Exemplo n.º 1
0
/*----------------------------------------------------------------------------*/
int
mtk_cfg80211_connect (
    struct wiphy *wiphy,
    struct net_device *ndev,
    struct cfg80211_connect_params *sme
    )
{
    P_GLUE_INFO_T prGlueInfo = NULL;
    WLAN_STATUS rStatus;
    UINT_32 u4BufLen;
    ENUM_PARAM_ENCRYPTION_STATUS_T eEncStatus;
    ENUM_PARAM_AUTH_MODE_T eAuthMode;
    UINT_32 cipher;
    PARAM_SSID_T rNewSsid;
    BOOLEAN fgCarryWPSIE = FALSE;
    ENUM_PARAM_OP_MODE_T eOpMode;

    prGlueInfo = (P_GLUE_INFO_T) wiphy_priv(wiphy);
    ASSERT(prGlueInfo);

    if (prGlueInfo->prAdapter->rWifiVar.rConnSettings.eOPMode > NET_TYPE_AUTO_SWITCH)
		eOpMode = NET_TYPE_AUTO_SWITCH;
	else 
	    eOpMode = prGlueInfo->prAdapter->rWifiVar.rConnSettings.eOPMode;
	
	rStatus = kalIoctl(prGlueInfo,
		wlanoidSetInfrastructureMode,
		&eOpMode,
		sizeof(eOpMode),
		FALSE,
		FALSE,
		TRUE,
		FALSE,
		&u4BufLen);

	if (rStatus != WLAN_STATUS_SUCCESS) {
		DBGLOG(INIT, INFO, ("wlanoidSetInfrastructureMode fail 0x%lx\n", rStatus));
		return -EFAULT;
	}

	/* after set operation mode, key table are cleared */

	/* reset wpa info */
	prGlueInfo->rWpaInfo.u4WpaVersion = IW_AUTH_WPA_VERSION_DISABLED;
	prGlueInfo->rWpaInfo.u4KeyMgmt = 0;
	prGlueInfo->rWpaInfo.u4CipherGroup = IW_AUTH_CIPHER_NONE;
	prGlueInfo->rWpaInfo.u4CipherPairwise = IW_AUTH_CIPHER_NONE;
	prGlueInfo->rWpaInfo.u4AuthAlg = IW_AUTH_ALG_OPEN_SYSTEM;
#if CFG_SUPPORT_802_11W
	prGlueInfo->rWpaInfo.u4Mfp = IW_AUTH_MFP_DISABLED;
#endif

    if (sme->crypto.wpa_versions & NL80211_WPA_VERSION_1)
        prGlueInfo->rWpaInfo.u4WpaVersion = IW_AUTH_WPA_VERSION_WPA;
    else if (sme->crypto.wpa_versions & NL80211_WPA_VERSION_2)
        prGlueInfo->rWpaInfo.u4WpaVersion = IW_AUTH_WPA_VERSION_WPA2;
    else
        prGlueInfo->rWpaInfo.u4WpaVersion = IW_AUTH_WPA_VERSION_DISABLED;
 
    switch (sme->auth_type) {
    case NL80211_AUTHTYPE_OPEN_SYSTEM:
        prGlueInfo->rWpaInfo.u4AuthAlg = IW_AUTH_ALG_OPEN_SYSTEM;
        break;
    case NL80211_AUTHTYPE_SHARED_KEY:
        prGlueInfo->rWpaInfo.u4AuthAlg = IW_AUTH_ALG_SHARED_KEY;
        break;
    default:
        prGlueInfo->rWpaInfo.u4AuthAlg = IW_AUTH_ALG_OPEN_SYSTEM | IW_AUTH_ALG_SHARED_KEY;
        break;
    }

    if (sme->crypto.n_ciphers_pairwise) {
        switch (sme->crypto.ciphers_pairwise[0]) {
        case WLAN_CIPHER_SUITE_WEP40:
            prGlueInfo->rWpaInfo.u4CipherPairwise = IW_AUTH_CIPHER_WEP40;
            break;
        case WLAN_CIPHER_SUITE_WEP104:
            prGlueInfo->rWpaInfo.u4CipherPairwise = IW_AUTH_CIPHER_WEP104;
            break;
        case WLAN_CIPHER_SUITE_TKIP:
            prGlueInfo->rWpaInfo.u4CipherPairwise = IW_AUTH_CIPHER_TKIP;
            break;
        case WLAN_CIPHER_SUITE_CCMP:
            prGlueInfo->rWpaInfo.u4CipherPairwise = IW_AUTH_CIPHER_CCMP;
            break;
        case WLAN_CIPHER_SUITE_AES_CMAC:
            prGlueInfo->rWpaInfo.u4CipherPairwise = IW_AUTH_CIPHER_CCMP;
            break;
        default:
            DBGLOG(REQ, WARN, ("invalid cipher pairwise (%d)\n",
                   sme->crypto.ciphers_pairwise[0]));
            return -EINVAL;
        }
    }

    if (sme->crypto.cipher_group) {
        switch (sme->crypto.cipher_group) {
        case WLAN_CIPHER_SUITE_WEP40:
            prGlueInfo->rWpaInfo.u4CipherGroup = IW_AUTH_CIPHER_WEP40;
            break;          
        case WLAN_CIPHER_SUITE_WEP104:
            prGlueInfo->rWpaInfo.u4CipherGroup = IW_AUTH_CIPHER_WEP104;
            break;
        case WLAN_CIPHER_SUITE_TKIP:
            prGlueInfo->rWpaInfo.u4CipherGroup = IW_AUTH_CIPHER_TKIP;
            break;
        case WLAN_CIPHER_SUITE_CCMP:
            prGlueInfo->rWpaInfo.u4CipherGroup = IW_AUTH_CIPHER_CCMP;
            break;
        case WLAN_CIPHER_SUITE_AES_CMAC:
            prGlueInfo->rWpaInfo.u4CipherGroup = IW_AUTH_CIPHER_CCMP;
            break;
        default:
            DBGLOG(REQ, WARN, ("invalid cipher group (%d)\n",
                   sme->crypto.cipher_group));
            return -EINVAL;
        }
    }

    if (sme->crypto.n_akm_suites) {
        if (prGlueInfo->rWpaInfo.u4WpaVersion == IW_AUTH_WPA_VERSION_WPA) {
            switch (sme->crypto.akm_suites[0]) {
            case WLAN_AKM_SUITE_8021X:
                eAuthMode = AUTH_MODE_WPA;
                break;
            case WLAN_AKM_SUITE_PSK:
                eAuthMode = AUTH_MODE_WPA_PSK;
            break;
            default:
                DBGLOG(REQ, WARN, ("invalid cipher group (%d)\n",
                       sme->crypto.cipher_group));
                return -EINVAL;
            }
        } else if (prGlueInfo->rWpaInfo.u4WpaVersion == IW_AUTH_WPA_VERSION_WPA2) {
            switch (sme->crypto.akm_suites[0]) {
            case WLAN_AKM_SUITE_8021X:
            eAuthMode = AUTH_MODE_WPA2;
            break;
            case WLAN_AKM_SUITE_PSK:
            eAuthMode = AUTH_MODE_WPA2_PSK;
            break;
            default:
                DBGLOG(REQ, WARN, ("invalid cipher group (%d)\n",
                       sme->crypto.cipher_group));
                return -EINVAL;
            }
        }
    }

    if (prGlueInfo->rWpaInfo.u4WpaVersion == IW_AUTH_WPA_VERSION_DISABLED) {
        eAuthMode = (prGlueInfo->rWpaInfo.u4AuthAlg == IW_AUTH_ALG_OPEN_SYSTEM) ?
             AUTH_MODE_OPEN : AUTH_MODE_AUTO_SWITCH;
    }

    prGlueInfo->rWpaInfo.fgPrivacyInvoke = sme->privacy;

    //prGlueInfo->prAdapter->rWifiVar.rConnSettings.fgWapiMode = FALSE;
    //prGlueInfo->prAdapter->prGlueInfo->u2WapiAssocInfoIESz = 0;
    prGlueInfo->fgWpsActive = FALSE;
    //prGlueInfo->prAdapter->prGlueInfo->u2WSCAssocInfoIELen = 0;

    if (sme->ie && sme->ie_len > 0) {
        WLAN_STATUS rStatus;
        UINT_32 u4BufLen;
        PUINT_8 prDesiredIE = NULL;

#if CFG_SUPPORT_WAPI
        rStatus = kalIoctl(prGlueInfo,
                wlanoidSetWapiAssocInfo,
                sme->ie,
                sme->ie_len,
                FALSE,
                FALSE,
                FALSE,
                FALSE,
                &u4BufLen);
        
        if (rStatus != WLAN_STATUS_SUCCESS) {
            DBGLOG(SEC, WARN, ("[wapi] set wapi assoc info error:%lx\n", rStatus));
        }
#endif
#if CFG_SUPPORT_WPS2
        if (wextSrchDesiredWPSIE(sme->ie,
                    sme->ie_len,
                    0xDD,
                    (PUINT_8 *)&prDesiredIE)) {
            prGlueInfo->fgWpsActive = TRUE;
            fgCarryWPSIE = TRUE;

            rStatus = kalIoctl(prGlueInfo,
                    wlanoidSetWSCAssocInfo,
                    prDesiredIE,
                    IE_SIZE(prDesiredIE),
                    FALSE,
                    FALSE,
                    FALSE,
                    FALSE,
                    &u4BufLen);
            if (rStatus != WLAN_STATUS_SUCCESS) {
                DBGLOG(SEC, WARN, ("WSC] set WSC assoc info error:%lx\n", rStatus));
            }
        }
#endif
    }

    /* clear WSC Assoc IE buffer in case WPS IE is not detected */
    if(fgCarryWPSIE == FALSE) {
        kalMemZero(&prGlueInfo->aucWSCAssocInfoIE, 200);
        prGlueInfo->u2WSCAssocInfoIELen = 0;
    }

    rStatus = kalIoctl(prGlueInfo,
            wlanoidSetAuthMode,
            &eAuthMode,
            sizeof(eAuthMode),
            FALSE,
            FALSE,
            FALSE,
            FALSE,
            &u4BufLen);
    if (rStatus != WLAN_STATUS_SUCCESS) {
        DBGLOG(REQ, WARN, ("set auth mode error:%lx\n", rStatus));
    }

    cipher = prGlueInfo->rWpaInfo.u4CipherGroup | prGlueInfo->rWpaInfo.u4CipherPairwise;

    if (prGlueInfo->rWpaInfo.fgPrivacyInvoke) {
        if (cipher & IW_AUTH_CIPHER_CCMP) {
            eEncStatus = ENUM_ENCRYPTION3_ENABLED;
        }
        else if (cipher & IW_AUTH_CIPHER_TKIP) {
            eEncStatus = ENUM_ENCRYPTION2_ENABLED;
        }
        else if (cipher & (IW_AUTH_CIPHER_WEP104 | IW_AUTH_CIPHER_WEP40)) {
            eEncStatus = ENUM_ENCRYPTION1_ENABLED;
        }
        else if (cipher & IW_AUTH_CIPHER_NONE){
            if (prGlueInfo->rWpaInfo.fgPrivacyInvoke)
                eEncStatus = ENUM_ENCRYPTION1_ENABLED;
            else
                eEncStatus = ENUM_ENCRYPTION_DISABLED;
        }
        else {
            eEncStatus = ENUM_ENCRYPTION_DISABLED;
        }
    }
    else {
        eEncStatus = ENUM_ENCRYPTION_DISABLED;
    }
    
    rStatus = kalIoctl(prGlueInfo,
            wlanoidSetEncryptionStatus,
            &eEncStatus,
            sizeof(eEncStatus),
            FALSE,
            FALSE,
            FALSE,
            FALSE,
            &u4BufLen);
    if (rStatus != WLAN_STATUS_SUCCESS) {
        DBGLOG(REQ, WARN, ("set encryption mode error:%lx\n", rStatus));
    }

    if (sme->key_len != 0 && prGlueInfo->rWpaInfo.u4WpaVersion == IW_AUTH_WPA_VERSION_DISABLED) {
        P_PARAM_WEP_T prWepKey = (P_PARAM_WEP_T) wepBuf;
        
        kalMemSet(prWepKey, 0, sizeof(prWepKey));
        prWepKey->u4Length = 12 + sme->key_len;
        prWepKey->u4KeyLength = (UINT_32) sme->key_len;
        prWepKey->u4KeyIndex = (UINT_32) sme->key_idx;
        prWepKey->u4KeyIndex |= BIT(31);
        if (prWepKey->u4KeyLength > 32) {
            DBGLOG(REQ, WARN, ("Too long key length (%u)\n", prWepKey->u4KeyLength));
            return -EINVAL;
        }
        kalMemCopy(prWepKey->aucKeyMaterial, sme->key, prWepKey->u4KeyLength);

        rStatus = kalIoctl(prGlueInfo,
                     wlanoidSetAddWep,
                     prWepKey,
                     prWepKey->u4Length,
                     FALSE,
                     FALSE,
                     TRUE,
                     FALSE,
                     &u4BufLen);
        
        if (rStatus != WLAN_STATUS_SUCCESS) {
            DBGLOG(INIT, INFO, ("wlanoidSetAddWep fail 0x%lx\n", rStatus));
            return -EFAULT;
        }
    }

    if(sme->ssid_len > 0) {
        /* connect by SSID */
        COPY_SSID(rNewSsid.aucSsid, rNewSsid.u4SsidLen, sme->ssid, sme->ssid_len);

        rStatus = kalIoctl(prGlueInfo,
                wlanoidSetSsid,
                (PVOID) &rNewSsid,
                sizeof(PARAM_SSID_T),
                FALSE,
                FALSE,
                TRUE,
                FALSE,
                &u4BufLen);

        if (rStatus != WLAN_STATUS_SUCCESS) {
            DBGLOG(REQ, WARN, ("set SSID:%lx\n", rStatus));
            return -EINVAL;
        }
    }
    else {
        /* connect by BSSID */
        rStatus = kalIoctl(prGlueInfo,
                wlanoidSetBssid,
                (PVOID) sme->bssid,
                sizeof(MAC_ADDR_LEN),
                FALSE,
                FALSE,
                TRUE,
                FALSE,
                &u4BufLen);

        if (rStatus != WLAN_STATUS_SUCCESS) {
            DBGLOG(REQ, WARN, ("set BSSID:%lx\n", rStatus));
            return -EINVAL;
        }
    }

    return 0;
}
/*----------------------------------------------------------------------------*/
VOID
kalUpdateReAssocReqInfo(IN P_GLUE_INFO_T prGlueInfo,
			IN PUINT_8 pucFrameBody,
			IN UINT_32 u4FrameBodyLen, IN BOOLEAN fgReassocRequest)
{
	PUINT_8 cp;
	PNDIS_802_11_ASSOCIATION_INFORMATION prNdisAssocInfo;

	if (fgReassocRequest) {
		ASSERT(u4FrameBodyLen >= MIN_REASSOC_REQ_BODY_LEN);

		if (u4FrameBodyLen < MIN_REASSOC_REQ_BODY_LEN) {
			return;
		}
	} else {
		ASSERT(u4FrameBodyLen >= MIN_ASSOC_REQ_BODY_LEN);

		if (u4FrameBodyLen < MIN_ASSOC_REQ_BODY_LEN) {
			return;
		}
	}

	prNdisAssocInfo = &prGlueInfo->rNdisAssocInfo;

	cp = pucFrameBody;

	/* Update the fixed information elements. */
	if (fgReassocRequest) {
		prNdisAssocInfo->AvailableRequestFixedIEs =
		    NDIS_802_11_AI_REQFI_CAPABILITIES |
		    NDIS_802_11_AI_REQFI_LISTENINTERVAL | NDIS_802_11_AI_REQFI_CURRENTAPADDRESS;
	} else {
		prNdisAssocInfo->AvailableRequestFixedIEs =
		    NDIS_802_11_AI_REQFI_CAPABILITIES | NDIS_802_11_AI_REQFI_LISTENINTERVAL;
	}

	kalMemCopy(&prNdisAssocInfo->RequestFixedIEs.Capabilities, cp, 2);
	cp += 2;
	u4FrameBodyLen -= 2;

	kalMemCopy(&prNdisAssocInfo->RequestFixedIEs.ListenInterval, cp, 2);
	cp += 2;
	u4FrameBodyLen -= 2;

	if (fgReassocRequest) {
		kalMemCopy(&prNdisAssocInfo->RequestFixedIEs.CurrentAPAddress, cp, 6);
		cp += 6;
		u4FrameBodyLen -= 6;
	} else {
		kalMemZero(&prNdisAssocInfo->RequestFixedIEs.CurrentAPAddress, 6);
	}

	/* Update the variable length information elements. */
	prNdisAssocInfo->RequestIELength = u4FrameBodyLen;
	prNdisAssocInfo->OffsetRequestIEs = sizeof(NDIS_802_11_ASSOCIATION_INFORMATION);

	kalMemCopy(prGlueInfo->aucNdisAssocInfoIEs, cp, u4FrameBodyLen);

	/* Clear the information for the last association/reassociation response
	   from the AP. */
	prNdisAssocInfo->AvailableResponseFixedIEs = 0;
	prNdisAssocInfo->ResponseFixedIEs.Capabilities = 0;
	prNdisAssocInfo->ResponseFixedIEs.StatusCode = 0;
	prNdisAssocInfo->ResponseFixedIEs.AssociationId = 0;
	prNdisAssocInfo->ResponseIELength = 0;
	prNdisAssocInfo->OffsetResponseIEs =
	    sizeof(NDIS_802_11_ASSOCIATION_INFORMATION) + u4FrameBodyLen;

}				/* kalUpdateReAssocReqInfo */
Exemplo n.º 3
0
static int netdev_event(struct notifier_block *nb, unsigned long notification, void *ptr)
{
    UINT_8  ip[4] = { 0 };
    UINT_32 u4NumIPv4 = 0;
//#ifdef  CONFIG_IPV6
#if 0
    UINT_8  ip6[16] = { 0 };     // FIX ME: avoid to allocate large memory in stack
    UINT_32 u4NumIPv6 = 0;
#endif
    struct in_ifaddr *ifa = (struct in_ifaddr *) ptr;
    struct net_device *prDev = ifa->ifa_dev->dev;
    UINT_32 i;
    P_PARAM_NETWORK_ADDRESS_IP prParamIpAddr;
    P_GLUE_INFO_T prGlueInfo = NULL;

    if (prDev == NULL) {
        DBGLOG(REQ, INFO, ("netdev_event: device is empty.\n"));
        return NOTIFY_DONE;
    }

    if ((strncmp(prDev->name, "p2p", 3) != 0) && (strncmp(prDev->name, "wlan", 4) != 0)) {
        DBGLOG(REQ, INFO, ("netdev_event: xxx\n"));
        return NOTIFY_DONE;
    }

#if 0//CFG_SUPPORT_HOTSPOT_2_0
	{
		//printk(KERN_INFO "[netdev_event] IPV4_DAD is unlock now!!\n");
		prGlueInfo->fgIsDad = FALSE;
	}
#endif

    prGlueInfo = *((P_GLUE_INFO_T *) netdev_priv(prDev));

    if (prGlueInfo == NULL) {
        DBGLOG(REQ, INFO, ("netdev_event: prGlueInfo is empty.\n"));
        return NOTIFY_DONE;
    }
    ASSERT(prGlueInfo);

    if (fgIsUnderEarlierSuspend == false) {
        DBGLOG(REQ, INFO, ("netdev_event: PARAM_MEDIA_STATE_DISCONNECTED. (%d)\n", prGlueInfo->eParamMediaStateIndicated));
        return NOTIFY_DONE;
    }



    // <3> get the IPv4 address
    if(!prDev || !(prDev->ip_ptr)||\
            !((struct in_device *)(prDev->ip_ptr))->ifa_list||\
            !(&(((struct in_device *)(prDev->ip_ptr))->ifa_list->ifa_local))){
        DBGLOG(REQ, INFO, ("ip is not avaliable.\n"));
        return NOTIFY_DONE;
    }

    kalMemCopy(ip, &(((struct in_device *)(prDev->ip_ptr))->ifa_list->ifa_local), sizeof(ip));
    DBGLOG(REQ, INFO, ("ip is %d.%d.%d.%d\n",
            ip[0],ip[1],ip[2],ip[3]));

    // todo: traverse between list to find whole sets of IPv4 addresses
    if (!((ip[0] == 0) &&
         (ip[1] == 0) &&
         (ip[2] == 0) &&
         (ip[3] == 0))) {
        u4NumIPv4++;
    }

//#ifdef  CONFIG_IPV6
#if 0
    if(!prDev || !(prDev->ip6_ptr)||\
        !((struct in_device *)(prDev->ip6_ptr))->ifa_list||\
        !(&(((struct in_device *)(prDev->ip6_ptr))->ifa_list->ifa_local))){
        printk(KERN_INFO "ipv6 is not avaliable.\n");
        return NOTIFY_DONE;
    }

    kalMemCopy(ip6, &(((struct in_device *)(prDev->ip6_ptr))->ifa_list->ifa_local), sizeof(ip6));
    printk(KERN_INFO"ipv6 is %d.%d.%d.%d.%d.%d.%d.%d.%d.%d.%d.%d.%d.%d.%d.%d\n",
            ip6[0],ip6[1],ip6[2],ip6[3],
            ip6[4],ip6[5],ip6[6],ip6[7],
            ip6[8],ip6[9],ip6[10],ip6[11],
            ip6[12],ip6[13],ip6[14],ip6[15]
            );

    // todo: traverse between list to find whole sets of IPv6 addresses
    if (!((ip6[0] == 0) &&
         (ip6[1] == 0) &&
         (ip6[2] == 0) &&
         (ip6[3] == 0) &&
         (ip6[4] == 0) &&
         (ip6[5] == 0))) {
        //u4NumIPv6++;
    }
#endif

    // here we can compare the dev with other network's netdev to
    // set the proper arp filter
    //
    // IMPORTANT: please make sure if the context can sleep, if the context can't sleep
    // we should schedule a kernel thread to do this for us

    // <7> set up the ARP filter
    {
        WLAN_STATUS rStatus = WLAN_STATUS_FAILURE;
        UINT_32 u4SetInfoLen = 0;
        UINT_8 aucBuf[32] = {0};
        UINT_32 u4Len = OFFSET_OF(PARAM_NETWORK_ADDRESS_LIST, arAddress);
        P_PARAM_NETWORK_ADDRESS_LIST prParamNetAddrList = (P_PARAM_NETWORK_ADDRESS_LIST)aucBuf;
        P_PARAM_NETWORK_ADDRESS prParamNetAddr = prParamNetAddrList->arAddress;

//#ifdef  CONFIG_IPV6
#if 0
        prParamNetAddrList->u4AddressCount = u4NumIPv4 + u4NumIPv6;
#else
        prParamNetAddrList->u4AddressCount = u4NumIPv4;
#endif
        prParamNetAddrList->u2AddressType = PARAM_PROTOCOL_ID_TCP_IP;
        for (i = 0; i < u4NumIPv4; i++) {
            prParamNetAddr->u2AddressLength = sizeof(PARAM_NETWORK_ADDRESS_IP);//4;;
            prParamNetAddr->u2AddressType = PARAM_PROTOCOL_ID_TCP_IP;;
#if 0
            kalMemCopy(prParamNetAddr->aucAddress, ip, sizeof(ip));
            prParamNetAddr = (P_PARAM_NETWORK_ADDRESS)((UINT_32)prParamNetAddr + sizeof(ip));
            u4Len += OFFSET_OF(PARAM_NETWORK_ADDRESS, aucAddress) + sizeof(ip);
#else
            prParamIpAddr = (P_PARAM_NETWORK_ADDRESS_IP)prParamNetAddr->aucAddress;
            kalMemCopy(&prParamIpAddr->in_addr, ip, sizeof(ip));
            prParamNetAddr = (P_PARAM_NETWORK_ADDRESS)((UINT_32)prParamNetAddr + sizeof(PARAM_NETWORK_ADDRESS));
            u4Len += OFFSET_OF(PARAM_NETWORK_ADDRESS, aucAddress) + sizeof(PARAM_NETWORK_ADDRESS);
#endif
        }
//#ifdef  CONFIG_IPV6
#if 0
        for (i = 0; i < u4NumIPv6; i++) {
            prParamNetAddr->u2AddressLength = 6;;
            prParamNetAddr->u2AddressType = PARAM_PROTOCOL_ID_TCP_IP;;
            kalMemCopy(prParamNetAddr->aucAddress, ip6, sizeof(ip6));
            prParamNetAddr = (P_PARAM_NETWORK_ADDRESS)((UINT_32)prParamNetAddr + sizeof(ip6));
            u4Len += OFFSET_OF(PARAM_NETWORK_ADDRESS, aucAddress) + sizeof(ip6);
       }
#endif
        ASSERT(u4Len <= sizeof(aucBuf));

    DBGLOG(REQ, INFO, ("kalIoctl (0x%x, 0x%x)\n", prGlueInfo, prParamNetAddrList));

        rStatus = kalIoctl(prGlueInfo,
                wlanoidSetNetworkAddress,
                (PVOID)prParamNetAddrList,
                u4Len,
                FALSE,
                FALSE,
                TRUE,
                FALSE,
                &u4SetInfoLen);

        if (rStatus != WLAN_STATUS_SUCCESS) {
            DBGLOG(REQ, INFO, ("set HW pattern filter fail 0x%lx\n", rStatus));
        }
    }

    return NOTIFY_DONE;

}
Exemplo n.º 4
0
/*----------------------------------------------------------------------------*/
int
mtk_cfg80211_add_key (
    struct wiphy *wiphy,
    struct net_device *ndev,
    u8 key_index,
    bool pairwise,
    const u8 *mac_addr,
    struct key_params *params
    )
{
    PARAM_KEY_T rKey;
    P_GLUE_INFO_T prGlueInfo = NULL;
    WLAN_STATUS rStatus = WLAN_STATUS_SUCCESS;
    INT_32 i4Rslt = -EINVAL;
    UINT_32 u4BufLen = 0;
    UINT_8 tmp1[8];
    UINT_8 tmp2[8];

    prGlueInfo = (P_GLUE_INFO_T) wiphy_priv(wiphy);
    ASSERT(prGlueInfo);
    
    kalMemZero(&rKey, sizeof(PARAM_KEY_T));

    rKey.u4KeyIndex = key_index;
    
    if(mac_addr) {
        COPY_MAC_ADDR(rKey.arBSSID, mac_addr);
        if ((rKey.arBSSID[0] == 0x00) && (rKey.arBSSID[1] == 0x00) && (rKey.arBSSID[2] == 0x00) &&
            (rKey.arBSSID[3] == 0x00) && (rKey.arBSSID[4] == 0x00) && (rKey.arBSSID[5] == 0x00)) {
            rKey.arBSSID[0] = 0xff;
            rKey.arBSSID[1] = 0xff;
            rKey.arBSSID[2] = 0xff;
            rKey.arBSSID[3] = 0xff;
            rKey.arBSSID[4] = 0xff;
            rKey.arBSSID[5] = 0xff;
        }
        if (rKey.arBSSID[0] != 0xFF) {
            rKey.u4KeyIndex |= BIT(31);
            if ((rKey.arBSSID[0] != 0x00) || (rKey.arBSSID[1] != 0x00) || (rKey.arBSSID[2] != 0x00) ||
                (rKey.arBSSID[3] != 0x00) || (rKey.arBSSID[4] != 0x00) || (rKey.arBSSID[5] != 0x00))
            rKey.u4KeyIndex |= BIT(30);
        }
    }
    else {
            rKey.arBSSID[0] = 0xff;
            rKey.arBSSID[1] = 0xff;
            rKey.arBSSID[2] = 0xff;
            rKey.arBSSID[3] = 0xff;
            rKey.arBSSID[4] = 0xff;
            rKey.arBSSID[5] = 0xff;
            //rKey.u4KeyIndex |= BIT(31); //Enable BIT 31 will make tx use bc key id, should use pairwise key id 0 
    }
    
    if(params->key) {
        //rKey.aucKeyMaterial[0] = kalMemAlloc(params->key_len, VIR_MEM_TYPE);
        kalMemCopy(rKey.aucKeyMaterial, params->key, params->key_len);
        if (params->key_len == 32) {
            kalMemCopy(tmp1, &params->key[16], 8);
            kalMemCopy(tmp2, &params->key[24], 8);        
            kalMemCopy(&rKey.aucKeyMaterial[16], tmp2, 8);
            kalMemCopy(&rKey.aucKeyMaterial[24], tmp1, 8);
        }
    }

    rKey.u4KeyLength = params->key_len;
    rKey.u4Length =  ((UINT_32)&(((P_P2P_PARAM_KEY_T)0)->aucKeyMaterial)) + rKey.u4KeyLength;
    
    rStatus = kalIoctl(prGlueInfo,
            wlanoidSetAddKey,
            &rKey,
            rKey.u4Length,
            FALSE,
            FALSE,
            TRUE,
            FALSE,
            &u4BufLen);
    
    if (rStatus == WLAN_STATUS_SUCCESS)
        i4Rslt = 0;

    return i4Rslt;
}
Exemplo n.º 5
0
/*----------------------------------------------------------------------------*/
UINT_8
secPrivacySeekForBcEntry(IN P_ADAPTER_T prAdapter,
			 IN UINT_8 ucBssIndex,
			 IN PUINT_8 pucAddr,
			 IN UINT_8 ucStaIdx,
			 IN UINT_8 ucAlg,
			 IN UINT_8 ucKeyId, IN UINT_8 ucCurrentKeyId, IN UINT_8 ucTxRx)
{
	UINT_8 ucEntry = WTBL_ALLOC_FAIL;
	UINT_8 ucStartIDX = 0, ucMaxIDX = 0;
	UINT_8 i;
	BOOLEAN fgCheckKeyId = TRUE;
	P_WLAN_TABLE_T prWtbl;
	/* P_BSS_INFO_T            prBSSInfo = GET_BSS_INFO_BY_INDEX(prAdapter,ucBssIndex); */

	prWtbl = prAdapter->rWifiVar.arWtbl;

	ASSERT(prAdapter);
	ASSERT(pucAddr);

#if 1
	ucStartIDX = 0;
	ucMaxIDX = NIC_TX_DEFAULT_WLAN_INDEX - 1;
#else
	if (ucAlg == CIPHER_SUITE_BIP) {
		if (ucNetTypeIdx != NETWORK_TYPE_AIS) {
			ASSERT(FALSE);
			return ucEntry;
		}
		ucEntry = WTBL_AIS_BIP_IDX;	/* Only support 11w at STA mode */
	}
#endif

	if (ucAlg == CIPHER_SUITE_WPI || ucAlg == CIPHER_SUITE_WEP40 ||
	    ucAlg == CIPHER_SUITE_WEP104 || ucAlg == CIPHER_SUITE_WEP128 ||
	    ucAlg == CIPHER_SUITE_NONE)
		fgCheckKeyId = FALSE;

#if 0
	if ((ucNetTypeIdx == NETWORK_TYPE_AIS)
	    && (prAdapter->aprBssInfo[ucBssIndex]->eCurrentOPMode == OP_MODE_IBSS)) {
		ucStartIDX = WTBL_IBSS_BC_IDX_0;
		ucMaxIDX = WTBL_BC_IDX_MAX;
	} else {
		ucStartIDX = WTBL_BC_IDX_0;
		ucMaxIDX = WTBL_BC_IDX_MAX;
	}
#endif

	for (i = ucStartIDX; i <= ucMaxIDX; i++) {
#if DBG
		if (i < 10) {
			DBGLOG(RSN, TRACE,
			       ("idx=%d use=%d P=%d BSSIdx=%d Addr=" MACSTR " keyid=%d\n", i,
				prWtbl[i].ucUsed, prWtbl[i].ucPairwise, prWtbl[i].ucBssIndex,
				MAC2STR(prWtbl[i].aucMacAddr), prWtbl[i].ucKeyId));
		}
#endif
		if (prWtbl[i].ucUsed && !prWtbl[i].ucPairwise && prWtbl[i].ucBssIndex == ucBssIndex
		    && 1
		    /* (EQUAL_MAC_ADDR(prWtbl[i].aucMacAddr, pucAddr) || (prBSSInfo && EQUAL_MAC_ADDR(prWtbl[i].aucMacAddr, prBSSInfo->aucOwnMacAddr))) */
		    ) {
			if (!fgCheckKeyId || prWtbl[i].ucKeyId == 0xff
			    || (fgCheckKeyId && prWtbl[i].ucKeyId == ucKeyId)) {
				ucEntry = i;
				DBGLOG(RSN, TRACE, ("[Wlan index]: Reuse entry #%d\n", i));
				break;
			}
			if (fgCheckKeyId && (prWtbl[i].ucKeyId != ucCurrentKeyId)) {
				ucEntry = i;
				DBGLOG(RSN, TRACE,
				       ("[Wlan index]: Replace the not current keyid entry #%d\n",
					i));
				break;
			}
		}
	}

	if (i == (ucMaxIDX + 1)) {
		for (i = ucStartIDX; i <= ucMaxIDX; i++) {
			if (prWtbl[i].ucUsed == FALSE) {
				ucEntry = i;
				DBGLOG(RSN, TRACE, ("[Wlan index]: Assign entry #%d\n", i));
				break;
			}
		}
	}

	if (ucEntry < WTBL_SIZE) {
		prWtbl[ucEntry].ucUsed = TRUE;
		prWtbl[ucEntry].ucKeyId = ucKeyId;
		prWtbl[ucEntry].ucBssIndex = ucBssIndex;
		prWtbl[ucEntry].ucPairwise = 0;
		kalMemCopy(prWtbl[ucEntry].aucMacAddr, pucAddr, MAC_ADDR_LEN);
		prWtbl[ucEntry].ucStaIndex = ucStaIdx;

		DBGLOG(RSN, TRACE,
		       ("[Wlan index] BSS#%d keyid#%d P=%d use WlanIndex#%d STAIdx=%d " MACSTR
			"\n", ucBssIndex, ucKeyId, prWtbl[ucEntry].ucPairwise, ucEntry, ucStaIdx,
			MAC2STR(pucAddr)));

#if DBG
		secCheckWTBLAssign(prAdapter);
#endif
	}

	ASSERT(ucEntry != WTBL_ALLOC_FAIL);

	return ucEntry;
}
/*----------------------------------------------------------------------------*/
int
mtk_cfg80211_join_ibss(struct wiphy *wiphy,
		       struct net_device *ndev, struct cfg80211_ibss_params *params)
{
	PARAM_SSID_T rNewSsid;
	P_GLUE_INFO_T prGlueInfo = NULL;
	UINT_32 u4ChnlFreq;	/* Store channel or frequency information */
	UINT_32 u4BufLen = 0;
	WLAN_STATUS rStatus;

	prGlueInfo = (P_GLUE_INFO_T) wiphy_priv(wiphy);
	ASSERT(prGlueInfo);

	/* set channel */
#if LINUX_VERSION_CODE <= KERNEL_VERSION(3, 7, 0)
	if (params->channel) {
		u4ChnlFreq = nicChannelNum2Freq(params->channel->hw_value);
#else
	if (params->chandef.chan) {
		u4ChnlFreq = nicChannelNum2Freq(params->chandef.chan->hw_value);
#endif
		rStatus = kalIoctl(prGlueInfo,
				   wlanoidSetFrequency,
				   &u4ChnlFreq,
				   sizeof(u4ChnlFreq), FALSE, FALSE, FALSE, FALSE, &u4BufLen);
		if (rStatus != WLAN_STATUS_SUCCESS) {
			return -EFAULT;
		}
	}

	/* set SSID */
	kalMemCopy(rNewSsid.aucSsid, params->ssid, params->ssid_len);
	rStatus = kalIoctl(prGlueInfo,
			   wlanoidSetSsid,
			   (PVOID) & rNewSsid,
			   sizeof(PARAM_SSID_T), FALSE, FALSE, TRUE, FALSE, &u4BufLen);

	if (rStatus != WLAN_STATUS_SUCCESS) {
		DBGLOG(REQ, WARN, ("set SSID:%lx\n", rStatus));
		return -EFAULT;
	}

	return 0;


	return -EINVAL;
}


/*----------------------------------------------------------------------------*/
/*----------------------------------------------------------------------------*/
int mtk_cfg80211_leave_ibss(struct wiphy *wiphy, struct net_device *ndev)
{
	P_GLUE_INFO_T prGlueInfo = NULL;
	WLAN_STATUS rStatus;
	UINT_32 u4BufLen;

	prGlueInfo = (P_GLUE_INFO_T) wiphy_priv(wiphy);
	ASSERT(prGlueInfo);

	rStatus = kalIoctl(prGlueInfo,
			   wlanoidSetDisassociate, NULL, 0, FALSE, FALSE, TRUE, FALSE, &u4BufLen);

	if (rStatus != WLAN_STATUS_SUCCESS) {
		DBGLOG(REQ, WARN, ("disassociate error:%lx\n", rStatus));
		return -EFAULT;
	}

	return 0;
}
Exemplo n.º 7
0
int mtk_cfg80211_vendor_set_significant_change(struct wiphy *wiphy, struct wireless_dev *wdev,
					       const void *data, int data_len)
{
	INT_32 i4Status = -EINVAL;
	P_PARAM_WIFI_SIGNIFICANT_CHANGE prWifiChangeCmd = NULL;
	UINT_8 flush = 0;
	/* struct nlattr *attr[GSCAN_ATTRIBUTE_SIGNIFICANT_CHANGE_FLUSH + 1]; */
	struct nlattr **attr = NULL;
	struct nlattr *paplist;
	int i, k;
	UINT_32 len_basic, len_aplist;

	ASSERT(wiphy);
	ASSERT(wdev);
	if ((data == NULL) || !data_len)
		goto nla_put_failure;
	DBGLOG(REQ, INFO, "%s for vendor command: data_len=%d \r\n", __func__, data_len);
	for (i = 0; i < 6; i++)
		DBGLOG(REQ, LOUD, "0x%x 0x%x 0x%x 0x%x \r\n",
			*((UINT_32 *) data + i * 4), *((UINT_32 *) data + i * 4 + 1),
			*((UINT_32 *) data + i * 4 + 2), *((UINT_32 *) data + i * 4 + 3));
	prWifiChangeCmd = kalMemAlloc(sizeof(PARAM_WIFI_SIGNIFICANT_CHANGE), VIR_MEM_TYPE);
	if (prWifiChangeCmd == NULL)
		goto nla_put_failure;
	kalMemZero(prWifiChangeCmd, sizeof(PARAM_WIFI_SIGNIFICANT_CHANGE));
	attr = kalMemAlloc(sizeof(struct nlattr *) * (GSCAN_ATTRIBUTE_SIGNIFICANT_CHANGE_FLUSH + 1), VIR_MEM_TYPE);
	if (attr == NULL)
		goto nla_put_failure;
	kalMemZero(attr, sizeof(struct nlattr *) * (GSCAN_ATTRIBUTE_SIGNIFICANT_CHANGE_FLUSH + 1));

	if (nla_parse_nested(attr, GSCAN_ATTRIBUTE_SIGNIFICANT_CHANGE_FLUSH,
		(struct nlattr *)(data - NLA_HDRLEN), nla_parse_policy) < 0)
		goto nla_put_failure;
	len_basic = 0;
	for (k = GSCAN_ATTRIBUTE_RSSI_SAMPLE_SIZE; k <= GSCAN_ATTRIBUTE_SIGNIFICANT_CHANGE_FLUSH; k++) {
		if (attr[k]) {
			switch (k) {
			case GSCAN_ATTRIBUTE_RSSI_SAMPLE_SIZE:
				prWifiChangeCmd->rssi_sample_size = nla_get_u16(attr[k]);
				len_basic += NLA_ALIGN(attr[k]->nla_len);
				break;
			case GSCAN_ATTRIBUTE_LOST_AP_SAMPLE_SIZE:
				prWifiChangeCmd->lost_ap_sample_size = nla_get_u16(attr[k]);
				len_basic += NLA_ALIGN(attr[k]->nla_len);
				break;
			case GSCAN_ATTRIBUTE_MIN_BREACHING:
				prWifiChangeCmd->min_breaching = nla_get_u16(attr[k]);
				len_basic += NLA_ALIGN(attr[k]->nla_len);
				break;
			case GSCAN_ATTRIBUTE_NUM_AP:
				prWifiChangeCmd->num_ap = nla_get_u16(attr[k]);
				len_basic += NLA_ALIGN(attr[k]->nla_len);
				DBGLOG(REQ, TRACE, "attr=0x%x, num_ap=%d nla_len=%d, \r\n",
				       *(UINT_32 *) attr[k], prWifiChangeCmd->num_ap, attr[k]->nla_len);
				break;
			case GSCAN_ATTRIBUTE_SIGNIFICANT_CHANGE_FLUSH:
				flush = nla_get_u8(attr[k]);
				len_basic += NLA_ALIGN(attr[k]->nla_len);
				break;
			}
		}
	}
	paplist = (struct nlattr *)((UINT_8 *) data + len_basic);
	DBGLOG(REQ, TRACE, "+++basic attribute size=%d flush=%d\r\n", len_basic, flush);

	if (paplist->nla_type == GSCAN_ATTRIBUTE_SIGNIFICANT_CHANGE_BSSIDS)
		paplist = (struct nlattr *)((UINT_8 *) paplist + NLA_HDRLEN);

	for (i = 0; i < prWifiChangeCmd->num_ap; i++) {
		if (nla_parse_nested(attr, GSCAN_ATTRIBUTE_RSSI_HIGH, (struct nlattr *)paplist, nla_parse_policy) < 0)
			goto nla_put_failure;
		paplist = (struct nlattr *)((UINT_8 *) paplist + NLA_HDRLEN);
		/* request.attr_start(i) as nested attribute */
		len_aplist = 0;
		for (k = GSCAN_ATTRIBUTE_BSSID; k <= GSCAN_ATTRIBUTE_RSSI_HIGH; k++) {
			if (attr[k]) {
				switch (k) {
				case GSCAN_ATTRIBUTE_BSSID:
					kalMemCopy(prWifiChangeCmd->ap[i].bssid, nla_data(attr[k]), sizeof(mac_addr));
					len_aplist += NLA_ALIGN(attr[k]->nla_len);
					break;
				case GSCAN_ATTRIBUTE_RSSI_LOW:
					prWifiChangeCmd->ap[i].low = nla_get_u32(attr[k]);
					len_aplist += NLA_ALIGN(attr[k]->nla_len);
					break;
				case GSCAN_ATTRIBUTE_RSSI_HIGH:
					prWifiChangeCmd->ap[i].high = nla_get_u32(attr[k]);
					len_aplist += NLA_ALIGN(attr[k]->nla_len);
					break;
				}
			}
		}
		if (((i + 1) % 4 == 0) || (i == prWifiChangeCmd->num_ap - 1))
			DBGLOG(REQ, TRACE, "ap[%d], len_aplist=%d\n", i, len_aplist);
		else
			DBGLOG(REQ, TRACE, "ap[%d], len_aplist=%d \t", i, len_aplist);
		paplist = (struct nlattr *)((UINT_8 *) paplist + len_aplist);
	}

	DBGLOG(REQ, TRACE,
		"flush=%d, rssi_sample_size=%d lost_ap_sample_size=%d min_breaching=%d",
		flush, prWifiChangeCmd->rssi_sample_size, prWifiChangeCmd->lost_ap_sample_size,
		prWifiChangeCmd->min_breaching);
	DBGLOG(REQ, TRACE,
		"ap[0].channel=%d low=%d high=%d, ap[1].channel=%d low=%d high=%d",
		prWifiChangeCmd->ap[0].channel, prWifiChangeCmd->ap[0].low, prWifiChangeCmd->ap[0].high,
		prWifiChangeCmd->ap[1].channel, prWifiChangeCmd->ap[1].low, prWifiChangeCmd->ap[1].high);
	kalMemFree(prWifiChangeCmd, VIR_MEM_TYPE, sizeof(PARAM_WIFI_SIGNIFICANT_CHANGE));
	kalMemFree(attr, VIR_MEM_TYPE, sizeof(struct nlattr *) * (GSCAN_ATTRIBUTE_SIGNIFICANT_CHANGE_FLUSH + 1));
	return 0;

nla_put_failure:
	if (prWifiChangeCmd)
		kalMemFree(prWifiChangeCmd, VIR_MEM_TYPE, sizeof(PARAM_WIFI_SIGNIFICANT_CHANGE));
	if (attr)
		kalMemFree(attr, VIR_MEM_TYPE,
			sizeof(struct nlattr *) * (GSCAN_ATTRIBUTE_SIGNIFICANT_CHANGE_FLUSH + 1));
	return i4Status;
}
Exemplo n.º 8
0
int mtk_cfg80211_vendor_set_hotlist(struct wiphy *wiphy, struct wireless_dev *wdev, const void *data, int data_len)
{
	/*WLAN_STATUS rStatus;*/
	P_GLUE_INFO_T prGlueInfo = NULL;
	CMD_SET_PSCAN_ADD_HOTLIST_BSSID rCmdPscnAddHotlist;

	INT_32 i4Status = -EINVAL;
	P_PARAM_WIFI_BSSID_HOTLIST prWifiHotlistCmd = NULL;
	UINT_8 flush = 0;
	/* struct nlattr *attr[GSCAN_ATTRIBUTE_SIGNIFICANT_CHANGE_FLUSH + 1]; */
	struct nlattr **attr = NULL;
	struct nlattr *paplist;
	int i, k;
	UINT_32 len_basic, len_aplist;

	ASSERT(wiphy);
	ASSERT(wdev);
	if ((data == NULL) || !data_len)
		goto nla_put_failure;
	DBGLOG(REQ, INFO, "%s for vendor command: data_len=%d \r\n", __func__, data_len);
	for (i = 0; i < 5; i++)
		DBGLOG(REQ, LOUD, "0x%x 0x%x 0x%x 0x%x \r\n",
			*((UINT_32 *) data + i * 4), *((UINT_32 *) data + i * 4 + 1),
			*((UINT_32 *) data + i * 4 + 2), *((UINT_32 *) data + i * 4 + 3));
	prWifiHotlistCmd = kalMemAlloc(sizeof(PARAM_WIFI_BSSID_HOTLIST), VIR_MEM_TYPE);
	if (prWifiHotlistCmd == NULL)
		goto nla_put_failure;
	kalMemZero(prWifiHotlistCmd, sizeof(PARAM_WIFI_BSSID_HOTLIST));
	attr = kalMemAlloc(sizeof(struct nlattr *) * (GSCAN_ATTRIBUTE_SIGNIFICANT_CHANGE_FLUSH + 1), VIR_MEM_TYPE);
	if (attr == NULL)
		goto nla_put_failure;
	kalMemZero(attr, sizeof(struct nlattr *) * (GSCAN_ATTRIBUTE_SIGNIFICANT_CHANGE_FLUSH + 1));

	if (nla_parse_nested(attr, GSCAN_ATTRIBUTE_NUM_AP, (struct nlattr *)(data - NLA_HDRLEN), nla_parse_policy) < 0)
		goto nla_put_failure;
	len_basic = 0;
	for (k = GSCAN_ATTRIBUTE_HOTLIST_FLUSH; k <= GSCAN_ATTRIBUTE_NUM_AP; k++) {
		if (attr[k]) {
			switch (k) {
			case GSCAN_ATTRIBUTE_LOST_AP_SAMPLE_SIZE:
				prWifiHotlistCmd->lost_ap_sample_size = nla_get_u32(attr[k]);
				len_basic += NLA_ALIGN(attr[k]->nla_len);
				break;
			case GSCAN_ATTRIBUTE_NUM_AP:
				prWifiHotlistCmd->num_ap = nla_get_u16(attr[k]);
				len_basic += NLA_ALIGN(attr[k]->nla_len);
				DBGLOG(REQ, TRACE, "attr=0x%x, num_ap=%d nla_len=%d, \r\n",
				       *(UINT_32 *) attr[k], prWifiHotlistCmd->num_ap, attr[k]->nla_len);
				break;
			case GSCAN_ATTRIBUTE_HOTLIST_FLUSH:
				flush = nla_get_u8(attr[k]);
				len_basic += NLA_ALIGN(attr[k]->nla_len);
				break;
			}
		}
	}
	paplist = (struct nlattr *)((UINT_8 *) data + len_basic);
	DBGLOG(REQ, TRACE, "+++basic attribute size=%d flush=%d\r\n", len_basic, flush);

	if (paplist->nla_type == GSCAN_ATTRIBUTE_HOTLIST_BSSIDS)
		paplist = (struct nlattr *)((UINT_8 *) paplist + NLA_HDRLEN);

	for (i = 0; i < prWifiHotlistCmd->num_ap; i++) {
		if (nla_parse_nested(attr, GSCAN_ATTRIBUTE_RSSI_HIGH, (struct nlattr *)paplist, nla_parse_policy) < 0)
			goto nla_put_failure;
		paplist = (struct nlattr *)((UINT_8 *) paplist + NLA_HDRLEN);
		/* request.attr_start(i) as nested attribute */
		len_aplist = 0;
		for (k = GSCAN_ATTRIBUTE_BSSID; k <= GSCAN_ATTRIBUTE_RSSI_HIGH; k++) {
			if (attr[k]) {
				switch (k) {
				case GSCAN_ATTRIBUTE_BSSID:
					kalMemCopy(prWifiHotlistCmd->ap[i].bssid, nla_data(attr[k]), sizeof(mac_addr));
					len_aplist += NLA_ALIGN(attr[k]->nla_len);
					break;
				case GSCAN_ATTRIBUTE_RSSI_LOW:
					prWifiHotlistCmd->ap[i].low = nla_get_u32(attr[k]);
					len_aplist += NLA_ALIGN(attr[k]->nla_len);
					break;
				case GSCAN_ATTRIBUTE_RSSI_HIGH:
					prWifiHotlistCmd->ap[i].high = nla_get_u32(attr[k]);
					len_aplist += NLA_ALIGN(attr[k]->nla_len);
					break;
				}
			}
		}
		if (((i + 1) % 4 == 0) || (i == prWifiHotlistCmd->num_ap - 1))
			DBGLOG(REQ, TRACE, "ap[%d], len_aplist=%d\n", i, len_aplist);
		else
			DBGLOG(REQ, TRACE, "ap[%d], len_aplist=%d \t", i, len_aplist);
		paplist = (struct nlattr *)((UINT_8 *) paplist + len_aplist);
	}

	DBGLOG(REQ, TRACE,
	"flush=%d, lost_ap_sample_size=%d, Hotlist:ap[0].channel=%d low=%d high=%d, ap[1].channel=%d low=%d high=%d",
		flush, prWifiHotlistCmd->lost_ap_sample_size,
		prWifiHotlistCmd->ap[0].channel, prWifiHotlistCmd->ap[0].low, prWifiHotlistCmd->ap[0].high,
		prWifiHotlistCmd->ap[1].channel, prWifiHotlistCmd->ap[1].low, prWifiHotlistCmd->ap[1].high);

	memcpy(&(rCmdPscnAddHotlist.aucMacAddr), &(prWifiHotlistCmd->ap[0].bssid), 6 * sizeof(UINT_8));
	rCmdPscnAddHotlist.ucFlags = (UINT_8) TRUE;
	prGlueInfo = (P_GLUE_INFO_T) wiphy_priv(wiphy);
	ASSERT(prGlueInfo);

	kalMemFree(prWifiHotlistCmd, VIR_MEM_TYPE, sizeof(PARAM_WIFI_BSSID_HOTLIST));
	kalMemFree(attr, VIR_MEM_TYPE, sizeof(struct nlattr *) * (GSCAN_ATTRIBUTE_SIGNIFICANT_CHANGE_FLUSH + 1));
	return 0;

nla_put_failure:
	if (prWifiHotlistCmd)
		kalMemFree(prWifiHotlistCmd, VIR_MEM_TYPE, sizeof(PARAM_WIFI_BSSID_HOTLIST));
	if (attr)
		kalMemFree(attr, VIR_MEM_TYPE,
			sizeof(struct nlattr *) * (GSCAN_ATTRIBUTE_SIGNIFICANT_CHANGE_FLUSH + 1));
	return i4Status;
}
Exemplo n.º 9
0
static int netdev_event(struct notifier_block *nb, unsigned long notification, void *ptr)
{
   struct in_device *in_dev;    /* ALPS00409409406 */
    UINT_8  ip[4] = { 0 };
    UINT_32 u4NumIPv4 = 0;
//#ifdef  CONFIG_IPV6
#if 0
    UINT_8  ip6[16] = { 0 };     // FIX ME: avoid to allocate large memory in stack
    UINT_32 u4NumIPv6 = 0;
#endif
    struct in_ifaddr *ifa = (struct in_ifaddr *) ptr;
    struct net_device *prDev = ifa->ifa_dev->dev;
    UINT_32 i;
    P_PARAM_NETWORK_ADDRESS_IP prParamIpAddr;
    P_GLUE_INFO_T prGlueInfo = NULL;

    if (prDev == NULL) {
        DBGLOG(REQ, INFO, ("netdev_event: device is empty.\n"));
        return NOTIFY_DONE;
    }

    if ((strncmp(prDev->name, "p2p", 3) != 0) && (strncmp(prDev->name, "wlan", 4) != 0)) {
        DBGLOG(REQ, INFO, ("netdev_event: xxx\n"));
        return NOTIFY_DONE;
    }

    prGlueInfo = *((P_GLUE_INFO_T *) netdev_priv(prDev));

    if (prGlueInfo == NULL) {
        DBGLOG(REQ, INFO, ("netdev_event: prGlueInfo is empty.\n"));
        return NOTIFY_DONE;
    }
    ASSERT(prGlueInfo);

#ifdef FIX_ALPS00409409406
           // <3> get the IPv4 address    
           in_dev = in_dev_get(prDev);
           if (!in_dev)
              return;
           
           //rtnl_lock();                  
           if(!in_dev->ifa_list ||!in_dev->ifa_list->ifa_local) {
                  //rtnl_unlock();
                  in_dev_put(in_dev);
                  DBGLOG(REQ, INFO, ("ip is not avaliable.\n"));
                  return;
          }
           // <4> copy the IPv4 address
           kalMemCopy(ip, &(in_dev->ifa_list->ifa_local), sizeof(ip));
           //rtnl_unlock();
           in_dev_put(in_dev);
            
           DBGLOG(REQ, INFO, ("ip is %d.%d.%d.%d\n",
                   ip[0],ip[1],ip[2],ip[3]));
#else
    // <3> get the IPv4 address
    if(!prDev || !(prDev->ip_ptr)||\
            !((struct in_device *)(prDev->ip_ptr))->ifa_list||\
            !(&(((struct in_device *)(prDev->ip_ptr))->ifa_list->ifa_local))){
        DBGLOG(REQ, INFO, ("ip is not avaliable.\n"));
        return NOTIFY_DONE;
    }

    kalMemCopy(ip, &(((struct in_device *)(prDev->ip_ptr))->ifa_list->ifa_local), sizeof(ip));
    DBGLOG(REQ, INFO, ("ip is %d.%d.%d.%d\n",
            ip[0],ip[1],ip[2],ip[3]));
#endif

    // todo: traverse between list to find whole sets of IPv4 addresses
    if (!((ip[0] == 0) &&
         (ip[1] == 0) &&
         (ip[2] == 0) &&
         (ip[3] == 0))) {
        u4NumIPv4++;
    }

#if defined(MTK_WLAN_ARP_OFFLOAD)
	if(NETDEV_UP == notification && PARAM_MEDIA_STATE_CONNECTED == prGlueInfo->eParamMediaStateIndicated){
		PARAM_CUSTOM_SW_CTRL_STRUC_T SwCtrlInfo;
		UINT_32 u4SetInfoLen;
		WLAN_STATUS rStatus = WLAN_STATUS_FAILURE;
		
		SwCtrlInfo.u4Id = 0x90110000;
		SwCtrlInfo.u4Data = 1;
		
		rStatus = kalIoctl(prGlueInfo,
                wlanoidSetSwCtrlWrite,
                (PVOID)&SwCtrlInfo,
                sizeof(SwCtrlInfo),
                FALSE,
                FALSE,
                TRUE,
                FALSE,
                &u4SetInfoLen);

     if (rStatus != WLAN_STATUS_SUCCESS) {
       		DBGLOG(REQ, INFO, ("ARP OFFLOAD fail 0x%lx\n", rStatus));
     }else{
       		DBGLOG(REQ, INFO, ("ARP OFFLOAD success\n"));  			
    } 	  
  }
#endif


#ifdef FIX_ALPS00409409406    
       if(atomic_read(&fgIsUnderEarlierSuspend)==0){
#else
       if (fgIsUnderEarlierSuspend == false) {
#endif
				DBGLOG(REQ, INFO, ("netdev_event: PARAM_MEDIA_STATE_DISCONNECTED. (%d)\n", prGlueInfo->eParamMediaStateIndicated));
				return NOTIFY_DONE;
    }

//#ifdef  CONFIG_IPV6
#if 0
    if(!prDev || !(prDev->ip6_ptr)||\
        !((struct in_device *)(prDev->ip6_ptr))->ifa_list||\
        !(&(((struct in_device *)(prDev->ip6_ptr))->ifa_list->ifa_local))){
        printk(KERN_INFO "ipv6 is not avaliable.\n");
        return NOTIFY_DONE;
    }

    kalMemCopy(ip6, &(((struct in_device *)(prDev->ip6_ptr))->ifa_list->ifa_local), sizeof(ip6));
    printk(KERN_INFO"ipv6 is %d.%d.%d.%d.%d.%d.%d.%d.%d.%d.%d.%d.%d.%d.%d.%d\n",
            ip6[0],ip6[1],ip6[2],ip6[3],
            ip6[4],ip6[5],ip6[6],ip6[7],
            ip6[8],ip6[9],ip6[10],ip6[11],
            ip6[12],ip6[13],ip6[14],ip6[15]
            );

    // todo: traverse between list to find whole sets of IPv6 addresses
    if (!((ip6[0] == 0) &&
         (ip6[1] == 0) &&
         (ip6[2] == 0) &&
         (ip6[3] == 0) &&
         (ip6[4] == 0) &&
         (ip6[5] == 0))) {
        //u4NumIPv6++;
    }
#endif

    // here we can compare the dev with other network's netdev to
    // set the proper arp filter
    //
    // IMPORTANT: please make sure if the context can sleep, if the context can't sleep
    // we should schedule a kernel thread to do this for us

    // <7> set up the ARP filter
    {
        WLAN_STATUS rStatus = WLAN_STATUS_FAILURE;
        UINT_32 u4SetInfoLen = 0;
        UINT_8 aucBuf[32] = {0};
        UINT_32 u4Len = OFFSET_OF(PARAM_NETWORK_ADDRESS_LIST, arAddress);
        P_PARAM_NETWORK_ADDRESS_LIST prParamNetAddrList = (P_PARAM_NETWORK_ADDRESS_LIST)aucBuf;
        P_PARAM_NETWORK_ADDRESS prParamNetAddr = prParamNetAddrList->arAddress;

//#ifdef  CONFIG_IPV6
#if 0
        prParamNetAddrList->u4AddressCount = u4NumIPv4 + u4NumIPv6;
#else
        prParamNetAddrList->u4AddressCount = u4NumIPv4;
#endif
        prParamNetAddrList->u2AddressType = PARAM_PROTOCOL_ID_TCP_IP;
        for (i = 0; i < u4NumIPv4; i++) {
            prParamNetAddr->u2AddressLength = sizeof(PARAM_NETWORK_ADDRESS_IP);//4;;
            prParamNetAddr->u2AddressType = PARAM_PROTOCOL_ID_TCP_IP;;
#if 0
            kalMemCopy(prParamNetAddr->aucAddress, ip, sizeof(ip));
            prParamNetAddr = (P_PARAM_NETWORK_ADDRESS)((UINT_32)prParamNetAddr + sizeof(ip));
            u4Len += OFFSET_OF(PARAM_NETWORK_ADDRESS, aucAddress) + sizeof(ip);
#else
            prParamIpAddr = (P_PARAM_NETWORK_ADDRESS_IP)prParamNetAddr->aucAddress;
            kalMemCopy(&prParamIpAddr->in_addr, ip, sizeof(ip));
            prParamNetAddr = (P_PARAM_NETWORK_ADDRESS)((UINT_32)prParamNetAddr + sizeof(PARAM_NETWORK_ADDRESS));
            u4Len += OFFSET_OF(PARAM_NETWORK_ADDRESS, aucAddress) + sizeof(PARAM_NETWORK_ADDRESS);
#endif
        }
//#ifdef  CONFIG_IPV6
#if 0
        for (i = 0; i < u4NumIPv6; i++) {
            prParamNetAddr->u2AddressLength = 6;;
            prParamNetAddr->u2AddressType = PARAM_PROTOCOL_ID_TCP_IP;;
            kalMemCopy(prParamNetAddr->aucAddress, ip6, sizeof(ip6));
            prParamNetAddr = (P_PARAM_NETWORK_ADDRESS)((UINT_32)prParamNetAddr + sizeof(ip6));
            u4Len += OFFSET_OF(PARAM_NETWORK_ADDRESS, aucAddress) + sizeof(ip6);
       }
#endif
        ASSERT(u4Len <= sizeof(aucBuf));

    DBGLOG(REQ, INFO, ("kalIoctl (0x%x, 0x%x)\n", prGlueInfo, prParamNetAddrList));

        rStatus = kalIoctl(prGlueInfo,
                wlanoidSetNetworkAddress,
                (PVOID)prParamNetAddrList,
                u4Len,
                FALSE,
                FALSE,
                TRUE,
                FALSE,
                &u4SetInfoLen);

        if (rStatus != WLAN_STATUS_SUCCESS) {
            DBGLOG(REQ, INFO, ("set HW pattern filter fail 0x%lx\n", rStatus));
        }
    }

    return NOTIFY_DONE;

}

static struct notifier_block inetaddr_notifier = {
    .notifier_call      =   netdev_event,
};

void wlanRegisterNotifier(void)
{
    register_inetaddr_notifier(&inetaddr_notifier);
}
Exemplo n.º 10
0
/*----------------------------------------------------------------------------*/
VOID
kalP2PInvitationIndication(IN P_GLUE_INFO_T prGlueInfo,
			   IN P_P2P_DEVICE_DESC_T prP2pDevDesc,
			   IN PUINT_8 pucSsid,
			   IN UINT_8 ucSsidLen,
			   IN UINT_8 ucOperatingChnl,
			   IN UINT_8 ucInvitationType, IN PUINT_8 pucGroupBssid)
{
#if 1
	union iwreq_data evt;
	UINT_8 aucBuffer[IW_CUSTOM_MAX];

	ASSERT(prGlueInfo);

	/* buffer peer information for later IOC_P2P_GET_STRUCT access */
	prGlueInfo->prP2PInfo->u4ConnReqNameLength =
	    (UINT_32) ((prP2pDevDesc->u2NameLength > 32) ? 32 : prP2pDevDesc->u2NameLength);
	kalMemCopy(prGlueInfo->prP2PInfo->aucConnReqDevName, prP2pDevDesc->aucName,
		   prGlueInfo->prP2PInfo->u4ConnReqNameLength);
	COPY_MAC_ADDR(prGlueInfo->prP2PInfo->rConnReqPeerAddr, prP2pDevDesc->aucDeviceAddr);
	COPY_MAC_ADDR(prGlueInfo->prP2PInfo->rConnReqGroupAddr, pucGroupBssid);
	prGlueInfo->prP2PInfo->i4ConnReqConfigMethod = (INT_32) (prP2pDevDesc->u2ConfigMethod);
	prGlueInfo->prP2PInfo->ucOperatingChnl = ucOperatingChnl;
	prGlueInfo->prP2PInfo->ucInvitationType = ucInvitationType;

	/* prepare event structure */
	memset(&evt, 0, sizeof(evt));

	snprintf(aucBuffer, IW_CUSTOM_MAX - 1, "P2P_INV_INDICATE");
	evt.data.length = strlen(aucBuffer);

	/* indicate in IWEVCUSTOM event */
	wireless_send_event(prGlueInfo->prP2PInfo->prDevHandler, IWEVCUSTOM, &evt, aucBuffer);
	return;

#else
	P_MSG_P2P_CONNECTION_REQUEST_T prP2pConnReq = (P_MSG_P2P_CONNECTION_REQUEST_T) NULL;
	P_P2P_SPECIFIC_BSS_INFO_T prP2pSpecificBssInfo = (P_P2P_SPECIFIC_BSS_INFO_T) NULL;
	P_P2P_CONNECTION_SETTINGS_T prP2pConnSettings = (P_P2P_CONNECTION_SETTINGS_T) NULL;

	do {
		ASSERT_BREAK((prGlueInfo != NULL) && (prP2pDevDesc != NULL));


		/* Not a real solution */

		prP2pSpecificBssInfo = prGlueInfo->prAdapter->rWifiVar.prP2pSpecificBssInfo;
		prP2pConnSettings = prGlueInfo->prAdapter->rWifiVar.prP2PConnSettings;

		prP2pConnReq = (P_MSG_P2P_CONNECTION_REQUEST_T) cnmMemAlloc(prGlueInfo->prAdapter,
									    RAM_TYPE_MSG,
									    sizeof
									    (MSG_P2P_CONNECTION_REQUEST_T));

		if (prP2pConnReq == NULL) {
			break;
		}


		kalMemZero(prP2pConnReq, sizeof(MSG_P2P_CONNECTION_REQUEST_T));

		prP2pConnReq->rMsgHdr.eMsgId = MID_MNY_P2P_CONNECTION_REQ;

		prP2pConnReq->eFormationPolicy = ENUM_P2P_FORMATION_POLICY_AUTO;

		COPY_MAC_ADDR(prP2pConnReq->aucDeviceID, prP2pDevDesc->aucDeviceAddr);

		prP2pConnReq->u2ConfigMethod = prP2pDevDesc->u2ConfigMethod;

		if (ucInvitationType == P2P_INVITATION_TYPE_INVITATION) {
			prP2pConnReq->fgIsPersistentGroup = FALSE;
			prP2pConnReq->fgIsTobeGO = FALSE;

		}

		else if (ucInvitationType == P2P_INVITATION_TYPE_REINVOKE) {
			DBGLOG(P2P, TRACE, ("Re-invoke Persistent Group\n"));
			prP2pConnReq->fgIsPersistentGroup = TRUE;
			prP2pConnReq->fgIsTobeGO =
			    (prGlueInfo->prP2PInfo->ucRole == 2) ? TRUE : FALSE;

		}


		p2pFsmRunEventDeviceDiscoveryAbort(prGlueInfo->prAdapter, NULL);

		if (ucOperatingChnl != 0) {
			prP2pSpecificBssInfo->ucPreferredChannel = ucOperatingChnl;
		}

		if ((ucSsidLen < 32) && (pucSsid != NULL)) {
			COPY_SSID(prP2pConnSettings->aucSSID,
				  prP2pConnSettings->ucSSIDLen, pucSsid, ucSsidLen);
		}

		mboxSendMsg(prGlueInfo->prAdapter,
			    MBOX_ID_0, (P_MSG_HDR_T) prP2pConnReq, MSG_SEND_METHOD_BUF);



	} while (FALSE);

	/* frog add. */
	/* TODO: Invitation Indication */

	return;
#endif

}				/* kalP2PInvitationIndication */
Exemplo n.º 11
0
VOID
wfdFuncGenerateWfd_IE (
    IN P_ADAPTER_T prAdapter,
    IN BOOLEAN fgIsAssocFrame,
    IN PUINT_16 pu2Offset,
    IN PUINT_8 pucBuf,
    IN UINT_16 u2BufSize,
    IN APPEND_VAR_ATTRI_ENTRY_T arAppendAttriTable[],
    IN UINT_32 u4AttriTableSize
    )
{


    PUINT_8 pucBuffer = (PUINT_8)NULL;
    P_IE_WFD_T prIeWFD = (P_IE_WFD_T)NULL;
    UINT_32 u4OverallAttriLen;
    UINT_32 u4AttriLen;
    UINT_8 aucWfaOui[] = VENDOR_OUI_WFA_SPECIFIC;
    UINT_8 aucTempBuffer[P2P_MAXIMUM_ATTRIBUTE_LEN];
    UINT_32 i;


    do {
        ASSERT_BREAK((prAdapter != NULL) && (pucBuf != NULL));

        pucBuffer = (PUINT_8)((UINT_32)pucBuf + (*pu2Offset));

        ASSERT_BREAK(pucBuffer != NULL);

        /* Check buffer length is still enough. */
        ASSERT_BREAK((u2BufSize - (*pu2Offset)) >= WFD_IE_OUI_HDR);

        prIeWFD = (P_IE_WFD_T)pucBuffer;

        prIeWFD->ucId = ELEM_ID_WFD;

        prIeWFD->aucOui[0] = aucWfaOui[0];
        prIeWFD->aucOui[1] = aucWfaOui[1];
        prIeWFD->aucOui[2] = aucWfaOui[2];
        prIeWFD->ucOuiType = VENDOR_OUI_TYPE_WFD;

        (*pu2Offset) += WFD_IE_OUI_HDR;

        /* Overall length of all Attributes */
        u4OverallAttriLen = 0;

        for (i = 0; i < u4AttriTableSize; i++) {

            if (arAppendAttriTable[i].pfnAppendAttri) {
                u4AttriLen = arAppendAttriTable[i].pfnAppendAttri(prAdapter, fgIsAssocFrame, pu2Offset, pucBuf, u2BufSize);

                u4OverallAttriLen += u4AttriLen;

                if (u4OverallAttriLen > P2P_MAXIMUM_ATTRIBUTE_LEN) {
                    u4OverallAttriLen -= P2P_MAXIMUM_ATTRIBUTE_LEN;

                    prIeWFD->ucLength = (VENDOR_OUI_TYPE_LEN + P2P_MAXIMUM_ATTRIBUTE_LEN);

                    pucBuffer = (PUINT_8)((UINT_32)prIeWFD + (WFD_IE_OUI_HDR + P2P_MAXIMUM_ATTRIBUTE_LEN));

                    prIeWFD = (P_IE_WFD_T)((UINT_32)prIeWFD + (WFD_IE_OUI_HDR + P2P_MAXIMUM_ATTRIBUTE_LEN));

                    kalMemCopy(aucTempBuffer, pucBuffer, u4OverallAttriLen);

                    prIeWFD->ucId = ELEM_ID_WFD;

                    prIeWFD->aucOui[0] = aucWfaOui[0];
                    prIeWFD->aucOui[1] = aucWfaOui[1];
                    prIeWFD->aucOui[2] = aucWfaOui[2];
                    prIeWFD->ucOuiType = VENDOR_OUI_TYPE_WFD;

                    kalMemCopy(prIeWFD->aucWFDAttributes, aucTempBuffer, u4OverallAttriLen);
                    (*pu2Offset) += WFD_IE_OUI_HDR;
                }

            }

        }

        prIeWFD->ucLength = (UINT_8)(VENDOR_OUI_TYPE_LEN + u4OverallAttriLen);


    } while (FALSE);

    return;
} /* wfdFuncGenerateWfd_IE */
Exemplo n.º 12
0
/*----------------------------------------------------------------------------*/
VOID joinComplete(IN P_ADAPTER_T prAdapter)
{
	P_JOIN_INFO_T prJoinInfo;
	P_BSS_DESC_T prBssDesc;
	P_PEER_BSS_INFO_T prPeerBssInfo;
	P_BSS_INFO_T prBssInfo;
	P_CONNECTION_SETTINGS_T prConnSettings;
	P_STA_RECORD_T prStaRec;
	P_TX_CTRL_T prTxCtrl;
#if CFG_SUPPORT_802_11D
	P_IE_COUNTRY_T prIECountry;
#endif

	DEBUGFUNC("joinComplete");


	ASSERT(prAdapter);
	prJoinInfo = &prAdapter->rJoinInfo;
	prBssDesc = prJoinInfo->prBssDesc;
	prPeerBssInfo = &prAdapter->rPeerBssInfo;
	prBssInfo = &prAdapter->rBssInfo;
	prConnSettings = &prAdapter->rConnSettings;
	prTxCtrl = &prAdapter->rTxCtrl;

/* 4 <1> Update Connecting & Connected Flag of BSS_DESC_T. */
	/* Remove previous AP's Connection Flags if have */
	scanRemoveConnectionFlagOfBssDescByBssid(prAdapter, prBssInfo->aucBSSID);

	prBssDesc->fgIsConnected = TRUE;	/* Mask as Connected */

	if (prBssDesc->fgIsHiddenSSID) {
		/* NOTE(Kevin): This is for the case of Passive Scan and the target BSS didn't
		 * broadcast SSID on its Beacon Frame.
		 */
		COPY_SSID(prBssDesc->aucSSID,
			  prBssDesc->ucSSIDLen,
			  prAdapter->rConnSettings.aucSSID, prAdapter->rConnSettings.ucSSIDLen);

		if (prBssDesc->ucSSIDLen)
			prBssDesc->fgIsHiddenSSID = FALSE;

#if DBG
		else
			ASSERT(0);

#endif				/* DBG */

		DBGLOG(JOIN, INFO, ("Hidden SSID! - Update SSID : %s\n", prBssDesc->aucSSID));
	}

/* 4 <2> Update BSS_INFO_T from BSS_DESC_T */
	/* 4 <2.A> PHY Type */
	prBssInfo->ePhyType = prBssDesc->ePhyType;

	/* 4 <2.B> BSS Type */
	prBssInfo->eBSSType = BSS_TYPE_INFRASTRUCTURE;

	/* 4 <2.C> BSSID */
	COPY_MAC_ADDR(prBssInfo->aucBSSID, prBssDesc->aucBSSID);

	DBGLOG(JOIN, INFO, ("JOIN to BSSID: [" MACSTR "]\n", MAC2STR(prBssDesc->aucBSSID)));


	/* 4 <2.D> SSID */
	COPY_SSID(prBssInfo->aucSSID,
		  prBssInfo->ucSSIDLen, prBssDesc->aucSSID, prBssDesc->ucSSIDLen);

	/* 4 <2.E> Channel / Band information. */
	prBssInfo->eBand = prBssDesc->eBand;
	prBssInfo->ucChnl = prBssDesc->ucChannelNum;

	/* 4 <2.F> RSN/WPA information. */
	secFsmRunEventStart(prAdapter);
	prBssInfo->u4RsnSelectedPairwiseCipher = prBssDesc->u4RsnSelectedPairwiseCipher;
	prBssInfo->u4RsnSelectedGroupCipher = prBssDesc->u4RsnSelectedGroupCipher;
	prBssInfo->u4RsnSelectedAKMSuite = prBssDesc->u4RsnSelectedAKMSuite;

	if (secRsnKeyHandshakeEnabled())
		prBssInfo->fgIsWPAorWPA2Enabled = TRUE;
	else
		prBssInfo->fgIsWPAorWPA2Enabled = FALSE;


	/* 4 <2.G> Beacon interval. */
	prBssInfo->u2BeaconInterval = prBssDesc->u2BeaconInterval;

	/* 4 <2.H> DTIM period. */
	prBssInfo->ucDtimPeriod = prBssDesc->ucDTIMPeriod;

	/* 4 <2.I> ERP Information */
	if ((prBssInfo->ePhyType == PHY_TYPE_ERP_INDEX) &&	/* Our BSS's PHY_TYPE is ERP now. */
	    (prBssDesc->fgIsERPPresent)) {

		prBssInfo->fgIsERPPresent = TRUE;
		prBssInfo->ucERP = prBssDesc->ucERP;	/* Save the ERP for later check */
	} else {
		/* Some AP, may send ProbeResp without ERP IE. Thus prBssDesc->fgIsERPPresent is FALSE. */
		prBssInfo->fgIsERPPresent = FALSE;
		prBssInfo->ucERP = 0;
	}

#if CFG_SUPPORT_802_11D
	/* 4 <2.J> Country inforamtion of the associated AP */
	if (prConnSettings->fgMultiDomainCapabilityEnabled) {
		DOMAIN_INFO_ENTRY rDomainInfo;
		if (domainGetDomainInfoByScanResult(prAdapter, &rDomainInfo)) {
			if (prBssDesc->prIECountry) {
				prIECountry = prBssDesc->prIECountry;

				domainParseCountryInfoElem(prIECountry, &prBssInfo->rDomainInfo);

				/* use the domain get from the BSS info */
				prBssInfo->fgIsCountryInfoPresent = TRUE;
				nicSetupOpChnlList(prAdapter, prBssInfo->rDomainInfo.u2CountryCode,
						   FALSE);
			} else {
				/* use the domain get from the scan result */
				prBssInfo->fgIsCountryInfoPresent = TRUE;
				nicSetupOpChnlList(prAdapter, rDomainInfo.u2CountryCode, FALSE);
			}
		}
	}
#endif

	/* 4 <2.K> Signal Power of the associated AP */
	prBssInfo->rRcpi = prBssDesc->rRcpi;
	prBssInfo->rRssi = RCPI_TO_dBm(prBssInfo->rRcpi);
	GET_CURRENT_SYSTIME(&prBssInfo->rRssiLastUpdateTime);

	/* 4 <2.L> Capability Field of the associated AP */
	prBssInfo->u2CapInfo = prBssDesc->u2CapInfo;

	DBGLOG(JOIN, INFO,
	       ("prBssInfo-> fgIsERPPresent = %d, ucERP = %02x, rRcpi = %d, rRssi = %ld\n",
		prBssInfo->fgIsERPPresent, prBssInfo->ucERP, prBssInfo->rRcpi, prBssInfo->rRssi));


/* 4 <3> Update BSS_INFO_T from PEER_BSS_INFO_T & NIC RATE FUNC */
	/* 4 <3.A> Association ID */
	prBssInfo->u2AssocId = prPeerBssInfo->u2AssocId;

	/* 4 <3.B> WMM Infomation */
	if (prAdapter->fgIsEnableWMM && (prPeerBssInfo->rWmmInfo.ucWmmFlag & WMM_FLAG_SUPPORT_WMM)) {

		prBssInfo->fgIsWmmAssoc = TRUE;
		prTxCtrl->rTxQForVoipAccess = TXQ_AC3;

		qosWmmInfoInit(&prBssInfo->rWmmInfo,
			       (prBssInfo->ePhyType == PHY_TYPE_HR_DSSS_INDEX) ? TRUE : FALSE);

		if (prPeerBssInfo->rWmmInfo.ucWmmFlag & WMM_FLAG_AC_PARAM_PRESENT) {
			kalMemCopy(&prBssInfo->rWmmInfo,
				   &prPeerBssInfo->rWmmInfo, sizeof(WMM_INFO_T));
		} else {
			kalMemCopy(&prBssInfo->rWmmInfo,
				   &prPeerBssInfo->rWmmInfo,
				   sizeof(WMM_INFO_T) -
				   sizeof(prPeerBssInfo->rWmmInfo.arWmmAcParams));
		}
	} else {
		prBssInfo->fgIsWmmAssoc = FALSE;
		prTxCtrl->rTxQForVoipAccess = TXQ_AC1;

		kalMemZero(&prBssInfo->rWmmInfo, sizeof(WMM_INFO_T));
	}


	/* 4 <3.C> Operational Rate Set & BSS Basic Rate Set */
	prBssInfo->u2OperationalRateSet = prPeerBssInfo->u2OperationalRateSet;
	prBssInfo->u2BSSBasicRateSet = prPeerBssInfo->u2BSSBasicRateSet;


	/* 4 <3.D> Short Preamble */
	if (prBssInfo->fgIsERPPresent) {

		/* NOTE(Kevin 2007/12/24): Truth Table.
		 * Short Preamble Bit in
		 * <AssocReq><AssocResp w/i ERP><BARKER(Long)>Final Driver Setting(Short)
		 * TRUE      FALSE              FALSE       FALSE(shouldn't have such case, use the AssocResp)
		 * TRUE      FALSE              TRUE        FALSE
		 * FALSE     FALSE              FALSE       FALSE(shouldn't have such case, use the AssocResp)
		 * FALSE     FALSE              TRUE        FALSE
		 * TRUE      TRUE               FALSE       TRUE(follow ERP)
		 * TRUE      TRUE               TRUE        FALSE(follow ERP)
		 * FALSE     TRUE               FALSE       FALSE(shouldn't have such case, and we should set to FALSE)
		 * FALSE     TRUE               TRUE        FALSE(we should set to FALSE)
		 */
		if ((prPeerBssInfo->fgIsShortPreambleAllowed) &&
			((prConnSettings->ePreambleType == PREAMBLE_TYPE_SHORT) ||
			/* Short Preamble Option Enable is TRUE */
								  ((prConnSettings->ePreambleType ==
								    PREAMBLE_TYPE_AUTO)
								   && (prBssDesc->
								       u2CapInfo &
								       CAP_INFO_SHORT_PREAMBLE)))) {

			prBssInfo->fgIsShortPreambleAllowed = TRUE;

			if (prBssInfo->ucERP & ERP_INFO_BARKER_PREAMBLE_MODE)
				prBssInfo->fgUseShortPreamble = FALSE;
			else
				prBssInfo->fgUseShortPreamble = TRUE;

		} else {
			prBssInfo->fgIsShortPreambleAllowed = FALSE;
			prBssInfo->fgUseShortPreamble = FALSE;
		}
	} else {
		/* NOTE(Kevin 2007/12/24): Truth Table.
		 * Short Preamble Bit in
		 * <AssocReq>     <AssocResp w/o ERP>     Final Driver Setting(Short)
		 * TRUE            FALSE                  FALSE
		 * FALSE           FALSE                  FALSE
		 * TRUE            TRUE                   TRUE
		 * FALSE           TRUE(status success)   TRUE
		 * --> Honor the result of prPeerBssInfo.
		 */

		prBssInfo->fgIsShortPreambleAllowed = prBssInfo->fgUseShortPreamble =
		    prPeerBssInfo->fgIsShortPreambleAllowed;
	}

	DBGLOG(JOIN, INFO,
	       ("prBssInfo->fgIsShortPreambleAllowed = %d, prBssInfo->fgUseShortPreamble = %d\n",
		prBssInfo->fgIsShortPreambleAllowed, prBssInfo->fgUseShortPreamble));


	/* 4 <3.E> Short Slot Time */
	prBssInfo->fgUseShortSlotTime = prPeerBssInfo->fgUseShortSlotTime;	/* AP support Short Slot Time */

	DBGLOG(JOIN, INFO, ("prBssInfo->fgUseShortSlotTime = %d\n", prBssInfo->fgUseShortSlotTime));

	nicSetSlotTime(prAdapter,
		       prBssInfo->ePhyType,
		       ((prConnSettings->fgIsShortSlotTimeOptionEnable &&
			 prBssInfo->fgUseShortSlotTime) ? TRUE : FALSE));


	/* 4 <3.F> Update Tx Rate for Control Frame */
	bssUpdateTxRateForControlFrame(prAdapter);


	/* 4 <3.G> Save the available Auth Types during Roaming (Design for Fast BSS Transition). */
	/* if (prAdapter->fgIsEnableRoaming) */ /* NOTE(Kevin): Always prepare info for roaming */
	{

		if (prJoinInfo->ucCurrAuthAlgNum == AUTH_ALGORITHM_NUM_OPEN_SYSTEM)
			prJoinInfo->ucRoamingAuthTypes |= AUTH_TYPE_OPEN_SYSTEM;
		else if (prJoinInfo->ucCurrAuthAlgNum == AUTH_ALGORITHM_NUM_SHARED_KEY)
			prJoinInfo->ucRoamingAuthTypes |= AUTH_TYPE_SHARED_KEY;


		prBssInfo->ucRoamingAuthTypes = prJoinInfo->ucRoamingAuthTypes;


		/* Set the stable time of the associated BSS. We won't do roaming decision
		 * during the stable time.
		 */
		SET_EXPIRATION_TIME(prBssInfo->rRoamingStableExpirationTime,
				    SEC_TO_SYSTIME(ROAMING_STABLE_TIMEOUT_SEC));
	}


	/* 4 <3.H> Update Parameter for TX Fragmentation Threshold */
#if CFG_TX_FRAGMENT
	txFragInfoUpdate(prAdapter);
#endif				/* CFG_TX_FRAGMENT */


/* 4 <4> Update STA_RECORD_T */
	/* Get a Station Record if possible */
	prStaRec = staRecGetStaRecordByAddr(prAdapter, prBssDesc->aucBSSID);

	if (prStaRec) {
		UINT_16 u2OperationalRateSet, u2DesiredRateSet;

		/* 4 <4.A> Desired Rate Set */
		u2OperationalRateSet = (rPhyAttributes[prBssInfo->ePhyType].u2SupportedRateSet &
					prBssInfo->u2OperationalRateSet);

		u2DesiredRateSet = (u2OperationalRateSet & prConnSettings->u2DesiredRateSet);
		if (u2DesiredRateSet) {
			prStaRec->u2DesiredRateSet = u2DesiredRateSet;
		} else {
			/* For Error Handling - The Desired Rate Set is not covered in Operational Rate Set. */
			prStaRec->u2DesiredRateSet = u2OperationalRateSet;
		}

		/* Try to set the best initial rate for this entry */
		if (!rateGetBestInitialRateIndex(prStaRec->u2DesiredRateSet,
						 prStaRec->rRcpi, &prStaRec->ucCurrRate1Index)) {

			if (!rateGetLowestRateIndexFromRateSet(prStaRec->u2DesiredRateSet,
							       &prStaRec->ucCurrRate1Index)) {
				ASSERT(0);
			}
		}

		DBGLOG(JOIN, INFO, ("prStaRec->ucCurrRate1Index = %d\n",
				    prStaRec->ucCurrRate1Index));

		/* 4 <4.B> Preamble Mode */
		prStaRec->fgIsShortPreambleOptionEnable = prBssInfo->fgUseShortPreamble;

		/* 4 <4.C> QoS Flag */
		prStaRec->fgIsQoS = prBssInfo->fgIsWmmAssoc;
	}
#if DBG
	else
		ASSERT(0);

#endif				/* DBG */


/* 4 <5> Update NIC */
	/* 4 <5.A> Update BSSID & Operation Mode */
	nicSetupBSS(prAdapter, prBssInfo);

	/* 4 <5.B> Update WLAN Table. */
	if (nicSetHwBySta(prAdapter, prStaRec) == FALSE)
		ASSERT(FALSE);

	/* 4 <5.C> Update Desired Rate Set for BT. */
#if CFG_TX_FRAGMENT
	if (prConnSettings->fgIsEnableTxAutoFragmentForBT)
		txRateSetInitForBT(prAdapter, prStaRec);

#endif				/* CFG_TX_FRAGMENT */

	/* 4 <5.D> TX AC Parameter and TX/RX Queue Control */
	if (prBssInfo->fgIsWmmAssoc) {

#if CFG_TX_AGGREGATE_HW_FIFO
		nicTxAggregateTXQ(prAdapter, FALSE);
#endif				/* CFG_TX_AGGREGATE_HW_FIFO */

		qosUpdateWMMParametersAndAssignAllowedACI(prAdapter, &prBssInfo->rWmmInfo);
	} else {

#if CFG_TX_AGGREGATE_HW_FIFO
		nicTxAggregateTXQ(prAdapter, TRUE);
#endif				/* CFG_TX_AGGREGATE_HW_FIFO */

		nicTxNonQoSAssignDefaultAdmittedTXQ(prAdapter);

		nicTxNonQoSUpdateTXQParameters(prAdapter, prBssInfo->ePhyType);
	}

#if CFG_TX_STOP_WRITE_TX_FIFO_UNTIL_JOIN
	{
		prTxCtrl->fgBlockTxDuringJoin = FALSE;

#if !CFG_TX_AGGREGATE_HW_FIFO	/* TX FIFO AGGREGATE already do flush once */
		nicTxFlushStopQueues(prAdapter, (UINT_8) TXQ_DATA_MASK, (UINT_8) NULL);
#endif				/* CFG_TX_AGGREGATE_HW_FIFO */

		nicTxRetransmitOfSendWaitQue(prAdapter);

		if (prTxCtrl->fgIsPacketInOsSendQueue)
			nicTxRetransmitOfOsSendQue(prAdapter);

#if CFG_SDIO_TX_ENHANCE
		halTxLeftClusteredMpdu(prAdapter);
#endif				/* CFG_SDIO_TX_ENHANCE */

	}
#endif				/* CFG_TX_STOP_WRITE_TX_FIFO_UNTIL_JOIN */


/* 4 <6> Setup CONNECTION flag. */
	prAdapter->eConnectionState = MEDIA_STATE_CONNECTED;
	prAdapter->eConnectionStateIndicated = MEDIA_STATE_CONNECTED;

	if (prJoinInfo->fgIsReAssoc)
		prAdapter->fgBypassPortCtrlForRoaming = TRUE;
	else
		prAdapter->fgBypassPortCtrlForRoaming = FALSE;

	kalIndicateStatusAndComplete(prAdapter->prGlueInfo,
				     WLAN_STATUS_MEDIA_CONNECT, (PVOID) NULL, 0);

	return;
}				/* end of joinComplete() */
static void wlanP2PEarlySuspend(void)
{
	struct net_device *prDev = NULL;
	P_GLUE_INFO_T prGlueInfo = NULL;
	UINT_8 ip[4] = { 0 };
	UINT_32 u4NumIPv4 = 0;
#ifdef CONFIG_IPV6
	UINT_8 ip6[16] = { 0 };	/* FIX ME: avoid to allocate large memory in stack */
	UINT_32 u4NumIPv6 = 0;
#endif
	UINT_32 i;
	P_PARAM_NETWORK_ADDRESS_IP prParamIpAddr;

	printk(KERN_INFO "*********p2pEarlySuspend************\n");

	if (!wlanExportGlueInfo(&prGlueInfo)) {
		printk(KERN_INFO "*********p2pEarlySuspend ignored************\n");
		return;
	}

	ASSERT(prGlueInfo);
	/* <1> Sanity check and acquire the net_device */
	prDev = prGlueInfo->prP2PInfo->prDevHandler;
	ASSERT(prDev);

	/* <3> get the IPv4 address */
	if (!prDev || !(prDev->ip_ptr) ||
	    !((struct in_device *)(prDev->ip_ptr))->ifa_list ||
	    !(&(((struct in_device *)(prDev->ip_ptr))->ifa_list->ifa_local))) {
		printk(KERN_INFO "ip is not avaliable.\n");
		return;
	}
	/* <4> copy the IPv4 address */
	kalMemCopy(ip, &(((struct in_device *)(prDev->ip_ptr))->ifa_list->ifa_local), sizeof(ip));
	printk(KERN_INFO "ip is %d.%d.%d.%d\n", ip[0], ip[1], ip[2], ip[3]);

	/* todo: traverse between list to find whole sets of IPv4 addresses */
	if (!((ip[0] == 0) && (ip[1] == 0) && (ip[2] == 0) && (ip[3] == 0))) {
		u4NumIPv4++;
	}
#ifdef CONFIG_IPV6
	/* <5> get the IPv6 address */
	if (!prDev || !(prDev->ip6_ptr) ||
	    !((struct in_device *)(prDev->ip6_ptr))->ifa_list ||
	    !(&(((struct in_device *)(prDev->ip6_ptr))->ifa_list->ifa_local))) {
		printk(KERN_INFO "ipv6 is not avaliable.\n");
		return;
	}
	/* <6> copy the IPv6 address */
	kalMemCopy(ip6, &(((struct in_device *)(prDev->ip6_ptr))->ifa_list->ifa_local),
		   sizeof(ip6));
	printk(KERN_INFO "ipv6 is %d.%d.%d.%d.%d.%d.%d.%d.%d.%d.%d.%d.%d.%d.%d.%d\n", ip6[0],
	       ip6[1], ip6[2], ip6[3], ip6[4], ip6[5], ip6[6], ip6[7], ip6[8], ip6[9], ip6[10],
	       ip6[11], ip6[12], ip6[13], ip6[14], ip6[15]
	    );
	/* todo: traverse between list to find whole sets of IPv6 addresses */

	if (!((ip6[0] == 0) &&
	      (ip6[1] == 0) && (ip6[2] == 0) && (ip6[3] == 0) && (ip6[4] == 0) && (ip6[5] == 0))) {
	}
#endif
	/* <7> set up the ARP filter */
	{
		WLAN_STATUS rStatus = WLAN_STATUS_FAILURE;
		UINT_32 u4SetInfoLen = 0;
/* UINT_8 aucBuf[32] = {0}; */
		UINT_32 u4Len = OFFSET_OF(PARAM_NETWORK_ADDRESS_LIST, arAddress);
		P_PARAM_NETWORK_ADDRESS_LIST prParamNetAddrList = (P_PARAM_NETWORK_ADDRESS_LIST) g_aucBufIpAddr;	/* aucBuf; */
		P_PARAM_NETWORK_ADDRESS prParamNetAddr = prParamNetAddrList->arAddress;

		kalMemZero(g_aucBufIpAddr, sizeof(g_aucBufIpAddr));

		prParamNetAddrList->u4AddressCount = u4NumIPv4 + u4NumIPv6;
		prParamNetAddrList->u2AddressType = PARAM_PROTOCOL_ID_TCP_IP;
		for (i = 0; i < u4NumIPv4; i++) {
			prParamNetAddr->u2AddressLength = sizeof(PARAM_NETWORK_ADDRESS_IP);	/* 4;; */
			prParamNetAddr->u2AddressType = PARAM_PROTOCOL_ID_TCP_IP;
#if 0
			kalMemCopy(prParamNetAddr->aucAddress, ip, sizeof(ip));
			prParamNetAddr =
			    (P_PARAM_NETWORK_ADDRESS) ((UINT_32) prParamNetAddr + sizeof(ip));
			u4Len += OFFSET_OF(PARAM_NETWORK_ADDRESS, aucAddress) + sizeof(ip);
#else
			prParamIpAddr = (P_PARAM_NETWORK_ADDRESS_IP) prParamNetAddr->aucAddress;
			kalMemCopy(&prParamIpAddr->in_addr, ip, sizeof(ip));

/* prParamNetAddr = (P_PARAM_NETWORK_ADDRESS)((UINT_32)prParamNetAddr + sizeof(PARAM_NETWORK_ADDRESS));    // TODO: frog. The pointer is not right. */

			prParamNetAddr = (P_PARAM_NETWORK_ADDRESS) ((UINT_32) prParamNetAddr +
								    (UINT_32) (prParamNetAddr->
									       u2AddressLength +
									       OFFSET_OF
									       (PARAM_NETWORK_ADDRESS,
										aucAddress)));

			u4Len +=
			    OFFSET_OF(PARAM_NETWORK_ADDRESS,
				      aucAddress) + sizeof(PARAM_NETWORK_ADDRESS_IP);
#endif
		}
#ifdef CONFIG_IPV6
		for (i = 0; i < u4NumIPv6; i++) {
			prParamNetAddr->u2AddressLength = 6;
			prParamNetAddr->u2AddressType = PARAM_PROTOCOL_ID_TCP_IP;
			kalMemCopy(prParamNetAddr->aucAddress, ip6, sizeof(ip6));
/* prParamNetAddr = (P_PARAM_NETWORK_ADDRESS)((UINT_32)prParamNetAddr + sizeof(ip6)); */

			prParamNetAddr = (P_PARAM_NETWORK_ADDRESS) ((UINT_32) prParamNetAddr +
								    (UINT_32) (prParamNetAddr->
									       u2AddressLength +
									       OFFSET_OF
									       (PARAM_NETWORK_ADDRESS,
										aucAddress)));

			u4Len += OFFSET_OF(PARAM_NETWORK_ADDRESS, aucAddress) + sizeof(ip6);
		}
#endif
		ASSERT(u4Len <= sizeof(g_aucBufIpAddr /*aucBuf */));

		rStatus = kalIoctl(prGlueInfo,
				   wlanoidSetP2pSetNetworkAddress,
				   (PVOID) prParamNetAddrList,
				   u4Len, FALSE, FALSE, TRUE, TRUE, &u4SetInfoLen);

		if (rStatus != WLAN_STATUS_SUCCESS) {
			printk(KERN_INFO DRV_NAME "set HW pattern filter fail 0x%lx\n", rStatus);
		}
	}
}
static void wlanP2PLateResume(void)
{
	struct net_device *prDev = NULL;
	P_GLUE_INFO_T prGlueInfo = NULL;
	UINT_8 ip[4] = { 0 };
#ifdef CONFIG_IPV6
	UINT_8 ip6[16] = { 0 };	/* FIX ME: avoid to allocate large memory in stack */
#endif

	printk(KERN_INFO "*********wlanP2PLateResume************\n");
	if (!wlanExportGlueInfo(&prGlueInfo)) {
		printk(KERN_INFO "*********p2pLateResume ignored************\n");
		return;
	}

	ASSERT(prGlueInfo);
	/* <1> Sanity check and acquire the net_device */
	prDev = prGlueInfo->prP2PInfo->prDevHandler;
	ASSERT(prDev);

	/* <3> get the IPv4 address */
	if (!prDev || !(prDev->ip_ptr) ||
	    !((struct in_device *)(prDev->ip_ptr))->ifa_list ||
	    !(&(((struct in_device *)(prDev->ip_ptr))->ifa_list->ifa_local))) {
		printk(KERN_INFO "ip is not avaliable.\n");
		return;
	}
	/* <4> copy the IPv4 address */
	kalMemCopy(ip, &(((struct in_device *)(prDev->ip_ptr))->ifa_list->ifa_local), sizeof(ip));
	printk(KERN_INFO "ip is %d.%d.%d.%d\n", ip[0], ip[1], ip[2], ip[3]);

#ifdef CONFIG_IPV6
	/* <5> get the IPv6 address */
	if (!prDev || !(prDev->ip6_ptr) ||
	    !((struct in_device *)(prDev->ip6_ptr))->ifa_list ||
	    !(&(((struct in_device *)(prDev->ip6_ptr))->ifa_list->ifa_local))) {
		printk(KERN_INFO "ipv6 is not avaliable.\n");
		return;
	}
	/* <6> copy the IPv6 address */
	kalMemCopy(ip6, &(((struct in_device *)(prDev->ip6_ptr))->ifa_list->ifa_local),
		   sizeof(ip6));
	printk(KERN_INFO "ipv6 is %d.%d.%d.%d.%d.%d.%d.%d.%d.%d.%d.%d.%d.%d.%d.%d\n", ip6[0],
	       ip6[1], ip6[2], ip6[3], ip6[4], ip6[5], ip6[6], ip6[7], ip6[8], ip6[9], ip6[10],
	       ip6[11], ip6[12], ip6[13], ip6[14], ip6[15]
	    );
#endif
	/* <7> clear the ARP filter */
	{
		WLAN_STATUS rStatus = WLAN_STATUS_FAILURE;
		UINT_32 u4SetInfoLen = 0;
/* UINT_8 aucBuf[32] = {0}; */
		UINT_32 u4Len = sizeof(PARAM_NETWORK_ADDRESS_LIST);
		P_PARAM_NETWORK_ADDRESS_LIST prParamNetAddrList = (P_PARAM_NETWORK_ADDRESS_LIST) g_aucBufIpAddr;	/* aucBuf; */

		kalMemZero(g_aucBufIpAddr, sizeof(g_aucBufIpAddr));

		prParamNetAddrList->u4AddressCount = 0;
		prParamNetAddrList->u2AddressType = PARAM_PROTOCOL_ID_TCP_IP;

		ASSERT(u4Len <= sizeof(g_aucBufIpAddr /*aucBuf */));
		rStatus = kalIoctl(prGlueInfo,
				   wlanoidSetP2pSetNetworkAddress,
				   (PVOID) prParamNetAddrList,
				   u4Len, FALSE, FALSE, TRUE, TRUE, &u4SetInfoLen);

		if (rStatus != WLAN_STATUS_SUCCESS) {
			printk(KERN_INFO DRV_NAME "set HW pattern filter fail 0x%lx\n", rStatus);
		}
	}
}
Exemplo n.º 15
0
/*----------------------------------------------------------------------------*/
VOID
rlmFuncCommonChannelList(IN P_ADAPTER_T prAdapter,
			 IN P_CHANNEL_ENTRY_FIELD_T prChannelEntryII, IN UINT_8 ucChannelListSize)
{
	P_P2P_CONNECTION_SETTINGS_T prP2pConnSetting = (P_P2P_CONNECTION_SETTINGS_T) NULL;
	P_CHANNEL_ENTRY_FIELD_T prChannelEntryI =
	    (P_CHANNEL_ENTRY_FIELD_T) NULL, prChannelEntryIII = (P_CHANNEL_ENTRY_FIELD_T) NULL;
	UINT_8 aucCommonChannelList[P2P_MAX_SUPPORTED_CHANNEL_LIST_SIZE];
	UINT_8 ucOriChnlSize = 0, ucNewChnlSize = 0;


	do {

		ASSERT_BREAK(prAdapter != NULL);

		prP2pConnSetting = prAdapter->rWifiVar.prP2PConnSettings;

		prChannelEntryIII = (P_CHANNEL_ENTRY_FIELD_T) aucCommonChannelList;

		while (ucChannelListSize > 0) {

			prChannelEntryI =
			    (P_CHANNEL_ENTRY_FIELD_T) prP2pConnSetting->aucChannelEntriesField;
			ucOriChnlSize = prP2pConnSetting->ucRfChannelListSize;

			while (ucOriChnlSize > 0) {
				if (prChannelEntryI->ucRegulatoryClass ==
				    prChannelEntryII->ucRegulatoryClass) {
					prChannelEntryIII->ucRegulatoryClass =
					    prChannelEntryI->ucRegulatoryClass;
					/* TODO: Currently we assume that the regulatory class the same, the channels are the same. */
					kalMemCopy(prChannelEntryIII->aucChannelList,
						   prChannelEntryII->aucChannelList,
						   prChannelEntryII->ucNumberOfChannels);
					prChannelEntryIII->ucNumberOfChannels =
					    prChannelEntryII->ucNumberOfChannels;

					ucNewChnlSize +=
					    P2P_ATTRI_LEN_CHANNEL_ENTRY +
					    prChannelEntryIII->ucNumberOfChannels;

					prChannelEntryIII =
					    (P_CHANNEL_ENTRY_FIELD_T) ((ULONG) prChannelEntryIII +
								       P2P_ATTRI_LEN_CHANNEL_ENTRY +
								       (ULONG) prChannelEntryIII->
								       ucNumberOfChannels);
				}

				ucOriChnlSize -=
				    (P2P_ATTRI_LEN_CHANNEL_ENTRY +
				     prChannelEntryI->ucNumberOfChannels);

				prChannelEntryI =
				    (P_CHANNEL_ENTRY_FIELD_T) ((ULONG) prChannelEntryI +
							       P2P_ATTRI_LEN_CHANNEL_ENTRY +
							       (ULONG) prChannelEntryI->
							       ucNumberOfChannels);


			}


			ucChannelListSize -=
			    (P2P_ATTRI_LEN_CHANNEL_ENTRY + prChannelEntryII->ucNumberOfChannels);

			prChannelEntryII = (P_CHANNEL_ENTRY_FIELD_T) ((ULONG) prChannelEntryII +
								      P2P_ATTRI_LEN_CHANNEL_ENTRY +
								      (ULONG) prChannelEntryII->
								      ucNumberOfChannels);


		}


		kalMemCopy(prP2pConnSetting->aucChannelEntriesField, aucCommonChannelList,
			   ucNewChnlSize);
		prP2pConnSetting->ucRfChannelListSize = ucNewChnlSize;

	} while (FALSE);

	return;
}				/* rlmFuncCommonChannelList */