| /****************************************************************************** |
| * |
| * This file is provided under a dual license. When you use or |
| * distribute this software, you may choose to be licensed under |
| * version 2 of the GNU General Public License ("GPLv2 License") |
| * or BSD License. |
| * |
| * GPLv2 License |
| * |
| * Copyright(C) 2016 MediaTek Inc. |
| * |
| * This program is free software; you can redistribute it and/or modify |
| * it under the terms of version 2 of the GNU General Public License as |
| * published by the Free Software Foundation. |
| * |
| * This program is distributed in the hope that it will be useful, but |
| * WITHOUT ANY WARRANTY; without even the implied warranty of |
| * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. |
| * See http://www.gnu.org/licenses/gpl-2.0.html for more details. |
| * |
| * BSD LICENSE |
| * |
| * Copyright(C) 2016 MediaTek Inc. All rights reserved. |
| * |
| * Redistribution and use in source and binary forms, with or without |
| * modification, are permitted provided that the following conditions |
| * are met: |
| * |
| * * Redistributions of source code must retain the above copyright |
| * notice, this list of conditions and the following disclaimer. |
| * * Redistributions in binary form must reproduce the above copyright |
| * notice, this list of conditions and the following disclaimer in |
| * the documentation and/or other materials provided with the |
| * distribution. |
| * * Neither the name of the copyright holder nor the names of its |
| * contributors may be used to endorse or promote products derived |
| * from this software without specific prior written permission. |
| * |
| * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS |
| * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT |
| * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR |
| * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT |
| * HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, |
| * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT |
| * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, |
| * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY |
| * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT |
| * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE |
| * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. |
| * |
| *****************************************************************************/ |
| /* |
| ** Id: //Department/DaVinci/BRANCHES/MT6620_WIFI_DRIVER_V2_3/nic/que_mgt.c#3 |
| */ |
| |
| /*! \file "que_mgt.c" |
| * \brief TX/RX queues management |
| * |
| * The main tasks of queue management include TC-based HIF TX flow control, |
| * adaptive TC quota adjustment, HIF TX grant scheduling, Power-Save |
| * forwarding control, RX packet reordering, and RX BA agreement management. |
| */ |
| |
| |
| /******************************************************************************* |
| * C O M P I L E R F L A G S |
| ******************************************************************************** |
| */ |
| |
| /******************************************************************************* |
| * E X T E R N A L R E F E R E N C E S |
| ******************************************************************************** |
| */ |
| #include "precomp.h" |
| #include "queue.h" |
| |
| /******************************************************************************* |
| * C O N S T A N T S |
| ******************************************************************************** |
| */ |
| |
| /******************************************************************************* |
| * D A T A T Y P E S |
| ******************************************************************************** |
| */ |
| |
| /******************************************************************************* |
| * P U B L I C D A T A |
| ******************************************************************************** |
| */ |
| OS_SYSTIME g_arMissTimeout[CFG_STA_REC_NUM][CFG_RX_MAX_BA_TID_NUM]; |
| |
| const UINT_8 aucTid2ACI[TX_DESC_TID_NUM] = { |
| WMM_AC_BE_INDEX, /* TID0 */ |
| WMM_AC_BK_INDEX, /* TID1 */ |
| WMM_AC_BK_INDEX, /* TID2 */ |
| WMM_AC_BE_INDEX, /* TID3 */ |
| WMM_AC_VI_INDEX, /* TID4 */ |
| WMM_AC_VI_INDEX, /* TID5 */ |
| WMM_AC_VO_INDEX, /* TID6 */ |
| WMM_AC_VO_INDEX /* TID7 */ |
| }; |
| |
| const UINT_8 aucACI2TxQIdx[WMM_AC_INDEX_NUM] = { |
| TX_QUEUE_INDEX_AC1, /* WMM_AC_BE_INDEX */ |
| TX_QUEUE_INDEX_AC0, /* WMM_AC_BK_INDEX */ |
| TX_QUEUE_INDEX_AC2, /* WMM_AC_VI_INDEX */ |
| TX_QUEUE_INDEX_AC3 /* WMM_AC_VO_INDEX */ |
| }; |
| |
| const PUINT_8 apucACI2Str[WMM_AC_INDEX_NUM] = { |
| "BE", "BK", "VI", "VO" |
| }; |
| |
| const UINT_8 arNetwork2TcResource[HW_BSSID_NUM + 1][NET_TC_NUM] = { |
| /* HW Queue Set 1 */ |
| /* AC_BE, AC_BK, AC_VI, AC_VO, MGMT, BMC */ |
| {TC1_INDEX, TC0_INDEX, TC2_INDEX, TC3_INDEX, TC4_INDEX, BMC_TC_INDEX}, /* AIS */ |
| {TC1_INDEX, TC0_INDEX, TC2_INDEX, TC3_INDEX, TC4_INDEX, BMC_TC_INDEX}, /* P2P/BoW */ |
| {TC1_INDEX, TC0_INDEX, TC2_INDEX, TC3_INDEX, TC4_INDEX, BMC_TC_INDEX}, /* P2P/BoW */ |
| {TC1_INDEX, TC0_INDEX, TC2_INDEX, TC3_INDEX, TC4_INDEX, BMC_TC_INDEX}, /* P2P/BoW */ |
| {TC1_INDEX, TC0_INDEX, TC2_INDEX, TC3_INDEX, TC4_INDEX, BMC_TC_INDEX}, /* P2P_DEV */ |
| |
| |
| /* HW Queue Set 2 */ |
| /* {TC7_INDEX, TC6_INDEX, TC8_INDEX, TC9_INDEX, TC4_INDEX, TC10_INDEX}, */ |
| }; |
| |
| const UINT_8 aucWmmAC2TcResourceSet1[WMM_AC_INDEX_NUM] = { |
| TC1_INDEX, |
| TC0_INDEX, |
| TC2_INDEX, |
| TC3_INDEX |
| }; |
| |
| #if NIC_TX_ENABLE_SECOND_HW_QUEUE |
| const UINT_8 aucWmmAC2TcResourceSet2[WMM_AC_INDEX_NUM] = { |
| TC7_INDEX, |
| TC6_INDEX, |
| TC8_INDEX, |
| TC9_INDEX |
| }; |
| #endif |
| /******************************************************************************* |
| * P R I V A T E D A T A |
| ******************************************************************************** |
| */ |
| |
| /******************************************************************************* |
| * M A C R O S |
| ******************************************************************************** |
| */ |
| |
| #if CFG_RX_REORDERING_ENABLED |
| #define qmHandleRxPackets_AOSP_1 \ |
| do { \ |
| /* ToDo[6630]: duplicate removal */ \ |
| if (!fgIsBMC && nicRxIsDuplicateFrame(prCurrSwRfb) == TRUE) { \ |
| DBGLOG(QM, TRACE, "Duplicated packet is detected\n"); \ |
| RX_INC_CNT(&prAdapter->rRxCtrl, RX_DUPICATE_DROP_COUNT); \ |
| prCurrSwRfb->eDst = RX_PKT_DESTINATION_NULL; \ |
| } \ |
| /* ToDo[6630]: defragmentation */ \ |
| if (prCurrSwRfb->fgFragFrame) { \ |
| prCurrSwRfb = incRxDefragMPDU(prAdapter, prCurrSwRfb, prReturnedQue); \ |
| if (prCurrSwRfb) { \ |
| prRxStatus = prCurrSwRfb->prRxStatus; \ |
| DBGLOG(QM, TRACE, "defragmentation RxStatus=%x\n", prRxStatus); \ |
| } \ |
| } \ |
| if (prCurrSwRfb) { \ |
| fgMicErr = FALSE; \ |
| if (HAL_RX_STATUS_GET_SEC_MODE(prRxStatus) == CIPHER_SUITE_TKIP_WO_MIC) { \ |
| if (prCurrSwRfb->prStaRec) { \ |
| UINT_8 ucBssIndex; \ |
| P_BSS_INFO_T prBssInfo = NULL; \ |
| PUINT_8 pucMicKey = NULL; \ |
| ucBssIndex = prCurrSwRfb->prStaRec->ucBssIndex; \ |
| ASSERT(ucBssIndex < BSS_INFO_NUM); \ |
| prBssInfo = GET_BSS_INFO_BY_INDEX(prAdapter, ucBssIndex); \ |
| ASSERT(prBssInfo); \ |
| if (prBssInfo->eCurrentOPMode == OP_MODE_INFRASTRUCTURE) { \ |
| pucMicKey = &(prAdapter->rWifiVar.rAisSpecificBssInfo.aucRxMicKey[0]); \ |
| prCurrSwRfb->ucTid = (UINT_8) (HAL_RX_STATUS_GET_TID(prRxStatus)); \ |
| } \ |
| else { \ |
| ASSERT(FALSE); \ |
| /* pucMicKey = &prCurrSwRfb->prStaRec->aucRxMicKey[0]; */ \ |
| } \ |
| /* SW TKIP MIC verify, adopt new function call for MIC calculation */ \ |
| /* TODO:[6630] Need to Check Header Translation Case */ \ |
| if (pucMicKey == NULL) { \ |
| DBGLOG(RX, ERROR, "Mark NULL the Packet for TKIP Key Error\n"); \ |
| fgMicErr = TRUE; \ |
| } \ |
| else if (tkipMicDecapsulateInRxHdrTransMode(prCurrSwRfb, pucMicKey) == FALSE) { \ |
| fgMicErr = TRUE; \ |
| } \ |
| } \ |
| if (fgMicErr) { \ |
| /* bypass tkip frag */ \ |
| if (!prCurrSwRfb->fgFragFrame) { \ |
| DBGLOG(RX, ERROR, "Mark NULL the Packet for TKIP Mic Error\n"); \ |
| RX_INC_CNT(&prAdapter->rRxCtrl, RX_MIC_ERROR_DROP_COUNT); \ |
| prCurrSwRfb->eDst = RX_PKT_DESTINATION_NULL; \ |
| } \ |
| } \ |
| } \ |
| QUEUE_INSERT_TAIL(prReturnedQue, (P_QUE_ENTRY_T)prCurrSwRfb); \ |
| } \ |
| } while (0) |
| #endif |
| |
| #define RX_DIRECT_REORDER_LOCK(pad, dbg) \ |
| do { \ |
| P_GLUE_INFO_T _glue = pad->prGlueInfo; \ |
| if (!HAL_IS_RX_DIRECT(pad) || !_glue) \ |
| break; \ |
| if (dbg) \ |
| DBGLOG(QM, EVENT, "RX_DIRECT_REORDER_LOCK %d\n", __LINE__); \ |
| spin_lock_bh(&_glue->rSpinLock[SPIN_LOCK_RX_DIRECT_REORDER]);\ |
| } while (0) |
| |
| #define RX_DIRECT_REORDER_UNLOCK(pad, dbg) \ |
| do { \ |
| P_GLUE_INFO_T _glue = pad->prGlueInfo; \ |
| if (!HAL_IS_RX_DIRECT(pad) || !_glue) \ |
| break; \ |
| if (dbg) \ |
| DBGLOG(QM, EVENT, "RX_DIRECT_REORDER_UNLOCK %u\n", __LINE__); \ |
| spin_unlock_bh(&_glue->rSpinLock[SPIN_LOCK_RX_DIRECT_REORDER]); \ |
| } while (0) |
| |
| /******************************************************************************* |
| * F U N C T I O N D E C L A R A T I O N S |
| ******************************************************************************** |
| */ |
| |
| /******************************************************************************* |
| * F U N C T I O N S |
| ******************************************************************************** |
| */ |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief Init Queue Management for TX |
| * |
| * \param[in] (none) |
| * |
| * \return (none) |
| */ |
| /*----------------------------------------------------------------------------*/ |
| VOID qmInit(IN P_ADAPTER_T prAdapter, IN BOOLEAN isTxResrouceControlEn) |
| { |
| UINT_32 u4Idx; |
| #if QM_ADAPTIVE_TC_RESOURCE_CTRL |
| UINT_32 u4TotalMinReservedTcResource = 0; |
| UINT_32 u4TotalTcResource = 0; |
| UINT_32 u4TotalGurantedTcResource = 0; |
| #endif |
| |
| P_QUE_MGT_T prQM = &prAdapter->rQM; |
| |
| /* DbgPrint("QM: Enter qmInit()\n"); */ |
| |
| /* 4 <2> Initialize other TX queues (queues not in STA_RECs) */ |
| for (u4Idx = 0; u4Idx < NUM_OF_PER_TYPE_TX_QUEUES; u4Idx++) |
| QUEUE_INITIALIZE(&(prQM->arTxQueue[u4Idx])); |
| |
| /* 4 <3> Initialize the RX BA table and RX queues */ |
| /* Initialize the RX Reordering Parameters and Queues */ |
| for (u4Idx = 0; u4Idx < CFG_NUM_OF_RX_BA_AGREEMENTS; u4Idx++) { |
| prQM->arRxBaTable[u4Idx].fgIsValid = FALSE; |
| QUEUE_INITIALIZE(&(prQM->arRxBaTable[u4Idx].rReOrderQue)); |
| prQM->arRxBaTable[u4Idx].u2WinStart = 0xFFFF; |
| prQM->arRxBaTable[u4Idx].u2WinEnd = 0xFFFF; |
| |
| prQM->arRxBaTable[u4Idx].fgIsWaitingForPktWithSsn = FALSE; |
| prQM->arRxBaTable[u4Idx].fgHasBubble = FALSE; |
| #if CFG_SUPPORT_RX_AMSDU |
| /* RX reorder for one MSDU in AMSDU issue */ |
| prQM->arRxBaTable[u4Idx].u8LastAmsduSubIdx = RX_PAYLOAD_FORMAT_MSDU; |
| prQM->arRxBaTable[u4Idx].fgAmsduNeedLastFrame = FALSE; |
| prQM->arRxBaTable[u4Idx].fgIsAmsduDuplicated = FALSE; |
| #endif |
| prQM->arRxBaTable[u4Idx].fgFirstSnToWinStart = FALSE; |
| cnmTimerInitTimer(prAdapter, |
| &(prQM->arRxBaTable[u4Idx].rReorderBubbleTimer), |
| (PFN_MGMT_TIMEOUT_FUNC) qmHandleReorderBubbleTimeout, |
| (ULONG) (&prQM->arRxBaTable[u4Idx])); |
| |
| } |
| prQM->ucRxBaCount = 0; |
| |
| kalMemSet(&g_arMissTimeout, 0, sizeof(g_arMissTimeout)); |
| |
| prQM->fgIsTxResrouceControlEn = isTxResrouceControlEn; |
| |
| #if QM_ADAPTIVE_TC_RESOURCE_CTRL |
| /* 4 <4> Initialize TC resource control variables */ |
| for (u4Idx = 0; u4Idx < TC_NUM; u4Idx++) |
| prQM->au4AverageQueLen[u4Idx] = 0; |
| |
| ASSERT(prQM->u4TimeToAdjustTcResource && prQM->u4TimeToUpdateQueLen); |
| |
| for (u4Idx = 0; u4Idx < TC_NUM; u4Idx++) { |
| prQM->au4CurrentTcResource[u4Idx] = prAdapter->rTxCtrl.rTc.au4MaxNumOfBuffer[u4Idx]; |
| |
| if (u4Idx != TC4_INDEX) { |
| u4TotalTcResource += prQM->au4CurrentTcResource[u4Idx]; |
| u4TotalGurantedTcResource += prQM->au4GuaranteedTcResource[u4Idx]; |
| u4TotalMinReservedTcResource += prQM->au4MinReservedTcResource[u4Idx]; |
| } |
| } |
| |
| /* Sanity Check */ |
| if (u4TotalMinReservedTcResource > u4TotalTcResource) |
| kalMemZero(prQM->au4MinReservedTcResource, sizeof(prQM->au4MinReservedTcResource)); |
| |
| if (u4TotalGurantedTcResource > u4TotalTcResource) |
| kalMemZero(prQM->au4GuaranteedTcResource, sizeof(prQM->au4GuaranteedTcResource)); |
| |
| u4TotalGurantedTcResource = 0; |
| |
| /* Initialize Residual TC resource */ |
| for (u4Idx = 0; u4Idx < TC_NUM; u4Idx++) { |
| if (prQM->au4GuaranteedTcResource[u4Idx] < prQM->au4MinReservedTcResource[u4Idx]) |
| prQM->au4GuaranteedTcResource[u4Idx] = prQM->au4MinReservedTcResource[u4Idx]; |
| |
| if (u4Idx != TC4_INDEX) |
| u4TotalGurantedTcResource += prQM->au4GuaranteedTcResource[u4Idx]; |
| } |
| |
| prQM->u4ResidualTcResource = u4TotalTcResource - u4TotalGurantedTcResource; |
| |
| prQM->fgTcResourcePostAnnealing = FALSE; |
| |
| #if QM_FAST_TC_RESOURCE_CTRL |
| prQM->fgTcResourceFastReaction = FALSE; |
| #endif |
| |
| #endif |
| |
| #if QM_TEST_MODE |
| prQM->u4PktCount = 0; |
| |
| #if QM_TEST_FAIR_FORWARDING |
| |
| prQM->u4CurrentStaRecIndexToEnqueue = 0; |
| { |
| UINT_8 aucMacAddr[MAC_ADDR_LEN]; |
| P_STA_RECORD_T prStaRec; |
| |
| /* Irrelevant in case this STA is an AIS AP (see qmDetermineStaRecIndex()) */ |
| aucMacAddr[0] = 0x11; |
| aucMacAddr[1] = 0x22; |
| aucMacAddr[2] = 0xAA; |
| aucMacAddr[3] = 0xBB; |
| aucMacAddr[4] = 0xCC; |
| aucMacAddr[5] = 0xDD; |
| |
| prStaRec = &prAdapter->arStaRec[1]; |
| ASSERT(prStaRec); |
| |
| prStaRec->fgIsValid = TRUE; |
| prStaRec->fgIsQoS = TRUE; |
| prStaRec->fgIsInPS = FALSE; |
| prStaRec->ucNetTypeIndex = NETWORK_TYPE_AIS_INDEX; |
| COPY_MAC_ADDR((prStaRec)->aucMacAddr, aucMacAddr); |
| |
| } |
| |
| #endif |
| |
| #endif |
| |
| #if QM_FORWARDING_FAIRNESS |
| for (u4Idx = 0; u4Idx < NUM_OF_PER_STA_TX_QUEUES; u4Idx++) { |
| prQM->au4ResourceUsedCount[u4Idx] = 0; |
| prQM->au4HeadStaRecIndex[u4Idx] = 0; |
| } |
| |
| prQM->u4GlobalResourceUsedCount = 0; |
| #endif |
| |
| prQM->u4TxAllowedStaCount = 0; |
| |
| prQM->rLastTxPktDumpTime = (OS_SYSTIME) kalGetTimeTick(); |
| |
| } |
| |
| #if QM_TEST_MODE |
| VOID qmTestCases(IN P_ADAPTER_T prAdapter) |
| { |
| P_QUE_MGT_T prQM = &prAdapter->rQM; |
| |
| DbgPrint("QM: ** TEST MODE **\n"); |
| |
| if (QM_TEST_STA_REC_DETERMINATION) { |
| if (prAdapter->arStaRec[0].fgIsValid) { |
| prAdapter->arStaRec[0].fgIsValid = FALSE; |
| DbgPrint("QM: (Test) Deactivate STA_REC[0]\n"); |
| } else { |
| prAdapter->arStaRec[0].fgIsValid = TRUE; |
| DbgPrint("QM: (Test) Activate STA_REC[0]\n"); |
| } |
| } |
| |
| if (QM_TEST_STA_REC_DEACTIVATION) { |
| /* Note that QM_STA_REC_HARD_CODING shall be set to 1 for this test */ |
| |
| if (prAdapter->arStaRec[0].fgIsValid) { |
| |
| DbgPrint("QM: (Test) Deactivate STA_REC[0]\n"); |
| qmDeactivateStaRec(prAdapter, &prAdapter->arStaRec[0]); |
| } else { |
| |
| UINT_8 aucMacAddr[MAC_ADDR_LEN]; |
| |
| /* Irrelevant in case this STA is an AIS AP (see qmDetermineStaRecIndex()) */ |
| aucMacAddr[0] = 0x11; |
| aucMacAddr[1] = 0x22; |
| aucMacAddr[2] = 0xAA; |
| aucMacAddr[3] = 0xBB; |
| aucMacAddr[4] = 0xCC; |
| aucMacAddr[5] = 0xDD; |
| |
| DbgPrint("QM: (Test) Activate STA_REC[0]\n"); |
| qmActivateStaRec(prAdapter, /* Adapter pointer */ |
| 0, /* STA_REC index from FW */ |
| TRUE, /* fgIsQoS */ |
| NETWORK_TYPE_AIS_INDEX, /* Network type */ |
| TRUE, /* fgIsAp */ |
| aucMacAddr /* MAC address */ |
| ); |
| } |
| } |
| |
| if (QM_TEST_FAIR_FORWARDING) { |
| if (prAdapter->arStaRec[1].fgIsValid) { |
| prQM->u4CurrentStaRecIndexToEnqueue++; |
| prQM->u4CurrentStaRecIndexToEnqueue %= 2; |
| DbgPrint("QM: (Test) Switch to STA_REC[%ld]\n", prQM->u4CurrentStaRecIndexToEnqueue); |
| } |
| } |
| |
| } |
| #endif |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief Update a STA_REC |
| * |
| * \param[in] prAdapter Pointer to the Adapter instance |
| * \param[in] prStaRec The pointer of the STA_REC |
| * |
| * \return (none) |
| */ |
| /*----------------------------------------------------------------------------*/ |
| VOID qmUpdateStaRec(IN P_ADAPTER_T prAdapter, IN P_STA_RECORD_T prStaRec) |
| { |
| P_BSS_INFO_T prBssInfo; |
| BOOLEAN fgIsTxAllowed = FALSE; |
| |
| if (!prStaRec) |
| return; |
| |
| prBssInfo = GET_BSS_INFO_BY_INDEX(prAdapter, prStaRec->ucBssIndex); |
| |
| /* 4 <1> Ensure STA is valid */ |
| if (prStaRec->fgIsValid) { |
| /* 4 <2.1> STA/BSS is protected */ |
| if (secIsProtectedBss(prAdapter, prBssInfo)) { |
| if (prStaRec->fgIsTxKeyReady) |
| fgIsTxAllowed = TRUE; |
| else /* whsu test for 1x */ |
| fgIsTxAllowed = FALSE; |
| } |
| /* 4 <2.2> OPEN security */ |
| else |
| fgIsTxAllowed = TRUE; |
| } |
| /* 4 <x> Update StaRec */ |
| qmSetStaRecTxAllowed(prAdapter, prStaRec, fgIsTxAllowed); |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief Activate a STA_REC |
| * |
| * \param[in] prAdapter Pointer to the Adapter instance |
| * \param[in] prStaRec The pointer of the STA_REC |
| * |
| * \return (none) |
| */ |
| /*----------------------------------------------------------------------------*/ |
| VOID qmActivateStaRec(IN P_ADAPTER_T prAdapter, IN P_STA_RECORD_T prStaRec) |
| { |
| /* 4 <1> Deactivate first */ |
| if (!prStaRec) |
| return; |
| |
| if (prStaRec->fgIsValid) { /* The STA_REC has been activated */ |
| DBGLOG(QM, WARN, "QM: (WARNING) Activating a STA_REC which has been activated\n"); |
| DBGLOG(QM, WARN, "QM: (WARNING) Deactivating a STA_REC before re-activating\n"); |
| qmDeactivateStaRec(prAdapter, prStaRec); /* To flush TX/RX queues and del RX BA agreements */ |
| } |
| /* 4 <2> Activate the STA_REC */ |
| /* Reset buffer count */ |
| prStaRec->ucFreeQuota = 0; |
| prStaRec->ucFreeQuotaForDelivery = 0; |
| prStaRec->ucFreeQuotaForNonDelivery = 0; |
| |
| /* Init the STA_REC */ |
| prStaRec->fgIsValid = TRUE; |
| prStaRec->fgIsInPS = FALSE; |
| |
| /* Default setting of TX/RX AMPDU */ |
| prStaRec->fgTxAmpduEn = IS_FEATURE_ENABLED(prAdapter->rWifiVar.ucAmpduTx); |
| prStaRec->fgRxAmpduEn = IS_FEATURE_ENABLED(prAdapter->rWifiVar.ucAmpduRx); |
| |
| nicTxGenerateDescTemplate(prAdapter, prStaRec); |
| |
| qmUpdateStaRec(prAdapter, prStaRec); |
| |
| /* Done in qmInit() or qmDeactivateStaRec() */ |
| #if 0 |
| /* At the beginning, no RX BA agreements have been established */ |
| for (i = 0; i < CFG_RX_MAX_BA_TID_NUM; i++) |
| (prStaRec->aprRxReorderParamRefTbl)[i] = NULL; |
| #endif |
| |
| DBGLOG(QM, INFO, "QM: +STA[%ld]\n", (UINT_32) prStaRec->ucIndex); |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief Deactivate a STA_REC |
| * |
| * \param[in] prAdapter Pointer to the Adapter instance |
| * \param[in] u4StaRecIdx The index of the STA_REC |
| * |
| * \return (none) |
| */ |
| /*----------------------------------------------------------------------------*/ |
| VOID qmDeactivateStaRec(IN P_ADAPTER_T prAdapter, IN P_STA_RECORD_T prStaRec) |
| { |
| UINT_32 i; |
| |
| if (!prStaRec) |
| return; |
| /* 4 <1> Flush TX queues */ |
| if (HAL_IS_TX_DIRECT(prAdapter)) { |
| nicTxDirectClearStaPsQ(prAdapter, prStaRec->ucIndex); |
| } else { |
| P_MSDU_INFO_T prFlushedTxPacketList = NULL; |
| |
| prFlushedTxPacketList = qmFlushStaTxQueues(prAdapter, prStaRec->ucIndex); |
| |
| if (prFlushedTxPacketList) |
| wlanProcessQueuedMsduInfo(prAdapter, prFlushedTxPacketList); |
| } |
| |
| /* 4 <2> Flush RX queues and delete RX BA agreements */ |
| for (i = 0; i < CFG_RX_MAX_BA_TID_NUM; i++) { |
| /* Delete the RX BA entry with TID = i */ |
| qmDelRxBaEntry(prAdapter, prStaRec->ucIndex, (UINT_8) i, FALSE); |
| } |
| |
| /* 4 <3> Deactivate the STA_REC */ |
| prStaRec->fgIsValid = FALSE; |
| prStaRec->fgIsInPS = FALSE; |
| prStaRec->fgIsTxKeyReady = FALSE; |
| |
| /* Reset buffer count */ |
| prStaRec->ucFreeQuota = 0; |
| prStaRec->ucFreeQuotaForDelivery = 0; |
| prStaRec->ucFreeQuotaForNonDelivery = 0; |
| |
| nicTxFreeDescTemplate(prAdapter, prStaRec); |
| |
| qmUpdateStaRec(prAdapter, prStaRec); |
| |
| DBGLOG(QM, INFO, "QM: -STA[%u]\n", prStaRec->ucIndex); |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief Deactivate a STA_REC |
| * |
| * \param[in] prAdapter Pointer to the Adapter instance |
| * \param[in] ucBssIndex The index of the BSS |
| * |
| * \return (none) |
| */ |
| /*----------------------------------------------------------------------------*/ |
| VOID qmFreeAllByBssIdx(IN P_ADAPTER_T prAdapter, IN UINT_8 ucBssIndex) |
| { |
| |
| P_QUE_MGT_T prQM; |
| P_QUE_T prQue; |
| QUE_T rNeedToFreeQue; |
| QUE_T rTempQue; |
| P_QUE_T prNeedToFreeQue; |
| P_QUE_T prTempQue; |
| P_MSDU_INFO_T prMsduInfo; |
| |
| prQM = &prAdapter->rQM; |
| prQue = &prQM->arTxQueue[TX_QUEUE_INDEX_BMCAST]; |
| |
| QUEUE_INITIALIZE(&rNeedToFreeQue); |
| QUEUE_INITIALIZE(&rTempQue); |
| |
| prNeedToFreeQue = &rNeedToFreeQue; |
| prTempQue = &rTempQue; |
| |
| QUEUE_MOVE_ALL(prTempQue, prQue); |
| |
| QUEUE_REMOVE_HEAD(prTempQue, prMsduInfo, P_MSDU_INFO_T); |
| while (prMsduInfo) { |
| |
| if (prMsduInfo->ucBssIndex == ucBssIndex) { |
| /* QUEUE_INSERT_TAIL */ |
| QUEUE_INSERT_TAIL(prNeedToFreeQue, (P_QUE_ENTRY_T) prMsduInfo); |
| } else { |
| /* QUEUE_INSERT_TAIL */ |
| QUEUE_INSERT_TAIL(prQue, (P_QUE_ENTRY_T) prMsduInfo); |
| } |
| |
| QUEUE_REMOVE_HEAD(prTempQue, prMsduInfo, P_MSDU_INFO_T); |
| } |
| if (QUEUE_IS_NOT_EMPTY(prNeedToFreeQue)) |
| wlanProcessQueuedMsduInfo(prAdapter, (P_MSDU_INFO_T) QUEUE_GET_HEAD(prNeedToFreeQue)); |
| |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief Flush all TX queues |
| * |
| * \param[in] (none) |
| * |
| * \return The flushed packets (in a list of MSDU_INFOs) |
| */ |
| /*----------------------------------------------------------------------------*/ |
| P_MSDU_INFO_T qmFlushTxQueues(IN P_ADAPTER_T prAdapter) |
| { |
| UINT_8 ucStaArrayIdx; |
| UINT_8 ucQueArrayIdx; |
| |
| P_QUE_MGT_T prQM = &prAdapter->rQM; |
| |
| QUE_T rTempQue; |
| P_QUE_T prTempQue = &rTempQue; |
| P_QUE_T prQue; |
| |
| DBGLOG(QM, TRACE, "QM: Enter qmFlushTxQueues()\n"); |
| |
| QUEUE_INITIALIZE(prTempQue); |
| |
| /* Concatenate all MSDU_INFOs in per-STA queues */ |
| for (ucStaArrayIdx = 0; ucStaArrayIdx < CFG_STA_REC_NUM; ucStaArrayIdx++) { |
| for (ucQueArrayIdx = 0; ucQueArrayIdx < NUM_OF_PER_STA_TX_QUEUES; ucQueArrayIdx++) { |
| prQue = &(prAdapter->arStaRec[ucStaArrayIdx].arPendingTxQueue[ucQueArrayIdx]); |
| QUEUE_CONCATENATE_QUEUES(prTempQue, prQue); |
| prQue = &(prAdapter->arStaRec[ucStaArrayIdx].arTxQueue[ucQueArrayIdx]); |
| QUEUE_CONCATENATE_QUEUES(prTempQue, prQue); |
| } |
| } |
| |
| /* Flush per-Type queues */ |
| for (ucQueArrayIdx = 0; ucQueArrayIdx < NUM_OF_PER_TYPE_TX_QUEUES; ucQueArrayIdx++) { |
| prQue = &(prQM->arTxQueue[ucQueArrayIdx]); |
| QUEUE_CONCATENATE_QUEUES(prTempQue, prQue); |
| } |
| |
| return (P_MSDU_INFO_T)QUEUE_GET_HEAD(prTempQue); |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief Flush TX packets for a particular STA |
| * |
| * \param[in] u4StaRecIdx STA_REC index |
| * |
| * \return The flushed packets (in a list of MSDU_INFOs) |
| */ |
| /*----------------------------------------------------------------------------*/ |
| P_MSDU_INFO_T qmFlushStaTxQueues(IN P_ADAPTER_T prAdapter, IN UINT_32 u4StaRecIdx) |
| { |
| UINT_8 ucQueArrayIdx; |
| P_STA_RECORD_T prStaRec; |
| P_QUE_T prQue; |
| QUE_T rTempQue; |
| P_QUE_T prTempQue = &rTempQue; |
| |
| DBGLOG(QM, TRACE, "QM: Enter qmFlushStaTxQueues(%ld)\n", u4StaRecIdx); |
| |
| ASSERT(u4StaRecIdx < CFG_STA_REC_NUM); |
| |
| prStaRec = &prAdapter->arStaRec[u4StaRecIdx]; |
| ASSERT(prStaRec); |
| |
| QUEUE_INITIALIZE(prTempQue); |
| |
| /* Concatenate all MSDU_INFOs in TX queues of this STA_REC */ |
| for (ucQueArrayIdx = 0; ucQueArrayIdx < NUM_OF_PER_STA_TX_QUEUES; ucQueArrayIdx++) { |
| prQue = &(prStaRec->arPendingTxQueue[ucQueArrayIdx]); |
| QUEUE_CONCATENATE_QUEUES(prTempQue, prQue); |
| prQue = &(prStaRec->arTxQueue[ucQueArrayIdx]); |
| QUEUE_CONCATENATE_QUEUES(prTempQue, prQue); |
| } |
| |
| return (P_MSDU_INFO_T)QUEUE_GET_HEAD(prTempQue); |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief Flush RX packets |
| * |
| * \param[in] (none) |
| * |
| * \return The flushed packets (in a list of SW_RFBs) |
| */ |
| /*----------------------------------------------------------------------------*/ |
| P_SW_RFB_T qmFlushRxQueues(IN P_ADAPTER_T prAdapter) |
| { |
| UINT_32 i; |
| P_SW_RFB_T prSwRfbListHead; |
| P_SW_RFB_T prSwRfbListTail; |
| P_QUE_MGT_T prQM = &prAdapter->rQM; |
| |
| prSwRfbListHead = prSwRfbListTail = NULL; |
| |
| DBGLOG(QM, TRACE, "QM: Enter qmFlushRxQueues()\n"); |
| |
| RX_DIRECT_REORDER_LOCK(prAdapter, 0); |
| for (i = 0; i < CFG_NUM_OF_RX_BA_AGREEMENTS; i++) { |
| if (QUEUE_IS_NOT_EMPTY(&(prQM->arRxBaTable[i].rReOrderQue))) { |
| if (!prSwRfbListHead) { |
| |
| /* The first MSDU_INFO is found */ |
| prSwRfbListHead = (P_SW_RFB_T) |
| QUEUE_GET_HEAD(&(prQM->arRxBaTable[i].rReOrderQue)); |
| prSwRfbListTail = (P_SW_RFB_T) |
| QUEUE_GET_TAIL(&(prQM->arRxBaTable[i].rReOrderQue)); |
| } else { |
| /* Concatenate the MSDU_INFO list with the existing list */ |
| QM_TX_SET_NEXT_MSDU_INFO(prSwRfbListTail, |
| QUEUE_GET_HEAD(&(prQM->arRxBaTable[i].rReOrderQue))); |
| |
| prSwRfbListTail = (P_SW_RFB_T) |
| QUEUE_GET_TAIL(&(prQM->arRxBaTable[i].rReOrderQue)); |
| } |
| |
| QUEUE_INITIALIZE(&(prQM->arRxBaTable[i].rReOrderQue)); |
| if (QM_RX_GET_NEXT_SW_RFB(prSwRfbListTail)) { |
| DBGLOG(QM, ERROR, |
| "QM: non-null tail->next at arRxBaTable[%u]\n", |
| i); |
| } |
| } else { |
| continue; |
| } |
| } |
| RX_DIRECT_REORDER_UNLOCK(prAdapter, 0); |
| |
| if (prSwRfbListTail) { |
| /* Terminate the MSDU_INFO list with a NULL pointer */ |
| QM_TX_SET_NEXT_SW_RFB(prSwRfbListTail, NULL); |
| } |
| return prSwRfbListHead; |
| |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief Flush RX packets with respect to a particular STA |
| * |
| * \param[in] u4StaRecIdx STA_REC index |
| * \param[in] u4Tid TID |
| * |
| * \return The flushed packets (in a list of SW_RFBs) |
| */ |
| /*----------------------------------------------------------------------------*/ |
| P_SW_RFB_T qmFlushStaRxQueue(IN P_ADAPTER_T prAdapter, IN UINT_32 u4StaRecIdx, IN UINT_32 u4Tid) |
| { |
| /* UINT_32 i; */ |
| P_SW_RFB_T prSwRfbListHead; |
| P_SW_RFB_T prSwRfbListTail; |
| P_RX_BA_ENTRY_T prReorderQueParm; |
| P_STA_RECORD_T prStaRec; |
| |
| DBGLOG(QM, TRACE, "QM: Enter qmFlushStaRxQueues(%ld)\n", u4StaRecIdx); |
| |
| prSwRfbListHead = prSwRfbListTail = NULL; |
| |
| prStaRec = &prAdapter->arStaRec[u4StaRecIdx]; |
| ASSERT(prStaRec); |
| |
| /* No matter whether this is an activated STA_REC, do flush */ |
| #if 0 |
| if (!prStaRec->fgIsValid) |
| return NULL; |
| #endif |
| |
| /* Obtain the RX BA Entry pointer */ |
| prReorderQueParm = ((prStaRec->aprRxReorderParamRefTbl)[u4Tid]); |
| |
| /* Note: For each queued packet, prCurrSwRfb->eDst equals RX_PKT_DESTINATION_HOST */ |
| if (prReorderQueParm) { |
| RX_DIRECT_REORDER_LOCK(prAdapter, 0); |
| if (QUEUE_IS_NOT_EMPTY(&(prReorderQueParm->rReOrderQue))) { |
| |
| prSwRfbListHead = (P_SW_RFB_T) |
| QUEUE_GET_HEAD(&(prReorderQueParm->rReOrderQue)); |
| prSwRfbListTail = (P_SW_RFB_T) |
| QUEUE_GET_TAIL(&(prReorderQueParm->rReOrderQue)); |
| |
| QUEUE_INITIALIZE(&(prReorderQueParm->rReOrderQue)); |
| } |
| RX_DIRECT_REORDER_UNLOCK(prAdapter, 0); |
| } |
| |
| if (prSwRfbListTail) { |
| if (QM_RX_GET_NEXT_SW_RFB(prSwRfbListTail)) { |
| DBGLOG(QM, ERROR, |
| "QM: non-empty tail->next at STA %u TID %u\n", |
| u4StaRecIdx, u4Tid); |
| } |
| |
| /* Terminate the MSDU_INFO list with a NULL pointer */ |
| QM_TX_SET_NEXT_SW_RFB(prSwRfbListTail, NULL); |
| } |
| return prSwRfbListHead; |
| |
| } |
| |
| P_QUE_T qmDetermineStaTxQueue(IN P_ADAPTER_T prAdapter, IN P_MSDU_INFO_T prMsduInfo, OUT PUINT_8 pucTC) |
| { |
| P_QUE_T prTxQue = NULL; |
| P_STA_RECORD_T prStaRec; |
| ENUM_WMM_ACI_T eAci = WMM_AC_BE_INDEX; |
| BOOLEAN fgCheckACMAgain; |
| UINT_8 ucTC, ucQueIdx = WMM_AC_BE_INDEX; |
| P_BSS_INFO_T prBssInfo; |
| UINT_8 aucNextUP[WMM_AC_INDEX_NUM] = { 1 /* BEtoBK */, |
| 1 /* na */, |
| 0 /* VItoBE */, |
| 4 /* VOtoVI */ |
| }; |
| |
| prBssInfo = GET_BSS_INFO_BY_INDEX(prAdapter, prMsduInfo->ucBssIndex); |
| prStaRec = QM_GET_STA_REC_PTR_FROM_INDEX(prAdapter, prMsduInfo->ucStaRecIndex); |
| |
| if (!prStaRec) { |
| DBGLOG(QM, ERROR, "prStaRec is null.\n"); |
| return NULL; |
| } |
| if (prMsduInfo->ucUserPriority < 8) { |
| QM_DBG_CNT_INC(&prAdapter->rQM, prMsduInfo->ucUserPriority + 15); |
| /* QM_DBG_CNT_15 *//* QM_DBG_CNT_16 *//* QM_DBG_CNT_17 *//* QM_DBG_CNT_18 */ |
| /* QM_DBG_CNT_19 *//* QM_DBG_CNT_20 *//* QM_DBG_CNT_21 *//* QM_DBG_CNT_22 */ |
| } |
| |
| eAci = WMM_AC_BE_INDEX; |
| do { |
| fgCheckACMAgain = FALSE; |
| if (prStaRec->fgIsQoS) { |
| if (prMsduInfo->ucUserPriority < TX_DESC_TID_NUM) { |
| eAci = aucTid2ACI[prMsduInfo->ucUserPriority]; |
| ucQueIdx = aucACI2TxQIdx[eAci]; |
| ucTC = arNetwork2TcResource[prMsduInfo->ucBssIndex][eAci]; |
| } else { |
| ucQueIdx = TX_QUEUE_INDEX_AC1; |
| ucTC = TC1_INDEX; |
| eAci = WMM_AC_BE_INDEX; |
| DBGLOG(QM, WARN, "Packet TID is not in [0~7]\n"); |
| ASSERT(0); |
| } |
| if ((prBssInfo->arACQueParms[eAci].ucIsACMSet) && (eAci != WMM_AC_BK_INDEX)) { |
| prMsduInfo->ucUserPriority = aucNextUP[eAci]; |
| fgCheckACMAgain = TRUE; |
| } |
| } else { |
| ucQueIdx = TX_QUEUE_INDEX_NON_QOS; |
| ucTC = arNetwork2TcResource[prMsduInfo->ucBssIndex][NET_TC_WMM_AC_BE_INDEX]; |
| } |
| |
| if (prAdapter->rWifiVar.ucTcRestrict < TC_NUM) { |
| ucTC = prAdapter->rWifiVar.ucTcRestrict; |
| ucQueIdx = ucTC; |
| } |
| |
| } while (fgCheckACMAgain); |
| |
| if (ucQueIdx >= NUM_OF_PER_STA_TX_QUEUES) { |
| DBGLOG(QM, ERROR, |
| "ucQueIdx = %u, needs 0~3 to avoid out-of-bounds.\n", ucQueIdx); |
| return NULL; |
| } |
| if (prStaRec->fgIsTxAllowed) { |
| /* non protected BSS or protected BSS with key set */ |
| prTxQue = prStaRec->aprTargetQueue[ucQueIdx]; |
| } else if (secIsProtectedBss(prAdapter, prBssInfo) && prMsduInfo->fgIs802_1x |
| && prMsduInfo->fgIs802_1x_NonProtected) { |
| /* protected BSS without key set */ |
| /* Tx pairwise EAPOL 1x packet (non-protected frame) */ |
| prTxQue = &prStaRec->arTxQueue[ucQueIdx]; |
| } else { |
| /* protected BSS without key set */ |
| /* Enqueue protected frame into pending queue */ |
| prTxQue = prStaRec->aprTargetQueue[ucQueIdx]; |
| } |
| |
| *pucTC = ucTC; |
| |
| return prTxQue; |
| } |
| |
| VOID qmSetTxPacketDescTemplate(IN P_ADAPTER_T prAdapter, IN P_MSDU_INFO_T prMsduInfo) |
| { |
| P_STA_RECORD_T prStaRec = QM_GET_STA_REC_PTR_FROM_INDEX(prAdapter, prMsduInfo->ucStaRecIndex); |
| |
| /* Check the Tx descriptor template is valid */ |
| if (prStaRec && prStaRec->aprTxDescTemplate[prMsduInfo->ucUserPriority]) { |
| prMsduInfo->fgIsTXDTemplateValid = TRUE; |
| } else { |
| if (prStaRec) { |
| DBGLOG(QM, TRACE, |
| "Cannot get TXD template for STA[%u] QoS[%u] MSDU UP[%u]\n", |
| prStaRec->ucIndex, prStaRec->fgIsQoS, prMsduInfo->ucUserPriority); |
| } |
| prMsduInfo->fgIsTXDTemplateValid = FALSE; |
| } |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief : To StaRec, function to stop TX |
| * |
| * \param[in] : |
| * |
| * \return none |
| */ |
| /*----------------------------------------------------------------------------*/ |
| VOID qmSetStaRecTxAllowed(IN P_ADAPTER_T prAdapter, IN P_STA_RECORD_T prStaRec, IN BOOLEAN fgIsTxAllowed) |
| { |
| UINT_8 ucIdx; |
| P_QUE_T prSrcQ, prDstQ; |
| |
| /* Update Tx queue */ |
| for (ucIdx = 0; ucIdx < NUM_OF_PER_STA_TX_QUEUES; ucIdx++) { |
| if (fgIsTxAllowed) { |
| prSrcQ = &prStaRec->arPendingTxQueue[ucIdx]; |
| prDstQ = &prStaRec->arTxQueue[ucIdx]; |
| } else { |
| prSrcQ = &prStaRec->arTxQueue[ucIdx]; |
| prDstQ = &prStaRec->arPendingTxQueue[ucIdx]; |
| } |
| |
| QUEUE_CONCATENATE_QUEUES_HEAD(prDstQ, prSrcQ); |
| prStaRec->aprTargetQueue[ucIdx] = prDstQ; |
| } |
| |
| if (prStaRec->fgIsTxAllowed != fgIsTxAllowed) { |
| if (fgIsTxAllowed) |
| prAdapter->rQM.u4TxAllowedStaCount++; |
| else |
| prAdapter->rQM.u4TxAllowedStaCount--; |
| } |
| prStaRec->fgIsTxAllowed = fgIsTxAllowed; |
| |
| DBGLOG(QM, INFO, "Set Sta[%u] TxAllowed[%u] %s TxQ\n", prStaRec->ucIndex, fgIsTxAllowed, |
| fgIsTxAllowed ? "normal":"pending"); |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief Enqueue TX packets |
| * |
| * \param[in] prMsduInfoListHead Pointer to the list of TX packets |
| * |
| * \return The freed packets, which are not enqueued |
| */ |
| /*----------------------------------------------------------------------------*/ |
| P_MSDU_INFO_T qmEnqueueTxPackets(IN P_ADAPTER_T prAdapter, IN P_MSDU_INFO_T prMsduInfoListHead) |
| { |
| P_MSDU_INFO_T prMsduInfoReleaseList; |
| P_MSDU_INFO_T prCurrentMsduInfo; |
| P_MSDU_INFO_T prNextMsduInfo; |
| |
| P_QUE_T prTxQue; |
| QUE_T rNotEnqueuedQue; |
| |
| UINT_8 ucTC; |
| P_QUE_MGT_T prQM = &prAdapter->rQM; |
| P_BSS_INFO_T prBssInfo; |
| BOOLEAN fgDropPacket; |
| |
| DBGLOG(QM, LOUD, "Enter qmEnqueueTxPackets\n"); |
| |
| ASSERT(prMsduInfoListHead); |
| |
| prMsduInfoReleaseList = NULL; |
| prCurrentMsduInfo = NULL; |
| QUEUE_INITIALIZE(&rNotEnqueuedQue); |
| prNextMsduInfo = prMsduInfoListHead; |
| |
| do { |
| prCurrentMsduInfo = prNextMsduInfo; |
| prNextMsduInfo = QM_TX_GET_NEXT_MSDU_INFO(prCurrentMsduInfo); |
| ucTC = TC1_INDEX; |
| |
| /* 4 <0> Sanity check of BSS_INFO */ |
| prBssInfo = GET_BSS_INFO_BY_INDEX(prAdapter, prCurrentMsduInfo->ucBssIndex); |
| |
| if (!prBssInfo) { |
| /* No BSS_INFO */ |
| fgDropPacket = TRUE; |
| } else if (IS_BSS_ACTIVE(prBssInfo)) { |
| /* BSS active */ |
| fgDropPacket = FALSE; |
| } else { |
| /* BSS inactive */ |
| fgDropPacket = TRUE; |
| } |
| |
| if (!fgDropPacket) { |
| /* 4 <1> Lookup the STA_REC index */ |
| /* The ucStaRecIndex will be set in this function */ |
| qmDetermineStaRecIndex(prAdapter, prCurrentMsduInfo); |
| |
| wlanUpdateTxStatistics(prAdapter, prCurrentMsduInfo, FALSE); /*get per-AC Tx packets */ |
| |
| DBGLOG(QM, LOUD, "Enqueue MSDU by StaRec[%u]!\n", prCurrentMsduInfo->ucStaRecIndex); |
| |
| switch (prCurrentMsduInfo->ucStaRecIndex) { |
| case STA_REC_INDEX_BMCAST: |
| prTxQue = &prQM->arTxQueue[TX_QUEUE_INDEX_BMCAST]; |
| ucTC = arNetwork2TcResource[prCurrentMsduInfo->ucBssIndex][NET_TC_BMC_INDEX]; |
| |
| /* Always set BMC packet retry limit to unlimited */ |
| if (!(prCurrentMsduInfo->u4Option & MSDU_OPT_MANUAL_RETRY_LIMIT)) |
| nicTxSetPktRetryLimit(prCurrentMsduInfo, TX_DESC_TX_COUNT_NO_LIMIT); |
| |
| QM_DBG_CNT_INC(prQM, QM_DBG_CNT_23); |
| break; |
| |
| case STA_REC_INDEX_NOT_FOUND: |
| /* Drop packet if no STA_REC is found */ |
| DBGLOG(QM, TRACE, "Drop the Packet for no STA_REC\n"); |
| |
| prTxQue = &rNotEnqueuedQue; |
| |
| TX_INC_CNT(&prAdapter->rTxCtrl, TX_INACTIVE_STA_DROP); |
| QM_DBG_CNT_INC(prQM, QM_DBG_CNT_24); |
| break; |
| |
| default: |
| prTxQue = qmDetermineStaTxQueue(prAdapter, prCurrentMsduInfo, &ucTC); |
| break; /*default */ |
| } /* switch (prCurrentMsduInfo->ucStaRecIndex) */ |
| |
| if (prCurrentMsduInfo->eSrc == TX_PACKET_FORWARDING) { |
| DBGLOG(QM, TRACE, "Forward Pkt to STA[%u] BSS[%u]\n", |
| prCurrentMsduInfo->ucStaRecIndex, prCurrentMsduInfo->ucBssIndex); |
| |
| if (prTxQue->u4NumElem >= prQM->u4MaxForwardBufferCount) { |
| DBGLOG(QM, INFO, |
| "Drop the Packet for full Tx queue (forwarding) Bss %u\n", |
| prCurrentMsduInfo->ucBssIndex); |
| prTxQue = &rNotEnqueuedQue; |
| TX_INC_CNT(&prAdapter->rTxCtrl, TX_FORWARD_OVERFLOW_DROP); |
| } |
| } |
| |
| } else { |
| DBGLOG(QM, TRACE, "Drop the Packet for inactive Bss %u\n", prCurrentMsduInfo->ucBssIndex); |
| QM_DBG_CNT_INC(prQM, QM_DBG_CNT_31); |
| prTxQue = &rNotEnqueuedQue; |
| TX_INC_CNT(&prAdapter->rTxCtrl, TX_INACTIVE_BSS_DROP); |
| } |
| |
| /* 4 <3> Fill the MSDU_INFO for constructing HIF TX header */ |
| /* Note that the BSS Index and STA_REC index are determined in |
| * qmDetermineStaRecIndex(prCurrentMsduInfo). |
| */ |
| prCurrentMsduInfo->ucTC = ucTC; |
| |
| /* Check the Tx descriptor template is valid */ |
| qmSetTxPacketDescTemplate(prAdapter, prCurrentMsduInfo); |
| |
| /* Set Tx rate */ |
| switch (prAdapter->rWifiVar.ucDataTxRateMode) { |
| case DATA_RATE_MODE_BSS_LOWEST: |
| nicTxSetPktLowestFixedRate(prAdapter, prCurrentMsduInfo); |
| break; |
| |
| case DATA_RATE_MODE_MANUAL: |
| prCurrentMsduInfo->u4FixedRateOption = prAdapter->rWifiVar.u4DataTxRateCode; |
| |
| prCurrentMsduInfo->ucRateMode = MSDU_RATE_MODE_MANUAL_DESC; |
| break; |
| |
| case DATA_RATE_MODE_AUTO: |
| default: |
| if (prCurrentMsduInfo->ucRateMode == MSDU_RATE_MODE_LOWEST_RATE) |
| nicTxSetPktLowestFixedRate(prAdapter, prCurrentMsduInfo); |
| break; |
| } |
| |
| /* 4 <4> Enqueue the packet */ |
| QUEUE_INSERT_TAIL(prTxQue, (P_QUE_ENTRY_T) prCurrentMsduInfo); |
| |
| #if QM_FAST_TC_RESOURCE_CTRL && QM_ADAPTIVE_TC_RESOURCE_CTRL |
| if (prTxQue != &rNotEnqueuedQue) { |
| /* Check and trigger fast TC resource adjustment for queued packets */ |
| qmCheckForFastTcResourceCtrl(prAdapter, ucTC); |
| } |
| #endif |
| |
| #if QM_TEST_MODE |
| if (++prQM->u4PktCount == QM_TEST_TRIGGER_TX_COUNT) { |
| prQM->u4PktCount = 0; |
| qmTestCases(prAdapter); |
| } |
| #endif |
| |
| DBGLOG(QM, LOUD, "Current queue length = %u\n", prTxQue->u4NumElem); |
| } while (prNextMsduInfo); |
| |
| if (QUEUE_IS_NOT_EMPTY(&rNotEnqueuedQue)) { |
| QM_TX_SET_NEXT_MSDU_INFO((P_MSDU_INFO_T) QUEUE_GET_TAIL(&rNotEnqueuedQue), NULL); |
| prMsduInfoReleaseList = (P_MSDU_INFO_T) QUEUE_GET_HEAD(&rNotEnqueuedQue); |
| } |
| #if QM_ADAPTIVE_TC_RESOURCE_CTRL |
| /* 4 <x> Update TC resource control related variables */ |
| /* Keep track of the queue length */ |
| qmDoAdaptiveTcResourceCtrl(prAdapter); |
| #endif |
| |
| return prMsduInfoReleaseList; |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief Determine the STA_REC index for a packet |
| * |
| * \param[in] prMsduInfo Pointer to the packet |
| * |
| * \return (none) |
| */ |
| /*----------------------------------------------------------------------------*/ |
| VOID qmDetermineStaRecIndex(IN P_ADAPTER_T prAdapter, IN P_MSDU_INFO_T prMsduInfo) |
| { |
| UINT_32 i; |
| |
| P_STA_RECORD_T prTempStaRec; |
| P_BSS_INFO_T prBssInfo; |
| |
| prBssInfo = GET_BSS_INFO_BY_INDEX(prAdapter, prMsduInfo->ucBssIndex); |
| prTempStaRec = NULL; |
| |
| ASSERT(prMsduInfo); |
| |
| DBGLOG(QM, LOUD, "Msdu BSS Idx[%u] OpMode[%u] StaRecOfApExist[%u]\n", |
| prMsduInfo->ucBssIndex, prBssInfo->eCurrentOPMode, prBssInfo->prStaRecOfAP ? TRUE : FALSE); |
| |
| switch (prBssInfo->eCurrentOPMode) { |
| case OP_MODE_IBSS: |
| case OP_MODE_ACCESS_POINT: |
| /* 4 <1> DA = BMCAST */ |
| if (IS_BMCAST_MAC_ADDR(prMsduInfo->aucEthDestAddr)) { |
| prMsduInfo->ucStaRecIndex = STA_REC_INDEX_BMCAST; |
| DBGLOG(QM, LOUD, "TX with DA = BMCAST\n"); |
| return; |
| } |
| break; |
| |
| /* Infra Client/GC */ |
| case OP_MODE_INFRASTRUCTURE: |
| case OP_MODE_BOW: |
| if (prBssInfo->prStaRecOfAP) { |
| #if CFG_SUPPORT_TDLS |
| |
| prTempStaRec = |
| cnmGetTdlsPeerByAddress(prAdapter, prBssInfo->ucBssIndex, prMsduInfo->aucEthDestAddr); |
| if (IS_DLS_STA(prTempStaRec) && prTempStaRec->ucStaState == STA_STATE_3) { |
| if (g_arTdlsLink[prTempStaRec->ucTdlsIndex]) { |
| prMsduInfo->ucStaRecIndex = prTempStaRec->ucIndex; |
| return; |
| } |
| } |
| #endif |
| /* 4 <2> Check if an AP STA is present */ |
| prTempStaRec = prBssInfo->prStaRecOfAP; |
| |
| DBGLOG(QM, LOUD, |
| "StaOfAp Idx[%u] WIDX[%u] Valid[%u] TxAllowed[%u] InUse[%u] Type[%u]\n", |
| prTempStaRec->ucIndex, prTempStaRec->ucWlanIndex, |
| prTempStaRec->fgIsValid, prTempStaRec->fgIsTxAllowed, |
| prTempStaRec->fgIsInUse, prTempStaRec->eStaType); |
| |
| if (prTempStaRec->fgIsInUse) { |
| prMsduInfo->ucStaRecIndex = prTempStaRec->ucIndex; |
| DBGLOG(QM, LOUD, "TX with AP_STA[%u]\n", prTempStaRec->ucIndex); |
| return; |
| } |
| } |
| break; |
| |
| case OP_MODE_P2P_DEVICE: |
| break; |
| |
| default: |
| break; |
| } |
| |
| /* 4 <3> Not BMCAST, No AP --> Compare DA (i.e., to see whether this is a unicast frame to a client) */ |
| for (i = 0; i < CFG_STA_REC_NUM; i++) { |
| prTempStaRec = &(prAdapter->arStaRec[i]); |
| if (prTempStaRec->fgIsInUse) { |
| if (EQUAL_MAC_ADDR(prTempStaRec->aucMacAddr, prMsduInfo->aucEthDestAddr)) { |
| prMsduInfo->ucStaRecIndex = prTempStaRec->ucIndex; |
| DBGLOG(QM, LOUD, "TX with STA[%u]\n", prTempStaRec->ucIndex); |
| return; |
| } |
| } |
| } |
| |
| /* 4 <4> No STA found, Not BMCAST --> Indicate NOT_FOUND to FW */ |
| prMsduInfo->ucStaRecIndex = STA_REC_INDEX_NOT_FOUND; |
| DBGLOG(QM, LOUD, "QM: TX with STA_REC_INDEX_NOT_FOUND\n"); |
| |
| #if (QM_TEST_MODE && QM_TEST_FAIR_FORWARDING) |
| prMsduInfo->ucStaRecIndex = (UINT_8) prQM->u4CurrentStaRecIndexToEnqueue; |
| #endif |
| } |
| |
| P_STA_RECORD_T qmDetermineStaToBeDequeued(IN P_ADAPTER_T prAdapter, IN UINT_32 u4StartStaRecIndex) |
| { |
| |
| return NULL; |
| } |
| |
| P_QUE_T qmDequeueStaTxPackets(IN P_ADAPTER_T prAdapter) |
| { |
| |
| return NULL; |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief Dequeue TX packets from a STA_REC for a particular TC |
| * |
| * \param[out] prQue The queue to put the dequeued packets |
| * \param[in] ucTC The TC index (TC0_INDEX to TC5_INDEX) |
| * \param[in] ucMaxNum The maximum amount of dequeued packets |
| * |
| * \return (none) |
| */ |
| /*----------------------------------------------------------------------------*/ |
| UINT_32 |
| qmDequeueTxPacketsFromPerStaQueues(IN P_ADAPTER_T prAdapter, OUT P_QUE_T prQue, |
| IN UINT_8 ucTC, IN UINT_32 u4CurrentQuota, IN UINT_32 u4TotalQuota) |
| { |
| UINT_32 ucLoop; /* Loop for */ |
| |
| UINT_32 u4CurStaIndex = 0; |
| UINT_32 u4CurStaUsedResource = 0; |
| |
| P_STA_RECORD_T prStaRec; /* The current focused STA */ |
| P_BSS_INFO_T prBssInfo; /* The Bss for current focused STA */ |
| P_QUE_T prCurrQueue; /* The current TX queue to dequeue */ |
| P_MSDU_INFO_T prDequeuedPkt; /* The dequeued packet */ |
| |
| UINT_32 u4CurStaForwardFrameCount; /* To remember the total forwarded packets for a STA */ |
| UINT_32 u4MaxForwardFrameCountLimit; /* The maximum number of packets a STA can forward */ |
| UINT_32 u4AvaliableResource; /* The TX resource amount */ |
| UINT_32 u4MaxResourceLimit; |
| |
| BOOLEAN fgEndThisRound; |
| P_QUE_MGT_T prQM = &prAdapter->rQM; |
| |
| PUINT_8 pucPsStaFreeQuota; |
| |
| /* Sanity Check */ |
| if (!u4CurrentQuota) { |
| DBGLOG(TX, LOUD, "(Fairness) Skip TC = %u u4CurrentQuota = %u\n", ucTC, u4CurrentQuota); |
| return u4CurrentQuota; |
| } |
| /* 4 <1> Assign init value */ |
| u4AvaliableResource = u4CurrentQuota; |
| u4MaxResourceLimit = u4TotalQuota; |
| |
| #if QM_FORWARDING_FAIRNESS |
| u4CurStaIndex = prQM->au4HeadStaRecIndex[ucTC]; |
| u4CurStaUsedResource = prQM->au4ResourceUsedCount[ucTC]; |
| #endif |
| |
| fgEndThisRound = FALSE; |
| ucLoop = 0; |
| u4CurStaForwardFrameCount = 0; |
| |
| DBGLOG(QM, LOUD, "(Fairness) TC[%u] Init Head STA[%u] Resource[%u]\n", |
| ucTC, u4CurStaIndex, u4AvaliableResource); |
| |
| /* 4 <2> Traverse STA array from Head STA */ |
| /* From STA[x] to STA[x+1] to STA[x+2] to ... to STA[x] */ |
| while (ucLoop < CFG_STA_REC_NUM) { |
| prStaRec = &prAdapter->arStaRec[u4CurStaIndex]; |
| prCurrQueue = &prStaRec->arTxQueue[ucTC]; |
| |
| /* 4 <2.1> Find a Tx allowed STA */ |
| /* Only Data frame will be queued in */ |
| /* if (prStaRec->fgIsTxAllowed) { */ |
| if (QUEUE_IS_NOT_EMPTY(prCurrQueue)) { |
| prBssInfo = GET_BSS_INFO_BY_INDEX(prAdapter, prStaRec->ucBssIndex); |
| |
| /* prCurrQueue = &prStaRec->aprTxQueue[ucTC]; */ |
| prDequeuedPkt = NULL; |
| pucPsStaFreeQuota = NULL; |
| /* Set default forward count limit to unlimited */ |
| u4MaxForwardFrameCountLimit = QM_STA_FORWARD_COUNT_UNLIMITED; |
| |
| /* 4 <2.2> Update forward frame/page count limit for this STA */ |
| /* AP mode: STA in PS buffer handling */ |
| if (prStaRec->fgIsInPS) { |
| if (prStaRec->fgIsQoS && prStaRec->fgIsUapsdSupported && |
| (prStaRec->ucBmpTriggerAC & BIT(ucTC))) { |
| u4MaxForwardFrameCountLimit = prStaRec->ucFreeQuotaForDelivery; |
| pucPsStaFreeQuota = &prStaRec->ucFreeQuotaForDelivery; |
| } else { |
| /* ASSERT(prStaRec->ucFreeQuotaForDelivery == 0); */ |
| u4MaxForwardFrameCountLimit = prStaRec->ucFreeQuotaForNonDelivery; |
| pucPsStaFreeQuota = &prStaRec->ucFreeQuotaForNonDelivery; |
| } |
| } |
| |
| /* fgIsInPS */ |
| /* Absent BSS handling */ |
| if (prBssInfo->fgIsNetAbsent) { |
| if (u4MaxForwardFrameCountLimit > prBssInfo->ucBssFreeQuota) |
| u4MaxForwardFrameCountLimit = prBssInfo->ucBssFreeQuota; |
| } |
| |
| #if CFG_SUPPORT_DBDC |
| if (prAdapter->rWifiVar.fgDbDcModeEn) |
| u4MaxResourceLimit = gmGetDequeueQuota(prAdapter, prStaRec, prBssInfo, u4TotalQuota); |
| #endif |
| |
| /* 4 <2.3> Dequeue packet */ |
| /* Three cases to break: (1) No resource (2) No packets (3) Fairness */ |
| while (!QUEUE_IS_EMPTY(prCurrQueue)) { |
| prDequeuedPkt = (P_MSDU_INFO_T) QUEUE_GET_HEAD(prCurrQueue); |
| |
| if ((u4CurStaForwardFrameCount >= u4MaxForwardFrameCountLimit) || |
| (u4CurStaUsedResource >= u4MaxResourceLimit)) { |
| /* Exceeds Limit */ |
| |
| break; |
| } else if (prDequeuedPkt->u4PageCount > u4AvaliableResource) { |
| /* Available Resource is not enough */ |
| if (!(prAdapter->rWifiVar.ucAlwaysResetUsedRes & BIT(0))) |
| fgEndThisRound = TRUE; |
| break; |
| } |
| /* Available to be Tx */ |
| |
| QUEUE_REMOVE_HEAD(prCurrQueue, prDequeuedPkt, P_MSDU_INFO_T); |
| |
| if (!QUEUE_IS_EMPTY(prCurrQueue)) { |
| /* XXX: check all queues for STA */ |
| prDequeuedPkt->ucPsForwardingType = PS_FORWARDING_MORE_DATA_ENABLED; |
| } |
| prDequeuedPkt->ucWmmQueSet = prBssInfo->ucWmmQueSet; /* to record WMM Set */ |
| QUEUE_INSERT_TAIL(prQue, (P_QUE_ENTRY_T) prDequeuedPkt); |
| |
| u4AvaliableResource -= prDequeuedPkt->u4PageCount; |
| u4CurStaUsedResource += prDequeuedPkt->u4PageCount; |
| u4CurStaForwardFrameCount++; |
| } |
| |
| /* AP mode: Update STA in PS Free quota */ |
| if (prStaRec->fgIsInPS && pucPsStaFreeQuota) { |
| if ((*pucPsStaFreeQuota) >= u4CurStaForwardFrameCount) |
| (*pucPsStaFreeQuota) -= u4CurStaForwardFrameCount; |
| else |
| (*pucPsStaFreeQuota) = 0; |
| } |
| |
| if (prBssInfo->fgIsNetAbsent) { |
| if (prBssInfo->ucBssFreeQuota >= u4CurStaForwardFrameCount) |
| prBssInfo->ucBssFreeQuota -= u4CurStaForwardFrameCount; |
| else |
| prBssInfo->ucBssFreeQuota = 0; |
| } |
| } |
| |
| if (fgEndThisRound) { |
| /* End this round */ |
| break; |
| } |
| |
| /* Prepare for next STA */ |
| ucLoop++; |
| u4CurStaIndex++; |
| u4CurStaIndex %= CFG_STA_REC_NUM; |
| u4CurStaUsedResource = 0; |
| u4CurStaForwardFrameCount = 0; |
| } |
| |
| /* 4 <3> Store Head Sta information to QM */ |
| /* No need to count used resource if thers is only one STA */ |
| if ((prQM->u4TxAllowedStaCount == 1) || (prAdapter->rWifiVar.ucAlwaysResetUsedRes & BIT(1))) |
| u4CurStaUsedResource = 0; |
| |
| #if QM_FORWARDING_FAIRNESS |
| prQM->au4HeadStaRecIndex[ucTC] = u4CurStaIndex; |
| prQM->au4ResourceUsedCount[ucTC] = u4CurStaUsedResource; |
| #endif |
| |
| DBGLOG(QM, LOUD, "(Fairness) TC[%u] Scheduled Head STA[%u] Left Resource[%u]\n", |
| ucTC, u4CurStaIndex, u4AvaliableResource); |
| |
| return u4AvaliableResource; |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief Dequeue TX packets from a per-Type-based Queue for a particular TC |
| * |
| * \param[out] prQue The queue to put the dequeued packets |
| * \param[in] ucTC The TC index (Shall always be TC5_INDEX) |
| * \param[in] ucMaxNum The maximum amount of available resource |
| * |
| * \return (none) |
| */ |
| /*----------------------------------------------------------------------------*/ |
| VOID |
| qmDequeueTxPacketsFromPerTypeQueues(IN P_ADAPTER_T prAdapter, OUT P_QUE_T prQue, |
| IN UINT_8 ucTC, IN UINT_32 u4CurrentQuota, IN UINT_32 u4TotalQuota) |
| { |
| UINT_32 u4AvaliableResource, u4LeftResource; |
| UINT_32 u4MaxResourceLimit; |
| UINT_32 u4TotalUsedResource = 0; |
| P_QUE_MGT_T prQM; |
| PFN_DEQUEUE_FUNCTION pfnDeQFunc[2]; |
| BOOLEAN fgChangeDeQFunc = TRUE; |
| BOOLEAN fgGlobalQueFirst = TRUE; |
| |
| DBGLOG(QM, LOUD, "Enter %s (TC = %d, quota = %u)\n", __func__, ucTC, u4CurrentQuota); |
| |
| /* Broadcast/Multicast data packets */ |
| if ((u4CurrentQuota == 0)) |
| return; |
| |
| prQM = &prAdapter->rQM; |
| |
| u4AvaliableResource = u4CurrentQuota; |
| u4MaxResourceLimit = u4TotalQuota; |
| #if QM_FORWARDING_FAIRNESS |
| u4TotalUsedResource = prQM->u4GlobalResourceUsedCount; |
| fgGlobalQueFirst = prQM->fgGlobalQFirst; |
| #endif |
| |
| /* Dequeue function selection */ |
| if (fgGlobalQueFirst) { |
| pfnDeQFunc[0] = qmDequeueTxPacketsFromGlobalQueue; |
| pfnDeQFunc[1] = qmDequeueTxPacketsFromPerStaQueues; |
| } else { |
| pfnDeQFunc[0] = qmDequeueTxPacketsFromPerStaQueues; |
| pfnDeQFunc[1] = qmDequeueTxPacketsFromGlobalQueue; |
| } |
| |
| /* 1st dequeue function */ |
| u4LeftResource = pfnDeQFunc[0](prAdapter, prQue, ucTC, u4AvaliableResource, |
| (u4MaxResourceLimit - u4TotalUsedResource)); |
| |
| /* dequeue function comsumes no resource, change */ |
| if ((u4LeftResource >= u4AvaliableResource) && (u4AvaliableResource >= NIC_TX_MAX_PAGE_PER_FRAME)) { |
| fgChangeDeQFunc = TRUE; |
| } else { |
| u4TotalUsedResource += (u4AvaliableResource - u4LeftResource); |
| /* Used resource exceeds limit, change */ |
| if (u4TotalUsedResource >= u4MaxResourceLimit) |
| fgChangeDeQFunc = TRUE; |
| } |
| |
| if (fgChangeDeQFunc) { |
| fgGlobalQueFirst = !fgGlobalQueFirst; |
| u4TotalUsedResource = 0; |
| } |
| |
| /* 2nd dequeue function */ |
| u4LeftResource = pfnDeQFunc[1](prAdapter, prQue, ucTC, u4LeftResource, u4MaxResourceLimit); |
| |
| #if QM_FORWARDING_FAIRNESS |
| prQM->fgGlobalQFirst = fgGlobalQueFirst; |
| prQM->u4GlobalResourceUsedCount = u4TotalUsedResource; |
| #endif |
| |
| } /* qmDequeueTxPacketsFromPerTypeQueues */ |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief Dequeue TX packets from a QM global Queue for a particular TC |
| * |
| * \param[out] prQue The queue to put the dequeued packets |
| * \param[in] ucTC The TC index (Shall always be TC5_INDEX) |
| * \param[in] ucMaxNum The maximum amount of available resource |
| * |
| * \return (none) |
| */ |
| /*----------------------------------------------------------------------------*/ |
| UINT_32 |
| qmDequeueTxPacketsFromGlobalQueue(IN P_ADAPTER_T prAdapter, OUT P_QUE_T prQue, |
| IN UINT_8 ucTC, IN UINT_32 u4CurrentQuota, IN UINT_32 u4TotalQuota) |
| { |
| P_BSS_INFO_T prBssInfo; |
| P_QUE_T prCurrQueue; |
| UINT_32 u4AvaliableResource; |
| P_MSDU_INFO_T prDequeuedPkt; |
| P_MSDU_INFO_T prBurstEndPkt; |
| QUE_T rMergeQue; |
| P_QUE_T prMergeQue; |
| P_QUE_MGT_T prQM; |
| |
| DBGLOG(QM, LOUD, "Enter %s (TC = %d, quota = %u)\n", __func__, ucTC, u4CurrentQuota); |
| |
| /* Broadcast/Multicast data packets */ |
| if (u4CurrentQuota == 0) |
| return u4CurrentQuota; |
| |
| prQM = &prAdapter->rQM; |
| |
| /* 4 <1> Determine the queue */ |
| prCurrQueue = &prQM->arTxQueue[TX_QUEUE_INDEX_BMCAST]; |
| u4AvaliableResource = u4CurrentQuota; |
| prDequeuedPkt = NULL; |
| prBurstEndPkt = NULL; |
| |
| QUEUE_INITIALIZE(&rMergeQue); |
| prMergeQue = &rMergeQue; |
| |
| /* 4 <2> Dequeue packets */ |
| while (!QUEUE_IS_EMPTY(prCurrQueue)) { |
| prDequeuedPkt = (P_MSDU_INFO_T) QUEUE_GET_HEAD(prCurrQueue); |
| if (prDequeuedPkt->u4PageCount > u4AvaliableResource) |
| break; |
| |
| QUEUE_REMOVE_HEAD(prCurrQueue, prDequeuedPkt, P_MSDU_INFO_T); |
| |
| prBssInfo = GET_BSS_INFO_BY_INDEX(prAdapter, prDequeuedPkt->ucBssIndex); |
| |
| if (IS_BSS_ACTIVE(prBssInfo)) { |
| if (!prBssInfo->fgIsNetAbsent) { |
| prDequeuedPkt->ucWmmQueSet = prBssInfo->ucWmmQueSet; /* to record WMM Set */ |
| QUEUE_INSERT_TAIL(prQue, (P_QUE_ENTRY_T) prDequeuedPkt); |
| prBurstEndPkt = prDequeuedPkt; |
| u4AvaliableResource -= prDequeuedPkt->u4PageCount; |
| QM_DBG_CNT_INC(prQM, QM_DBG_CNT_26); |
| } else { |
| QUEUE_INSERT_TAIL(prMergeQue, (P_QUE_ENTRY_T) prDequeuedPkt); |
| } |
| } else { |
| QM_TX_SET_NEXT_MSDU_INFO(prDequeuedPkt, NULL); |
| wlanProcessQueuedMsduInfo(prAdapter, prDequeuedPkt); |
| } |
| } |
| |
| if (QUEUE_IS_NOT_EMPTY(prMergeQue)) { |
| QUEUE_CONCATENATE_QUEUES(prMergeQue, prCurrQueue); |
| QUEUE_MOVE_ALL(prCurrQueue, prMergeQue); |
| QM_TX_SET_NEXT_MSDU_INFO((P_MSDU_INFO_T) QUEUE_GET_TAIL(prCurrQueue), NULL); |
| } |
| |
| return u4AvaliableResource; |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief Dequeue TX packets to send to HIF TX |
| * |
| * \param[in] prTcqStatus Info about the maximum amount of dequeued packets |
| * |
| * \return The list of dequeued TX packets |
| */ |
| /*----------------------------------------------------------------------------*/ |
| P_MSDU_INFO_T qmDequeueTxPackets(IN P_ADAPTER_T prAdapter, IN P_TX_TCQ_STATUS_T prTcqStatus) |
| { |
| INT_32 i; |
| P_MSDU_INFO_T prReturnedPacketListHead; |
| QUE_T rReturnedQue; |
| UINT_32 u4MaxQuotaLimit; |
| |
| DBGLOG(QM, LOUD, "Enter qmDequeueTxPackets\n"); |
| |
| QUEUE_INITIALIZE(&rReturnedQue); |
| |
| prReturnedPacketListHead = NULL; |
| |
| /* TC0 to TC3: AC0~AC3 (commands packets are not handled by QM) */ |
| for (i = TC3_INDEX; i >= TC0_INDEX; i--) { |
| DBGLOG(QM, LOUD, "Dequeue packets from Per-STA queue[%u]\n", i); |
| |
| /* If only one STA is Tx allowed, no need to restrict Max quota */ |
| if (prAdapter->rWifiVar.u4MaxTxDeQLimit) |
| u4MaxQuotaLimit = prAdapter->rWifiVar.u4MaxTxDeQLimit; |
| else if (prAdapter->rQM.u4TxAllowedStaCount == 1) |
| u4MaxQuotaLimit = QM_STA_FORWARD_COUNT_UNLIMITED; |
| else |
| u4MaxQuotaLimit = (UINT_32) prTcqStatus->au4MaxNumOfPage[i]; |
| |
| if (i == BMC_TC_INDEX) |
| qmDequeueTxPacketsFromPerTypeQueues(prAdapter, &rReturnedQue, (UINT_8)i, |
| prTcqStatus->au4FreePageCount[i], u4MaxQuotaLimit); |
| else |
| qmDequeueTxPacketsFromPerStaQueues(prAdapter, &rReturnedQue, (UINT_8)i, |
| prTcqStatus->au4FreePageCount[i], u4MaxQuotaLimit); |
| |
| /* The aggregate number of dequeued packets */ |
| DBGLOG(QM, LOUD, "DQA)[%u](%lu)\n", i, rReturnedQue.u4NumElem); |
| } |
| |
| if (QUEUE_IS_NOT_EMPTY(&rReturnedQue)) { |
| prReturnedPacketListHead = (P_MSDU_INFO_T) QUEUE_GET_HEAD(&rReturnedQue); |
| QM_TX_SET_NEXT_MSDU_INFO((P_MSDU_INFO_T) QUEUE_GET_TAIL(&rReturnedQue), NULL); |
| } |
| |
| return prReturnedPacketListHead; |
| } |
| |
| #if CFG_SUPPORT_MULTITHREAD |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief Dequeue TX packets to send to HIF TX |
| * |
| * \param[in] prTcqStatus Info about the maximum amount of dequeued packets |
| * |
| * \return The list of dequeued TX packets |
| */ |
| /*----------------------------------------------------------------------------*/ |
| P_MSDU_INFO_T qmDequeueTxPacketsMthread(IN P_ADAPTER_T prAdapter, IN P_TX_TCQ_STATUS_T prTcqStatus) |
| { |
| |
| /* INT_32 i; */ |
| P_MSDU_INFO_T prReturnedPacketListHead; |
| /* QUE_T rReturnedQue; */ |
| /* UINT_32 u4MaxQuotaLimit; */ |
| P_MSDU_INFO_T prMsduInfo, prNextMsduInfo; |
| |
| KAL_SPIN_LOCK_DECLARATION(); |
| |
| KAL_ACQUIRE_SPIN_LOCK(prAdapter, SPIN_LOCK_TX_RESOURCE); |
| |
| prReturnedPacketListHead = qmDequeueTxPackets(prAdapter, prTcqStatus); |
| |
| /* require the resource first to prevent from unsync */ |
| prMsduInfo = prReturnedPacketListHead; |
| while (prMsduInfo) { |
| prNextMsduInfo = (P_MSDU_INFO_T) QUEUE_GET_NEXT_ENTRY((P_QUE_ENTRY_T) prMsduInfo); |
| nicTxAcquireResource(prAdapter, prMsduInfo->ucTC, |
| nicTxGetPageCount(prMsduInfo->u2FrameLength, FALSE), FALSE); |
| prMsduInfo = prNextMsduInfo; |
| } |
| |
| KAL_RELEASE_SPIN_LOCK(prAdapter, SPIN_LOCK_TX_RESOURCE); |
| |
| return prReturnedPacketListHead; |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief Adjust the TC quotas according to traffic demands |
| * |
| * \param[out] prTcqAdjust The resulting adjustment |
| * \param[in] prTcqStatus Info about the current TC quotas and counters |
| * |
| * \return (none) |
| */ |
| /*----------------------------------------------------------------------------*/ |
| BOOLEAN |
| qmAdjustTcQuotasMthread(IN P_ADAPTER_T prAdapter, OUT P_TX_TCQ_ADJUST_T prTcqAdjust, IN P_TX_TCQ_STATUS_T prTcqStatus) |
| { |
| #if QM_ADAPTIVE_TC_RESOURCE_CTRL |
| UINT_32 i; |
| P_QUE_MGT_T prQM = &prAdapter->rQM; |
| |
| KAL_SPIN_LOCK_DECLARATION(); |
| |
| /* Must initialize */ |
| for (i = 0; i < QM_ACTIVE_TC_NUM; i++) |
| prTcqAdjust->ai4Variation[i] = 0; |
| |
| /* 4 <1> If TC resource is not just adjusted, exit directly */ |
| if (!prQM->fgTcResourcePostAnnealing) |
| return FALSE; |
| /* 4 <2> Adjust TcqStatus according to the updated prQM->au4CurrentTcResource */ |
| else { |
| INT_32 i4TotalExtraQuota = 0; |
| INT_32 ai4ExtraQuota[QM_ACTIVE_TC_NUM]; |
| BOOLEAN fgResourceRedistributed = TRUE; |
| |
| /* Must initialize */ |
| for (i = 0; i < TC_NUM; i++) |
| prTcqAdjust->ai4Variation[i] = 0; |
| |
| KAL_ACQUIRE_SPIN_LOCK(prAdapter, SPIN_LOCK_TX_RESOURCE); |
| |
| /* Obtain the free-to-distribute resource */ |
| for (i = 0; i < QM_ACTIVE_TC_NUM; i++) { |
| ai4ExtraQuota[i] = |
| (INT_32) prTcqStatus->au4MaxNumOfBuffer[i] - (INT_32) prQM->au4CurrentTcResource[i]; |
| |
| if (ai4ExtraQuota[i] > 0) { /* The resource shall be reallocated to other TCs */ |
| if (ai4ExtraQuota[i] > prTcqStatus->au4FreeBufferCount[i]) { |
| ai4ExtraQuota[i] = prTcqStatus->au4FreeBufferCount[i]; |
| fgResourceRedistributed = FALSE; |
| } |
| |
| i4TotalExtraQuota += ai4ExtraQuota[i]; |
| prTcqAdjust->ai4Variation[i] = (-ai4ExtraQuota[i]); |
| } |
| } |
| |
| /* Distribute quotas to TCs which need extra resource according to prQM->au4CurrentTcResource */ |
| for (i = 0; i < QM_ACTIVE_TC_NUM; i++) { |
| if (ai4ExtraQuota[i] < 0) { |
| if ((-ai4ExtraQuota[i]) > i4TotalExtraQuota) { |
| ai4ExtraQuota[i] = (-i4TotalExtraQuota); |
| fgResourceRedistributed = FALSE; |
| } |
| |
| i4TotalExtraQuota += ai4ExtraQuota[i]; |
| prTcqAdjust->ai4Variation[i] = (-ai4ExtraQuota[i]); |
| } |
| } |
| |
| /* In case some TC is waiting for TX Done, continue to adjust TC quotas upon TX Done */ |
| prQM->fgTcResourcePostAnnealing = (!fgResourceRedistributed); |
| |
| for (i = 0; i < TC_NUM; i++) { |
| prTcqStatus->au4FreePageCount[i] += (prTcqAdjust->ai4Variation[i] * NIC_TX_MAX_PAGE_PER_FRAME); |
| prTcqStatus->au4MaxNumOfPage[i] += (prTcqAdjust->ai4Variation[i] * NIC_TX_MAX_PAGE_PER_FRAME); |
| |
| prTcqStatus->au4FreeBufferCount[i] += prTcqAdjust->ai4Variation[i]; |
| prTcqStatus->au4MaxNumOfBuffer[i] += prTcqAdjust->ai4Variation[i]; |
| |
| ASSERT(prTcqStatus->au4FreeBufferCount[i] >= 0); |
| ASSERT(prTcqStatus->au4MaxNumOfBuffer[i] >= 0); |
| } |
| |
| #if QM_FAST_TC_RESOURCE_CTRL |
| prQM->fgTcResourceFastReaction = FALSE; |
| #endif |
| KAL_RELEASE_SPIN_LOCK(prAdapter, SPIN_LOCK_TX_RESOURCE); |
| } |
| |
| return TRUE; |
| #else |
| return FALSE; |
| #endif |
| } |
| #endif |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief Adjust the TC quotas according to traffic demands |
| * |
| * \param[out] prTcqAdjust The resulting adjustment |
| * \param[in] prTcqStatus Info about the current TC quotas and counters |
| * |
| * \return (none) |
| */ |
| /*----------------------------------------------------------------------------*/ |
| BOOLEAN qmAdjustTcQuotas(IN P_ADAPTER_T prAdapter, OUT P_TX_TCQ_ADJUST_T prTcqAdjust, IN P_TX_TCQ_STATUS_T prTcqStatus) |
| { |
| #if QM_ADAPTIVE_TC_RESOURCE_CTRL |
| UINT_32 i; |
| P_QUE_MGT_T prQM = &prAdapter->rQM; |
| |
| /* Must initialize */ |
| for (i = 0; i < QM_ACTIVE_TC_NUM; i++) |
| prTcqAdjust->ai4Variation[i] = 0; |
| |
| /* 4 <1> If TC resource is not just adjusted, exit directly */ |
| if (!prQM->fgTcResourcePostAnnealing) |
| return FALSE; |
| /* 4 <2> Adjust TcqStatus according to the updated prQM->au4CurrentTcResource */ |
| else { |
| INT_32 i4TotalExtraQuota = 0; |
| INT_32 ai4ExtraQuota[QM_ACTIVE_TC_NUM]; |
| BOOLEAN fgResourceRedistributed = TRUE; |
| |
| /* Obtain the free-to-distribute resource */ |
| for (i = 0; i < QM_ACTIVE_TC_NUM; i++) { |
| ai4ExtraQuota[i] = |
| (INT_32) prTcqStatus->au4MaxNumOfBuffer[i] - (INT_32) prQM->au4CurrentTcResource[i]; |
| |
| if (ai4ExtraQuota[i] > 0) { /* The resource shall be reallocated to other TCs */ |
| if (ai4ExtraQuota[i] > prTcqStatus->au4FreeBufferCount[i]) { |
| ai4ExtraQuota[i] = prTcqStatus->au4FreeBufferCount[i]; |
| fgResourceRedistributed = FALSE; |
| } |
| |
| i4TotalExtraQuota += ai4ExtraQuota[i]; |
| prTcqAdjust->ai4Variation[i] = (-ai4ExtraQuota[i]); |
| } |
| } |
| |
| /* Distribute quotas to TCs which need extra resource according to prQM->au4CurrentTcResource */ |
| for (i = 0; i < QM_ACTIVE_TC_NUM; i++) { |
| if (ai4ExtraQuota[i] < 0) { |
| if ((-ai4ExtraQuota[i]) > i4TotalExtraQuota) { |
| ai4ExtraQuota[i] = (-i4TotalExtraQuota); |
| fgResourceRedistributed = FALSE; |
| } |
| |
| i4TotalExtraQuota += ai4ExtraQuota[i]; |
| prTcqAdjust->ai4Variation[i] = (-ai4ExtraQuota[i]); |
| } |
| } |
| |
| /* In case some TC is waiting for TX Done, continue to adjust TC quotas upon TX Done */ |
| prQM->fgTcResourcePostAnnealing = (!fgResourceRedistributed); |
| |
| #if QM_FAST_TC_RESOURCE_CTRL |
| prQM->fgTcResourceFastReaction = FALSE; |
| #endif |
| |
| #if QM_PRINT_TC_RESOURCE_CTRL |
| DBGLOG(QM, LOUD, "QM: Curr Quota [0]=%u [1]=%u [2]=%u [3]=%u [4]=%u [5]=%u\n", |
| prTcqStatus->au4FreeBufferCount[0], |
| prTcqStatus->au4FreeBufferCount[1], |
| prTcqStatus->au4FreeBufferCount[2], |
| prTcqStatus->au4FreeBufferCount[3], |
| prTcqStatus->au4FreeBufferCount[4], prTcqStatus->au4FreeBufferCount[5]); |
| #endif |
| } |
| |
| return TRUE; |
| #else |
| return FALSE; |
| #endif |
| } |
| |
| #if QM_ADAPTIVE_TC_RESOURCE_CTRL |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief Update the average TX queue length for the TC resource control mechanism |
| * |
| * \param (none) |
| * |
| * \return (none) |
| */ |
| /*----------------------------------------------------------------------------*/ |
| VOID qmUpdateAverageTxQueLen(IN P_ADAPTER_T prAdapter) |
| { |
| INT_32 u4CurrQueLen, u4Tc, u4StaRecIdx; |
| P_STA_RECORD_T prStaRec; |
| P_QUE_MGT_T prQM = &prAdapter->rQM; |
| P_BSS_INFO_T prBssInfo; |
| |
| /* 4 <1> Update the queue lengths for TC0 to TC3 (skip TC4) and TC5 */ |
| for (u4Tc = 0; u4Tc < QM_ACTIVE_TC_NUM; u4Tc++) { |
| u4CurrQueLen = 0; |
| |
| /* Calculate per-STA queue length */ |
| if (u4Tc < NUM_OF_PER_STA_TX_QUEUES) { |
| for (u4StaRecIdx = 0; u4StaRecIdx < CFG_STA_REC_NUM; u4StaRecIdx++) { |
| prStaRec = cnmGetStaRecByIndex(prAdapter, u4StaRecIdx); |
| if (prStaRec) { |
| prBssInfo = GET_BSS_INFO_BY_INDEX(prAdapter, prStaRec->ucBssIndex); |
| |
| /* If the STA is activated, get the queue length */ |
| if ((prStaRec->fgIsValid) && (!prBssInfo->fgIsNetAbsent)) |
| u4CurrQueLen += (prStaRec->arTxQueue[u4Tc].u4NumElem); |
| } |
| } |
| } |
| |
| if (u4Tc == BMC_TC_INDEX) { |
| /* Update the queue length for (BMCAST) */ |
| u4CurrQueLen += prQM->arTxQueue[TX_QUEUE_INDEX_BMCAST].u4NumElem; |
| } |
| |
| if (prQM->au4AverageQueLen[u4Tc] == 0) { |
| prQM->au4AverageQueLen[u4Tc] = (u4CurrQueLen << prQM->u4QueLenMovingAverage); |
| } else { |
| prQM->au4AverageQueLen[u4Tc] -= (prQM->au4AverageQueLen[u4Tc] >> prQM->u4QueLenMovingAverage); |
| prQM->au4AverageQueLen[u4Tc] += (u4CurrQueLen); |
| } |
| } |
| #if 0 |
| /* Update the queue length for TC5 (BMCAST) */ |
| u4CurrQueLen = prQM->arTxQueue[TX_QUEUE_INDEX_BMCAST].u4NumElem; |
| |
| if (prQM->au4AverageQueLen[TC5_INDEX] == 0) { |
| prQM->au4AverageQueLen[TC5_INDEX] = (u4CurrQueLen << QM_QUE_LEN_MOVING_AVE_FACTOR); |
| } else { |
| prQM->au4AverageQueLen[TC5_INDEX] -= |
| (prQM->au4AverageQueLen[TC5_INDEX] >> QM_QUE_LEN_MOVING_AVE_FACTOR); |
| prQM->au4AverageQueLen[TC5_INDEX] += (u4CurrQueLen); |
| } |
| #endif |
| } |
| |
| VOID qmAllocateResidualTcResource(IN P_ADAPTER_T prAdapter, IN PINT_32 ai4TcResDemand, |
| IN PUINT_32 pu4ResidualResource, IN PUINT_32 pu4ShareCount) |
| { |
| P_QUE_MGT_T prQM = &prAdapter->rQM; |
| UINT_32 u4Share = 0; |
| UINT_32 u4TcIdx; |
| UINT_8 ucIdx; |
| UINT_32 au4AdjTc[] = { TC3_INDEX, TC2_INDEX, TC5_INDEX, TC1_INDEX, TC0_INDEX }; |
| UINT_32 u4AdjTcSize = (sizeof(au4AdjTc) / sizeof(UINT_32)); |
| UINT_32 u4ResidualResource = *pu4ResidualResource; |
| UINT_32 u4ShareCount = *pu4ShareCount; |
| |
| /* If there is no resource left, exit directly */ |
| if (u4ResidualResource == 0) |
| return; |
| |
| /* This shall not happen */ |
| if (u4ShareCount == 0) { |
| prQM->au4CurrentTcResource[TC1_INDEX] += u4ResidualResource; |
| DBGLOG(QM, ERROR, "QM: (Error) u4ShareCount = 0\n"); |
| return; |
| } |
| |
| /* Share the residual resource evenly */ |
| u4Share = (u4ResidualResource / u4ShareCount); |
| if (u4Share) { |
| for (u4TcIdx = 0; u4TcIdx < QM_ACTIVE_TC_NUM; u4TcIdx++) { |
| /* Skip TC4 (not adjustable) */ |
| if (u4TcIdx == TC4_INDEX) |
| continue; |
| |
| if (ai4TcResDemand[u4TcIdx] > 0) { |
| if (ai4TcResDemand[u4TcIdx] > u4Share) { |
| prQM->au4CurrentTcResource[u4TcIdx] += u4Share; |
| u4ResidualResource -= u4Share; |
| ai4TcResDemand[u4TcIdx] -= u4Share; |
| } else { |
| prQM->au4CurrentTcResource[u4TcIdx] += ai4TcResDemand[u4TcIdx]; |
| u4ResidualResource -= ai4TcResDemand[u4TcIdx]; |
| ai4TcResDemand[u4TcIdx] = 0; |
| } |
| } |
| } |
| } |
| |
| /* By priority, allocate the left resource that is not divisible by u4Share */ |
| ucIdx = 0; |
| while (u4ResidualResource) { |
| u4TcIdx = au4AdjTc[ucIdx]; |
| |
| if (ai4TcResDemand[u4TcIdx]) { |
| prQM->au4CurrentTcResource[u4TcIdx]++; |
| u4ResidualResource--; |
| ai4TcResDemand[u4TcIdx]--; |
| |
| if (ai4TcResDemand[u4TcIdx] == 0) |
| u4ShareCount--; |
| } |
| |
| if (u4ShareCount <= 0) |
| break; |
| |
| ucIdx++; |
| ucIdx %= u4AdjTcSize; |
| } |
| |
| /* Allocate the left resource */ |
| prQM->au4CurrentTcResource[TC3_INDEX] += u4ResidualResource; |
| |
| *pu4ResidualResource = u4ResidualResource; |
| *pu4ShareCount = u4ShareCount; |
| |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief Assign TX resource for each TC according to TX queue length and current assignment |
| * |
| * \param (none) |
| * |
| * \return (none) |
| */ |
| /*----------------------------------------------------------------------------*/ |
| VOID qmReassignTcResource(IN P_ADAPTER_T prAdapter) |
| { |
| INT_32 i4TotalResourceDemand = 0; |
| UINT_32 u4ResidualResource = 0; |
| UINT_32 u4TcIdx; |
| INT_32 ai4TcResDemand[QM_ACTIVE_TC_NUM]; |
| UINT_32 u4ShareCount = 0; |
| UINT_32 u4Share = 0; |
| P_QUE_MGT_T prQM = &prAdapter->rQM; |
| UINT_32 u4ActiveTcCount = 0; |
| UINT_32 u4LastActiveTcIdx = TC3_INDEX; |
| |
| /* Note: After the new assignment is obtained, set prQM->fgTcResourcePostAnnealing to TRUE to |
| * start the TC-quota adjusting procedure, which will be invoked upon every TX Done |
| */ |
| |
| /* 4 <1> Determine the demands */ |
| /* Determine the amount of extra resource to fulfill all of the demands */ |
| for (u4TcIdx = 0; u4TcIdx < QM_ACTIVE_TC_NUM; u4TcIdx++) { |
| /* Skip TC4, which is not adjustable */ |
| if (u4TcIdx == TC4_INDEX) |
| continue; |
| |
| /* Define: extra_demand = que_length + min_reserved_quota - current_quota */ |
| ai4TcResDemand[u4TcIdx] = ((INT_32)(QM_GET_TX_QUEUE_LEN(prAdapter, u4TcIdx) + |
| prQM->au4MinReservedTcResource[u4TcIdx]) - (INT_32)prQM->au4CurrentTcResource[u4TcIdx]); |
| |
| /* If there are queued packets, allocate extra resource for the TC (for TCP consideration) */ |
| if (QM_GET_TX_QUEUE_LEN(prAdapter, u4TcIdx)) { |
| ai4TcResDemand[u4TcIdx] += prQM->u4ExtraReservedTcResource; |
| u4ActiveTcCount++; |
| } |
| |
| i4TotalResourceDemand += ai4TcResDemand[u4TcIdx]; |
| } |
| |
| /* 4 <2> Case 1: Demand <= Total Resource */ |
| if (i4TotalResourceDemand <= 0) { |
| |
| /* 4 <2.1> Calculate the residual resource evenly */ |
| if (u4ActiveTcCount == 0) |
| u4ShareCount = (QM_ACTIVE_TC_NUM - 1); /* excluding TC4 */ |
| else |
| u4ShareCount = u4ActiveTcCount; |
| u4ResidualResource = (UINT_32) (-i4TotalResourceDemand); |
| u4Share = (u4ResidualResource / u4ShareCount); |
| |
| /* 4 <2.2> Satisfy every TC and share the residual resource evenly */ |
| for (u4TcIdx = 0; u4TcIdx < QM_ACTIVE_TC_NUM; u4TcIdx++) { |
| /* Skip TC4 (not adjustable) */ |
| if (u4TcIdx == TC4_INDEX) |
| continue; |
| |
| prQM->au4CurrentTcResource[u4TcIdx] += ai4TcResDemand[u4TcIdx]; |
| |
| /* Every TC is fully satisfied */ |
| ai4TcResDemand[u4TcIdx] = 0; |
| |
| /* The left resource will be allocated */ |
| if (QM_GET_TX_QUEUE_LEN(prAdapter, u4TcIdx) || (u4ActiveTcCount == 0)) { |
| prQM->au4CurrentTcResource[u4TcIdx] += u4Share; |
| u4ResidualResource -= u4Share; |
| u4LastActiveTcIdx = u4TcIdx; |
| } |
| } |
| |
| /* 4 <2.3> Allocate the left resource to last active TC */ |
| prQM->au4CurrentTcResource[u4LastActiveTcIdx] += (u4ResidualResource); |
| |
| } |
| /* 4 <3> Case 2: Demand > Total Resource --> Guarantee a minimum amount of resource for each TC */ |
| else { |
| u4ShareCount = 0; |
| u4ResidualResource = prQM->u4ResidualTcResource; |
| |
| /* 4 <3.1> Allocated resouce amount = minimum of (guaranteed, total demand) */ |
| for (u4TcIdx = 0; u4TcIdx < QM_ACTIVE_TC_NUM; u4TcIdx++) { |
| /* Skip TC4 (not adjustable) */ |
| if (u4TcIdx == TC4_INDEX) |
| continue; |
| |
| /* The demand can be fulfilled with the guaranteed resource amount */ |
| if ((prQM->au4CurrentTcResource[u4TcIdx] + ai4TcResDemand[u4TcIdx]) <= |
| prQM->au4GuaranteedTcResource[u4TcIdx]) { |
| |
| prQM->au4CurrentTcResource[u4TcIdx] += ai4TcResDemand[u4TcIdx]; |
| u4ResidualResource += |
| (prQM->au4GuaranteedTcResource[u4TcIdx] - prQM->au4CurrentTcResource[u4TcIdx]); |
| ai4TcResDemand[u4TcIdx] = 0; |
| } |
| |
| /* The demand can not be fulfilled with the guaranteed resource amount */ |
| else { |
| ai4TcResDemand[u4TcIdx] -= |
| (prQM->au4GuaranteedTcResource[u4TcIdx] - prQM->au4CurrentTcResource[u4TcIdx]); |
| |
| prQM->au4CurrentTcResource[u4TcIdx] = prQM->au4GuaranteedTcResource[u4TcIdx]; |
| u4ShareCount++; |
| } |
| } |
| |
| /* 4 <3.2> Allocate the residual resource */ |
| qmAllocateResidualTcResource(prAdapter, ai4TcResDemand, &u4ResidualResource, &u4ShareCount); |
| } |
| |
| prQM->fgTcResourcePostAnnealing = TRUE; |
| |
| #if QM_PRINT_TC_RESOURCE_CTRL |
| /* Debug print */ |
| DBGLOG(QM, INFO, "QM: TC Rsc adjust to [%03u:%03u:%03u:%03u:%03u:%03u]\n", |
| prQM->au4CurrentTcResource[0], prQM->au4CurrentTcResource[1], |
| prQM->au4CurrentTcResource[2], prQM->au4CurrentTcResource[3], |
| prQM->au4CurrentTcResource[4], prQM->au4CurrentTcResource[5]); |
| #endif |
| |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief Adjust TX resource for each TC according to TX queue length and current assignment |
| * |
| * \param (none) |
| * |
| * \return (none) |
| */ |
| /*----------------------------------------------------------------------------*/ |
| VOID qmDoAdaptiveTcResourceCtrl(IN P_ADAPTER_T prAdapter) |
| { |
| P_QUE_MGT_T prQM = &prAdapter->rQM; |
| |
| /* 4 <0> Check to update queue length or not */ |
| if (--prQM->u4TimeToUpdateQueLen) |
| return; |
| /* 4 <1> Update TC queue length */ |
| prQM->u4TimeToUpdateQueLen = QM_INIT_TIME_TO_UPDATE_QUE_LEN; |
| qmUpdateAverageTxQueLen(prAdapter); |
| |
| /* 4 <2> Adjust TC resource assignment */ |
| /* Check whether it is time to adjust the TC resource assignment */ |
| if (--prQM->u4TimeToAdjustTcResource == 0) { |
| /* The last assignment has not been completely applied */ |
| if (prQM->fgTcResourcePostAnnealing) { |
| /* Upon the next qmUpdateAverageTxQueLen function call, do this check again */ |
| prQM->u4TimeToAdjustTcResource = 1; |
| } |
| |
| /* The last assignment has been applied */ |
| else { |
| prQM->u4TimeToAdjustTcResource = QM_INIT_TIME_TO_ADJUST_TC_RSC; |
| qmReassignTcResource(prAdapter); |
| #if QM_FAST_TC_RESOURCE_CTRL |
| if (prQM->fgTcResourceFastReaction) { |
| prQM->fgTcResourceFastReaction = FALSE; |
| nicTxAdjustTcq(prAdapter); |
| } |
| #endif |
| } |
| } |
| |
| /* Debug */ |
| #if QM_PRINT_TC_RESOURCE_CTRL |
| do { |
| UINT_32 u4Tc; |
| |
| for (u4Tc = 0; u4Tc < QM_ACTIVE_TC_NUM; u4Tc++) { |
| if (QM_GET_TX_QUEUE_LEN(prAdapter, u4Tc) >= 100) { |
| DBGLOG(QM, LOUD, "QM: QueLen [%ld %ld %ld %ld %ld %ld]\n", |
| QM_GET_TX_QUEUE_LEN(prAdapter, 0), |
| QM_GET_TX_QUEUE_LEN(prAdapter, 1), |
| QM_GET_TX_QUEUE_LEN(prAdapter, 2), |
| QM_GET_TX_QUEUE_LEN(prAdapter, 3), |
| QM_GET_TX_QUEUE_LEN(prAdapter, 4), QM_GET_TX_QUEUE_LEN(prAdapter, 5) |
| ); |
| break; |
| } |
| } |
| } while (FALSE); |
| #endif |
| |
| } |
| |
| #if QM_FAST_TC_RESOURCE_CTRL |
| VOID qmCheckForFastTcResourceCtrl(IN P_ADAPTER_T prAdapter, IN UINT_8 ucTc) |
| { |
| P_QUE_MGT_T prQM = &prAdapter->rQM; |
| BOOLEAN fgTrigger = FALSE; |
| |
| /* Trigger TC resource adjustment if there is a requirement coming for a empty TC */ |
| if (!prAdapter->rTxCtrl.rTc.au4FreeBufferCount[ucTc]) { |
| if (!prQM->au4CurrentTcResource[ucTc] || |
| nicTxGetAdjustableResourceCnt(prAdapter)) |
| fgTrigger = TRUE; |
| } |
| |
| if (fgTrigger) { |
| prQM->u4TimeToUpdateQueLen = 1; |
| prQM->u4TimeToAdjustTcResource = 1; |
| prQM->fgTcResourceFastReaction = TRUE; |
| |
| DBGLOG(QM, LOUD, "Trigger TC Resource adjustment for TC[%u]\n", ucTc); |
| } |
| } |
| #endif |
| |
| #endif |
| |
| UINT_32 |
| gmGetDequeueQuota( |
| IN P_ADAPTER_T prAdapter, |
| IN P_STA_RECORD_T prStaRec, |
| IN P_BSS_INFO_T prBssInfo, |
| IN UINT_32 u4TotalQuota |
| ) |
| { |
| UINT_32 u4Weight = 100; |
| UINT_32 u4Quota; |
| |
| P_QUE_MGT_T prQM = &prAdapter->rQM; |
| |
| if ((prAdapter->rWifiVar.uDeQuePercentEnable == FALSE) || |
| (prQM->fgIsTxResrouceControlEn == FALSE)) |
| return u4TotalQuota; |
| |
| if (prStaRec->ucDesiredPhyTypeSet & PHY_TYPE_BIT_VHT) { |
| if (prBssInfo->ucVhtChannelWidth > VHT_OP_CHANNEL_WIDTH_20_40) { |
| /* BW80 NSS1 rate: MCS9 433 Mbps */ |
| u4Weight = prAdapter->rWifiVar.u4DeQuePercentVHT80Nss1; |
| } else if (prBssInfo->eBssSCO != CHNL_EXT_SCN) { |
| /* BW40 NSS1 Max rate: 200 Mbps */ |
| u4Weight = prAdapter->rWifiVar.u4DeQuePercentVHT40Nss1; |
| } else { |
| /* BW20 NSS1 Max rate: 72.2Mbps (MCS8 86.7Mbps) */ |
| u4Weight = prAdapter->rWifiVar.u4DeQuePercentVHT20Nss1; |
| } |
| } else if (prStaRec->ucDesiredPhyTypeSet & PHY_TYPE_BIT_HT) { |
| if (prBssInfo->ucHtOpInfo1 & HT_OP_INFO1_STA_CHNL_WIDTH) { |
| /* BW40 NSS1 Max rate: 150 Mbps (MCS9 200Mbps)*/ |
| u4Weight = prAdapter->rWifiVar.u4DeQuePercentHT40Nss1; |
| } else { |
| /* BW20 NSS1 Max rate: 72.2Mbps (MCS8 86.7Mbps)*/ |
| u4Weight = prAdapter->rWifiVar.u4DeQuePercentHT20Nss1; |
| } |
| } |
| |
| u4Quota = u4TotalQuota * u4Weight / 100; |
| |
| if (u4Quota > u4TotalQuota || u4Quota <= 0) |
| return u4TotalQuota; |
| |
| return u4Quota; |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /* RX-Related Queue Management */ |
| /*----------------------------------------------------------------------------*/ |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief Init Queue Management for RX |
| * |
| * \param[in] (none) |
| * |
| * \return (none) |
| */ |
| /*----------------------------------------------------------------------------*/ |
| VOID qmInitRxQueues(IN P_ADAPTER_T prAdapter) |
| { |
| /* DbgPrint("QM: Enter qmInitRxQueues()\n"); */ |
| /* TODO */ |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief Handle RX packets (buffer reordering) |
| * |
| * \param[in] prSwRfbListHead The list of RX packets |
| * |
| * \return The list of packets which are not buffered for reordering |
| */ |
| /*----------------------------------------------------------------------------*/ |
| P_SW_RFB_T qmHandleRxPackets(IN P_ADAPTER_T prAdapter, IN P_SW_RFB_T prSwRfbListHead) |
| { |
| |
| #if CFG_RX_REORDERING_ENABLED |
| /* UINT_32 i; */ |
| P_SW_RFB_T prCurrSwRfb; |
| P_SW_RFB_T prNextSwRfb; |
| P_HW_MAC_RX_DESC_T prRxStatus; |
| QUE_T rReturnedQue; |
| P_QUE_T prReturnedQue; |
| PUINT_8 pucEthDestAddr; |
| BOOLEAN fgIsBMC, fgIsHTran; |
| BOOLEAN fgMicErr; |
| #if CFG_SUPPORT_REPLAY_DETECTION |
| UINT_8 ucBssIndexRly = 0; |
| P_BSS_INFO_T prBssInfoRly = NULL; |
| #endif |
| |
| /* DbgPrint("QM: Enter qmHandleRxPackets()\n"); */ |
| |
| DEBUGFUNC("qmHandleRxPackets"); |
| |
| ASSERT(prSwRfbListHead); |
| |
| prReturnedQue = &rReturnedQue; |
| |
| QUEUE_INITIALIZE(prReturnedQue); |
| prNextSwRfb = prSwRfbListHead; |
| |
| do { |
| prCurrSwRfb = prNextSwRfb; |
| prNextSwRfb = QM_RX_GET_NEXT_SW_RFB(prCurrSwRfb); |
| |
| /* prHifRxHdr = prCurrSwRfb->prHifRxHdr; // TODO: (Tehuang) Use macro to obtain the pointer */ |
| prRxStatus = prCurrSwRfb->prRxStatus; |
| |
| /* TODO: (Tehuang) Check if relaying */ |
| prCurrSwRfb->eDst = RX_PKT_DESTINATION_HOST; |
| |
| /* Decide the Destination */ |
| #if CFG_RX_PKTS_DUMP |
| if (prAdapter->rRxCtrl.u4RxPktsDumpTypeMask & BIT(HIF_RX_PKT_TYPE_DATA)) { |
| DBGLOG(SW4, INFO, "QM RX DATA: net _u sta idx %u wlan idx %u ssn _u tid %u ptype %u 11 %u\n", |
| /* HIF_RX_HDR_GET_NETWORK_IDX(prHifRxHdr), */ |
| prCurrSwRfb->ucStaRecIdx, prRxStatus->ucWlanIdx, |
| /* HIF_RX_HDR_GET_SN(prHifRxHdr), *//* The new SN of the frame */ |
| HAL_RX_STATUS_GET_TID(prRxStatus), |
| prCurrSwRfb->ucPacketType, prCurrSwRfb->fgReorderBuffer); |
| |
| DBGLOG_MEM8(SW4, TRACE, (PUINT_8) prCurrSwRfb->pvHeader, prCurrSwRfb->u2PacketLen); |
| } |
| #endif |
| |
| fgIsBMC = HAL_RX_STATUS_IS_BC(prRxStatus) | HAL_RX_STATUS_IS_MC(prRxStatus); |
| fgIsHTran = FALSE; |
| if (HAL_RX_STATUS_GET_HEADER_TRAN(prRxStatus) == TRUE) { |
| /* (!HIF_RX_HDR_GET_80211_FLAG(prHifRxHdr)){ */ |
| |
| UINT_8 ucBssIndex; |
| P_BSS_INFO_T prBssInfo; |
| UINT_8 aucTaAddr[MAC_ADDR_LEN]; |
| |
| fgIsHTran = TRUE; |
| pucEthDestAddr = prCurrSwRfb->pvHeader; |
| |
| if (prCurrSwRfb->prStaRec == NULL) { |
| /* Workaround WTBL Issue */ |
| if (prCurrSwRfb->prRxStatusGroup4 == NULL) { |
| DBGLOG_MEM8(SW4, TRACE, (PUINT_8) prCurrSwRfb->prRxStatus, |
| prCurrSwRfb->prRxStatus->u2RxByteCount); |
| ASSERT(0); |
| } |
| HAL_RX_STATUS_GET_TA(prCurrSwRfb->prRxStatusGroup4, aucTaAddr); |
| prCurrSwRfb->ucStaRecIdx = secLookupStaRecIndexFromTA(prAdapter, aucTaAddr); |
| if (prCurrSwRfb->ucStaRecIdx < CFG_STA_REC_NUM) { |
| prCurrSwRfb->prStaRec = |
| cnmGetStaRecByIndex(prAdapter, prCurrSwRfb->ucStaRecIdx); |
| DBGLOG(QM, TRACE, |
| "Re-search the staRec = %d, mac = " MACSTR ", byteCnt= %d\n", |
| prCurrSwRfb->ucStaRecIdx, MAC2STR(aucTaAddr), prRxStatus->u2RxByteCount); |
| } |
| |
| if (prCurrSwRfb->prStaRec == NULL) { |
| DBGLOG(QM, TRACE, |
| "Mark NULL Packet,StaRec=NULL,wlanIdx:%d,but via Header Translation\n", |
| prRxStatus->ucWlanIdx); |
| /* DBGLOG_MEM8(SW4, TRACE, (PUINT_8)prRxStatus, prRxStatus->u2RxByteCount); */ |
| RX_INC_CNT(&prAdapter->rRxCtrl, RX_NO_STA_DROP_COUNT); |
| prCurrSwRfb->eDst = RX_PKT_DESTINATION_NULL; |
| QUEUE_INSERT_TAIL(prReturnedQue, (P_QUE_ENTRY_T) prCurrSwRfb); |
| continue; |
| } |
| |
| prCurrSwRfb->ucWlanIdx = prCurrSwRfb->prStaRec->ucWlanIndex; |
| GLUE_SET_PKT_BSS_IDX(prCurrSwRfb->pvPacket, |
| secGetBssIdxByWlanIdx(prAdapter, prCurrSwRfb->ucWlanIdx)); |
| } |
| /* ASSERT(prAdapter->rWifiVar.arWtbl[prCurrSwRfb->ucWlanIdx].ucUsed); */ |
| if (prAdapter->rRxCtrl.rFreeSwRfbList.u4NumElem |
| > (CFG_RX_MAX_PKT_NUM - CFG_NUM_OF_QM_RX_PKT_NUM) || TRUE) { |
| |
| ucBssIndex = prCurrSwRfb->prStaRec->ucBssIndex; |
| prBssInfo = GET_BSS_INFO_BY_INDEX(prAdapter, ucBssIndex); |
| /* DBGLOG_MEM8(QM, TRACE,prCurrSwRfb->pvHeader, 16); */ |
| /* */ |
| |
| /* if ((OP_MODE_ACCESS_POINT != prBssInfo->eCurrentOPMode)) { */ |
| /* fgIsBMC = HAL_RX_STATUS_IS_BC(prRxStatus) | HAL_RX_STATUS_IS_MC(prRxStatus); */ |
| /* } */ |
| |
| if (!IS_BSS_ACTIVE(prBssInfo)) { |
| DBGLOG(QM, TRACE, "Mark NULL the Packet for inactive Bss %u\n", ucBssIndex); |
| RX_INC_CNT(&prAdapter->rRxCtrl, RX_INACTIVE_BSS_DROP_COUNT); |
| prCurrSwRfb->eDst = RX_PKT_DESTINATION_NULL; |
| QUEUE_INSERT_TAIL(prReturnedQue, (P_QUE_ENTRY_T) prCurrSwRfb); |
| continue; |
| } |
| |
| if (prBssInfo->eCurrentOPMode == OP_MODE_ACCESS_POINT) { |
| if (IS_BMCAST_MAC_ADDR(pucEthDestAddr)) { |
| prCurrSwRfb->eDst = RX_PKT_DESTINATION_HOST_WITH_FORWARD; |
| } else if (secLookupStaRecIndexFromTA(prAdapter, pucEthDestAddr) |
| != STA_REC_INDEX_NOT_FOUND) { |
| |
| prCurrSwRfb->eDst = RX_PKT_DESTINATION_FORWARD; |
| /* TODO : need to check the dst mac is valid */ |
| /* If src mac is invalid, the packet will be freed in fw */ |
| } |
| } |
| #if CFG_SUPPORT_PASSPOINT |
| else if (hs20IsFrameFilterEnabled(prAdapter, prBssInfo) && |
| hs20IsUnsecuredFrame(prAdapter, prBssInfo, prCurrSwRfb)) { |
| DBGLOG(QM, WARN, "Mark NULL the Packet for Dropped Packet %u\n", ucBssIndex); |
| RX_INC_CNT(&prAdapter->rRxCtrl, RX_HS20_DROP_COUNT); |
| prCurrSwRfb->eDst = RX_PKT_DESTINATION_NULL; |
| QUEUE_INSERT_TAIL(prReturnedQue, (P_QUE_ENTRY_T) prCurrSwRfb); |
| continue; |
| } |
| #endif /* CFG_SUPPORT_PASSPOINT */ |
| |
| } else { |
| /* Dont not occupy other SW RFB */ |
| DBGLOG(QM, TRACE, "Mark NULL the Packet for less Free Sw Rfb\n"); |
| RX_INC_CNT(&prAdapter->rRxCtrl, RX_LESS_SW_RFB_DROP_COUNT); |
| prCurrSwRfb->eDst = RX_PKT_DESTINATION_NULL; |
| QUEUE_INSERT_TAIL(prReturnedQue, (P_QUE_ENTRY_T) prCurrSwRfb); |
| continue; |
| } |
| |
| } |
| |
| #if CFG_SUPPORT_WAPI |
| if (prCurrSwRfb->u2PacketLen > ETHER_HEADER_LEN) { |
| PUINT_8 pc = (PUINT_8) prCurrSwRfb->pvHeader; |
| UINT_16 u2Etype = 0; |
| |
| u2Etype = (pc[ETHER_TYPE_LEN_OFFSET] << 8) | (pc[ETHER_TYPE_LEN_OFFSET + 1]); |
| /* for wapi integrity test. WPI_1x packet should be always in non-encrypted mode. |
| * if we received any WPI(0x88b4) packet that is encrypted, drop here. |
| */ |
| if (u2Etype == ETH_WPI_1X && |
| HAL_RX_STATUS_GET_SEC_MODE(prRxStatus) != 0 && |
| HAL_RX_STATUS_IS_CIPHER_MISMATCH(prRxStatus) == 0) { |
| DBGLOG(QM, INFO, "drop wpi packet with sec mode\n"); |
| prCurrSwRfb->eDst = RX_PKT_DESTINATION_NULL; |
| QUEUE_INSERT_TAIL(prReturnedQue, (P_QUE_ENTRY_T) prCurrSwRfb); |
| continue; |
| } |
| } |
| #endif |
| |
| |
| /* Todo:: Move the data class error check here */ |
| |
| #if CFG_SUPPORT_REPLAY_DETECTION |
| if (prCurrSwRfb->prStaRec) { |
| ucBssIndexRly = prCurrSwRfb->prStaRec->ucBssIndex; |
| prBssInfoRly = GET_BSS_INFO_BY_INDEX(prAdapter, ucBssIndexRly); |
| if (!IS_BSS_ACTIVE(prBssInfoRly)) { |
| DBGLOG(QM, INFO, |
| "Mark NULL the Packet for inactive Bss %u\n", |
| ucBssIndexRly); |
| prCurrSwRfb->eDst = RX_PKT_DESTINATION_NULL; |
| QUEUE_INSERT_TAIL(prReturnedQue, (P_QUE_ENTRY_T) prCurrSwRfb); |
| continue; |
| } |
| if (fgIsBMC |
| && prBssInfoRly |
| && (IS_BSS_AIS(prBssInfoRly) || IS_BSS_P2P(prBssInfoRly)) |
| && qmHandleRxReplay(prAdapter, prCurrSwRfb)) { |
| prCurrSwRfb->eDst = RX_PKT_DESTINATION_NULL; |
| QUEUE_INSERT_TAIL(prReturnedQue, (P_QUE_ENTRY_T) prCurrSwRfb); |
| continue; |
| } |
| } |
| #endif |
| |
| if (prCurrSwRfb->fgReorderBuffer && !fgIsBMC && fgIsHTran) { |
| /* If this packet should dropped or indicated to the host immediately, |
| * it should be enqueued into the rReturnedQue with specific flags. If |
| * this packet should be buffered for reordering, it should be enqueued |
| * into the reordering queue in the STA_REC rather than into the |
| * rReturnedQue. |
| */ |
| qmProcessPktWithReordering(prAdapter, prCurrSwRfb, prReturnedQue); |
| |
| } else if (prCurrSwRfb->fgDataFrame) { |
| /* Check Class Error */ |
| if (secCheckClassError(prAdapter, prCurrSwRfb, prCurrSwRfb->prStaRec) == TRUE) { |
| P_RX_BA_ENTRY_T prReorderQueParm = NULL; |
| |
| /* Invalid BA aggrement */ |
| if (fgIsHTran) { |
| UINT_16 u2FrameCtrl = 0; |
| |
| u2FrameCtrl = HAL_RX_STATUS_GET_FRAME_CTL_FIELD(prCurrSwRfb->prRxStatusGroup4); |
| /* Check FC type, if DATA, then no-reordering */ |
| if ((u2FrameCtrl & MASK_FRAME_TYPE) == MAC_FRAME_DATA) { |
| DBGLOG(QM, TRACE, "FC [0x%04X], no-reordering...\n", u2FrameCtrl); |
| } else { |
| prReorderQueParm = |
| ((prCurrSwRfb->prStaRec-> |
| aprRxReorderParamRefTbl)[prCurrSwRfb->ucTid]); |
| } |
| } |
| |
| if (prReorderQueParm && prReorderQueParm->fgIsValid && !fgIsBMC) |
| qmProcessPktWithReordering(prAdapter, prCurrSwRfb, prReturnedQue); |
| else |
| qmHandleRxPackets_AOSP_1; |
| } else { |
| DBGLOG(QM, TRACE, "Mark NULL the Packet for class error\n"); |
| RX_INC_CNT(&prAdapter->rRxCtrl, RX_CLASS_ERR_DROP_COUNT); |
| prCurrSwRfb->eDst = RX_PKT_DESTINATION_NULL; |
| QUEUE_INSERT_TAIL(prReturnedQue, (P_QUE_ENTRY_T) prCurrSwRfb); |
| } |
| } else { |
| P_WLAN_MAC_HEADER_T prWlanMacHeader; |
| |
| ASSERT(prCurrSwRfb->pvHeader); |
| |
| prWlanMacHeader = (P_WLAN_MAC_HEADER_T) prCurrSwRfb->pvHeader; |
| prCurrSwRfb->eDst = RX_PKT_DESTINATION_NULL; |
| |
| switch (prWlanMacHeader->u2FrameCtrl & MASK_FRAME_TYPE) { |
| /* BAR frame */ |
| case MAC_FRAME_BLOCK_ACK_REQ: |
| qmProcessBarFrame(prAdapter, prCurrSwRfb, prReturnedQue); |
| RX_INC_CNT(&prAdapter->rRxCtrl, RX_BAR_DROP_COUNT); |
| break; |
| default: |
| DBGLOG(QM, TRACE, "Mark NULL the Packet for non-interesting type\n"); |
| RX_INC_CNT(&prAdapter->rRxCtrl, RX_NO_INTEREST_DROP_COUNT); |
| QUEUE_INSERT_TAIL(prReturnedQue, (P_QUE_ENTRY_T) prCurrSwRfb); |
| break; |
| } |
| } |
| |
| } while (prNextSwRfb); |
| |
| /* The returned list of SW_RFBs must end with a NULL pointer */ |
| if (QUEUE_IS_NOT_EMPTY(prReturnedQue)) |
| QM_TX_SET_NEXT_MSDU_INFO((P_SW_RFB_T) QUEUE_GET_TAIL(prReturnedQue), NULL); |
| |
| return (P_SW_RFB_T) QUEUE_GET_HEAD(prReturnedQue); |
| |
| #else |
| |
| /* DbgPrint("QM: Enter qmHandleRxPackets()\n"); */ |
| return prSwRfbListHead; |
| |
| #endif |
| |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief Reorder the received packet |
| * |
| * \param[in] prSwRfb The RX packet to process |
| * \param[out] prReturnedQue The queue for indicating packets |
| * |
| * \return (none) |
| */ |
| /*----------------------------------------------------------------------------*/ |
| VOID qmProcessPktWithReordering(IN P_ADAPTER_T prAdapter, IN P_SW_RFB_T prSwRfb, OUT P_QUE_T prReturnedQue) |
| { |
| |
| P_STA_RECORD_T prStaRec; |
| P_HW_MAC_RX_DESC_T prRxStatus; |
| P_HW_MAC_RX_STS_GROUP_4_T prRxStatusGroup4 = NULL; |
| P_RX_BA_ENTRY_T prReorderQueParm; |
| |
| /* P_SW_RFB_T prReorderedSwRfb; */ |
| #if CFG_SUPPORT_RX_AMSDU |
| UINT_8 u8AmsduSubframeIdx; |
| UINT_32 u4SeqNo; |
| #endif |
| DEBUGFUNC("qmProcessPktWithReordering"); |
| |
| ASSERT(prSwRfb); |
| ASSERT(prReturnedQue); |
| ASSERT(prSwRfb->prRxStatus); |
| |
| /* Incorrect STA_REC index */ |
| if (prSwRfb->ucStaRecIdx >= CFG_STA_REC_NUM) { |
| RX_INC_CNT(&prAdapter->rRxCtrl, RX_NO_STA_DROP_COUNT); |
| prSwRfb->eDst = RX_PKT_DESTINATION_NULL; |
| QUEUE_INSERT_TAIL(prReturnedQue, (P_QUE_ENTRY_T) prSwRfb); |
| DBGLOG(QM, WARN, "Reordering for a NULL STA_REC, ucStaRecIdx = %d\n", prSwRfb->ucStaRecIdx); |
| authSendDeauthFrame(prAdapter, NULL, NULL, prSwRfb, REASON_CODE_CLASS_3_ERR, |
| (PFN_TX_DONE_HANDLER)NULL); |
| /* ASSERT(0); */ |
| return; |
| } |
| |
| /* Check whether the STA_REC is activated */ |
| prStaRec = prSwRfb->prStaRec; |
| ASSERT(prStaRec); |
| |
| prRxStatus = prSwRfb->prRxStatus; |
| prSwRfb->ucTid = (UINT_8) (HAL_RX_STATUS_GET_TID(prRxStatus)); |
| /* prSwRfb->eDst = RX_PKT_DESTINATION_HOST; */ |
| |
| #if 0 |
| if (!(prStaRec->fgIsValid)) { |
| /* TODO: (Tehuang) Handle the Host-FW sync issue. */ |
| prSwRfb->eDst = RX_PKT_DESTINATION_NULL; |
| QUEUE_INSERT_TAIL(prReturnedQue, (P_QUE_ENTRY_T) prSwRfb); |
| DBGLOG(QM, WARN, "Reordering for an invalid STA_REC\n"); |
| /* ASSERT(0); */ |
| return; |
| } |
| #endif |
| |
| RX_INC_CNT(&prAdapter->rRxCtrl, RX_DATA_REORDER_TOTAL_COUINT); |
| |
| /* Check whether the BA agreement exists */ |
| prReorderQueParm = ((prStaRec->aprRxReorderParamRefTbl)[prSwRfb->ucTid]); |
| if (!prReorderQueParm || !(prReorderQueParm->fgIsValid)) { |
| /* TODO: (Tehuang) Handle the Host-FW sync issue. */ |
| prSwRfb->eDst = RX_PKT_DESTINATION_HOST; |
| QUEUE_INSERT_TAIL(prReturnedQue, (P_QUE_ENTRY_T) prSwRfb); |
| DBGLOG(QM, TRACE, "Reordering for a NULL ReorderQueParm\n"); |
| return; |
| } |
| |
| prRxStatusGroup4 = prSwRfb->prRxStatusGroup4; |
| if (prRxStatusGroup4 == NULL) { |
| DBGLOG(QM, ERROR, "prRxStatusGroup4 is NULL !!!\n"); |
| DBGLOG(QM, ERROR, "prSwRfb->pvHeader is 0x%p !!!\n", (PUINT_32) prSwRfb->pvHeader); |
| DBGLOG(QM, ERROR, "prSwRfb->u2PacketLen is %d !!!\n", prSwRfb->u2PacketLen); |
| DBGLOG(QM, ERROR, "========= START TO DUMP prSwRfb =========\n"); |
| DBGLOG_MEM8(QM, ERROR, prSwRfb->pvHeader, prSwRfb->u2PacketLen); |
| DBGLOG(QM, ERROR, "========= END OF DUMP prSwRfb =========\n"); |
| ASSERT(prRxStatusGroup4); |
| } |
| |
| prSwRfb->u2SSN = HAL_RX_STATUS_GET_SEQFrag_NUM(prRxStatusGroup4) >> RX_STATUS_SEQ_NUM_OFFSET; |
| |
| #if CFG_SUPPORT_RX_AMSDU |
| /* RX reorder for one MSDU in AMSDU issue */ |
| /* QUEUE_INITIALIZE(&prSwRfb->rAmsduQue); */ |
| |
| u8AmsduSubframeIdx = HAL_RX_STATUS_GET_PAYLOAD_FORMAT(prRxStatus); |
| |
| /* prMpduSwRfb = prReorderQueParm->prMpduSwRfb; */ |
| u4SeqNo = (UINT_32)prSwRfb->u2SSN; |
| |
| switch (u8AmsduSubframeIdx) { |
| case RX_PAYLOAD_FORMAT_FIRST_SUB_AMSDU: |
| if (prReorderQueParm->fgAmsduNeedLastFrame) { |
| RX_INC_CNT(&prAdapter->rRxCtrl, RX_DATA_AMSDU_MISS_COUNT); |
| prReorderQueParm->fgAmsduNeedLastFrame = FALSE; |
| } |
| RX_INC_CNT(&prAdapter->rRxCtrl, RX_DATA_MSDU_IN_AMSDU_COUNT); |
| RX_INC_CNT(&prAdapter->rRxCtrl, RX_DATA_AMSDU_COUNT); |
| break; |
| |
| case RX_PAYLOAD_FORMAT_MIDDLE_SUB_AMSDU: |
| prReorderQueParm->fgAmsduNeedLastFrame = TRUE; |
| RX_INC_CNT(&prAdapter->rRxCtrl, RX_DATA_MSDU_IN_AMSDU_COUNT); |
| if (prReorderQueParm->u4SeqNo != u4SeqNo) { |
| RX_INC_CNT(&prAdapter->rRxCtrl, RX_DATA_AMSDU_MISS_COUNT); |
| RX_INC_CNT(&prAdapter->rRxCtrl, RX_DATA_AMSDU_COUNT); |
| } |
| break; |
| case RX_PAYLOAD_FORMAT_LAST_SUB_AMSDU: |
| prReorderQueParm->fgAmsduNeedLastFrame = FALSE; |
| RX_INC_CNT(&prAdapter->rRxCtrl, RX_DATA_MSDU_IN_AMSDU_COUNT); |
| if (prReorderQueParm->u4SeqNo != u4SeqNo) { |
| RX_INC_CNT(&prAdapter->rRxCtrl, RX_DATA_AMSDU_MISS_COUNT); |
| RX_INC_CNT(&prAdapter->rRxCtrl, RX_DATA_AMSDU_COUNT); |
| } |
| break; |
| |
| case RX_PAYLOAD_FORMAT_MSDU: |
| if (prReorderQueParm->fgAmsduNeedLastFrame) { |
| RX_INC_CNT(&prAdapter->rRxCtrl, RX_DATA_AMSDU_MISS_COUNT); |
| prReorderQueParm->fgAmsduNeedLastFrame = FALSE; |
| } |
| break; |
| default: |
| break; |
| } |
| |
| prReorderQueParm->u4SeqNo = u4SeqNo; |
| #endif |
| |
| RX_DIRECT_REORDER_LOCK(prAdapter, 0); |
| /* After resuming, WinStart and WinEnd are obsolete and unsync |
| * with AP's SN. So assign the SN of first packet to WinStart |
| * as "Fall Within" case. |
| */ |
| if (prReorderQueParm->fgFirstSnToWinStart) { |
| DBGLOG(QM, INFO, |
| "[%u] First resumed SN(%u) reset Window{%u,%u}\n", |
| prSwRfb->ucTid, prSwRfb->u2SSN, |
| prReorderQueParm->u2WinStart, |
| prReorderQueParm->u2WinEnd); |
| |
| prReorderQueParm->u2WinStart = prSwRfb->u2SSN; |
| prReorderQueParm->u2WinEnd = |
| ((prReorderQueParm->u2WinStart) + |
| (prReorderQueParm->u2WinSize) - 1) % MAX_SEQ_NO_COUNT; |
| prReorderQueParm->fgFirstSnToWinStart = FALSE; |
| } |
| |
| /* Insert reorder packet */ |
| qmInsertReorderPkt(prAdapter, prSwRfb, prReorderQueParm, prReturnedQue); |
| RX_DIRECT_REORDER_UNLOCK(prAdapter, 0); |
| } |
| |
| VOID qmProcessBarFrame(IN P_ADAPTER_T prAdapter, IN P_SW_RFB_T prSwRfb, OUT P_QUE_T prReturnedQue) |
| { |
| |
| P_STA_RECORD_T prStaRec; |
| P_HW_MAC_RX_DESC_T prRxStatus; |
| P_RX_BA_ENTRY_T prReorderQueParm; |
| P_CTRL_BAR_FRAME_T prBarCtrlFrame; |
| |
| UINT_32 u4SSN; |
| UINT_32 u4WinStart; |
| UINT_32 u4WinEnd; |
| |
| ASSERT(prSwRfb); |
| ASSERT(prReturnedQue); |
| ASSERT(prSwRfb->prRxStatus); |
| ASSERT(prSwRfb->pvHeader); |
| |
| prRxStatus = prSwRfb->prRxStatus; |
| |
| prBarCtrlFrame = (P_CTRL_BAR_FRAME_T) prSwRfb->pvHeader; |
| |
| prSwRfb->ucTid = |
| (*((PUINT_16) ((PUINT_8) prBarCtrlFrame + CTRL_BAR_BAR_CONTROL_OFFSET))) >> BAR_CONTROL_TID_INFO_OFFSET; |
| prSwRfb->u2SSN = |
| (*((PUINT_16) ((PUINT_8) prBarCtrlFrame + CTRL_BAR_BAR_INFORMATION_OFFSET))) >> OFFSET_BAR_SSC_SN; |
| |
| prSwRfb->eDst = RX_PKT_DESTINATION_NULL; |
| QUEUE_INSERT_TAIL(prReturnedQue, (P_QUE_ENTRY_T) prSwRfb); |
| |
| /* Incorrect STA_REC index */ |
| prSwRfb->ucStaRecIdx = secLookupStaRecIndexFromTA(prAdapter, prBarCtrlFrame->aucSrcAddr); |
| if (prSwRfb->ucStaRecIdx >= CFG_STA_REC_NUM) { |
| DBGLOG(QM, WARN, "QM: (Warning) BAR for a NULL STA_REC, ucStaRecIdx = %d\n", prSwRfb->ucStaRecIdx); |
| /* ASSERT(0); */ |
| return; |
| } |
| |
| /* Check whether the STA_REC is activated */ |
| prSwRfb->prStaRec = cnmGetStaRecByIndex(prAdapter, prSwRfb->ucStaRecIdx); |
| prStaRec = prSwRfb->prStaRec; |
| if (prStaRec == NULL) { |
| /* ASSERT(prStaRec); */ |
| return; |
| } |
| #if 0 |
| if (!(prStaRec->fgIsValid)) { |
| /* TODO: (Tehuang) Handle the Host-FW sync issue. */ |
| DbgPrint("QM: (Warning) BAR for an invalid STA_REC\n"); |
| /* ASSERT(0); */ |
| return; |
| } |
| #endif |
| |
| /* Check whether the BA agreement exists */ |
| prReorderQueParm = prStaRec->aprRxReorderParamRefTbl[prSwRfb->ucTid]; |
| if (!prReorderQueParm) { |
| /* TODO: (Tehuang) Handle the Host-FW sync issue. */ |
| DBGLOG(QM, WARN, "QM: (Warning) BAR for a NULL ReorderQueParm\n"); |
| /* ASSERT(0); */ |
| return; |
| } |
| |
| RX_DIRECT_REORDER_LOCK(prAdapter, 0); |
| |
| u4SSN = (UINT_32) (prSwRfb->u2SSN); |
| u4WinStart = (UINT_32) (prReorderQueParm->u2WinStart); |
| u4WinEnd = (UINT_32) (prReorderQueParm->u2WinEnd); |
| |
| if (qmCompareSnIsLessThan(u4WinStart, u4SSN)) { |
| prReorderQueParm->u2WinStart = (UINT_16) u4SSN; |
| prReorderQueParm->u2WinEnd = |
| ((prReorderQueParm->u2WinStart) + (prReorderQueParm->u2WinSize) - 1) % MAX_SEQ_NO_COUNT; |
| #if CFG_SUPPORT_RX_AMSDU |
| /* RX reorder for one MSDU in AMSDU issue */ |
| prReorderQueParm->u8LastAmsduSubIdx = RX_PAYLOAD_FORMAT_MSDU; |
| #endif |
| DBGLOG(QM, TRACE, "QM:(BAR)[%u](%u){%u,%u}\n", prSwRfb->ucTid, |
| u4SSN, prReorderQueParm->u2WinStart, |
| prReorderQueParm->u2WinEnd); |
| qmPopOutDueToFallAhead(prAdapter, prReorderQueParm, prReturnedQue); |
| } else { |
| DBGLOG(QM, TRACE, "QM:(BAR)(%u)(%u){%u,%u}\n", prSwRfb->ucTid, |
| u4SSN, u4WinStart, u4WinEnd); |
| } |
| RX_DIRECT_REORDER_UNLOCK(prAdapter, 0); |
| } |
| |
| VOID qmInsertReorderPkt(IN P_ADAPTER_T prAdapter, IN P_SW_RFB_T prSwRfb, |
| IN P_RX_BA_ENTRY_T prReorderQueParm, OUT P_QUE_T prReturnedQue) |
| { |
| UINT_32 u4SeqNo; |
| UINT_32 u4WinStart; |
| UINT_32 u4WinEnd; |
| |
| /* Start to reorder packets */ |
| u4SeqNo = (UINT_32) (prSwRfb->u2SSN); |
| u4WinStart = (UINT_32) (prReorderQueParm->u2WinStart); |
| u4WinEnd = (UINT_32) (prReorderQueParm->u2WinEnd); |
| |
| /* Debug */ |
| DBGLOG(QM, LOUD, "QM:(R)[%u](%u){%u,%u}\n", prSwRfb->ucTid, u4SeqNo, |
| u4WinStart, u4WinEnd); |
| |
| /* Case 1: Fall within */ |
| if /* 0 - start - sn - end - 4095 */ |
| (((u4WinStart <= u4SeqNo) && (u4SeqNo <= u4WinEnd)) |
| /* 0 - end - start - sn - 4095 */ |
| || ((u4WinEnd < u4WinStart) && (u4WinStart <= u4SeqNo)) |
| /* 0 - sn - end - start - 4095 */ |
| || ((u4SeqNo <= u4WinEnd) && (u4WinEnd < u4WinStart))) { |
| |
| qmInsertFallWithinReorderPkt(prAdapter, prSwRfb, prReorderQueParm, prReturnedQue); |
| |
| #if QM_RX_WIN_SSN_AUTO_ADVANCING |
| if (prReorderQueParm->fgIsWaitingForPktWithSsn) { |
| /* Let the first received packet pass the reorder check */ |
| DBGLOG(QM, LOUD, "QM:(A)[%u](%u){%u,%u}\n", |
| prSwRfb->ucTid, u4SeqNo, u4WinStart, u4WinEnd); |
| |
| prReorderQueParm->u2WinStart = (UINT_16) u4SeqNo; |
| prReorderQueParm->u2WinEnd = |
| ((prReorderQueParm->u2WinStart) + (prReorderQueParm->u2WinSize) - 1) % MAX_SEQ_NO_COUNT; |
| prReorderQueParm->fgIsWaitingForPktWithSsn = FALSE; |
| #if CFG_SUPPORT_RX_AMSDU |
| /* RX reorder for one MSDU in AMSDU issue */ |
| prReorderQueParm->u8LastAmsduSubIdx = RX_PAYLOAD_FORMAT_MSDU; |
| #endif |
| } |
| #endif |
| |
| qmPopOutDueToFallWithin(prAdapter, prReorderQueParm, prReturnedQue); |
| } |
| /* Case 2: Fall ahead */ |
| else if |
| /* 0 - start - end - sn - (start+2048) - 4095 */ |
| (((u4WinStart < u4WinEnd) |
| && (u4WinEnd < u4SeqNo) |
| && (u4SeqNo < (u4WinStart + HALF_SEQ_NO_COUNT))) |
| /* 0 - sn - (start+2048) - start - end - 4095 */ |
| || ((u4SeqNo < u4WinStart) |
| && (u4WinStart < u4WinEnd) |
| && ((u4SeqNo + MAX_SEQ_NO_COUNT) < (u4WinStart + HALF_SEQ_NO_COUNT))) |
| /* 0 - end - sn - (start+2048) - start - 4095 */ |
| || ((u4WinEnd < u4SeqNo) |
| && (u4SeqNo < u4WinStart) |
| && ((u4SeqNo + MAX_SEQ_NO_COUNT) < (u4WinStart + HALF_SEQ_NO_COUNT)))) { |
| |
| UINT_16 u2Delta, u2BeforeWinEnd; |
| UINT_32 u4BeforeCount, u4MissingCount; |
| |
| #if QM_RX_WIN_SSN_AUTO_ADVANCING |
| if (prReorderQueParm->fgIsWaitingForPktWithSsn) |
| prReorderQueParm->fgIsWaitingForPktWithSsn = FALSE; |
| #endif |
| |
| qmInsertFallAheadReorderPkt(prAdapter, prSwRfb, prReorderQueParm, prReturnedQue); |
| |
| u2BeforeWinEnd = prReorderQueParm->u2WinEnd; |
| |
| /* Advance the window after inserting a new tail */ |
| prReorderQueParm->u2WinEnd = (UINT_16) u4SeqNo; |
| prReorderQueParm->u2WinStart = |
| (prReorderQueParm->u2WinEnd + MAX_SEQ_NO_COUNT - |
| prReorderQueParm->u2WinSize + 1) % MAX_SEQ_NO_COUNT; |
| #if CFG_SUPPORT_RX_AMSDU |
| /* RX reorder for one MSDU in AMSDU issue */ |
| prReorderQueParm->u8LastAmsduSubIdx = RX_PAYLOAD_FORMAT_MSDU; |
| #endif |
| u4BeforeCount = prReorderQueParm->rReOrderQue.u4NumElem; |
| qmPopOutDueToFallAhead(prAdapter, prReorderQueParm, prReturnedQue); |
| |
| if (prReorderQueParm->u2WinEnd >= u2BeforeWinEnd) |
| u2Delta = prReorderQueParm->u2WinEnd - u2BeforeWinEnd; |
| else |
| u2Delta = MAX_SEQ_NO_COUNT - (u2BeforeWinEnd - prReorderQueParm->u2WinEnd); |
| |
| u4MissingCount = u2Delta - (u4BeforeCount - prReorderQueParm->rReOrderQue.u4NumElem); |
| |
| RX_ADD_CNT(&prAdapter->rRxCtrl, RX_DATA_REORDER_MISS_COUNT, u4MissingCount); |
| } |
| /* Case 3: Fall behind */ |
| else { |
| #if QM_RX_WIN_SSN_AUTO_ADVANCING && QM_RX_INIT_FALL_BEHIND_PASS |
| if (prReorderQueParm->fgIsWaitingForPktWithSsn) { |
| DBGLOG(QM, LOUD, "QM:(P)[%u](%u){%u,%u}\n", |
| prSwRfb->ucTid, u4SeqNo, u4WinStart, u4WinEnd); |
| qmPopOutReorderPkt(prAdapter, prSwRfb, prReturnedQue, |
| RX_DATA_REORDER_BEHIND_COUNT); |
| return; |
| } |
| #endif |
| |
| /* An erroneous packet */ |
| DBGLOG(QM, LOUD, "QM:(D)[%u](%u){%u,%u}\n", prSwRfb->ucTid, |
| u4SeqNo, u4WinStart, u4WinEnd); |
| prSwRfb->eDst = RX_PKT_DESTINATION_NULL; |
| qmPopOutReorderPkt(prAdapter, prSwRfb, prReturnedQue, |
| RX_DATA_REORDER_BEHIND_COUNT); |
| return; |
| } |
| } |
| |
| VOID qmInsertFallWithinReorderPkt(IN P_ADAPTER_T prAdapter, IN P_SW_RFB_T prSwRfb, |
| IN P_RX_BA_ENTRY_T prReorderQueParm, OUT P_QUE_T prReturnedQue) |
| { |
| P_SW_RFB_T prExaminedQueuedSwRfb; |
| P_QUE_T prReorderQue; |
| P_HW_MAC_RX_DESC_T prRxStatus; |
| UINT_8 u8AmsduSubframeIdx; /* RX reorder for one MSDU in AMSDU issue */ |
| |
| ASSERT(prSwRfb); |
| ASSERT(prReorderQueParm); |
| ASSERT(prReturnedQue); |
| |
| prReorderQue = &(prReorderQueParm->rReOrderQue); |
| prExaminedQueuedSwRfb = (P_SW_RFB_T) QUEUE_GET_HEAD(prReorderQue); |
| |
| prRxStatus = prSwRfb->prRxStatus; |
| u8AmsduSubframeIdx = HAL_RX_STATUS_GET_PAYLOAD_FORMAT(prRxStatus); |
| |
| /* There are no packets queued in the Reorder Queue */ |
| if (prExaminedQueuedSwRfb == NULL) { |
| ((P_QUE_ENTRY_T) prSwRfb)->prPrev = NULL; |
| ((P_QUE_ENTRY_T) prSwRfb)->prNext = NULL; |
| prReorderQue->prHead = (P_QUE_ENTRY_T) prSwRfb; |
| prReorderQue->prTail = (P_QUE_ENTRY_T) prSwRfb; |
| prReorderQue->u4NumElem++; |
| } |
| |
| /* Determine the insert position */ |
| else { |
| do { |
| /* Case 1: Terminate. A duplicate packet */ |
| if (((prExaminedQueuedSwRfb->u2SSN) == (prSwRfb->u2SSN))) { |
| #if CFG_SUPPORT_RX_AMSDU |
| /* RX reorder for one MSDU in AMSDU issue */ |
| /* if middle or last and first is not duplicated, not a duplicat packet */ |
| if (!prReorderQueParm->fgIsAmsduDuplicated && |
| (u8AmsduSubframeIdx == RX_PAYLOAD_FORMAT_MIDDLE_SUB_AMSDU || |
| u8AmsduSubframeIdx == RX_PAYLOAD_FORMAT_LAST_SUB_AMSDU)) { |
| |
| prExaminedQueuedSwRfb = |
| (P_SW_RFB_T) (((P_QUE_ENTRY_T) prExaminedQueuedSwRfb)->prNext); |
| while (prExaminedQueuedSwRfb && |
| ((prExaminedQueuedSwRfb->u2SSN) == (prSwRfb->u2SSN))) |
| prExaminedQueuedSwRfb = |
| (P_SW_RFB_T) (((P_QUE_ENTRY_T) prExaminedQueuedSwRfb)->prNext); |
| |
| break; |
| } |
| /* if first is duplicated, drop subsequent middle and last frames */ |
| if (u8AmsduSubframeIdx == RX_PAYLOAD_FORMAT_FIRST_SUB_AMSDU) |
| prReorderQueParm->fgIsAmsduDuplicated = TRUE; |
| #endif |
| prSwRfb->eDst = RX_PKT_DESTINATION_NULL; |
| qmPopOutReorderPkt(prAdapter, prSwRfb, prReturnedQue, RX_DUPICATE_DROP_COUNT); |
| return; |
| } |
| |
| /* Case 2: Terminate. The insert point is found */ |
| else if (qmCompareSnIsLessThan((prSwRfb->u2SSN), (prExaminedQueuedSwRfb->u2SSN))) |
| break; |
| |
| /* Case 3: Insert point not found. Check the next SW_RFB in the Reorder Queue */ |
| else |
| prExaminedQueuedSwRfb = |
| (P_SW_RFB_T) (((P_QUE_ENTRY_T) prExaminedQueuedSwRfb)->prNext); |
| } while (prExaminedQueuedSwRfb); |
| #if CFG_SUPPORT_RX_AMSDU |
| prReorderQueParm->fgIsAmsduDuplicated = FALSE; |
| #endif |
| |
| /* Update the Reorder Queue Parameters according to the found insert position */ |
| if (prExaminedQueuedSwRfb == NULL) { |
| /* The received packet shall be placed at the tail */ |
| ((P_QUE_ENTRY_T) prSwRfb)->prPrev = prReorderQue->prTail; |
| ((P_QUE_ENTRY_T) prSwRfb)->prNext = NULL; |
| (prReorderQue->prTail)->prNext = (P_QUE_ENTRY_T) (prSwRfb); |
| prReorderQue->prTail = (P_QUE_ENTRY_T) (prSwRfb); |
| } else { |
| ((P_QUE_ENTRY_T) prSwRfb)->prPrev = ((P_QUE_ENTRY_T) prExaminedQueuedSwRfb)->prPrev; |
| ((P_QUE_ENTRY_T) prSwRfb)->prNext = (P_QUE_ENTRY_T) prExaminedQueuedSwRfb; |
| if (((P_QUE_ENTRY_T) prExaminedQueuedSwRfb) == (prReorderQue->prHead)) { |
| /* The received packet will become the head */ |
| prReorderQue->prHead = (P_QUE_ENTRY_T) prSwRfb; |
| } else { |
| (((P_QUE_ENTRY_T) prExaminedQueuedSwRfb)->prPrev)->prNext = (P_QUE_ENTRY_T) prSwRfb; |
| } |
| ((P_QUE_ENTRY_T) prExaminedQueuedSwRfb)->prPrev = (P_QUE_ENTRY_T) prSwRfb; |
| } |
| |
| prReorderQue->u4NumElem++; |
| } |
| |
| } |
| |
| VOID qmInsertFallAheadReorderPkt(IN P_ADAPTER_T prAdapter, IN P_SW_RFB_T prSwRfb, |
| IN P_RX_BA_ENTRY_T prReorderQueParm, OUT P_QUE_T prReturnedQue) |
| { |
| P_QUE_T prReorderQue; |
| |
| ASSERT(prSwRfb); |
| ASSERT(prReorderQueParm); |
| ASSERT(prReturnedQue); |
| #if CFG_SUPPORT_RX_AMSDU |
| /* RX reorder for one MSDU in AMSDU issue */ |
| prReorderQueParm->fgIsAmsduDuplicated = FALSE; |
| #endif |
| prReorderQue = &(prReorderQueParm->rReOrderQue); |
| /* There are no packets queued in the Reorder Queue */ |
| if (QUEUE_IS_EMPTY(prReorderQue)) { |
| ((P_QUE_ENTRY_T) prSwRfb)->prPrev = NULL; |
| ((P_QUE_ENTRY_T) prSwRfb)->prNext = NULL; |
| prReorderQue->prHead = (P_QUE_ENTRY_T) prSwRfb; |
| } else { |
| ((P_QUE_ENTRY_T) prSwRfb)->prPrev = prReorderQue->prTail; |
| ((P_QUE_ENTRY_T) prSwRfb)->prNext = NULL; |
| (prReorderQue->prTail)->prNext = (P_QUE_ENTRY_T) (prSwRfb); |
| } |
| prReorderQue->prTail = (P_QUE_ENTRY_T) prSwRfb; |
| prReorderQue->u4NumElem++; |
| } |
| |
| VOID qmPopOutReorderPkt(IN P_ADAPTER_T prAdapter, IN P_SW_RFB_T prSwRfb, OUT P_QUE_T prReturnedQue, |
| IN ENUM_RX_STATISTIC_COUNTER_T eRxCounter) |
| { |
| UINT_32 u4PktCnt = 0; |
| /* RX reorder for one MSDU in AMSDU issue */ |
| #if 0 |
| P_SW_RFB_T prAmsduSwRfb; |
| #endif |
| |
| u4PktCnt++; |
| QUEUE_INSERT_TAIL(prReturnedQue, (P_QUE_ENTRY_T)prSwRfb); |
| |
| #if 0 |
| u4PktCnt += prSwRfb->rAmsduQue.u4NumElem; |
| QUEUE_REMOVE_HEAD(&prSwRfb->rAmsduQue, prAmsduSwRfb, P_SW_RFB_T); |
| while (prAmsduSwRfb) { |
| /* Update MSDU destination of AMSDU */ |
| prAmsduSwRfb->eDst = prSwRfb->eDst; |
| QUEUE_INSERT_TAIL(prReturnedQue, (P_QUE_ENTRY_T)prAmsduSwRfb); |
| QUEUE_REMOVE_HEAD(&prSwRfb->rAmsduQue, prAmsduSwRfb, P_SW_RFB_T); |
| } |
| #endif |
| |
| RX_ADD_CNT(&prAdapter->rRxCtrl, eRxCounter, u4PktCnt); |
| } |
| |
| VOID qmPopOutDueToFallWithin(IN P_ADAPTER_T prAdapter, IN P_RX_BA_ENTRY_T prReorderQueParm, OUT P_QUE_T prReturnedQue) |
| { |
| P_SW_RFB_T prReorderedSwRfb; |
| P_QUE_T prReorderQue; |
| BOOLEAN fgDequeuHead, fgMissing; |
| OS_SYSTIME rCurrentTime, *prMissTimeout; |
| P_HW_MAC_RX_DESC_T prRxStatus; |
| UINT_8 fgIsAmsduSubframe;/* RX reorder for one MSDU in AMSDU issue */ |
| |
| prReorderQue = &(prReorderQueParm->rReOrderQue); |
| |
| fgMissing = FALSE; |
| rCurrentTime = 0; |
| prMissTimeout = &g_arMissTimeout[prReorderQueParm->ucStaRecIdx][prReorderQueParm->ucTid]; |
| if (*prMissTimeout) { |
| fgMissing = TRUE; |
| GET_CURRENT_SYSTIME(&rCurrentTime); |
| } |
| |
| /* Check whether any packet can be indicated to the higher layer */ |
| while (TRUE) { |
| if (QUEUE_IS_EMPTY(prReorderQue)) |
| break; |
| |
| /* Always examine the head packet */ |
| prReorderedSwRfb = (P_SW_RFB_T) QUEUE_GET_HEAD(prReorderQue); |
| fgDequeuHead = FALSE; |
| |
| /* RX reorder for one MSDU in AMSDU issue */ |
| prRxStatus = prReorderedSwRfb->prRxStatus; |
| fgIsAmsduSubframe = HAL_RX_STATUS_GET_PAYLOAD_FORMAT(prRxStatus); |
| #if CFG_SUPPORT_RX_AMSDU |
| /* If SN + 1 come and last frame is first or middle, update winstart */ |
| if ((qmCompareSnIsLessThan((prReorderQueParm->u2WinStart), (prReorderedSwRfb->u2SSN))) |
| && (prReorderQueParm->u4SeqNo != prReorderQueParm->u2WinStart)) { |
| if (prReorderQueParm->u8LastAmsduSubIdx == RX_PAYLOAD_FORMAT_FIRST_SUB_AMSDU |
| || prReorderQueParm->u8LastAmsduSubIdx == RX_PAYLOAD_FORMAT_MIDDLE_SUB_AMSDU) { |
| |
| prReorderQueParm->u2WinStart = |
| (((prReorderQueParm->u2WinStart) + 1) % MAX_SEQ_NO_COUNT); |
| prReorderQueParm->u8LastAmsduSubIdx = RX_PAYLOAD_FORMAT_MSDU; |
| } |
| } |
| #endif |
| /* SN == WinStart, so the head packet shall be indicated (advance the window) */ |
| if ((prReorderedSwRfb->u2SSN) == (prReorderQueParm->u2WinStart)) { |
| |
| fgDequeuHead = TRUE; |
| /* RX reorder for one MSDU in AMSDU issue */ |
| /* if last frame, winstart++. Otherwise, keep winstart */ |
| if (fgIsAmsduSubframe == RX_PAYLOAD_FORMAT_LAST_SUB_AMSDU |
| || fgIsAmsduSubframe == RX_PAYLOAD_FORMAT_MSDU) |
| prReorderQueParm->u2WinStart = (((prReorderedSwRfb->u2SSN) + 1) % MAX_SEQ_NO_COUNT); |
| #if CFG_SUPPORT_RX_AMSDU |
| prReorderQueParm->u8LastAmsduSubIdx = fgIsAmsduSubframe; |
| #endif |
| } |
| /* SN > WinStart, break to update WinEnd */ |
| else { |
| /* Start bubble timer */ |
| if (!prReorderQueParm->fgHasBubble) { |
| cnmTimerStartTimer(prAdapter, &(prReorderQueParm->rReorderBubbleTimer), |
| QM_RX_BA_ENTRY_MISS_TIMEOUT_MS); |
| prReorderQueParm->fgHasBubble = TRUE; |
| prReorderQueParm->u2FirstBubbleSn = prReorderQueParm->u2WinStart; |
| |
| DBGLOG(QM, TRACE, |
| "QM:(Bub Timer) STA[%u] TID[%u] BubSN[%u] Win{%u, %u}\n", |
| prReorderQueParm->ucStaRecIdx, |
| prReorderedSwRfb->ucTid, |
| prReorderQueParm->u2FirstBubbleSn, |
| prReorderQueParm->u2WinStart, |
| prReorderQueParm->u2WinEnd); |
| } |
| |
| if (fgMissing && CHECK_FOR_TIMEOUT(rCurrentTime, *prMissTimeout, |
| MSEC_TO_SYSTIME(QM_RX_BA_ENTRY_MISS_TIMEOUT_MS))) { |
| |
| DBGLOG(QM, TRACE, |
| "QM:RX BA Timout Next Tid %u SSN %u\n", |
| prReorderQueParm->ucTid, |
| prReorderedSwRfb->u2SSN); |
| fgDequeuHead = TRUE; |
| prReorderQueParm->u2WinStart = (((prReorderedSwRfb->u2SSN) + 1) % MAX_SEQ_NO_COUNT); |
| #if CFG_SUPPORT_RX_AMSDU |
| /* RX reorder for one MSDU in AMSDU issue */ |
| prReorderQueParm->u8LastAmsduSubIdx = RX_PAYLOAD_FORMAT_MSDU; |
| #endif |
| fgMissing = FALSE; |
| } else |
| break; |
| } |
| |
| /* Dequeue the head packet */ |
| if (fgDequeuHead) { |
| if (((P_QUE_ENTRY_T) prReorderedSwRfb)->prNext == NULL) { |
| prReorderQue->prHead = NULL; |
| prReorderQue->prTail = NULL; |
| } else { |
| prReorderQue->prHead = ((P_QUE_ENTRY_T) prReorderedSwRfb)->prNext; |
| (((P_QUE_ENTRY_T) prReorderedSwRfb)->prNext)->prPrev = NULL; |
| } |
| prReorderQue->u4NumElem--; |
| DBGLOG(QM, LOUD, "QM: [%u] %u (%u)\n", |
| prReorderQueParm->ucTid, |
| prReorderedSwRfb->u2PacketLen, |
| prReorderedSwRfb->u2SSN); |
| qmPopOutReorderPkt(prAdapter, prReorderedSwRfb, prReturnedQue, RX_DATA_REORDER_WITHIN_COUNT); |
| } |
| } |
| |
| if (QUEUE_IS_EMPTY(prReorderQue)) |
| *prMissTimeout = 0; |
| else { |
| if (fgMissing == FALSE) |
| GET_CURRENT_SYSTIME(prMissTimeout); |
| } |
| |
| /* After WinStart has been determined, update the WinEnd */ |
| prReorderQueParm->u2WinEnd = |
| (((prReorderQueParm->u2WinStart) + (prReorderQueParm->u2WinSize) - 1) % MAX_SEQ_NO_COUNT); |
| |
| } |
| |
| VOID qmPopOutDueToFallAhead(IN P_ADAPTER_T prAdapter, IN P_RX_BA_ENTRY_T prReorderQueParm, OUT P_QUE_T prReturnedQue) |
| { |
| P_SW_RFB_T prReorderedSwRfb; |
| P_QUE_T prReorderQue; |
| BOOLEAN fgDequeuHead; |
| P_HW_MAC_RX_DESC_T prRxStatus; |
| UINT_8 fgIsAmsduSubframe;/* RX reorder for one MSDU in AMSDU issue */ |
| |
| prReorderQue = &(prReorderQueParm->rReOrderQue); |
| |
| /* Check whether any packet can be indicated to the higher layer */ |
| while (TRUE) { |
| if (QUEUE_IS_EMPTY(prReorderQue)) |
| break; |
| |
| /* Always examine the head packet */ |
| prReorderedSwRfb = (P_SW_RFB_T) QUEUE_GET_HEAD(prReorderQue); |
| fgDequeuHead = FALSE; |
| |
| /* RX reorder for one MSDU in AMSDU issue */ |
| prRxStatus = prReorderedSwRfb->prRxStatus; |
| fgIsAmsduSubframe = HAL_RX_STATUS_GET_PAYLOAD_FORMAT(prRxStatus); |
| #if CFG_SUPPORT_RX_AMSDU |
| /* If SN + 1 come and last frame is first or middle, update winstart */ |
| if ((qmCompareSnIsLessThan((prReorderQueParm->u2WinStart), (prReorderedSwRfb->u2SSN))) |
| && (prReorderQueParm->u4SeqNo != prReorderQueParm->u2WinStart)) { |
| if (prReorderQueParm->u8LastAmsduSubIdx == RX_PAYLOAD_FORMAT_FIRST_SUB_AMSDU |
| || prReorderQueParm->u8LastAmsduSubIdx == RX_PAYLOAD_FORMAT_MIDDLE_SUB_AMSDU) { |
| |
| prReorderQueParm->u2WinStart = |
| (((prReorderQueParm->u2WinStart) + 1) % MAX_SEQ_NO_COUNT); |
| prReorderQueParm->u8LastAmsduSubIdx = RX_PAYLOAD_FORMAT_MSDU; |
| } |
| } |
| #endif |
| /* SN == WinStart, so the head packet shall be indicated (advance the window) */ |
| if ((prReorderedSwRfb->u2SSN) == (prReorderQueParm->u2WinStart)) { |
| |
| fgDequeuHead = TRUE; |
| /* RX reorder for one MSDU in AMSDU issue */ |
| /* if last frame, winstart++. Otherwise, keep winstart */ |
| if (fgIsAmsduSubframe == RX_PAYLOAD_FORMAT_LAST_SUB_AMSDU |
| || fgIsAmsduSubframe == RX_PAYLOAD_FORMAT_MSDU) |
| prReorderQueParm->u2WinStart = (((prReorderedSwRfb->u2SSN) + 1) % MAX_SEQ_NO_COUNT); |
| #if CFG_SUPPORT_RX_AMSDU |
| prReorderQueParm->u8LastAmsduSubIdx = fgIsAmsduSubframe; |
| #endif |
| } |
| |
| /* SN < WinStart, so the head packet shall be indicated (do not advance the window) */ |
| else if (qmCompareSnIsLessThan((UINT_32)(prReorderedSwRfb->u2SSN), |
| (UINT_32)(prReorderQueParm->u2WinStart))) |
| fgDequeuHead = TRUE; |
| |
| /* SN > WinStart, break to update WinEnd */ |
| else { |
| /* Start bubble timer */ |
| if (!prReorderQueParm->fgHasBubble) { |
| cnmTimerStartTimer(prAdapter, &(prReorderQueParm->rReorderBubbleTimer), |
| QM_RX_BA_ENTRY_MISS_TIMEOUT_MS); |
| prReorderQueParm->fgHasBubble = TRUE; |
| prReorderQueParm->u2FirstBubbleSn = prReorderQueParm->u2WinStart; |
| |
| DBGLOG(QM, TRACE, |
| "QM:(Bub Timer) STA[%u] TID[%u] BubSN[%u] Win{%u,%u}\n", |
| prReorderQueParm->ucStaRecIdx, |
| prReorderedSwRfb->ucTid, |
| prReorderQueParm->u2FirstBubbleSn, |
| prReorderQueParm->u2WinStart, |
| prReorderQueParm->u2WinEnd); |
| } |
| break; |
| } |
| |
| /* Dequeue the head packet */ |
| if (fgDequeuHead) { |
| if (((P_QUE_ENTRY_T) prReorderedSwRfb)->prNext == NULL) { |
| prReorderQue->prHead = NULL; |
| prReorderQue->prTail = NULL; |
| } else { |
| prReorderQue->prHead = ((P_QUE_ENTRY_T) prReorderedSwRfb)->prNext; |
| (((P_QUE_ENTRY_T) prReorderedSwRfb)->prNext)->prPrev = NULL; |
| } |
| prReorderQue->u4NumElem--; |
| DBGLOG(QM, TRACE, "QM: [%u] %u (%u)\n", |
| prReorderQueParm->ucTid, |
| prReorderedSwRfb->u2PacketLen, |
| prReorderedSwRfb->u2SSN); |
| |
| qmPopOutReorderPkt(prAdapter, prReorderedSwRfb, prReturnedQue, RX_DATA_REORDER_AHEAD_COUNT); |
| } |
| } |
| |
| /* After WinStart has been determined, update the WinEnd */ |
| prReorderQueParm->u2WinEnd = |
| (((prReorderQueParm->u2WinStart) + (prReorderQueParm->u2WinSize) - 1) % MAX_SEQ_NO_COUNT); |
| |
| } |
| |
| VOID qmHandleReorderBubbleTimeout(IN P_ADAPTER_T prAdapter, IN ULONG ulParamPtr) |
| { |
| P_RX_BA_ENTRY_T prReorderQueParm = (P_RX_BA_ENTRY_T) ulParamPtr; |
| P_SW_RFB_T prSwRfb = (P_SW_RFB_T) NULL; |
| P_WIFI_EVENT_T prEvent = NULL; |
| P_EVENT_CHECK_REORDER_BUBBLE_T prCheckReorderEvent; |
| |
| KAL_SPIN_LOCK_DECLARATION(); |
| |
| if (!prReorderQueParm->fgIsValid) { |
| DBGLOG(QM, TRACE, "QM:(Bub Check Cancel) STA[%u] TID[%u], No Rx BA entry\n", |
| prReorderQueParm->ucStaRecIdx, prReorderQueParm->ucTid); |
| return; |
| } |
| |
| if (!prReorderQueParm->fgHasBubble) { |
| DBGLOG(QM, TRACE, |
| "QM:(Bub Check Cancel) STA[%u] TID[%u], Bubble has been filled\n", |
| prReorderQueParm->ucStaRecIdx, prReorderQueParm->ucTid); |
| return; |
| } |
| |
| DBGLOG(QM, TRACE, "QM:(Bub Timeout) STA[%u] TID[%u] BubSN[%u]\n", |
| prReorderQueParm->ucStaRecIdx, prReorderQueParm->ucTid, prReorderQueParm->u2FirstBubbleSn); |
| |
| /* Generate a self-inited event to Rx path */ |
| KAL_ACQUIRE_SPIN_LOCK(prAdapter, SPIN_LOCK_RX_FREE_QUE); |
| QUEUE_REMOVE_HEAD(&prAdapter->rRxCtrl.rFreeSwRfbList, prSwRfb, P_SW_RFB_T); |
| KAL_RELEASE_SPIN_LOCK(prAdapter, SPIN_LOCK_RX_FREE_QUE); |
| |
| if (prSwRfb) { |
| prEvent = (P_WIFI_EVENT_T) (prSwRfb->pucRecvBuff); |
| prEvent->ucEID = EVENT_ID_CHECK_REORDER_BUBBLE; |
| prEvent->ucSeqNum = 0; |
| prEvent->u2PacketLength = sizeof(WIFI_EVENT_T) + sizeof(EVENT_CHECK_REORDER_BUBBLE_T); |
| |
| prCheckReorderEvent = (P_EVENT_CHECK_REORDER_BUBBLE_T) prEvent->aucBuffer; |
| prCheckReorderEvent->ucStaRecIdx = prReorderQueParm->ucStaRecIdx; |
| prCheckReorderEvent->ucTid = prReorderQueParm->ucTid; |
| |
| prSwRfb->ucPacketType = RX_PKT_TYPE_SW_DEFINED; |
| prSwRfb->prRxStatus->u2PktTYpe = RXM_RXD_PKT_TYPE_SW_EVENT; |
| |
| KAL_ACQUIRE_SPIN_LOCK(prAdapter, SPIN_LOCK_RX_QUE); |
| QUEUE_INSERT_TAIL(&prAdapter->rRxCtrl.rReceivedRfbList, &prSwRfb->rQueEntry); |
| RX_INC_CNT(&prAdapter->rRxCtrl, RX_MPDU_TOTAL_COUNT); |
| KAL_RELEASE_SPIN_LOCK(prAdapter, SPIN_LOCK_RX_QUE); |
| |
| DBGLOG(QM, LOUD, "QM:(Bub Check Event Sent) STA[%u] TID[%u]\n", |
| prReorderQueParm->ucStaRecIdx, prReorderQueParm->ucTid); |
| |
| nicRxProcessRFBs(prAdapter); |
| |
| DBGLOG(QM, LOUD, "QM:(Bub Check Event Handled) STA[%u] TID[%u]\n", |
| prReorderQueParm->ucStaRecIdx, prReorderQueParm->ucTid); |
| } else { |
| DBGLOG(QM, TRACE, |
| "QM:(Bub Check Cancel) STA[%u] TID[%u], Bub check event alloc failed\n", |
| prReorderQueParm->ucStaRecIdx, prReorderQueParm->ucTid); |
| |
| cnmTimerStartTimer(prAdapter, &(prReorderQueParm->rReorderBubbleTimer), QM_RX_BA_ENTRY_MISS_TIMEOUT_MS); |
| |
| DBGLOG(QM, TRACE, |
| "QM:(Bub Timer Restart) STA[%u] TID[%u] BubSN[%u] Win{%u,%u}\n", |
| prReorderQueParm->ucStaRecIdx, prReorderQueParm->ucTid, |
| prReorderQueParm->u2FirstBubbleSn, |
| prReorderQueParm->u2WinStart, |
| prReorderQueParm->u2WinEnd); |
| } |
| |
| } |
| |
| VOID qmHandleEventCheckReorderBubble(IN P_ADAPTER_T prAdapter, IN P_WIFI_EVENT_T prEvent) |
| { |
| P_EVENT_CHECK_REORDER_BUBBLE_T prCheckReorderEvent; |
| P_RX_BA_ENTRY_T prReorderQueParm; |
| P_QUE_T prReorderQue; |
| QUE_T rReturnedQue; |
| P_QUE_T prReturnedQue = &rReturnedQue; |
| P_SW_RFB_T prReorderedSwRfb, prSwRfb; |
| OS_SYSTIME *prMissTimeout; |
| |
| prCheckReorderEvent = (P_EVENT_CHECK_REORDER_BUBBLE_T) (prEvent->aucBuffer); |
| |
| QUEUE_INITIALIZE(prReturnedQue); |
| |
| /* Get target Rx BA entry */ |
| prReorderQueParm = qmLookupRxBaEntry(prAdapter, prCheckReorderEvent->ucStaRecIdx, prCheckReorderEvent->ucTid); |
| |
| /* Sanity Check */ |
| if (!prReorderQueParm) { |
| DBGLOG(QM, TRACE, "QM:(Bub Check Cancel) STA[%u] TID[%u], No Rx BA entry\n", |
| prCheckReorderEvent->ucStaRecIdx, prCheckReorderEvent->ucTid); |
| return; |
| } |
| |
| if (!prReorderQueParm->fgIsValid) { |
| DBGLOG(QM, TRACE, "QM:(Bub Check Cancel) STA[%u] TID[%u], No Rx BA entry\n", |
| prReorderQueParm->ucStaRecIdx, prReorderQueParm->ucTid); |
| return; |
| } |
| |
| if (!prReorderQueParm->fgHasBubble) { |
| DBGLOG(QM, TRACE, |
| "QM:(Bub Check Cancel) STA[%u] TID[%u], Bubble has been filled\n", |
| prReorderQueParm->ucStaRecIdx, prReorderQueParm->ucTid); |
| return; |
| } |
| |
| prReorderQue = &(prReorderQueParm->rReOrderQue); |
| |
| RX_DIRECT_REORDER_LOCK(prAdapter, 0); |
| |
| if (QUEUE_IS_EMPTY(prReorderQue)) { |
| prReorderQueParm->fgHasBubble = FALSE; |
| |
| DBGLOG(QM, TRACE, |
| "QM:(Bub Check Cancel) STA[%u] TID[%u], Bubble has been filled\n", |
| prReorderQueParm->ucStaRecIdx, prReorderQueParm->ucTid); |
| RX_DIRECT_REORDER_UNLOCK(prAdapter, 0); |
| return; |
| } |
| |
| DBGLOG(QM, TRACE, "QM:(Bub Check Event Got) STA[%u] TID[%u]\n", |
| prReorderQueParm->ucStaRecIdx, prReorderQueParm->ucTid); |
| |
| /* Expected bubble timeout => pop out packets before win_end */ |
| if (prReorderQueParm->u2FirstBubbleSn == prReorderQueParm->u2WinStart) { |
| prReorderedSwRfb = (P_SW_RFB_T)QUEUE_GET_TAIL(prReorderQue); |
| |
| prReorderQueParm->u2WinStart = prReorderedSwRfb->u2SSN + 1; |
| if (prReorderQueParm->u2WinStart >= MAX_SEQ_NO_COUNT) |
| prReorderQueParm->u2WinStart %= MAX_SEQ_NO_COUNT; |
| |
| prReorderQueParm->u2WinEnd = |
| ((prReorderQueParm->u2WinStart) + (prReorderQueParm->u2WinSize) - 1) % MAX_SEQ_NO_COUNT; |
| #if CFG_SUPPORT_RX_AMSDU |
| prReorderQueParm->u8LastAmsduSubIdx = RX_PAYLOAD_FORMAT_MSDU; |
| #endif |
| qmPopOutDueToFallAhead(prAdapter, prReorderQueParm, prReturnedQue); |
| |
| DBGLOG(QM, TRACE, |
| "QM:(Bub Flush) STA[%u] TID[%u] BubSN[%u] Win{%u,%u}\n", |
| prReorderQueParm->ucStaRecIdx, prReorderQueParm->ucTid, |
| prReorderQueParm->u2FirstBubbleSn, |
| prReorderQueParm->u2WinStart, |
| prReorderQueParm->u2WinEnd); |
| |
| prReorderQueParm->fgHasBubble = FALSE; |
| RX_DIRECT_REORDER_UNLOCK(prAdapter, 0); |
| |
| /* process prReturnedQue after unlock prReturnedQue */ |
| if (QUEUE_IS_NOT_EMPTY(prReturnedQue)) { |
| P_QUE_ENTRY_T prTail = QUEUE_GET_TAIL(prReturnedQue); |
| |
| QM_RX_SET_NEXT_SW_RFB((P_SW_RFB_T)prTail, NULL); |
| |
| prSwRfb = (P_SW_RFB_T) QUEUE_GET_HEAD(prReturnedQue); |
| while (prSwRfb) { |
| DBGLOG(QM, TRACE, |
| "QM:(Bub Flush) STA[%u] TID[%u] Pop Out SN[%u]\n", |
| prReorderQueParm->ucStaRecIdx, prReorderQueParm->ucTid, prSwRfb->u2SSN); |
| |
| prSwRfb = (P_SW_RFB_T) QUEUE_GET_NEXT_ENTRY((P_QUE_ENTRY_T) prSwRfb); |
| } |
| |
| wlanProcessQueuedSwRfb(prAdapter, (P_SW_RFB_T) QUEUE_GET_HEAD(prReturnedQue)); |
| } else { |
| DBGLOG(QM, TRACE, "QM:(Bub Flush) STA[%u] TID[%u] Pop Out 0 packet\n", |
| prReorderQueParm->ucStaRecIdx, prReorderQueParm->ucTid); |
| } |
| } |
| /* First bubble has been filled but others exist */ |
| else { |
| prReorderQueParm->u2FirstBubbleSn = prReorderQueParm->u2WinStart; |
| DBGLOG(QM, TRACE, |
| "QM:(Bub Timer) STA[%u] TID[%u] BubSN[%u] Win{%u,%u}\n", |
| prReorderQueParm->ucStaRecIdx, prReorderQueParm->ucTid, |
| prReorderQueParm->u2FirstBubbleSn, |
| prReorderQueParm->u2WinStart, |
| prReorderQueParm->u2WinEnd); |
| RX_DIRECT_REORDER_UNLOCK(prAdapter, 0); |
| |
| cnmTimerStartTimer(prAdapter, |
| &(prReorderQueParm->rReorderBubbleTimer), |
| QM_RX_BA_ENTRY_MISS_TIMEOUT_MS); |
| } |
| |
| prMissTimeout = &g_arMissTimeout[prReorderQueParm->ucStaRecIdx][prReorderQueParm->ucTid]; |
| if (QUEUE_IS_EMPTY(prReorderQue)) { |
| DBGLOG(QM, TRACE, "QM:(Bub Check) Reset prMissTimeout to zero\n"); |
| *prMissTimeout = 0; |
| } else { |
| DBGLOG(QM, TRACE, "QM:(Bub Check) Reset prMissTimeout to current time\n"); |
| GET_CURRENT_SYSTIME(prMissTimeout); |
| } |
| } |
| |
| BOOLEAN qmCompareSnIsLessThan(IN UINT_32 u4SnLess, IN UINT_32 u4SnGreater) |
| { |
| /* 0 <---> SnLess <--(gap>2048)--> SnGreater : SnLess > SnGreater */ |
| if ((u4SnLess + HALF_SEQ_NO_COUNT) <= u4SnGreater) /* Shall be <= */ |
| return FALSE; |
| |
| /* 0 <---> SnGreater <--(gap>2048)--> SnLess : SnLess < SnGreater */ |
| else if ((u4SnGreater + HALF_SEQ_NO_COUNT) < u4SnLess) |
| return TRUE; |
| |
| /* 0 <---> SnGreater <--(gap<2048)--> SnLess : SnLess > SnGreater */ |
| /* 0 <---> SnLess <--(gap<2048)--> SnGreater : SnLess < SnGreater */ |
| else |
| return u4SnLess < u4SnGreater; |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief Handle Mailbox RX messages |
| * |
| * \param[in] prMailboxRxMsg The received Mailbox message from the FW |
| * |
| * \return (none) |
| */ |
| /*----------------------------------------------------------------------------*/ |
| VOID qmHandleMailboxRxMessage(IN MAILBOX_MSG_T prMailboxRxMsg) |
| { |
| /* DbgPrint("QM: Enter qmHandleMailboxRxMessage()\n"); */ |
| /* TODO */ |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief Handle ADD RX BA Event from the FW |
| * |
| * \param[in] prAdapter Adapter pointer |
| * \param[in] prEvent The event packet from the FW |
| * |
| * \return (none) |
| */ |
| /*----------------------------------------------------------------------------*/ |
| VOID qmHandleEventRxAddBa(IN P_ADAPTER_T prAdapter, IN P_WIFI_EVENT_T prEvent) |
| { |
| P_EVENT_RX_ADDBA_T prEventRxAddBa; |
| P_STA_RECORD_T prStaRec; |
| UINT_32 u4Tid; |
| UINT_32 u4WinSize; |
| |
| DBGLOG(QM, INFO, "QM:Event +RxBa\n"); |
| |
| prEventRxAddBa = (P_EVENT_RX_ADDBA_T) (prEvent->aucBuffer); |
| prStaRec = QM_GET_STA_REC_PTR_FROM_INDEX(prAdapter, prEventRxAddBa->ucStaRecIdx); |
| |
| if (!prStaRec) { |
| /* Invalid STA_REC index, discard the event packet */ |
| /* ASSERT(0); */ |
| DBGLOG(QM, INFO, "QM: (Warning) RX ADDBA Event for a NULL STA_REC\n"); |
| return; |
| } |
| #if 0 |
| if (!(prStaRec->fgIsValid)) { |
| /* TODO: (Tehuang) Handle the Host-FW synchronization issue */ |
| DBGLOG(QM, WARN, "QM: (Warning) RX ADDBA Event for an invalid STA_REC\n"); |
| /* ASSERT(0); */ |
| /* return; */ |
| } |
| #endif |
| |
| u4Tid = (((prEventRxAddBa->u2BAParameterSet) & BA_PARAM_SET_TID_MASK) |
| >> BA_PARAM_SET_TID_MASK_OFFSET); |
| |
| u4WinSize = (((prEventRxAddBa->u2BAParameterSet) & BA_PARAM_SET_BUFFER_SIZE_MASK) |
| >> BA_PARAM_SET_BUFFER_SIZE_MASK_OFFSET); |
| |
| if (!qmAddRxBaEntry(prAdapter, |
| prStaRec->ucIndex, |
| (UINT_8) u4Tid, |
| (prEventRxAddBa->u2BAStartSeqCtrl >> OFFSET_BAR_SSC_SN), (UINT_16) u4WinSize)) { |
| |
| /* FW shall ensure the availabiilty of the free-to-use BA entry */ |
| DBGLOG(QM, ERROR, "QM: (Error) qmAddRxBaEntry() failure\n"); |
| ASSERT(0); |
| } |
| |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief Handle DEL RX BA Event from the FW |
| * |
| * \param[in] prAdapter Adapter pointer |
| * \param[in] prEvent The event packet from the FW |
| * |
| * \return (none) |
| */ |
| /*----------------------------------------------------------------------------*/ |
| VOID qmHandleEventRxDelBa(IN P_ADAPTER_T prAdapter, IN P_WIFI_EVENT_T prEvent) |
| { |
| P_EVENT_RX_DELBA_T prEventRxDelBa; |
| P_STA_RECORD_T prStaRec; |
| |
| /* DbgPrint("QM:Event -RxBa\n"); */ |
| |
| prEventRxDelBa = (P_EVENT_RX_DELBA_T) (prEvent->aucBuffer); |
| prStaRec = QM_GET_STA_REC_PTR_FROM_INDEX(prAdapter, prEventRxDelBa->ucStaRecIdx); |
| |
| if (!prStaRec) |
| /* Invalid STA_REC index, discard the event packet */ |
| /* ASSERT(0); */ |
| return; |
| #if 0 |
| if (!(prStaRec->fgIsValid)) |
| /* TODO: (Tehuang) Handle the Host-FW synchronization issue */ |
| /* ASSERT(0); */ |
| return; |
| #endif |
| |
| qmDelRxBaEntry(prAdapter, prStaRec->ucIndex, prEventRxDelBa->ucTid, TRUE); |
| |
| } |
| |
| P_RX_BA_ENTRY_T qmLookupRxBaEntry(IN P_ADAPTER_T prAdapter, UINT_8 ucStaRecIdx, UINT_8 ucTid) |
| { |
| int i; |
| P_QUE_MGT_T prQM = &prAdapter->rQM; |
| |
| /* DbgPrint("QM: Enter qmLookupRxBaEntry()\n"); */ |
| |
| for (i = 0; i < CFG_NUM_OF_RX_BA_AGREEMENTS; i++) { |
| if (prQM->arRxBaTable[i].fgIsValid) { |
| if ((prQM->arRxBaTable[i].ucStaRecIdx == ucStaRecIdx) && (prQM->arRxBaTable[i].ucTid == ucTid)) |
| return &prQM->arRxBaTable[i]; |
| } |
| } |
| return NULL; |
| } |
| |
| BOOL |
| qmAddRxBaEntry(IN P_ADAPTER_T prAdapter, |
| IN UINT_8 ucStaRecIdx, IN UINT_8 ucTid, IN UINT_16 u2WinStart, IN UINT_16 u2WinSize) |
| { |
| int i; |
| P_RX_BA_ENTRY_T prRxBaEntry = NULL; |
| P_STA_RECORD_T prStaRec; |
| P_QUE_MGT_T prQM = &prAdapter->rQM; |
| |
| ASSERT(ucStaRecIdx < CFG_STA_REC_NUM); |
| |
| if (ucStaRecIdx >= CFG_STA_REC_NUM) { |
| /* Invalid STA_REC index, discard the event packet */ |
| DBGLOG(QM, WARN, "QM: (WARNING) RX ADDBA Event for a invalid ucStaRecIdx = %d\n", ucStaRecIdx); |
| return FALSE; |
| } |
| |
| prStaRec = &prAdapter->arStaRec[ucStaRecIdx]; |
| ASSERT(prStaRec); |
| |
| /* if(!(prStaRec->fgIsValid)){ */ |
| /* DbgPrint("QM: (WARNING) Invalid STA when adding an RX BA\n"); */ |
| /* return FALSE; */ |
| /* } */ |
| |
| /* 4 <1> Delete before adding */ |
| /* Remove the BA entry for the same (STA, TID) tuple if it exists */ |
| if (qmLookupRxBaEntry(prAdapter, ucStaRecIdx, ucTid)) |
| qmDelRxBaEntry(prAdapter, ucStaRecIdx, ucTid, TRUE); /* prQM->ucRxBaCount-- */ |
| /* 4 <2> Add a new BA entry */ |
| /* No available entry to store the BA agreement info. Retrun FALSE. */ |
| if (prQM->ucRxBaCount >= CFG_NUM_OF_RX_BA_AGREEMENTS) { |
| DBGLOG(QM, ERROR, "QM: **failure** (limited resource, ucRxBaCount=%d)\n", prQM->ucRxBaCount); |
| return FALSE; |
| } |
| /* Find the free-to-use BA entry */ |
| for (i = 0; i < CFG_NUM_OF_RX_BA_AGREEMENTS; i++) { |
| if (!prQM->arRxBaTable[i].fgIsValid) { |
| prRxBaEntry = &(prQM->arRxBaTable[i]); |
| prQM->ucRxBaCount++; |
| DBGLOG(QM, LOUD, "QM: ucRxBaCount=%d\n", prQM->ucRxBaCount); |
| break; |
| } |
| } |
| |
| /* If a free-to-use entry is found, configure it and associate it with the STA_REC */ |
| u2WinSize += CFG_RX_BA_INC_SIZE; |
| if (prRxBaEntry) { |
| prRxBaEntry->ucStaRecIdx = ucStaRecIdx; |
| prRxBaEntry->ucTid = ucTid; |
| prRxBaEntry->u2WinStart = u2WinStart; |
| prRxBaEntry->u2WinSize = u2WinSize; |
| prRxBaEntry->u2WinEnd = ((u2WinStart + u2WinSize - 1) % MAX_SEQ_NO_COUNT); |
| #if CFG_SUPPORT_RX_AMSDU |
| /* RX reorder for one MSDU in AMSDU issue */ |
| prRxBaEntry->u8LastAmsduSubIdx = RX_PAYLOAD_FORMAT_MSDU; |
| prRxBaEntry->fgAmsduNeedLastFrame = FALSE; |
| prRxBaEntry->fgIsAmsduDuplicated = FALSE; |
| #endif |
| prRxBaEntry->fgIsValid = TRUE; |
| prRxBaEntry->fgIsWaitingForPktWithSsn = TRUE; |
| prRxBaEntry->fgHasBubble = FALSE; |
| |
| g_arMissTimeout[ucStaRecIdx][ucTid] = 0; |
| |
| DBGLOG(QM, INFO, |
| "QM: +RxBA(STA=%u TID=%u WinStart=%u WinEnd=%u WinSize=%u)\n", |
| ucStaRecIdx, ucTid, prRxBaEntry->u2WinStart, |
| prRxBaEntry->u2WinEnd, prRxBaEntry->u2WinSize); |
| |
| /* Update the BA entry reference table for per-packet lookup */ |
| prStaRec->aprRxReorderParamRefTbl[ucTid] = prRxBaEntry; |
| } else { |
| /* This shall not happen because FW should keep track of the usage of RX BA entries */ |
| DBGLOG(QM, ERROR, "QM: **AddBA Error** (ucRxBaCount=%d)\n", prQM->ucRxBaCount); |
| return FALSE; |
| } |
| |
| |
| return TRUE; |
| } |
| |
| VOID qmDelRxBaEntry(IN P_ADAPTER_T prAdapter, IN UINT_8 ucStaRecIdx, IN UINT_8 ucTid, IN BOOLEAN fgFlushToHost) |
| { |
| P_RX_BA_ENTRY_T prRxBaEntry; |
| P_STA_RECORD_T prStaRec; |
| P_SW_RFB_T prFlushedPacketList = NULL; |
| P_QUE_MGT_T prQM = &prAdapter->rQM; |
| |
| ASSERT(ucStaRecIdx < CFG_STA_REC_NUM); |
| |
| prStaRec = &prAdapter->arStaRec[ucStaRecIdx]; |
| ASSERT(prStaRec); |
| |
| #if 0 |
| if (!(prStaRec->fgIsValid)) { |
| DbgPrint("QM: (WARNING) Invalid STA when deleting an RX BA\n"); |
| return; |
| } |
| #endif |
| |
| /* Remove the BA entry for the same (STA, TID) tuple if it exists */ |
| prRxBaEntry = prStaRec->aprRxReorderParamRefTbl[ucTid]; |
| |
| if (prRxBaEntry) { |
| |
| prFlushedPacketList = qmFlushStaRxQueue(prAdapter, ucStaRecIdx, ucTid); |
| |
| if (prFlushedPacketList) { |
| |
| if (fgFlushToHost) { |
| wlanProcessQueuedSwRfb(prAdapter, prFlushedPacketList); |
| } else { |
| |
| P_SW_RFB_T prSwRfb; |
| P_SW_RFB_T prNextSwRfb; |
| |
| prSwRfb = prFlushedPacketList; |
| |
| do { |
| prNextSwRfb = (P_SW_RFB_T) QUEUE_GET_NEXT_ENTRY((P_QUE_ENTRY_T) |
| prSwRfb); |
| nicRxReturnRFB(prAdapter, prSwRfb); |
| prSwRfb = prNextSwRfb; |
| } while (prSwRfb); |
| |
| } |
| |
| } |
| |
| if (prRxBaEntry->fgHasBubble) { |
| DBGLOG(QM, TRACE, "QM:(Bub Check Cancel) STA[%u] TID[%u], DELBA\n", |
| prRxBaEntry->ucStaRecIdx, prRxBaEntry->ucTid); |
| |
| cnmTimerStopTimer(prAdapter, &prRxBaEntry->rReorderBubbleTimer); |
| prRxBaEntry->fgHasBubble = FALSE; |
| } |
| #if ((QM_TEST_MODE == 0) && (QM_TEST_STA_REC_DEACTIVATION == 0)) |
| /* Update RX BA entry state. Note that RX queue flush is not done here */ |
| prRxBaEntry->fgIsValid = FALSE; |
| prQM->ucRxBaCount--; |
| |
| /* Debug */ |
| #if 0 |
| DbgPrint("QM: ucRxBaCount=%d\n", prQM->ucRxBaCount); |
| #endif |
| |
| /* Update STA RX BA table */ |
| prStaRec->aprRxReorderParamRefTbl[ucTid] = NULL; |
| #endif |
| |
| DBGLOG(QM, INFO, "QM: -RxBA(STA=%d,TID=%d)\n", ucStaRecIdx, ucTid); |
| |
| } |
| |
| /* Debug */ |
| #if CFG_HIF_RX_STARVATION_WARNING |
| { |
| P_RX_CTRL_T prRxCtrl; |
| |
| prRxCtrl = &prAdapter->rRxCtrl; |
| DBGLOG(QM, TRACE, |
| "QM: (RX DEBUG) Enqueued: %d / Dequeued: %d\n", prRxCtrl->u4QueuedCnt, prRxCtrl->u4DequeuedCnt); |
| } |
| #endif |
| } |
| |
| VOID mqmParseAssocReqWmmIe(IN P_ADAPTER_T prAdapter, IN PUINT_8 pucIE, IN P_STA_RECORD_T prStaRec) |
| { |
| P_IE_WMM_INFO_T prIeWmmInfo; |
| UINT_8 ucQosInfo; |
| UINT_8 ucQosInfoAC; |
| UINT_8 ucBmpAC; |
| UINT_8 aucWfaOui[] = VENDOR_OUI_WFA; |
| |
| if ((WMM_IE_OUI_TYPE(pucIE) == VENDOR_OUI_TYPE_WMM) && (!kalMemCmp(WMM_IE_OUI(pucIE), aucWfaOui, 3))) { |
| |
| switch (WMM_IE_OUI_SUBTYPE(pucIE)) { |
| case VENDOR_OUI_SUBTYPE_WMM_INFO: |
| if (IE_LEN(pucIE) != 7) |
| break; /* WMM Info IE with a wrong length */ |
| |
| prStaRec->fgIsQoS = TRUE; |
| prStaRec->fgIsWmmSupported = TRUE; |
| |
| prIeWmmInfo = (P_IE_WMM_INFO_T) pucIE; |
| ucQosInfo = prIeWmmInfo->ucQosInfo; |
| ucQosInfoAC = ucQosInfo & BITS(0, 3); |
| |
| if (IS_FEATURE_ENABLED(prAdapter->rWifiVar.ucUapsd)) |
| prStaRec->fgIsUapsdSupported = (ucQosInfoAC) ? TRUE : FALSE; |
| else |
| prStaRec->fgIsUapsdSupported = FALSE; |
| |
| ucBmpAC = 0; |
| |
| if (ucQosInfoAC & WMM_QOS_INFO_VO_UAPSD) |
| ucBmpAC |= BIT(ACI_VO); |
| |
| if (ucQosInfoAC & WMM_QOS_INFO_VI_UAPSD) |
| ucBmpAC |= BIT(ACI_VI); |
| |
| if (ucQosInfoAC & WMM_QOS_INFO_BE_UAPSD) |
| ucBmpAC |= BIT(ACI_BE); |
| |
| if (ucQosInfoAC & WMM_QOS_INFO_BK_UAPSD) |
| ucBmpAC |= BIT(ACI_BK); |
| prStaRec->ucBmpTriggerAC = prStaRec->ucBmpDeliveryAC = ucBmpAC; |
| prStaRec->ucUapsdSp = (ucQosInfo & WMM_QOS_INFO_MAX_SP_LEN_MASK) >> 5; |
| break; |
| |
| default: |
| /* Other WMM QoS IEs. Ignore any */ |
| break; |
| } |
| } |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief To process WMM related IEs in ASSOC_RSP |
| * |
| * \param[in] prAdapter Adapter pointer |
| * \param[in] prSwRfb The received frame |
| * \param[in] pucIE The pointer to the first IE in the frame |
| * \param[in] u2IELength The total length of IEs in the frame |
| * |
| * \return none |
| */ |
| /*----------------------------------------------------------------------------*/ |
| VOID mqmProcessAssocReq(IN P_ADAPTER_T prAdapter, IN P_SW_RFB_T prSwRfb, IN PUINT_8 pucIE, IN UINT_16 u2IELength) |
| { |
| P_STA_RECORD_T prStaRec; |
| UINT_16 u2Offset; |
| PUINT_8 pucIEStart; |
| UINT_32 u4Flags; |
| |
| DEBUGFUNC("mqmProcessAssocReq"); |
| |
| ASSERT(prSwRfb); |
| ASSERT(pucIE); |
| |
| prStaRec = cnmGetStaRecByIndex(prAdapter, prSwRfb->ucStaRecIdx); |
| ASSERT(prStaRec); |
| |
| if (prStaRec == NULL) |
| return; |
| |
| prStaRec->fgIsQoS = FALSE; |
| prStaRec->fgIsWmmSupported = prStaRec->fgIsUapsdSupported = FALSE; |
| |
| pucIEStart = pucIE; |
| |
| /* If the device does not support QoS or if WMM is not supported by the peer, exit. */ |
| if (IS_FEATURE_DISABLED(prAdapter->rWifiVar.ucQoS)) |
| return; |
| |
| /* Determine whether QoS is enabled with the association */ |
| else { |
| prStaRec->u4Flags = 0; |
| IE_FOR_EACH(pucIE, u2IELength, u2Offset) { |
| switch (IE_ID(pucIE)) { |
| case ELEM_ID_VENDOR: |
| mqmParseAssocReqWmmIe(prAdapter, pucIE, prStaRec); |
| |
| #if CFG_SUPPORT_MTK_SYNERGY |
| if (rlmParseCheckMTKOuiIE(prAdapter, pucIE, &u4Flags)) |
| prStaRec->u4Flags = u4Flags; |
| #endif |
| |
| break; |
| |
| case ELEM_ID_HT_CAP: |
| /* Some client won't put the WMM IE if client is 802.11n */ |
| if (IE_LEN(pucIE) == (sizeof(IE_HT_CAP_T) - 2)) |
| prStaRec->fgIsQoS = TRUE; |
| break; |
| default: |
| break; |
| } |
| } |
| |
| DBGLOG(QM, TRACE, "MQM: Assoc_Req Parsing (QoS Enabled=%d)\n", prStaRec->fgIsQoS); |
| |
| } |
| } |
| |
| VOID mqmParseAssocRspWmmIe(IN PUINT_8 pucIE, IN P_STA_RECORD_T prStaRec) |
| { |
| UINT_8 aucWfaOui[] = VENDOR_OUI_WFA; |
| |
| if ((WMM_IE_OUI_TYPE(pucIE) == VENDOR_OUI_TYPE_WMM) && (!kalMemCmp(WMM_IE_OUI(pucIE), aucWfaOui, 3))) { |
| |
| switch (WMM_IE_OUI_SUBTYPE(pucIE)) { |
| case VENDOR_OUI_SUBTYPE_WMM_PARAM: |
| if (IE_LEN(pucIE) != 24) |
| break; /* WMM Info IE with a wrong length */ |
| prStaRec->fgIsQoS = TRUE; |
| break; |
| |
| case VENDOR_OUI_SUBTYPE_WMM_INFO: |
| if (IE_LEN(pucIE) != 7) |
| break; /* WMM Info IE with a wrong length */ |
| prStaRec->fgIsQoS = TRUE; |
| break; |
| |
| default: |
| /* Other WMM QoS IEs. Ignore any */ |
| break; |
| } |
| } |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief To process WMM related IEs in ASSOC_RSP |
| * |
| * \param[in] prAdapter Adapter pointer |
| * \param[in] prSwRfb The received frame |
| * \param[in] pucIE The pointer to the first IE in the frame |
| * \param[in] u2IELength The total length of IEs in the frame |
| * |
| * \return none |
| */ |
| /*----------------------------------------------------------------------------*/ |
| VOID mqmProcessAssocRsp(IN P_ADAPTER_T prAdapter, IN P_SW_RFB_T prSwRfb, IN PUINT_8 pucIE, IN UINT_16 u2IELength) |
| { |
| P_STA_RECORD_T prStaRec; |
| UINT_16 u2Offset; |
| PUINT_8 pucIEStart; |
| UINT_32 u4Flags; |
| |
| DEBUGFUNC("mqmProcessAssocRsp"); |
| |
| ASSERT(prSwRfb); |
| ASSERT(pucIE); |
| |
| prStaRec = cnmGetStaRecByIndex(prAdapter, prSwRfb->ucStaRecIdx); |
| ASSERT(prStaRec); |
| |
| if (prStaRec == NULL) |
| return; |
| |
| prStaRec->fgIsQoS = FALSE; |
| |
| pucIEStart = pucIE; |
| |
| DBGLOG(QM, TRACE, "QM: (fgIsWmmSupported=%d, fgSupportQoS=%d)\n", |
| prStaRec->fgIsWmmSupported, prAdapter->rWifiVar.ucQoS); |
| |
| /* If the device does not support QoS or if WMM is not supported by the peer, exit. */ |
| /* if((!prAdapter->rWifiVar.fgSupportQoS) || (!prStaRec->fgIsWmmSupported)) */ |
| if (IS_FEATURE_DISABLED(prAdapter->rWifiVar.ucQoS)) |
| return; |
| |
| /* Determine whether QoS is enabled with the association */ |
| else { |
| prStaRec->u4Flags = 0; |
| IE_FOR_EACH(pucIE, u2IELength, u2Offset) { |
| switch (IE_ID(pucIE)) { |
| case ELEM_ID_VENDOR: |
| /* Process WMM related IE */ |
| mqmParseAssocRspWmmIe(pucIE, prStaRec); |
| |
| #if CFG_SUPPORT_MTK_SYNERGY |
| if (rlmParseCheckMTKOuiIE(prAdapter, pucIE, &u4Flags)) |
| prStaRec->u4Flags = u4Flags; |
| #endif |
| |
| break; |
| |
| case ELEM_ID_HT_CAP: |
| /* Some AP won't put the WMM IE if client is 802.11n */ |
| if (IE_LEN(pucIE) == (sizeof(IE_HT_CAP_T) - 2)) |
| prStaRec->fgIsQoS = TRUE; |
| break; |
| default: |
| break; |
| } |
| } |
| |
| /* Parse AC parameters and write to HW CRs */ |
| if ((prStaRec->fgIsQoS) && (prStaRec->eStaType == STA_TYPE_LEGACY_AP)) |
| mqmParseEdcaParameters(prAdapter, prSwRfb, pucIEStart, u2IELength, TRUE); |
| |
| DBGLOG(QM, TRACE, "MQM: Assoc_Rsp Parsing (QoS Enabled=%d)\n", prStaRec->fgIsQoS); |
| if (prStaRec->fgIsWmmSupported) |
| nicQmUpdateWmmParms(prAdapter, prStaRec->ucBssIndex); |
| } |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief |
| * |
| * \param[in] |
| * |
| * \return none |
| */ |
| /*----------------------------------------------------------------------------*/ |
| VOID mqmProcessBcn(IN P_ADAPTER_T prAdapter, IN P_SW_RFB_T prSwRfb, IN PUINT_8 pucIE, IN UINT_16 u2IELength) |
| { |
| P_BSS_INFO_T prBssInfo; |
| BOOLEAN fgNewParameter; |
| UINT_8 i; |
| |
| ASSERT(prAdapter); |
| ASSERT(prSwRfb); |
| ASSERT(pucIE); |
| |
| DBGLOG(QM, TRACE, "Enter %s\n", __func__); |
| |
| fgNewParameter = FALSE; |
| |
| for (i = 0; i < BSS_INFO_NUM; i++) { |
| prBssInfo = GET_BSS_INFO_BY_INDEX(prAdapter, i); |
| |
| if (IS_BSS_ACTIVE(prBssInfo)) { |
| if (prBssInfo->eCurrentOPMode == OP_MODE_INFRASTRUCTURE && |
| prBssInfo->eConnectionState == PARAM_MEDIA_STATE_CONNECTED) { |
| /* P2P client or AIS infra STA */ |
| if (EQUAL_MAC_ADDR(prBssInfo->aucBSSID, ((P_WLAN_MAC_MGMT_HEADER_T) |
| (prSwRfb->pvHeader))->aucBSSID)) { |
| |
| fgNewParameter = mqmParseEdcaParameters(prAdapter, |
| prSwRfb, pucIE, u2IELength, FALSE); |
| } |
| } |
| |
| /* Appy new parameters if necessary */ |
| if (fgNewParameter) { |
| /* DBGLOG(QM, INFO, ("Update EDCA parameter for BSS[%u]\n", prBssInfo->ucBssIndex)); */ |
| nicQmUpdateWmmParms(prAdapter, prBssInfo->ucBssIndex); |
| fgNewParameter = FALSE; |
| } |
| } /* end of IS_BSS_ACTIVE() */ |
| } |
| } |
| |
| BOOLEAN mqmUpdateEdcaParameters(IN P_BSS_INFO_T prBssInfo, IN PUINT_8 pucIE, IN BOOLEAN fgForceOverride) |
| { |
| P_AC_QUE_PARMS_T prAcQueParams; |
| P_IE_WMM_PARAM_T prIeWmmParam; |
| ENUM_WMM_ACI_T eAci; |
| BOOLEAN fgNewParameter = FALSE; |
| |
| do { |
| if (IE_LEN(pucIE) != 24) |
| break; /* WMM Param IE with a wrong length */ |
| |
| prIeWmmParam = (P_IE_WMM_PARAM_T) pucIE; |
| |
| /* Check the Parameter Set Count to determine whether EDCA parameters have been changed */ |
| if (!fgForceOverride) { |
| if (mqmCompareEdcaParameters(prIeWmmParam, prBssInfo)) { |
| fgNewParameter = FALSE; |
| break; |
| } |
| } |
| |
| fgNewParameter = TRUE; |
| /* Update Parameter Set Count */ |
| prBssInfo->ucWmmParamSetCount = (prIeWmmParam->ucQosInfo & WMM_QOS_INFO_PARAM_SET_CNT); |
| /* Update EDCA parameters */ |
| for (eAci = 0; eAci < WMM_AC_INDEX_NUM; eAci++) { |
| prAcQueParams = &prBssInfo->arACQueParms[eAci]; |
| mqmFillAcQueParam(prIeWmmParam, eAci, prAcQueParams); |
| DBGLOG(QM, INFO, |
| "BSS[%u]: eAci[%d] ACM[%d] Aifsn[%d] CWmin/max[%d/%d] TxopLimit[%d] NewParameter[%d]\n", |
| prBssInfo->ucBssIndex, eAci, prAcQueParams->ucIsACMSet, |
| prAcQueParams->u2Aifsn, prAcQueParams->u2CWmin, prAcQueParams->u2CWmax, |
| prAcQueParams->u2TxopLimit, fgNewParameter); |
| } |
| } while (FALSE); |
| |
| return fgNewParameter; |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief To parse WMM Parameter IE (in BCN or Assoc_Rsp) |
| * |
| * \param[in] prAdapter Adapter pointer |
| * \param[in] prSwRfb The received frame |
| * \param[in] pucIE The pointer to the first IE in the frame |
| * \param[in] u2IELength The total length of IEs in the frame |
| * \param[in] fgForceOverride TRUE: If EDCA parameters are found, always set to HW CRs. |
| * |
| * \return none |
| */ |
| /*----------------------------------------------------------------------------*/ |
| BOOLEAN |
| mqmParseEdcaParameters(IN P_ADAPTER_T prAdapter, |
| IN P_SW_RFB_T prSwRfb, IN PUINT_8 pucIE, IN UINT_16 u2IELength, IN BOOLEAN fgForceOverride) |
| { |
| P_STA_RECORD_T prStaRec; |
| UINT_16 u2Offset; |
| UINT_8 aucWfaOui[] = VENDOR_OUI_WFA; |
| P_BSS_INFO_T prBssInfo; |
| BOOLEAN fgNewParameter = FALSE; |
| |
| DEBUGFUNC("mqmParseEdcaParameters"); |
| |
| if (!prSwRfb) |
| return FALSE; |
| |
| if (!pucIE) |
| return FALSE; |
| |
| prStaRec = cnmGetStaRecByIndex(prAdapter, prSwRfb->ucStaRecIdx); |
| /* ASSERT(prStaRec); */ |
| |
| if (prStaRec == NULL) |
| return FALSE; |
| |
| DBGLOG(QM, TRACE, "QM: (fgIsWmmSupported=%d, fgIsQoS=%d)\n", prStaRec->fgIsWmmSupported, prStaRec->fgIsQoS); |
| |
| if (IS_FEATURE_DISABLED(prAdapter->rWifiVar.ucQoS) || (!prStaRec->fgIsWmmSupported) |
| || (!prStaRec->fgIsQoS)) |
| return FALSE; |
| |
| prBssInfo = GET_BSS_INFO_BY_INDEX(prAdapter, prStaRec->ucBssIndex); |
| |
| /* Goal: Obtain the EDCA parameters */ |
| IE_FOR_EACH(pucIE, u2IELength, u2Offset) { |
| switch (IE_ID(pucIE)) { |
| case ELEM_ID_WMM: |
| if (!((WMM_IE_OUI_TYPE(pucIE) == VENDOR_OUI_TYPE_WMM) && |
| (!kalMemCmp(WMM_IE_OUI(pucIE), aucWfaOui, 3)))) |
| break; |
| |
| switch (WMM_IE_OUI_SUBTYPE(pucIE)) { |
| case VENDOR_OUI_SUBTYPE_WMM_PARAM: |
| fgNewParameter = mqmUpdateEdcaParameters(prBssInfo, pucIE, fgForceOverride); |
| break; |
| |
| default: |
| /* Other WMM QoS IEs. Ignore */ |
| break; |
| } |
| |
| /* else: VENDOR_OUI_TYPE_WPA, VENDOR_OUI_TYPE_WPS, ... (not cared) */ |
| break; |
| default: |
| break; |
| } |
| } |
| |
| return fgNewParameter; |
| } |
| |
| BOOLEAN mqmCompareEdcaParameters(IN P_IE_WMM_PARAM_T prIeWmmParam, IN P_BSS_INFO_T prBssInfo) |
| { |
| P_AC_QUE_PARMS_T prAcQueParams; |
| P_WMM_AC_PARAM_T prWmmAcParams; |
| ENUM_WMM_ACI_T eAci; |
| |
| /* return FALSE; */ |
| |
| /* Check Set Count */ |
| if (prBssInfo->ucWmmParamSetCount != (prIeWmmParam->ucQosInfo & WMM_QOS_INFO_PARAM_SET_CNT)) |
| return FALSE; |
| |
| for (eAci = 0; eAci < WMM_AC_INDEX_NUM; eAci++) { |
| prAcQueParams = &prBssInfo->arACQueParms[eAci]; |
| prWmmAcParams = &prIeWmmParam->arAcParam[eAci]; |
| |
| /* ACM */ |
| if (prAcQueParams->ucIsACMSet != ((prWmmAcParams->ucAciAifsn & WMM_ACIAIFSN_ACM) ? TRUE : FALSE)) |
| return FALSE; |
| |
| /* AIFSN */ |
| if (prAcQueParams->u2Aifsn != (prWmmAcParams->ucAciAifsn & WMM_ACIAIFSN_AIFSN)) |
| return FALSE; |
| |
| /* CW Max */ |
| if (prAcQueParams->u2CWmax != |
| (BIT((prWmmAcParams->ucEcw & WMM_ECW_WMAX_MASK) >> WMM_ECW_WMAX_OFFSET) - 1)) |
| return FALSE; |
| |
| /* CW Min */ |
| if (prAcQueParams->u2CWmin != (BIT(prWmmAcParams->ucEcw & WMM_ECW_WMIN_MASK) - 1)) |
| return FALSE; |
| |
| if (prAcQueParams->u2TxopLimit != prWmmAcParams->u2TxopLimit) |
| return FALSE; |
| } |
| |
| return TRUE; |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief This function is used for parsing EDCA parameters specified in the WMM Parameter IE |
| * |
| * \param[in] prAdapter Adapter pointer |
| * \param[in] prIeWmmParam The pointer to the WMM Parameter IE |
| * \param[in] u4AcOffset The offset specifying the AC queue for parsing |
| * \param[in] prHwAcParams The parameter structure used to configure the HW CRs |
| * |
| * \return none |
| */ |
| /*----------------------------------------------------------------------------*/ |
| VOID mqmFillAcQueParam(IN P_IE_WMM_PARAM_T prIeWmmParam, IN UINT_32 u4AcOffset, OUT P_AC_QUE_PARMS_T prAcQueParams) |
| { |
| P_WMM_AC_PARAM_T prAcParam = &prIeWmmParam->arAcParam[u4AcOffset]; |
| |
| prAcQueParams->ucIsACMSet = (prAcParam->ucAciAifsn & WMM_ACIAIFSN_ACM) ? TRUE : FALSE; |
| |
| prAcQueParams->u2Aifsn = (prAcParam->ucAciAifsn & WMM_ACIAIFSN_AIFSN); |
| |
| prAcQueParams->u2CWmax = BIT((prAcParam->ucEcw & WMM_ECW_WMAX_MASK) >> WMM_ECW_WMAX_OFFSET) - 1; |
| |
| prAcQueParams->u2CWmin = BIT(prAcParam->ucEcw & WMM_ECW_WMIN_MASK) - 1; |
| |
| WLAN_GET_FIELD_16(&prAcParam->u2TxopLimit, &prAcQueParams->u2TxopLimit); |
| |
| prAcQueParams->ucGuradTime = TXM_DEFAULT_FLUSH_QUEUE_GUARD_TIME; |
| |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief To parse WMM/11n related IEs in scan results (only for AP peers) |
| * |
| * \param[in] prAdapter Adapter pointer |
| * \param[in] prScanResult The scan result which shall be parsed to obtain needed info |
| * \param[out] prStaRec The obtained info is stored in the STA_REC |
| * |
| * \return none |
| */ |
| /*----------------------------------------------------------------------------*/ |
| VOID mqmProcessScanResult(IN P_ADAPTER_T prAdapter, IN P_BSS_DESC_T prScanResult, OUT P_STA_RECORD_T prStaRec) |
| { |
| PUINT_8 pucIE; |
| UINT_16 u2IELength; |
| UINT_16 u2Offset; |
| UINT_8 aucWfaOui[] = VENDOR_OUI_WFA; |
| BOOLEAN fgIsHtVht; |
| |
| DEBUGFUNC("mqmProcessScanResult"); |
| |
| ASSERT(prScanResult); |
| ASSERT(prStaRec); |
| |
| /* Reset the flag before parsing */ |
| prStaRec->fgIsWmmSupported = FALSE; |
| prStaRec->fgIsUapsdSupported = FALSE; |
| prStaRec->fgIsQoS = FALSE; |
| |
| fgIsHtVht = FALSE; |
| |
| if (IS_FEATURE_DISABLED(prAdapter->rWifiVar.ucQoS)) |
| return; |
| |
| u2IELength = prScanResult->u2IELength; |
| pucIE = prScanResult->aucIEBuf; |
| |
| /* <1> Determine whether the peer supports WMM/QoS and UAPSDU */ |
| IE_FOR_EACH(pucIE, u2IELength, u2Offset) { |
| switch (IE_ID(pucIE)) { |
| |
| case ELEM_ID_EXTENDED_CAP: |
| #if CFG_SUPPORT_TDLS |
| TdlsBssExtCapParse(prStaRec, pucIE); |
| #endif /* CFG_SUPPORT_TDLS */ |
| break; |
| |
| case ELEM_ID_WMM: |
| if ((WMM_IE_OUI_TYPE(pucIE) == VENDOR_OUI_TYPE_WMM) && |
| (!kalMemCmp(WMM_IE_OUI(pucIE), aucWfaOui, 3))) { |
| |
| switch (WMM_IE_OUI_SUBTYPE(pucIE)) { |
| case VENDOR_OUI_SUBTYPE_WMM_PARAM: |
| if (IE_LEN(pucIE) != 24) |
| break; /* WMM Param IE with a wrong length */ |
| |
| prStaRec->fgIsWmmSupported = TRUE; |
| prStaRec->fgIsUapsdSupported = |
| (((((P_IE_WMM_PARAM_T)pucIE)->ucQosInfo) |
| & WMM_QOS_INFO_UAPSD) ? |
| TRUE : FALSE); |
| break; |
| |
| case VENDOR_OUI_SUBTYPE_WMM_INFO: |
| if (IE_LEN(pucIE) != 7) |
| break; /* WMM Info IE with a wrong length */ |
| |
| prStaRec->fgIsWmmSupported = TRUE; |
| prStaRec->fgIsUapsdSupported = |
| (((((P_IE_WMM_INFO_T) pucIE)->ucQosInfo) |
| & WMM_QOS_INFO_UAPSD) ? |
| TRUE : FALSE); |
| break; |
| |
| default: |
| /* A WMM QoS IE that doesn't matter. Ignore it. */ |
| break; |
| } |
| } |
| /* else: VENDOR_OUI_TYPE_WPA, VENDOR_OUI_TYPE_WPS, ... (not cared) */ |
| |
| break; |
| |
| default: |
| /* A WMM IE that doesn't matter. Ignore it. */ |
| break; |
| } |
| } |
| |
| /* <1> Determine QoS */ |
| if (prStaRec->ucDesiredPhyTypeSet & (PHY_TYPE_SET_802_11N | PHY_TYPE_SET_802_11AC)) |
| fgIsHtVht = TRUE; |
| |
| if (fgIsHtVht || prStaRec->fgIsWmmSupported) |
| prStaRec->fgIsQoS = TRUE; |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * @brief Generate the WMM Info IE by Param |
| * |
| * \param[in] prAdapter Adapter pointer |
| * @param prMsduInfo The TX MMPDU |
| * |
| * @return (none) |
| */ |
| /*----------------------------------------------------------------------------*/ |
| UINT_32 |
| mqmFillWmmInfoIE(P_UINT_8 pucOutBuf, |
| BOOLEAN fgSupportUAPSD, UINT_8 ucBmpDeliveryAC, UINT_8 ucBmpTriggerAC, UINT_8 ucUapsdSp) |
| { |
| P_IE_WMM_INFO_T prIeWmmInfo; |
| UINT_32 ucUapsd[] = { |
| WMM_QOS_INFO_BE_UAPSD, |
| WMM_QOS_INFO_BK_UAPSD, |
| WMM_QOS_INFO_VI_UAPSD, |
| WMM_QOS_INFO_VO_UAPSD |
| }; |
| UINT_8 aucWfaOui[] = VENDOR_OUI_WFA; |
| |
| ASSERT(pucOutBuf); |
| |
| prIeWmmInfo = (P_IE_WMM_INFO_T) pucOutBuf; |
| |
| prIeWmmInfo->ucId = ELEM_ID_WMM; |
| prIeWmmInfo->ucLength = ELEM_MAX_LEN_WMM_INFO; |
| |
| /* WMM-2.2.1 WMM Information Element Field Values */ |
| prIeWmmInfo->aucOui[0] = aucWfaOui[0]; |
| prIeWmmInfo->aucOui[1] = aucWfaOui[1]; |
| prIeWmmInfo->aucOui[2] = aucWfaOui[2]; |
| prIeWmmInfo->ucOuiType = VENDOR_OUI_TYPE_WMM; |
| prIeWmmInfo->ucOuiSubtype = VENDOR_OUI_SUBTYPE_WMM_INFO; |
| |
| prIeWmmInfo->ucVersion = VERSION_WMM; |
| prIeWmmInfo->ucQosInfo = 0; |
| |
| /* UAPSD initial queue configurations (delivery and trigger enabled) */ |
| if (fgSupportUAPSD) { |
| UINT_8 ucQosInfo = 0; |
| UINT_8 i; |
| |
| /* Static U-APSD setting */ |
| for (i = ACI_BE; i <= ACI_VO; i++) { |
| if (ucBmpDeliveryAC & ucBmpTriggerAC & BIT(i)) |
| ucQosInfo |= (UINT_8) ucUapsd[i]; |
| } |
| |
| if (ucBmpDeliveryAC & ucBmpTriggerAC) { |
| switch (ucUapsdSp) { |
| case WMM_MAX_SP_LENGTH_ALL: |
| ucQosInfo |= WMM_QOS_INFO_MAX_SP_ALL; |
| break; |
| |
| case WMM_MAX_SP_LENGTH_2: |
| ucQosInfo |= WMM_QOS_INFO_MAX_SP_2; |
| break; |
| |
| case WMM_MAX_SP_LENGTH_4: |
| ucQosInfo |= WMM_QOS_INFO_MAX_SP_4; |
| break; |
| |
| case WMM_MAX_SP_LENGTH_6: |
| ucQosInfo |= WMM_QOS_INFO_MAX_SP_6; |
| break; |
| |
| default: |
| DBGLOG(QM, INFO, "MQM: Incorrect SP length\n"); |
| ucQosInfo |= WMM_QOS_INFO_MAX_SP_2; |
| break; |
| } |
| } |
| prIeWmmInfo->ucQosInfo = ucQosInfo; |
| |
| } |
| |
| /* Increment the total IE length for the Element ID and Length fields. */ |
| return IE_SIZE(prIeWmmInfo); |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * @brief Generate the WMM Info IE |
| * |
| * \param[in] prAdapter Adapter pointer |
| * @param prMsduInfo The TX MMPDU |
| * |
| * @return (none) |
| */ |
| /*----------------------------------------------------------------------------*/ |
| UINT_32 |
| mqmGenerateWmmInfoIEByStaRec(P_ADAPTER_T prAdapter, P_BSS_INFO_T prBssInfo, P_STA_RECORD_T prStaRec, P_UINT_8 pucOutBuf) |
| { |
| P_PM_PROFILE_SETUP_INFO_T prPmProfSetupInfo; |
| BOOLEAN fgSupportUapsd; |
| |
| ASSERT(pucOutBuf); |
| |
| /* In case QoS is not turned off, exit directly */ |
| if (IS_FEATURE_DISABLED(prAdapter->rWifiVar.ucQoS)) |
| return 0; |
| |
| if (prStaRec == NULL) |
| return 0; |
| |
| if (!prStaRec->fgIsWmmSupported) |
| return 0; |
| |
| prPmProfSetupInfo = &prBssInfo->rPmProfSetupInfo; |
| |
| fgSupportUapsd = (IS_FEATURE_ENABLED(prAdapter->rWifiVar.ucUapsd) |
| && prStaRec->fgIsUapsdSupported); |
| |
| return mqmFillWmmInfoIE(pucOutBuf, |
| fgSupportUapsd, |
| prPmProfSetupInfo->ucBmpDeliveryAC, |
| prPmProfSetupInfo->ucBmpTriggerAC, prPmProfSetupInfo->ucUapsdSp); |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * @brief Generate the WMM Info IE |
| * |
| * \param[in] prAdapter Adapter pointer |
| * @param prMsduInfo The TX MMPDU |
| * |
| * @return (none) |
| */ |
| /*----------------------------------------------------------------------------*/ |
| VOID mqmGenerateWmmInfoIE(IN P_ADAPTER_T prAdapter, IN P_MSDU_INFO_T prMsduInfo) |
| { |
| P_BSS_INFO_T prBssInfo; |
| P_STA_RECORD_T prStaRec; |
| UINT_32 u4Length; |
| |
| DEBUGFUNC("mqmGenerateWmmInfoIE"); |
| |
| ASSERT(prMsduInfo); |
| |
| /* In case QoS is not turned off, exit directly */ |
| if (IS_FEATURE_DISABLED(prAdapter->rWifiVar.ucQoS)) |
| return; |
| |
| prStaRec = cnmGetStaRecByIndex(prAdapter, prMsduInfo->ucStaRecIndex); |
| ASSERT(prStaRec); |
| |
| if (prStaRec == NULL) |
| return; |
| |
| if (!prStaRec->fgIsWmmSupported) |
| return; |
| |
| prBssInfo = GET_BSS_INFO_BY_INDEX(prAdapter, prStaRec->ucBssIndex); |
| |
| u4Length = mqmGenerateWmmInfoIEByStaRec(prAdapter, |
| prBssInfo, |
| prStaRec, ((PUINT_8) prMsduInfo->prPacket + prMsduInfo->u2FrameLength)); |
| |
| prMsduInfo->u2FrameLength += u4Length; |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * @brief Generate the WMM Param IE |
| * |
| * \param[in] prAdapter Adapter pointer |
| * @param prMsduInfo The TX MMPDU |
| * |
| * @return (none) |
| */ |
| /*----------------------------------------------------------------------------*/ |
| VOID mqmGenerateWmmParamIE(IN P_ADAPTER_T prAdapter, IN P_MSDU_INFO_T prMsduInfo) |
| { |
| P_IE_WMM_PARAM_T prIeWmmParam; |
| |
| UINT_8 aucWfaOui[] = VENDOR_OUI_WFA; |
| |
| UINT_8 aucACI[] = { |
| WMM_ACI_AC_BE, |
| WMM_ACI_AC_BK, |
| WMM_ACI_AC_VI, |
| WMM_ACI_AC_VO |
| }; |
| |
| P_BSS_INFO_T prBssInfo; |
| P_STA_RECORD_T prStaRec; |
| ENUM_WMM_ACI_T eAci; |
| P_WMM_AC_PARAM_T prAcParam; |
| |
| DEBUGFUNC("mqmGenerateWmmParamIE"); |
| DBGLOG(QM, LOUD, "\n"); |
| |
| ASSERT(prMsduInfo); |
| |
| /* In case QoS is not turned off, exit directly */ |
| if (IS_FEATURE_DISABLED(prAdapter->rWifiVar.ucQoS)) |
| return; |
| |
| prStaRec = cnmGetStaRecByIndex(prAdapter, prMsduInfo->ucStaRecIndex); |
| |
| if (prStaRec) { |
| if (!prStaRec->fgIsQoS) |
| return; |
| } |
| |
| prBssInfo = GET_BSS_INFO_BY_INDEX(prAdapter, prMsduInfo->ucBssIndex); |
| |
| if (!prBssInfo->fgIsQBSS) |
| return; |
| |
| prIeWmmParam = (P_IE_WMM_PARAM_T) |
| ((PUINT_8) prMsduInfo->prPacket + prMsduInfo->u2FrameLength); |
| |
| prIeWmmParam->ucId = ELEM_ID_WMM; |
| prIeWmmParam->ucLength = ELEM_MAX_LEN_WMM_PARAM; |
| |
| /* WMM-2.2.1 WMM Information Element Field Values */ |
| prIeWmmParam->aucOui[0] = aucWfaOui[0]; |
| prIeWmmParam->aucOui[1] = aucWfaOui[1]; |
| prIeWmmParam->aucOui[2] = aucWfaOui[2]; |
| prIeWmmParam->ucOuiType = VENDOR_OUI_TYPE_WMM; |
| prIeWmmParam->ucOuiSubtype = VENDOR_OUI_SUBTYPE_WMM_PARAM; |
| |
| prIeWmmParam->ucVersion = VERSION_WMM; |
| prIeWmmParam->ucQosInfo = (prBssInfo->ucWmmParamSetCount & WMM_QOS_INFO_PARAM_SET_CNT); |
| |
| /* UAPSD initial queue configurations (delivery and trigger enabled) */ |
| if (IS_FEATURE_ENABLED(prAdapter->rWifiVar.ucUapsd)) |
| prIeWmmParam->ucQosInfo |= WMM_QOS_INFO_UAPSD; |
| |
| /* EDCA parameter */ |
| |
| for (eAci = 0; eAci < WMM_AC_INDEX_NUM; eAci++) { |
| prAcParam = &prIeWmmParam->arAcParam[eAci]; |
| |
| /* DBGLOG(QM, LOUD, ("MQM: eAci=%d, ACM = %d, Aifsn = %d, CWmin = %d, CWmax = %d, TxopLimit = %d\n", */ |
| /* eAci,prBssInfo->arACQueParmsForBcast[eAci].ucIsACMSet , */ |
| /* prBssInfo->arACQueParmsForBcast[eAci].u2Aifsn, */ |
| /* prBssInfo->arACQueParmsForBcast[eAci].u2CWmin, */ |
| /* prBssInfo->arACQueParmsForBcast[eAci].u2CWmax, */ |
| /* prBssInfo->arACQueParmsForBcast[eAci].u2TxopLimit)); */ |
| |
| /* ACI */ |
| prAcParam->ucAciAifsn = aucACI[eAci]; |
| /* ACM */ |
| if (prBssInfo->arACQueParmsForBcast[eAci].ucIsACMSet) |
| prAcParam->ucAciAifsn |= WMM_ACIAIFSN_ACM; |
| /* AIFSN */ |
| prAcParam->ucAciAifsn |= (prBssInfo->arACQueParmsForBcast[eAci].u2Aifsn & WMM_ACIAIFSN_AIFSN); |
| |
| /* ECW Min */ |
| prAcParam->ucEcw = (prBssInfo->aucCWminLog2ForBcast[eAci] & WMM_ECW_WMIN_MASK); |
| /* ECW Max */ |
| prAcParam->ucEcw |= |
| ((prBssInfo->aucCWmaxLog2ForBcast[eAci] << WMM_ECW_WMAX_OFFSET) & WMM_ECW_WMAX_MASK); |
| |
| /* Txop limit */ |
| WLAN_SET_FIELD_16(&prAcParam->u2TxopLimit, prBssInfo->arACQueParmsForBcast[eAci].u2TxopLimit); |
| |
| } |
| |
| /* Increment the total IE length for the Element ID and Length fields. */ |
| prMsduInfo->u2FrameLength += IE_SIZE(prIeWmmParam); |
| |
| } |
| |
| #if CFG_SUPPORT_TDLS |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * @brief Generate the WMM Param IE |
| * |
| * \param[in] prAdapter Adapter pointer |
| * @param prMsduInfo The TX MMPDU |
| * |
| * @return (none) |
| */ |
| /*----------------------------------------------------------------------------*/ |
| UINT_32 mqmGenerateWmmParamIEByParam(P_ADAPTER_T prAdapter, P_BSS_INFO_T prBssInfo, PUINT_8 pOutBuf) |
| { |
| P_IE_WMM_PARAM_T prIeWmmParam; |
| |
| UINT_8 aucWfaOui[] = VENDOR_OUI_WFA; |
| |
| UINT_8 aucACI[] = { |
| WMM_ACI_AC_BE, |
| WMM_ACI_AC_BK, |
| WMM_ACI_AC_VI, |
| WMM_ACI_AC_VO |
| }; |
| |
| P_AC_QUE_PARMS_T prACQueParms; |
| UINT_8 auCWminLog2ForBcast[WMM_AC_INDEX_NUM] = { 4 /*BE*/, 4 /*BK*/, 3 /*VO*/, 2 /*VI*/ }; |
| UINT_8 auCWmaxLog2ForBcast[WMM_AC_INDEX_NUM] = { 10, 10, 4, 3 }; |
| UINT_8 auAifsForBcast[WMM_AC_INDEX_NUM] = { 3, 7, 2, 2 }; |
| UINT_8 auTxopForBcast[WMM_AC_INDEX_NUM] = { 0, 0, 94, 47 }; /* If the AP is OFDM */ |
| |
| ENUM_WMM_ACI_T eAci; |
| P_WMM_AC_PARAM_T prAcParam; |
| |
| DEBUGFUNC("mqmGenerateWmmParamIE"); |
| DBGLOG(QM, LOUD, "\n"); |
| |
| ASSERT(pOutBuf); |
| |
| /* In case QoS is not turned off, exit directly */ |
| if (IS_FEATURE_DISABLED(prAdapter->rWifiVar.ucQoS)) |
| return WLAN_STATUS_SUCCESS; |
| |
| if (!prBssInfo->fgIsQBSS) |
| return WLAN_STATUS_SUCCESS; |
| |
| if (IS_FEATURE_ENABLED(prAdapter->rWifiVar.fgTdlsBufferSTASleep)) { |
| prACQueParms = prBssInfo->arACQueParmsForBcast; |
| |
| for (eAci = 0; eAci < WMM_AC_INDEX_NUM; eAci++) { |
| prACQueParms[eAci].ucIsACMSet = FALSE; |
| prACQueParms[eAci].u2Aifsn = auAifsForBcast[eAci]; |
| prACQueParms[eAci].u2CWmin = BIT(auCWminLog2ForBcast[eAci]) - 1; |
| prACQueParms[eAci].u2CWmax = BIT(auCWmaxLog2ForBcast[eAci]) - 1; |
| prACQueParms[eAci].u2TxopLimit = auTxopForBcast[eAci]; |
| |
| /* used to send WMM IE */ |
| prBssInfo->aucCWminLog2ForBcast[eAci] = auCWminLog2ForBcast[eAci]; |
| prBssInfo->aucCWmaxLog2ForBcast[eAci] = auCWmaxLog2ForBcast[eAci]; |
| |
| /* DBGLOG(TDLS, INFO, "eAci = %d, ACM = %d, Aifsn = %d, CWmin = %d, CWmax = %d, |
| * TxopLimit = %d\n", |
| * eAci, prACQueParms[eAci].ucIsACMSet, prACQueParms[eAci].u2Aifsn, |
| * prACQueParms[eAci].u2CWmin, prACQueParms[eAci].u2CWmax, prACQueParms[eAci].u2TxopLimit); |
| */ |
| } |
| } |
| |
| prIeWmmParam = (P_IE_WMM_PARAM_T) pOutBuf; |
| |
| prIeWmmParam->ucId = ELEM_ID_WMM; |
| prIeWmmParam->ucLength = ELEM_MAX_LEN_WMM_PARAM; |
| |
| /* WMM-2.2.1 WMM Information Element Field Values */ |
| prIeWmmParam->aucOui[0] = aucWfaOui[0]; |
| prIeWmmParam->aucOui[1] = aucWfaOui[1]; |
| prIeWmmParam->aucOui[2] = aucWfaOui[2]; |
| prIeWmmParam->ucOuiType = VENDOR_OUI_TYPE_WMM; |
| prIeWmmParam->ucOuiSubtype = VENDOR_OUI_SUBTYPE_WMM_PARAM; |
| |
| prIeWmmParam->ucVersion = VERSION_WMM; |
| /* STAUT Buffer STA, also sleeps (optional) |
| * The STAUT sends a TDLS Setup/Response/Confirm Frame, to STA 2, via the AP, |
| * with all four AC flags set to 1 in QoS Info Field |
| */ |
| if (IS_FEATURE_ENABLED(prAdapter->rWifiVar.fgTdlsBufferSTASleep)) |
| prIeWmmParam->ucQosInfo = (0x0F & WMM_QOS_INFO_PARAM_SET_CNT); |
| else |
| prIeWmmParam->ucQosInfo = (prBssInfo->ucWmmParamSetCount & WMM_QOS_INFO_PARAM_SET_CNT); |
| |
| /* UAPSD initial queue configurations (delivery and trigger enabled) */ |
| if (IS_FEATURE_ENABLED(prAdapter->rWifiVar.ucUapsd)) |
| prIeWmmParam->ucQosInfo |= WMM_QOS_INFO_UAPSD; |
| |
| /* EDCA parameter */ |
| |
| for (eAci = 0; eAci < WMM_AC_INDEX_NUM; eAci++) { |
| prAcParam = &prIeWmmParam->arAcParam[eAci]; |
| |
| /* DBGLOG(QM, LOUD, ("MQM: eAci=%d, ACM = %d, Aifsn = %d, CWmin = %d, CWmax = %d, TxopLimit = %d\n", */ |
| /* eAci,prBssInfo->arACQueParmsForBcast[eAci].ucIsACMSet , */ |
| /* prBssInfo->arACQueParmsForBcast[eAci].u2Aifsn, */ |
| /* prBssInfo->arACQueParmsForBcast[eAci].u2CWmin, */ |
| /* prBssInfo->arACQueParmsForBcast[eAci].u2CWmax, */ |
| /* prBssInfo->arACQueParmsForBcast[eAci].u2TxopLimit)); */ |
| |
| /* ACI */ |
| prAcParam->ucAciAifsn = aucACI[eAci]; |
| /* ACM */ |
| if (prBssInfo->arACQueParmsForBcast[eAci].ucIsACMSet) |
| prAcParam->ucAciAifsn |= WMM_ACIAIFSN_ACM; |
| /* AIFSN */ |
| prAcParam->ucAciAifsn |= (prBssInfo->arACQueParmsForBcast[eAci].u2Aifsn & WMM_ACIAIFSN_AIFSN); |
| |
| /* ECW Min */ |
| prAcParam->ucEcw = (prBssInfo->aucCWminLog2ForBcast[eAci] & WMM_ECW_WMIN_MASK); |
| /* ECW Max */ |
| prAcParam->ucEcw |= |
| ((prBssInfo->aucCWmaxLog2ForBcast[eAci] << WMM_ECW_WMAX_OFFSET) & WMM_ECW_WMAX_MASK); |
| |
| /* Txop limit */ |
| WLAN_SET_FIELD_16(&prAcParam->u2TxopLimit, prBssInfo->arACQueParmsForBcast[eAci].u2TxopLimit); |
| |
| } |
| |
| /* Increment the total IE length for the Element ID and Length fields. */ |
| return IE_SIZE(prIeWmmParam); |
| |
| } |
| |
| #endif |
| |
| BOOLEAN isProbeResponse(IN P_MSDU_INFO_T prMgmtTxMsdu) |
| { |
| P_WLAN_MAC_HEADER_T prWlanHdr = (P_WLAN_MAC_HEADER_T) NULL; |
| |
| prWlanHdr = (P_WLAN_MAC_HEADER_T) ((ULONG) prMgmtTxMsdu->prPacket + |
| MAC_TX_RESERVED_FIELD); |
| |
| return (prWlanHdr->u2FrameCtrl & MASK_FRAME_TYPE) == MAC_FRAME_PROBE_RSP ? |
| TRUE : FALSE; |
| } |
| |
| |
| ENUM_FRAME_ACTION_T |
| qmGetFrameAction(IN P_ADAPTER_T prAdapter, IN UINT_8 ucBssIndex, |
| IN UINT_8 ucStaRecIdx, IN P_MSDU_INFO_T prMsduInfo, |
| IN ENUM_FRAME_TYPE_IN_CMD_Q_T eFrameType, IN UINT_16 u2FrameLength) |
| { |
| ENUM_FRAME_ACTION_T eFrameAction = FRAME_ACTION_TX_PKT; |
| P_BSS_INFO_T prBssInfo; |
| P_STA_RECORD_T prStaRec; |
| UINT_8 ucTC = nicTxGetFrameResourceType(eFrameType, prMsduInfo); |
| UINT_16 u2FreeResource = nicTxGetResource(prAdapter, ucTC); |
| UINT_8 ucReqResource; |
| P_WIFI_VAR_T prWifiVar = &prAdapter->rWifiVar; |
| |
| DEBUGFUNC("qmGetFrameAction"); |
| |
| prBssInfo = GET_BSS_INFO_BY_INDEX(prAdapter, ucBssIndex); |
| prStaRec = QM_GET_STA_REC_PTR_FROM_INDEX(prAdapter, ucStaRecIdx); |
| |
| do { |
| /* 4 <1> Tx, if FORCE_TX is set */ |
| if (prMsduInfo) { |
| if (prMsduInfo->ucControlFlag & MSDU_CONTROL_FLAG_FORCE_TX) { |
| eFrameAction = FRAME_ACTION_TX_PKT; |
| break; |
| } |
| } |
| /* 4 <2> Drop, if BSS is inactive */ |
| if (!IS_BSS_ACTIVE(prBssInfo)) { |
| DBGLOG(QM, TRACE, "Drop packets (BSS[%u] is INACTIVE)\n", prBssInfo->ucBssIndex); |
| eFrameAction = FRAME_ACTION_DROP_PKT; |
| break; |
| } |
| |
| /* 4 <3> Queue, if BSS is absent, drop probe response */ |
| if (prBssInfo->fgIsNetAbsent) { |
| if (prMsduInfo && isProbeResponse(prMsduInfo)) { |
| DBGLOG(TX, TRACE, "Drop probe response (BSS[%u] Absent)\n", |
| prBssInfo->ucBssIndex); |
| |
| eFrameAction = FRAME_ACTION_DROP_PKT; |
| } else { |
| DBGLOG(TX, TRACE, "Queue packets (BSS[%u] Absent)\n", |
| prBssInfo->ucBssIndex); |
| eFrameAction = FRAME_ACTION_QUEUE_PKT; |
| } |
| break; |
| } |
| |
| /* 4 <4> Check based on StaRec */ |
| if (prStaRec) { |
| /* 4 <4.1> Drop, if StaRec is not in use */ |
| if (!prStaRec->fgIsInUse) { |
| DBGLOG(QM, TRACE, "Drop packets (Sta[%u] not in USE)\n", prStaRec->ucIndex); |
| eFrameAction = FRAME_ACTION_DROP_PKT; |
| break; |
| } |
| /* 4 <4.2> Sta in PS */ |
| if (prStaRec->fgIsInPS) { |
| ucReqResource = nicTxGetPageCount(u2FrameLength, FALSE) + |
| prWifiVar->ucCmdRsvResource + QM_MGMT_QUEUED_THRESHOLD; |
| |
| /* 4 <4.2.1> Tx, if resource is enough */ |
| if (u2FreeResource > ucReqResource) { |
| eFrameAction = FRAME_ACTION_TX_PKT; |
| break; |
| } |
| /* 4 <4.2.2> Queue, if resource is not enough */ |
| else { |
| DBGLOG(QM, INFO, "Queue packets (Sta[%u] in PS)\n", prStaRec->ucIndex); |
| eFrameAction = FRAME_ACTION_QUEUE_PKT; |
| break; |
| } |
| } |
| } |
| |
| } while (FALSE); |
| |
| /* <5> Resource CHECK! */ |
| /* <5.1> Reserve resource for CMD & 1X */ |
| if (eFrameType == FRAME_TYPE_MMPDU) { |
| ucReqResource = nicTxGetPageCount(u2FrameLength, FALSE) + prWifiVar->ucCmdRsvResource; |
| |
| if (u2FreeResource < ucReqResource) { |
| eFrameAction = FRAME_ACTION_QUEUE_PKT; |
| DBGLOG(QM, INFO, "Queue MGMT (MSDU[0x%p] Req/Rsv/Free[%u/%u/%u])\n", |
| prMsduInfo, |
| nicTxGetPageCount(u2FrameLength, FALSE), prWifiVar->ucCmdRsvResource, u2FreeResource); |
| } |
| |
| /* <6> Timeout check! */ |
| #if CFG_ENABLE_PKT_LIFETIME_PROFILE |
| if ((eFrameAction == FRAME_ACTION_QUEUE_PKT) && prMsduInfo) { |
| OS_SYSTIME rCurrentTime, rEnqTime; |
| |
| GET_CURRENT_SYSTIME(&rCurrentTime); |
| rEnqTime = prMsduInfo->rPktProfile.rEnqueueTimestamp; |
| |
| if (CHECK_FOR_TIMEOUT(rCurrentTime, rEnqTime, |
| MSEC_TO_SYSTIME(prWifiVar->u4MgmtQueueDelayTimeout))) { |
| eFrameAction = FRAME_ACTION_DROP_PKT; |
| DBGLOG(QM, INFO, "Drop MGMT (MSDU[0x%p] timeout[%ums])\n", |
| prMsduInfo, prWifiVar->u4MgmtQueueDelayTimeout); |
| } |
| } |
| #endif |
| } |
| |
| return eFrameAction; |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief Handle BSS change operation Event from the FW |
| * |
| * \param[in] prAdapter Adapter pointer |
| * \param[in] prEvent The event packet from the FW |
| * |
| * \return (none) |
| */ |
| /*----------------------------------------------------------------------------*/ |
| VOID qmHandleEventBssAbsencePresence(IN P_ADAPTER_T prAdapter, IN P_WIFI_EVENT_T prEvent) |
| { |
| P_EVENT_BSS_ABSENCE_PRESENCE_T prEventBssStatus; |
| P_BSS_INFO_T prBssInfo; |
| BOOLEAN fgIsNetAbsentOld; |
| |
| prEventBssStatus = (P_EVENT_BSS_ABSENCE_PRESENCE_T) (prEvent->aucBuffer); |
| prBssInfo = GET_BSS_INFO_BY_INDEX(prAdapter, prEventBssStatus->ucBssIndex); |
| fgIsNetAbsentOld = prBssInfo->fgIsNetAbsent; |
| prBssInfo->fgIsNetAbsent = prEventBssStatus->ucIsAbsent; |
| prBssInfo->ucBssFreeQuota = prEventBssStatus->ucBssFreeQuota; |
| |
| /* DBGLOG(QM, TRACE, ("qmHandleEventBssAbsencePresence (ucNetTypeIdx=%d, fgIsAbsent=%d, FreeQuota=%d)\n", */ |
| /* prEventBssStatus->ucNetTypeIdx, prBssInfo->fgIsNetAbsent, prBssInfo->ucBssFreeQuota)); */ |
| |
| DBGLOG(QM, INFO, "NAF=%d,%d,%d\n", |
| prEventBssStatus->ucBssIndex, prBssInfo->fgIsNetAbsent, prBssInfo->ucBssFreeQuota); |
| |
| if (!prBssInfo->fgIsNetAbsent) { |
| /* ToDo:: QM_DBG_CNT_INC */ |
| QM_DBG_CNT_INC(&(prAdapter->rQM), QM_DBG_CNT_27); |
| } else { |
| /* ToDo:: QM_DBG_CNT_INC */ |
| QM_DBG_CNT_INC(&(prAdapter->rQM), QM_DBG_CNT_28); |
| } |
| /* From Absent to Present */ |
| if ((fgIsNetAbsentOld) && (!prBssInfo->fgIsNetAbsent)) { |
| if (HAL_IS_TX_DIRECT(prAdapter)) |
| nicTxDirectStartCheckQTimer(prAdapter); |
| else |
| kalSetEvent(prAdapter->prGlueInfo); |
| } |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief Handle STA change PS mode Event from the FW |
| * |
| * \param[in] prAdapter Adapter pointer |
| * \param[in] prEvent The event packet from the FW |
| * |
| * \return (none) |
| */ |
| /*----------------------------------------------------------------------------*/ |
| VOID qmHandleEventStaChangePsMode(IN P_ADAPTER_T prAdapter, IN P_WIFI_EVENT_T prEvent) |
| { |
| P_EVENT_STA_CHANGE_PS_MODE_T prEventStaChangePsMode; |
| P_STA_RECORD_T prStaRec; |
| BOOLEAN fgIsInPSOld; |
| |
| /* DbgPrint("QM:Event -RxBa\n"); */ |
| |
| prEventStaChangePsMode = (P_EVENT_STA_CHANGE_PS_MODE_T) (prEvent->aucBuffer); |
| prStaRec = QM_GET_STA_REC_PTR_FROM_INDEX(prAdapter, prEventStaChangePsMode->ucStaRecIdx); |
| /* ASSERT(prStaRec); */ |
| |
| if (prStaRec) { |
| |
| fgIsInPSOld = prStaRec->fgIsInPS; |
| prStaRec->fgIsInPS = prEventStaChangePsMode->ucIsInPs; |
| |
| qmUpdateFreeQuota(prAdapter, |
| prStaRec, prEventStaChangePsMode->ucUpdateMode, prEventStaChangePsMode->ucFreeQuota); |
| |
| /* DBGLOG(QM, TRACE, ("qmHandleEventStaChangePsMode (ucStaRecIdx=%d, fgIsInPs=%d)\n", */ |
| /* prEventStaChangePsMode->ucStaRecIdx, prStaRec->fgIsInPS)); */ |
| |
| DBGLOG(QM, INFO, "PS=%d,%d\n", prEventStaChangePsMode->ucStaRecIdx, prStaRec->fgIsInPS); |
| |
| /* From PS to Awake */ |
| if ((fgIsInPSOld) && (!prStaRec->fgIsInPS)) { |
| if (HAL_IS_TX_DIRECT(prAdapter)) |
| nicTxDirectStartCheckQTimer(prAdapter); |
| else |
| kalSetEvent(prAdapter->prGlueInfo); |
| } |
| } |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief Update STA free quota Event from FW |
| * |
| * \param[in] prAdapter Adapter pointer |
| * \param[in] prEvent The event packet from the FW |
| * |
| * \return (none) |
| */ |
| /*----------------------------------------------------------------------------*/ |
| VOID qmHandleEventStaUpdateFreeQuota(IN P_ADAPTER_T prAdapter, IN P_WIFI_EVENT_T prEvent) |
| { |
| P_EVENT_STA_UPDATE_FREE_QUOTA_T prEventStaUpdateFreeQuota; |
| P_STA_RECORD_T prStaRec; |
| |
| prEventStaUpdateFreeQuota = (P_EVENT_STA_UPDATE_FREE_QUOTA_T) (prEvent->aucBuffer); |
| prStaRec = QM_GET_STA_REC_PTR_FROM_INDEX(prAdapter, prEventStaUpdateFreeQuota->ucStaRecIdx); |
| /* 2013/08/30 |
| * Station Record possible been freed. |
| */ |
| /* ASSERT(prStaRec); */ |
| |
| if (prStaRec) { |
| if (prStaRec->fgIsInPS) { |
| qmUpdateFreeQuota(prAdapter, |
| prStaRec, |
| prEventStaUpdateFreeQuota->ucUpdateMode, |
| prEventStaUpdateFreeQuota->ucFreeQuota); |
| |
| if (HAL_IS_TX_DIRECT(prAdapter)) |
| nicTxDirectStartCheckQTimer(prAdapter); |
| else |
| kalSetEvent(prAdapter->prGlueInfo); |
| } |
| #if 0 |
| DBGLOG(QM, TRACE, |
| "qmHandleEventStaUpdateFreeQuota (ucStaRecIdx=%d, ucUpdateMode=%d, ucFreeQuota=%d)\n", |
| prEventStaUpdateFreeQuota->ucStaRecIdx, |
| prEventStaUpdateFreeQuota->ucUpdateMode, prEventStaUpdateFreeQuota->ucFreeQuota); |
| #endif |
| |
| DBGLOG(QM, TRACE, "UFQ=%d,%d,%d\n", |
| prEventStaUpdateFreeQuota->ucStaRecIdx, |
| prEventStaUpdateFreeQuota->ucUpdateMode, prEventStaUpdateFreeQuota->ucFreeQuota); |
| |
| } |
| |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief Update STA free quota |
| * |
| * \param[in] prStaRec the STA |
| * \param[in] ucUpdateMode the method to update free quota |
| * \param[in] ucFreeQuota the value for update |
| * |
| * \return (none) |
| */ |
| /*----------------------------------------------------------------------------*/ |
| VOID |
| qmUpdateFreeQuota(IN P_ADAPTER_T prAdapter, IN P_STA_RECORD_T prStaRec, IN UINT_8 ucUpdateMode, IN UINT_8 ucFreeQuota) |
| { |
| |
| UINT_8 ucFreeQuotaForNonDelivery; |
| UINT_8 ucFreeQuotaForDelivery; |
| |
| ASSERT(prStaRec); |
| DBGLOG(QM, LOUD, "qmUpdateFreeQuota orig ucFreeQuota=%d Mode %u New %u\n", |
| prStaRec->ucFreeQuota, ucUpdateMode, ucFreeQuota); |
| |
| if (!prStaRec->fgIsInPS) |
| return; |
| |
| switch (ucUpdateMode) { |
| case FREE_QUOTA_UPDATE_MODE_INIT: |
| case FREE_QUOTA_UPDATE_MODE_OVERWRITE: |
| prStaRec->ucFreeQuota = ucFreeQuota; |
| break; |
| case FREE_QUOTA_UPDATE_MODE_INCREASE: |
| prStaRec->ucFreeQuota += ucFreeQuota; |
| break; |
| case FREE_QUOTA_UPDATE_MODE_DECREASE: |
| prStaRec->ucFreeQuota -= ucFreeQuota; |
| break; |
| default: |
| ASSERT(0); |
| } |
| |
| DBGLOG(QM, LOUD, "qmUpdateFreeQuota new ucFreeQuota=%d)\n", prStaRec->ucFreeQuota); |
| |
| ucFreeQuota = prStaRec->ucFreeQuota; |
| |
| ucFreeQuotaForNonDelivery = 0; |
| ucFreeQuotaForDelivery = 0; |
| |
| if (ucFreeQuota > 0) { |
| if (prStaRec->fgIsQoS && prStaRec->fgIsUapsdSupported |
| /* && prAdapter->rWifiVar.fgSupportQoS */ |
| /* && prAdapter->rWifiVar.fgSupportUAPSD */) { |
| /* XXX We should assign quota to aucFreeQuotaPerQueue[NUM_OF_PER_STA_TX_QUEUES] */ |
| |
| if (prStaRec->ucFreeQuotaForNonDelivery > 0 && prStaRec->ucFreeQuotaForDelivery > 0) { |
| ucFreeQuotaForNonDelivery = ucFreeQuota >> 1; |
| ucFreeQuotaForDelivery = ucFreeQuota - ucFreeQuotaForNonDelivery; |
| } else if (prStaRec->ucFreeQuotaForNonDelivery == 0 && prStaRec->ucFreeQuotaForDelivery == 0) { |
| ucFreeQuotaForNonDelivery = ucFreeQuota >> 1; |
| ucFreeQuotaForDelivery = ucFreeQuota - ucFreeQuotaForNonDelivery; |
| } else if (prStaRec->ucFreeQuotaForNonDelivery > 0) { |
| /* NonDelivery is not busy */ |
| if (ucFreeQuota >= 3) { |
| ucFreeQuotaForNonDelivery = 2; |
| ucFreeQuotaForDelivery = ucFreeQuota - ucFreeQuotaForNonDelivery; |
| } else { |
| ucFreeQuotaForDelivery = ucFreeQuota; |
| ucFreeQuotaForNonDelivery = 0; |
| } |
| } else if (prStaRec->ucFreeQuotaForDelivery > 0) { |
| /* Delivery is not busy */ |
| if (ucFreeQuota >= 3) { |
| ucFreeQuotaForDelivery = 2; |
| ucFreeQuotaForNonDelivery = ucFreeQuota - ucFreeQuotaForDelivery; |
| } else { |
| ucFreeQuotaForNonDelivery = ucFreeQuota; |
| ucFreeQuotaForDelivery = 0; |
| } |
| } |
| |
| } else { |
| /* !prStaRec->fgIsUapsdSupported */ |
| ucFreeQuotaForNonDelivery = ucFreeQuota; |
| ucFreeQuotaForDelivery = 0; |
| } |
| } |
| /* ucFreeQuota > 0 */ |
| prStaRec->ucFreeQuotaForDelivery = ucFreeQuotaForDelivery; |
| prStaRec->ucFreeQuotaForNonDelivery = ucFreeQuotaForNonDelivery; |
| |
| DBGLOG(QM, LOUD, "new QuotaForDelivery = %d QuotaForNonDelivery = %d\n", |
| prStaRec->ucFreeQuotaForDelivery, prStaRec->ucFreeQuotaForNonDelivery); |
| |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief Return the reorder queued RX packets |
| * |
| * \param[in] (none) |
| * |
| * \return The number of queued RX packets |
| */ |
| /*----------------------------------------------------------------------------*/ |
| UINT_32 qmGetRxReorderQueuedBufferCount(IN P_ADAPTER_T prAdapter) |
| { |
| UINT_32 i, u4Total; |
| P_QUE_MGT_T prQM = &prAdapter->rQM; |
| |
| u4Total = 0; |
| /* XXX The summation may impact the performance */ |
| for (i = 0; i < CFG_NUM_OF_RX_BA_AGREEMENTS; i++) { |
| u4Total += prQM->arRxBaTable[i].rReOrderQue.u4NumElem; |
| #if DBG && 0 |
| if (QUEUE_IS_EMPTY(&(prQM->arRxBaTable[i].rReOrderQue))) |
| ASSERT(prQM->arRxBaTable[i].rReOrderQue == 0); |
| #endif |
| } |
| ASSERT(u4Total <= (CFG_NUM_OF_QM_RX_PKT_NUM * 2)); |
| return u4Total; |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief Dump current queue status |
| * |
| * \param[in] (none) |
| * |
| * \return (none) |
| */ |
| /*----------------------------------------------------------------------------*/ |
| UINT_32 qmDumpQueueStatus(IN P_ADAPTER_T prAdapter, IN PUINT_8 pucBuf, IN UINT_32 u4Max) |
| { |
| P_TX_CTRL_T prTxCtrl; |
| P_QUE_MGT_T prQM; |
| P_GLUE_INFO_T prGlueInfo; |
| UINT_32 i, u4TotalBufferCount, u4TotalPageCount; |
| UINT_32 u4CurBufferCount, u4CurPageCount; |
| UINT_32 u4Len = 0; |
| |
| DEBUGFUNC(("%s", __func__)); |
| |
| prTxCtrl = &prAdapter->rTxCtrl; |
| prQM = &prAdapter->rQM; |
| prGlueInfo = prAdapter->prGlueInfo; |
| u4TotalBufferCount = 0; |
| u4TotalPageCount = 0; |
| u4CurBufferCount = 0; |
| u4CurPageCount = 0; |
| |
| LOGBUF(pucBuf, u4Max, u4Len, "\n"); |
| LOGBUF(pucBuf, u4Max, u4Len, "------<Dump QUEUE Status>------\n"); |
| |
| for (i = TC0_INDEX; i < TC_NUM; i++) { |
| LOGBUF(pucBuf, u4Max, u4Len, "TC%u ResCount: Max[%02u/%03u] Free[%02u/%03u] PreUsed[%03u]\n", |
| i, prTxCtrl->rTc.au4MaxNumOfBuffer[i], prTxCtrl->rTc.au4MaxNumOfPage[i], |
| prTxCtrl->rTc.au4FreeBufferCount[i], prTxCtrl->rTc.au4FreePageCount[i], |
| prTxCtrl->rTc.au4PreUsedPageCount[i]); |
| |
| u4TotalBufferCount += prTxCtrl->rTc.au4MaxNumOfBuffer[i]; |
| u4TotalPageCount += prTxCtrl->rTc.au4MaxNumOfPage[i]; |
| u4CurBufferCount += prTxCtrl->rTc.au4FreeBufferCount[i]; |
| u4CurPageCount += prTxCtrl->rTc.au4FreePageCount[i]; |
| } |
| |
| LOGBUF(pucBuf, u4Max, u4Len, "ToT ResCount: Max[%02u/%03u] Free[%02u/%03u]\n", |
| u4TotalBufferCount, u4TotalPageCount, u4CurBufferCount, u4CurPageCount); |
| |
| LOGBUF(pucBuf, u4Max, u4Len, "---------------------------------\n"); |
| |
| #if QM_ADAPTIVE_TC_RESOURCE_CTRL |
| for (i = TC0_INDEX; i < TC_NUM; i++) { |
| LOGBUF(pucBuf, u4Max, u4Len, "TC%u AvgQLen[%04u] minRsv[%02u] CurTcRes[%02u] GrtdTcRes[%02u]\n", |
| i, QM_GET_TX_QUEUE_LEN(prAdapter, i), prQM->au4MinReservedTcResource[i], |
| prQM->au4CurrentTcResource[i], prQM->au4GuaranteedTcResource[i]); |
| } |
| |
| LOGBUF(pucBuf, u4Max, u4Len, "Resource Residual[%u] ExtraRsv[%u]\n", |
| prQM->u4ResidualTcResource, prQM->u4ExtraReservedTcResource); |
| LOGBUF(pucBuf, u4Max, u4Len, "QueLenMovingAvg[%u] Time2AdjResource[%u] Time2UpdateQLen[%u]\n", |
| prQM->u4QueLenMovingAverage, prQM->u4TimeToAdjustTcResource, prQM->u4TimeToUpdateQueLen); |
| #endif |
| |
| DBGLOG(SW4, INFO, "---------------------------------\n"); |
| |
| #if QM_FORWARDING_FAIRNESS |
| for (i = 0; i < NUM_OF_PER_STA_TX_QUEUES; i++) { |
| LOGBUF(pucBuf, u4Max, u4Len, "TC%u HeadSta[%u] ResourceUsedCount[%u]\n", |
| i, prQM->au4HeadStaRecIndex[i], prQM->au4ResourceUsedCount[i]); |
| } |
| #endif |
| |
| LOGBUF(pucBuf, u4Max, u4Len, "BMC or unknown TxQueue Len[%u]\n", prQM->arTxQueue[0].u4NumElem); |
| LOGBUF(pucBuf, u4Max, u4Len, "Pending QLen Normal[%u] Sec[%u] Cmd[%u]\n", |
| GLUE_GET_REF_CNT(prGlueInfo->i4TxPendingFrameNum), |
| GLUE_GET_REF_CNT(prGlueInfo->i4TxPendingSecurityFrameNum), |
| GLUE_GET_REF_CNT(prGlueInfo->i4TxPendingCmdNum)); |
| |
| #if defined(LINUX) |
| for (i = 0; i < HW_BSSID_NUM; i++) { |
| LOGBUF(pucBuf, u4Max, u4Len, "Pending BSS[%u] QLen[%u:%u:%u:%u]\n", i, |
| prGlueInfo->ai4TxPendingFrameNumPerQueue[i][0], |
| prGlueInfo->ai4TxPendingFrameNumPerQueue[i][1], |
| prGlueInfo->ai4TxPendingFrameNumPerQueue[i][2], |
| prGlueInfo->ai4TxPendingFrameNumPerQueue[i][3]); |
| } |
| #endif |
| LOGBUF(pucBuf, u4Max, u4Len, "Pending FWD CNT[%d]\n", prTxCtrl->i4PendingFwdFrameCount); |
| LOGBUF(pucBuf, u4Max, u4Len, "Pending MGMT CNT[%d]\n", prTxCtrl->i4TxMgmtPendingNum); |
| |
| LOGBUF(pucBuf, u4Max, u4Len, "---------------------------------\n"); |
| |
| LOGBUF(pucBuf, u4Max, u4Len, "Total RFB[%u]\n", CFG_RX_MAX_PKT_NUM); |
| LOGBUF(pucBuf, u4Max, u4Len, "rFreeSwRfbList[%u]\n", prAdapter->rRxCtrl.rFreeSwRfbList.u4NumElem); |
| LOGBUF(pucBuf, u4Max, u4Len, "rReceivedRfbList[%u]\n", prAdapter->rRxCtrl.rReceivedRfbList.u4NumElem); |
| LOGBUF(pucBuf, u4Max, u4Len, "rIndicatedRfbList[%u]\n", prAdapter->rRxCtrl.rIndicatedRfbList.u4NumElem); |
| LOGBUF(pucBuf, u4Max, u4Len, "ucNumIndPacket[%u]\n", prAdapter->rRxCtrl.ucNumIndPacket); |
| LOGBUF(pucBuf, u4Max, u4Len, "ucNumRetainedPacket[%u]\n", prAdapter->rRxCtrl.ucNumRetainedPacket); |
| |
| LOGBUF(pucBuf, u4Max, u4Len, "---------------------------------\n"); |
| LOGBUF(pucBuf, u4Max, u4Len, "CMD: Free[%u/%u] Cmd[%u] ToTx[%u]\n", |
| prAdapter->rFreeCmdList.u4NumElem, CFG_TX_MAX_CMD_PKT_NUM, |
| prAdapter->rPendingCmdQueue.u4NumElem, prGlueInfo->rCmdQueue.u4NumElem); |
| LOGBUF(pucBuf, u4Max, u4Len, "MSDU: Free[%u/%u] Pending[%u] Done[%u]\n", |
| prAdapter->rTxCtrl.rFreeMsduInfoList.u4NumElem, CFG_TX_MAX_PKT_NUM, |
| prAdapter->rTxCtrl.rTxMgmtTxingQueue.u4NumElem, |
| prAdapter->rTxDataDoneQueue.u4NumElem); |
| |
| LOGBUF(pucBuf, u4Max, u4Len, "---------------------------------\n"); |
| |
| return u4Len; |
| } |
| |
| #if CFG_M0VE_BA_TO_DRIVER |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * @brief Send DELBA Action frame |
| * |
| * @param fgIsInitiator DELBA_ROLE_INITIATOR or DELBA_ROLE_RECIPIENT |
| * @param prStaRec Pointer to the STA_REC of the receiving peer |
| * @param u4Tid TID of the BA entry |
| * @param u4ReasonCode The reason code carried in the Action frame |
| * |
| * @return (none) |
| */ |
| /*----------------------------------------------------------------------------*/ |
| VOID |
| mqmSendDelBaFrame(IN P_ADAPTER_T prAdapter, |
| IN BOOLEAN fgIsInitiator, IN P_STA_RECORD_T prStaRec, IN UINT_32 u4Tid, IN UINT_32 u4ReasonCode) |
| { |
| |
| P_MSDU_INFO_T prTxMsduInfo; |
| P_ACTION_DELBA_FRAME_T prDelBaFrame; |
| P_BSS_INFO_T prBssInfo; |
| |
| DBGLOG(QM, WARN, "[Puff]: Enter mqmSendDelBaFrame()\n"); |
| |
| ASSERT(prStaRec); |
| |
| /* 3 <1> Block the message in case of invalid STA */ |
| if (!prStaRec->fgIsInUse) { |
| DBGLOG(QM, WARN, "[Puff][%s]: (Warning) sta_rec is not inuse\n", __func__); |
| return; |
| } |
| /* Check HT-capabale STA */ |
| if (!(prStaRec->ucDesiredPhyTypeSet & PHY_TYPE_BIT_HT)) { |
| DBGLOG(QM, WARN, |
| "[Puff][%s]: (Warning) sta is NOT HT-capable(0x%08X)\n", __func__, |
| prStaRec->ucDesiredPhyTypeSet); |
| return; |
| } |
| /* 4 <2> Construct the DELBA frame */ |
| prTxMsduInfo = (P_MSDU_INFO_T) cnmMgtPktAlloc(prAdapter, ACTION_DELBA_FRAME_LEN); |
| |
| if (!prTxMsduInfo) { |
| DBGLOG(QM, WARN, |
| "[Puff][%s]: (Warning) DELBA for TID=%ld was not sent (MSDU_INFO alloc failure)\n", |
| __func__, u4Tid); |
| return; |
| } |
| |
| prBssInfo = GET_BSS_INFO_BY_INDEX(prAdapter, prStaRec->ucBssIndex); |
| |
| /* Fill the Action frame */ |
| prDelBaFrame = (P_ACTION_DELBA_FRAME_T) ((UINT_32) (prTxMsduInfo->prPacket) + MAC_TX_RESERVED_FIELD); |
| prDelBaFrame->u2FrameCtrl = MAC_FRAME_ACTION; |
| #if CFG_SUPPORT_802_11W |
| if (rsnCheckBipKeyInstalled(prAdapter, prStaRec)) { |
| DBGLOG(QM, WARN, "[Puff][%s]: (Warning) DELBA is 80211w enabled\n", __func__); |
| prDelBaFrame->u2FrameCtrl |= MASK_FC_PROTECTED_FRAME; |
| } |
| #endif |
| |
| prDelBaFrame->u2DurationID = 0; |
| prDelBaFrame->ucCategory = CATEGORY_BLOCK_ACK_ACTION; |
| prDelBaFrame->ucAction = ACTION_DELBA; |
| |
| prDelBaFrame->u2DelBaParameterSet = 0; |
| prDelBaFrame->u2DelBaParameterSet |= ((fgIsInitiator ? ACTION_DELBA_INITIATOR_MASK : 0)); |
| prDelBaFrame->u2DelBaParameterSet |= ((u4Tid << ACTION_DELBA_TID_OFFSET) & ACTION_DELBA_TID_MASK); |
| prDelBaFrame->u2ReasonCode = u4ReasonCode; |
| |
| COPY_MAC_ADDR(prDelBaFrame->aucDestAddr, prStaRec->aucMacAddr); |
| COPY_MAC_ADDR(prDelBaFrame->aucSrcAddr, prBssInfo->aucOwnMacAddr); |
| COPY_MAC_ADDR(prDelBaFrame->aucBSSID, prBssInfo->aucBSSID); |
| |
| /* 4 <3> Configure the MSDU_INFO and forward it to TXM */ |
| TX_SET_MMPDU(prAdapter, |
| prTxMsduInfo, |
| prStaRec->ucBssIndex, |
| (prStaRec != NULL) ? (prStaRec->ucIndex) : (STA_REC_INDEX_NOT_FOUND), |
| WLAN_MAC_HEADER_LEN, ACTION_DELBA_FRAME_LEN, NULL, MSDU_RATE_MODE_AUTO); |
| |
| #if CFG_SUPPORT_802_11W |
| if (rsnCheckBipKeyInstalled(prAdapter, prStaRec)) { |
| DBGLOG(RSN, INFO, "Set MSDU_OPT_PROTECTED_FRAME\n"); |
| nicTxConfigPktOption(prTxMsduInfo, MSDU_OPT_PROTECTED_FRAME, TRUE); |
| } |
| #endif |
| |
| /* TID and fgIsInitiator are needed when processing TX Done of the DELBA frame */ |
| prTxMsduInfo->ucTID = (UINT_8) u4Tid; |
| prTxMsduInfo->ucControlFlag = (fgIsInitiator ? 1 : 0); |
| |
| nicTxEnqueueMsdu(prAdapter, prTxMsduInfo); |
| |
| DBGLOG(QM, WARN, "[Puff][%s]: Send DELBA for TID=%ld Initiator=%d\n", __func__, u4Tid, fgIsInitiator); |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * @brief Callback function for the TX Done event for an ADDBA_RSP |
| * |
| * @param prMsduInfo The TX packet |
| * @param rWlanStatus WLAN_STATUS_SUCCESS if TX is successful |
| * |
| * @return WLAN_STATUS_BUFFER_RETAINED is returned if the buffer shall not be freed by TXM |
| */ |
| /*----------------------------------------------------------------------------*/ |
| WLAN_STATUS |
| mqmCallbackAddBaRspSent(IN P_ADAPTER_T prAdapter, IN P_MSDU_INFO_T prMsduInfo, IN ENUM_TX_RESULT_CODE_T rTxDoneStatus) |
| { |
| P_RX_BA_ENTRY_T prRxBaEntry; |
| P_STA_RECORD_T prStaRec; |
| P_QUE_MGT_T prQM; |
| |
| UINT_32 u4Tid = 0; |
| |
| /* ASSERT(prMsduInfo); */ |
| prStaRec = cnmGetStaRecByIndex(prAdapter, prMsduInfo->ucStaRecIndex); |
| ASSERT(prStaRec); |
| |
| prQM = &prAdapter->rQM; |
| |
| DBGLOG(QM, WARN, "[Puff]: Enter mqmCallbackAddBaRspSent()\n"); |
| |
| /* 4 <0> Check STA_REC status */ |
| /* Check STA_REC is inuse */ |
| if (!prStaRec->fgIsInUse) { |
| DBGLOG(QM, WARN, "[Puff][%s]: (Warning) sta_rec is not inuse\n", __func__); |
| return WLAN_STATUS_SUCCESS; |
| } |
| /* Check HT-capabale STA */ |
| if (!(prStaRec->ucDesiredPhyTypeSet & PHY_TYPE_BIT_HT)) { |
| DBGLOG(QM, WARN, |
| "[Puff][%s]: (Warning) sta is NOT HT-capable(0x%08X)\n", __func__, |
| prStaRec->ucDesiredPhyTypeSet); |
| return WLAN_STATUS_SUCCESS; /* To free the received ADDBA_REQ directly */ |
| } |
| /* 4 <1> Find the corresponding BA entry */ |
| u4Tid = prMsduInfo->ucTID; /* TID is stored in MSDU_INFO when composing the ADDBA_RSP frame */ |
| prRxBaEntry = &prQM->arRxBaTable[u4Tid]; |
| |
| /* Note: Due to some reason, for example, receiving a DELBA, the BA entry may not be in state NEGO */ |
| /* 4 <2> INVALID state */ |
| if (!prRxBaEntry) { |
| DBGLOG(QM, WARN, |
| "[Puff][%s]: (RX_BA) ADDBA_RSP ---> peer (STA=%d TID=%d)(TX successful)(invalid BA)\n", |
| __func__, prStaRec->ucIndex, u4Tid); |
| } |
| /* 4 <3> NEGO, ACTIVE, or DELETING state */ |
| else { |
| switch (rTxDoneStatus) { |
| /* 4 <Case 1> TX Success */ |
| case TX_RESULT_SUCCESS: |
| |
| DBGLOG(QM, WARN, |
| "[Puff][%s]: (RX_BA) ADDBA_RSP ---> peer (STA=%d TID=%d)(TX successful)\n", |
| __func__, prStaRec->ucIndex, u4Tid); |
| |
| /* 4 <Case 1.1> NEGO or ACTIVE state */ |
| if (prRxBaEntry->ucStatus != BA_ENTRY_STATUS_DELETING) |
| mqmRxModifyBaEntryStatus(prAdapter, prRxBaEntry, BA_ENTRY_STATUS_ACTIVE); |
| /* 4 <Case 1.2> DELETING state */ |
| /* else */ |
| /* Deleting is on-going, so do nothing and wait for TX done of the DELBA frame */ |
| |
| break; |
| |
| /* 4 <Case 2> TX Failure */ |
| default: |
| |
| DBGLOG(QM, WARN, |
| "[Puff][%s]: (RX_BA) ADDBA_RSP ---> peer (STA=%d TID=%ld Entry_Status=%d)(TX failed)\n", |
| __func__, prStaRec->ucIndex, u4Tid, prRxBaEntry->ucStatus); |
| |
| /* 4 <Case 2.1> NEGO or ACTIVE state */ |
| /* Notify the host to delete the agreement */ |
| if (prRxBaEntry->ucStatus != BA_ENTRY_STATUS_DELETING) { |
| mqmRxModifyBaEntryStatus(prAdapter, prRxBaEntry, BA_ENTRY_STATUS_DELETING); |
| |
| /* Send DELBA to the peer to ensure the BA state is synchronized */ |
| mqmSendDelBaFrame(prAdapter, DELBA_ROLE_RECIPIENT, prStaRec, u4Tid, |
| STATUS_CODE_UNSPECIFIED_FAILURE); |
| } |
| /* 4 <Case 2.2> DELETING state */ |
| /* else */ |
| /* Deleting is on-going, so do nothing and wait for the TX done of the DELBA frame */ |
| |
| break; |
| } |
| |
| } |
| |
| return WLAN_STATUS_SUCCESS; /* TXM shall release the packet */ |
| |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * @brief Check if there is any idle RX BA |
| * |
| * @param u4Param (not used) |
| * |
| * @return (none) |
| */ |
| /*----------------------------------------------------------------------------*/ |
| VOID mqmTimeoutCheckIdleRxBa(IN P_ADAPTER_T prAdapter, IN ULONG ulParamPtr) |
| { |
| INT_8 i; |
| P_RX_BA_ENTRY_T prRxBa; |
| UINT_32 u4IdleCountThreshold = 0; |
| P_STA_RECORD_T prStaRec; |
| P_QUE_MGT_T prQM; |
| |
| DBGLOG(QM, WARN, "[Puff]: Enter mqmTimeoutIdleRxBaDetection()\n"); |
| |
| prQM = &prAdapter->rQM; |
| |
| /* 4 <1> Restart the timer */ |
| cnmTimerStopTimer(prAdapter, &prAdapter->rMqmIdleRxBaDetectionTimer); |
| cnmTimerStartTimer(prAdapter, &prAdapter->rMqmIdleRxBaDetectionTimer, MQM_IDLE_RX_BA_CHECK_INTERVAL); |
| |
| /* 4 <2> Increment the idle count for each idle BA */ |
| for (i = 0; i < CFG_NUM_OF_RX_BA_AGREEMENTS; i++) { |
| |
| prRxBa = &prQM->arRxBaTable[i]; |
| |
| if (prRxBa->ucStatus == BA_ENTRY_STATUS_ACTIVE) { |
| |
| prStaRec = cnmGetStaRecByIndex(prAdapter, prRxBa->ucStaRecIdx); |
| |
| if (!prStaRec->fgIsInUse) { |
| DBGLOG(QM, WARN, "[Puff][%s]: (Warning) sta_rec is not inuse\n", __func__); |
| ASSERT(0); |
| } |
| /* Check HT-capabale STA */ |
| if (!(prStaRec->ucDesiredPhyTypeSet & PHY_TYPE_BIT_HT)) { |
| DBGLOG(QM, WARN, |
| "[Puff][%s]: (Warning) sta is NOT HT-capable(0x%08X)\n", |
| __func__, prStaRec->ucDesiredPhyTypeSet); |
| ASSERT(0); |
| } |
| /* 4 <2.1> Idle detected, increment idle count and see if a DELBA should be sent */ |
| if (prRxBa->u2SnapShotSN == prStaRec->au2CachedSeqCtrl[prRxBa->ucTid]) { |
| |
| prRxBa->ucIdleCount++; |
| |
| ASSERT(prRxBa->ucTid < 8); |
| switch (aucTid2ACI[prRxBa->ucTid]) { |
| case 0: /* BK */ |
| u4IdleCountThreshold = MQM_DEL_IDLE_RXBA_THRESHOLD_BK; |
| break; |
| case 1: /* BE */ |
| u4IdleCountThreshold = MQM_DEL_IDLE_RXBA_THRESHOLD_BE; |
| break; |
| case 2: /* VI */ |
| u4IdleCountThreshold = MQM_DEL_IDLE_RXBA_THRESHOLD_VI; |
| break; |
| case 3: /* VO */ |
| u4IdleCountThreshold = MQM_DEL_IDLE_RXBA_THRESHOLD_VO; |
| break; |
| } |
| |
| if (prRxBa->ucIdleCount >= u4IdleCountThreshold) { |
| mqmRxModifyBaEntryStatus(prAdapter, prRxBa, BA_ENTRY_STATUS_INVALID); |
| mqmSendDelBaFrame(prAdapter, DELBA_ROLE_RECIPIENT, prStaRec, |
| (UINT_32) prRxBa->ucTid, REASON_CODE_PEER_TIME_OUT); |
| qmDelRxBaEntry(prAdapter, prStaRec->ucIndex, prRxBa->ucTid, TRUE); |
| } |
| } |
| /* 4 <2.2> Activity detected */ |
| else { |
| prRxBa->u2SnapShotSN = prStaRec->au2CachedSeqCtrl[prRxBa->ucTid]; |
| prRxBa->ucIdleCount = 0; |
| continue; /* check the next BA entry */ |
| } |
| } |
| } |
| |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * @brief Do RX BA entry state transition |
| * |
| * @param prRxBaEntry The BA entry pointer |
| * @param eStatus The state to transition to |
| * |
| * @return (none) |
| */ |
| /*----------------------------------------------------------------------------*/ |
| VOID |
| mqmRxModifyBaEntryStatus(IN P_ADAPTER_T prAdapter, IN P_RX_BA_ENTRY_T prRxBaEntry, IN ENUM_BA_ENTRY_STATUS_T eStatus) |
| { |
| P_STA_RECORD_T prStaRec; |
| P_QUE_MGT_T prQM; |
| |
| BOOLEAN fgResetScoreBoard = FALSE; |
| |
| ASSERT(prRxBaEntry); |
| |
| prStaRec = cnmGetStaRecByIndex(prAdapter, prRxBaEntry->ucStaRecIdx); |
| ASSERT(prStaRec); |
| prQM = &prAdapter->rQM; |
| |
| if (prRxBaEntry->ucStatus == (UINT_8) eStatus) { |
| DBGLOG(QM, WARN, "[Puff][%s]: eStatus are identical...\n", __func__, prRxBaEntry->ucStatus); |
| return; |
| } |
| /* 4 <1> State transition from state X */ |
| switch (prRxBaEntry->ucStatus) { |
| |
| /* 4 <1.1> From (X = INVALID) to (ACTIVE or NEGO or DELETING) */ |
| case BA_ENTRY_STATUS_INVALID: |
| |
| /* Associate the BA entry with the STA_REC when leaving INVALID state */ |
| kalMemCopy(&prQM->arRxBaTable[prRxBaEntry->ucTid], prRxBaEntry, sizeof(RX_BA_ENTRY_T)); |
| |
| /* Increment the RX BA counter */ |
| prQM->ucRxBaCount++; |
| ASSERT(prQM->ucRxBaCount <= CFG_NUM_OF_RX_BA_AGREEMENTS); |
| |
| /* Since AMPDU may be received during INVALID state */ |
| fgResetScoreBoard = TRUE; |
| |
| /* Reset Idle Count since this BA entry is being activated now. |
| * Note: If there is no ACTIVE entry, the idle detection timer will not be started. |
| */ |
| prRxBaEntry->ucIdleCount = 0; |
| break; |
| |
| /* 4 <1.2> Other cases */ |
| default: |
| break; |
| } |
| |
| /* 4 <2> State trasition to state Y */ |
| switch (eStatus) { |
| |
| /* 4 <2.1> From (NEGO, ACTIVE, DELETING) to (Y=INVALID) */ |
| case BA_ENTRY_STATUS_INVALID: |
| |
| /* Disassociate the BA entry with the STA_REC */ |
| kalMemZero(&prQM->arRxBaTable[prRxBaEntry->ucTid], sizeof(RX_BA_ENTRY_T)); |
| |
| /* Decrement the RX BA counter */ |
| prQM->ucRxBaCount--; |
| ASSERT(prQM->ucRxBaCount < CFG_NUM_OF_RX_BA_AGREEMENTS); |
| |
| /* (TBC) */ |
| fgResetScoreBoard = TRUE; |
| |
| /* If there is not any BA agreement, stop doing idle detection */ |
| if (prQM->ucRxBaCount == 0) { |
| if (MQM_CHECK_FLAG(prAdapter->u4FlagBitmap, MQM_FLAG_IDLE_RX_BA_TIMER_STARTED)) { |
| cnmTimerStopTimer(prAdapter, &prAdapter->rMqmIdleRxBaDetectionTimer); |
| MQM_CLEAR_FLAG(prAdapter->u4FlagBitmap, MQM_FLAG_IDLE_RX_BA_TIMER_STARTED); |
| } |
| } |
| |
| break; |
| |
| /* 4 <2.2> From (any) to (Y=ACTIVE) */ |
| case BA_ENTRY_STATUS_ACTIVE: |
| |
| /* If there is at least one BA going into ACTIVE, start idle detection */ |
| if (!MQM_CHECK_FLAG(prAdapter->u4FlagBitmap, MQM_FLAG_IDLE_RX_BA_TIMER_STARTED)) { |
| cnmTimerInitTimer(prAdapter, &prAdapter->rMqmIdleRxBaDetectionTimer, |
| (PFN_MGMT_TIMEOUT_FUNC) mqmTimeoutCheckIdleRxBa, (ULONG) NULL); |
| /* No parameter */ |
| |
| cnmTimerStopTimer(prAdapter, &prAdapter->rMqmIdleRxBaDetectionTimer); |
| |
| #if MQM_IDLE_RX_BA_DETECTION |
| cnmTimerStartTimer(prAdapter, &prAdapter->rMqmIdleRxBaDetectionTimer, |
| MQM_IDLE_RX_BA_CHECK_INTERVAL); |
| MQM_SET_FLAG(prAdapter->u4FlagBitmap, MQM_FLAG_IDLE_RX_BA_TIMER_STARTED); |
| #endif |
| } |
| |
| break; |
| |
| case BA_ENTRY_STATUS_NEGO: |
| default: |
| break; |
| } |
| |
| if (fgResetScoreBoard) { |
| P_CMD_RESET_BA_SCOREBOARD_T prCmdBody; |
| |
| prCmdBody = (P_CMD_RESET_BA_SCOREBOARD_T) |
| cnmMemAlloc(prAdapter, RAM_TYPE_BUF, sizeof(CMD_RESET_BA_SCOREBOARD_T)); |
| ASSERT(prCmdBody); |
| |
| prCmdBody->ucflag = MAC_ADDR_TID_MATCH; |
| prCmdBody->ucTID = prRxBaEntry->ucTid; |
| kalMemCopy(prCmdBody->aucMacAddr, prStaRec->aucMacAddr, PARAM_MAC_ADDR_LEN); |
| |
| wlanoidResetBAScoreboard(prAdapter, prCmdBody, sizeof(CMD_RESET_BA_SCOREBOARD_T)); |
| |
| } |
| |
| DBGLOG(QM, WARN, "[Puff]QM: (RX_BA) [STA=%d TID=%d] status from %d to %d\n", |
| prRxBaEntry->ucStaRecIdx, prRxBaEntry->ucTid, prRxBaEntry->ucStatus, eStatus); |
| |
| prRxBaEntry->ucStatus = (UINT_8) eStatus; |
| |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief |
| * |
| * \param[in] |
| * |
| * \return none |
| */ |
| /*----------------------------------------------------------------------------*/ |
| VOID mqmHandleAddBaReq(IN P_ADAPTER_T prAdapter, IN P_SW_RFB_T prSwRfb) |
| { |
| P_STA_RECORD_T prStaRec; |
| P_BSS_INFO_T prBssInfo; |
| P_ACTION_ADDBA_REQ_FRAME_T prAddBaReq; |
| ACTION_ADDBA_REQ_BODY_T rAddBaReqBody; |
| P_ACTION_ADDBA_RSP_FRAME_T prAddBaRsp; |
| ACTION_ADDBA_RSP_BODY_T rAddBaRspBody; |
| P_RX_BA_ENTRY_T prRxBaEntry; |
| P_MSDU_INFO_T prTxMsduInfo; |
| P_QUE_MGT_T prQM; |
| |
| BOOLEAN fgIsReqAccepted = TRUE; /* Reject or accept the ADDBA_REQ */ |
| BOOLEAN fgIsNewEntryAdded = FALSE; /* Indicator: Whether a new RX BA entry will be added */ |
| |
| UINT_32 u4Tid; |
| UINT_32 u4StaRecIdx; |
| UINT_16 u2WinStart; |
| UINT_16 u2WinSize; |
| UINT_32 u4BuffSize; |
| |
| #if CFG_SUPPORT_BCM |
| UINT_32 u4BuffSizeBT; |
| #endif |
| |
| ASSERT(prSwRfb); |
| |
| prStaRec = prSwRfb->prStaRec; |
| prQM = &prAdapter->rQM; |
| |
| do { |
| |
| /* 4 <0> Check if this is an active HT-capable STA */ |
| /* Check STA_REC is inuse */ |
| if (!prStaRec->fgIsInUse) { |
| DBGLOG(QM, WARN, "[Puff][%s]: (Warning) sta_rec is not inuse\n", __func__); |
| break; |
| } |
| /* Check HT-capabale STA */ |
| if (!(prStaRec->ucDesiredPhyTypeSet & PHY_TYPE_BIT_HT)) { |
| DBGLOG(QM, WARN, |
| "[Puff][%s]: (Warning) sta is NOT HT-capable(0x%08X)\n", __func__, |
| prStaRec->ucDesiredPhyTypeSet); |
| break; /* To free the received ADDBA_REQ directly */ |
| } |
| /* 4 <1> Check user configurations and HW capabilities */ |
| /* Check configurations (QoS support, AMPDU RX support) */ |
| if ((!prAdapter->rWifiVar.fgSupportQoS) || |
| (!prAdapter->rWifiVar.fgSupportAmpduRx) || (!prStaRec->fgRxAmpduEn)) { |
| DBGLOG(QM, WARN, |
| "[Puff][%s]: (Warning) BA ACK Policy not supported fgSupportQoS(%d)", |
| __func__, prAdapter->rWifiVar.fgSupportQoS); |
| DBGLOG(QM, WARN, |
| "fgSupportAmpduRx(%d), fgRxAmpduEn(%d)\n", |
| prAdapter->rWifiVar.fgSupportAmpduRx, prStaRec->fgRxAmpduEn); |
| fgIsReqAccepted = FALSE; /* Will send an ADDBA_RSP with DECLINED */ |
| } |
| /* Check capability */ |
| prAddBaReq = ((P_ACTION_ADDBA_REQ_FRAME_T) (prSwRfb->pvHeader)); |
| kalMemCopy((PUINT_8) (&rAddBaReqBody), (PUINT_8) (&(prAddBaReq->aucBAParameterSet[0])), 6); |
| if ((((rAddBaReqBody.u2BAParameterSet) & BA_PARAM_SET_ACK_POLICY_MASK) >> |
| BA_PARAM_SET_ACK_POLICY_MASK_OFFSET) |
| != BA_PARAM_SET_ACK_POLICY_IMMEDIATE_BA) { /* Only Immediate_BA is supported */ |
| DBGLOG(QM, WARN, |
| "[Puff][%s]: (Warning) BA ACK Policy not supported (0x%08X)\n", |
| __func__, rAddBaReqBody.u2BAParameterSet); |
| fgIsReqAccepted = FALSE; /* Will send an ADDBA_RSP with DECLINED */ |
| } |
| |
| /* 4 <2> Determine the RX BA entry (existing or to be added) */ |
| /* Note: BA entry index = (TID, STA_REC index) */ |
| u4Tid = (((rAddBaReqBody.u2BAParameterSet) & BA_PARAM_SET_TID_MASK) >> BA_PARAM_SET_TID_MASK_OFFSET); |
| u4StaRecIdx = prStaRec->ucIndex; |
| DBGLOG(QM, WARN, |
| "[Puff][%s]: BA entry index = [TID(%d), STA_REC index(%d)]\n", __func__, u4Tid, u4StaRecIdx); |
| |
| u2WinStart = ((rAddBaReqBody.u2BAStartSeqCtrl) >> OFFSET_BAR_SSC_SN); |
| u2WinSize = (((rAddBaReqBody.u2BAParameterSet) & BA_PARAM_SET_BUFFER_SIZE_MASK) |
| >> BA_PARAM_SET_BUFFER_SIZE_MASK_OFFSET); |
| DBGLOG(QM, WARN, |
| "[Puff][%s]: BA entry info = [WinStart(%d), WinSize(%d)]\n", __func__, u2WinStart, u2WinSize); |
| |
| if (fgIsReqAccepted) { |
| |
| prRxBaEntry = &prQM->arRxBaTable[u4Tid]; |
| |
| if (!prRxBaEntry) { |
| |
| /* 4 <Case 2.1> INVALID state && BA entry available --> Add a new entry and accept */ |
| if (prQM->ucRxBaCount < CFG_NUM_OF_RX_BA_AGREEMENTS) { |
| |
| fgIsNewEntryAdded = qmAddRxBaEntry(prAdapter, |
| (UINT_8) u4StaRecIdx, |
| (UINT_8) u4Tid, u2WinStart, u2WinSize); |
| |
| if (!fgIsNewEntryAdded) { |
| DBGLOG(QM, ERROR, |
| "[Puff][%s]: (Error) Free RX BA entry alloc failure\n"); |
| fgIsReqAccepted = FALSE; |
| } else { |
| DBGLOG(QM, WARN, "[Puff][%s]: Create a new BA Entry\n"); |
| } |
| } |
| /* 4 <Case 2.2> INVALID state && BA entry unavailable --> Reject the ADDBA_REQ */ |
| else { |
| DBGLOG(QM, WARN, |
| "[Puff][%s]: (Warning) Free RX BA entry unavailable(req: %d)\n", |
| __func__, prQM->ucRxBaCount); |
| fgIsReqAccepted = FALSE; /* Will send an ADDBA_RSP with DECLINED */ |
| } |
| } else { |
| |
| /* 4 <Case 2.3> NEGO or DELETING state --> Ignore the ADDBA_REQ */ |
| /* For NEGO: do nothing. Wait for TX Done of ADDBA_RSP */ |
| /* For DELETING: do nothing. Wait for TX Done of DELBA */ |
| if (prRxBaEntry->ucStatus != BA_ENTRY_STATUS_ACTIVE) { |
| DBGLOG(QM, WARN, |
| "[Puff][%s]:(Warning)ADDBA_REQ for TID=%ld is received, status:%d)\n", |
| __func__, u4Tid, prRxBaEntry->ucStatus); |
| break; /* Ignore the ADDBA_REQ since the current state is NEGO */ |
| } |
| /* 4 <Case 2.4> ACTIVE state --> Accept */ |
| /* Send an ADDBA_RSP to accept the request again */ |
| /* else */ |
| } |
| } |
| /* 4 <3> Construct the ADDBA_RSP frame */ |
| prTxMsduInfo = (P_MSDU_INFO_T) cnmMgtPktAlloc(prAdapter, ACTION_ADDBA_RSP_FRAME_LEN); |
| prBssInfo = GET_BSS_INFO_BY_INDEX(prAdapter, prStaRec->ucBssIndex); |
| |
| if (!prTxMsduInfo) { |
| |
| /* The peer may send an ADDBA_REQ message later. |
| * Do nothing to the BA entry. No DELBA will be sent (because cnmMgtPktAlloc() may fail again). |
| * No BA deletion event will be sent to the host (because cnmMgtPktAlloc() may fail again). |
| */ |
| DBGLOG(QM, WARN, "[Puff][%s]: (Warning) ADDBA_RSP alloc failure\n", __func__); |
| |
| if (fgIsNewEntryAdded) { |
| /* If a new entry has been created due to this ADDBA_REQ, delete it */ |
| ASSERT(prRxBaEntry); |
| mqmRxModifyBaEntryStatus(prAdapter, prRxBaEntry, BA_ENTRY_STATUS_INVALID); |
| } |
| |
| break; /* Exit directly to free the ADDBA_REQ */ |
| } |
| |
| /* Fill the ADDBA_RSP message */ |
| prAddBaRsp = (P_ACTION_ADDBA_RSP_FRAME_T) ((UINT_32) (prTxMsduInfo->prPacket) + MAC_TX_RESERVED_FIELD); |
| prAddBaRsp->u2FrameCtrl = MAC_FRAME_ACTION; |
| |
| #if CFG_SUPPORT_802_11W |
| if (rsnCheckBipKeyInstalled(prAdapter, prStaRec)) { |
| DBGLOG(QM, WARN, "[Puff][%s]: (Warning) ADDBA_RSP is 80211w enabled\n", __func__); |
| prAddBaReq->u2FrameCtrl |= MASK_FC_PROTECTED_FRAME; |
| } |
| #endif |
| prAddBaRsp->u2DurationID = 0; |
| prAddBaRsp->ucCategory = CATEGORY_BLOCK_ACK_ACTION; |
| prAddBaRsp->ucAction = ACTION_ADDBA_RSP; |
| prAddBaRsp->ucDialogToken = prAddBaReq->ucDialogToken; |
| |
| DBGLOG(QM, WARN, |
| "[Puff][%s]: (Warning) ADDBA_RSP DurationID(%d) Category(%d) Action(%d) DialogToken(%d)\n", |
| __func__, prAddBaRsp->u2DurationID, prAddBaRsp->ucCategory, |
| prAddBaRsp->ucAction, prAddBaRsp->ucDialogToken); |
| |
| if (fgIsReqAccepted) |
| rAddBaRspBody.u2StatusCode = STATUS_CODE_SUCCESSFUL; |
| else |
| rAddBaRspBody.u2StatusCode = STATUS_CODE_REQ_DECLINED; |
| |
| /* WinSize = min(WinSize in ADDBA_REQ, CFG_RX_BA_MAX_WINSIZE) */ |
| u4BuffSize = (((rAddBaReqBody.u2BAParameterSet) & BA_PARAM_SET_BUFFER_SIZE_MASK) |
| >> BA_PARAM_SET_BUFFER_SIZE_MASK_OFFSET); |
| |
| /*If ADDBA req WinSize<=0 => use default WinSize(16) */ |
| if ((u4BuffSize > CFG_RX_BA_MAX_WINSIZE) || (u4BuffSize <= 0)) |
| u4BuffSize = CFG_RX_BA_MAX_WINSIZE; |
| #if CFG_SUPPORT_BCM |
| /* TODO: Call BT coexistence function to limit the winsize */ |
| u4BuffSizeBT = bcmRequestBaWinSize(); |
| DBGLOG(QM, WARN, "[Puff][%s]: (Warning) bcmRequestBaWinSize(%d)\n", __func__, u4BuffSizeBT); |
| |
| if (u4BuffSize > u4BuffSizeBT) |
| u4BuffSize = u4BuffSizeBT; |
| #endif /* CFG_SUPPORT_BCM */ |
| |
| rAddBaRspBody.u2BAParameterSet = (BA_POLICY_IMMEDIATE | |
| (u4Tid << BA_PARAM_SET_TID_MASK_OFFSET) | |
| (u4BuffSize << BA_PARAM_SET_BUFFER_SIZE_MASK_OFFSET)); |
| |
| /* TODO: Determine the BA timeout value according to the default preference */ |
| rAddBaRspBody.u2BATimeoutValue = rAddBaReqBody.u2BATimeoutValue; |
| |
| DBGLOG(QM, WARN, |
| "[Puff][%s]: (Warning) ADDBA_RSP u4BuffSize(%d) StatusCode(%d)", |
| __func__, u4BuffSize, rAddBaRspBody.u2StatusCode); |
| DBGLOG(QM, WARN, |
| "BAParameterSet(0x%08X) BATimeoutValue(%d)\n", |
| rAddBaRspBody.u2BAParameterSet, rAddBaRspBody.u2BATimeoutValue); |
| kalMemCopy((PUINT_8) (&(prAddBaRsp->aucStatusCode[0])), (PUINT_8) (&rAddBaRspBody), 6); |
| |
| COPY_MAC_ADDR(prAddBaRsp->aucDestAddr, prStaRec->aucMacAddr); |
| COPY_MAC_ADDR(prAddBaRsp->aucSrcAddr, prBssInfo->aucOwnMacAddr); |
| /* COPY_MAC_ADDR(prAddBaRsp->aucBSSID,g_aprBssInfo[prStaRec->ucNetTypeIndex]->aucBSSID); */ |
| COPY_MAC_ADDR(prAddBaRsp->aucBSSID, prAddBaReq->aucBSSID); |
| |
| /* 4 <4> Forward the ADDBA_RSP to TXM */ |
| TX_SET_MMPDU(prAdapter, |
| prTxMsduInfo, |
| prStaRec->ucBssIndex, |
| (prStaRec != NULL) ? (prStaRec->ucIndex) : (STA_REC_INDEX_NOT_FOUND), |
| WLAN_MAC_HEADER_LEN, |
| ACTION_ADDBA_RSP_FRAME_LEN, mqmCallbackAddBaRspSent, MSDU_RATE_MODE_AUTO); |
| |
| #if CFG_SUPPORT_802_11W |
| if (rsnCheckBipKeyInstalled(prAdapter, prStaRec)) { |
| DBGLOG(RSN, INFO, "Set MSDU_OPT_PROTECTED_FRAME\n"); |
| nicTxConfigPktOption(prTxMsduInfo, MSDU_OPT_PROTECTED_FRAME, TRUE); |
| } |
| #endif |
| |
| /* Note: prTxMsduInfo->ucTID is not used for transmitting the ADDBA_RSP. |
| * However, when processing TX Done of this ADDBA_RSP, the TID value is needed, so |
| * store the TID value in advance to prevent parsing the ADDBA_RSP frame |
| */ |
| prTxMsduInfo->ucTID = (UINT_8) u4Tid; |
| |
| nicTxEnqueueMsdu(prAdapter, prTxMsduInfo); |
| |
| DBGLOG(QM, WARN, |
| "[Puff][%s]: (RX_BA) ADDBA_RSP ---> peer (STA=%d TID=%ld)\n", __func__, |
| prStaRec->ucIndex, u4Tid); |
| |
| #if 0 |
| /* 4 <5> Notify the host to start buffer reordering */ |
| if (fgIsNewEntryAdded) { /* Only when a new BA entry is indeed added will the host be notified */ |
| ASSERT(fgIsReqAccepted); |
| |
| prSwRfbEventToHost = (P_SW_RFB_T) cnmMgtPktAlloc(EVENT_RX_ADDBA_PACKET_LEN); |
| |
| if (!prSwRfbEventToHost) { |
| |
| /* Note: DELBA will not be sent since cnmMgtPktAlloc() may fail again. However, |
| * it does not matter because upon receipt of AMPDUs without a RX BA agreement, |
| * MQM will send DELBA frames |
| */ |
| |
| DBGLOG(MQM, WARN, "MQM: (Warning) EVENT packet alloc failed\n"); |
| |
| /* Ensure that host and FW are synchronized */ |
| mqmRxModifyBaEntryStatus(prRxBaEntry, BA_ENTRY_STATUS_INVALID); |
| |
| break; /* Free the received ADDBA_REQ */ |
| } |
| prEventRxAddBa = (P_EVENT_RX_ADDBA_T) prSwRfbEventToHost->pucBuffer; |
| prEventRxAddBa->ucStaRecIdx = (UINT_8) u4StaRecIdx; |
| prEventRxAddBa->u2Length = EVENT_RX_ADDBA_PACKET_LEN; |
| prEventRxAddBa->ucEID = EVENT_ID_RX_ADDBA; |
| prEventRxAddBa->ucSeqNum = 0; /* Unsolicited event packet */ |
| prEventRxAddBa->u2BAParameterSet = rAddBaRspBody.u2BAParameterSet; |
| prEventRxAddBa->u2BAStartSeqCtrl = rAddBaReqBody.u2BAStartSeqCtrl; |
| prEventRxAddBa->u2BATimeoutValue = rAddBaReqBody.u2BATimeoutValue; |
| prEventRxAddBa->ucDialogToken = prAddBaReq->ucDialogToken; |
| |
| DBGLOG(MQM, INFO, |
| "MQM: (RX_BA) Event ADDBA ---> driver (STA=%ld TID=%ld WinStart=%d)\n", |
| u4StaRecIdx, u4Tid, (prEventRxAddBa->u2BAStartSeqCtrl >> 4)); |
| |
| /* Configure the SW_RFB for the Event packet */ |
| RXM_SET_EVENT_PACKET( |
| /* P_SW_RFB_T */ (P_SW_RFB_T) |
| prSwRfbEventToHost, |
| /* HIF RX Packet pointer */ |
| (PUINT_8) prEventRxAddBa, |
| /* HIF RX port number */ HIF_RX0_INDEX |
| ); |
| |
| rxmSendEventToHost(prSwRfbEventToHost); |
| |
| |
| } |
| #endif |
| |
| } while (FALSE); |
| |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief |
| * |
| * \param[in] |
| * |
| * \return none |
| */ |
| /*----------------------------------------------------------------------------*/ |
| VOID mqmHandleAddBaRsp(IN P_SW_RFB_T prSwRfb) |
| { |
| |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief |
| * |
| * \param[in] |
| * |
| * \return none |
| */ |
| /*----------------------------------------------------------------------------*/ |
| VOID mqmHandleDelBa(IN P_SW_RFB_T prSwRfb) |
| { |
| |
| } |
| |
| /*----------------------------------------------------------------------------*/ |
| /*! |
| * \brief |
| * |
| * \param[in] |
| * |
| * \return none |
| */ |
| /*----------------------------------------------------------------------------*/ |
| VOID mqmHandleBaActionFrame(IN P_ADAPTER_T prAdapter, IN P_SW_RFB_T prSwRfb) |
| { |
| P_WLAN_ACTION_FRAME prRxFrame; |
| |
| ASSERT(prAdapter); |
| ASSERT(prSwRfb); |
| |
| prRxFrame = (P_WLAN_ACTION_FRAME) prSwRfb->pvHeader; |
| DBGLOG(RLM, WARN, "[Puff][%s] Action(%d)\n", __func__, prRxFrame->ucAction); |
| |
| switch (prRxFrame->ucAction) { |
| |
| case ACTION_ADDBA_REQ: |
| DBGLOG(RLM, WARN, "[Puff][%s] (RX_BA) ADDBA_REQ <--- peer\n", __func__); |
| mqmHandleAddBaReq(prAdapter, prSwRfb); |
| break; |
| |
| case ACTION_ADDBA_RSP: |
| DBGLOG(RLM, WARN, "[Puff][%s] (RX_BA) ADDBA_RSP <--- peer\n", __func__); |
| mqmHandleAddBaRsp(prSwRfb); |
| break; |
| |
| case ACTION_DELBA: |
| DBGLOG(RLM, WARN, "[Puff][%s] (RX_BA) DELBA <--- peer\n", __func__); |
| mqmHandleDelBa(prSwRfb); |
| break; |
| |
| default: |
| DBGLOG(RLM, WARN, "[Puff][%s] Unknown BA Action Frame\n", __func__); |
| break; |
| } |
| |
| } |
| |
| #endif |
| |
| #if QM_ADAPTIVE_TC_RESOURCE_CTRL |
| VOID qmResetTcControlResource(IN P_ADAPTER_T prAdapter) |
| { |
| UINT_32 u4Idx; |
| UINT_32 u4TotalMinReservedTcResource = 0; |
| UINT_32 u4TotalTcResource = 0; |
| UINT_32 u4TotalGurantedTcResource = 0; |
| P_QUE_MGT_T prQM = &prAdapter->rQM; |
| |
| /* Initialize TC resource control variables */ |
| for (u4Idx = 0; u4Idx < TC_NUM; u4Idx++) |
| prQM->au4AverageQueLen[u4Idx] = 0; |
| |
| ASSERT(prQM->u4TimeToAdjustTcResource && prQM->u4TimeToUpdateQueLen); |
| |
| for (u4Idx = 0; u4Idx < TC_NUM; u4Idx++) { |
| prQM->au4CurrentTcResource[u4Idx] = prAdapter->rTxCtrl.rTc.au4MaxNumOfBuffer[u4Idx]; |
| |
| if (u4Idx != TC4_INDEX) { |
| u4TotalTcResource += prQM->au4CurrentTcResource[u4Idx]; |
| u4TotalGurantedTcResource += prQM->au4GuaranteedTcResource[u4Idx]; |
| u4TotalMinReservedTcResource += prQM->au4MinReservedTcResource[u4Idx]; |
| } |
| } |
| |
| /* Sanity Check */ |
| if (u4TotalMinReservedTcResource > u4TotalTcResource) |
| kalMemZero(prQM->au4MinReservedTcResource, sizeof(prQM->au4MinReservedTcResource)); |
| |
| if (u4TotalGurantedTcResource > u4TotalTcResource) |
| kalMemZero(prQM->au4GuaranteedTcResource, sizeof(prQM->au4GuaranteedTcResource)); |
| |
| u4TotalGurantedTcResource = 0; |
| |
| /* Initialize Residual TC resource */ |
| for (u4Idx = 0; u4Idx < TC_NUM; u4Idx++) { |
| if (prQM->au4GuaranteedTcResource[u4Idx] < prQM->au4MinReservedTcResource[u4Idx]) |
| prQM->au4GuaranteedTcResource[u4Idx] = prQM->au4MinReservedTcResource[u4Idx]; |
| |
| if (u4Idx != TC4_INDEX) |
| u4TotalGurantedTcResource += prQM->au4GuaranteedTcResource[u4Idx]; |
| } |
| |
| prQM->u4ResidualTcResource = u4TotalTcResource - u4TotalGurantedTcResource; |
| |
| } |
| #endif |
| |
| |
| #if CFG_SUPPORT_REPLAY_DETECTION |
| /* To change PN number to UINT64 */ |
| #define CCMPTSCPNNUM 6 |
| BOOLEAN qmRxPNtoU64(PUINT_8 pucPN, UINT_8 uPNNum, PUINT_64 pu8Rets) |
| { |
| UINT_8 ucCount = 0; |
| UINT_64 u8Data = 0; |
| UINT_64 ucTmp = 0; |
| |
| if (!pu8Rets) { |
| DBGLOG(QM, ERROR, "Please input valid pu8Rets\n"); |
| return FALSE; |
| } |
| |
| if (uPNNum > CCMPTSCPNNUM) { |
| DBGLOG(QM, ERROR, "Please input valid uPNNum:%d\n", uPNNum); |
| return FALSE; |
| } |
| |
| *pu8Rets = 0; |
| for (; ucCount < uPNNum; ucCount++) { |
| ucTmp = pucPN[ucCount]; |
| u8Data = ucTmp << 8*ucCount; |
| *pu8Rets += u8Data; |
| } |
| return TRUE; |
| } |
| |
| /* To check PN/TSC between RxStatus and local record. return TRUE if PNS is not bigger than PNT */ |
| BOOLEAN qmRxDetectReplay(PUINT_8 pucPNS, PUINT_8 pucPNT) |
| { |
| UINT_64 u8RxNum = 0; |
| UINT_64 u8LocalRec = 0; |
| |
| if (!pucPNS || !pucPNT) { |
| DBGLOG(QM, ERROR, "Please input valid PNS:%p and PNT:%p\n", pucPNS, pucPNT); |
| return TRUE; |
| } |
| |
| if (!qmRxPNtoU64(pucPNS, CCMPTSCPNNUM, &u8RxNum) |
| || !qmRxPNtoU64(pucPNT, CCMPTSCPNNUM, &u8LocalRec)) { |
| DBGLOG(QM, ERROR, "PN2U64 failed\n"); |
| return TRUE; |
| } |
| /* PN overflow ? */ |
| |
| return !(u8RxNum > u8LocalRec); |
| } |
| |
| /* TO filter broadcast and multicast data packet replay issue. */ |
| BOOLEAN qmHandleRxReplay(P_ADAPTER_T prAdapter, P_SW_RFB_T prSwRfb) |
| { |
| PUINT_8 pucPN = NULL; |
| UINT_8 ucKeyID = 0; /* 0~4 */ |
| UINT_8 ucSecMode = CIPHER_SUITE_NONE; /* CIPHER_SUITE_NONE~CIPHER_SUITE_GCMP */ |
| P_GLUE_INFO_T prGlueInfo = NULL; |
| P_GL_WPA_INFO_T prWpaInfo = NULL; |
| struct SEC_DETECT_REPLAY_INFO *prDetRplyInfo = NULL; |
| P_HW_MAC_RX_DESC_T prRxStatus = NULL; |
| UINT_8 ucBssIndex = 0; |
| P_BSS_INFO_T prBssInfo = NULL; |
| UINT_8 ucCheckZeroPN; |
| UINT_8 i; |
| |
| if (!prAdapter) |
| return TRUE; |
| if (prSwRfb->u2PacketLen <= ETHER_HEADER_LEN) |
| return TRUE; |
| |
| ucBssIndex = prSwRfb->prStaRec->ucBssIndex; |
| prBssInfo = GET_BSS_INFO_BY_INDEX(prAdapter, ucBssIndex); |
| |
| ASSERT(prBssInfo); |
| |
| prGlueInfo = prAdapter->prGlueInfo; |
| prWpaInfo = &prGlueInfo->rWpaInfo; |
| |
| if (!(prSwRfb->ucGroupVLD & BIT(RX_GROUP_VLD_1))) |
| return FALSE; |
| |
| /* BMC only need check CCMP and TKIP Cipher suite */ |
| prRxStatus = prSwRfb->prRxStatus; |
| ucSecMode = HAL_RX_STATUS_GET_SEC_MODE(prRxStatus); |
| if (ucSecMode != CIPHER_SUITE_CCMP |
| && ucSecMode != CIPHER_SUITE_TKIP) { |
| DBGLOG(QM, TRACE, "SecMode: %d and CipherGroup: %d, no need check replay\n", |
| ucSecMode, prWpaInfo->u4CipherGroup); |
| #if 0 |
| if (!(prSwRfb->ucGroupVLD & BIT(RX_GROUP_VLD_1))) { |
| DBGLOG(QM, ERROR, "Group 1 invalid\n"); |
| return TRUE; |
| } |
| #endif |
| return FALSE; |
| } |
| |
| ucKeyID = HAL_RX_STATUS_GET_KEY_ID(prRxStatus); |
| if (ucKeyID >= MAX_KEY_NUM) { |
| DBGLOG(QM, ERROR, "KeyID: %d error\n", ucKeyID); |
| return TRUE; |
| } |
| |
| prDetRplyInfo = &prBssInfo->rDetRplyInfo; |
| |
| #if 0 |
| if (prDetRplyInfo->arReplayPNInfo[ucKeyID].fgFirstPkt) { |
| prDetRplyInfo->arReplayPNInfo[ucKeyID].fgFirstPkt = FALSE; |
| HAL_RX_STATUS_GET_PN(prSwRfb->prRxStatusGroup1, prDetRplyInfo->arReplayPNInfo[ucKeyID].auPN); |
| DBGLOG(QM, INFO, |
| "First check packet. Key ID:0x%x\n", ucKeyID); |
| return FALSE; |
| } |
| #endif |
| |
| pucPN = prSwRfb->prRxStatusGroup1->aucPN; |
| DBGLOG(QM, TRACE, |
| "BC packet 0x%x:0x%x:0x%x:0x%x:0x%x:0x%x--0x%x:0x%x:0x%x:0x%x:0x%x:0x%x\n", |
| pucPN[0], pucPN[1], pucPN[2], pucPN[3], pucPN[4], pucPN[5], |
| prDetRplyInfo->arReplayPNInfo[ucKeyID].auPN[0], |
| prDetRplyInfo->arReplayPNInfo[ucKeyID].auPN[1], |
| prDetRplyInfo->arReplayPNInfo[ucKeyID].auPN[2], |
| prDetRplyInfo->arReplayPNInfo[ucKeyID].auPN[3], |
| prDetRplyInfo->arReplayPNInfo[ucKeyID].auPN[4], |
| prDetRplyInfo->arReplayPNInfo[ucKeyID].auPN[5]); |
| |
| if (prDetRplyInfo->fgKeyRscFresh == TRUE) { |
| |
| /* PN non-fresh setting */ |
| prDetRplyInfo->fgKeyRscFresh = FALSE; |
| ucCheckZeroPN = 0; |
| |
| for (i = 0; i < 8; i++) { |
| if (prSwRfb->prRxStatusGroup1->aucPN[i] == 0x0) |
| ucCheckZeroPN++; |
| } |
| |
| /* for AP start PN from 0, bypass PN check and update */ |
| if (ucCheckZeroPN == 8) { |
| DBGLOG(QM, WARN, "Fresh BC_PN with AP PN=0\n"); |
| return FALSE; |
| } |
| } |
| |
| if (qmRxDetectReplay(pucPN, prDetRplyInfo->arReplayPNInfo[ucKeyID].auPN)) { |
| DBGLOG(QM, WARN, "Drop BC replay packet!\n"); |
| return TRUE; |
| } |
| |
| HAL_RX_STATUS_GET_PN(prSwRfb->prRxStatusGroup1, prDetRplyInfo->arReplayPNInfo[ucKeyID].auPN); |
| |
| return FALSE; |
| } |
| |
| #endif |