/* * wifi_api.c * * Created on: 01/11/2017 * Author: pvvx */ #include #include "rtl8195a.h" #include "drv_types.h" #include #include "FreeRTOS.h" #if 1 #include "drv_types.h" // or #include "wlan_lib.h" #else #include "wifi_constants.h" #include "wifi_structures.h" //#include "wlan_lib.h" // or #include "drv_types.h" #endif #if CONFIG_EXAMPLE_WLAN_FAST_CONNECT #error "Udnef CONFIG_EXAMPLE_WLAN_FAST_CONNECT!" #endif #ifndef USE_FLASH_EEP #error "Define USE_FLASH_EEP!" #endif #include "task.h" #include #include #include "flash_api.h" #include #include "dhcp/dhcps.h" #include "ethernetif.h" #if CONFIG_ETHERNET #include "ethernet_mii/ethernet_mii.h" #endif #include "flash_eep.h" #include "feep_config.h" #include "wifi_api.h" #include "main.h" #include "wifi_user_set.h" #if 0 #undef debug_printf #define debug_printf(fmt, ...) rtl_printf(fmt, ##__VA_ARGS__) #undef info_printf #define info_printf(fmt, ...) rtl_printf(fmt, ##__VA_ARGS__) #undef warning_printf #define warning_printf(fmt, ...) rtl_printf(fmt, ##__VA_ARGS__) #undef error_printf #define error_printf(fmt, ...) rtl_printf(fmt, ##__VA_ARGS__) #endif #if defined(CONFIG_ENABLE_WPS_AP) && CONFIG_ENABLE_WPS_AP extern void cmd_ap_wps(int argc, char **argv); extern int wpas_wps_dev_config(u8 *dev_addr, u8 bregistrar); #endif //CONFIG_WPS_AP //========================================= //--- Wlan Config Init------------------- WIFI_CONFIG wifi_cfg = { .mode = DEF_WIFI_MODE, // rtw_mode_t .adaptivity = DEF_WIFI_ADAPTIVITY, // rtw_adaptivity_mode_t .country_code = DEF_WIFI_COUNTRY,// rtw_country_code_t .tx_pwr = DEF_WIFI_TX_PWR, // rtw_tx_pwr_percentage_t .bgn = DEF_WIFI_BGN, // rtw_network_mode_t .load_flg = DEF_LOAD_CFG, .save_flg = DEF_SAVE_CFG }; //---- Interface 0 - wlan0 - AP - init --- SOFTAP_CONFIG wifi_ap_cfg = { .ssid = DEF_AP_SSID, .password = DEF_AP_PASSWORD, .security = (unsigned char)DEF_AP_SECURITY, // RTW_SECURITY_WPA2_AES_PSK or RTW_SECURITY_OPEN .beacon_interval = DEF_AP_BEACON, .channel = DEF_AP_CHANNEL, .ssid_hidden = 0, .max_sta = DEF_WIFI_AP_STATIONS // Max number of STAs, should be 1..3, default is 3 }; DHCP_CONFIG wifi_ap_dhcp = { .ip = DEF_AP_IP, .mask = DEF_AP_MSK, .gw = DEF_AP_GW, .mode = 2 }; //---- Interface 1 - wlan1 - ST - init --- STATION_CONFIG wifi_st_cfg = { .ssid = DEF_ST_SSID, .password = DEF_ST_PASSWORD, .bssid = DEF_ST_BSSID, .flg = DEF_ST_USE_BSSID, .security = DEF_ST_SECURITY, .autoreconnect = DEF_ST_AUTORECONNECT, .reconnect_pause = DEF_ST_RECONNECT_PAUSE, .sleep = DEF_ST_SLEEP, .dtim = DEF_ST_LPS_DTIM }; DHCP_CONFIG wifi_st_dhcp = { .ip = DEF_ST_IP, .mask = DEF_ST_MSK, .gw = DEF_ST_GW, .mode = 1 }; unsigned char wifi_run_mode = RTW_MODE_NONE; // rtw_mode_t unsigned char wifi_st_status; typedef int (*wlan_init_done_ptr)(void); typedef int (*write_reconnect_ptr)(uint8_t *data, uint32_t len); //Function #if CONFIG_AUTO_RECONNECT extern void (*p_wlan_autoreconnect_hdl)(rtw_security_t, char*, int, char*, int, int); #endif extern wlan_init_done_ptr p_wlan_init_done_callback; //extern write_reconnect_ptr p_write_reconnect_ptr; extern struct netif xnetif[NET_IF_NUM]; extern uint8_t rtw_power_percentage_idx; extern Rltk_wlan_t rltk_wlan_info[2]; // in wrapper.h #define PARM_RECONNECT 1 struct wifi_autoreconnect_param { #if PARM_RECONNECT rtw_security_t security_type; int key_id; #else rtw_security_t security_type; char *ssid; int ssid_len; char *password; int password_len; int key_id; #endif }; struct wifi_autoreconnect_param wifi_autoreconnect; typedef struct _feep_element { uint16 id; uint16 size; void * obj; } FEEP_ELEMENT, *PFEEP_ELEMENT; FEEP_ELEMENT feep_tab[] = { { FEEP_ID_WIFI_AP_CFG, sizeof(wifi_ap_cfg), &wifi_ap_cfg }, // Bit0 BID_WIFI_AP_CFG { FEEP_ID_WIFI_ST_CFG, sizeof(wifi_st_cfg), &wifi_st_cfg }, // Bit1 BID_WIFI_ST_CFG { FEEP_ID_AP_DHCP_CFG, sizeof(wifi_ap_dhcp), &wifi_ap_dhcp }, // Bit2 BID_AP_DHCP_CFG { FEEP_ID_ST_DHCP_CFG, sizeof(wifi_st_dhcp), &wifi_st_dhcp }, // Bit3 BID_ST_DHCP_CFG { FEEP_ID_WIFI_CFG, sizeof(wifi_cfg), &wifi_cfg }, // Bit4 BID_WIFI_CFG { FEEP_ID_AP_HOSTNAME, LWIP_NETIF_HOSTNAME_SIZE, &lwip_host_name[1] }, // Bit5 BID_AP_HOSTNAME { FEEP_ID_ST_HOSTNAME, LWIP_NETIF_HOSTNAME_SIZE, &lwip_host_name[0] }, // Bit5 BID_ST_HOSTNAME { 0, 0, NULL } }; uint32 read_wifi_cfg(uint32 flg) { uint32 ret = 0; PFEEP_ELEMENT p = feep_tab; for(int m = 1; m && p->id != 0; m <<= 1, p++) { if((flg & m) && flash_read_cfg(p->obj, p->id, p->size) < p->size) { ret |= m; }; }; return ret; } uint32 write_wifi_cfg(uint32 flg) { uint32 ret = 0; PFEEP_ELEMENT p = feep_tab; for(int m = 1; m && p->id != 0; m <<= 1, p++) { if(flg & m) { if(!flash_write_cfg(p->obj, p->id, p->size)) { ret |= m; }; }; }; return ret; } #if CONFIG_WLAN_CONNECT_CB _WEAK void connect_start(void) { info_printf("%s: Time at start %d ms.\n", __func__, xTaskGetTickCount()); } _WEAK void connect_close(void) { info_printf("%s: Time at start %d ms.\n", __func__, xTaskGetTickCount()); } #endif #ifdef NOT_USE_CALLS LOCAL int wlan_init_done_callback(void) { printf("WiFi Init after %d ms\n", xTaskGetTickCount()); return 0; } #endif // #ifdef NOT_USE_CALLS //char wlan_st_name[] = WLAN0_NAME; char wlan_st_name[] = WLAN0_NAME; char wlan_ap_name[] = WLAN1_NAME; unsigned char wlan_st_netifn = 0; unsigned char wlan_ap_netifn = 1; uint32 get_new_ip(void) { if(!(wifi_cfg.mode ^ wifi_run_mode)) { return current_netif->ip_addr.addr; } else if(wifi_cfg.mode == RTW_MODE_AP) { return wifi_ap_dhcp.ip; } else if(wifi_st_dhcp.mode == 2) { return wifi_st_dhcp.ip; } return 0; } uint8 * get_new_hostname(void) { if(!(wifi_cfg.mode ^ wifi_run_mode)) { return current_netif->hostname; } else if(wifi_cfg.mode == RTW_MODE_AP) { return lwip_host_name[1]; }; return lwip_host_name[0]; } LOCAL uint8 chk_ap_netif_num(void) { if (wifi_mode == RTW_MODE_AP) { wlan_st_name[4] = '1'; wlan_ap_name[4] = '0'; wlan_st_netifn = 1; wlan_ap_netifn = 0; } else { // if (wifi_mode == RTW_MODE_STA) { wlan_st_name[4] = '0'; wlan_ap_name[4] = '1'; wlan_st_netifn = 0; wlan_ap_netifn = 1; } return wlan_ap_netifn; } extern Rltk_wlan_t rltk_wlan_info[2]; // in wrapper.h /*LOCAL _adapter * get_padaptern(int num) { if(rltk_wlan_info[num].enable) { return *(_adapter **)((rltk_wlan_info[0].dev)->priv); } return NULL; };*/ #define get_padaptern(num) (*(_adapter **)((rltk_wlan_info[num].dev)->priv)); rtw_result_t _wext_set_lps_dtim(int adapter_num, uint8 lps_dtim ) { _adapter * pad = get_padaptern(adapter_num); rtw_result_t ret = RTW_ERROR; if(pad) { ret = rtw_pm_set_lps_dtim(pad, lps_dtim); } return ret; } int _wext_get_lps_dtim(int adapter_num) { _adapter * pad = get_padaptern(adapter_num); return rtw_pm_get_lps_dtim(pad); } rtw_result_t _wext_enable_powersave(int adapter_num, uint8 ips_mode, uint8 lps_mode) { _adapter * pad = get_padaptern(adapter_num); rtw_result_t ret = RTW_ERROR; if(pad) { ret = rtw_pm_set_ips(pad, ips_mode); // 2 режима 1,2 ? if(ret == RTW_SUCCESS) { LeaveAllPowerSaveMode(pad); ret = rtw_pm_set_lps(pad, lps_mode); } } return ret; } LOCAL int _wext_cmp_ssid(int adapter_num, unsigned char *ssid) { _adapter * pad = get_padaptern(adapter_num); int ret = 0; if((pad != NULL) && (pad->mlmepriv.fw_state & 0x41) != 0) { int len = pad->mlmepriv.cur_network.network.Ssid.SsidLength; if(len < 32) len++; else len = 32; ret = (rtl_memcmp(ssid, &pad->mlmepriv.cur_network.network.Ssid.Ssid, len) == 0); debug_printf("%d s[%d]'%s'\n", pad->mlmepriv.fw_state, len, ssid); } return ret; } #ifdef NOT_USE_CALLS LOCAL rtw_result_t _wext_get_mode(int adapter_num, int *mode) { _adapter * pad = get_padaptern(adapter_num); rtw_result_t ret = RTW_ERROR; if(pad) { uint16 f = pad->mlmepriv.fw_state; if(f & 8) *mode = 2; else if(f & 0x60) *mode = 1; else if(!(f & 0x10)) *mode = 0; else *mode = 3; ret = RTW_SUCCESS; } return ret; } LOCAL rtw_result_t _wext_get_channel(int adapter_num, uint8 *ch) { _adapter * pad = get_padaptern(adapter_num); rtw_result_t ret = RTW_ERROR; if(pad) { if(pad->mlmepriv.fw_state & 1) { *ch = pad->mlmepriv.htpriv.ch_offset; } else { *ch = pad->mlmeextpriv.cur_channel; } ret = RTW_SUCCESS; } return ret; } #endif // #ifdef NOT_USE_CALLS LOCAL rtw_result_t wifi_run_ap(void) { rtw_result_t ret = RTW_NOTAP; if( (wifi_mode == RTW_MODE_AP) || (wifi_mode == RTW_MODE_STA_AP) ){ info_printf("Starting AP (%s, netif%d)...\n", wlan_ap_name, wlan_ap_netifn); /* netif_set_addr(&xnetif[WLAN_AP_NETIF_NUM], &wifi_ap_dhcp.ip, &wifi_ap_dhcp.mask, &wifi_ap_dhcp.gw); */ if(wext_set_sta_num(wifi_ap_cfg.max_sta) != 0) { // Max number of STAs, should be 1..3, default is 3 error_printf("AP not set max connections %d!\n", wifi_ap_cfg.max_sta); }; #if defined(CONFIG_ENABLE_WPS_AP) && CONFIG_ENABLE_WPS_AP // todo: ветка не доделана wpas_wps_dev_config(xnetif[WLAN_AP_NETIF_NUM].hwaddr, 1); #endif //CONFIG_WPS_AP if(wifi_ap_cfg.channel == 0 || wifi_ap_cfg.channel > 14) { wifi_ap_cfg.channel = 1; } ret = wifi_start_ap(wifi_ap_cfg.ssid, //char *ssid, wifi_ap_cfg.security, //rtw_security_t ecurity_type, wifi_ap_cfg.password, //char *password, wifi_ap_cfg.channel, //int channel wifi_ap_cfg.ssid_hidden); // // wifi_run_mode |= RTW_MODE_AP; if (ret != RTW_SUCCESS) { error_printf("Error(%d): Start AP failed!\n\n", ret);; } else { int timeout = wifi_test_timeout_ms / wifi_test_timeout_step_ms; while (1) { #if 1 if (_wext_cmp_ssid(WLAN_AP_NETIF_NUM, wifi_ap_cfg.ssid )) { #else char essid[33]; if ((wext_get_ssid(wlan_ap_name, (unsigned char *) essid) > 0) &&(strcmp((const char * ) essid, (const char * )wifi_ap_cfg.ssid) == 0)) { #endif #ifdef CONFIG_DONT_CARE_TP pnetiff->flags |= NETIF_FLAG_IPSWITCH; #endif if(wifi_ap_dhcp.mode) { #if defined(DEF_AP_DHCP_START) && defined(DEF_AP_DHCP_STOP) dhcps_ip4addr_pool_start = DEF_AP_DHCP_START; dhcps_ip4addr_pool_end = DEF_AP_DHCP_STOP; #endif dhcps_init(&xnetif[WLAN_AP_NETIF_NUM]); }; info_printf("AP '%s' started after %d ms\n", wifi_ap_cfg.ssid, xTaskGetTickCount()); show_wifi_ap_ip(); if(wifi_cfg.save_flg & (BID_WIFI_AP_CFG | BID_AP_DHCP_CFG)) write_wifi_cfg(wifi_cfg.save_flg & (BID_WIFI_AP_CFG | BID_AP_DHCP_CFG)); ret = RTW_SUCCESS; #if CONFIG_WLAN_CONNECT_CB // extern void connect_start(void); connect_start(); #endif break; } if (timeout == 0) { error_printf("Start AP timeout!\n"); ret = RTW_TIMEOUT; break; } vTaskDelay(wifi_test_timeout_step_ms / portTICK_RATE_MS); timeout--; } } } return ret; } LOCAL rtw_result_t StartStDHCPClient(void) { debug_printf("Start DHCPClient...\n"); int ret = RTW_SUCCESS; struct netif * pnetif = &xnetif[WLAN_ST_NETIF_NUM]; DHCP_CONFIG *p = (DHCP_CONFIG *)&wifi_st_dhcp; unsigned char mode = p->mode; if(mode == 2 && p->ip != IP4ADDR(255,255,255,255) && p->ip != IP4ADDR(0,0,0,0)) { // fixed ip netif_set_addr(pnetif, (ip_addr_t *)&p->ip, (ip_addr_t *)&p->mask, (ip_addr_t *)&p->gw); } else if(mode) { // DHCP On UBaseType_t savePriority = uxTaskPriorityGet(NULL); /* If not rise priority, LwIP DHCP may timeout */ vTaskPrioritySet(NULL, tskIDLE_PRIORITY + 3); /* Start DHCP Client */ ret = LwIP_DHCP(WLAN_ST_NETIF_NUM, DHCP_START); vTaskPrioritySet(NULL, savePriority); if (ret == DHCP_ADDRESS_ASSIGNED) { p->ip = pnetif->ip_addr.addr; p->gw = pnetif->gw.addr; p->mask = pnetif->netmask.addr; if(mode > 2) { // 3+ Auto fix p->mode = 2; // fixed ip write_wifi_cfg(BID_ST_DHCP_CFG); } ret = RTW_SUCCESS; } else { debug_printf("LwIP_DHCP ret=%d\n", ret); ret = RTW_ERROR; } } if(ret == RTW_SUCCESS) { show_wifi_st_ip(); wifi_st_status = WIFI_STA_CONNECTED; #if CONFIG_WLAN_CONNECT_CB // extern void connect_start(void); connect_start(); #endif } return ret; } LOCAL void wifi_autoreconnect_thread_(void *param) { int ret = RTW_ERROR; struct wifi_autoreconnect_param *reconnect_param = (struct wifi_autoreconnect_param *) param; printf("auto reconnect ...\n"); wifi_st_status = WIFI_STA_RECONNECT; ret = wifi_connect( wifi_st_cfg.bssid, wifi_st_cfg.flg, #if PARM_RECONNECT wifi_st_cfg.ssid, reconnect_param->security_type, wifi_st_cfg.password, #else reconnect_param->ssid, reconnect_param->security_type, reconnect_param->password, #endif reconnect_param->key_id, NULL); if (ret == RTW_SUCCESS) { if(wifi_cfg.save_flg & BID_WIFI_ST_CFG) write_wifi_cfg(BID_WIFI_ST_CFG); // Start DHCPClient StartStDHCPClient(); } vTaskDelete(NULL); } LOCAL void wifi_autoreconnect_hdl_(rtw_security_t security_type, char *ssid, int ssid_len, char *password, int password_len, int key_id) { wifi_autoreconnect.security_type = security_type; wifi_autoreconnect.key_id = key_id; #if PARM_RECONNECT==0 wifi_autoreconnect.ssid = ssid; wifi_autoreconnect.password = password; #endif _adapter * ad = *(_adapter **)((rltk_wlan_info[0].dev)->priv); if(ad->mlmeextpriv.reconnect_cnt == 255) { ad->mlmeextpriv.reconnect_cnt = 0; }; xTaskCreate(wifi_autoreconnect_thread_, (const char * )"st_recon", 400, &wifi_autoreconnect, tskIDLE_PRIORITY + 1, NULL); } LOCAL void st_set_autoreconnect(uint8 mode, uint8 count, uint16 timeout) { p_wlan_autoreconnect_hdl = wifi_autoreconnect_hdl_; _adapter * ad = *(_adapter **)((rltk_wlan_info[0].dev)->priv); ad->mlmeextpriv.reconnect_times = count; ad->mlmeextpriv.reconnect_timeout = timeout; ad->mlmeextpriv.reconnect_cnt = 0; ad->mlmeextpriv.auto_reconnect = (mode != 0); } LOCAL rtw_result_t wifi_run_st(void) { rtw_result_t ret = RTW_SUCCESS; // chk_ap_netif_num(); if((wifi_mode == RTW_MODE_STA) || (wifi_mode == RTW_MODE_STA_AP)) { #if CONFIG_AUTO_RECONNECT // p_wlan_autoreconnect_hdl = NULL; if (wifi_st_cfg.autoreconnect) { st_set_autoreconnect(1, wifi_st_cfg.autoreconnect, wifi_st_cfg.reconnect_pause); ret = wext_set_autoreconnect(WLAN0_NAME, 1, wifi_st_cfg.autoreconnect, wifi_st_cfg.reconnect_pause); if (ret != RTW_SUCCESS) warning_printf("ERROR: Operation failed! Error=%d\n", ret); } #endif info_printf("Connected to AP (%s, netif%d)...\n", wlan_st_name, wlan_st_netifn); ret = wifi_connect( wifi_st_cfg.bssid, wifi_st_cfg.flg, wifi_st_cfg.ssid, idx_to_rtw_security(wifi_st_cfg.security), wifi_st_cfg.password, -1, NULL); wifi_st_status = WIFI_STA_START; // wifi_run_mode |= RTW_MODE_STA; if (ret != RTW_SUCCESS) { error_printf("%s: Operation failed! Error(%d)\n", __func__, ret); } else { if(wifi_cfg.save_flg & BID_WIFI_ST_CFG) write_wifi_cfg(BID_WIFI_ST_CFG); // Start DHCPClient StartStDHCPClient(); } }; return ret; } LOCAL int _wifi_on(rtw_mode_t mode) { int ret = 0; /* if (!((rltk_wlan_running(WLAN0_IDX) == 0) && (rltk_wlan_running(WLAN1_IDX) == 0))) { warning_printf("WIFI is already running\n"); return 0; } */ info_printf("Initializing WIFI...\n"); uint8 devnum = (mode == RTW_MODE_STA_AP); // flag = 1 -> 2 netif wifi_mode = mode; chk_ap_netif_num(); // set wifi mib // extern uint8_t rtw_adaptivity_en; // rtw_adaptivity_en = 0; // wext_set_adaptivity(RTW_ADAPTIVITY_DISABLE); // rtw_adaptivity_mode_t wext_set_adaptivity(wifi_cfg.adaptivity & 3); debug_printf("Wlan0 init...\n"); ret = rltk_wlan_init(WLAN0_IDX, mode); // rtw_mode_t debug_printf("netif_set_up 0...\n"); netif_set_up(&xnetif[0]); if (ret < 0) return ret; if(devnum) { debug_printf("Wlan1 init...\n"); ret = rltk_wlan_init(WLAN1_IDX, mode); if (ret < 0) return ret; netif_set_up(&xnetif[1]); } else { netif_set_down(&xnetif[1]); } debug_printf("Wlan start...\n"); uint32 timeout = xTaskGetTickCount(); rltk_wlan_start(WLAN0_IDX); if(devnum) rltk_wlan_start(WLAN1_IDX); while (1) { if (rltk_wlan_running(WLAN0_IDX) && rltk_wlan_running(devnum) ) { //#if CONFIG_DEBUG_LOG > 2 debug_printf("WIFI initialized (%d ms)\n", xTaskGetTickCount() - timeout); //#endif break; } if(xTaskGetTickCount() - timeout > wifi_test_timeout_ms/portTICK_RATE_MS) { error_printf("WIFI init timeout!\n"); break; } vTaskDelay(wifi_test_timeout_step_ms / portTICK_RATE_MS); } return ret; } extern int lwip_init_done; LOCAL void _LwIP_Init(void) { if(!lwip_init_done) { int idx; debug_printf("LwIP Init (%d)\n", wifi_mode); /* Create tcp_ip stack thread */ tcpip_init( NULL, NULL ); // chk_ap_netif_num(); // Исполняется после _wifi_on() for(idx = 0; idx < NET_IF_NUM; idx++) { xnetif[idx].name[0] = 'r'; xnetif[idx].name[1] = '0' + idx; } netif_add(&xnetif[WLAN_ST_NETIF_NUM], (ip_addr_t *)&wifi_st_dhcp.ip, (ip_addr_t *)&wifi_st_dhcp.mask, (ip_addr_t *)&wifi_st_dhcp.gw, NULL, ðernetif_init, &tcpip_input); netif_add(&xnetif[WLAN_AP_NETIF_NUM], (ip_addr_t *)&wifi_ap_dhcp.ip, (ip_addr_t *)&wifi_ap_dhcp.mask, (ip_addr_t *)&wifi_ap_dhcp.gw, NULL, ðernetif_init, &tcpip_input); #if CONFIG_ETHERNET // && NET_IF_NUM > 2 { struct ip_addr ipaddr; struct ip_addr netmask; struct ip_addr gw; ipaddr.addr = DEF_EH_IP; netmask.addr = DEF_EH_MSK; gw.addr = DEF_EH_GW; netif_add(&xnetif[2], &ipaddr, &netmask, &gw, NULL, ðernetif_mii_init, &tcpip_input); } #endif /* Registers the default network interface. */ netif_set_default(&xnetif[0]); /* When the netif is fully configured this function must be called.*/ for(idx = 0; idx < NET_IF_NUM; idx++) { netif_set_up(&xnetif[idx]); } info_printf("interface %d is initialized\n", idx); lwip_init_done = 1; init_event_callback_list(); } } extern int rltk_set_tx_power_percentage(rtw_tx_pwr_percentage_t power_percentage_idx); int wifi_run(rtw_mode_t mode) { int ret = 0; #if CONFIG_DEBUG_LOG > 4 debug_printf("\n%s(%d), %d\n", __func__, mode, wifi_run_mode); debug_printf("old mode = %d, new mode = %d\n", wifi_run_mode, mode); #endif if(wifi_mode) { // != mode) { info_printf("Deinitializing WIFI ...\n"); wifi_off(); wifi_st_status = WIFI_STA_OFF; // wifi_run_mode = RTW_MODE_NONE; vTaskDelay(30); } if (mode != RTW_MODE_NONE) { if (_wifi_on(mode) < 0) { error_printf("Wifi On failed!\n"); goto error_end; }; /* if(wifi_cfg.adaptivity) wext_set_adaptivity(wifi_cfg.adaptivity & 3); */ if(wifi_set_country(wifi_cfg.country_code) != RTW_SUCCESS) { error_printf("WiFi: Error set tx country_code (%d)!", wifi_cfg.country_code); }; if(rtw_power_percentage_idx != wifi_cfg.tx_pwr) { if(rltk_set_tx_power_percentage(wifi_cfg.tx_pwr) != RTW_SUCCESS) { error_printf("WiFi: Error set tx power (%d)!", wifi_cfg.tx_pwr); }; } if(wifi_set_network_mode(wifi_cfg.bgn) != RTW_SUCCESS) { error_printf("WiFi: Error set network mode (%d)!", wifi_cfg.bgn); } debug_printf("mode=%d, wifi_mode=%d, old_mоde=%d\n", mode, wifi_mode, wifi_run_mode); if(mode <= RTW_MODE_STA_AP) { struct netif * pnif = &xnetif[WLAN_ST_NETIF_NUM]; #if LWIP_NETIF_HOSTNAME // @todo ethernetif_init()... pnif->hostname = lwip_host_name[0]; #ifdef USE_NETBIOS netbios_set_name(WLAN_ST_NETIF_NUM, lwip_host_name[0]); #endif #endif netif_set_addr(&xnetif[WLAN_ST_NETIF_NUM], (ip_addr_t *) &wifi_st_dhcp.ip, (ip_addr_t *) &wifi_st_dhcp.mask, (ip_addr_t *) &wifi_st_dhcp.gw); pnif = &xnetif[WLAN_AP_NETIF_NUM]; #if LWIP_NETIF_HOSTNAME // @todo ethernetif_init()... pnif->hostname = lwip_host_name[1]; #ifdef USE_NETBIOS netbios_set_name(WLAN_AP_NETIF_NUM, lwip_host_name[1]); #endif #endif netif_set_addr(&xnetif[WLAN_AP_NETIF_NUM], (ip_addr_t *) &wifi_ap_dhcp.ip, (ip_addr_t *) &wifi_ap_dhcp.mask, (ip_addr_t *) &wifi_ap_dhcp.gw); } switch(mode) { case RTW_MODE_STA_AP: ret = wifi_run_ap() | wifi_run_st(); // _wext_enable_powersave(0, 0, 0); break; case RTW_MODE_STA: ret = wifi_run_st(); if(_wext_set_lps_dtim(0, wifi_st_cfg.dtim)!= RTW_SUCCESS) { error_printf("WiFi: Error set DTIM(%d)!", wifi_st_cfg.dtim); }; if(_wext_enable_powersave(0, wifi_st_cfg.sleep & 1, (wifi_st_cfg.sleep >> 1) & 1) != RTW_SUCCESS) { // rtw_pm_set_ips(get_padaptern(0), wifi_st_cfg.sleep & 1 ); // rtw_pm_set_lps(get_padaptern(0), (wifi_st_cfg.sleep >> 1) & 1 ); error_printf("WiFi: Error set powersave mode!"); }; break; case RTW_MODE_AP: ret = wifi_run_ap(); // _wext_enable_powersave(WLAN0_NAME, 0, 0); break; #if 0// CONFIG_ENABLE_?? case RTW_MODE_PROMISC: // @todo break; #endif #if CONFIG_ENABLE_P2P case RTW_MODE_P2P: // @todo break; #endif default: ret = 1; error_printf("WiFi: Error mode(%d)\n", wifi_mode); }; wifi_run_mode = mode; if(ret == 0 && (wifi_cfg.save_flg & BID_WIFI_CFG)) { wifi_cfg.mode = mode; write_wifi_cfg(BID_WIFI_CFG); }; } else { ret = 0; error_end: #if CONFIG_WLAN_CONNECT_CB connect_close(); #endif if(wifi_run_mode) { wifi_disconnect(); }; wifi_off(); wifi_st_status = WIFI_STA_OFF; wifi_run_mode = RTW_MODE_NONE; chk_ap_netif_num(); }; return ret; } /* Load cfg, init WiFi + LwIP init, WiFi start if wifi_cfg.mode != RTW_MODE_NONE */ void wifi_init(void) { debug_printf("\nLoad Config\n"); read_wifi_cfg(wifi_cfg.load_flg); // DEF_LOAD_CFG // Call back from wlan driver after wlan init done // p_wlan_init_done_callback = wlan_init_done_callback; // Call back from application layer after wifi_connection success // p_write_reconnect_ptr = wlan_write_reconnect_data_to_flash; p_wlan_autoreconnect_hdl = NULL; _LwIP_Init(); #if CONFIG_WIFI_IND_USE_THREAD wifi_manager_init(); #endif // wifi_cfg.mode = RTW_MODE_PROMISC; //RTW_MODE_P2P; wifi_run(wifi_cfg.mode); } unsigned char *tab_txt_rtw_secyrity[] = { "OPEN", //0 Open security "WEP", //1 WEP Security with open authentication "WEP SHARED", //2 WEP Security with shared authentication "WPA TKIP", //3 WPA Security with TKIP "WPA AES", //4 WPA Security with AES "WPA2 TKIP", //5 WPA2 Security with TKIP "WPA2 AES", //6 WPA2 Security with AES "WPA2 Mixed", //7 WPA2 Security with AES & TKIP "WPA/WPA2 AES", //8 WPA/WPA2 Security "Unknown" //9 }; unsigned int tab_code_rtw_secyrity[] = { RTW_SECURITY_OPEN, //0 Open security RTW_SECURITY_WEP_PSK, //1 WEP Security with open authentication RTW_SECURITY_WEP_SHARED, //2 WEP Security with shared authentication RTW_SECURITY_WPA_TKIP_PSK, //3 WPA Security with TKIP RTW_SECURITY_WPA_AES_PSK, //4 WPA Security with AES RTW_SECURITY_WPA2_TKIP_PSK, //5 WPA2 Security with TKIP RTW_SECURITY_WPA2_AES_PSK, //6 WPA2 Security with AES RTW_SECURITY_WPA2_MIXED_PSK, //7 WPA2 Security with AES & TKIP RTW_SECURITY_WPA_WPA2_MIXED, //8 WPA/WPA2 Security RTW_SECURITY_UNKNOWN //9 }; /* unsigned char *tab_txt_rtw_eccryption[] = { "Unknown", "OPEN", "WEP40", "WPA_TKIP", "WPA_AES", "WPA2_TKIP", "WPA2_AES", "WPA2_MIXED", "???", "WEP104", "Udef" // 0xff }; */ rtw_security_t idx_to_rtw_security(unsigned char idx) { if(idx > IDX_SECURITY_UNKNOWN - 1) idx = IDX_SECURITY_WPA2_AES_PSK; return (rtw_security_t)tab_code_rtw_secyrity[idx]; } unsigned char rtw_security_to_idx(rtw_security_t rtw_sec_type) { unsigned char i = 0; while(rtw_sec_type != tab_code_rtw_secyrity[i] && tab_code_rtw_secyrity[i] != RTW_SECURITY_UNKNOWN) i++; return i; } unsigned char * idx_security_to_str(unsigned char idx) { if(idx > IDX_SECURITY_UNKNOWN) idx = IDX_SECURITY_UNKNOWN; return tab_txt_rtw_secyrity[idx]; } unsigned char * rtw_security_to_str(rtw_security_t rtw_sec_type) { return tab_txt_rtw_secyrity[rtw_security_to_idx(rtw_sec_type)]; } void show_wifi_ap_ip(void) { printf("SoftAP ip: " IPSTR "\n", IP2STR(&xnetif[WLAN_AP_NETIF_NUM].ip_addr)); } void show_wifi_st_ip(void) { printf("Station ip: " IPSTR "\n", IP2STR(&xnetif[WLAN_ST_NETIF_NUM].ip_addr)); } void show_wifi_MAC(void) { printf("MAC: " IPSTR "\n", IP2STR(&xnetif[WLAN_ST_NETIF_NUM].ip_addr)); } void show_wifi_st_cfg(void) { printf("\tSSID: '%s'\n", wifi_st_cfg.ssid); printf("\tPassword: '%s'\n", wifi_st_cfg.password); printf("\tSecurity type: %s\n", idx_security_to_str(wifi_st_cfg.security)); printf("\tAuto-reconnect: %d\n", wifi_st_cfg.autoreconnect); printf("\tReconnect pause: %d\n", wifi_st_cfg.reconnect_pause); printf("\tSleep mode: %p\n", wifi_st_cfg.sleep); printf("\tDTIM: %d\n", wifi_st_cfg.dtim); } void show_wifi_ap_cfg(void) { printf("\tSSID: '%s'\n", wifi_ap_cfg.ssid); printf("\tSSID hidden: %d\n", wifi_ap_cfg.ssid_hidden); printf("\tPassword: '%s'\n", wifi_ap_cfg.password); printf("\tSecurity type: %s\n", (wifi_ap_cfg.security)? tab_txt_rtw_secyrity[IDX_SECURITY_WPA2_AES_PSK] : tab_txt_rtw_secyrity[IDX_SECURITY_OPEN]); printf("\tChannel: %d\n", wifi_ap_cfg.channel); printf("\tBeacon interval: %d ms\n", wifi_ap_cfg.beacon_interval); printf("\tMax connections: %d\n", wifi_ap_cfg.max_sta); } void show_wifi_cfg(void) { printf("\tStart mode: %p\n", wifi_cfg.mode); printf("\tCountry code: %d\n", wifi_cfg.country_code); printf("\tNetwork mode: %d\n", wifi_cfg.bgn); printf("\tTx power: %d\n", wifi_cfg.tx_pwr); printf("\tAdaptivity: %d\n", wifi_cfg.adaptivity); printf("\tLoad flags: %p\n", wifi_cfg.load_flg); printf("\tSave flags: %p\n", wifi_cfg.save_flg); } int show_wifi_ap_clients(void) { if((wifi_mode == RTW_MODE_AP) || (wifi_mode == RTW_MODE_STA_AP)) { struct { int count; rtw_mac_t mac_list[AP_STA_NUM]; } client_info; client_info.count = AP_STA_NUM; if(wext_get_associated_client_list(wlan_ap_name, &client_info, sizeof(client_info)) >= 0) { if(client_info.count) { printf("\tAP %u clients:\n", client_info.count); int client_idx = 0; while(client_idx++ < client_info.count) { unsigned char *pmac = client_info.mac_list[client_idx].octet; printf("\tsta[%u]: %02x:%02x:%02x:%02x:%02x:%02x\n", client_idx, pmac[0],pmac[1],pmac[2],pmac[3],pmac[4],pmac[5]); } } else { printf("\tAP clients none\n"); } return client_info.count; }; }; printf("Get AP clients error!\n"); return -1; } extern int max_skbbuf_used_num, skbbuf_used_num, max_skbdata_used_num, skbdata_used_num, max_timer_used_num; void show_wlan_info(int idx) { if(rltk_wlan_info[idx].enable) { struct net_device_stats * stats = rltk_wlan_info[idx].dev->get_stats(rltk_wlan_info[idx].dev); if(stats) { printf("\tTotal %d packets received (%d bytes), dropped %d\n", stats->rx_packets, stats->rx_bytes, stats->rx_dropped); printf("\tTotal %d packets transmitted (%d bytes), dropped %d\n", stats->tx_packets, stats->tx_bytes, stats->tx_dropped); printf("\tRX fifo overflow count %d\n", stats->rx_overflow); printf("\tMax skb %d bufers used, buffers %d\n", max_skbbuf_used_num, skbbuf_used_num); printf("\tMax skb %d data used, data %d\n", max_skbdata_used_num, skbdata_used_num); printf("\tMax %d timers used\n", max_timer_used_num); // printf("\tMax %d timers used, timers %d\n", max_timer_used_num, timer_used_num); } } }