/*! * @file coreconfigurator.c * @brief * @author * @sa coreconfigurator.h * @date 1 Mar 2012 * @version 1.0 */ #include "coreconfigurator.h" #include "wilc_wlan_if.h" #include "wilc_wlan.h" #include #include #define TAG_PARAM_OFFSET (MAC_HDR_LEN + TIME_STAMP_LEN + \ BEACON_INTERVAL_LEN + CAP_INFO_LEN) /* Basic Frame Type Codes (2-bit) */ enum basic_frame_type { FRAME_TYPE_CONTROL = 0x04, FRAME_TYPE_DATA = 0x08, FRAME_TYPE_MANAGEMENT = 0x00, FRAME_TYPE_RESERVED = 0x0C, FRAME_TYPE_FORCE_32BIT = 0xFFFFFFFF }; /* Frame Type and Subtype Codes (6-bit) */ enum sub_frame_type { ASSOC_REQ = 0x00, ASSOC_RSP = 0x10, REASSOC_REQ = 0x20, REASSOC_RSP = 0x30, PROBE_REQ = 0x40, PROBE_RSP = 0x50, BEACON = 0x80, ATIM = 0x90, DISASOC = 0xA0, AUTH = 0xB0, DEAUTH = 0xC0, ACTION = 0xD0, PS_POLL = 0xA4, RTS = 0xB4, CTS = 0xC4, ACK = 0xD4, CFEND = 0xE4, CFEND_ACK = 0xF4, DATA = 0x08, DATA_ACK = 0x18, DATA_POLL = 0x28, DATA_POLL_ACK = 0x38, NULL_FRAME = 0x48, CFACK = 0x58, CFPOLL = 0x68, CFPOLL_ACK = 0x78, QOS_DATA = 0x88, QOS_DATA_ACK = 0x98, QOS_DATA_POLL = 0xA8, QOS_DATA_POLL_ACK = 0xB8, QOS_NULL_FRAME = 0xC8, QOS_CFPOLL = 0xE8, QOS_CFPOLL_ACK = 0xF8, BLOCKACK_REQ = 0x84, BLOCKACK = 0x94, FRAME_SUBTYPE_FORCE_32BIT = 0xFFFFFFFF }; /* Element ID of various Information Elements */ enum info_element_id { ISSID = 0, /* Service Set Identifier */ ISUPRATES = 1, /* Supported Rates */ IFHPARMS = 2, /* FH parameter set */ IDSPARMS = 3, /* DS parameter set */ ICFPARMS = 4, /* CF parameter set */ ITIM = 5, /* Traffic Information Map */ IIBPARMS = 6, /* IBSS parameter set */ ICOUNTRY = 7, /* Country element */ IEDCAPARAMS = 12, /* EDCA parameter set */ ITSPEC = 13, /* Traffic Specification */ ITCLAS = 14, /* Traffic Classification */ ISCHED = 15, /* Schedule */ ICTEXT = 16, /* Challenge Text */ IPOWERCONSTRAINT = 32, /* Power Constraint */ IPOWERCAPABILITY = 33, /* Power Capability */ ITPCREQUEST = 34, /* TPC Request */ ITPCREPORT = 35, /* TPC Report */ ISUPCHANNEL = 36, /* Supported channel list */ ICHSWANNOUNC = 37, /* Channel Switch Announcement */ IMEASUREMENTREQUEST = 38, /* Measurement request */ IMEASUREMENTREPORT = 39, /* Measurement report */ IQUIET = 40, /* Quiet element Info */ IIBSSDFS = 41, /* IBSS DFS */ IERPINFO = 42, /* ERP Information */ ITSDELAY = 43, /* TS Delay */ ITCLASPROCESS = 44, /* TCLAS Processing */ IHTCAP = 45, /* HT Capabilities */ IQOSCAP = 46, /* QoS Capability */ IRSNELEMENT = 48, /* RSN Information Element */ IEXSUPRATES = 50, /* Extended Supported Rates */ IEXCHSWANNOUNC = 60, /* Extended Ch Switch Announcement*/ IHTOPERATION = 61, /* HT Information */ ISECCHOFF = 62, /* Secondary Channel Offeset */ I2040COEX = 72, /* 20/40 Coexistence IE */ I2040INTOLCHREPORT = 73, /* 20/40 Intolerant channel report*/ IOBSSSCAN = 74, /* OBSS Scan parameters */ IEXTCAP = 127, /* Extended capability */ IWMM = 221, /* WMM parameters */ IWPAELEMENT = 221, /* WPA Information Element */ INFOELEM_ID_FORCE_32BIT = 0xFFFFFFFF }; /* This function extracts the beacon period field from the beacon or probe */ /* response frame. */ static inline u16 get_beacon_period(u8 *data) { u16 bcn_per; bcn_per = data[0]; bcn_per |= (data[1] << 8); return bcn_per; } static inline u32 get_beacon_timestamp_lo(u8 *data) { u32 time_stamp = 0; u32 index = MAC_HDR_LEN; time_stamp |= data[index++]; time_stamp |= (data[index++] << 8); time_stamp |= (data[index++] << 16); time_stamp |= (data[index] << 24); return time_stamp; } static inline u32 get_beacon_timestamp_hi(u8 *data) { u32 time_stamp = 0; u32 index = (MAC_HDR_LEN + 4); time_stamp |= data[index++]; time_stamp |= (data[index++] << 8); time_stamp |= (data[index++] << 16); time_stamp |= (data[index] << 24); return time_stamp; } /* This function extracts the 'frame type and sub type' bits from the MAC */ /* header of the input frame. */ /* Returns the value in the LSB of the returned value. */ static inline enum sub_frame_type get_sub_type(u8 *header) { return ((enum sub_frame_type)(header[0] & 0xFC)); } /* This function extracts the 'to ds' bit from the MAC header of the input */ /* frame. */ /* Returns the value in the LSB of the returned value. */ static inline u8 get_to_ds(u8 *header) { return (header[1] & 0x01); } /* This function extracts the 'from ds' bit from the MAC header of the input */ /* frame. */ /* Returns the value in the LSB of the returned value. */ static inline u8 get_from_ds(u8 *header) { return ((header[1] & 0x02) >> 1); } /* This function extracts the MAC Address in 'address1' field of the MAC */ /* header and updates the MAC Address in the allocated 'addr' variable. */ static inline void get_address1(u8 *pu8msa, u8 *addr) { memcpy(addr, pu8msa + 4, 6); } /* This function extracts the MAC Address in 'address2' field of the MAC */ /* header and updates the MAC Address in the allocated 'addr' variable. */ static inline void get_address2(u8 *pu8msa, u8 *addr) { memcpy(addr, pu8msa + 10, 6); } /* This function extracts the MAC Address in 'address3' field of the MAC */ /* header and updates the MAC Address in the allocated 'addr' variable. */ static inline void get_address3(u8 *pu8msa, u8 *addr) { memcpy(addr, pu8msa + 16, 6); } /* This function extracts the BSSID from the incoming WLAN packet based on */ /* the 'from ds' bit, and updates the MAC Address in the allocated 'addr' */ /* variable. */ static inline void get_BSSID(u8 *data, u8 *bssid) { if (get_from_ds(data) == 1) get_address2(data, bssid); else if (get_to_ds(data) == 1) get_address1(data, bssid); else get_address3(data, bssid); } /* This function extracts the SSID from a beacon/probe response frame */ static inline void get_ssid(u8 *data, u8 *ssid, u8 *p_ssid_len) { u8 len = 0; u8 i = 0; u8 j = 0; len = data[MAC_HDR_LEN + TIME_STAMP_LEN + BEACON_INTERVAL_LEN + CAP_INFO_LEN + 1]; j = MAC_HDR_LEN + TIME_STAMP_LEN + BEACON_INTERVAL_LEN + CAP_INFO_LEN + 2; /* If the SSID length field is set wrongly to a value greater than the */ /* allowed maximum SSID length limit, reset the length to 0 */ if (len >= MAX_SSID_LEN) len = 0; for (i = 0; i < len; i++, j++) ssid[i] = data[j]; ssid[len] = '\0'; *p_ssid_len = len; } /* This function extracts the capability info field from the beacon or probe */ /* response frame. */ static inline u16 get_cap_info(u8 *data) { u16 cap_info = 0; u16 index = MAC_HDR_LEN; enum sub_frame_type st; st = get_sub_type(data); /* Location of the Capability field is different for Beacon and */ /* Association frames. */ if ((st == BEACON) || (st == PROBE_RSP)) index += TIME_STAMP_LEN + BEACON_INTERVAL_LEN; cap_info = data[index]; cap_info |= (data[index + 1] << 8); return cap_info; } /* This function extracts the capability info field from the Association */ /* response frame. */ static inline u16 get_assoc_resp_cap_info(u8 *data) { u16 cap_info; cap_info = data[0]; cap_info |= (data[1] << 8); return cap_info; } /* This function extracts the association status code from the incoming */ /* association response frame and returns association status code */ static inline u16 get_asoc_status(u8 *data) { u16 asoc_status; asoc_status = data[3]; asoc_status = (asoc_status << 8) | data[2]; return asoc_status; } /* This function extracts association ID from the incoming association */ /* response frame */ static inline u16 get_asoc_id(u8 *data) { u16 asoc_id; asoc_id = data[4]; asoc_id |= (data[5] << 8); return asoc_id; } u8 *get_tim_elm(u8 *pu8msa, u16 u16RxLen, u16 u16TagParamOffset) { u16 u16index; /*************************************************************************/ /* Beacon Frame - Frame Body */ /* --------------------------------------------------------------------- */ /* |Timestamp |BeaconInt |CapInfo |SSID |SupRates |DSParSet |TIM elm | */ /* --------------------------------------------------------------------- */ /* |8 |2 |2 |2-34 |3-10 |3 |4-256 | */ /* --------------------------------------------------------------------- */ /* */ /*************************************************************************/ u16index = u16TagParamOffset; /* Search for the TIM Element Field and return if the element is found */ while (u16index < (u16RxLen - FCS_LEN)) { if (pu8msa[u16index] == ITIM) return &pu8msa[u16index]; u16index += (IE_HDR_LEN + pu8msa[u16index + 1]); } return NULL; } /* This function gets the current channel information from * the 802.11n beacon/probe response frame */ u8 get_current_channel_802_11n(u8 *pu8msa, u16 u16RxLen) { u16 index; index = TAG_PARAM_OFFSET; while (index < (u16RxLen - FCS_LEN)) { if (pu8msa[index] == IDSPARMS) return pu8msa[index + 2]; /* Increment index by length information and header */ index += pu8msa[index + 1] + IE_HDR_LEN; } /* Return current channel information from the MIB, if beacon/probe */ /* response frame does not contain the DS parameter set IE */ /* return (mget_CurrentChannel() + 1); */ return 0; /* no MIB here */ } /** * @brief parses the received 'N' message * @details * @param[in] pu8MsgBuffer The message to be parsed * @param[out] ppstrNetworkInfo pointer to pointer to the structure containing the parsed Network Info * @return Error code indicating success/failure * @note * @author mabubakr * @date 1 Mar 2012 * @version 1.0 */ s32 parse_network_info(u8 *pu8MsgBuffer, tstrNetworkInfo **ppstrNetworkInfo) { tstrNetworkInfo *pstrNetworkInfo = NULL; u8 u8MsgType = 0; u8 u8MsgID = 0; u16 u16MsgLen = 0; u16 u16WidID = (u16)WID_NIL; u16 u16WidLen = 0; u8 *pu8WidVal = NULL; u8MsgType = pu8MsgBuffer[0]; /* Check whether the received message type is 'N' */ if ('N' != u8MsgType) { PRINT_ER("Received Message format incorrect.\n"); return -EFAULT; } /* Extract message ID */ u8MsgID = pu8MsgBuffer[1]; /* Extract message Length */ u16MsgLen = MAKE_WORD16(pu8MsgBuffer[2], pu8MsgBuffer[3]); /* Extract WID ID */ u16WidID = MAKE_WORD16(pu8MsgBuffer[4], pu8MsgBuffer[5]); /* Extract WID Length */ u16WidLen = MAKE_WORD16(pu8MsgBuffer[6], pu8MsgBuffer[7]); /* Assign a pointer to the WID value */ pu8WidVal = &pu8MsgBuffer[8]; /* parse the WID value of the WID "WID_NEWORK_INFO" */ { u8 *pu8msa = NULL; u16 u16RxLen = 0; u8 *pu8TimElm = NULL; u8 *pu8IEs = NULL; u16 u16IEsLen = 0; u8 u8index = 0; u32 u32Tsf_Lo; u32 u32Tsf_Hi; pstrNetworkInfo = kzalloc(sizeof(tstrNetworkInfo), GFP_KERNEL); if (!pstrNetworkInfo) return -ENOMEM; pstrNetworkInfo->s8rssi = pu8WidVal[0]; /* Assign a pointer to msa "Mac Header Start Address" */ pu8msa = &pu8WidVal[1]; u16RxLen = u16WidLen - 1; /* parse msa*/ /* Get the cap_info */ pstrNetworkInfo->u16CapInfo = get_cap_info(pu8msa); /* Get time-stamp [Low only 32 bit] */ pstrNetworkInfo->u32Tsf = get_beacon_timestamp_lo(pu8msa); PRINT_D(CORECONFIG_DBG, "TSF :%x\n", pstrNetworkInfo->u32Tsf); /* Get full time-stamp [Low and High 64 bit] */ u32Tsf_Lo = get_beacon_timestamp_lo(pu8msa); u32Tsf_Hi = get_beacon_timestamp_hi(pu8msa); pstrNetworkInfo->u64Tsf = u32Tsf_Lo | ((u64)u32Tsf_Hi << 32); /* Get SSID */ get_ssid(pu8msa, pstrNetworkInfo->au8ssid, &pstrNetworkInfo->u8SsidLen); /* Get BSSID */ get_BSSID(pu8msa, pstrNetworkInfo->au8bssid); /* * Extract current channel information from * the beacon/probe response frame */ pstrNetworkInfo->u8channel = get_current_channel_802_11n(pu8msa, u16RxLen + FCS_LEN); /* Get beacon period */ u8index = MAC_HDR_LEN + TIME_STAMP_LEN; pstrNetworkInfo->u16BeaconPeriod = get_beacon_period(pu8msa + u8index); u8index += BEACON_INTERVAL_LEN + CAP_INFO_LEN; /* Get DTIM Period */ pu8TimElm = get_tim_elm(pu8msa, u16RxLen + FCS_LEN, u8index); if (pu8TimElm != NULL) pstrNetworkInfo->u8DtimPeriod = pu8TimElm[3]; pu8IEs = &pu8msa[MAC_HDR_LEN + TIME_STAMP_LEN + BEACON_INTERVAL_LEN + CAP_INFO_LEN]; u16IEsLen = u16RxLen - (MAC_HDR_LEN + TIME_STAMP_LEN + BEACON_INTERVAL_LEN + CAP_INFO_LEN); if (u16IEsLen > 0) { pstrNetworkInfo->pu8IEs = kmemdup(pu8IEs, u16IEsLen, GFP_KERNEL); if (!pstrNetworkInfo->pu8IEs) return -ENOMEM; } pstrNetworkInfo->u16IEsLen = u16IEsLen; } *ppstrNetworkInfo = pstrNetworkInfo; return 0; } /** * @brief Deallocates the parsed Network Info * @details * @param[in] pstrNetworkInfo Network Info to be deallocated * @return Error code indicating success/failure * @note * @author mabubakr * @date 1 Mar 2012 * @version 1.0 */ s32 DeallocateNetworkInfo(tstrNetworkInfo *pstrNetworkInfo) { s32 s32Error = 0; if (pstrNetworkInfo != NULL) { if (pstrNetworkInfo->pu8IEs != NULL) { kfree(pstrNetworkInfo->pu8IEs); pstrNetworkInfo->pu8IEs = NULL; } else { s32Error = -EFAULT; } kfree(pstrNetworkInfo); pstrNetworkInfo = NULL; } else { s32Error = -EFAULT; } return s32Error; } /** * @brief parses the received Association Response frame * @details * @param[in] pu8Buffer The Association Response frame to be parsed * @param[out] ppstrConnectRespInfo pointer to pointer to the structure containing the parsed Association Response Info * @return Error code indicating success/failure * @note * @author mabubakr * @date 2 Apr 2012 * @version 1.0 */ s32 ParseAssocRespInfo(u8 *pu8Buffer, u32 u32BufferLen, tstrConnectRespInfo **ppstrConnectRespInfo) { s32 s32Error = 0; tstrConnectRespInfo *pstrConnectRespInfo = NULL; u16 u16AssocRespLen = 0; u8 *pu8IEs = NULL; u16 u16IEsLen = 0; pstrConnectRespInfo = kzalloc(sizeof(tstrConnectRespInfo), GFP_KERNEL); if (!pstrConnectRespInfo) return -ENOMEM; /* u16AssocRespLen = pu8Buffer[0]; */ u16AssocRespLen = (u16)u32BufferLen; /* get the status code */ pstrConnectRespInfo->u16ConnectStatus = get_asoc_status(pu8Buffer); if (pstrConnectRespInfo->u16ConnectStatus == SUCCESSFUL_STATUSCODE) { /* get the capability */ pstrConnectRespInfo->u16capability = get_assoc_resp_cap_info(pu8Buffer); /* get the Association ID */ pstrConnectRespInfo->u16AssocID = get_asoc_id(pu8Buffer); /* get the Information Elements */ pu8IEs = &pu8Buffer[CAP_INFO_LEN + STATUS_CODE_LEN + AID_LEN]; u16IEsLen = u16AssocRespLen - (CAP_INFO_LEN + STATUS_CODE_LEN + AID_LEN); pstrConnectRespInfo->pu8RespIEs = kmemdup(pu8IEs, u16IEsLen, GFP_KERNEL); if (!pstrConnectRespInfo->pu8RespIEs) return -ENOMEM; pstrConnectRespInfo->u16RespIEsLen = u16IEsLen; } *ppstrConnectRespInfo = pstrConnectRespInfo; return s32Error; } /** * @brief Deallocates the parsed Association Response Info * @details * @param[in] pstrNetworkInfo Network Info to be deallocated * @return Error code indicating success/failure * @note * @author mabubakr * @date 2 Apr 2012 * @version 1.0 */ s32 DeallocateAssocRespInfo(tstrConnectRespInfo *pstrConnectRespInfo) { s32 s32Error = 0; if (pstrConnectRespInfo != NULL) { if (pstrConnectRespInfo->pu8RespIEs != NULL) { kfree(pstrConnectRespInfo->pu8RespIEs); pstrConnectRespInfo->pu8RespIEs = NULL; } else { s32Error = -EFAULT; } kfree(pstrConnectRespInfo); pstrConnectRespInfo = NULL; } else { s32Error = -EFAULT; } return s32Error; } /** * @brief sends certain Configuration Packet based on the input WIDs pstrWIDs * using driver config layer * * @details * @param[in] pstrWIDs WIDs to be sent in the configuration packet * @param[in] u32WIDsCount number of WIDs to be sent in the configuration packet * @param[out] pu8RxResp The received Packet Response * @param[out] ps32RxRespLen Length of the received Packet Response * @return Error code indicating success/failure * @note * @author mabubakr * @date 1 Mar 2012 * @version 1.0 */ s32 send_config_pkt(u8 mode, struct wid *wids, u32 count, u32 drv) { s32 counter = 0, ret = 0; if (mode == GET_CFG) { for (counter = 0; counter < count; counter++) { PRINT_INFO(CORECONFIG_DBG, "Sending CFG packet [%d][%d]\n", !counter, (counter == count - 1)); if (!wilc_wlan_cfg_get(!counter, wids[counter].id, (counter == count - 1), drv)) { ret = -1; printk("[Sendconfigpkt]Get Timed out\n"); break; } } counter = 0; for (counter = 0; counter < count; counter++) { wids[counter].size = wilc_wlan_cfg_get_val( wids[counter].id, wids[counter].val, wids[counter].size); } } else if (mode == SET_CFG) { for (counter = 0; counter < count; counter++) { PRINT_D(CORECONFIG_DBG, "Sending config SET PACKET WID:%x\n", wids[counter].id); if (!wilc_wlan_cfg_set(!counter, wids[counter].id, wids[counter].val, wids[counter].size, (counter == count - 1), drv)) { ret = -1; printk("[Sendconfigpkt]Set Timed out\n"); break; } } } return ret; }