1
0
mirror of https://github.com/aircrack-ng/rtl8812au.git synced 2024-11-25 14:44:09 +00:00
rtl8812au/hal/btc/HalBtc8703b1Ant.c

5000 lines
136 KiB
C
Raw Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

//============================================================
// Description:
//
// This file is for RTL8703B Co-exist mechanism
//
// History
// 2012/11/15 Cosa first check in.
//
//============================================================
//============================================================
// include files
//============================================================
#include "Mp_Precomp.h"
#if WPP_SOFTWARE_TRACE
#include "HalBtc8703b1Ant.tmh"
#endif
//#include <Math.h>
#if(BT_30_SUPPORT == 1)
//============================================================
// Global variables, these are static variables
//============================================================
static COEX_DM_8703B_1ANT GLCoexDm8703b1Ant;
static PCOEX_DM_8703B_1ANT pCoexDm=&GLCoexDm8703b1Ant;
static COEX_STA_8703B_1ANT GLCoexSta8703b1Ant;
static PCOEX_STA_8703B_1ANT pCoexSta=&GLCoexSta8703b1Ant;
static PSDSCAN_STA_8703B_1ANT GLPsdScan8703b1Ant;
static PPSDSCAN_STA_8703B_1ANT pPsdScan = &GLPsdScan8703b1Ant;
const char *const GLBtInfoSrc8703b1Ant[]={
"BT Info[wifi fw]",
"BT Info[bt rsp]",
"BT Info[bt auto report]",
};
u4Byte GLCoexVerDate8703b1Ant=20150413;
u4Byte GLCoexVer8703b1Ant=0x01;
//============================================================
// local function proto type if needed
//============================================================
//============================================================
// local function start with halbtc8703b1ant_
//============================================================
u1Byte
halbtc8703b1ant_BtRssiState(
u1Byte levelNum,
u1Byte rssiThresh,
u1Byte rssiThresh1
)
{
s4Byte btRssi=0;
u1Byte btRssiState=pCoexSta->preBtRssiState;
btRssi = pCoexSta->btRssi;
if(levelNum == 2)
{
if( (pCoexSta->preBtRssiState == BTC_RSSI_STATE_LOW) ||
(pCoexSta->preBtRssiState == BTC_RSSI_STATE_STAY_LOW))
{
if(btRssi >= (rssiThresh+BTC_RSSI_COEX_THRESH_TOL_8703B_1ANT))
{
btRssiState = BTC_RSSI_STATE_HIGH;
}
else
{
btRssiState = BTC_RSSI_STATE_STAY_LOW;
}
}
else
{
if(btRssi < rssiThresh)
{
btRssiState = BTC_RSSI_STATE_LOW;
}
else
{
btRssiState = BTC_RSSI_STATE_STAY_HIGH;
}
}
}
else if(levelNum == 3)
{
if(rssiThresh > rssiThresh1)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT Rssi thresh error!!\n"));
return pCoexSta->preBtRssiState;
}
if( (pCoexSta->preBtRssiState == BTC_RSSI_STATE_LOW) ||
(pCoexSta->preBtRssiState == BTC_RSSI_STATE_STAY_LOW))
{
if(btRssi >= (rssiThresh+BTC_RSSI_COEX_THRESH_TOL_8703B_1ANT))
{
btRssiState = BTC_RSSI_STATE_MEDIUM;
}
else
{
btRssiState = BTC_RSSI_STATE_STAY_LOW;
}
}
else if( (pCoexSta->preBtRssiState == BTC_RSSI_STATE_MEDIUM) ||
(pCoexSta->preBtRssiState == BTC_RSSI_STATE_STAY_MEDIUM))
{
if(btRssi >= (rssiThresh1+BTC_RSSI_COEX_THRESH_TOL_8703B_1ANT))
{
btRssiState = BTC_RSSI_STATE_HIGH;
}
else if(btRssi < rssiThresh)
{
btRssiState = BTC_RSSI_STATE_LOW;
}
else
{
btRssiState = BTC_RSSI_STATE_STAY_MEDIUM;
}
}
else
{
if(btRssi < rssiThresh1)
{
btRssiState = BTC_RSSI_STATE_MEDIUM;
}
else
{
btRssiState = BTC_RSSI_STATE_STAY_HIGH;
}
}
}
pCoexSta->preBtRssiState = btRssiState;
return btRssiState;
}
u1Byte
halbtc8703b1ant_WifiRssiState(
IN PBTC_COEXIST pBtCoexist,
IN u1Byte index,
IN u1Byte levelNum,
IN u1Byte rssiThresh,
IN u1Byte rssiThresh1
)
{
s4Byte wifiRssi=0;
u1Byte wifiRssiState=pCoexSta->preWifiRssiState[index];
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_S4_WIFI_RSSI, &wifiRssi);
if(levelNum == 2)
{
if( (pCoexSta->preWifiRssiState[index] == BTC_RSSI_STATE_LOW) ||
(pCoexSta->preWifiRssiState[index] == BTC_RSSI_STATE_STAY_LOW))
{
if(wifiRssi >= (rssiThresh+BTC_RSSI_COEX_THRESH_TOL_8703B_1ANT))
{
wifiRssiState = BTC_RSSI_STATE_HIGH;
}
else
{
wifiRssiState = BTC_RSSI_STATE_STAY_LOW;
}
}
else
{
if(wifiRssi < rssiThresh)
{
wifiRssiState = BTC_RSSI_STATE_LOW;
}
else
{
wifiRssiState = BTC_RSSI_STATE_STAY_HIGH;
}
}
}
else if(levelNum == 3)
{
if(rssiThresh > rssiThresh1)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], wifi RSSI thresh error!!\n"));
return pCoexSta->preWifiRssiState[index];
}
if( (pCoexSta->preWifiRssiState[index] == BTC_RSSI_STATE_LOW) ||
(pCoexSta->preWifiRssiState[index] == BTC_RSSI_STATE_STAY_LOW))
{
if(wifiRssi >= (rssiThresh+BTC_RSSI_COEX_THRESH_TOL_8703B_1ANT))
{
wifiRssiState = BTC_RSSI_STATE_MEDIUM;
}
else
{
wifiRssiState = BTC_RSSI_STATE_STAY_LOW;
}
}
else if( (pCoexSta->preWifiRssiState[index] == BTC_RSSI_STATE_MEDIUM) ||
(pCoexSta->preWifiRssiState[index] == BTC_RSSI_STATE_STAY_MEDIUM))
{
if(wifiRssi >= (rssiThresh1+BTC_RSSI_COEX_THRESH_TOL_8703B_1ANT))
{
wifiRssiState = BTC_RSSI_STATE_HIGH;
}
else if(wifiRssi < rssiThresh)
{
wifiRssiState = BTC_RSSI_STATE_LOW;
}
else
{
wifiRssiState = BTC_RSSI_STATE_STAY_MEDIUM;
}
}
else
{
if(wifiRssi < rssiThresh1)
{
wifiRssiState = BTC_RSSI_STATE_MEDIUM;
}
else
{
wifiRssiState = BTC_RSSI_STATE_STAY_HIGH;
}
}
}
pCoexSta->preWifiRssiState[index] = wifiRssiState;
return wifiRssiState;
}
VOID
halbtc8703b1ant_UpdateRaMask(
IN PBTC_COEXIST pBtCoexist,
IN BOOLEAN bForceExec,
IN u4Byte disRateMask
)
{
pCoexDm->curRaMask = disRateMask;
if( bForceExec || (pCoexDm->preRaMask != pCoexDm->curRaMask))
{
pBtCoexist->fBtcSet(pBtCoexist, BTC_SET_ACT_UPDATE_RAMASK, &pCoexDm->curRaMask);
}
pCoexDm->preRaMask = pCoexDm->curRaMask;
}
VOID
halbtc8703b1ant_AutoRateFallbackRetry(
IN PBTC_COEXIST pBtCoexist,
IN BOOLEAN bForceExec,
IN u1Byte type
)
{
BOOLEAN bWifiUnderBMode=FALSE;
pCoexDm->curArfrType = type;
if( bForceExec || (pCoexDm->preArfrType != pCoexDm->curArfrType))
{
switch(pCoexDm->curArfrType)
{
case 0: // normal mode
pBtCoexist->fBtcWrite4Byte(pBtCoexist, 0x430, pCoexDm->backupArfrCnt1);
pBtCoexist->fBtcWrite4Byte(pBtCoexist, 0x434, pCoexDm->backupArfrCnt2);
break;
case 1:
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_UNDER_B_MODE, &bWifiUnderBMode);
if(bWifiUnderBMode)
{
pBtCoexist->fBtcWrite4Byte(pBtCoexist, 0x430, 0x0);
pBtCoexist->fBtcWrite4Byte(pBtCoexist, 0x434, 0x01010101);
}
else
{
pBtCoexist->fBtcWrite4Byte(pBtCoexist, 0x430, 0x0);
pBtCoexist->fBtcWrite4Byte(pBtCoexist, 0x434, 0x04030201);
}
break;
default:
break;
}
}
pCoexDm->preArfrType = pCoexDm->curArfrType;
}
VOID
halbtc8703b1ant_RetryLimit(
IN PBTC_COEXIST pBtCoexist,
IN BOOLEAN bForceExec,
IN u1Byte type
)
{
pCoexDm->curRetryLimitType = type;
if( bForceExec || (pCoexDm->preRetryLimitType != pCoexDm->curRetryLimitType))
{
switch(pCoexDm->curRetryLimitType)
{
case 0: // normal mode
pBtCoexist->fBtcWrite2Byte(pBtCoexist, 0x42a, pCoexDm->backupRetryLimit);
break;
case 1: // retry limit=8
pBtCoexist->fBtcWrite2Byte(pBtCoexist, 0x42a, 0x0808);
break;
default:
break;
}
}
pCoexDm->preRetryLimitType = pCoexDm->curRetryLimitType;
}
VOID
halbtc8703b1ant_AmpduMaxTime(
IN PBTC_COEXIST pBtCoexist,
IN BOOLEAN bForceExec,
IN u1Byte type
)
{
pCoexDm->curAmpduTimeType = type;
if( bForceExec || (pCoexDm->preAmpduTimeType != pCoexDm->curAmpduTimeType))
{
switch(pCoexDm->curAmpduTimeType)
{
case 0: // normal mode
pBtCoexist->fBtcWrite1Byte(pBtCoexist, 0x456, pCoexDm->backupAmpduMaxTime);
break;
case 1: // AMPDU timw = 0x38 * 32us
pBtCoexist->fBtcWrite1Byte(pBtCoexist, 0x456, 0x38);
break;
default:
break;
}
}
pCoexDm->preAmpduTimeType = pCoexDm->curAmpduTimeType;
}
VOID
halbtc8703b1ant_LimitedTx(
IN PBTC_COEXIST pBtCoexist,
IN BOOLEAN bForceExec,
IN u1Byte raMaskType,
IN u1Byte arfrType,
IN u1Byte retryLimitType,
IN u1Byte ampduTimeType
)
{
switch(raMaskType)
{
case 0: // normal mode
halbtc8703b1ant_UpdateRaMask(pBtCoexist, bForceExec, 0x0);
break;
case 1: // disable cck 1/2
halbtc8703b1ant_UpdateRaMask(pBtCoexist, bForceExec, 0x00000003);
break;
case 2: // disable cck 1/2/5.5, ofdm 6/9/12/18/24, mcs 0/1/2/3/4
halbtc8703b1ant_UpdateRaMask(pBtCoexist, bForceExec, 0x0001f1f7);
break;
default:
break;
}
halbtc8703b1ant_AutoRateFallbackRetry(pBtCoexist, bForceExec, arfrType);
halbtc8703b1ant_RetryLimit(pBtCoexist, bForceExec, retryLimitType);
halbtc8703b1ant_AmpduMaxTime(pBtCoexist, bForceExec, ampduTimeType);
}
VOID
halbtc8703b1ant_LimitedRx(
IN PBTC_COEXIST pBtCoexist,
IN BOOLEAN bForceExec,
IN BOOLEAN bRejApAggPkt,
IN BOOLEAN bBtCtrlAggBufSize,
IN u1Byte aggBufSize
)
{
BOOLEAN bRejectRxAgg=bRejApAggPkt;
BOOLEAN bBtCtrlRxAggSize=bBtCtrlAggBufSize;
u1Byte rxAggSize=aggBufSize;
//============================================
// Rx Aggregation related setting
//============================================
pBtCoexist->fBtcSet(pBtCoexist, BTC_SET_BL_TO_REJ_AP_AGG_PKT, &bRejectRxAgg);
// decide BT control aggregation buf size or not
pBtCoexist->fBtcSet(pBtCoexist, BTC_SET_BL_BT_CTRL_AGG_SIZE, &bBtCtrlRxAggSize);
// aggregation buf size, only work when BT control Rx aggregation size.
pBtCoexist->fBtcSet(pBtCoexist, BTC_SET_U1_AGG_BUF_SIZE, &rxAggSize);
// real update aggregation setting
pBtCoexist->fBtcSet(pBtCoexist, BTC_SET_ACT_AGGREGATE_CTRL, NULL);
}
VOID
halbtc8703b1ant_QueryBtInfo(
IN PBTC_COEXIST pBtCoexist
)
{
u1Byte H2C_Parameter[1] ={0};
pCoexSta->bC2hBtInfoReqSent = TRUE;
H2C_Parameter[0] |= BIT0; // trigger
RT_TRACE(COMP_COEX, DBG_TRACE, ("[BTCoex], Query Bt Info, FW write 0x61=0x%x\n",
H2C_Parameter[0]));
pBtCoexist->fBtcFillH2c(pBtCoexist, 0x61, 1, H2C_Parameter);
}
VOID
halbtc8703b1ant_MonitorBtCtr(
IN PBTC_COEXIST pBtCoexist
)
{
u4Byte regHPTxRx, regLPTxRx, u4Tmp, u4Tmp1;
u4Byte regHPTx=0, regHPRx=0, regLPTx=0, regLPRx=0;
u1Byte u1Tmp, u1Tmp1;
s4Byte wifiRssi;
static u1Byte NumOfBtCounterChk = 0;
//to avoid 0x76e[3] = 1 (WLAN_Act control by PTA) during IPS
//if (! (pBtCoexist->fBtcRead1Byte(pBtCoexist, 0x76e) & 0x8) )
if (pCoexSta->bUnderIps)
{
//pCoexSta->highPriorityTx = 65535;
//pCoexSta->highPriorityRx = 65535;
//pCoexSta->lowPriorityTx = 65535;
//pCoexSta->lowPriorityRx = 65535;
//return;
}
regHPTxRx = 0x770;
regLPTxRx = 0x774;
u4Tmp = pBtCoexist->fBtcRead4Byte(pBtCoexist, regHPTxRx);
regHPTx = u4Tmp & bMaskLWord;
regHPRx = (u4Tmp & bMaskHWord)>>16;
u4Tmp = pBtCoexist->fBtcRead4Byte(pBtCoexist, regLPTxRx);
regLPTx = u4Tmp & bMaskLWord;
regLPRx = (u4Tmp & bMaskHWord)>>16;
pCoexSta->highPriorityTx = regHPTx;
pCoexSta->highPriorityRx = regHPRx;
pCoexSta->lowPriorityTx = regLPTx;
pCoexSta->lowPriorityRx = regLPRx;
if( (pCoexSta->lowPriorityTx > 1150) && (!pCoexSta->bC2hBtInquiryPage))
pCoexSta->popEventCnt++;
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Hi-Pri Rx/Tx: %d/%d, Lo-Pri Rx/Tx: %d/%d\n",
regHPRx, regHPTx, regLPRx, regLPTx));
// reset counter
pBtCoexist->fBtcWrite1Byte(pBtCoexist, 0x76e, 0xc);
if ((regHPTx == 0) && (regHPRx ==0) && (regLPTx == 0) && (regLPRx == 0))
{
NumOfBtCounterChk++;
if (NumOfBtCounterChk >= 3)
{
halbtc8703b1ant_QueryBtInfo(pBtCoexist);
NumOfBtCounterChk = 0;
}
}
}
VOID
halbtc8703b1ant_MonitorWiFiCtr(
IN PBTC_COEXIST pBtCoexist
)
{
u4Byte u4Tmp;
u2Byte u2Tmp[3];
s4Byte wifiRssi=0;
BOOLEAN bWifiBusy = FALSE, bWifiUnderBMode = FALSE;
static u1Byte nCCKLockCounter = 0;
u4Byte TotalCnt;
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_BUSY, &bWifiBusy);
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_S4_WIFI_RSSI, &wifiRssi);
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_UNDER_B_MODE, &bWifiUnderBMode);
if (pCoexSta->bUnderIps)
{
pCoexSta->nCRCOK_CCK = 0;
pCoexSta->nCRCOK_11g = 0;
pCoexSta->nCRCOK_11n = 0;
pCoexSta->nCRCOK_11nAgg = 0;
pCoexSta->nCRCErr_CCK = 0;
pCoexSta->nCRCErr_11g = 0;
pCoexSta->nCRCErr_11n = 0;
pCoexSta->nCRCErr_11nAgg = 0;
}
else
{
pCoexSta->nCRCOK_CCK = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0xf88);
pCoexSta->nCRCOK_11g = pBtCoexist->fBtcRead2Byte(pBtCoexist, 0xf94);
pCoexSta->nCRCOK_11n = pBtCoexist->fBtcRead2Byte(pBtCoexist, 0xf90);
pCoexSta->nCRCOK_11nAgg= pBtCoexist->fBtcRead2Byte(pBtCoexist, 0xfb8);
pCoexSta->nCRCErr_CCK = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0xf84);
pCoexSta->nCRCErr_11g = pBtCoexist->fBtcRead2Byte(pBtCoexist, 0xf96);
pCoexSta->nCRCErr_11n = pBtCoexist->fBtcRead2Byte(pBtCoexist, 0xf92);
pCoexSta->nCRCErr_11nAgg = pBtCoexist->fBtcRead2Byte(pBtCoexist, 0xfba);
}
//reset counter
pBtCoexist->fBtcWrite1ByteBitMask(pBtCoexist, 0xf16, 0x1, 0x1);
pBtCoexist->fBtcWrite1ByteBitMask(pBtCoexist, 0xf16, 0x1, 0x0);
if ( (bWifiBusy) && (wifiRssi >= 30) && (!bWifiUnderBMode))
{
TotalCnt = pCoexSta->nCRCOK_CCK + pCoexSta->nCRCOK_11g + pCoexSta->nCRCOK_11n +
pCoexSta->nCRCOK_11nAgg;
if ( (pCoexDm->btStatus == BT_8703B_1ANT_BT_STATUS_ACL_BUSY) ||
(pCoexDm->btStatus == BT_8703B_1ANT_BT_STATUS_ACL_SCO_BUSY) ||
(pCoexDm->btStatus == BT_8703B_1ANT_BT_STATUS_SCO_BUSY) )
{
if (pCoexSta->nCRCOK_CCK >(TotalCnt -pCoexSta->nCRCOK_CCK))
{
if (nCCKLockCounter < 3)
nCCKLockCounter++;
}
else
{
if (nCCKLockCounter > 0)
nCCKLockCounter--;
}
}
else
{
if (nCCKLockCounter > 0)
nCCKLockCounter--;
}
}
else
{
if (nCCKLockCounter > 0)
nCCKLockCounter--;
}
if (!pCoexSta->bPreCCKLock)
{
if (nCCKLockCounter >= 3)
pCoexSta->bCCKLock = TRUE;
else
pCoexSta->bCCKLock = FALSE;
}
else
{
if (nCCKLockCounter == 0)
pCoexSta->bCCKLock = FALSE;
else
pCoexSta->bCCKLock = TRUE;
}
if (pCoexSta->bCCKLock)
pCoexSta->bCCKEverLock = TRUE;
pCoexSta->bPreCCKLock = pCoexSta->bCCKLock;
}
BOOLEAN
halbtc8703b1ant_IsWifiStatusChanged(
IN PBTC_COEXIST pBtCoexist
)
{
static BOOLEAN bPreWifiBusy=FALSE, bPreUnder4way=FALSE, bPreBtHsOn=FALSE;
BOOLEAN bWifiBusy=FALSE, bUnder4way=FALSE, bBtHsOn=FALSE;
BOOLEAN bWifiConnected=FALSE;
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_CONNECTED, &bWifiConnected);
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_BUSY, &bWifiBusy);
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_HS_OPERATION, &bBtHsOn);
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_4_WAY_PROGRESS, &bUnder4way);
if(bWifiConnected)
{
if(bWifiBusy != bPreWifiBusy)
{
bPreWifiBusy = bWifiBusy;
return TRUE;
}
if(bUnder4way != bPreUnder4way)
{
bPreUnder4way = bUnder4way;
return TRUE;
}
if(bBtHsOn != bPreBtHsOn)
{
bPreBtHsOn = bBtHsOn;
return TRUE;
}
}
return FALSE;
}
VOID
halbtc8703b1ant_UpdateBtLinkInfo(
IN PBTC_COEXIST pBtCoexist
)
{
PBTC_BT_LINK_INFO pBtLinkInfo=&pBtCoexist->btLinkInfo;
BOOLEAN bBtHsOn=FALSE;
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_HS_OPERATION, &bBtHsOn);
pBtLinkInfo->bBtLinkExist = pCoexSta->bBtLinkExist;
pBtLinkInfo->bScoExist = pCoexSta->bScoExist;
pBtLinkInfo->bA2dpExist = pCoexSta->bA2dpExist;
pBtLinkInfo->bPanExist = pCoexSta->bPanExist;
pBtLinkInfo->bHidExist = pCoexSta->bHidExist;
pBtLinkInfo->bBtHiPriLinkExist = pCoexSta->bBtHiPriLinkExist;
// work around for HS mode.
if(bBtHsOn)
{
pBtLinkInfo->bPanExist = TRUE;
pBtLinkInfo->bBtLinkExist = TRUE;
}
// check if Sco only
if( pBtLinkInfo->bScoExist &&
!pBtLinkInfo->bA2dpExist &&
!pBtLinkInfo->bPanExist &&
!pBtLinkInfo->bHidExist )
pBtLinkInfo->bScoOnly = TRUE;
else
pBtLinkInfo->bScoOnly = FALSE;
// check if A2dp only
if( !pBtLinkInfo->bScoExist &&
pBtLinkInfo->bA2dpExist &&
!pBtLinkInfo->bPanExist &&
!pBtLinkInfo->bHidExist )
pBtLinkInfo->bA2dpOnly = TRUE;
else
pBtLinkInfo->bA2dpOnly = FALSE;
// check if Pan only
if( !pBtLinkInfo->bScoExist &&
!pBtLinkInfo->bA2dpExist &&
pBtLinkInfo->bPanExist &&
!pBtLinkInfo->bHidExist )
pBtLinkInfo->bPanOnly = TRUE;
else
pBtLinkInfo->bPanOnly = FALSE;
// check if Hid only
if( !pBtLinkInfo->bScoExist &&
!pBtLinkInfo->bA2dpExist &&
!pBtLinkInfo->bPanExist &&
pBtLinkInfo->bHidExist )
pBtLinkInfo->bHidOnly = TRUE;
else
pBtLinkInfo->bHidOnly = FALSE;
}
VOID
halbtc8703b1ant_UpdateWifiChannelInfo(
IN PBTC_COEXIST pBtCoexist,
IN u1Byte type
)
{
u1Byte H2C_Parameter[3] ={0};
u4Byte wifiBw;
u1Byte wifiCentralChnl;
BOOLEAN bWifiUnderBMode = FALSE;
// only 2.4G we need to inform bt the chnl mask
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_U1_WIFI_CENTRAL_CHNL, &wifiCentralChnl);
if( (BTC_MEDIA_CONNECT == type) &&
(wifiCentralChnl <= 14) )
{
H2C_Parameter[0] = 0x1; //enable BT AFH skip WL channel for 8703b because BT Rx LO interference
//H2C_Parameter[0] = 0x0;
H2C_Parameter[1] = wifiCentralChnl;
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_U4_WIFI_BW, &wifiBw);
if(BTC_WIFI_BW_HT40 == wifiBw)
H2C_Parameter[2] = 0x30;
else
H2C_Parameter[2] = 0x20;
}
pCoexDm->wifiChnlInfo[0] = H2C_Parameter[0];
pCoexDm->wifiChnlInfo[1] = H2C_Parameter[1];
pCoexDm->wifiChnlInfo[2] = H2C_Parameter[2];
RT_TRACE(COMP_COEX, DBG_TRACE, ("[BTCoex], FW write 0x66=0x%x\n",
H2C_Parameter[0]<<16|H2C_Parameter[1]<<8|H2C_Parameter[2]));
pBtCoexist->fBtcFillH2c(pBtCoexist, 0x66, 3, H2C_Parameter);
}
u1Byte
halbtc8703b1ant_ActionAlgorithm(
IN PBTC_COEXIST pBtCoexist
)
{
PBTC_BT_LINK_INFO pBtLinkInfo=&pBtCoexist->btLinkInfo;
BOOLEAN bBtHsOn=FALSE;
u1Byte algorithm=BT_8703B_1ANT_COEX_ALGO_UNDEFINED;
u1Byte numOfDiffProfile=0;
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_HS_OPERATION, &bBtHsOn);
if(!pBtLinkInfo->bBtLinkExist)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], No BT link exists!!!\n"));
return algorithm;
}
if(pBtLinkInfo->bScoExist)
numOfDiffProfile++;
if(pBtLinkInfo->bHidExist)
numOfDiffProfile++;
if(pBtLinkInfo->bPanExist)
numOfDiffProfile++;
if(pBtLinkInfo->bA2dpExist)
numOfDiffProfile++;
if(numOfDiffProfile == 1)
{
if(pBtLinkInfo->bScoExist)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT Profile = SCO only\n"));
algorithm = BT_8703B_1ANT_COEX_ALGO_SCO;
}
else
{
if(pBtLinkInfo->bHidExist)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT Profile = HID only\n"));
algorithm = BT_8703B_1ANT_COEX_ALGO_HID;
}
else if(pBtLinkInfo->bA2dpExist)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT Profile = A2DP only\n"));
algorithm = BT_8703B_1ANT_COEX_ALGO_A2DP;
}
else if(pBtLinkInfo->bPanExist)
{
if(bBtHsOn)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT Profile = PAN(HS) only\n"));
algorithm = BT_8703B_1ANT_COEX_ALGO_PANHS;
}
else
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT Profile = PAN(EDR) only\n"));
algorithm = BT_8703B_1ANT_COEX_ALGO_PANEDR;
}
}
}
}
else if(numOfDiffProfile == 2)
{
if(pBtLinkInfo->bScoExist)
{
if(pBtLinkInfo->bHidExist)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT Profile = SCO + HID\n"));
algorithm = BT_8703B_1ANT_COEX_ALGO_HID;
}
else if(pBtLinkInfo->bA2dpExist)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT Profile = SCO + A2DP ==> SCO\n"));
algorithm = BT_8703B_1ANT_COEX_ALGO_SCO;
}
else if(pBtLinkInfo->bPanExist)
{
if(bBtHsOn)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT Profile = SCO + PAN(HS)\n"));
algorithm = BT_8703B_1ANT_COEX_ALGO_SCO;
}
else
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT Profile = SCO + PAN(EDR)\n"));
algorithm = BT_8703B_1ANT_COEX_ALGO_PANEDR_HID;
}
}
}
else
{
if( pBtLinkInfo->bHidExist &&
pBtLinkInfo->bA2dpExist )
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT Profile = HID + A2DP\n"));
algorithm = BT_8703B_1ANT_COEX_ALGO_HID_A2DP;
}
else if( pBtLinkInfo->bHidExist &&
pBtLinkInfo->bPanExist )
{
if(bBtHsOn)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT Profile = HID + PAN(HS)\n"));
algorithm = BT_8703B_1ANT_COEX_ALGO_HID_A2DP;
}
else
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT Profile = HID + PAN(EDR)\n"));
algorithm = BT_8703B_1ANT_COEX_ALGO_PANEDR_HID;
}
}
else if( pBtLinkInfo->bPanExist &&
pBtLinkInfo->bA2dpExist )
{
if(bBtHsOn)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT Profile = A2DP + PAN(HS)\n"));
algorithm = BT_8703B_1ANT_COEX_ALGO_A2DP_PANHS;
}
else
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT Profile = A2DP + PAN(EDR)\n"));
algorithm = BT_8703B_1ANT_COEX_ALGO_PANEDR_A2DP;
}
}
}
}
else if(numOfDiffProfile == 3)
{
if(pBtLinkInfo->bScoExist)
{
if( pBtLinkInfo->bHidExist &&
pBtLinkInfo->bA2dpExist )
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT Profile = SCO + HID + A2DP ==> HID\n"));
algorithm = BT_8703B_1ANT_COEX_ALGO_HID;
}
else if( pBtLinkInfo->bHidExist &&
pBtLinkInfo->bPanExist )
{
if(bBtHsOn)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT Profile = SCO + HID + PAN(HS)\n"));
algorithm = BT_8703B_1ANT_COEX_ALGO_HID_A2DP;
}
else
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT Profile = SCO + HID + PAN(EDR)\n"));
algorithm = BT_8703B_1ANT_COEX_ALGO_PANEDR_HID;
}
}
else if( pBtLinkInfo->bPanExist &&
pBtLinkInfo->bA2dpExist )
{
if(bBtHsOn)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT Profile = SCO + A2DP + PAN(HS)\n"));
algorithm = BT_8703B_1ANT_COEX_ALGO_SCO;
}
else
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT Profile = SCO + A2DP + PAN(EDR) ==> HID\n"));
algorithm = BT_8703B_1ANT_COEX_ALGO_PANEDR_HID;
}
}
}
else
{
if( pBtLinkInfo->bHidExist &&
pBtLinkInfo->bPanExist &&
pBtLinkInfo->bA2dpExist )
{
if(bBtHsOn)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT Profile = HID + A2DP + PAN(HS)\n"));
algorithm = BT_8703B_1ANT_COEX_ALGO_HID_A2DP;
}
else
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT Profile = HID + A2DP + PAN(EDR)\n"));
algorithm = BT_8703B_1ANT_COEX_ALGO_HID_A2DP_PANEDR;
}
}
}
}
else if(numOfDiffProfile >= 3)
{
if(pBtLinkInfo->bScoExist)
{
if( pBtLinkInfo->bHidExist &&
pBtLinkInfo->bPanExist &&
pBtLinkInfo->bA2dpExist )
{
if(bBtHsOn)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Error!!! BT Profile = SCO + HID + A2DP + PAN(HS)\n"));
}
else
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT Profile = SCO + HID + A2DP + PAN(EDR)==>PAN(EDR)+HID\n"));
algorithm = BT_8703B_1ANT_COEX_ALGO_PANEDR_HID;
}
}
}
}
return algorithm;
}
VOID
halbtc8703b1ant_SetBtAutoReport(
IN PBTC_COEXIST pBtCoexist,
IN BOOLEAN bEnableAutoReport
)
{
u1Byte H2C_Parameter[1] ={0};
H2C_Parameter[0] = 0;
if(bEnableAutoReport)
{
H2C_Parameter[0] |= BIT0;
}
RT_TRACE(COMP_COEX, DBG_TRACE, ("[BTCoex], BT FW auto report : %s, FW write 0x68=0x%x\n",
(bEnableAutoReport? "Enabled!!":"Disabled!!"), H2C_Parameter[0]));
pBtCoexist->fBtcFillH2c(pBtCoexist, 0x68, 1, H2C_Parameter);
}
VOID
halbtc8703b1ant_BtAutoReport(
IN PBTC_COEXIST pBtCoexist,
IN BOOLEAN bForceExec,
IN BOOLEAN bEnableAutoReport
)
{
RT_TRACE(COMP_COEX, DBG_TRACE, ("[BTCoex], %s BT Auto report = %s\n",
(bForceExec? "force to":""), ((bEnableAutoReport)? "Enabled":"Disabled")));
pCoexDm->bCurBtAutoReport = bEnableAutoReport;
if(!bForceExec)
{
if(pCoexDm->bPreBtAutoReport == pCoexDm->bCurBtAutoReport)
return;
}
halbtc8703b1ant_SetBtAutoReport(pBtCoexist, pCoexDm->bCurBtAutoReport);
pCoexDm->bPreBtAutoReport = pCoexDm->bCurBtAutoReport;
}
VOID
halbtc8703b1ant_SetSwPenaltyTxRateAdaptive(
IN PBTC_COEXIST pBtCoexist,
IN BOOLEAN bLowPenaltyRa
)
{
u1Byte H2C_Parameter[6] ={0};
H2C_Parameter[0] = 0x6; // opCode, 0x6= Retry_Penalty
if(bLowPenaltyRa)
{
H2C_Parameter[1] |= BIT0;
H2C_Parameter[2] = 0x00; //normal rate except MCS7/6/5, OFDM54/48/36
H2C_Parameter[3] = 0xf7; //MCS7 or OFDM54
H2C_Parameter[4] = 0xf8; //MCS6 or OFDM48
H2C_Parameter[5] = 0xf9; //MCS5 or OFDM36
}
RT_TRACE(COMP_COEX, DBG_TRACE, ("[BTCoex], set WiFi Low-Penalty Retry: %s",
(bLowPenaltyRa? "ON!!":"OFF!!") ));
pBtCoexist->fBtcFillH2c(pBtCoexist, 0x69, 6, H2C_Parameter);
}
VOID
halbtc8703b1ant_LowPenaltyRa(
IN PBTC_COEXIST pBtCoexist,
IN BOOLEAN bForceExec,
IN BOOLEAN bLowPenaltyRa
)
{
pCoexDm->bCurLowPenaltyRa = bLowPenaltyRa;
if(!bForceExec)
{
if(pCoexDm->bPreLowPenaltyRa == pCoexDm->bCurLowPenaltyRa)
return;
}
halbtc8703b1ant_SetSwPenaltyTxRateAdaptive(pBtCoexist, pCoexDm->bCurLowPenaltyRa);
pCoexDm->bPreLowPenaltyRa = pCoexDm->bCurLowPenaltyRa;
}
u4Byte
halbtc8703b1ant_LTECoex_InDirectReadReg(
IN PBTC_COEXIST pBtCoexist,
IN u2Byte RegAddr
)
{
u4Byte j =0;
//wait for ready bit before access 0x7c0
pBtCoexist->fBtcWrite4Byte(pBtCoexist, 0x7c0, 0x800F0000|RegAddr);
do
{
j++;
}while( ((pBtCoexist->fBtcRead1Byte(pBtCoexist, 0x7c3) & BIT5) ==0) && (j <BT_8703B_1ANT_LTECOEX_INDIRECTREG_ACCESS_TIMEOUT) );
return(pBtCoexist->fBtcRead4Byte(pBtCoexist, 0x7c8)); //get read data
}
VOID
halbtc8703b1ant_LTECoex_InDirectWriteReg(
IN PBTC_COEXIST pBtCoexist,
IN u2Byte RegAddr,
IN u4Byte BitMask,
IN u4Byte RegValue
)
{
u4Byte val, i=0, j=0, bitpos = 0;
if (BitMask == 0x0)
return;
if (BitMask == 0xffffffff)
{
pBtCoexist->fBtcWrite4Byte(pBtCoexist, 0x7c4, RegValue); //put write data
//wait for ready bit before access 0x7c0
do
{
j++;
}while( ((pBtCoexist->fBtcRead1Byte(pBtCoexist, 0x7c3) & BIT5) ==0) && (j <BT_8703B_1ANT_LTECOEX_INDIRECTREG_ACCESS_TIMEOUT) );
pBtCoexist->fBtcWrite4Byte(pBtCoexist, 0x7c0, 0xc00F0000|RegAddr);
}
else
{
for(i=0; i<=31; i++)
{
if ( ((BitMask >> i) & 0x1) == 0x1)
{
bitpos = i;
break;
}
}
//read back register value before write
val = halbtc8703b1ant_LTECoex_InDirectReadReg(pBtCoexist, RegAddr);
val = (val & (~BitMask)) | (RegValue << bitpos);
pBtCoexist->fBtcWrite4Byte(pBtCoexist, 0x7c4, val); //put write data
//wait for ready bit before access 0x7c0
do
{
j++;
}while( ((pBtCoexist->fBtcRead1Byte(pBtCoexist, 0x7c3) & BIT5) ==0) && (j <BT_8703B_1ANT_LTECOEX_INDIRECTREG_ACCESS_TIMEOUT) );
pBtCoexist->fBtcWrite4Byte(pBtCoexist, 0x7c0, 0xc00F0000|RegAddr);
}
}
void
halbtc8703b1ant_LTECoex_Enable(
IN PBTC_COEXIST pBtCoexist,
IN BOOLEAN bEnable
)
{
u1Byte val;
val = (bEnable)? 1 : 0;
halbtc8703b1ant_LTECoex_InDirectWriteReg(pBtCoexist, 0x38, 0x80, val); //0x38[7]
}
void
halbtc8703b1ant_LTECoex_PathControlOwner(
IN PBTC_COEXIST pBtCoexist,
IN BOOLEAN bWiFiControl
)
{
u1Byte val;
val = (bWiFiControl)? 1 : 0;
pBtCoexist->fBtcWrite1ByteBitMask(pBtCoexist, 0x73, 0x4, val); //0x70[26]
}
void
halbtc8703b1ant_LTECoex_Set_GNT_BT(
IN PBTC_COEXIST pBtCoexist,
IN u1Byte nControlBlock,
IN BOOLEAN bSWControl,
IN u1Byte nState
)
{
u4Byte val=0, BitMask;
nState = nState & 0x1;
val = (bSWControl)? ((nState<<1) | 0x1) : 0;
switch(nControlBlock)
{
case RFC_AND_BB:
default:
BitMask = 0xc000;
halbtc8703b1ant_LTECoex_InDirectWriteReg(pBtCoexist, 0x38, BitMask, val); // 0x38[15:14]
BitMask = 0x0c00;
halbtc8703b1ant_LTECoex_InDirectWriteReg(pBtCoexist, 0x38, BitMask, val); // 0x38[11:10]
break;
case RFC_ONLY:
BitMask = 0xc000;
halbtc8703b1ant_LTECoex_InDirectWriteReg(pBtCoexist, 0x38, BitMask, val); // 0x38[15:14]
break;
case BB_ONLY:
BitMask = 0x0c00;
halbtc8703b1ant_LTECoex_InDirectWriteReg(pBtCoexist, 0x38, BitMask, val); // 0x38[11:10]
break;
}
}
void
halbtc8703b1ant_LTECoex_Set_GNT_WL(
IN PBTC_COEXIST pBtCoexist,
IN u1Byte nControlBlock,
IN BOOLEAN bSWControl,
IN u1Byte nState
)
{
u4Byte val=0, BitMask;
nState = nState & 0x1;
val = (bSWControl)? ((nState<<1) | 0x1) : 0;
switch(nControlBlock)
{
case RFC_AND_BB:
default:
BitMask = 0x3000;
halbtc8703b1ant_LTECoex_InDirectWriteReg(pBtCoexist, 0x38, BitMask, val); // 0x38[13:12]
BitMask = 0x0300;
halbtc8703b1ant_LTECoex_InDirectWriteReg(pBtCoexist, 0x38, BitMask, val); // 0x38[9:8]
break;
case RFC_ONLY:
BitMask = 0x3000;
halbtc8703b1ant_LTECoex_InDirectWriteReg(pBtCoexist, 0x38, BitMask, val); // 0x38[13:12]
break;
case BB_ONLY:
BitMask = 0x0300;
halbtc8703b1ant_LTECoex_InDirectWriteReg(pBtCoexist, 0x38, BitMask, val); // 0x38[9:8]
break;
}
}
void
halbtc8703b1ant_LTECoex_Set_CoexTable(
IN PBTC_COEXIST pBtCoexist,
IN u1Byte nTableType,
IN u2Byte nTableContent
)
{
u2Byte RegAddr = 0x0000;
switch(nTableType)
{
case WL_VS_LTE:
RegAddr = 0xa0;
break;
case BT_VS_LTE:
RegAddr = 0xa4;
break;
}
if (RegAddr != 0x0000)
halbtc8703b1ant_LTECoex_InDirectWriteReg(pBtCoexist, RegAddr, 0xffff, nTableContent); // 0xa0[15:0] or 0xa4[15:0]
}
void
halbtc8703b1ant_LTECoex_Set_BreakTable(
IN PBTC_COEXIST pBtCoexist,
IN u1Byte nTableType,
IN u1Byte nTableContent
)
{
u2Byte RegAddr = 0x0000;
switch(nTableType)
{
case WL_BREAK_LTE:
RegAddr = 0xa8;
break;
case BT_BREAK_LTE:
RegAddr = 0xac;
break;
case LTE_BREAK_WL:
RegAddr = 0xb0;
break;
case LTE_BREAK_BT:
RegAddr = 0xb4;
break;
}
if (RegAddr != 0x0000)
halbtc8703b1ant_LTECoex_InDirectWriteReg(pBtCoexist, RegAddr, 0xff, nTableContent); // 0xa8[15:0] or 0xb4[15:0]
}
VOID
halbtc8703b1ant_SetCoexTable(
IN PBTC_COEXIST pBtCoexist,
IN u4Byte val0x6c0,
IN u4Byte val0x6c4,
IN u4Byte val0x6c8,
IN u1Byte val0x6cc
)
{
RT_TRACE(COMP_COEX, DBG_TRACE, ("[BTCoex], set coex table, set 0x6c0=0x%x\n", val0x6c0));
pBtCoexist->fBtcWrite4Byte(pBtCoexist, 0x6c0, val0x6c0);
RT_TRACE(COMP_COEX, DBG_TRACE, ("[BTCoex], set coex table, set 0x6c4=0x%x\n", val0x6c4));
pBtCoexist->fBtcWrite4Byte(pBtCoexist, 0x6c4, val0x6c4);
RT_TRACE(COMP_COEX, DBG_TRACE, ("[BTCoex], set coex table, set 0x6c8=0x%x\n", val0x6c8));
pBtCoexist->fBtcWrite4Byte(pBtCoexist, 0x6c8, val0x6c8);
RT_TRACE(COMP_COEX, DBG_TRACE, ("[BTCoex], set coex table, set 0x6cc=0x%x\n", val0x6cc));
pBtCoexist->fBtcWrite1Byte(pBtCoexist, 0x6cc, val0x6cc);
}
VOID
halbtc8703b1ant_CoexTable(
IN PBTC_COEXIST pBtCoexist,
IN BOOLEAN bForceExec,
IN u4Byte val0x6c0,
IN u4Byte val0x6c4,
IN u4Byte val0x6c8,
IN u1Byte val0x6cc
)
{
RT_TRACE(COMP_COEX, DBG_TRACE, ("[BTCoex], %s write Coex Table 0x6c0=0x%x, 0x6c4=0x%x, 0x6cc=0x%x\n",
(bForceExec? "force to":""), val0x6c0, val0x6c4, val0x6cc));
pCoexDm->curVal0x6c0 = val0x6c0;
pCoexDm->curVal0x6c4 = val0x6c4;
pCoexDm->curVal0x6c8 = val0x6c8;
pCoexDm->curVal0x6cc = val0x6cc;
if(!bForceExec)
{
if( (pCoexDm->preVal0x6c0 == pCoexDm->curVal0x6c0) &&
(pCoexDm->preVal0x6c4 == pCoexDm->curVal0x6c4) &&
(pCoexDm->preVal0x6c8 == pCoexDm->curVal0x6c8) &&
(pCoexDm->preVal0x6cc == pCoexDm->curVal0x6cc) )
return;
}
halbtc8703b1ant_SetCoexTable(pBtCoexist, val0x6c0, val0x6c4, val0x6c8, val0x6cc);
pCoexDm->preVal0x6c0 = pCoexDm->curVal0x6c0;
pCoexDm->preVal0x6c4 = pCoexDm->curVal0x6c4;
pCoexDm->preVal0x6c8 = pCoexDm->curVal0x6c8;
pCoexDm->preVal0x6cc = pCoexDm->curVal0x6cc;
}
VOID
halbtc8703b1ant_CoexTableWithType(
IN PBTC_COEXIST pBtCoexist,
IN BOOLEAN bForceExec,
IN u1Byte type
)
{
PBTC_BOARD_INFO pBoardInfo=&pBtCoexist->boardInfo;
u4Byte nBreakTable;
u1Byte nSelectTable;
RT_TRACE(COMP_COEX, DBG_TRACE, ("[BTCoex], ********** CoexTable(%d) **********\n", type));
pCoexSta->nCoexTableType = type;
if (pCoexSta->bConCurrentRxModeOn == true)
{
nBreakTable = 0xf0ffffff; //set WL hi-pri can break BT
nSelectTable = 0xb; //set Tx response = Hi-Pri (ex: Transmitting ACK,BA,CTS)
}
else
{
nBreakTable = 0xffffff;
nSelectTable = 0x3;
}
switch(type)
{
case 0:
halbtc8703b1ant_CoexTable(pBtCoexist, bForceExec, 0x55555555, 0x55555555, nBreakTable, nSelectTable);
break;
case 1:
halbtc8703b1ant_CoexTable(pBtCoexist, bForceExec, 0x55555555, 0x5a5a5a5a, nBreakTable, nSelectTable);
break;
case 2:
halbtc8703b1ant_CoexTable(pBtCoexist, bForceExec, 0xaa5a5a5a, 0xaa5a5a5a, nBreakTable, nSelectTable);
break;
case 3:
halbtc8703b1ant_CoexTable(pBtCoexist, bForceExec, 0xaa555555, 0xaa5a5a5a, nBreakTable, nSelectTable);
break;
case 4:
if ( (pCoexSta->bCCKEverLock) && (pCoexSta->nScanAPNum <= 5) )
halbtc8703b1ant_CoexTable(pBtCoexist, bForceExec, 0xaa555555, 0xaaaa5a5a, nBreakTable, nSelectTable);
else
halbtc8703b1ant_CoexTable(pBtCoexist, bForceExec, 0xaa555555, 0xaa5a5a5a, nBreakTable, nSelectTable);
break;
case 5:
if ( (pCoexSta->bCCKEverLock) && (pCoexSta->nScanAPNum <= 5) )
halbtc8703b1ant_CoexTable(pBtCoexist, bForceExec, 0xaa555555, 0xaaaa5a5a, nBreakTable, nSelectTable);
else
halbtc8703b1ant_CoexTable(pBtCoexist, bForceExec, 0xaa5a5a5a, 0xaa5a5a5a, nBreakTable, nSelectTable);
break;
case 6:
halbtc8703b1ant_CoexTable(pBtCoexist, bForceExec, 0x55555555, 0xaaaaaaaa, nBreakTable, nSelectTable);
break;
case 7:
halbtc8703b1ant_CoexTable(pBtCoexist, bForceExec, 0xaaaaaaaa, 0xaaaaaaaa, nBreakTable, nSelectTable);
break;
case 8:
halbtc8703b1ant_CoexTable(pBtCoexist, bForceExec, 0x55dd55dd, 0x5ada5ada, nBreakTable, nSelectTable);
break;
case 9:
halbtc8703b1ant_CoexTable(pBtCoexist, bForceExec, 0x55dd55dd, 0x5ada5ada, nBreakTable, nSelectTable);
break;
case 10:
halbtc8703b1ant_CoexTable(pBtCoexist, bForceExec, 0x55dd55dd, 0x5ada5ada, nBreakTable, nSelectTable);
break;
case 11:
halbtc8703b1ant_CoexTable(pBtCoexist, bForceExec, 0x55dd55dd, 0x5ada5ada, nBreakTable, nSelectTable);
break;
case 12:
halbtc8703b1ant_CoexTable(pBtCoexist, bForceExec, 0x55dd55dd, 0x5ada5ada, nBreakTable, nSelectTable);
break;
case 13:
halbtc8703b1ant_CoexTable(pBtCoexist, bForceExec, 0x5fff5fff, 0xaaaaaaaa, nBreakTable, nSelectTable);
break;
case 14:
halbtc8703b1ant_CoexTable(pBtCoexist, bForceExec, 0x5fff5fff, 0x5ada5ada, nBreakTable, nSelectTable);
break;
case 15:
halbtc8703b1ant_CoexTable(pBtCoexist, bForceExec, 0x55dd55dd, 0xaaaaaaaa, nBreakTable, nSelectTable);
break;
default:
break;
}
}
VOID
halbtc8703b1ant_SetFwIgnoreWlanAct(
IN PBTC_COEXIST pBtCoexist,
IN BOOLEAN bEnable
)
{
u1Byte H2C_Parameter[1] ={0};
if(bEnable)
{
H2C_Parameter[0] |= BIT0; // function enable
}
RT_TRACE(COMP_COEX, DBG_TRACE, ("[BTCoex], set FW for BT Ignore Wlan_Act, FW write 0x63=0x%x\n",
H2C_Parameter[0]));
pBtCoexist->fBtcFillH2c(pBtCoexist, 0x63, 1, H2C_Parameter);
}
VOID
halbtc8703b1ant_IgnoreWlanAct(
IN PBTC_COEXIST pBtCoexist,
IN BOOLEAN bForceExec,
IN BOOLEAN bEnable
)
{
RT_TRACE(COMP_COEX, DBG_TRACE, ("[BTCoex], %s turn Ignore WlanAct %s\n",
(bForceExec? "force to":""), (bEnable? "ON":"OFF")));
pCoexDm->bCurIgnoreWlanAct = bEnable;
if(!bForceExec)
{
if(pCoexDm->bPreIgnoreWlanAct == pCoexDm->bCurIgnoreWlanAct)
return;
}
halbtc8703b1ant_SetFwIgnoreWlanAct(pBtCoexist, bEnable);
pCoexDm->bPreIgnoreWlanAct = pCoexDm->bCurIgnoreWlanAct;
}
VOID
halbtc8703b1ant_SetLpsRpwm(
IN PBTC_COEXIST pBtCoexist,
IN u1Byte lpsVal,
IN u1Byte rpwmVal
)
{
u1Byte lps=lpsVal;
u1Byte rpwm=rpwmVal;
pBtCoexist->fBtcSet(pBtCoexist, BTC_SET_U1_LPS_VAL, &lps);
pBtCoexist->fBtcSet(pBtCoexist, BTC_SET_U1_RPWM_VAL, &rpwm);
}
VOID
halbtc8703b1ant_LpsRpwm(
IN PBTC_COEXIST pBtCoexist,
IN BOOLEAN bForceExec,
IN u1Byte lpsVal,
IN u1Byte rpwmVal
)
{
BOOLEAN bForceExecPwrCmd=FALSE;
RT_TRACE(COMP_COEX, DBG_TRACE, ("[BTCoex], %s set lps/rpwm=0x%x/0x%x \n",
(bForceExec? "force to":""), lpsVal, rpwmVal));
pCoexDm->curLps = lpsVal;
pCoexDm->curRpwm = rpwmVal;
if(!bForceExec)
{
if( (pCoexDm->preLps == pCoexDm->curLps) &&
(pCoexDm->preRpwm == pCoexDm->curRpwm) )
{
return;
}
}
halbtc8703b1ant_SetLpsRpwm(pBtCoexist, lpsVal, rpwmVal);
pCoexDm->preLps = pCoexDm->curLps;
pCoexDm->preRpwm = pCoexDm->curRpwm;
}
VOID
halbtc8703b1ant_SwMechanism(
IN PBTC_COEXIST pBtCoexist,
IN BOOLEAN bLowPenaltyRA
)
{
halbtc8703b1ant_LowPenaltyRa(pBtCoexist, NORMAL_EXEC, bLowPenaltyRA);
}
VOID
halbtc8703b1ant_SetAntPath(
IN PBTC_COEXIST pBtCoexist,
IN u1Byte antPosType,
IN BOOLEAN bForceExec,
IN BOOLEAN bInitHwCfg,
IN BOOLEAN bWifiOff
)
{
PBTC_BOARD_INFO pBoardInfo=&pBtCoexist->boardInfo;
u4Byte fwVer=0, u4Tmp=0, cntBtCalChk=0;
BOOLEAN bPgExtSwitch=FALSE;
BOOLEAN bUseExtSwitch=FALSE;
BOOLEAN bIsInMpMode = FALSE;
u1Byte H2C_Parameter[2] ={0}, u1Tmp = 0;
u4Byte u4Tmp1=0, u4Tmp2=0;
pCoexDm->curAntPosType = antPosType;
#if 1
u4Tmp1 = halbtc8703b1ant_LTECoex_InDirectReadReg(pBtCoexist, 0x38);
u4Tmp2 = halbtc8703b1ant_LTECoex_InDirectReadReg(pBtCoexist, 0x54);
u1Tmp = pBtCoexist->fBtcRead1Byte(pBtCoexist, 0x73);
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], ********** (Before Setup) 0x73 = 0x%x, 0x38= 0x%x, 0x54= 0x%x**********\n", u1Tmp, u4Tmp1, u4Tmp2));
#endif
if(bInitHwCfg)
{
//Disable LTE Coex Function in WiFi side (this should be on if LTE coex is required)
halbtc8703b1ant_LTECoex_Enable(pBtCoexist, 0x0);
//GNT_WL_LTE always = 1 (this should be config if LTE coex is required)
halbtc8703b1ant_LTECoex_Set_CoexTable(pBtCoexist, WL_VS_LTE, 0xffff);
//GNT_BT_LTE always = 1 (this should be config if LTE coex is required)
halbtc8703b1ant_LTECoex_Set_CoexTable(pBtCoexist, BT_VS_LTE, 0xffff);
// Wait If BT IQK running, because Path control owner is at BT during BT IQK (setup by WiFi firmware)
while(cntBtCalChk <= 20)
{
u1Tmp = pBtCoexist->fBtcRead1Byte(pBtCoexist, 0x49d);
cntBtCalChk++;
if(u1Tmp & BIT0)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], ########### BT is calibrating (wait cnt=%d) ###########\n", cntBtCalChk));
delay_ms(50);
}
else
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], ********** BT is NOT calibrating (wait cnt=%d)**********\n", cntBtCalChk));
break;
}
}
//set Path control owner to WL at initial step
halbtc8703b1ant_LTECoex_PathControlOwner(pBtCoexist, WLSIDE_CONTROL);
}
else if(bWifiOff)
{
//Disable LTE Coex Function in WiFi side
halbtc8703b1ant_LTECoex_Enable(pBtCoexist, 0x0);
//if MP mode
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_IS_IN_MP_MODE, &bIsInMpMode);
if(bIsInMpMode)
halbtc8703b1ant_LTECoex_PathControlOwner(pBtCoexist, WLSIDE_CONTROL); //set Path control owner to BT
else
halbtc8703b1ant_LTECoex_PathControlOwner(pBtCoexist, BTSIDE_CONTROL);//set Path control owner to WiFi
}
else
{
//
}
if(bForceExec || (pCoexDm->curAntPosType != pCoexDm->preAntPosType) || bInitHwCfg || bWifiOff)
{
// internal switch setting
switch(antPosType)
{
case BTC_ANT_PATH_WIFI:
// set GNT_BT to low
halbtc8703b1ant_LTECoex_Set_GNT_BT(pBtCoexist, RFC_AND_BB, CONTROL_BY_SW, SET_TO_LOW);
//Set GNT_WL to high
halbtc8703b1ant_LTECoex_Set_GNT_WL(pBtCoexist, RFC_AND_BB, CONTROL_BY_SW, SET_TO_HIGH);
break;
case BTC_ANT_PATH_BT:
// set GNT_BT to high
halbtc8703b1ant_LTECoex_Set_GNT_BT(pBtCoexist, RFC_AND_BB, CONTROL_BY_SW, SET_TO_HIGH);
//Set GNT_WL to low
halbtc8703b1ant_LTECoex_Set_GNT_WL(pBtCoexist, RFC_AND_BB, CONTROL_BY_SW, SET_TO_LOW);
break;
default:
case BTC_ANT_PATH_PTA:
// set GNT_BT to PTA
halbtc8703b1ant_LTECoex_Set_GNT_BT(pBtCoexist, RFC_AND_BB, CONTROL_BY_PTA, SET_BY_HW);
//Set GNT_WL to PTA
halbtc8703b1ant_LTECoex_Set_GNT_WL(pBtCoexist, RFC_AND_BB, CONTROL_BY_PTA, SET_BY_HW);
break;
}
}
#if 1
u4Tmp1 = halbtc8703b1ant_LTECoex_InDirectReadReg(pBtCoexist, 0x38);
u4Tmp2 = halbtc8703b1ant_LTECoex_InDirectReadReg(pBtCoexist, 0x54);
u1Tmp = pBtCoexist->fBtcRead1Byte(pBtCoexist, 0x73);
if(bInitHwCfg)
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], ********** (After Init) 0x73 = 0x%x, 0x38= 0x%x, 0x54= 0x%x**********\n", u1Tmp, u4Tmp1, u4Tmp2));
else if (bWifiOff)
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], ********** (After WiFi off) 0x73 = 0x%x, 0x38= 0x%x, 0x54= 0x%x**********\n", u1Tmp, u4Tmp1, u4Tmp2));
else
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], ********** (After Run time) 0x73 = 0x%x, 0x38= 0x%x, 0x54= 0x%x**********\n", u1Tmp, u4Tmp1, u4Tmp2));
#endif
pCoexDm->preAntPosType = pCoexDm->curAntPosType;
}
VOID
halbtc8703b1ant_SetFwPstdma(
IN PBTC_COEXIST pBtCoexist,
IN u1Byte byte1,
IN u1Byte byte2,
IN u1Byte byte3,
IN u1Byte byte4,
IN u1Byte byte5
)
{
u1Byte H2C_Parameter[5] ={0};
u1Byte realByte1=byte1, realByte5=byte5;
BOOLEAN bApEnable=FALSE;
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_AP_MODE_ENABLE, &bApEnable);
if(bApEnable)
{
if(byte1&BIT4 && !(byte1&BIT5))
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], FW for 1Ant AP mode\n"));
realByte1 &= ~BIT4;
realByte1 |= BIT5;
realByte5 |= BIT5;
realByte5 &= ~BIT6;
}
}
H2C_Parameter[0] = realByte1;
H2C_Parameter[1] = byte2;
H2C_Parameter[2] = byte3;
H2C_Parameter[3] = byte4;
H2C_Parameter[4] = realByte5;
pCoexDm->psTdmaPara[0] = realByte1;
pCoexDm->psTdmaPara[1] = byte2;
pCoexDm->psTdmaPara[2] = byte3;
pCoexDm->psTdmaPara[3] = byte4;
pCoexDm->psTdmaPara[4] = realByte5;
RT_TRACE(COMP_COEX, DBG_TRACE, ("[BTCoex], PS-TDMA H2C cmd =0x%x%08x\n",
H2C_Parameter[0],
H2C_Parameter[1]<<24|H2C_Parameter[2]<<16|H2C_Parameter[3]<<8|H2C_Parameter[4]));
pBtCoexist->fBtcFillH2c(pBtCoexist, 0x60, 5, H2C_Parameter);
}
VOID
halbtc8703b1ant_PsTdma(
IN PBTC_COEXIST pBtCoexist,
IN BOOLEAN bForceExec,
IN BOOLEAN bTurnOn,
IN u1Byte type
)
{
PBTC_BOARD_INFO pBoardInfo=&pBtCoexist->boardInfo;
PBTC_BT_LINK_INFO pBtLinkInfo=&pBtCoexist->btLinkInfo;
BOOLEAN bTurnOnByCnt=FALSE, bWifiBusy=FALSE, bWiFiNoisy=FALSE;
u1Byte psTdmaTypeByCnt=0, rssiAdjustVal=0;
u1Byte psTdmaByte4Val = 0x50, psTdmaByte0Val = 0x51, psTdmaByte3Val = 0x10;
s1Byte nWiFiDurationAdjust = 0x0;
static BOOLEAN bPreWifiBusy=FALSE;
pCoexDm->bCurPsTdmaOn = bTurnOn;
pCoexDm->curPsTdma = type;
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_BUSY, &bWifiBusy);
if (bWifiBusy != bPreWifiBusy)
{
bForceExec = TRUE;
bPreWifiBusy = bWifiBusy;
}
if (pCoexDm->bCurPsTdmaOn)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], ********** TDMA(on, %d) **********\n",
pCoexDm->curPsTdma));
}
else
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], ********** TDMA(off, %d) **********\n",
pCoexDm->curPsTdma));
}
if(!bForceExec)
{
if( (pCoexDm->bPrePsTdmaOn == pCoexDm->bCurPsTdmaOn) &&
(pCoexDm->prePsTdma == pCoexDm->curPsTdma) )
return;
}
if (pCoexSta->nScanAPNum <= 5)
nWiFiDurationAdjust = 5;
//nWiFiDurationAdjust = 2;
else if (pCoexSta->nScanAPNum >= 40)
nWiFiDurationAdjust = -15;
else if (pCoexSta->nScanAPNum >= 20)
nWiFiDurationAdjust = -10;
if ((type == 1) || (type == 2) || (type == 9) || (type == 11) || (type == 101)
|| (type == 102) || (type == 109) || (type == 101))
{
if (!pCoexSta->bForceLpsOn) //Native power save TDMA, only for A2DP-only case 1/2/9/11 while wifi noisy threshold > 30
{
psTdmaByte0Val = 0x61; //no null-pkt
psTdmaByte3Val = 0x11; // no tx-pause at BT-slot
psTdmaByte4Val = 0x10; // 0x778 = d/1 toggle, no dynamic slot
}
else
{
psTdmaByte0Val = 0x51; //null-pkt
psTdmaByte3Val = 0x10; //tx-pause at BT-slot
psTdmaByte4Val = 0x50; // 0x778 = d/1 toggle, dynamic slot
}
}
else if ((type == 3) || (type == 13) || (type == 14) || (type == 103) || (type == 113) || (type == 114))
{
psTdmaByte0Val = 0x51; //null-pkt
psTdmaByte3Val = 0x10; //tx-pause at BT-slot
psTdmaByte4Val = 0x10; // 0x778 = d/1 toggle, no dynamic slot
#if 0
if (!bWifiBusy)
psTdmaByte4Val = psTdmaByte4Val | 0x1; //0x778 = 0x1 at wifi slot (no blocking BT Low-Pri pkts)
#endif
}
else //native power save case
{
psTdmaByte0Val = 0x61; //no null-pkt
psTdmaByte3Val = 0x11; // no tx-pause at BT-slot
psTdmaByte4Val = 0x11; // 0x778 = d/1 toggle, no dynamic slot
//psTdmaByte4Va is not defne for 0x778 = d/1, 1/1 case
}
//if (pBtLinkInfo->bSlaveRole == TRUE)
if ((pBtLinkInfo->bSlaveRole == TRUE) && (pBtLinkInfo->bA2dpExist))
psTdmaByte4Val = psTdmaByte4Val | 0x1; //0x778 = 0x1 at wifi slot (no blocking BT Low-Pri pkts)
if (type > 100)
{
psTdmaByte0Val = psTdmaByte0Val | 0x82; //set antenna control by SW
psTdmaByte3Val = psTdmaByte3Val | 0x60; //set antenna no toggle, control by antenna diversity
}
if(bTurnOn)
{
switch(type)
{
default:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, 0x51, 0x1a, 0x1a, 0x0, psTdmaByte4Val);
break;
case 1:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x3a+nWiFiDurationAdjust, 0x03, psTdmaByte3Val, psTdmaByte4Val);
break;
case 2:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x2d+nWiFiDurationAdjust, 0x03, psTdmaByte3Val, psTdmaByte4Val);
break;
case 3:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x3a, 0x03, psTdmaByte3Val, psTdmaByte4Val);
break;
case 4:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, 0x93, 0x15, 0x3, 0x14, 0x0);
break;
case 5:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x15, 0x3, psTdmaByte3Val, 0x11);
break;
case 6:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x20, 0x3, psTdmaByte3Val, 0x11);
break;
case 7:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, 0x13, 0xc, 0x5, 0x0, 0x0);
break;
case 8:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, 0x93, 0x25, 0x3, 0x10, 0x0);
break;
case 9:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x21, 0x3, psTdmaByte3Val, psTdmaByte4Val);
break;
case 10:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, 0x13, 0xa, 0xa, 0x0, 0x40);
break;
case 11:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x21, 0x03, psTdmaByte3Val, psTdmaByte4Val);
break;
case 12:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, 0x51, 0x0a, 0x0a, 0x0, 0x50);
break;
case 13:
if (pCoexSta->nScanAPNum <= 3) // for Lenovo CPT test A2DP + OPP
halbtc8703b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x3a, 0x3, psTdmaByte3Val, psTdmaByte4Val);
else
halbtc8703b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x21, 0x3, psTdmaByte3Val, psTdmaByte4Val);
break;
case 14:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x21, 0x3, psTdmaByte3Val, psTdmaByte4Val);
break;
case 15:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, 0x13, 0xa, 0x3, 0x8, 0x0);
break;
case 16:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, 0x93, 0x15, 0x3, 0x10, 0x0);
break;
case 18:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, 0x93, 0x25, 0x3, 0x10, 0x0);
break;
case 20:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x3f, 0x03, psTdmaByte3Val, 0x10);
break;
case 21:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, 0x61, 0x25, 0x03, 0x11, 0x11);
break;
case 22:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x25, 0x03, psTdmaByte3Val, 0x10);
break;
case 23:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, 0xe3, 0x25, 0x3, 0x31, 0x18);
break;
case 24:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, 0xe3, 0x15, 0x3, 0x31, 0x18);
break;
case 25:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, 0xe3, 0xa, 0x3, 0x31, 0x18);
break;
case 26:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, 0xe3, 0xa, 0x3, 0x31, 0x18);
break;
case 27:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, 0xe3, 0x25, 0x3, 0x31, 0x98);
break;
case 28:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, 0x69, 0x25, 0x3, 0x31, 0x0);
break;
case 29:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, 0xab, 0x1a, 0x1a, 0x1, 0x10);
break;
case 30:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, 0x51, 0x30, 0x3, 0x10, 0x10);
break;
case 31:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, 0xd3, 0x1a, 0x1a, 0, 0x58);
break;
case 32:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x35, 0x3, psTdmaByte3Val, psTdmaByte4Val);
break;
case 33:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x35, 0x3, psTdmaByte3Val, 0x10);
break;
case 34:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, 0x53, 0x1a, 0x1a, 0x0, 0x10);
break;
case 35:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, 0x63, 0x1a, 0x1a, 0x0, 0x10);
break;
case 36:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, 0xd3, 0x12, 0x3, 0x14, 0x50);
break;
case 40: // SoftAP only with no sta associated,BT disable ,TDMA mode for power saving
/* here softap mode screen off will cost 70-80mA for phone */
halbtc8703b1ant_SetFwPstdma(pBtCoexist, 0x23, 0x18, 0x00, 0x10, 0x24);
break;
//for 1-Ant translate to 2-Ant
case 101:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x3a+nWiFiDurationAdjust, 0x03, psTdmaByte3Val, psTdmaByte4Val);
break;
case 102:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x2d+nWiFiDurationAdjust, 0x03, psTdmaByte3Val, psTdmaByte4Val);
break;
case 103:
//halbtc8703b1ant_SetFwPstdma(pBtCoexist, 0x51, 0x1d, 0x1d, 0x0, psTdmaByte4Val);
halbtc8703b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x3a, 0x03, psTdmaByte3Val, psTdmaByte4Val);
break;
case 105:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x15, 0x3, psTdmaByte3Val, 0x11);
break;
case 106:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x20, 0x3, psTdmaByte3Val, 0x11);
break;
case 109:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x21, 0x3, psTdmaByte3Val, psTdmaByte4Val);
break;
case 111:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x21, 0x03, psTdmaByte3Val, psTdmaByte4Val);
break;
case 113:
//halbtc8703b1ant_SetFwPstdma(pBtCoexist, 0x51, 0x12, 0x12, 0x0, psTdmaByte4Val);
halbtc8703b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x21, 0x3, psTdmaByte3Val, psTdmaByte4Val);
break;
case 114:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x21, 0x3, psTdmaByte3Val, psTdmaByte4Val);
break;
case 120:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x3f, 0x03, psTdmaByte3Val, 0x10);
break;
case 122:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x25, 0x03, psTdmaByte3Val, 0x10);
break;
case 132:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x25, 0x03, psTdmaByte3Val, psTdmaByte4Val);
break;
case 133:
halbtc8703b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x25, 0x03, psTdmaByte3Val, 0x11);
break;
}
}
else
{
// disable PS tdma
switch(type)
{
case 8: //PTA Control
halbtc8703b1ant_SetFwPstdma(pBtCoexist, 0x8, 0x0, 0x0, 0x0, 0x0);
break;
case 0:
default: //Software control, Antenna at BT side
halbtc8703b1ant_SetFwPstdma(pBtCoexist, 0x0, 0x0, 0x0, 0x0, 0x0);
break;
case 1: // 2-Ant, 0x778=3, antenna control by antenna diversity
halbtc8703b1ant_SetFwPstdma(pBtCoexist, 0x0, 0x0, 0x0, 0x48, 0x0);
break;
#if 0
case 9: //Software control, Antenna at WiFi side
halbtc8703b1ant_SetFwPstdma(pBtCoexist, 0x0, 0x0, 0x0, 0x0, 0x0);
halbtc8703b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_WIFI, FALSE, FALSE);
break;
#endif
}
}
rssiAdjustVal =0;
pBtCoexist->fBtcSet(pBtCoexist, BTC_SET_U1_RSSI_ADJ_VAL_FOR_1ANT_COEX_TYPE, &rssiAdjustVal);
RT_TRACE(COMP_COEX, DBG_LOUD, ("############# [BTCoex], 0x948=0x%x, 0x765=0x%x, 0x67=0x%x\n",
pBtCoexist->fBtcRead4Byte(pBtCoexist, 0x948), pBtCoexist->fBtcRead1Byte(pBtCoexist, 0x765), pBtCoexist->fBtcRead1Byte(pBtCoexist, 0x67)));
// update pre state
pCoexDm->bPrePsTdmaOn = pCoexDm->bCurPsTdmaOn;
pCoexDm->prePsTdma = pCoexDm->curPsTdma;
}
BOOLEAN
halbtc8703b1ant_IsCommonAction(
IN PBTC_COEXIST pBtCoexist
)
{
BOOLEAN bCommon=FALSE, bWifiConnected=FALSE, bWifiBusy=FALSE;
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_CONNECTED, &bWifiConnected);
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_BUSY, &bWifiBusy);
if(!bWifiConnected &&
BT_8703B_1ANT_BT_STATUS_NON_CONNECTED_IDLE == pCoexDm->btStatus)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Wifi non connected-idle + BT non connected-idle!!\n"));
//halbtc8703b1ant_SwMechanism(pBtCoexist, FALSE);
bCommon = TRUE;
}
else if(bWifiConnected &&
(BT_8703B_1ANT_BT_STATUS_NON_CONNECTED_IDLE == pCoexDm->btStatus) )
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Wifi connected + BT non connected-idle!!\n"));
//halbtc8703b1ant_SwMechanism(pBtCoexist, FALSE);
bCommon = TRUE;
}
else if(!bWifiConnected &&
(BT_8703B_1ANT_BT_STATUS_CONNECTED_IDLE == pCoexDm->btStatus) )
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Wifi non connected-idle + BT connected-idle!!\n"));
//halbtc8703b1ant_SwMechanism(pBtCoexist, FALSE);
bCommon = TRUE;
}
else if(bWifiConnected &&
(BT_8703B_1ANT_BT_STATUS_CONNECTED_IDLE == pCoexDm->btStatus) )
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Wifi connected + BT connected-idle!!\n"));
//halbtc8703b1ant_SwMechanism(pBtCoexist, FALSE);
bCommon = TRUE;
}
else if(!bWifiConnected &&
(BT_8703B_1ANT_BT_STATUS_CONNECTED_IDLE != pCoexDm->btStatus) )
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Wifi non connected-idle + BT Busy!!\n"));
//halbtc8703b1ant_SwMechanism(pBtCoexist, FALSE);
bCommon = TRUE;
}
else
{
if (bWifiBusy)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Wifi Connected-Busy + BT Busy!!\n"));
}
else
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Wifi Connected-Idle + BT Busy!!\n"));
}
bCommon = FALSE;
}
return bCommon;
}
VOID
halbtc8703b1ant_TdmaDurationAdjustForAcl(
IN PBTC_COEXIST pBtCoexist,
IN u1Byte wifiStatus
)
{
static s4Byte up,dn,m,n,WaitCount;
s4Byte result; //0: no change, +1: increase WiFi duration, -1: decrease WiFi duration
u1Byte retryCount=0, btInfoExt;
static BOOLEAN bPreWifiBusy=FALSE;
BOOLEAN bWifiBusy = FALSE;
RT_TRACE(COMP_COEX, DBG_TRACE, ("[BTCoex], TdmaDurationAdjustForAcl()\n"));
if(BT_8703B_1ANT_WIFI_STATUS_CONNECTED_BUSY == wifiStatus)
bWifiBusy = TRUE;
else
bWifiBusy = FALSE;
if( (BT_8703B_1ANT_WIFI_STATUS_NON_CONNECTED_ASSO_AUTH_SCAN == wifiStatus) ||
(BT_8703B_1ANT_WIFI_STATUS_CONNECTED_SCAN == wifiStatus) ||
(BT_8703B_1ANT_WIFI_STATUS_CONNECTED_SPECIAL_PKT == wifiStatus) )
{
if( pCoexDm->curPsTdma != 1 &&
pCoexDm->curPsTdma != 2 &&
pCoexDm->curPsTdma != 3 &&
pCoexDm->curPsTdma != 9 )
{
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 9);
pCoexDm->psTdmaDuAdjType = 9;
up = 0;
dn = 0;
m = 1;
n= 3;
result = 0;
WaitCount = 0;
}
return;
}
if(!pCoexDm->bAutoTdmaAdjust)
{
pCoexDm->bAutoTdmaAdjust = TRUE;
RT_TRACE(COMP_COEX, DBG_TRACE, ("[BTCoex], first run TdmaDurationAdjust()!!\n"));
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 2);
pCoexDm->psTdmaDuAdjType = 2;
//============
up = 0;
dn = 0;
m = 1;
n= 3;
result = 0;
WaitCount = 0;
}
else
{
//accquire the BT TRx retry count from BT_Info byte2
retryCount = pCoexSta->btRetryCnt;
btInfoExt = pCoexSta->btInfoExt;
if ( (pCoexSta->lowPriorityTx) > 1050 || (pCoexSta->lowPriorityRx) > 1250 )
retryCount++;
result = 0;
WaitCount++;
if(retryCount == 0) // no retry in the last 2-second duration
{
up++;
dn--;
if (dn <= 0)
dn = 0;
if(up >= n) // if <20>s<EFBFBD><73> n <20><>2<EFBFBD><32> retry count<6E><74>0, <20>h<EFBFBD>ռeWiFi duration
{
WaitCount = 0;
n = 3;
up = 0;
dn = 0;
result = 1;
RT_TRACE(COMP_COEX, DBG_TRACE, ("[BTCoex], Increase wifi duration!!\n"));
}
}
else if (retryCount <= 3) // <=3 retry in the last 2-second duration
{
up--;
dn++;
if (up <= 0)
up = 0;
if (dn == 2) // if <20>s<EFBFBD><73> 2 <20><>2<EFBFBD><32> retry count< 3, <20>h<EFBFBD>կ<EFBFBD>WiFi duration
{
if (WaitCount <= 2)
m++; // <20>קK<D7A7>@<40><><EFBFBD>b<EFBFBD><62><EFBFBD><EFBFBD>level<65><6C><EFBFBD>Ӧ^
else
m = 1;
if ( m >= 20) //m <20>̤j<CCA4><6A> = 20 ' <20>̤j120<32><30> recheck<63>O<EFBFBD>_<EFBFBD>վ<EFBFBD> WiFi duration.
m = 20;
n = 3*m;
up = 0;
dn = 0;
WaitCount = 0;
result = -1;
RT_TRACE(COMP_COEX, DBG_TRACE, ("[BTCoex], Decrease wifi duration for retryCounter<3!!\n"));
}
}
else //retry count > 3, <20>u<EFBFBD>n1<6E><31> retry count > 3, <20>h<EFBFBD>կ<EFBFBD>WiFi duration
{
if (WaitCount == 1)
m++; // <20>קK<D7A7>@<40><><EFBFBD>b<EFBFBD><62><EFBFBD><EFBFBD>level<65><6C><EFBFBD>Ӧ^
else
m = 1;
if ( m >= 20) //m <20>̤j<CCA4><6A> = 20 ' <20>̤j120<32><30> recheck<63>O<EFBFBD>_<EFBFBD>վ<EFBFBD> WiFi duration.
m = 20;
n = 3*m;
up = 0;
dn = 0;
WaitCount = 0;
result = -1;
RT_TRACE(COMP_COEX, DBG_TRACE, ("[BTCoex], Decrease wifi duration for retryCounter>3!!\n"));
}
if(result == -1)
{
/* if( (BT_INFO_8703B_1ANT_A2DP_BASIC_RATE(btInfoExt)) &&
((pCoexDm->curPsTdma == 1) ||(pCoexDm->curPsTdma == 2)) )
{
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 9);
pCoexDm->psTdmaDuAdjType = 9;
}
else */ if(pCoexDm->curPsTdma == 1)
{
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 2);
pCoexDm->psTdmaDuAdjType = 2;
}
else if(pCoexDm->curPsTdma == 2)
{
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 9);
pCoexDm->psTdmaDuAdjType = 9;
}
else if(pCoexDm->curPsTdma == 9)
{
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 11);
pCoexDm->psTdmaDuAdjType = 11;
}
}
else if(result == 1)
{
/* if( (BT_INFO_8703B_1ANT_A2DP_BASIC_RATE(btInfoExt)) &&
((pCoexDm->curPsTdma == 1) ||(pCoexDm->curPsTdma == 2)) )
{
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 9);
pCoexDm->psTdmaDuAdjType = 9;
}
else */ if(pCoexDm->curPsTdma == 11)
{
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 9);
pCoexDm->psTdmaDuAdjType = 9;
}
else if(pCoexDm->curPsTdma == 9)
{
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 2);
pCoexDm->psTdmaDuAdjType = 2;
}
else if(pCoexDm->curPsTdma == 2)
{
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 1);
pCoexDm->psTdmaDuAdjType = 1;
}
}
else //no change
{
/* Bryant Modify
if(bWifiBusy != bPreWifiBusy) //if busy / idle change
{
bPreWifiBusy = bWifiBusy;
halbtc8703b1ant_PsTdma(pBtCoexist, FORCE_EXEC, TRUE, pCoexDm->curPsTdma);
}
*/
RT_TRACE(COMP_COEX, DBG_TRACE, ("[BTCoex], ********** TDMA(on, %d) **********\n",
pCoexDm->curPsTdma));
}
if( pCoexDm->curPsTdma != 1 &&
pCoexDm->curPsTdma != 2 &&
pCoexDm->curPsTdma != 9 &&
pCoexDm->curPsTdma != 11 )
{
// recover to previous adjust type
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, pCoexDm->psTdmaDuAdjType);
}
}
}
VOID
halbtc8703b1ant_PsTdmaCheckForPowerSaveState(
IN PBTC_COEXIST pBtCoexist,
IN BOOLEAN bNewPsState
)
{
u1Byte lpsMode=0x0;
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_U1_LPS_MODE, &lpsMode);
if(lpsMode) // already under LPS state
{
if(bNewPsState)
{
// keep state under LPS, do nothing.
}
else
{
// will leave LPS state, turn off psTdma first
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, FALSE, 8);
}
}
else // NO PS state
{
if(bNewPsState)
{
// will enter LPS state, turn off psTdma first
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, FALSE, 8);
}
else
{
// keep state under NO PS state, do nothing.
}
}
}
VOID
halbtc8703b1ant_PowerSaveState(
IN PBTC_COEXIST pBtCoexist,
IN u1Byte psType,
IN u1Byte lpsVal,
IN u1Byte rpwmVal
)
{
BOOLEAN bLowPwrDisable=FALSE;
switch(psType)
{
case BTC_PS_WIFI_NATIVE:
// recover to original 32k low power setting
bLowPwrDisable = FALSE;
pBtCoexist->fBtcSet(pBtCoexist, BTC_SET_ACT_DISABLE_LOW_POWER, &bLowPwrDisable);
pBtCoexist->fBtcSet(pBtCoexist, BTC_SET_ACT_NORMAL_LPS, NULL);
pCoexSta->bForceLpsOn = FALSE;
break;
case BTC_PS_LPS_ON:
halbtc8703b1ant_PsTdmaCheckForPowerSaveState(pBtCoexist, TRUE);
halbtc8703b1ant_LpsRpwm(pBtCoexist, NORMAL_EXEC, lpsVal, rpwmVal);
// when coex force to enter LPS, do not enter 32k low power.
bLowPwrDisable = TRUE;
pBtCoexist->fBtcSet(pBtCoexist, BTC_SET_ACT_DISABLE_LOW_POWER, &bLowPwrDisable);
// power save must executed before psTdma.
pBtCoexist->fBtcSet(pBtCoexist, BTC_SET_ACT_ENTER_LPS, NULL);
pCoexSta->bForceLpsOn = TRUE;
break;
case BTC_PS_LPS_OFF:
halbtc8703b1ant_PsTdmaCheckForPowerSaveState(pBtCoexist, FALSE);
pBtCoexist->fBtcSet(pBtCoexist, BTC_SET_ACT_LEAVE_LPS, NULL);
pCoexSta->bForceLpsOn = FALSE;
break;
default:
break;
}
}
VOID
halbtc8703b1ant_ActionWifiOnly(
IN PBTC_COEXIST pBtCoexist
)
{
halbtc8703b1ant_CoexTableWithType(pBtCoexist, FORCE_EXEC, 0);
halbtc8703b1ant_PsTdma(pBtCoexist, FORCE_EXEC, FALSE, 8);
halbtc8703b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_PTA, FORCE_EXEC, FALSE, FALSE);
}
VOID
halbtc8703b1ant_MonitorBtEnableDisable(
IN PBTC_COEXIST pBtCoexist
)
{
static BOOLEAN bPreBtDisabled=FALSE;
static u4Byte btDisableCnt=0;
BOOLEAN bBtActive=TRUE, bBtDisabled=FALSE;
// This function check if bt is disabled
if( pCoexSta->highPriorityTx == 0 &&
pCoexSta->highPriorityRx == 0 &&
pCoexSta->lowPriorityTx == 0 &&
pCoexSta->lowPriorityRx == 0)
{
bBtActive = FALSE;
}
if( pCoexSta->highPriorityTx == 0xffff &&
pCoexSta->highPriorityRx == 0xffff &&
pCoexSta->lowPriorityTx == 0xffff &&
pCoexSta->lowPriorityRx == 0xffff)
{
bBtActive = FALSE;
}
if(bBtActive)
{
btDisableCnt = 0;
bBtDisabled = FALSE;
pBtCoexist->fBtcSet(pBtCoexist, BTC_SET_BL_BT_DISABLE, &bBtDisabled);
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT is enabled !!\n"));
}
else
{
btDisableCnt++;
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], bt all counters=0, %d times!!\n",
btDisableCnt));
if(btDisableCnt >= 2)
{
bBtDisabled = TRUE;
pBtCoexist->fBtcSet(pBtCoexist, BTC_SET_BL_BT_DISABLE, &bBtDisabled);
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT is disabled !!\n"));
halbtc8703b1ant_ActionWifiOnly(pBtCoexist);
}
}
if(bPreBtDisabled != bBtDisabled)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT is from %s to %s!!\n",
(bPreBtDisabled ? "disabled":"enabled"),
(bBtDisabled ? "disabled":"enabled")));
bPreBtDisabled = bBtDisabled;
if(!bBtDisabled)
{
}
else
{
pBtCoexist->fBtcSet(pBtCoexist, BTC_SET_ACT_LEAVE_LPS, NULL);
pBtCoexist->fBtcSet(pBtCoexist, BTC_SET_ACT_NORMAL_LPS, NULL);
}
}
}
//=============================================
//
// Software Coex Mechanism start
//
//=============================================
// SCO only or SCO+PAN(HS)
/*
VOID
halbtc8703b1ant_ActionSco(
IN PBTC_COEXIST pBtCoexist
)
{
halbtc8703b1ant_SwMechanism(pBtCoexist, TRUE);
}
VOID
halbtc8703b1ant_ActionHid(
IN PBTC_COEXIST pBtCoexist
)
{
halbtc8703b1ant_SwMechanism(pBtCoexist, TRUE);
}
//A2DP only / PAN(EDR) only/ A2DP+PAN(HS)
VOID
halbtc8703b1ant_ActionA2dp(
IN PBTC_COEXIST pBtCoexist
)
{
halbtc8703b1ant_SwMechanism(pBtCoexist, FALSE);
}
VOID
halbtc8703b1ant_ActionA2dpPanHs(
IN PBTC_COEXIST pBtCoexist
)
{
halbtc8703b1ant_SwMechanism(pBtCoexist, FALSE);
}
VOID
halbtc8703b1ant_ActionPanEdr(
IN PBTC_COEXIST pBtCoexist
)
{
halbtc8703b1ant_SwMechanism(pBtCoexist, FALSE);
}
//PAN(HS) only
VOID
halbtc8703b1ant_ActionPanHs(
IN PBTC_COEXIST pBtCoexist
)
{
halbtc8703b1ant_SwMechanism(pBtCoexist, FALSE);
}
//PAN(EDR)+A2DP
VOID
halbtc8703b1ant_ActionPanEdrA2dp(
IN PBTC_COEXIST pBtCoexist
)
{
halbtc8703b1ant_SwMechanism(pBtCoexist, FALSE);
}
VOID
halbtc8703b1ant_ActionPanEdrHid(
IN PBTC_COEXIST pBtCoexist
)
{
halbtc8703b1ant_SwMechanism(pBtCoexist, TRUE);
}
// HID+A2DP+PAN(EDR)
VOID
halbtc8703b1ant_ActionHidA2dpPanEdr(
IN PBTC_COEXIST pBtCoexist
)
{
halbtc8703b1ant_SwMechanism(pBtCoexist, TRUE);
}
VOID
halbtc8703b1ant_ActionHidA2dp(
IN PBTC_COEXIST pBtCoexist
)
{
halbtc8703b1ant_SwMechanism(pBtCoexist, TRUE);
}
*/
//=============================================
//
// Non-Software Coex Mechanism start
//
//=============================================
VOID
halbtc8703b1ant_ActionBtWhckTest(
IN PBTC_COEXIST pBtCoexist
)
{
halbtc8703b1ant_PowerSaveState(pBtCoexist, BTC_PS_WIFI_NATIVE, 0x0, 0x0);
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, FALSE, 8);
halbtc8703b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_PTA, NORMAL_EXEC, FALSE, FALSE);
halbtc8703b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 0);
}
VOID
halbtc8703b1ant_ActionWifiMultiPort(
IN PBTC_COEXIST pBtCoexist
)
{
halbtc8703b1ant_PowerSaveState(pBtCoexist, BTC_PS_WIFI_NATIVE, 0x0, 0x0);
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, FALSE, 8);
halbtc8703b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_PTA, NORMAL_EXEC, FALSE, FALSE);
halbtc8703b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 2);
}
VOID
halbtc8703b1ant_ActionHs(
IN PBTC_COEXIST pBtCoexist
)
{
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 5);
halbtc8703b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 2);
}
VOID
halbtc8703b1ant_ActionBtInquiry(
IN PBTC_COEXIST pBtCoexist
)
{
PBTC_BT_LINK_INFO pBtLinkInfo=&pBtCoexist->btLinkInfo;
BOOLEAN bWifiConnected=FALSE, bApEnable=FALSE, bWifiBusy=FALSE, bBtBusy=FALSE;
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_AP_MODE_ENABLE, &bApEnable);
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_CONNECTED, &bWifiConnected);
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_BUSY, &bWifiBusy);
pBtCoexist->fBtcSet(pBtCoexist, BTC_SET_BL_BT_TRAFFIC_BUSY, &bBtBusy);
if ( (!bWifiConnected) && (!pCoexSta->bWiFiIsHighPriTask) )
{
halbtc8703b1ant_PowerSaveState(pBtCoexist, BTC_PS_WIFI_NATIVE, 0x0, 0x0);
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, FALSE, 8);
halbtc8703b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_PTA, NORMAL_EXEC, FALSE, FALSE);
halbtc8703b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 0);
}
else if( (pBtLinkInfo->bScoExist) || (pBtLinkInfo->bHidExist) || (pBtLinkInfo->bA2dpExist) )
{
// SCO/HID/A2DP busy
halbtc8703b1ant_PowerSaveState(pBtCoexist, BTC_PS_WIFI_NATIVE, 0x0, 0x0);
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 32);
halbtc8703b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 4);
}
else if ( (pBtLinkInfo->bPanExist) || (bWifiBusy) )
{
halbtc8703b1ant_PowerSaveState(pBtCoexist, BTC_PS_WIFI_NATIVE, 0x0, 0x0);
//for BT inquiry/page fail after S4 resume
//halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 20);
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 32);
halbtc8703b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 4);
}
else
{
halbtc8703b1ant_PowerSaveState(pBtCoexist, BTC_PS_WIFI_NATIVE, 0x0, 0x0);
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, FALSE, 8);
halbtc8703b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_PTA, NORMAL_EXEC, FALSE, FALSE);
halbtc8703b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 7);
//halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 32);
//halbtc8703b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 4);
}
}
VOID
halbtc8703b1ant_ActionBtScoHidOnlyBusy(
IN PBTC_COEXIST pBtCoexist,
IN u1Byte wifiStatus
)
{
PBTC_BT_LINK_INFO pBtLinkInfo=&pBtCoexist->btLinkInfo;
BOOLEAN bWifiConnected=FALSE;
u1Byte wifiRssiState=BTC_RSSI_STATE_HIGH;
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_CONNECTED, &bWifiConnected);
// tdma and coex table
if(pBtLinkInfo->bScoExist)
{
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 5);
halbtc8703b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 5);
}
else //HID
{
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 6);
halbtc8703b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 5);
}
}
VOID
halbtc8703b1ant_ActionWifiConnectedBtAclBusy(
IN PBTC_COEXIST pBtCoexist,
IN u1Byte wifiStatus
)
{
u1Byte btRssiState;
PBTC_BT_LINK_INFO pBtLinkInfo=&pBtCoexist->btLinkInfo;
btRssiState = halbtc8703b1ant_BtRssiState(2, 28, 0);
if ( (pCoexSta->lowPriorityRx >= 950) && (!pCoexSta->bUnderIps) )
{
pBtLinkInfo->bSlaveRole = TRUE;
}
else
{
pBtLinkInfo->bSlaveRole = FALSE;
}
if(pBtLinkInfo->bHidOnly) //HID
{
halbtc8703b1ant_ActionBtScoHidOnlyBusy(pBtCoexist, wifiStatus);
pCoexDm->bAutoTdmaAdjust = FALSE;
return;
}
else if(pBtLinkInfo->bA2dpOnly) //A2DP
{
if(BT_8703B_1ANT_WIFI_STATUS_CONNECTED_IDLE == wifiStatus)
{
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 32);
halbtc8703b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 4);
pCoexDm->bAutoTdmaAdjust = FALSE;
}
else
{
halbtc8703b1ant_TdmaDurationAdjustForAcl(pBtCoexist, wifiStatus);
halbtc8703b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 4);
pCoexDm->bAutoTdmaAdjust = TRUE;
}
}
else if ( ((pBtLinkInfo->bA2dpExist) && (pBtLinkInfo->bPanExist)) ||
(pBtLinkInfo->bHidExist&&pBtLinkInfo->bA2dpExist&&pBtLinkInfo->bPanExist) ) //A2DP+PAN(OPP,FTP), HID+A2DP+PAN(OPP,FTP)
{
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 13);
halbtc8703b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 4);
pCoexDm->bAutoTdmaAdjust = FALSE;
}
else if(pBtLinkInfo->bHidExist&&pBtLinkInfo->bA2dpExist) //HID+A2DP
{
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 14);
pCoexDm->bAutoTdmaAdjust = FALSE;
halbtc8703b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 4);
}
else if( (pBtLinkInfo->bPanOnly) || (pBtLinkInfo->bHidExist&&pBtLinkInfo->bPanExist) ) //PAN(OPP,FTP), HID+PAN(OPP,FTP)
{
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 3);
halbtc8703b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 4);
pCoexDm->bAutoTdmaAdjust = FALSE;
}
else
{
//BT no-profile busy (0x9)
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 33);
halbtc8703b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 4);
pCoexDm->bAutoTdmaAdjust = FALSE;
}
}
VOID
halbtc8703b1ant_ActionWifiNotConnected(
IN PBTC_COEXIST pBtCoexist
)
{
// power save state
halbtc8703b1ant_PowerSaveState(pBtCoexist, BTC_PS_WIFI_NATIVE, 0x0, 0x0);
// tdma and coex table
halbtc8703b1ant_PsTdma(pBtCoexist, FORCE_EXEC, FALSE, 8);
halbtc8703b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_PTA, NORMAL_EXEC, FALSE, FALSE);
halbtc8703b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 0);
}
VOID
halbtc8703b1ant_ActionWifiNotConnectedScan(
IN PBTC_COEXIST pBtCoexist
)
{
PBTC_BT_LINK_INFO pBtLinkInfo=&pBtCoexist->btLinkInfo;
halbtc8703b1ant_PowerSaveState(pBtCoexist, BTC_PS_WIFI_NATIVE, 0x0, 0x0);
// tdma and coex table
if(BT_8703B_1ANT_BT_STATUS_ACL_BUSY == pCoexDm->btStatus)
{
if (pBtLinkInfo->bA2dpExist)
{
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 32);
halbtc8703b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 4);
}
else if (pBtLinkInfo->bA2dpExist && pBtLinkInfo->bPanExist)
{
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 22);
halbtc8703b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 4);
}
else
{
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 20);
halbtc8703b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 4);
}
}
else if( (BT_8703B_1ANT_BT_STATUS_SCO_BUSY == pCoexDm->btStatus) ||
(BT_8703B_1ANT_BT_STATUS_ACL_SCO_BUSY == pCoexDm->btStatus) )
{
halbtc8703b1ant_ActionBtScoHidOnlyBusy(pBtCoexist,
BT_8703B_1ANT_WIFI_STATUS_CONNECTED_SCAN);
}
else
{
//Bryant Add
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, FALSE, 8);
halbtc8703b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_PTA, NORMAL_EXEC, FALSE, FALSE);
halbtc8703b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 2);
}
}
VOID
halbtc8703b1ant_ActionWifiNotConnectedAssoAuth(
IN PBTC_COEXIST pBtCoexist
)
{
PBTC_BT_LINK_INFO pBtLinkInfo=&pBtCoexist->btLinkInfo;
halbtc8703b1ant_PowerSaveState(pBtCoexist, BTC_PS_WIFI_NATIVE, 0x0, 0x0);
// tdma and coex table
if( (pBtLinkInfo->bScoExist) || (pBtLinkInfo->bHidExist) || (pBtLinkInfo->bA2dpExist) )
{
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 32);
halbtc8703b1ant_CoexTableWithType(pBtCoexist, FORCE_EXEC, 4);
}
else if (pBtLinkInfo->bPanExist)
{
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 20);
halbtc8703b1ant_CoexTableWithType(pBtCoexist, FORCE_EXEC, 4);
}
else
{
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, FALSE, 8);
halbtc8703b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_PTA, NORMAL_EXEC, FALSE, FALSE);
halbtc8703b1ant_CoexTableWithType(pBtCoexist, FORCE_EXEC, 2);
}
}
VOID
halbtc8703b1ant_ActionWifiConnectedScan(
IN PBTC_COEXIST pBtCoexist
)
{
PBTC_BT_LINK_INFO pBtLinkInfo=&pBtCoexist->btLinkInfo;
halbtc8703b1ant_PowerSaveState(pBtCoexist, BTC_PS_WIFI_NATIVE, 0x0, 0x0);
// tdma and coex table
if(BT_8703B_1ANT_BT_STATUS_ACL_BUSY == pCoexDm->btStatus)
{
if (pBtLinkInfo->bA2dpExist)
{
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 32);
halbtc8703b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 4);
}
else if (pBtLinkInfo->bA2dpExist && pBtLinkInfo->bPanExist)
{
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 22);
halbtc8703b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 4);
}
else
{
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 20);
halbtc8703b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 4);
}
}
else if( (BT_8703B_1ANT_BT_STATUS_SCO_BUSY == pCoexDm->btStatus) ||
(BT_8703B_1ANT_BT_STATUS_ACL_SCO_BUSY == pCoexDm->btStatus) )
{
halbtc8703b1ant_ActionBtScoHidOnlyBusy(pBtCoexist,
BT_8703B_1ANT_WIFI_STATUS_CONNECTED_SCAN);
}
else
{
//Bryant Add
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, FALSE, 8);
halbtc8703b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_PTA, NORMAL_EXEC, FALSE, FALSE);
halbtc8703b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 2);
}
}
VOID
halbtc8703b1ant_ActionWifiConnectedSpecialPacket(
IN PBTC_COEXIST pBtCoexist
)
{
PBTC_BT_LINK_INFO pBtLinkInfo=&pBtCoexist->btLinkInfo;
BOOLEAN bWifiBusy = FALSE;
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_BUSY, &bWifiBusy);
//no special packet process for both WiFi and BT very busy
if ((bWifiBusy) && ((pBtLinkInfo->bPanExist) || (pCoexSta->nNumOfProfile >= 2)))
return;
halbtc8703b1ant_PowerSaveState(pBtCoexist, BTC_PS_WIFI_NATIVE, 0x0, 0x0);
// tdma and coex table
if((pBtLinkInfo->bScoExist) || (pBtLinkInfo->bHidExist))
{
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 32);
halbtc8703b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 5);
}
else if (pBtLinkInfo->bA2dpExist)
{
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 32);
halbtc8703b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 4);
}
else if(pBtLinkInfo->bPanExist)
{
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 20);
halbtc8703b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 4);
}
else
{
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, FALSE, 8);
halbtc8703b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_PTA, NORMAL_EXEC, FALSE, FALSE);
halbtc8703b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 2);
}
}
VOID
halbtc8703b1ant_ActionWifiConnected(
IN PBTC_COEXIST pBtCoexist
)
{
BOOLEAN bWifiBusy=FALSE;
BOOLEAN bScan=FALSE, bLink=FALSE, bRoam=FALSE;
BOOLEAN bUnder4way=FALSE, bApEnable=FALSE;
u4Byte wifiBw;
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], CoexForWifiConnect()===>\n"));
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_4_WAY_PROGRESS, &bUnder4way);
if(bUnder4way)
{
halbtc8703b1ant_ActionWifiConnectedSpecialPacket(pBtCoexist);
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], CoexForWifiConnect(), return for wifi is under 4way<===\n"));
return;
}
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_SCAN, &bScan);
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_LINK, &bLink);
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_ROAM, &bRoam);
if(bScan || bLink || bRoam)
{
if(bScan)
halbtc8703b1ant_ActionWifiConnectedScan(pBtCoexist);
else
halbtc8703b1ant_ActionWifiConnectedSpecialPacket(pBtCoexist);
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], CoexForWifiConnect(), return for wifi is under scan<===\n"));
return;
}
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_AP_MODE_ENABLE, &bApEnable);
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_BUSY, &bWifiBusy);
// power save state
if(!bApEnable && BT_8703B_1ANT_BT_STATUS_ACL_BUSY == pCoexDm->btStatus && !pBtCoexist->btLinkInfo.bHidOnly)
{
if(pBtCoexist->btLinkInfo.bA2dpOnly) //A2DP
{
if(!bWifiBusy)
halbtc8703b1ant_PowerSaveState(pBtCoexist, BTC_PS_WIFI_NATIVE, 0x0, 0x0);
else //busy
{
if (pCoexSta->nScanAPNum >= BT_8703B_1ANT_WIFI_NOISY_THRESH) //no force LPS, no PS-TDMA, use pure TDMA
{
halbtc8703b1ant_PowerSaveState(pBtCoexist, BTC_PS_WIFI_NATIVE, 0x0, 0x0);
}
else
{
halbtc8703b1ant_PowerSaveState(pBtCoexist, BTC_PS_LPS_ON, 0x50, 0x4);
}
}
}
else if ((pCoexSta->bPanExist == FALSE) && (pCoexSta->bA2dpExist == FALSE) && (pCoexSta->bHidExist == FALSE))
halbtc8703b1ant_PowerSaveState(pBtCoexist, BTC_PS_WIFI_NATIVE, 0x0, 0x0);
else
halbtc8703b1ant_PowerSaveState(pBtCoexist, BTC_PS_LPS_ON, 0x50, 0x4);
}
else
halbtc8703b1ant_PowerSaveState(pBtCoexist, BTC_PS_WIFI_NATIVE, 0x0, 0x0);
// tdma and coex table
if(!bWifiBusy)
{
if(BT_8703B_1ANT_BT_STATUS_ACL_BUSY == pCoexDm->btStatus)
{
halbtc8703b1ant_ActionWifiConnectedBtAclBusy(pBtCoexist,
BT_8703B_1ANT_WIFI_STATUS_CONNECTED_IDLE);
}
else if( (BT_8703B_1ANT_BT_STATUS_SCO_BUSY == pCoexDm->btStatus) ||
(BT_8703B_1ANT_BT_STATUS_ACL_SCO_BUSY == pCoexDm->btStatus) )
{
halbtc8703b1ant_ActionBtScoHidOnlyBusy(pBtCoexist,
BT_8703B_1ANT_WIFI_STATUS_CONNECTED_IDLE);
}
else
{
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, FALSE, 8);
halbtc8703b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_PTA, NORMAL_EXEC, FALSE, FALSE);
if ( (pCoexSta->highPriorityTx) + (pCoexSta->highPriorityRx) <= 60 )
halbtc8703b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 2);
else
halbtc8703b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 7);
}
}
else
{
if(BT_8703B_1ANT_BT_STATUS_ACL_BUSY == pCoexDm->btStatus)
{
halbtc8703b1ant_ActionWifiConnectedBtAclBusy(pBtCoexist,
BT_8703B_1ANT_WIFI_STATUS_CONNECTED_BUSY);
}
else if( (BT_8703B_1ANT_BT_STATUS_SCO_BUSY == pCoexDm->btStatus) ||
(BT_8703B_1ANT_BT_STATUS_ACL_SCO_BUSY == pCoexDm->btStatus) )
{
halbtc8703b1ant_ActionBtScoHidOnlyBusy(pBtCoexist,
BT_8703B_1ANT_WIFI_STATUS_CONNECTED_BUSY);
}
else
{
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, FALSE, 8);
halbtc8703b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_PTA, NORMAL_EXEC, FALSE, FALSE);
if ( (pCoexSta->highPriorityTx) + (pCoexSta->highPriorityRx) <= 60 )
halbtc8703b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 2);
else
halbtc8703b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 7);
}
}
}
VOID
halbtc8703b1ant_RunSwCoexistMechanism(
IN PBTC_COEXIST pBtCoexist
)
{
u1Byte algorithm=0;
algorithm = halbtc8703b1ant_ActionAlgorithm(pBtCoexist);
pCoexDm->curAlgorithm = algorithm;
if(halbtc8703b1ant_IsCommonAction(pBtCoexist))
{
}
else
{
switch(pCoexDm->curAlgorithm)
{
case BT_8703B_1ANT_COEX_ALGO_SCO:
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Action algorithm = SCO.\n"));
//halbtc8703b1ant_ActionSco(pBtCoexist);
break;
case BT_8703B_1ANT_COEX_ALGO_HID:
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Action algorithm = HID.\n"));
//halbtc8703b1ant_ActionHid(pBtCoexist);
break;
case BT_8703B_1ANT_COEX_ALGO_A2DP:
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Action algorithm = A2DP.\n"));
//halbtc8703b1ant_ActionA2dp(pBtCoexist);
break;
case BT_8703B_1ANT_COEX_ALGO_A2DP_PANHS:
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Action algorithm = A2DP+PAN(HS).\n"));
//halbtc8703b1ant_ActionA2dpPanHs(pBtCoexist);
break;
case BT_8703B_1ANT_COEX_ALGO_PANEDR:
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Action algorithm = PAN(EDR).\n"));
//halbtc8703b1ant_ActionPanEdr(pBtCoexist);
break;
case BT_8703B_1ANT_COEX_ALGO_PANHS:
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Action algorithm = HS mode.\n"));
//halbtc8703b1ant_ActionPanHs(pBtCoexist);
break;
case BT_8703B_1ANT_COEX_ALGO_PANEDR_A2DP:
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Action algorithm = PAN+A2DP.\n"));
//halbtc8703b1ant_ActionPanEdrA2dp(pBtCoexist);
break;
case BT_8703B_1ANT_COEX_ALGO_PANEDR_HID:
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Action algorithm = PAN(EDR)+HID.\n"));
//halbtc8703b1ant_ActionPanEdrHid(pBtCoexist);
break;
case BT_8703B_1ANT_COEX_ALGO_HID_A2DP_PANEDR:
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Action algorithm = HID+A2DP+PAN.\n"));
//halbtc8703b1ant_ActionHidA2dpPanEdr(pBtCoexist);
break;
case BT_8703B_1ANT_COEX_ALGO_HID_A2DP:
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Action algorithm = HID+A2DP.\n"));
//halbtc8703b1ant_ActionHidA2dp(pBtCoexist);
break;
default:
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Action algorithm = coexist All Off!!\n"));
//halbtc8703b1ant_CoexAllOff(pBtCoexist);
break;
}
pCoexDm->preAlgorithm = pCoexDm->curAlgorithm;
}
}
VOID
halbtc8703b1ant_RunCoexistMechanism(
IN PBTC_COEXIST pBtCoexist
)
{
PBTC_BT_LINK_INFO pBtLinkInfo=&pBtCoexist->btLinkInfo;
BOOLEAN bWifiConnected=FALSE, bBtHsOn=FALSE;
BOOLEAN bIncreaseScanDevNum=FALSE;
BOOLEAN bBtCtrlAggBufSize=FALSE;
BOOLEAN bMiracastPlusBt=FALSE;
u1Byte aggBufSize=5;
u1Byte wifiRssiState=BTC_RSSI_STATE_HIGH;
u4Byte wifiLinkStatus=0;
u4Byte numOfWifiLink=0, wifiBw;
u1Byte iotPeer=BTC_IOT_PEER_UNKNOWN;
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], RunCoexistMechanism()===>\n"));
if(pBtCoexist->bManualControl)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], RunCoexistMechanism(), return for Manual CTRL <===\n"));
return;
}
if(pBtCoexist->bStopCoexDm)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], RunCoexistMechanism(), return for Stop Coex DM <===\n"));
return;
}
if(pCoexSta->bUnderIps)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], wifi is under IPS !!!\n"));
return;
}
if(pCoexSta->bBtWhckTest)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT is under WHCK TEST!!!\n"));
halbtc8703b1ant_ActionBtWhckTest(pBtCoexist);
return;
}
if( (BT_8703B_1ANT_BT_STATUS_ACL_BUSY == pCoexDm->btStatus) ||
(BT_8703B_1ANT_BT_STATUS_SCO_BUSY == pCoexDm->btStatus) ||
(BT_8703B_1ANT_BT_STATUS_ACL_SCO_BUSY == pCoexDm->btStatus) )
{
bIncreaseScanDevNum = TRUE;
}
pBtCoexist->fBtcSet(pBtCoexist, BTC_SET_BL_INC_SCAN_DEV_NUM, &bIncreaseScanDevNum);
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_CONNECTED, &bWifiConnected);
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_U4_WIFI_LINK_STATUS, &wifiLinkStatus);
numOfWifiLink = wifiLinkStatus>>16;
if((numOfWifiLink>=2) || (wifiLinkStatus&WIFI_P2P_GO_CONNECTED))
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("############# [BTCoex], Multi-Port numOfWifiLink = %d, wifiLinkStatus = 0x%x\n", numOfWifiLink,wifiLinkStatus) );
if(pBtLinkInfo->bBtLinkExist)
{
halbtc8703b1ant_LimitedTx(pBtCoexist, NORMAL_EXEC, 1, 1, 0, 1);
bMiracastPlusBt = TRUE;
}
else
{
halbtc8703b1ant_LimitedTx(pBtCoexist, NORMAL_EXEC, 0, 0, 0, 0);
bMiracastPlusBt = FALSE;
}
pBtCoexist->fBtcSet(pBtCoexist, BTC_SET_BL_MIRACAST_PLUS_BT, &bMiracastPlusBt);
halbtc8703b1ant_LimitedRx(pBtCoexist, NORMAL_EXEC, FALSE, bBtCtrlAggBufSize, aggBufSize);
if ( (pBtLinkInfo->bA2dpExist) && (pCoexSta->bC2hBtInquiryPage) )
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("############# [BTCoex], BT Is Inquirying \n") );
halbtc8703b1ant_ActionBtInquiry(pBtCoexist);
}
else
halbtc8703b1ant_ActionWifiMultiPort(pBtCoexist);
return;
}
else
{
bMiracastPlusBt = FALSE;
pBtCoexist->fBtcSet(pBtCoexist, BTC_SET_BL_MIRACAST_PLUS_BT, &bMiracastPlusBt);
}
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_U4_WIFI_BW, &wifiBw);
if ( (pBtLinkInfo->bBtLinkExist) && (bWifiConnected) )
{
halbtc8703b1ant_LimitedTx(pBtCoexist, NORMAL_EXEC, 1, 1, 0, 1);
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_U1_IOT_PEER, &iotPeer);
if(BTC_IOT_PEER_CISCO != iotPeer)
{
if(pBtLinkInfo->bScoExist)//if (pBtLinkInfo->bBtHiPriLinkExist)
halbtc8703b1ant_LimitedRx(pBtCoexist, NORMAL_EXEC, TRUE, FALSE, 0x5);
else
halbtc8703b1ant_LimitedRx(pBtCoexist, NORMAL_EXEC, FALSE, FALSE, 0x5);
}
else
{
if(pBtLinkInfo->bScoExist)
halbtc8703b1ant_LimitedRx(pBtCoexist, NORMAL_EXEC, TRUE, FALSE, 0x5);
else
{
if (BTC_WIFI_BW_HT40==wifiBw)
halbtc8703b1ant_LimitedRx(pBtCoexist, NORMAL_EXEC, FALSE, TRUE, 0x10);
else
halbtc8703b1ant_LimitedRx(pBtCoexist, NORMAL_EXEC, FALSE, TRUE, 0x8);
}
}
halbtc8703b1ant_SwMechanism(pBtCoexist, TRUE);
halbtc8703b1ant_RunSwCoexistMechanism(pBtCoexist); //just print debug message
}
else
{
halbtc8703b1ant_LimitedTx(pBtCoexist, NORMAL_EXEC, 0, 0, 0, 0);
halbtc8703b1ant_LimitedRx(pBtCoexist, NORMAL_EXEC, FALSE, FALSE, 0x5);
halbtc8703b1ant_SwMechanism(pBtCoexist, FALSE);
halbtc8703b1ant_RunSwCoexistMechanism(pBtCoexist); ////just print debug message
}
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_HS_OPERATION, &bBtHsOn);
if(pCoexSta->bC2hBtInquiryPage)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("############# [BTCoex], BT Is Inquirying \n") );
halbtc8703b1ant_ActionBtInquiry(pBtCoexist);
return;
}
else if(bBtHsOn)
{
halbtc8703b1ant_ActionHs(pBtCoexist);
return;
}
if(!bWifiConnected)
{
BOOLEAN bScan=FALSE, bLink=FALSE, bRoam=FALSE;
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], wifi is non connected-idle !!!\n"));
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_SCAN, &bScan);
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_LINK, &bLink);
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_ROAM, &bRoam);
if(bScan || bLink || bRoam)
{
if (bScan)
halbtc8703b1ant_ActionWifiNotConnectedScan(pBtCoexist);
else
halbtc8703b1ant_ActionWifiNotConnectedAssoAuth(pBtCoexist);
}
else
halbtc8703b1ant_ActionWifiNotConnected(pBtCoexist);
}
else // wifi LPS/Busy
{
halbtc8703b1ant_ActionWifiConnected(pBtCoexist);
}
}
u4Byte
halbtc8703b1ant_PSD_Log2Base(
IN PBTC_COEXIST pBtCoexist,
IN u4Byte val
)
{
u1Byte i,j;
u4Byte tmp, tmp2, val_integerdB=0, tindex, shiftcount=0;
u4Byte result,val_fractiondB=0,Table_fraction[21]= {0,432, 332, 274, 232, 200,
174, 151,132,115,100,86,74,62,51,42,
32,23,15,7,0};
if (val == 0)
return 0;
tmp = val;
while(1)
{
if (tmp == 1)
break;
else
{
tmp = (tmp >> 1);
shiftcount++;
}
}
val_integerdB = shiftcount+1;
tmp2=1;
for (j=1; j<= val_integerdB;j++)
tmp2 = tmp2*2;
tmp = (val*100) /tmp2;
tindex = tmp/5;
if (tindex > 20)
tindex = 20;
val_fractiondB = Table_fraction[tindex];
result = val_integerdB*100 - val_fractiondB;
return (result);
}
VOID
halbtc8703b1ant_InitCoexDm(
IN PBTC_COEXIST pBtCoexist
)
{
// force to reset coex mechanism
// sw all off
halbtc8703b1ant_SwMechanism(pBtCoexist, FALSE);
//halbtc8703b1ant_PsTdma(pBtCoexist, FORCE_EXEC, FALSE, 8);
//halbtc8703b1ant_CoexTableWithType(pBtCoexist, FORCE_EXEC, 0);
pCoexSta->popEventCnt = 0;
}
VOID
halbtc8703b1ant_InitHwConfig(
IN PBTC_COEXIST pBtCoexist,
IN BOOLEAN bBackUp,
IN BOOLEAN bWifiOnly
)
{
PBTC_BOARD_INFO pBoardInfo=&pBtCoexist->boardInfo;
u4Byte u4Tmp=0;//, fwVer;
u2Byte u2Tmp=0;
u1Byte u1Tmp=0, u1Tmpa=0, u1Tmpb=0;
u1Byte H2C_Parameter[2] ={0};
u4Byte u4Tmp1=0, u4Tmp2=0;
u4Tmp1 = halbtc8703b1ant_LTECoex_InDirectReadReg(pBtCoexist, 0x38);
u4Tmp2 = halbtc8703b1ant_LTECoex_InDirectReadReg(pBtCoexist, 0x54);
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], ********** (Before Init HW config) 0x38= 0x%x, 0x54= 0x%x**********\n", u4Tmp1, u4Tmp2));
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], 1Ant Init HW Config!!\n"));
pBtCoexist->fBtcWrite1ByteBitMask(pBtCoexist, 0x550, 0x8, 0x1); //enable TBTT nterrupt
//BT report packet sample rate
pBtCoexist->fBtcWrite1Byte(pBtCoexist, 0x790, 0x5);
// Enable BT counter statistics
pBtCoexist->fBtcWrite1Byte(pBtCoexist, 0x778, 0x1);
//Enable PTA (3-wire function form BT side)
pBtCoexist->fBtcWrite1ByteBitMask(pBtCoexist, 0x40, 0x20, 0x1);
//Enable PTA (tx/rx signal form WiFi side)
pBtCoexist->fBtcWrite1ByteBitMask(pBtCoexist, 0x4c6, 0x10, 0x1);
//enable GNT_WL/GNT_BT debug signal to GPIO14/15
pBtCoexist->fBtcWrite1ByteBitMask(pBtCoexist, 0x73, 0x8, 0x1);
//enable GNT_WL
pBtCoexist->fBtcWrite1ByteBitMask(pBtCoexist, 0x4e, 0x40, 0x0);
pBtCoexist->fBtcWrite1ByteBitMask(pBtCoexist, 0x67, 0x1, 0x0);
halbtc8703b1ant_PsTdma(pBtCoexist, FORCE_EXEC, FALSE, 8);
//Antenna config
if(bWifiOnly)
{
pCoexSta->bConCurrentRxModeOn = false;
halbtc8703b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_WIFI, FORCE_EXEC, TRUE, FALSE);
halbtc8703b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_WIFI, FORCE_EXEC, FALSE, FALSE);
}
else
{
pCoexSta->bConCurrentRxModeOn = true;
pBtCoexist->fBtcWrite1ByteBitMask(pBtCoexist, 0x953, 0x2, 0x1);
//RF 0x1[0] = 0 -> Set GNT_WL_RF_Rx always = 1 for con-current Rx
pBtCoexist->fBtcSetRfReg(pBtCoexist, BTC_RF_A, 0x1, 0x1, 0x0);
halbtc8703b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_BT, FORCE_EXEC, TRUE, FALSE);
}
// PTA parameter
halbtc8703b1ant_CoexTableWithType(pBtCoexist, FORCE_EXEC, 0);
}
VOID
halbtc8703b1ant_PSD_ShowData(
IN PBTC_COEXIST pBtCoexist
)
{
pu1Byte cliBuf=pBtCoexist->cliBuf;
u4Byte nDeltaFreqPerPoint;
u4Byte freq,freq1,freq2,n=0,i=0, j=0, m=0, PsdRep1, PsdRep2;
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n\n============[PSD info] (%d)============\n",
pPsdScan->nPSDGenCount);
CL_PRINTF(cliBuf);
if (pPsdScan->nPSDGenCount == 0)
{
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n No Data !!\n");
CL_PRINTF(cliBuf);
return;
}
if (pPsdScan->nPSDPoint == 0)
nDeltaFreqPerPoint = 0;
else
nDeltaFreqPerPoint = pPsdScan->nPSDBandWidth/pPsdScan->nPSDPoint;
//if (pPsdScan->bIsPSDShowMaxOnly)
if (0)
{
PsdRep1 = pPsdScan->nPSDMaxValue/100;
PsdRep2 = pPsdScan->nPSDMaxValue - PsdRep1 * 100;
freq = ((pPsdScan->nRealCentFreq-20) * 1000000 + pPsdScan->nPSDMaxValuePoint * nDeltaFreqPerPoint);
freq1 = freq/1000000;
freq2 = freq/1000 - freq1 * 1000;
if (freq2 < 100)
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n Freq = %d.0%d MHz",
freq1, freq2);
else
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n Freq = %d.%d MHz",
freq1, freq2);
if (PsdRep2 < 10)
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, ", Value = %d.0%d dB, (%d) \n",
PsdRep1, PsdRep2, pPsdScan->nPSDMaxValue);
else
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, ", Value = %d.%d dB, (%d)\n",
PsdRep1, PsdRep2, pPsdScan->nPSDMaxValue);
CL_PRINTF(cliBuf);
}
else
{
m = pPsdScan->nPSDStartPoint;
n = pPsdScan->nPSDStartPoint;
i = 1;
j = 1;
while(1)
{
do
{
freq = ((pPsdScan->nRealCentFreq-20) * 1000000 + m * nDeltaFreqPerPoint);
freq1 = freq/1000000;
freq2 = freq/1000 - freq1 * 1000;
if (i ==1)
{
if (freq2 == 0)
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n Freq%6d.000", freq1);
else if (freq2 < 100)
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n Freq%6d.0%2d", freq1,freq2);
else
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n Freq%6d.%3d", freq1,freq2);
}
else if ( (i%8 == 0) || (m == pPsdScan->nPSDStopPoint) )
{
if (freq2 == 0)
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "%6d.000\n", freq1);
else if (freq2 < 100)
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "%6d.0%2d\n", freq1,freq2);
else
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "%6d.%3d\n", freq1,freq2);
}
else
{
if (freq2 == 0)
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "%6d.000", freq1);
else if (freq2 < 100)
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "%6d.0%2d", freq1,freq2);
else
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "%6d.%3d", freq1,freq2);
}
i++;
m++;
CL_PRINTF(cliBuf);
}while( (i <= 8) && (m <= pPsdScan->nPSDStopPoint));
do
{
PsdRep1 = pPsdScan->nPSDReport_MaxHold[n]/100;
PsdRep2 = pPsdScan->nPSDReport_MaxHold[n] - PsdRep1 * 100;
if (j ==1)
{
if (PsdRep2 <10)
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n Val %7d.0%d", PsdRep1,PsdRep2);
else
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n Val %7d.%d", PsdRep1,PsdRep2);
}
else if ( (j%8 == 0) || (n == pPsdScan->nPSDStopPoint) )
{
if (PsdRep2 <10)
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "%7d.0%d\n", PsdRep1,PsdRep2);
else
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "%7d.%d\n", PsdRep1,PsdRep2);
}
else
{
if (PsdRep2 <10)
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "%7d.0%d", PsdRep1,PsdRep2);
else
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "%7d.%d", PsdRep1,PsdRep2);
}
j++;
n++;
CL_PRINTF(cliBuf);
} while( (j <= 8) && (n <= pPsdScan->nPSDStopPoint));
if ( (m > pPsdScan->nPSDStopPoint) || (n > pPsdScan->nPSDStopPoint) )
break;
else
{
i = 1;
j = 1;
}
}
}
}
VOID
halbtc8703b1ant_PSD_MaxHoldData(
IN PBTC_COEXIST pBtCoexist,
IN u4Byte GenCount
)
{
u4Byte i=0, i_max=0, val_max=0, j;
if (GenCount== 1)
{
memcpy(pPsdScan->nPSDReport_MaxHold, pPsdScan->nPSDReport, BT_8703B_1ANT_ANTDET_PSD_POINTS*sizeof(u4Byte));
for (i= pPsdScan->nPSDStartPoint; i<=pPsdScan->nPSDStopPoint; i++)
{
//RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx SweepPSDPoint(), Max_Hold i = %d, PSDReport = %d dB\n", i, pPsdScan->nPSDReport_MaxHold[i]));
}
pPsdScan->nPSDMaxValuePoint = 0;
pPsdScan->nPSDMaxValue = 0;
}
else
{
for (i= pPsdScan->nPSDStartPoint; i<=pPsdScan->nPSDStopPoint; i++)
{
if (pPsdScan->nPSDReport[i] > pPsdScan->nPSDReport_MaxHold[i])
pPsdScan->nPSDReport_MaxHold[i] = pPsdScan->nPSDReport[i];
//search Max Value
if (i ==pPsdScan->nPSDStartPoint )
{
i_max = i;
val_max = pPsdScan->nPSDReport_MaxHold[i];
}
else
{
if (pPsdScan->nPSDReport_MaxHold[i] > val_max)
{
i_max = i;
val_max = pPsdScan->nPSDReport_MaxHold[i];
}
}
//RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx SweepPSDPoint(), Max_Hold i = %d, PSDReport = %d dB\n", i, pPsdScan->nPSDReport_MaxHold[i]));
}
pPsdScan->nPSDMaxValuePoint = i_max;
pPsdScan->nPSDMaxValue = val_max;
//RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx SweepPSDPoint(), Max_Hold i_Max = %d, PSDReport_Max = %d dB\n", pPsdScan->nPSDMaxValuePoint
// ,pPsdScan->nPSDMaxValue));
}
}
u4Byte
halbtc8703b1ant_PSD_GetData(
IN PBTC_COEXIST pBtCoexist,
IN u4Byte nPoint
)
{
//reg 0x808[9:0]: FFT data x
//reg 0x808[22]: 0-->1 to get 1 FFT data y
//reg 0x8b4[15:0]: FFT data y report
u4Byte val = 0, psd_report =0;
val = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0x808);
val &= 0xffbffc00;
val |= nPoint;
pBtCoexist->fBtcWrite4Byte(pBtCoexist, 0x808, val);
val |= 0x00400000;
pBtCoexist->fBtcWrite4Byte(pBtCoexist, 0x808, val);
val = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0x8b4);
psd_report = val & 0x0000ffff;
return psd_report;
}
VOID
halbtc8703b1ant_PSD_SweepPoint(
IN PBTC_COEXIST pBtCoexist,
IN u4Byte centFreq,
IN s4Byte offset,
IN u4Byte span,
IN u4Byte points,
IN u4Byte avgnum
)
{
u4Byte i,val,n,k=0;
u4Byte nPoints=0, psd_report=0;
u4Byte nStartP=0, nStopP=0, nDeltaFreqPerPoint=156250;
u4Byte nPSDCenterFreq=20*10^6, freq,freq1,freq2;
BOOLEAN outloop = FALSE;
u1Byte flag = 0;
u4Byte tmp, PsdRep1, PsdRep2;
u4Byte WiFi_OriginalChannel = 1;
pPsdScan->bIsPSDRunning = TRUE;
do
{
switch(flag)
{
case 0: //Get PSD parameters
default:
//RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx SweepPSDPoint(), centFreq=0x%x, offset=0x%x, span=0x%x\n",
// centFreq, offset, span));
pPsdScan->nPSDBandWidth = 40*1000000;
pPsdScan->nPSDPoint = points;
pPsdScan->nPSDStartBase = points/2;
pPsdScan->nPSDAvgNum = avgnum;
pPsdScan->nRealCentFreq = centFreq;
pPsdScan->nRealOffset = offset;
pPsdScan->nRealSpan = span;
nPoints = pPsdScan->nPSDPoint;
nDeltaFreqPerPoint = pPsdScan->nPSDBandWidth/pPsdScan->nPSDPoint;
//PSD point setup
val = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0x808);
val &= 0xffff0fff;
switch(pPsdScan->nPSDPoint)
{
case 128:
val |= 0x0;
break;
case 256:
default:
val |=0x00004000;
break;
case 512:
val |= 0x00008000;
break;
case 1024:
val |= 0x0000c000;
break;
}
switch(pPsdScan->nPSDAvgNum)
{
case 1:
val |= 0x0;
break;
case 8:
val |=0x00001000;
break;
case 16:
val |= 0x00002000;
break;
case 32:
default:
val |= 0x00003000;
break;
}
pBtCoexist->fBtcWrite4Byte(pBtCoexist, 0x808, val);
//RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx SweepPSDPoint(), PSD BW= %d, DeltaFreq=%d\n"
// , pPsdScan->nPSDBandWidth, nDeltaFreqPerPoint));
flag = 1;
break;
case 1: //calculate the PSD point index from freq/offset/span
nPSDCenterFreq = pPsdScan->nPSDBandWidth /2 +offset*(1000000);
//RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx SweepPSDPoint(), PSD Center Freq = %d\n", (centFreq + offset)));
nStartP = pPsdScan->nPSDStartBase + (nPSDCenterFreq - span *(1000000)/2) /nDeltaFreqPerPoint;
pPsdScan->nPSDStartPoint = nStartP - pPsdScan->nPSDStartBase;
//RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx SweepPSDPoint(), Start PSD Poin Matrix Index = %d\n", pPsdScan->nPSDStartPoint));
nStopP = pPsdScan->nPSDStartBase + (nPSDCenterFreq + span *(1000000)/2) /nDeltaFreqPerPoint;
pPsdScan->nPSDStopPoint = nStopP - pPsdScan->nPSDStartBase-1;
//RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx SweepPSDPoint(), Stop PSD Poin Matrix Index = %d\n",pPsdScan->nPSDStopPoint));
flag = 2;
break;
case 2: //set RF channel/BW/Mode
//set 3-wire off
val = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0x88c);
val |= 0x00300000;
pBtCoexist->fBtcWrite4Byte(pBtCoexist,0x88c,val);
//CCK off
val = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0x800);
val &= 0xfeffffff;
pBtCoexist->fBtcWrite4Byte(pBtCoexist,0x800,val);
//store WiFi original channel
WiFi_OriginalChannel = pBtCoexist->fBtcGetRfReg(pBtCoexist, BTC_RF_A, 0x18, 0x3ff);
//Set RF channel
if (centFreq == 2484)
pBtCoexist->fBtcSetRfReg(pBtCoexist, BTC_RF_A, 0x18, 0x3ff, 0xe);
else
pBtCoexist->fBtcSetRfReg(pBtCoexist, BTC_RF_A, 0x18, 0x3ff, (centFreq-2412)/5 + 1); //WiFi TRx Mask on
//Set RF mode = Rx, RF Gain = 0x8a0
pBtCoexist->fBtcSetRfReg(pBtCoexist, BTC_RF_A, 0x0, 0xfffff, 0x308a0);
//Set RF Rx filter corner
pBtCoexist->fBtcSetRfReg(pBtCoexist, BTC_RF_A, 0x1e, 0xfffff, 0x3e4);
//Set TRx mask off
//un-lock TRx Mask setup
pBtCoexist->fBtcSetRfReg(pBtCoexist, BTC_RF_A, 0xdd, 0x80, 0x1);
pBtCoexist->fBtcSetRfReg(pBtCoexist, BTC_RF_A, 0xdf, 0x1, 0x1);
pBtCoexist->fBtcSetRfReg(pBtCoexist, BTC_RF_A, 0x1, 0xfffff, 0x0);
flag = 3;
break;
case 3:
memset(pPsdScan->nPSDReport,0, pPsdScan->nPSDPoint*sizeof(u4Byte));
nStartP = pPsdScan->nPSDStartPoint + pPsdScan->nPSDStartBase;
nStopP = pPsdScan->nPSDStopPoint + pPsdScan->nPSDStartBase + 1;
i = nStartP;
while (i < nStopP)
{
if (i >= nPoints)
{
psd_report = halbtc8703b1ant_PSD_GetData(pBtCoexist,i-nPoints);
}
else
{
psd_report = halbtc8703b1ant_PSD_GetData(pBtCoexist,i);
}
if (psd_report == 0)
tmp = 0;
else
//tmp = 20*log10((double)psd_report);
//20*log2(x)/log2(10), log2Base return theresult of the psd_report*100
tmp = 6 * halbtc8703b1ant_PSD_Log2Base(pBtCoexist, psd_report);
n = i-pPsdScan->nPSDStartBase;
pPsdScan->nPSDReport[n] = tmp;
PsdRep1 = pPsdScan->nPSDReport[n] /100;
PsdRep2 = pPsdScan->nPSDReport[n] - PsdRep1 * 100;
freq = ((centFreq-20) * 1000000 + n * nDeltaFreqPerPoint);
freq1 = freq/1000000;
freq2 = freq/1000 - freq1 * 1000;
/*
if (freq2 < 100)
RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx SweepPSDPoint(), i = %d (%d.0%d MHz)", n, freq1, freq2));
else
RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx SweepPSDPoint(), i = %d (%d.%d MHz)", n, freq1, freq2));
if (PsdRep2 < 10)
RT_TRACE(COMP_COEX, DBG_LOUD, (", PSDReport = %d (%d.0%d dB)\n",psd_report, PsdRep1, PsdRep2));
else
RT_TRACE(COMP_COEX, DBG_LOUD, (", PSDReport = %d (%d.%d dB)\n",psd_report, PsdRep1,PsdRep2));
*/
i++;
k=0;
//Add Delay between PSD point
while(1)
{
if (k++ > 20000)
break;
}
//RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx SweepPSDPoint()==============\n"));
}
flag = 100;
break;
case 99: //error
outloop = TRUE;
break;
case 100: //recovery
//set 3-wire on
val = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0x88c);
val &=0xffcfffff;
pBtCoexist->fBtcWrite4Byte(pBtCoexist,0x88c,val);
//CCK on
val = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0x800);
val |= 0x01000000;
pBtCoexist->fBtcWrite4Byte(pBtCoexist,0x800,val);
//PSD off
val = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0x808);
val &=0xffbfffff;
pBtCoexist->fBtcWrite4Byte(pBtCoexist,0x808,val);
//TRx Mask on
pBtCoexist->fBtcSetRfReg(pBtCoexist, BTC_RF_A, 0x1, 0xfffff, 0x780);
//lock TRx Mask setup
pBtCoexist->fBtcSetRfReg(pBtCoexist, BTC_RF_A, 0xdd, 0x80, 0x0);
pBtCoexist->fBtcSetRfReg(pBtCoexist, BTC_RF_A, 0xdf, 0x1, 0x0);
//Set RF Rx filter corner
pBtCoexist->fBtcSetRfReg(pBtCoexist, BTC_RF_A, 0x1e, 0xfffff, 0x0);
//restore WiFi original channel
pBtCoexist->fBtcSetRfReg(pBtCoexist, BTC_RF_A, 0x18, 0x3ff, WiFi_OriginalChannel);
outloop = TRUE;
break;
}
}while (!outloop);
pPsdScan->bIsPSDRunning = FALSE;
}
//============================================================
// work around function start with wa_halbtc8703b1ant_
//============================================================
//============================================================
// extern function start with EXhalbtc8703b1ant_
//============================================================
VOID
EXhalbtc8703b1ant_PowerOnSetting(
IN PBTC_COEXIST pBtCoexist
)
{
PBTC_BOARD_INFO pBoardInfo=&pBtCoexist->boardInfo;
u1Byte u1Tmp=0x0;
u2Byte u2Tmp=0x0;
RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx Execute 8703b 1-Ant PowerOn Setting xxxxxxxxxxxxxxxx!!\n"));
RT_TRACE(COMP_COEX, DBG_LOUD, ("Ant Det Finish = %s, Ant Det Number = %d\n",
(pBoardInfo->btdmAntDetFinish? "Yes":"No"), pBoardInfo->btdmAntNumByAntDet));
pBtCoexist->bStopCoexDm = TRUE;
// enable BB, REG_SYS_FUNC_EN such that we can write 0x948 correctly.
u2Tmp = pBtCoexist->fBtcRead2Byte(pBtCoexist, 0x2);
pBtCoexist->fBtcWrite2Byte(pBtCoexist, 0x2, u2Tmp|BIT0|BIT1);
//set Path control owner to WiFi
halbtc8703b1ant_LTECoex_PathControlOwner(pBtCoexist, WLSIDE_CONTROL);
// set GNT_BT to high
halbtc8703b1ant_LTECoex_Set_GNT_BT(pBtCoexist, RFC_AND_BB, CONTROL_BY_SW, SET_TO_HIGH);
//Set GNT_WL to low
halbtc8703b1ant_LTECoex_Set_GNT_WL(pBtCoexist, RFC_AND_BB, CONTROL_BY_SW, SET_TO_LOW);
// set WLAN_ACT = 0
pBtCoexist->fBtcWrite1Byte(pBtCoexist, 0x76e, 0x4);
//
// S0 or S1 setting and Local register setting(By the setting fw can get ant number, S0/S1, ... info)
// Local setting bit define
// BIT0: "0" for no antenna inverse; "1" for antenna inverse
// BIT1: "0" for internal switch; "1" for external switch
// BIT2: "0" for one antenna; "1" for two antenna
// NOTE: here default all internal switch and 1-antenna ==> BIT1=0 and BIT2=0
u1Tmp = 0;
pBoardInfo->btdmAntPos = BTC_ANTENNA_AT_MAIN_PORT;
if(pBtCoexist->chipInterface == BTC_INTF_USB)
{
pBtCoexist->fBtcWriteLocalReg1Byte(pBtCoexist, 0xfe08, u1Tmp);
}
else if(pBtCoexist->chipInterface == BTC_INTF_SDIO)
{
pBtCoexist->fBtcWriteLocalReg1Byte(pBtCoexist, 0x60, u1Tmp);
}
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], ********** LTE coex Reg 0x38 (Power-On) = 0x%x**********\n", halbtc8703b1ant_LTECoex_InDirectReadReg(pBtCoexist, 0x38)));
#if 0
if(pBtCoexist->chipInterface == BTC_INTF_USB)
{
// fixed at S0 for USB interface
pBtCoexist->fBtcWrite4Byte(pBtCoexist, 0x948, 0x0);
u1Tmp |= 0x1; // antenna inverse
pBtCoexist->fBtcWriteLocalReg1Byte(pBtCoexist, 0xfe08, u1Tmp);
pBoardInfo->btdmAntPos = BTC_ANTENNA_AT_AUX_PORT;
}
else
{
// for PCIE and SDIO interface, we check efuse 0xc3[6]
if(pBoardInfo->singleAntPath == 0)
{
// set to S1
pBtCoexist->fBtcWrite4Byte(pBtCoexist, 0x948, 0x280);
pBoardInfo->btdmAntPos = BTC_ANTENNA_AT_MAIN_PORT;
}
else if(pBoardInfo->singleAntPath == 1)
{
// set to S0
pBtCoexist->fBtcWrite4Byte(pBtCoexist, 0x948, 0x0);
u1Tmp |= 0x1; // antenna inverse
pBoardInfo->btdmAntPos = BTC_ANTENNA_AT_AUX_PORT;
}
if(pBtCoexist->chipInterface == BTC_INTF_PCI)
{
pBtCoexist->fBtcWriteLocalReg1Byte(pBtCoexist, 0x384, u1Tmp);
}
else if(pBtCoexist->chipInterface == BTC_INTF_SDIO)
{
pBtCoexist->fBtcWriteLocalReg1Byte(pBtCoexist, 0x60, u1Tmp);
}
}
#endif
}
VOID
EXhalbtc8703b1ant_PreLoadFirmware(
IN PBTC_COEXIST pBtCoexist
)
{
}
VOID
EXhalbtc8703b1ant_InitHwConfig(
IN PBTC_COEXIST pBtCoexist,
IN BOOLEAN bWifiOnly
)
{
halbtc8703b1ant_InitHwConfig(pBtCoexist, TRUE, bWifiOnly);
pBtCoexist->bStopCoexDm = FALSE;
}
VOID
EXhalbtc8703b1ant_InitCoexDm(
IN PBTC_COEXIST pBtCoexist
)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Coex Mechanism Init!!\n"));
pBtCoexist->bStopCoexDm = FALSE;
halbtc8703b1ant_InitCoexDm(pBtCoexist);
halbtc8703b1ant_QueryBtInfo(pBtCoexist);
}
VOID
EXhalbtc8703b1ant_DisplayCoexInfo(
IN PBTC_COEXIST pBtCoexist
)
{
PBTC_BOARD_INFO pBoardInfo=&pBtCoexist->boardInfo;
PBTC_STACK_INFO pStackInfo=&pBtCoexist->stackInfo;
PBTC_BT_LINK_INFO pBtLinkInfo=&pBtCoexist->btLinkInfo;
pu1Byte cliBuf=pBtCoexist->cliBuf;
u1Byte u1Tmp[4], i, btInfoExt, psTdmaCase=0;
u2Byte u2Tmp[4];
u4Byte u4Tmp[4];
u4Byte faOfdm, faCck;
u4Byte fwVer=0, btPatchVer=0;
static u1Byte PopReportIn10s = 0;
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n ============[BT Coexist info]============");
CL_PRINTF(cliBuf);
if(pBtCoexist->bManualControl)
{
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n ============[Under Manual Control]============");
CL_PRINTF(cliBuf);
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n ==========================================");
CL_PRINTF(cliBuf);
}
if(pBtCoexist->bStopCoexDm)
{
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n ============[Coex is STOPPED]============");
CL_PRINTF(cliBuf);
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n ==========================================");
CL_PRINTF(cliBuf);
}
if (pPsdScan->bAntDet_TryCount == 0)
{
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %d/ %d/ %d", "Ant PG Num/ Mech/ Pos",
pBoardInfo->pgAntNum, pBoardInfo->btdmAntNum, pBoardInfo->btdmAntPos);
CL_PRINTF(cliBuf);
}
else
{
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %d/ %d/ %d (%d/%d/%d)", "Ant PG Num/ Mech(Ant_Det)/ Pos",
pBoardInfo->pgAntNum, pBoardInfo->btdmAntNumByAntDet, pBoardInfo->btdmAntPos,
pPsdScan->bAntDet_TryCount, pPsdScan->bAntDet_FailCount, pPsdScan->nAntDet_Result);
CL_PRINTF(cliBuf);
if (pBoardInfo->btdmAntDetFinish)
{
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %s", "Ant Det PSD Value", pPsdScan->nAntDet_PeakVal);
CL_PRINTF(cliBuf);
}
}
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %s / %d", "BT stack/ hci ext ver", \
((pStackInfo->bProfileNotified)? "Yes":"No"), pStackInfo->hciVersion);
CL_PRINTF(cliBuf);
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_U4_BT_PATCH_VER, &btPatchVer);
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_U4_WIFI_FW_VER, &fwVer);
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %d_%x/ 0x%x/ 0x%x(%d)", "CoexVer/ FwVer/ PatchVer", \
GLCoexVerDate8703b1Ant, GLCoexVer8703b1Ant, fwVer, btPatchVer, btPatchVer);
CL_PRINTF(cliBuf);
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %02x %02x %02x ", "Wifi channel informed to BT", \
pCoexDm->wifiChnlInfo[0], pCoexDm->wifiChnlInfo[1],
pCoexDm->wifiChnlInfo[2]);
CL_PRINTF(cliBuf);
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %s/ %s/ %s", "WifibHiPri/ Ccklock/ CckEverLock", \
(pCoexSta->bWiFiIsHighPriTask? "Yes":"No"),
(pCoexSta->bCCKLock? "Yes":"No"),
(pCoexSta->bCCKEverLock? "Yes":"No"));
CL_PRINTF(cliBuf);
// wifi status
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s", "============[Wifi Status]============");
CL_PRINTF(cliBuf);
pBtCoexist->fBtcDispDbgMsg(pBtCoexist, BTC_DBG_DISP_WIFI_STATUS);
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s", "============[BT Status]============");
CL_PRINTF(cliBuf);
PopReportIn10s++;
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = [%s/ %d/ %d/ %d] ", "BT [status/ rssi/ retryCnt/ popCnt]", \
((pBtCoexist->btInfo.bBtDisabled)? ("disabled"): ((pCoexSta->bC2hBtInquiryPage)?("inquiry/page scan"):((BT_8703B_1ANT_BT_STATUS_NON_CONNECTED_IDLE == pCoexDm->btStatus)? "non-connected idle":
( (BT_8703B_1ANT_BT_STATUS_CONNECTED_IDLE == pCoexDm->btStatus)? "connected-idle":"busy")))),
pCoexSta->btRssi, pCoexSta->btRetryCnt, pCoexSta->popEventCnt);
CL_PRINTF(cliBuf);
if (PopReportIn10s >= 5)
{
pCoexSta->popEventCnt = 0;
PopReportIn10s = 0;
}
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %d / %d / %d / %d / %d", "SCO/HID/PAN/A2DP/Hi-Pri", \
pBtLinkInfo->bScoExist, pBtLinkInfo->bHidExist, pBtLinkInfo->bPanExist, pBtLinkInfo->bA2dpExist, pBtLinkInfo->bBtHiPriLinkExist);
CL_PRINTF(cliBuf);
if (pStackInfo->bProfileNotified)
{
pBtCoexist->fBtcDispDbgMsg(pBtCoexist, BTC_DBG_DISP_BT_LINK_INFO);
}
else
{
btInfoExt = pCoexSta->btInfoExt;
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %s/ %s", "BT Role/A2DP rate", \
(pBtLinkInfo->bSlaveRole )? "Slave":"Master", (btInfoExt&BIT0)? "BR":"EDR");
CL_PRINTF(cliBuf);
}
for(i=0; i<BT_INFO_SRC_8703B_1ANT_MAX; i++)
{
if(pCoexSta->btInfoC2hCnt[i])
{
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %02x %02x %02x %02x %02x %02x %02x(%d)", GLBtInfoSrc8703b1Ant[i], \
pCoexSta->btInfoC2h[i][0], pCoexSta->btInfoC2h[i][1],
pCoexSta->btInfoC2h[i][2], pCoexSta->btInfoC2h[i][3],
pCoexSta->btInfoC2h[i][4], pCoexSta->btInfoC2h[i][5],
pCoexSta->btInfoC2h[i][6], pCoexSta->btInfoC2hCnt[i]);
CL_PRINTF(cliBuf);
}
}
if(pBtCoexist->bManualControl)
{
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s", "============[Sw mechanism] (before Manual)============");
}
else
{
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s", "============[Sw mechanism]============");
}
CL_PRINTF(cliBuf);
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %d/ 0x%x", "SM[LowPenaltyRA]/RA Mask", \
pCoexDm->bCurLowPenaltyRa, pBtCoexist->btInfo.raMask);
CL_PRINTF(cliBuf);
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %s/ %s/ %d ", "NoAggr/ CtrlAggr/ AggrSize", \
(pBtCoexist->btInfo.bRejectAggPkt? "Yes":"No"), (pBtCoexist->btInfo.bBtCtrlAggBufSize? "Yes":"No"),
pBtCoexist->btInfo.aggBufSize);
CL_PRINTF(cliBuf);
// Fw mechanism
if(pBtCoexist->bManualControl)
{
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s", "============[Fw mechanism] (before Manual) ============");
}
else
{
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s", "============[Fw mechanism]============");
}
CL_PRINTF(cliBuf);
psTdmaCase = pCoexDm->curPsTdma;
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %02x %02x %02x %02x %02x case-%d (%s,%s)", "PS TDMA", \
pCoexDm->psTdmaPara[0], pCoexDm->psTdmaPara[1],
pCoexDm->psTdmaPara[2], pCoexDm->psTdmaPara[3],
pCoexDm->psTdmaPara[4], psTdmaCase,
(pCoexDm->bCurPsTdmaOn? "On":"Off"),
(pCoexDm->bAutoTdmaAdjust? "Adj":"Fix") );
CL_PRINTF(cliBuf);
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %d", "WL/BT Coex Table Type", \
pCoexSta->nCoexTableType);
CL_PRINTF(cliBuf);
u4Tmp[0] = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0x6c0);
u4Tmp[1] = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0x6c4);
u4Tmp[2] = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0x6c8);
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = 0x%x/ 0x%x/ 0x%x", "0x6c0/0x6c4/0x6c8(coexTable)", \
u4Tmp[0], u4Tmp[1], u4Tmp[2]);
CL_PRINTF(cliBuf);
u1Tmp[0] = pBtCoexist->fBtcRead1Byte(pBtCoexist, 0x778);
u4Tmp[0] = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0x6cc);
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = 0x%x/ 0x%x/ 0x%x", "0x778/0x6cc/IgnWlanAct", \
u1Tmp[0], u4Tmp[0], pCoexDm->bCurIgnoreWlanAct);
CL_PRINTF(cliBuf);
u4Tmp[0] = halbtc8703b1ant_LTECoex_InDirectReadReg(pBtCoexist, 0xa0);
u4Tmp[1] = halbtc8703b1ant_LTECoex_InDirectReadReg(pBtCoexist, 0xa4);
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = 0x%x/ 0x%x", "LTE Coex Table W_L/B_L", \
u4Tmp[0]&0xffff, u4Tmp[1]&0xffff);
CL_PRINTF(cliBuf);
u4Tmp[0] = halbtc8703b1ant_LTECoex_InDirectReadReg(pBtCoexist, 0xa8);
u4Tmp[1] = halbtc8703b1ant_LTECoex_InDirectReadReg(pBtCoexist, 0xac);
u4Tmp[2] = halbtc8703b1ant_LTECoex_InDirectReadReg(pBtCoexist, 0xb0);
u4Tmp[3] = halbtc8703b1ant_LTECoex_InDirectReadReg(pBtCoexist, 0xb4);
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = 0x%x/ 0x%x/ 0x%x/ 0x%x", "LTE Break Table W_L/B_L/L_W/L_B", \
u4Tmp[0]&0xffff, u4Tmp[1]&0xffff, u4Tmp[2]&0xffff, u4Tmp[3]&0xffff);
CL_PRINTF(cliBuf);
// Hw setting
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s", "============[Hw setting]============");
CL_PRINTF(cliBuf);
u4Tmp[0] = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0x430);
u4Tmp[1] = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0x434);
u2Tmp[0] = pBtCoexist->fBtcRead2Byte(pBtCoexist, 0x42a);
u1Tmp[0] = pBtCoexist->fBtcRead1Byte(pBtCoexist, 0x456);
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = 0x%x/0x%x/0x%x/0x%x", "0x430/0x434/0x42a/0x456", \
u4Tmp[0], u4Tmp[1], u2Tmp[0], u1Tmp[0]);
CL_PRINTF(cliBuf);
u4Tmp[0] = halbtc8703b1ant_LTECoex_InDirectReadReg(pBtCoexist, 0x38);
u1Tmp[0] = pBtCoexist->fBtcRead1Byte(pBtCoexist, 0x73);
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %d/ %s", "LTE CoexOn/Path Ctrl Owner", \
((u4Tmp[0]&BIT7)>> 7), ((u1Tmp[0]&BIT2)? "WL":"BT"));
CL_PRINTF(cliBuf);
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %d/ %d/ %d/ %d", "LTE 3Wire/OPMode/UART/UARTMode", \
((u4Tmp[0]&BIT6)>> 6), ((u4Tmp[0]&(BIT5|BIT4))>> 4),((u4Tmp[0]&BIT3)>> 3), (u4Tmp[0]&(BIT2|BIT1|BIT0)));
CL_PRINTF(cliBuf);
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %d/ %d/ %s", "GNT_WL_SWCtrl/GNT_BT_SWCtrl/Dbg", \
((u4Tmp[0]&BIT12)>> 12), ((u4Tmp[0]&BIT14)>> 14), ((u1Tmp[0]&BIT3)? "On":"Off"));
CL_PRINTF(cliBuf);
u4Tmp[0] = halbtc8703b1ant_LTECoex_InDirectReadReg(pBtCoexist, 0x54);
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %d/ %d/ %d/ %d", "GNT_WL/GNT_BT/LTE_Busy/UART_Busy", \
((u4Tmp[0]&BIT2)>> 2), ((u4Tmp[0]&BIT3)>> 3), ((u4Tmp[0]&BIT1)>> 1), (u4Tmp[0]&BIT0));
CL_PRINTF(cliBuf);
u1Tmp[0] = pBtCoexist->fBtcRead1Byte(pBtCoexist, 0x4c6);
u1Tmp[1] = pBtCoexist->fBtcRead1Byte(pBtCoexist, 0x40);
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = 0x%x/ 0x%x", "0x4c6[4]/0x40[5] (WL/BT PTA)", \
((u1Tmp[0] & BIT4)>>4), ((u1Tmp[1] & BIT5)>>5));
CL_PRINTF(cliBuf);
u4Tmp[0] = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0x550);
u1Tmp[0] = pBtCoexist->fBtcRead1Byte(pBtCoexist, 0x522);
u1Tmp[1] = pBtCoexist->fBtcRead1Byte(pBtCoexist, 0x953);
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = 0x%x/ 0x%x/ %s", "0x550(bcn ctrl)/0x522/4-RxAGC", \
u4Tmp[0], u1Tmp[0], (u1Tmp[1]&0x2)? "On": "Off");
CL_PRINTF(cliBuf);
u4Tmp[0] = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0xda0);
u4Tmp[1] = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0xda4);
u4Tmp[2] = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0xda8);
u4Tmp[3] = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0xcf0);
u1Tmp[0] = pBtCoexist->fBtcRead1Byte(pBtCoexist, 0xa5b);
u1Tmp[1] = pBtCoexist->fBtcRead1Byte(pBtCoexist, 0xa5c);
faOfdm = ((u4Tmp[0]&0xffff0000) >> 16) + ((u4Tmp[1]&0xffff0000) >> 16) + (u4Tmp[1] & 0xffff) + (u4Tmp[2] & 0xffff) + \
((u4Tmp[3]&0xffff0000) >> 16) + (u4Tmp[3] & 0xffff) ;
faCck = (u1Tmp[0] << 8) + u1Tmp[1];
u4Tmp[1] = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0xc50);
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = 0x%x/ 0x%x/ 0x%x/ 0x%x", "0xc50/OFDM-CCA/OFDM-FA/CCK-FA", \
u4Tmp[1]&0xff, u4Tmp[0]&0xffff, faOfdm, faCck);
CL_PRINTF(cliBuf);
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %d/ %d/ %d/ %d", "CRC_OK CCK/11g/11n/11n-Agg", \
pCoexSta->nCRCOK_CCK, pCoexSta->nCRCOK_11g, pCoexSta->nCRCOK_11n, pCoexSta->nCRCOK_11nAgg);
CL_PRINTF(cliBuf);
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %d/ %d/ %d/ %d", "CRC_Err CCK/11g/11n/11n-Agg", \
pCoexSta->nCRCErr_CCK, pCoexSta->nCRCErr_11g, pCoexSta->nCRCErr_11n, pCoexSta->nCRCErr_11nAgg);
CL_PRINTF(cliBuf);
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %d/ %d", "0x770(high-pri rx/tx)", \
pCoexSta->highPriorityRx, pCoexSta->highPriorityTx);
CL_PRINTF(cliBuf);
CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %d/ %d", "0x774(low-pri rx/tx)", \
pCoexSta->lowPriorityRx, pCoexSta->lowPriorityTx);
CL_PRINTF(cliBuf);
#if(BT_AUTO_REPORT_ONLY_8703B_1ANT == 1)
//halbtc8703b1ant_MonitorBtCtr(pBtCoexist);
#endif
pBtCoexist->fBtcDispDbgMsg(pBtCoexist, BTC_DBG_DISP_COEX_STATISTICS);
}
VOID
EXhalbtc8703b1ant_IpsNotify(
IN PBTC_COEXIST pBtCoexist,
IN u1Byte type
)
{
u4Byte u4Tmp=0;
if(pBtCoexist->bManualControl || pBtCoexist->bStopCoexDm)
return;
if(BTC_IPS_ENTER == type)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], IPS ENTER notify\n"));
pCoexSta->bUnderIps = TRUE;
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, FALSE, 0);
halbtc8703b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_BT, FORCE_EXEC, FALSE, TRUE);
halbtc8703b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 0);
}
else if(BTC_IPS_LEAVE == type)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], IPS LEAVE notify\n"));
halbtc8703b1ant_InitHwConfig(pBtCoexist, FALSE, FALSE);
halbtc8703b1ant_InitCoexDm(pBtCoexist);
halbtc8703b1ant_QueryBtInfo(pBtCoexist);
pCoexSta->bUnderIps = FALSE;
}
}
VOID
EXhalbtc8703b1ant_LpsNotify(
IN PBTC_COEXIST pBtCoexist,
IN u1Byte type
)
{
if(pBtCoexist->bManualControl || pBtCoexist->bStopCoexDm)
return;
if(BTC_LPS_ENABLE == type)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], LPS ENABLE notify\n"));
pCoexSta->bUnderLps = TRUE;
}
else if(BTC_LPS_DISABLE == type)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], LPS DISABLE notify\n"));
pCoexSta->bUnderLps = FALSE;
}
}
VOID
EXhalbtc8703b1ant_ScanNotify(
IN PBTC_COEXIST pBtCoexist,
IN u1Byte type
)
{
BOOLEAN bWifiConnected=FALSE, bBtHsOn=FALSE;
u4Byte wifiLinkStatus=0;
u4Byte numOfWifiLink=0;
BOOLEAN bBtCtrlAggBufSize=FALSE;
u1Byte aggBufSize=5;
u1Byte u1Tmpa, u1Tmpb;
u4Byte u4Tmp;
if(pBtCoexist->bManualControl ||
pBtCoexist->bStopCoexDm )
return;
if(BTC_SCAN_START == type)
{
pCoexSta->bWiFiIsHighPriTask = TRUE;
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], SCAN START notify\n"));
halbtc8703b1ant_PsTdma(pBtCoexist, FORCE_EXEC, FALSE, 8); //Force antenna setup for no scan result issue
halbtc8703b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_PTA, FORCE_EXEC, FALSE, FALSE);
}
else
{
pCoexSta->bWiFiIsHighPriTask = FALSE;
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], SCAN FINISH notify\n"));
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_U1_AP_NUM, &pCoexSta->nScanAPNum);
}
if(pBtCoexist->btInfo.bBtDisabled)
return;
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_HS_OPERATION, &bBtHsOn);
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_CONNECTED, &bWifiConnected);
halbtc8703b1ant_QueryBtInfo(pBtCoexist);
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_U4_WIFI_LINK_STATUS, &wifiLinkStatus);
numOfWifiLink = wifiLinkStatus>>16;
if(numOfWifiLink >= 2)
{
halbtc8703b1ant_LimitedTx(pBtCoexist, NORMAL_EXEC, 0, 0, 0, 0);
halbtc8703b1ant_LimitedRx(pBtCoexist, NORMAL_EXEC, FALSE, bBtCtrlAggBufSize, aggBufSize);
halbtc8703b1ant_ActionWifiMultiPort(pBtCoexist);
return;
}
if(pCoexSta->bC2hBtInquiryPage)
{
halbtc8703b1ant_ActionBtInquiry(pBtCoexist);
return;
}
else if(bBtHsOn)
{
halbtc8703b1ant_ActionHs(pBtCoexist);
return;
}
if(BTC_SCAN_START == type)
{
//RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], SCAN START notify\n"));
if(!bWifiConnected) // non-connected scan
{
halbtc8703b1ant_ActionWifiNotConnectedScan(pBtCoexist);
}
else // wifi is connected
{
halbtc8703b1ant_ActionWifiConnectedScan(pBtCoexist);
}
}
else if(BTC_SCAN_FINISH == type)
{
//RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], SCAN FINISH notify\n"));
if(!bWifiConnected) // non-connected scan
{
halbtc8703b1ant_ActionWifiNotConnected(pBtCoexist);
}
else
{
halbtc8703b1ant_ActionWifiConnected(pBtCoexist);
}
}
}
VOID
EXhalbtc8703b1ant_ConnectNotify(
IN PBTC_COEXIST pBtCoexist,
IN u1Byte type
)
{
BOOLEAN bWifiConnected=FALSE, bBtHsOn=FALSE;
u4Byte wifiLinkStatus=0;
u4Byte numOfWifiLink=0;
BOOLEAN bBtCtrlAggBufSize=FALSE;
u1Byte aggBufSize=5;
if(pBtCoexist->bManualControl ||
pBtCoexist->bStopCoexDm ||
pBtCoexist->btInfo.bBtDisabled )
return;
if(BTC_ASSOCIATE_START == type)
{
pCoexSta->bWiFiIsHighPriTask = TRUE;
halbtc8703b1ant_PsTdma(pBtCoexist, FORCE_EXEC, FALSE, 8); //Force antenna setup for no scan result issue
halbtc8703b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_PTA, FORCE_EXEC, FALSE, FALSE);
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], CONNECT START notify\n"));
pCoexDm->nArpCnt = 0;
}
else
{
pCoexSta->bWiFiIsHighPriTask = FALSE;
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], CONNECT FINISH notify\n"));
//pCoexDm->nArpCnt = 0;
}
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_U4_WIFI_LINK_STATUS, &wifiLinkStatus);
numOfWifiLink = wifiLinkStatus>>16;
if(numOfWifiLink >= 2)
{
halbtc8703b1ant_LimitedTx(pBtCoexist, NORMAL_EXEC, 0, 0, 0, 0);
halbtc8703b1ant_LimitedRx(pBtCoexist, NORMAL_EXEC, FALSE, bBtCtrlAggBufSize, aggBufSize);
halbtc8703b1ant_ActionWifiMultiPort(pBtCoexist);
return;
}
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_HS_OPERATION, &bBtHsOn);
if(pCoexSta->bC2hBtInquiryPage)
{
halbtc8703b1ant_ActionBtInquiry(pBtCoexist);
return;
}
else if(bBtHsOn)
{
halbtc8703b1ant_ActionHs(pBtCoexist);
return;
}
if(BTC_ASSOCIATE_START == type)
{
//RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], CONNECT START notify\n"));
halbtc8703b1ant_ActionWifiNotConnectedAssoAuth(pBtCoexist);
}
else if(BTC_ASSOCIATE_FINISH == type)
{
//RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], CONNECT FINISH notify\n"));
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_CONNECTED, &bWifiConnected);
if(!bWifiConnected) // non-connected scan
{
halbtc8703b1ant_ActionWifiNotConnected(pBtCoexist);
}
else
{
halbtc8703b1ant_ActionWifiConnected(pBtCoexist);
}
}
}
VOID
EXhalbtc8703b1ant_MediaStatusNotify(
IN PBTC_COEXIST pBtCoexist,
IN u1Byte type
)
{
u1Byte H2C_Parameter[3] ={0};
u4Byte wifiBw;
u1Byte wifiCentralChnl;
BOOLEAN bWifiUnderBMode = FALSE;
if(pBtCoexist->bManualControl ||
pBtCoexist->bStopCoexDm ||
pBtCoexist->btInfo.bBtDisabled )
return;
if(BTC_MEDIA_CONNECT == type)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], MEDIA connect notify\n"));
halbtc8703b1ant_PsTdma(pBtCoexist, FORCE_EXEC, FALSE, 8); //Force antenna setup for no scan result issue
halbtc8703b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_PTA, FORCE_EXEC, FALSE, FALSE);
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_UNDER_B_MODE, &bWifiUnderBMode);
//Set CCK Tx/Rx high Pri except 11b mode
if (bWifiUnderBMode)
{
pBtCoexist->fBtcWrite1Byte(pBtCoexist, 0x6cd, 0x00); //CCK Tx
pBtCoexist->fBtcWrite1Byte(pBtCoexist, 0x6cf, 0x00); //CCK Rx
}
else
{
//pBtCoexist->fBtcWrite1Byte(pBtCoexist, 0x6cd, 0x10); //CCK Tx
//pBtCoexist->fBtcWrite1Byte(pBtCoexist, 0x6cf, 0x10); //CCK Rx
pBtCoexist->fBtcWrite1Byte(pBtCoexist, 0x6cd, 0x00); //CCK Tx
pBtCoexist->fBtcWrite1Byte(pBtCoexist, 0x6cf, 0x10); //CCK Rx
}
pCoexDm->backupArfrCnt1 = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0x430);
pCoexDm->backupArfrCnt2 = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0x434);
pCoexDm->backupRetryLimit = pBtCoexist->fBtcRead2Byte(pBtCoexist, 0x42a);
pCoexDm->backupAmpduMaxTime = pBtCoexist->fBtcRead1Byte(pBtCoexist, 0x456);
}
else
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], MEDIA disconnect notify\n"));
pCoexDm->nArpCnt = 0;
pBtCoexist->fBtcWrite1Byte(pBtCoexist, 0x6cd, 0x0); //CCK Tx
pBtCoexist->fBtcWrite1Byte(pBtCoexist, 0x6cf, 0x0); //CCK Rx
pCoexSta->bCCKEverLock = FALSE;
}
halbtc8703b1ant_UpdateWifiChannelInfo(pBtCoexist, type);
}
VOID
EXhalbtc8703b1ant_SpecialPacketNotify(
IN PBTC_COEXIST pBtCoexist,
IN u1Byte type
)
{
BOOLEAN bBtHsOn=FALSE;
u4Byte wifiLinkStatus=0;
u4Byte numOfWifiLink=0;
BOOLEAN bBtCtrlAggBufSize=FALSE, bUnder4way=FALSE;
u1Byte aggBufSize=5;
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_4_WAY_PROGRESS, &bUnder4way);
if(pBtCoexist->bManualControl ||
pBtCoexist->bStopCoexDm ||
pBtCoexist->btInfo.bBtDisabled )
return;
if( BTC_PACKET_DHCP == type ||
BTC_PACKET_EAPOL == type ||
BTC_PACKET_ARP == type )
{
if (BTC_PACKET_ARP == type)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], special Packet ARP notify\n"));
pCoexDm->nArpCnt++;
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], ARP Packet Count = %d\n", pCoexDm->nArpCnt));
if((pCoexDm->nArpCnt >= 10) && (!bUnder4way)) // if APR PKT > 10 after connect, do not go to ActionWifiConnectedSpecialPacket(pBtCoexist)
{
pCoexSta->bWiFiIsHighPriTask = FALSE;
}
else
{
pCoexSta->bWiFiIsHighPriTask = TRUE;
}
}
else
{
pCoexSta->bWiFiIsHighPriTask = TRUE;
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], special Packet DHCP or EAPOL notify\n"));
}
}
else
{
pCoexSta->bWiFiIsHighPriTask = FALSE;
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], special Packet [Type = %d] notify\n", type));
}
pCoexSta->specialPktPeriodCnt = 0;
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_U4_WIFI_LINK_STATUS, &wifiLinkStatus);
numOfWifiLink = wifiLinkStatus>>16;
if(numOfWifiLink >= 2)
{
halbtc8703b1ant_LimitedTx(pBtCoexist, NORMAL_EXEC, 0, 0, 0, 0);
halbtc8703b1ant_LimitedRx(pBtCoexist, NORMAL_EXEC, FALSE, bBtCtrlAggBufSize, aggBufSize);
halbtc8703b1ant_ActionWifiMultiPort(pBtCoexist);
return;
}
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_HS_OPERATION, &bBtHsOn);
if(pCoexSta->bC2hBtInquiryPage)
{
halbtc8703b1ant_ActionBtInquiry(pBtCoexist);
return;
}
else if(bBtHsOn)
{
halbtc8703b1ant_ActionHs(pBtCoexist);
return;
}
if( BTC_PACKET_DHCP == type ||
BTC_PACKET_EAPOL == type ||
( (BTC_PACKET_ARP == type ) && (pCoexSta->bWiFiIsHighPriTask) ) )
{
halbtc8703b1ant_ActionWifiConnectedSpecialPacket(pBtCoexist);
}
}
VOID
EXhalbtc8703b1ant_BtInfoNotify(
IN PBTC_COEXIST pBtCoexist,
IN pu1Byte tmpBuf,
IN u1Byte length
)
{
PBTC_BT_LINK_INFO pBtLinkInfo=&pBtCoexist->btLinkInfo;
u1Byte btInfo=0;
u1Byte i, rspSource=0;
BOOLEAN bWifiConnected=FALSE;
BOOLEAN bBtBusy=FALSE;
PBTC_BOARD_INFO pBoardInfo=&pBtCoexist->boardInfo;
pCoexSta->bC2hBtInfoReqSent = FALSE;
rspSource = tmpBuf[0]&0xf;
if(rspSource >= BT_INFO_SRC_8703B_1ANT_MAX)
rspSource = BT_INFO_SRC_8703B_1ANT_WIFI_FW;
pCoexSta->btInfoC2hCnt[rspSource]++;
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Bt info[%d], length=%d, hex data=[", rspSource, length));
for(i=0; i<length; i++)
{
pCoexSta->btInfoC2h[rspSource][i] = tmpBuf[i];
if(i == 1)
btInfo = tmpBuf[i];
if(i == length-1)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("0x%02x]\n", tmpBuf[i]));
}
else
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("0x%02x, ", tmpBuf[i]));
}
}
// if 0xff, it means BT is under WHCK test
if (btInfo == 0xff)
pCoexSta->bBtWhckTest = TRUE;
else
pCoexSta->bBtWhckTest = FALSE;
if(BT_INFO_SRC_8703B_1ANT_WIFI_FW != rspSource)
{
pCoexSta->btRetryCnt = // [3:0]
pCoexSta->btInfoC2h[rspSource][2]&0xf;
if (pCoexSta->btRetryCnt >= 1)
pCoexSta->popEventCnt++;
if (pCoexSta->btInfoC2h[rspSource][2]&0x20)
pCoexSta->bC2hBtPage = TRUE;
else
pCoexSta->bC2hBtPage = FALSE;
pCoexSta->btRssi =
pCoexSta->btInfoC2h[rspSource][3]*2-90;
//pCoexSta->btInfoC2h[rspSource][3]*2+10;
pCoexSta->btInfoExt =
pCoexSta->btInfoC2h[rspSource][4];
pCoexSta->bBtTxRxMask = (pCoexSta->btInfoC2h[rspSource][2]&0x40);
pBtCoexist->fBtcSet(pBtCoexist, BTC_SET_BL_BT_TX_RX_MASK, &pCoexSta->bBtTxRxMask);
// Here we need to resend some wifi info to BT
// because bt is reset and loss of the info.
if(pCoexSta->btInfoExt & BIT1)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT ext info bit1 check, send wifi BW&Chnl to BT!!\n"));
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_CONNECTED, &bWifiConnected);
if(bWifiConnected)
{
halbtc8703b1ant_UpdateWifiChannelInfo(pBtCoexist, BTC_MEDIA_CONNECT);
}
else
{
halbtc8703b1ant_UpdateWifiChannelInfo(pBtCoexist, BTC_MEDIA_DISCONNECT);
}
}
if(pCoexSta->btInfoExt & BIT3)
{
if(!pBtCoexist->bManualControl && !pBtCoexist->bStopCoexDm)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT ext info bit3 check, set BT NOT to ignore Wlan active!!\n"));
halbtc8703b1ant_IgnoreWlanAct(pBtCoexist, FORCE_EXEC, FALSE);
}
}
else
{
// BT already NOT ignore Wlan active, do nothing here.
}
#if(BT_AUTO_REPORT_ONLY_8703B_1ANT == 0)
if( (pCoexSta->btInfoExt & BIT4) )
{
// BT auto report already enabled, do nothing
}
else
{
halbtc8703b1ant_BtAutoReport(pBtCoexist, FORCE_EXEC, TRUE);
}
#endif
}
// check BIT2 first ==> check if bt is under inquiry or page scan
if(btInfo & BT_INFO_8703B_1ANT_B_INQ_PAGE)
pCoexSta->bC2hBtInquiryPage = TRUE;
else
pCoexSta->bC2hBtInquiryPage = FALSE;
pCoexSta->nNumOfProfile = 0;
// set link exist status
if(!(btInfo&BT_INFO_8703B_1ANT_B_CONNECTION))
{
pCoexSta->bBtLinkExist = FALSE;
pCoexSta->bPanExist = FALSE;
pCoexSta->bA2dpExist = FALSE;
pCoexSta->bHidExist = FALSE;
pCoexSta->bScoExist = FALSE;
pCoexSta->bBtHiPriLinkExist = FALSE;
}
else // connection exists
{
pCoexSta->bBtLinkExist = TRUE;
if(btInfo & BT_INFO_8703B_1ANT_B_FTP)
{
pCoexSta->bPanExist = TRUE;
pCoexSta->nNumOfProfile++;
}
else
pCoexSta->bPanExist = FALSE;
if(btInfo & BT_INFO_8703B_1ANT_B_A2DP)
{
pCoexSta->bA2dpExist = TRUE;
pCoexSta->nNumOfProfile++;
}
else
pCoexSta->bA2dpExist = FALSE;
if(btInfo & BT_INFO_8703B_1ANT_B_HID)
{
pCoexSta->bHidExist = TRUE;
pCoexSta->nNumOfProfile++;
}
else
pCoexSta->bHidExist = FALSE;
if(btInfo & BT_INFO_8703B_1ANT_B_SCO_ESCO)
{
pCoexSta->bScoExist = TRUE;
pCoexSta->nNumOfProfile++;
}
else
pCoexSta->bScoExist = FALSE;
if ((pCoexSta->bHidExist == FALSE) && (pCoexSta->bC2hBtInquiryPage == FALSE) &&( pCoexSta->bScoExist == FALSE))
{
if (pCoexSta->highPriorityTx + pCoexSta->highPriorityRx >= 160)
{
pCoexSta->bHidExist = TRUE;
pCoexSta->wrongProfileNotification++;
pCoexSta->nNumOfProfile++;
btInfo = btInfo | 0x28;
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BtInfoNotify(), BT HID = true (Hi-Pri > 160)!\n"));
}
}
//Add Hi-Pri Tx/Rx counter to avoid false detection
if (((pCoexSta->bHidExist) || (pCoexSta->bScoExist)) && (pCoexSta->highPriorityTx + pCoexSta->highPriorityRx >= 160)
&& (!pCoexSta->bC2hBtInquiryPage))
pCoexSta->bBtHiPriLinkExist = TRUE;
else
pCoexSta->bBtHiPriLinkExist = FALSE;
if((btInfo&BT_INFO_8703B_1ANT_B_ACL_BUSY) && (pCoexSta->nNumOfProfile == 0))
{
if (pCoexSta->lowPriorityTx + pCoexSta->lowPriorityRx >= 160)
{
pCoexSta->bPanExist = TRUE;
pCoexSta->nNumOfProfile++;
pCoexSta->wrongProfileNotification++;
btInfo = btInfo | 0x88;
}
}
}
halbtc8703b1ant_UpdateBtLinkInfo(pBtCoexist);
btInfo = btInfo & 0x1f; //mask profile bit for connect-ilde identification ( for CSR case: A2DP idle --> 0x41)
if(!(btInfo&BT_INFO_8703B_1ANT_B_CONNECTION))
{
pCoexDm->btStatus = BT_8703B_1ANT_BT_STATUS_NON_CONNECTED_IDLE;
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BtInfoNotify(), BT Non-Connected idle!!!\n"));
}
else if(btInfo == BT_INFO_8703B_1ANT_B_CONNECTION) // connection exists but no busy
{
pCoexDm->btStatus = BT_8703B_1ANT_BT_STATUS_CONNECTED_IDLE;
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BtInfoNotify(), BT Connected-idle!!!\n"));
}
else if((btInfo&BT_INFO_8703B_1ANT_B_SCO_ESCO) ||
(btInfo&BT_INFO_8703B_1ANT_B_SCO_BUSY))
{
pCoexDm->btStatus = BT_8703B_1ANT_BT_STATUS_SCO_BUSY;
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BtInfoNotify(), BT SCO busy!!!\n"));
}
else if(btInfo&BT_INFO_8703B_1ANT_B_ACL_BUSY)
{
if(BT_8703B_1ANT_BT_STATUS_ACL_BUSY != pCoexDm->btStatus)
pCoexDm->bAutoTdmaAdjust = FALSE;
pCoexDm->btStatus = BT_8703B_1ANT_BT_STATUS_ACL_BUSY;
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BtInfoNotify(), BT ACL busy!!!\n"));
}
else
{
pCoexDm->btStatus = BT_8703B_1ANT_BT_STATUS_MAX;
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BtInfoNotify(), BT Non-Defined state!!!\n"));
}
if( (BT_8703B_1ANT_BT_STATUS_ACL_BUSY == pCoexDm->btStatus) ||
(BT_8703B_1ANT_BT_STATUS_SCO_BUSY == pCoexDm->btStatus) ||
(BT_8703B_1ANT_BT_STATUS_ACL_SCO_BUSY == pCoexDm->btStatus) )
bBtBusy = TRUE;
else
bBtBusy = FALSE;
pBtCoexist->fBtcSet(pBtCoexist, BTC_SET_BL_BT_TRAFFIC_BUSY, &bBtBusy);
halbtc8703b1ant_RunCoexistMechanism(pBtCoexist);
}
VOID
EXhalbtc8703b1ant_RfStatusNotify(
IN PBTC_COEXIST pBtCoexist,
IN u1Byte type
)
{
u4Byte u4Tmp;
u1Byte u1Tmpa,u1Tmpb, u1Tmpc;
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], RF Status notify\n"));
if(BTC_RF_ON == type)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], RF is turned ON!!\n"));
pBtCoexist->bStopCoexDm = FALSE;
}
else if(BTC_RF_OFF == type)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], RF is turned OFF!!\n"));
halbtc8703b1ant_PowerSaveState(pBtCoexist, BTC_PS_WIFI_NATIVE, 0x0, 0x0);
halbtc8703b1ant_PsTdma(pBtCoexist, FORCE_EXEC, FALSE, 0);
halbtc8703b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_BT, FORCE_EXEC, FALSE, TRUE);
halbtc8703b1ant_IgnoreWlanAct(pBtCoexist, FORCE_EXEC, TRUE);
pBtCoexist->bStopCoexDm = TRUE;
}
}
VOID
EXhalbtc8703b1ant_HaltNotify(
IN PBTC_COEXIST pBtCoexist
)
{
u4Byte u4Tmp;
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Halt notify\n"));
halbtc8703b1ant_PowerSaveState(pBtCoexist, BTC_PS_WIFI_NATIVE, 0x0, 0x0);
halbtc8703b1ant_PsTdma(pBtCoexist, FORCE_EXEC, FALSE, 0);
halbtc8703b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_BT, FORCE_EXEC, FALSE, TRUE);
halbtc8703b1ant_IgnoreWlanAct(pBtCoexist, FORCE_EXEC, TRUE);
EXhalbtc8703b1ant_MediaStatusNotify(pBtCoexist, BTC_MEDIA_DISCONNECT);
pBtCoexist->bStopCoexDm = TRUE;
}
VOID
EXhalbtc8703b1ant_PnpNotify(
IN PBTC_COEXIST pBtCoexist,
IN u1Byte pnpState
)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Pnp notify\n"));
if(BTC_WIFI_PNP_SLEEP == pnpState)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Pnp notify to SLEEP\n"));
halbtc8703b1ant_PowerSaveState(pBtCoexist, BTC_PS_WIFI_NATIVE, 0x0, 0x0);
halbtc8703b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, FALSE, 0);
halbtc8703b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_BT, FORCE_EXEC, FALSE, TRUE);
halbtc8703b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 2);
pBtCoexist->bStopCoexDm = TRUE;
}
else if(BTC_WIFI_PNP_WAKE_UP == pnpState)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Pnp notify to WAKE UP\n"));
pBtCoexist->bStopCoexDm = FALSE;
halbtc8703b1ant_InitHwConfig(pBtCoexist, FALSE, FALSE);
halbtc8703b1ant_InitCoexDm(pBtCoexist);
halbtc8703b1ant_QueryBtInfo(pBtCoexist);
}
}
VOID
EXhalbtc8703b1ant_CoexDmReset(
IN PBTC_COEXIST pBtCoexist
)
{
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], *****************Coex DM Reset*****************\n"));
halbtc8703b1ant_InitHwConfig(pBtCoexist, FALSE, FALSE);
//pBtCoexist->fBtcSetRfReg(pBtCoexist, BTC_RF_A, 0x1, 0xfffff, 0x0);
//pBtCoexist->fBtcSetRfReg(pBtCoexist, BTC_RF_A, 0x2, 0xfffff, 0x0);
halbtc8703b1ant_InitCoexDm(pBtCoexist);
}
VOID
EXhalbtc8703b1ant_Periodical(
IN PBTC_COEXIST pBtCoexist
)
{
static u1Byte disVerInfoCnt=0;
u4Byte fwVer=0, btPatchVer=0;
PBTC_BOARD_INFO pBoardInfo=&pBtCoexist->boardInfo;
PBTC_STACK_INFO pStackInfo=&pBtCoexist->stackInfo;
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], ==========================Periodical===========================\n"));
if(disVerInfoCnt <= 5)
{
disVerInfoCnt += 1;
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], ****************************************************************\n"));
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Ant PG Num/ Ant Mech/ Ant Pos = %d/ %d/ %d\n",
pBoardInfo->pgAntNum, pBoardInfo->btdmAntNum, pBoardInfo->btdmAntPos));
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT stack/ hci ext ver = %s / %d\n",
((pStackInfo->bProfileNotified)? "Yes":"No"), pStackInfo->hciVersion));
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_U4_BT_PATCH_VER, &btPatchVer);
pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_U4_WIFI_FW_VER, &fwVer);
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], CoexVer/ FwVer/ PatchVer = %d_%x/ 0x%x/ 0x%x(%d)\n",
GLCoexVerDate8703b1Ant, GLCoexVer8703b1Ant, fwVer, btPatchVer, btPatchVer));
RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], ****************************************************************\n"));
}
#if(BT_AUTO_REPORT_ONLY_8703B_1ANT == 0)
halbtc8703b1ant_QueryBtInfo(pBtCoexist);
halbtc8703b1ant_MonitorBtEnableDisable(pBtCoexist);
#else
halbtc8703b1ant_MonitorBtCtr(pBtCoexist);
halbtc8703b1ant_MonitorWiFiCtr(pBtCoexist);
#if BT_8703B_1ANT_ANTDET_ENABLE
halbtc8703b1ant_MonitorBtEnableDisable(pBtCoexist);
#endif
if( halbtc8703b1ant_IsWifiStatusChanged(pBtCoexist) ||
pCoexDm->bAutoTdmaAdjust )
{
halbtc8703b1ant_RunCoexistMechanism(pBtCoexist);
}
pCoexSta->specialPktPeriodCnt++;
// sample to set bt to execute Ant detection
//pBtCoexist->fBtcSetBtAntDetection(pBtCoexist, 20, 14);
/*
if (pPsdScan->bIsAntDetEnable)
{
if (pPsdScan->nPSDGenCount > pPsdScan->realseconds)
pPsdScan->nPSDGenCount = 0;
halbtc8703b1ant_AntennaDetection(pBtCoexist, pPsdScan->realcentFreq, pPsdScan->realoffset, pPsdScan->realspan, pPsdScan->realseconds);
pPsdScan->nPSDGenTotalCount +=2;
pPsdScan->nPSDGenCount += 2;
}
*/
#endif
}
VOID
EXhalbtc8703b1ant_AntennaDetection(
IN PBTC_COEXIST pBtCoexist,
IN u4Byte centFreq,
IN u4Byte offset,
IN u4Byte span,
IN u4Byte seconds
)
{
//No Antenna Detection required because 8730b is only 1-Ant
}
VOID
EXhalbtc8703b1ant_AntennaIsolation(
IN PBTC_COEXIST pBtCoexist,
IN u4Byte centFreq,
IN u4Byte offset,
IN u4Byte span,
IN u4Byte seconds
)
{
}
VOID
EXhalbtc8703b1ant_PSDScan(
IN PBTC_COEXIST pBtCoexist,
IN u4Byte centFreq,
IN u4Byte offset,
IN u4Byte span,
IN u4Byte seconds
)
{
}
VOID
EXhalbtc8703b1ant_DisplayAntDetection(
IN PBTC_COEXIST pBtCoexist
)
{
}
#endif