T_8188E(struct odm_dm_struct *dm_odm)
}
for (i = 0; i < arraylen; i += 2) {
u4Byte v1 = array[i];
u4Byte v2 = array[i+1];
u32 v1 = array[i];
u32 v2 = array[i+1];
/* This (offset, data) pair meets the condition. */
if (v1 < 0xCDCDCDCD) {
@ -527,7 +527,7 @@ enum HAL_STATUS ODM_ReadAndConfig_PHY_REG_1T_8188E(struct odm_dm_struct *dm_odm)
} else {
if (v1 == 0xa24)
dm_odm->RFCalibrateInfo.RegA24 = v2;
rtw_IOL_append_WD_cmd(pxmit_frame, (u2Byte)v1, v2, bMaskDWord);
rtw_IOL_append_WD_cmd(pxmit_frame, (u16)v1, v2, bMaskDWord);
}
} else {
odm_ConfigBB_PHY_8188E(dm_odm, v1, bMaskDWord, v2);
@ -566,7 +566,7 @@ enum HAL_STATUS ODM_ReadAndConfig_PHY_REG_1T_8188E(struct odm_dm_struct *dm_odm)
if (v1 == 0xa24)
dm_odm->RFCalibrateInfo.RegA24 = v2;
rtw_IOL_append_WD_cmd(pxmit_frame, (u2Byte)v1, v2, bMaskDWord);
rtw_IOL_append_WD_cmd(pxmit_frame, (u16)v1, v2, bMaskDWord);
}
} else {
odm_ConfigBB_PHY_8188E(dm_odm, v1, bMaskDWord, v2);
@ -592,7 +592,7 @@ enum HAL_STATUS ODM_ReadAndConfig_PHY_REG_1T_8188E(struct odm_dm_struct *dm_odm)
* PHY_REG_PG.TXT
******************************************************************************/
static u4Byte array_phy_reg_pg_8188e[] = {
static u32 array_phy_reg_pg_8188e[] = {
0xE00, 0xFFFFFFFF, 0x06070809,
0xE04, 0xFFFFFFFF, 0x02020405,
0xE08, 0x0000FF00, 0x00000006,
@ -686,24 +686,24 @@ static u4Byte array_phy_reg_pg_8188e[] = {
void ODM_ReadAndConfig_PHY_REG_PG_8188E(struct odm_dm_struct *dm_odm)
{
u4Byte hex;
u4Byte i = 0;
u2Byte count = 0;
pu4Byte ptr_array = NULL;
u1Byte platform = dm_odm->SupportPlatform;
u1Byte interfaceValue = dm_odm->SupportInterface;
u1Byte board = dm_odm->BoardType;
u4Byte arraylen = sizeof(array_phy_reg_pg_8188e) / sizeof(u4Byte);
pu4Byte array = array_phy_reg_pg_8188e;
u32 hex;
u32 i = 0;
u16 count = 0;
u32 *ptr_array = NULL;
u8 platform = dm_odm->SupportPlatform;
u8 interfaceValue = dm_odm->SupportInterface;
u8 board = dm_odm->BoardType;
u32 arraylen = sizeof(array_phy_reg_pg_8188e) / sizeof(u32);
u32 *array = array_phy_reg_pg_8188e;
bool biol = false;
hex = board + (interfaceValue << 8);
hex += (platform << 16) + 0xFF000000;
for (i = 0; i < arraylen; i += 3) {
u4Byte v1 = array[i];
u4Byte v2 = array[i+1];
u4Byte v3 = array[i+2];
u32 v1 = array[i];
u32 v2 = array[i+1];
u32 v3 = array[i+2];
/* this line is a line of pure_body */
if (v1 < 0xCDCDCDCD) {

42
hal/HalHWImg8188E_MAC.c
View file

@ -21,12 +21,12 @@
#include "odm_precomp.h"
#include <rtw_iol.h>
static bool Checkcondition(const u4Byte condition, const u4Byte hex)
static bool Checkcondition(const u32 condition, const u32 hex)
{
u4Byte _board = (hex & 0x000000FF);
u4Byte _interface = (hex & 0x0000FF00) >> 8;
u4Byte _platform = (hex & 0x00FF0000) >> 16;
u4Byte cond = condition;
u32 _board = (hex & 0x000000FF);
u32 _interface = (hex & 0x0000FF00) >> 8;
u32 _platform = (hex & 0x00FF0000) >> 16;
u32 cond = condition;
if (condition == 0xCDCDCDCD)
return true;
@ -52,7 +52,7 @@ static bool Checkcondition(const u4Byte condition, const u4Byte hex)
* MAC_REG.TXT
******************************************************************************/
static u4Byte array_MAC_REG_8188E[] = {
static u32 array_MAC_REG_8188E[] = {
0x026, 0x00000041,
0x027, 0x00000035,
0x428, 0x0000000A,
@ -149,15 +149,15 @@ enum HAL_STATUS ODM_ReadAndConfig_MAC_REG_8188E(struct odm_dm_struct *dm_odm)
{
#define READ_NEXT_PAIR(v1, v2, i) do { i += 2; v1 = array[i]; v2 = array[i+1]; } while (0)
u4Byte hex = 0;
u4Byte i;
u2Byte count = 0;
pu4Byte ptr_array = NULL;
u1Byte platform = dm_odm->SupportPlatform;
u1Byte interface_val = dm_odm->SupportInterface;
u1Byte board = dm_odm->BoardType;
u4Byte array_len = sizeof(array_MAC_REG_8188E)/sizeof(u4Byte);
pu4Byte array = array_MAC_REG_8188E;
u32 hex = 0;
u32 i;
u16 count = 0;
u32 *ptr_array = NULL;
u8 platform = dm_odm->SupportPlatform;
u8 interface_val = dm_odm->SupportInterface;
u8 board = dm_odm->BoardType;
u32 array_len = sizeof(array_MAC_REG_8188E)/sizeof(u32);
u32 *array = array_MAC_REG_8188E;
bool biol = false;
struct adapter *adapt = dm_odm->Adapter;
@ -180,17 +180,17 @@ enum HAL_STATUS ODM_ReadAndConfig_MAC_REG_8188E(struct odm_dm_struct *dm_odm)
}
for (i = 0; i < array_len; i += 2) {
u4Byte v1 = array[i];
u4Byte v2 = array[i+1];
u32 v1 = array[i];
u32 v2 = array[i+1];
/* This (offset, data) pair meets the condition. */
if (v1 < 0xCDCDCDCD) {
if (biol) {
if (rtw_IOL_cmd_boundary_handle(pxmit_frame))
bndy_cnt++;
rtw_IOL_append_WB_cmd(pxmit_frame, (u2Byte)v1, (u1Byte)v2, 0xFF);
rtw_IOL_append_WB_cmd(pxmit_frame, (u16)v1, (u8)v2, 0xFF);
} else {
odm_ConfigMAC_8188E(dm_odm, v1, (u1Byte)v2);
odm_ConfigMAC_8188E(dm_odm, v1, (u8)v2);
}
continue;
} else { /* This line is the start line of branch. */
@ -211,9 +211,9 @@ enum HAL_STATUS ODM_ReadAndConfig_MAC_REG_8188E(struct odm_dm_struct *dm_odm)
if (biol) {
if (rtw_IOL_cmd_boundary_handle(pxmit_frame))
bndy_cnt++;
rtw_IOL_append_WB_cmd(pxmit_frame, (u2Byte)v1, (u1Byte)v2, 0xFF);
rtw_IOL_append_WB_cmd(pxmit_frame, (u16)v1, (u8)v2, 0xFF);
} else {
odm_ConfigMAC_8188E(dm_odm, v1, (u1Byte)v2);
odm_ConfigMAC_8188E(dm_odm, v1, (u8)v2);
}
READ_NEXT_PAIR(v1, v2, i);

38
hal/HalHWImg8188E_RF.c
View file

@ -22,12 +22,12 @@
#include <rtw_iol.h>
static bool CheckCondition(const u4Byte Condition, const u4Byte Hex)
static bool CheckCondition(const u32 Condition, const u32 Hex)
{
u4Byte _board = (Hex & 0x000000FF);
u4Byte _interface = (Hex & 0x0000FF00) >> 8;
u4Byte _platform = (Hex & 0x00FF0000) >> 16;
u4Byte cond = Condition;
u32 _board = (Hex & 0x000000FF);
u32 _interface = (Hex & 0x0000FF00) >> 8;
u32 _platform = (Hex & 0x00FF0000) >> 16;
u32 cond = Condition;
if (Condition == 0xCDCDCDCD)
return true;
@ -53,7 +53,7 @@ static bool CheckCondition(const u4Byte Condition, const u4Byte Hex)
* RadioA_1T.TXT
******************************************************************************/
static u4Byte Array_RadioA_1T_8188E[] = {
static u32 Array_RadioA_1T_8188E[] = {
0x000, 0x00030000,
0x008, 0x00084000,
0x018, 0x00000407,
@ -161,15 +161,15 @@ enum HAL_STATUS ODM_ReadAndConfig_RadioA_1T_8188E(struct odm_dm_struct *pDM_Odm)
{ i += 2; v1 = Array[i]; \
v2 = Array[i+1]; } while (0)
u4Byte hex = 0;
u4Byte i = 0;
u2Byte count = 0;
pu4Byte ptr_array = NULL;
u1Byte platform = pDM_Odm->SupportPlatform;
u1Byte interfaceValue = pDM_Odm->SupportInterface;
u1Byte board = pDM_Odm->BoardType;
u4Byte ArrayLen = sizeof(Array_RadioA_1T_8188E)/sizeof(u4Byte);
pu4Byte Array = Array_RadioA_1T_8188E;
u32 hex = 0;
u32 i = 0;
u16 count = 0;
u32 *ptr_array = NULL;
u8 platform = pDM_Odm->SupportPlatform;
u8 interfaceValue = pDM_Odm->SupportInterface;
u8 board = pDM_Odm->BoardType;
u32 ArrayLen = sizeof(Array_RadioA_1T_8188E)/sizeof(u32);
u32 *Array = Array_RadioA_1T_8188E;
bool biol = false;
struct adapter *Adapter = pDM_Odm->Adapter;
struct xmit_frame *pxmit_frame;
@ -191,8 +191,8 @@ enum HAL_STATUS ODM_ReadAndConfig_RadioA_1T_8188E(struct odm_dm_struct *pDM_Odm)
}
for (i = 0; i < ArrayLen; i += 2) {
u4Byte v1 = Array[i];
u4Byte v2 = Array[i+1];
u32 v1 = Array[i];
u32 v2 = Array[i+1];
/* This (offset, data) pair meets the condition. */
if (v1 < 0xCDCDCDCD) {
@ -213,7 +213,7 @@ enum HAL_STATUS ODM_ReadAndConfig_RadioA_1T_8188E(struct odm_dm_struct *pDM_Odm)
else if (v1 == 0xf9)
rtw_IOL_append_DELAY_US_cmd(pxmit_frame, 1);
else
rtw_IOL_append_WRF_cmd(pxmit_frame, ODM_RF_PATH_A, (u2Byte)v1, v2, bRFRegOffsetMask);
rtw_IOL_append_WRF_cmd(pxmit_frame, ODM_RF_PATH_A, (u16)v1, v2, bRFRegOffsetMask);
} else {
odm_ConfigRF_RadioA_8188E(pDM_Odm, v1, v2);
}
@ -249,7 +249,7 @@ enum HAL_STATUS ODM_ReadAndConfig_RadioA_1T_8188E(struct odm_dm_struct *pDM_Odm)
else if (v1 == 0xf9)
rtw_IOL_append_DELAY_US_cmd(pxmit_frame, 1);
else
rtw_IOL_append_WRF_cmd(pxmit_frame, ODM_RF_PATH_A, (u2Byte)v1, v2, bRFRegOffsetMask);
rtw_IOL_append_WRF_cmd(pxmit_frame, ODM_RF_PATH_A, (u16)v1, v2, bRFRegOffsetMask);
} else {
odm_ConfigRF_RadioA_8188E(pDM_Odm, v1, v2);
}

8
hal/HalPhyRf.c
View file

@ -26,7 +26,7 @@
void ODM_ResetIQKResult(struct odm_dm_struct *pDM_Odm)
{
u1Byte i;
u8 i;
struct adapter *adapt = pDM_Odm->Adapter;
if (!IS_HARDWARE_TYPE_8192D(adapt))
@ -52,16 +52,16 @@ void ODM_ResetIQKResult(struct odm_dm_struct *pDM_Odm)
}
}
u1Byte ODM_GetRightChnlPlaceforIQK(u1Byte chnl)
u8 ODM_GetRightChnlPlaceforIQK(u8 chnl)
{
u1Byte channel_all[ODM_TARGET_CHNL_NUM_2G_5G] = {
u8 channel_all[ODM_TARGET_CHNL_NUM_2G_5G] = {
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14,
36, 38, 40, 42, 44, 46, 48, 50, 52, 54, 56, 58, 60, 62, 64,
100, 102, 104, 106, 108, 110, 112, 114, 116, 118, 120, 122,
124, 126, 128, 130, 132, 134, 136, 138, 140, 149, 151, 153,
155, 157, 159, 161, 163, 165
};
u1Byte place = chnl;
u8 place = chnl;
if (chnl > 14) {
for (place = 14; place < sizeof(channel_all); place++) {

234
hal/HalPhyRf_8188e.c
View file

@ -48,12 +48,12 @@
* 04/23/2012 MHC Adjust TX agc directly not throughput BB digital.
*
*---------------------------------------------------------------------------*/
void ODM_TxPwrTrackAdjust88E(struct odm_dm_struct *dm_odm, u1Byte Type,/* 0 = OFDM, 1 = CCK */
pu1Byte pDirection, /* 1 = +(increase) 2 = -(decrease) */
pu4Byte pOutWriteVal /* Tx tracking CCK/OFDM BB swing index adjust */
void ODM_TxPwrTrackAdjust88E(struct odm_dm_struct *dm_odm, u8 Type,/* 0 = OFDM, 1 = CCK */
u8 *pDirection, /* 1 = +(increase) 2 = -(decrease) */
u32 *pOutWriteVal /* Tx tracking CCK/OFDM BB swing index adjust */
)
{
u1Byte pwr_value = 0;
u8 pwr_value = 0;
/* Tx power tracking BB swing table. */
/* The base index = 12. +((12-n)/2)dB 13~?? = decrease tx pwr by -((n-12)/2)dB */
if (Type == 0) { /* For OFDM afjust */
@ -130,20 +130,20 @@ odm_TXPowerTrackingCallback_ThermalMeter_8188E(
)
{
struct hal_data_8188e *pHalData = GET_HAL_DATA(Adapter);
u1Byte ThermalValue = 0, delta, delta_LCK, delta_IQK, offset;
u1Byte ThermalValue_AVG_count = 0;
u4Byte ThermalValue_AVG = 0;
s4Byte ele_A = 0, ele_D, TempCCk, X, value32;
s4Byte Y, ele_C = 0;
s1Byte OFDM_index[2], CCK_index = 0;
s1Byte OFDM_index_old[2] = {0, 0}, CCK_index_old = 0;
u4Byte i = 0, j = 0;
u8 ThermalValue = 0, delta, delta_LCK, delta_IQK, offset;
u8 ThermalValue_AVG_count = 0;
u32 ThermalValue_AVG = 0;
s32 ele_A = 0, ele_D, TempCCk, X, value32;
s32 Y, ele_C = 0;
s8 OFDM_index[2], CCK_index = 0;
s8 OFDM_index_old[2] = {0, 0}, CCK_index_old = 0;
u32 i = 0, j = 0;
bool is2t = false;
bool bInteralPA = false;
u1Byte OFDM_min_index = 6, rf; /* OFDM BB Swing should be less than +3.0dB, which is required by Arthur */
u1Byte Indexforchannel = 0/*GetRightChnlPlaceforIQK(pHalData->CurrentChannel)*/;
s1Byte OFDM_index_mapping[2][index_mapping_NUM_88E] = {
u8 OFDM_min_index = 6, rf; /* OFDM BB Swing should be less than +3.0dB, which is required by Arthur */
u8 Indexforchannel = 0/*GetRightChnlPlaceforIQK(pHalData->CurrentChannel)*/;
s8 OFDM_index_mapping[2][index_mapping_NUM_88E] = {
{0, 0, 2, 3, 4, 4, /* 2.4G, decrease power */
5, 6, 7, 7, 8, 9,
10, 10, 11}, /* For lower temperature, 20120220 updated on 20120220. */
@ -151,7 +151,7 @@ odm_TXPowerTrackingCallback_ThermalMeter_8188E(
-4, -4, -4, -5, -7, -8,
-9, -9, -10},
};
u1Byte Thermal_mapping[2][index_mapping_NUM_88E] = {
u8 Thermal_mapping[2][index_mapping_NUM_88E] = {
{0, 2, 4, 6, 8, 10, /* 2.4G, decrease power */
12, 14, 16, 18, 20, 22,
24, 26, 27},
@ -174,7 +174,7 @@ odm_TXPowerTrackingCallback_ThermalMeter_8188E(
("===>dm_TXPowerTrackingCallback_ThermalMeter_8188E txpowercontrol %d\n",
dm_odm->RFCalibrateInfo.TxPowerTrackControl));
ThermalValue = (u1Byte)ODM_GetRFReg(dm_odm, RF_PATH_A, RF_T_METER_88E, 0xfc00); /* 0x42: RF Reg[15:10] 88E */
ThermalValue = (u8)ODM_GetRFReg(dm_odm, RF_PATH_A, RF_T_METER_88E, 0xfc00); /* 0x42: RF Reg[15:10] 88E */
ODM_RT_TRACE(dm_odm, ODM_COMP_CALIBRATION, ODM_DBG_LOUD,
("Readback Thermal Meter = 0x%x pre thermal meter 0x%x EEPROMthermalmeter 0x%x\n",
@ -190,8 +190,8 @@ odm_TXPowerTrackingCallback_ThermalMeter_8188E(
ele_D = ODM_GetBBReg(dm_odm, rOFDM0_XATxIQImbalance, bMaskDWord)&bMaskOFDM_D;
for (i = 0; i < OFDM_TABLE_SIZE_92D; i++) { /* find the index */
if (ele_D == (OFDMSwingTable[i]&bMaskOFDM_D)) {
OFDM_index_old[0] = (u1Byte)i;
dm_odm->BbSwingIdxOfdmBase = (u1Byte)i;
OFDM_index_old[0] = (u8)i;
dm_odm->BbSwingIdxOfdmBase = (u8)i;
ODM_RT_TRACE(dm_odm, ODM_COMP_CALIBRATION, ODM_DBG_LOUD,
("Initial pathA ele_D reg0x%x = 0x%x, OFDM_index=0x%x\n",
rOFDM0_XATxIQImbalance, ele_D, OFDM_index_old[0]));
@ -204,7 +204,7 @@ odm_TXPowerTrackingCallback_ThermalMeter_8188E(
ele_D = ODM_GetBBReg(dm_odm, rOFDM0_XBTxIQImbalance, bMaskDWord)&bMaskOFDM_D;
for (i = 0; i < OFDM_TABLE_SIZE_92D; i++) { /* find the index */
if (ele_D == (OFDMSwingTable[i]&bMaskOFDM_D)) {
OFDM_index_old[1] = (u1Byte)i;
OFDM_index_old[1] = (u8)i;
ODM_RT_TRACE(dm_odm, ODM_COMP_CALIBRATION, ODM_DBG_LOUD,
("Initial pathB ele_D reg0x%x = 0x%x, OFDM_index=0x%x\n",
rOFDM0_XBTxIQImbalance, ele_D, OFDM_index_old[1]));
@ -219,8 +219,8 @@ odm_TXPowerTrackingCallback_ThermalMeter_8188E(
for (i = 0; i < CCK_TABLE_SIZE; i++) {
if (dm_odm->RFCalibrateInfo.bCCKinCH14) {
if (ODM_CompareMemory(dm_odm, (void *)&TempCCk, (void *)&CCKSwingTable_Ch14[i][2], 4) == 0) {
CCK_index_old = (u1Byte)i;
dm_odm->BbSwingIdxCckBase = (u1Byte)i;
CCK_index_old = (u8)i;
dm_odm->BbSwingIdxCckBase = (u8)i;
ODM_RT_TRACE(dm_odm, ODM_COMP_CALIBRATION, ODM_DBG_LOUD,
("Initial reg0x%x = 0x%x, CCK_index=0x%x, ch 14 %d\n",
rCCK0_TxFilter2, TempCCk, CCK_index_old, dm_odm->RFCalibrateInfo.bCCKinCH14));
@ -231,8 +231,8 @@ odm_TXPowerTrackingCallback_ThermalMeter_8188E(
("RegA24: 0x%X, CCKSwingTable_Ch1_Ch13[%d][2]: CCKSwingTable_Ch1_Ch13[i][2]: 0x%X\n",
TempCCk, i, CCKSwingTable_Ch1_Ch13[i][2]));
if (ODM_CompareMemory(dm_odm, (void *)&TempCCk, (void *)&CCKSwingTable_Ch1_Ch13[i][2], 4) == 0) {
CCK_index_old = (u1Byte)i;
dm_odm->BbSwingIdxCckBase = (u1Byte)i;
CCK_index_old = (u8)i;
dm_odm->BbSwingIdxCckBase = (u8)i;
ODM_RT_TRACE(dm_odm, ODM_COMP_CALIBRATION, ODM_DBG_LOUD,
("Initial reg0x%x = 0x%x, CCK_index=0x%x, ch14 %d\n",
rCCK0_TxFilter2, TempCCk, CCK_index_old, dm_odm->RFCalibrateInfo.bCCKinCH14));
@ -269,7 +269,7 @@ odm_TXPowerTrackingCallback_ThermalMeter_8188E(
}
if (ThermalValue_AVG_count) {
ThermalValue = (u1Byte)(ThermalValue_AVG / ThermalValue_AVG_count);
ThermalValue = (u8)(ThermalValue_AVG / ThermalValue_AVG_count);
ODM_RT_TRACE(dm_odm, ODM_COMP_CALIBRATION, ODM_DBG_LOUD,
("AVG Thermal Meter = 0x%x\n", ThermalValue));
}
@ -374,13 +374,13 @@ odm_TXPowerTrackingCallback_ThermalMeter_8188E(
dm_odm->RFCalibrateInfo.bDoneTxpower = true;
/* Adujst OFDM Ant_A according to IQK result */
ele_D = (OFDMSwingTable[(u1Byte)OFDM_index[0]] & 0xFFC00000)>>22;
ele_D = (OFDMSwingTable[(u8)OFDM_index[0]] & 0xFFC00000)>>22;
X = dm_odm->RFCalibrateInfo.IQKMatrixRegSetting[Indexforchannel].Value[0][0];
Y = dm_odm->RFCalibrateInfo.IQKMatrixRegSetting[Indexforchannel].Value[0][1];
/* Revse TX power table. */
dm_odm->BbSwingIdxOfdm = (u1Byte)OFDM_index[0];
dm_odm->BbSwingIdxCck = (u1Byte)CCK_index;
dm_odm->BbSwingIdxOfdm = (u8)OFDM_index[0];
dm_odm->BbSwingIdxCck = (u8)CCK_index;
if (dm_odm->BbSwingIdxOfdmCurrent != dm_odm->BbSwingIdxOfdm) {
dm_odm->BbSwingIdxOfdmCurrent = dm_odm->BbSwingIdxOfdm;
@ -408,10 +408,10 @@ odm_TXPowerTrackingCallback_ThermalMeter_8188E(
ODM_RT_TRACE(dm_odm, ODM_COMP_CALIBRATION, ODM_DBG_LOUD,
("TxPwrTracking for path A: X=0x%x, Y=0x%x ele_A=0x%x ele_C=0x%x ele_D=0x%x 0xe94=0x%x 0xe9c=0x%x\n",
(u4Byte)X, (u4Byte)Y, (u4Byte)ele_A, (u4Byte)ele_C, (u4Byte)ele_D, (u4Byte)X, (u4Byte)Y));
(u32)X, (u32)Y, (u32)ele_A, (u32)ele_C, (u32)ele_D, (u32)X, (u32)Y));
if (is2t) {
ele_D = (OFDMSwingTable[(u1Byte)OFDM_index[1]] & 0xFFC00000)>>22;
ele_D = (OFDMSwingTable[(u8)OFDM_index[1]] & 0xFFC00000)>>22;
/* new element A = element D x X */
X = dm_odm->RFCalibrateInfo.IQKMatrixRegSetting[Indexforchannel].Value[0][4];
@ -437,15 +437,15 @@ odm_TXPowerTrackingCallback_ThermalMeter_8188E(
value32 = ((X * ele_D)>>7)&0x01;
ODM_SetBBReg(dm_odm, rOFDM0_ECCAThreshold, BIT28, value32);
} else {
ODM_SetBBReg(dm_odm, rOFDM0_XBTxIQImbalance, bMaskDWord, OFDMSwingTable[(u1Byte)OFDM_index[1]]);
ODM_SetBBReg(dm_odm, rOFDM0_XBTxIQImbalance, bMaskDWord, OFDMSwingTable[(u8)OFDM_index[1]]);
ODM_SetBBReg(dm_odm, rOFDM0_XDTxAFE, bMaskH4Bits, 0x00);
ODM_SetBBReg(dm_odm, rOFDM0_ECCAThreshold, BIT28, 0x00);
}
ODM_RT_TRACE(dm_odm, ODM_COMP_CALIBRATION, ODM_DBG_LOUD,
("TxPwrTracking path B: X=0x%x, Y=0x%x ele_A=0x%x ele_C=0x%x ele_D=0x%x 0xeb4=0x%x 0xebc=0x%x\n",
(u4Byte)X, (u4Byte)Y, (u4Byte)ele_A,
(u4Byte)ele_C, (u4Byte)ele_D, (u4Byte)X, (u4Byte)Y));
(u32)X, (u32)Y, (u32)ele_A,
(u32)ele_C, (u32)ele_D, (u32)X, (u32)Y));
}
ODM_RT_TRACE(dm_odm, ODM_COMP_CALIBRATION, ODM_DBG_LOUD,
@ -474,11 +474,11 @@ odm_TXPowerTrackingCallback_ThermalMeter_8188E(
#define MAX_TOLERANCE 5
#define IQK_DELAY_TIME 1 /* ms */
static u1Byte /* bit0 = 1 => Tx OK, bit1 = 1 => Rx OK */
static u8 /* bit0 = 1 => Tx OK, bit1 = 1 => Rx OK */
phy_PathA_IQK_8188E(struct adapter *adapt, bool configPathB)
{
u4Byte regeac, regE94, regE9C, regEA4;
u1Byte result = 0x00;
u32 regeac, regE94, regE9C, regEA4;
u8 result = 0x00;
struct hal_data_8188e *pHalData = GET_HAL_DATA(adapt);
struct odm_dm_struct *dm_odm = &pHalData->odmpriv;
ODM_RT_TRACE(dm_odm, ODM_COMP_CALIBRATION, ODM_DBG_LOUD, ("Path A IQK!\n"));
@ -522,11 +522,11 @@ phy_PathA_IQK_8188E(struct adapter *adapt, bool configPathB)
return result;
}
static u1Byte /* bit0 = 1 => Tx OK, bit1 = 1 => Rx OK */
static u8 /* bit0 = 1 => Tx OK, bit1 = 1 => Rx OK */
phy_PathA_RxIQK(struct adapter *adapt, bool configPathB)
{
u4Byte regeac, regE94, regE9C, regEA4, u4tmp;
u1Byte result = 0x00;
u32 regeac, regE94, regE9C, regEA4, u4tmp;
u8 result = 0x00;
struct hal_data_8188e *pHalData = GET_HAL_DATA(adapt);
struct odm_dm_struct *dm_odm = &pHalData->odmpriv;
ODM_RT_TRACE(dm_odm, ODM_COMP_CALIBRATION, ODM_DBG_LOUD, ("Path A Rx IQK!\n"));
@ -650,11 +650,11 @@ phy_PathA_RxIQK(struct adapter *adapt, bool configPathB)
return result;
}
static u1Byte /* bit0 = 1 => Tx OK, bit1 = 1 => Rx OK */
static u8 /* bit0 = 1 => Tx OK, bit1 = 1 => Rx OK */
phy_PathB_IQK_8188E(struct adapter *adapt)
{
u4Byte regeac, regeb4, regebc, regec4, regecc;
u1Byte result = 0x00;
u32 regeac, regeb4, regebc, regec4, regecc;
u8 result = 0x00;
struct hal_data_8188e *pHalData = GET_HAL_DATA(adapt);
struct odm_dm_struct *dm_odm = &pHalData->odmpriv;
ODM_RT_TRACE(dm_odm, ODM_COMP_CALIBRATION, ODM_DBG_LOUD, ("Path B IQK!\n"));
@ -703,10 +703,10 @@ phy_PathB_IQK_8188E(struct adapter *adapt)
return result;
}
static void patha_fill_iqk(struct adapter *adapt, bool iqkok, s4Byte result[][8], u1Byte final_candidate, bool txonly)
static void patha_fill_iqk(struct adapter *adapt, bool iqkok, s32 result[][8], u8 final_candidate, bool txonly)
{
u4Byte Oldval_0, X, TX0_A, reg;
s4Byte Y, TX0_C;
u32 Oldval_0, X, TX0_A, reg;
s32 Y, TX0_C;
struct hal_data_8188e *pHalData = GET_HAL_DATA(adapt);
struct odm_dm_struct *dm_odm = &pHalData->odmpriv;
ODM_RT_TRACE(dm_odm, ODM_COMP_CALIBRATION, ODM_DBG_LOUD,
@ -756,10 +756,10 @@ static void patha_fill_iqk(struct adapter *adapt, bool iqkok, s4Byte result[][8]
}
}
static void pathb_fill_iqk(struct adapter *adapt, bool iqkok, s4Byte result[][8], u1Byte final_candidate, bool txonly)
static void pathb_fill_iqk(struct adapter *adapt, bool iqkok, s32 result[][8], u8 final_candidate, bool txonly)
{
u4Byte Oldval_1, X, TX1_A, reg;
s4Byte Y, TX1_C;
u32 Oldval_1, X, TX1_A, reg;
s32 Y, TX1_C;
struct hal_data_8188e *pHalData = GET_HAL_DATA(adapt);
struct odm_dm_struct *dm_odm = &pHalData->odmpriv;
ODM_RT_TRACE(dm_odm, ODM_COMP_CALIBRATION, ODM_DBG_LOUD,
@ -814,9 +814,9 @@ static bool ODM_CheckPowerStatus(struct adapter *Adapter)
return true;
}
void _PHY_SaveADDARegisters(struct adapter *adapt, pu4Byte ADDAReg, pu4Byte ADDABackup, u4Byte RegisterNum)
void _PHY_SaveADDARegisters(struct adapter *adapt, u32 *ADDAReg, u32 *ADDABackup, u32 RegisterNum)
{
u4Byte i;
u32 i;
struct hal_data_8188e *pHalData = GET_HAL_DATA(adapt);
struct odm_dm_struct *dm_odm = &pHalData->odmpriv;
@ -831,11 +831,11 @@ void _PHY_SaveADDARegisters(struct adapter *adapt, pu4Byte ADDAReg, pu4Byte ADDA
static void _PHY_SaveMACRegisters(
struct adapter *adapt,
pu4Byte MACReg,
pu4Byte MACBackup
u32 *MACReg,
u32 *MACBackup
)
{
u4Byte i;
u32 i;
struct hal_data_8188e *pHalData = GET_HAL_DATA(adapt);
struct odm_dm_struct *dm_odm = &pHalData->odmpriv;
ODM_RT_TRACE(dm_odm, ODM_COMP_CALIBRATION, ODM_DBG_LOUD, ("Save MAC parameters.\n"));
@ -845,9 +845,9 @@ static void _PHY_SaveMACRegisters(
MACBackup[i] = ODM_Read4Byte(dm_odm, MACReg[i]);
}
static void reload_adda_reg(struct adapter *adapt, pu4Byte ADDAReg, pu4Byte ADDABackup, u4Byte RegiesterNum)
static void reload_adda_reg(struct adapter *adapt, u32 *ADDAReg, u32 *ADDABackup, u32 RegiesterNum)
{
u4Byte i;
u32 i;
struct hal_data_8188e *pHalData = GET_HAL_DATA(adapt);
struct odm_dm_struct *dm_odm = &pHalData->odmpriv;
@ -859,17 +859,17 @@ static void reload_adda_reg(struct adapter *adapt, pu4Byte ADDAReg, pu4Byte ADDA
static void
_PHY_ReloadMACRegisters(
struct adapter *adapt,
pu4Byte MACReg,
pu4Byte MACBackup
u32 *MACReg,
u32 *MACBackup
)
{
u4Byte i;
u32 i;
struct hal_data_8188e *pHalData = GET_HAL_DATA(adapt);
struct odm_dm_struct *dm_odm = &pHalData->odmpriv;
ODM_RT_TRACE(dm_odm, ODM_COMP_CALIBRATION, ODM_DBG_LOUD, ("Reload MAC parameters !\n"));
for (i = 0; i < (IQK_MAC_REG_NUM - 1); i++) {
ODM_Write1Byte(dm_odm, MACReg[i], (u1Byte)MACBackup[i]);
ODM_Write1Byte(dm_odm, MACReg[i], (u8)MACBackup[i]);
}
ODM_Write4Byte(dm_odm, MACReg[i], MACBackup[i]);
}
@ -877,13 +877,13 @@ _PHY_ReloadMACRegisters(
void
_PHY_PathADDAOn(
struct adapter *adapt,
pu4Byte ADDAReg,
u32 *ADDAReg,
bool isPathAOn,
bool is2t
)
{
u4Byte pathOn;
u4Byte i;
u32 pathOn;
u32 i;
struct hal_data_8188e *pHalData = GET_HAL_DATA(adapt);
struct odm_dm_struct *dm_odm = &pHalData->odmpriv;
ODM_RT_TRACE(dm_odm, ODM_COMP_CALIBRATION, ODM_DBG_LOUD, ("ADDA ON.\n"));
@ -903,11 +903,11 @@ _PHY_PathADDAOn(
void
_PHY_MACSettingCalibration(
struct adapter *adapt,
pu4Byte MACReg,
pu4Byte MACBackup
u32 *MACReg,
u32 *MACBackup
)
{
u4Byte i = 0;
u32 i = 0;
struct hal_data_8188e *pHalData = GET_HAL_DATA(adapt);
struct odm_dm_struct *dm_odm = &pHalData->odmpriv;
@ -916,9 +916,9 @@ _PHY_MACSettingCalibration(
ODM_Write1Byte(dm_odm, MACReg[i], 0x3F);
for (i = 1; i < (IQK_MAC_REG_NUM - 1); i++) {
ODM_Write1Byte(dm_odm, MACReg[i], (u1Byte)(MACBackup[i]&(~BIT3)));
ODM_Write1Byte(dm_odm, MACReg[i], (u8)(MACBackup[i]&(~BIT3)));
}
ODM_Write1Byte(dm_odm, MACReg[i], (u1Byte)(MACBackup[i]&(~BIT5)));
ODM_Write1Byte(dm_odm, MACReg[i], (u8)(MACBackup[i]&(~BIT5)));
}
void
@ -941,7 +941,7 @@ static void _PHY_PIModeSwitch(
bool PIMode
)
{
u4Byte mode;
u32 mode;
struct hal_data_8188e *pHalData = GET_HAL_DATA(adapt);
struct odm_dm_struct *dm_odm = &pHalData->odmpriv;
@ -954,18 +954,18 @@ static void _PHY_PIModeSwitch(
static bool phy_SimularityCompare_8188E(
struct adapter *adapt,
s4Byte resulta[][8],
u1Byte c1,
u1Byte c2
s32 resulta[][8],
u8 c1,
u8 c2
)
{
u4Byte i, j, diff, sim_bitmap, bound = 0;
u32 i, j, diff, sim_bitmap, bound = 0;
struct hal_data_8188e *pHalData = GET_HAL_DATA(adapt);
struct odm_dm_struct *dm_odm = &pHalData->odmpriv;
u1Byte final_candidate[2] = {0xFF, 0xFF}; /* for path A and path B */
u8 final_candidate[2] = {0xFF, 0xFF}; /* for path A and path B */
bool result = true;
bool is2t;
s4Byte tmp1 = 0, tmp2 = 0;
s32 tmp1 = 0, tmp2 = 0;
if ((dm_odm->RFType == ODM_2T2R) || (dm_odm->RFType == ODM_2T3R) || (dm_odm->RFType == ODM_2T4R))
is2t = true;
@ -1051,13 +1051,13 @@ static bool phy_SimularityCompare_8188E(
}
}
static void phy_IQCalibrate_8188E(struct adapter *adapt, s4Byte result[][8], u1Byte t, bool is2t)
static void phy_IQCalibrate_8188E(struct adapter *adapt, s32 result[][8], u8 t, bool is2t)
{
struct hal_data_8188e *pHalData = GET_HAL_DATA(adapt);
struct odm_dm_struct *dm_odm = &pHalData->odmpriv;
u4Byte i;
u1Byte PathAOK, PathBOK;
u4Byte ADDA_REG[IQK_ADDA_REG_NUM] = {
u32 i;
u8 PathAOK, PathBOK;
u32 ADDA_REG[IQK_ADDA_REG_NUM] = {
rFPGA0_XCD_SwitchControl, rBlue_Tooth,
rRx_Wait_CCA, rTx_CCK_RFON,
rTx_CCK_BBON, rTx_OFDM_RFON,
@ -1066,19 +1066,19 @@ static void phy_IQCalibrate_8188E(struct adapter *adapt, s4Byte result[][8], u1B
rRx_OFDM, rRx_Wait_RIFS,
rRx_TO_Rx, rStandby,
rSleep, rPMPD_ANAEN };
u4Byte IQK_MAC_REG[IQK_MAC_REG_NUM] = {
u32 IQK_MAC_REG[IQK_MAC_REG_NUM] = {
REG_TXPAUSE, REG_BCN_CTRL,
REG_BCN_CTRL_1, REG_GPIO_MUXCFG};
/* since 92C & 92D have the different define in IQK_BB_REG */
u4Byte IQK_BB_REG_92C[IQK_BB_REG_NUM] = {
u32 IQK_BB_REG_92C[IQK_BB_REG_NUM] = {
rOFDM0_TRxPathEnable, rOFDM0_TRMuxPar,
rFPGA0_XCD_RFInterfaceSW, rConfig_AntA, rConfig_AntB,
rFPGA0_XAB_RFInterfaceSW, rFPGA0_XA_RFInterfaceOE,
rFPGA0_XB_RFInterfaceOE, rFPGA0_RFMOD
};
u4Byte retryCount = 9;
u32 retryCount = 9;
if (*(dm_odm->mp_mode) == 1)
retryCount = 9;
else
@ -1098,7 +1098,7 @@ static void phy_IQCalibrate_8188E(struct adapter *adapt, s4Byte result[][8], u1B
_PHY_PathADDAOn(adapt, ADDA_REG, true, is2t);
if (t == 0)
dm_odm->RFCalibrateInfo.bRfPiEnable = (u1Byte)ODM_GetBBReg(dm_odm, rFPGA0_XA_HSSIParameter1, BIT(8));
dm_odm->RFCalibrateInfo.bRfPiEnable = (u8)ODM_GetBBReg(dm_odm, rFPGA0_XA_HSSIParameter1, BIT(8));
if (!dm_odm->RFCalibrateInfo.bRfPiEnable) {
/* Switch BB to PI mode to do IQ Calibration. */
@ -1222,8 +1222,8 @@ static void phy_IQCalibrate_8188E(struct adapter *adapt, s4Byte result[][8], u1B
static void phy_LCCalibrate_8188E(struct adapter *adapt, bool is2t)
{
u1Byte tmpreg;
u4Byte RF_Amode = 0, RF_Bmode = 0, LC_Cal;
u8 tmpreg;
u32 RF_Amode = 0, RF_Bmode = 0, LC_Cal;
struct hal_data_8188e *pHalData = GET_HAL_DATA(adapt);
struct odm_dm_struct *dm_odm = &pHalData->odmpriv;
@ -1282,28 +1282,28 @@ static void phy_LCCalibrate_8188E(struct adapter *adapt, bool is2t)
#define APK_CURVE_REG_NUM 4
#define PATH_NUM 2
static void phy_APCalibrate_8188E(struct adapter *adapt, s1Byte delta, bool is2t)
static void phy_APCalibrate_8188E(struct adapter *adapt, s8 delta, bool is2t)
{
struct hal_data_8188e *pHalData = GET_HAL_DATA(adapt);
struct odm_dm_struct *dm_odm = &pHalData->odmpriv;
u4Byte regD[PATH_NUM];
u4Byte tmpreg, index, offset, apkbound;
u1Byte path, i, pathbound = PATH_NUM;
u4Byte BB_backup[APK_BB_REG_NUM];
u4Byte BB_REG[APK_BB_REG_NUM] = {
u32 regD[PATH_NUM];
u32 tmpreg, index, offset, apkbound;
u8 path, i, pathbound = PATH_NUM;
u32 BB_backup[APK_BB_REG_NUM];
u32 BB_REG[APK_BB_REG_NUM] = {
rFPGA1_TxBlock, rOFDM0_TRxPathEnable,
rFPGA0_RFMOD, rOFDM0_TRMuxPar,
rFPGA0_XCD_RFInterfaceSW, rFPGA0_XAB_RFInterfaceSW,
rFPGA0_XA_RFInterfaceOE, rFPGA0_XB_RFInterfaceOE };
u4Byte BB_AP_MODE[APK_BB_REG_NUM] = {
u32 BB_AP_MODE[APK_BB_REG_NUM] = {
0x00000020, 0x00a05430, 0x02040000,
0x000800e4, 0x00204000 };
u4Byte BB_normal_AP_MODE[APK_BB_REG_NUM] = {
u32 BB_normal_AP_MODE[APK_BB_REG_NUM] = {
0x00000020, 0x00a05430, 0x02040000,
0x000800e4, 0x22204000 };
u4Byte AFE_backup[IQK_ADDA_REG_NUM];
u4Byte AFE_REG[IQK_ADDA_REG_NUM] = {
u32 AFE_backup[IQK_ADDA_REG_NUM];
u32 AFE_REG[IQK_ADDA_REG_NUM] = {
rFPGA0_XCD_SwitchControl, rBlue_Tooth,
rRx_Wait_CCA, rTx_CCK_RFON,
rTx_CCK_BBON, rTx_OFDM_RFON,
@ -1313,47 +1313,47 @@ static void phy_APCalibrate_8188E(struct adapter *adapt, s1Byte delta, bool is2t
rRx_TO_Rx, rStandby,
rSleep, rPMPD_ANAEN };
u4Byte MAC_backup[IQK_MAC_REG_NUM];
u4Byte MAC_REG[IQK_MAC_REG_NUM] = {
u32 MAC_backup[IQK_MAC_REG_NUM];
u32 MAC_REG[IQK_MAC_REG_NUM] = {
REG_TXPAUSE, REG_BCN_CTRL,
REG_BCN_CTRL_1, REG_GPIO_MUXCFG};
u4Byte APK_RF_init_value[PATH_NUM][APK_BB_REG_NUM] = {
u32 APK_RF_init_value[PATH_NUM][APK_BB_REG_NUM] = {
{0x0852c, 0x1852c, 0x5852c, 0x1852c, 0x5852c},
{0x2852e, 0x0852e, 0x3852e, 0x0852e, 0x0852e}
};
u4Byte APK_normal_RF_init_value[PATH_NUM][APK_BB_REG_NUM] = {
u32 APK_normal_RF_init_value[PATH_NUM][APK_BB_REG_NUM] = {
{0x0852c, 0x0a52c, 0x3a52c, 0x5a52c, 0x5a52c}, /* path settings equal to path b settings */
{0x0852c, 0x0a52c, 0x5a52c, 0x5a52c, 0x5a52c}
};
u4Byte APK_RF_value_0[PATH_NUM][APK_BB_REG_NUM] = {
u32 APK_RF_value_0[PATH_NUM][APK_BB_REG_NUM] = {
{0x52019, 0x52014, 0x52013, 0x5200f, 0x5208d},
{0x5201a, 0x52019, 0x52016, 0x52033, 0x52050}
};
u4Byte APK_normal_RF_value_0[PATH_NUM][APK_BB_REG_NUM] = {
u32 APK_normal_RF_value_0[PATH_NUM][APK_BB_REG_NUM] = {
{0x52019, 0x52017, 0x52010, 0x5200d, 0x5206a}, /* path settings equal to path b settings */
{0x52019, 0x52017, 0x52010, 0x5200d, 0x5206a}
};
u4Byte AFE_on_off[PATH_NUM] = {
u32 AFE_on_off[PATH_NUM] = {
0x04db25a4, 0x0b1b25a4}; /* path A on path B off / path A off path B on */
u4Byte APK_offset[PATH_NUM] = {
u32 APK_offset[PATH_NUM] = {
rConfig_AntA, rConfig_AntB};
u4Byte APK_normal_offset[PATH_NUM] = {
u32 APK_normal_offset[PATH_NUM] = {
rConfig_Pmpd_AntA, rConfig_Pmpd_AntB};
u4Byte APK_value[PATH_NUM] = {
u32 APK_value[PATH_NUM] = {
0x92fc0000, 0x12fc0000};
u4Byte APK_normal_value[PATH_NUM] = {
u32 APK_normal_value[PATH_NUM] = {
0x92680000, 0x12680000};
s1Byte APK_delta_mapping[APK_BB_REG_NUM][13] = {
s8 APK_delta_mapping[APK_BB_REG_NUM][13] = {
{-4, -3, -2, -2, -1, -1, 0, 1, 2, 3, 4, 5, 6},
{-4, -3, -2, -2, -1, -1, 0, 1, 2, 3, 4, 5, 6},
{-6, -4, -2, -2, -1, -1, 0, 1, 2, 3, 4, 5, 6},
@ -1361,21 +1361,21 @@ static void phy_APCalibrate_8188E(struct adapter *adapt, s1Byte delta, bool is2t
{-11, -9, -7, -5, -3, -1, 0, 0, 0, 0, 0, 0, 0}
};
u4Byte APK_normal_setting_value_1[13] = {
u32 APK_normal_setting_value_1[13] = {
0x01017018, 0xf7ed8f84, 0x1b1a1816, 0x2522201e, 0x322e2b28,
0x433f3a36, 0x5b544e49, 0x7b726a62, 0xa69a8f84, 0xdfcfc0b3,
0x12680000, 0x00880000, 0x00880000
};
u4Byte APK_normal_setting_value_2[16] = {
u32 APK_normal_setting_value_2[16] = {
0x01c7021d, 0x01670183, 0x01000123, 0x00bf00e2, 0x008d00a3,
0x0068007b, 0x004d0059, 0x003a0042, 0x002b0031, 0x001f0025,
0x0017001b, 0x00110014, 0x000c000f, 0x0009000b, 0x00070008,
0x00050006
};
u4Byte APK_result[PATH_NUM][APK_BB_REG_NUM]; /* val_1_1a, val_1_2a, val_2a, val_3a, val_4a */
s4Byte BB_offset, delta_V, delta_offset;
u32 APK_result[PATH_NUM][APK_BB_REG_NUM]; /* val_1_1a, val_1_2a, val_2a, val_3a, val_4a */
s32 BB_offset, delta_V, delta_offset;
if (*(dm_odm->mp_mode) == 1) {
struct mpt_context *pMptCtx = &(adapt->mppriv.MptCtx);
@ -1684,13 +1684,13 @@ void PHY_IQCalibrate_8188E(struct adapter *adapt, bool recovery)
struct hal_data_8188e *pHalData = GET_HAL_DATA(adapt);
struct odm_dm_struct *dm_odm = &pHalData->odmpriv;
struct mpt_context *pMptCtx = &(adapt->mppriv.MptCtx);
s4Byte result[4][8]; /* last is final result */
u1Byte i, final_candidate, Indexforchannel;
s32 result[4][8]; /* last is final result */
u8 i, final_candidate, Indexforchannel;
bool pathaok, pathbok;
s4Byte RegE94, RegE9C, RegEA4, RegEAC, RegEB4, RegEBC, RegEC4, RegECC;
s32 RegE94, RegE9C, RegEA4, RegEAC, RegEB4, RegEBC, RegEC4, RegECC;
bool is12simular, is13simular, is23simular;
bool singletone = false, carrier_sup = false;
u4Byte IQK_BB_REG_92C[IQK_BB_REG_NUM] = {
u32 IQK_BB_REG_92C[IQK_BB_REG_NUM] = {
rOFDM0_XARxIQImbalance, rOFDM0_XBRxIQImbalance,
rOFDM0_ECCAThreshold, rOFDM0_AGCRSSITable,
rOFDM0_XATxIQImbalance, rOFDM0_XBTxIQImbalance,
@ -1834,7 +1834,7 @@ void PHY_IQCalibrate_8188E(struct adapter *adapt, bool recovery)
void PHY_LCCalibrate_8188E(struct adapter *adapt)
{
bool singletone = false, carrier_sup = false;
u4Byte timeout = 2000, timecount = 0;
u32 timeout = 2000, timecount = 0;
struct hal_data_8188e *pHalData = GET_HAL_DATA(adapt);
struct odm_dm_struct *dm_odm = &pHalData->odmpriv;
struct mpt_context *pMptCtx = &(adapt->mppriv.MptCtx);
@ -1869,7 +1869,7 @@ void PHY_LCCalibrate_8188E(struct adapter *adapt)
("LCK:Finish!!!interface %d\n", dm_odm->InterfaceIndex));
}
void PHY_APCalibrate_8188E(struct adapter *adapt, s1Byte delta)
void PHY_APCalibrate_8188E(struct adapter *adapt, s8 delta)
{
struct hal_data_8188e *pHalData = GET_HAL_DATA(adapt);
struct odm_dm_struct *dm_odm = &pHalData->odmpriv;
@ -1897,7 +1897,7 @@ static void phy_setrfpathswitch_8188e(struct adapter *adapt, bool main, bool is2
struct odm_dm_struct *dm_odm = &pHalData->odmpriv;
if (!adapt->hw_init_completed) {
u1Byte u1btmp;
u8 u1btmp;
u1btmp = ODM_Read1Byte(dm_odm, REG_LEDCFG2) | BIT7;
ODM_Write1Byte(dm_odm, REG_LEDCFG2, u1btmp);
ODM_SetBBReg(dm_odm, rFPGA0_XAB_RFParameter, BIT13, 0x01);

216
hal/odm.c
View file

@ -22,7 +22,7 @@
#include "odm_precomp.h"
static const u2Byte dB_Invert_Table[8][12] = {
static const u16 dB_Invert_Table[8][12] = {
{1, 1, 1, 2, 2, 2, 2, 3, 3, 3, 4, 4},
{4, 5, 6, 6, 7, 8, 9, 10, 11, 13, 14, 16},
{18, 20, 22, 25, 28, 32, 35, 40, 45, 50, 56, 63},
@ -34,7 +34,7 @@ static const u2Byte dB_Invert_Table[8][12] = {
};
/* avoid to warn in FreeBSD ==> To DO modify */
static u4Byte EDCAParam[HT_IOT_PEER_MAX][3] = {
static u32 EDCAParam[HT_IOT_PEER_MAX][3] = {
/* UL DL */
{0x5ea42b, 0x5ea42b, 0x5ea42b}, /* 0:unknown AP */
{0xa44f, 0x5ea44f, 0x5e431c}, /* 1:realtek AP */
@ -49,7 +49,7 @@ static u4Byte EDCAParam[HT_IOT_PEER_MAX][3] = {
};
/* Global var */
u4Byte OFDMSwingTable[OFDM_TABLE_SIZE_92D] = {
u32 OFDMSwingTable[OFDM_TABLE_SIZE_92D] = {
0x7f8001fe, /* 0, +6.0dB */
0x788001e2, /* 1, +5.5dB */
0x71c001c7, /* 2, +5.0dB */
@ -95,7 +95,7 @@ u4Byte OFDMSwingTable[OFDM_TABLE_SIZE_92D] = {
0x0b40002d,/* 42, -15.0dB */
};
u1Byte CCKSwingTable_Ch1_Ch13[CCK_TABLE_SIZE][8] = {
u8 CCKSwingTable_Ch1_Ch13[CCK_TABLE_SIZE][8] = {
{0x36, 0x35, 0x2e, 0x25, 0x1c, 0x12, 0x09, 0x04}, /* 0, +0dB */
{0x33, 0x32, 0x2b, 0x23, 0x1a, 0x11, 0x08, 0x04}, /* 1, -0.5dB */
{0x30, 0x2f, 0x29, 0x21, 0x19, 0x10, 0x08, 0x03}, /* 2, -1.0dB */
@ -131,7 +131,7 @@ u1Byte CCKSwingTable_Ch1_Ch13[CCK_TABLE_SIZE][8] = {
{0x09, 0x08, 0x07, 0x06, 0x04, 0x03, 0x01, 0x01} /* 32, -16.0dB */
};
u1Byte CCKSwingTable_Ch14[CCK_TABLE_SIZE][8] = {
u8 CCKSwingTable_Ch14[CCK_TABLE_SIZE][8] = {
{0x36, 0x35, 0x2e, 0x1b, 0x00, 0x00, 0x00, 0x00}, /* 0, +0dB */
{0x33, 0x32, 0x2b, 0x19, 0x00, 0x00, 0x00, 0x00}, /* 1, -0.5dB */
{0x30, 0x2f, 0x29, 0x18, 0x00, 0x00, 0x00, 0x00}, /* 2, -1.0dB */
@ -254,52 +254,52 @@ void ODM_DMWatchdog(struct odm_dm_struct *pDM_Odm)
}
/* Init /.. Fixed HW value. Only init time. */
void ODM_CmnInfoInit(struct odm_dm_struct *pDM_Odm, enum odm_common_info_def CmnInfo, u4Byte Value)
void ODM_CmnInfoInit(struct odm_dm_struct *pDM_Odm, enum odm_common_info_def CmnInfo, u32 Value)
{
/* This section is used for init value */
switch (CmnInfo) {
/* Fixed ODM value. */
case ODM_CMNINFO_ABILITY:
pDM_Odm->SupportAbility = (u4Byte)Value;
pDM_Odm->SupportAbility = (u32)Value;
break;
case ODM_CMNINFO_PLATFORM:
pDM_Odm->SupportPlatform = (u1Byte)Value;
pDM_Odm->SupportPlatform = (u8)Value;
break;
case ODM_CMNINFO_INTERFACE:
pDM_Odm->SupportInterface = (u1Byte)Value;
pDM_Odm->SupportInterface = (u8)Value;
break;
case ODM_CMNINFO_MP_TEST_CHIP:
pDM_Odm->bIsMPChip = (u1Byte)Value;
pDM_Odm->bIsMPChip = (u8)Value;
break;
case ODM_CMNINFO_IC_TYPE:
pDM_Odm->SupportICType = Value;
break;
case ODM_CMNINFO_CUT_VER:
pDM_Odm->CutVersion = (u1Byte)Value;
pDM_Odm->CutVersion = (u8)Value;
break;
case ODM_CMNINFO_FAB_VER:
pDM_Odm->FabVersion = (u1Byte)Value;
pDM_Odm->FabVersion = (u8)Value;
break;
case ODM_CMNINFO_RF_TYPE:
pDM_Odm->RFType = (u1Byte)Value;
pDM_Odm->RFType = (u8)Value;
break;
case ODM_CMNINFO_RF_ANTENNA_TYPE:
pDM_Odm->AntDivType = (u1Byte)Value;
pDM_Odm->AntDivType = (u8)Value;
break;
case ODM_CMNINFO_BOARD_TYPE:
pDM_Odm->BoardType = (u1Byte)Value;
pDM_Odm->BoardType = (u8)Value;
break;
case ODM_CMNINFO_EXT_LNA:
pDM_Odm->ExtLNA = (u1Byte)Value;
pDM_Odm->ExtLNA = (u8)Value;
break;
case ODM_CMNINFO_EXT_PA:
pDM_Odm->ExtPA = (u1Byte)Value;
pDM_Odm->ExtPA = (u8)Value;
break;
case ODM_CMNINFO_EXT_TRSW:
pDM_Odm->ExtTRSW = (u1Byte)Value;
pDM_Odm->ExtTRSW = (u8)Value;
break;
case ODM_CMNINFO_PATCH_ID:
pDM_Odm->PatchID = (u1Byte)Value;
pDM_Odm->PatchID = (u8)Value;
break;
case ODM_CMNINFO_BINHCT_TEST:
pDM_Odm->bInHctTest = (bool)Value;
@ -331,31 +331,31 @@ void ODM_CmnInfoHook(struct odm_dm_struct *pDM_Odm, enum odm_common_info_def Cmn
switch (CmnInfo) {
/* Dynamic call by reference pointer. */
case ODM_CMNINFO_MAC_PHY_MODE:
pDM_Odm->pMacPhyMode = (u1Byte *)pValue;
pDM_Odm->pMacPhyMode = (u8 *)pValue;
break;
case ODM_CMNINFO_TX_UNI:
pDM_Odm->pNumTxBytesUnicast = (u8Byte *)pValue;
pDM_Odm->pNumTxBytesUnicast = (u64 *)pValue;
break;
case ODM_CMNINFO_RX_UNI:
pDM_Odm->pNumRxBytesUnicast = (u8Byte *)pValue;
pDM_Odm->pNumRxBytesUnicast = (u64 *)pValue;
break;
case ODM_CMNINFO_WM_MODE:
pDM_Odm->pWirelessMode = (u1Byte *)pValue;
pDM_Odm->pWirelessMode = (u8 *)pValue;
break;
case ODM_CMNINFO_BAND:
pDM_Odm->pBandType = (u1Byte *)pValue;
pDM_Odm->pBandType = (u8 *)pValue;
break;
case ODM_CMNINFO_SEC_CHNL_OFFSET:
pDM_Odm->pSecChOffset = (u1Byte *)pValue;
pDM_Odm->pSecChOffset = (u8 *)pValue;
break;
case ODM_CMNINFO_SEC_MODE:
pDM_Odm->pSecurity = (u1Byte *)pValue;
pDM_Odm->pSecurity = (u8 *)pValue;
break;
case ODM_CMNINFO_BW:
pDM_Odm->pBandWidth = (u1Byte *)pValue;
pDM_Odm->pBandWidth = (u8 *)pValue;
break;
case ODM_CMNINFO_CHNL:
pDM_Odm->pChannel = (u1Byte *)pValue;
pDM_Odm->pChannel = (u8 *)pValue;
break;
case ODM_CMNINFO_DMSP_GET_VALUE:
pDM_Odm->pbGetValueFromOtherMac = (bool *)pValue;
@ -373,7 +373,7 @@ void ODM_CmnInfoHook(struct odm_dm_struct *pDM_Odm, enum odm_common_info_def Cmn
pDM_Odm->pbPowerSaving = (bool *)pValue;
break;
case ODM_CMNINFO_ONE_PATH_CCA:
pDM_Odm->pOnePathCCA = (u1Byte *)pValue;
pDM_Odm->pOnePathCCA = (u8 *)pValue;
break;
case ODM_CMNINFO_DRV_STOP:
pDM_Odm->pbDriverStopped = (bool *)pValue;
@ -385,13 +385,13 @@ void ODM_CmnInfoHook(struct odm_dm_struct *pDM_Odm, enum odm_common_info_def Cmn
pDM_Odm->pinit_adpt_in_progress = (bool *)pValue;
break;
case ODM_CMNINFO_ANT_TEST:
pDM_Odm->pAntennaTest = (u1Byte *)pValue;
pDM_Odm->pAntennaTest = (u8 *)pValue;
break;
case ODM_CMNINFO_NET_CLOSED:
pDM_Odm->pbNet_closed = (bool *)pValue;
break;
case ODM_CMNINFO_MP_MODE:
pDM_Odm->mp_mode = (u1Byte *)pValue;
pDM_Odm->mp_mode = (u8 *)pValue;
break;
/* To remove the compiler warning, must add an empty default statement to handle the other values. */
default:
@ -400,7 +400,7 @@ void ODM_CmnInfoHook(struct odm_dm_struct *pDM_Odm, enum odm_common_info_def Cmn
}
}
void ODM_CmnInfoPtrArrayHook(struct odm_dm_struct *pDM_Odm, enum odm_common_info_def CmnInfo, u2Byte Index, void *pValue)
void ODM_CmnInfoPtrArrayHook(struct odm_dm_struct *pDM_Odm, enum odm_common_info_def CmnInfo, u16 Index, void *pValue)
{
/* Hook call by reference pointer. */
switch (CmnInfo) {
@ -416,17 +416,17 @@ void ODM_CmnInfoPtrArrayHook(struct odm_dm_struct *pDM_Odm, enum odm_common_info
}
/* Update Band/CHannel/.. The values are dynamic but non-per-packet. */
void ODM_CmnInfoUpdate(struct odm_dm_struct *pDM_Odm, u4Byte CmnInfo, u8Byte Value)
void ODM_CmnInfoUpdate(struct odm_dm_struct *pDM_Odm, u32 CmnInfo, u64 Value)
{
/* */
/* This init variable may be changed in run time. */
/* */
switch (CmnInfo) {
case ODM_CMNINFO_ABILITY:
pDM_Odm->SupportAbility = (u4Byte)Value;
pDM_Odm->SupportAbility = (u32)Value;
break;
case ODM_CMNINFO_RF_TYPE:
pDM_Odm->RFType = (u1Byte)Value;
pDM_Odm->RFType = (u8)Value;
break;
case ODM_CMNINFO_WIFI_DIRECT:
pDM_Odm->bWIFI_Direct = (bool)Value;
@ -438,19 +438,19 @@ void ODM_CmnInfoUpdate(struct odm_dm_struct *pDM_Odm, u4Byte CmnInfo, u8Byte Val
pDM_Odm->bLinked = (bool)Value;
break;
case ODM_CMNINFO_RSSI_MIN:
pDM_Odm->RSSI_Min = (u1Byte)Value;
pDM_Odm->RSSI_Min = (u8)Value;
break;
case ODM_CMNINFO_DBG_COMP:
pDM_Odm->DebugComponents = Value;
break;
case ODM_CMNINFO_DBG_LEVEL:
pDM_Odm->DebugLevel = (u4Byte)Value;
pDM_Odm->DebugLevel = (u32)Value;
break;
case ODM_CMNINFO_RA_THRESHOLD_HIGH:
pDM_Odm->RateAdaptive.HighRSSIThresh = (u1Byte)Value;
pDM_Odm->RateAdaptive.HighRSSIThresh = (u8)Value;
break;
case ODM_CMNINFO_RA_THRESHOLD_LOW:
pDM_Odm->RateAdaptive.LowRSSIThresh = (u1Byte)Value;
pDM_Odm->RateAdaptive.LowRSSIThresh = (u8)Value;
break;
}
}
@ -458,7 +458,7 @@ void ODM_CmnInfoUpdate(struct odm_dm_struct *pDM_Odm, u4Byte CmnInfo, u8Byte Val
void odm_CommonInfoSelfInit(struct odm_dm_struct *pDM_Odm)
{
pDM_Odm->bCckHighPower = (bool) ODM_GetBBReg(pDM_Odm, 0x824, BIT9);
pDM_Odm->RFPathRxEnable = (u1Byte) ODM_GetBBReg(pDM_Odm, 0xc04, 0x0F);
pDM_Odm->RFPathRxEnable = (u8) ODM_GetBBReg(pDM_Odm, 0xc04, 0x0F);
if (pDM_Odm->SupportICType & (ODM_RTL8192C|ODM_RTL8192D))
pDM_Odm->AntDivType = CG_TRX_HW_ANTDIV;
if (pDM_Odm->SupportICType & (ODM_RTL8723A))
@ -469,8 +469,8 @@ void odm_CommonInfoSelfInit(struct odm_dm_struct *pDM_Odm)
void odm_CommonInfoSelfUpdate(struct odm_dm_struct *pDM_Odm)
{
u1Byte EntryCnt = 0;
u1Byte i;
u8 EntryCnt = 0;
u8 i;
struct sta_info *pEntry;
if (*(pDM_Odm->pBandWidth) == ODM_BW40M) {
@ -558,7 +558,7 @@ void odm_CmnInfoUpdate_Debug(struct odm_dm_struct *pDM_Odm)
* When Who Remark
*
*---------------------------------------------------------------------------*/
static void ODM_ChangeDynamicInitGainThresh(struct odm_dm_struct *pDM_Odm, u4Byte DM_Type, u4Byte DM_Value)
static void ODM_ChangeDynamicInitGainThresh(struct odm_dm_struct *pDM_Odm, u32 DM_Type, u32 DM_Value)
{
struct rtw_dig *pDM_DigTable = &pDM_Odm->DM_DigTable;
@ -573,15 +573,15 @@ static void ODM_ChangeDynamicInitGainThresh(struct odm_dm_struct *pDM_Odm, u4Byt
} else if (DM_Type == RT_TYPE_BACKOFF) {
if (DM_Value > 30)
DM_Value = 30;
pDM_DigTable->BackoffVal = (u1Byte)DM_Value;
pDM_DigTable->BackoffVal = (u8)DM_Value;
} else if (DM_Type == RT_TYPE_RX_GAIN_MIN) {
if (DM_Value == 0)
DM_Value = 0x1;
pDM_DigTable->rx_gain_range_min = (u1Byte)DM_Value;
pDM_DigTable->rx_gain_range_min = (u8)DM_Value;
} else if (DM_Type == RT_TYPE_RX_GAIN_MAX) {
if (DM_Value > 0x50)
DM_Value = 0x50;
pDM_DigTable->rx_gain_range_max = (u1Byte)DM_Value;
pDM_DigTable->rx_gain_range_max = (u8)DM_Value;
}
} /* DM_ChangeDynamicInitGainThresh */
@ -600,7 +600,7 @@ static int getIGIForDiff(int value_IGI)
}
}
void ODM_Write_DIG(struct odm_dm_struct *pDM_Odm, u1Byte CurrentIGI)
void ODM_Write_DIG(struct odm_dm_struct *pDM_Odm, u8 CurrentIGI)
{
struct rtw_dig *pDM_DigTable = &pDM_Odm->DM_DigTable;
@ -649,9 +649,9 @@ void odm_DIGbyRSSI_LPS(struct odm_dm_struct *pDM_Odm)
struct rtw_dig *pDM_DigTable = &pDM_Odm->DM_DigTable;
struct false_alarm_stats *pFalseAlmCnt = &pDM_Odm->FalseAlmCnt;
u1Byte RSSI_Lower = DM_DIG_MIN_NIC; /* 0x1E or 0x1C */
u1Byte bFwCurrentInPSMode = false;
u1Byte CurrentIGI = pDM_Odm->RSSI_Min;
u8 RSSI_Lower = DM_DIG_MIN_NIC; /* 0x1E or 0x1C */
u8 bFwCurrentInPSMode = false;
u8 CurrentIGI = pDM_Odm->RSSI_Min;
if (!(pDM_Odm->SupportICType & (ODM_RTL8723A | ODM_RTL8188E)))
return;
@ -694,7 +694,7 @@ void odm_DIGInit(struct odm_dm_struct *pDM_Odm)
{
struct rtw_dig *pDM_DigTable = &pDM_Odm->DM_DigTable;
pDM_DigTable->CurIGValue = (u1Byte) ODM_GetBBReg(pDM_Odm, ODM_REG(IGI_A, pDM_Odm), ODM_BIT(IGI, pDM_Odm));
pDM_DigTable->CurIGValue = (u8) ODM_GetBBReg(pDM_Odm, ODM_REG(IGI_A, pDM_Odm), ODM_BIT(IGI, pDM_Odm));
pDM_DigTable->RssiLowThresh = DM_DIG_THRESH_LOW;
pDM_DigTable->RssiHighThresh = DM_DIG_THRESH_HIGH;
pDM_DigTable->FALowThresh = DM_false_ALARM_THRESH_LOW;
@ -728,11 +728,11 @@ void odm_DIG(struct odm_dm_struct *pDM_Odm)
struct rtw_dig *pDM_DigTable = &pDM_Odm->DM_DigTable;
struct false_alarm_stats *pFalseAlmCnt = &pDM_Odm->FalseAlmCnt;
struct rx_hpc *pRX_HP_Table = &pDM_Odm->DM_RXHP_Table;
u1Byte DIG_Dynamic_MIN;
u1Byte DIG_MaxOfMin;
u8 DIG_Dynamic_MIN;
u8 DIG_MaxOfMin;
bool FirstConnect, FirstDisConnect;
u1Byte dm_dig_max, dm_dig_min;
u1Byte CurrentIGI = pDM_DigTable->CurIGValue;
u8 dm_dig_max, dm_dig_min;
u8 CurrentIGI = pDM_DigTable->CurIGValue;
ODM_RT_TRACE(pDM_Odm, ODM_COMP_DIG, ODM_DBG_LOUD, ("odm_DIG()==>\n"));
if ((!(pDM_Odm->SupportAbility&ODM_BB_DIG)) || (!(pDM_Odm->SupportAbility&ODM_BB_FA_CNT))) {
@ -840,7 +840,7 @@ void odm_DIG(struct odm_dm_struct *pDM_Odm)
(pDM_Odm->SupportAbility & ODM_BB_ANT_DIV)) {
/* 1 Lower Bound for 88E AntDiv */
if (pDM_Odm->AntDivType == CG_TRX_HW_ANTDIV) {
DIG_Dynamic_MIN = (u1Byte) pDM_DigTable->AntDiv_RSSI_max;
DIG_Dynamic_MIN = (u8) pDM_DigTable->AntDiv_RSSI_max;
ODM_RT_TRACE(pDM_Odm, ODM_COMP_ANT_DIV, ODM_DBG_LOUD,
("odm_DIG(): pDM_DigTable->AntDiv_RSSI_max=%d\n",
pDM_DigTable->AntDiv_RSSI_max));
@ -963,7 +963,7 @@ void odm_DIG(struct odm_dm_struct *pDM_Odm)
void odm_FalseAlarmCounterStatistics(struct odm_dm_struct *pDM_Odm)
{
u4Byte ret_value;
u32 ret_value;
struct false_alarm_stats *FalseAlmCnt = &(pDM_Odm->FalseAlmCnt);
if (!(pDM_Odm->SupportAbility & ODM_BB_FA_CNT))
@ -1071,7 +1071,7 @@ void odm_FalseAlarmCounterStatistics(struct odm_dm_struct *pDM_Odm)
void odm_CCKPacketDetectionThresh(struct odm_dm_struct *pDM_Odm)
{
struct rtw_dig *pDM_DigTable = &pDM_Odm->DM_DigTable;
u1Byte CurCCK_CCAThres;
u8 CurCCK_CCAThres;
struct false_alarm_stats *FalseAlmCnt = &(pDM_Odm->FalseAlmCnt);
if (!(pDM_Odm->SupportAbility & (ODM_BB_CCK_PD|ODM_BB_FA_CNT)))
@ -1098,7 +1098,7 @@ void odm_CCKPacketDetectionThresh(struct odm_dm_struct *pDM_Odm)
ODM_Write_CCK_CCA_Thres(pDM_Odm, CurCCK_CCAThres);
}
void ODM_Write_CCK_CCA_Thres(struct odm_dm_struct *pDM_Odm, u1Byte CurCCK_CCAThres)
void ODM_Write_CCK_CCA_Thres(struct odm_dm_struct *pDM_Odm, u8 CurCCK_CCAThres)
{
struct rtw_dig *pDM_DigTable = &pDM_Odm->DM_DigTable;
@ -1176,11 +1176,11 @@ void odm_1R_CCA(struct odm_dm_struct *pDM_Odm)
}
}
void ODM_RF_Saving(struct odm_dm_struct *pDM_Odm, u1Byte bForceInNormal)
void ODM_RF_Saving(struct odm_dm_struct *pDM_Odm, u8 bForceInNormal)
{
struct rtl_ps *pDM_PSTable = &pDM_Odm->DM_PSTable;
u1Byte Rssi_Up_bound = 30;
u1Byte Rssi_Low_bound = 25;
u8 Rssi_Up_bound = 30;
u8 Rssi_Low_bound = 25;
if (pDM_Odm->PatchID == 40) { /* RT_CID_819x_FUNAI_TV */
Rssi_Up_bound = 50;
@ -1263,11 +1263,11 @@ void odm_RateAdaptiveMaskInit(struct odm_dm_struct *pDM_Odm)
pOdmRA->LowRSSIThresh = 20;
}
u4Byte ODM_Get_Rate_Bitmap(struct odm_dm_struct *pDM_Odm, u4Byte macid, u4Byte ra_mask, u1Byte rssi_level)
u32 ODM_Get_Rate_Bitmap(struct odm_dm_struct *pDM_Odm, u32 macid, u32 ra_mask, u8 rssi_level)
{
struct sta_info *pEntry;
u4Byte rate_bitmap = 0x0fffffff;
u1Byte WirelessMode;
u32 rate_bitmap = 0x0fffffff;
u8 WirelessMode;
pEntry = pDM_Odm->pODM_StaInfo[macid];
if (!IS_STA_VALID(pEntry))
@ -1384,7 +1384,7 @@ void odm_RefreshRateAdaptiveMaskMP(struct odm_dm_struct *pDM_Odm)
void odm_RefreshRateAdaptiveMaskCE(struct odm_dm_struct *pDM_Odm)
{
u1Byte i;
u8 i;
struct adapter *pAdapter = pDM_Odm->Adapter;
if (pAdapter->bDriverStopped) {
@ -1416,13 +1416,13 @@ void odm_RefreshRateAdaptiveMaskAPADSL(struct odm_dm_struct *pDM_Odm)
/* Return Value: bool */
/* - true: RATRState is changed. */
bool ODM_RAStateCheck(struct odm_dm_struct *pDM_Odm, s4Byte RSSI, bool bForceUpdate, pu1Byte pRATRState)
bool ODM_RAStateCheck(struct odm_dm_struct *pDM_Odm, s32 RSSI, bool bForceUpdate, u8 *pRATRState)
{
struct odm_rate_adapt *pRA = &pDM_Odm->RateAdaptive;
const u1Byte GoUpGap = 5;
u1Byte HighRSSIThreshForRA = pRA->HighRSSIThresh;
u1Byte LowRSSIThreshForRA = pRA->LowRSSIThresh;
u1Byte RATRState;
const u8 GoUpGap = 5;
u8 HighRSSIThreshForRA = pRA->HighRSSIThresh;
u8 LowRSSIThreshForRA = pRA->LowRSSIThresh;
u8 RATRState;
/* Threshold Adjustment: */
/* when RSSI state trends to go up one or two levels, make sure RSSI is high enough. */
@ -1475,8 +1475,8 @@ void odm_DynamicTxPowerInit(struct odm_dm_struct *pDM_Odm)
static void odm_DynamicTxPowerSavePowerIndex(struct odm_dm_struct *pDM_Odm)
{
u1Byte index;
u4Byte Power_Index_REG[6] = {0xc90, 0xc91, 0xc92, 0xc98, 0xc99, 0xc9a};
u8 index;
u32 Power_Index_REG[6] = {0xc90, 0xc91, 0xc92, 0xc98, 0xc99, 0xc9a};
struct adapter *Adapter = pDM_Odm->Adapter;
struct hal_data_8188e *pHalData = GET_HAL_DATA(Adapter);
@ -1487,20 +1487,20 @@ static void odm_DynamicTxPowerSavePowerIndex(struct odm_dm_struct *pDM_Odm)
static void odm_DynamicTxPowerRestorePowerIndex(struct odm_dm_struct *pDM_Odm)
{
u1Byte index;
u8 index;
struct adapter *Adapter = pDM_Odm->Adapter;
struct hal_data_8188e *pHalData = GET_HAL_DATA(Adapter);
u4Byte Power_Index_REG[6] = {0xc90, 0xc91, 0xc92, 0xc98, 0xc99, 0xc9a};
u32 Power_Index_REG[6] = {0xc90, 0xc91, 0xc92, 0xc98, 0xc99, 0xc9a};
struct dm_priv *pdmpriv = &pHalData->dmpriv;
for (index = 0; index < 6; index++)
rtw_write8(Adapter, Power_Index_REG[index], pdmpriv->PowerIndex_backup[index]);
}
static void odm_DynamicTxPowerWritePowerIndex(struct odm_dm_struct *pDM_Odm, u1Byte Value)
static void odm_DynamicTxPowerWritePowerIndex(struct odm_dm_struct *pDM_Odm, u8 Value)
{
u1Byte index;
u4Byte Power_Index_REG[6] = {0xc90, 0xc91, 0xc92, 0xc98, 0xc99, 0xc9a};
u8 index;
u32 Power_Index_REG[6] = {0xc90, 0xc91, 0xc92, 0xc98, 0xc99, 0xc9a};
for (index = 0; index < 6; index++)
ODM_Write1Byte(pDM_Odm, Power_Index_REG[index], Value);
@ -1788,11 +1788,11 @@ void odm_SwAntDivInit(struct odm_dm_struct *pDM_Odm)
{
}
void ODM_SwAntDivChkPerPktRssi(struct odm_dm_struct *pDM_Odm, u1Byte StationID, struct odm_phy_status_info *pPhyInfo)
void ODM_SwAntDivChkPerPktRssi(struct odm_dm_struct *pDM_Odm, u8 StationID, struct odm_phy_status_info *pPhyInfo)
{
}
void odm_SwAntDivChkAntSwitch(struct odm_dm_struct *pDM_Odm, u1Byte Step)
void odm_SwAntDivChkAntSwitch(struct odm_dm_struct *pDM_Odm, u8 Step)
{
}
@ -1815,8 +1815,8 @@ void odm_SwAntDivChkAntSwitchCallback(void *FunctionContext)
static void odm_InitHybridAntDiv_88C_92D(struct odm_dm_struct *pDM_Odm)
{
struct sw_ant_switch *pDM_SWAT_Table = &pDM_Odm->DM_SWAT_Table;
u1Byte bTxPathSel = 0; /* 0:Path-A 1:Path-B */
u1Byte i;
u8 bTxPathSel = 0; /* 0:Path-A 1:Path-B */
u8 i;
ODM_RT_TRACE(pDM_Odm, ODM_COMP_ANT_DIV, ODM_DBG_LOUD, ("odm_InitHybridAntDiv==============>\n"));
@ -1887,8 +1887,8 @@ void odm_InitHybridAntDiv(struct odm_dm_struct *pDM_Odm)
}
static bool odm_StaDefAntSel(struct odm_dm_struct *pDM_Odm, u4Byte OFDM_Ant1_Cnt,
u4Byte OFDM_Ant2_Cnt, u4Byte CCK_Ant1_Cnt, u4Byte CCK_Ant2_Cnt, u1Byte *pDefAnt)
static bool odm_StaDefAntSel(struct odm_dm_struct *pDM_Odm, u32 OFDM_Ant1_Cnt,
u32 OFDM_Ant2_Cnt, u32 CCK_Ant1_Cnt, u32 CCK_Ant2_Cnt, u8 *pDefAnt)
{
ODM_RT_TRACE(pDM_Odm, ODM_COMP_ANT_DIV, ODM_DBG_LOUD, ("odm_StaDefAntSelect==============>\n"));
@ -1926,7 +1926,7 @@ static bool odm_StaDefAntSel(struct odm_dm_struct *pDM_Odm, u4Byte OFDM_Ant1_Cnt
return true;
}
static void odm_SetRxIdleAnt(struct odm_dm_struct *pDM_Odm, u1Byte Ant, bool bDualPath)
static void odm_SetRxIdleAnt(struct odm_dm_struct *pDM_Odm, u8 Ant, bool bDualPath)
{
struct sw_ant_switch *pDM_SWAT_Table = &pDM_Odm->DM_SWAT_Table;
@ -1949,7 +1949,7 @@ static void odm_SetRxIdleAnt(struct odm_dm_struct *pDM_Odm, u1Byte Ant, bool bDu
ODM_RT_TRACE(pDM_Odm, ODM_COMP_ANT_DIV, ODM_DBG_LOUD, ("RxIdleAnt: %s Reg858=0x%x\n", (Ant == 1) ? "Ant1" : "Ant2", (Ant == 1) ? 0x65a9 : 0x569a));
}
void ODM_AntselStatistics_88C(struct odm_dm_struct *pDM_Odm, u1Byte MacId, u4Byte PWDBAll, bool isCCKrate)
void ODM_AntselStatistics_88C(struct odm_dm_struct *pDM_Odm, u8 MacId, u32 PWDBAll, bool isCCKrate)
{
struct sw_ant_switch *pDM_SWAT_Table = &pDM_Odm->DM_SWAT_Table;
@ -1977,8 +1977,8 @@ static void ODM_SetTxAntByTxInfo_88C_92D(struct odm_dm_struct *pDM_Odm)
static void odm_HwAntDiv_92C_92D(struct odm_dm_struct *pDM_Odm)
{
struct sw_ant_switch *pDM_SWAT_Table = &pDM_Odm->DM_SWAT_Table;
u4Byte RSSI_Min = 0xFF, RSSI, RSSI_Ant1, RSSI_Ant2;
u1Byte RxIdleAnt, i;
u32 RSSI_Min = 0xFF, RSSI, RSSI_Ant1, RSSI_Ant2;
u8 RxIdleAnt, i;
bool bRet = false;
struct sta_info *pEntry;
@ -2177,9 +2177,9 @@ dm_CheckEdcaTurbo_EXIT:
/* need to ODM CE Platform */
/* move to here for ANT detection mechanism using */
u4Byte GetPSDData(struct odm_dm_struct *pDM_Odm, unsigned int point, u1Byte initial_gain_psd)
u32 GetPSDData(struct odm_dm_struct *pDM_Odm, unsigned int point, u8 initial_gain_psd)
{
u4Byte psd_report;
u32 psd_report;
/* Set DCO frequency index, offset=(40MHz/SamplePts)*point */
ODM_SetBBReg(pDM_Odm, 0x808, 0x3FF, point);
@ -2192,16 +2192,16 @@ u4Byte GetPSDData(struct odm_dm_struct *pDM_Odm, unsigned int point, u1Byte init
/* Read PSD report, Reg8B4[15:0] */
psd_report = ODM_GetBBReg(pDM_Odm, 0x8B4, bMaskDWord) & 0x0000FFFF;
psd_report = (u4Byte) (ConvertTo_dB(psd_report))+(u4Byte)(initial_gain_psd-0x1c);
psd_report = (u32) (ConvertTo_dB(psd_report))+(u32)(initial_gain_psd-0x1c);
return psd_report;
}
u4Byte ConvertTo_dB(u4Byte Value)
u32 ConvertTo_dB(u32 Value)
{
u1Byte i;
u1Byte j;
u4Byte dB;
u8 i;
u8 j;
u32 dB;
Value = Value & 0xFFFF;
for (i = 0; i < 8; i++) {
@ -2241,18 +2241,18 @@ void ODM_SingleDualAntennaDefaultSetting(struct odm_dm_struct *pDM_Odm)
/* 2 8723A ANT DETECT */
static void odm_PHY_SaveAFERegisters(struct odm_dm_struct *pDM_Odm, pu4Byte AFEReg, pu4Byte AFEBackup, u4Byte RegisterNum)
static void odm_PHY_SaveAFERegisters(struct odm_dm_struct *pDM_Odm, u32 *AFEReg, u32 *AFEBackup, u32 RegisterNum)
{
u4Byte i;
u32 i;
/* RTPRINT(FINIT, INIT_IQK, ("Save ADDA parameters.\n")); */
for (i = 0; i < RegisterNum; i++)
AFEBackup[i] = ODM_GetBBReg(pDM_Odm, AFEReg[i], bMaskDWord);
}
static void odm_PHY_ReloadAFERegisters(struct odm_dm_struct *pDM_Odm, pu4Byte AFEReg, pu4Byte AFEBackup, u4Byte RegiesterNum)
static void odm_PHY_ReloadAFERegisters(struct odm_dm_struct *pDM_Odm, u32 *AFEReg, u32 *AFEBackup, u32 RegiesterNum)
{
u4Byte i;
u32 i;
for (i = 0; i < RegiesterNum; i++)
ODM_SetBBReg(pDM_Odm, AFEReg[i], bMaskDWord, AFEBackup[i]);
@ -2262,18 +2262,18 @@ static void odm_PHY_ReloadAFERegisters(struct odm_dm_struct *pDM_Odm, pu4Byte AF
/* Description: */
/* Implement IQK single tone for RF DPK loopback and BB PSD scanning. */
/* This function is cooperated with BB team Neil. */
bool ODM_SingleDualAntennaDetection(struct odm_dm_struct *pDM_Odm, u1Byte mode)
bool ODM_SingleDualAntennaDetection(struct odm_dm_struct *pDM_Odm, u8 mode)
{
struct sw_ant_switch *pDM_SWAT_Table = &pDM_Odm->DM_SWAT_Table;
u4Byte CurrentChannel, RfLoopReg;
u1Byte n;
u4Byte Reg88c, Regc08, Reg874, Regc50;
u1Byte initial_gain = 0x5a;
u4Byte PSD_report_tmp;
u4Byte AntA_report = 0x0, AntB_report = 0x0, AntO_report = 0x0;
u32 CurrentChannel, RfLoopReg;
u8 n;
u32 Reg88c, Regc08, Reg874, Regc50;
u8 initial_gain = 0x5a;
u32 PSD_report_tmp;
u32 AntA_report = 0x0, AntB_report = 0x0, AntO_report = 0x0;
bool bResult = true;
u4Byte AFE_Backup[16];
u4Byte AFE_REG_8723A[16] = {
u32 AFE_Backup[16];
u32 AFE_REG_8723A[16] = {
rRx_Wait_CCA, rTx_CCK_RFON,
rTx_CCK_BBON, rTx_OFDM_RFON,
rTx_OFDM_BBON, rTx_To_Rx,

94
hal/odm_HWConfig.c
View file

@ -27,7 +27,7 @@
#define READ_AND_CONFIG_MP(ic, txt) (ODM_ReadAndConfig##txt##ic(dm_odm))
#define READ_AND_CONFIG_TC(ic, txt) (ODM_ReadAndConfig_TC##txt##ic(dm_odm))
static u1Byte odm_QueryRxPwrPercentage(s1Byte AntPower)
static u8 odm_QueryRxPwrPercentage(s8 AntPower)
{
if ((AntPower <= -100) || (AntPower >= 20))
return 0;
@ -39,22 +39,22 @@ static u1Byte odm_QueryRxPwrPercentage(s1Byte AntPower)
/* 2012/01/12 MH MOve some signal strength smooth method to MP HAL layer. */
/* IF other SW team do not support the feature, remove this section.?? */
static s4Byte odm_sig_patch_lenove(struct odm_dm_struct *dm_odm, s4Byte CurrSig)
static s32 odm_sig_patch_lenove(struct odm_dm_struct *dm_odm, s32 CurrSig)
{
s4Byte RetSig;
s32 RetSig;
return RetSig;
}
static s4Byte odm_sig_patch_netcore(struct odm_dm_struct *dm_odm, s4Byte CurrSig)
static s32 odm_sig_patch_netcore(struct odm_dm_struct *dm_odm, s32 CurrSig)
{
s4Byte RetSig;
s32 RetSig;
return RetSig;
}
static s4Byte odm_SignalScaleMapping_92CSeries(struct odm_dm_struct *dm_odm, s4Byte CurrSig)
static s32 odm_SignalScaleMapping_92CSeries(struct odm_dm_struct *dm_odm, s32 CurrSig)
{
s4Byte RetSig;
s32 RetSig;
if ((dm_odm->SupportInterface == ODM_ITRF_USB) ||
(dm_odm->SupportInterface == ODM_ITRF_SDIO)) {
@ -78,7 +78,7 @@ static s4Byte odm_SignalScaleMapping_92CSeries(struct odm_dm_struct *dm_odm, s4B
return RetSig;
}
static s4Byte odm_SignalScaleMapping(struct odm_dm_struct *dm_odm, s4Byte CurrSig)
static s32 odm_SignalScaleMapping(struct odm_dm_struct *dm_odm, s32 CurrSig)
{
if ((dm_odm->SupportPlatform == ODM_MP) &&
(dm_odm->SupportInterface != ODM_ITRF_PCIE) && /* USB & SDIO */
@ -93,17 +93,17 @@ static s4Byte odm_SignalScaleMapping(struct odm_dm_struct *dm_odm, s4Byte CurrSi
}
/* pMgntInfo->CustomerID == RT_CID_819x_Lenovo */
static u1Byte odm_SQ_process_patch_RT_CID_819x_Lenovo(struct odm_dm_struct *dm_odm,
u1Byte isCCKrate, u1Byte PWDB_ALL, u1Byte path, u1Byte RSSI)
static u8 odm_SQ_process_patch_RT_CID_819x_Lenovo(struct odm_dm_struct *dm_odm,
u8 isCCKrate, u8 PWDB_ALL, u8 path, u8 RSSI)
{
u1Byte SQ;
u8 SQ;
return SQ;
}
static u1Byte odm_EVMdbToPercentage(s1Byte Value)
static u8 odm_EVMdbToPercentage(s8 Value)
{
/* -33dB~0dB to 0%~99% */
s1Byte ret_val;
s8 ret_val;
ret_val = Value;
@ -122,18 +122,18 @@ static u1Byte odm_EVMdbToPercentage(s1Byte Value)
static void odm_RxPhyStatus92CSeries_Parsing(struct odm_dm_struct *dm_odm,
struct odm_phy_status_info *pPhyInfo,
pu1Byte pPhyStatus,
u8 *pPhyStatus,
struct odm_per_pkt_info *pPktinfo)
{
struct sw_ant_switch *pDM_SWAT_Table = &dm_odm->DM_SWAT_Table;
u1Byte i, Max_spatial_stream;
s1Byte rx_pwr[4], rx_pwr_all = 0;
u1Byte EVM, PWDB_ALL = 0, PWDB_ALL_BT;
u1Byte RSSI, total_rssi = 0;
u1Byte isCCKrate = 0;
u1Byte rf_rx_num = 0;
u1Byte cck_highpwr = 0;
u1Byte LNA_idx, VGA_idx;
u8 i, Max_spatial_stream;
s8 rx_pwr[4], rx_pwr_all = 0;
u8 EVM, PWDB_ALL = 0, PWDB_ALL_BT;
u8 RSSI, total_rssi = 0;
u8 isCCKrate = 0;
u8 rf_rx_num = 0;
u8 cck_highpwr = 0;
u8 LNA_idx, VGA_idx;
struct phy_status_rpt *pPhyStaRpt = (struct phy_status_rpt *)pPhyStatus;
@ -143,8 +143,8 @@ static void odm_RxPhyStatus92CSeries_Parsing(struct odm_dm_struct *dm_odm,
pPhyInfo->RxMIMOSignalQuality[ODM_RF_PATH_B] = -1;
if (isCCKrate) {
u1Byte report;
u1Byte cck_agc_rpt;
u8 report;
u8 cck_agc_rpt;
dm_odm->PhyDbgInfo.NumQryPhyStatusCCK++;
/* (1)Hardware does not provide RSSI for CCK */
@ -271,7 +271,7 @@ static void odm_RxPhyStatus92CSeries_Parsing(struct odm_dm_struct *dm_odm,
pPhyInfo->RecvSignalPower = rx_pwr_all;
/* (3) Get Signal Quality (EVM) */
if (pPktinfo->bPacketMatchBSSID) {
u1Byte SQ, SQ_rpt;
u8 SQ, SQ_rpt;
if ((dm_odm->SupportPlatform == ODM_MP) && (dm_odm->PatchID == 19)) {
SQ = odm_SQ_process_patch_RT_CID_819x_Lenovo(dm_odm, isCCKrate, PWDB_ALL, 0, 0);
@ -320,11 +320,11 @@ static void odm_RxPhyStatus92CSeries_Parsing(struct odm_dm_struct *dm_odm,
RSSI -= 4;
}
pPhyInfo->RxMIMOSignalStrength[i] = (u1Byte)RSSI;
pPhyInfo->RxMIMOSignalStrength[i] = (u8)RSSI;
/* Get Rx snr value in DB */
pPhyInfo->RxSNR[i] = (s4Byte)(pPhyStaRpt->path_rxsnr[i]/2);
dm_odm->PhyDbgInfo.RxSNRdB[i] = (s4Byte)(pPhyStaRpt->path_rxsnr[i]/2);
pPhyInfo->RxSNR[i] = (s32)(pPhyStaRpt->path_rxsnr[i]/2);
dm_odm->PhyDbgInfo.RxSNRdB[i] = (s32)(pPhyStaRpt->path_rxsnr[i]/2);
/* Record Signal Strength for next packet */
if (pPktinfo->bPacketMatchBSSID) {
@ -362,8 +362,8 @@ static void odm_RxPhyStatus92CSeries_Parsing(struct odm_dm_struct *dm_odm,
if (pPktinfo->bPacketMatchBSSID) {
if (i == ODM_RF_PATH_A) /* Fill value in RFD, Get the first spatial stream only */
pPhyInfo->SignalQuality = (u1Byte)(EVM & 0xff);
pPhyInfo->RxMIMOSignalQuality[i] = (u1Byte)(EVM & 0xff);
pPhyInfo->SignalQuality = (u8)(EVM & 0xff);
pPhyInfo->RxMIMOSignalQuality[i] = (u8)(EVM & 0xff);
}
}
}
@ -371,10 +371,10 @@ static void odm_RxPhyStatus92CSeries_Parsing(struct odm_dm_struct *dm_odm,
/* UI BSS List signal strength(in percentage), make it good looking, from 0~100. */
/* It is assigned to the BSS List in GetValueFromBeaconOrProbeRsp(). */
if (isCCKrate) {
pPhyInfo->SignalStrength = (u1Byte)(odm_SignalScaleMapping(dm_odm, PWDB_ALL));/* PWDB_ALL; */
pPhyInfo->SignalStrength = (u8)(odm_SignalScaleMapping(dm_odm, PWDB_ALL));/* PWDB_ALL; */
} else {
if (rf_rx_num != 0)
pPhyInfo->SignalStrength = (u1Byte)(odm_SignalScaleMapping(dm_odm, total_rssi /= rf_rx_num));
pPhyInfo->SignalStrength = (u8)(odm_SignalScaleMapping(dm_odm, total_rssi /= rf_rx_num));
}
/* For 92C/92D HW (Hybrid) Antenna Diversity */
@ -393,12 +393,12 @@ static void odm_Process_RSSIForDM(struct odm_dm_struct *dm_odm,
struct odm_phy_status_info *pPhyInfo,
struct odm_per_pkt_info *pPktinfo)
{
s4Byte UndecoratedSmoothedPWDB, UndecoratedSmoothedCCK;
s4Byte UndecoratedSmoothedOFDM, RSSI_Ave;
u1Byte isCCKrate = 0;
u1Byte RSSI_max, RSSI_min, i;
u4Byte OFDM_pkt = 0;
u4Byte Weighting = 0;
s32 UndecoratedSmoothedPWDB, UndecoratedSmoothedCCK;
s32 UndecoratedSmoothedOFDM, RSSI_Ave;
u8 isCCKrate = 0;
u8 RSSI_max, RSSI_min, i;
u32 OFDM_pkt = 0;
u32 Weighting = 0;
struct sta_info *pEntry;
if (pPktinfo->StationID == 0xFF)
@ -413,7 +413,7 @@ static void odm_Process_RSSIForDM(struct odm_dm_struct *dm_odm,
/* Smart Antenna Debug Message------------------ */
if (dm_odm->SupportICType == ODM_RTL8188E) {
u1Byte antsel_tr_mux;
u8 antsel_tr_mux;
struct fast_ant_train *pDM_FatTable = &dm_odm->DM_FatTable;
if (dm_odm->AntDivType == CG_TRX_SMART_ANTDIV) {
@ -466,7 +466,7 @@ static void odm_Process_RSSIForDM(struct odm_dm_struct *dm_odm,
if (UndecoratedSmoothedOFDM <= 0) { /* initialize */
UndecoratedSmoothedOFDM = pPhyInfo->RxPWDBAll;
} else {
if (pPhyInfo->RxPWDBAll > (u4Byte)UndecoratedSmoothedOFDM) {
if (pPhyInfo->RxPWDBAll > (u32)UndecoratedSmoothedOFDM) {
UndecoratedSmoothedOFDM =
(((UndecoratedSmoothedOFDM)*(Rx_Smooth_Factor-1)) +
(RSSI_Ave)) / (Rx_Smooth_Factor);
@ -487,7 +487,7 @@ static void odm_Process_RSSIForDM(struct odm_dm_struct *dm_odm,
if (UndecoratedSmoothedCCK <= 0) { /* initialize */
UndecoratedSmoothedCCK = pPhyInfo->RxPWDBAll;
} else {
if (pPhyInfo->RxPWDBAll > (u4Byte)UndecoratedSmoothedCCK) {
if (pPhyInfo->RxPWDBAll > (u32)UndecoratedSmoothedCCK) {
UndecoratedSmoothedCCK =
((UndecoratedSmoothedCCK * (Rx_Smooth_Factor-1)) +
pPhyInfo->RxPWDBAll) / Rx_Smooth_Factor;
@ -507,7 +507,7 @@ static void odm_Process_RSSIForDM(struct odm_dm_struct *dm_odm,
pEntry->rssi_stat.ValidBit++;
for (i = 0; i < pEntry->rssi_stat.ValidBit; i++)
OFDM_pkt += (u1Byte)(pEntry->rssi_stat.PacketMap>>i)&BIT0;
OFDM_pkt += (u8)(pEntry->rssi_stat.PacketMap>>i)&BIT0;
if (pEntry->rssi_stat.ValidBit == 64) {
Weighting = ((OFDM_pkt<<4) > 64) ? 64 : (OFDM_pkt<<4);
@ -529,7 +529,7 @@ static void odm_Process_RSSIForDM(struct odm_dm_struct *dm_odm,
/* Endianness before calling this API */
static void ODM_PhyStatusQuery_92CSeries(struct odm_dm_struct *dm_odm,
struct odm_phy_status_info *pPhyInfo,
pu1Byte pPhyStatus,
u8 *pPhyStatus,
struct odm_per_pkt_info *pPktinfo)
{
odm_RxPhyStatus92CSeries_Parsing(dm_odm, pPhyInfo, pPhyStatus,
@ -545,14 +545,14 @@ static void ODM_PhyStatusQuery_92CSeries(struct odm_dm_struct *dm_odm,
void ODM_PhyStatusQuery(struct odm_dm_struct *dm_odm,
struct odm_phy_status_info *pPhyInfo,
pu1Byte pPhyStatus, struct odm_per_pkt_info *pPktinfo)
u8 *pPhyStatus, struct odm_per_pkt_info *pPktinfo)
{
ODM_PhyStatusQuery_92CSeries(dm_odm, pPhyInfo, pPhyStatus, pPktinfo);
}
/* For future use. */
void ODM_MacStatusQuery(struct odm_dm_struct *dm_odm, pu1Byte mac_stat,
u1Byte macid, bool pkt_match_bssid,
void ODM_MacStatusQuery(struct odm_dm_struct *dm_odm, u8 *mac_stat,
u8 macid, bool pkt_match_bssid,
bool pkttoself, bool pkt_beacon)
{
/* 2011/10/19 Driver team will handle in the future. */
@ -593,7 +593,7 @@ enum HAL_STATUS ODM_ConfigBBWithHeaderFile(struct odm_dm_struct *dm_odm,
enum HAL_STATUS ODM_ConfigMACWithHeaderFile(struct odm_dm_struct *dm_odm)
{
u1Byte result = HAL_STATUS_SUCCESS;
u8 result = HAL_STATUS_SUCCESS;
if (dm_odm->SupportICType == ODM_RTL8188E)
result = READ_AND_CONFIG(8188E, _MAC_REG_);
return result;

28
hal/odm_RTL8188E.c
View file

@ -25,7 +25,7 @@ void ODM_DIG_LowerBound_88E(struct odm_dm_struct *dm_odm)
struct rtw_dig *pDM_DigTable = &dm_odm->DM_DigTable;
if (dm_odm->AntDivType == CG_TRX_HW_ANTDIV) {
pDM_DigTable->rx_gain_range_min = (u1Byte) pDM_DigTable->AntDiv_RSSI_max;
pDM_DigTable->rx_gain_range_min = (u8) pDM_DigTable->AntDiv_RSSI_max;
ODM_RT_TRACE(dm_odm, ODM_COMP_ANT_DIV, ODM_DBG_LOUD,
("ODM_DIG_LowerBound_88E(): pDM_DigTable->AntDiv_RSSI_max=%d\n", pDM_DigTable->AntDiv_RSSI_max));
}
@ -34,7 +34,7 @@ void ODM_DIG_LowerBound_88E(struct odm_dm_struct *dm_odm)
static void odm_RX_HWAntDivInit(struct odm_dm_struct *dm_odm)
{
u4Byte value32;
u32 value32;
struct adapter *Adapter = dm_odm->Adapter;
if (*(dm_odm->mp_mode) == 1) {
@ -64,7 +64,7 @@ static void odm_RX_HWAntDivInit(struct odm_dm_struct *dm_odm)
static void odm_TRX_HWAntDivInit(struct odm_dm_struct *dm_odm)
{
u4Byte value32;
u32 value32;
struct adapter *Adapter = dm_odm->Adapter;
if (*(dm_odm->mp_mode) == 1) {
@ -103,9 +103,9 @@ static void odm_TRX_HWAntDivInit(struct odm_dm_struct *dm_odm)
static void odm_FastAntTrainingInit(struct odm_dm_struct *dm_odm)
{
u4Byte value32, i;
u32 value32, i;
struct fast_ant_train *dm_fat_tbl = &dm_odm->DM_FatTable;
u4Byte AntCombination = 2;
u32 AntCombination = 2;
struct adapter *Adapter = dm_odm->Adapter;
ODM_RT_TRACE(dm_odm, ODM_COMP_ANT_DIV, ODM_DBG_LOUD, ("odm_FastAntTrainingInit()\n"));
@ -198,10 +198,10 @@ void ODM_AntennaDiversityInit_88E(struct odm_dm_struct *dm_odm)
odm_FastAntTrainingInit(dm_odm);
}
void ODM_UpdateRxIdleAnt_88E(struct odm_dm_struct *dm_odm, u1Byte Ant)
void ODM_UpdateRxIdleAnt_88E(struct odm_dm_struct *dm_odm, u8 Ant)
{
struct fast_ant_train *dm_fat_tbl = &dm_odm->DM_FatTable;
u4Byte DefaultAnt, OptionalAnt;
u32 DefaultAnt, OptionalAnt;
if (dm_fat_tbl->RxIdleAnt != Ant) {
ODM_RT_TRACE(dm_odm, ODM_COMP_ANT_DIV, ODM_DBG_LOUD, ("Need to Update Rx Idle Ant\n"));
@ -228,10 +228,10 @@ void ODM_UpdateRxIdleAnt_88E(struct odm_dm_struct *dm_odm, u1Byte Ant)
pr_info("RxIdleAnt=%s\n", (Ant == MAIN_ANT) ? "MAIN_ANT" : "AUX_ANT");
}
static void odm_UpdateTxAnt_88E(struct odm_dm_struct *dm_odm, u1Byte Ant, u4Byte MacId)
static void odm_UpdateTxAnt_88E(struct odm_dm_struct *dm_odm, u8 Ant, u32 MacId)
{
struct fast_ant_train *dm_fat_tbl = &dm_odm->DM_FatTable;
u1Byte TargetAnt;
u8 TargetAnt;
if (Ant == MAIN_ANT)
TargetAnt = MAIN_ANT_CG_TRX;
@ -249,7 +249,7 @@ static void odm_UpdateTxAnt_88E(struct odm_dm_struct *dm_odm, u1Byte Ant, u4Byte
dm_fat_tbl->antsel_c[MacId], dm_fat_tbl->antsel_b[MacId], dm_fat_tbl->antsel_a[MacId]));
}
void ODM_SetTxAntByTxInfo_88E(struct odm_dm_struct *dm_odm, pu1Byte pDesc, u1Byte macId)
void ODM_SetTxAntByTxInfo_88E(struct odm_dm_struct *dm_odm, u8 *pDesc, u8 macId)
{
struct fast_ant_train *dm_fat_tbl = &dm_odm->DM_FatTable;
@ -260,7 +260,7 @@ void ODM_SetTxAntByTxInfo_88E(struct odm_dm_struct *dm_odm, pu1Byte pDesc, u1Byt
}
}
void ODM_AntselStatistics_88E(struct odm_dm_struct *dm_odm, u1Byte antsel_tr_mux, u4Byte MacId, u1Byte RxPWDBAll)
void ODM_AntselStatistics_88E(struct odm_dm_struct *dm_odm, u8 antsel_tr_mux, u32 MacId, u8 RxPWDBAll)
{
struct fast_ant_train *dm_fat_tbl = &dm_odm->DM_FatTable;
if (dm_odm->AntDivType == CG_TRX_HW_ANTDIV) {
@ -284,9 +284,9 @@ void ODM_AntselStatistics_88E(struct odm_dm_struct *dm_odm, u1Byte antsel_tr_mux
static void odm_HWAntDiv(struct odm_dm_struct *dm_odm)
{
u4Byte i, MinRSSI = 0xFF, AntDivMaxRSSI = 0, MaxRSSI = 0, LocalMinRSSI, LocalMaxRSSI;
u4Byte Main_RSSI, Aux_RSSI;
u1Byte RxIdleAnt = 0, TargetAnt = 7;
u32 i, MinRSSI = 0xFF, AntDivMaxRSSI = 0, MaxRSSI = 0, LocalMinRSSI, LocalMaxRSSI;
u32 Main_RSSI, Aux_RSSI;
u8 RxIdleAnt = 0, TargetAnt = 7;
struct fast_ant_train *dm_fat_tbl = &dm_odm->DM_FatTable;
struct rtw_dig *pDM_DigTable = &dm_odm->DM_DigTable;
bool bMatchBSSID;

28
hal/odm_RegConfig8188E.c
View file

@ -20,9 +20,9 @@
#include "odm_precomp.h"
void odm_ConfigRFReg_8188E(struct odm_dm_struct *pDM_Odm, u4Byte Addr,
u4Byte Data, enum ODM_RF_RADIO_PATH RF_PATH,
u4Byte RegAddr)
void odm_ConfigRFReg_8188E(struct odm_dm_struct *pDM_Odm, u32 Addr,
u32 Data, enum ODM_RF_RADIO_PATH RF_PATH,
u32 RegAddr)
{
if (Addr == 0xffe) {
ODM_sleep_ms(50);
@ -43,32 +43,32 @@ void odm_ConfigRFReg_8188E(struct odm_dm_struct *pDM_Odm, u4Byte Addr,
}
}
void odm_ConfigRF_RadioA_8188E(struct odm_dm_struct *pDM_Odm, u4Byte Addr, u4Byte Data)
void odm_ConfigRF_RadioA_8188E(struct odm_dm_struct *pDM_Odm, u32 Addr, u32 Data)
{
u4Byte content = 0x1000; /* RF_Content: radioa_txt */
u4Byte maskforPhySet = (u4Byte)(content&0xE000);
u32 content = 0x1000; /* RF_Content: radioa_txt */
u32 maskforPhySet = (u32)(content&0xE000);
odm_ConfigRFReg_8188E(pDM_Odm, Addr, Data, ODM_RF_PATH_A, Addr|maskforPhySet);
ODM_RT_TRACE(pDM_Odm, ODM_COMP_INIT, ODM_DBG_TRACE, ("===> ODM_ConfigRFWithHeaderFile: [RadioA] %08X %08X\n", Addr, Data));
}
void odm_ConfigRF_RadioB_8188E(struct odm_dm_struct *pDM_Odm, u4Byte Addr, u4Byte Data)
void odm_ConfigRF_RadioB_8188E(struct odm_dm_struct *pDM_Odm, u32 Addr, u32 Data)
{
u4Byte content = 0x1001; /* RF_Content: radiob_txt */
u4Byte maskforPhySet = (u4Byte)(content&0xE000);
u32 content = 0x1001; /* RF_Content: radiob_txt */
u32 maskforPhySet = (u32)(content&0xE000);
odm_ConfigRFReg_8188E(pDM_Odm, Addr, Data, ODM_RF_PATH_B, Addr|maskforPhySet);
ODM_RT_TRACE(pDM_Odm, ODM_COMP_INIT, ODM_DBG_TRACE, ("===> ODM_ConfigRFWithHeaderFile: [RadioB] %08X %08X\n", Addr, Data));
}
void odm_ConfigMAC_8188E(struct odm_dm_struct *pDM_Odm, u4Byte Addr, u1Byte Data)
void odm_ConfigMAC_8188E(struct odm_dm_struct *pDM_Odm, u32 Addr, u8 Data)
{
ODM_Write1Byte(pDM_Odm, Addr, Data);
ODM_RT_TRACE(pDM_Odm, ODM_COMP_INIT, ODM_DBG_TRACE, ("===> ODM_ConfigMACWithHeaderFile: [MAC_REG] %08X %08X\n", Addr, Data));
}
void odm_ConfigBB_AGC_8188E(struct odm_dm_struct *pDM_Odm, u4Byte Addr, u4Byte Bitmask, u4Byte Data)
void odm_ConfigBB_AGC_8188E(struct odm_dm_struct *pDM_Odm, u32 Addr, u32 Bitmask, u32 Data)
{
ODM_SetBBReg(pDM_Odm, Addr, Bitmask, Data);
/* Add 1us delay between BB/RF register setting. */
@ -79,8 +79,8 @@ void odm_ConfigBB_AGC_8188E(struct odm_dm_struct *pDM_Odm, u4Byte Addr, u4Byte B
Addr, Data));
}
void odm_ConfigBB_PHY_REG_PG_8188E(struct odm_dm_struct *pDM_Odm, u4Byte Addr,
u4Byte Bitmask, u4Byte Data)
void odm_ConfigBB_PHY_REG_PG_8188E(struct odm_dm_struct *pDM_Odm, u32 Addr,
u32 Bitmask, u32 Data)
{
if (Addr == 0xfe) {
ODM_sleep_ms(50);
@ -102,7 +102,7 @@ void odm_ConfigBB_PHY_REG_PG_8188E(struct odm_dm_struct *pDM_Odm, u4Byte Addr,
}
}
void odm_ConfigBB_PHY_8188E(struct odm_dm_struct *pDM_Odm, u4Byte Addr, u4Byte Bitmask, u4Byte Data)
void odm_ConfigBB_PHY_8188E(struct odm_dm_struct *pDM_Odm, u32 Addr, u32 Bitmask, u32 Data)
{
if (Addr == 0xfe) {
ODM_sleep_ms(50);

48
hal/odm_interface.c
View file

@ -21,91 +21,91 @@
#include "odm_precomp.h"
/* ODM IO Relative API. */
u1Byte ODM_Read1Byte(struct odm_dm_struct *pDM_Odm, u4Byte RegAddr)
u8 ODM_Read1Byte(struct odm_dm_struct *pDM_Odm, u32 RegAddr)
{
struct adapter *Adapter = pDM_Odm->Adapter;
return rtw_read8(Adapter, RegAddr);
}
u2Byte ODM_Read2Byte(struct odm_dm_struct *pDM_Odm, u4Byte RegAddr)
u16 ODM_Read2Byte(struct odm_dm_struct *pDM_Odm, u32 RegAddr)
{
struct adapter *Adapter = pDM_Odm->Adapter;
return rtw_read16(Adapter, RegAddr);
}
u4Byte ODM_Read4Byte(struct odm_dm_struct *pDM_Odm, u4Byte RegAddr)
u32 ODM_Read4Byte(struct odm_dm_struct *pDM_Odm, u32 RegAddr)
{
struct adapter *Adapter = pDM_Odm->Adapter;
return rtw_read32(Adapter, RegAddr);
}
void ODM_Write1Byte(struct odm_dm_struct *pDM_Odm, u4Byte RegAddr, u1Byte Data)
void ODM_Write1Byte(struct odm_dm_struct *pDM_Odm, u32 RegAddr, u8 Data)
{
struct adapter *Adapter = pDM_Odm->Adapter;
rtw_write8(Adapter, RegAddr, Data);
}
void ODM_Write2Byte(struct odm_dm_struct *pDM_Odm, u4Byte RegAddr, u2Byte Data)
void ODM_Write2Byte(struct odm_dm_struct *pDM_Odm, u32 RegAddr, u16 Data)
{
struct adapter *Adapter = pDM_Odm->Adapter;
rtw_write16(Adapter, RegAddr, Data);
}
void ODM_Write4Byte(struct odm_dm_struct *pDM_Odm, u4Byte RegAddr, u4Byte Data)
void ODM_Write4Byte(struct odm_dm_struct *pDM_Odm, u32 RegAddr, u32 Data)
{
struct adapter *Adapter = pDM_Odm->Adapter;
rtw_write32(Adapter, RegAddr, Data);
}
void ODM_SetMACReg(struct odm_dm_struct *pDM_Odm, u4Byte RegAddr, u4Byte BitMask, u4Byte Data)
void ODM_SetMACReg(struct odm_dm_struct *pDM_Odm, u32 RegAddr, u32 BitMask, u32 Data)
{
struct adapter *Adapter = pDM_Odm->Adapter;
PHY_SetBBReg(Adapter, RegAddr, BitMask, Data);
}
u4Byte ODM_GetMACReg(struct odm_dm_struct *pDM_Odm, u4Byte RegAddr, u4Byte BitMask)
u32 ODM_GetMACReg(struct odm_dm_struct *pDM_Odm, u32 RegAddr, u32 BitMask)
{
struct adapter *Adapter = pDM_Odm->Adapter;
return PHY_QueryBBReg(Adapter, RegAddr, BitMask);
}
void ODM_SetBBReg(struct odm_dm_struct *pDM_Odm, u4Byte RegAddr, u4Byte BitMask, u4Byte Data)
void ODM_SetBBReg(struct odm_dm_struct *pDM_Odm, u32 RegAddr, u32 BitMask, u32 Data)
{
struct adapter *Adapter = pDM_Odm->Adapter;
PHY_SetBBReg(Adapter, RegAddr, BitMask, Data);
}
u4Byte ODM_GetBBReg(struct odm_dm_struct *pDM_Odm, u4Byte RegAddr, u4Byte BitMask)
u32 ODM_GetBBReg(struct odm_dm_struct *pDM_Odm, u32 RegAddr, u32 BitMask)
{
struct adapter *Adapter = pDM_Odm->Adapter;
return PHY_QueryBBReg(Adapter, RegAddr, BitMask);
}
void ODM_SetRFReg(struct odm_dm_struct *pDM_Odm, enum ODM_RF_RADIO_PATH eRFPath, u4Byte RegAddr, u4Byte BitMask, u4Byte Data)
void ODM_SetRFReg(struct odm_dm_struct *pDM_Odm, enum ODM_RF_RADIO_PATH eRFPath, u32 RegAddr, u32 BitMask, u32 Data)
{
struct adapter *Adapter = pDM_Odm->Adapter;
PHY_SetRFReg(Adapter, (enum rf_radio_path)eRFPath, RegAddr, BitMask, Data);
}
u4Byte ODM_GetRFReg(struct odm_dm_struct *pDM_Odm, enum ODM_RF_RADIO_PATH eRFPath, u4Byte RegAddr, u4Byte BitMask)
u32 ODM_GetRFReg(struct odm_dm_struct *pDM_Odm, enum ODM_RF_RADIO_PATH eRFPath, u32 RegAddr, u32 BitMask)
{
struct adapter *Adapter = pDM_Odm->Adapter;
return PHY_QueryRFReg(Adapter, (enum rf_radio_path)eRFPath, RegAddr, BitMask);
}
/* ODM Memory relative API. */
void ODM_AllocateMemory(struct odm_dm_struct *pDM_Odm, void **pPtr, u4Byte length)
void ODM_AllocateMemory(struct odm_dm_struct *pDM_Odm, void **pPtr, u32 length)
{
*pPtr = rtw_zvmalloc(length);
}
/* length could be ignored, used to detect memory leakage. */
void ODM_FreeMemory(struct odm_dm_struct *pDM_Odm, void *pPtr, u4Byte length)
void ODM_FreeMemory(struct odm_dm_struct *pDM_Odm, void *pPtr, u32 length)
{
rtw_vmfree(pPtr, length);
}
s4Byte ODM_CompareMemory(struct odm_dm_struct *pDM_Odm, void *pBuf1, void *pBuf2, u4Byte length)
s32 ODM_CompareMemory(struct odm_dm_struct *pDM_Odm, void *pBuf1, void *pBuf2, u32 length)
{
return _rtw_memcmp(pBuf1, pBuf2, length);
}
@ -147,32 +147,32 @@ void ODM_IsWorkItemScheduled(void *pRtWorkItem)
}
/* ODM Timer relative API. */
void ODM_StallExecution(u4Byte usDelay)
void ODM_StallExecution(u32 usDelay)
{
rtw_udelay_os(usDelay);
}
void ODM_delay_ms(u4Byte ms)
void ODM_delay_ms(u32 ms)
{
rtw_mdelay_os(ms);
}
void ODM_delay_us(u4Byte us)
void ODM_delay_us(u32 us)
{
rtw_udelay_os(us);
}
void ODM_sleep_ms(u4Byte ms)
void ODM_sleep_ms(u32 ms)
{
rtw_msleep_os(ms);
}
void ODM_sleep_us(u4Byte us)
void ODM_sleep_us(u32 us)
{
rtw_usleep_os(us);
}
void ODM_SetTimer(struct odm_dm_struct *pDM_Odm, struct timer_list *pTimer, u4Byte msDelay)
void ODM_SetTimer(struct odm_dm_struct *pDM_Odm, struct timer_list *pTimer, u32 msDelay)
{
_set_timer(pTimer, msDelay); /* ms */
}
@ -195,9 +195,9 @@ void ODM_ReleaseTimer(struct odm_dm_struct *pDM_Odm, struct timer_list *pTimer)
}
/* ODM FW relative API. */
u4Byte ODM_FillH2CCmd(pu1Byte pH2CBuffer, u4Byte H2CBufferLen, u4Byte CmdNum,
pu4Byte pElementID, pu4Byte pCmdLen,
pu1Byte *pCmbBuffer, pu1Byte CmdStartSeq)
u32 ODM_FillH2CCmd(u8 *pH2CBuffer, u32 H2CBufferLen, u32 CmdNum,
u32 *pElementID, u32 *pCmdLen,
u8 **pCmbBuffer, u8 *CmdStartSeq)
{
return true;
}

26
hal/rtl8188e_hal_init.c
View file

@ -163,7 +163,7 @@ efuse_phymap_to_logical(u8 *phymap, u16 _offset, u16 _size_byte, u8 *pbuf)
rtemp8 = *(phymap+eFuse_Addr);
eFuse_Addr++;
efuse_utilized++;
eFuseWord[offset][i] |= (((u2Byte)rtemp8 << 8) & 0xff00);
eFuseWord[offset][i] |= (((u16)rtemp8 << 8) & 0xff00);
if (eFuse_Addr >= EFUSE_REAL_CONTENT_LEN_88E)
break;
@ -1044,7 +1044,7 @@ Hal_EfuseReadEFuse88E(
ReadEFuseByte(Adapter, eFuse_Addr, rtemp8, bPseudoTest);
eFuse_Addr++;
efuse_utilized++;
eFuseWord[offset][i] |= (((u2Byte)*rtemp8 << 8) & 0xff00);
eFuseWord[offset][i] |= (((u16)*rtemp8 << 8) & 0xff00);
if (eFuse_Addr >= EFUSE_REAL_CONTENT_LEN_88E)
break;
}
@ -1160,7 +1160,7 @@ static void rtl8188e_ReadEFuse(struct adapter *Adapter, u8 efuseType,
}
/* Do not support BT */
static void Hal_EFUSEGetEfuseDefinition88E(struct adapter *pAdapter, u1Byte efuseType, u1Byte type, void *pOut)
static void Hal_EFUSEGetEfuseDefinition88E(struct adapter *pAdapter, u8 efuseType, u8 type, void *pOut)
{
switch (type) {
case TYPE_EFUSE_MAX_SECTION:
@ -1228,43 +1228,43 @@ static void Hal_EFUSEGetEfuseDefinition_Pseudo88E(struct adapter *pAdapter, u8 e
case TYPE_EFUSE_MAX_SECTION:
{
u8 *pMax_section;
pMax_section = (pu1Byte)pOut;
pMax_section = (u8 *)pOut;
*pMax_section = EFUSE_MAX_SECTION_88E;
}
break;
case TYPE_EFUSE_REAL_CONTENT_LEN:
{
u16 *pu2Tmp;
pu2Tmp = (pu2Byte)pOut;
pu2Tmp = (u16 *)pOut;
*pu2Tmp = EFUSE_REAL_CONTENT_LEN_88E;
}
break;
case TYPE_EFUSE_CONTENT_LEN_BANK:
{
u16 *pu2Tmp;
pu2Tmp = (pu2Byte)pOut;
pu2Tmp = (u16 *)pOut;
*pu2Tmp = EFUSE_REAL_CONTENT_LEN_88E;
}
break;
case TYPE_AVAILABLE_EFUSE_BYTES_BANK:
{
u16 *pu2Tmp;
pu2Tmp = (pu2Byte)pOut;
*pu2Tmp = (u2Byte)(EFUSE_REAL_CONTENT_LEN_88E-EFUSE_OOB_PROTECT_BYTES_88E);
pu2Tmp = (u16 *)pOut;
*pu2Tmp = (u16)(EFUSE_REAL_CONTENT_LEN_88E-EFUSE_OOB_PROTECT_BYTES_88E);
}
break;
case TYPE_AVAILABLE_EFUSE_BYTES_TOTAL:
{
u16 *pu2Tmp;
pu2Tmp = (pu2Byte)pOut;
*pu2Tmp = (u2Byte)(EFUSE_REAL_CONTENT_LEN_88E-EFUSE_OOB_PROTECT_BYTES_88E);
pu2Tmp = (u16 *)pOut;
*pu2Tmp = (u16)(EFUSE_REAL_CONTENT_LEN_88E-EFUSE_OOB_PROTECT_BYTES_88E);
}
break;
case TYPE_EFUSE_MAP_LEN:
{
u16 *pu2Tmp;
pu2Tmp = (pu2Byte)pOut;
*pu2Tmp = (u2Byte)EFUSE_MAP_LEN_88E;
pu2Tmp = (u16 *)pOut;
*pu2Tmp = (u16)EFUSE_MAP_LEN_88E;
}
break;
case TYPE_EFUSE_PROTECT_BYTES_BANK:
@ -2600,7 +2600,7 @@ void Hal_ReadAntennaDiversity88E(struct adapter *pAdapter, u8 *PROMContent, bool
void Hal_ReadThermalMeter_88E(struct adapter *Adapter, u8 *PROMContent, bool AutoloadFail)
{
struct hal_data_8188e *pHalData = GET_HAL_DATA(Adapter);
u1Byte tempval;
u8 tempval;
/* ThermalMeter from EEPROM */
if (!AutoloadFail)

10
hal/rtl8188e_mp.c
View file

@ -110,14 +110,14 @@ void Hal_mpt_SwitchRfSetting(struct adapter *pAdapter)
{
/* struct hal_data_8188e *pHalData = GET_HAL_DATA(pAdapter); */
struct mp_priv *pmp = &pAdapter->mppriv;
u1Byte ChannelToSw = pmp->channel;
ULONG ulRateIdx = pmp->rateidx;
ULONG ulbandwidth = pmp->bandwidth;
u8 ChannelToSw = pmp->channel;
u32 ulRateIdx = pmp->rateidx;
u32 ulbandwidth = pmp->bandwidth;
struct hal_data_8188e *pHalData = GET_HAL_DATA(pAdapter);
/* <20120525, Kordan> Dynamic mechanism for APK, asked by Dennis. */
pmp->MptCtx.backup0x52_RF_A = (u1Byte)PHY_QueryRFReg(pAdapter, RF_PATH_A, RF_0x52, 0x000F0);
pmp->MptCtx.backup0x52_RF_B = (u1Byte)PHY_QueryRFReg(pAdapter, RF_PATH_B, RF_0x52, 0x000F0);
pmp->MptCtx.backup0x52_RF_A = (u8)PHY_QueryRFReg(pAdapter, RF_PATH_A, RF_0x52, 0x000F0);
pmp->MptCtx.backup0x52_RF_B = (u8)PHY_QueryRFReg(pAdapter, RF_PATH_B, RF_0x52, 0x000F0);
PHY_SetRFReg(pAdapter, RF_PATH_A, RF_0x52, 0x000F0, 0xD);
PHY_SetRFReg(pAdapter, RF_PATH_B, RF_0x52, 0x000F0, 0xD);

44
hal/rtl8188e_phycfg.c
View file

@ -55,10 +55,10 @@
* OverView: Get shifted position of the BitMask
*
* Input:
* u4Byte BitMask,
* u32 BitMask,
*
* Output: none
* Return: u4Byte Return the shift bit bit position of the mask
* Return: u32 Return the shift bit bit position of the mask
*/
static u32 phy_CalculateBitShift(u32 BitMask)
{
@ -78,11 +78,11 @@ static u32 phy_CalculateBitShift(u32 BitMask)
*
* Input:
* struct adapter *Adapter,
* u4Byte RegAddr, The target address to be readback
* u4Byte BitMask The target bit position in the target address
* u32 RegAddr, The target address to be readback
* u32 BitMask The target bit position in the target address
* to be readback
* Output: None
* Return: u4Byte Data The readback register value
* Return: u32 Data The readback register value
* Note: This function is equal to "GetRegSetting" in PHY programming guide
*/
u32
@ -109,10 +109,10 @@ rtl8188e_PHY_QueryBBReg(
*
* Input:
* struct adapter *Adapter,
* u4Byte RegAddr, The target address to be modified
* u4Byte BitMask The target bit position in the target address
* u32 RegAddr, The target address to be modified
* u32 BitMask The target bit position in the target address
* to be modified
* u4Byte Data The new register value in the target bit position
* u32 Data The new register value in the target bit position
* of the target address
*
* Output: None
@ -146,10 +146,10 @@ void rtl8188e_PHY_SetBBReg(struct adapter *Adapter, u32 RegAddr, u32 BitMask, u3
* Input:
* struct adapter *Adapter,
* enum rf_radio_path eRFPath, Radio path of A/B/C/D
* u4Byte Offset, The target address to be read
* u32 Offset, The target address to be read
*
* Output: None
* Return: u4Byte reback value
* Return: u32 reback value
* Note: Threre are three types of serial operations:
* 1. Software serial write
* 2. Hardware LSSI-Low Speed Serial Interface
@ -220,8 +220,8 @@ phy_RFSerialRead(
* Input:
* struct adapter *Adapter,
* enum rf_radio_path eRFPath, Radio path of A/B/C/D
* u4Byte Offset, The target address to be read
* u4Byte Data The new register Data in the target bit position
* u32 Offset, The target address to be read
* u32 Data The new register Data in the target bit position
* of the target to be read
*
* Output: None
@ -297,12 +297,12 @@ phy_RFSerialWrite(
* Input:
* struct adapter *Adapter,
* enum rf_radio_path eRFPath, Radio path of A/B/C/D
* u4Byte RegAddr, The target address to be read
* u4Byte BitMask The target bit position in the target address
* u32 RegAddr, The target address to be read
* u32 BitMask The target bit position in the target address
* to be read
*
* Output: None
* Return: u4Byte Readback value
* Return: u32 Readback value
* Note: This function is equal to "GetRFRegSetting" in PHY programming guide
*/
u32 rtl8188e_PHY_QueryRFReg(struct adapter *Adapter, enum rf_radio_path eRFPath,
@ -325,10 +325,10 @@ u32 rtl8188e_PHY_QueryRFReg(struct adapter *Adapter, enum rf_radio_path eRFPath,
* Input:
* struct adapter *Adapter,
* enum rf_radio_path eRFPath, Radio path of A/B/C/D
* u4Byte RegAddr, The target address to be modified
* u4Byte BitMask The target bit position in the target address
* u32 RegAddr, The target address to be modified
* u32 BitMask The target bit position in the target address
* to be modified
* u4Byte Data The new register Data in the target bit position
* u32 Data The new register Data in the target bit position
* of the target address
*
* Output: None
@ -367,7 +367,7 @@ rtl8188e_PHY_SetRFReg(
* Read/Write
*
* Input: struct adapter *Adapter
* ps1Byte pFileName
* ps8 pFileName
*
* Output: NONE
*
@ -542,7 +542,7 @@ phy_InitBBRFRegisterDefinition(
* Read/Write
*
* Input: struct adapter *Adapter
* ps1Byte pFileName
* ps8 pFileName
*
* Output: NONE
*
@ -753,7 +753,7 @@ int PHY_RFConfig8188E(struct adapter *Adapter)
* Overview: This function read RF parameters from general file format, and do RF 3-wire
*
* Input: struct adapter *Adapter
* ps1Byte pFileName
* ps8 pFileName
* enum rf_radio_path eRFPath
*
* Output: NONE
@ -1008,7 +1008,7 @@ static void phy_PowerIndexCheck88E(struct adapter *Adapter, u8 channel, u8 *cckP
* We must consider RF path later!!!!!!!
*
* Input: struct adapter *Adapter
* u1Byte channel
* u8 channel
*
* Output: NONE
*

12
hal/rtl8188e_rf6052.c
View file

@ -79,7 +79,7 @@ static struct rf_shadow RF_Shadow[RF6052_MAX_PATH][RF6052_MAX_REG];
*
* Overview: For RL6052, we must change some RF settign for 1T or 2T.
*
* Input: u2Byte DataRate 0x80-8f, 0x90-9f
* Input: u16 DataRate 0x80-8f, 0x90-9f
*
* Output: NONE
*
@ -281,10 +281,10 @@ static void get_rx_power_val_by_reg(struct adapter *Adapter, u8 Channel,
{
struct hal_data_8188e *pHalData = GET_HAL_DATA(Adapter);
struct dm_priv *pdmpriv = &pHalData->dmpriv;
u1Byte i, chnlGroup = 0, pwr_diff_limit[4], customer_pwr_limit;
s1Byte pwr_diff = 0;
u4Byte writeVal, customer_limit, rf;
u1Byte Regulatory = pHalData->EEPROMRegulatory;
u8 i, chnlGroup = 0, pwr_diff_limit[4], customer_pwr_limit;
s8 pwr_diff = 0;
u32 writeVal, customer_limit, rf;
u8 Regulatory = pHalData->EEPROMRegulatory;
/* Index 0 & 1= legacy OFDM, 2-5=HT_MCS rate */
@ -341,7 +341,7 @@ static void get_rx_power_val_by_reg(struct adapter *Adapter, u8 Channel,
pwr_diff = customer_pwr_limit - pwr_diff;
for (i = 0; i < 4; i++) {
pwr_diff_limit[i] = (u1Byte)((pHalData->MCSTxPowerLevelOriginalOffset[chnlGroup][index+(rf ? 8 : 0)]&(0x7f<<(i*8)))>>(i*8));
pwr_diff_limit[i] = (u8)((pHalData->MCSTxPowerLevelOriginalOffset[chnlGroup][index+(rf ? 8 : 0)]&(0x7f<<(i*8)))>>(i*8));
if (pwr_diff_limit[i] > pwr_diff)
pwr_diff_limit[i] = pwr_diff;

4
hal/usb_halinit.c
View file

@ -2472,7 +2472,7 @@ GetHalDefVar8188EUsb(
break;
case HW_DEF_ODM_DBG_FLAG:
{
u8Byte DebugComponents = *((u32 *)pValue);
u64 DebugComponents = *((u32 *)pValue);
struct odm_dm_struct *dm_ocm = &(haldata->odmpriv);
pr_info("dm_ocm->DebugComponents = 0x%llx\n", dm_ocm->DebugComponents);
}
@ -2548,7 +2548,7 @@ static u8 SetHalDefVar8188EUsb(struct adapter *Adapter, enum hal_def_variable eV
break;
case HW_DEF_ODM_DBG_FLAG:
{
u8Byte DebugComponents = *((u8Byte *)pValue);
u64 DebugComponents = *((u64 *)pValue);
struct odm_dm_struct *dm_ocm = &(haldata->odmpriv);
dm_ocm->DebugComponents = DebugComponents;
}

24
include/Hal8188ERateAdaptive.h
View file

@ -52,24 +52,24 @@ void ODM_RASupport_Init(struct odm_dm_struct *dm_odm);
int ODM_RAInfo_Init_all(struct odm_dm_struct *dm_odm);
int ODM_RAInfo_Init(struct odm_dm_struct *dm_odm, u1Byte MacID);
int ODM_RAInfo_Init(struct odm_dm_struct *dm_odm, u8 MacID);
u1Byte ODM_RA_GetShortGI_8188E(struct odm_dm_struct *dm_odm, u1Byte MacID);
u8 ODM_RA_GetShortGI_8188E(struct odm_dm_struct *dm_odm, u8 MacID);
u1Byte ODM_RA_GetDecisionRate_8188E(struct odm_dm_struct *dm_odm, u1Byte MacID);
u8 ODM_RA_GetDecisionRate_8188E(struct odm_dm_struct *dm_odm, u8 MacID);
u1Byte ODM_RA_GetHwPwrStatus_8188E(struct odm_dm_struct *dm_odm, u1Byte MacID);
void ODM_RA_UpdateRateInfo_8188E(struct odm_dm_struct *dm_odm, u1Byte MacID,
u1Byte RateID, u4Byte RateMask,
u1Byte SGIEnable);
u8 ODM_RA_GetHwPwrStatus_8188E(struct odm_dm_struct *dm_odm, u8 MacID);
void ODM_RA_UpdateRateInfo_8188E(struct odm_dm_struct *dm_odm, u8 MacID,
u8 RateID, u32 RateMask,
u8 SGIEnable);
void ODM_RA_SetRSSI_8188E(struct odm_dm_struct *dm_odm, u1Byte macid,
u1Byte rssi);
void ODM_RA_SetRSSI_8188E(struct odm_dm_struct *dm_odm, u8 macid,
u8 rssi);
void ODM_RA_TxRPT2Handle_8188E(struct odm_dm_struct *dm_odm,
u1Byte *txrpt_buf, u2Byte txrpt_len,
u4Byte validentry0, u4Byte validentry1);
u8 *txrpt_buf, u16 txrpt_len,
u32 validentry0, u32 validentry1);
void ODM_RA_Set_TxRPT_Time(struct odm_dm_struct *dm_odm, u2Byte minRptTime);
void ODM_RA_Set_TxRPT_Time(struct odm_dm_struct *dm_odm, u16 minRptTime);
#endif

2
include/HalHWImg8188E_BB.h
View file

@ -21,7 +21,7 @@
#ifndef __INC_BB_8188E_HW_IMG_H
#define __INC_BB_8188E_HW_IMG_H
/* static bool CheckCondition(const u4Byte Condition, const u4Byte Hex); */
/* static bool CheckCondition(const u32 Condition, const u32 Hex); */
/******************************************************************************
* AGC_TAB_1T.TXT

2
include/HalPhyRf.h
View file

@ -25,6 +25,6 @@
void ODM_ResetIQKResult(struct odm_dm_struct *pDM_Odm);
u1Byte ODM_GetRightChnlPlaceforIQK(u1Byte chnl);
u8 ODM_GetRightChnlPlaceforIQK(u8 chnl);
#endif /* #ifndef __HAL_PHY_RF_H__ */

20
include/HalPhyRf_8188e.h
View file

@ -28,9 +28,9 @@
void ODM_TxPwrTrackAdjust88E(struct odm_dm_struct *pDM_Odm,
u1Byte Type, /* 0 = OFDM, 1 = CCK */
pu1Byte pDirection,/* 1 = +(incr) 2 = -(decr) */
pu4Byte pOutWriteVal); /* Tx tracking CCK/OFDM BB
u8 Type, /* 0 = OFDM, 1 = CCK */
u8 *pDirection,/* 1 = +(incr) 2 = -(decr) */
u32 *pOutWriteVal); /* Tx tracking CCK/OFDM BB
* swing index adjust */
@ -45,18 +45,18 @@ void PHY_IQCalibrate_8188E(struct adapter *Adapter, bool ReCovery);
void PHY_LCCalibrate_8188E(struct adapter *pAdapter);
/* AP calibrate */
void PHY_APCalibrate_8188E(struct adapter *pAdapter, s1Byte delta);
void PHY_APCalibrate_8188E(struct adapter *pAdapter, s8 delta);
void PHY_DigitalPredistortion_8188E(struct adapter * pAdapter);
void PHY_DigitalPredistortion_8188E(struct adapter *pAdapter);
void _PHY_SaveADDARegisters(struct adapter *pAdapter, pu4Byte ADDAReg,
pu4Byte ADDABackup, u4Byte RegisterNum);
void _PHY_SaveADDARegisters(struct adapter *pAdapter, u32 *ADDAReg,
u32 *ADDABackup, u32 RegisterNum);
void _PHY_PathADDAOn(struct adapter *pAdapter, pu4Byte ADDAReg,
void _PHY_PathADDAOn(struct adapter *pAdapter, u32 *ADDAReg,
bool isPathAOn, bool is2T);
void _PHY_MACSettingCalibration(struct adapter *pAdapter, pu4Byte MACReg,
pu4Byte MACBackup);
void _PHY_MACSettingCalibration(struct adapter *pAdapter, u32 *MACReg,
u32 *MACBackup);
void _PHY_PathAStandBy(struct adapter *pAdapter);

5
include/basic_types.h
View file

@ -26,11 +26,6 @@
#include <linux/types.h>
#define NDIS_OID uint
#define UCHAR u8
#define USHORT u16
#define UINT u32
#define ULONG u32
typedef void (*proc_t)(void *);
#define FIELD_OFFSET(s, field) ((ssize_t)&((s *)(0))->field)

4
include/drv_types.h
View file

@ -158,9 +158,9 @@ struct registry_priv {
};
/* For registry parameters */
#define RGTRY_OFT(field) ((ULONG)FIELD_OFFSET(struct registry_priv, field))
#define RGTRY_OFT(field) ((u32)FIELD_OFFSET(struct registry_priv, field))
#define RGTRY_SZ(field) sizeof(((struct registry_priv *)0)->field)
#define BSSID_OFT(field) ((ULONG)FIELD_OFFSET(struct wlan_bssid_ex, field))
#define BSSID_OFT(field) ((u32)FIELD_OFFSET(struct wlan_bssid_ex, field))
#define BSSID_SZ(field) sizeof(((struct wlan_bssid_ex *)0)->field)
#define MAX_CONTINUAL_URB_ERR 4

14
include/ethernet.h
View file

@ -29,14 +29,14 @@
#define MAXIMUM_ETHERNET_PACKET_SIZE 1514 /* Max Ethernet Packet Size */
/* Is Multicast Address? */
#define RT_ETH_IS_MULTICAST(_addr) ((((UCHAR *)(_addr))[0]&0x01) != 0)
#define RT_ETH_IS_MULTICAST(_addr) ((((u8 *)(_addr))[0]&0x01) != 0)
#define RT_ETH_IS_BROADCAST(_addr) ( \
((UCHAR *)(_addr))[0] == 0xff && \
((UCHAR *)(_addr))[1] == 0xff && \
((UCHAR *)(_addr))[2] == 0xff && \
((UCHAR *)(_addr))[3] == 0xff && \
((UCHAR *)(_addr))[4] == 0xff && \
((UCHAR *)(_addr))[5] == 0xff) /* Is Broadcast Address? */
((u8 *)(_addr))[0] == 0xff && \
((u8 *)(_addr))[1] == 0xff && \
((u8 *)(_addr))[2] == 0xff && \
((u8 *)(_addr))[3] == 0xff && \
((u8 *)(_addr))[4] == 0xff && \
((u8 *)(_addr))[5] == 0xff) /* Is Broadcast Address? */
#endif /* #ifndef __INC_ETHERNET_H */

581
include/odm.h
View file

@ -114,102 +114,102 @@
/* We need to remove to other position??? */
/* */
struct rtl8192cd_priv {
u1Byte temp;
u8 temp;
};
struct rtw_dig {
u1Byte Dig_Enable_Flag;
u1Byte Dig_Ext_Port_Stage;
u8 Dig_Enable_Flag;
u8 Dig_Ext_Port_Stage;
int RssiLowThresh;
int RssiHighThresh;
u4Byte FALowThresh;
u4Byte FAHighThresh;
u32 FALowThresh;
u32 FAHighThresh;
u1Byte CurSTAConnectState;
u1Byte PreSTAConnectState;
u1Byte CurMultiSTAConnectState;
u8 CurSTAConnectState;
u8 PreSTAConnectState;
u8 CurMultiSTAConnectState;
u1Byte PreIGValue;
u1Byte CurIGValue;
u1Byte BackupIGValue;
u8 PreIGValue;
u8 CurIGValue;
u8 BackupIGValue;
s1Byte BackoffVal;
s1Byte BackoffVal_range_max;
s1Byte BackoffVal_range_min;
u1Byte rx_gain_range_max;
u1Byte rx_gain_range_min;
u1Byte Rssi_val_min;
s8 BackoffVal;
s8 BackoffVal_range_max;
s8 BackoffVal_range_min;
u8 rx_gain_range_max;
u8 rx_gain_range_min;
u8 Rssi_val_min;
u1Byte PreCCK_CCAThres;
u1Byte CurCCK_CCAThres;
u1Byte PreCCKPDState;
u1Byte CurCCKPDState;
u8 PreCCK_CCAThres;
u8 CurCCK_CCAThres;
u8 PreCCKPDState;
u8 CurCCKPDState;
u1Byte LargeFAHit;
u1Byte ForbiddenIGI;
u4Byte Recover_cnt;
u8 LargeFAHit;
u8 ForbiddenIGI;
u32 Recover_cnt;
u1Byte DIG_Dynamic_MIN_0;
u1Byte DIG_Dynamic_MIN_1;
u8 DIG_Dynamic_MIN_0;
u8 DIG_Dynamic_MIN_1;
bool bMediaConnect_0;
bool bMediaConnect_1;
u4Byte AntDiv_RSSI_max;
u4Byte RSSI_max;
u32 AntDiv_RSSI_max;
u32 RSSI_max;
};
struct rtl_ps {
u1Byte PreCCAState;
u1Byte CurCCAState;
u8 PreCCAState;
u8 CurCCAState;
u1Byte PreRFState;
u1Byte CurRFState;
u8 PreRFState;
u8 CurRFState;
int Rssi_val_min;
u1Byte initialize;
u4Byte Reg874,RegC70,Reg85C,RegA74;
u8 initialize;
u32 Reg874,RegC70,Reg85C,RegA74;
};
struct false_alarm_stats {
u4Byte Cnt_Parity_Fail;
u4Byte Cnt_Rate_Illegal;
u4Byte Cnt_Crc8_fail;
u4Byte Cnt_Mcs_fail;
u4Byte Cnt_Ofdm_fail;
u4Byte Cnt_Cck_fail;
u4Byte Cnt_all;
u4Byte Cnt_Fast_Fsync;
u4Byte Cnt_SB_Search_fail;
u4Byte Cnt_OFDM_CCA;
u4Byte Cnt_CCK_CCA;
u4Byte Cnt_CCA_all;
u4Byte Cnt_BW_USC; /* Gary */
u4Byte Cnt_BW_LSC; /* Gary */
u32 Cnt_Parity_Fail;
u32 Cnt_Rate_Illegal;
u32 Cnt_Crc8_fail;
u32 Cnt_Mcs_fail;
u32 Cnt_Ofdm_fail;
u32 Cnt_Cck_fail;
u32 Cnt_all;
u32 Cnt_Fast_Fsync;
u32 Cnt_SB_Search_fail;
u32 Cnt_OFDM_CCA;
u32 Cnt_CCK_CCA;
u32 Cnt_CCA_all;
u32 Cnt_BW_USC; /* Gary */
u32 Cnt_BW_LSC; /* Gary */
};
struct dyn_primary_cca {
u1Byte PriCCA_flag;
u1Byte intf_flag;
u1Byte intf_type;
u1Byte DupRTS_flag;
u1Byte Monitor_flag;
u8 PriCCA_flag;
u8 intf_flag;
u8 intf_type;
u8 DupRTS_flag;
u8 Monitor_flag;
};
struct rx_hpc {
u1Byte RXHP_flag;
u1Byte PSD_func_trigger;
u1Byte PSD_bitmap_RXHP[80];
u1Byte Pre_IGI;
u1Byte Cur_IGI;
u1Byte Pre_pw_th;
u1Byte Cur_pw_th;
u8 RXHP_flag;
u8 PSD_func_trigger;
u8 PSD_bitmap_RXHP[80];
u8 Pre_IGI;
u8 Cur_IGI;
u8 Pre_pw_th;
u8 Cur_pw_th;
bool First_time_enter;
bool RXHP_enable;
u1Byte TP_Mode;
u8 TP_Mode;
struct timer_list PSDTimer;
};
@ -229,60 +229,60 @@ struct rx_hpc {
#define TRAFFIC_HIGH 1
struct sw_ant_switch {
u1Byte try_flag;
s4Byte PreRSSI;
u1Byte CurAntenna;
u1Byte PreAntenna;
u1Byte RSSI_Trying;
u1Byte TestMode;
u1Byte bTriggerAntennaSwitch;
u1Byte SelectAntennaMap;
u1Byte RSSI_target;
u8 try_flag;
s32 PreRSSI;
u8 CurAntenna;
u8 PreAntenna;
u8 RSSI_Trying;
u8 TestMode;
u8 bTriggerAntennaSwitch;
u8 SelectAntennaMap;
u8 RSSI_target;
/* Before link Antenna Switch check */
u1Byte SWAS_NoLink_State;
u4Byte SWAS_NoLink_BK_Reg860;
u8 SWAS_NoLink_State;
u32 SWAS_NoLink_BK_Reg860;
bool ANTA_ON; /* To indicate Ant A is or not */
bool ANTB_ON; /* To indicate Ant B is on or not */
s4Byte RSSI_sum_A;
s4Byte RSSI_sum_B;
s4Byte RSSI_cnt_A;
s4Byte RSSI_cnt_B;
s32 RSSI_sum_A;
s32 RSSI_sum_B;
s32 RSSI_cnt_A;
s32 RSSI_cnt_B;
u8Byte lastTxOkCnt;
u8Byte lastRxOkCnt;
u8Byte TXByteCnt_A;
u8Byte TXByteCnt_B;
u8Byte RXByteCnt_A;
u8Byte RXByteCnt_B;
u1Byte TrafficLoad;
u64 lastTxOkCnt;
u64 lastRxOkCnt;
u64 TXByteCnt_A;
u64 TXByteCnt_B;
u64 RXByteCnt_A;
u64 RXByteCnt_B;
u8 TrafficLoad;
struct timer_list SwAntennaSwitchTimer;
/* Hybrid Antenna Diversity */
u4Byte CCK_Ant1_Cnt[ASSOCIATE_ENTRY_NUM];
u4Byte CCK_Ant2_Cnt[ASSOCIATE_ENTRY_NUM];
u4Byte OFDM_Ant1_Cnt[ASSOCIATE_ENTRY_NUM];
u4Byte OFDM_Ant2_Cnt[ASSOCIATE_ENTRY_NUM];
u4Byte RSSI_Ant1_Sum[ASSOCIATE_ENTRY_NUM];
u4Byte RSSI_Ant2_Sum[ASSOCIATE_ENTRY_NUM];
u1Byte TxAnt[ASSOCIATE_ENTRY_NUM];
u1Byte TargetSTA;
u1Byte antsel;
u1Byte RxIdleAnt;
u32 CCK_Ant1_Cnt[ASSOCIATE_ENTRY_NUM];
u32 CCK_Ant2_Cnt[ASSOCIATE_ENTRY_NUM];
u32 OFDM_Ant1_Cnt[ASSOCIATE_ENTRY_NUM];
u32 OFDM_Ant2_Cnt[ASSOCIATE_ENTRY_NUM];
u32 RSSI_Ant1_Sum[ASSOCIATE_ENTRY_NUM];
u32 RSSI_Ant2_Sum[ASSOCIATE_ENTRY_NUM];
u8 TxAnt[ASSOCIATE_ENTRY_NUM];
u8 TargetSTA;
u8 antsel;
u8 RxIdleAnt;
};
struct edca_turbo {
bool bCurrentTurboEDCA;
bool bIsCurRDLState;
u4Byte prv_traffic_idx; /* edca turbo */
u32 prv_traffic_idx; /* edca turbo */
};
struct odm_rate_adapt {
u1Byte Type; /* DM_Type_ByFW/DM_Type_ByDriver */
u1Byte HighRSSIThresh; /* if RSSI > HighRSSIThresh => RATRState is DM_RATR_STA_HIGH */
u1Byte LowRSSIThresh; /* if RSSI <= LowRSSIThresh => RATRState is DM_RATR_STA_LOW */
u1Byte RATRState; /* Current RSSI level, DM_RATR_STA_HIGH/DM_RATR_STA_MIDDLE/DM_RATR_STA_LOW */
u4Byte LastRATR; /* RATR Register Content */
u8 Type; /* DM_Type_ByFW/DM_Type_ByDriver */
u8 HighRSSIThresh; /* if RSSI > HighRSSIThresh => RATRState is DM_RATR_STA_HIGH */
u8 LowRSSIThresh; /* if RSSI <= LowRSSIThresh => RATRState is DM_RATR_STA_LOW */
u8 RATRState; /* Current RSSI level, DM_RATR_STA_HIGH/DM_RATR_STA_MIDDLE/DM_RATR_STA_LOW */
u32 LastRATR; /* RATR Register Content */
};
@ -307,27 +307,27 @@ struct odm_rate_adapt {
#define MAX_PATH_NUM_92CS 2
struct odm_phy_status_info {
u1Byte RxPWDBAll;
u1Byte SignalQuality; /* in 0-100 index. */
u1Byte RxMIMOSignalQuality[MAX_PATH_NUM_92CS]; /* EVM */
u1Byte RxMIMOSignalStrength[MAX_PATH_NUM_92CS];/* in 0~100 index */
s1Byte RxPower; /* in dBm Translate from PWdB */
s1Byte RecvSignalPower;/* Real power in dBm for this packet, no beautification and aggregation. Keep this raw info to be used for the other procedures. */
u1Byte BTRxRSSIPercentage;
u1Byte SignalStrength; /* in 0-100 index. */
u1Byte RxPwr[MAX_PATH_NUM_92CS];/* per-path's pwdb */
u1Byte RxSNR[MAX_PATH_NUM_92CS];/* per-path's SNR */
u8 RxPWDBAll;
u8 SignalQuality; /* in 0-100 index. */
u8 RxMIMOSignalQuality[MAX_PATH_NUM_92CS]; /* EVM */
u8 RxMIMOSignalStrength[MAX_PATH_NUM_92CS];/* in 0~100 index */
s8 RxPower; /* in dBm Translate from PWdB */
s8 RecvSignalPower;/* Real power in dBm for this packet, no beautification and aggregation. Keep this raw info to be used for the other procedures. */
u8 BTRxRSSIPercentage;
u8 SignalStrength; /* in 0-100 index. */
u8 RxPwr[MAX_PATH_NUM_92CS];/* per-path's pwdb */
u8 RxSNR[MAX_PATH_NUM_92CS];/* per-path's SNR */
};
struct odm_phy_dbg_info {
/* ODM Write,debug info */
s1Byte RxSNRdB[MAX_PATH_NUM_92CS];
u8Byte NumQryPhyStatus;
u8Byte NumQryPhyStatusCCK;
u8Byte NumQryPhyStatusOFDM;
s8 RxSNRdB[MAX_PATH_NUM_92CS];
u64 NumQryPhyStatus;
u64 NumQryPhyStatusCCK;
u64 NumQryPhyStatusOFDM;
/* Others */
s4Byte RxEVM[MAX_PATH_NUM_92CS];
s32 RxEVM[MAX_PATH_NUM_92CS];
};
@ -340,7 +340,7 @@ struct odm_per_pkt_info {
};
struct odm_mac_status_info {
u1Byte test;
u8 test;
};
@ -367,14 +367,14 @@ enum odm_ability {
struct odm_sta_info {
/* Driver Write */
bool bUsed; /* record the sta status link or not? */
u1Byte IOTPeer; /* Enum value. HT_IOT_PEER_E */
u8 IOTPeer; /* Enum value. HT_IOT_PEER_E */
/* ODM Write */
/* 1 PHY_STATUS_INFO */
u1Byte RSSI_Path[4]; /* */
u1Byte RSSI_Ave;
u1Byte RXEVM[4];
u1Byte RXSNR[4];
u8 RSSI_Path[4]; /* */
u8 RSSI_Ave;
u8 RXEVM[4];
u8 RXSNR[4];
/* */
/* Please use compile flag to disable the struictrue for other IC except 88E. */
@ -445,11 +445,11 @@ enum odm_common_info_def {
ODM_CMNINFO_WIFI_DISPLAY,
ODM_CMNINFO_LINK,
ODM_CMNINFO_RSSI_MIN,
ODM_CMNINFO_DBG_COMP, /* u8Byte */
ODM_CMNINFO_DBG_LEVEL, /* u4Byte */
ODM_CMNINFO_RA_THRESHOLD_HIGH, /* u1Byte */
ODM_CMNINFO_RA_THRESHOLD_LOW, /* u1Byte */
ODM_CMNINFO_RF_ANTENNA_TYPE, /* u1Byte */
ODM_CMNINFO_DBG_COMP, /* u64 */
ODM_CMNINFO_DBG_LEVEL, /* u32 */
ODM_CMNINFO_RA_THRESHOLD_HIGH, /* u8 */
ODM_CMNINFO_RA_THRESHOLD_LOW, /* u8 */
ODM_CMNINFO_RF_ANTENNA_TYPE, /* u8 */
ODM_CMNINFO_BT_DISABLED,
ODM_CMNINFO_BT_OPERATION,
ODM_CMNINFO_BT_DIG,
@ -659,136 +659,136 @@ enum odm_cca_path {
};
struct odm_ra_info {
u1Byte RateID;
u4Byte RateMask;
u4Byte RAUseRate;
u1Byte RateSGI;
u1Byte RssiStaRA;
u1Byte PreRssiStaRA;
u1Byte SGIEnable;
u1Byte DecisionRate;
u1Byte PreRate;
u1Byte HighestRate;
u1Byte LowestRate;
u4Byte NscUp;
u4Byte NscDown;
u2Byte RTY[5];
u4Byte TOTAL;
u2Byte DROP;
u1Byte Active;
u2Byte RptTime;
u1Byte RAWaitingCounter;
u1Byte RAPendingCounter;
u1Byte PTActive; /* on or off */
u1Byte PTTryState; /* 0 trying state, 1 for decision state */
u1Byte PTStage; /* 0~6 */
u1Byte PTStopCount; /* Stop PT counter */
u1Byte PTPreRate; /* if rate change do PT */
u1Byte PTPreRssi; /* if RSSI change 5% do PT */
u1Byte PTModeSS; /* decide whitch rate should do PT */
u1Byte RAstage; /* StageRA, decide how many times RA will be done between PT */
u1Byte PTSmoothFactor;
u8 RateID;
u32 RateMask;
u32 RAUseRate;
u8 RateSGI;
u8 RssiStaRA;
u8 PreRssiStaRA;
u8 SGIEnable;
u8 DecisionRate;
u8 PreRate;
u8 HighestRate;
u8 LowestRate;
u32 NscUp;
u32 NscDown;
u16 RTY[5];
u32 TOTAL;
u16 DROP;
u8 Active;
u16 RptTime;
u8 RAWaitingCounter;
u8 RAPendingCounter;
u8 PTActive; /* on or off */
u8 PTTryState; /* 0 trying state, 1 for decision state */
u8 PTStage; /* 0~6 */
u8 PTStopCount; /* Stop PT counter */
u8 PTPreRate; /* if rate change do PT */
u8 PTPreRssi; /* if RSSI change 5% do PT */
u8 PTModeSS; /* decide whitch rate should do PT */
u8 RAstage; /* StageRA, decide how many times RA will be done between PT */
u8 PTSmoothFactor;
};
struct ijk_matrix_regs_set {
bool bIQKDone;
s4Byte Value[1][IQK_Matrix_REG_NUM];
s32 Value[1][IQK_Matrix_REG_NUM];
};
struct odm_rf_cal {
/* for tx power tracking */
u4Byte RegA24; /* for TempCCK */
s4Byte RegE94;
s4Byte RegE9C;
s4Byte RegEB4;
s4Byte RegEBC;
u32 RegA24; /* for TempCCK */
s32 RegE94;
s32 RegE9C;
s32 RegEB4;
s32 RegEBC;
/* u1Byte bTXPowerTracking; */
u1Byte TXPowercount;
/* u8 bTXPowerTracking; */
u8 TXPowercount;
bool bTXPowerTrackingInit;
bool bTXPowerTracking;
u1Byte TxPowerTrackControl; /* for mp mode, turn off txpwrtracking as default */
u1Byte TM_Trigger;
u1Byte InternalPA5G[2]; /* pathA / pathB */
u8 TxPowerTrackControl; /* for mp mode, turn off txpwrtracking as default */
u8 TM_Trigger;
u8 InternalPA5G[2]; /* pathA / pathB */
u1Byte ThermalMeter[2]; /* ThermalMeter, index 0 for RFIC0, and 1 for RFIC1 */
u1Byte ThermalValue;
u1Byte ThermalValue_LCK;
u1Byte ThermalValue_IQK;
u1Byte ThermalValue_DPK;
u1Byte ThermalValue_AVG[AVG_THERMAL_NUM];
u1Byte ThermalValue_AVG_index;
u1Byte ThermalValue_RxGain;
u1Byte ThermalValue_Crystal;
u1Byte ThermalValue_DPKstore;
u1Byte ThermalValue_DPKtrack;
u8 ThermalMeter[2]; /* ThermalMeter, index 0 for RFIC0, and 1 for RFIC1 */
u8 ThermalValue;
u8 ThermalValue_LCK;
u8 ThermalValue_IQK;
u8 ThermalValue_DPK;
u8 ThermalValue_AVG[AVG_THERMAL_NUM];
u8 ThermalValue_AVG_index;
u8 ThermalValue_RxGain;
u8 ThermalValue_Crystal;
u8 ThermalValue_DPKstore;
u8 ThermalValue_DPKtrack;
bool TxPowerTrackingInProgress;
bool bDPKenable;
bool bReloadtxpowerindex;
u1Byte bRfPiEnable;
u4Byte TXPowerTrackingCallbackCnt; /* cosa add for debug */
u8 bRfPiEnable;
u32 TXPowerTrackingCallbackCnt; /* cosa add for debug */
u1Byte bCCKinCH14;
u1Byte CCK_index;
u1Byte OFDM_index[2];
u8 bCCKinCH14;
u8 CCK_index;
u8 OFDM_index[2];
bool bDoneTxpower;
u1Byte ThermalValue_HP[HP_THERMAL_NUM];
u1Byte ThermalValue_HP_index;
u8 ThermalValue_HP[HP_THERMAL_NUM];
u8 ThermalValue_HP_index;
struct ijk_matrix_regs_set IQKMatrixRegSetting[IQK_Matrix_Settings_NUM];
u1Byte Delta_IQK;
u1Byte Delta_LCK;
u8 Delta_IQK;
u8 Delta_LCK;
/* for IQK */
u4Byte RegC04;
u4Byte Reg874;
u4Byte RegC08;
u4Byte RegB68;
u4Byte RegB6C;
u4Byte Reg870;
u4Byte Reg860;
u4Byte Reg864;
u32 RegC04;
u32 Reg874;
u32 RegC08;
u32 RegB68;
u32 RegB6C;
u32 Reg870;
u32 Reg860;
u32 Reg864;
bool bIQKInitialized;
bool bLCKInProgress;
bool bAntennaDetected;
u4Byte ADDA_backup[IQK_ADDA_REG_NUM];
u4Byte IQK_MAC_backup[IQK_MAC_REG_NUM];
u4Byte IQK_BB_backup_recover[9];
u4Byte IQK_BB_backup[IQK_BB_REG_NUM];
u32 ADDA_backup[IQK_ADDA_REG_NUM];
u32 IQK_MAC_backup[IQK_MAC_REG_NUM];
u32 IQK_BB_backup_recover[9];
u32 IQK_BB_backup[IQK_BB_REG_NUM];
/* for APK */
u4Byte APKoutput[2][2]; /* path A/B; output1_1a/output1_2a */
u1Byte bAPKdone;
u1Byte bAPKThermalMeterIgnore;
u1Byte bDPdone;
u1Byte bDPPathAOK;
u1Byte bDPPathBOK;
u32 APKoutput[2][2]; /* path A/B; output1_1a/output1_2a */
u8 bAPKdone;
u8 bAPKThermalMeterIgnore;
u8 bDPdone;
u8 bDPPathAOK;
u8 bDPPathBOK;
};
/* ODM Dynamic common info value definition */
struct fast_ant_train {
u1Byte Bssid[6];
u1Byte antsel_rx_keep_0;
u1Byte antsel_rx_keep_1;
u1Byte antsel_rx_keep_2;
u4Byte antSumRSSI[7];
u4Byte antRSSIcnt[7];
u4Byte antAveRSSI[7];
u1Byte FAT_State;
u4Byte TrainIdx;
u1Byte antsel_a[ODM_ASSOCIATE_ENTRY_NUM];
u1Byte antsel_b[ODM_ASSOCIATE_ENTRY_NUM];
u1Byte antsel_c[ODM_ASSOCIATE_ENTRY_NUM];
u4Byte MainAnt_Sum[ODM_ASSOCIATE_ENTRY_NUM];
u4Byte AuxAnt_Sum[ODM_ASSOCIATE_ENTRY_NUM];
u4Byte MainAnt_Cnt[ODM_ASSOCIATE_ENTRY_NUM];
u4Byte AuxAnt_Cnt[ODM_ASSOCIATE_ENTRY_NUM];
u1Byte RxIdleAnt;
u8 Bssid[6];
u8 antsel_rx_keep_0;
u8 antsel_rx_keep_1;
u8 antsel_rx_keep_2;
u32 antSumRSSI[7];
u32 antRSSIcnt[7];
u32 antAveRSSI[7];
u8 FAT_State;
u32 TrainIdx;
u8 antsel_a[ODM_ASSOCIATE_ENTRY_NUM];
u8 antsel_b[ODM_ASSOCIATE_ENTRY_NUM];
u8 antsel_c[ODM_ASSOCIATE_ENTRY_NUM];
u32 MainAnt_Sum[ODM_ASSOCIATE_ENTRY_NUM];
u32 AuxAnt_Sum[ODM_ASSOCIATE_ENTRY_NUM];
u32 MainAnt_Cnt[ODM_ASSOCIATE_ENTRY_NUM];
u32 AuxAnt_Cnt[ODM_ASSOCIATE_ENTRY_NUM];
u8 RxIdleAnt;
bool bBecomeLinked;
};
@ -815,47 +815,47 @@ struct odm_dm_struct {
bool odm_ready;
struct rtl8192cd_priv *fake_priv;
u8Byte DebugComponents;
u4Byte DebugLevel;
u64 DebugComponents;
u32 DebugLevel;
/* ODM HANDLE, DRIVER NEEDS NOT TO HOOK------ */
bool bCckHighPower;
u1Byte RFPathRxEnable; /* ODM_CMNINFO_RFPATH_ENABLE */
u1Byte ControlChannel;
u8 RFPathRxEnable; /* ODM_CMNINFO_RFPATH_ENABLE */
u8 ControlChannel;
/* ODM HANDLE, DRIVER NEEDS NOT TO HOOK------ */
/* 1 COMMON INFORMATION */
/* Init Value */
/* HOOK BEFORE REG INIT----------- */
/* ODM Platform info AP/ADSL/CE/MP = 1/2/3/4 */
u1Byte SupportPlatform;
u8 SupportPlatform;
/* ODM Support Ability DIG/RATR/TX_PWR_TRACK/ ¡K¡K = 1/2/3/¡K */
u4Byte SupportAbility;
u32 SupportAbility;
/* ODM PCIE/USB/SDIO/GSPI = 0/1/2/3 */
u1Byte SupportInterface;
u8 SupportInterface;
/* ODM composite or independent. Bit oriented/ 92C+92D+ .... or any other type = 1/2/3/... */
u4Byte SupportICType;
u32 SupportICType;
/* Cut Version TestChip/A-cut/B-cut... = 0/1/2/3/... */
u1Byte CutVersion;
u8 CutVersion;
/* Fab Version TSMC/UMC = 0/1 */
u1Byte FabVersion;
u8 FabVersion;
/* RF Type 4T4R/3T3R/2T2R/1T2R/1T1R/... */
u1Byte RFType;
u8 RFType;
/* Board Type Normal/HighPower/MiniCard/SLIM/Combo/... = 0/1/2/3/4/... */
u1Byte BoardType;
u8 BoardType;
/* with external LNA NO/Yes = 0/1 */
u1Byte ExtLNA;
u8 ExtLNA;
/* with external PA NO/Yes = 0/1 */
u1Byte ExtPA;
u8 ExtPA;
/* with external TRSW NO/Yes = 0/1 */
u1Byte ExtTRSW;
u1Byte PatchID; /* Customer ID */
u8 ExtTRSW;
u8 PatchID; /* Customer ID */
bool bInHctTest;
bool bWIFITest;
bool bDualMacSmartConcurrent;
u4Byte BK_SupportAbility;
u1Byte AntDivType;
u32 BK_SupportAbility;
u8 AntDivType;
/* HOOK BEFORE REG INIT----------- */
/* */
@ -863,28 +863,28 @@ struct odm_dm_struct {
/* */
/* POINTER REFERENCE----------- */
u1Byte u1Byte_temp;
u8 u8_temp;
bool bool_temp;
struct adapter *adapter_temp;
/* MAC PHY Mode SMSP/DMSP/DMDP = 0/1/2 */
u1Byte *pMacPhyMode;
u8 *pMacPhyMode;
/* TX Unicast byte count */
u8Byte *pNumTxBytesUnicast;
u64 *pNumTxBytesUnicast;
/* RX Unicast byte count */
u8Byte *pNumRxBytesUnicast;
u64 *pNumRxBytesUnicast;
/* Wireless mode B/G/A/N = BIT0/BIT1/BIT2/BIT3 */
u1Byte *pWirelessMode; /* ODM_WIRELESS_MODE_E */
u8 *pWirelessMode; /* ODM_WIRELESS_MODE_E */
/* Frequence band 2.4G/5G = 0/1 */
u1Byte *pBandType;
u8 *pBandType;
/* Secondary channel offset don't_care/below/above = 0/1/2 */
u1Byte *pSecChOffset;
u8 *pSecChOffset;
/* Security mode Open/WEP/AES/TKIP = 0/1/2/3 */
u1Byte *pSecurity;
u8 *pSecurity;
/* BW info 20M/40M/80M = 0/1/2 */
u1Byte *pBandWidth;
u8 *pBandWidth;
/* Central channel location Ch1/Ch2/.... */
u1Byte *pChannel; /* central channel number */
u8 *pChannel; /* central channel number */
/* Common info for 92D DMSP */
bool *pbGetValueFromOtherMac;
@ -894,9 +894,9 @@ struct odm_dm_struct {
bool *pbScanInProcess;
bool *pbPowerSaving;
/* CCA Path 2-path/path-A/path-B = 0/1/2; using ODM_CCA_PATH_E. */
u1Byte *pOnePathCCA;
u8 *pOnePathCCA;
/* pMgntInfo->AntennaTest */
u1Byte *pAntennaTest;
u8 *pAntennaTest;
bool *pbNet_closed;
/* POINTER REFERENCE----------- */
/* */
@ -904,14 +904,14 @@ struct odm_dm_struct {
bool bWIFI_Direct;
bool bWIFI_Display;
bool bLinked;
u1Byte RSSI_Min;
u1Byte InterfaceIndex; /* Add for 92D dual MAC: 0--Mac0 1--Mac1 */
u8 RSSI_Min;
u8 InterfaceIndex; /* Add for 92D dual MAC: 0--Mac0 1--Mac1 */
bool bIsMPChip;
bool bOneEntryOnly;
/* Common info for BTDM */
bool bBtDisabled; /* BT is disabled */
bool bBtHsOperation; /* BT HS mode is under progress */
u1Byte btHsDigVal; /* use BT rssi to decide the DIG value */
u8 btHsDigVal; /* use BT rssi to decide the DIG value */
bool bBtDisableEdcaTurbo; /* Under some condition, don't enable the EDCA Turbo */
bool bBtBusy; /* BT is busy. */
/* CALL BY VALUE------------- */
@ -921,7 +921,7 @@ struct odm_dm_struct {
/* 2012/01/12 MH For MP, we need to reduce one array pointer for default port.?? */
struct sta_info *pODM_StaInfo[ODM_ASSOCIATE_ENTRY_NUM];
u2Byte CurrminRptTime;
u16 CurrminRptTime;
struct odm_ra_info RAInfo[ODM_ASSOCIATE_ENTRY_NUM]; /* Use MacID as array index. STA MacID=0, VWiFi Client MacID={1, ODM_ASSOCIATE_ENTRY_NUM-1} */
/* */
/* 2012/02/14 MH Add to share 88E ra with other SW team. */
@ -951,7 +951,7 @@ struct odm_dm_struct {
bool RSSI_test;
struct edca_turbo DM_EDCA_Table;
u4Byte WMMEDCA_BE;
u32 WMMEDCA_BE;
/* Copy from SD4 structure */
/* */
/* ================================================== */
@ -964,12 +964,12 @@ struct odm_dm_struct {
/* PSD */
bool bUserAssignLevel;
struct timer_list PSDTimer;
u1Byte RSSI_BT; /* come from BT */
u8 RSSI_BT; /* come from BT */
bool bPSDinProcess;
bool bDMInitialGainEnable;
/* for rate adaptive, in fact, 88c/92c fw will handle this */
u1Byte bUseRAMask;
u8 bUseRAMask;
struct odm_rate_adapt RateAdaptive;
@ -979,15 +979,15 @@ struct odm_dm_struct {
/* */
/* TX power tracking */
/* */
u1Byte BbSwingIdxOfdm;
u1Byte BbSwingIdxOfdmCurrent;
u1Byte BbSwingIdxOfdmBase;
u8 BbSwingIdxOfdm;
u8 BbSwingIdxOfdmCurrent;
u8 BbSwingIdxOfdmBase;
bool BbSwingFlagOfdm;
u1Byte BbSwingIdxCck;
u1Byte BbSwingIdxCckCurrent;
u1Byte BbSwingIdxCckBase;
u8 BbSwingIdxCck;
u8 BbSwingIdxCckCurrent;
u8 BbSwingIdxCckBase;
bool BbSwingFlagCck;
u1Byte *mp_mode;
u8 *mp_mode;
/* */
/* ODM system resource. */
/* */
@ -1166,9 +1166,9 @@ enum dm_swas {
#define OFDM_TABLE_SIZE_92D 43
#define CCK_TABLE_SIZE 33
extern u4Byte OFDMSwingTable[OFDM_TABLE_SIZE_92D];
extern u1Byte CCKSwingTable_Ch1_Ch13[CCK_TABLE_SIZE][8];
extern u1Byte CCKSwingTable_Ch14 [CCK_TABLE_SIZE][8];
extern u32 OFDMSwingTable[OFDM_TABLE_SIZE_92D];
extern u8 CCKSwingTable_Ch1_Ch13[CCK_TABLE_SIZE][8];
extern u8 CCKSwingTable_Ch14 [CCK_TABLE_SIZE][8];
@ -1184,18 +1184,18 @@ extern u1Byte CCKSwingTable_Ch14 [CCK_TABLE_SIZE][8];
#define SWAW_STEP_PEAK 0
#define SWAW_STEP_DETERMINE 1
void ODM_Write_DIG(struct odm_dm_struct *pDM_Odm, u1Byte CurrentIGI);
void ODM_Write_CCK_CCA_Thres(struct odm_dm_struct *pDM_Odm, u1Byte CurCCK_CCAThres);
void ODM_Write_DIG(struct odm_dm_struct *pDM_Odm, u8 CurrentIGI);
void ODM_Write_CCK_CCA_Thres(struct odm_dm_struct *pDM_Odm, u8 CurCCK_CCAThres);
void
ODM_SetAntenna(
struct odm_dm_struct *pDM_Odm,
u1Byte Antenna);
u8 Antenna);
#define dm_RF_Saving ODM_RF_Saving
void ODM_RF_Saving( struct odm_dm_struct *pDM_Odm,
u1Byte bForceInNormal );
u8 bForceInNormal );
#define SwAntDivRestAfterLink ODM_SwAntDivRestAfterLink
void ODM_SwAntDivRestAfterLink( struct odm_dm_struct *pDM_Odm);
@ -1206,35 +1206,30 @@ ODM_TXPowerTrackingCheck(
struct odm_dm_struct *pDM_Odm
);
bool
ODM_RAStateCheck(
struct odm_dm_struct *pDM_Odm,
s4Byte RSSI,
bool bForceUpdate,
pu1Byte pRATRState
);
bool ODM_RAStateCheck(struct odm_dm_struct *pDM_Odm, s32 RSSI,
bool bForceUpdate, u8 *pRATRState);
#define dm_SWAW_RSSI_Check ODM_SwAntDivChkPerPktRssi
void ODM_SwAntDivChkPerPktRssi(struct odm_dm_struct *pDM_Odm, u1Byte StationID, struct odm_phy_status_info *pPhyInfo);
void ODM_SwAntDivChkPerPktRssi(struct odm_dm_struct *pDM_Odm, u8 StationID, struct odm_phy_status_info *pPhyInfo);
u4Byte ConvertTo_dB(u4Byte Value);
u32 ConvertTo_dB(u32 Value);
u4Byte
u32
GetPSDData(
struct odm_dm_struct *pDM_Odm,
unsigned int point,
u1Byte initial_gain_psd);
u8 initial_gain_psd);
void
odm_DIGbyRSSI_LPS(
struct odm_dm_struct *pDM_Odm
);
u4Byte ODM_Get_Rate_Bitmap(
u32 ODM_Get_Rate_Bitmap(
struct odm_dm_struct *pDM_Odm,
u4Byte macid,
u4Byte ra_mask,
u1Byte rssi_level);
u32 macid,
u32 ra_mask,
u8 rssi_level);
void ODM_DMInit( struct odm_dm_struct *pDM_Odm);
@ -1247,7 +1242,7 @@ void
ODM_CmnInfoInit(
struct odm_dm_struct *pDM_Odm,
enum odm_common_info_def CmnInfo,
u4Byte Value
u32 Value
);
void
@ -1261,15 +1256,15 @@ void
ODM_CmnInfoPtrArrayHook(
struct odm_dm_struct *pDM_Odm,
enum odm_common_info_def CmnInfo,
u2Byte Index,
u16 Index,
void * pValue
);
void
ODM_CmnInfoUpdate(
struct odm_dm_struct *pDM_Odm,
u4Byte CmnInfo,
u8Byte Value
u32 CmnInfo,
u64 Value
);
void
@ -1295,8 +1290,8 @@ ODM_ResetIQKResult(
void
ODM_AntselStatistics_88C(
struct odm_dm_struct *pDM_Odm,
u1Byte MacId,
u4Byte PWDBAll,
u8 MacId,
u32 PWDBAll,
bool isCCKrate
);
@ -1308,7 +1303,7 @@ ODM_SingleDualAntennaDefaultSetting(
bool
ODM_SingleDualAntennaDetection(
struct odm_dm_struct *pDM_Odm,
u1Byte mode
u8 mode
);
void odm_dtc(struct odm_dm_struct *pDM_Odm);

70
include/odm_HWConfig.h
View file

@ -70,47 +70,47 @@
struct phy_rx_agc_info {
#ifdef __LITTLE_ENDIAN
u1Byte gain:7,trsw:1;
u8 gain:7,trsw:1;
#else
u1Byte trsw:1,gain:7;
u8 trsw:1,gain:7;
#endif
};
struct phy_status_rpt {
struct phy_rx_agc_info path_agc[2];
u1Byte ch_corr[2];
u1Byte cck_sig_qual_ofdm_pwdb_all;
u1Byte cck_agc_rpt_ofdm_cfosho_a;
u1Byte cck_rpt_b_ofdm_cfosho_b;
u1Byte rsvd_1;/* ch_corr_msb; */
u1Byte noise_power_db_msb;
u1Byte path_cfotail[2];
u1Byte pcts_mask[2];
s1Byte stream_rxevm[2];
u1Byte path_rxsnr[2];
u1Byte noise_power_db_lsb;
u1Byte rsvd_2[3];
u1Byte stream_csi[2];
u1Byte stream_target_csi[2];
s1Byte sig_evm;
u1Byte rsvd_3;
u8 ch_corr[2];
u8 cck_sig_qual_ofdm_pwdb_all;
u8 cck_agc_rpt_ofdm_cfosho_a;
u8 cck_rpt_b_ofdm_cfosho_b;
u8 rsvd_1;/* ch_corr_msb; */
u8 noise_power_db_msb;
u8 path_cfotail[2];
u8 pcts_mask[2];
s8 stream_rxevm[2];
u8 path_rxsnr[2];
u8 noise_power_db_lsb;
u8 rsvd_2[3];
u8 stream_csi[2];
u8 stream_target_csi[2];
s8 sig_evm;
u8 rsvd_3;
#ifdef __LITTLE_ENDIAN
u1Byte antsel_rx_keep_2:1; /* ex_intf_flg:1; */
u1Byte sgi_en:1;
u1Byte rxsc:2;
u1Byte idle_long:1;
u1Byte r_ant_train_en:1;
u1Byte ant_sel_b:1;
u1Byte ant_sel:1;
u8 antsel_rx_keep_2:1; /* ex_intf_flg:1; */
u8 sgi_en:1;
u8 rxsc:2;
u8 idle_long:1;
u8 r_ant_train_en:1;
u8 ant_sel_b:1;
u8 ant_sel:1;
#else /* _BIG_ENDIAN_ */
u1Byte ant_sel:1;
u1Byte ant_sel_b:1;
u1Byte r_ant_train_en:1;
u1Byte idle_long:1;
u1Byte rxsc:2;
u1Byte sgi_en:1;
u1Byte antsel_rx_keep_2:1; /* ex_intf_flg:1; */
u8 ant_sel:1;
u8 ant_sel_b:1;
u8 r_ant_train_en:1;
u8 idle_long:1;
u8 rxsc:2;
u8 sgi_en:1;
u8 antsel_rx_keep_2:1; /* ex_intf_flg:1; */
#endif
};
@ -123,15 +123,15 @@ void
ODM_PhyStatusQuery(
struct odm_dm_struct * pDM_Odm,
struct odm_phy_status_info *pPhyInfo,
pu1Byte pPhyStatus,
u8 *pPhyStatus,
struct odm_per_pkt_info *pPktinfo
);
void
ODM_MacStatusQuery(
struct odm_dm_struct * pDM_Odm,
pu1Byte pMacStatus,
u1Byte MacID,
u8 *pMacStatus,
u8 MacID,
bool bPacketMatchBSSID,
bool bPacketToSelf,
bool bPacketBeacon

13
include/odm_RTL8188E.h
View file

@ -33,17 +33,14 @@ void ODM_AntennaDiversityInit_88E(struct odm_dm_struct *pDM_Odm);
void ODM_AntennaDiversity_88E(struct odm_dm_struct *pDM_Odm);
void ODM_SetTxAntByTxInfo_88E(struct odm_dm_struct *pDM_Odm,
pu1Byte pDesc,
u1Byte macId
);
void ODM_SetTxAntByTxInfo_88E(struct odm_dm_struct *pDM_Odm, u8 *pDesc, u8 macId);
void ODM_UpdateRxIdleAnt_88E(struct odm_dm_struct *pDM_Odm, u1Byte Ant);
void ODM_UpdateRxIdleAnt_88E(struct odm_dm_struct *pDM_Odm, u8 Ant);
void ODM_AntselStatistics_88E(struct odm_dm_struct *pDM_Odm,
u1Byte antsel_tr_mux,
u4Byte MacId,
u1Byte RxPWDBAll
u8 antsel_tr_mux,
u32 MacId,
u8 RxPWDBAll
);
void

34
include/odm_RegConfig8188E.h
View file

@ -20,51 +20,51 @@
#ifndef __INC_ODM_REGCONFIG_H_8188E
#define __INC_ODM_REGCONFIG_H_8188E
void odm_ConfigRFReg_8188E(struct odm_dm_struct *pDM_Odm, u4Byte Addr, u4Byte Data,
enum ODM_RF_RADIO_PATH RF_PATH, u4Byte RegAddr);
void odm_ConfigRFReg_8188E(struct odm_dm_struct *pDM_Odm, u32 Addr, u32 Data,
enum ODM_RF_RADIO_PATH RF_PATH, u32 RegAddr);
void
odm_ConfigRF_RadioA_8188E(
struct odm_dm_struct *pDM_Odm,
u4Byte Addr,
u4Byte Data
u32 Addr,
u32 Data
);
void
odm_ConfigRF_RadioB_8188E(
struct odm_dm_struct *pDM_Odm,
u4Byte Addr,
u4Byte Data
u32 Addr,
u32 Data
);
void
odm_ConfigMAC_8188E(
struct odm_dm_struct *pDM_Odm,
u4Byte Addr,
u1Byte Data
u32 Addr,
u8 Data
);
void
odm_ConfigBB_AGC_8188E(
struct odm_dm_struct *pDM_Odm,
u4Byte Addr,
u4Byte Bitmask,
u4Byte Data
u32 Addr,
u32 Bitmask,
u32 Data
);
void
odm_ConfigBB_PHY_REG_PG_8188E(
struct odm_dm_struct *pDM_Odm,
u4Byte Addr,
u4Byte Bitmask,
u4Byte Data
u32 Addr,
u32 Bitmask,
u32 Data
);
void
odm_ConfigBB_PHY_8188E(
struct odm_dm_struct *pDM_Odm,
u4Byte Addr,
u4Byte Bitmask,
u4Byte Data
u32 Addr,
u32 Bitmask,
u32 Data
);
#endif

2
include/odm_debug.h
View file

@ -143,7 +143,7 @@
if (((comp) & pDM_Odm->DebugComponents) && (level <= pDM_Odm->DebugLevel)) \
{ \
int __i; \
pu1Byte __ptr = (pu1Byte)ptr; \
pu8 __ptr = (pu8)ptr; \
DbgPrint("[ODM] "); \
DbgPrint(title_str); \
DbgPrint(" "); \

44
include/odm_interface.h
View file

@ -83,37 +83,37 @@ typedef void (*RT_WORKITEM_CALL_BACK)(void * pContext);
/* =========== EXtern Function Prototype */
/* */
u1Byte ODM_Read1Byte(struct odm_dm_struct *pDM_Odm, u4Byte RegAddr);
u8 ODM_Read1Byte(struct odm_dm_struct *pDM_Odm, u32 RegAddr);
u2Byte ODM_Read2Byte(struct odm_dm_struct *pDM_Odm, u4Byte RegAddr);
u16 ODM_Read2Byte(struct odm_dm_struct *pDM_Odm, u32 RegAddr);
u4Byte ODM_Read4Byte(struct odm_dm_struct *pDM_Odm, u4Byte RegAddr);
u32 ODM_Read4Byte(struct odm_dm_struct *pDM_Odm, u32 RegAddr);
void ODM_Write1Byte(struct odm_dm_struct *pDM_Odm, u4Byte RegAddr, u1Byte Data);
void ODM_Write1Byte(struct odm_dm_struct *pDM_Odm, u32 RegAddr, u8 Data);
void ODM_Write2Byte(struct odm_dm_struct *pDM_Odm, u4Byte RegAddr, u2Byte Data);
void ODM_Write2Byte(struct odm_dm_struct *pDM_Odm, u32 RegAddr, u16 Data);
void ODM_Write4Byte(struct odm_dm_struct *pDM_Odm, u4Byte RegAddr, u4Byte Data);
void ODM_Write4Byte(struct odm_dm_struct *pDM_Odm, u32 RegAddr, u32 Data);
void ODM_SetMACReg(struct odm_dm_struct *pDM_Odm, u4Byte RegAddr, u4Byte BitMask, u4Byte Data);
void ODM_SetMACReg(struct odm_dm_struct *pDM_Odm, u32 RegAddr, u32 BitMask, u32 Data);
u4Byte ODM_GetMACReg(struct odm_dm_struct *pDM_Odm, u4Byte RegAddr, u4Byte BitMask);
u32 ODM_GetMACReg(struct odm_dm_struct *pDM_Odm, u32 RegAddr, u32 BitMask);
void ODM_SetBBReg(struct odm_dm_struct *pDM_Odm, u4Byte RegAddr, u4Byte BitMask, u4Byte Data);
void ODM_SetBBReg(struct odm_dm_struct *pDM_Odm, u32 RegAddr, u32 BitMask, u32 Data);
u4Byte ODM_GetBBReg(struct odm_dm_struct *pDM_Odm, u4Byte RegAddr, u4Byte BitMask);
u32 ODM_GetBBReg(struct odm_dm_struct *pDM_Odm, u32 RegAddr, u32 BitMask);
void ODM_SetRFReg(struct odm_dm_struct *pDM_Odm, enum ODM_RF_RADIO_PATH eRFPath, u4Byte RegAddr, u4Byte BitMask, u4Byte Data);
void ODM_SetRFReg(struct odm_dm_struct *pDM_Odm, enum ODM_RF_RADIO_PATH eRFPath, u32 RegAddr, u32 BitMask, u32 Data);
u4Byte ODM_GetRFReg(struct odm_dm_struct *pDM_Odm, enum ODM_RF_RADIO_PATH eRFPath, u4Byte RegAddr, u4Byte BitMask);
u32 ODM_GetRFReg(struct odm_dm_struct *pDM_Odm, enum ODM_RF_RADIO_PATH eRFPath, u32 RegAddr, u32 BitMask);
/* */
/* Memory Relative Function. */
/* */
void ODM_AllocateMemory(struct odm_dm_struct *pDM_Odm, void **pPtr, u4Byte length);
void ODM_FreeMemory(struct odm_dm_struct *pDM_Odm, void *pPtr, u4Byte length);
void ODM_AllocateMemory(struct odm_dm_struct *pDM_Odm, void **pPtr, u32 length);
void ODM_FreeMemory(struct odm_dm_struct *pDM_Odm, void *pPtr, u32 length);
s4Byte ODM_CompareMemory(struct odm_dm_struct *pDM_Odm, void *pBuf1, void *pBuf2, u4Byte length);
s32 ODM_CompareMemory(struct odm_dm_struct *pDM_Odm, void *pBuf1, void *pBuf2, u32 length);
/* */
/* ODM MISC-spin lock relative API. */
@ -142,17 +142,17 @@ void ODM_IsWorkItemScheduled(void *pRtWorkItem);
/* */
/* ODM Timer relative API. */
/* */
void ODM_StallExecution(u4Byte usDelay);
void ODM_StallExecution(u32 usDelay);
void ODM_delay_ms(u4Byte ms);
void ODM_delay_ms(u32 ms);
void ODM_delay_us(u4Byte us);
void ODM_delay_us(u32 us);
void ODM_sleep_ms(u4Byte ms);
void ODM_sleep_ms(u32 ms);
void ODM_sleep_us(u4Byte us);
void ODM_sleep_us(u32 us);
void ODM_SetTimer(struct odm_dm_struct *pDM_Odm, struct timer_list *pTimer, u4Byte msDelay);
void ODM_SetTimer(struct odm_dm_struct *pDM_Odm, struct timer_list *pTimer, u32 msDelay);
void ODM_InitializeTimer(struct odm_dm_struct *pDM_Odm, struct timer_list *pTimer, void *CallBackFunc, void *pContext, const char *szID);
@ -163,6 +163,6 @@ void ODM_ReleaseTimer(struct odm_dm_struct *pDM_Odm, struct timer_list *pTimer);
/* */
/* ODM FW relative API. */
/* */
u4Byte ODM_FillH2CCmd(pu1Byte pH2CBuffer, u4Byte H2CBufferLen, u4Byte CmdNum, pu4Byte pElementID, pu4Byte pCmdLen, pu1Byte *pCmbBuffer, pu1Byte CmdStartSeq);
u32 ODM_FillH2CCmd(u8 *pH2CBuffer, u32 H2CBufferLen, u32 CmdNum, u32 *pElementID, u32 *pCmdLen, u8 **pCmbBuffer, u8 *CmdStartSeq);
#endif /* __ODM_INTERFACE_H__ */

2
include/odm_precomp.h
View file

@ -81,7 +81,7 @@ void odm_DIG(struct odm_dm_struct *pDM_Odm);
void odm_CCKPacketDetectionThresh(struct odm_dm_struct *pDM_Odm);
void odm_RefreshRateAdaptiveMaskMP(struct odm_dm_struct *pDM_Odm);
void odm_DynamicBBPowerSaving(struct odm_dm_struct *pDM_Odm);
void odm_SwAntDivChkAntSwitch(struct odm_dm_struct *pDM_Odm, u1Byte Step);
void odm_SwAntDivChkAntSwitch(struct odm_dm_struct *pDM_Odm, u8 Step);
void odm_EdcaTurboCheck(struct odm_dm_struct *pDM_Odm);
void odm_DynamicTxPower(struct odm_dm_struct *pDM_Odm);
void odm_CommonInfoSelfInit(struct odm_dm_struct *pDM_Odm);

24
include/odm_types.h
View file

@ -43,30 +43,6 @@ enum RT_SPINLOCK_TYPE {
#include <basic_types.h>
#define u1Byte u8
#define pu1Byte u8*
#define u2Byte u16
#define pu2Byte u16*
#define u4Byte u32
#define pu4Byte u32*
#define u8Byte u64
#define pu8Byte u64*
#define s1Byte s8
#define ps1Byte s8*
#define s2Byte s16
#define ps2Byte s16*
#define s4Byte s32
#define ps4Byte s32*
#define s8Byte s64
#define ps8Byte s64*
#define DEV_BUS_TYPE RT_USB_INTERFACE
#define SET_TX_DESC_ANTSEL_A_88E(__pTxDesc, __Value) SET_BITS_TO_LE_4BYTE(__pTxDesc+8, 24, 1, __Value)

12
include/rtl8188e_hal.h
View file

@ -194,13 +194,13 @@ enum ChannelPlan
};
struct txpowerinfo24g {
u1Byte IndexCCK_Base[MAX_RF_PATH][MAX_CHNL_GROUP_24G];
u1Byte IndexBW40_Base[MAX_RF_PATH][MAX_CHNL_GROUP_24G-1];
u8 IndexCCK_Base[MAX_RF_PATH][MAX_CHNL_GROUP_24G];
u8 IndexBW40_Base[MAX_RF_PATH][MAX_CHNL_GROUP_24G-1];
/* If only one tx, only BW20 and OFDM are used. */
s1Byte CCK_Diff[MAX_RF_PATH][MAX_TX_COUNT];
s1Byte OFDM_Diff[MAX_RF_PATH][MAX_TX_COUNT];
s1Byte BW20_Diff[MAX_RF_PATH][MAX_TX_COUNT];
s1Byte BW40_Diff[MAX_RF_PATH][MAX_TX_COUNT];
s8 CCK_Diff[MAX_RF_PATH][MAX_TX_COUNT];
s8 OFDM_Diff[MAX_RF_PATH][MAX_TX_COUNT];
s8 BW20_Diff[MAX_RF_PATH][MAX_TX_COUNT];
s8 BW40_Diff[MAX_RF_PATH][MAX_TX_COUNT];
};
#define EFUSE_REAL_CONTENT_LEN 512

122
include/rtw_mp.h
View file

@ -81,44 +81,38 @@
#define NDIS_STATUS_NO_ROUTE_TO_DESTINATION ((int)0xC0010029L) /* cause 3 */
enum antenna_path {
ANTENNA_NONE = 0x00,
ANTENNA_D ,
ANTENNA_C ,
ANTENNA_CD ,
ANTENNA_B ,
ANTENNA_BD ,
ANTENNA_BC ,
ANTENNA_BCD ,
ANTENNA_A ,
ANTENNA_AD ,
ANTENNA_AC ,
ANTENNA_ACD ,
ANTENNA_AB ,
ANTENNA_ABD ,
ANTENNA_ABC ,
ANTENNA_ABCD
ANTENNA_NONE = 0x00,
ANTENNA_D,
ANTENNA_C,
ANTENNA_CD,
ANTENNA_B,
ANTENNA_BD,
ANTENNA_BC,
ANTENNA_BCD,
ANTENNA_A,
ANTENNA_AD,
ANTENNA_AC,
ANTENNA_ACD,
ANTENNA_AB,
ANTENNA_ABD,
ANTENNA_ABC,
ANTENNA_ABCD
};
#define MAX_MP_XMITBUF_SZ 2048
#define NR_MP_XMITFRAME 8
struct mp_xmit_frame
{
struct mp_xmit_frame {
struct list_head list;
struct pkt_attrib attrib;
struct sk_buff *pkt;
int frame_tag;
struct adapter *padapter;
struct urb *pxmit_urb[8];
/* insert urb, irp, and irpcnt info below... */
u8 *mem_addr;
u32 sz[8];
struct urb * pxmit_urb[8];
u8 bpending[8];
int ac_tag[8];
int last[8];
@ -127,15 +121,14 @@ struct mp_xmit_frame
uint mem[(MAX_MP_XMITBUF_SZ >> 2)];
};
struct mp_wiparam
{
struct mp_wiparam {
u32 bcompleted;
u32 act_type;
u32 io_offset;
u32 io_value;
};
typedef void(*wi_act_func)(void* padapter);
typedef void(*wi_act_func)(void *padapter);
struct mp_tx {
u8 stop;
@ -153,41 +146,6 @@ struct mp_tx {
#define MP_MAX_LINES 1000
#define MP_MAX_LINES_BYTES 256
#define u1Byte u8
#define s1Byte s8
#define u4Byte u32
#define s4Byte s32
#define u1Byte u8
#define pu1Byte u8*
#define u2Byte u16
#define pu2Byte u16*
#define u4Byte u32
#define pu4Byte u32*
#define u8Byte u64
#define pu8Byte u64*
#define s1Byte s8
#define ps1Byte s8*
#define s2Byte s16
#define ps2Byte s16*
#define s4Byte s32
#define ps4Byte s32*
#define s8Byte s64
#define ps8Byte s64*
#define UCHAR u8
#define USHORT u16
#define UINT u32
#define ULONG u32
#define PULONG u32*
typedef void (*MPT_WORK_ITEM_HANDLER)(void *Adapter);
@ -215,23 +173,23 @@ struct mpt_context {
MPT_WORK_ITEM_HANDLER CurrMptAct;
/* 1=Start, 0=Stop from UI. */
ULONG MptTestStart;
u32 MptTestStart;
/* _TEST_MODE, defined in MPT_Req2.h */
ULONG MptTestItem;
u32 MptTestItem;
/* Variable needed in each implementation of CurrMptAct. */
ULONG MptActType; /* Type of action performed in CurrMptAct. */
u32 MptActType; /* Type of action performed in CurrMptAct. */
/* The Offset of IO operation is depend of MptActType. */
ULONG MptIoOffset;
u32 MptIoOffset;
/* The Value of IO operation is depend of MptActType. */
ULONG MptIoValue;
u32 MptIoValue;
/* The RfPath of IO operation is depend of MptActType. */
ULONG MptRfPath;
u32 MptRfPath;
enum wireless_mode MptWirelessModeToSw; /* Wireless mode to switch. */
u8 MptChannelToSw; /* Channel to switch. */
u8 MptInitGainToSet; /* Initial gain to set. */
ULONG MptBandWidth; /* bandwidth to switch. */
ULONG MptRateIndex; /* rate index. */
u32 MptBandWidth; /* bandwidth to switch. */
u32 MptRateIndex; /* rate index. */
/* Register value kept for Single Carrier Tx test. */
u8 btMpCckTxPower;
/* Register value kept for Single Carrier Tx test. */
@ -240,13 +198,13 @@ struct mpt_context {
u8 TxPwrLevel[2]; /* rf-A, rf-B */
/* Content of RCR Regsiter for Mass Production Test. */
ULONG MptRCR;
u32 MptRCR;
/* true if we only receive packets with specific pattern. */
bool bMptFilterPattern;
/* Rx OK count, statistics used in Mass Production Test. */
ULONG MptRxOkCnt;
u32 MptRxOkCnt;
/* Rx CRC32 error count, statistics used in Mass Production Test. */
ULONG MptRxCrcErrCnt;
u32 MptRxCrcErrCnt;
bool bCckContTx; /* true if we are in CCK Continuous Tx test. */
bool bOfdmContTx; /* true if we are in OFDM Continuous Tx test. */
@ -260,12 +218,12 @@ struct mpt_context {
/* ACK counter asked by K.Y.. */
bool bMptEnableAckCounter;
ULONG MptAckCounter;
u32 MptAckCounter;
/* SD3 Willis For 8192S to save 1T/2T RF table for ACUT Only fro ACUT delete later ~~~! */
/* s1Byte BufOfLines[2][MAX_LINES_HWCONFIG_TXT][MAX_BYTES_LINE_HWCONFIG_TXT]; */
/* s1Byte BufOfLines[2][MP_MAX_LINES][MP_MAX_LINES_BYTES]; */
/* s4Byte RfReadLine[2]; */
/* s8 BufOfLines[2][MAX_LINES_HWCONFIG_TXT][MAX_BYTES_LINE_HWCONFIG_TXT]; */
/* s8 BufOfLines[2][MP_MAX_LINES][MP_MAX_LINES_BYTES]; */
/* s32 RfReadLine[2]; */
u8 APK_bound[2]; /* for APK path A/path B */
bool bMptIndexEven;
@ -276,12 +234,12 @@ struct mpt_context {
u8 backup0x52_RF_A;
u8 backup0x52_RF_B;
u1Byte h2cReqNum;
u1Byte c2hBuf[20];
u8 h2cReqNum;
u8 c2hBuf[20];
u1Byte btInBuf[100];
ULONG mptOutLen;
u1Byte mptOutBuf[100];
u8 btInBuf[100];
u32 mptOutLen;
u8 mptOutBuf[100];
};

2
include/usb_osintf.h
View file

@ -27,7 +27,7 @@
extern char *rtw_initmac;
extern int rtw_mc2u_disable;
#define USBD_HALTED(Status) ((ULONG)(Status) >> 30 == 3)
#define USBD_HALTED(Status) ((u32)(Status) >> 30 == 3)
u8 usbvendorrequest(struct dvobj_priv *pdvobjpriv, enum bt_usb_request brequest,
enum rt_usb_wvalue wvalue, u8 windex, void *data,

110
include/wlan_bssdef.h
View file

@ -30,8 +30,8 @@
#define NDIS_802_11_RSSI long /* in dBm */
struct ndis_802_11_ssid {
ULONG SsidLength;
UCHAR Ssid[32];
u32 SsidLength;
u8 Ssid[32];
};
enum NDIS_802_11_NETWORK_TYPE {
@ -43,10 +43,10 @@ enum NDIS_802_11_NETWORK_TYPE {
};
struct ndis_802_11_config_fh {
ULONG Length; /* Length of structure */
ULONG HopPattern; /* As defined by 802.11, MSB set */
ULONG HopSet; /* to one if non-802.11 */
ULONG DwellTime; /* units are Kusec */
u32 Length; /* Length of structure */
u32 HopPattern; /* As defined by 802.11, MSB set */
u32 HopSet; /* to one if non-802.11 */
u32 DwellTime; /* units are Kusec */
};
/*
@ -54,10 +54,10 @@ struct ndis_802_11_config_fh {
* ODI Handler will convert the channel number to freq. number.
*/
struct ndis_802_11_config {
ULONG Length; /* Length of structure */
ULONG BeaconPeriod; /* units are Kusec */
ULONG ATIMWindow; /* units are Kusec */
ULONG DSConfig; /* Frequency, units are kHz */
u32 Length; /* Length of structure */
u32 BeaconPeriod; /* units are Kusec */
u32 ATIMWindow; /* units are Kusec */
u32 DSConfig; /* Frequency, units are kHz */
struct ndis_802_11_config_fh FHConfig;
};
@ -70,22 +70,22 @@ enum ndis_802_11_network_infra {
};
struct ndis_802_11_fixed_ie {
UCHAR Timestamp[8];
USHORT BeaconInterval;
USHORT Capabilities;
u8 Timestamp[8];
u16 BeaconInterval;
u16 Capabilities;
};
struct ndis_802_11_var_ie {
UCHAR ElementID;
UCHAR Length;
UCHAR data[1];
u8 ElementID;
u8 Length;
u8 data[1];
};
/*
* Length is the 4 bytes multiples of the sume of
* [ETH_ALEN] + 2 + sizeof (struct ndis_802_11_ssid) + sizeof (ULONG)
* [ETH_ALEN] + 2 + sizeof (struct ndis_802_11_ssid) + sizeof (u32)
* + sizeof (NDIS_802_11_RSSI) + sizeof (enum NDIS_802_11_NETWORK_TYPE)
* + sizeof (struct ndis_802_11_config)
* + NDIS_802_11_LENGTH_RATES_EX + IELength
@ -129,27 +129,27 @@ enum ndis_802_11_wep_status {
#define NDIS_802_11_AI_RESFI_ASSOCIATIONID 4
struct ndis_802_11_ai_reqfi {
USHORT Capabilities;
USHORT ListenInterval;
u16 Capabilities;
u16 ListenInterval;
unsigned char CurrentAPAddress[ETH_ALEN];
};
struct ndis_802_11_ai_resfi {
USHORT Capabilities;
USHORT StatusCode;
USHORT AssociationId;
u16 Capabilities;
u16 StatusCode;
u16 AssociationId;
};
struct ndis_802_11_assoc_info {
ULONG Length;
USHORT AvailableRequestFixedIEs;
u32 Length;
u16 AvailableRequestFixedIEs;
struct ndis_802_11_ai_reqfi RequestFixedIEs;
ULONG RequestIELength;
ULONG OffsetRequestIEs;
USHORT AvailableResponseFixedIEs;
u32 RequestIELength;
u32 OffsetRequestIEs;
u16 AvailableResponseFixedIEs;
struct ndis_802_11_ai_resfi ResponseFixedIEs;
ULONG ResponseIELength;
ULONG OffsetResponseIEs;
u32 ResponseIELength;
u32 OffsetResponseIEs;
};
enum ndis_802_11_reload_def {
@ -158,32 +158,32 @@ enum ndis_802_11_reload_def {
/* Key mapping keys require a BSSID */
struct ndis_802_11_key {
ULONG Length; /* Length of this structure */
ULONG KeyIndex;
ULONG KeyLength; /* length of key in bytes */
u32 Length; /* Length of this structure */
u32 KeyIndex;
u32 KeyLength; /* length of key in bytes */
unsigned char BSSID[ETH_ALEN];
unsigned long long KeyRSC;
UCHAR KeyMaterial[32]; /* var len depending on above field */
u8 KeyMaterial[32]; /* var len depending on above field */
};
struct ndis_802_11_remove_key {
ULONG Length; /* Length */
ULONG KeyIndex;
u32 Length; /* Length */
u32 KeyIndex;
unsigned char BSSID[ETH_ALEN];
};
struct ndis_802_11_wep {
ULONG Length; /* Length of this structure */
ULONG KeyIndex; /* 0 is the per-client key,
u32 Length; /* Length of this structure */
u32 KeyIndex; /* 0 is the per-client key,
* 1-N are the global keys */
ULONG KeyLength; /* length of key in bytes */
UCHAR KeyMaterial[16];/* variable len depending on above field */
u32 KeyLength; /* length of key in bytes */
u8 KeyMaterial[16];/* variable len depending on above field */
};
struct ndis_802_11_auth_req {
ULONG Length; /* Length of structure */
u32 Length; /* Length of structure */
unsigned char Bssid[ETH_ALEN];
ULONG Flags;
u32 Flags;
};
enum ndis_802_11_status_type {
@ -214,8 +214,8 @@ struct ndis_802_11_auth_evt {
};
struct ndis_802_11_test {
ULONG Length;
ULONG Type;
u32 Length;
u32 Type;
union {
struct ndis_802_11_auth_evt AuthenticationEvent;
NDIS_802_11_RSSI RssiTrigger;
@ -251,19 +251,19 @@ struct wlan_bcn_info {
* struct wlan_bssid_ex and get_struct wlan_bssid_ex_sz()
*/
struct wlan_bssid_ex {
ULONG Length;
u32 Length;
unsigned char MacAddress[ETH_ALEN];
UCHAR Reserved[2];/* 0]: IS beacon frame */
u8 Reserved[2];/* 0]: IS beacon frame */
struct ndis_802_11_ssid Ssid;
ULONG Privacy;
u32 Privacy;
NDIS_802_11_RSSI Rssi;/* in dBM,raw data ,get from PHY) */
enum NDIS_802_11_NETWORK_TYPE NetworkTypeInUse;
struct ndis_802_11_config Configuration;
enum ndis_802_11_network_infra InfrastructureMode;
unsigned char SupportedRates[NDIS_802_11_LENGTH_RATES_EX];
struct wlan_phy_info PhyInfo;
ULONG IELength;
UCHAR IEs[MAX_IE_SZ]; /* timestamp, beacon interval, and
u32 IELength;
u8 IEs[MAX_IE_SZ]; /* timestamp, beacon interval, and
* capability information) */
} __packed;
@ -318,12 +318,12 @@ enum UAPSD_MAX_SP {
struct pmkid_candidate {
unsigned char BSSID[ETH_ALEN];
ULONG Flags;
u32 Flags;
};
struct ndis_802_11_pmkid_list {
ULONG Version; /* Version of the structure */
ULONG NumCandidates; /* No. of pmkid candidates */
u32 Version; /* Version of the structure */
u32 NumCandidates; /* No. of pmkid candidates */
struct pmkid_candidate CandidateList[1];
};
@ -333,10 +333,10 @@ struct ndis_802_11_auth_encrypt {
};
struct ndis_802_11_cap {
ULONG Length;
ULONG Version;
ULONG NoOfPMKIDs;
ULONG NoOfAuthEncryptPairsSupported;
u32 Length;
u32 Version;
u32 NoOfPMKIDs;
u32 NoOfAuthEncryptPairsSupported;
struct ndis_802_11_auth_encrypt AuthenticationEncryptionSupported[1];
};