#include #include #include "FreeRTOS.h" #include #include #include #include int iw_ioctl(const char * ifname, unsigned long request, struct iwreq * pwrq) { memcpy(pwrq->ifr_name, ifname, 5); return rltk_wlan_control(request, (void *) pwrq); } int wext_get_ssid(const char *ifname, __u8 *ssid) { struct iwreq iwr; int ret = 0; memset(&iwr, 0, sizeof(iwr)); iwr.u.essid.pointer = ssid; iwr.u.essid.length = 32; if (iw_ioctl(ifname, SIOCGIWESSID, &iwr) < 0) { #if defined(CONFIG_EXAMPLE_BT_CONFIG) && (CONFIG_EXAMPLE_BT_CONFIG!=1) printf("\n\rioctl[SIOCGIWESSID] ssid = NULL, not connected"); //do not use perror #endif ret = -1; } else { ret = iwr.u.essid.length; if (ret > 32) ret = 32; /* Some drivers include nul termination in the SSID, so let's * remove it here before further processing. WE-21 changes this * to explicitly require the length _not_ to include nul * termination. */ if (ret > 0 && ssid[ret - 1] == '\0') ret--; ssid[ret] = '\0'; } return ret; } int wext_set_ssid(const char *ifname, const __u8 *ssid, __u16 ssid_len) { struct iwreq iwr; int ret = 0; memset(&iwr, 0, sizeof(iwr)); iwr.u.essid.pointer = (void *) ssid; iwr.u.essid.length = ssid_len; iwr.u.essid.flags = (ssid_len != 0); if (iw_ioctl(ifname, SIOCSIWESSID, &iwr) < 0) { printf("\n\rioctl[SIOCSIWESSID] error"); ret = -1; } return ret; } int wext_set_bssid(const char *ifname, const __u8 *bssid) { struct iwreq iwr; int ret = 0; memset(&iwr, 0, sizeof(iwr)); iwr.u.ap_addr.sa_family = ARPHRD_ETHER; memcpy(iwr.u.ap_addr.sa_data, bssid, ETH_ALEN); if(bssid[ETH_ALEN]=='#' && bssid[ETH_ALEN + 1]=='@'){ memcpy(iwr.u.ap_addr.sa_data + ETH_ALEN, bssid + ETH_ALEN, 6); } if (iw_ioctl(ifname, SIOCSIWAP, &iwr) < 0) { printf("\n\rioctl[SIOCSIWAP] error"); ret = -1; } return ret; } int wext_get_bssid(const char*ifname, __u8 *bssid) { struct iwreq iwr; int ret = 0; memset(&iwr, 0, sizeof(iwr)); if (iw_ioctl(ifname, SIOCGIWAP, &iwr) < 0) { printf("\n\rioctl[SIOCSIWAP] error"); ret = -1; } else { memcpy(bssid, iwr.u.ap_addr.sa_data, ETH_ALEN); } return ret; } int is_broadcast_ether_addr(const unsigned char *addr) { return (addr[0] & addr[1] & addr[2] & addr[3] & addr[4] & addr[5]) == 0xff; } int wext_set_auth_param(const char *ifname, __u16 idx, __u32 value) { struct iwreq iwr; int ret = 0; memset(&iwr, 0, sizeof(iwr)); iwr.u.param.flags = idx & IW_AUTH_INDEX; iwr.u.param.value = value; if (iw_ioctl(ifname, SIOCSIWAUTH, &iwr) < 0) { printf("\n\rWEXT: SIOCSIWAUTH(param %d value 0x%x) failed)", idx, value); } return ret; } int wext_set_mfp_support(const char *ifname, __u8 value) { int ret = 0; struct iwreq iwr; memset(&iwr, 0, sizeof(iwr)); iwr.u.param.value = value; if (iw_ioctl(ifname, SIOCSIWMFP, &iwr) < 0) { RTW_API_INFO(("\n\rWEXT: SIOCSIWMFP(value 0x%x) failed)", value)); } return ret; } #ifdef CONFIG_SAE_SUPPORT int wext_set_group_id(const char *ifname, __u8 value) { int ret = 0; struct iwreq iwr; memset(&iwr, 0, sizeof(iwr)); iwr.u.param.value = value; if (iw_ioctl(ifname, SIOCSIWGRPID, &iwr) < 0) { RTW_API_INFO(("\n\rWEXT: SIOCSIWGRPID(value 0x%x) failed)", value)); } return ret; } extern u8 rtw_cmd_tsk_spt_wap3; int wext_set_support_wpa3(__u8 enable) { rtw_cmd_tsk_spt_wap3 = enable; return 0; } __u8 wext_get_support_wpa3(void) { return rtw_cmd_tsk_spt_wap3; } #endif #ifdef CONFIG_PMKSA_CACHING int wext_set_pmk_cache_enable(const char *ifname, __u8 value) { int ret = 0; struct iwreq iwr; memset(&iwr, 0, sizeof(iwr)); iwr.u.param.value = value; if (iw_ioctl(ifname, SIOCSIWPMKSA, &iwr) < 0) { RTW_API_INFO(("\n\rWEXT: SIOCSIWPMKSA(value 0x%x) failed)", value)); } return ret; } #endif int wext_set_key_ext(const char *ifname, __u16 alg, const __u8 *addr, int key_idx, int set_tx, const __u8 *seq, __u16 seq_len, __u8 *key, __u16 key_len) { struct iwreq iwr; int ret = 0; struct iw_encode_ext *ext; ext = (struct iw_encode_ext *) malloc(sizeof(struct iw_encode_ext) + key_len); if (ext == NULL) return -1; else memset(ext, 0, sizeof(struct iw_encode_ext) + key_len); memset(&iwr, 0, sizeof(iwr)); iwr.u.encoding.flags = key_idx + 1; iwr.u.encoding.flags |= IW_ENCODE_TEMP; iwr.u.encoding.pointer = ext; iwr.u.encoding.length = sizeof(struct iw_encode_ext) + key_len; if (alg == IW_ENCODE_DISABLED) iwr.u.encoding.flags |= IW_ENCODE_DISABLED; if (addr == NULL || is_broadcast_ether_addr(addr)) ext->ext_flags |= IW_ENCODE_EXT_GROUP_KEY; if (set_tx) ext->ext_flags |= IW_ENCODE_EXT_SET_TX_KEY; ext->addr.sa_family = ARPHRD_ETHER; if (addr) memcpy(ext->addr.sa_data, addr, ETH_ALEN); else memset(ext->addr.sa_data, 0xff, ETH_ALEN); if (key && key_len) { memcpy(ext->key, key, key_len); ext->key_len = key_len; } ext->alg = alg; if (seq && seq_len) { ext->ext_flags |= IW_ENCODE_EXT_RX_SEQ_VALID; memcpy(ext->rx_seq, seq, seq_len); } if (iw_ioctl(ifname, SIOCSIWENCODEEXT, &iwr) < 0) { ret = -2; printf("\n\rioctl[SIOCSIWENCODEEXT] set key fail"); } free(ext); return ret; } int wext_get_enc_ext(const char *ifname, __u16 *alg, __u8 *key_idx, __u8 *passphrase) { struct iwreq iwr; int ret = 0; struct iw_encode_ext *ext; ext = (struct iw_encode_ext *) malloc(sizeof(struct iw_encode_ext) + 16); if (ext == NULL) return -1; else memset(ext, 0, sizeof(struct iw_encode_ext) + 16); iwr.u.encoding.pointer = ext; if (iw_ioctl(ifname, SIOCGIWENCODEEXT, &iwr) < 0) { printf("\n\rioctl[SIOCGIWENCODEEXT] error"); ret = -1; } else { *alg = ext->alg; if(key_idx) *key_idx = (__u8)iwr.u.encoding.flags; if(passphrase) memcpy(passphrase, ext->key, ext->key_len); } if(ext != NULL) free(ext); return ret; } int wext_get_auth_type(const char *ifname, __u32 *auth_type) { struct iwreq iwr; int ret = 0; memset(&iwr, 0, sizeof(iwr)); if (iw_ioctl(ifname, SIOCGIWAUTH, &iwr) < 0) { printf("\n\rioctl[SIOCGIWAUTH] error"); ret = -1; }else{ *auth_type = (__u32) iwr.u.param.value; } return ret; } int wext_set_passphrase(const char *ifname, const __u8 *passphrase, __u16 passphrase_len) { struct iwreq iwr; int ret = 0; memset(&iwr, 0, sizeof(iwr)); iwr.u.passphrase.pointer = (void *) passphrase; iwr.u.passphrase.length = passphrase_len; iwr.u.passphrase.flags = (passphrase_len != 0); if (iw_ioctl(ifname, SIOCSIWPRIVPASSPHRASE, &iwr) < 0) { printf("\n\rioctl[SIOCSIWESSID+0x1f] error"); ret = -1; } return ret; } int wext_get_passphrase(const char *ifname, __u8 *passphrase) { struct iwreq iwr; int ret = 0; memset(&iwr, 0, sizeof(iwr)); iwr.u.passphrase.pointer = (void *) passphrase; if (iw_ioctl(ifname, SIOCGIWPRIVPASSPHRASE, &iwr) < 0) { printf("\n\rioctl[SIOCGIWPRIVPASSPHRASE] error"); ret = -1; } else { ret = iwr.u.passphrase.length; passphrase[ret] = '\0'; } return ret; } #if 0 int wext_set_mac_address(const char *ifname, char * mac) { char buf[13+17+1]; rtw_memset(buf, 0, sizeof(buf)); snprintf(buf, 13+17, "write_mac %s", mac); return wext_private_command(ifname, buf, 0); } int wext_get_mac_address(const char *ifname, char * mac) { int ret = 0; char buf[32]; rtw_memset(buf, 0, sizeof(buf)); rtw_memcpy(buf, "read_mac", 8); ret = wext_private_command_with_retval(ifname, buf, buf, 32); strcpy(mac, buf); return ret; } #endif int wext_enable_powersave(const char *ifname, __u8 ips_mode, __u8 lps_mode) { struct iwreq iwr; int ret = 0; __u16 pindex = 0; __u8 *para = NULL; int cmd_len = 0; memset(&iwr, 0, sizeof(iwr)); cmd_len = sizeof("pm_set"); // Encode parameters as TLV (type, length, value) format para = pvPortMalloc( 7 + (1+1+1) + (1+1+1) ); if(para == NULL) return -1; snprintf((char*)para, cmd_len, "pm_set"); pindex = 7; para[pindex++] = 0; // type 0 for ips para[pindex++] = 1; para[pindex++] = ips_mode; para[pindex++] = 1; // type 1 for lps para[pindex++] = 1; para[pindex++] = lps_mode; iwr.u.data.pointer = para; iwr.u.data.length = pindex; if (iw_ioctl(ifname, SIOCDEVPRIVATE, &iwr) < 0) { printf("\n\rioctl[SIOCSIWPRIVAPESSID] error"); ret = -1; } vPortFree(para); return ret; } int wext_disable_powersave(const char *ifname) { struct iwreq iwr; int ret = 0; __u16 pindex = 0; __u8 *para = NULL; int cmd_len = 0; memset(&iwr, 0, sizeof(iwr)); cmd_len = sizeof("pm_set"); // Encode parameters as TLV (type, length, value) format para = pvPortMalloc( 7 + (1+1+1) + (1+1+1) ); if(para == NULL) return -1; snprintf((char*)para, cmd_len, "pm_set"); pindex = 7; para[pindex++] = 0; // type 0 for ips para[pindex++] = 1; para[pindex++] = 0; // ips = 0 para[pindex++] = 1; // type 1 for lps para[pindex++] = 1; para[pindex++] = 0; // lps = 0 iwr.u.data.pointer = para; iwr.u.data.length = pindex; if (iw_ioctl(ifname, SIOCDEVPRIVATE, &iwr) < 0) { printf("\n\rioctl[SIOCSIWPRIVAPESSID] error"); ret = -1; } vPortFree(para); return ret; } int wext_set_tdma_param(const char *ifname, __u8 slot_period, __u8 rfon_period_len_1, __u8 rfon_period_len_2, __u8 rfon_period_len_3) { struct iwreq iwr; int ret = 0; __u16 pindex = 0; __u8 *para = NULL; int cmd_len = 0; memset(&iwr, 0, sizeof(iwr)); cmd_len = sizeof("pm_set"); // Encode parameters as TLV (type, length, value) format para = pvPortMalloc( 7 + (1+1+4) ); snprintf((char*)para, cmd_len, "pm_set"); pindex = 7; para[pindex++] = 2; // type 2 tdma param para[pindex++] = 4; para[pindex++] = slot_period; para[pindex++] = rfon_period_len_1; para[pindex++] = rfon_period_len_2; para[pindex++] = rfon_period_len_3; iwr.u.data.pointer = para; iwr.u.data.length = pindex; if (iw_ioctl(ifname, SIOCDEVPRIVATE, &iwr) < 0) { printf("\n\rioctl[SIOCSIWPRIVAPESSID] error"); ret = -1; } vPortFree(para); return ret; } int wext_set_lps_dtim(const char *ifname, __u8 lps_dtim) { struct iwreq iwr; int ret = 0; __u16 pindex = 0; __u8 *para = NULL; int cmd_len = 0; memset(&iwr, 0, sizeof(iwr)); cmd_len = sizeof("pm_set"); // Encode parameters as TLV (type, length, value) format para = pvPortMalloc( 7 + (1+1+1) ); snprintf((char*)para, cmd_len, "pm_set"); pindex = 7; para[pindex++] = 3; // type 3 lps dtim para[pindex++] = 1; para[pindex++] = lps_dtim; iwr.u.data.pointer = para; iwr.u.data.length = pindex; if (iw_ioctl(ifname, SIOCDEVPRIVATE, &iwr) < 0) { printf("\n\rioctl[SIOCSIWPRIVAPESSID] error"); ret = -1; } vPortFree(para); return ret; } int wext_get_lps_dtim(const char *ifname, __u8 *lps_dtim) { struct iwreq iwr; int ret = 0; __u16 pindex = 0; __u8 *para = NULL; int cmd_len = 0; memset(&iwr, 0, sizeof(iwr)); cmd_len = sizeof("pm_get"); // Encode parameters as TLV (type, length, value) format para = pvPortMalloc( 7 + (1+1+1) ); snprintf((char*)para, cmd_len, "pm_get"); pindex = 7; para[pindex++] = 3; // type 3 for lps dtim para[pindex++] = 1; para[pindex++] = 0; iwr.u.data.pointer = para; iwr.u.data.length = pindex; if (iw_ioctl(ifname, SIOCDEVPRIVATE, &iwr) < 0) { printf("\n\rioctl[SIOCSIWPRIVAPESSID] error"); ret = -1; goto exit; } //get result at the beginning of iwr.u.data.pointer if((para[0]==3)&&(para[1]==1)) *lps_dtim = para[2]; else printf("\n\r%s error", __func__); exit: vPortFree(para); return ret; } int wext_set_tos_value(const char *ifname, __u8 *tos_value) { struct iwreq iwr; int ret = 0; __u8 *para = NULL; int cmd_len = sizeof("set_tos_value"); memset(&iwr, 0, sizeof(iwr)); para = pvPortMalloc(cmd_len + 4); snprintf((char*)para, cmd_len, "set_tos_value"); if(*tos_value >= 0 && *tos_value <=32){ *(para + cmd_len) = 0x4f; *(para + cmd_len+1) = 0xa4; *(para + cmd_len+2) = 0; *(para + cmd_len+3) = 0; } else if(*tos_value > 32 && *tos_value <=96){ *(para + cmd_len) = 0x2b; *(para + cmd_len+1) = 0xa4; *(para + cmd_len+2) = 0; *(para + cmd_len+3) = 0; } else if(*tos_value > 96 && *tos_value <= 160){ *(para + cmd_len) = 0x22; *(para + cmd_len+1) = 0x43; *(para + cmd_len+2) = 0x5e; *(para + cmd_len+3) = 0; } else if(*tos_value > 160){ *(para + cmd_len) = 0x22; *(para + cmd_len+1) = 0x32; *(para + cmd_len+2) = 0x2f; *(para + cmd_len+3) = 0; } iwr.u.data.pointer = para; iwr.u.data.length = cmd_len + 4; if (iw_ioctl(ifname, SIOCDEVPRIVATE, &iwr) < 0) { printf("\n\rwext_set_tos_value():ioctl[SIOCDEVPRIVATE] error"); ret = -1; } vPortFree(para); return ret; } int wext_get_tx_power(const char *ifname, __u8 *poweridx) { struct iwreq iwr; int ret = 0; __u8 *para = NULL; int cmd_len = sizeof("get_tx_power"); memset(&iwr, 0, sizeof(iwr)); //Tx power size : 20 Bytes //CCK 1M,2M,5.5M,11M : 4 Bytes //OFDM 6M, 9M, 12M, 18M, 24M, 36M 48M, 54M : 8 Bytes //MCS 0~7 : 8 Bytes para = pvPortMalloc(cmd_len + 20); snprintf((char*)para, cmd_len, "get_tx_power"); iwr.u.data.pointer = para; iwr.u.data.length = cmd_len + 20; if (iw_ioctl(ifname, SIOCDEVPRIVATE, &iwr) < 0) { printf("\n\rwext_get_tx_power():ioctl[SIOCDEVPRIVATE] error"); ret = -1; } memcpy(poweridx,(__u8 *)(iwr.u.data.pointer),20); vPortFree(para); return ret; } #if 0 int wext_set_txpower(const char *ifname, int poweridx) { int ret = 0; char buf[24]; rtw_memset(buf, 0, sizeof(buf)); snprintf(buf, 24, "txpower patha=%d", poweridx); ret = wext_private_command(ifname, buf, 0); return ret; } int wext_get_associated_client_list(const char *ifname, void * client_list_buffer, uint16_t buffer_length) { int ret = 0; char buf[25]; rtw_memset(buf, 0, sizeof(buf)); snprintf(buf, 25, "get_client_list %x", client_list_buffer); ret = wext_private_command(ifname, buf, 0); return ret; } int wext_get_ap_info(const char *ifname, rtw_bss_info_t * ap_info, rtw_security_t* security) { int ret = 0; char buf[24]; rtw_memset(buf, 0, sizeof(buf)); snprintf(buf, 24, "get_ap_info %x", ap_info); ret = wext_private_command(ifname, buf, 0); snprintf(buf, 24, "get_security"); ret = wext_private_command_with_retval(ifname, buf, buf, 24); sscanf(buf, "%d", security); return ret; } #endif int wext_set_mode(const char *ifname, int mode) { struct iwreq iwr; int ret = 0; memset(&iwr, 0, sizeof(iwr)); iwr.u.mode = mode; if (iw_ioctl(ifname, SIOCSIWMODE, &iwr) < 0) { printf("\n\rioctl[SIOCSIWMODE] error"); ret = -1; } return ret; } int wext_get_mode(const char *ifname, int *mode) { struct iwreq iwr; int ret = 0; memset(&iwr, 0, sizeof(iwr)); if (iw_ioctl(ifname, SIOCGIWMODE, &iwr) < 0) { printf("\n\rioctl[SIOCGIWMODE] error"); ret = -1; } else *mode = iwr.u.mode; return ret; } int wext_set_ap_ssid(const char *ifname, const __u8 *ssid, __u16 ssid_len) { struct iwreq iwr; int ret = 0; if(ssid_len > 32){ printf("Error: SSID should be 0-32 characters\r\n"); return RTW_BADARG; } memset(&iwr, 0, sizeof(iwr)); iwr.u.essid.pointer = (void *) ssid; iwr.u.essid.length = ssid_len; iwr.u.essid.flags = (ssid_len != 0); if (iw_ioctl(ifname, SIOCSIWPRIVAPESSID, &iwr) < 0) { printf("\n\rioctl[SIOCSIWPRIVAPESSID] error"); ret = -1; } return ret; } int wext_set_country(const char *ifname, rtw_country_code_t country_code) { struct iwreq iwr; int ret = 0; memset(&iwr, 0, sizeof(iwr)); iwr.u.param.value = country_code; if (iw_ioctl(ifname, SIOCSIWPRIVCOUNTRY, &iwr) < 0) { printf("\n\rioctl[SIOCSIWPRIVCOUNTRY] error"); ret = -1; } return ret; } int wext_get_rssi(const char *ifname, int *rssi) { struct iwreq iwr; int ret = 0; memset(&iwr, 0, sizeof(iwr)); if (iw_ioctl(ifname, SIOCGIWSENS, &iwr) < 0) { printf("\n\rioctl[SIOCGIWSENS] error"); ret = -1; } else { *rssi = 0 - iwr.u.sens.value; } return ret; } int wext_get_bcn_rssi(const char *ifname, int *rssi) { struct iwreq iwr; int ret = 0; memset(&iwr, 0, sizeof(iwr)); if (iw_ioctl(ifname, SIOCGIWBCNSENS, &iwr) < 0) { printf("\n\rioctl[SIOCGIWBCNSENS] error"); ret = -1; } else { *rssi = 0 - iwr.u.bcnsens.value; } return ret; } int wext_get_snr(const char *ifname, int *snr) { struct iwreq iwr; int ret = 0; memset(&iwr, 0, sizeof(iwr)); if (iw_ioctl(ifname, SIOCGIWSNR, &iwr) < 0) { printf("\n\rioctl[SIOCGIWSNR] error"); ret = -1; } else { *snr = iwr.u.snr.value; } return ret; } int wext_set_pscan_channel(const char *ifname, __u8 *ch, __u8 *pscan_config, __u8 length) { struct iwreq iwr; int ret = 0; __u8 *para = NULL; int i =0; memset(&iwr, 0, sizeof(iwr)); //Format of para:function_name num_channel chan1... pscan_config1 ... para = pvPortMalloc((length + length + 1) + 12);//size:num_chan + num_time + length + function_name if(para == NULL) return -1; //Cmd snprintf((char*)para, 12, "PartialScan"); //length *(para+12) = length; for(i = 0; i < length; i++){ *(para + 13 + i)= *(ch + i); *(para + 13 + length + i)= *(pscan_config + i); } iwr.u.data.pointer = para; iwr.u.data.length = (length + length + 1) + 12; if (iw_ioctl(ifname, SIOCDEVPRIVATE, &iwr) < 0) { printf("\n\rwext_set_pscan_channel():ioctl[SIOCDEVPRIVATE] error"); ret = -1; } vPortFree(para); return ret; } int wext_set_channel(const char *ifname, __u8 ch) { struct iwreq iwr; int ret = 0; memset(&iwr, 0, sizeof(iwr)); iwr.u.freq.m = 0; iwr.u.freq.e = 0; iwr.u.freq.i = ch; if (iw_ioctl(ifname, SIOCSIWFREQ, &iwr) < 0) { printf("\n\rioctl[SIOCSIWFREQ] error"); ret = -1; } return ret; } int wext_get_channel(const char *ifname, __u8 *ch) { struct iwreq iwr; int ret = 0; memset(&iwr, 0, sizeof(iwr)); if (iw_ioctl(ifname, SIOCGIWFREQ, &iwr) < 0) { printf("\n\rioctl[SIOCGIWFREQ] error"); ret = -1; } else *ch = iwr.u.freq.i; return ret; } int wext_register_multicast_address(const char *ifname, rtw_mac_t *mac) { int ret = 0; char buf[32]; rtw_memset(buf, 0, sizeof(buf)); snprintf(buf, 32, "reg_multicast "MAC_FMT, MAC_ARG(mac->octet)); ret = wext_private_command(ifname, buf, 0); return ret; } int wext_unregister_multicast_address(const char *ifname, rtw_mac_t *mac) { int ret = 0; char buf[35]; rtw_memset(buf, 0, sizeof(buf)); snprintf(buf, 35, "reg_multicast -d "MAC_FMT, MAC_ARG(mac->octet)); ret = wext_private_command(ifname, buf, 0); return ret; } int wext_set_scan(const char *ifname, char *buf, __u16 buf_len, __u16 flags) { struct iwreq iwr; int ret = 0; memset(&iwr, 0, sizeof(iwr)); #if 0 //for scan_with_ssid if(buf) memset(buf, 0, buf_len); #endif iwr.u.data.pointer = buf; iwr.u.data.flags = flags; iwr.u.data.length = buf_len; if (iw_ioctl(ifname, SIOCSIWSCAN, &iwr) < 0) { printf("\n\rioctl[SIOCSIWSCAN] error"); ret = -1; } return ret; } int wext_get_scan(const char *ifname, char *buf, __u16 buf_len) { struct iwreq iwr; int ret = 0; iwr.u.data.pointer = buf; iwr.u.data.length = buf_len; if (iw_ioctl(ifname, SIOCGIWSCAN, &iwr) < 0) { printf("\n\rioctl[SIOCGIWSCAN] error"); ret = -1; }else ret = iwr.u.data.flags; return ret; } int wext_private_command_with_retval(const char *ifname, char *cmd, char *ret_buf, int ret_len) { struct iwreq iwr; int ret = 0, buf_size; char *buf; buf_size = 128; if(strlen(cmd) >= buf_size) buf_size = strlen(cmd) + 1; // 1 : '\0' buf = (char*)pvPortMalloc(buf_size); if(!buf){ printf("\n\rWEXT: Can't malloc memory"); return -1; } memset(buf, 0, buf_size); strcpy(buf, cmd); memset(&iwr, 0, sizeof(iwr)); iwr.u.data.pointer = buf; iwr.u.data.length = buf_size; iwr.u.data.flags = 0; if ((ret = iw_ioctl(ifname, SIOCDEVPRIVATE, &iwr)) < 0) { printf("\n\rioctl[SIOCDEVPRIVATE] error. ret=%d\n", ret); } if(ret_buf){ if(ret_len > iwr.u.data.length) ret_len = iwr.u.data.length; rtw_memcpy(ret_buf, (char *) iwr.u.data.pointer, ret_len); } vPortFree(buf); return ret; } int wext_private_command(const char *ifname, char *cmd, int show_msg) { struct iwreq iwr; int ret = 0, buf_size; char *buf; u8 cmdname[17] = {0}; // IFNAMSIZ+1 sscanf(cmd, "%16s", cmdname); if((strcmp((const char *)cmdname, "config_get") == 0) || (strcmp((const char *)cmdname, "config_set") == 0) || (strcmp((const char *)cmdname, "efuse_get") == 0) || (strcmp((const char *)cmdname, "efuse_set") == 0) || (strcmp((const char *)cmdname, "mp_psd") == 0)) buf_size = 2600;//2600 for config_get rmap,0,512 (or realmap) else buf_size = 512; if(strlen(cmd) >= buf_size) buf_size = strlen(cmd) + 1; // 1 : '\0' buf = (char*)pvPortMalloc(buf_size); if(!buf){ printf("\n\rWEXT: Can't malloc memory"); return -1; } memset(buf, 0, buf_size); strcpy(buf, cmd); memset(&iwr, 0, sizeof(iwr)); iwr.u.data.pointer = buf; iwr.u.data.length = buf_size; iwr.u.data.flags = 0; if ((ret = iw_ioctl(ifname, SIOCDEVPRIVATE, &iwr)) < 0) { printf("\n\rioctl[SIOCDEVPRIVATE] error. ret=%d\n", ret); } if (show_msg && iwr.u.data.length) { if(iwr.u.data.length > buf_size) printf("\n\rWEXT: Malloc memory is not enough"); printf("\n\rPrivate Message: %s", (char *) iwr.u.data.pointer); } vPortFree(buf); return ret; } void wext_wlan_indicate(unsigned int cmd, union iwreq_data *wrqu, char *extra) { unsigned char null_mac[6] = {0}; switch(cmd) { case SIOCGIWAP: if(wrqu->ap_addr.sa_family == ARPHRD_ETHER) { if(!memcmp(wrqu->ap_addr.sa_data, null_mac, sizeof(null_mac))) wifi_indication(WIFI_EVENT_DISCONNECT, wrqu->ap_addr.sa_data, sizeof(null_mac)+ 2, 0); else wifi_indication(WIFI_EVENT_CONNECT, wrqu->ap_addr.sa_data, sizeof(null_mac), 0); } break; case IWEVCUSTOM: if(extra) { if(!memcmp(IW_EXT_STR_FOURWAY_DONE, extra, strlen(IW_EXT_STR_FOURWAY_DONE))) wifi_indication(WIFI_EVENT_FOURWAY_HANDSHAKE_DONE, extra, strlen(IW_EXT_STR_FOURWAY_DONE), 0); else if(!memcmp(IW_EXT_STR_RECONNECTION_FAIL, extra, strlen(IW_EXT_STR_RECONNECTION_FAIL))) wifi_indication(WIFI_EVENT_RECONNECTION_FAIL, extra, strlen(IW_EXT_STR_RECONNECTION_FAIL), 0); else if(!memcmp(IW_EVT_STR_NO_NETWORK, extra, strlen(IW_EVT_STR_NO_NETWORK))) wifi_indication(WIFI_EVENT_NO_NETWORK, extra, strlen(IW_EVT_STR_NO_NETWORK), 0); else if(!memcmp(IW_EVT_STR_ICV_ERROR, extra, strlen(IW_EVT_STR_ICV_ERROR))) wifi_indication(WIFI_EVENT_ICV_ERROR, extra, strlen(IW_EVT_STR_ICV_ERROR), 0); else if(!memcmp(IW_EVT_STR_CHALLENGE_FAIL, extra, strlen(IW_EVT_STR_CHALLENGE_FAIL))) wifi_indication(WIFI_EVENT_CHALLENGE_FAIL, extra, strlen(IW_EVT_STR_CHALLENGE_FAIL), 0); #if CONFIG_ENABLE_P2P || defined(CONFIG_AP_MODE) else if(!memcmp(IW_EVT_STR_STA_ASSOC, extra, strlen(IW_EVT_STR_STA_ASSOC))) wifi_indication(WIFI_EVENT_STA_ASSOC, wrqu->data.pointer, wrqu->data.length, 0); else if(!memcmp(IW_EVT_STR_STA_DISASSOC, extra, strlen(IW_EVT_STR_STA_DISASSOC))) wifi_indication(WIFI_EVENT_STA_DISASSOC, wrqu->addr.sa_data, sizeof(null_mac), 0); else if(!memcmp(IW_EVT_STR_SEND_ACTION_DONE, extra, strlen(IW_EVT_STR_SEND_ACTION_DONE))) wifi_indication(WIFI_EVENT_SEND_ACTION_DONE, NULL, 0, wrqu->data.flags); #endif } break; case SIOCGIWSCAN: if(wrqu->data.pointer == NULL) wifi_indication(WIFI_EVENT_SCAN_DONE, NULL, 0, 0); else wifi_indication(WIFI_EVENT_SCAN_RESULT_REPORT, wrqu->data.pointer, wrqu->data.length, 0); break; case IWEVMGNTRECV: wifi_indication(WIFI_EVENT_RX_MGNT, wrqu->data.pointer, wrqu->data.length, wrqu->data.flags); break; #ifdef REPORT_STA_EVENT case IWEVREGISTERED: if(wrqu->addr.sa_family == ARPHRD_ETHER) wifi_indication(WIFI_EVENT_STA_ASSOC, wrqu->addr.sa_data, sizeof(null_mac), 0); break; case IWEVEXPIRED: if(wrqu->addr.sa_family == ARPHRD_ETHER) wifi_indication(WIFI_EVENT_STA_DISASSOC, wrqu->addr.sa_data, sizeof(null_mac), 0); break; #endif default: break; } } int wext_send_eapol(const char *ifname, char *buf, __u16 buf_len, __u16 flags) { struct iwreq iwr; int ret = 0; memset(&iwr, 0, sizeof(iwr)); iwr.u.data.pointer = buf; iwr.u.data.length = buf_len; iwr.u.data.flags = flags; if (iw_ioctl(ifname, SIOCSIWEAPOLSEND, &iwr) < 0) { printf("\n\rioctl[SIOCSIWEAPOLSEND] error"); ret = -1; } return ret; } int wext_send_mgnt(const char *ifname, char *buf, __u16 buf_len, __u16 flags) { struct iwreq iwr; int ret = 0; memset(&iwr, 0, sizeof(iwr)); iwr.u.data.pointer = buf; iwr.u.data.length = buf_len; iwr.u.data.flags = flags; if (iw_ioctl(ifname, SIOCSIWMGNTSEND, &iwr) < 0) { printf("\n\rioctl[SIOCSIWMGNTSEND] error"); ret = -1; } return ret; } int wext_set_gen_ie(const char *ifname, char *buf, __u16 buf_len, __u16 flags) { struct iwreq iwr; int ret = 0; memset(&iwr, 0, sizeof(iwr)); iwr.u.data.pointer = buf; iwr.u.data.length = buf_len; iwr.u.data.flags = flags; if (iw_ioctl(ifname, SIOCSIWGENIE, &iwr) < 0) { printf("\n\rioctl[SIOCSIWGENIE] error"); ret = -1; } return ret; } int wext_set_autoreconnect(const char *ifname, __u8 mode, __u8 retry_times, __u16 timeout) { struct iwreq iwr; int ret = 0; __u8 *para = NULL; int cmd_len = 0; memset(&iwr, 0, sizeof(iwr)); cmd_len = sizeof("SetAutoRecnt"); para = pvPortMalloc((4) + cmd_len);//size:para_len+cmd_len if(para == NULL) return -1; //Cmd snprintf((char*)para, cmd_len, "SetAutoRecnt"); //length *(para+cmd_len) = mode; //para1 *(para+cmd_len+1) = retry_times; //para2 *(para+cmd_len+2) = timeout; //para3 iwr.u.data.pointer = para; iwr.u.data.length = (4) + cmd_len; if (iw_ioctl(ifname, SIOCDEVPRIVATE, &iwr) < 0) { printf("\n\rwext_set_autoreconnect():ioctl[SIOCDEVPRIVATE] error"); ret = -1; } vPortFree(para); return ret; } int wext_get_autoreconnect(const char *ifname, __u8 *mode) { struct iwreq iwr; int ret = 0; __u8 *para = NULL; int cmd_len = 0; memset(&iwr, 0, sizeof(iwr)); cmd_len = sizeof("GetAutoRecnt"); para = pvPortMalloc(cmd_len);//size:para_len+cmd_len //Cmd snprintf((char*)para, cmd_len, "GetAutoRecnt"); //length iwr.u.data.pointer = para; iwr.u.data.length = cmd_len; if (iw_ioctl(ifname, SIOCDEVPRIVATE, &iwr) < 0) { printf("\n\rwext_get_autoreconnect():ioctl[SIOCDEVPRIVATE] error"); ret = -1; } *mode = *(__u8 *)(iwr.u.data.pointer); vPortFree(para); return ret; } int wext_get_drv_ability(const char *ifname, __u32 *ability) { int ret = 0; char * buf = (char *)rtw_zmalloc(33); if(buf == NULL) return -1; snprintf(buf, 33, "get_drv_ability %x", ability); ret = wext_private_command(ifname, buf, 0); rtw_free(buf); return ret; } #ifdef CONFIG_CUSTOM_IE int wext_add_custom_ie(const char *ifname, void *cus_ie, int ie_num) { struct iwreq iwr; int ret = 0; __u8 *para = NULL; int cmd_len = 0; if(ie_num <= 0 || !cus_ie){ printf("\n\rwext_add_custom_ie():wrong parameter"); ret = -1; return ret; } memset(&iwr, 0, sizeof(iwr)); cmd_len = sizeof("SetCusIE"); para = pvPortMalloc((4)* 2 + cmd_len);//size:addr len+cmd_len if(para == NULL) return -1; //Cmd snprintf(para, cmd_len, "SetCusIE"); //addr length *(__u32 *)(para + cmd_len) = (__u32)cus_ie; //ie addr //ie_num *(__u32 *)(para + cmd_len + 4) = ie_num; //num of ie iwr.u.data.pointer = para; iwr.u.data.length = (4)* 2 + cmd_len;// 2 input if (iw_ioctl(ifname, SIOCDEVPRIVATE, &iwr) < 0) { printf("\n\rwext_add_custom_ie():ioctl[SIOCDEVPRIVATE] error"); ret = -1; } vPortFree(para); return ret; } int wext_update_custom_ie(const char *ifname, void * cus_ie, int ie_index) { struct iwreq iwr; int ret = 0; __u8 *para = NULL; int cmd_len = 0; if(ie_index <= 0 || !cus_ie){ printf("\n\rwext_update_custom_ie():wrong parameter"); ret = -1; return ret; } memset(&iwr, 0, sizeof(iwr)); cmd_len = sizeof("UpdateIE"); para = pvPortMalloc((4)* 2 + cmd_len);//size:addr len+cmd_len if(para == NULL) return -1; //Cmd snprintf(para, cmd_len, "UpdateIE"); //addr length *(__u32 *)(para + cmd_len) = (__u32)cus_ie; //ie addr //ie_index *(__u32 *)(para + cmd_len + 4) = ie_index; //num of ie iwr.u.data.pointer = para; iwr.u.data.length = (4)* 2 + cmd_len;// 2 input if (iw_ioctl(ifname, SIOCDEVPRIVATE, &iwr) < 0) { printf("\n\rwext_update_custom_ie():ioctl[SIOCDEVPRIVATE] error"); ret = -1; } vPortFree(para); return ret; } int wext_del_custom_ie(const char *ifname) { struct iwreq iwr; int ret = 0; __u8 *para = NULL; int cmd_len = 0; memset(&iwr, 0, sizeof(iwr)); cmd_len = sizeof("DelIE"); para = pvPortMalloc(cmd_len);//size:addr len+cmd_len //Cmd snprintf(para, cmd_len, "DelIE"); iwr.u.data.pointer = para; iwr.u.data.length = cmd_len; if (iw_ioctl(ifname, SIOCDEVPRIVATE, &iwr) < 0) { printf("\n\rwext_del_custom_ie():ioctl[SIOCDEVPRIVATE] error"); ret = -1; } vPortFree(para); return ret; } #endif #ifdef CONFIG_AP_MODE int wext_enable_forwarding(const char *ifname) { struct iwreq iwr; int ret = 0; __u8 *para = NULL; int cmd_len = 0; memset(&iwr, 0, sizeof(iwr)); cmd_len = sizeof("forwarding_set"); para = pvPortMalloc(cmd_len + 1); if(para == NULL) return -1; // forwarding_set 1 snprintf((char *) para, cmd_len, "forwarding_set"); *(para + cmd_len) = '1'; iwr.u.essid.pointer = para; iwr.u.essid.length = cmd_len + 1; if (iw_ioctl(ifname, SIOCDEVPRIVATE, &iwr) < 0) { printf("\n\rwext_enable_forwarding(): ioctl[SIOCDEVPRIVATE] error"); ret = -1; } vPortFree(para); return ret; } int wext_disable_forwarding(const char *ifname) { struct iwreq iwr; int ret = 0; __u8 *para = NULL; int cmd_len = 0; memset(&iwr, 0, sizeof(iwr)); cmd_len = sizeof("forwarding_set"); para = pvPortMalloc(cmd_len + 1); if(para == NULL) return -1; // forwarding_set 0 snprintf((char *) para, cmd_len, "forwarding_set"); *(para + cmd_len) = '0'; iwr.u.essid.pointer = para; iwr.u.essid.length = cmd_len + 1; if (iw_ioctl(ifname, SIOCDEVPRIVATE, &iwr) < 0) { printf("\n\rwext_disable_forwarding(): ioctl[SIOCDEVPRIVATE] error"); ret = -1; } vPortFree(para); return ret; } #endif #ifdef CONFIG_CONCURRENT_MODE int wext_set_ch_deauth(const char *ifname, __u8 enable) { int ret = 0; char * buf = (char *)rtw_zmalloc(16); if(buf == NULL) return -1; snprintf(buf, 16, "SetChDeauth %d", enable); ret = wext_private_command(ifname, buf, 0); rtw_free(buf); return ret; } #endif int wext_set_adaptivity(rtw_adaptivity_mode_t adaptivity_mode) { extern u8 rtw_adaptivity_en; extern u8 rtw_adaptivity_mode; switch(adaptivity_mode){ case RTW_ADAPTIVITY_NORMAL: rtw_adaptivity_en = 1; // enable adaptivity rtw_adaptivity_mode = RTW_ADAPTIVITY_MODE_NORMAL; break; case RTW_ADAPTIVITY_CARRIER_SENSE: rtw_adaptivity_en = 1; // enable adaptivity rtw_adaptivity_mode = RTW_ADAPTIVITY_MODE_CARRIER_SENSE; break; case RTW_ADAPTIVITY_DISABLE: default: rtw_adaptivity_en = 0; //disable adaptivity break; } return 0; } int wext_set_adaptivity_th_l2h_ini(__u8 l2h_threshold) { extern s8 rtw_adaptivity_th_l2h_ini; rtw_adaptivity_th_l2h_ini = (__s8)l2h_threshold; return 0; } int wext_set_trp_tis(__u8 enable) { extern u8 rtw_tx_pwr_lmt_enable; extern u8 rtw_tx_pwr_by_rate; extern u8 rtw_trp_tis_test_en; if(enable != RTW_TRP_TIS_DISABLE){ //close the tx power limit and pwr by rate incase the efficiency of Antenna is not good enough. rtw_tx_pwr_lmt_enable = 2;//set 0 to disable, set 2 to use efuse value rtw_tx_pwr_by_rate = 2;//set 0 to disable, set 2 to use efuse value if(enable == RTW_TRP_TIS_NORMAL){ //disable some dynamic mechanism rtw_trp_tis_test_en = BIT0; }else if(enable == RTW_TRP_TIS_DYNAMIC){ rtw_trp_tis_test_en = BIT1 | BIT0; }else if(enable == RTW_TRP_TIS_FIX_ACK_RATE){ rtw_trp_tis_test_en = BIT2 | BIT0; } //you can change autoreconnct mode to RTW_AUTORECONNECT_INFINITE in init_thread function } return 0; } #if defined(CONFIG_WLAN_LOW_PW) extern void rtw_enable_wlan_low_pwr_mode(WLAN_LOW_PW_MODE mode); void wext_set_low_power_mode(__u8 enable) { extern WLAN_LOW_PW_MODE rtw_wlan_low_pw_mode; extern int rtw_wlan_low_pw_mode4_c1; extern int rtw_wlan_low_pw_mode4_c2; extern int rtw_reduce_pa_gain; if(enable == ENABLE){ rtw_wlan_low_pw_mode = PW_MODE_1|PW_MODE_2|PW_MODE_3|PW_MODE_4|PW_MODE_6; rtw_wlan_low_pw_mode4_c1 = 24; rtw_wlan_low_pw_mode4_c2 = 16; rtw_reduce_pa_gain = 1; //0:not reduce, 1:reduce 2, 2:reduce 3 rtw_enable_wlan_low_pwr_mode(rtw_wlan_low_pw_mode); } } #endif extern int rltk_get_auto_chl(const char *ifname, unsigned char *channel_set, unsigned char channel_num); int wext_get_auto_chl(const char *ifname, unsigned char *channel_set, unsigned char channel_num) { int ret = -1; int channel = 0; wext_disable_powersave(ifname); if((channel = rltk_get_auto_chl(ifname,channel_set,channel_num)) != 0 ) ret = channel ; wext_enable_powersave(ifname, 1, 1); return ret; } extern int rltk_set_sta_num(unsigned char ap_sta_num); int wext_set_sta_num(unsigned char ap_sta_num) { return rltk_set_sta_num(ap_sta_num); } extern int rltk_del_station(const char *ifname, unsigned char* hwaddr); int wext_del_station(const char *ifname, unsigned char* hwaddr) { return rltk_del_station(ifname, hwaddr); } extern struct list_head *mf_list_head; int wext_init_mac_filter(void) { if(mf_list_head != NULL){ return -1; } mf_list_head = malloc(sizeof(struct list_head)); if(mf_list_head == NULL){ printf("\n\r[ERROR] %s : can't allocate mf_list_head",__func__); return -1; } INIT_LIST_HEAD(mf_list_head); return 0; } int wext_deinit_mac_filter(void) { if(mf_list_head == NULL){ return -1; } struct list_head *iterator; rtw_mac_filter_list_t *item; list_for_each(iterator, mf_list_head) { item = list_entry(iterator, rtw_mac_filter_list_t, node); list_del(iterator); free(item); item = NULL; iterator = mf_list_head; } free(mf_list_head); mf_list_head = NULL; return 0; } int wext_add_mac_filter(unsigned char* hwaddr) { if(mf_list_head == NULL){ return -1; } rtw_mac_filter_list_t *mf_list_new; mf_list_new = malloc(sizeof(rtw_mac_filter_list_t)); if(mf_list_new == NULL){ printf("\n\r[ERROR] %s : can't allocate mf_list_new",__func__); return -1; } memcpy(mf_list_new->mac_addr,hwaddr,6); list_add(&(mf_list_new->node), mf_list_head); return 0; } int wext_del_mac_filter(unsigned char* hwaddr) { if(mf_list_head == NULL){ return -1; } struct list_head *iterator; rtw_mac_filter_list_t *item; list_for_each(iterator, mf_list_head) { item = list_entry(iterator, rtw_mac_filter_list_t, node); if(memcmp(item->mac_addr,hwaddr,6) == 0){ list_del(iterator); free(item); item = NULL; return 0; } } return -1; } extern void rtw_set_indicate_mgnt(int enable); void wext_set_indicate_mgnt(int enable) { rtw_set_indicate_mgnt(enable); return; } void wext_set_sigstat_fast_enable(int enable) { // TODO: doesn't exist in lib_wlan // rtw_set_sigstat_fast_enable(enable); return; } void wext_set_lowrssi_use_b(int enable,int rssi) { // TODO: doesn't exist in lib_wlan // rtw_set_lowrssi_use_b(enable,rssi); return ; } #ifdef CONFIG_AP_MODE extern void rltk_stop_softap(const char *ifname); extern void rltk_suspend_softap(const char *ifname); extern void rltk_suspend_softap_beacon(const char *ifname); void wext_stop_softap(const char *ifname) { rltk_stop_softap(ifname); } void wext_suspend_softap(const char *ifname) { rltk_suspend_softap(ifname); } void wext_suspend_softap_beacon(const char *ifname) { rltk_suspend_softap_beacon(ifname); } void wext_resume_softap(const char *ifname) { // TODO: doesn't exist in lib_wlan // rltk_resume_softap(ifname); } // extern int rtw_ap_switch_chl_and_inform(unsigned char new_channel); int wext_ap_switch_chl_and_inform(unsigned char new_channel) { // TODO: doesn't exist in lib_wlan // if(rtw_ap_switch_chl_and_inform(new_channel)) return RTW_SUCCESS; // else // return RTW_ERROR; } #endif extern int rltk_get_nhm_ratio_level(const char *ifname, __u32 * level); int wext_get_nhm_ratio_level(const char *ifname, __u32 *level) { int ret = -1; wext_disable_powersave(ifname); ret = rltk_get_nhm_ratio_level(ifname, level); wext_enable_powersave(ifname, 1, 1); return ret; } extern int rltk_get_retry_drop_num(const char *ifname, rtw_fw_retry_drop_t * retry); int wext_get_retry_drop_num(const char *ifname, rtw_fw_retry_drop_t * retry) { return rltk_get_retry_drop_num(ifname, retry); } extern int rltk_get_sw_trx_statistics(const char *ifname, rtw_net_device_stats_t *stats); int wext_get_sw_trx_statistics(const char *ifname, rtw_net_device_stats_t *stats) { return rltk_get_sw_trx_statistics(ifname, stats); } #ifndef CONFIG_MCC_STA_AP_MODE extern int rtw_get_RxInfo(const char *ifname,u8* BeaconCnt, int *rssi, u8* CurIGValue, u32* Fa_Ofdm_count, u32* Fa_Cck_count); int wext_get_RxInfo(const char *ifname, __u8* BeaconCnt, int *rssi, __u8* CurIGValue, __u32* Fa_Ofdm_count, __u32* Fa_Cck_count) { return rtw_get_RxInfo(ifname, BeaconCnt, rssi, CurIGValue, Fa_Ofdm_count, Fa_Cck_count); } extern int rtw_get_RxCrcInfo(const char *ifname, u32* CCK_Crc_Fail, u32* CCK_Crc_OK, u32* OFDM_Crc_Fail, u32* OFDM_Crc_OK, u32* HT_Crc_Fail, u32* HT_Crc_OK); int wext_get_RxCrcInfo(const char *ifname, __u32* CCK_Crc_Fail, __u32* CCK_Crc_OK, __u32* OFDM_Crc_Fail, __u32* OFDM_Crc_OK, __u32* HT_Crc_Fail, __u32* HT_Crc_OK) { return rtw_get_RxCrcInfo(ifname, CCK_Crc_Fail, CCK_Crc_OK, OFDM_Crc_Fail, OFDM_Crc_OK, HT_Crc_Fail, HT_Crc_OK); } extern int rtw_get_TxInfo(const char *ifname, u32 *tx_ok, u32 *tx_retry, u32 *tx_drop); int wext_get_TxInfo(const char *ifname, __u32 *tx_ok, __u32 *tx_retry, __u32 *tx_drop) { return rtw_get_TxInfo(ifname, tx_ok, tx_retry, tx_drop); } extern int rtw_get_PSInfo(const char *ifname, u32* tim_wake_up_count); int wext_get_PSInfo(const char *ifname, __u32* tim_wake_up_count) { return rtw_get_PSInfo(ifname, tim_wake_up_count); } #endif #ifdef CONFIG_SYNCPKT int wext_set_syncpkt_da(const char *ifname, __u8 *da) { struct iwreq iwr; int ret = 0; memset(&iwr, 0, sizeof(iwr)); iwr.u.data.pointer = da; iwr.u.data.length= 6; if (iw_ioctl(ifname, SIOCSIWSYNCDASET, &iwr) < 0) { printf("\n\rioctl[SIOCSIWSYNCDASET] error"); ret = -1; } return ret; } int wext_send_syncpkt(const char *ifname, __u8 flag, __u8 pktnum, __u8 interval) { struct iwreq iwr; int ret = 0; memset(&iwr, 0, sizeof(iwr)); iwr.u.param.flags = pktnum; iwr.u.param.fixed = interval; iwr.u.param.disabled = flag; if (iw_ioctl(ifname, SIOCSIWSYNCSET, &iwr) < 0) { printf("\n\rioctl[SIOCSIWSYNCSET] error"); ret = -1; } return ret; } int wext_disable_fw_ips(const char *ifname, __u8 enable) { struct iwreq iwr; int ret = 0; memset(&iwr, 0, sizeof(iwr)); iwr.u.param.flags = enable; if (iw_ioctl(ifname, SIOCSIWSYNCFWIPS, &iwr) < 0) { printf("\n\rioctl[SIOCSIWSYNCFWIPS] error"); ret = -1; } return ret; } #endif /** * \brief This function can set adaptivity enable value in runtime. * * \param ifname "wlan0" / "wlan1" * \param value 0 diable, 1 enable * \return 0 success, others fail */ int wext_set_adaptivity_enable(const char *ifname, __u8 value) { int ret = 0; struct iwreq iwr; memset(&iwr, 0, sizeof(iwr)); iwr.u.param.value = value; if (iw_ioctl(ifname, SIOCSIWPRIVADAPTIVITY, &iwr) < 0) { printf("\n\rwext_set_adaptivity_enable():ioctl[SIOCSIWPRIVADAPTIVITY] error"); ret = -1; } return ret; } extern u8 rtw_get_adaptivity_enable(const char *ifname); /** * \brief This function can get adaptivity enable value in use. * * \param ifname "wlan0" / "wlan1" * \return 0 disable, 1 enable */ __u8 wext_get_adaptivity_enable(const char *ifname) { return rtw_get_adaptivity_enable(ifname); } extern int rtw_set_adaptivity_mode(const char *ifname, u8 mode); /** * \brief This function can set adaptivity mode in runtime. * * \param ifname "wlan0" / "wlan1" * \param mode 0 RTW_ADAPTIVITY_NORMAL, 1 RTW_ADAPTIVITY_CARRIER_SENSE * \return 0 success, others fail */ int wext_set_adaptivity_mode(const char *ifname, __u8 mode) { return rtw_set_adaptivity_mode(ifname, mode); } extern u8 rtw_get_adaptivity_mode(const char *ifname); /** * \brief This function can get adaptivity mode in use. * * \param ifname "wlan0" / "wlan1" * \return 0 RTW_ADAPTIVITY_NORMAL, 1 RTW_ADAPTIVITY_CARRIER_SENSE */ __u8 wext_get_adaptivity_mode(const char *ifname) { return rtw_get_adaptivity_mode(ifname); } extern u8 rtw_get_channel_plan(const char *ifname); /** * \brief This function can get channel plan in use. * * \param ifname "wlan0" / "wlan1" * \return refer to enum _RT_CHANNEL_DOMAIN, RT_CHANNEL_DOMAIN_WORLD_NULL = 0x20, RT_CHANNEL_DOMAIN_ETSI1_NULL = 0x21 etc. */ __u8 wext_get_channel_plan(const char *ifname) { return rtw_get_channel_plan(ifname); }