open-ameba/RTL00_SDKV35a/component/common/api/wifi_api.c
2017-03-18 15:52:14 +03:00

753 lines
21 KiB
C

/*
* wifi_api.c
*
* Created on: 01/11/2017
* Author: pvvx
*/
#include "FreeRTOS.h"
#include <autoconf.h>
#include "main.h"
#include <platform_opts.h>
#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 <platform/platform_stdlib.h>
#include <wifi/wifi_conf.h>
#include "flash_api.h"
#include <lwip_netconf.h>
#include "dhcp/dhcps.h"
#include "ethernetif.h"
#if CONFIG_ETHERNET
#include "ethernet_mii/ethernet_mii.h"
#endif
#include "wlan_lib.h"
#include "flash_eep.h"
#include "feep_config.h"
#include "wifi_api.h"
#include "wifi_user_set.h"
//=========================================
//--- Wlan Config Init-------------------
WIFI_CONFIG wifi_cfg = {
.mode = DEF_WIFI_MODE, // rtw_mode_t
.sleep = DEF_WIFI_ST_SLEEP,
.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_type = DEF_AP_SECURITY,
.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,
.security_type = DEF_ST_SECURITY,
.autoreconnect = DEF_ST_AUTORECONNECT,
.reconnect_pause = DEF_ST_RECONNECT_PAUSE
};
DHCP_CONFIG wifi_st_dhcp = {
.ip = DEF_ST_IP,
.mask = DEF_ST_MSK,
.gw = DEF_ST_GW,
.mode = 1
};
rtw_mode_t wifi_run_mode = RTW_MODE_NONE;
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
{ FEEP_ID_WIFI_ST_CFG, sizeof(wifi_st_cfg), &wifi_st_cfg }, // Bit1
{ FEEP_ID_AP_DHCP_CFG, sizeof(wifi_ap_dhcp), &wifi_ap_dhcp }, // Bit2
{ FEEP_ID_ST_DHCP_CFG, sizeof(wifi_st_dhcp), &wifi_st_dhcp }, // Bit3
{ FEEP_ID_WIFI_CFG, sizeof(wifi_cfg), &wifi_cfg }, // Bit4
// { FEEP_ID_LWIP_CFG, sizeof(lwip_conn_info), &lwip_conn_info }, // Bit5
{ 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)
&& flash_write_cfg(p->obj, p->id, p->size) < p->size) {
ret |= m;
};
};
return ret;
}
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];
_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());
}
_WEAK void user_start(void)
{
info_printf("\%s: Time at start %d ms.\n", __func__, xTaskGetTickCount());
}
int wlan_init_done_callback(void) {
info_printf("WiFi Init after %d ms\n", xTaskGetTickCount());
return 0;
}
//char wlan_st_name[] = WLAN0_NAME;
char wlan_st_name[] = WLAN0_NAME;
char wlan_ap_name[] = WLAN1_NAME;
char wlan_st_netifn = 0;
char wlan_ap_netifn = 1;
extern rtw_mode_t wifi_mode; // новый режим работы
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;
}
rtw_result_t wifi_run_ap(void) {
chk_ap_netif_num();
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);
};
ret = wifi_start_ap(wifi_ap_cfg.ssid, //char *ssid,
wifi_ap_cfg.security_type, //rtw_security_t ecurity_type,
wifi_ap_cfg.password, //char *password,
strlen(wifi_ap_cfg.ssid), //int ssid_len,
strlen(wifi_ap_cfg.password), //int password_len,
wifi_ap_cfg.channel); //int channel
wifi_run_mode |= RTW_MODE_AP;
if (ret != RTW_SUCCESS) {
error_printf("Error(%d): Start AP failed!\n\n", ret);;
} else {
int timeout = 10000 / 200;
while (1) {
char essid[33];
if (wext_get_ssid(wlan_ap_name, (unsigned char *) essid) > 0) {
if (strcmp((const char * ) essid,
(const char * )wifi_ap_cfg.ssid)
== 0) {
#ifdef CONFIG_DONT_CARE_TP
pnetiff->flags |= NETIF_FLAG_IPSWITCH;
#endif
dhcps_ip4addr_pool_start = DEF_AP_DHCP_START;
dhcps_ip4addr_pool_end = DEF_AP_DHCP_STOP;
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;
break;
}
}
if (timeout == 0) {
error_printf("Start AP timeout!\n");
ret = RTW_TIMEOUT;
break;
}
vTaskDelay(200 / portTICK_RATE_MS);
timeout--;
}
}
}
return ret;
}
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_cfg *)&wifi_st_dhcp;
unsigned char mode = p->mode;
if((mode == 3)
&& (p->ip == IP4ADDR(255,255,255,255)
|| p->ip == IP4ADDR(0,0,0,0))) {
mode = 2;
}
else mode = 1;
if(mode == 2) {
netif_set_addr(pnetif, (ip_addr_t *)&p->ip, (ip_addr_t *)&p->mask, (ip_addr_t *)&p->gw);
// dhcps_init(pnetif);
}
else if(mode) {
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(p->mode == 3) {
p->mode = 2;
write_wifi_cfg(BID_ST_DHCP_CFG);
}
ret = RTW_SUCCESS;
}
else {
debug_printf("LwIP_DHCP ret=%d\n", ret);
ret = RTW_ERROR;
}
}
return ret;
}
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) {
ret = wifi_config_autoreconnect(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.ssid, wifi_st_cfg.security_type,
wifi_st_cfg.password, strlen(wifi_st_cfg.ssid),
strlen(wifi_st_cfg.password), -1, NULL);
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
ret = StartStDHCPClient();
if(ret == RTW_SUCCESS) {
show_wifi_st_ip();
#if CONFIG_WLAN_CONNECT_CB
// extern void connect_start(void);
connect_start();
#endif
}
}
};
return ret;
}
int _wifi_on(rtw_mode_t mode) {
int ret = 0;
uint32 timeout = xTaskGetTickCount();
uint8 devnum;
if (rltk_wlan_running(WLAN0_IDX)) {
warning_printf("WIFI is already running\n");
return 0;
}
static int event_init = 0;
if (event_init == 0) {
init_event_callback_list();
event_init = 1;
}
wifi_mode = mode;
info_printf("Initializing WIFI...\n");
// set wifi mib
// adaptivity
wext_set_adaptivity(RTW_ADAPTIVITY_DISABLE);
// wext_set_adaptivity(RTW_ADAPTIVITY_NORMAL);
// wext_set_adaptivity(RTW_ADAPTIVITY_CARRIER_SENSE);
devnum = (mode == RTW_MODE_STA_AP);
ret = rltk_wlan_init(0, mode);
if (ret < 0) return ret;
if(devnum) {
ret = rltk_wlan_init(1, mode);
if (ret < 0) return ret;
}
rltk_wlan_start(0);
if(devnum) rltk_wlan_start(1);
while (1) {
if (rltk_wlan_running(0) &&
rltk_wlan_running(devnum) ) {
#if CONFIG_DEBUG_LOG > 2
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;
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(int 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], (struct netif *)&wifi_st_dhcp.ip, (struct netif *)&wifi_st_dhcp.mask, (struct netif *)&wifi_st_dhcp.gw, NULL, &ethernetif_init, &tcpip_input);
netif_add(&xnetif[WLAN_AP_NETIF_NUM], (struct netif *)&wifi_ap_dhcp.ip, (struct netif *)&wifi_ap_dhcp.mask, (struct netif *)&wifi_ap_dhcp.gw, NULL, &ethernetif_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, &ethernetif_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);
wifi_mode = 0;
lwip_init_done = 1;
}
}
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);
#endif
if(mode != RTW_MODE_NONE) {
_LwIP_Init();
};
if(wifi_run_mode & RTW_MODE_AP) {
info_printf("Deinit old AP...\n");
LwIP_DHCP(WLAN_AP_NETIF_NUM, DHCP_STOP);
#if CONFIG_DEBUG_LOG > 4
debug_printf("dhcps_deinit()\n");
#endif
dhcps_deinit();
wifi_run_mode &= ~RTW_MODE_AP;
};
if(wifi_run_mode & RTW_MODE_STA) {
info_printf("Deinit old ST...\n");
LwIP_DHCP(WLAN_ST_NETIF_NUM, DHCP_STOP);
wifi_run_mode &= ~RTW_MODE_STA;
};
// if(mode != wifi_mode)
// wifi_mode = mode;
// chk_ap_netif_num();
if (mode != RTW_MODE_NONE) {
if(mode != (volatile)wifi_mode) {
info_printf("Deinitializing WIFI ...\n");
wifi_off();
vTaskDelay(30);
debug_printf("WiFi_on(%d)\n", mode);
if (_wifi_on(mode) < 0) {
error_printf("Wifi On failed!\n");
goto error_end;
};
wifi_mode = mode;
};
if(wifi_set_country(wifi_cfg.country_code) != RTW_SUCCESS) {
error_printf("Error set tx country_code (%d)!", wifi_cfg.country_code);
};
// extern uint8_t rtw_power_percentage_idx;
if(rtw_power_percentage_idx != wifi_cfg.tx_pwr) {
if(rltk_set_tx_power_percentage(wifi_cfg.tx_pwr) != RTW_SUCCESS) {
error_printf("Error set tx power (%d)!", wifi_cfg.tx_pwr);
};
}
debug_printf("mode == wifi_mode? (%d == %d?)\n", mode, wifi_mode);
// if(mode == wifi_mode)
{
if((wifi_mode == RTW_MODE_AP) || (wifi_mode == RTW_MODE_STA_AP)) {
wifi_run_ap();
};
if((wifi_mode == RTW_MODE_STA) || (wifi_mode == RTW_MODE_STA_AP)) {
wifi_run_st();
};
#if CONFIG_INTERACTIVE_MODE
/* Initial uart rx swmaphore*/
vSemaphoreCreateBinary(uart_rx_interrupt_sema);
xSemaphoreTake(uart_rx_interrupt_sema, 1/portTICK_RATE_MS);
start_interactive_mode();
#endif
// if(wifi_run_mode == wifi_cfg.mode)
ret = 1;
};
} else {
ret = 1;
error_end:
#if CONFIG_WLAN_CONNECT_CB
connect_close();
#endif
wifi_off();
};
chk_ap_netif_num();
return ret;
}
void wifi_init_thrd(void) {
debug_printf("\nLoad Config\n");
read_wifi_cfg(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;
if (wifi_cfg.mode != RTW_MODE_NONE) {
wifi_mode = wifi_cfg.mode;
user_start();
#if CONFIG_WIFI_IND_USE_THREAD
wifi_manager_init();
#endif
wifi_run(wifi_cfg.mode);
}
/* Initilaize the console stack */
console_init();
/* Kill init thread after all init tasks done */
vTaskDelete(NULL);
}
rtw_security_t translate_rtw_security(u8 security_type)
{
rtw_security_t security_mode = RTW_SECURITY_OPEN;
switch (security_type) {
// case RTW_ENCRYPTION_OPEN:
// security_mode = RTW_SECURITY_OPEN;
// break;
case RTW_ENCRYPTION_WEP40:
case RTW_ENCRYPTION_WEP104:
security_mode = RTW_SECURITY_WEP_PSK;
break;
case RTW_ENCRYPTION_WPA_TKIP:
case RTW_ENCRYPTION_WPA_AES:
case RTW_ENCRYPTION_WPA2_TKIP:
case RTW_ENCRYPTION_WPA2_AES:
case RTW_ENCRYPTION_WPA2_MIXED:
security_mode = RTW_SECURITY_WPA2_AES_PSK;
break;
// case RTW_ENCRYPTION_UNKNOWN:
// case RTW_ENCRYPTION_UNDEF:
// default:
//security_mode = RTW_SECURITY_OPEN;
}
return security_mode;
}
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_st_cfg(void) {
printf("\tSSID: '%s'\n", wifi_st_cfg.ssid);
printf("\tPassword: '%s'\n", wifi_st_cfg.password);
printf("\tSecurity type: %p\n", wifi_st_cfg.security_type);
printf("\tAuto-reconnect: %d\n", wifi_st_cfg.autoreconnect);
printf("\tReconnect pause: %d\n", wifi_st_cfg.reconnect_pause);
}
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: %p\n", wifi_ap_cfg.security_type);
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("\tSleep mode: %p\n", wifi_cfg.sleep);
printf("\tNetwork mode: %d\n", wifi_cfg.bgn);
printf("\tTx power: %d\n", wifi_cfg.tx_pwr);
printf("\tLoad flags: %p\n", wifi_cfg.load_flg);
printf("\tSave flags: %p\n", wifi_cfg.save_flg);
}
//==========================================================
//--- CONSOLE --------------------------
#include "section_config.h"
#include "hal_diag.h"
// ATPN=<SSID>[,password[,encryption[,auto reconnect[,reconnect pause]]]: WIFI Connect to AP
void fATPN(int argc, char *argv[]){
if(argc > 1) {
if(argv[1][0] == '?') {
show_wifi_st_cfg();
}
else {
strncpy(wifi_st_cfg.ssid, argv[1], NDIS_802_11_LENGTH_SSID);
if(argc > 2) {
strncpy(wifi_st_cfg.password, argv[2], NDIS_802_11_LENGTH_SSID);
int i = strlen(wifi_st_cfg.password);
if(i > 7) {
wifi_st_cfg.security_type = RTW_SECURITY_WPA2_AES_PSK;
}
else if(!i) {
wifi_st_cfg.security_type = RTW_SECURITY_OPEN;
}
else {
printf("password len < 8!\n");
wifi_st_cfg.security_type = RTW_SECURITY_OPEN;
}
}
else {
wifi_st_cfg.password[0] = 0;
wifi_st_cfg.security_type = RTW_SECURITY_OPEN;
}
if(argc > 3) {
wifi_st_cfg.security_type = translate_rtw_security(atoi(argv[3]));
}
if(argc > 4) {
wifi_st_cfg.autoreconnect = atoi(argv[3]);
}
else wifi_st_cfg.autoreconnect = 0;
if(argc > 5) {
wifi_st_cfg.reconnect_pause = atoi(argv[3]);
}
else wifi_st_cfg.reconnect_pause = 5;
show_wifi_st_cfg();
wifi_run(wifi_run_mode | RTW_MODE_STA);
}
}
}
// ATPA=<SSID>[,password[,encryption[,channel[,hidden[,max connections]]]]]: Start WIFI AP
void fATPA(int argc, char *argv[]){
if(argc > 1) {
if(argv[1][0] == '?') {
show_wifi_ap_cfg();
}
else {
strncpy(wifi_ap_cfg.ssid, argv[1], NDIS_802_11_LENGTH_SSID);
if(argc > 2) {
strncpy(wifi_ap_cfg.password, argv[2], NDIS_802_11_LENGTH_SSID);
int i = strlen(wifi_ap_cfg.password);
if(i > 7) {
wifi_ap_cfg.security_type = RTW_SECURITY_WPA2_AES_PSK;
}
else if(i == 0) {
wifi_ap_cfg.security_type = RTW_SECURITY_OPEN;
}
else {
printf("password len < 8!\n");
wifi_ap_cfg.security_type = RTW_SECURITY_OPEN;
}
}
else {
wifi_ap_cfg.password[0] = 0;
wifi_ap_cfg.security_type = RTW_SECURITY_OPEN;
}
if(argc > 3) {
wifi_ap_cfg.security_type = translate_rtw_security(atoi(argv[3]));
}
if(argc > 4) {
wifi_ap_cfg.channel = atoi(argv[4]);
}
else wifi_ap_cfg.channel = 1;
if(argc > 5) {
wifi_ap_cfg.ssid_hidden = atoi(argv[5]);
}
else wifi_ap_cfg.ssid_hidden = 0;
if(argc > 6) {
wifi_ap_cfg.max_sta = atoi(argv[6]);
}
else wifi_ap_cfg.max_sta = 3;
show_wifi_ap_cfg();
wifi_run(wifi_run_mode | RTW_MODE_AP);
}
}
}
// WIFI Connect, Disconnect
void fATWR(int argc, char *argv[]){
rtw_mode_t mode = RTW_MODE_NONE;
if(argc > 1) mode = atoi(argv[1]);
wifi_run(mode);
}
// Close connections
void fATOF(int argc, char *argv[]){
connect_close();
}
// Open connections
void fATON(int argc, char *argv[]){
connect_start();
}
void fATWI(int argc, char *argv[]) {
rtw_wifi_setting_t Setting;
if((wifi_run_mode & RTW_MODE_AP)
&& wifi_get_setting(wlan_ap_name, &Setting) == 0) {
wifi_show_setting(wlan_ap_name, &Setting);
// show_wifi_ap_ip();
printf("\tIP: " IPSTR "\n", IP2STR(&xnetif[WLAN_AP_NETIF_NUM].ip_addr));
}
if((wifi_run_mode & RTW_MODE_STA)
&& wifi_get_setting(wlan_st_name, &Setting) == 0) {
wifi_show_setting(wlan_st_name, &Setting);
// show_wifi_st_ip();
printf("\tIP: " IPSTR "\n", IP2STR(&xnetif[WLAN_ST_NETIF_NUM].ip_addr));
}
printf("\nWIFI config:\n");
printf(&str_rom_57ch3Dch0A[25]); // "================================\n"
show_wifi_cfg();
printf("\nWIFI AP config:\n");
printf(&str_rom_57ch3Dch0A[25]); // "================================\n"
show_wifi_ap_cfg();
printf("\nWIFI ST config:\n");
printf(&str_rom_57ch3Dch0A[25]); // "================================\n"
show_wifi_st_cfg();
printf("\n");
if(argc > 2
&& (argv[1][0] == 's'
|| argv[1][0] == 'S')) {
int i = atoi(argv[2]);
printf("Save configs(%d)..\n", i);
write_wifi_cfg(atoi(argv[2]));
}
}
void fATWT(int argc, char *argv[]) {
if(argc > 1) {
int txpwr = atoi(argv[1]);
debug_printf("set tx power (%d)...\n", txpwr);
if(rltk_set_tx_power_percentage(txpwr) != RTW_SUCCESS) {
error_printf("Error set tx power (%d)!", wifi_cfg.tx_pwr);
}
}
printf("TX power = %d\n", rtw_power_percentage_idx);
}
//-- Test tsf (64-bits counts, 1 us step) ---
#include "hal_com_reg.h"
#define ReadTSF_Lo32() (*((volatile unsigned int *)(WIFI_REG_BASE + REG_TSFTR)))
#define ReadTSF_Hi32() (*((volatile unsigned int *)(WIFI_REG_BASE + REG_TSFTR1)))
uint64_t get_tsf(void)
{
return *((uint64_t *)(WIFI_REG_BASE + REG_TSFTR));
}
void fATSF(int argc, char *argv[])
{
uint64_t tsf = get_tsf();
printf("\nTSF: %08x%08x\n", (uint32_t)(tsf>>32), (uint32_t)(tsf));
}
MON_RAM_TAB_SECTION COMMAND_TABLE console_cmd_wifi_api[] = {
{"ATPN", 1, fATPN, "=<SSID>[,password[,encryption[,auto-reconnect[,reconnect pause]]]: WIFI Connect to AP"},
{"ATPA", 1, fATPA, "=<SSID>[,password[,encryption[,channel[,hidden[,max connections]]]]]: Start WIFI AP"},
{"ATWR", 0, fATWR, ": WIFI Connect, Disconnect"},
{"ATON", 0, fATON, ": Open connections"},
{"ATOF", 0, fATOF, ": Close connections"},
{"ATWI", 0, fATWI, ": WiFi Info"},
#if CONFIG_DEBUG_LOG > 3
{"ATWT", 1, fATWT, "=<tx_power>: WiFi tx power: 0 - 100%, 1 - 75%, 2 - 50%, 3 - 25%, 4 - 12.5%"},
{"ATSF", 0, fATSF, ": Test TSF value"},
#endif
};