#include <hal_data.h>
#include <rtw_debug.h>
#include <hal_btcoex.h>
#include <Mp_Precomp.h>
struct btc_coexist GLBtCoexist;
static u8 GLBtcWiFiInScanState;
static u8 GLBtcWiFiInIQKState;
static u8 halbtcoutsrc_IsBtCoexistAvailable(struct btc_coexist *pBtCoexist)
{
if (!pBtCoexist->bBinded || !pBtCoexist->Adapter)
return false;
return true;
}
static void halbtcoutsrc_LeaveLps(struct btc_coexist *pBtCoexist)
{
struct adapter *padapter;
padapter = pBtCoexist->Adapter;
pBtCoexist->btInfo.bBtCtrlLps = true;
pBtCoexist->btInfo.bBtLpsOn = false;
rtw_btcoex_LPS_Leave(padapter);
}
static void halbtcoutsrc_EnterLps(struct btc_coexist *pBtCoexist)
{
struct adapter *padapter;
padapter = pBtCoexist->Adapter;
pBtCoexist->btInfo.bBtCtrlLps = true;
pBtCoexist->btInfo.bBtLpsOn = true;
rtw_btcoex_LPS_Enter(padapter);
}
static void halbtcoutsrc_NormalLps(struct btc_coexist *pBtCoexist)
{
struct adapter *padapter;
padapter = pBtCoexist->Adapter;
if (pBtCoexist->btInfo.bBtCtrlLps) {
pBtCoexist->btInfo.bBtLpsOn = false;
rtw_btcoex_LPS_Leave(padapter);
pBtCoexist->btInfo.bBtCtrlLps = false;
}
}
static void halbtcoutsrc_LeaveLowPower(struct btc_coexist *pBtCoexist)
{
struct adapter *padapter;
s32 ready;
unsigned long stime;
unsigned long utime;
u32 timeout;
padapter = pBtCoexist->Adapter;
ready = _FAIL;
#ifdef LPS_RPWM_WAIT_MS
timeout = LPS_RPWM_WAIT_MS;
#else /* !LPS_RPWM_WAIT_MS */
timeout = 30;
#endif /* !LPS_RPWM_WAIT_MS */
stime = jiffies;
do {
ready = rtw_register_task_alive(padapter, BTCOEX_ALIVE);
if (_SUCCESS == ready)
break;
utime = jiffies_to_msecs(jiffies - stime);
if (utime > timeout)
break;
msleep(1);
} while (1);
}
static void halbtcoutsrc_NormalLowPower(struct btc_coexist *pBtCoexist)
{
struct adapter *padapter;
padapter = pBtCoexist->Adapter;
rtw_unregister_task_alive(padapter, BTCOEX_ALIVE);
}
static void halbtcoutsrc_DisableLowPower(struct btc_coexist *pBtCoexist, u8 bLowPwrDisable)
{
pBtCoexist->btInfo.bBtDisableLowPwr = bLowPwrDisable;
if (bLowPwrDisable)
halbtcoutsrc_LeaveLowPower(pBtCoexist);
else
halbtcoutsrc_NormalLowPower(pBtCoexist);
}
static void halbtcoutsrc_AggregationCheck(struct btc_coexist *pBtCoexist)
{
struct adapter *padapter;
bool bNeedToAct;
padapter = pBtCoexist->Adapter;
bNeedToAct = false;
if (pBtCoexist->btInfo.bRejectAggPkt) {
rtw_btcoex_RejectApAggregatedPacket(padapter, true);
} else {
if (pBtCoexist->btInfo.bPreBtCtrlAggBufSize !=
pBtCoexist->btInfo.bBtCtrlAggBufSize) {
bNeedToAct = true;
pBtCoexist->btInfo.bPreBtCtrlAggBufSize = pBtCoexist->btInfo.bBtCtrlAggBufSize;
}
if (pBtCoexist->btInfo.bBtCtrlAggBufSize) {
if (pBtCoexist->btInfo.preAggBufSize !=
pBtCoexist->btInfo.aggBufSize){
bNeedToAct = true;
}
pBtCoexist->btInfo.preAggBufSize = pBtCoexist->btInfo.aggBufSize;
}
if (bNeedToAct) {
rtw_btcoex_RejectApAggregatedPacket(padapter, true);
rtw_btcoex_RejectApAggregatedPacket(padapter, false);
}
}
}
static u8 halbtcoutsrc_IsWifiBusy(struct adapter *padapter)
{
struct mlme_priv *pmlmepriv;
pmlmepriv = &padapter->mlmepriv;
if (check_fwstate(pmlmepriv, WIFI_ASOC_STATE) == true) {
if (check_fwstate(pmlmepriv, WIFI_AP_STATE) == true)
return true;
if (pmlmepriv->LinkDetectInfo.bBusyTraffic)
return true;
}
return false;
}
static u32 _halbtcoutsrc_GetWifiLinkStatus(struct adapter *padapter)
{
struct mlme_priv *pmlmepriv;
u8 bp2p;
u32 portConnectedStatus;
pmlmepriv = &padapter->mlmepriv;
bp2p = false;
portConnectedStatus = 0;
if (check_fwstate(pmlmepriv, WIFI_ASOC_STATE) == true) {
if (check_fwstate(pmlmepriv, WIFI_AP_STATE) == true) {
if (bp2p)
portConnectedStatus |= WIFI_P2P_GO_CONNECTED;
else
portConnectedStatus |= WIFI_AP_CONNECTED;
} else {
if (bp2p)
portConnectedStatus |= WIFI_P2P_GC_CONNECTED;
else
portConnectedStatus |= WIFI_STA_CONNECTED;
}
}
return portConnectedStatus;
}
static u32 halbtcoutsrc_GetWifiLinkStatus(struct btc_coexist *pBtCoexist)
{
struct adapter *padapter;
u32 retVal;
u32 portConnectedStatus, numOfConnectedPort;
padapter = pBtCoexist->Adapter;
portConnectedStatus = 0;
numOfConnectedPort = 0;
retVal = _halbtcoutsrc_GetWifiLinkStatus(padapter);
if (retVal) {
portConnectedStatus |= retVal;
numOfConnectedPort++;
}
retVal = (numOfConnectedPort << 16) | portConnectedStatus;
return retVal;
}
static u32 halbtcoutsrc_GetBtPatchVer(struct btc_coexist *pBtCoexist)
{
return pBtCoexist->btInfo.btRealFwVer;
}
static s32 halbtcoutsrc_GetWifiRssi(struct adapter *padapter)
{
struct hal_com_data *pHalData = GET_HAL_DATA(padapter);
return pHalData->dmpriv.EntryMinUndecoratedSmoothedPWDB;
}
static u8 halbtcoutsrc_GetWifiScanAPNum(struct adapter *padapter)
{
struct mlme_ext_priv *pmlmeext;
static u8 scan_AP_num;
pmlmeext = &padapter->mlmeextpriv;
if (!GLBtcWiFiInScanState) {
if (pmlmeext->sitesurvey_res.bss_cnt > 0xFF)
scan_AP_num = 0xFF;
else
scan_AP_num = (u8)pmlmeext->sitesurvey_res.bss_cnt;
}
return scan_AP_num;
}
static u8 halbtcoutsrc_Get(void *pBtcContext, u8 getType, void *pOutBuf)
{
struct btc_coexist *pBtCoexist;
struct adapter *padapter;
struct hal_com_data *pHalData;
struct mlme_ext_priv *mlmeext;
u8 *pu8;
s32 *pS4Tmp;
u32 *pU4Tmp;
u8 ret;
pBtCoexist = (struct btc_coexist *)pBtcContext;
if (!halbtcoutsrc_IsBtCoexistAvailable(pBtCoexist))
return false;
padapter = pBtCoexist->Adapter;
pHalData = GET_HAL_DATA(padapter);
mlmeext = &padapter->mlmeextpriv;
pu8 = pOutBuf;
pS4Tmp = pOutBuf;
pU4Tmp = pOutBuf;
ret = true;
switch (getType) {
case BTC_GET_BL_HS_OPERATION:
*pu8 = false;
ret = false;
break;
case BTC_GET_BL_HS_CONNECTING:
*pu8 = false;
ret = false;
break;
case BTC_GET_BL_WIFI_CONNECTED:
*pu8 = check_fwstate(&padapter->mlmepriv, WIFI_ASOC_STATE);
break;
case BTC_GET_BL_WIFI_BUSY:
*pu8 = halbtcoutsrc_IsWifiBusy(padapter);
break;
case BTC_GET_BL_WIFI_SCAN:
*pu8 = GLBtcWiFiInScanState;
break;
case BTC_GET_BL_WIFI_LINK:
*pu8 = check_fwstate(&padapter->mlmepriv, WIFI_UNDER_LINKING);
break;
case BTC_GET_BL_WIFI_ROAM:
*pu8 = check_fwstate(&padapter->mlmepriv, WIFI_UNDER_LINKING);
break;
case BTC_GET_BL_WIFI_4_WAY_PROGRESS:
*pu8 = false;
break;
case BTC_GET_BL_WIFI_AP_MODE_ENABLE:
*pu8 = check_fwstate(&padapter->mlmepriv, WIFI_AP_STATE);
break;
case BTC_GET_BL_WIFI_ENABLE_ENCRYPTION:
*pu8 = padapter->securitypriv.dot11PrivacyAlgrthm != 0;
break;
case BTC_GET_BL_WIFI_UNDER_B_MODE:
if (mlmeext->cur_wireless_mode == WIRELESS_11B)
*pu8 = true;
else
*pu8 = false;
break;
case BTC_GET_BL_WIFI_IS_IN_MP_MODE:
*pu8 = false;
break;
case BTC_GET_BL_EXT_SWITCH:
*pu8 = false;
break;
case BTC_GET_S4_WIFI_RSSI:
*pS4Tmp = halbtcoutsrc_GetWifiRssi(padapter);
break;
case BTC_GET_S4_HS_RSSI:
*pS4Tmp = 0;
ret = false;
break;
case BTC_GET_U4_WIFI_BW:
if (is_legacy_only(mlmeext->cur_wireless_mode))
*pU4Tmp = BTC_WIFI_BW_LEGACY;
else if (pHalData->CurrentChannelBW == CHANNEL_WIDTH_20)
*pU4Tmp = BTC_WIFI_BW_HT20;
else
*pU4Tmp = BTC_WIFI_BW_HT40;
break;
case BTC_GET_U4_WIFI_TRAFFIC_DIRECTION:
{
struct rt_link_detect_t *plinkinfo;
plinkinfo = &padapter->mlmepriv.LinkDetectInfo;
if (plinkinfo->NumTxOkInPeriod > plinkinfo->NumRxOkInPeriod)
*pU4Tmp = BTC_WIFI_TRAFFIC_TX;
else
*pU4Tmp = BTC_WIFI_TRAFFIC_RX;
}
break;
case BTC_GET_U4_WIFI_FW_VER:
*pU4Tmp = pHalData->FirmwareVersion << 16;
*pU4Tmp |= pHalData->FirmwareSubVersion;
break;
case BTC_GET_U4_WIFI_LINK_STATUS:
*pU4Tmp = halbtcoutsrc_GetWifiLinkStatus(pBtCoexist);
break;
case BTC_GET_U4_BT_PATCH_VER:
*pU4Tmp = halbtcoutsrc_GetBtPatchVer(pBtCoexist);
break;
case BTC_GET_U1_WIFI_DOT11_CHNL:
*pu8 = padapter->mlmeextpriv.cur_channel;
break;
case BTC_GET_U1_WIFI_CENTRAL_CHNL:
*pu8 = pHalData->CurrentChannel;
break;
case BTC_GET_U1_WIFI_HS_CHNL:
*pu8 = 0;
ret = false;
break;
case BTC_GET_U1_MAC_PHY_MODE:
*pu8 = BTC_SMSP;
break;
case BTC_GET_U1_AP_NUM:
*pu8 = halbtcoutsrc_GetWifiScanAPNum(padapter);
break;
case BTC_GET_U1_LPS_MODE:
*pu8 = padapter->dvobj->pwrctl_priv.pwr_mode;
break;
default:
ret = false;
break;
}
return ret;
}
static u8 halbtcoutsrc_Set(void *pBtcContext, u8 setType, void *pInBuf)
{
struct btc_coexist *pBtCoexist;
struct adapter *padapter;
u8 *pu8;
u32 *pU4Tmp;
u8 ret;
pBtCoexist = (struct btc_coexist *)pBtcContext;
padapter = pBtCoexist->Adapter;
pu8 = pInBuf;
pU4Tmp = pInBuf;
ret = true;
if (!halbtcoutsrc_IsBtCoexistAvailable(pBtCoexist))
return false;
switch (setType) {
case BTC_SET_BL_BT_DISABLE:
pBtCoexist->btInfo.bBtDisabled = *pu8;
break;
case BTC_SET_BL_BT_TRAFFIC_BUSY:
pBtCoexist->btInfo.bBtBusy = *pu8;
break;
case BTC_SET_BL_BT_LIMITED_DIG:
pBtCoexist->btInfo.bLimitedDig = *pu8;
break;
case BTC_SET_BL_FORCE_TO_ROAM:
pBtCoexist->btInfo.bForceToRoam = *pu8;
break;
case BTC_SET_BL_TO_REJ_AP_AGG_PKT:
pBtCoexist->btInfo.bRejectAggPkt = *pu8;
break;
case BTC_SET_BL_BT_CTRL_AGG_SIZE:
pBtCoexist->btInfo.bBtCtrlAggBufSize = *pu8;
break;
case BTC_SET_BL_INC_SCAN_DEV_NUM:
pBtCoexist->btInfo.bIncreaseScanDevNum = *pu8;
break;
case BTC_SET_BL_BT_TX_RX_MASK:
pBtCoexist->btInfo.bBtTxRxMask = *pu8;
break;
case BTC_SET_U1_RSSI_ADJ_VAL_FOR_AGC_TABLE_ON:
pBtCoexist->btInfo.rssiAdjustForAgcTableOn = *pu8;
break;
case BTC_SET_U1_AGG_BUF_SIZE:
pBtCoexist->btInfo.aggBufSize = *pu8;
break;
case BTC_SET_ACT_GET_BT_RSSI:
ret = false;
break;
case BTC_SET_ACT_AGGREGATE_CTRL:
halbtcoutsrc_AggregationCheck(pBtCoexist);
break;
case BTC_SET_U1_RSSI_ADJ_VAL_FOR_1ANT_COEX_TYPE:
pBtCoexist->btInfo.rssiAdjustFor1AntCoexType = *pu8;
break;
case BTC_SET_U1_LPS_VAL:
pBtCoexist->btInfo.lpsVal = *pu8;
break;
case BTC_SET_U1_RPWM_VAL:
pBtCoexist->btInfo.rpwmVal = *pu8;
break;
case BTC_SET_ACT_LEAVE_LPS:
halbtcoutsrc_LeaveLps(pBtCoexist);
break;
case BTC_SET_ACT_ENTER_LPS:
halbtcoutsrc_EnterLps(pBtCoexist);
break;
case BTC_SET_ACT_NORMAL_LPS:
halbtcoutsrc_NormalLps(pBtCoexist);
break;
case BTC_SET_ACT_DISABLE_LOW_POWER:
halbtcoutsrc_DisableLowPower(pBtCoexist, *pu8);
break;
case BTC_SET_ACT_UPDATE_RAMASK:
pBtCoexist->btInfo.raMask = *pU4Tmp;
if (check_fwstate(&padapter->mlmepriv, WIFI_ASOC_STATE) == true) {
struct sta_info *psta;
struct wlan_bssid_ex *cur_network;
cur_network = &padapter->mlmeextpriv.mlmext_info.network;
psta = rtw_get_stainfo(&padapter->stapriv, cur_network->mac_address);
rtw_hal_update_ra_mask(psta, 0);
}
break;
case BTC_SET_ACT_SEND_MIMO_PS:
ret = false;
break;
case BTC_SET_ACT_CTRL_BT_INFO:
ret = false;
break;
case BTC_SET_ACT_CTRL_BT_COEX:
ret = false;
break;
case BTC_SET_ACT_CTRL_8723B_ANT:
ret = false;
break;
default:
ret = false;
break;
}
return ret;
}
static u8 halbtcoutsrc_Read1Byte(void *pBtcContext, u32 RegAddr)
{
struct btc_coexist *pBtCoexist;
struct adapter *padapter;
pBtCoexist = (struct btc_coexist *)pBtcContext;
padapter = pBtCoexist->Adapter;
return rtw_read8(padapter, RegAddr);
}
static u16 halbtcoutsrc_Read2Byte(void *pBtcContext, u32 RegAddr)
{
struct btc_coexist *pBtCoexist;
struct adapter *padapter;
pBtCoexist = (struct btc_coexist *)pBtcContext;
padapter = pBtCoexist->Adapter;
return rtw_read16(padapter, RegAddr);
}
static u32 halbtcoutsrc_Read4Byte(void *pBtcContext, u32 RegAddr)
{
struct btc_coexist *pBtCoexist;
struct adapter *padapter;
pBtCoexist = (struct btc_coexist *)pBtcContext;
padapter = pBtCoexist->Adapter;
return rtw_read32(padapter, RegAddr);
}
static void halbtcoutsrc_Write1Byte(void *pBtcContext, u32 RegAddr, u8 Data)
{
struct btc_coexist *pBtCoexist;
struct adapter *padapter;
pBtCoexist = (struct btc_coexist *)pBtcContext;
padapter = pBtCoexist->Adapter;
rtw_write8(padapter, RegAddr, Data);
}
static void halbtcoutsrc_BitMaskWrite1Byte(void *pBtcContext, u32 regAddr, u8 bitMask, u8 data1b)
{
struct btc_coexist *pBtCoexist;
struct adapter *padapter;
u8 originalValue, bitShift;
u8 i;
pBtCoexist = (struct btc_coexist *)pBtcContext;
padapter = pBtCoexist->Adapter;
originalValue = 0;
bitShift = 0;
if (bitMask != 0xFF) {
originalValue = rtw_read8(padapter, regAddr);
for (i = 0; i <= 7; i++) {
if ((bitMask >> i) & 0x1)
break;
}
bitShift = i;
data1b = (originalValue & ~bitMask) | ((data1b << bitShift) & bitMask);
}
rtw_write8(padapter, regAddr, data1b);
}
static void halbtcoutsrc_Write2Byte(void *pBtcContext, u32 RegAddr, u16 Data)
{
struct btc_coexist *pBtCoexist;
struct adapter *padapter;
pBtCoexist = (struct btc_coexist *)pBtcContext;
padapter = pBtCoexist->Adapter;
rtw_write16(padapter, RegAddr, Data);
}
static void halbtcoutsrc_Write4Byte(void *pBtcContext, u32 RegAddr, u32 Data)
{
struct btc_coexist *pBtCoexist;
struct adapter *padapter;
pBtCoexist = (struct btc_coexist *)pBtcContext;
padapter = pBtCoexist->Adapter;
rtw_write32(padapter, RegAddr, Data);
}
static void halbtcoutsrc_WriteLocalReg1Byte(void *pBtcContext, u32 RegAddr, u8 Data)
{
struct btc_coexist *pBtCoexist = (struct btc_coexist *)pBtcContext;
struct adapter *Adapter = pBtCoexist->Adapter;
if (BTC_INTF_SDIO == pBtCoexist->chipInterface)
rtw_write8(Adapter, SDIO_LOCAL_BASE | RegAddr, Data);
else
rtw_write8(Adapter, RegAddr, Data);
}
static void halbtcoutsrc_SetBbReg(void *pBtcContext, u32 RegAddr, u32 BitMask, u32 Data)
{
struct btc_coexist *pBtCoexist;
struct adapter *padapter;
pBtCoexist = (struct btc_coexist *)pBtcContext;
padapter = pBtCoexist->Adapter;
PHY_SetBBReg(padapter, RegAddr, BitMask, Data);
}
static u32 halbtcoutsrc_GetBbReg(void *pBtcContext, u32 RegAddr, u32 BitMask)
{
struct btc_coexist *pBtCoexist;
struct adapter *padapter;
pBtCoexist = (struct btc_coexist *)pBtcContext;
padapter = pBtCoexist->Adapter;
return PHY_QueryBBReg(padapter, RegAddr, BitMask);
}
static void halbtcoutsrc_SetRfReg(void *pBtcContext, u8 eRFPath, u32 RegAddr, u32 BitMask, u32 Data)
{
struct btc_coexist *pBtCoexist;
struct adapter *padapter;
pBtCoexist = (struct btc_coexist *)pBtcContext;
padapter = pBtCoexist->Adapter;
PHY_SetRFReg(padapter, eRFPath, RegAddr, BitMask, Data);
}
static u32 halbtcoutsrc_GetRfReg(void *pBtcContext, u8 eRFPath, u32 RegAddr, u32 BitMask)
{
struct btc_coexist *pBtCoexist;
struct adapter *padapter;
pBtCoexist = (struct btc_coexist *)pBtcContext;
padapter = pBtCoexist->Adapter;
return PHY_QueryRFReg(padapter, eRFPath, RegAddr, BitMask);
}
static void halbtcoutsrc_SetBtReg(void *pBtcContext, u8 RegType, u32 RegAddr, u32 Data)
{
struct btc_coexist *pBtCoexist;
struct adapter *padapter;
u8 CmdBuffer1[4] = {0};
u8 CmdBuffer2[4] = {0};
u8 *AddrToSet = (u8 *)&RegAddr;
u8 *ValueToSet = (u8 *)&Data;
u8 OperVer = 0;
u8 ReqNum = 0;
pBtCoexist = (struct btc_coexist *)pBtcContext;
padapter = pBtCoexist->Adapter;
CmdBuffer1[0] |= (OperVer & 0x0f);
CmdBuffer1[0] |= ((ReqNum << 4) & 0xf0);
CmdBuffer1[1] = 0x0d;
CmdBuffer1[2] = ValueToSet[0];
rtw_hal_fill_h2c_cmd(padapter, 0x67, 4, &(CmdBuffer1[0]));
msleep(200);
ReqNum++;
CmdBuffer2[0] |= (OperVer & 0x0f);
CmdBuffer2[0] |= ((ReqNum << 4) & 0xf0);
CmdBuffer2[1] = 0x0c;
CmdBuffer2[3] = AddrToSet[0];
rtw_hal_fill_h2c_cmd(padapter, 0x67, 4, &(CmdBuffer2[0]));
}
static u32 halbtcoutsrc_GetBtReg(void *pBtcContext, u8 RegType, u32 RegAddr)
{
return 0;
}
static void halbtcoutsrc_FillH2cCmd(void *pBtcContext, u8 elementId, u32 cmdLen, u8 *pCmdBuffer)
{
struct btc_coexist *pBtCoexist;
struct adapter *padapter;
pBtCoexist = (struct btc_coexist *)pBtcContext;
padapter = pBtCoexist->Adapter;
rtw_hal_fill_h2c_cmd(padapter, elementId, cmdLen, pCmdBuffer);
}
static u8 EXhalbtcoutsrc_BindBtCoexWithAdapter(void *padapter)
{
struct btc_coexist *pBtCoexist = &GLBtCoexist;
if (pBtCoexist->bBinded)
return false;
else
pBtCoexist->bBinded = true;
pBtCoexist->statistics.cntBind++;
pBtCoexist->Adapter = padapter;
pBtCoexist->stackInfo.bProfileNotified = false;
pBtCoexist->btInfo.bBtCtrlAggBufSize = false;
pBtCoexist->btInfo.aggBufSize = 5;
pBtCoexist->btInfo.bIncreaseScanDevNum = false;
pBtCoexist->boardInfo.btdmAntPos = BTC_ANTENNA_AT_MAIN_PORT;
return true;
}
void hal_btcoex_Initialize(void *padapter)
{
struct btc_coexist *pBtCoexist;
memset(&GLBtCoexist, 0, sizeof(GLBtCoexist));
pBtCoexist = &GLBtCoexist;
pBtCoexist->chipInterface = BTC_INTF_SDIO;
EXhalbtcoutsrc_BindBtCoexWithAdapter(padapter);
pBtCoexist->fBtcRead1Byte = halbtcoutsrc_Read1Byte;
pBtCoexist->fBtcWrite1Byte = halbtcoutsrc_Write1Byte;
pBtCoexist->fBtcWrite1ByteBitMask = halbtcoutsrc_BitMaskWrite1Byte;
pBtCoexist->fBtcRead2Byte = halbtcoutsrc_Read2Byte;
pBtCoexist->fBtcWrite2Byte = halbtcoutsrc_Write2Byte;
pBtCoexist->fBtcRead4Byte = halbtcoutsrc_Read4Byte;
pBtCoexist->fBtcWrite4Byte = halbtcoutsrc_Write4Byte;
pBtCoexist->fBtcWriteLocalReg1Byte = halbtcoutsrc_WriteLocalReg1Byte;
pBtCoexist->fBtcSetBbReg = halbtcoutsrc_SetBbReg;
pBtCoexist->fBtcGetBbReg = halbtcoutsrc_GetBbReg;
pBtCoexist->fBtcSetRfReg = halbtcoutsrc_SetRfReg;
pBtCoexist->fBtcGetRfReg = halbtcoutsrc_GetRfReg;
pBtCoexist->fBtcFillH2c = halbtcoutsrc_FillH2cCmd;
pBtCoexist->fBtcGet = halbtcoutsrc_Get;
pBtCoexist->fBtcSet = halbtcoutsrc_Set;
pBtCoexist->fBtcGetBtReg = halbtcoutsrc_GetBtReg;
pBtCoexist->fBtcSetBtReg = halbtcoutsrc_SetBtReg;
pBtCoexist->boardInfo.singleAntPath = 0;
GLBtcWiFiInScanState = false;
GLBtcWiFiInIQKState = false;
}
void EXhalbtcoutsrc_PowerOnSetting(struct btc_coexist *pBtCoexist)
{
if (!halbtcoutsrc_IsBtCoexistAvailable(pBtCoexist))
return;
if (pBtCoexist->boardInfo.btdmAntNum == 2)
EXhalbtc8723b2ant_PowerOnSetting(pBtCoexist);
else if (pBtCoexist->boardInfo.btdmAntNum == 1)
EXhalbtc8723b1ant_PowerOnSetting(pBtCoexist);
}
void EXhalbtcoutsrc_InitHwConfig(struct btc_coexist *pBtCoexist, u8 bWifiOnly)
{
if (!halbtcoutsrc_IsBtCoexistAvailable(pBtCoexist))
return;
pBtCoexist->statistics.cntInitHwConfig++;
if (pBtCoexist->boardInfo.btdmAntNum == 2)
EXhalbtc8723b2ant_InitHwConfig(pBtCoexist, bWifiOnly);
else if (pBtCoexist->boardInfo.btdmAntNum == 1)
EXhalbtc8723b1ant_InitHwConfig(pBtCoexist, bWifiOnly);
}
void EXhalbtcoutsrc_InitCoexDm(struct btc_coexist *pBtCoexist)
{
if (!halbtcoutsrc_IsBtCoexistAvailable(pBtCoexist))
return;
pBtCoexist->statistics.cntInitCoexDm++;
if (pBtCoexist->boardInfo.btdmAntNum == 2)
EXhalbtc8723b2ant_InitCoexDm(pBtCoexist);
else if (pBtCoexist->boardInfo.btdmAntNum == 1)
EXhalbtc8723b1ant_InitCoexDm(pBtCoexist);
pBtCoexist->bInitilized = true;
}
void EXhalbtcoutsrc_IpsNotify(struct btc_coexist *pBtCoexist, u8 type)
{
u8 ipsType;
if (!halbtcoutsrc_IsBtCoexistAvailable(pBtCoexist))
return;
pBtCoexist->statistics.cntIpsNotify++;
if (pBtCoexist->bManualControl)
return;
if (IPS_NONE == type)
ipsType = BTC_IPS_LEAVE;
else
ipsType = BTC_IPS_ENTER;
if (pBtCoexist->boardInfo.btdmAntNum == 2)
EXhalbtc8723b2ant_IpsNotify(pBtCoexist, ipsType);
else if (pBtCoexist->boardInfo.btdmAntNum == 1)
EXhalbtc8723b1ant_IpsNotify(pBtCoexist, ipsType);
}
void EXhalbtcoutsrc_LpsNotify(struct btc_coexist *pBtCoexist, u8 type)
{
u8 lpsType;
if (!halbtcoutsrc_IsBtCoexistAvailable(pBtCoexist))
return;
pBtCoexist->statistics.cntLpsNotify++;
if (pBtCoexist->bManualControl)
return;
if (PS_MODE_ACTIVE == type)
lpsType = BTC_LPS_DISABLE;
else
lpsType = BTC_LPS_ENABLE;
if (pBtCoexist->boardInfo.btdmAntNum == 2)
EXhalbtc8723b2ant_LpsNotify(pBtCoexist, lpsType);
else if (pBtCoexist->boardInfo.btdmAntNum == 1)
EXhalbtc8723b1ant_LpsNotify(pBtCoexist, lpsType);
}
void EXhalbtcoutsrc_ScanNotify(struct btc_coexist *pBtCoexist, u8 type)
{
u8 scanType;
if (!halbtcoutsrc_IsBtCoexistAvailable(pBtCoexist))
return;
pBtCoexist->statistics.cntScanNotify++;
if (pBtCoexist->bManualControl)
return;
if (type) {
scanType = BTC_SCAN_START;
GLBtcWiFiInScanState = true;
} else {
scanType = BTC_SCAN_FINISH;
GLBtcWiFiInScanState = false;
}
if (pBtCoexist->boardInfo.btdmAntNum == 2)
EXhalbtc8723b2ant_ScanNotify(pBtCoexist, scanType);
else if (pBtCoexist->boardInfo.btdmAntNum == 1)
EXhalbtc8723b1ant_ScanNotify(pBtCoexist, scanType);
}
void EXhalbtcoutsrc_ConnectNotify(struct btc_coexist *pBtCoexist, u8 action)
{
u8 assoType;
if (!halbtcoutsrc_IsBtCoexistAvailable(pBtCoexist))
return;
pBtCoexist->statistics.cntConnectNotify++;
if (pBtCoexist->bManualControl)
return;
if (action)
assoType = BTC_ASSOCIATE_START;
else
assoType = BTC_ASSOCIATE_FINISH;
if (pBtCoexist->boardInfo.btdmAntNum == 2)
EXhalbtc8723b2ant_ConnectNotify(pBtCoexist, assoType);
else if (pBtCoexist->boardInfo.btdmAntNum == 1)
EXhalbtc8723b1ant_ConnectNotify(pBtCoexist, assoType);
}
void EXhalbtcoutsrc_MediaStatusNotify(struct btc_coexist *pBtCoexist, enum
rt_media_status mediaStatus)
{
u8 mStatus;
if (!halbtcoutsrc_IsBtCoexistAvailable(pBtCoexist))
return;
pBtCoexist->statistics.cntMediaStatusNotify++;
if (pBtCoexist->bManualControl)
return;
if (RT_MEDIA_CONNECT == mediaStatus)
mStatus = BTC_MEDIA_CONNECT;
else
mStatus = BTC_MEDIA_DISCONNECT;
if (pBtCoexist->boardInfo.btdmAntNum == 2)
EXhalbtc8723b2ant_MediaStatusNotify(pBtCoexist, mStatus);
else if (pBtCoexist->boardInfo.btdmAntNum == 1)
EXhalbtc8723b1ant_MediaStatusNotify(pBtCoexist, mStatus);
}
void EXhalbtcoutsrc_SpecialPacketNotify(struct btc_coexist *pBtCoexist, u8 pktType)
{
u8 packetType;
if (!halbtcoutsrc_IsBtCoexistAvailable(pBtCoexist))
return;
pBtCoexist->statistics.cntSpecialPacketNotify++;
if (pBtCoexist->bManualControl)
return;
if (PACKET_DHCP == pktType) {
packetType = BTC_PACKET_DHCP;
} else if (PACKET_EAPOL == pktType) {
packetType = BTC_PACKET_EAPOL;
} else if (PACKET_ARP == pktType) {
packetType = BTC_PACKET_ARP;
} else {
return;
}
if (pBtCoexist->boardInfo.btdmAntNum == 2)
EXhalbtc8723b2ant_SpecialPacketNotify(pBtCoexist, packetType);
else if (pBtCoexist->boardInfo.btdmAntNum == 1)
EXhalbtc8723b1ant_SpecialPacketNotify(pBtCoexist, packetType);
}
void EXhalbtcoutsrc_BtInfoNotify(struct btc_coexist *pBtCoexist, u8 *tmpBuf, u8 length)
{
if (!halbtcoutsrc_IsBtCoexistAvailable(pBtCoexist))
return;
pBtCoexist->statistics.cntBtInfoNotify++;
if (pBtCoexist->boardInfo.btdmAntNum == 2)
EXhalbtc8723b2ant_BtInfoNotify(pBtCoexist, tmpBuf, length);
else if (pBtCoexist->boardInfo.btdmAntNum == 1)
EXhalbtc8723b1ant_BtInfoNotify(pBtCoexist, tmpBuf, length);
}
void EXhalbtcoutsrc_HaltNotify(struct btc_coexist *pBtCoexist)
{
if (!halbtcoutsrc_IsBtCoexistAvailable(pBtCoexist))
return;
if (pBtCoexist->boardInfo.btdmAntNum == 2)
EXhalbtc8723b2ant_HaltNotify(pBtCoexist);
else if (pBtCoexist->boardInfo.btdmAntNum == 1)
EXhalbtc8723b1ant_HaltNotify(pBtCoexist);
pBtCoexist->bBinded = false;
}
void EXhalbtcoutsrc_PnpNotify(struct btc_coexist *pBtCoexist, u8 pnpState)
{
if (!halbtcoutsrc_IsBtCoexistAvailable(pBtCoexist))
return;
if (pBtCoexist->boardInfo.btdmAntNum == 1)
EXhalbtc8723b1ant_PnpNotify(pBtCoexist, pnpState);
else if (pBtCoexist->boardInfo.btdmAntNum == 2)
EXhalbtc8723b2ant_PnpNotify(pBtCoexist, pnpState);
}
void EXhalbtcoutsrc_Periodical(struct btc_coexist *pBtCoexist)
{
if (!halbtcoutsrc_IsBtCoexistAvailable(pBtCoexist))
return;
pBtCoexist->statistics.cntPeriodical++;
if (pBtCoexist->boardInfo.btdmAntNum == 2)
EXhalbtc8723b2ant_Periodical(pBtCoexist);
else if (pBtCoexist->boardInfo.btdmAntNum == 1)
EXhalbtc8723b1ant_Periodical(pBtCoexist);
}
void EXhalbtcoutsrc_SetAntNum(u8 type, u8 antNum)
{
if (BT_COEX_ANT_TYPE_PG == type) {
GLBtCoexist.boardInfo.pgAntNum = antNum;
GLBtCoexist.boardInfo.btdmAntNum = antNum;
} else if (BT_COEX_ANT_TYPE_ANTDIV == type) {
GLBtCoexist.boardInfo.btdmAntNum = antNum;
} else if (BT_COEX_ANT_TYPE_DETECTED == type) {
GLBtCoexist.boardInfo.btdmAntNum = antNum;
}
}
void EXhalbtcoutsrc_SetSingleAntPath(u8 singleAntPath)
{
GLBtCoexist.boardInfo.singleAntPath = singleAntPath;
}
void hal_btcoex_SetBTCoexist(struct adapter *padapter, u8 bBtExist)
{
struct hal_com_data *pHalData;
pHalData = GET_HAL_DATA(padapter);
pHalData->bt_coexist.bBtExist = bBtExist;
}
bool hal_btcoex_IsBtExist(struct adapter *padapter)
{
struct hal_com_data *pHalData;
pHalData = GET_HAL_DATA(padapter);
return pHalData->bt_coexist.bBtExist;
}
bool hal_btcoex_IsBtDisabled(struct adapter *padapter)
{
if (!hal_btcoex_IsBtExist(padapter))
return true;
if (GLBtCoexist.btInfo.bBtDisabled)
return true;
else
return false;
}
void hal_btcoex_SetPgAntNum(struct adapter *padapter, u8 antNum)
{
struct hal_com_data *pHalData;
pHalData = GET_HAL_DATA(padapter);
pHalData->bt_coexist.btTotalAntNum = antNum;
EXhalbtcoutsrc_SetAntNum(BT_COEX_ANT_TYPE_PG, antNum);
}
void hal_btcoex_SetSingleAntPath(struct adapter *padapter, u8 singleAntPath)
{
EXhalbtcoutsrc_SetSingleAntPath(singleAntPath);
}
void hal_btcoex_PowerOnSetting(struct adapter *padapter)
{
EXhalbtcoutsrc_PowerOnSetting(&GLBtCoexist);
}
void hal_btcoex_InitHwConfig(struct adapter *padapter, u8 bWifiOnly)
{
if (!hal_btcoex_IsBtExist(padapter))
return;
EXhalbtcoutsrc_InitHwConfig(&GLBtCoexist, bWifiOnly);
EXhalbtcoutsrc_InitCoexDm(&GLBtCoexist);
}
void hal_btcoex_IpsNotify(struct adapter *padapter, u8 type)
{
EXhalbtcoutsrc_IpsNotify(&GLBtCoexist, type);
}
void hal_btcoex_LpsNotify(struct adapter *padapter, u8 type)
{
EXhalbtcoutsrc_LpsNotify(&GLBtCoexist, type);
}
void hal_btcoex_ScanNotify(struct adapter *padapter, u8 type)
{
EXhalbtcoutsrc_ScanNotify(&GLBtCoexist, type);
}
void hal_btcoex_ConnectNotify(struct adapter *padapter, u8 action)
{
EXhalbtcoutsrc_ConnectNotify(&GLBtCoexist, action);
}
void hal_btcoex_MediaStatusNotify(struct adapter *padapter, u8 mediaStatus)
{
EXhalbtcoutsrc_MediaStatusNotify(&GLBtCoexist, mediaStatus);
}
void hal_btcoex_SpecialPacketNotify(struct adapter *padapter, u8 pktType)
{
EXhalbtcoutsrc_SpecialPacketNotify(&GLBtCoexist, pktType);
}
void hal_btcoex_IQKNotify(struct adapter *padapter, u8 state)
{
GLBtcWiFiInIQKState = state;
}
void hal_btcoex_BtInfoNotify(struct adapter *padapter, u8 length, u8 *tmpBuf)
{
if (GLBtcWiFiInIQKState)
return;
EXhalbtcoutsrc_BtInfoNotify(&GLBtCoexist, tmpBuf, length);
}
void hal_btcoex_SuspendNotify(struct adapter *padapter, u8 state)
{
if (state == 1)
state = BTC_WIFI_PNP_SLEEP;
else
state = BTC_WIFI_PNP_WAKE_UP;
EXhalbtcoutsrc_PnpNotify(&GLBtCoexist, state);
}
void hal_btcoex_HaltNotify(struct adapter *padapter)
{
EXhalbtcoutsrc_HaltNotify(&GLBtCoexist);
}
void hal_btcoex_Handler(struct adapter *padapter)
{
EXhalbtcoutsrc_Periodical(&GLBtCoexist);
}
s32 hal_btcoex_IsBTCoexCtrlAMPDUSize(struct adapter *padapter)
{
return (s32)GLBtCoexist.btInfo.bBtCtrlAggBufSize;
}
bool hal_btcoex_IsBtControlLps(struct adapter *padapter)
{
if (!hal_btcoex_IsBtExist(padapter))
return false;
if (GLBtCoexist.btInfo.bBtDisabled)
return false;
if (GLBtCoexist.btInfo.bBtCtrlLps)
return true;
return false;
}
bool hal_btcoex_IsLpsOn(struct adapter *padapter)
{
if (!hal_btcoex_IsBtExist(padapter))
return false;
if (GLBtCoexist.btInfo.bBtDisabled)
return false;
if (GLBtCoexist.btInfo.bBtLpsOn)
return true;
return false;
}
u8 hal_btcoex_RpwmVal(struct adapter *padapter)
{
return GLBtCoexist.btInfo.rpwmVal;
}
u8 hal_btcoex_LpsVal(struct adapter *padapter)
{
return GLBtCoexist.btInfo.lpsVal;
}
u32 hal_btcoex_GetRaMask(struct adapter *padapter)
{
if (!hal_btcoex_IsBtExist(padapter))
return 0;
if (GLBtCoexist.btInfo.bBtDisabled)
return 0;
if (GLBtCoexist.boardInfo.btdmAntNum != 1)
return 0;
return GLBtCoexist.btInfo.raMask;
}
void hal_btcoex_RecordPwrMode(struct adapter *padapter, u8 *pCmdBuf, u8 cmdLen)
{
memcpy(GLBtCoexist.pwrModeVal, pCmdBuf, cmdLen);
}