Pileus Git - ~andy/linux/blob - drivers/staging/vt6656/int.c

   1 /*
   2  * Copyright (c) 1996, 2003 VIA Networking Technologies, Inc.
   3  * All rights reserved.
   4  *
   5  * This program is free software; you can redistribute it and/or modify
   6  * it under the terms of the GNU General Public License as published by
   7  * the Free Software Foundation; either version 2 of the License, or
   8  * (at your option) any later version.
   9  *
  10  * This program is distributed in the hope that it will be useful,
  11  * but WITHOUT ANY WARRANTY; without even the implied warranty of
  12  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
  13  * GNU General Public License for more details.
  14  *
  15  * You should have received a copy of the GNU General Public License along
  16  * with this program; if not, write to the Free Software Foundation, Inc.,
  17  * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
  18  *
  19  *
  20  * File: int.c
  21  *
  22  * Purpose: Handle USB interrupt endpoint
  23  *
  24  * Author: Jerry Chen
  25  *
  26  * Date: Apr. 2, 2004
  27  *
  28  * Functions:
  29  *
  30  * Revision History:
  31  *      04-02-2004 Jerry Chen:  Initial release
  32  *
  33  */
  34
  35 #include "int.h"
  36 #include "mib.h"
  37 #include "tmacro.h"
  38 #include "mac.h"
  39 #include "power.h"
  40 #include "bssdb.h"
  41 #include "usbpipe.h"
  42
  43 /*---------------------  Static Definitions -------------------------*/
  44 static int msglevel = MSG_LEVEL_INFO; /* MSG_LEVEL_DEBUG */
  45
  46 /*---------------------  Static Classes  ----------------------------*/
  47
  48 /*---------------------  Static Variables  --------------------------*/
  49
  50 /*---------------------  Static Functions  --------------------------*/
  51
  52 /*---------------------  Export Variables  --------------------------*/
  53
  54 /*---------------------  Export Functions  --------------------------*/
  55
  56 /*+
  57  *
  58  *  Function:   InterruptPollingThread
  59  *
  60  *  Synopsis:   Thread running at IRQL PASSIVE_LEVEL.
  61  *
  62  *  Arguments: Device Extension
  63  *
  64  *  Returns:
  65  *
  66  *  Algorithm:  Call USBD for input data;
  67  *
  68  *  History:    dd-mm-yyyy   Author    Comment
  69  *
  70  *
  71  *  Notes:
  72  *
  73  *  USB reads are by nature 'Blocking', and when in a read, the device looks
  74  *  like it's in a 'stall' condition, so we deliberately time out every second
  75  *  if we've gotten no data
  76  *
  77 -*/
  78 void INTvWorkItem(struct vnt_private *pDevice)
  79 {
  80         int ntStatus;
  81
  82         DBG_PRT(MSG_LEVEL_DEBUG, KERN_INFO"---->Interrupt Polling Thread\n");
  83
  84         spin_lock_irq(&pDevice->lock);
  85         if (pDevice->fKillEventPollingThread != true)
  86                 ntStatus = PIPEnsInterruptRead(pDevice);
  87         spin_unlock_irq(&pDevice->lock);
  88 }
  89
  90 void INTnsProcessData(struct vnt_private *pDevice)
  91 {
  92         PSINTData pINTData;
  93         struct vnt_manager *pMgmt = &pDevice->vnt_mgmt;
  94         struct net_device_stats *pStats = &pDevice->stats;
  95
  96         DBG_PRT(MSG_LEVEL_DEBUG, KERN_INFO"---->s_nsInterruptProcessData\n");
  97
  98         pINTData = (PSINTData) pDevice->intBuf.pDataBuf;
  99         if (pINTData->byTSR0 & TSR_VALID) {
 100                 STAvUpdateTDStatCounter(&(pDevice->scStatistic),
 101                                         (BYTE)(pINTData->byPkt0 & 0x0F),
 102                                         (BYTE)(pINTData->byPkt0>>4),
 103                                         pINTData->byTSR0);
 104                 BSSvUpdateNodeTxCounter(pDevice,
 105                                         &(pDevice->scStatistic),
 106                                         pINTData->byTSR0,
 107                                         pINTData->byPkt0);
 108                 /*DBG_PRN_GRP01(("TSR0 %02x\n", pINTData->byTSR0));*/
 109         }
 110         if (pINTData->byTSR1 & TSR_VALID) {
 111                 STAvUpdateTDStatCounter(&(pDevice->scStatistic),
 112                                         (BYTE)(pINTData->byPkt1 & 0x0F),
 113                                         (BYTE)(pINTData->byPkt1>>4),
 114                                         pINTData->byTSR1);
 115                 BSSvUpdateNodeTxCounter(pDevice,
 116                                         &(pDevice->scStatistic),
 117                                         pINTData->byTSR1,
 118                                         pINTData->byPkt1);
 119                 /*DBG_PRN_GRP01(("TSR1 %02x\n", pINTData->byTSR1));*/
 120         }
 121         if (pINTData->byTSR2 & TSR_VALID) {
 122                 STAvUpdateTDStatCounter(&(pDevice->scStatistic),
 123                                         (BYTE)(pINTData->byPkt2 & 0x0F),
 124                                         (BYTE)(pINTData->byPkt2>>4),
 125                                         pINTData->byTSR2);
 126                 BSSvUpdateNodeTxCounter(pDevice,
 127                                         &(pDevice->scStatistic),
 128                                         pINTData->byTSR2,
 129                                         pINTData->byPkt2);
 130                 /*DBG_PRN_GRP01(("TSR2 %02x\n", pINTData->byTSR2));*/
 131         }
 132         if (pINTData->byTSR3 & TSR_VALID) {
 133                 STAvUpdateTDStatCounter(&(pDevice->scStatistic),
 134                                         (BYTE)(pINTData->byPkt3 & 0x0F),
 135                                         (BYTE)(pINTData->byPkt3>>4),
 136                                         pINTData->byTSR3);
 137                 BSSvUpdateNodeTxCounter(pDevice,
 138                                         &(pDevice->scStatistic),
 139                                         pINTData->byTSR3,
 140                                         pINTData->byPkt3);
 141                 /*DBG_PRN_GRP01(("TSR3 %02x\n", pINTData->byTSR3));*/
 142         }
 143         if (pINTData->byISR0 != 0) {
 144                 if (pINTData->byISR0 & ISR_BNTX) {
 145                         if (pDevice->eOPMode == OP_MODE_AP) {
 146                                 if (pMgmt->byDTIMCount > 0) {
 147                                         pMgmt->byDTIMCount--;
 148                                         pMgmt->sNodeDBTable[0].bRxPSPoll =
 149                                                 false;
 150                                 } else if (pMgmt->byDTIMCount == 0) {
 151                                         /* check if multicast tx buffering */
 152                                         pMgmt->byDTIMCount =
 153                                                 pMgmt->byDTIMPeriod-1;
 154                                         pMgmt->sNodeDBTable[0].bRxPSPoll = true;
 155                                         if (pMgmt->sNodeDBTable[0].bPSEnable)
 156                                                 bScheduleCommand((void *) pDevice,
 157                                                                  WLAN_CMD_RX_PSPOLL,
 158                                                                  NULL);
 159                                 }
 160                                 bScheduleCommand((void *) pDevice,
 161                                                 WLAN_CMD_BECON_SEND,
 162                                                 NULL);
 163                         } /* if (pDevice->eOPMode == OP_MODE_AP) */
 164                 pDevice->bBeaconSent = true;
 165                 } else {
 166                         pDevice->bBeaconSent = false;
 167                 }
 168                 if (pINTData->byISR0 & ISR_TBTT) {
 169                         if (pDevice->bEnablePSMode)
 170                                 bScheduleCommand((void *) pDevice,
 171                                                 WLAN_CMD_TBTT_WAKEUP,
 172                                                 NULL);
 173                         if (pDevice->bChannelSwitch) {
 174                                 pDevice->byChannelSwitchCount--;
 175                                 if (pDevice->byChannelSwitchCount == 0)
 176                                         bScheduleCommand((void *) pDevice,
 177                                                         WLAN_CMD_11H_CHSW,
 178                                                         NULL);
 179                         }
 180                 }
 181                 pDevice->qwCurrTSF = cpu_to_le64(pINTData->qwTSF);
 182                 /*DBG_PRN_GRP01(("ISR0 = %02x ,
 183                   LoTsf =  %08x,
 184                   HiTsf =  %08x\n",
 185                   pINTData->byISR0,
 186                   pINTData->dwLoTSF,
 187                   pINTData->dwHiTSF)); */
 188
 189                 STAvUpdate802_11Counter(&pDevice->s802_11Counter,
 190                                         &pDevice->scStatistic,
 191                                         pINTData->byRTSSuccess,
 192                                         pINTData->byRTSFail,
 193                                         pINTData->byACKFail,
 194                                         pINTData->byFCSErr);
 195                 STAvUpdateIsrStatCounter(&pDevice->scStatistic,
 196                                         pINTData->byISR0,
 197                                         pINTData->byISR1);
 198         }
 199         if (pINTData->byISR1 != 0)
 200                 if (pINTData->byISR1 & ISR_GPIO3)
 201                         bScheduleCommand((void *) pDevice,
 202                                         WLAN_CMD_RADIO,
 203                                         NULL);
 204         pDevice->intBuf.uDataLen = 0;
 205         pDevice->intBuf.bInUse = false;
 206
 207         pStats->tx_packets = pDevice->scStatistic.ullTsrOK;
 208         pStats->tx_bytes = pDevice->scStatistic.ullTxDirectedBytes +
 209                 pDevice->scStatistic.ullTxMulticastBytes +
 210                 pDevice->scStatistic.ullTxBroadcastBytes;
 211         pStats->tx_errors = pDevice->scStatistic.dwTsrErr;
 212         pStats->tx_dropped = pDevice->scStatistic.dwTsrErr;
 213 }