/* ************************************************************************* * Ralink Tech Inc. * 5F., No.36, Taiyuan St., Jhubei City, * Hsinchu County 302, * Taiwan, R.O.C. * * (c) Copyright 2002-2007, Ralink Technology, Inc. * * This program is free software; you can redistribute it and/or modify * * it under the terms of the GNU General Public License as published by * * the Free Software Foundation; either version 2 of the License, or * * (at your option) any later version. * * * * This program is distributed in the hope that it will be useful, * * but WITHOUT ANY WARRANTY; without even the implied warranty of * * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * * GNU General Public License for more details. * * * * You should have received a copy of the GNU General Public License * * along with this program; if not, write to the * * Free Software Foundation, Inc., * * 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. * * * ************************************************************************* */ #include #include "rt_config.h" ULONG RTDebugLevel = RT_DEBUG_ERROR; // for wireless system event message char const *pWirelessSysEventText[IW_SYS_EVENT_TYPE_NUM] = { // system status event "had associated successfully", /* IW_ASSOC_EVENT_FLAG */ "had disassociated", /* IW_DISASSOC_EVENT_FLAG */ "had deauthenticated", /* IW_DEAUTH_EVENT_FLAG */ "had been aged-out and disassociated", /* IW_AGEOUT_EVENT_FLAG */ "occurred CounterMeasures attack", /* IW_COUNTER_MEASURES_EVENT_FLAG */ "occurred replay counter different in Key Handshaking", /* IW_REPLAY_COUNTER_DIFF_EVENT_FLAG */ "occurred RSNIE different in Key Handshaking", /* IW_RSNIE_DIFF_EVENT_FLAG */ "occurred MIC different in Key Handshaking", /* IW_MIC_DIFF_EVENT_FLAG */ "occurred ICV error in RX", /* IW_ICV_ERROR_EVENT_FLAG */ "occurred MIC error in RX", /* IW_MIC_ERROR_EVENT_FLAG */ "Group Key Handshaking timeout", /* IW_GROUP_HS_TIMEOUT_EVENT_FLAG */ "Pairwise Key Handshaking timeout", /* IW_PAIRWISE_HS_TIMEOUT_EVENT_FLAG */ "RSN IE sanity check failure", /* IW_RSNIE_SANITY_FAIL_EVENT_FLAG */ "set key done in WPA/WPAPSK", /* IW_SET_KEY_DONE_WPA1_EVENT_FLAG */ "set key done in WPA2/WPA2PSK", /* IW_SET_KEY_DONE_WPA2_EVENT_FLAG */ "connects with our wireless client", /* IW_STA_LINKUP_EVENT_FLAG */ "disconnects with our wireless client", /* IW_STA_LINKDOWN_EVENT_FLAG */ "scan completed" /* IW_SCAN_COMPLETED_EVENT_FLAG */ "scan terminate!! Busy!! Enqueue fail!!" /* IW_SCAN_ENQUEUE_FAIL_EVENT_FLAG */ }; // for wireless IDS_spoof_attack event message char const *pWirelessSpoofEventText[IW_SPOOF_EVENT_TYPE_NUM] = { "detected conflict SSID", /* IW_CONFLICT_SSID_EVENT_FLAG */ "detected spoofed association response", /* IW_SPOOF_ASSOC_RESP_EVENT_FLAG */ "detected spoofed reassociation responses", /* IW_SPOOF_REASSOC_RESP_EVENT_FLAG */ "detected spoofed probe response", /* IW_SPOOF_PROBE_RESP_EVENT_FLAG */ "detected spoofed beacon", /* IW_SPOOF_BEACON_EVENT_FLAG */ "detected spoofed disassociation", /* IW_SPOOF_DISASSOC_EVENT_FLAG */ "detected spoofed authentication", /* IW_SPOOF_AUTH_EVENT_FLAG */ "detected spoofed deauthentication", /* IW_SPOOF_DEAUTH_EVENT_FLAG */ "detected spoofed unknown management frame", /* IW_SPOOF_UNKNOWN_MGMT_EVENT_FLAG */ "detected replay attack" /* IW_REPLAY_ATTACK_EVENT_FLAG */ }; // for wireless IDS_flooding_attack event message char const *pWirelessFloodEventText[IW_FLOOD_EVENT_TYPE_NUM] = { "detected authentication flooding", /* IW_FLOOD_AUTH_EVENT_FLAG */ "detected association request flooding", /* IW_FLOOD_ASSOC_REQ_EVENT_FLAG */ "detected reassociation request flooding", /* IW_FLOOD_REASSOC_REQ_EVENT_FLAG */ "detected probe request flooding", /* IW_FLOOD_PROBE_REQ_EVENT_FLAG */ "detected disassociation flooding", /* IW_FLOOD_DISASSOC_EVENT_FLAG */ "detected deauthentication flooding", /* IW_FLOOD_DEAUTH_EVENT_FLAG */ "detected 802.1x eap-request flooding" /* IW_FLOOD_EAP_REQ_EVENT_FLAG */ }; /* timeout -- ms */ VOID RTMP_SetPeriodicTimer( IN NDIS_MINIPORT_TIMER *pTimer, IN unsigned long timeout) { timeout = ((timeout*OS_HZ) / 1000); pTimer->expires = jiffies + timeout; add_timer(pTimer); } /* convert NdisMInitializeTimer --> RTMP_OS_Init_Timer */ VOID RTMP_OS_Init_Timer( IN PRTMP_ADAPTER pAd, IN NDIS_MINIPORT_TIMER *pTimer, IN TIMER_FUNCTION function, IN PVOID data) { init_timer(pTimer); pTimer->data = (unsigned long)data; pTimer->function = function; } VOID RTMP_OS_Add_Timer( IN NDIS_MINIPORT_TIMER *pTimer, IN unsigned long timeout) { if (timer_pending(pTimer)) return; timeout = ((timeout*OS_HZ) / 1000); pTimer->expires = jiffies + timeout; add_timer(pTimer); } VOID RTMP_OS_Mod_Timer( IN NDIS_MINIPORT_TIMER *pTimer, IN unsigned long timeout) { timeout = ((timeout*OS_HZ) / 1000); mod_timer(pTimer, jiffies + timeout); } VOID RTMP_OS_Del_Timer( IN NDIS_MINIPORT_TIMER *pTimer, OUT BOOLEAN *pCancelled) { if (timer_pending(pTimer)) { *pCancelled = del_timer_sync(pTimer); } else { *pCancelled = TRUE; } } VOID RTMP_OS_Release_Packet( IN PRTMP_ADAPTER pAd, IN PQUEUE_ENTRY pEntry) { //RTMPFreeNdisPacket(pAd, (struct sk_buff *)pEntry); } // Unify all delay routine by using udelay VOID RTMPusecDelay( IN ULONG usec) { ULONG i; for (i = 0; i < (usec / 50); i++) udelay(50); if (usec % 50) udelay(usec % 50); } void RTMP_GetCurrentSystemTime(LARGE_INTEGER *time) { time->u.LowPart = jiffies; } // pAd MUST allow to be NULL NDIS_STATUS os_alloc_mem( IN RTMP_ADAPTER *pAd, OUT UCHAR **mem, IN ULONG size) { *mem = (PUCHAR) kmalloc(size, GFP_ATOMIC); if (*mem) return (NDIS_STATUS_SUCCESS); else return (NDIS_STATUS_FAILURE); } // pAd MUST allow to be NULL NDIS_STATUS os_free_mem( IN PRTMP_ADAPTER pAd, IN PVOID mem) { ASSERT(mem); kfree(mem); return (NDIS_STATUS_SUCCESS); } PNDIS_PACKET RtmpOSNetPktAlloc( IN RTMP_ADAPTER *pAd, IN int size) { struct sk_buff *skb; /* Add 2 more bytes for ip header alignment*/ skb = dev_alloc_skb(size+2); return ((PNDIS_PACKET)skb); } PNDIS_PACKET RTMP_AllocateFragPacketBuffer( IN PRTMP_ADAPTER pAd, IN ULONG Length) { struct sk_buff *pkt; pkt = dev_alloc_skb(Length); if (pkt == NULL) { DBGPRINT(RT_DEBUG_ERROR, ("can't allocate frag rx %ld size packet\n",Length)); } if (pkt) { RTMP_SET_PACKET_SOURCE(OSPKT_TO_RTPKT(pkt), PKTSRC_NDIS); } return (PNDIS_PACKET) pkt; } PNDIS_PACKET RTMP_AllocateTxPacketBuffer( IN PRTMP_ADAPTER pAd, IN ULONG Length, IN BOOLEAN Cached, OUT PVOID *VirtualAddress) { struct sk_buff *pkt; pkt = dev_alloc_skb(Length); if (pkt == NULL) { DBGPRINT(RT_DEBUG_ERROR, ("can't allocate tx %ld size packet\n",Length)); } if (pkt) { RTMP_SET_PACKET_SOURCE(OSPKT_TO_RTPKT(pkt), PKTSRC_NDIS); *VirtualAddress = (PVOID) pkt->data; } else { *VirtualAddress = (PVOID) NULL; } return (PNDIS_PACKET) pkt; } VOID build_tx_packet( IN PRTMP_ADAPTER pAd, IN PNDIS_PACKET pPacket, IN PUCHAR pFrame, IN ULONG FrameLen) { struct sk_buff *pTxPkt; ASSERT(pPacket); pTxPkt = RTPKT_TO_OSPKT(pPacket); NdisMoveMemory(skb_put(pTxPkt, FrameLen), pFrame, FrameLen); } VOID RTMPFreeAdapter( IN PRTMP_ADAPTER pAd) { POS_COOKIE os_cookie; int index; os_cookie=(POS_COOKIE)pAd->OS_Cookie; if (pAd->BeaconBuf) kfree(pAd->BeaconBuf); NdisFreeSpinLock(&pAd->MgmtRingLock); #ifdef RTMP_MAC_PCI NdisFreeSpinLock(&pAd->RxRingLock); #ifdef RT3090 NdisFreeSpinLock(&pAd->McuCmdLock); #endif // RT3090 // #endif // RTMP_MAC_PCI // for (index =0 ; index < NUM_OF_TX_RING; index++) { NdisFreeSpinLock(&pAd->TxSwQueueLock[index]); NdisFreeSpinLock(&pAd->DeQueueLock[index]); pAd->DeQueueRunning[index] = FALSE; } NdisFreeSpinLock(&pAd->irq_lock); vfree(pAd); // pci_free_consistent(os_cookie->pci_dev,sizeof(RTMP_ADAPTER),pAd,os_cookie->pAd_pa); if (os_cookie) kfree(os_cookie); } BOOLEAN OS_Need_Clone_Packet(void) { return (FALSE); } /* ======================================================================== Routine Description: clone an input NDIS PACKET to another one. The new internally created NDIS PACKET must have only one NDIS BUFFER return - byte copied. 0 means can't create NDIS PACKET NOTE: internally created NDIS_PACKET should be destroyed by RTMPFreeNdisPacket Arguments: pAd Pointer to our adapter pInsAMSDUHdr EWC A-MSDU format has extra 14-bytes header. if TRUE, insert this 14-byte hdr in front of MSDU. *pSrcTotalLen return total packet length. This lenght is calculated with 802.3 format packet. Return Value: NDIS_STATUS_SUCCESS NDIS_STATUS_FAILURE Note: ======================================================================== */ NDIS_STATUS RTMPCloneNdisPacket( IN PRTMP_ADAPTER pAd, IN BOOLEAN pInsAMSDUHdr, IN PNDIS_PACKET pInPacket, OUT PNDIS_PACKET *ppOutPacket) { struct sk_buff *pkt; ASSERT(pInPacket); ASSERT(ppOutPacket); // 1. Allocate a packet pkt = dev_alloc_skb(2048); if (pkt == NULL) { return NDIS_STATUS_FAILURE; } skb_put(pkt, GET_OS_PKT_LEN(pInPacket)); NdisMoveMemory(pkt->data, GET_OS_PKT_DATAPTR(pInPacket), GET_OS_PKT_LEN(pInPacket)); *ppOutPacket = OSPKT_TO_RTPKT(pkt); RTMP_SET_PACKET_SOURCE(OSPKT_TO_RTPKT(pkt), PKTSRC_NDIS); printk("###Clone###\n"); return NDIS_STATUS_SUCCESS; } // the allocated NDIS PACKET must be freed via RTMPFreeNdisPacket() NDIS_STATUS RTMPAllocateNdisPacket( IN PRTMP_ADAPTER pAd, OUT PNDIS_PACKET *ppPacket, IN PUCHAR pHeader, IN UINT HeaderLen, IN PUCHAR pData, IN UINT DataLen) { PNDIS_PACKET pPacket; ASSERT(pData); ASSERT(DataLen); // 1. Allocate a packet pPacket = (PNDIS_PACKET *) dev_alloc_skb(HeaderLen + DataLen + RTMP_PKT_TAIL_PADDING); if (pPacket == NULL) { *ppPacket = NULL; #ifdef DEBUG printk("RTMPAllocateNdisPacket Fail\n\n"); #endif return NDIS_STATUS_FAILURE; } // 2. clone the frame content if (HeaderLen > 0) NdisMoveMemory(GET_OS_PKT_DATAPTR(pPacket), pHeader, HeaderLen); if (DataLen > 0) NdisMoveMemory(GET_OS_PKT_DATAPTR(pPacket) + HeaderLen, pData, DataLen); // 3. update length of packet skb_put(GET_OS_PKT_TYPE(pPacket), HeaderLen+DataLen); RTMP_SET_PACKET_SOURCE(pPacket, PKTSRC_NDIS); // printk("%s : pPacket = %p, len = %d\n", __FUNCTION__, pPacket, GET_OS_PKT_LEN(pPacket)); *ppPacket = pPacket; return NDIS_STATUS_SUCCESS; } /* ======================================================================== Description: This routine frees a miniport internally allocated NDIS_PACKET and its corresponding NDIS_BUFFER and allocated memory. ======================================================================== */ VOID RTMPFreeNdisPacket( IN PRTMP_ADAPTER pAd, IN PNDIS_PACKET pPacket) { dev_kfree_skb_any(RTPKT_TO_OSPKT(pPacket)); } // IRQL = DISPATCH_LEVEL // NOTE: we do have an assumption here, that Byte0 and Byte1 always reasid at the same // scatter gather buffer NDIS_STATUS Sniff2BytesFromNdisBuffer( IN PNDIS_BUFFER pFirstBuffer, IN UCHAR DesiredOffset, OUT PUCHAR pByte0, OUT PUCHAR pByte1) { *pByte0 = *(PUCHAR)(pFirstBuffer + DesiredOffset); *pByte1 = *(PUCHAR)(pFirstBuffer + DesiredOffset + 1); return NDIS_STATUS_SUCCESS; } void RTMP_QueryPacketInfo( IN PNDIS_PACKET pPacket, OUT PACKET_INFO *pPacketInfo, OUT PUCHAR *pSrcBufVA, OUT UINT *pSrcBufLen) { pPacketInfo->BufferCount = 1; pPacketInfo->pFirstBuffer = (PNDIS_BUFFER)GET_OS_PKT_DATAPTR(pPacket); pPacketInfo->PhysicalBufferCount = 1; pPacketInfo->TotalPacketLength = GET_OS_PKT_LEN(pPacket); *pSrcBufVA = GET_OS_PKT_DATAPTR(pPacket); *pSrcBufLen = GET_OS_PKT_LEN(pPacket); } void RTMP_QueryNextPacketInfo( IN PNDIS_PACKET *ppPacket, OUT PACKET_INFO *pPacketInfo, OUT PUCHAR *pSrcBufVA, OUT UINT *pSrcBufLen) { PNDIS_PACKET pPacket = NULL; if (*ppPacket) pPacket = GET_OS_PKT_NEXT(*ppPacket); if (pPacket) { pPacketInfo->BufferCount = 1; pPacketInfo->pFirstBuffer = (PNDIS_BUFFER)GET_OS_PKT_DATAPTR(pPacket); pPacketInfo->PhysicalBufferCount = 1; pPacketInfo->TotalPacketLength = GET_OS_PKT_LEN(pPacket); *pSrcBufVA = GET_OS_PKT_DATAPTR(pPacket); *pSrcBufLen = GET_OS_PKT_LEN(pPacket); *ppPacket = GET_OS_PKT_NEXT(pPacket); } else { pPacketInfo->BufferCount = 0; pPacketInfo->pFirstBuffer = NULL; pPacketInfo->PhysicalBufferCount = 0; pPacketInfo->TotalPacketLength = 0; *pSrcBufVA = NULL; *pSrcBufLen = 0; *ppPacket = NULL; } } PNDIS_PACKET DuplicatePacket( IN PRTMP_ADAPTER pAd, IN PNDIS_PACKET pPacket, IN UCHAR FromWhichBSSID) { struct sk_buff *skb; PNDIS_PACKET pRetPacket = NULL; USHORT DataSize; UCHAR *pData; DataSize = (USHORT) GET_OS_PKT_LEN(pPacket); pData = (PUCHAR) GET_OS_PKT_DATAPTR(pPacket); skb = skb_clone(RTPKT_TO_OSPKT(pPacket), MEM_ALLOC_FLAG); if (skb) { skb->dev = get_netdev_from_bssid(pAd, FromWhichBSSID); pRetPacket = OSPKT_TO_RTPKT(skb); } return pRetPacket; } PNDIS_PACKET duplicate_pkt( IN PRTMP_ADAPTER pAd, IN PUCHAR pHeader802_3, IN UINT HdrLen, IN PUCHAR pData, IN ULONG DataSize, IN UCHAR FromWhichBSSID) { struct sk_buff *skb; PNDIS_PACKET pPacket = NULL; if ((skb = __dev_alloc_skb(HdrLen + DataSize + 2, MEM_ALLOC_FLAG)) != NULL) { skb_reserve(skb, 2); NdisMoveMemory(skb_tail_pointer(skb), pHeader802_3, HdrLen); skb_put(skb, HdrLen); NdisMoveMemory(skb_tail_pointer(skb), pData, DataSize); skb_put(skb, DataSize); skb->dev = get_netdev_from_bssid(pAd, FromWhichBSSID); pPacket = OSPKT_TO_RTPKT(skb); } return pPacket; } #define TKIP_TX_MIC_SIZE 8 PNDIS_PACKET duplicate_pkt_with_TKIP_MIC( IN PRTMP_ADAPTER pAd, IN PNDIS_PACKET pPacket) { struct sk_buff *skb, *newskb; skb = RTPKT_TO_OSPKT(pPacket); if (skb_tailroom(skb) < TKIP_TX_MIC_SIZE) { // alloc a new skb and copy the packet newskb = skb_copy_expand(skb, skb_headroom(skb), TKIP_TX_MIC_SIZE, GFP_ATOMIC); dev_kfree_skb_any(skb); if (newskb == NULL) { DBGPRINT(RT_DEBUG_ERROR, ("Extend Tx.MIC for packet failed!, dropping packet!\n")); return NULL; } skb = newskb; } return OSPKT_TO_RTPKT(skb); } PNDIS_PACKET ClonePacket( IN PRTMP_ADAPTER pAd, IN PNDIS_PACKET pPacket, IN PUCHAR pData, IN ULONG DataSize) { struct sk_buff *pRxPkt; struct sk_buff *pClonedPkt; ASSERT(pPacket); pRxPkt = RTPKT_TO_OSPKT(pPacket); // clone the packet pClonedPkt = skb_clone(pRxPkt, MEM_ALLOC_FLAG); if (pClonedPkt) { // set the correct dataptr and data len pClonedPkt->dev = pRxPkt->dev; pClonedPkt->data = pData; pClonedPkt->len = DataSize; pClonedPkt->tail = pClonedPkt->data + pClonedPkt->len; ASSERT(DataSize < 1530); } return pClonedPkt; } // // change OS packet DataPtr and DataLen // void update_os_packet_info( IN PRTMP_ADAPTER pAd, IN RX_BLK *pRxBlk, IN UCHAR FromWhichBSSID) { struct sk_buff *pOSPkt; ASSERT(pRxBlk->pRxPacket); pOSPkt = RTPKT_TO_OSPKT(pRxBlk->pRxPacket); pOSPkt->dev = get_netdev_from_bssid(pAd, FromWhichBSSID); pOSPkt->data = pRxBlk->pData; pOSPkt->len = pRxBlk->DataSize; pOSPkt->tail = pOSPkt->data + pOSPkt->len; } void wlan_802_11_to_802_3_packet( IN PRTMP_ADAPTER pAd, IN RX_BLK *pRxBlk, IN PUCHAR pHeader802_3, IN UCHAR FromWhichBSSID) { struct sk_buff *pOSPkt; ASSERT(pRxBlk->pRxPacket); ASSERT(pHeader802_3); pOSPkt = RTPKT_TO_OSPKT(pRxBlk->pRxPacket); pOSPkt->dev = get_netdev_from_bssid(pAd, FromWhichBSSID); pOSPkt->data = pRxBlk->pData; pOSPkt->len = pRxBlk->DataSize; pOSPkt->tail = pOSPkt->data + pOSPkt->len; // // copy 802.3 header // // #ifdef CONFIG_STA_SUPPORT IF_DEV_CONFIG_OPMODE_ON_STA(pAd) NdisMoveMemory(skb_push(pOSPkt, LENGTH_802_3), pHeader802_3, LENGTH_802_3); #endif // CONFIG_STA_SUPPORT // } void announce_802_3_packet( IN PRTMP_ADAPTER pAd, IN PNDIS_PACKET pPacket) { struct sk_buff *pRxPkt; #ifdef INF_AMAZON_PPA int ret = 0; unsigned int ppa_flags = 0; /* reserved for now */ #endif // INF_AMAZON_PPA // ASSERT(pPacket); pRxPkt = RTPKT_TO_OSPKT(pPacket); #ifdef CONFIG_STA_SUPPORT #endif // CONFIG_STA_SUPPORT // /* Push up the protocol stack */ #ifdef IKANOS_VX_1X0 IKANOS_DataFrameRx(pAd, pRxPkt->dev, pRxPkt, pRxPkt->len); #else #ifdef INF_AMAZON_SE #ifdef BG_FT_SUPPORT BG_FTPH_PacketFromApHandle(pRxPkt); return; #endif // BG_FT_SUPPORT // #endif // INF_AMAZON_SE // pRxPkt->protocol = eth_type_trans(pRxPkt, pRxPkt->dev); #ifdef INF_AMAZON_PPA if (ppa_hook_directpath_send_fn && pAd->PPAEnable==TRUE ) { memset(pRxPkt->head,0,pRxPkt->data-pRxPkt->head-14); DBGPRINT(RT_DEBUG_TRACE, ("ppa_hook_directpath_send_fn rx :ret:%d headroom:%d dev:%s pktlen:%d<===\n",ret,skb_headroom(pRxPkt) ,pRxPkt->dev->name,pRxPkt->len)); hex_dump("rx packet", pRxPkt->data, 32); ret = ppa_hook_directpath_send_fn(pAd->g_if_id, pRxPkt, pRxPkt->len, ppa_flags); pRxPkt=NULL; return; } #endif // INF_AMAZON_PPA // //#ifdef CONFIG_5VT_ENHANCE // *(int*)(pRxPkt->cb) = BRIDGE_TAG; //#endif { netif_rx(pRxPkt); } #endif // IKANOS_VX_1X0 // } PRTMP_SCATTER_GATHER_LIST rt_get_sg_list_from_packet(PNDIS_PACKET pPacket, RTMP_SCATTER_GATHER_LIST *sg) { sg->NumberOfElements = 1; sg->Elements[0].Address = GET_OS_PKT_DATAPTR(pPacket); sg->Elements[0].Length = GET_OS_PKT_LEN(pPacket); return (sg); } void hex_dump(char *str, unsigned char *pSrcBufVA, unsigned int SrcBufLen) { unsigned char *pt; int x; if (RTDebugLevel < RT_DEBUG_TRACE) return; pt = pSrcBufVA; printk("%s: %p, len = %d\n",str, pSrcBufVA, SrcBufLen); for (x=0; x= 15 //union iwreq_data wrqu; PSTRING pBuf = NULL, pBufPtr = NULL; USHORT event, type, BufLen; UCHAR event_table_len = 0; type = Event_flag & 0xFF00; event = Event_flag & 0x00FF; switch (type) { case IW_SYS_EVENT_FLAG_START: event_table_len = IW_SYS_EVENT_TYPE_NUM; break; case IW_SPOOF_EVENT_FLAG_START: event_table_len = IW_SPOOF_EVENT_TYPE_NUM; break; case IW_FLOOD_EVENT_FLAG_START: event_table_len = IW_FLOOD_EVENT_TYPE_NUM; break; } if (event_table_len == 0) { DBGPRINT(RT_DEBUG_ERROR, ("%s : The type(%0x02x) is not valid.\n", __FUNCTION__, type)); return; } if (event >= event_table_len) { DBGPRINT(RT_DEBUG_ERROR, ("%s : The event(%0x02x) is not valid.\n", __FUNCTION__, event)); return; } //Allocate memory and copy the msg. if((pBuf = kmalloc(IW_CUSTOM_MAX_LEN, GFP_ATOMIC)) != NULL) { //Prepare the payload memset(pBuf, 0, IW_CUSTOM_MAX_LEN); pBufPtr = pBuf; if (pAddr) pBufPtr += sprintf(pBufPtr, "(RT2860) STA(%02x:%02x:%02x:%02x:%02x:%02x) ", PRINT_MAC(pAddr)); else if (BssIdx < MAX_MBSSID_NUM) pBufPtr += sprintf(pBufPtr, "(RT2860) BSS(ra%d) ", BssIdx); else pBufPtr += sprintf(pBufPtr, "(RT2860) "); if (type == IW_SYS_EVENT_FLAG_START) pBufPtr += sprintf(pBufPtr, "%s", pWirelessSysEventText[event]); else if (type == IW_SPOOF_EVENT_FLAG_START) pBufPtr += sprintf(pBufPtr, "%s (RSSI=%d)", pWirelessSpoofEventText[event], Rssi); else if (type == IW_FLOOD_EVENT_FLAG_START) pBufPtr += sprintf(pBufPtr, "%s", pWirelessFloodEventText[event]); else pBufPtr += sprintf(pBufPtr, "%s", "unknown event"); pBufPtr[pBufPtr - pBuf] = '\0'; BufLen = pBufPtr - pBuf; RtmpOSWrielessEventSend(pAd, IWEVCUSTOM, Event_flag, NULL, (PUCHAR)pBuf, BufLen); //DBGPRINT(RT_DEBUG_TRACE, ("%s : %s\n", __FUNCTION__, pBuf)); kfree(pBuf); } else DBGPRINT(RT_DEBUG_ERROR, ("%s : Can't allocate memory for wireless event.\n", __FUNCTION__)); #else DBGPRINT(RT_DEBUG_ERROR, ("%s : The Wireless Extension MUST be v15 or newer.\n", __FUNCTION__)); #endif /* WIRELESS_EXT >= 15 */ } #ifdef CONFIG_STA_SUPPORT void send_monitor_packets( IN PRTMP_ADAPTER pAd, IN RX_BLK *pRxBlk) { struct sk_buff *pOSPkt; wlan_ng_prism2_header *ph; int rate_index = 0; USHORT header_len = 0; UCHAR temp_header[40] = {0}; u_int32_t ralinkrate[256] = {2,4,11,22, 12,18,24,36,48,72,96, 108, 109, 110, 111, 112, 13, 26, 39, 52,78,104, 117, 130, 26, 52, 78,104, 156, 208, 234, 260, 27, 54,81,108,162, 216, 243, 270, // Last 38 54, 108, 162, 216, 324, 432, 486, 540, 14, 29, 43, 57, 87, 115, 130, 144, 29, 59,87,115, 173, 230,260, 288, 30, 60,90,120,180,240,270,300,60,120,180,240,360,480,540,600, 0,1,2,3,4,5,6,7,8,9,10, 11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,37,38,39,40,41,42,43,44,45,46,47,48,49,50,51,52,53,54,55,56,57,58,59,60,61,62,63,64,65,66,67,68,69,70,71,72,73,74,75,76,77,78,79,80}; ASSERT(pRxBlk->pRxPacket); if (pRxBlk->DataSize < 10) { DBGPRINT(RT_DEBUG_ERROR, ("%s : Size is too small! (%d)\n", __FUNCTION__, pRxBlk->DataSize)); goto err_free_sk_buff; } if (pRxBlk->DataSize + sizeof(wlan_ng_prism2_header) > RX_BUFFER_AGGRESIZE) { DBGPRINT(RT_DEBUG_ERROR, ("%s : Size is too large! (%d)\n", __FUNCTION__, pRxBlk->DataSize + sizeof(wlan_ng_prism2_header))); goto err_free_sk_buff; } pOSPkt = RTPKT_TO_OSPKT(pRxBlk->pRxPacket); pOSPkt->dev = get_netdev_from_bssid(pAd, BSS0); if (pRxBlk->pHeader->FC.Type == BTYPE_DATA) { pRxBlk->DataSize -= LENGTH_802_11; if ((pRxBlk->pHeader->FC.ToDs == 1) && (pRxBlk->pHeader->FC.FrDs == 1)) header_len = LENGTH_802_11_WITH_ADDR4; else header_len = LENGTH_802_11; // QOS if (pRxBlk->pHeader->FC.SubType & 0x08) { header_len += 2; // Data skip QOS contorl field pRxBlk->DataSize -=2; } // Order bit: A-Ralink or HTC+ if (pRxBlk->pHeader->FC.Order) { header_len += 4; // Data skip HTC contorl field pRxBlk->DataSize -= 4; } // Copy Header if (header_len <= 40) NdisMoveMemory(temp_header, pRxBlk->pData, header_len); // skip HW padding if (pRxBlk->RxD.L2PAD) pRxBlk->pData += (header_len + 2); else pRxBlk->pData += header_len; } //end if if (pRxBlk->DataSize < pOSPkt->len) { skb_trim(pOSPkt,pRxBlk->DataSize); } else { skb_put(pOSPkt,(pRxBlk->DataSize - pOSPkt->len)); } //end if if ((pRxBlk->pData - pOSPkt->data) > 0) { skb_put(pOSPkt,(pRxBlk->pData - pOSPkt->data)); skb_pull(pOSPkt,(pRxBlk->pData - pOSPkt->data)); } //end if if (skb_headroom(pOSPkt) < (sizeof(wlan_ng_prism2_header)+ header_len)) { if (pskb_expand_head(pOSPkt, (sizeof(wlan_ng_prism2_header) + header_len), 0, GFP_ATOMIC)) { DBGPRINT(RT_DEBUG_ERROR, ("%s : Reallocate header size of sk_buff fail!\n", __FUNCTION__)); goto err_free_sk_buff; } //end if } //end if if (header_len > 0) NdisMoveMemory(skb_push(pOSPkt, header_len), temp_header, header_len); ph = (wlan_ng_prism2_header *) skb_push(pOSPkt, sizeof(wlan_ng_prism2_header)); NdisZeroMemory(ph, sizeof(wlan_ng_prism2_header)); ph->msgcode = DIDmsg_lnxind_wlansniffrm; ph->msglen = sizeof(wlan_ng_prism2_header); strcpy((PSTRING) ph->devname, (PSTRING) pAd->net_dev->name); ph->hosttime.did = DIDmsg_lnxind_wlansniffrm_hosttime; ph->hosttime.status = 0; ph->hosttime.len = 4; ph->hosttime.data = jiffies; ph->mactime.did = DIDmsg_lnxind_wlansniffrm_mactime; ph->mactime.status = 0; ph->mactime.len = 0; ph->mactime.data = 0; ph->istx.did = DIDmsg_lnxind_wlansniffrm_istx; ph->istx.status = 0; ph->istx.len = 0; ph->istx.data = 0; ph->channel.did = DIDmsg_lnxind_wlansniffrm_channel; ph->channel.status = 0; ph->channel.len = 4; ph->channel.data = (u_int32_t)pAd->CommonCfg.Channel; ph->rssi.did = DIDmsg_lnxind_wlansniffrm_rssi; ph->rssi.status = 0; ph->rssi.len = 4; ph->rssi.data = (u_int32_t)RTMPMaxRssi(pAd, ConvertToRssi(pAd, pRxBlk->pRxWI->RSSI0, RSSI_0), ConvertToRssi(pAd, pRxBlk->pRxWI->RSSI1, RSSI_1), ConvertToRssi(pAd, pRxBlk->pRxWI->RSSI2, RSSI_2));; ph->signal.did = DIDmsg_lnxind_wlansniffrm_signal; ph->signal.status = 0; ph->signal.len = 4; ph->signal.data = 0; //rssi + noise; ph->noise.did = DIDmsg_lnxind_wlansniffrm_noise; ph->noise.status = 0; ph->noise.len = 4; ph->noise.data = 0; #ifdef DOT11_N_SUPPORT if (pRxBlk->pRxWI->PHYMODE >= MODE_HTMIX) { rate_index = 16 + ((UCHAR)pRxBlk->pRxWI->BW *16) + ((UCHAR)pRxBlk->pRxWI->ShortGI *32) + ((UCHAR)pRxBlk->pRxWI->MCS); } else #endif // DOT11_N_SUPPORT // if (pRxBlk->pRxWI->PHYMODE == MODE_OFDM) rate_index = (UCHAR)(pRxBlk->pRxWI->MCS) + 4; else rate_index = (UCHAR)(pRxBlk->pRxWI->MCS); if (rate_index < 0) rate_index = 0; if (rate_index > 255) rate_index = 255; ph->rate.did = DIDmsg_lnxind_wlansniffrm_rate; ph->rate.status = 0; ph->rate.len = 4; ph->rate.data = ralinkrate[rate_index]; ph->frmlen.did = DIDmsg_lnxind_wlansniffrm_frmlen; ph->frmlen.status = 0; ph->frmlen.len = 4; ph->frmlen.data = (u_int32_t)pRxBlk->DataSize; pOSPkt->pkt_type = PACKET_OTHERHOST; pOSPkt->protocol = eth_type_trans(pOSPkt, pOSPkt->dev); pOSPkt->ip_summed = CHECKSUM_NONE; netif_rx(pOSPkt); return; err_free_sk_buff: RELEASE_NDIS_PACKET(pAd, pRxBlk->pRxPacket, NDIS_STATUS_FAILURE); return; } #endif // CONFIG_STA_SUPPORT // /******************************************************************************* File open/close related functions. *******************************************************************************/ RTMP_OS_FD RtmpOSFileOpen(char *pPath, int flag, int mode) { struct file *filePtr; filePtr = filp_open(pPath, flag, 0); if (IS_ERR(filePtr)) { DBGPRINT(RT_DEBUG_ERROR, ("%s(): Error %ld opening %s\n", __FUNCTION__, -PTR_ERR(filePtr), pPath)); } return (RTMP_OS_FD)filePtr; } int RtmpOSFileClose(RTMP_OS_FD osfd) { filp_close(osfd, NULL); return 0; } void RtmpOSFileSeek(RTMP_OS_FD osfd, int offset) { osfd->f_pos = offset; } int RtmpOSFileRead(RTMP_OS_FD osfd, char *pDataPtr, int readLen) { // The object must have a read method if (osfd->f_op && osfd->f_op->read) { return osfd->f_op->read(osfd, pDataPtr, readLen, &osfd->f_pos); } else { DBGPRINT(RT_DEBUG_ERROR, ("no file read method\n")); return -1; } } int RtmpOSFileWrite(RTMP_OS_FD osfd, char *pDataPtr, int writeLen) { return osfd->f_op->write(osfd, pDataPtr, (size_t)writeLen, &osfd->f_pos); } void RtmpOSFSInfoChange(RTMP_OS_FS_INFO *pOSFSInfo, BOOLEAN bSet) { if (bSet) { // Save uid and gid used for filesystem access. // Set user and group to 0 (root) #if LINUX_VERSION_CODE < KERNEL_VERSION(2,6,29) pOSFSInfo->fsuid= current->fsuid; pOSFSInfo->fsgid = current->fsgid; current->fsuid = current->fsgid = 0; #else pOSFSInfo->fsuid = current_fsuid(); pOSFSInfo->fsgid = current_fsgid(); #endif pOSFSInfo->fs = get_fs(); set_fs(KERNEL_DS); } else { set_fs(pOSFSInfo->fs); #if LINUX_VERSION_CODE < KERNEL_VERSION(2,6,29) current->fsuid = pOSFSInfo->fsuid; current->fsgid = pOSFSInfo->fsgid; #endif } } /******************************************************************************* Task create/management/kill related functions. *******************************************************************************/ NDIS_STATUS RtmpOSTaskKill( IN RTMP_OS_TASK *pTask) { RTMP_ADAPTER *pAd; int ret = NDIS_STATUS_FAILURE; pAd = (RTMP_ADAPTER *)pTask->priv; #ifdef KTHREAD_SUPPORT if (pTask->kthread_task) { kthread_stop(pTask->kthread_task); ret = NDIS_STATUS_SUCCESS; } #else CHECK_PID_LEGALITY(pTask->taskPID) { printk("Terminate the task(%s) with pid(%d)!\n", pTask->taskName, GET_PID_NUMBER(pTask->taskPID)); mb(); pTask->task_killed = 1; mb(); ret = KILL_THREAD_PID(pTask->taskPID, SIGTERM, 1); if (ret) { printk(KERN_WARNING "kill task(%s) with pid(%d) failed(retVal=%d)!\n", pTask->taskName, GET_PID_NUMBER(pTask->taskPID), ret); } else { wait_for_completion(&pTask->taskComplete); pTask->taskPID = THREAD_PID_INIT_VALUE; pTask->task_killed = 0; ret = NDIS_STATUS_SUCCESS; } } #endif return ret; } INT RtmpOSTaskNotifyToExit( IN RTMP_OS_TASK *pTask) { #ifndef KTHREAD_SUPPORT complete_and_exit(&pTask->taskComplete, 0); #endif return 0; } void RtmpOSTaskCustomize( IN RTMP_OS_TASK *pTask) { #ifndef KTHREAD_SUPPORT #if LINUX_VERSION_CODE >= KERNEL_VERSION(2,5,0) daemonize((PSTRING)&pTask->taskName[0]/*"%s",pAd->net_dev->name*/); allow_signal(SIGTERM); allow_signal(SIGKILL); current->flags |= PF_NOFREEZE; #else unsigned long flags; daemonize(); reparent_to_init(); strcpy(current->comm, &pTask->taskName[0]); siginitsetinv(¤t->blocked, sigmask(SIGTERM) | sigmask(SIGKILL)); /* Allow interception of SIGKILL only * Don't allow other signals to interrupt the transmission */ #if LINUX_VERSION_CODE > KERNEL_VERSION(2,4,22) spin_lock_irqsave(¤t->sigmask_lock, flags); flush_signals(current); recalc_sigpending(current); spin_unlock_irqrestore(¤t->sigmask_lock, flags); #endif #endif /* signal that we've started the thread */ complete(&pTask->taskComplete); #endif } NDIS_STATUS RtmpOSTaskAttach( IN RTMP_OS_TASK *pTask, IN int (*fn)(void *), IN void *arg) { NDIS_STATUS status = NDIS_STATUS_SUCCESS; pid_t pid_number = -1; #ifdef KTHREAD_SUPPORT pTask->task_killed = 0; pTask->kthread_task = NULL; pTask->kthread_task = kthread_run(fn, arg, pTask->taskName); if (IS_ERR(pTask->kthread_task)) status = NDIS_STATUS_FAILURE; #else pid_number = kernel_thread(fn, arg, RTMP_OS_MGMT_TASK_FLAGS); if (pid_number < 0) { DBGPRINT (RT_DEBUG_ERROR, ("Attach task(%s) failed!\n", pTask->taskName)); status = NDIS_STATUS_FAILURE; } else { pTask->taskPID = GET_PID(pid_number); // Wait for the thread to start wait_for_completion(&pTask->taskComplete); status = NDIS_STATUS_SUCCESS; } #endif return status; } NDIS_STATUS RtmpOSTaskInit( IN RTMP_OS_TASK *pTask, IN PSTRING pTaskName, IN VOID *pPriv) { int len; ASSERT(pTask); #ifndef KTHREAD_SUPPORT NdisZeroMemory((PUCHAR)(pTask), sizeof(RTMP_OS_TASK)); #endif len = strlen(pTaskName); len = len > (RTMP_OS_TASK_NAME_LEN -1) ? (RTMP_OS_TASK_NAME_LEN-1) : len; NdisMoveMemory(&pTask->taskName[0], pTaskName, len); pTask->priv = pPriv; #ifndef KTHREAD_SUPPORT RTMP_SEM_EVENT_INIT_LOCKED(&(pTask->taskSema)); pTask->taskPID = THREAD_PID_INIT_VALUE; init_completion (&pTask->taskComplete); #endif return NDIS_STATUS_SUCCESS; } void RTMP_IndicateMediaState( IN PRTMP_ADAPTER pAd) { if (pAd->CommonCfg.bWirelessEvent) { if (pAd->IndicateMediaState == NdisMediaStateConnected) { RTMPSendWirelessEvent(pAd, IW_STA_LINKUP_EVENT_FLAG, pAd->MacTab.Content[BSSID_WCID].Addr, BSS0, 0); } else { RTMPSendWirelessEvent(pAd, IW_STA_LINKDOWN_EVENT_FLAG, pAd->MacTab.Content[BSSID_WCID].Addr, BSS0, 0); } } } #if LINUX_VERSION_CODE <= 0x20402 // Red Hat 7.1 //static struct net_device *alloc_netdev(int sizeof_priv, const char *mask, void (*setup)(struct net_device *)) //sample struct net_device *alloc_netdev( int sizeof_priv, const char *mask, void (*setup)(struct net_device *)) { struct net_device *dev; INT alloc_size; /* ensure 32-byte alignment of the private area */ alloc_size = sizeof (*dev) + sizeof_priv + 31; dev = (struct net_device *) kmalloc(alloc_size, GFP_KERNEL); if (dev == NULL) { DBGPRINT(RT_DEBUG_ERROR, ("alloc_netdev: Unable to allocate device memory.\n")); return NULL; } memset(dev, 0, alloc_size); if (sizeof_priv) dev->priv = (void *) (((long)(dev + 1) + 31) & ~31); setup(dev); strcpy(dev->name, mask); return dev; } #endif // LINUX_VERSION_CODE // int RtmpOSWrielessEventSend( IN RTMP_ADAPTER *pAd, IN UINT32 eventType, IN INT flags, IN PUCHAR pSrcMac, IN PUCHAR pData, IN UINT32 dataLen) { union iwreq_data wrqu; memset(&wrqu, 0, sizeof(wrqu)); if (flags>-1) wrqu.data.flags = flags; if (pSrcMac) memcpy(wrqu.ap_addr.sa_data, pSrcMac, MAC_ADDR_LEN); if ((pData!= NULL) && (dataLen > 0)) wrqu.data.length = dataLen; wireless_send_event(pAd->net_dev, eventType, &wrqu, (char *)pData); return 0; } int RtmpOSNetDevAddrSet( IN PNET_DEV pNetDev, IN PUCHAR pMacAddr) { struct net_device *net_dev; RTMP_ADAPTER *pAd; net_dev = pNetDev; //pAd = (RTMP_ADAPTER *)net_dev->priv; pAd=RTMP_OS_NETDEV_GET_PRIV(pNetDev); #ifdef CONFIG_STA_SUPPORT // work-around for the SuSE due to it has it's own interface name management system. IF_DEV_CONFIG_OPMODE_ON_STA(pAd) { NdisZeroMemory(pAd->StaCfg.dev_name, 16); NdisMoveMemory(pAd->StaCfg.dev_name, net_dev->name, strlen(net_dev->name)); } #endif // CONFIG_STA_SUPPORT // NdisMoveMemory(net_dev->dev_addr, pMacAddr, 6); return 0; } /* * Assign the network dev name for created Ralink WiFi interface. */ static int RtmpOSNetDevRequestName( IN RTMP_ADAPTER *pAd, IN PNET_DEV dev, IN PSTRING pPrefixStr, IN INT devIdx) { PNET_DEV existNetDev; STRING suffixName[IFNAMSIZ]; STRING desiredName[IFNAMSIZ]; int ifNameIdx, prefixLen, slotNameLen; int Status; prefixLen = strlen(pPrefixStr); ASSERT((prefixLen < IFNAMSIZ)); for (ifNameIdx = devIdx; ifNameIdx < 32; ifNameIdx++) { memset(suffixName, 0, IFNAMSIZ); memset(desiredName, 0, IFNAMSIZ); strncpy(&desiredName[0], pPrefixStr, prefixLen); #ifdef MULTIPLE_CARD_SUPPORT if (pAd->MC_RowID >= 0) sprintf(suffixName, "%02d_%d", pAd->MC_RowID, ifNameIdx); else #endif // MULTIPLE_CARD_SUPPORT // sprintf(suffixName, "%d", ifNameIdx); slotNameLen = strlen(suffixName); ASSERT(((slotNameLen + prefixLen) < IFNAMSIZ)); strcat(desiredName, suffixName); existNetDev = RtmpOSNetDevGetByName(dev, &desiredName[0]); if (existNetDev == NULL) break; else RtmpOSNetDeviceRefPut(existNetDev); } if(ifNameIdx < 32) { strcpy(&dev->name[0], &desiredName[0]); Status = NDIS_STATUS_SUCCESS; } else { DBGPRINT(RT_DEBUG_ERROR, ("Cannot request DevName with preifx(%s) and in range(0~32) as suffix from OS!\n", pPrefixStr)); Status = NDIS_STATUS_FAILURE; } return Status; } void RtmpOSNetDevClose( IN PNET_DEV pNetDev) { dev_close(pNetDev); } void RtmpOSNetDevFree(PNET_DEV pNetDev) { ASSERT(pNetDev); #if LINUX_VERSION_CODE >= KERNEL_VERSION(2,5,0) free_netdev(pNetDev); #else kfree(pNetDev); #endif } INT RtmpOSNetDevAlloc( IN PNET_DEV *new_dev_p, IN UINT32 privDataSize) { // assign it as null first. *new_dev_p = NULL; DBGPRINT(RT_DEBUG_TRACE, ("Allocate a net device with private data size=%d!\n", privDataSize)); #if LINUX_VERSION_CODE <= 0x20402 // Red Hat 7.1 *new_dev_p = alloc_netdev(privDataSize, "eth%d", ether_setup); #else *new_dev_p = alloc_etherdev(privDataSize); #endif // LINUX_VERSION_CODE // if (*new_dev_p) return NDIS_STATUS_SUCCESS; else return NDIS_STATUS_FAILURE; } PNET_DEV RtmpOSNetDevGetByName(PNET_DEV pNetDev, PSTRING pDevName) { PNET_DEV pTargetNetDev = NULL; #if LINUX_VERSION_CODE >= KERNEL_VERSION(2,5,0) #if LINUX_VERSION_CODE >= KERNEL_VERSION(2,6,24) #if LINUX_VERSION_CODE >= KERNEL_VERSION(2,6,26) pTargetNetDev = dev_get_by_name(dev_net(pNetDev), pDevName); #else ASSERT(pNetDev); pTargetNetDev = dev_get_by_name(pNetDev->nd_net, pDevName); #endif #else pTargetNetDev = dev_get_by_name(pDevName); #endif // KERNEL_VERSION(2,6,24) // #else int devNameLen; devNameLen = strlen(pDevName); ASSERT((devNameLen <= IFNAMSIZ)); for(pTargetNetDev=dev_base; pTargetNetDev!=NULL; pTargetNetDev=pTargetNetDev->next) { if (strncmp(pTargetNetDev->name, pDevName, devNameLen) == 0) break; } #endif // KERNEL_VERSION(2,5,0) // return pTargetNetDev; } void RtmpOSNetDeviceRefPut(PNET_DEV pNetDev) { #if LINUX_VERSION_CODE >= KERNEL_VERSION(2,5,0) /* every time dev_get_by_name is called, and it has returned a valid struct net_device*, dev_put should be called afterwards, because otherwise the machine hangs when the device is unregistered (since dev->refcnt > 1). */ if(pNetDev) dev_put(pNetDev); #endif // LINUX_VERSION_CODE // } INT RtmpOSNetDevDestory( IN RTMP_ADAPTER *pAd, IN PNET_DEV pNetDev) { // TODO: Need to fix this printk("WARNING: This function(%s) not implement yet!!!\n", __FUNCTION__); return 0; } void RtmpOSNetDevDetach(PNET_DEV pNetDev) { unregister_netdev(pNetDev); } int RtmpOSNetDevAttach( IN PNET_DEV pNetDev, IN RTMP_OS_NETDEV_OP_HOOK *pDevOpHook) { int ret, rtnl_locked = FALSE; DBGPRINT(RT_DEBUG_TRACE, ("RtmpOSNetDevAttach()--->\n")); // If we need hook some callback function to the net device structrue, now do it. if (pDevOpHook) { PRTMP_ADAPTER pAd = RTMP_OS_NETDEV_GET_PRIV(pNetDev); pNetDev->netdev_ops = pDevOpHook->netdev_ops; /* OS specific flags, here we used to indicate if we are virtual interface */ pNetDev->priv_flags = pDevOpHook->priv_flags; #if (WIRELESS_EXT < 21) && (WIRELESS_EXT >= 12) pNetDev->get_wireless_stats = rt28xx_get_wireless_stats; #endif #ifdef CONFIG_STA_SUPPORT #if WIRELESS_EXT >= 12 if (pAd->OpMode == OPMODE_STA) { pNetDev->wireless_handlers = &rt28xx_iw_handler_def; } #endif //WIRELESS_EXT >= 12 #endif // CONFIG_STA_SUPPORT // #ifdef CONFIG_APSTA_MIXED_SUPPORT #if WIRELESS_EXT >= 12 if (pAd->OpMode == OPMODE_AP) { pNetDev->wireless_handlers = &rt28xx_ap_iw_handler_def; } #endif //WIRELESS_EXT >= 12 #endif // CONFIG_APSTA_MIXED_SUPPORT // // copy the net device mac address to the net_device structure. NdisMoveMemory(pNetDev->dev_addr, &pDevOpHook->devAddr[0], MAC_ADDR_LEN); rtnl_locked = pDevOpHook->needProtcted; } if (rtnl_locked) ret = register_netdevice(pNetDev); else ret = register_netdev(pNetDev); DBGPRINT(RT_DEBUG_TRACE, ("<---RtmpOSNetDevAttach(), ret=%d\n", ret)); if (ret == 0) return NDIS_STATUS_SUCCESS; else return NDIS_STATUS_FAILURE; } PNET_DEV RtmpOSNetDevCreate( IN RTMP_ADAPTER *pAd, IN INT devType, IN INT devNum, IN INT privMemSize, IN PSTRING pNamePrefix) { struct net_device *pNetDev = NULL; int status; /* allocate a new network device */ status = RtmpOSNetDevAlloc(&pNetDev, 0 /*privMemSize*/); if (status != NDIS_STATUS_SUCCESS) { /* allocation fail, exit */ DBGPRINT(RT_DEBUG_ERROR, ("Allocate network device fail (%s)...\n", pNamePrefix)); return NULL; } /* find a available interface name, max 32 interfaces */ status = RtmpOSNetDevRequestName(pAd, pNetDev, pNamePrefix, devNum); if (status != NDIS_STATUS_SUCCESS) { /* error! no any available ra name can be used! */ DBGPRINT(RT_DEBUG_ERROR, ("Assign interface name (%s with suffix 0~32) failed...\n", pNamePrefix)); RtmpOSNetDevFree(pNetDev); return NULL; } else { DBGPRINT(RT_DEBUG_TRACE, ("The name of the new %s interface is %s...\n", pNamePrefix, pNetDev->name)); } return pNetDev; }