//============================================================ // Description: // // This file is for RTL8723B Co-exist mechanism // // History // 2012/11/15 Cosa first check in. // //============================================================ //============================================================ // include files //============================================================ #include "Mp_Precomp.h" #if WPP_SOFTWARE_TRACE #include "HalBtc8723b1Ant.tmh" #endif //#include #if(BT_30_SUPPORT == 1) //============================================================ // Global variables, these are static variables //============================================================ static COEX_DM_8723B_1ANT GLCoexDm8723b1Ant; static PCOEX_DM_8723B_1ANT pCoexDm=&GLCoexDm8723b1Ant; static COEX_STA_8723B_1ANT GLCoexSta8723b1Ant; static PCOEX_STA_8723B_1ANT pCoexSta=&GLCoexSta8723b1Ant; static PSDSCAN_STA_8723B_1ANT GLPsdScan8723b1Ant; static PPSDSCAN_STA_8723B_1ANT pPsdScan = &GLPsdScan8723b1Ant; const char *const GLBtInfoSrc8723b1Ant[]={ "BT Info[wifi fw]", "BT Info[bt rsp]", "BT Info[bt auto report]", }; u4Byte GLCoexVerDate8723b1Ant=20150119; u4Byte GLCoexVer8723b1Ant=0x58; //============================================================ // local function proto type if needed //============================================================ //============================================================ // local function start with halbtc8723b1ant_ //============================================================ u1Byte halbtc8723b1ant_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_8723B_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_8723B_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_8723B_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 halbtc8723b1ant_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_8723B_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_8723B_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_8723B_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 halbtc8723b1ant_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 halbtc8723b1ant_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 halbtc8723b1ant_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 halbtc8723b1ant_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 halbtc8723b1ant_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 halbtc8723b1ant_UpdateRaMask(pBtCoexist, bForceExec, 0x0); break; case 1: // disable cck 1/2 halbtc8723b1ant_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 halbtc8723b1ant_UpdateRaMask(pBtCoexist, bForceExec, 0x0001f1f7); break; default: break; } halbtc8723b1ant_AutoRateFallbackRetry(pBtCoexist, bForceExec, arfrType); halbtc8723b1ant_RetryLimit(pBtCoexist, bForceExec, retryLimitType); halbtc8723b1ant_AmpduMaxTime(pBtCoexist, bForceExec, ampduTimeType); } VOID halbtc8723b1ant_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 halbtc8723b1ant_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 halbtc8723b1ant_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 u4Byte 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 > 1050) && (!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); // This part is for wifi FW and driver to update BT's status as disabled. // The flow is as the following // 1. disable BT // 2. if all BT Tx/Rx counter=0, after 6 sec we query bt info // 3. Because BT will not rsp from mailbox, so wifi fw will know BT is disabled // 4. FW will rsp c2h for BT that driver will know BT is disabled. if ((regHPTx == 0) && (regHPRx ==0) && (regLPTx == 0) && (regLPRx == 0)) { NumOfBtCounterChk++; if (NumOfBtCounterChk == 3) { halbtc8723b1ant_QueryBtInfo(pBtCoexist); } } else { NumOfBtCounterChk = 0; } } VOID halbtc8723b1ant_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_8723B_1ANT_BT_STATUS_ACL_BUSY) || (pCoexDm->btStatus == BT_8723B_1ANT_BT_STATUS_ACL_SCO_BUSY) || (pCoexDm->btStatus == BT_8723B_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 halbtc8723b1ant_IsWifiStatusChanged( IN PBTC_COEXIST pBtCoexist ) { static BOOLEAN bPreWifiBusy=FALSE, bPreUnder4way=FALSE, bPreBtHsOn=FALSE; BOOLEAN bWifiBusy=FALSE, bUnder4way=FALSE, bBtHsOn=FALSE; BOOLEAN bWifiConnected=FALSE; u1Byte wifiRssiState=BTC_RSSI_STATE_HIGH; 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 halbtc8723b1ant_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; } u1Byte halbtc8723b1ant_ActionAlgorithm( IN PBTC_COEXIST pBtCoexist ) { PBTC_BT_LINK_INFO pBtLinkInfo=&pBtCoexist->btLinkInfo; BOOLEAN bBtHsOn=FALSE; u1Byte algorithm=BT_8723B_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_8723B_1ANT_COEX_ALGO_SCO; } else { if(pBtLinkInfo->bHidExist) { RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT Profile = HID only\n")); algorithm = BT_8723B_1ANT_COEX_ALGO_HID; } else if(pBtLinkInfo->bA2dpExist) { RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT Profile = A2DP only\n")); algorithm = BT_8723B_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_8723B_1ANT_COEX_ALGO_PANHS; } else { RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT Profile = PAN(EDR) only\n")); algorithm = BT_8723B_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_8723B_1ANT_COEX_ALGO_HID; } else if(pBtLinkInfo->bA2dpExist) { RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT Profile = SCO + A2DP ==> SCO\n")); algorithm = BT_8723B_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_8723B_1ANT_COEX_ALGO_SCO; } else { RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT Profile = SCO + PAN(EDR)\n")); algorithm = BT_8723B_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_8723B_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_8723B_1ANT_COEX_ALGO_HID_A2DP; } else { RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT Profile = HID + PAN(EDR)\n")); algorithm = BT_8723B_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_8723B_1ANT_COEX_ALGO_A2DP_PANHS; } else { RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT Profile = A2DP + PAN(EDR)\n")); algorithm = BT_8723B_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_8723B_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_8723B_1ANT_COEX_ALGO_HID_A2DP; } else { RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT Profile = SCO + HID + PAN(EDR)\n")); algorithm = BT_8723B_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_8723B_1ANT_COEX_ALGO_SCO; } else { RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT Profile = SCO + A2DP + PAN(EDR) ==> HID\n")); algorithm = BT_8723B_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_8723B_1ANT_COEX_ALGO_HID_A2DP; } else { RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BT Profile = HID + A2DP + PAN(EDR)\n")); algorithm = BT_8723B_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_8723B_1ANT_COEX_ALGO_PANEDR_HID; } } } } return algorithm; } VOID halbtc8723b1ant_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 halbtc8723b1ant_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; } halbtc8723b1ant_SetBtAutoReport(pBtCoexist, pCoexDm->bCurBtAutoReport); pCoexDm->bPreBtAutoReport = pCoexDm->bCurBtAutoReport; } VOID halbtc8723b1ant_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 halbtc8723b1ant_LowPenaltyRa( IN PBTC_COEXIST pBtCoexist, IN BOOLEAN bForceExec, IN BOOLEAN bLowPenaltyRa ) { pCoexDm->bCurLowPenaltyRa = bLowPenaltyRa; if(!bForceExec) { if(pCoexDm->bPreLowPenaltyRa == pCoexDm->bCurLowPenaltyRa) return; } halbtc8723b1ant_SetSwPenaltyTxRateAdaptive(pBtCoexist, pCoexDm->bCurLowPenaltyRa); pCoexDm->bPreLowPenaltyRa = pCoexDm->bCurLowPenaltyRa; } VOID halbtc8723b1ant_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 halbtc8723b1ant_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; } halbtc8723b1ant_SetCoexTable(pBtCoexist, val0x6c0, val0x6c4, val0x6c8, val0x6cc); pCoexDm->preVal0x6c0 = pCoexDm->curVal0x6c0; pCoexDm->preVal0x6c4 = pCoexDm->curVal0x6c4; pCoexDm->preVal0x6c8 = pCoexDm->curVal0x6c8; pCoexDm->preVal0x6cc = pCoexDm->curVal0x6cc; } VOID halbtc8723b1ant_CoexTableWithType( IN PBTC_COEXIST pBtCoexist, IN BOOLEAN bForceExec, IN u1Byte type ) { PBTC_BOARD_INFO pBoardInfo=&pBtCoexist->boardInfo; #if BT_8723B_1ANT_ANTDET_ENABLE #if BT_8723B_1ANT_ANTDET_COEXMECHANISMSWITCH_ENABLE if (pBoardInfo->btdmAntNumByAntDet == 2) { if (type == 3) type = 14; else if (type == 4) type = 13; else if (type == 5) type = 8; } #endif #endif RT_TRACE(COMP_COEX, DBG_TRACE, ("[BTCoex], ********** CoexTable(%d) **********\n", type)); pCoexSta->nCoexTableType = type; switch(type) { case 0: halbtc8723b1ant_CoexTable(pBtCoexist, bForceExec, 0x55555555, 0x55555555, 0xffffff, 0x3); break; case 1: halbtc8723b1ant_CoexTable(pBtCoexist, bForceExec, 0x55555555, 0x5a5a5a5a, 0xffffff, 0x3); break; case 2: halbtc8723b1ant_CoexTable(pBtCoexist, bForceExec, 0x5a5a5a5a, 0x5a5a5a5a, 0xffffff, 0x3); break; case 3: halbtc8723b1ant_CoexTable(pBtCoexist, bForceExec, 0x55555555, 0x5a5a5a5a, 0xffffff, 0x3); break; case 4: if ( pCoexSta->bCCKEverLock) halbtc8723b1ant_CoexTable(pBtCoexist, bForceExec, 0x55555555, 0xaaaaaaaa, 0xffffff, 0x3); else halbtc8723b1ant_CoexTable(pBtCoexist, bForceExec, 0x55555555, 0xaaaa5a5a, 0xffffff, 0x3); break; case 5: if ( pCoexSta->bCCKEverLock) halbtc8723b1ant_CoexTable(pBtCoexist, bForceExec, 0xaaaa5a5a, 0xaaaa5a5a, 0xffffff, 0x3); else halbtc8723b1ant_CoexTable(pBtCoexist, bForceExec, 0x5a5a5a5a, 0x5a5a5a5a, 0xffffff, 0x3); break; case 6: halbtc8723b1ant_CoexTable(pBtCoexist, bForceExec, 0x55555555, 0xaaaaaaaa, 0xffffff, 0x3); break; case 7: halbtc8723b1ant_CoexTable(pBtCoexist, bForceExec, 0xaaaaaaaa, 0xaaaaaaaa, 0xffffff, 0x3); break; case 8: halbtc8723b1ant_CoexTable(pBtCoexist, bForceExec, 0x55dd55dd, 0x5ada5ada, 0xffffff, 0x3); break; case 9: halbtc8723b1ant_CoexTable(pBtCoexist, bForceExec, 0x55dd55dd, 0x5ada5ada, 0xffffff, 0x3); break; case 10: halbtc8723b1ant_CoexTable(pBtCoexist, bForceExec, 0x55dd55dd, 0x5ada5ada, 0xffffff, 0x3); break; case 11: halbtc8723b1ant_CoexTable(pBtCoexist, bForceExec, 0x55dd55dd, 0x5ada5ada, 0xffffff, 0x3); break; case 12: halbtc8723b1ant_CoexTable(pBtCoexist, bForceExec, 0x55dd55dd, 0x5ada5ada, 0xffffff, 0x3); break; case 13: halbtc8723b1ant_CoexTable(pBtCoexist, bForceExec, 0x5fff5fff, 0xaaaaaaaa, 0xffffff, 0x3); break; case 14: halbtc8723b1ant_CoexTable(pBtCoexist, bForceExec, 0x5fff5fff, 0x5ada5ada, 0xffffff, 0x3); break; case 15: halbtc8723b1ant_CoexTable(pBtCoexist, bForceExec, 0x55dd55dd, 0xaaaaaaaa, 0xffffff, 0x3); break; default: break; } } VOID halbtc8723b1ant_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 halbtc8723b1ant_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; } halbtc8723b1ant_SetFwIgnoreWlanAct(pBtCoexist, bEnable); pCoexDm->bPreIgnoreWlanAct = pCoexDm->bCurIgnoreWlanAct; } VOID halbtc8723b1ant_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 halbtc8723b1ant_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; } } halbtc8723b1ant_SetLpsRpwm(pBtCoexist, lpsVal, rpwmVal); pCoexDm->preLps = pCoexDm->curLps; pCoexDm->preRpwm = pCoexDm->curRpwm; } VOID halbtc8723b1ant_SwMechanism( IN PBTC_COEXIST pBtCoexist, IN BOOLEAN bLowPenaltyRA ) { halbtc8723b1ant_LowPenaltyRa(pBtCoexist, NORMAL_EXEC, bLowPenaltyRA); } VOID halbtc8723b1ant_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; pCoexDm->curAntPosType = antPosType; pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_EXT_SWITCH, &bPgExtSwitch); pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_U4_WIFI_FW_VER, &fwVer); // [31:16]=fw ver, [15:0]=fw sub ver if((fwVer>0 && fwVer<0xc0000) || bPgExtSwitch) bUseExtSwitch = TRUE; #if BT_8723B_1ANT_ANTDET_ENABLE #if BT_8723B_1ANT_ANTDET_COEXMECHANISMSWITCH_ENABLE if (antPosType == BTC_ANT_PATH_PTA) { if ((pBoardInfo->btdmAntDetFinish) && (pBoardInfo->btdmAntNumByAntDet == 2)) { if(pBoardInfo->btdmAntPos == BTC_ANTENNA_AT_MAIN_PORT) antPosType = BTC_ANT_PATH_WIFI; else antPosType = BTC_ANT_PATH_BT; } } #endif #endif if(bInitHwCfg) { pBtCoexist->fBtcSetRfReg(pBtCoexist, BTC_RF_A, 0x1, 0xfffff, 0x780); //WiFi TRx Mask on //remove due to interrupt is disabled that polling c2h will fail and delay 100ms. //pBtCoexist->fBtcSetBtReg(pBtCoexist, BTC_BT_REG_RF, 0x3c, 0x15); //BT TRx Mask on if(fwVer >= 0x180000) { /* Use H2C to set GNT_BT to HIGH */ H2C_Parameter[0] = 1; pBtCoexist->fBtcFillH2c(pBtCoexist, 0x6E, 1, H2C_Parameter); } else { // set grant_bt to high pBtCoexist->fBtcWrite1Byte(pBtCoexist, 0x765, 0x18); } //set wlan_act control by PTA pBtCoexist->fBtcWrite1Byte(pBtCoexist, 0x76e, 0x4); pBtCoexist->fBtcWrite1ByteBitMask(pBtCoexist, 0x67, 0x20, 0x0); //BT select s0/s1 is controlled by BT pBtCoexist->fBtcWrite1ByteBitMask(pBtCoexist, 0x39, 0x8, 0x1); pBtCoexist->fBtcWrite1Byte(pBtCoexist, 0x974, 0xff); pBtCoexist->fBtcWrite1ByteBitMask(pBtCoexist, 0x944, 0x3, 0x3); pBtCoexist->fBtcWrite1Byte(pBtCoexist, 0x930, 0x77); } else if(bWifiOff) { if(fwVer >= 0x180000) { /* Use H2C to set GNT_BT to HIGH */ H2C_Parameter[0] = 1; pBtCoexist->fBtcFillH2c(pBtCoexist, 0x6E, 1, H2C_Parameter); } else { // set grant_bt to high pBtCoexist->fBtcWrite1Byte(pBtCoexist, 0x765, 0x18); } //set wlan_act to always low pBtCoexist->fBtcWrite1Byte(pBtCoexist, 0x76e, 0x4); pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_IS_IN_MP_MODE, &bIsInMpMode); if(!bIsInMpMode) pBtCoexist->fBtcWrite1ByteBitMask(pBtCoexist, 0x67, 0x20, 0x0); //BT select s0/s1 is controlled by BT else pBtCoexist->fBtcWrite1ByteBitMask(pBtCoexist, 0x67, 0x20, 0x1); //BT select s0/s1 is controlled by WiFi // 0x4c[24:23]=00, Set Antenna control by BT_RFE_CTRL BT Vendor 0xac=0xf002 u4Tmp = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0x4c); u4Tmp &= ~BIT23; u4Tmp &= ~BIT24; pBtCoexist->fBtcWrite4Byte(pBtCoexist, 0x4c, u4Tmp); } else { /* Use H2C to set GNT_BT to LOW */ if(fwVer >= 0x180000) { if (pBtCoexist->fBtcRead1Byte(pBtCoexist, 0x765) != 0) { H2C_Parameter[0] = 0; pBtCoexist->fBtcFillH2c(pBtCoexist, 0x6E, 1, H2C_Parameter); } } else { // BT calibration check 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 grant_bt to PTA pBtCoexist->fBtcWrite1Byte(pBtCoexist, 0x765, 0x0); } if (pBtCoexist->fBtcRead1Byte(pBtCoexist, 0x76e) != 0xc) { //set wlan_act control by PTA pBtCoexist->fBtcWrite1Byte(pBtCoexist, 0x76e, 0xc); } pBtCoexist->fBtcWrite1ByteBitMask(pBtCoexist, 0x67, 0x20, 0x1); //BT select s0/s1 is controlled by WiFi } if(bUseExtSwitch) { if(bInitHwCfg) { // 0x4c[23]=0, 0x4c[24]=1 Antenna control by WL/BT u4Tmp = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0x4c); u4Tmp &=~BIT23; u4Tmp |= BIT24; pBtCoexist->fBtcWrite4Byte(pBtCoexist, 0x4c, u4Tmp); pBtCoexist->fBtcWrite4Byte(pBtCoexist, 0x948, 0x0); // fixed internal switch S1->WiFi, S0->BT if(pBoardInfo->btdmAntPos == BTC_ANTENNA_AT_MAIN_PORT) { //tell firmware "no antenna inverse" H2C_Parameter[0] = 0; H2C_Parameter[1] = 1; //ext switch type pBtCoexist->fBtcFillH2c(pBtCoexist, 0x65, 2, H2C_Parameter); } else { //tell firmware "antenna inverse" H2C_Parameter[0] = 1; H2C_Parameter[1] = 1; //ext switch type pBtCoexist->fBtcFillH2c(pBtCoexist, 0x65, 2, H2C_Parameter); } } if(bForceExec || (pCoexDm->curAntPosType != pCoexDm->preAntPosType)) { // ext switch setting switch(antPosType) { case BTC_ANT_PATH_WIFI: if(pBoardInfo->btdmAntPos == BTC_ANTENNA_AT_MAIN_PORT) pBtCoexist->fBtcWrite1ByteBitMask(pBtCoexist, 0x92c, 0x3, 0x1); else pBtCoexist->fBtcWrite1ByteBitMask(pBtCoexist, 0x92c, 0x3, 0x2); break; case BTC_ANT_PATH_BT: if(pBoardInfo->btdmAntPos == BTC_ANTENNA_AT_MAIN_PORT) pBtCoexist->fBtcWrite1ByteBitMask(pBtCoexist, 0x92c, 0x3, 0x2); else pBtCoexist->fBtcWrite1ByteBitMask(pBtCoexist, 0x92c, 0x3, 0x1); break; default: case BTC_ANT_PATH_PTA: if(pBoardInfo->btdmAntPos == BTC_ANTENNA_AT_MAIN_PORT) pBtCoexist->fBtcWrite1ByteBitMask(pBtCoexist, 0x92c, 0x3, 0x1); else pBtCoexist->fBtcWrite1ByteBitMask(pBtCoexist, 0x92c, 0x3, 0x2); break; } } } else { if(bInitHwCfg) { // 0x4c[23]=1, 0x4c[24]=0 Antenna control by 0x64 u4Tmp = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0x4c); u4Tmp |= BIT23; u4Tmp &=~BIT24; pBtCoexist->fBtcWrite4Byte(pBtCoexist, 0x4c, u4Tmp); //Fix Ext switch Main->S1, Aux->S0 pBtCoexist->fBtcWrite1ByteBitMask(pBtCoexist, 0x64, 0x1, 0x0); if(pBoardInfo->btdmAntPos == BTC_ANTENNA_AT_MAIN_PORT) { //tell firmware "no antenna inverse" H2C_Parameter[0] = 0; H2C_Parameter[1] = 0; //internal switch type pBtCoexist->fBtcFillH2c(pBtCoexist, 0x65, 2, H2C_Parameter); } else { //tell firmware "antenna inverse" H2C_Parameter[0] = 1; H2C_Parameter[1] = 0; //internal switch type pBtCoexist->fBtcFillH2c(pBtCoexist, 0x65, 2, H2C_Parameter); } } if(bForceExec || (pCoexDm->curAntPosType != pCoexDm->preAntPosType)) { // internal switch setting switch(antPosType) { case BTC_ANT_PATH_WIFI: if(pBoardInfo->btdmAntPos == BTC_ANTENNA_AT_MAIN_PORT) pBtCoexist->fBtcWrite4Byte(pBtCoexist, 0x948, 0x0); else pBtCoexist->fBtcWrite4Byte(pBtCoexist, 0x948, 0x280); break; case BTC_ANT_PATH_BT: if(pBoardInfo->btdmAntPos == BTC_ANTENNA_AT_MAIN_PORT) pBtCoexist->fBtcWrite4Byte(pBtCoexist, 0x948, 0x280); else pBtCoexist->fBtcWrite4Byte(pBtCoexist, 0x948, 0x0); break; default: case BTC_ANT_PATH_PTA: if(pBoardInfo->btdmAntPos == BTC_ANTENNA_AT_MAIN_PORT) pBtCoexist->fBtcWrite4Byte(pBtCoexist, 0x948, 0x200); else pBtCoexist->fBtcWrite4Byte(pBtCoexist, 0x948, 0x80); break; } } } pCoexDm->preAntPosType = pCoexDm->curAntPosType; } VOID halbtc8723b1ant_SetAntPathDCut( IN PBTC_COEXIST pBtCoexist, IN BOOLEAN bAntennaAux, //For 1-Ant--> 1: Antenna at S0, 0: Antenna at S1. Set 0 for 2-Ant IN BOOLEAN bExtSwitch, // 1: Ext Switch (SPDT) exist on module, 0: no Ext Switch (SPDT) exist on module IN BOOLEAN bTwoAntenna, // 1: 2-Antenna, 0:1-Antenna IN u1Byte antennaPos, //Set Antenna Pos, For 1-Ant: BTC_ANT_PATH_WIFI, BTC_ANT_PATH_BT, BTC_ANT_PATH_PTA, For 2-Ant:BTC_ANT_WIFI_AT_MAIN, BTC_ANT_WIFI_AT_Aux IN u1Byte wifiState //BTC_WIFI_STAT_INIT, BTC_WIFI_STAT_IQK, BTC_WIFI_STAT_NORMAL_OFF, BTC_WIFI_STAT_MP_OFF, BTC_WIFI_STAT_NORMAL, BTC_WIFI_STAT_ANT_DIV ) { u1Byte dataLen=5; u1Byte buf[6] = {0}; RT_TRACE(COMP_COEX, DBG_TRACE, ("[BTCoex], set BT Ant, bAntennaAux/bExtSwitch/bTwoAntenna/antennaPos/wifiState=%d/%d/%d/%d/%d\n", bAntennaAux, bExtSwitch, bTwoAntenna, antennaPos, wifiState)); buf[0] = dataLen; if(bAntennaAux) buf[1] = 0x1; if(bExtSwitch) buf[2] = 0x1; if(bTwoAntenna) buf[3] = 0x1; buf[4] = antennaPos; buf[5] = wifiState; pBtCoexist->fBtcSet(pBtCoexist, BTC_SET_ACT_CTRL_8723B_ANT, (PVOID)&buf[0]); } VOID halbtc8723b1ant_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 halbtc8723b1ant_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; #if BT_8723B_1ANT_ANTDET_ENABLE #if BT_8723B_1ANT_ANTDET_COEXMECHANISMSWITCH_ENABLE if (pBoardInfo->btdmAntNumByAntDet == 2) { if (bTurnOn) type = type +100; //for WiFi RSSI low or BT RSSI low else type = 1; //always translate to TDMA(off,1) for TDMA-off case } #endif #endif 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; if (pCoexSta->nA2DPBitPool >= 35) nWiFiDurationAdjust = -10; else if (pCoexSta->nA2DPBitPool >= 45) nWiFiDurationAdjust = -15; } else if (pCoexSta->nScanAPNum >= 40) { nWiFiDurationAdjust = -15; if (pCoexSta->nA2DPBitPool < 35) nWiFiDurationAdjust = -5; else if (pCoexSta->nA2DPBitPool < 45) nWiFiDurationAdjust = -10; } else if (pCoexSta->nScanAPNum >= 20) { nWiFiDurationAdjust = -10; if (pCoexSta->nA2DPBitPool >= 45) nWiFiDurationAdjust = -15; } else { nWiFiDurationAdjust = 0; if (pCoexSta->nA2DPBitPool >= 35) nWiFiDurationAdjust = -10; else if (pCoexSta->nA2DPBitPool >= 45) nWiFiDurationAdjust = -15; } 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: halbtc8723b1ant_SetFwPstdma(pBtCoexist, 0x51, 0x1a, 0x1a, 0x0, psTdmaByte4Val); break; case 1: halbtc8723b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x3a+nWiFiDurationAdjust, 0x03, psTdmaByte3Val, psTdmaByte4Val); break; case 2: halbtc8723b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x2d+nWiFiDurationAdjust, 0x03, psTdmaByte3Val, psTdmaByte4Val); break; case 3: halbtc8723b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x3a, 0x03, psTdmaByte3Val, psTdmaByte4Val); break; case 4: halbtc8723b1ant_SetFwPstdma(pBtCoexist, 0x93, 0x15, 0x3, 0x14, 0x0); break; case 5: halbtc8723b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x15, 0x3, psTdmaByte3Val, 0x11); break; case 6: halbtc8723b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x20, 0x3, psTdmaByte3Val, 0x11); break; case 7: halbtc8723b1ant_SetFwPstdma(pBtCoexist, 0x13, 0xc, 0x5, 0x0, 0x0); break; case 8: halbtc8723b1ant_SetFwPstdma(pBtCoexist, 0x93, 0x25, 0x3, 0x10, 0x0); break; case 9: halbtc8723b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x21, 0x3, psTdmaByte3Val, psTdmaByte4Val); break; case 10: halbtc8723b1ant_SetFwPstdma(pBtCoexist, 0x13, 0xa, 0xa, 0x0, 0x40); break; case 11: halbtc8723b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x21, 0x03, psTdmaByte3Val, psTdmaByte4Val); break; case 12: halbtc8723b1ant_SetFwPstdma(pBtCoexist, 0x51, 0x0a, 0x0a, 0x0, 0x50); break; case 13: halbtc8723b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x21, 0x3, psTdmaByte3Val, psTdmaByte4Val); break; case 14: halbtc8723b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x21, 0x3, psTdmaByte3Val, psTdmaByte4Val); break; case 15: halbtc8723b1ant_SetFwPstdma(pBtCoexist, 0x13, 0xa, 0x3, 0x8, 0x0); break; case 16: halbtc8723b1ant_SetFwPstdma(pBtCoexist, 0x93, 0x15, 0x3, 0x10, 0x0); break; case 18: halbtc8723b1ant_SetFwPstdma(pBtCoexist, 0x93, 0x25, 0x3, 0x10, 0x0); break; case 20: halbtc8723b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x3f, 0x03, psTdmaByte3Val, 0x10); break; case 21: halbtc8723b1ant_SetFwPstdma(pBtCoexist, 0x61, 0x25, 0x03, 0x11, 0x11); break; case 22: halbtc8723b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x25, 0x03, psTdmaByte3Val, 0x10); break; case 23: halbtc8723b1ant_SetFwPstdma(pBtCoexist, 0xe3, 0x25, 0x3, 0x31, 0x18); break; case 24: halbtc8723b1ant_SetFwPstdma(pBtCoexist, 0xe3, 0x15, 0x3, 0x31, 0x18); break; case 25: halbtc8723b1ant_SetFwPstdma(pBtCoexist, 0xe3, 0xa, 0x3, 0x31, 0x18); break; case 26: halbtc8723b1ant_SetFwPstdma(pBtCoexist, 0xe3, 0xa, 0x3, 0x31, 0x18); break; case 27: halbtc8723b1ant_SetFwPstdma(pBtCoexist, 0xe3, 0x25, 0x3, 0x31, 0x98); break; case 28: halbtc8723b1ant_SetFwPstdma(pBtCoexist, 0x69, 0x25, 0x3, 0x31, 0x0); break; case 29: halbtc8723b1ant_SetFwPstdma(pBtCoexist, 0xab, 0x1a, 0x1a, 0x1, 0x10); break; case 30: halbtc8723b1ant_SetFwPstdma(pBtCoexist, 0x51, 0x30, 0x3, 0x10, 0x10); break; case 31: halbtc8723b1ant_SetFwPstdma(pBtCoexist, 0xd3, 0x1a, 0x1a, 0, 0x58); break; case 32: halbtc8723b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x35, 0x3, psTdmaByte3Val, psTdmaByte4Val); break; case 33: halbtc8723b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x35, 0x3, psTdmaByte3Val, 0x10); break; case 34: halbtc8723b1ant_SetFwPstdma(pBtCoexist, 0x53, 0x1a, 0x1a, 0x0, 0x10); break; case 35: halbtc8723b1ant_SetFwPstdma(pBtCoexist, 0x63, 0x1a, 0x1a, 0x0, 0x10); break; case 36: halbtc8723b1ant_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 */ halbtc8723b1ant_SetFwPstdma(pBtCoexist, 0x23, 0x18, 0x00, 0x10, 0x24); break; //for 1-Ant translate to 2-Ant case 101: halbtc8723b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x3a+nWiFiDurationAdjust, 0x03, psTdmaByte3Val, psTdmaByte4Val); break; case 102: halbtc8723b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x2d+nWiFiDurationAdjust, 0x03, psTdmaByte3Val, psTdmaByte4Val); break; case 103: //halbtc8723b1ant_SetFwPstdma(pBtCoexist, 0x51, 0x1d, 0x1d, 0x0, psTdmaByte4Val); halbtc8723b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x3a, 0x03, psTdmaByte3Val, psTdmaByte4Val); break; case 105: halbtc8723b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x15, 0x3, psTdmaByte3Val, 0x11); break; case 106: halbtc8723b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x20, 0x3, psTdmaByte3Val, 0x11); break; case 109: halbtc8723b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x21, 0x3, psTdmaByte3Val, psTdmaByte4Val); break; case 111: halbtc8723b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x21, 0x03, psTdmaByte3Val, psTdmaByte4Val); break; case 113: //halbtc8723b1ant_SetFwPstdma(pBtCoexist, 0x51, 0x12, 0x12, 0x0, psTdmaByte4Val); halbtc8723b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x21, 0x3, psTdmaByte3Val, psTdmaByte4Val); break; case 114: halbtc8723b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x21, 0x3, psTdmaByte3Val, psTdmaByte4Val); break; case 120: halbtc8723b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x3f, 0x03, psTdmaByte3Val, 0x10); break; case 122: halbtc8723b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x25, 0x03, psTdmaByte3Val, 0x10); break; case 132: halbtc8723b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x25, 0x03, psTdmaByte3Val, psTdmaByte4Val); break; case 133: halbtc8723b1ant_SetFwPstdma(pBtCoexist, psTdmaByte0Val, 0x25, 0x03, psTdmaByte3Val, 0x11); break; } } else { // disable PS tdma switch(type) { case 8: //PTA Control halbtc8723b1ant_SetFwPstdma(pBtCoexist, 0x8, 0x0, 0x0, 0x0, 0x0); break; case 0: default: //Software control, Antenna at BT side halbtc8723b1ant_SetFwPstdma(pBtCoexist, 0x0, 0x0, 0x0, 0x0, 0x0); break; case 1: // 2-Ant, 0x778=3, antenna control by antenna diversity halbtc8723b1ant_SetFwPstdma(pBtCoexist, 0x0, 0x0, 0x0, 0x48, 0x0); break; #if 0 case 9: //Software control, Antenna at WiFi side halbtc8723b1ant_SetFwPstdma(pBtCoexist, 0x0, 0x0, 0x0, 0x0, 0x0); //halbtc8723b1ant_SetAntPathDCut(pBtCoexist, FALSE, FALSE, FALSE, BTC_ANT_PATH_WIFI, BTC_WIFI_STAT_NORMAL); halbtc8723b1ant_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 halbtc8723b1ant_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_8723B_1ANT_BT_STATUS_NON_CONNECTED_IDLE == pCoexDm->btStatus) { RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Wifi non connected-idle + BT non connected-idle!!\n")); //halbtc8723b1ant_SwMechanism(pBtCoexist, FALSE); bCommon = TRUE; } else if(bWifiConnected && (BT_8723B_1ANT_BT_STATUS_NON_CONNECTED_IDLE == pCoexDm->btStatus) ) { RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Wifi connected + BT non connected-idle!!\n")); //halbtc8723b1ant_SwMechanism(pBtCoexist, FALSE); bCommon = TRUE; } else if(!bWifiConnected && (BT_8723B_1ANT_BT_STATUS_CONNECTED_IDLE == pCoexDm->btStatus) ) { RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Wifi non connected-idle + BT connected-idle!!\n")); //halbtc8723b1ant_SwMechanism(pBtCoexist, FALSE); bCommon = TRUE; } else if(bWifiConnected && (BT_8723B_1ANT_BT_STATUS_CONNECTED_IDLE == pCoexDm->btStatus) ) { RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Wifi connected + BT connected-idle!!\n")); //halbtc8723b1ant_SwMechanism(pBtCoexist, FALSE); bCommon = TRUE; } else if(!bWifiConnected && (BT_8723B_1ANT_BT_STATUS_CONNECTED_IDLE != pCoexDm->btStatus) ) { RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Wifi non connected-idle + BT Busy!!\n")); //halbtc8723b1ant_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 halbtc8723b1ant_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_8723B_1ANT_WIFI_STATUS_CONNECTED_BUSY == wifiStatus) bWifiBusy = TRUE; else bWifiBusy = FALSE; if( (BT_8723B_1ANT_WIFI_STATUS_NON_CONNECTED_ASSO_AUTH_SCAN == wifiStatus) || (BT_8723B_1ANT_WIFI_STATUS_CONNECTED_SCAN == wifiStatus) || (BT_8723B_1ANT_WIFI_STATUS_CONNECTED_SPECIAL_PKT == wifiStatus) ) { if( pCoexDm->curPsTdma != 1 && pCoexDm->curPsTdma != 2 && pCoexDm->curPsTdma != 3 && pCoexDm->curPsTdma != 9 ) { halbtc8723b1ant_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")); halbtc8723b1ant_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 連續 n 個2秒 retry count為0, 則調寬WiFi 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 連續 2 個2秒 retry count< 3, 則調窄WiFi duration { if (WaitCount <= 2) m++; // 避免一直在兩個level中來回 else m = 1; if ( m >= 20) //m 最大值 = 20 ' 最大120秒 recheck是否調整 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, 只要1次 retry count > 3, 則調窄WiFi duration { if (WaitCount == 1) m++; // 避免一直在兩個level中來回 else m = 1; if ( m >= 20) //m 最大值 = 20 ' 最大120秒 recheck是否調整 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_8723B_1ANT_A2DP_BASIC_RATE(btInfoExt)) && ((pCoexDm->curPsTdma == 1) ||(pCoexDm->curPsTdma == 2)) ) { halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 9); pCoexDm->psTdmaDuAdjType = 9; } else */ if(pCoexDm->curPsTdma == 1) { halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 2); pCoexDm->psTdmaDuAdjType = 2; } else if(pCoexDm->curPsTdma == 2) { halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 9); pCoexDm->psTdmaDuAdjType = 9; } else if(pCoexDm->curPsTdma == 9) { halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 11); pCoexDm->psTdmaDuAdjType = 11; } } else if(result == 1) { /* if( (BT_INFO_8723B_1ANT_A2DP_BASIC_RATE(btInfoExt)) && ((pCoexDm->curPsTdma == 1) ||(pCoexDm->curPsTdma == 2)) ) { halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 9); pCoexDm->psTdmaDuAdjType = 9; } else */ if(pCoexDm->curPsTdma == 11) { halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 9); pCoexDm->psTdmaDuAdjType = 9; } else if(pCoexDm->curPsTdma == 9) { halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 2); pCoexDm->psTdmaDuAdjType = 2; } else if(pCoexDm->curPsTdma == 2) { halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 1); pCoexDm->psTdmaDuAdjType = 1; } } else //no change { /* Bryant Modify if(bWifiBusy != bPreWifiBusy) //if busy / idle change { bPreWifiBusy = bWifiBusy; halbtc8723b1ant_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 halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, pCoexDm->psTdmaDuAdjType); } } } VOID halbtc8723b1ant_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 halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, FALSE, 8); } } else // NO PS state { if(bNewPsState) { // will enter LPS state, turn off psTdma first halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, FALSE, 8); } else { // keep state under NO PS state, do nothing. } } } VOID halbtc8723b1ant_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: halbtc8723b1ant_PsTdmaCheckForPowerSaveState(pBtCoexist, TRUE); halbtc8723b1ant_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: halbtc8723b1ant_PsTdmaCheckForPowerSaveState(pBtCoexist, FALSE); pBtCoexist->fBtcSet(pBtCoexist, BTC_SET_ACT_LEAVE_LPS, NULL); pCoexSta->bForceLpsOn = FALSE; break; default: break; } } VOID halbtc8723b1ant_ActionWifiOnly( IN PBTC_COEXIST pBtCoexist ) { halbtc8723b1ant_CoexTableWithType(pBtCoexist, FORCE_EXEC, 0); halbtc8723b1ant_PsTdma(pBtCoexist, FORCE_EXEC, FALSE, 8); halbtc8723b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_PTA, FORCE_EXEC, FALSE, FALSE); } VOID halbtc8723b1ant_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; } else { btDisableCnt++; RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], bt all counters=0, %d times!!\n", btDisableCnt)); if(btDisableCnt >= 2) { bBtDisabled = TRUE; } } 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; pBtCoexist->fBtcSet(pBtCoexist, BTC_SET_BL_BT_DISABLE, &bBtDisabled); if(bBtDisabled) { halbtc8723b1ant_ActionWifiOnly(pBtCoexist); 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 halbtc8723b1ant_ActionSco( IN PBTC_COEXIST pBtCoexist ) { halbtc8723b1ant_SwMechanism(pBtCoexist, TRUE); } VOID halbtc8723b1ant_ActionHid( IN PBTC_COEXIST pBtCoexist ) { halbtc8723b1ant_SwMechanism(pBtCoexist, TRUE); } //A2DP only / PAN(EDR) only/ A2DP+PAN(HS) VOID halbtc8723b1ant_ActionA2dp( IN PBTC_COEXIST pBtCoexist ) { halbtc8723b1ant_SwMechanism(pBtCoexist, FALSE); } VOID halbtc8723b1ant_ActionA2dpPanHs( IN PBTC_COEXIST pBtCoexist ) { halbtc8723b1ant_SwMechanism(pBtCoexist, FALSE); } VOID halbtc8723b1ant_ActionPanEdr( IN PBTC_COEXIST pBtCoexist ) { halbtc8723b1ant_SwMechanism(pBtCoexist, FALSE); } //PAN(HS) only VOID halbtc8723b1ant_ActionPanHs( IN PBTC_COEXIST pBtCoexist ) { halbtc8723b1ant_SwMechanism(pBtCoexist, FALSE); } //PAN(EDR)+A2DP VOID halbtc8723b1ant_ActionPanEdrA2dp( IN PBTC_COEXIST pBtCoexist ) { halbtc8723b1ant_SwMechanism(pBtCoexist, FALSE); } VOID halbtc8723b1ant_ActionPanEdrHid( IN PBTC_COEXIST pBtCoexist ) { halbtc8723b1ant_SwMechanism(pBtCoexist, TRUE); } // HID+A2DP+PAN(EDR) VOID halbtc8723b1ant_ActionHidA2dpPanEdr( IN PBTC_COEXIST pBtCoexist ) { halbtc8723b1ant_SwMechanism(pBtCoexist, TRUE); } VOID halbtc8723b1ant_ActionHidA2dp( IN PBTC_COEXIST pBtCoexist ) { halbtc8723b1ant_SwMechanism(pBtCoexist, TRUE); } */ //============================================= // // Non-Software Coex Mechanism start // //============================================= VOID halbtc8723b1ant_ActionBtWhckTest( IN PBTC_COEXIST pBtCoexist ) { halbtc8723b1ant_PowerSaveState(pBtCoexist, BTC_PS_WIFI_NATIVE, 0x0, 0x0); halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, FALSE, 8); halbtc8723b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_PTA, NORMAL_EXEC, FALSE, FALSE); halbtc8723b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 0); } VOID halbtc8723b1ant_ActionWifiMultiPort( IN PBTC_COEXIST pBtCoexist ) { halbtc8723b1ant_PowerSaveState(pBtCoexist, BTC_PS_WIFI_NATIVE, 0x0, 0x0); halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, FALSE, 8); halbtc8723b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_PTA, NORMAL_EXEC, FALSE, FALSE); halbtc8723b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 2); } VOID halbtc8723b1ant_ActionHs( IN PBTC_COEXIST pBtCoexist ) { halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 5); halbtc8723b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 2); } VOID halbtc8723b1ant_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) ) { halbtc8723b1ant_PowerSaveState(pBtCoexist, BTC_PS_WIFI_NATIVE, 0x0, 0x0); halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, FALSE, 8); halbtc8723b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_PTA, NORMAL_EXEC, FALSE, FALSE); halbtc8723b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 0); } else if( (pBtLinkInfo->bScoExist) || (pBtLinkInfo->bHidExist) || (pBtLinkInfo->bA2dpExist) ) { // SCO/HID/A2DP busy halbtc8723b1ant_PowerSaveState(pBtCoexist, BTC_PS_WIFI_NATIVE, 0x0, 0x0); if (pCoexSta->bC2hBtRemoteNameReq) halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 33); else halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 32); halbtc8723b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 4); } else if ( (pBtLinkInfo->bPanExist) || (bWifiBusy) ) { halbtc8723b1ant_PowerSaveState(pBtCoexist, BTC_PS_WIFI_NATIVE, 0x0, 0x0); if (pCoexSta->bC2hBtRemoteNameReq) halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 33); else halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 32); halbtc8723b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 4); } else { halbtc8723b1ant_PowerSaveState(pBtCoexist, BTC_PS_WIFI_NATIVE, 0x0, 0x0); halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, FALSE, 8); halbtc8723b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_PTA, NORMAL_EXEC, FALSE, FALSE); halbtc8723b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 7); } } VOID halbtc8723b1ant_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) { halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 5); halbtc8723b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 5); } else //HID { halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 6); halbtc8723b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 5); } } VOID halbtc8723b1ant_ActionWifiConnectedBtAclBusy( IN PBTC_COEXIST pBtCoexist, IN u1Byte wifiStatus ) { u1Byte btRssiState; PBTC_BT_LINK_INFO pBtLinkInfo=&pBtCoexist->btLinkInfo; btRssiState = halbtc8723b1ant_BtRssiState(2, 28, 0); if ( (pCoexSta->lowPriorityRx >= 950) && (!pCoexSta->bUnderIps) ) { pBtLinkInfo->bSlaveRole = TRUE; } else { pBtLinkInfo->bSlaveRole = FALSE; } if(pBtLinkInfo->bHidOnly) //HID { halbtc8723b1ant_ActionBtScoHidOnlyBusy(pBtCoexist, wifiStatus); pCoexDm->bAutoTdmaAdjust = FALSE; return; } else if(pBtLinkInfo->bA2dpOnly) //A2DP { if(BT_8723B_1ANT_WIFI_STATUS_CONNECTED_IDLE == wifiStatus) { halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 32); halbtc8723b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 4); pCoexDm->bAutoTdmaAdjust = FALSE; } else { halbtc8723b1ant_TdmaDurationAdjustForAcl(pBtCoexist, wifiStatus); halbtc8723b1ant_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) { halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 13); halbtc8723b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 4); pCoexDm->bAutoTdmaAdjust = FALSE; } else if(pBtLinkInfo->bHidExist&&pBtLinkInfo->bA2dpExist) //HID+A2DP { halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 14); pCoexDm->bAutoTdmaAdjust = FALSE; halbtc8723b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 3); } else if( (pBtLinkInfo->bPanOnly) || (pBtLinkInfo->bHidExist&&pBtLinkInfo->bPanExist) ) //PAN(OPP,FTP), HID+PAN(OPP,FTP) { halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 3); halbtc8723b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 4); pCoexDm->bAutoTdmaAdjust = FALSE; } else { //BT no-profile busy (0x9) halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 33); halbtc8723b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 4); pCoexDm->bAutoTdmaAdjust = FALSE; } } VOID halbtc8723b1ant_ActionWifiNotConnected( IN PBTC_COEXIST pBtCoexist ) { // power save state halbtc8723b1ant_PowerSaveState(pBtCoexist, BTC_PS_WIFI_NATIVE, 0x0, 0x0); // tdma and coex table halbtc8723b1ant_PsTdma(pBtCoexist, FORCE_EXEC, FALSE, 8); halbtc8723b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_PTA, NORMAL_EXEC, FALSE, FALSE); halbtc8723b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 0); } VOID halbtc8723b1ant_ActionWifiNotConnectedScan( IN PBTC_COEXIST pBtCoexist ) { PBTC_BT_LINK_INFO pBtLinkInfo=&pBtCoexist->btLinkInfo; halbtc8723b1ant_PowerSaveState(pBtCoexist, BTC_PS_WIFI_NATIVE, 0x0, 0x0); // tdma and coex table if(BT_8723B_1ANT_BT_STATUS_ACL_BUSY == pCoexDm->btStatus) { if (pBtLinkInfo->bA2dpExist) { halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 32); halbtc8723b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 4); } else if (pBtLinkInfo->bA2dpExist && pBtLinkInfo->bPanExist) { halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 22); halbtc8723b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 4); } else { halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 20); halbtc8723b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 4); } } else if( (BT_8723B_1ANT_BT_STATUS_SCO_BUSY == pCoexDm->btStatus) || (BT_8723B_1ANT_BT_STATUS_ACL_SCO_BUSY == pCoexDm->btStatus) ) { halbtc8723b1ant_ActionBtScoHidOnlyBusy(pBtCoexist, BT_8723B_1ANT_WIFI_STATUS_CONNECTED_SCAN); } else { //Bryant Add halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, FALSE, 8); halbtc8723b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_PTA, NORMAL_EXEC, FALSE, FALSE); halbtc8723b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 2); } } VOID halbtc8723b1ant_ActionWifiNotConnectedAssoAuth( IN PBTC_COEXIST pBtCoexist ) { PBTC_BT_LINK_INFO pBtLinkInfo=&pBtCoexist->btLinkInfo; halbtc8723b1ant_PowerSaveState(pBtCoexist, BTC_PS_WIFI_NATIVE, 0x0, 0x0); // tdma and coex table if( (pBtLinkInfo->bScoExist) || (pBtLinkInfo->bHidExist) || (pBtLinkInfo->bA2dpExist) ) { halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 32); halbtc8723b1ant_CoexTableWithType(pBtCoexist, FORCE_EXEC, 4); } else if (pBtLinkInfo->bPanExist) { halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 20); halbtc8723b1ant_CoexTableWithType(pBtCoexist, FORCE_EXEC, 4); } else { halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, FALSE, 8); halbtc8723b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_PTA, NORMAL_EXEC, FALSE, FALSE); halbtc8723b1ant_CoexTableWithType(pBtCoexist, FORCE_EXEC, 2); } } VOID halbtc8723b1ant_ActionWifiConnectedScan( IN PBTC_COEXIST pBtCoexist ) { PBTC_BT_LINK_INFO pBtLinkInfo=&pBtCoexist->btLinkInfo; halbtc8723b1ant_PowerSaveState(pBtCoexist, BTC_PS_WIFI_NATIVE, 0x0, 0x0); // tdma and coex table if(BT_8723B_1ANT_BT_STATUS_ACL_BUSY == pCoexDm->btStatus) { if (pBtLinkInfo->bA2dpExist) { halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 32); halbtc8723b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 4); } else if (pBtLinkInfo->bA2dpExist && pBtLinkInfo->bPanExist) { halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 22); halbtc8723b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 4); } else { halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 20); halbtc8723b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 4); } } else if( (BT_8723B_1ANT_BT_STATUS_SCO_BUSY == pCoexDm->btStatus) || (BT_8723B_1ANT_BT_STATUS_ACL_SCO_BUSY == pCoexDm->btStatus) ) { halbtc8723b1ant_ActionBtScoHidOnlyBusy(pBtCoexist, BT_8723B_1ANT_WIFI_STATUS_CONNECTED_SCAN); } else { //Bryant Add halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, FALSE, 8); halbtc8723b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_PTA, NORMAL_EXEC, FALSE, FALSE); halbtc8723b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 2); } } VOID halbtc8723b1ant_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; halbtc8723b1ant_PowerSaveState(pBtCoexist, BTC_PS_WIFI_NATIVE, 0x0, 0x0); // tdma and coex table if((pBtLinkInfo->bScoExist) || (pBtLinkInfo->bHidExist)) { halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 32); halbtc8723b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 5); } else if (pBtLinkInfo->bA2dpExist) { halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 32); halbtc8723b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 4); } else if(pBtLinkInfo->bPanExist) { halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, TRUE, 20); halbtc8723b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 4); } else { halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, FALSE, 8); halbtc8723b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_PTA, NORMAL_EXEC, FALSE, FALSE); halbtc8723b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 2); } } VOID halbtc8723b1ant_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) { halbtc8723b1ant_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) halbtc8723b1ant_ActionWifiConnectedScan(pBtCoexist); else halbtc8723b1ant_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_8723B_1ANT_BT_STATUS_ACL_BUSY == pCoexDm->btStatus && !pBtCoexist->btLinkInfo.bHidOnly) { if(pBtCoexist->btLinkInfo.bA2dpOnly) //A2DP { if(!bWifiBusy) halbtc8723b1ant_PowerSaveState(pBtCoexist, BTC_PS_WIFI_NATIVE, 0x0, 0x0); else //busy { if (pCoexSta->nScanAPNum >= BT_8723B_1ANT_WIFI_NOISY_THRESH) //no force LPS, no PS-TDMA, use pure TDMA { halbtc8723b1ant_PowerSaveState(pBtCoexist, BTC_PS_WIFI_NATIVE, 0x0, 0x0); } else { halbtc8723b1ant_PowerSaveState(pBtCoexist, BTC_PS_LPS_ON, 0x50, 0x4); } } } else if ((pCoexSta->bPanExist == FALSE) && (pCoexSta->bA2dpExist == FALSE) && (pCoexSta->bHidExist == FALSE)) halbtc8723b1ant_PowerSaveState(pBtCoexist, BTC_PS_WIFI_NATIVE, 0x0, 0x0); else halbtc8723b1ant_PowerSaveState(pBtCoexist, BTC_PS_LPS_ON, 0x50, 0x4); } else halbtc8723b1ant_PowerSaveState(pBtCoexist, BTC_PS_WIFI_NATIVE, 0x0, 0x0); // tdma and coex table if(!bWifiBusy) { if(BT_8723B_1ANT_BT_STATUS_ACL_BUSY == pCoexDm->btStatus) { halbtc8723b1ant_ActionWifiConnectedBtAclBusy(pBtCoexist, BT_8723B_1ANT_WIFI_STATUS_CONNECTED_IDLE); } else if( (BT_8723B_1ANT_BT_STATUS_SCO_BUSY == pCoexDm->btStatus) || (BT_8723B_1ANT_BT_STATUS_ACL_SCO_BUSY == pCoexDm->btStatus) ) { halbtc8723b1ant_ActionBtScoHidOnlyBusy(pBtCoexist, BT_8723B_1ANT_WIFI_STATUS_CONNECTED_IDLE); } else { halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, FALSE, 8); halbtc8723b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_PTA, NORMAL_EXEC, FALSE, FALSE); if ( (pCoexSta->highPriorityTx) + (pCoexSta->highPriorityRx) <= 60 ) halbtc8723b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 2); else halbtc8723b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 7); } } else { if(BT_8723B_1ANT_BT_STATUS_ACL_BUSY == pCoexDm->btStatus) { halbtc8723b1ant_ActionWifiConnectedBtAclBusy(pBtCoexist, BT_8723B_1ANT_WIFI_STATUS_CONNECTED_BUSY); } else if( (BT_8723B_1ANT_BT_STATUS_SCO_BUSY == pCoexDm->btStatus) || (BT_8723B_1ANT_BT_STATUS_ACL_SCO_BUSY == pCoexDm->btStatus) ) { halbtc8723b1ant_ActionBtScoHidOnlyBusy(pBtCoexist, BT_8723B_1ANT_WIFI_STATUS_CONNECTED_BUSY); } else { halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, FALSE, 8); halbtc8723b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_PTA, NORMAL_EXEC, FALSE, FALSE); if ( (pCoexSta->highPriorityTx) + (pCoexSta->highPriorityRx) <= 60 ) halbtc8723b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 2); else halbtc8723b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 7); } } } VOID halbtc8723b1ant_RunSwCoexistMechanism( IN PBTC_COEXIST pBtCoexist ) { u1Byte algorithm=0; algorithm = halbtc8723b1ant_ActionAlgorithm(pBtCoexist); pCoexDm->curAlgorithm = algorithm; if(halbtc8723b1ant_IsCommonAction(pBtCoexist)) { } else { switch(pCoexDm->curAlgorithm) { case BT_8723B_1ANT_COEX_ALGO_SCO: RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Action algorithm = SCO.\n")); //halbtc8723b1ant_ActionSco(pBtCoexist); break; case BT_8723B_1ANT_COEX_ALGO_HID: RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Action algorithm = HID.\n")); //halbtc8723b1ant_ActionHid(pBtCoexist); break; case BT_8723B_1ANT_COEX_ALGO_A2DP: RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Action algorithm = A2DP.\n")); //halbtc8723b1ant_ActionA2dp(pBtCoexist); break; case BT_8723B_1ANT_COEX_ALGO_A2DP_PANHS: RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Action algorithm = A2DP+PAN(HS).\n")); //halbtc8723b1ant_ActionA2dpPanHs(pBtCoexist); break; case BT_8723B_1ANT_COEX_ALGO_PANEDR: RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Action algorithm = PAN(EDR).\n")); //halbtc8723b1ant_ActionPanEdr(pBtCoexist); break; case BT_8723B_1ANT_COEX_ALGO_PANHS: RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Action algorithm = HS mode.\n")); //halbtc8723b1ant_ActionPanHs(pBtCoexist); break; case BT_8723B_1ANT_COEX_ALGO_PANEDR_A2DP: RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Action algorithm = PAN+A2DP.\n")); //halbtc8723b1ant_ActionPanEdrA2dp(pBtCoexist); break; case BT_8723B_1ANT_COEX_ALGO_PANEDR_HID: RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Action algorithm = PAN(EDR)+HID.\n")); //halbtc8723b1ant_ActionPanEdrHid(pBtCoexist); break; case BT_8723B_1ANT_COEX_ALGO_HID_A2DP_PANEDR: RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Action algorithm = HID+A2DP+PAN.\n")); //halbtc8723b1ant_ActionHidA2dpPanEdr(pBtCoexist); break; case BT_8723B_1ANT_COEX_ALGO_HID_A2DP: RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Action algorithm = HID+A2DP.\n")); //halbtc8723b1ant_ActionHidA2dp(pBtCoexist); break; default: RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Action algorithm = coexist All Off!!\n")); //halbtc8723b1ant_CoexAllOff(pBtCoexist); break; } pCoexDm->preAlgorithm = pCoexDm->curAlgorithm; } } VOID halbtc8723b1ant_RunCoexistMechanism( IN PBTC_COEXIST pBtCoexist ) { PBTC_BT_LINK_INFO pBtLinkInfo=&pBtCoexist->btLinkInfo; BOOLEAN bWifiConnected=FALSE, bBtHsOn=FALSE, bWifiBusy = 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")); halbtc8723b1ant_ActionBtWhckTest(pBtCoexist); return; } if( (BT_8723B_1ANT_BT_STATUS_ACL_BUSY == pCoexDm->btStatus) || (BT_8723B_1ANT_BT_STATUS_SCO_BUSY == pCoexDm->btStatus) || (BT_8723B_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_BL_WIFI_BUSY, &bWifiBusy); 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) { halbtc8723b1ant_LimitedTx(pBtCoexist, NORMAL_EXEC, 1, 1, 0, 1); bMiracastPlusBt = TRUE; } else { halbtc8723b1ant_LimitedTx(pBtCoexist, NORMAL_EXEC, 0, 0, 0, 0); bMiracastPlusBt = FALSE; } pBtCoexist->fBtcSet(pBtCoexist, BTC_SET_BL_MIRACAST_PLUS_BT, &bMiracastPlusBt); halbtc8723b1ant_LimitedRx(pBtCoexist, NORMAL_EXEC, FALSE, bBtCtrlAggBufSize, aggBufSize); if (( (pBtLinkInfo->bA2dpExist) || (bWifiBusy) ) && (pCoexSta->bC2hBtInquiryPage) ) { RT_TRACE(COMP_COEX, DBG_LOUD, ("############# [BTCoex], BT Is Inquirying \n") ); halbtc8723b1ant_ActionBtInquiry(pBtCoexist); } else halbtc8723b1ant_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) ) { halbtc8723b1ant_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) //halbtc8723b1ant_LimitedRx(pBtCoexist, NORMAL_EXEC, TRUE, FALSE, 0x5); halbtc8723b1ant_LimitedRx(pBtCoexist, NORMAL_EXEC, FALSE, FALSE, 0x5); else halbtc8723b1ant_LimitedRx(pBtCoexist, NORMAL_EXEC, FALSE, FALSE, 0x5); //halbtc8723b1ant_LimitedRx(pBtCoexist, NORMAL_EXEC, FALSE, TRUE, 0x8); } else { if(pBtLinkInfo->bScoExist) halbtc8723b1ant_LimitedRx(pBtCoexist, NORMAL_EXEC, TRUE, FALSE, 0x5); else { if (BTC_WIFI_BW_HT40==wifiBw) halbtc8723b1ant_LimitedRx(pBtCoexist, NORMAL_EXEC, FALSE, TRUE, 0x10); else halbtc8723b1ant_LimitedRx(pBtCoexist, NORMAL_EXEC, FALSE, TRUE, 0x8); } } halbtc8723b1ant_SwMechanism(pBtCoexist, TRUE); halbtc8723b1ant_RunSwCoexistMechanism(pBtCoexist); //just print debug message } else { halbtc8723b1ant_LimitedTx(pBtCoexist, NORMAL_EXEC, 0, 0, 0, 0); halbtc8723b1ant_LimitedRx(pBtCoexist, NORMAL_EXEC, FALSE, FALSE, 0x5); halbtc8723b1ant_SwMechanism(pBtCoexist, FALSE); halbtc8723b1ant_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") ); halbtc8723b1ant_ActionBtInquiry(pBtCoexist); return; } else if(bBtHsOn) { halbtc8723b1ant_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) halbtc8723b1ant_ActionWifiNotConnectedScan(pBtCoexist); else halbtc8723b1ant_ActionWifiNotConnectedAssoAuth(pBtCoexist); } else halbtc8723b1ant_ActionWifiNotConnected(pBtCoexist); } else // wifi LPS/Busy { halbtc8723b1ant_ActionWifiConnected(pBtCoexist); } } u4Byte halbtc8723b1ant_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 halbtc8723b1ant_InitCoexDm( IN PBTC_COEXIST pBtCoexist ) { // force to reset coex mechanism // sw all off halbtc8723b1ant_SwMechanism(pBtCoexist, FALSE); //halbtc8723b1ant_PsTdma(pBtCoexist, FORCE_EXEC, FALSE, 8); //halbtc8723b1ant_CoexTableWithType(pBtCoexist, FORCE_EXEC, 0); pCoexSta->popEventCnt = 0; } VOID halbtc8723b1ant_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}; RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], 1Ant Init HW Config!!\n")); pPsdScan->nAntDet_IsAntDetAvailable = FALSE; //0xf0[15:12] --> Chip Cut information pCoexSta->nCutVersion = (pBtCoexist->fBtcRead1Byte(pBtCoexist, 0xf1) & 0xf0) >> 4; #if 0//move to BTC_MEDIA_CONNECT if(bBackUp) { pCoexDm->backupArfrCnt1 = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0x430); pCoexDm->backupArfrCnt2 = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0x434); pCoexDm->backupRetryLimit = pBtCoexist->fBtcRead2Byte(pBtCoexist, 0x42a); pCoexDm->backupAmpduMaxTime = pBtCoexist->fBtcRead1Byte(pBtCoexist, 0x456); } #endif pBtCoexist->fBtcWrite1ByteBitMask(pBtCoexist, 0x550, 0x8, 0x1); //enable TBTT nterrupt // 0x790[5:0]=0x5 pBtCoexist->fBtcWrite1Byte(pBtCoexist, 0x790, 0x5); // Enable counter statistics //pBtCoexist->fBtcWrite1Byte(pBtCoexist, 0x76e, 0xc); //0x76e[3] =1, WLAN_Act control by PTA pBtCoexist->fBtcWrite1Byte(pBtCoexist, 0x778, 0x1); pBtCoexist->fBtcWrite1ByteBitMask(pBtCoexist, 0x40, 0x20, 0x1); //pBtCoexist->fBtcWrite1ByteBitMask(pBtCoexist, 0x67, 0x20, 0x1); //BT select s0/s1 is controlled by WiFi halbtc8723b1ant_PsTdma(pBtCoexist, FORCE_EXEC, FALSE, 8); //Antenna config if(bWifiOnly) halbtc8723b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_WIFI, FORCE_EXEC, TRUE, FALSE); else halbtc8723b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_BT, FORCE_EXEC, TRUE, FALSE); #if 0 if(bWifiOnly) { halbtc8723b1ant_SetAntPathDCut(pBtCoexist, FALSE, FALSE, FALSE, BTC_ANT_PATH_WIFI, BTC_WIFI_STAT_INIT); halbtc8723b1ant_PsTdma(pBtCoexist, FORCE_EXEC, FALSE, 8); } else halbtc8723b1ant_SetAntPathDCut(pBtCoexist, FALSE, FALSE, FALSE, BTC_ANT_PATH_BT, BTC_WIFI_STAT_INIT); #endif // PTA parameter halbtc8723b1ant_CoexTableWithType(pBtCoexist, FORCE_EXEC, 0); u4Tmp = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0x948); u1Tmpa = pBtCoexist->fBtcRead1Byte(pBtCoexist, 0x765); u1Tmpb = pBtCoexist->fBtcRead1Byte(pBtCoexist, 0x67); RT_TRACE(COMP_COEX, DBG_LOUD, ("############# [BTCoex], 0x948=0x%x, 0x765=0x%x, 0x67=0x%x\n", u4Tmp, u1Tmpa, u1Tmpb)); } VOID halbtc8723b1ant_MechanismSwitch( IN PBTC_COEXIST pBtCoexist, IN BOOLEAN bSwitchTo2Antenna ) { if (bSwitchTo2Antenna) // 1-Ant -> 2-Ant { //un-lock TRx Mask setup for 8723b f-cut pBtCoexist->fBtcSetRfReg(pBtCoexist, BTC_RF_A, 0xdd, 0x80, 0x1); pBtCoexist->fBtcSetRfReg(pBtCoexist, BTC_RF_A, 0xdf, 0x1, 0x1); //WiFi TRx Mask on pBtCoexist->fBtcSetRfReg(pBtCoexist, BTC_RF_A, 0x1, 0xfffff, 0x0); //BT TRx Mask un-lock 0x2c[0], 0x30[0] = 1 pBtCoexist->fBtcSetBtReg(pBtCoexist, BTC_BT_REG_RF, 0x2c, 0x7c45); pBtCoexist->fBtcSetBtReg(pBtCoexist, BTC_BT_REG_RF, 0x30, 0x7c45); //BT TRx Mask on pBtCoexist->fBtcSetBtReg(pBtCoexist, BTC_BT_REG_RF, 0x3c, 0x1); halbtc8723b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_BT, FORCE_EXEC, FALSE, FALSE); } else { //WiFi TRx Mask on pBtCoexist->fBtcSetRfReg(pBtCoexist, BTC_RF_A, 0x1, 0xfffff, 0x780); //lock TRx Mask setup for 8723b f-cut pBtCoexist->fBtcSetRfReg(pBtCoexist, BTC_RF_A, 0xdd, 0x80, 0x0); pBtCoexist->fBtcSetRfReg(pBtCoexist, BTC_RF_A, 0xdf, 0x1, 0x0); //BT TRx Mask on pBtCoexist->fBtcSetBtReg(pBtCoexist, BTC_BT_REG_RF, 0x3c, 0x15); //BT TRx Mask ock 0x2c[0], 0x30[0] = 0 pBtCoexist->fBtcSetBtReg(pBtCoexist, BTC_BT_REG_RF, 0x2c, 0x7c44); pBtCoexist->fBtcSetBtReg(pBtCoexist, BTC_BT_REG_RF, 0x30, 0x7c44); halbtc8723b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_PTA, FORCE_EXEC, FALSE, FALSE); } } VOID halbtc8723b1ant_PSD_ShowAntennaDetectResult( IN PBTC_COEXIST pBtCoexist ) { pu1Byte cliBuf=pBtCoexist->cliBuf; PBTC_BOARD_INFO pBoardInfo=&pBtCoexist->boardInfo; CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n============[Antenna Detection info] ============\n"); CL_PRINTF(cliBuf); if (pPsdScan->nAntDet_Result == 1) CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %s (>%d)", "Ant Det Result", "2-Antenna (Bad-Isolation)", BT_8723B_1ANT_ANTDET_PSDTHRES_2ANT_BADISOLATION); else if (pPsdScan->nAntDet_Result == 2) CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %s (%d~%d)", "Ant Det Result", "2-Antenna (Good-Isolation)", BT_8723B_1ANT_ANTDET_PSDTHRES_2ANT_GOODISOLATION+pPsdScan->nAntDet_ThresOffset, BT_8723B_1ANT_ANTDET_PSDTHRES_2ANT_BADISOLATION); else CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %s (%d~%d)", "Ant Det Result", "1-Antenna", BT_8723B_1ANT_ANTDET_PSDTHRES_1ANT, BT_8723B_1ANT_ANTDET_PSDTHRES_2ANT_GOODISOLATION+pPsdScan->nAntDet_ThresOffset); CL_PRINTF(cliBuf); CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %s ", "Antenna Detection Finish", (pBoardInfo->btdmAntDetFinish? "Yes":"No")); CL_PRINTF(cliBuf); switch(pPsdScan->nAntDet_Result) { case 0: CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "(BT is not available)"); break; case 1: // 2-Ant bad-isolation CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "(BT is available)"); break; case 2: // 2-Ant good-isolation CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "(BT is available)"); break; case 3: // 1-Ant CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "(BT is available)"); break; case 4: CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "(Uncertainty result)"); break; case 5: CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "(Pre-Scan fai)"); break; case 6: CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "(WiFi is Scanning)"); break; case 7: CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "(BT is not idle)"); break; case 8: CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "(Abort by WiFi Scanning)"); break; case 9: CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "(Antenna Init is not ready)"); break; case 10: CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "(BT is Inquiry or page)"); break; case 11: CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "(BT is Disabled)"); break; } CL_PRINTF(cliBuf); CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %d", "Ant Detect Total Count",pPsdScan->bAntDet_TryCount); CL_PRINTF(cliBuf); CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %d", "Ant Detect Fail Count",pPsdScan->bAntDet_FailCount); CL_PRINTF(cliBuf); if ( (!pBoardInfo->btdmAntDetFinish) && (pPsdScan->nAntDet_Result != 5) ) return; CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %s", "BT Response",(pPsdScan->nAntDet_Result? "ok":"fail")); CL_PRINTF(cliBuf); CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %d ms", "BT Tx Time", pPsdScan->nAntDet_BTTxTime); CL_PRINTF(cliBuf); CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %d", "BT Tx Ch", pPsdScan->nAntDet_BTLEChannel); CL_PRINTF(cliBuf); CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %d/ %d/ %d", "WiFi PSD Cent-Ch/Offset/Span", pPsdScan->nRealCentFreq, pPsdScan->nRealOffset, pPsdScan->nRealSpan); CL_PRINTF(cliBuf); CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %d dB", "PSD Pre-Scan Peak Value", pPsdScan->nAntDet_PrePSDScanPeakVal/100); CL_PRINTF(cliBuf); CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %s (<= %d)", "PSD Pre-Scan result", (pPsdScan->nAntDet_Result != 5? "ok":"fail"), BT_8723B_1ANT_ANTDET_PSDTHRES_BACKGROUND+pPsdScan->nAntDet_ThresOffset); CL_PRINTF(cliBuf); if (pPsdScan->nAntDet_Result == 5) return; CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %s dB", "PSD Scan Peak Value", pPsdScan->nAntDet_PeakVal); CL_PRINTF(cliBuf); CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %s MHz", "PSD Scan Peak Freq", pPsdScan->nAntDet_PeakFreq); CL_PRINTF(cliBuf); CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %s", "TFBGA Package", (pBoardInfo->bTfbgaPackage)? "Yes":"No"); CL_PRINTF(cliBuf); CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %d", "PSD Threshold Offset", pPsdScan->nAntDet_ThresOffset); CL_PRINTF(cliBuf); } VOID halbtc8723b1ant_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 halbtc8723b1ant_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_8723B_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 halbtc8723b1ant_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 halbtc8723b1ant_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 = halbtc8723b1ant_PSD_GetData(pBtCoexist,i-nPoints); } else { psd_report = halbtc8723b1ant_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 * halbtc8723b1ant_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; } VOID halbtc8723b1ant_PSD_AntennaDetection( IN PBTC_COEXIST pBtCoexist, IN u4Byte BTTxTime, IN u4Byte BTLEChannel ) { u4Byte realseconds = 0, i=0, j=0; u4Byte WLPSD_CentFreq = 2484, WLPSD_Span = 2, WLPSD_SweepCount = 50; s4Byte WLPSD_Offset = -4; u1Byte BTLECh[13] = {3,6,8,11,13,16,18,21,23,26,28,31,33}; u1Byte H2C_Parameter[3] ={0},u1Tmpa,u1Tmpb; u1Byte state=0; BOOLEAN outloop = FALSE, BTResp = FALSE, bScan ,bRoam; u4Byte freq,freq1,freq2,PsdRep1, PsdRep2, nDeltaFreqPerPoint,u4Tmp; PBTC_BOARD_INFO pBoardInfo=&pBtCoexist->boardInfo; pBoardInfo->btdmAntDetFinish = FALSE; memset(pPsdScan->nAntDet_PeakVal, 0, 16*sizeof(UCHAR)); memset(pPsdScan->nAntDet_PeakFreq, 0, 16*sizeof(UCHAR)); if (pBoardInfo->bTfbgaPackage) //for TFBGA pPsdScan->nAntDet_ThresOffset = 5; else pPsdScan->nAntDet_ThresOffset = 0; do { switch(state) { case 0: if (BTLEChannel == 39) WLPSD_CentFreq = 2484; else { for (i=1; i<=13; i++) { if (BTLECh[i-1] == BTLEChannel) { WLPSD_CentFreq = 2412 + (i-1) * 5; break; } } if (i == 14) { RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx AntennaDetect(), Abort!!, Invalid LE channel = %d\n ", BTLEChannel)); outloop = TRUE; break; } } WLPSD_SweepCount = BTTxTime * 238 /100; //BTTxTime/0.42 if (WLPSD_SweepCount % 5 != 0) WLPSD_SweepCount = (WLPSD_SweepCount/5 + 1) * 5; RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx AntennaDetect(), BT_LETxTime=%d, BT_LECh = %d\n", BTTxTime, BTLEChannel)); RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx AntennaDetect(), WLPSD_CentFreq=%d, WLPSD_Offset = %d, WLPSD_Span = %d, WLPSD_SweepCount = %d\n", WLPSD_CentFreq, WLPSD_Offset, WLPSD_Span,WLPSD_SweepCount)); state = 1; break; case 1: //stop coex DM & set antenna path //Stop Coex DM pBtCoexist->bStopCoexDm = TRUE; RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx AntennaDetect(), Stop Coex DM!!\n")); //set native power save halbtc8723b1ant_PowerSaveState(pBtCoexist, BTC_PS_WIFI_NATIVE, 0x0, 0x0); //Set TDMA off, halbtc8723b1ant_PsTdma(pBtCoexist, FORCE_EXEC, FALSE, 0); //Set coex table halbtc8723b1ant_CoexTableWithType(pBtCoexist, FORCE_EXEC, 0); if(pBoardInfo->btdmAntPos == BTC_ANTENNA_AT_MAIN_PORT) { RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx AntennaDetect(), Antenna at Main Port\n")); } else { RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx AntennaDetect(), Antenna at Aux Port\n")); } //Set Antenna path, switch WiFi to un-certain antenna port halbtc8723b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_BT, FORCE_EXEC, FALSE, FALSE); RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx AntennaDetect(), Set Antenna to BT!!\n")); //Set AFH mask on at WiFi channel 2472MHz +/- 10MHz H2C_Parameter[0] = 0x1; H2C_Parameter[1] = 0xd; H2C_Parameter[2] = 0x14; RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx AntennaDetect(), Set AFH on, Cent-Ch= %d, Mask=%d\n", H2C_Parameter[1],H2C_Parameter[2])); pBtCoexist->fBtcFillH2c(pBtCoexist, 0x66, 3, H2C_Parameter); u4Tmp = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0x948); u1Tmpa = pBtCoexist->fBtcRead1Byte(pBtCoexist, 0x765); u1Tmpb = pBtCoexist->fBtcRead1Byte(pBtCoexist, 0x778); RT_TRACE(COMP_COEX, DBG_LOUD, ("############# [BTCoex], 0x948=0x%x, 0x765=0x%x, 0x778=0x%x\n", u4Tmp, u1Tmpa, u1Tmpb)); state =2; break; case 2: //Pre-sweep background psd for (pPsdScan->nPSDGenCount=1; pPsdScan->nPSDGenCount<=3; pPsdScan->nPSDGenCount++) { RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx AntennaDetect(), PSDGenCount = %d\n ", pPsdScan->nPSDGenCount)); halbtc8723b1ant_PSD_SweepPoint(pBtCoexist, WLPSD_CentFreq, WLPSD_Offset, WLPSD_Span, BT_8723B_1ANT_ANTDET_PSD_POINTS, BT_8723B_1ANT_ANTDET_PSD_AVGNUM); halbtc8723b1ant_PSD_MaxHoldData(pBtCoexist, pPsdScan->nPSDGenCount); } pPsdScan->nAntDet_PrePSDScanPeakVal = pPsdScan->nPSDMaxValue; if (pPsdScan->nPSDMaxValue > (BT_8723B_1ANT_ANTDET_PSDTHRES_BACKGROUND+pPsdScan->nAntDet_ThresOffset)*100) { RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx AntennaDetect(), Abort Antenna Detection!! becaus background = %d > thres (%d)\n", pPsdScan->nPSDMaxValue/100, BT_8723B_1ANT_ANTDET_PSDTHRES_BACKGROUND+pPsdScan->nAntDet_ThresOffset)); pBoardInfo->btdmAntDetFinish = FALSE; pBoardInfo->btdmAntNumByAntDet = 1; pPsdScan->nAntDet_Result = 5; state = 99; } else { RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx AntennaDetect(), Start Antenna Detection!! becaus background = %d <= thres (%d)\n", pPsdScan->nPSDMaxValue/100, BT_8723B_1ANT_ANTDET_PSDTHRES_BACKGROUND+pPsdScan->nAntDet_ThresOffset)); state = 3; } break; case 3: BTResp = pBtCoexist->fBtcSetBtAntDetection(pBtCoexist, (u1Byte)(BTTxTime&0xff), (u1Byte)(BTLEChannel&0xff)); for (pPsdScan->nPSDGenCount=1; pPsdScan->nPSDGenCount<=WLPSD_SweepCount; pPsdScan->nPSDGenCount++) { RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx AntennaDetect(), PSDGenCount = %d\n ", pPsdScan->nPSDGenCount)); halbtc8723b1ant_PSD_SweepPoint(pBtCoexist, WLPSD_CentFreq, WLPSD_Offset, WLPSD_Span, BT_8723B_1ANT_ANTDET_PSD_POINTS, BT_8723B_1ANT_ANTDET_PSD_AVGNUM); halbtc8723b1ant_PSD_MaxHoldData(pBtCoexist, pPsdScan->nPSDGenCount); pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_SCAN, &bScan); pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_ROAM, &bRoam); if (bScan ||bRoam) { pBoardInfo->btdmAntDetFinish = FALSE; pBoardInfo->btdmAntNumByAntDet = 1; pPsdScan->nAntDet_Result = 8; state = 99; break; } } pPsdScan->nAntDet_PSDScanPeakVal = pPsdScan->nPSDMaxValue; pPsdScan->nAntDet_PSDScanPeakFreq = pPsdScan->nPSDMaxValuePoint; state = 4; break; case 4: if (pPsdScan->nPSDPoint == 0) nDeltaFreqPerPoint = 0; else nDeltaFreqPerPoint = pPsdScan->nPSDBandWidth/pPsdScan->nPSDPoint; 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) { RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx AntennaDetect(), Max Value: Freq = %d.0%d MHz", freq1, freq2)); CL_SPRINTF(pPsdScan->nAntDet_PeakFreq, BT_8723B_1ANT_ANTDET_BUF_LEN, "%d.0%d", freq1,freq2); } else { RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx AntennaDetect(), Max Value: Freq = %d.%d MHz", freq1, freq2)); CL_SPRINTF(pPsdScan->nAntDet_PeakFreq, BT_8723B_1ANT_ANTDET_BUF_LEN, "%d.%d", freq1,freq2); } if (PsdRep2 < 10) { RT_TRACE(COMP_COEX, DBG_LOUD, (", Value = %d.0%d dB\n", PsdRep1, PsdRep2)); CL_SPRINTF(pPsdScan->nAntDet_PeakVal, BT_8723B_1ANT_ANTDET_BUF_LEN, "%d.0%d", PsdRep1,PsdRep2); } else { RT_TRACE(COMP_COEX, DBG_LOUD, (", Value = %d.%d dB\n",PsdRep1, PsdRep2)); CL_SPRINTF(pPsdScan->nAntDet_PeakVal, BT_8723B_1ANT_ANTDET_BUF_LEN, "%d.%d", PsdRep1,PsdRep2); } pPsdScan->nAntDet_IsBTReplyAvailable = TRUE; if (BTResp == FALSE) { pPsdScan->nAntDet_IsBTReplyAvailable = FALSE; pPsdScan->nAntDet_Result = 0; pBoardInfo->btdmAntDetFinish = FALSE; pBoardInfo->btdmAntNumByAntDet = 1; RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx AntennaDetect(), BT Response = Fail \n ")); } else if (pPsdScan->nPSDMaxValue > (BT_8723B_1ANT_ANTDET_PSDTHRES_2ANT_BADISOLATION)*100) { pPsdScan->nAntDet_Result = 1; pBoardInfo->btdmAntDetFinish = TRUE; pBoardInfo->btdmAntNumByAntDet = 2; RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx AntennaDetect(), Detect Result = 2-Ant, Bad-Isolation!! \n")); } else if (pPsdScan->nPSDMaxValue > (BT_8723B_1ANT_ANTDET_PSDTHRES_2ANT_GOODISOLATION+pPsdScan->nAntDet_ThresOffset)*100) { pPsdScan->nAntDet_Result = 2; pBoardInfo->btdmAntDetFinish = TRUE; pBoardInfo->btdmAntNumByAntDet = 2; RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx AntennaDetect(), Detect Result = 2-Ant, Good-Isolation!! \n")); } else if (pPsdScan->nPSDMaxValue > (BT_8723B_1ANT_ANTDET_PSDTHRES_1ANT)*100) { pPsdScan->nAntDet_Result = 3; pBoardInfo->btdmAntDetFinish = TRUE; pBoardInfo->btdmAntNumByAntDet = 1; RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx AntennaDetect(), Detect Result = 1-Ant!!\n")); } else { pPsdScan->nAntDet_Result = 4; pBoardInfo->btdmAntDetFinish = FALSE; pBoardInfo->btdmAntNumByAntDet = 1; RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx AntennaDetect(), Detect Result = 1-Ant, un-certainity!!\n")); } state = 99; break; case 99: //restore setup //Set AFH mask off at WiFi channel 2472MHz +/- 10MHz H2C_Parameter[0] = 0x0; H2C_Parameter[1] = 0x0; H2C_Parameter[2] = 0x0; RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx AntennaDetect(), Set AFH on, Cent-Ch= %d, Mask=%d\n", H2C_Parameter[1],H2C_Parameter[2])); pBtCoexist->fBtcFillH2c(pBtCoexist, 0x66, 3, H2C_Parameter); //Set Antenna Path halbtc8723b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_PTA, FORCE_EXEC, FALSE, FALSE); RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx AntennaDetect(), Set Antenna to PTA\n!!")); //Resume Coex DM pBtCoexist->bStopCoexDm = FALSE; RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx AntennaDetect(), Resume Coex DM\n!!")); //stimulate coex running halbtc8723b1ant_RunCoexistMechanism(pBtCoexist); RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx AntennaDetect(), Stimulate Coex running\n!!")); outloop = TRUE; break; } }while(!outloop); } VOID halbtc8723b1ant_PSD_AntennaDetectionCheck( IN PBTC_COEXIST pBtCoexist ) { static u4Byte AntDetCount = 0, AntDetFailCount = 0; PBTC_BOARD_INFO pBoardInfo=&pBtCoexist->boardInfo; BOOLEAN bScan, bRoam; pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_SCAN, &bScan); pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_ROAM, &bRoam); pPsdScan->nAntDet_BTTxTime = 20; //0.42ms*50 = 20ms pPsdScan->nAntDet_BTLEChannel = 39; AntDetCount++; pPsdScan->bAntDet_TryCount = AntDetCount; if (bScan ||bRoam) { pBoardInfo->btdmAntDetFinish = FALSE; pPsdScan->nAntDet_Result = 6; } else if(pBtCoexist->btInfo.bBtDisabled) { pBoardInfo->btdmAntDetFinish = FALSE; pPsdScan->nAntDet_Result = 11; } else if (pCoexSta->nNumOfProfile >= 1) { pBoardInfo->btdmAntDetFinish = FALSE; pPsdScan->nAntDet_Result = 7; } else if (!pPsdScan->nAntDet_IsAntDetAvailable) //Antenna initial setup is not ready { pBoardInfo->btdmAntDetFinish = FALSE; pPsdScan->nAntDet_Result = 9; } else if (pCoexSta->bC2hBtInquiryPage) { pBoardInfo->btdmAntDetFinish = FALSE; pPsdScan->nAntDet_Result = 10; } else { halbtc8723b1ant_PSD_AntennaDetection(pBtCoexist, pPsdScan->nAntDet_BTTxTime, pPsdScan->nAntDet_BTLEChannel); } if (!pBoardInfo->btdmAntDetFinish) AntDetFailCount++; pPsdScan->bAntDet_FailCount = AntDetFailCount; } //============================================================ // work around function start with wa_halbtc8723b1ant_ //============================================================ //============================================================ // extern function start with EXhalbtc8723b1ant_ //============================================================ VOID EXhalbtc8723b1ant_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 8723b 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; pBtCoexist->fBtcWrite1Byte(pBtCoexist, 0x67, 0x20); // 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 GRAN_BT = 1 pBtCoexist->fBtcWrite1Byte(pBtCoexist, 0x765, 0x18); // 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 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); } } } VOID EXhalbtc8723b1ant_PreLoadFirmware( IN PBTC_COEXIST pBtCoexist ) { } VOID EXhalbtc8723b1ant_InitHwConfig( IN PBTC_COEXIST pBtCoexist, IN BOOLEAN bWifiOnly ) { halbtc8723b1ant_InitHwConfig(pBtCoexist, TRUE, bWifiOnly); pBtCoexist->bStopCoexDm = FALSE; } VOID EXhalbtc8723b1ant_InitCoexDm( IN PBTC_COEXIST pBtCoexist ) { RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Coex Mechanism Init!!\n")); pBtCoexist->bStopCoexDm = FALSE; halbtc8723b1ant_InitCoexDm(pBtCoexist); halbtc8723b1ant_QueryBtInfo(pBtCoexist); } VOID EXhalbtc8723b1ant_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)/ %c", "Version Coex/ Fw/ Patch/ Cut", \ GLCoexVerDate8723b1Ant, GLCoexVer8723b1Ant, fwVer, btPatchVer, btPatchVer, pCoexSta->nCutVersion+65); 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_8723B_1ANT_BT_STATUS_NON_CONNECTED_IDLE == pCoexDm->btStatus)? "non-connected idle": ( (BT_8723B_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 / %d", "SCO/HID/PAN/A2DP/NameReq/WHQL", \ pBtLinkInfo->bScoExist, pBtLinkInfo->bHidExist, pBtLinkInfo->bPanExist, pBtLinkInfo->bA2dpExist, pCoexSta->bC2hBtRemoteNameReq, pCoexSta->bBtWhckTest ); CL_PRINTF(cliBuf); if (pStackInfo->bProfileNotified) { pBtCoexist->fBtcDispDbgMsg(pBtCoexist, BTC_DBG_DISP_BT_LINK_INFO); } else { CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %s", "BT Role", \ (pBtLinkInfo->bSlaveRole )? "Slave":"Master"); CL_PRINTF(cliBuf); } btInfoExt = pCoexSta->btInfoExt; CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %s/ %d", "A2DP Rate/Bitpool", \ (btInfoExt&BIT0)? "BR":"EDR", pCoexSta->nA2DPBitPool); CL_PRINTF(cliBuf); for(i=0; ibtInfoC2hCnt[i]) { CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %02x %02x %02x %02x %02x %02x %02x(%d)", GLBtInfoSrc8723b1Ant[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", "SM[LowPenaltyRA]", \ pCoexDm->bCurLowPenaltyRa); CL_PRINTF(cliBuf); CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %s/ %s/ %d ", "DelBA/ BtCtrlAgg/ AggSize", \ (pBtCoexist->btInfo.bRejectAggPkt? "Yes":"No"), (pBtCoexist->btInfo.bBtCtrlAggBufSize? "Yes":"No"), pBtCoexist->btInfo.aggBufSize); CL_PRINTF(cliBuf); CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = 0x%x ", "Rate Mask", \ pBtCoexist->btInfo.raMask); 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; if (pBoardInfo->btdmAntNumByAntDet == 2) { if (pCoexDm->bCurPsTdmaOn) psTdmaCase = psTdmaCase +100; //for WiFi RSSI low or BT RSSI low else psTdmaCase = 1; //always translate to TDMA(off,1) for TDMA-off case } 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", "Coex Table Type", \ pCoexSta->nCoexTableType); CL_PRINTF(cliBuf); CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = %d", "IgnWlanAct", \ pCoexDm->bCurIgnoreWlanAct); CL_PRINTF(cliBuf); /* CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = 0x%x ", "Latest error condition(should be 0)", \ pCoexDm->errorCondition); CL_PRINTF(cliBuf); */ // Hw setting CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s", "============[Hw setting]============"); CL_PRINTF(cliBuf); CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = 0x%x/0x%x/0x%x/0x%x", "backup ARFR1/ARFR2/RL/AMaxTime", \ pCoexDm->backupArfrCnt1, pCoexDm->backupArfrCnt2, pCoexDm->backupRetryLimit, pCoexDm->backupAmpduMaxTime); 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); u1Tmp[0] = pBtCoexist->fBtcRead1Byte(pBtCoexist, 0x778); u4Tmp[0] = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0x6cc); u4Tmp[1] = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0x880); CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = 0x%x/ 0x%x/ 0x%x", "0x778/0x6cc/0x880[29:25]", \ u1Tmp[0], u4Tmp[0], (u4Tmp[1]&0x3e000000) >> 25); CL_PRINTF(cliBuf); u4Tmp[0] = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0x948); u1Tmp[0] = pBtCoexist->fBtcRead1Byte(pBtCoexist, 0x67); u4Tmp[1] = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0x764); u1Tmp[1] = pBtCoexist->fBtcRead1Byte(pBtCoexist, 0x76e); CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = 0x%x/ 0x%x/ 0x%x/ 0x%x", "0x948/ 0x67[5] / 0x764 / 0x76e", \ u4Tmp[0], ((u1Tmp[0]&0x20)>> 5), (u4Tmp[1] & 0xffff), u1Tmp[1]); CL_PRINTF(cliBuf); u4Tmp[0] = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0x92c); u4Tmp[1] = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0x930); u4Tmp[2] = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0x944); CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = 0x%x/ 0x%x/ 0x%x", "0x92c[1:0]/ 0x930[7:0]/0x944[1:0]", \ u4Tmp[0]&0x3, u4Tmp[1]&0xff, u4Tmp[2]&0x3); CL_PRINTF(cliBuf); u1Tmp[0] = pBtCoexist->fBtcRead1Byte(pBtCoexist, 0x39); u1Tmp[1] = pBtCoexist->fBtcRead1Byte(pBtCoexist, 0x40); u4Tmp[0] = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0x4c); u1Tmp[2] = pBtCoexist->fBtcRead1Byte(pBtCoexist, 0x64); CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = 0x%x/ 0x%x/ 0x%x/ 0x%x", "0x38[11]/0x40/0x4c[24:23]/0x64[0]", \ ((u1Tmp[0] & 0x8)>>3), u1Tmp[1], ((u4Tmp[0]&0x01800000)>>23), u1Tmp[2]&0x1); CL_PRINTF(cliBuf); u4Tmp[0] = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0x550); u1Tmp[0] = pBtCoexist->fBtcRead1Byte(pBtCoexist, 0x522); CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = 0x%x/ 0x%x", "0x550(bcn ctrl)/0x522", \ u4Tmp[0], u1Tmp[0]); CL_PRINTF(cliBuf); u4Tmp[0] = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0xc50); u1Tmp[0] = pBtCoexist->fBtcRead1Byte(pBtCoexist, 0x49c); CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = 0x%x/ 0x%x", "0xc50(dig)/0x49c(null-drop)", \ u4Tmp[0]&0xff, u1Tmp[0]); 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]; CL_SPRINTF(cliBuf, BT_TMP_BUF_SIZE, "\r\n %-35s = 0x%x/ 0x%x/ 0x%x", "OFDM-CCA/OFDM-FA/CCK-FA", \ 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); 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); 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_8723B_1ANT == 1) //halbtc8723b1ant_MonitorBtCtr(pBtCoexist); #endif pBtCoexist->fBtcDispDbgMsg(pBtCoexist, BTC_DBG_DISP_COEX_STATISTICS); } VOID EXhalbtc8723b1ant_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; halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, FALSE, 0); halbtc8723b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_BT, FORCE_EXEC, FALSE, TRUE); halbtc8723b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 0); //halbtc8723b1ant_SetAntPathDCut(pBtCoexist, FALSE, FALSE, FALSE, BTC_ANT_PATH_BT, BTC_WIFI_STAT_NORMAL_OFF); } else if(BTC_IPS_LEAVE == type) { RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], IPS LEAVE notify\n")); halbtc8723b1ant_InitHwConfig(pBtCoexist, FALSE, FALSE); halbtc8723b1ant_InitCoexDm(pBtCoexist); halbtc8723b1ant_QueryBtInfo(pBtCoexist); pCoexSta->bUnderIps = FALSE; } } VOID EXhalbtc8723b1ant_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 EXhalbtc8723b1ant_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")); pPsdScan->nAntDet_IsAntDetAvailable = TRUE; halbtc8723b1ant_PsTdma(pBtCoexist, FORCE_EXEC, FALSE, 8); //Force antenna setup for no scan result issue halbtc8723b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_PTA, FORCE_EXEC, FALSE, FALSE); u4Tmp = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0x948); u1Tmpa = pBtCoexist->fBtcRead1Byte(pBtCoexist, 0x765); u1Tmpb = pBtCoexist->fBtcRead1Byte(pBtCoexist, 0x67); RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], 0x948=0x%x, 0x765=0x%x, 0x67=0x%x\n", u4Tmp, u1Tmpa, u1Tmpb)); } 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); halbtc8723b1ant_QueryBtInfo(pBtCoexist); pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_U4_WIFI_LINK_STATUS, &wifiLinkStatus); numOfWifiLink = wifiLinkStatus>>16; if(numOfWifiLink >= 2) { halbtc8723b1ant_LimitedTx(pBtCoexist, NORMAL_EXEC, 0, 0, 0, 0); halbtc8723b1ant_LimitedRx(pBtCoexist, NORMAL_EXEC, FALSE, bBtCtrlAggBufSize, aggBufSize); halbtc8723b1ant_ActionWifiMultiPort(pBtCoexist); return; } if(pCoexSta->bC2hBtInquiryPage) { halbtc8723b1ant_ActionBtInquiry(pBtCoexist); return; } else if(bBtHsOn) { halbtc8723b1ant_ActionHs(pBtCoexist); return; } if(BTC_SCAN_START == type) { //RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], SCAN START notify\n")); if(!bWifiConnected) // non-connected scan { halbtc8723b1ant_ActionWifiNotConnectedScan(pBtCoexist); } else // wifi is connected { halbtc8723b1ant_ActionWifiConnectedScan(pBtCoexist); } } else if(BTC_SCAN_FINISH == type) { //RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], SCAN FINISH notify\n")); if(!bWifiConnected) // non-connected scan { halbtc8723b1ant_ActionWifiNotConnected(pBtCoexist); } else { halbtc8723b1ant_ActionWifiConnected(pBtCoexist); } } } VOID EXhalbtc8723b1ant_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; pPsdScan->nAntDet_IsAntDetAvailable = TRUE; halbtc8723b1ant_PsTdma(pBtCoexist, FORCE_EXEC, FALSE, 8); //Force antenna setup for no scan result issue halbtc8723b1ant_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) { halbtc8723b1ant_LimitedTx(pBtCoexist, NORMAL_EXEC, 0, 0, 0, 0); halbtc8723b1ant_LimitedRx(pBtCoexist, NORMAL_EXEC, FALSE, bBtCtrlAggBufSize, aggBufSize); halbtc8723b1ant_ActionWifiMultiPort(pBtCoexist); return; } pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_HS_OPERATION, &bBtHsOn); if(pCoexSta->bC2hBtInquiryPage) { halbtc8723b1ant_ActionBtInquiry(pBtCoexist); return; } else if(bBtHsOn) { halbtc8723b1ant_ActionHs(pBtCoexist); return; } if(BTC_ASSOCIATE_START == type) { //RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], CONNECT START notify\n")); halbtc8723b1ant_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 { halbtc8723b1ant_ActionWifiNotConnected(pBtCoexist); } else { halbtc8723b1ant_ActionWifiConnected(pBtCoexist); } } } VOID EXhalbtc8723b1ant_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")); halbtc8723b1ant_PsTdma(pBtCoexist, FORCE_EXEC, FALSE, 8); //Force antenna setup for no scan result issue halbtc8723b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_PTA, FORCE_EXEC, FALSE, FALSE); pPsdScan->nAntDet_IsAntDetAvailable = TRUE; 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 } 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; } // 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; 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); } VOID EXhalbtc8723b1ant_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) { halbtc8723b1ant_LimitedTx(pBtCoexist, NORMAL_EXEC, 0, 0, 0, 0); halbtc8723b1ant_LimitedRx(pBtCoexist, NORMAL_EXEC, FALSE, bBtCtrlAggBufSize, aggBufSize); halbtc8723b1ant_ActionWifiMultiPort(pBtCoexist); return; } pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_HS_OPERATION, &bBtHsOn); if(pCoexSta->bC2hBtInquiryPage) { halbtc8723b1ant_ActionBtInquiry(pBtCoexist); return; } else if(bBtHsOn) { halbtc8723b1ant_ActionHs(pBtCoexist); return; } if( BTC_PACKET_DHCP == type || BTC_PACKET_EAPOL == type || ( (BTC_PACKET_ARP == type ) && (pCoexSta->bWiFiIsHighPriTask) ) ) { halbtc8723b1ant_ActionWifiConnectedSpecialPacket(pBtCoexist); } } VOID EXhalbtc8723b1ant_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_8723B_1ANT_MAX) rspSource = BT_INFO_SRC_8723B_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; ibtInfoC2h[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_8723B_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->bC2hBtRemoteNameReq = TRUE; else pCoexSta->bC2hBtRemoteNameReq = FALSE; pCoexSta->btRssi = pCoexSta->btInfoC2h[rspSource][3]*2-90; //pCoexSta->btInfoC2h[rspSource][3]*2+10; pCoexSta->btInfoExt = pCoexSta->btInfoC2h[rspSource][4]; if (pCoexSta->btInfoC2h[rspSource][1] == 0x49) { pCoexSta->nA2DPBitPool = pCoexSta->btInfoC2h[rspSource][6]; } else pCoexSta->nA2DPBitPool = 0; pCoexSta->bBtTxRxMask = (pCoexSta->btInfoC2h[rspSource][2]&0x40); pBtCoexist->fBtcSet(pBtCoexist, BTC_SET_BL_BT_TX_RX_MASK, &pCoexSta->bBtTxRxMask); #if BT_8723B_1ANT_ANTDET_ENABLE #if BT_8723B_1ANT_ANTDET_COEXMECHANISMSWITCH_ENABLE if ((pBoardInfo->btdmAntDetFinish) && (pBoardInfo->btdmAntNumByAntDet == 2)) { if(pCoexSta->bBtTxRxMask) { /* BT into is responded by BT FW and BT RF REG 0x3C != 0x15 => Need to switch BT TRx Mask */ RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Switch BT TRx Mask since BT RF REG 0x3C != 0x1\n")); //BT TRx Mask un-lock 0x2c[0], 0x30[0] = 1 pBtCoexist->fBtcSetBtReg(pBtCoexist, BTC_BT_REG_RF, 0x2c, 0x7c45); pBtCoexist->fBtcSetBtReg(pBtCoexist, BTC_BT_REG_RF, 0x30, 0x7c45); pBtCoexist->fBtcSetBtReg(pBtCoexist, BTC_BT_REG_RF, 0x3c, 0x1); } } else #endif #endif { if(!pCoexSta->bBtTxRxMask) { /* BT into is responded by BT FW and BT RF REG 0x3C != 0x15 => Need to switch BT TRx Mask */ RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Switch BT TRx Mask since BT RF REG 0x3C != 0x15\n")); pBtCoexist->fBtcSetBtReg(pBtCoexist, BTC_BT_REG_RF, 0x3c, 0x15); //BT TRx Mask lock 0x2c[0], 0x30[0] = 0 pBtCoexist->fBtcSetBtReg(pBtCoexist, BTC_BT_REG_RF, 0x2c, 0x7c44); pBtCoexist->fBtcSetBtReg(pBtCoexist, BTC_BT_REG_RF, 0x30, 0x7c44); } } // 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) { EXhalbtc8723b1ant_MediaStatusNotify(pBtCoexist, BTC_MEDIA_CONNECT); } else { EXhalbtc8723b1ant_MediaStatusNotify(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")); halbtc8723b1ant_IgnoreWlanAct(pBtCoexist, FORCE_EXEC, FALSE); } } else { // BT already NOT ignore Wlan active, do nothing here. } #if(BT_AUTO_REPORT_ONLY_8723B_1ANT == 0) if( (pCoexSta->btInfoExt & BIT4) ) { // BT auto report already enabled, do nothing } else { halbtc8723b1ant_BtAutoReport(pBtCoexist, FORCE_EXEC, TRUE); } #endif } // check BIT2 first ==> check if bt is under inquiry or page scan if(btInfo & BT_INFO_8723B_1ANT_B_INQ_PAGE) pCoexSta->bC2hBtInquiryPage = TRUE; else pCoexSta->bC2hBtInquiryPage = FALSE; pCoexSta->nNumOfProfile = 0; // set link exist status if(!(btInfo&BT_INFO_8723B_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_8723B_1ANT_B_FTP) { pCoexSta->bPanExist = TRUE; pCoexSta->nNumOfProfile++; } else pCoexSta->bPanExist = FALSE; if(btInfo & BT_INFO_8723B_1ANT_B_A2DP) { pCoexSta->bA2dpExist = TRUE; pCoexSta->nNumOfProfile++; } else pCoexSta->bA2dpExist = FALSE; if(btInfo & BT_INFO_8723B_1ANT_B_HID) { pCoexSta->bHidExist = TRUE; pCoexSta->nNumOfProfile++; } else pCoexSta->bHidExist = FALSE; if(btInfo & BT_INFO_8723B_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; } } //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; if((btInfo&BT_INFO_8723B_1ANT_B_ACL_BUSY) && (pCoexSta->nNumOfProfile == 0)) { if (pCoexSta->lowPriorityTx + pCoexSta->lowPriorityRx >= 160) { pCoexSta->bPanExist = TRUE; pCoexSta->nNumOfProfile++; pCoexSta->wrongProfileNotification++; btInfo = btInfo | 0x88; } } } halbtc8723b1ant_UpdateBtLinkInfo(pBtCoexist); btInfo = btInfo & 0x1f; //mask profile bit for connect-ilde identification ( for CSR case: A2DP idle --> 0x41) if(!(btInfo&BT_INFO_8723B_1ANT_B_CONNECTION)) { pCoexDm->btStatus = BT_8723B_1ANT_BT_STATUS_NON_CONNECTED_IDLE; RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BtInfoNotify(), BT Non-Connected idle!!!\n")); } else if(btInfo == BT_INFO_8723B_1ANT_B_CONNECTION) // connection exists but no busy { pCoexDm->btStatus = BT_8723B_1ANT_BT_STATUS_CONNECTED_IDLE; RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BtInfoNotify(), BT Connected-idle!!!\n")); } else if((btInfo&BT_INFO_8723B_1ANT_B_SCO_ESCO) || (btInfo&BT_INFO_8723B_1ANT_B_SCO_BUSY)) { pCoexDm->btStatus = BT_8723B_1ANT_BT_STATUS_SCO_BUSY; RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BtInfoNotify(), BT SCO busy!!!\n")); } else if(btInfo&BT_INFO_8723B_1ANT_B_ACL_BUSY) { if(BT_8723B_1ANT_BT_STATUS_ACL_BUSY != pCoexDm->btStatus) pCoexDm->bAutoTdmaAdjust = FALSE; pCoexDm->btStatus = BT_8723B_1ANT_BT_STATUS_ACL_BUSY; RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BtInfoNotify(), BT ACL busy!!!\n")); } else { pCoexDm->btStatus = BT_8723B_1ANT_BT_STATUS_MAX; RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], BtInfoNotify(), BT Non-Defined state!!!\n")); } if( (BT_8723B_1ANT_BT_STATUS_ACL_BUSY == pCoexDm->btStatus) || (BT_8723B_1ANT_BT_STATUS_SCO_BUSY == pCoexDm->btStatus) || (BT_8723B_1ANT_BT_STATUS_ACL_SCO_BUSY == pCoexDm->btStatus) ) bBtBusy = TRUE; else bBtBusy = FALSE; pBtCoexist->fBtcSet(pBtCoexist, BTC_SET_BL_BT_TRAFFIC_BUSY, &bBtBusy); halbtc8723b1ant_RunCoexistMechanism(pBtCoexist); } VOID EXhalbtc8723b1ant_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")); halbtc8723b1ant_PowerSaveState(pBtCoexist, BTC_PS_WIFI_NATIVE, 0x0, 0x0); halbtc8723b1ant_PsTdma(pBtCoexist, FORCE_EXEC, FALSE, 0); halbtc8723b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_BT, FORCE_EXEC, FALSE, TRUE); //halbtc8723b1ant_SetAntPathDCut(pBtCoexist, FALSE, FALSE, FALSE, BTC_ANT_PATH_BT, BTC_WIFI_STAT_NORMAL_OFF); halbtc8723b1ant_IgnoreWlanAct(pBtCoexist, FORCE_EXEC, TRUE); pBtCoexist->bStopCoexDm = TRUE; u4Tmp = pBtCoexist->fBtcRead4Byte(pBtCoexist, 0x948); u1Tmpa = pBtCoexist->fBtcRead1Byte(pBtCoexist, 0x765); u1Tmpb = pBtCoexist->fBtcRead1Byte(pBtCoexist, 0x67); u1Tmpc = pBtCoexist->fBtcRead1Byte(pBtCoexist, 0x76e); RT_TRACE(COMP_COEX, DBG_LOUD, ("############# [BTCoex], 0x948=0x%x, 0x765=0x%x, 0x67=0x%x, 0x76e=0x%x\n", u4Tmp, u1Tmpa, u1Tmpb, u1Tmpc)); } } VOID EXhalbtc8723b1ant_HaltNotify( IN PBTC_COEXIST pBtCoexist ) { u4Byte u4Tmp; RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], Halt notify\n")); halbtc8723b1ant_PowerSaveState(pBtCoexist, BTC_PS_WIFI_NATIVE, 0x0, 0x0); halbtc8723b1ant_PsTdma(pBtCoexist, FORCE_EXEC, FALSE, 0); halbtc8723b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_BT, FORCE_EXEC, FALSE, TRUE); //halbtc8723b1ant_SetAntPathDCut(pBtCoexist, FALSE, FALSE, FALSE, BTC_ANT_PATH_BT, BTC_WIFI_STAT_NORMAL_OFF); halbtc8723b1ant_IgnoreWlanAct(pBtCoexist, FORCE_EXEC, TRUE); EXhalbtc8723b1ant_MediaStatusNotify(pBtCoexist, BTC_MEDIA_DISCONNECT); pBtCoexist->bStopCoexDm = TRUE; } VOID EXhalbtc8723b1ant_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")); halbtc8723b1ant_PowerSaveState(pBtCoexist, BTC_PS_WIFI_NATIVE, 0x0, 0x0); halbtc8723b1ant_PsTdma(pBtCoexist, NORMAL_EXEC, FALSE, 0); halbtc8723b1ant_SetAntPath(pBtCoexist, BTC_ANT_PATH_BT, FORCE_EXEC, FALSE, TRUE); halbtc8723b1ant_CoexTableWithType(pBtCoexist, NORMAL_EXEC, 2); //halbtc8723b1ant_SetAntPathDCut(pBtCoexist, FALSE, FALSE, FALSE, BTC_ANT_PATH_BT, BTC_WIFI_STAT_NORMAL_OFF); 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; halbtc8723b1ant_InitHwConfig(pBtCoexist, FALSE, FALSE); halbtc8723b1ant_InitCoexDm(pBtCoexist); halbtc8723b1ant_QueryBtInfo(pBtCoexist); } } VOID EXhalbtc8723b1ant_CoexDmReset( IN PBTC_COEXIST pBtCoexist ) { RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], *****************Coex DM Reset*****************\n")); halbtc8723b1ant_InitHwConfig(pBtCoexist, FALSE, FALSE); //pBtCoexist->fBtcSetRfReg(pBtCoexist, BTC_RF_A, 0x1, 0xfffff, 0x0); //pBtCoexist->fBtcSetRfReg(pBtCoexist, BTC_RF_A, 0x2, 0xfffff, 0x0); halbtc8723b1ant_InitCoexDm(pBtCoexist); } VOID EXhalbtc8723b1ant_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; PBTC_BT_LINK_INFO pBtLinkInfo=&pBtCoexist->btLinkInfo; 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", GLCoexVerDate8723b1Ant, GLCoexVer8723b1Ant, fwVer, btPatchVer, btPatchVer)); RT_TRACE(COMP_COEX, DBG_LOUD, ("[BTCoex], ****************************************************************\n")); } #if(BT_AUTO_REPORT_ONLY_8723B_1ANT == 0) halbtc8723b1ant_QueryBtInfo(pBtCoexist); halbtc8723b1ant_MonitorBtEnableDisable(pBtCoexist); #else halbtc8723b1ant_MonitorBtCtr(pBtCoexist); halbtc8723b1ant_MonitorWiFiCtr(pBtCoexist); #if BT_8723B_1ANT_ANTDET_ENABLE halbtc8723b1ant_MonitorBtEnableDisable(pBtCoexist); #endif if ( (pCoexSta->highPriorityTx + pCoexSta->highPriorityRx < 50) && (pBtLinkInfo->bHidExist == TRUE)) { pBtLinkInfo->bHidExist = FALSE; } if( halbtc8723b1ant_IsWifiStatusChanged(pBtCoexist) || pCoexDm->bAutoTdmaAdjust ) { halbtc8723b1ant_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; halbtc8723b1ant_AntennaDetection(pBtCoexist, pPsdScan->realcentFreq, pPsdScan->realoffset, pPsdScan->realspan, pPsdScan->realseconds); pPsdScan->nPSDGenTotalCount +=2; pPsdScan->nPSDGenCount += 2; } */ #endif } VOID EXhalbtc8723b1ant_AntennaDetection( IN PBTC_COEXIST pBtCoexist, IN u4Byte centFreq, IN u4Byte offset, IN u4Byte span, IN u4Byte seconds ) { static u4Byte AntDetCount = 0, AntDetFailCount = 0; PBTC_BOARD_INFO pBoardInfo=&pBtCoexist->boardInfo; BOOLEAN bScan, bRoam; #if BT_8723B_1ANT_ANTDET_ENABLE if (seconds == 0) { pPsdScan->bAntDet_TryCount = 0; pPsdScan->bAntDet_FailCount = 0; AntDetCount = 0; AntDetFailCount = 0; pBoardInfo->btdmAntDetFinish = FALSE; pBoardInfo->btdmAntNumByAntDet = 1; return; } if (!pBoardInfo->btdmAntDetFinish) { pPsdScan->nAntDet_IntevalCount = pPsdScan->nAntDet_IntevalCount+2; if (pPsdScan->nAntDet_IntevalCount >= BT_8723B_1ANT_ANTDET_RETRY_INTERVAL) { RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx AntennaDetect(), Antenna Det Timer is up, Try Detect!!\n")); halbtc8723b1ant_PSD_AntennaDetectionCheck(pBtCoexist); if (pBoardInfo->btdmAntDetFinish) { RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx AntennaDetect(), Antenna Det Success!!\n")); #if 1 if (pBoardInfo->btdmAntNumByAntDet == 2) halbtc8723b1ant_MechanismSwitch(pBtCoexist, TRUE); else halbtc8723b1ant_MechanismSwitch(pBtCoexist, FALSE); #endif } else RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx AntennaDetect(), Antenna Det Fail!!\n")); pPsdScan->nAntDet_IntevalCount = 0; } else { RT_TRACE(COMP_COEX, DBG_LOUD, ("xxxxxxxxxxxxxxxx AntennaDetect(), Antenna Det Timer is not up! (%d)\n", pPsdScan->nAntDet_IntevalCount)); } } #endif /* pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_SCAN, &bScan); pBtCoexist->fBtcGet(pBtCoexist, BTC_GET_BL_WIFI_ROAM, &bRoam); pPsdScan->nAntDet_BTTxTime = seconds; //0.42ms*50 = 20ms pPsdScan->nAntDet_BTLEChannel = centFreq; if (seconds == 0) { pPsdScan->bAntDet_TryCount = 0; pPsdScan->bAntDet_FailCount = 0; AntDetCount = 0; AntDetFailCount = 0; pBoardInfo->btdmAntDetFinish = FALSE; pBoardInfo->btdmAntNumByAntDet = 1; return; } else { AntDetCount++; pPsdScan->bAntDet_TryCount = AntDetCount; if (bScan ||bRoam) { pBoardInfo->btdmAntDetFinish = FALSE; pPsdScan->nAntDet_Result = 6; } else if (pCoexSta->nNumOfProfile >= 1) { pBoardInfo->btdmAntDetFinish = FALSE; pPsdScan->nAntDet_Result = 7; } else if (!pPsdScan->nAntDet_IsAntDetAvailable) //Antenna initial setup is not ready { pBoardInfo->btdmAntDetFinish = FALSE; pPsdScan->nAntDet_Result = 9; } else if (pCoexSta->bC2hBtInquiryPage) { pBoardInfo->btdmAntDetFinish = FALSE; pPsdScan->nAntDet_Result = 10; } else { //halbtc8723b1ant_PSD_AntennaDetection(pBtCoexist, pPsdScan->nAntDet_BTTxTime, pPsdScan->nAntDet_BTLEChannel); } if (!pBoardInfo->btdmAntDetFinish) AntDetFailCount++; pPsdScan->bAntDet_FailCount = AntDetFailCount; } */ } VOID EXhalbtc8723b1ant_AntennaIsolation( IN PBTC_COEXIST pBtCoexist, IN u4Byte centFreq, IN u4Byte offset, IN u4Byte span, IN u4Byte seconds ) { } VOID EXhalbtc8723b1ant_PSDScan( IN PBTC_COEXIST pBtCoexist, IN u4Byte centFreq, IN u4Byte offset, IN u4Byte span, IN u4Byte seconds ) { } VOID EXhalbtc8723b1ant_DisplayAntDetection( IN PBTC_COEXIST pBtCoexist ) { PBTC_BOARD_INFO pBoardInfo=&pBtCoexist->boardInfo; #if BT_8723B_1ANT_ANTDET_ENABLE if (pPsdScan->bAntDet_TryCount != 0) { halbtc8723b1ant_PSD_ShowAntennaDetectResult(pBtCoexist); if (pBoardInfo->btdmAntDetFinish) halbtc8723b1ant_PSD_ShowData(pBtCoexist); return; } #endif //halbtc8723b1ant_ShowPSDData(pBtCoexist); } #endif