esp-idf/examples/common_components/iperf/wifi_cmd.c
aditi_lonkar 6b95b4ffd7 esp_wifi: Update some wifi config options
1) Update sta_config_t options.
        2) Update HE constellation tx/rx default value.
2023-02-23 11:13:25 +05:30

1081 lines
37 KiB
C

/*
* SPDX-FileCopyrightText: 2022-2023 Espressif Systems (Shanghai) CO LTD
*
* SPDX-License-Identifier: Apache-2.0
*/
#include <stdio.h>
#include <string.h>
#include "esp_log.h"
#include "freertos/FreeRTOS.h"
#include "freertos/event_groups.h"
#include "ping/ping_sock.h"
#include "lwip/inet.h"
#include "lwip/netdb.h"
#include "esp_mac.h"
#include "wifi_cmd.h"
#if CONFIG_SOC_WIFI_HE_SUPPORT
#include "esp_console.h"
#include "argtable3/argtable3.h"
#include "esp_netif.h"
#include "esp_event.h"
#include "esp_wifi.h"
#include "esp_wifi_types.h"
#include "esp_wifi_he.h"
#include "esp_private/esp_wifi_he_private.h"
/*******************************************************
* Macros
*******************************************************/
/*
* enable/disable rx/tx statistics after wifi started:
* (1) esp_wifi_enable_rx_statistics(true, true);
* (2) esp_wifi_enable_tx_statistics(ESP_WIFI_ACI_BE, true);
*/
/*******************************************************
* Constants
*******************************************************/
static const char *TAG = "cmd";
/*******************************************************
* Structures
*******************************************************/
typedef struct {
struct arg_dbl *read;
struct arg_dbl *write;
struct arg_dbl *value;
struct arg_end *end;
} reg_rw_args_t;
typedef struct {
struct arg_dbl *disable;
struct arg_end *end;
} wifi_stbc_args_t;
typedef struct {
struct arg_dbl *disable;
struct arg_end *end;
} wifi_bmfmee_args_t;
typedef struct {
struct arg_dbl *ul_mu_disable;
struct arg_dbl *ul_mu_data_disable;
struct arg_dbl *ersu_disable;
struct arg_dbl *report;
struct arg_dbl *resounding;
struct arg_end *end;
} wifi_omctrl_args_t;
typedef struct {
struct arg_dbl *tf_padding;
struct arg_end *end;
} wifi_tf_padding_args_t;
typedef struct {
struct arg_int *enable;
struct arg_int *txq;
struct arg_end *end;
} wifi_edca_args_t;
typedef struct {
struct arg_int *reset_timer;
struct arg_int *read_timer;
struct arg_end *end;
} wifi_muedca_args_t;
typedef struct {
struct arg_dbl *enable;
struct arg_end *end;
} wifi_cca_ignore_args_t;
typedef struct {
struct arg_dbl *timeout;
struct arg_dbl *interval;
struct arg_int *data_size;
struct arg_int *count;
struct arg_int *tos;
struct arg_str *host;
struct arg_lit *abort;
struct arg_end *end;
} wifi_ping_args_t;
typedef struct {
struct arg_str *ip;
struct arg_str *gw;
struct arg_str *netmask;
struct arg_end *end;
} static_ip_args_t;
typedef struct {
struct arg_str *proto;
struct arg_end *end;
} wifi_proto_args_t;
typedef struct {
struct arg_int *val;
struct arg_end *end;
} wifi_inactive_time_args_t;
typedef struct {
struct arg_int *format;
struct arg_int *rate;
struct arg_end *end;
} wifi_sounding_rate_t;
typedef struct {
struct arg_int *mcs;
struct arg_int *power;
struct arg_end *end;
} wifi_tx_pwr_t;
/*******************************************************
* Variable Definitions
*******************************************************/
static reg_rw_args_t reg_rw_args;
static wifi_stbc_args_t stbc_args;
static wifi_bmfmee_args_t bmfmee_args;
static wifi_omctrl_args_t omctrl_args;
static wifi_tf_padding_args_t tf_padding_args;
static wifi_edca_args_t edca_args;
static wifi_cca_ignore_args_t cca_args;
static wifi_ping_args_t ping_args;
static static_ip_args_t static_ip_args;
static wifi_proto_args_t proto_args;
static wifi_inactive_time_args_t inactive_time_args;
static wifi_sounding_rate_t wifi_sounding_rate_args;
static wifi_muedca_args_t muedca_args;
static wifi_tx_pwr_t tx_pwr_args;
extern esp_netif_t *netif_ap;
extern esp_netif_t *netif_sta;
extern EventGroupHandle_t wifi_event_group;
extern const int CONNECTED_BIT;
/*******************************************************
* Function Declarations
*******************************************************/
/*******************************************************
* Function Definitions
*******************************************************/
static int wifi_cmd_get_mac(int argc, char **argv)
{
uint8_t mac[6] = { 0, };
if (esp_wifi_get_mac(WIFI_IF_STA, mac) == ESP_OK) {
ESP_LOGW(TAG, "sta mac: " MACSTR "", MAC2STR(mac));
}
if (esp_wifi_get_mac(WIFI_IF_AP, mac) == ESP_OK) {
ESP_LOGW(TAG, "ap mac: " MACSTR "", MAC2STR(mac));
}
return 0;
}
static int wifi_cmd_set_omc(int argc, char **argv)
{
//TODO ER-SU
esp_wifi_htc_omc_t omc = { 0, };
esp_err_t err = ESP_OK;
int nerrors = arg_parse(argc, argv, (void **) &omctrl_args);
if (nerrors != 0) {
arg_print_errors(stderr, omctrl_args.end, argv[0]);
return 1;
}
do {
if (!omctrl_args.ul_mu_disable->count && !omctrl_args.ul_mu_data_disable->count) {
omc.ul_mu_disable = 1;
omc.ul_mu_data_disable = 0;
break;
}
/* parse inputs */
if (omctrl_args.ul_mu_disable->count) {
omc.ul_mu_disable = omctrl_args.ul_mu_disable->dval[0];
}
if (omctrl_args.ul_mu_data_disable->count) {
omc.ul_mu_data_disable = omctrl_args.ul_mu_data_disable->dval[0];
}
if (omctrl_args.ersu_disable->count) {
omc.er_su_disable = omctrl_args.ersu_disable->dval[0];
}
if (omctrl_args.resounding->count) {
omc.dl_mu_mimo_resounding_recommendation = omctrl_args.resounding->dval[0];
}
} while (0);
if (omctrl_args.report->count && omctrl_args.report->dval[0] == 0) {
/* not report to ap the om control */
hal_he_set_ul_mu(omc.ul_mu_disable, omc.ul_mu_data_disable);
ESP_LOGW(TAG, "(omc)(internal)disable ul mu(%d, data:%d) successfully", omc.ul_mu_disable,
omc.ul_mu_data_disable);
} else {
err = esp_wifi_set_htc_omc(&omc);
if (err != ESP_OK) {
ESP_LOGW(TAG, "(omc)disable ul mu(%d, data:%d) failed, err:0x%x", omc.ul_mu_disable, omc.ul_mu_data_disable,
err);
} else {
ESP_LOGW(TAG, "(omc)disable ul mu(%d, data:%d) successfully", omc.ul_mu_disable, omc.ul_mu_data_disable);
}
}
return 0;
}
static int wifi_cmd_edca_tx(int argc, char **argv)
{
int nerrors = arg_parse(argc, argv, (void **) &edca_args);
if (nerrors != 0) {
arg_print_errors(stderr, edca_args.end, argv[0]);
return 1;
}
int txq = 2;
if (!edca_args.enable->count && !edca_args.txq->count) {
esp_test_disable_edca_tx(txq);
ESP_LOGW(TAG, "(tx)disable edca, txq[%d]", txq);
return 0;
}
txq = edca_args.txq->count ? edca_args.txq->ival[0] : txq;
if (edca_args.enable->ival[0] == 0) {
esp_test_disable_edca_tx(txq);
ESP_LOGW(TAG, "(tx)disable edca, txq[%d]", txq);
} else {
esp_test_enable_edca_tx(txq);
ESP_LOGW(TAG, "(tx)enable edca, txq[%d]", txq);
}
return 0;
}
static int wifi_cmd_reg_rw(int argc, char **argv)
{
int nerrors = arg_parse(argc, argv, (void **) &reg_rw_args);
uint32_t addr;
if (nerrors != 0) {
arg_print_errors(stderr, reg_rw_args.end, argv[0]);
return 1;
}
if (reg_rw_args.read->count) {
addr = (uint32_t) reg_rw_args.read->dval[0];
ESP_LOGW(TAG, "reg read 0x%08x : 0x%08x\n", addr, REG_READ(addr));
} else if (reg_rw_args.write->count && (uint32_t) reg_rw_args.value->count) {
addr = (uint32_t) reg_rw_args.write->dval[0];
ESP_LOGW(TAG, "reg write 0x%8x : 0x%8x\n", addr, (uint32_t) reg_rw_args.value->dval[0]);
REG_WRITE(addr, (uint32_t ) reg_rw_args.value->dval[0]);
ESP_LOGW(TAG, "reg read 0x%08x : 0x%08x\n", addr, REG_READ(addr));
} else {
printf("Input Error\n");
}
return 0;
}
static int wifi_cmd_set_tf_padding(int argc, char **argv)
{
int nerrors = arg_parse(argc, argv, (void **) &tf_padding_args);
if (nerrors != 0) {
arg_print_errors(stderr, tf_padding_args.end, argv[0]);
return 1;
}
if (tf_padding_args.tf_padding->count) {
esp_wifi_set_tf_padding_duration((int)tf_padding_args.tf_padding->dval[0]);
ESP_LOGW(TAG, "(test)set trigger frame mac padding duration:%d", (int)tf_padding_args.tf_padding->dval[0]);
} else {
printf("Input Error\n");
}
return 0;
}
static int wifi_cmd_tb(int argc, char **argv)
{
dbg_read_axtb_diag();
dbg_read_ax_diag(1);
return 0;
}
static int wifi_cmd_stbc(int argc, char **argv)
{
int nerrors = arg_parse(argc, argv, (void **) &stbc_args);
if (nerrors != 0) {
arg_print_errors(stderr, stbc_args.end, argv[0]);
return 1;
}
if (stbc_args.disable->count) {
esp_wifi_enable_rx_stbc(0);
ESP_LOGI(TAG, "(cfg)disable he stbc");
} else {
esp_wifi_enable_rx_stbc(1);
ESP_LOGI(TAG, "(cfg)enable he stbc");
}
return 0;
}
static int wifi_cmd_su_bmfmee(int argc, char **argv)
{
int nerrors = arg_parse(argc, argv, (void **) &bmfmee_args);
if (nerrors != 0) {
arg_print_errors(stderr, bmfmee_args.end, argv[0]);
return 1;
}
if (bmfmee_args.disable->count) {
esp_wifi_enable_su_bmfmee(0);
ESP_LOGI(TAG, "(cfg)disable he su bmfmee");
} else {
esp_wifi_enable_su_bmfmee(1);
ESP_LOGI(TAG, "(cfg)enable he su bmfmee");
}
return 0;
}
static int wifi_cmd_ignore_cca(int argc, char **argv)
{
int nerrors = arg_parse(argc, argv, (void **) &cca_args);
if (nerrors != 0) {
arg_print_errors(stderr, cca_args.end, argv[0]);
return 1;
}
if (cca_args.enable->count) {
dbg_tb_ignore_cca_enable(1);
} else {
dbg_tb_ignore_cca_enable(0);
}
return 0;
}
static int wifi_cmd_set_ps_type(int argc, char **argv)
{
ESP_LOGW(TAG, "set to WIFI_PS_MIN_MODEM");
ESP_ERROR_CHECK(esp_wifi_set_ps(WIFI_PS_MIN_MODEM));
return 0;
}
static void cmd_ping_on_ping_success(esp_ping_handle_t hdl, void *args)
{
uint8_t ttl;
uint16_t seqno;
uint32_t elapsed_time, recv_len;
ip_addr_t target_addr;
esp_ping_get_profile(hdl, ESP_PING_PROF_SEQNO, &seqno, sizeof(seqno));
esp_ping_get_profile(hdl, ESP_PING_PROF_TTL, &ttl, sizeof(ttl));
esp_ping_get_profile(hdl, ESP_PING_PROF_IPADDR, &target_addr, sizeof(target_addr));
esp_ping_get_profile(hdl, ESP_PING_PROF_SIZE, &recv_len, sizeof(recv_len));
esp_ping_get_profile(hdl, ESP_PING_PROF_TIMEGAP, &elapsed_time, sizeof(elapsed_time));
printf("%d bytes from %s icmp_seq=%d ttl=%d time=%d ms\n",
recv_len, inet_ntoa(target_addr.u_addr.ip4), seqno, ttl, elapsed_time);
}
static void cmd_ping_on_ping_timeout(esp_ping_handle_t hdl, void *args)
{
uint16_t seqno;
ip_addr_t target_addr;
esp_ping_get_profile(hdl, ESP_PING_PROF_SEQNO, &seqno, sizeof(seqno));
esp_ping_get_profile(hdl, ESP_PING_PROF_IPADDR, &target_addr, sizeof(target_addr));
printf("From %s icmp_seq=%d timeout\n", inet_ntoa(target_addr.u_addr.ip4), seqno);
}
static void cmd_ping_on_ping_end(esp_ping_handle_t hdl, void *args)
{
ip_addr_t target_addr;
uint32_t transmitted;
uint32_t received;
uint32_t total_time_ms;
esp_ping_get_profile(hdl, ESP_PING_PROF_REQUEST, &transmitted, sizeof(transmitted));
esp_ping_get_profile(hdl, ESP_PING_PROF_REPLY, &received, sizeof(received));
esp_ping_get_profile(hdl, ESP_PING_PROF_IPADDR, &target_addr, sizeof(target_addr));
esp_ping_get_profile(hdl, ESP_PING_PROF_DURATION, &total_time_ms, sizeof(total_time_ms));
uint32_t loss = (uint32_t)((1 - ((float)received) / transmitted) * 100);
if (IP_IS_V4(&target_addr)) {
printf("\n--- %s ping statistics ---\n", inet_ntoa(*ip_2_ip4(&target_addr)));
} else {
printf("\n--- %s ping statistics ---\n", inet6_ntoa(*ip_2_ip6(&target_addr)));
}
printf("%d packets transmitted, %d received, %d%% packet loss, time %dms\n",
transmitted, received, loss, total_time_ms);
// delete the ping sessions, so that we clean up all resources and can create a new ping session
// we don't have to call delete function in the callback, instead we can call delete function from other tasks
esp_ping_delete_session(hdl);
}
static int do_ping_cmd(int argc, char **argv)
{
esp_ping_config_t config = ESP_PING_DEFAULT_CONFIG();
static esp_ping_handle_t ping;
int nerrors = arg_parse(argc, argv, (void **)&ping_args);
if (nerrors != 0) {
arg_print_errors(stderr, ping_args.end, argv[0]);
return 1;
}
if (ping_args.timeout->count > 0) {
config.timeout_ms = (uint32_t)(ping_args.timeout->dval[0] * 1000);
}
if (ping_args.interval->count > 0) {
config.interval_ms = (uint32_t)(ping_args.interval->dval[0] * 1000);
}
if (ping_args.data_size->count > 0) {
config.data_size = (uint32_t)(ping_args.data_size->ival[0]);
}
if (ping_args.count->count > 0) {
config.count = (uint32_t)(ping_args.count->ival[0]);
}
if (ping_args.tos->count > 0) {
config.tos = (uint32_t)(ping_args.tos->ival[0]);
}
if (ping_args.abort->count) {
esp_ping_stop(ping);
return 0;
}
// parse IP address
ip_addr_t target_addr;
struct addrinfo hint;
struct addrinfo *res = NULL;
memset(&hint, 0, sizeof(hint));
memset(&target_addr, 0, sizeof(target_addr));
/* convert domain name to IP address */
if (getaddrinfo(ping_args.host->sval[0], NULL, &hint, &res) != 0) {
printf("ping: unknown host %s\n", ping_args.host->sval[0]);
return 1;
}
if (res->ai_family == AF_INET) {
struct in_addr addr4 = ((struct sockaddr_in *) (res->ai_addr))->sin_addr;
inet_addr_to_ip4addr(ip_2_ip4(&target_addr), &addr4);
} else {
struct in6_addr addr6 = ((struct sockaddr_in6 *) (res->ai_addr))->sin6_addr;
inet6_addr_to_ip6addr(ip_2_ip6(&target_addr), &addr6);
}
freeaddrinfo(res);
config.target_addr = target_addr;
/* set callback functions */
esp_ping_callbacks_t cbs = {
.on_ping_success = cmd_ping_on_ping_success,
.on_ping_timeout = cmd_ping_on_ping_timeout,
.on_ping_end = cmd_ping_on_ping_end,
.cb_args = NULL
};
esp_ping_new_session(&config, &cbs, &ping);
esp_ping_start(ping);
return 0;
}
extern bool pm_is_waked(void);
extern bool pm_is_sleeping(void);
extern bool pm_is_dream(void);
static int wifi_cmd_get_ps_state(int argc, char **argv)
{
ESP_LOGW(TAG, "ps: awake:%d, sleep:%d, dream:%d", pm_is_waked(), pm_is_sleeping(), pm_is_dream());
return 0;
}
esp_err_t esp_netif_set_static_ip(esp_netif_t *netif_sta, uint32_t ip, uint32_t gw,
uint32_t netmask)
{
esp_netif_dhcpc_stop(netif_sta);
esp_netif_ip_info_t ip_info;
esp_netif_set_ip4_addr(&ip_info.ip, ip & 0xFF, (ip >> 8) & 0xFF, (ip >> 16) & 0xFF,
(ip >> 24) & 0xFF);
esp_netif_set_ip4_addr(&ip_info.gw, gw & 0xFF, (gw >> 8) & 0xFF, (gw >> 16) & 0xFF,
(gw >> 24) & 0xFF);
esp_netif_set_ip4_addr(&ip_info.netmask, netmask & 0xFF, (netmask >> 8) & 0xFF,
(netmask >> 16) & 0xFF, (netmask >> 24) & 0xFF);
esp_netif_set_ip_info(netif_sta, &ip_info);
return ESP_OK;
}
static int wifi_cmd_set_ip(int argc, char **argv)
{
uint32_t ip = 0, gw = 0, netmask = 0;
int nerrors = arg_parse(argc, argv, (void **) &static_ip_args);
if (nerrors != 0) {
arg_print_errors(stderr, static_ip_args.end, argv[0]);
return 0;
}
if (static_ip_args.ip->count != 0) {
ip = esp_ip4addr_aton(static_ip_args.ip->sval[0]);
}
if (static_ip_args.gw->count != 0) {
gw = esp_ip4addr_aton(static_ip_args.gw->sval[0]);
}
if (static_ip_args.netmask->count != 0) {
netmask = esp_ip4addr_aton(static_ip_args.netmask->sval[0]);
}
if (!ip || !netmask) {
return 0;
}
/* set static IP settings */
esp_netif_set_static_ip(netif_sta, ip, gw, netmask);
ESP_LOGD(TAG, "ip:%d.%d.%d.%d, gateway:%d.%d.%d.%d, netmask:%d.%d.%d.%d,", ip & 0xFF,
(ip >> 8) & 0xFF, (ip >> 16) & 0xFF, (ip >> 24) & 0xFF, gw & 0xFF, (gw >> 8) & 0xFF,
(gw >> 16) & 0xFF, (gw >> 24) & 0xFF, netmask & 0xFF, (netmask >> 8) & 0xFF,
(netmask >> 16) & 0xFF, (netmask >> 24) & 0xFF);
return 0;
}
void wifi_get_local_ip(esp_netif_ip_info_t *ip_info)
{
int bits = xEventGroupWaitBits(wifi_event_group, CONNECTED_BIT, 0, 1, 0);
esp_netif_t *netif = netif_ap;
wifi_mode_t mode;
esp_wifi_get_mode(&mode);
if (WIFI_MODE_STA == mode) {
bits = xEventGroupWaitBits(wifi_event_group, CONNECTED_BIT, 0, 1, 0);
if (bits & CONNECTED_BIT) {
netif = netif_sta;
} else {
ESP_LOGE(TAG, "sta has no IP");
}
}
esp_netif_get_ip_info(netif, ip_info);
}
static int wifi_cmd_query(int argc, char **argv)
{
wifi_config_t cfg;
wifi_bandwidth_t cbw;
uint8_t mac[6];
esp_netif_ip_info_t ip_info = { 0, };
wifi_mode_t mode;
esp_wifi_get_mode(&mode);
wifi_get_local_ip(&ip_info);
bool is_sta_disconnect = false;
char temp_ssid[33] = { 0 };
printf("Wireless info:");
if (WIFI_MODE_AP == mode) {
esp_wifi_get_config(WIFI_IF_AP, &cfg);
esp_wifi_get_bandwidth(WIFI_IF_AP, &cbw);
printf("\n");
printf("\tmode: ap\n");
strncpy(temp_ssid, (char *) cfg.ap.ssid, 32);
printf("\tssid: %s\n", temp_ssid);
printf("\tpassword: %s\n", cfg.ap.password);
printf("\tchannel: %d\n", cfg.ap.channel);
if (cbw == WIFI_BW_HT20) {
printf("\tcbw: 20 MHz\n");
} else if (cbw == WIFI_BW_HT40) {
printf("\tcbw: 40 MHz\n");
}
if (esp_wifi_get_mac(WIFI_IF_AP, mac) == ESP_OK) {
printf("\tap mac: "MACSTR, MAC2STR(mac));
printf("\n");
}
printf("\tip: %d.%d.%d.%d\n", ip_info.ip.addr & 0xFF, (ip_info.ip.addr >> 8) & 0xFF,
(ip_info.ip.addr >> 16) & 0xFF, (ip_info.ip.addr >> 24) & 0xFF);
printf("\tnetmask: %d.%d.%d.%d\n", ip_info.netmask.addr & 0xFF,
(ip_info.netmask.addr >> 8) & 0xFF, (ip_info.netmask.addr >> 16) & 0xFF,
(ip_info.netmask.addr >> 24) & 0xFF);
printf("\tgateway: %d.%d.%d.%d\n", ip_info.gw.addr & 0xFF, (ip_info.gw.addr >> 8) & 0xFF,
(ip_info.gw.addr >> 16) & 0xFF, (ip_info.gw.addr >> 24) & 0xFF);
printf("\n");
} else if (WIFI_MODE_STA == mode) {
int bits = xEventGroupWaitBits(wifi_event_group, CONNECTED_BIT, 0, 1, 0);
if (bits & CONNECTED_BIT) {
is_sta_disconnect = false;
esp_wifi_get_config(WIFI_IF_STA, &cfg);
esp_wifi_get_bandwidth(WIFI_IF_STA, &cbw);
printf("\n");
printf("\tmode: station\n");
printf("\tstatus: connected\n");
strncpy(temp_ssid, (char *) cfg.sta.ssid, 32);
printf("\tssid: %s\n", temp_ssid);
printf("\tbssid: "MACSTR, MAC2STR(cfg.sta.bssid));
printf("\n");
printf("\tchannel: %d\n", cfg.sta.channel);
uint16_t aid;
esp_wifi_sta_get_aid(&aid);
printf("\taid: %d\n", aid);
if (cfg.sta.pmf_cfg.capable) {
if (cfg.sta.pmf_cfg.required) {
printf("\tpmf: required\n");
} else {
printf("\tpmf: optional\n");
}
} else {
printf("\tpmf: disabled\n");
}
if (cbw == WIFI_BW_HT20) {
printf("\tcbw: 20 MHz\n");
} else if (cbw == WIFI_BW_HT40) {
printf("\tcbw: 40 MHz\n");
}
if (esp_wifi_get_mac(WIFI_IF_STA, mac) == ESP_OK) {
printf("\tsta mac: "MACSTR, MAC2STR(mac));
printf("\n");
}
printf("\tip: %d.%d.%d.%d\n", ip_info.ip.addr & 0xFF, (ip_info.ip.addr >> 8) & 0xFF,
(ip_info.ip.addr >> 16) & 0xFF, (ip_info.ip.addr >> 24) & 0xFF);
printf("\tnetmask: %d.%d.%d.%d\n", ip_info.netmask.addr & 0xFF,
(ip_info.netmask.addr >> 8) & 0xFF, (ip_info.netmask.addr >> 16) & 0xFF,
(ip_info.netmask.addr >> 24) & 0xFF);
printf("\tgateway: %d.%d.%d.%d\n", ip_info.gw.addr & 0xFF,
(ip_info.gw.addr >> 8) & 0xFF, (ip_info.gw.addr >> 16) & 0xFF,
(ip_info.gw.addr >> 24) & 0xFF);
printf("\n");
} else {
printf("\n");
printf("\tmode: disconnected\n");
is_sta_disconnect = true;
}
}
if (WIFI_MODE_NULL == mode || is_sta_disconnect) {
printf("\n");
if (WIFI_MODE_NULL == mode) {
printf("\tmode: null\n");
}
if (esp_wifi_get_mac(WIFI_IF_AP, mac) == ESP_OK) {
printf("\tap mac: "MACSTR, MAC2STR(mac));
printf("\n");
}
if (esp_wifi_get_mac(WIFI_IF_STA, mac) == ESP_OK) {
printf("\tsta mac: "MACSTR, MAC2STR(mac));
printf("\n");
}
return 0;
}
return 0;
}
static int wifi_cmd_proto(int argc, char **argv)
{
int nerrors = arg_parse(argc, argv, (void **)&proto_args);
if (nerrors != 0) {
arg_print_errors(stderr, proto_args.end, argv[0]);
return 1;
}
wifi_mode_t mode;
esp_wifi_get_mode(&mode);
int ifx = (WIFI_MODE_STA == mode) ? 0 : 1;
if (proto_args.proto->count) {
if (!strcmp(proto_args.proto->sval[0], "ax")) {
ESP_ERROR_CHECK(esp_wifi_set_protocol(ifx, WIFI_PROTOCOL_11B | WIFI_PROTOCOL_11G | WIFI_PROTOCOL_11N | WIFI_PROTOCOL_11AX));
printf("(%s)set to 11ax\n", (ifx == WIFI_IF_STA) ? "sta" : "ap");
} else if (!strcmp(proto_args.proto->sval[0], "bgn")) {
ESP_ERROR_CHECK(esp_wifi_set_protocol(ifx, WIFI_PROTOCOL_11B | WIFI_PROTOCOL_11G | WIFI_PROTOCOL_11N));
printf("(%s)set to bgn\n", (ifx == WIFI_IF_STA) ? "sta" : "ap");
} else if (!strcmp(proto_args.proto->sval[0], "bg")) {
ESP_ERROR_CHECK(esp_wifi_set_protocol(ifx, WIFI_PROTOCOL_11B | WIFI_PROTOCOL_11G));
printf("(%s)set to bg\n", (ifx == WIFI_IF_STA) ? "sta" : "ap");
} else {
ESP_ERROR_CHECK(esp_wifi_set_protocol(ifx, WIFI_PROTOCOL_11B));
printf("(%s)set to b\n", (ifx == WIFI_IF_STA) ? "sta" : "ap");
}
}
uint8_t protocol_bitmap = 0;
ESP_ERROR_CHECK(esp_wifi_get_protocol(ifx, &protocol_bitmap) );
if (protocol_bitmap & WIFI_PROTOCOL_11AX) {
printf("(%s)11ax\n", (ifx == WIFI_IF_STA) ? "sta" : "ap");
} else if (protocol_bitmap & WIFI_PROTOCOL_11N) {
printf("(%s)bgn\n", (ifx == WIFI_IF_STA) ? "sta" : "ap");
} else if (protocol_bitmap & WIFI_PROTOCOL_11G) {
printf("(%s)bg\n", (ifx == WIFI_IF_STA) ? "sta" : "ap");
} else if (protocol_bitmap & WIFI_PROTOCOL_11B) {
printf("(%s)b\n", (ifx == WIFI_IF_STA) ? "sta" : "ap");
}
return 0;
}
static int wifi_disconnect(int argc, char **argv)
{
wifi_mode_t mode;
esp_wifi_get_mode(&mode);
if (WIFI_MODE_AP == mode) {
// TODO
ESP_LOGI(TAG, "WIFI_MODE_AP, not support");
} else if (WIFI_MODE_STA == mode) {
esp_wifi_disconnect();
printf("disconnect\n");
} else {
ESP_LOGI(TAG, "NULL mode");
}
return 0;
}
static int wifi_cmd_inactive_time(int argc, char **argv)
{
int nerrors = arg_parse(argc, argv, (void **)&inactive_time_args);
if (nerrors != 0) {
arg_print_errors(stderr, inactive_time_args.end, argv[0]);
return 1;
}
esp_err_t err = ESP_OK;
wifi_mode_t mode;
esp_wifi_get_mode(&mode);
if ((mode & WIFI_MODE_AP) && inactive_time_args.val->count) {
err = esp_wifi_set_inactive_time(ESP_IF_WIFI_AP, inactive_time_args.val->ival[0]);
if (err != ESP_OK) {
ESP_LOGW(TAG, "set softAP inactive time to %d seconds, err:0x%x\n", inactive_time_args.val->ival[0], err);
} else {
ESP_LOGI(TAG, "set softAP inactive time to %d seconds, err:0x%x\n", inactive_time_args.val->ival[0]);
}
}
//WIFI_MODE_STA or WIFI_MODE_APSTA
if ((mode & WIFI_MODE_STA) && inactive_time_args.val->count) {
err = esp_wifi_set_inactive_time(ESP_IF_WIFI_STA, inactive_time_args.val->ival[0]);
if (err != ESP_OK) {
ESP_LOGW(TAG, "set STA inactive time to %d seconds, err:0x%x\n", inactive_time_args.val->ival[0], err);
} else {
ESP_LOGI(TAG, "set STA inactive time to %d seconds, err:0x%x\n", inactive_time_args.val->ival[0]);
}
}
uint16_t secs = 0;
esp_wifi_get_inactive_time(ESP_IF_WIFI_STA, &secs);
printf("inactive time: %d seconds\n", secs);
return 0;
}
static int wifi_cmd_sounding_rate(int argc, char **argv)
{
int nerrors = arg_parse(argc, argv, (void **)&wifi_sounding_rate_args);
if (nerrors != 0) {
arg_print_errors(stderr, wifi_sounding_rate_args.end, argv[0]);
return 1;
}
if (wifi_sounding_rate_args.format->count && wifi_sounding_rate_args.rate->count) {
if (wifi_sounding_rate_args.format->ival[0] == SIG_MODE_LEGACY) {
if (wifi_sounding_rate_args.rate->ival[0] < WIFI_PHY_RATE_MCS0_LGI &&
wifi_sounding_rate_args.rate->ival[0] >= 0) {
hal_he_set_bf_report_rate(SIG_MODE_LEGACY, wifi_sounding_rate_args.rate->ival[0]);
} else {
ESP_LOGW(TAG, "need correct legacy rate(0-%d)", WIFI_PHY_RATE_9M);
}
} else {
if (wifi_sounding_rate_args.rate->ival[0] >= WIFI_PHY_RATE_MCS0_LGI &&
wifi_sounding_rate_args.rate->ival[0] <= WIFI_PHY_RATE_MCS9_SGI) {
hal_he_set_bf_report_rate(wifi_sounding_rate_args.format->ival[0],
wifi_sounding_rate_args.rate->ival[0]);
} else {
ESP_LOGW(TAG, "need correct mcs(%d-%d)", WIFI_PHY_RATE_MCS0_LGI, WIFI_PHY_RATE_MCS9_SGI);
}
}
} else {
ESP_LOGW(TAG, "set rate fail");
}
return 0;
}
static int wifi_cmd_muedca(int argc, char **argv)
{
int nerrors = arg_parse(argc, argv, (void **)&muedca_args);
if (nerrors != 0) {
arg_print_errors(stderr, muedca_args.end, argv[0]);
return 1;
}
if (muedca_args.reset_timer->count) {
esp_wifi_sta_reset_muedca_timer(muedca_args.reset_timer->ival[0]);
}
uint8_t aci_bitmap = 0;
if (muedca_args.read_timer->count) {
aci_bitmap = muedca_args.read_timer->ival[0];
if (aci_bitmap & BIT(0)) {
dbg_read_muedca_timer(3);
}
if (aci_bitmap & BIT(1)) {
dbg_read_muedca_timer(2);
}
if (aci_bitmap & BIT(2)) {
dbg_read_muedca_timer(1);
}
if (aci_bitmap & BIT(3)) {
dbg_read_muedca_timer(0);
}
}
return 0;
}
static int wifi_cmd_set_tx_pwr(int argc, char **argv)
{
int nerrors = arg_parse(argc, argv, (void **)&tx_pwr_args);
if (nerrors != 0) {
arg_print_errors(stderr, tx_pwr_args.end, argv[0]);
return 1;
}
if (tx_pwr_args.mcs->count && tx_pwr_args.power->count) {
if (tx_pwr_args.mcs->ival[0] <= 9 && tx_pwr_args.mcs->ival[0] >= 0) {
if (tx_pwr_args.power->ival[0] >= -13 &&
tx_pwr_args.power->ival[0] <= 20) {
esp_test_set_tx_mcs_pwr(tx_pwr_args.mcs->ival[0] + WIFI_PHY_RATE_MCS0_LGI, tx_pwr_args.power->ival[0]);
ESP_LOGW(TAG, "set MCS%d TX PWR to %d", tx_pwr_args.mcs->ival[0], tx_pwr_args.power->ival[0]);
} else if (tx_pwr_args.power->ival[0] == 0xff) {
esp_test_set_tx_mcs_pwr(tx_pwr_args.mcs->ival[0] + WIFI_PHY_RATE_MCS0_LGI, tx_pwr_args.power->ival[0]);
ESP_LOGW(TAG, "set MCS%d TX PWR to default value", tx_pwr_args.mcs->ival[0], tx_pwr_args.power->ival[0]);
}
} else {
ESP_LOGW(TAG, "Set TX power fail, MCS should in range [0,9], power should in range [-13, 30] or set 0xFF for default");
}
}
return 0;
}
static int wifi_read_avgsnr(int argc, char **argv)
{
wifi_mode_t mode;
esp_wifi_get_mode(&mode);
if (WIFI_MODE_AP == mode) {
// TODO
ESP_LOGI(TAG, "WIFI_MODE_AP, not support");
} else if (WIFI_MODE_STA == mode || WIFI_MODE_APSTA == mode) {
printf("%.2f\n", esp_test_get_bfr_avgsnr());
} else {
ESP_LOGI(TAG, "NULL mode");
}
return 0;
}
void register_wifi_cmd(void)
{
/* mac */
const esp_console_cmd_t maccmd = {
.command = "mac",
.help = "get mac",
.hint = NULL,
.func = &wifi_cmd_get_mac,
};
ESP_ERROR_CHECK(esp_console_cmd_register(&maccmd));
/* disable edca */
edca_args.enable = arg_int0("e", "enable", "[enable]", "enable edca tx");
edca_args.txq = arg_int0("q", "txq", "[txq]", "enable edca txq");
edca_args.end = arg_end(1);
const esp_console_cmd_t edca_cmd = {
.command = "edca",
.help = "enable/disable edca",
.hint = NULL,
.func = &wifi_cmd_edca_tx,
};
ESP_ERROR_CHECK(esp_console_cmd_register(&edca_cmd));
/* read/write hw registers */
reg_rw_args.read = arg_dbl0("r", NULL, "<read_addr>", "read register address");
reg_rw_args.write = arg_dbl0("w", NULL, "<write_addr>", "write register address");
reg_rw_args.value = arg_dbl0("v", NULL, "<value>", "write value");
reg_rw_args.end = arg_end(2);
const esp_console_cmd_t reg_rw_cmd = {
.command = "reg",
.help = "r/w hw register",
.hint = NULL,
.func = &wifi_cmd_reg_rw,
.argtable = &reg_rw_args,
};
ESP_ERROR_CHECK(esp_console_cmd_register(&reg_rw_cmd));
/* om control */
omctrl_args.ul_mu_disable = arg_dbl0("u", "ulmu", "[ulmu]", "disable ul mu");
omctrl_args.ul_mu_data_disable = arg_dbl0("d", "uldata", "[uldata]", "disable ul mu data");
omctrl_args.ersu_disable = arg_dbl0("e", "ersu", "[ersu]", "disable ersu");
omctrl_args.report = arg_dbl0("r", "report", "[report]", "report om control to ap");
omctrl_args.resounding = arg_dbl0("s", "resounding", "[resounding]", "DL MU-MIMO resound Recoummendation");
omctrl_args.end = arg_end(1);
const esp_console_cmd_t omctrl_cmd = {
.command = "omc",
.help = "om control",
.hint = NULL,
.func = &wifi_cmd_set_omc,
.argtable = &omctrl_args,
};
ESP_ERROR_CHECK(esp_console_cmd_register(&omctrl_cmd));
/* stbc */
stbc_args.disable = arg_dbl0("d", "disable", "[disable]", "disable stbc");
stbc_args.end = arg_end(1);
const esp_console_cmd_t stbc_cmd = {
.command = "stbc",
.help = "configure stbc",
.hint = NULL,
.func = &wifi_cmd_stbc,
.argtable = &stbc_args
};
ESP_ERROR_CHECK(esp_console_cmd_register(&stbc_cmd));
/* su bmfmee */
bmfmee_args.disable = arg_dbl0("d", "disable", "[disable]", "disable bmfmee");
bmfmee_args.end = arg_end(1);
const esp_console_cmd_t bmfmee_cmd = {
.command = "bmfmee",
.help = "configure su bmfmee",
.hint = NULL,
.func = &wifi_cmd_su_bmfmee,
.argtable = &bmfmee_args
};
ESP_ERROR_CHECK(esp_console_cmd_register(&bmfmee_cmd));
/* set trigger frame mac padding duration */
tf_padding_args.tf_padding = arg_dbl0("p", "padding", "[padding]", "set trigger frame mac padding duration");
tf_padding_args.end = arg_end(1);
const esp_console_cmd_t tf_padding_cmd = {
.command = "tf",
.help = "set padding",
.hint = NULL,
.func = &wifi_cmd_set_tf_padding,
.argtable = &tf_padding_args,
};
ESP_ERROR_CHECK(esp_console_cmd_register(&tf_padding_cmd));
/* ignore cca */
cca_args.enable = arg_dbl0("e", "enable", "[enable]", "enable ignore cca");
cca_args.end = arg_end(1);
const esp_console_cmd_t cca_cmd = {
.command = "cca",
.help = "ignore cca",
.hint = NULL,
.func = &wifi_cmd_ignore_cca,
.argtable = &cca_args,
};
ESP_ERROR_CHECK(esp_console_cmd_register(&cca_cmd));
/* dump tx tb ppdu */
const esp_console_cmd_t tb_cmd = {
.command = "tb",
.help = "dump tx tb ppdu",
.hint = NULL,
.func = &wifi_cmd_tb,
};
ESP_ERROR_CHECK(esp_console_cmd_register(&tb_cmd));
/* set ps type */
const esp_console_cmd_t ps_cmd = {
.command = "ps",
.help = "set ps type",
.hint = NULL,
.func = &wifi_cmd_set_ps_type,
};
ESP_ERROR_CHECK(esp_console_cmd_register(&ps_cmd));
/* ping test */
ping_args.timeout = arg_dbl0("W", "timeout", "<t>", "Time to wait for a response, in seconds");
ping_args.interval = arg_dbl0("i", "interval", "<t>", "Wait interval seconds between sending each packet");
ping_args.data_size = arg_int0("s", "size", "<n>", "Specify the number of data bytes to be sent");
ping_args.count = arg_int0("c", "count", "<n>", "Stop after sending count packets");
ping_args.tos = arg_int0("Q", "tos", "<n>", "Set Type of Service related bits in IP datagrams");
ping_args.host = arg_str0(NULL, NULL, "[host]", "Host address");
ping_args.abort = arg_lit0("a", "abort", "abort");
ping_args.end = arg_end(1);
const esp_console_cmd_t ping_cmd = {
.command = "ping",
.help = "send ICMP ECHO_REQUEST to network hosts",
.hint = NULL,
.func = &do_ping_cmd,
.argtable = &ping_args
};
ESP_ERROR_CHECK(esp_console_cmd_register(&ping_cmd));
/* get ps state */
const esp_console_cmd_t pss_cmd = {
.command = "pss",
.help = "get ps state",
.hint = NULL,
.func = &wifi_cmd_get_ps_state,
};
ESP_ERROR_CHECK(esp_console_cmd_register(&pss_cmd));
/* ip */
static_ip_args.ip = arg_str0("i", "ip", "<ip>", "ip address");
static_ip_args.gw = arg_str0("g", "gateway", "<gw>", "gateway address");
static_ip_args.netmask = arg_str0("n", "netmask", "<netmask>", "netmask addess");
static_ip_args.end = arg_end(1);
const esp_console_cmd_t static_ip_cmd = {
.command = "ip",
.help = "ip settings",
.hint = NULL,
.func = &wifi_cmd_set_ip,
.argtable = &static_ip_args,
};
ESP_ERROR_CHECK(esp_console_cmd_register(&static_ip_cmd));
/* query */
const esp_console_cmd_t query_cmd = {
.command = "query",
.help = "query WiFi info",
.hint = NULL,
.func = &wifi_cmd_query,
};
ESP_ERROR_CHECK(esp_console_cmd_register(&query_cmd));
/* proto */
proto_args.proto = arg_str0(NULL, NULL, "<proto>", "proto [ax,bgn,bg,b]");
proto_args.end = arg_end(1);
const esp_console_cmd_t proto_cmd = {
.command = "proto",
.help = "set wifi protocol",
.hint = NULL,
.func = &wifi_cmd_proto,
.argtable = &proto_args
};
ESP_ERROR_CHECK(esp_console_cmd_register(&proto_cmd));
/* disconnect */
const esp_console_cmd_t disconnect_cmd = {
.command = "disconnect",
.help = "disconnect",
.hint = NULL,
.func = &wifi_disconnect,
};
ESP_ERROR_CHECK(esp_console_cmd_register(&disconnect_cmd));
/* inactive time */
inactive_time_args.val = arg_int0("t", "time", "time", "set inactive time, in seconds");
inactive_time_args.end = arg_end(1);
const esp_console_cmd_t inactive_cmd = {
.command = "inactive",
.help = "inactive time, unit: seconds",
.hint = NULL,
.func = &wifi_cmd_inactive_time,
.argtable = &inactive_time_args,
};
ESP_ERROR_CHECK(esp_console_cmd_register(&inactive_cmd));
/* set beamforming report rate */
wifi_sounding_rate_args.format = arg_int0("f", "format", "format", "set format");
wifi_sounding_rate_args.rate = arg_int0("r", "rate", "rate", "set rate");
wifi_sounding_rate_args.end = arg_end(1);
const esp_console_cmd_t sounding_rate_cmd = {
.command = "sounding",
.help = "set beamforming report rate",
.hint = NULL,
.func = &wifi_cmd_sounding_rate,
.argtable = &wifi_sounding_rate_args,
};
ESP_ERROR_CHECK(esp_console_cmd_register(&sounding_rate_cmd));
/* muedca */
muedca_args.reset_timer = arg_int0("r", NULL, "reset timer", "reset muedca timer");
muedca_args.read_timer = arg_int0("d", NULL, "read timer", "read muedca timer");
muedca_args.end = arg_end(1);
const esp_console_cmd_t reg_muedca_cmd = {
.command = "muedca",
.help = "Reset/Read muedca timer",
.hint = NULL,
.func = &wifi_cmd_muedca,
.argtable = &muedca_args,
};
ESP_ERROR_CHECK(esp_console_cmd_register(&reg_muedca_cmd));
/* tx_pwr */
tx_pwr_args.mcs = arg_int0("m", NULL, "[0, 9]", "force tx power on MCSX");
tx_pwr_args.power = arg_int0("p", NULL, "[-13, 20]", "set max power, set 0xFF for default");
tx_pwr_args.end = arg_end(1);
const esp_console_cmd_t reg_tx_pwr_cmd = {
.command = "txpwr",
.help = "force tx power on MCSX",
.hint = NULL,
.func = &wifi_cmd_set_tx_pwr,
.argtable = &tx_pwr_args,
};
ESP_ERROR_CHECK(esp_console_cmd_register(&reg_tx_pwr_cmd));
/* avgSNR */
const esp_console_cmd_t avgsnr_cmd = {
.command = "avgsnr",
.help = "show avgSnr in beamforming memory",
.hint = NULL,
.func = &wifi_read_avgsnr,
};
ESP_ERROR_CHECK(esp_console_cmd_register(&avgsnr_cmd));
}
#else
void register_wifi_cmd(void)
{
;
}
#endif /* CONFIG_SOC_WIFI_HE_SUPPORT */