/**************************************************************************** * Ralink Tech Inc. * 4F, No. 2 Technology 5th Rd. * Science-based Industrial Park * Hsin-chu, Taiwan, R.O.C. * (c) Copyright 2002, Ralink Technology, Inc. * * All rights reserved. Ralink's source code is an unpublished work and the * use of a copyright notice does not imply otherwise. This source code * contains confidential trade secret material of Ralink Tech. Any attemp * or participation in deciphering, decoding, reverse engineering or in any * way altering the source code is stricitly prohibited, unless the prior * written consent of Ralink Technology, Inc. is obtained. **************************************************************************** Module Name: cmm_cfg.c Abstract: Ralink WiFi Driver configuration related subroutines Revision History: Who When What --------- ---------- ---------------------------------------------- */ #include "rt_config.h" #ifdef DOT11_N_SUPPORT #if defined(RT65xx) || defined(MT7601) #define MAX_AGG_CNT 32 #elif defined(RT2883) || defined(RT3883) #define MAX_AGG_CNT 16 #else #define MAX_AGG_CNT 8 #endif /* DisplayTxAgg - display Aggregation statistics from MAC */ void DisplayTxAgg (RTMP_ADAPTER *pAd) { ULONG totalCount; ULONG aggCnt[MAX_AGG_CNT + 2]; int i; AsicReadAggCnt(pAd, aggCnt, sizeof(aggCnt) / sizeof(ULONG)); totalCount = aggCnt[0] + aggCnt[1]; if (totalCount > 0) for (i=0; iApCfg.ApCliTab[apidx].CurrentAddress, MAC_ADDR_LEN); else #endif /* APCLI_SUPPORT */ NdisMoveMemory(&macAddr[0], pAd->ApCfg.MBSSID[apidx].Bssid, MAC_ADDR_LEN); } #endif /* CONFIG_AP_SUPPORT */ iPin = macAddr[3] * 256 * 256 + macAddr[4] * 256 + macAddr[5]; iPin = iPin % 10000000; checksum = ComputeChecksum( iPin ); iPin = iPin*10 + checksum; return iPin; } static char *phy_mode_str[]={"CCK", "OFDM", "HTMIX", "GF", "VHT"}; char* get_phymode_str(int Mode) { if (Mode >= MODE_CCK && Mode <= MODE_VHT) return phy_mode_str[Mode]; else return "N/A"; } static UCHAR *phy_bw_str[] = {"20M", "40M", "80M", "10M"}; char* get_bw_str(int bandwidth) { if (bandwidth >= BW_20 && bandwidth <= BW_10) return phy_bw_str[bandwidth]; else return "N/A"; } /* ========================================================================== Description: Set Country Region to pAd->CommonCfg.CountryRegion. This command will not work, if the field of CountryRegion in eeprom is programmed. Return: TRUE if all parameters are OK, FALSE otherwise ========================================================================== */ INT RT_CfgSetCountryRegion( IN PRTMP_ADAPTER pAd, IN PSTRING arg, IN INT band) { LONG region; UCHAR *pCountryRegion; region = simple_strtol(arg, 0, 10); if (band == BAND_24G) pCountryRegion = &pAd->CommonCfg.CountryRegion; else pCountryRegion = &pAd->CommonCfg.CountryRegionForABand; /* 1. If this value is set before interface up, do not reject this value. 2. Country can be set only when EEPROM not programmed */ if (RTMP_TEST_FLAG(pAd, fRTMP_ADAPTER_INTERRUPT_IN_USE) && (*pCountryRegion & EEPROM_IS_PROGRAMMED)) { DBGPRINT(RT_DEBUG_ERROR, ("CfgSetCountryRegion():CountryRegion in eeprom was programmed\n")); return FALSE; } if((region >= 0) && (((band == BAND_24G) &&((region <= REGION_MAXIMUM_BG_BAND) || (region == REGION_31_BG_BAND) || (region == REGION_32_BG_BAND) || (region == REGION_33_BG_BAND) )) || ((band == BAND_5G) && (region <= REGION_MAXIMUM_A_BAND) )) ) { *pCountryRegion= (UCHAR) region; } else { DBGPRINT(RT_DEBUG_ERROR, ("CfgSetCountryRegion():region(%ld) out of range!\n", region)); return FALSE; } return TRUE; } static UCHAR CFG_WMODE_MAP[]={ PHY_11BG_MIXED, (WMODE_B | WMODE_G), /* 0 => B/G mixed */ PHY_11B, (WMODE_B), /* 1 => B only */ PHY_11A, (WMODE_A), /* 2 => A only */ PHY_11ABG_MIXED, (WMODE_A | WMODE_B | WMODE_G), /* 3 => A/B/G mixed */ PHY_11G, WMODE_G, /* 4 => G only */ PHY_11ABGN_MIXED, (WMODE_B | WMODE_G | WMODE_GN | WMODE_A | WMODE_AN), /* 5 => A/B/G/GN/AN mixed */ PHY_11N_2_4G, (WMODE_GN), /* 6 => N in 2.4G band only */ PHY_11GN_MIXED, (WMODE_G | WMODE_GN), /* 7 => G/GN, i.e., no CCK mode */ PHY_11AN_MIXED, (WMODE_A | WMODE_AN), /* 8 => A/N in 5 band */ PHY_11BGN_MIXED, (WMODE_B | WMODE_G | WMODE_GN), /* 9 => B/G/GN mode*/ PHY_11AGN_MIXED, (WMODE_G | WMODE_GN | WMODE_A | WMODE_AN), /* 10 => A/AN/G/GN mode, not support B mode */ PHY_11N_5G, (WMODE_AN), /* 11 => only N in 5G band */ #ifdef DOT11_VHT_AC PHY_11VHT_N_ABG_MIXED, (WMODE_B | WMODE_G | WMODE_GN |WMODE_A | WMODE_AN | WMODE_AC), /* 12 => B/G/GN/A/AN/AC mixed*/ PHY_11VHT_N_AG_MIXED, (WMODE_G | WMODE_GN |WMODE_A | WMODE_AN | WMODE_AC), /* 13 => G/GN/A/AN/AC mixed , no B mode */ PHY_11VHT_N_A_MIXED, (WMODE_A | WMODE_AN | WMODE_AC), /* 14 => A/AC/AN mixed */ PHY_11VHT_N_MIXED, (WMODE_AN | WMODE_AC), /* 15 => AC/AN mixed, but no A mode */ #endif /* DOT11_VHT_AC */ PHY_MODE_MAX, WMODE_INVALID /* default phy mode if not match */ }; static PSTRING BAND_STR[] = {"Invalid", "2.4G", "5G", "2.4G/5G"}; static PSTRING WMODE_STR[]= {"", "A", "B", "G", "gN", "aN", "AC"}; UCHAR *wmode_2_str(UCHAR wmode) { UCHAR *str; INT idx, pos, max_len; max_len = WMODE_COMP * 3; if (os_alloc_mem(NULL, &str, max_len) == NDIS_STATUS_SUCCESS) { NdisZeroMemory(str, max_len); pos = 0; for (idx = 0; idx < WMODE_COMP; idx++) { if (wmode & (1 << idx)) { if ((strlen(str) + strlen(WMODE_STR[idx + 1])) >= (max_len - 1)) break; if (strlen(str)) { NdisMoveMemory(&str[pos], "/", 1); pos++; } NdisMoveMemory(&str[pos], WMODE_STR[idx + 1], strlen(WMODE_STR[idx + 1])); pos += strlen(WMODE_STR[idx + 1]); } if (strlen(str) >= max_len) break; } return str; } else return NULL; } UCHAR cfgmode_2_wmode(UCHAR cfg_mode) { DBGPRINT(RT_DEBUG_OFF, ("cfg_mode=%d\n", cfg_mode)); if (cfg_mode >= PHY_MODE_MAX) cfg_mode = PHY_MODE_MAX; return CFG_WMODE_MAP[cfg_mode * 2 + 1]; } UCHAR wmode_2_cfgmode(UCHAR wmode) { INT index; DBGPRINT(RT_DEBUG_OFF, ("wmode=%d\n", wmode)); for (index = 0; index < PHY_MODE_MAX; index++ ) { if ( wmode == CFG_WMODE_MAP[index*2 + 1]) return CFG_WMODE_MAP[index*2]; } return PHY_11ABGN_MIXED; } static BOOLEAN wmode_valid(RTMP_ADAPTER *pAd, enum WIFI_MODE wmode) { if ((WMODE_CAP_5G(wmode) && (!PHY_CAP_5G(pAd->chipCap.phy_caps))) || (WMODE_CAP_2G(wmode) && (!PHY_CAP_2G(pAd->chipCap.phy_caps))) || (WMODE_CAP_N(wmode) && RTMP_TEST_MORE_FLAG(pAd, fRTMP_ADAPTER_DISABLE_DOT_11N)) ) return FALSE; else return TRUE; } static BOOLEAN wmode_valid_and_correct(RTMP_ADAPTER *pAd, UCHAR* wmode) { BOOLEAN ret = TRUE; UCHAR mode = *wmode; if (WMODE_CAP_5G(*wmode) && (!PHY_CAP_5G(pAd->chipCap.phy_caps))) { *wmode = *wmode & ~(WMODE_A | WMODE_AN | WMODE_AC); } else if (WMODE_CAP_2G(*wmode) && (!PHY_CAP_2G(pAd->chipCap.phy_caps))) { *wmode = *wmode & ~(WMODE_B | WMODE_G | WMODE_GN); } else if (WMODE_CAP_N(*wmode) && RTMP_TEST_MORE_FLAG(pAd, fRTMP_ADAPTER_DISABLE_DOT_11N)) { *wmode = *wmode & ~(WMODE_GN | WMODE_AN); } if ( *wmode == 0 ) ret = FALSE; return ret; } BOOLEAN wmode_band_equal(UCHAR smode, UCHAR tmode) { BOOLEAN eq = FALSE; UCHAR *str1, *str2; if ((WMODE_CAP_5G(smode) == WMODE_CAP_5G(tmode)) && (WMODE_CAP_2G(smode) == WMODE_CAP_2G(tmode))) eq = TRUE; str1 = wmode_2_str(smode); str2 = wmode_2_str(tmode); if (str1 && str2) { DBGPRINT(RT_DEBUG_TRACE, ("Old WirelessMode:%s(0x%x), " "New WirelessMode:%s(0x%x)!\n", str1, smode, str2, tmode)); } if (str1) os_free_mem(NULL, str1); if (str2) os_free_mem(NULL, str2); return eq; } /* ========================================================================== Description: Set Wireless Mode Return: TRUE if all parameters are OK, FALSE otherwise ========================================================================== */ INT RT_CfgSetWirelessMode(RTMP_ADAPTER *pAd, PSTRING arg) { LONG cfg_mode; UCHAR wmode, *mode_str; cfg_mode = simple_strtol(arg, 0, 10); /* check if chip support 5G band when WirelessMode is 5G band */ wmode = cfgmode_2_wmode((UCHAR)cfg_mode); if ((wmode == WMODE_INVALID) || (!wmode_valid_and_correct(pAd, &wmode))) { DBGPRINT(RT_DEBUG_ERROR, ("%s(): Invalid wireless mode(%ld), ChipCap(%s)\n", __FUNCTION__, cfg_mode, BAND_STR[pAd->chipCap.phy_caps & 0x3])); return FALSE; } if (wmode_band_equal(pAd->CommonCfg.PhyMode, wmode) == TRUE) DBGPRINT(RT_DEBUG_OFF, ("wmode_band_equal(): Band Equal!\n")); else DBGPRINT(RT_DEBUG_OFF, ("wmode_band_equal(): Band Not Equal!\n")); pAd->CommonCfg.PhyMode = wmode; pAd->CommonCfg.cfg_wmode = wmode; mode_str = wmode_2_str(wmode); if (mode_str) { DBGPRINT(RT_DEBUG_TRACE, ("%s(): Set WMODE=%s(0x%x)\n", __FUNCTION__, mode_str, wmode)); os_free_mem(NULL, mode_str); } return TRUE; } /* maybe can be moved to GPL code, ap_mbss.c, but the code will be open */ #ifdef CONFIG_AP_SUPPORT #ifdef MBSS_SUPPORT static UCHAR RT_CfgMbssWirelessModeMaxGet(RTMP_ADAPTER *pAd) { UCHAR wmode = 0, *mode_str; INT idx; MULTISSID_STRUCT *wdev; for(idx = 0; idx < pAd->ApCfg.BssidNum; idx++) { wdev = &pAd->ApCfg.MBSSID[idx]; mode_str = wmode_2_str(wdev->PhyMode); if (mode_str) { DBGPRINT(RT_DEBUG_TRACE, ("%s(BSS%d): wmode=%s(0x%x)\n", __FUNCTION__, idx, mode_str, wdev->PhyMode)); os_free_mem(pAd, mode_str); } wmode |= wdev->PhyMode; } mode_str = wmode_2_str(wmode); if (mode_str) { DBGPRINT(RT_DEBUG_TRACE, ("%s(): Combined WirelessMode = %s(0x%x)\n", __FUNCTION__, mode_str, wmode)); os_free_mem(pAd, mode_str); } return wmode; } /* ========================================================================== Description: Set Wireless Mode for MBSS Return: TRUE if all parameters are OK, FALSE otherwise ========================================================================== */ INT RT_CfgSetMbssWirelessMode(RTMP_ADAPTER *pAd, PSTRING arg) { LONG cfg_mode; UCHAR wmode; cfg_mode = simple_strtol(arg, 0, 10); wmode = cfgmode_2_wmode((UCHAR)cfg_mode); if ((wmode == WMODE_INVALID) || (!wmode_valid(pAd, wmode))) { DBGPRINT(RT_DEBUG_ERROR, ("%s(): Invalid wireless mode(%d, wmode=0x%x), ChipCap(%s)\n", __FUNCTION__, cfg_mode, wmode, BAND_STR[pAd->chipCap.phy_caps & 0x3])); return FALSE; } if (WMODE_CAP_5G(wmode) && WMODE_CAP_2G(wmode)) { DBGPRINT(RT_DEBUG_ERROR, ("AP cannot support 2.4G/5G band mxied mode!\n")); return FALSE; } if (pAd->ApCfg.BssidNum > 1) { /* pAd->CommonCfg.PhyMode = maximum capability of all MBSS */ if (wmode_band_equal(pAd->CommonCfg.PhyMode, wmode) == TRUE) { wmode = RT_CfgMbssWirelessModeMaxGet(pAd); DBGPRINT(RT_DEBUG_TRACE, ("mbss> Maximum phy mode = %d!\n", wmode)); } else { UINT32 IdBss; /* replace all phy mode with the one with different band */ DBGPRINT(RT_DEBUG_TRACE, ("mbss> Different band with the current one!\n")); DBGPRINT(RT_DEBUG_TRACE, ("mbss> Reset band of all BSS to the new one!\n")); for(IdBss=0; IdBssApCfg.BssidNum; IdBss++) pAd->ApCfg.MBSSID[IdBss].PhyMode = wmode; } } pAd->CommonCfg.PhyMode = wmode; pAd->CommonCfg.cfg_wmode = wmode; return TRUE; } #endif /* MBSS_SUPPORT */ #endif /* CONFIG_AP_SUPPORT */ static BOOLEAN RT_isLegalCmdBeforeInfUp( IN PSTRING SetCmd) { BOOLEAN TestFlag; TestFlag = !strcmp(SetCmd, "Debug") || #ifdef CONFIG_APSTA_MIXED_SUPPORT !strcmp(SetCmd, "OpMode") || #endif /* CONFIG_APSTA_MIXED_SUPPORT */ #ifdef EXT_BUILD_CHANNEL_LIST !strcmp(SetCmd, "CountryCode") || !strcmp(SetCmd, "DfsType") || !strcmp(SetCmd, "ChannelListAdd") || !strcmp(SetCmd, "ChannelListShow") || !strcmp(SetCmd, "ChannelListDel") || #endif /* EXT_BUILD_CHANNEL_LIST */ #ifdef SINGLE_SKU !strcmp(SetCmd, "ModuleTxpower") || #endif /* SINGLE_SKU */ FALSE; /* default */ return TestFlag; } INT RT_CfgSetShortSlot( IN PRTMP_ADAPTER pAd, IN PSTRING arg) { LONG ShortSlot; ShortSlot = simple_strtol(arg, 0, 10); if (ShortSlot == 1) pAd->CommonCfg.bUseShortSlotTime = TRUE; else if (ShortSlot == 0) pAd->CommonCfg.bUseShortSlotTime = FALSE; else return FALSE; /*Invalid argument */ return TRUE; } /* ========================================================================== Description: Set WEP KEY base on KeyIdx Return: TRUE if all parameters are OK, FALSE otherwise ========================================================================== */ INT RT_CfgSetWepKey( IN PRTMP_ADAPTER pAd, IN PSTRING keyString, IN CIPHER_KEY *pSharedKey, IN INT keyIdx) { INT KeyLen; INT i; /*UCHAR CipherAlg = CIPHER_NONE;*/ BOOLEAN bKeyIsHex = FALSE; /* TODO: Shall we do memset for the original key info??*/ memset(pSharedKey, 0, sizeof(CIPHER_KEY)); KeyLen = strlen(keyString); switch (KeyLen) { case 5: /*wep 40 Ascii type*/ case 13: /*wep 104 Ascii type*/ bKeyIsHex = FALSE; pSharedKey->KeyLen = KeyLen; NdisMoveMemory(pSharedKey->Key, keyString, KeyLen); break; case 10: /*wep 40 Hex type*/ case 26: /*wep 104 Hex type*/ for(i=0; i < KeyLen; i++) { if( !isxdigit(*(keyString+i)) ) return FALSE; /*Not Hex value;*/ } bKeyIsHex = TRUE; pSharedKey->KeyLen = KeyLen/2 ; AtoH(keyString, pSharedKey->Key, pSharedKey->KeyLen); break; default: /*Invalid argument */ DBGPRINT(RT_DEBUG_TRACE, ("RT_CfgSetWepKey(keyIdx=%d):Invalid argument (arg=%s)\n", keyIdx, keyString)); return FALSE; } pSharedKey->CipherAlg = ((KeyLen % 5) ? CIPHER_WEP128 : CIPHER_WEP64); DBGPRINT(RT_DEBUG_TRACE, ("RT_CfgSetWepKey:(KeyIdx=%d,type=%s, Alg=%s)\n", keyIdx, (bKeyIsHex == FALSE ? "Ascii" : "Hex"), CipherName[pSharedKey->CipherAlg])); return TRUE; } /* ========================================================================== Description: Set WPA PSK key Arguments: pAdapter Pointer to our adapter keyString WPA pre-shared key string pHashStr String used for password hash function hashStrLen Lenght of the hash string pPMKBuf Output buffer of WPAPSK key Return: TRUE if all parameters are OK, FALSE otherwise ========================================================================== */ INT RT_CfgSetWPAPSKKey( IN RTMP_ADAPTER *pAd, IN PSTRING keyString, IN INT keyStringLen, IN UCHAR *pHashStr, IN INT hashStrLen, OUT PUCHAR pPMKBuf) { UCHAR keyMaterial[40]; if ((keyStringLen < 8) || (keyStringLen > 64)) { DBGPRINT(RT_DEBUG_TRACE, ("WPAPSK Key length(%d) error, required 8 ~ 64 characters!(keyStr=%s)\n", keyStringLen, keyString)); return FALSE; } NdisZeroMemory(pPMKBuf, 32); if (keyStringLen == 64) { AtoH(keyString, pPMKBuf, 32); } else { RtmpPasswordHash(keyString, pHashStr, hashStrLen, keyMaterial); NdisMoveMemory(pPMKBuf, keyMaterial, 32); } return TRUE; } INT RT_CfgSetFixedTxPhyMode(PSTRING arg) { INT fix_tx_mode = FIXED_TXMODE_HT; ULONG value; if (rtstrcasecmp(arg, "OFDM") == TRUE) fix_tx_mode = FIXED_TXMODE_OFDM; else if (rtstrcasecmp(arg, "CCK") == TRUE) fix_tx_mode = FIXED_TXMODE_CCK; else if (rtstrcasecmp(arg, "HT") == TRUE) fix_tx_mode = FIXED_TXMODE_HT; else if (rtstrcasecmp(arg, "VHT") == TRUE) fix_tx_mode = FIXED_TXMODE_VHT; else { value = simple_strtol(arg, 0, 10); switch (value) { case FIXED_TXMODE_CCK: case FIXED_TXMODE_OFDM: case FIXED_TXMODE_HT: case FIXED_TXMODE_VHT: fix_tx_mode = value; default: fix_tx_mode = FIXED_TXMODE_HT; } } return fix_tx_mode; } INT RT_CfgSetMacAddress( IN PRTMP_ADAPTER pAd, IN PSTRING arg) { INT i, mac_len; /* Mac address acceptable format 01:02:03:04:05:06 length 17 */ mac_len = strlen(arg); if(mac_len != 17) { DBGPRINT(RT_DEBUG_ERROR, ("%s : invalid length (%d)\n", __FUNCTION__, mac_len)); return FALSE; } if(strcmp(arg, "00:00:00:00:00:00") == 0) { DBGPRINT(RT_DEBUG_ERROR, ("%s : invalid mac setting \n", __FUNCTION__)); return FALSE; } for (i = 0; i < MAC_ADDR_LEN; i++) { AtoH(arg, &pAd->CurrentAddress[i], 1); arg = arg + 3; } pAd->bLocalAdminMAC = TRUE; return TRUE; } INT RT_CfgSetTxMCSProc(PSTRING arg, BOOLEAN *pAutoRate) { INT Value = simple_strtol(arg, 0, 10); INT TxMcs; if ((Value >= 0 && Value <= 23) || (Value == 32)) /* 3*3*/ { TxMcs = Value; *pAutoRate = FALSE; } else { TxMcs = MCS_AUTO; *pAutoRate = TRUE; } return TxMcs; } INT RT_CfgSetAutoFallBack( IN PRTMP_ADAPTER pAd, IN PSTRING arg) { TX_RTY_CFG_STRUC tx_rty_cfg; UCHAR AutoFallBack = (UCHAR)simple_strtol(arg, 0, 10); RTMP_IO_READ32(pAd, TX_RTY_CFG, &tx_rty_cfg.word); tx_rty_cfg.field.TxautoFBEnable = (AutoFallBack) ? 1 : 0; RTMP_IO_WRITE32(pAd, TX_RTY_CFG, tx_rty_cfg.word); DBGPRINT(RT_DEBUG_TRACE, ("RT_CfgSetAutoFallBack::(tx_rty_cfg=0x%x)\n", tx_rty_cfg.word)); return TRUE; } #ifdef WSC_INCLUDED INT RT_CfgSetWscPinCode( IN RTMP_ADAPTER *pAd, IN PSTRING pPinCodeStr, OUT PWSC_CTRL pWscControl) { UINT pinCode; pinCode = (UINT) simple_strtol(pPinCodeStr, 0, 10); /* When PinCode is 03571361, return value is 3571361.*/ if (strlen(pPinCodeStr) == 4) { pWscControl->WscEnrolleePinCode = pinCode; pWscControl->WscEnrolleePinCodeLen = 4; } else if ( ValidateChecksum(pinCode) ) { pWscControl->WscEnrolleePinCode = pinCode; pWscControl->WscEnrolleePinCodeLen = 8; } else { DBGPRINT(RT_DEBUG_ERROR, ("RT_CfgSetWscPinCode(): invalid Wsc PinCode (%d)\n", pinCode)); return FALSE; } DBGPRINT(RT_DEBUG_TRACE, ("RT_CfgSetWscPinCode():Wsc PinCode=%d\n", pinCode)); return TRUE; } #endif /* WSC_INCLUDED */ /* ======================================================================== Routine Description: Handler for CMD_RTPRIV_IOCTL_STA_SIOCGIWNAME. Arguments: pAd - WLAN control block pointer *pData - the communication data pointer Data - the communication data Return Value: NDIS_STATUS_SUCCESS or NDIS_STATUS_FAILURE Note: ======================================================================== */ INT RtmpIoctl_rt_ioctl_giwname( IN RTMP_ADAPTER *pAd, IN VOID *pData, IN ULONG Data) { UCHAR CurOpMode = OPMODE_AP; if (CurOpMode == OPMODE_AP) { strcpy(pData, "RTWIFI SoftAP"); } return NDIS_STATUS_SUCCESS; } INT RTMP_COM_IoctlHandle( IN VOID *pAdSrc, IN RTMP_IOCTL_INPUT_STRUCT *wrq, IN INT cmd, IN USHORT subcmd, IN VOID *pData, IN ULONG Data) { PRTMP_ADAPTER pAd = (PRTMP_ADAPTER)pAdSrc; POS_COOKIE pObj = (POS_COOKIE)pAd->OS_Cookie; INT Status = NDIS_STATUS_SUCCESS, i; UCHAR PermanentAddress[MAC_ADDR_LEN]; USHORT Addr01, Addr23, Addr45; pObj = pObj; /* avoid compile warning */ switch(cmd) { case CMD_RTPRIV_IOCTL_NETDEV_GET: /* get main net_dev */ { VOID **ppNetDev = (VOID **)pData; *ppNetDev = (VOID *)(pAd->net_dev); } break; case CMD_RTPRIV_IOCTL_NETDEV_SET: /* set main net_dev */ pAd->net_dev = pData; #ifdef CONFIG_AP_SUPPORT pAd->ApCfg.MBSSID[MAIN_MBSSID].MSSIDDev = pData; #endif /* CONFIG_AP_SUPPORT */ break; case CMD_RTPRIV_IOCTL_OPMODE_GET: /* get Operation Mode */ *(ULONG *)pData = pAd->OpMode; break; case CMD_RTPRIV_IOCTL_TASK_LIST_GET: /* get all Tasks */ { RT_CMD_WAIT_QUEUE_LIST *pList = (RT_CMD_WAIT_QUEUE_LIST *)pData; pList->pMlmeTask = &pAd->mlmeTask; #ifdef RTMP_TIMER_TASK_SUPPORT pList->pTimerTask = &pAd->timerTask; #endif /* RTMP_TIMER_TASK_SUPPORT */ pList->pCmdQTask = &pAd->cmdQTask; #ifdef WSC_INCLUDED pList->pWscTask = &pAd->wscTask; #endif /* WSC_INCLUDED */ } break; case CMD_RTPRIV_IOCTL_IRQ_INIT: /* init IRQ */ RTMP_IRQ_INIT(pAd); break; case CMD_RTPRIV_IOCTL_IRQ_RELEASE: /* release IRQ */ RTMP_OS_IRQ_RELEASE(pAd, pAd->net_dev); break; case CMD_RTPRIV_IOCTL_NIC_NOT_EXIST: /* set driver state to fRTMP_ADAPTER_NIC_NOT_EXIST */ RTMP_SET_FLAG(pAd, fRTMP_ADAPTER_NIC_NOT_EXIST); break; case CMD_RTPRIV_IOCTL_MCU_SLEEP_CLEAR: RTMP_CLEAR_PSFLAG(pAd, fRTMP_PS_MCU_SLEEP); break; #ifdef CONFIG_APSTA_MIXED_SUPPORT case CMD_RTPRIV_IOCTL_MAX_IN_BIT: /* set MAX_IN_BIT for WMM */ CW_MAX_IN_BITS = Data; break; #endif /* CONFIG_APSTA_MIXED_SUPPORT */ case CMD_RTPRIV_IOCTL_ADAPTER_SUSPEND_SET: /* set driver state to fRTMP_ADAPTER_SUSPEND */ RTMP_SET_FLAG(pAd,fRTMP_ADAPTER_SUSPEND); break; case CMD_RTPRIV_IOCTL_ADAPTER_SUSPEND_CLEAR: /* clear driver state to fRTMP_ADAPTER_SUSPEND */ RTMP_CLEAR_FLAG(pAd,fRTMP_ADAPTER_SUSPEND); break; case CMD_RTPRIV_IOCTL_ADAPTER_RT28XX_USB_ASICRADIO_OFF: /* RT28xxUsbAsicRadioOff */ //RT28xxUsbAsicRadioOff(pAd); ASIC_RADIO_OFF(pAd, SUSPEND_RADIO_OFF); break; case CMD_RTPRIV_IOCTL_ADAPTER_RT28XX_USB_ASICRADIO_ON: /* RT28xxUsbAsicRadioOn */ //RT28xxUsbAsicRadioOn(pAd); ASIC_RADIO_ON(pAd, RESUME_RADIO_ON); break; case CMD_RTPRIV_IOCTL_SANITY_CHECK: /* sanity check before IOCTL */ if ((!RTMP_TEST_FLAG(pAd, fRTMP_ADAPTER_INTERRUPT_IN_USE)) #ifdef IFUP_IN_PROBE || (RTMP_TEST_FLAG(pAd, fRTMP_ADAPTER_RESET_IN_PROGRESS)) || (RTMP_TEST_FLAG(pAd, fRTMP_ADAPTER_HALT_IN_PROGRESS)) || (RTMP_TEST_FLAG(pAd, fRTMP_ADAPTER_NIC_NOT_EXIST)) #endif /* IFUP_IN_PROBE */ ) { if(pData == NULL || RT_isLegalCmdBeforeInfUp((PSTRING) pData) == FALSE) return NDIS_STATUS_FAILURE; } break; case CMD_RTPRIV_IOCTL_SIOCGIWFREQ: /* get channel number */ *(ULONG *)pData = pAd->CommonCfg.Channel; break; case CMD_RTPRIV_IOCTL_BEACON_UPDATE: /* update all beacon contents */ #ifdef CONFIG_AP_SUPPORT APMakeAllBssBeacon(pAd); APUpdateAllBeaconFrame(pAd); #endif /* CONFIG_AP_SUPPORT */ break; case CMD_RTPRIV_IOCTL_RXPATH_GET: /* get the number of rx path */ *(ULONG *)pData = pAd->Antenna.field.RxPath; break; case CMD_RTPRIV_IOCTL_CHAN_LIST_NUM_GET: *(ULONG *)pData = pAd->ChannelListNum; break; case CMD_RTPRIV_IOCTL_CHAN_LIST_GET: { UINT32 i; UCHAR *pChannel = (UCHAR *)pData; for (i = 1; i <= pAd->ChannelListNum; i++) { *pChannel = pAd->ChannelList[i-1].Channel; pChannel ++; } } break; case CMD_RTPRIV_IOCTL_FREQ_LIST_GET: { UINT32 i; UINT32 *pFreq = (UINT32 *)pData; UINT32 m; for (i = 1; i <= pAd->ChannelListNum; i++) { m = 2412000; MAP_CHANNEL_ID_TO_KHZ(pAd->ChannelList[i-1].Channel, m); (*pFreq) = m; pFreq ++; } } break; #ifdef EXT_BUILD_CHANNEL_LIST case CMD_RTPRIV_SET_PRECONFIG_VALUE: /* Set some preconfigured value before interface up*/ pAd->CommonCfg.DfsType = MAX_RD_REGION; break; #endif /* EXT_BUILD_CHANNEL_LIST */ #ifdef RTMP_USB_SUPPORT case CMD_RTPRIV_IOCTL_USB_MORE_FLAG_SET: { RT_CMD_USB_MORE_FLAG_CONFIG *pConfig; UINT32 VendorID, ProductID; pConfig = (RT_CMD_USB_MORE_FLAG_CONFIG *)pData; VendorID = pConfig->VendorID; ProductID = pConfig->ProductID; if (VendorID == 0x0DB0) { if ((ProductID == 0x871C) || (ProductID == 0x822C)) { RTMP_SET_MORE_FLAG(pAd, (fRTMP_ADAPTER_DISABLE_DOT_11N | fRTMP_ADAPTER_WSC_PBC_PIN0)); } if ((ProductID == 0x871A) || (ProductID == 0x822A)) { RTMP_SET_MORE_FLAG(pAd, fRTMP_ADAPTER_DISABLE_DOT_11N); } if ((ProductID == 0x871B) || (ProductID == 0x822B)) { RTMP_SET_MORE_FLAG(pAd, fRTMP_ADAPTER_WSC_PBC_PIN0); } } if (VendorID == 0x07D1) { if (ProductID == 0x3C0F) RTMP_SET_MORE_FLAG(pAd, fRTMP_ADAPTER_DISABLE_DOT_11N); } } break; case CMD_RTPRIV_IOCTL_USB_CONFIG_INIT: { RT_CMD_USB_DEV_CONFIG *pConfig; UINT32 i; pConfig = (RT_CMD_USB_DEV_CONFIG *)pData; pAd->NumberOfPipes = pConfig->NumberOfPipes; pAd->BulkInMaxPacketSize = pConfig->BulkInMaxPacketSize; pAd->BulkOutMaxPacketSize = pConfig->BulkOutMaxPacketSize; for (i = 0; i < 6; i++) pAd->BulkOutEpAddr[i] = pConfig->BulkOutEpAddr[i]; for (i = 0; i < 6; i++) { DBGPRINT(RT_DEBUG_OFF, ("%s():pAd->BulkOutEpAddr=0x%x\n", __FUNCTION__, pAd->BulkOutEpAddr[i])); } for (i = 0; i < 2; i++) pAd->BulkInEpAddr[i] = pConfig->BulkInEpAddr[i]; pAd->config = pConfig->pConfig; } break; case CMD_RTPRIV_IOCTL_USB_SUSPEND: pAd->PM_FlgSuspend = 1; if (Data) { RTUSBCancelPendingBulkInIRP(pAd); RTUSBCancelPendingBulkOutIRP(pAd); } break; case CMD_RTPRIV_IOCTL_USB_RESUME: pAd->PM_FlgSuspend = 0; break; #endif /* RTMP_USB_SUPPORT */ #ifdef RT_CFG80211_SUPPORT case CMD_RTPRIV_IOCTL_CFG80211_CFG_START: RT_CFG80211_REINIT(pAd); RT_CFG80211_CRDA_REG_RULE_APPLY(pAd); break; #endif /* RT_CFG80211_SUPPORT */ #ifdef INF_PPA_SUPPORT case CMD_RTPRIV_IOCTL_INF_PPA_INIT: os_alloc_mem(NULL, (UCHAR **)&(pAd->pDirectpathCb), sizeof(PPA_DIRECTPATH_CB)); break; case CMD_RTPRIV_IOCTL_INF_PPA_EXIT: if (ppa_hook_directpath_register_dev_fn && pAd->PPAEnable==TRUE) { UINT status; status=ppa_hook_directpath_register_dev_fn(&pAd->g_if_id, pAd->net_dev, NULL, 0); DBGPRINT(RT_DEBUG_TRACE, ("unregister PPA:g_if_id=%d status=%d\n",pAd->g_if_id,status)); } os_free_mem(NULL, pAd->pDirectpathCb); break; #endif /* INF_PPA_SUPPORT*/ case CMD_RTPRIV_IOCTL_VIRTUAL_INF_UP: /* interface up */ { RT_CMD_INF_UP_DOWN *pInfConf = (RT_CMD_INF_UP_DOWN *)pData; if (VIRTUAL_IF_NUM(pAd) == 0) { if (pInfConf->rt28xx_open(pAd->net_dev) != 0) { DBGPRINT(RT_DEBUG_TRACE, ("rt28xx_open return fail!\n")); return NDIS_STATUS_FAILURE; } } else { #ifdef CONFIG_AP_SUPPORT extern VOID APMakeAllBssBeacon(IN PRTMP_ADAPTER pAd); extern VOID APUpdateAllBeaconFrame(IN PRTMP_ADAPTER pAd); APMakeAllBssBeacon(pAd); APUpdateAllBeaconFrame(pAd); #endif /* CONFIG_AP_SUPPORT */ } VIRTUAL_IF_INC(pAd); } break; case CMD_RTPRIV_IOCTL_VIRTUAL_INF_DOWN: /* interface down */ { RT_CMD_INF_UP_DOWN *pInfConf = (RT_CMD_INF_UP_DOWN *)pData; VIRTUAL_IF_DEC(pAd); if (VIRTUAL_IF_NUM(pAd) == 0) pInfConf->rt28xx_close(pAd->net_dev); } break; case CMD_RTPRIV_IOCTL_VIRTUAL_INF_GET: /* get virtual interface number */ *(ULONG *)pData = VIRTUAL_IF_NUM(pAd); break; case CMD_RTPRIV_IOCTL_INF_TYPE_GET: /* get current interface type */ *(ULONG *)pData = pAd->infType; break; case CMD_RTPRIV_IOCTL_INF_STATS_GET: /* get statistics */ { RT_CMD_STATS *pStats = (RT_CMD_STATS *)pData; pStats->pStats = pAd->stats; if(pAd->OpMode == OPMODE_STA) { pStats->rx_packets = pAd->WlanCounters.ReceivedFragmentCount.QuadPart; pStats->tx_packets = pAd->WlanCounters.TransmittedFragmentCount.QuadPart; pStats->rx_bytes = pAd->RalinkCounters.ReceivedByteCount; pStats->tx_bytes = pAd->RalinkCounters.TransmittedByteCount; pStats->rx_errors = pAd->Counters8023.RxErrors; pStats->tx_errors = pAd->Counters8023.TxErrors; pStats->multicast = pAd->WlanCounters.MulticastReceivedFrameCount.QuadPart; /* multicast packets received*/ pStats->collisions = pAd->Counters8023.OneCollision + pAd->Counters8023.MoreCollisions; /* Collision packets*/ pStats->rx_over_errors = pAd->Counters8023.RxNoBuffer; /* receiver ring buff overflow*/ pStats->rx_crc_errors = 0;/*pAd->WlanCounters.FCSErrorCount; recved pkt with crc error*/ pStats->rx_frame_errors = pAd->Counters8023.RcvAlignmentErrors; /* recv'd frame alignment error*/ pStats->rx_fifo_errors = pAd->Counters8023.RxNoBuffer; /* recv'r fifo overrun*/ } #ifdef CONFIG_AP_SUPPORT else if(pAd->OpMode == OPMODE_AP) { INT index; for(index = 0; index < MAX_MBSSID_NUM(pAd); index++) { if (pAd->ApCfg.MBSSID[index].MSSIDDev == (PNET_DEV)(pStats->pNetDev)) { break; } } if(index >= MAX_MBSSID_NUM(pAd)) { //reset counters pStats->rx_packets = 0; pStats->tx_packets = 0; pStats->rx_bytes = 0; pStats->tx_bytes = 0; pStats->rx_errors = 0; pStats->tx_errors = 0; pStats->multicast = 0; /* multicast packets received*/ pStats->collisions = 0; /* Collision packets*/ pStats->rx_over_errors = 0; /* receiver ring buff overflow*/ pStats->rx_crc_errors = 0; /* recved pkt with crc error*/ pStats->rx_frame_errors = 0; /* recv'd frame alignment error*/ pStats->rx_fifo_errors = 0; /* recv'r fifo overrun*/ DBGPRINT(RT_DEBUG_ERROR, ("CMD_RTPRIV_IOCTL_INF_STATS_GET: can not find mbss I/F\n")); return NDIS_STATUS_FAILURE; } pStats->rx_packets = pAd->ApCfg.MBSSID[index].RxCount; pStats->tx_packets = pAd->ApCfg.MBSSID[index].TxCount; pStats->rx_bytes = pAd->ApCfg.MBSSID[index].ReceivedByteCount; pStats->tx_bytes = pAd->ApCfg.MBSSID[index].TransmittedByteCount; pStats->rx_errors = pAd->ApCfg.MBSSID[index].RxErrorCount; pStats->tx_errors = pAd->ApCfg.MBSSID[index].TxErrorCount; pStats->multicast = pAd->ApCfg.MBSSID[index].mcPktsRx; /* multicast packets received */ pStats->collisions = 0; /* Collision packets*/ pStats->rx_over_errors = 0; /* receiver ring buff overflow*/ pStats->rx_crc_errors = 0;/* recved pkt with crc error*/ pStats->rx_frame_errors = 0; /* recv'd frame alignment error*/ pStats->rx_fifo_errors = 0; /* recv'r fifo overrun*/ } #endif } break; case CMD_RTPRIV_IOCTL_INF_IW_STATUS_GET: /* get wireless statistics */ { UCHAR CurOpMode = OPMODE_AP; #ifdef CONFIG_AP_SUPPORT PMAC_TABLE_ENTRY pMacEntry = NULL; #endif /* CONFIG_AP_SUPPORT */ RT_CMD_IW_STATS *pStats = (RT_CMD_IW_STATS *)pData; pStats->qual = 0; pStats->level = 0; pStats->noise = 0; pStats->pStats = pAd->iw_stats; /*check if the interface is down*/ if(!RTMP_TEST_FLAG(pAd, fRTMP_ADAPTER_INTERRUPT_IN_USE)) return NDIS_STATUS_FAILURE; #ifdef CONFIG_AP_SUPPORT if (CurOpMode == OPMODE_AP) { #ifdef APCLI_SUPPORT if ((pStats->priv_flags == INT_APCLI) ) { INT ApCliIdx = ApCliIfLookUp(pAd, (PUCHAR)pStats->dev_addr); if ((ApCliIdx >= 0) && VALID_WCID(pAd->ApCfg.ApCliTab[ApCliIdx].MacTabWCID)) pMacEntry = &pAd->MacTab.Content[pAd->ApCfg.ApCliTab[ApCliIdx].MacTabWCID]; } else #endif /* APCLI_SUPPORT */ { /* only AP client support wireless stats function. return NULL pointer for all other cases. */ pMacEntry = NULL; } } #endif /* CONFIG_AP_SUPPORT */ #ifdef CONFIG_AP_SUPPORT if (CurOpMode == OPMODE_AP) { if (pMacEntry != NULL) pStats->qual = ((pMacEntry->ChannelQuality * 12)/10 + 10); else pStats->qual = ((pAd->Mlme.ChannelQuality * 12)/10 + 10); } #endif /* CONFIG_AP_SUPPORT */ if (pStats->qual > 100) pStats->qual = 100; #ifdef CONFIG_AP_SUPPORT if (CurOpMode == OPMODE_AP) { if (pMacEntry != NULL) pStats->level = RTMPMaxRssi(pAd, pMacEntry->RssiSample.AvgRssi0, pMacEntry->RssiSample.AvgRssi1, pMacEntry->RssiSample.AvgRssi2); } #endif /* CONFIG_AP_SUPPORT */ #ifdef CONFIG_AP_SUPPORT pStats->noise = RTMPMaxRssi(pAd, pAd->ApCfg.RssiSample.AvgRssi0, pAd->ApCfg.RssiSample.AvgRssi1, pAd->ApCfg.RssiSample.AvgRssi2) - RTMPMinSnr(pAd, pAd->ApCfg.RssiSample.AvgSnr0, pAd->ApCfg.RssiSample.AvgSnr1); #endif /* CONFIG_AP_SUPPORT */ } break; case CMD_RTPRIV_IOCTL_INF_MAIN_CREATE: *(VOID **)pData = RtmpPhyNetDevMainCreate(pAd); break; case CMD_RTPRIV_IOCTL_INF_MAIN_ID_GET: *(ULONG *)pData = INT_MAIN; break; case CMD_RTPRIV_IOCTL_INF_MAIN_CHECK: if (Data != INT_MAIN) return NDIS_STATUS_FAILURE; break; case CMD_RTPRIV_IOCTL_INF_P2P_CHECK: if (Data != INT_P2P) return NDIS_STATUS_FAILURE; break; #ifdef WDS_SUPPORT case CMD_RTPRIV_IOCTL_WDS_INIT: WDS_Init(pAd, pData); break; case CMD_RTPRIV_IOCTL_WDS_REMOVE: WDS_Remove(pAd); break; case CMD_RTPRIV_IOCTL_WDS_STATS_GET: if (Data == INT_WDS) { if (WDS_StatsGet(pAd, pData) != TRUE) return NDIS_STATUS_FAILURE; } else return NDIS_STATUS_FAILURE; break; #endif /* WDS_SUPPORT */ #ifdef RALINK_ATE #ifdef RALINK_QA case CMD_RTPRIV_IOCTL_ATE: RtmpDoAte(pAd, wrq, pData); break; #endif /* RALINK_QA */ #endif /* RALINK_ATE */ case CMD_RTPRIV_IOCTL_MAC_ADDR_GET: RT28xx_EEPROM_READ16(pAd, 0x04, Addr01); RT28xx_EEPROM_READ16(pAd, 0x06, Addr23); RT28xx_EEPROM_READ16(pAd, 0x08, Addr45); PermanentAddress[0] = (UCHAR)(Addr01 & 0xff); PermanentAddress[1] = (UCHAR)(Addr01 >> 8); PermanentAddress[2] = (UCHAR)(Addr23 & 0xff); PermanentAddress[3] = (UCHAR)(Addr23 >> 8); PermanentAddress[4] = (UCHAR)(Addr45 & 0xff); PermanentAddress[5] = (UCHAR)(Addr45 >> 8); for(i=0; i<6; i++) *(UCHAR *)(pData+i) = PermanentAddress[i]; break; #ifdef CONFIG_AP_SUPPORT case CMD_RTPRIV_IOCTL_AP_SIOCGIWRATEQ: /* handle for SIOCGIWRATEQ */ { RT_CMD_IOCTL_RATE *pRate = (RT_CMD_IOCTL_RATE *)pData; HTTRANSMIT_SETTING HtPhyMode; #ifdef APCLI_SUPPORT if (pRate->priv_flags == INT_APCLI) HtPhyMode = pAd->ApCfg.ApCliTab[pObj->ioctl_if].HTPhyMode; else #endif /* APCLI_SUPPORT */ #ifdef WDS_SUPPORT if (pRate->priv_flags == INT_WDS) HtPhyMode = pAd->WdsTab.WdsEntry[pObj->ioctl_if].HTPhyMode; else #endif /* WDS_SUPPORT */ { HtPhyMode = pAd->ApCfg.MBSSID[pObj->ioctl_if].HTPhyMode; #ifdef MBSS_SUPPORT /* reset phy mode for MBSS */ MBSS_PHY_MODE_RESET(pObj->ioctl_if, HtPhyMode); #endif /* MBSS_SUPPORT */ } RtmpDrvMaxRateGet(pAd, HtPhyMode.field.MODE, HtPhyMode.field.ShortGI, HtPhyMode.field.BW, HtPhyMode.field.MCS, (UINT32 *)&pRate->BitRate); } break; #endif /* CONFIG_AP_SUPPORT */ case CMD_RTPRIV_IOCTL_SIOCGIWNAME: RtmpIoctl_rt_ioctl_giwname(pAd, pData, 0); break; #if defined(CONFIG_CSO_SUPPORT) || defined(CONFIG_RX_CSO_SUPPORT) case CMD_RTPRIV_IOCTL_ADAPTER_CSO_SUPPORT_TEST: *(UCHAR *)pData = (pAd->MoreFlags & fASIC_CAP_CSO) ? 1:0; break; #endif /* defined(CONFIG_CSO_SUPPORT) || defined(CONFIG_RX_CSO_SUPPORT) */ } #ifdef RT_CFG80211_SUPPORT if ((CMD_RTPRIV_IOCTL_80211_START <= cmd) && (cmd <= CMD_RTPRIV_IOCTL_80211_END)) { CFG80211DRV_IoctlHandle(pAd, wrq, cmd, subcmd, pData, Data); } #endif /* RT_CFG80211_SUPPORT */ if (cmd >= CMD_RTPRIV_IOCTL_80211_COM_LATEST_ONE) return NDIS_STATUS_FAILURE; return Status; } /* ========================================================================== Description: Issue a site survey command to driver Arguments: pAdapter Pointer to our adapter wrq Pointer to the ioctl argument Return Value: None Note: Usage: 1.) iwpriv ra0 set site_survey ========================================================================== */ INT Set_SiteSurvey_Proc( IN PRTMP_ADAPTER pAd, IN PSTRING arg) { NDIS_802_11_SSID Ssid; POS_COOKIE pObj; pObj = (POS_COOKIE) pAd->OS_Cookie; //check if the interface is down if (!RTMP_TEST_FLAG(pAd, fRTMP_ADAPTER_INTERRUPT_IN_USE)) { DBGPRINT(RT_DEBUG_TRACE, ("INFO::Network is down!\n")); return -ENETDOWN; } NdisZeroMemory(&Ssid, sizeof(NDIS_802_11_SSID)); #ifdef CONFIG_AP_SUPPORT #ifdef AP_SCAN_SUPPORT IF_DEV_CONFIG_OPMODE_ON_AP(pAd) { if ((strlen(arg) != 0) && (strlen(arg) <= MAX_LEN_OF_SSID)) { NdisMoveMemory(Ssid.Ssid, arg, strlen(arg)); Ssid.SsidLength = strlen(arg); } if (Ssid.SsidLength == 0) ApSiteSurvey(pAd, &Ssid, SCAN_PASSIVE, FALSE); else ApSiteSurvey(pAd, &Ssid, SCAN_ACTIVE, FALSE); return TRUE; } #endif /* AP_SCAN_SUPPORT */ #endif // CONFIG_AP_SUPPORT // DBGPRINT(RT_DEBUG_TRACE, ("Set_SiteSurvey_Proc\n")); return TRUE; } INT Set_Antenna_Proc( IN PRTMP_ADAPTER pAd, IN PSTRING arg) { ANT_DIVERSITY_TYPE UsedAnt; int i; DBGPRINT(RT_DEBUG_OFF, ("==> Set_Antenna_Proc *******************\n")); for (i = 0; i < strlen(arg); i++) if (!isdigit(arg[i])) return -EINVAL; UsedAnt = simple_strtol(arg, 0, 10); switch (UsedAnt) { /* 2: Fix in the PHY Antenna CON1*/ case ANT_FIX_ANT0: AsicSetRxAnt(pAd, 0); DBGPRINT(RT_DEBUG_OFF, ("<== Set_Antenna_Proc(Fix in Ant CON1), (%d,%d)\n", pAd->RxAnt.Pair1PrimaryRxAnt, pAd->RxAnt.Pair1SecondaryRxAnt)); break; /* 3: Fix in the PHY Antenna CON2*/ case ANT_FIX_ANT1: AsicSetRxAnt(pAd, 1); DBGPRINT(RT_DEBUG_OFF, ("<== %s(Fix in Ant CON2), (%d,%d)\n", __FUNCTION__, pAd->RxAnt.Pair1PrimaryRxAnt, pAd->RxAnt.Pair1SecondaryRxAnt)); break; default: DBGPRINT(RT_DEBUG_ERROR, ("<== %s(N/A cmd: %d), (%d,%d)\n", __FUNCTION__, UsedAnt, pAd->RxAnt.Pair1PrimaryRxAnt, pAd->RxAnt.Pair1SecondaryRxAnt)); break; } return TRUE; } #ifdef MICROWAVE_OVEN_SUPPORT INT Set_MO_FalseCCATh_Proc( IN PRTMP_ADAPTER pAd, IN PSTRING arg) { ULONG th; th = simple_strtol(arg, 0, 10); if (th > 65535) th = 65535; pAd->CommonCfg.MO_Cfg.nFalseCCATh = th; DBGPRINT(RT_DEBUG_OFF, ("%s: set falseCCA threshold %lu for microwave oven application!!\n", __FUNCTION__, th)); return TRUE; } #endif /* MICROWAVE_OVEN_SUPPORT */